/* * This file was generated automatically by gen-mterp.py for 'mips'. * * --> DO NOT EDIT <-- */ /* File: mips/header.S */ /* * Copyright (C) 2016 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /* Art assembly interpreter notes: First validate assembly code by implementing ExecuteXXXImpl() style body (doesn't handle invoke, allows higher-level code to create frame & shadow frame. Once that's working, support direct entry code & eliminate shadow frame (and excess locals allocation. Some (hopefully) temporary ugliness. We'll treat rFP as pointing to the base of the vreg array within the shadow frame. Access the other fields, dex_pc_, method_ and number_of_vregs_ via negative offsets. For now, we'll continue the shadow frame mechanism of double-storing object references - via rFP & number_of_vregs_. */ #include "asm_support.h" #if (__mips==32) && (__mips_isa_rev>=2) #define MIPS32REVGE2 /* mips32r2 and greater */ #if (__mips==32) && (__mips_isa_rev>=5) #define FPU64 /* 64 bit FPU */ #if (__mips==32) && (__mips_isa_rev>=6) #define MIPS32REVGE6 /* mips32r6 and greater */ #endif #endif #endif /* MIPS definitions and declarations reg nick purpose s0 rPC interpreted program counter, used for fetching instructions s1 rFP interpreted frame pointer, used for accessing locals and args s2 rSELF self (Thread) pointer s3 rIBASE interpreted instruction base pointer, used for computed goto s4 rINST first 16-bit code unit of current instruction s5 rOBJ object pointer s6 rREFS base of object references in shadow frame (ideally, we'll get rid of this later). s7 rTEMP used as temp storage that can survive a function call s8 rPROFILE branch profiling countdown */ /* single-purpose registers, given names for clarity */ #define rPC s0 #define rFP s1 #define rSELF s2 #define rIBASE s3 #define rINST s4 #define rOBJ s5 #define rREFS s6 #define rTEMP s7 #define rPROFILE s8 #define rARG0 a0 #define rARG1 a1 #define rARG2 a2 #define rARG3 a3 #define rRESULT0 v0 #define rRESULT1 v1 /* GP register definitions */ #define zero $0 /* always zero */ #define AT $at /* assembler temp */ #define v0 $2 /* return value */ #define v1 $3 #define a0 $4 /* argument registers */ #define a1 $5 #define a2 $6 #define a3 $7 #define t0 $8 /* temp registers (not saved across subroutine calls) */ #define t1 $9 #define t2 $10 #define t3 $11 #define t4 $12 #define t5 $13 #define t6 $14 #define t7 $15 #define ta0 $12 /* alias */ #define ta1 $13 #define ta2 $14 #define ta3 $15 #define s0 $16 /* saved across subroutine calls (callee saved) */ #define s1 $17 #define s2 $18 #define s3 $19 #define s4 $20 #define s5 $21 #define s6 $22 #define s7 $23 #define t8 $24 /* two more temp registers */ #define t9 $25 #define k0 $26 /* kernel temporary */ #define k1 $27 #define gp $28 /* global pointer */ #define sp $29 /* stack pointer */ #define s8 $30 /* one more callee saved */ #define ra $31 /* return address */ /* FP register definitions */ #define fv0 $f0 #define fv0f $f1 #define fv1 $f2 #define fv1f $f3 #define fa0 $f12 #define fa0f $f13 #define fa1 $f14 #define fa1f $f15 #define ft0 $f4 #define ft0f $f5 #define ft1 $f6 #define ft1f $f7 #define ft2 $f8 #define ft2f $f9 #define ft3 $f10 #define ft3f $f11 #define ft4 $f16 #define ft4f $f17 #define ft5 $f18 #define ft5f $f19 #define fs0 $f20 #define fs0f $f21 #define fs1 $f22 #define fs1f $f23 #define fs2 $f24 #define fs2f $f25 #define fs3 $f26 #define fs3f $f27 #define fs4 $f28 #define fs4f $f29 #define fs5 $f30 #define fs5f $f31 #ifndef MIPS32REVGE6 #define fcc0 $fcc0 #define fcc1 $fcc1 #endif #ifdef MIPS32REVGE2 #define SEB(rd, rt) \ seb rd, rt #define SEH(rd, rt) \ seh rd, rt #define INSERT_HIGH_HALF(rd_lo, rt_hi) \ ins rd_lo, rt_hi, 16, 16 #else #define SEB(rd, rt) \ sll rd, rt, 24; \ sra rd, rd, 24 #define SEH(rd, rt) \ sll rd, rt, 16; \ sra rd, rd, 16 /* Clobbers rt_hi on pre-R2. */ #define INSERT_HIGH_HALF(rd_lo, rt_hi) \ sll rt_hi, rt_hi, 16; \ or rd_lo, rt_hi #endif #ifdef FPU64 #define MOVE_TO_FPU_HIGH(r, flo, fhi) \ mthc1 r, flo #else #define MOVE_TO_FPU_HIGH(r, flo, fhi) \ mtc1 r, fhi #endif #ifdef MIPS32REVGE6 #define JR(rt) \ jic rt, 0 #define LSA(rd, rs, rt, sa) \ .if sa; \ lsa rd, rs, rt, sa; \ .else; \ addu rd, rs, rt; \ .endif #else #define JR(rt) \ jalr zero, rt #define LSA(rd, rs, rt, sa) \ .if sa; \ .set push; \ .set noat; \ sll AT, rs, sa; \ addu rd, AT, rt; \ .set pop; \ .else; \ addu rd, rs, rt; \ .endif #endif /* * Instead of holding a pointer to the shadow frame, we keep rFP at the base of the vregs. So, * to access other shadow frame fields, we need to use a backwards offset. Define those here. */ #define OFF_FP(a) (a - SHADOWFRAME_VREGS_OFFSET) #define OFF_FP_NUMBER_OF_VREGS OFF_FP(SHADOWFRAME_NUMBER_OF_VREGS_OFFSET) #define OFF_FP_DEX_PC OFF_FP(SHADOWFRAME_DEX_PC_OFFSET) #define OFF_FP_LINK OFF_FP(SHADOWFRAME_LINK_OFFSET) #define OFF_FP_METHOD OFF_FP(SHADOWFRAME_METHOD_OFFSET) #define OFF_FP_RESULT_REGISTER OFF_FP(SHADOWFRAME_RESULT_REGISTER_OFFSET) #define OFF_FP_DEX_PC_PTR OFF_FP(SHADOWFRAME_DEX_PC_PTR_OFFSET) #define OFF_FP_CODE_ITEM OFF_FP(SHADOWFRAME_CODE_ITEM_OFFSET) #define OFF_FP_SHADOWFRAME OFF_FP(0) #define MTERP_PROFILE_BRANCHES 1 #define MTERP_LOGGING 0 /* * "export" the PC to dex_pc field in the shadow frame, f/b/o future exception objects. Must * be done *before* something throws. * * It's okay to do this more than once. * * NOTE: the fast interpreter keeps track of dex pc as a direct pointer to the mapped * dex byte codes. However, the rest of the runtime expects dex pc to be an instruction * offset into the code_items_[] array. For effiency, we will "export" the * current dex pc as a direct pointer using the EXPORT_PC macro, and rely on GetDexPC * to convert to a dex pc when needed. */ #define EXPORT_PC() \ sw rPC, OFF_FP_DEX_PC_PTR(rFP) #define EXPORT_DEX_PC(tmp) \ lw tmp, OFF_FP_CODE_ITEM(rFP); \ sw rPC, OFF_FP_DEX_PC_PTR(rFP); \ addu tmp, CODEITEM_INSNS_OFFSET; \ subu tmp, rPC, tmp; \ sra tmp, tmp, 1; \ sw tmp, OFF_FP_DEX_PC(rFP) /* * Fetch the next instruction from rPC into rINST. Does not advance rPC. */ #define FETCH_INST() lhu rINST, (rPC) /* * Fetch the next instruction from the specified offset. Advances rPC * to point to the next instruction. "_count" is in 16-bit code units. * * This must come AFTER anything that can throw an exception, or the * exception catch may miss. (This also implies that it must come after * EXPORT_PC().) */ #define FETCH_ADVANCE_INST(_count) \ lhu rINST, ((_count)*2)(rPC); \ addu rPC, rPC, ((_count) * 2) /* * Similar to FETCH_ADVANCE_INST, but does not update rPC. Used to load * rINST ahead of possible exception point. Be sure to manually advance rPC * later. */ #define PREFETCH_INST(_count) lhu rINST, ((_count)*2)(rPC) /* Advance rPC by some number of code units. */ #define ADVANCE(_count) addu rPC, rPC, ((_count) * 2) /* * Fetch the next instruction from an offset specified by rd. Updates * rPC to point to the next instruction. "rd" must specify the distance * in bytes, *not* 16-bit code units, and may be a signed value. */ #define FETCH_ADVANCE_INST_RB(rd) \ addu rPC, rPC, rd; \ lhu rINST, (rPC) /* * Fetch a half-word code unit from an offset past the current PC. The * "_count" value is in 16-bit code units. Does not advance rPC. * * The "_S" variant works the same but treats the value as signed. */ #define FETCH(rd, _count) lhu rd, ((_count) * 2)(rPC) #define FETCH_S(rd, _count) lh rd, ((_count) * 2)(rPC) /* * Fetch one byte from an offset past the current PC. Pass in the same * "_count" as you would for FETCH, and an additional 0/1 indicating which * byte of the halfword you want (lo/hi). */ #define FETCH_B(rd, _count, _byte) lbu rd, ((_count) * 2 + _byte)(rPC) /* * Put the instruction's opcode field into the specified register. */ #define GET_INST_OPCODE(rd) and rd, rINST, 0xFF /* * Transform opcode into branch target address. */ #define GET_OPCODE_TARGET(rd) \ sll rd, rd, 7; \ addu rd, rIBASE, rd /* * Begin executing the opcode in rd. */ #define GOTO_OPCODE(rd) \ GET_OPCODE_TARGET(rd); \ JR(rd) /* * Get/set the 32-bit value from a Dalvik register. */ #define GET_VREG(rd, rix) LOAD_eas2(rd, rFP, rix) #define GET_VREG_F(rd, rix) \ .set noat; \ EAS2(AT, rFP, rix); \ l.s rd, (AT); \ .set at #ifdef MIPS32REVGE6 #define SET_VREG(rd, rix) \ lsa t8, rix, rFP, 2; \ sw rd, 0(t8); \ lsa t8, rix, rREFS, 2; \ sw zero, 0(t8) #else #define SET_VREG(rd, rix) \ .set noat; \ sll AT, rix, 2; \ addu t8, rFP, AT; \ sw rd, 0(t8); \ addu t8, rREFS, AT; \ .set at; \ sw zero, 0(t8) #endif #ifdef MIPS32REVGE6 #define SET_VREG_OBJECT(rd, rix) \ lsa t8, rix, rFP, 2; \ sw rd, 0(t8); \ lsa t8, rix, rREFS, 2; \ sw rd, 0(t8) #else #define SET_VREG_OBJECT(rd, rix) \ .set noat; \ sll AT, rix, 2; \ addu t8, rFP, AT; \ sw rd, 0(t8); \ addu t8, rREFS, AT; \ .set at; \ sw rd, 0(t8) #endif #ifdef MIPS32REVGE6 #define SET_VREG64(rlo, rhi, rix) \ lsa t8, rix, rFP, 2; \ sw rlo, 0(t8); \ sw rhi, 4(t8); \ lsa t8, rix, rREFS, 2; \ sw zero, 0(t8); \ sw zero, 4(t8) #else #define SET_VREG64(rlo, rhi, rix) \ .set noat; \ sll AT, rix, 2; \ addu t8, rFP, AT; \ sw rlo, 0(t8); \ sw rhi, 4(t8); \ addu t8, rREFS, AT; \ .set at; \ sw zero, 0(t8); \ sw zero, 4(t8) #endif #ifdef MIPS32REVGE6 #define SET_VREG_F(rd, rix) \ lsa t8, rix, rFP, 2; \ s.s rd, 0(t8); \ lsa t8, rix, rREFS, 2; \ sw zero, 0(t8) #else #define SET_VREG_F(rd, rix) \ .set noat; \ sll AT, rix, 2; \ addu t8, rFP, AT; \ s.s rd, 0(t8); \ addu t8, rREFS, AT; \ .set at; \ sw zero, 0(t8) #endif #ifdef MIPS32REVGE6 #define SET_VREG64_F(rlo, rhi, rix) \ lsa t8, rix, rFP, 2; \ .set noat; \ mfhc1 AT, rlo; \ s.s rlo, 0(t8); \ sw AT, 4(t8); \ .set at; \ lsa t8, rix, rREFS, 2; \ sw zero, 0(t8); \ sw zero, 4(t8) #elif defined(FPU64) #define SET_VREG64_F(rlo, rhi, rix) \ .set noat; \ sll AT, rix, 2; \ addu t8, rREFS, AT; \ sw zero, 0(t8); \ sw zero, 4(t8); \ addu t8, rFP, AT; \ mfhc1 AT, rlo; \ sw AT, 4(t8); \ .set at; \ s.s rlo, 0(t8) #else #define SET_VREG64_F(rlo, rhi, rix) \ .set noat; \ sll AT, rix, 2; \ addu t8, rFP, AT; \ s.s rlo, 0(t8); \ s.s rhi, 4(t8); \ addu t8, rREFS, AT; \ .set at; \ sw zero, 0(t8); \ sw zero, 4(t8) #endif /* Combination of the SET_VREG and GOTO_OPCODE functions to save 1 instruction */ #ifdef MIPS32REVGE6 #define SET_VREG_GOTO(rd, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ lsa t8, rix, rFP, 2; \ sw rd, 0(t8); \ lsa t8, rix, rREFS, 2; \ jalr zero, dst; \ sw zero, 0(t8); \ .set reorder #else #define SET_VREG_GOTO(rd, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ .set noat; \ sll AT, rix, 2; \ addu t8, rFP, AT; \ sw rd, 0(t8); \ addu t8, rREFS, AT; \ .set at; \ jalr zero, dst; \ sw zero, 0(t8); \ .set reorder #endif /* Combination of the SET_VREG_OBJECT and GOTO_OPCODE functions to save 1 instruction */ #ifdef MIPS32REVGE6 #define SET_VREG_OBJECT_GOTO(rd, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ lsa t8, rix, rFP, 2; \ sw rd, 0(t8); \ lsa t8, rix, rREFS, 2; \ jalr zero, dst; \ sw rd, 0(t8); \ .set reorder #else #define SET_VREG_OBJECT_GOTO(rd, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ .set noat; \ sll AT, rix, 2; \ addu t8, rFP, AT; \ sw rd, 0(t8); \ addu t8, rREFS, AT; \ .set at; \ jalr zero, dst; \ sw rd, 0(t8); \ .set reorder #endif /* Combination of the SET_VREG64 and GOTO_OPCODE functions to save 1 instruction */ #ifdef MIPS32REVGE6 #define SET_VREG64_GOTO(rlo, rhi, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ lsa t8, rix, rFP, 2; \ sw rlo, 0(t8); \ sw rhi, 4(t8); \ lsa t8, rix, rREFS, 2; \ sw zero, 0(t8); \ jalr zero, dst; \ sw zero, 4(t8); \ .set reorder #else #define SET_VREG64_GOTO(rlo, rhi, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ .set noat; \ sll AT, rix, 2; \ addu t8, rFP, AT; \ sw rlo, 0(t8); \ sw rhi, 4(t8); \ addu t8, rREFS, AT; \ .set at; \ sw zero, 0(t8); \ jalr zero, dst; \ sw zero, 4(t8); \ .set reorder #endif /* Combination of the SET_VREG_F and GOTO_OPCODE functions to save 1 instruction */ #ifdef MIPS32REVGE6 #define SET_VREG_F_GOTO(rd, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ lsa t8, rix, rFP, 2; \ s.s rd, 0(t8); \ lsa t8, rix, rREFS, 2; \ jalr zero, dst; \ sw zero, 0(t8); \ .set reorder #else #define SET_VREG_F_GOTO(rd, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ .set noat; \ sll AT, rix, 2; \ addu t8, rFP, AT; \ s.s rd, 0(t8); \ addu t8, rREFS, AT; \ .set at; \ jalr zero, dst; \ sw zero, 0(t8); \ .set reorder #endif /* Combination of the SET_VREG64_F and GOTO_OPCODE functions to save 1 instruction */ #ifdef MIPS32REVGE6 #define SET_VREG64_F_GOTO(rlo, rhi, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ lsa t8, rix, rFP, 2; \ .set noat; \ mfhc1 AT, rlo; \ s.s rlo, 0(t8); \ sw AT, 4(t8); \ .set at; \ lsa t8, rix, rREFS, 2; \ sw zero, 0(t8); \ jalr zero, dst; \ sw zero, 4(t8); \ .set reorder #elif defined(FPU64) #define SET_VREG64_F_GOTO(rlo, rhi, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ .set noat; \ sll AT, rix, 2; \ addu t8, rREFS, AT; \ sw zero, 0(t8); \ sw zero, 4(t8); \ addu t8, rFP, AT; \ mfhc1 AT, rlo; \ sw AT, 4(t8); \ .set at; \ jalr zero, dst; \ s.s rlo, 0(t8); \ .set reorder #else #define SET_VREG64_F_GOTO(rlo, rhi, rix, dst) \ .set noreorder; \ GET_OPCODE_TARGET(dst); \ .set noat; \ sll AT, rix, 2; \ addu t8, rFP, AT; \ s.s rlo, 0(t8); \ s.s rhi, 4(t8); \ addu t8, rREFS, AT; \ .set at; \ sw zero, 0(t8); \ jalr zero, dst; \ sw zero, 4(t8); \ .set reorder #endif #define GET_OPA(rd) srl rd, rINST, 8 #ifdef MIPS32REVGE2 #define GET_OPA4(rd) ext rd, rINST, 8, 4 #else #define GET_OPA4(rd) GET_OPA(rd); and rd, 0xf #endif #define GET_OPB(rd) srl rd, rINST, 12 /* * Form an Effective Address rd = rbase + roff<<shift; * Uses reg AT on pre-R6. */ #define EASN(rd, rbase, roff, shift) LSA(rd, roff, rbase, shift) #define EAS1(rd, rbase, roff) EASN(rd, rbase, roff, 1) #define EAS2(rd, rbase, roff) EASN(rd, rbase, roff, 2) #define EAS3(rd, rbase, roff) EASN(rd, rbase, roff, 3) #define EAS4(rd, rbase, roff) EASN(rd, rbase, roff, 4) #define LOAD_eas2(rd, rbase, roff) \ .set noat; \ EAS2(AT, rbase, roff); \ lw rd, 0(AT); \ .set at #define STORE_eas2(rd, rbase, roff) \ .set noat; \ EAS2(AT, rbase, roff); \ sw rd, 0(AT); \ .set at #define LOAD_RB_OFF(rd, rbase, off) lw rd, off(rbase) #define STORE_RB_OFF(rd, rbase, off) sw rd, off(rbase) #define STORE64_off(rlo, rhi, rbase, off) \ sw rlo, off(rbase); \ sw rhi, (off+4)(rbase) #define LOAD64_off(rlo, rhi, rbase, off) \ lw rlo, off(rbase); \ lw rhi, (off+4)(rbase) #define STORE64(rlo, rhi, rbase) STORE64_off(rlo, rhi, rbase, 0) #define LOAD64(rlo, rhi, rbase) LOAD64_off(rlo, rhi, rbase, 0) #ifdef FPU64 #define STORE64_off_F(rlo, rhi, rbase, off) \ s.s rlo, off(rbase); \ .set noat; \ mfhc1 AT, rlo; \ sw AT, (off+4)(rbase); \ .set at #define LOAD64_off_F(rlo, rhi, rbase, off) \ l.s rlo, off(rbase); \ .set noat; \ lw AT, (off+4)(rbase); \ mthc1 AT, rlo; \ .set at #else #define STORE64_off_F(rlo, rhi, rbase, off) \ s.s rlo, off(rbase); \ s.s rhi, (off+4)(rbase) #define LOAD64_off_F(rlo, rhi, rbase, off) \ l.s rlo, off(rbase); \ l.s rhi, (off+4)(rbase) #endif #define STORE64_F(rlo, rhi, rbase) STORE64_off_F(rlo, rhi, rbase, 0) #define LOAD64_F(rlo, rhi, rbase) LOAD64_off_F(rlo, rhi, rbase, 0) #define LOAD_base_offMirrorArray_length(rd, rbase) LOAD_RB_OFF(rd, rbase, MIRROR_ARRAY_LENGTH_OFFSET) #define STACK_STORE(rd, off) sw rd, off(sp) #define STACK_LOAD(rd, off) lw rd, off(sp) #define CREATE_STACK(n) subu sp, sp, n #define DELETE_STACK(n) addu sp, sp, n #define LOAD_ADDR(dest, addr) la dest, addr #define LOAD_IMM(dest, imm) li dest, imm #define MOVE_REG(dest, src) move dest, src #define STACK_SIZE 128 #define STACK_OFFSET_ARG04 16 #define STACK_OFFSET_ARG05 20 #define STACK_OFFSET_ARG06 24 #define STACK_OFFSET_ARG07 28 #define STACK_OFFSET_GP 84 #define JAL(n) jal n #define BAL(n) bal n /* * FP register usage restrictions: * 1) We don't use the callee save FP registers so we don't have to save them. * 2) We don't use the odd FP registers so we can share code with mips32r6. */ #define STACK_STORE_FULL() CREATE_STACK(STACK_SIZE); \ STACK_STORE(ra, 124); \ STACK_STORE(s8, 120); \ STACK_STORE(s0, 116); \ STACK_STORE(s1, 112); \ STACK_STORE(s2, 108); \ STACK_STORE(s3, 104); \ STACK_STORE(s4, 100); \ STACK_STORE(s5, 96); \ STACK_STORE(s6, 92); \ STACK_STORE(s7, 88); #define STACK_LOAD_FULL() STACK_LOAD(gp, STACK_OFFSET_GP); \ STACK_LOAD(s7, 88); \ STACK_LOAD(s6, 92); \ STACK_LOAD(s5, 96); \ STACK_LOAD(s4, 100); \ STACK_LOAD(s3, 104); \ STACK_LOAD(s2, 108); \ STACK_LOAD(s1, 112); \ STACK_LOAD(s0, 116); \ STACK_LOAD(s8, 120); \ STACK_LOAD(ra, 124); \ DELETE_STACK(STACK_SIZE) #define REFRESH_IBASE() \ lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) /* Constants for float/double_to_int/long conversions */ #define INT_MIN 0x80000000 #define INT_MIN_AS_FLOAT 0xCF000000 #define INT_MIN_AS_DOUBLE_HIGH 0xC1E00000 #define LONG_MIN_HIGH 0x80000000 #define LONG_MIN_AS_FLOAT 0xDF000000 #define LONG_MIN_AS_DOUBLE_HIGH 0xC3E00000 /* File: mips/entry.S */ /* * Copyright (C) 2016 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /* * Interpreter entry point. */ .text .align 2 .global ExecuteMterpImpl .ent ExecuteMterpImpl .frame sp, STACK_SIZE, ra /* * On entry: * a0 Thread* self * a1 code_item * a2 ShadowFrame * a3 JValue* result_register * */ ExecuteMterpImpl: .set noreorder .cpload t9 .set reorder /* Save to the stack. Frame size = STACK_SIZE */ STACK_STORE_FULL() /* This directive will make sure all subsequent jal restore gp at a known offset */ .cprestore STACK_OFFSET_GP /* Remember the return register */ sw a3, SHADOWFRAME_RESULT_REGISTER_OFFSET(a2) /* Remember the code_item */ sw a1, SHADOWFRAME_CODE_ITEM_OFFSET(a2) /* set up "named" registers */ move rSELF, a0 lw a0, SHADOWFRAME_NUMBER_OF_VREGS_OFFSET(a2) addu rFP, a2, SHADOWFRAME_VREGS_OFFSET # point to vregs. EAS2(rREFS, rFP, a0) # point to reference array in shadow frame lw a0, SHADOWFRAME_DEX_PC_OFFSET(a2) # Get starting dex_pc addu rPC, a1, CODEITEM_INSNS_OFFSET # Point to base of insns[] EAS1(rPC, rPC, a0) # Create direct pointer to 1st dex opcode EXPORT_PC() /* Starting ibase */ lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) /* Set up for backwards branches & osr profiling */ lw a0, OFF_FP_METHOD(rFP) addu a1, rFP, OFF_FP_SHADOWFRAME JAL(MterpSetUpHotnessCountdown) # (method, shadow_frame) move rPROFILE, v0 # Starting hotness countdown to rPROFILE /* start executing the instruction at rPC */ FETCH_INST() # load rINST from rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* NOTE: no fallthrough */ .global artMterpAsmInstructionStart .type artMterpAsmInstructionStart, %function artMterpAsmInstructionStart = .L_op_nop .text /* ------------------------------ */ .balign 128 .L_op_nop: /* 0x00 */ /* File: mips/op_nop.S */ FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_move: /* 0x01 */ /* File: mips/op_move.S */ /* for move, move-object, long-to-int */ /* op vA, vB */ GET_OPB(a1) # a1 <- B from 15:12 GET_OPA4(a0) # a0 <- A from 11:8 FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_VREG(a2, a1) # a2 <- fp[B] GET_INST_OPCODE(t0) # t0 <- opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(a2, a0, t0) # fp[A] <- a2 .else SET_VREG_GOTO(a2, a0, t0) # fp[A] <- a2 .endif /* ------------------------------ */ .balign 128 .L_op_move_from16: /* 0x02 */ /* File: mips/op_move_from16.S */ /* for: move/from16, move-object/from16 */ /* op vAA, vBBBB */ FETCH(a1, 1) # a1 <- BBBB GET_OPA(a0) # a0 <- AA FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_VREG(a2, a1) # a2 <- fp[BBBB] GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(a2, a0, t0) # fp[AA] <- a2 .else SET_VREG_GOTO(a2, a0, t0) # fp[AA] <- a2 .endif /* ------------------------------ */ .balign 128 .L_op_move_16: /* 0x03 */ /* File: mips/op_move_16.S */ /* for: move/16, move-object/16 */ /* op vAAAA, vBBBB */ FETCH(a1, 2) # a1 <- BBBB FETCH(a0, 1) # a0 <- AAAA FETCH_ADVANCE_INST(3) # advance rPC, load rINST GET_VREG(a2, a1) # a2 <- fp[BBBB] GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(a2, a0, t0) # fp[AAAA] <- a2 .else SET_VREG_GOTO(a2, a0, t0) # fp[AAAA] <- a2 .endif /* ------------------------------ */ .balign 128 .L_op_move_wide: /* 0x04 */ /* File: mips/op_move_wide.S */ /* move-wide vA, vB */ /* NOTE: regs can overlap, e.g. "move v6, v7" or "move v7, v6" */ GET_OPA4(a2) # a2 <- A(+) GET_OPB(a3) # a3 <- B EAS2(a3, rFP, a3) # a3 <- &fp[B] LOAD64(a0, a1, a3) # a0/a1 <- fp[B] FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, a2, t0) # fp[A] <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_move_wide_from16: /* 0x05 */ /* File: mips/op_move_wide_from16.S */ /* move-wide/from16 vAA, vBBBB */ /* NOTE: regs can overlap, e.g. "move v6, v7" or "move v7, v6" */ FETCH(a3, 1) # a3 <- BBBB GET_OPA(a2) # a2 <- AA EAS2(a3, rFP, a3) # a3 <- &fp[BBBB] LOAD64(a0, a1, a3) # a0/a1 <- fp[BBBB] FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, a2, t0) # fp[AA] <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_move_wide_16: /* 0x06 */ /* File: mips/op_move_wide_16.S */ /* move-wide/16 vAAAA, vBBBB */ /* NOTE: regs can overlap, e.g. "move v6, v7" or "move v7, v6" */ FETCH(a3, 2) # a3 <- BBBB FETCH(a2, 1) # a2 <- AAAA EAS2(a3, rFP, a3) # a3 <- &fp[BBBB] LOAD64(a0, a1, a3) # a0/a1 <- fp[BBBB] FETCH_ADVANCE_INST(3) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, a2, t0) # fp[AAAA] <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_move_object: /* 0x07 */ /* File: mips/op_move_object.S */ /* File: mips/op_move.S */ /* for move, move-object, long-to-int */ /* op vA, vB */ GET_OPB(a1) # a1 <- B from 15:12 GET_OPA4(a0) # a0 <- A from 11:8 FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_VREG(a2, a1) # a2 <- fp[B] GET_INST_OPCODE(t0) # t0 <- opcode from rINST .if 1 SET_VREG_OBJECT_GOTO(a2, a0, t0) # fp[A] <- a2 .else SET_VREG_GOTO(a2, a0, t0) # fp[A] <- a2 .endif /* ------------------------------ */ .balign 128 .L_op_move_object_from16: /* 0x08 */ /* File: mips/op_move_object_from16.S */ /* File: mips/op_move_from16.S */ /* for: move/from16, move-object/from16 */ /* op vAA, vBBBB */ FETCH(a1, 1) # a1 <- BBBB GET_OPA(a0) # a0 <- AA FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_VREG(a2, a1) # a2 <- fp[BBBB] GET_INST_OPCODE(t0) # extract opcode from rINST .if 1 SET_VREG_OBJECT_GOTO(a2, a0, t0) # fp[AA] <- a2 .else SET_VREG_GOTO(a2, a0, t0) # fp[AA] <- a2 .endif /* ------------------------------ */ .balign 128 .L_op_move_object_16: /* 0x09 */ /* File: mips/op_move_object_16.S */ /* File: mips/op_move_16.S */ /* for: move/16, move-object/16 */ /* op vAAAA, vBBBB */ FETCH(a1, 2) # a1 <- BBBB FETCH(a0, 1) # a0 <- AAAA FETCH_ADVANCE_INST(3) # advance rPC, load rINST GET_VREG(a2, a1) # a2 <- fp[BBBB] GET_INST_OPCODE(t0) # extract opcode from rINST .if 1 SET_VREG_OBJECT_GOTO(a2, a0, t0) # fp[AAAA] <- a2 .else SET_VREG_GOTO(a2, a0, t0) # fp[AAAA] <- a2 .endif /* ------------------------------ */ .balign 128 .L_op_move_result: /* 0x0a */ /* File: mips/op_move_result.S */ /* for: move-result, move-result-object */ /* op vAA */ GET_OPA(a2) # a2 <- AA FETCH_ADVANCE_INST(1) # advance rPC, load rINST lw a0, OFF_FP_RESULT_REGISTER(rFP) # get pointer to result JType lw a0, 0(a0) # a0 <- result.i GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(a0, a2, t0) # fp[AA] <- a0 .else SET_VREG_GOTO(a0, a2, t0) # fp[AA] <- a0 .endif /* ------------------------------ */ .balign 128 .L_op_move_result_wide: /* 0x0b */ /* File: mips/op_move_result_wide.S */ /* move-result-wide vAA */ GET_OPA(a2) # a2 <- AA lw a3, OFF_FP_RESULT_REGISTER(rFP) # get pointer to result JType LOAD64(a0, a1, a3) # a0/a1 <- retval.j FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, a2, t0) # fp[AA] <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_move_result_object: /* 0x0c */ /* File: mips/op_move_result_object.S */ /* File: mips/op_move_result.S */ /* for: move-result, move-result-object */ /* op vAA */ GET_OPA(a2) # a2 <- AA FETCH_ADVANCE_INST(1) # advance rPC, load rINST lw a0, OFF_FP_RESULT_REGISTER(rFP) # get pointer to result JType lw a0, 0(a0) # a0 <- result.i GET_INST_OPCODE(t0) # extract opcode from rINST .if 1 SET_VREG_OBJECT_GOTO(a0, a2, t0) # fp[AA] <- a0 .else SET_VREG_GOTO(a0, a2, t0) # fp[AA] <- a0 .endif /* ------------------------------ */ .balign 128 .L_op_move_exception: /* 0x0d */ /* File: mips/op_move_exception.S */ /* move-exception vAA */ GET_OPA(a2) # a2 <- AA lw a3, THREAD_EXCEPTION_OFFSET(rSELF) # get exception obj FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GET_OPCODE_TARGET(t0) SET_VREG_OBJECT(a3, a2) # fp[AA] <- exception obj sw zero, THREAD_EXCEPTION_OFFSET(rSELF) # clear exception JR(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_return_void: /* 0x0e */ /* File: mips/op_return_void.S */ .extern MterpThreadFenceForConstructor JAL(MterpThreadFenceForConstructor) lw ra, THREAD_FLAGS_OFFSET(rSELF) move a0, rSELF and ra, THREAD_SUSPEND_OR_CHECKPOINT_REQUEST beqz ra, 1f JAL(MterpSuspendCheck) # (self) 1: move v0, zero move v1, zero b MterpReturn /* ------------------------------ */ .balign 128 .L_op_return: /* 0x0f */ /* File: mips/op_return.S */ /* * Return a 32-bit value. * * for: return, return-object */ /* op vAA */ .extern MterpThreadFenceForConstructor JAL(MterpThreadFenceForConstructor) lw ra, THREAD_FLAGS_OFFSET(rSELF) move a0, rSELF and ra, THREAD_SUSPEND_OR_CHECKPOINT_REQUEST beqz ra, 1f JAL(MterpSuspendCheck) # (self) 1: GET_OPA(a2) # a2 <- AA GET_VREG(v0, a2) # v0 <- vAA move v1, zero b MterpReturn /* ------------------------------ */ .balign 128 .L_op_return_wide: /* 0x10 */ /* File: mips/op_return_wide.S */ /* * Return a 64-bit value. */ /* return-wide vAA */ .extern MterpThreadFenceForConstructor JAL(MterpThreadFenceForConstructor) lw ra, THREAD_FLAGS_OFFSET(rSELF) move a0, rSELF and ra, THREAD_SUSPEND_OR_CHECKPOINT_REQUEST beqz ra, 1f JAL(MterpSuspendCheck) # (self) 1: GET_OPA(a2) # a2 <- AA EAS2(a2, rFP, a2) # a2 <- &fp[AA] LOAD64(v0, v1, a2) # v0/v1 <- vAA/vAA+1 b MterpReturn /* ------------------------------ */ .balign 128 .L_op_return_object: /* 0x11 */ /* File: mips/op_return_object.S */ /* File: mips/op_return.S */ /* * Return a 32-bit value. * * for: return, return-object */ /* op vAA */ .extern MterpThreadFenceForConstructor JAL(MterpThreadFenceForConstructor) lw ra, THREAD_FLAGS_OFFSET(rSELF) move a0, rSELF and ra, THREAD_SUSPEND_OR_CHECKPOINT_REQUEST beqz ra, 1f JAL(MterpSuspendCheck) # (self) 1: GET_OPA(a2) # a2 <- AA GET_VREG(v0, a2) # v0 <- vAA move v1, zero b MterpReturn /* ------------------------------ */ .balign 128 .L_op_const_4: /* 0x12 */ /* File: mips/op_const_4.S */ /* const/4 vA, +B */ sll a1, rINST, 16 # a1 <- Bxxx0000 GET_OPA(a0) # a0 <- A+ FETCH_ADVANCE_INST(1) # advance rPC, load rINST sra a1, a1, 28 # a1 <- sssssssB (sign-extended) and a0, a0, 15 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a1, a0, t0) # fp[A] <- a1 /* ------------------------------ */ .balign 128 .L_op_const_16: /* 0x13 */ /* File: mips/op_const_16.S */ /* const/16 vAA, +BBBB */ FETCH_S(a0, 1) # a0 <- ssssBBBB (sign-extended) GET_OPA(a3) # a3 <- AA FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, a3, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_const: /* 0x14 */ /* File: mips/op_const.S */ /* const vAA, +BBBBbbbb */ GET_OPA(a3) # a3 <- AA FETCH(a0, 1) # a0 <- bbbb (low) FETCH(a1, 2) # a1 <- BBBB (high) FETCH_ADVANCE_INST(3) # advance rPC, load rINST INSERT_HIGH_HALF(a0, a1) # a0 <- BBBBbbbb GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, a3, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_const_high16: /* 0x15 */ /* File: mips/op_const_high16.S */ /* const/high16 vAA, +BBBB0000 */ FETCH(a0, 1) # a0 <- 0000BBBB (zero-extended) GET_OPA(a3) # a3 <- AA sll a0, a0, 16 # a0 <- BBBB0000 FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, a3, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_const_wide_16: /* 0x16 */ /* File: mips/op_const_wide_16.S */ /* const-wide/16 vAA, +BBBB */ FETCH_S(a0, 1) # a0 <- ssssBBBB (sign-extended) GET_OPA(a3) # a3 <- AA sra a1, a0, 31 # a1 <- ssssssss FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, a3, t0) # vAA/vAA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_const_wide_32: /* 0x17 */ /* File: mips/op_const_wide_32.S */ /* const-wide/32 vAA, +BBBBbbbb */ FETCH(a0, 1) # a0 <- 0000bbbb (low) GET_OPA(a3) # a3 <- AA FETCH_S(a2, 2) # a2 <- ssssBBBB (high) FETCH_ADVANCE_INST(3) # advance rPC, load rINST INSERT_HIGH_HALF(a0, a2) # a0 <- BBBBbbbb sra a1, a0, 31 # a1 <- ssssssss GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, a3, t0) # vAA/vAA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_const_wide: /* 0x18 */ /* File: mips/op_const_wide.S */ /* const-wide vAA, +HHHHhhhhBBBBbbbb */ FETCH(a0, 1) # a0 <- bbbb (low) FETCH(a1, 2) # a1 <- BBBB (low middle) FETCH(a2, 3) # a2 <- hhhh (high middle) INSERT_HIGH_HALF(a0, a1) # a0 <- BBBBbbbb (low word) FETCH(a3, 4) # a3 <- HHHH (high) GET_OPA(t1) # t1 <- AA INSERT_HIGH_HALF(a2, a3) # a2 <- HHHHhhhh (high word) FETCH_ADVANCE_INST(5) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a2, t1, t0) # vAA/vAA+1 <- a0/a2 /* ------------------------------ */ .balign 128 .L_op_const_wide_high16: /* 0x19 */ /* File: mips/op_const_wide_high16.S */ /* const-wide/high16 vAA, +BBBB000000000000 */ FETCH(a1, 1) # a1 <- 0000BBBB (zero-extended) GET_OPA(a3) # a3 <- AA li a0, 0 # a0 <- 00000000 sll a1, 16 # a1 <- BBBB0000 FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, a3, t0) # vAA/vAA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_const_string: /* 0x1a */ /* File: mips/op_const_string.S */ /* const/string vAA, string@BBBB */ EXPORT_PC() FETCH(a0, 1) # a0 <- BBBB GET_OPA(a1) # a1 <- AA addu a2, rFP, OFF_FP_SHADOWFRAME # a2 <- shadow frame move a3, rSELF JAL(MterpConstString) # v0 <- Mterp(index, tgt_reg, shadow_frame, self) PREFETCH_INST(2) # load rINST bnez v0, MterpPossibleException ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_const_string_jumbo: /* 0x1b */ /* File: mips/op_const_string_jumbo.S */ /* const/string vAA, string@BBBBBBBB */ EXPORT_PC() FETCH(a0, 1) # a0 <- bbbb (low) FETCH(a2, 2) # a2 <- BBBB (high) GET_OPA(a1) # a1 <- AA INSERT_HIGH_HALF(a0, a2) # a0 <- BBBBbbbb addu a2, rFP, OFF_FP_SHADOWFRAME # a2 <- shadow frame move a3, rSELF JAL(MterpConstString) # v0 <- Mterp(index, tgt_reg, shadow_frame, self) PREFETCH_INST(3) # load rINST bnez v0, MterpPossibleException ADVANCE(3) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_const_class: /* 0x1c */ /* File: mips/op_const_class.S */ /* const/class vAA, class@BBBB */ EXPORT_PC() FETCH(a0, 1) # a0 <- BBBB GET_OPA(a1) # a1 <- AA addu a2, rFP, OFF_FP_SHADOWFRAME # a2 <- shadow frame move a3, rSELF JAL(MterpConstClass) PREFETCH_INST(2) # load rINST bnez v0, MterpPossibleException ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_monitor_enter: /* 0x1d */ /* File: mips/op_monitor_enter.S */ /* * Synchronize on an object. */ /* monitor-enter vAA */ EXPORT_PC() GET_OPA(a2) # a2 <- AA GET_VREG(a0, a2) # a0 <- vAA (object) move a1, rSELF # a1 <- self JAL(artLockObjectFromCode) # v0 <- artLockObject(obj, self) bnez v0, MterpException FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_monitor_exit: /* 0x1e */ /* File: mips/op_monitor_exit.S */ /* * Unlock an object. * * Exceptions that occur when unlocking a monitor need to appear as * if they happened at the following instruction. See the Dalvik * instruction spec. */ /* monitor-exit vAA */ EXPORT_PC() GET_OPA(a2) # a2 <- AA GET_VREG(a0, a2) # a0 <- vAA (object) move a1, rSELF # a1 <- self JAL(artUnlockObjectFromCode) # v0 <- artUnlockObject(obj, self) bnez v0, MterpException FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_check_cast: /* 0x1f */ /* File: mips/op_check_cast.S */ /* * Check to see if a cast from one class to another is allowed. */ /* check-cast vAA, class@BBBB */ EXPORT_PC() FETCH(a0, 1) # a0 <- BBBB GET_OPA(a1) # a1 <- AA EAS2(a1, rFP, a1) # a1 <- &object lw a2, OFF_FP_METHOD(rFP) # a2 <- method move a3, rSELF # a3 <- self JAL(MterpCheckCast) # v0 <- CheckCast(index, &obj, method, self) PREFETCH_INST(2) bnez v0, MterpPossibleException ADVANCE(2) GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_instance_of: /* 0x20 */ /* File: mips/op_instance_of.S */ /* * Check to see if an object reference is an instance of a class. * * Most common situation is a non-null object, being compared against * an already-resolved class. */ /* instance-of vA, vB, class@CCCC */ EXPORT_PC() FETCH(a0, 1) # a0 <- CCCC GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &object lw a2, OFF_FP_METHOD(rFP) # a2 <- method move a3, rSELF # a3 <- self GET_OPA4(rOBJ) # rOBJ <- A+ JAL(MterpInstanceOf) # v0 <- Mterp(index, &obj, method, self) lw a1, THREAD_EXCEPTION_OFFSET(rSELF) PREFETCH_INST(2) # load rINST bnez a1, MterpException ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(v0, rOBJ, t0) # vA <- v0 /* ------------------------------ */ .balign 128 .L_op_array_length: /* 0x21 */ /* File: mips/op_array_length.S */ /* * Return the length of an array. */ /* array-length vA, vB */ GET_OPB(a1) # a1 <- B GET_OPA4(a2) # a2 <- A+ GET_VREG(a0, a1) # a0 <- vB (object ref) # is object null? beqz a0, common_errNullObject # yup, fail FETCH_ADVANCE_INST(1) # advance rPC, load rINST LOAD_base_offMirrorArray_length(a3, a0) # a3 <- array length GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a3, a2, t0) # vA <- length /* ------------------------------ */ .balign 128 .L_op_new_instance: /* 0x22 */ /* File: mips/op_new_instance.S */ /* * Create a new instance of a class. */ /* new-instance vAA, class@BBBB */ EXPORT_PC() addu a0, rFP, OFF_FP_SHADOWFRAME move a1, rSELF move a2, rINST JAL(MterpNewInstance) beqz v0, MterpPossibleException FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_new_array: /* 0x23 */ /* File: mips/op_new_array.S */ /* * Allocate an array of objects, specified with the array class * and a count. * * The verifier guarantees that this is an array class, so we don't * check for it here. */ /* new-array vA, vB, class@CCCC */ EXPORT_PC() addu a0, rFP, OFF_FP_SHADOWFRAME move a1, rPC move a2, rINST move a3, rSELF JAL(MterpNewArray) beqz v0, MterpPossibleException FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_filled_new_array: /* 0x24 */ /* File: mips/op_filled_new_array.S */ /* * Create a new array with elements filled from registers. * * for: filled-new-array, filled-new-array/range */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, type@BBBB */ .extern MterpFilledNewArray EXPORT_PC() addu a0, rFP, OFF_FP_SHADOWFRAME # a0 <- shadow frame move a1, rPC move a2, rSELF JAL(MterpFilledNewArray) # v0 <- helper(shadow_frame, pc, self) beqz v0, MterpPossibleException # has exception FETCH_ADVANCE_INST(3) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_filled_new_array_range: /* 0x25 */ /* File: mips/op_filled_new_array_range.S */ /* File: mips/op_filled_new_array.S */ /* * Create a new array with elements filled from registers. * * for: filled-new-array, filled-new-array/range */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, type@BBBB */ .extern MterpFilledNewArrayRange EXPORT_PC() addu a0, rFP, OFF_FP_SHADOWFRAME # a0 <- shadow frame move a1, rPC move a2, rSELF JAL(MterpFilledNewArrayRange) # v0 <- helper(shadow_frame, pc, self) beqz v0, MterpPossibleException # has exception FETCH_ADVANCE_INST(3) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_fill_array_data: /* 0x26 */ /* File: mips/op_fill_array_data.S */ /* fill-array-data vAA, +BBBBBBBB */ EXPORT_PC() FETCH(a1, 1) # a1 <- bbbb (lo) FETCH(a0, 2) # a0 <- BBBB (hi) GET_OPA(a3) # a3 <- AA INSERT_HIGH_HALF(a1, a0) # a1 <- BBBBbbbb GET_VREG(a0, a3) # a0 <- vAA (array object) EAS1(a1, rPC, a1) # a1 <- PC + BBBBbbbb*2 (array data off.) JAL(MterpFillArrayData) # v0 <- Mterp(obj, payload) beqz v0, MterpPossibleException # has exception FETCH_ADVANCE_INST(3) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_throw: /* 0x27 */ /* File: mips/op_throw.S */ /* * Throw an exception object in the current thread. */ /* throw vAA */ EXPORT_PC() # exception handler can throw GET_OPA(a2) # a2 <- AA GET_VREG(a1, a2) # a1 <- vAA (exception object) # null object? beqz a1, common_errNullObject # yes, throw an NPE instead sw a1, THREAD_EXCEPTION_OFFSET(rSELF) # thread->exception <- obj b MterpException /* ------------------------------ */ .balign 128 .L_op_goto: /* 0x28 */ /* File: mips/op_goto.S */ /* * Unconditional branch, 8-bit offset. * * The branch distance is a signed code-unit offset, which we need to * double to get a byte offset. */ /* goto +AA */ sll a0, rINST, 16 # a0 <- AAxx0000 sra rINST, a0, 24 # rINST <- ssssssAA (sign-extended) b MterpCommonTakenBranchNoFlags /* ------------------------------ */ .balign 128 .L_op_goto_16: /* 0x29 */ /* File: mips/op_goto_16.S */ /* * Unconditional branch, 16-bit offset. * * The branch distance is a signed code-unit offset, which we need to * double to get a byte offset. */ /* goto/16 +AAAA */ FETCH_S(rINST, 1) # rINST <- ssssAAAA (sign-extended) b MterpCommonTakenBranchNoFlags /* ------------------------------ */ .balign 128 .L_op_goto_32: /* 0x2a */ /* File: mips/op_goto_32.S */ /* * Unconditional branch, 32-bit offset. * * The branch distance is a signed code-unit offset, which we need to * double to get a byte offset. * * Unlike most opcodes, this one is allowed to branch to itself, so * our "backward branch" test must be "<=0" instead of "<0". */ /* goto/32 +AAAAAAAA */ FETCH(rINST, 1) # rINST <- aaaa (lo) FETCH(a1, 2) # a1 <- AAAA (hi) INSERT_HIGH_HALF(rINST, a1) # rINST <- AAAAaaaa b MterpCommonTakenBranchNoFlags /* ------------------------------ */ .balign 128 .L_op_packed_switch: /* 0x2b */ /* File: mips/op_packed_switch.S */ /* * Handle a packed-switch or sparse-switch instruction. In both cases * we decode it and hand it off to a helper function. * * We don't really expect backward branches in a switch statement, but * they're perfectly legal, so we check for them here. * * for: packed-switch, sparse-switch */ /* op vAA, +BBBB */ FETCH(a0, 1) # a0 <- bbbb (lo) FETCH(a1, 2) # a1 <- BBBB (hi) GET_OPA(a3) # a3 <- AA INSERT_HIGH_HALF(a0, a1) # a0 <- BBBBbbbb GET_VREG(a1, a3) # a1 <- vAA EAS1(a0, rPC, a0) # a0 <- PC + BBBBbbbb*2 JAL(MterpDoPackedSwitch) # a0 <- code-unit branch offset move rINST, v0 b MterpCommonTakenBranchNoFlags /* ------------------------------ */ .balign 128 .L_op_sparse_switch: /* 0x2c */ /* File: mips/op_sparse_switch.S */ /* File: mips/op_packed_switch.S */ /* * Handle a packed-switch or sparse-switch instruction. In both cases * we decode it and hand it off to a helper function. * * We don't really expect backward branches in a switch statement, but * they're perfectly legal, so we check for them here. * * for: packed-switch, sparse-switch */ /* op vAA, +BBBB */ FETCH(a0, 1) # a0 <- bbbb (lo) FETCH(a1, 2) # a1 <- BBBB (hi) GET_OPA(a3) # a3 <- AA INSERT_HIGH_HALF(a0, a1) # a0 <- BBBBbbbb GET_VREG(a1, a3) # a1 <- vAA EAS1(a0, rPC, a0) # a0 <- PC + BBBBbbbb*2 JAL(MterpDoSparseSwitch) # a0 <- code-unit branch offset move rINST, v0 b MterpCommonTakenBranchNoFlags /* ------------------------------ */ .balign 128 .L_op_cmpl_float: /* 0x2d */ /* File: mips/op_cmpl_float.S */ /* * Compare two floating-point values. Puts 0(==), 1(>), or -1(<) * into the destination register based on the comparison results. * * for: cmpl-float, cmpg-float */ /* op vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB and a2, a0, 255 # a2 <- BB srl a3, a0, 8 GET_VREG_F(ft0, a2) GET_VREG_F(ft1, a3) #ifdef MIPS32REVGE6 cmp.eq.s ft2, ft0, ft1 li rTEMP, 0 bc1nez ft2, 1f # done if vBB == vCC (ordered) .if 0 cmp.lt.s ft2, ft0, ft1 li rTEMP, -1 bc1nez ft2, 1f # done if vBB < vCC (ordered) li rTEMP, 1 # vBB > vCC or unordered .else cmp.lt.s ft2, ft1, ft0 li rTEMP, 1 bc1nez ft2, 1f # done if vBB > vCC (ordered) li rTEMP, -1 # vBB < vCC or unordered .endif #else c.eq.s fcc0, ft0, ft1 li rTEMP, 0 bc1t fcc0, 1f # done if vBB == vCC (ordered) .if 0 c.olt.s fcc0, ft0, ft1 li rTEMP, -1 bc1t fcc0, 1f # done if vBB < vCC (ordered) li rTEMP, 1 # vBB > vCC or unordered .else c.olt.s fcc0, ft1, ft0 li rTEMP, 1 bc1t fcc0, 1f # done if vBB > vCC (ordered) li rTEMP, -1 # vBB < vCC or unordered .endif #endif 1: GET_OPA(rOBJ) FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(rTEMP, rOBJ, t0) # vAA <- rTEMP /* ------------------------------ */ .balign 128 .L_op_cmpg_float: /* 0x2e */ /* File: mips/op_cmpg_float.S */ /* File: mips/op_cmpl_float.S */ /* * Compare two floating-point values. Puts 0(==), 1(>), or -1(<) * into the destination register based on the comparison results. * * for: cmpl-float, cmpg-float */ /* op vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB and a2, a0, 255 # a2 <- BB srl a3, a0, 8 GET_VREG_F(ft0, a2) GET_VREG_F(ft1, a3) #ifdef MIPS32REVGE6 cmp.eq.s ft2, ft0, ft1 li rTEMP, 0 bc1nez ft2, 1f # done if vBB == vCC (ordered) .if 1 cmp.lt.s ft2, ft0, ft1 li rTEMP, -1 bc1nez ft2, 1f # done if vBB < vCC (ordered) li rTEMP, 1 # vBB > vCC or unordered .else cmp.lt.s ft2, ft1, ft0 li rTEMP, 1 bc1nez ft2, 1f # done if vBB > vCC (ordered) li rTEMP, -1 # vBB < vCC or unordered .endif #else c.eq.s fcc0, ft0, ft1 li rTEMP, 0 bc1t fcc0, 1f # done if vBB == vCC (ordered) .if 1 c.olt.s fcc0, ft0, ft1 li rTEMP, -1 bc1t fcc0, 1f # done if vBB < vCC (ordered) li rTEMP, 1 # vBB > vCC or unordered .else c.olt.s fcc0, ft1, ft0 li rTEMP, 1 bc1t fcc0, 1f # done if vBB > vCC (ordered) li rTEMP, -1 # vBB < vCC or unordered .endif #endif 1: GET_OPA(rOBJ) FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(rTEMP, rOBJ, t0) # vAA <- rTEMP /* ------------------------------ */ .balign 128 .L_op_cmpl_double: /* 0x2f */ /* File: mips/op_cmpl_double.S */ /* * Compare two floating-point values. Puts 0(==), 1(>), or -1(<) * into the destination register based on the comparison results. * * For: cmpl-double, cmpg-double */ /* op vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB and rOBJ, a0, 255 # rOBJ <- BB srl t0, a0, 8 # t0 <- CC EAS2(rOBJ, rFP, rOBJ) # rOBJ <- &fp[BB] EAS2(t0, rFP, t0) # t0 <- &fp[CC] LOAD64_F(ft0, ft0f, rOBJ) LOAD64_F(ft1, ft1f, t0) #ifdef MIPS32REVGE6 cmp.eq.d ft2, ft0, ft1 li rTEMP, 0 bc1nez ft2, 1f # done if vBB == vCC (ordered) .if 0 cmp.lt.d ft2, ft0, ft1 li rTEMP, -1 bc1nez ft2, 1f # done if vBB < vCC (ordered) li rTEMP, 1 # vBB > vCC or unordered .else cmp.lt.d ft2, ft1, ft0 li rTEMP, 1 bc1nez ft2, 1f # done if vBB > vCC (ordered) li rTEMP, -1 # vBB < vCC or unordered .endif #else c.eq.d fcc0, ft0, ft1 li rTEMP, 0 bc1t fcc0, 1f # done if vBB == vCC (ordered) .if 0 c.olt.d fcc0, ft0, ft1 li rTEMP, -1 bc1t fcc0, 1f # done if vBB < vCC (ordered) li rTEMP, 1 # vBB > vCC or unordered .else c.olt.d fcc0, ft1, ft0 li rTEMP, 1 bc1t fcc0, 1f # done if vBB > vCC (ordered) li rTEMP, -1 # vBB < vCC or unordered .endif #endif 1: GET_OPA(rOBJ) FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(rTEMP, rOBJ, t0) # vAA <- rTEMP /* ------------------------------ */ .balign 128 .L_op_cmpg_double: /* 0x30 */ /* File: mips/op_cmpg_double.S */ /* File: mips/op_cmpl_double.S */ /* * Compare two floating-point values. Puts 0(==), 1(>), or -1(<) * into the destination register based on the comparison results. * * For: cmpl-double, cmpg-double */ /* op vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB and rOBJ, a0, 255 # rOBJ <- BB srl t0, a0, 8 # t0 <- CC EAS2(rOBJ, rFP, rOBJ) # rOBJ <- &fp[BB] EAS2(t0, rFP, t0) # t0 <- &fp[CC] LOAD64_F(ft0, ft0f, rOBJ) LOAD64_F(ft1, ft1f, t0) #ifdef MIPS32REVGE6 cmp.eq.d ft2, ft0, ft1 li rTEMP, 0 bc1nez ft2, 1f # done if vBB == vCC (ordered) .if 1 cmp.lt.d ft2, ft0, ft1 li rTEMP, -1 bc1nez ft2, 1f # done if vBB < vCC (ordered) li rTEMP, 1 # vBB > vCC or unordered .else cmp.lt.d ft2, ft1, ft0 li rTEMP, 1 bc1nez ft2, 1f # done if vBB > vCC (ordered) li rTEMP, -1 # vBB < vCC or unordered .endif #else c.eq.d fcc0, ft0, ft1 li rTEMP, 0 bc1t fcc0, 1f # done if vBB == vCC (ordered) .if 1 c.olt.d fcc0, ft0, ft1 li rTEMP, -1 bc1t fcc0, 1f # done if vBB < vCC (ordered) li rTEMP, 1 # vBB > vCC or unordered .else c.olt.d fcc0, ft1, ft0 li rTEMP, 1 bc1t fcc0, 1f # done if vBB > vCC (ordered) li rTEMP, -1 # vBB < vCC or unordered .endif #endif 1: GET_OPA(rOBJ) FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(rTEMP, rOBJ, t0) # vAA <- rTEMP /* ------------------------------ */ .balign 128 .L_op_cmp_long: /* 0x31 */ /* File: mips/op_cmp_long.S */ /* * Compare two 64-bit values * x = y return 0 * x < y return -1 * x > y return 1 * * I think I can improve on the ARM code by the following observation * slt t0, x.hi, y.hi; # (x.hi < y.hi) ? 1:0 * sgt t1, x.hi, y.hi; # (y.hi > x.hi) ? 1:0 * subu v0, t0, t1 # v0= -1:1:0 for [ < > = ] */ /* cmp-long vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(a3, rFP, a3) # a3 <- &fp[CC] LOAD64(a0, a1, a2) # a0/a1 <- vBB/vBB+1 LOAD64(a2, a3, a3) # a2/a3 <- vCC/vCC+1 FETCH_ADVANCE_INST(2) # advance rPC, load rINST slt t0, a1, a3 # compare hi sgt t1, a1, a3 subu v0, t1, t0 # v0 <- (-1, 1, 0) bnez v0, .Lop_cmp_long_finish # at this point x.hi==y.hi sltu t0, a0, a2 # compare lo sgtu t1, a0, a2 subu v0, t1, t0 # v0 <- (-1, 1, 0) for [< > =] .Lop_cmp_long_finish: GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(v0, rOBJ, t0) # vAA <- v0 /* ------------------------------ */ .balign 128 .L_op_if_eq: /* 0x32 */ /* File: mips/op_if_eq.S */ /* File: mips/bincmp.S */ /* * Generic two-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * For: if-eq, if-ne, if-lt, if-ge, if-gt, if-le */ /* if-cmp vA, vB, +CCCC */ GET_OPA4(a0) # a0 <- A+ GET_OPB(a1) # a1 <- B GET_VREG(a3, a1) # a3 <- vB GET_VREG(a0, a0) # a0 <- vA FETCH_S(rINST, 1) # rINST<- branch offset, in code units beq a0, a3, MterpCommonTakenBranchNoFlags # compare (vA, vB) li t0, JIT_CHECK_OSR beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_ne: /* 0x33 */ /* File: mips/op_if_ne.S */ /* File: mips/bincmp.S */ /* * Generic two-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * For: if-eq, if-ne, if-lt, if-ge, if-gt, if-le */ /* if-cmp vA, vB, +CCCC */ GET_OPA4(a0) # a0 <- A+ GET_OPB(a1) # a1 <- B GET_VREG(a3, a1) # a3 <- vB GET_VREG(a0, a0) # a0 <- vA FETCH_S(rINST, 1) # rINST<- branch offset, in code units bne a0, a3, MterpCommonTakenBranchNoFlags # compare (vA, vB) li t0, JIT_CHECK_OSR beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_lt: /* 0x34 */ /* File: mips/op_if_lt.S */ /* File: mips/bincmp.S */ /* * Generic two-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * For: if-eq, if-ne, if-lt, if-ge, if-gt, if-le */ /* if-cmp vA, vB, +CCCC */ GET_OPA4(a0) # a0 <- A+ GET_OPB(a1) # a1 <- B GET_VREG(a3, a1) # a3 <- vB GET_VREG(a0, a0) # a0 <- vA FETCH_S(rINST, 1) # rINST<- branch offset, in code units blt a0, a3, MterpCommonTakenBranchNoFlags # compare (vA, vB) li t0, JIT_CHECK_OSR beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_ge: /* 0x35 */ /* File: mips/op_if_ge.S */ /* File: mips/bincmp.S */ /* * Generic two-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * For: if-eq, if-ne, if-lt, if-ge, if-gt, if-le */ /* if-cmp vA, vB, +CCCC */ GET_OPA4(a0) # a0 <- A+ GET_OPB(a1) # a1 <- B GET_VREG(a3, a1) # a3 <- vB GET_VREG(a0, a0) # a0 <- vA FETCH_S(rINST, 1) # rINST<- branch offset, in code units bge a0, a3, MterpCommonTakenBranchNoFlags # compare (vA, vB) li t0, JIT_CHECK_OSR beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_gt: /* 0x36 */ /* File: mips/op_if_gt.S */ /* File: mips/bincmp.S */ /* * Generic two-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * For: if-eq, if-ne, if-lt, if-ge, if-gt, if-le */ /* if-cmp vA, vB, +CCCC */ GET_OPA4(a0) # a0 <- A+ GET_OPB(a1) # a1 <- B GET_VREG(a3, a1) # a3 <- vB GET_VREG(a0, a0) # a0 <- vA FETCH_S(rINST, 1) # rINST<- branch offset, in code units bgt a0, a3, MterpCommonTakenBranchNoFlags # compare (vA, vB) li t0, JIT_CHECK_OSR beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_le: /* 0x37 */ /* File: mips/op_if_le.S */ /* File: mips/bincmp.S */ /* * Generic two-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * For: if-eq, if-ne, if-lt, if-ge, if-gt, if-le */ /* if-cmp vA, vB, +CCCC */ GET_OPA4(a0) # a0 <- A+ GET_OPB(a1) # a1 <- B GET_VREG(a3, a1) # a3 <- vB GET_VREG(a0, a0) # a0 <- vA FETCH_S(rINST, 1) # rINST<- branch offset, in code units ble a0, a3, MterpCommonTakenBranchNoFlags # compare (vA, vB) li t0, JIT_CHECK_OSR beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_eqz: /* 0x38 */ /* File: mips/op_if_eqz.S */ /* File: mips/zcmp.S */ /* * Generic one-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * for: if-eqz, if-nez, if-ltz, if-gez, if-gtz, if-lez */ /* if-cmp vAA, +BBBB */ GET_OPA(a0) # a0 <- AA GET_VREG(a0, a0) # a0 <- vAA FETCH_S(rINST, 1) # rINST <- branch offset, in code units beq a0, zero, MterpCommonTakenBranchNoFlags li t0, JIT_CHECK_OSR # possible OSR re-entry? beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_nez: /* 0x39 */ /* File: mips/op_if_nez.S */ /* File: mips/zcmp.S */ /* * Generic one-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * for: if-eqz, if-nez, if-ltz, if-gez, if-gtz, if-lez */ /* if-cmp vAA, +BBBB */ GET_OPA(a0) # a0 <- AA GET_VREG(a0, a0) # a0 <- vAA FETCH_S(rINST, 1) # rINST <- branch offset, in code units bne a0, zero, MterpCommonTakenBranchNoFlags li t0, JIT_CHECK_OSR # possible OSR re-entry? beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_ltz: /* 0x3a */ /* File: mips/op_if_ltz.S */ /* File: mips/zcmp.S */ /* * Generic one-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * for: if-eqz, if-nez, if-ltz, if-gez, if-gtz, if-lez */ /* if-cmp vAA, +BBBB */ GET_OPA(a0) # a0 <- AA GET_VREG(a0, a0) # a0 <- vAA FETCH_S(rINST, 1) # rINST <- branch offset, in code units blt a0, zero, MterpCommonTakenBranchNoFlags li t0, JIT_CHECK_OSR # possible OSR re-entry? beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_gez: /* 0x3b */ /* File: mips/op_if_gez.S */ /* File: mips/zcmp.S */ /* * Generic one-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * for: if-eqz, if-nez, if-ltz, if-gez, if-gtz, if-lez */ /* if-cmp vAA, +BBBB */ GET_OPA(a0) # a0 <- AA GET_VREG(a0, a0) # a0 <- vAA FETCH_S(rINST, 1) # rINST <- branch offset, in code units bge a0, zero, MterpCommonTakenBranchNoFlags li t0, JIT_CHECK_OSR # possible OSR re-entry? beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_gtz: /* 0x3c */ /* File: mips/op_if_gtz.S */ /* File: mips/zcmp.S */ /* * Generic one-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * for: if-eqz, if-nez, if-ltz, if-gez, if-gtz, if-lez */ /* if-cmp vAA, +BBBB */ GET_OPA(a0) # a0 <- AA GET_VREG(a0, a0) # a0 <- vAA FETCH_S(rINST, 1) # rINST <- branch offset, in code units bgt a0, zero, MterpCommonTakenBranchNoFlags li t0, JIT_CHECK_OSR # possible OSR re-entry? beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_if_lez: /* 0x3d */ /* File: mips/op_if_lez.S */ /* File: mips/zcmp.S */ /* * Generic one-operand compare-and-branch operation. Provide a "condition" * fragment that specifies the comparison to perform. * * for: if-eqz, if-nez, if-ltz, if-gez, if-gtz, if-lez */ /* if-cmp vAA, +BBBB */ GET_OPA(a0) # a0 <- AA GET_VREG(a0, a0) # a0 <- vAA FETCH_S(rINST, 1) # rINST <- branch offset, in code units ble a0, zero, MterpCommonTakenBranchNoFlags li t0, JIT_CHECK_OSR # possible OSR re-entry? beq rPROFILE, t0, .L_check_not_taken_osr FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_unused_3e: /* 0x3e */ /* File: mips/op_unused_3e.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_3f: /* 0x3f */ /* File: mips/op_unused_3f.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_40: /* 0x40 */ /* File: mips/op_unused_40.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_41: /* 0x41 */ /* File: mips/op_unused_41.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_42: /* 0x42 */ /* File: mips/op_unused_42.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_43: /* 0x43 */ /* File: mips/op_unused_43.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_aget: /* 0x44 */ /* File: mips/op_aget.S */ /* * Array get, 32 bits or less. vAA <- vBB[vCC]. * * Note: using the usual FETCH/and/shift stuff, this fits in exactly 17 * instructions. We use a pair of FETCH_Bs instead. * * for: aget, aget-boolean, aget-byte, aget-char, aget-short * * NOTE: assumes data offset for arrays is the same for all non-wide types. * If this changes, specialize. */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EASN(a0, a0, a1, 2) # a0 <- arrayObj + index*width # a1 >= a3; compare unsigned index bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST lw a2, MIRROR_INT_ARRAY_DATA_OFFSET(a0) # a2 <- vBB[vCC] GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a2, rOBJ, t0) # vAA <- a2 /* ------------------------------ */ .balign 128 .L_op_aget_wide: /* 0x45 */ /* File: mips/op_aget_wide.S */ /* * Array get, 64 bits. vAA <- vBB[vCC]. * * Arrays of long/double are 64-bit aligned. */ /* aget-wide vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EAS3(a0, a0, a1) # a0 <- arrayObj + index*width bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST LOAD64_off(a2, a3, a0, MIRROR_WIDE_ARRAY_DATA_OFFSET) GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a2, a3, rOBJ, t0) # vAA/vAA+1 <- a2/a3 /* ------------------------------ */ .balign 128 .L_op_aget_object: /* 0x46 */ /* File: mips/op_aget_object.S */ /* * Array object get. vAA <- vBB[vCC]. * * for: aget-object */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC EXPORT_PC() GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) JAL(artAGetObjectFromMterp) # v0 <- GetObj(array, index) lw a1, THREAD_EXCEPTION_OFFSET(rSELF) PREFETCH_INST(2) # load rINST bnez a1, MterpException ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_OBJECT_GOTO(v0, rOBJ, t0) # vAA <- v0 /* ------------------------------ */ .balign 128 .L_op_aget_boolean: /* 0x47 */ /* File: mips/op_aget_boolean.S */ /* File: mips/op_aget.S */ /* * Array get, 32 bits or less. vAA <- vBB[vCC]. * * Note: using the usual FETCH/and/shift stuff, this fits in exactly 17 * instructions. We use a pair of FETCH_Bs instead. * * for: aget, aget-boolean, aget-byte, aget-char, aget-short * * NOTE: assumes data offset for arrays is the same for all non-wide types. * If this changes, specialize. */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EASN(a0, a0, a1, 0) # a0 <- arrayObj + index*width # a1 >= a3; compare unsigned index bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST lbu a2, MIRROR_BOOLEAN_ARRAY_DATA_OFFSET(a0) # a2 <- vBB[vCC] GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a2, rOBJ, t0) # vAA <- a2 /* ------------------------------ */ .balign 128 .L_op_aget_byte: /* 0x48 */ /* File: mips/op_aget_byte.S */ /* File: mips/op_aget.S */ /* * Array get, 32 bits or less. vAA <- vBB[vCC]. * * Note: using the usual FETCH/and/shift stuff, this fits in exactly 17 * instructions. We use a pair of FETCH_Bs instead. * * for: aget, aget-boolean, aget-byte, aget-char, aget-short * * NOTE: assumes data offset for arrays is the same for all non-wide types. * If this changes, specialize. */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EASN(a0, a0, a1, 0) # a0 <- arrayObj + index*width # a1 >= a3; compare unsigned index bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST lb a2, MIRROR_BYTE_ARRAY_DATA_OFFSET(a0) # a2 <- vBB[vCC] GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a2, rOBJ, t0) # vAA <- a2 /* ------------------------------ */ .balign 128 .L_op_aget_char: /* 0x49 */ /* File: mips/op_aget_char.S */ /* File: mips/op_aget.S */ /* * Array get, 32 bits or less. vAA <- vBB[vCC]. * * Note: using the usual FETCH/and/shift stuff, this fits in exactly 17 * instructions. We use a pair of FETCH_Bs instead. * * for: aget, aget-boolean, aget-byte, aget-char, aget-short * * NOTE: assumes data offset for arrays is the same for all non-wide types. * If this changes, specialize. */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EASN(a0, a0, a1, 1) # a0 <- arrayObj + index*width # a1 >= a3; compare unsigned index bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST lhu a2, MIRROR_CHAR_ARRAY_DATA_OFFSET(a0) # a2 <- vBB[vCC] GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a2, rOBJ, t0) # vAA <- a2 /* ------------------------------ */ .balign 128 .L_op_aget_short: /* 0x4a */ /* File: mips/op_aget_short.S */ /* File: mips/op_aget.S */ /* * Array get, 32 bits or less. vAA <- vBB[vCC]. * * Note: using the usual FETCH/and/shift stuff, this fits in exactly 17 * instructions. We use a pair of FETCH_Bs instead. * * for: aget, aget-boolean, aget-byte, aget-char, aget-short * * NOTE: assumes data offset for arrays is the same for all non-wide types. * If this changes, specialize. */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EASN(a0, a0, a1, 1) # a0 <- arrayObj + index*width # a1 >= a3; compare unsigned index bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST lh a2, MIRROR_SHORT_ARRAY_DATA_OFFSET(a0) # a2 <- vBB[vCC] GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a2, rOBJ, t0) # vAA <- a2 /* ------------------------------ */ .balign 128 .L_op_aput: /* 0x4b */ /* File: mips/op_aput.S */ /* * Array put, 32 bits or less. vBB[vCC] <- vAA. * * for: aput, aput-boolean, aput-byte, aput-char, aput-short * * NOTE: this assumes data offset for arrays is the same for all non-wide types. * If this changes, specialize. */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EASN(a0, a0, a1, 2) # a0 <- arrayObj + index*width bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_VREG(a2, rOBJ) # a2 <- vAA GET_INST_OPCODE(t0) # extract opcode from rINST GET_OPCODE_TARGET(t0) sw a2, MIRROR_INT_ARRAY_DATA_OFFSET(a0) # vBB[vCC] <- a2 JR(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_aput_wide: /* 0x4c */ /* File: mips/op_aput_wide.S */ /* * Array put, 64 bits. vBB[vCC] <- vAA. */ /* aput-wide vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(t0) # t0 <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EAS3(a0, a0, a1) # a0 <- arrayObj + index*width EAS2(rOBJ, rFP, t0) # rOBJ <- &fp[AA] # compare unsigned index, length bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST LOAD64(a2, a3, rOBJ) # a2/a3 <- vAA/vAA+1 GET_INST_OPCODE(t0) # extract opcode from rINST GET_OPCODE_TARGET(t0) STORE64_off(a2, a3, a0, MIRROR_WIDE_ARRAY_DATA_OFFSET) # a2/a3 <- vBB[vCC] JR(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_aput_object: /* 0x4d */ /* File: mips/op_aput_object.S */ /* * Store an object into an array. vBB[vCC] <- vAA. * */ /* op vAA, vBB, vCC */ EXPORT_PC() addu a0, rFP, OFF_FP_SHADOWFRAME move a1, rPC move a2, rINST JAL(MterpAputObject) beqz v0, MterpPossibleException FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_aput_boolean: /* 0x4e */ /* File: mips/op_aput_boolean.S */ /* File: mips/op_aput.S */ /* * Array put, 32 bits or less. vBB[vCC] <- vAA. * * for: aput, aput-boolean, aput-byte, aput-char, aput-short * * NOTE: this assumes data offset for arrays is the same for all non-wide types. * If this changes, specialize. */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EASN(a0, a0, a1, 0) # a0 <- arrayObj + index*width bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_VREG(a2, rOBJ) # a2 <- vAA GET_INST_OPCODE(t0) # extract opcode from rINST GET_OPCODE_TARGET(t0) sb a2, MIRROR_BOOLEAN_ARRAY_DATA_OFFSET(a0) # vBB[vCC] <- a2 JR(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_aput_byte: /* 0x4f */ /* File: mips/op_aput_byte.S */ /* File: mips/op_aput.S */ /* * Array put, 32 bits or less. vBB[vCC] <- vAA. * * for: aput, aput-boolean, aput-byte, aput-char, aput-short * * NOTE: this assumes data offset for arrays is the same for all non-wide types. * If this changes, specialize. */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EASN(a0, a0, a1, 0) # a0 <- arrayObj + index*width bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_VREG(a2, rOBJ) # a2 <- vAA GET_INST_OPCODE(t0) # extract opcode from rINST GET_OPCODE_TARGET(t0) sb a2, MIRROR_BYTE_ARRAY_DATA_OFFSET(a0) # vBB[vCC] <- a2 JR(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_aput_char: /* 0x50 */ /* File: mips/op_aput_char.S */ /* File: mips/op_aput.S */ /* * Array put, 32 bits or less. vBB[vCC] <- vAA. * * for: aput, aput-boolean, aput-byte, aput-char, aput-short * * NOTE: this assumes data offset for arrays is the same for all non-wide types. * If this changes, specialize. */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EASN(a0, a0, a1, 1) # a0 <- arrayObj + index*width bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_VREG(a2, rOBJ) # a2 <- vAA GET_INST_OPCODE(t0) # extract opcode from rINST GET_OPCODE_TARGET(t0) sh a2, MIRROR_CHAR_ARRAY_DATA_OFFSET(a0) # vBB[vCC] <- a2 JR(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_aput_short: /* 0x51 */ /* File: mips/op_aput_short.S */ /* File: mips/op_aput.S */ /* * Array put, 32 bits or less. vBB[vCC] <- vAA. * * for: aput, aput-boolean, aput-byte, aput-char, aput-short * * NOTE: this assumes data offset for arrays is the same for all non-wide types. * If this changes, specialize. */ /* op vAA, vBB, vCC */ FETCH_B(a2, 1, 0) # a2 <- BB GET_OPA(rOBJ) # rOBJ <- AA FETCH_B(a3, 1, 1) # a3 <- CC GET_VREG(a0, a2) # a0 <- vBB (array object) GET_VREG(a1, a3) # a1 <- vCC (requested index) # null array object? beqz a0, common_errNullObject # yes, bail LOAD_base_offMirrorArray_length(a3, a0) # a3 <- arrayObj->length EASN(a0, a0, a1, 1) # a0 <- arrayObj + index*width bgeu a1, a3, common_errArrayIndex # index >= length, bail FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_VREG(a2, rOBJ) # a2 <- vAA GET_INST_OPCODE(t0) # extract opcode from rINST GET_OPCODE_TARGET(t0) sh a2, MIRROR_SHORT_ARRAY_DATA_OFFSET(a0) # vBB[vCC] <- a2 JR(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iget: /* 0x52 */ /* File: mips/op_iget.S */ /* * General instance field get. * * for: iget, iget-object, iget-boolean, iget-byte, iget-char, iget-short */ /* op vA, vB, field@CCCC */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- referrer move a3, rSELF # a3 <- self JAL(artGet32InstanceFromCode) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA4(a2) # a2<- A+ PREFETCH_INST(2) # load rINST bnez a3, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[A] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[A] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_iget_wide: /* 0x53 */ /* File: mips/op_iget_wide.S */ /* * 64-bit instance field get. * * for: iget-wide */ /* op vA, vB, field@CCCC */ EXPORT_PC() FETCH(a0, 1) # a0 <- field byte offset GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- referrer move a3, rSELF # a3 <- self JAL(artGet64InstanceFromCode) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA4(a2) # a2<- A+ PREFETCH_INST(2) # load rINST bnez a3, MterpException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, a2, t0) # fp[A] <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_iget_object: /* 0x54 */ /* File: mips/op_iget_object.S */ /* File: mips/op_iget.S */ /* * General instance field get. * * for: iget, iget-object, iget-boolean, iget-byte, iget-char, iget-short */ /* op vA, vB, field@CCCC */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- referrer move a3, rSELF # a3 <- self JAL(artGetObjInstanceFromCode) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA4(a2) # a2<- A+ PREFETCH_INST(2) # load rINST bnez a3, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST .if 1 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[A] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[A] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_iget_boolean: /* 0x55 */ /* File: mips/op_iget_boolean.S */ /* File: mips/op_iget.S */ /* * General instance field get. * * for: iget, iget-object, iget-boolean, iget-byte, iget-char, iget-short */ /* op vA, vB, field@CCCC */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- referrer move a3, rSELF # a3 <- self JAL(artGetBooleanInstanceFromCode) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA4(a2) # a2<- A+ PREFETCH_INST(2) # load rINST bnez a3, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[A] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[A] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_iget_byte: /* 0x56 */ /* File: mips/op_iget_byte.S */ /* File: mips/op_iget.S */ /* * General instance field get. * * for: iget, iget-object, iget-boolean, iget-byte, iget-char, iget-short */ /* op vA, vB, field@CCCC */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- referrer move a3, rSELF # a3 <- self JAL(artGetByteInstanceFromCode) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA4(a2) # a2<- A+ PREFETCH_INST(2) # load rINST bnez a3, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[A] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[A] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_iget_char: /* 0x57 */ /* File: mips/op_iget_char.S */ /* File: mips/op_iget.S */ /* * General instance field get. * * for: iget, iget-object, iget-boolean, iget-byte, iget-char, iget-short */ /* op vA, vB, field@CCCC */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- referrer move a3, rSELF # a3 <- self JAL(artGetCharInstanceFromCode) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA4(a2) # a2<- A+ PREFETCH_INST(2) # load rINST bnez a3, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[A] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[A] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_iget_short: /* 0x58 */ /* File: mips/op_iget_short.S */ /* File: mips/op_iget.S */ /* * General instance field get. * * for: iget, iget-object, iget-boolean, iget-byte, iget-char, iget-short */ /* op vA, vB, field@CCCC */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- referrer move a3, rSELF # a3 <- self JAL(artGetShortInstanceFromCode) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA4(a2) # a2<- A+ PREFETCH_INST(2) # load rINST bnez a3, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[A] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[A] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_iput: /* 0x59 */ /* File: mips/op_iput.S */ /* * General 32-bit instance field put. * * for: iput, iput-boolean, iput-byte, iput-char, iput-short */ /* op vA, vB, field@CCCC */ .extern artSet32InstanceFromMterp EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer GET_OPA4(a2) # a2 <- A+ GET_VREG(a2, a2) # a2 <- fp[A] lw a3, OFF_FP_METHOD(rFP) # a3 <- referrer PREFETCH_INST(2) # load rINST JAL(artSet32InstanceFromMterp) bnez v0, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_wide: /* 0x5a */ /* File: mips/op_iput_wide.S */ /* iput-wide vA, vB, field@CCCC */ .extern artSet64InstanceFromMterp EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer GET_OPA4(a2) # a2 <- A+ EAS2(a2, rFP, a2) # a2 <- &fp[A] lw a3, OFF_FP_METHOD(rFP) # a3 <- referrer PREFETCH_INST(2) # load rINST JAL(artSet64InstanceFromMterp) bnez v0, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_object: /* 0x5b */ /* File: mips/op_iput_object.S */ /* * 32-bit instance field put. * * for: iput-object, iput-object-volatile */ /* op vA, vB, field@CCCC */ EXPORT_PC() addu a0, rFP, OFF_FP_SHADOWFRAME move a1, rPC move a2, rINST move a3, rSELF JAL(MterpIputObject) beqz v0, MterpException FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_boolean: /* 0x5c */ /* File: mips/op_iput_boolean.S */ /* File: mips/op_iput.S */ /* * General 32-bit instance field put. * * for: iput, iput-boolean, iput-byte, iput-char, iput-short */ /* op vA, vB, field@CCCC */ .extern artSet8InstanceFromMterp EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer GET_OPA4(a2) # a2 <- A+ GET_VREG(a2, a2) # a2 <- fp[A] lw a3, OFF_FP_METHOD(rFP) # a3 <- referrer PREFETCH_INST(2) # load rINST JAL(artSet8InstanceFromMterp) bnez v0, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_byte: /* 0x5d */ /* File: mips/op_iput_byte.S */ /* File: mips/op_iput.S */ /* * General 32-bit instance field put. * * for: iput, iput-boolean, iput-byte, iput-char, iput-short */ /* op vA, vB, field@CCCC */ .extern artSet8InstanceFromMterp EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer GET_OPA4(a2) # a2 <- A+ GET_VREG(a2, a2) # a2 <- fp[A] lw a3, OFF_FP_METHOD(rFP) # a3 <- referrer PREFETCH_INST(2) # load rINST JAL(artSet8InstanceFromMterp) bnez v0, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_char: /* 0x5e */ /* File: mips/op_iput_char.S */ /* File: mips/op_iput.S */ /* * General 32-bit instance field put. * * for: iput, iput-boolean, iput-byte, iput-char, iput-short */ /* op vA, vB, field@CCCC */ .extern artSet16InstanceFromMterp EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer GET_OPA4(a2) # a2 <- A+ GET_VREG(a2, a2) # a2 <- fp[A] lw a3, OFF_FP_METHOD(rFP) # a3 <- referrer PREFETCH_INST(2) # load rINST JAL(artSet16InstanceFromMterp) bnez v0, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_short: /* 0x5f */ /* File: mips/op_iput_short.S */ /* File: mips/op_iput.S */ /* * General 32-bit instance field put. * * for: iput, iput-boolean, iput-byte, iput-char, iput-short */ /* op vA, vB, field@CCCC */ .extern artSet16InstanceFromMterp EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPB(a1) # a1 <- B GET_VREG(a1, a1) # a1 <- fp[B], the object pointer GET_OPA4(a2) # a2 <- A+ GET_VREG(a2, a2) # a2 <- fp[A] lw a3, OFF_FP_METHOD(rFP) # a3 <- referrer PREFETCH_INST(2) # load rINST JAL(artSet16InstanceFromMterp) bnez v0, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_sget: /* 0x60 */ /* File: mips/op_sget.S */ /* * General SGET handler. * * for: sget, sget-object, sget-boolean, sget-byte, sget-char, sget-short */ /* op vAA, field@BBBB */ .extern MterpGet32Static EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB lw a1, OFF_FP_METHOD(rFP) # a1 <- method move a2, rSELF # a2 <- self JAL(MterpGet32Static) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA(a2) # a2 <- AA PREFETCH_INST(2) bnez a3, MterpException # bail out ADVANCE(2) GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[AA] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[AA] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_sget_wide: /* 0x61 */ /* File: mips/op_sget_wide.S */ /* * 64-bit SGET handler. */ /* sget-wide vAA, field@BBBB */ .extern MterpGet64Static EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB lw a1, OFF_FP_METHOD(rFP) # a1 <- method move a2, rSELF # a2 <- self JAL(MterpGet64Static) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) bnez a3, MterpException GET_OPA(a1) # a1 <- AA FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, a1, t0) # vAA/vAA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_sget_object: /* 0x62 */ /* File: mips/op_sget_object.S */ /* File: mips/op_sget.S */ /* * General SGET handler. * * for: sget, sget-object, sget-boolean, sget-byte, sget-char, sget-short */ /* op vAA, field@BBBB */ .extern MterpGetObjStatic EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB lw a1, OFF_FP_METHOD(rFP) # a1 <- method move a2, rSELF # a2 <- self JAL(MterpGetObjStatic) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA(a2) # a2 <- AA PREFETCH_INST(2) bnez a3, MterpException # bail out ADVANCE(2) GET_INST_OPCODE(t0) # extract opcode from rINST .if 1 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[AA] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[AA] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_sget_boolean: /* 0x63 */ /* File: mips/op_sget_boolean.S */ /* File: mips/op_sget.S */ /* * General SGET handler. * * for: sget, sget-object, sget-boolean, sget-byte, sget-char, sget-short */ /* op vAA, field@BBBB */ .extern MterpGetBooleanStatic EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB lw a1, OFF_FP_METHOD(rFP) # a1 <- method move a2, rSELF # a2 <- self JAL(MterpGetBooleanStatic) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA(a2) # a2 <- AA PREFETCH_INST(2) bnez a3, MterpException # bail out ADVANCE(2) GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[AA] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[AA] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_sget_byte: /* 0x64 */ /* File: mips/op_sget_byte.S */ /* File: mips/op_sget.S */ /* * General SGET handler. * * for: sget, sget-object, sget-boolean, sget-byte, sget-char, sget-short */ /* op vAA, field@BBBB */ .extern MterpGetByteStatic EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB lw a1, OFF_FP_METHOD(rFP) # a1 <- method move a2, rSELF # a2 <- self JAL(MterpGetByteStatic) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA(a2) # a2 <- AA PREFETCH_INST(2) bnez a3, MterpException # bail out ADVANCE(2) GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[AA] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[AA] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_sget_char: /* 0x65 */ /* File: mips/op_sget_char.S */ /* File: mips/op_sget.S */ /* * General SGET handler. * * for: sget, sget-object, sget-boolean, sget-byte, sget-char, sget-short */ /* op vAA, field@BBBB */ .extern MterpGetCharStatic EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB lw a1, OFF_FP_METHOD(rFP) # a1 <- method move a2, rSELF # a2 <- self JAL(MterpGetCharStatic) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA(a2) # a2 <- AA PREFETCH_INST(2) bnez a3, MterpException # bail out ADVANCE(2) GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[AA] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[AA] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_sget_short: /* 0x66 */ /* File: mips/op_sget_short.S */ /* File: mips/op_sget.S */ /* * General SGET handler. * * for: sget, sget-object, sget-boolean, sget-byte, sget-char, sget-short */ /* op vAA, field@BBBB */ .extern MterpGetShortStatic EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB lw a1, OFF_FP_METHOD(rFP) # a1 <- method move a2, rSELF # a2 <- self JAL(MterpGetShortStatic) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA(a2) # a2 <- AA PREFETCH_INST(2) bnez a3, MterpException # bail out ADVANCE(2) GET_INST_OPCODE(t0) # extract opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[AA] <- v0 .else SET_VREG_GOTO(v0, a2, t0) # fp[AA] <- v0 .endif /* ------------------------------ */ .balign 128 .L_op_sput: /* 0x67 */ /* File: mips/op_sput.S */ /* * General SPUT handler. * * for: sput, sput-boolean, sput-byte, sput-char, sput-short */ /* op vAA, field@BBBB */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB GET_OPA(a3) # a3 <- AA GET_VREG(a1, a3) # a1 <- fp[AA], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- method move a3, rSELF # a3 <- self PREFETCH_INST(2) # load rINST JAL(MterpSet32Static) bnez v0, MterpException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_sput_wide: /* 0x68 */ /* File: mips/op_sput_wide.S */ /* * 64-bit SPUT handler. */ /* sput-wide vAA, field@BBBB */ .extern MterpSet64Static EXPORT_PC() FETCH(a0, 1) # a0 <- field ref CCCC GET_OPA(a1) # a1 <- AA EAS2(a1, rFP, a1) # a1 <- &fp[AA] lw a2, OFF_FP_METHOD(rFP) # a2 <- method move a3, rSELF # a3 <- self PREFETCH_INST(2) # load rINST JAL(MterpSet64Static) bnez v0, MterpException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_sput_object: /* 0x69 */ /* File: mips/op_sput_object.S */ /* * General 32-bit SPUT handler. * * for: sput-object, */ /* op vAA, field@BBBB */ EXPORT_PC() addu a0, rFP, OFF_FP_SHADOWFRAME move a1, rPC move a2, rINST move a3, rSELF JAL(MterpSputObject) beqz v0, MterpException FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_sput_boolean: /* 0x6a */ /* File: mips/op_sput_boolean.S */ /* File: mips/op_sput.S */ /* * General SPUT handler. * * for: sput, sput-boolean, sput-byte, sput-char, sput-short */ /* op vAA, field@BBBB */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB GET_OPA(a3) # a3 <- AA GET_VREG(a1, a3) # a1 <- fp[AA], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- method move a3, rSELF # a3 <- self PREFETCH_INST(2) # load rINST JAL(MterpSetBooleanStatic) bnez v0, MterpException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_sput_byte: /* 0x6b */ /* File: mips/op_sput_byte.S */ /* File: mips/op_sput.S */ /* * General SPUT handler. * * for: sput, sput-boolean, sput-byte, sput-char, sput-short */ /* op vAA, field@BBBB */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB GET_OPA(a3) # a3 <- AA GET_VREG(a1, a3) # a1 <- fp[AA], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- method move a3, rSELF # a3 <- self PREFETCH_INST(2) # load rINST JAL(MterpSetByteStatic) bnez v0, MterpException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_sput_char: /* 0x6c */ /* File: mips/op_sput_char.S */ /* File: mips/op_sput.S */ /* * General SPUT handler. * * for: sput, sput-boolean, sput-byte, sput-char, sput-short */ /* op vAA, field@BBBB */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB GET_OPA(a3) # a3 <- AA GET_VREG(a1, a3) # a1 <- fp[AA], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- method move a3, rSELF # a3 <- self PREFETCH_INST(2) # load rINST JAL(MterpSetCharStatic) bnez v0, MterpException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_sput_short: /* 0x6d */ /* File: mips/op_sput_short.S */ /* File: mips/op_sput.S */ /* * General SPUT handler. * * for: sput, sput-boolean, sput-byte, sput-char, sput-short */ /* op vAA, field@BBBB */ EXPORT_PC() FETCH(a0, 1) # a0 <- field ref BBBB GET_OPA(a3) # a3 <- AA GET_VREG(a1, a3) # a1 <- fp[AA], the object pointer lw a2, OFF_FP_METHOD(rFP) # a2 <- method move a3, rSELF # a3 <- self PREFETCH_INST(2) # load rINST JAL(MterpSetShortStatic) bnez v0, MterpException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_invoke_virtual: /* 0x6e */ /* File: mips/op_invoke_virtual.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeVirtual EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeVirtual) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_invoke_super: /* 0x6f */ /* File: mips/op_invoke_super.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeSuper EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeSuper) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_invoke_direct: /* 0x70 */ /* File: mips/op_invoke_direct.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeDirect EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeDirect) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_invoke_static: /* 0x71 */ /* File: mips/op_invoke_static.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeStatic EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeStatic) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_invoke_interface: /* 0x72 */ /* File: mips/op_invoke_interface.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeInterface EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeInterface) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_return_void_no_barrier: /* 0x73 */ /* File: mips/op_return_void_no_barrier.S */ lw ra, THREAD_FLAGS_OFFSET(rSELF) move a0, rSELF and ra, THREAD_SUSPEND_OR_CHECKPOINT_REQUEST beqz ra, 1f JAL(MterpSuspendCheck) # (self) 1: move v0, zero move v1, zero b MterpReturn /* ------------------------------ */ .balign 128 .L_op_invoke_virtual_range: /* 0x74 */ /* File: mips/op_invoke_virtual_range.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeVirtualRange EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeVirtualRange) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_invoke_super_range: /* 0x75 */ /* File: mips/op_invoke_super_range.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeSuperRange EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeSuperRange) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_invoke_direct_range: /* 0x76 */ /* File: mips/op_invoke_direct_range.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeDirectRange EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeDirectRange) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_invoke_static_range: /* 0x77 */ /* File: mips/op_invoke_static_range.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeStaticRange EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeStaticRange) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_invoke_interface_range: /* 0x78 */ /* File: mips/op_invoke_interface_range.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeInterfaceRange EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeInterfaceRange) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_unused_79: /* 0x79 */ /* File: mips/op_unused_79.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_7a: /* 0x7a */ /* File: mips/op_unused_7a.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_neg_int: /* 0x7b */ /* File: mips/op_neg_int.S */ /* File: mips/unop.S */ /* * Generic 32-bit unary operation. Provide an "instr" line that * specifies an instruction that performs "result0 = op a0". * This could be a MIPS instruction or a function call. * * for: int-to-byte, int-to-char, int-to-short, * neg-int, not-int, neg-float */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(t0) # t0 <- A+ GET_VREG(a0, a3) # a0 <- vB FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op negu a0, a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t1) # extract opcode from rINST SET_VREG_GOTO(a0, t0, t1) # vA <- result0 /* ------------------------------ */ .balign 128 .L_op_not_int: /* 0x7c */ /* File: mips/op_not_int.S */ /* File: mips/unop.S */ /* * Generic 32-bit unary operation. Provide an "instr" line that * specifies an instruction that performs "result0 = op a0". * This could be a MIPS instruction or a function call. * * for: int-to-byte, int-to-char, int-to-short, * neg-int, not-int, neg-float */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(t0) # t0 <- A+ GET_VREG(a0, a3) # a0 <- vB FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op not a0, a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t1) # extract opcode from rINST SET_VREG_GOTO(a0, t0, t1) # vA <- result0 /* ------------------------------ */ .balign 128 .L_op_neg_long: /* 0x7d */ /* File: mips/op_neg_long.S */ /* File: mips/unopWide.S */ /* * Generic 64-bit unary operation. Provide an "instr" line that * specifies an instruction that performs "result0/result1 = op a0/a1". * This could be MIPS instruction or a function call. * * For: neg-long, not-long, neg-double, */ /* unop vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B EAS2(a3, rFP, a3) # a3 <- &fp[B] LOAD64(a0, a1, a3) # a0/a1 <- vA FETCH_ADVANCE_INST(1) # advance rPC, load rINST negu v0, a0 # optional op negu v1, a1; sltu a0, zero, v0; subu v1, v1, a0 # a0/a1 <- op, a2-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vA/vA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_not_long: /* 0x7e */ /* File: mips/op_not_long.S */ /* File: mips/unopWide.S */ /* * Generic 64-bit unary operation. Provide an "instr" line that * specifies an instruction that performs "result0/result1 = op a0/a1". * This could be MIPS instruction or a function call. * * For: neg-long, not-long, neg-double, */ /* unop vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B EAS2(a3, rFP, a3) # a3 <- &fp[B] LOAD64(a0, a1, a3) # a0/a1 <- vA FETCH_ADVANCE_INST(1) # advance rPC, load rINST not a0, a0 # optional op not a1, a1 # a0/a1 <- op, a2-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, rOBJ, t0) # vA/vA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_neg_float: /* 0x7f */ /* File: mips/op_neg_float.S */ /* File: mips/unop.S */ /* * Generic 32-bit unary operation. Provide an "instr" line that * specifies an instruction that performs "result0 = op a0". * This could be a MIPS instruction or a function call. * * for: int-to-byte, int-to-char, int-to-short, * neg-int, not-int, neg-float */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(t0) # t0 <- A+ GET_VREG(a0, a3) # a0 <- vB FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op addu a0, a0, 0x80000000 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t1) # extract opcode from rINST SET_VREG_GOTO(a0, t0, t1) # vA <- result0 /* ------------------------------ */ .balign 128 .L_op_neg_double: /* 0x80 */ /* File: mips/op_neg_double.S */ /* File: mips/unopWide.S */ /* * Generic 64-bit unary operation. Provide an "instr" line that * specifies an instruction that performs "result0/result1 = op a0/a1". * This could be MIPS instruction or a function call. * * For: neg-long, not-long, neg-double, */ /* unop vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B EAS2(a3, rFP, a3) # a3 <- &fp[B] LOAD64(a0, a1, a3) # a0/a1 <- vA FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op addu a1, a1, 0x80000000 # a0/a1 <- op, a2-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, rOBJ, t0) # vA/vA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_int_to_long: /* 0x81 */ /* File: mips/op_int_to_long.S */ /* File: mips/unopWider.S */ /* * Generic 32bit-to-64bit unary operation. Provide an "instr" line * that specifies an instruction that performs "result0/result1 = op a0". * * For: int-to-long */ /* unop vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, a3) # a0 <- vB FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op sra a1, a0, 31 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, rOBJ, t0) # vA/vA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_int_to_float: /* 0x82 */ /* File: mips/op_int_to_float.S */ /* File: mips/funop.S */ /* * Generic 32-bit floating-point unary operation. Provide an "instr" * line that specifies an instruction that performs "fv0 = op fa0". * This could be a MIPS instruction or a function call. * * for: int-to-float */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG_F(fa0, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST cvt.s.w fv0, fa0 GET_INST_OPCODE(t1) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t1) # vA <- fv0 /* ------------------------------ */ .balign 128 .L_op_int_to_double: /* 0x83 */ /* File: mips/op_int_to_double.S */ /* File: mips/funopWider.S */ /* * Generic 32bit-to-64bit floating-point unary operation. Provide an "instr" * line that specifies an instruction that performs "fv0 = op fa0". * * For: int-to-double, float-to-double */ /* unop vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG_F(fa0, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST cvt.d.w fv0, fa0 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vA/vA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_long_to_int: /* 0x84 */ /* File: mips/op_long_to_int.S */ /* we ignore the high word, making this equivalent to a 32-bit reg move */ /* File: mips/op_move.S */ /* for move, move-object, long-to-int */ /* op vA, vB */ GET_OPB(a1) # a1 <- B from 15:12 GET_OPA4(a0) # a0 <- A from 11:8 FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_VREG(a2, a1) # a2 <- fp[B] GET_INST_OPCODE(t0) # t0 <- opcode from rINST .if 0 SET_VREG_OBJECT_GOTO(a2, a0, t0) # fp[A] <- a2 .else SET_VREG_GOTO(a2, a0, t0) # fp[A] <- a2 .endif /* ------------------------------ */ .balign 128 .L_op_long_to_float: /* 0x85 */ /* File: mips/op_long_to_float.S */ /* * long-to-float */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(rOBJ) # rOBJ <- A+ EAS2(a3, rFP, a3) # a3 <- &fp[B] #ifdef MIPS32REVGE6 LOAD64_F(fv0, fv0f, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST cvt.s.l fv0, fv0 #else LOAD64(rARG0, rARG1, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST JAL(__floatdisf) #endif GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vA <- fv0 /* ------------------------------ */ .balign 128 .L_op_long_to_double: /* 0x86 */ /* File: mips/op_long_to_double.S */ /* * long-to-double */ /* unop vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B EAS2(a3, rFP, a3) # a3 <- &fp[B] #ifdef MIPS32REVGE6 LOAD64_F(fv0, fv0f, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST cvt.d.l fv0, fv0 #else LOAD64(rARG0, rARG1, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST JAL(__floatdidf) # a0/a1 <- op, a2-a3 changed #endif GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vA/vA+1 <- result /* ------------------------------ */ .balign 128 .L_op_float_to_int: /* 0x87 */ /* File: mips/op_float_to_int.S */ /* * float-to-int * * We have to clip values to int min/max per the specification. The * expected common case is a "reasonable" value that converts directly * to modest integer. The EABI convert function isn't doing this for us. */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG_F(fa0, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST li t0, INT_MIN_AS_FLOAT mtc1 t0, fa1 #ifdef MIPS32REVGE6 /* * TODO: simplify this when the MIPS64R6 emulator * supports NAN2008=1. */ cmp.le.s ft0, fa1, fa0 GET_INST_OPCODE(t1) # extract opcode from rINST bc1nez ft0, 1f # if INT_MIN <= vB, proceed to truncation cmp.eq.s ft0, fa0, fa0 selnez.s fa0, fa1, ft0 # fa0 = ordered(vB) ? INT_MIN_AS_FLOAT : 0 #else c.ole.s fcc0, fa1, fa0 GET_INST_OPCODE(t1) # extract opcode from rINST bc1t fcc0, 1f # if INT_MIN <= vB, proceed to truncation c.eq.s fcc0, fa0, fa0 mtc1 zero, fa0 movt.s fa0, fa1, fcc0 # fa0 = ordered(vB) ? INT_MIN_AS_FLOAT : 0 #endif 1: trunc.w.s fa0, fa0 SET_VREG_F_GOTO(fa0, rOBJ, t1) # vA <- result /* ------------------------------ */ .balign 128 .L_op_float_to_long: /* 0x88 */ /* File: mips/op_float_to_long.S */ /* * float-to-long * * We have to clip values to long min/max per the specification. The * expected common case is a "reasonable" value that converts directly * to modest integer. The EABI convert function isn't doing this for us. */ /* unop vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG_F(fa0, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST #ifdef MIPS32REVGE6 /* * TODO: simplify this when the MIPS64R6 emulator * supports NAN2008=1. */ li t0, LONG_MIN_AS_FLOAT mtc1 t0, fa1 cmp.le.s ft0, fa1, fa0 GET_INST_OPCODE(t1) # extract opcode from rINST bc1nez ft0, 1f # if LONG_MIN <= vB, proceed to truncation cmp.eq.s ft0, fa0, fa0 selnez.s fa0, fa1, ft0 # fa0 = ordered(vB) ? LONG_MIN_AS_FLOAT : 0 1: trunc.l.s fa0, fa0 SET_VREG64_F_GOTO(fa0, fa0f, rOBJ, t1) # vA <- result #else c.eq.s fcc0, fa0, fa0 li rRESULT0, 0 li rRESULT1, 0 bc1f fcc0, .Lop_float_to_long_get_opcode li t0, LONG_MIN_AS_FLOAT mtc1 t0, fa1 c.ole.s fcc0, fa0, fa1 li rRESULT1, LONG_MIN_HIGH bc1t fcc0, .Lop_float_to_long_get_opcode neg.s fa1, fa1 c.ole.s fcc0, fa1, fa0 nor rRESULT0, rRESULT0, zero nor rRESULT1, rRESULT1, zero bc1t fcc0, .Lop_float_to_long_get_opcode JAL(__fixsfdi) GET_INST_OPCODE(t1) # extract opcode from rINST b .Lop_float_to_long_set_vreg #endif /* ------------------------------ */ .balign 128 .L_op_float_to_double: /* 0x89 */ /* File: mips/op_float_to_double.S */ /* File: mips/funopWider.S */ /* * Generic 32bit-to-64bit floating-point unary operation. Provide an "instr" * line that specifies an instruction that performs "fv0 = op fa0". * * For: int-to-double, float-to-double */ /* unop vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG_F(fa0, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST cvt.d.s fv0, fa0 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vA/vA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_double_to_int: /* 0x8a */ /* File: mips/op_double_to_int.S */ /* * double-to-int * * We have to clip values to int min/max per the specification. The * expected common case is a "reasonable" value that converts directly * to modest integer. The EABI convert function isn't doing this for us. */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(rOBJ) # rOBJ <- A+ EAS2(a3, rFP, a3) # a3 <- &fp[B] LOAD64_F(fa0, fa0f, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST li t0, INT_MIN_AS_DOUBLE_HIGH mtc1 zero, fa1 MOVE_TO_FPU_HIGH(t0, fa1, fa1f) #ifdef MIPS32REVGE6 /* * TODO: simplify this when the MIPS64R6 emulator * supports NAN2008=1. */ cmp.le.d ft0, fa1, fa0 GET_INST_OPCODE(t1) # extract opcode from rINST bc1nez ft0, 1f # if INT_MIN <= vB, proceed to truncation cmp.eq.d ft0, fa0, fa0 selnez.d fa0, fa1, ft0 # fa0 = ordered(vB) ? INT_MIN_AS_DOUBLE : 0 #else c.ole.d fcc0, fa1, fa0 GET_INST_OPCODE(t1) # extract opcode from rINST bc1t fcc0, 1f # if INT_MIN <= vB, proceed to truncation c.eq.d fcc0, fa0, fa0 mtc1 zero, fa0 MOVE_TO_FPU_HIGH(zero, fa0, fa0f) movt.d fa0, fa1, fcc0 # fa0 = ordered(vB) ? INT_MIN_AS_DOUBLE : 0 #endif 1: trunc.w.d fa0, fa0 SET_VREG_F_GOTO(fa0, rOBJ, t1) # vA <- result /* ------------------------------ */ .balign 128 .L_op_double_to_long: /* 0x8b */ /* File: mips/op_double_to_long.S */ /* * double-to-long * * We have to clip values to long min/max per the specification. The * expected common case is a "reasonable" value that converts directly * to modest integer. The EABI convert function isn't doing this for us. */ /* unop vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B EAS2(a3, rFP, a3) # a3 <- &fp[B] LOAD64_F(fa0, fa0f, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST #ifdef MIPS32REVGE6 /* * TODO: simplify this when the MIPS64R6 emulator * supports NAN2008=1. */ li t0, LONG_MIN_AS_DOUBLE_HIGH mtc1 zero, fa1 mthc1 t0, fa1 cmp.le.d ft0, fa1, fa0 GET_INST_OPCODE(t1) # extract opcode from rINST bc1nez ft0, 1f # if LONG_MIN <= vB, proceed to truncation cmp.eq.d ft0, fa0, fa0 selnez.d fa0, fa1, ft0 # fa0 = ordered(vB) ? LONG_MIN_AS_DOUBLE : 0 1: trunc.l.d fa0, fa0 SET_VREG64_F_GOTO(fa0, fa0f, rOBJ, t1) # vA <- result #else c.eq.d fcc0, fa0, fa0 li rRESULT0, 0 li rRESULT1, 0 bc1f fcc0, .Lop_double_to_long_get_opcode li t0, LONG_MIN_AS_DOUBLE_HIGH mtc1 zero, fa1 MOVE_TO_FPU_HIGH(t0, fa1, fa1f) c.ole.d fcc0, fa0, fa1 li rRESULT1, LONG_MIN_HIGH bc1t fcc0, .Lop_double_to_long_get_opcode neg.d fa1, fa1 c.ole.d fcc0, fa1, fa0 nor rRESULT0, rRESULT0, zero nor rRESULT1, rRESULT1, zero bc1t fcc0, .Lop_double_to_long_get_opcode JAL(__fixdfdi) GET_INST_OPCODE(t1) # extract opcode from rINST b .Lop_double_to_long_set_vreg #endif /* ------------------------------ */ .balign 128 .L_op_double_to_float: /* 0x8c */ /* File: mips/op_double_to_float.S */ /* File: mips/unopNarrower.S */ /* * Generic 64bit-to-32bit floating-point unary operation. Provide an "instr" * line that specifies an instruction that performs "fv0 = op fa0". * * For: double-to-float */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(rOBJ) # rOBJ <- A+ EAS2(a3, rFP, a3) # a3 <- &fp[B] LOAD64_F(fa0, fa0f, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST cvt.s.d fv0, fa0 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vA <- fv0 /* ------------------------------ */ .balign 128 .L_op_int_to_byte: /* 0x8d */ /* File: mips/op_int_to_byte.S */ /* File: mips/unop.S */ /* * Generic 32-bit unary operation. Provide an "instr" line that * specifies an instruction that performs "result0 = op a0". * This could be a MIPS instruction or a function call. * * for: int-to-byte, int-to-char, int-to-short, * neg-int, not-int, neg-float */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(t0) # t0 <- A+ GET_VREG(a0, a3) # a0 <- vB FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op SEB(a0, a0) # a0 <- op, a0-a3 changed GET_INST_OPCODE(t1) # extract opcode from rINST SET_VREG_GOTO(a0, t0, t1) # vA <- result0 /* ------------------------------ */ .balign 128 .L_op_int_to_char: /* 0x8e */ /* File: mips/op_int_to_char.S */ /* File: mips/unop.S */ /* * Generic 32-bit unary operation. Provide an "instr" line that * specifies an instruction that performs "result0 = op a0". * This could be a MIPS instruction or a function call. * * for: int-to-byte, int-to-char, int-to-short, * neg-int, not-int, neg-float */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(t0) # t0 <- A+ GET_VREG(a0, a3) # a0 <- vB FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op and a0, 0xffff # a0 <- op, a0-a3 changed GET_INST_OPCODE(t1) # extract opcode from rINST SET_VREG_GOTO(a0, t0, t1) # vA <- result0 /* ------------------------------ */ .balign 128 .L_op_int_to_short: /* 0x8f */ /* File: mips/op_int_to_short.S */ /* File: mips/unop.S */ /* * Generic 32-bit unary operation. Provide an "instr" line that * specifies an instruction that performs "result0 = op a0". * This could be a MIPS instruction or a function call. * * for: int-to-byte, int-to-char, int-to-short, * neg-int, not-int, neg-float */ /* unop vA, vB */ GET_OPB(a3) # a3 <- B GET_OPA4(t0) # t0 <- A+ GET_VREG(a0, a3) # a0 <- vB FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op SEH(a0, a0) # a0 <- op, a0-a3 changed GET_INST_OPCODE(t1) # extract opcode from rINST SET_VREG_GOTO(a0, t0, t1) # vA <- result0 /* ------------------------------ */ .balign 128 .L_op_add_int: /* 0x90 */ /* File: mips/op_add_int.S */ /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op addu a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_sub_int: /* 0x91 */ /* File: mips/op_sub_int.S */ /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op subu a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_mul_int: /* 0x92 */ /* File: mips/op_mul_int.S */ /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op mul a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_div_int: /* 0x93 */ /* File: mips/op_div_int.S */ #ifdef MIPS32REVGE6 /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op div a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 #else /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST div zero, a0, a1 # optional op mflo a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 #endif /* ------------------------------ */ .balign 128 .L_op_rem_int: /* 0x94 */ /* File: mips/op_rem_int.S */ #ifdef MIPS32REVGE6 /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op mod a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 #else /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST div zero, a0, a1 # optional op mfhi a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 #endif /* ------------------------------ */ .balign 128 .L_op_and_int: /* 0x95 */ /* File: mips/op_and_int.S */ /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op and a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_or_int: /* 0x96 */ /* File: mips/op_or_int.S */ /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op or a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_xor_int: /* 0x97 */ /* File: mips/op_xor_int.S */ /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op xor a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_shl_int: /* 0x98 */ /* File: mips/op_shl_int.S */ /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op sll a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_shr_int: /* 0x99 */ /* File: mips/op_shr_int.S */ /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op sra a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_ushr_int: /* 0x9a */ /* File: mips/op_ushr_int.S */ /* File: mips/binop.S */ /* * Generic 32-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0 op a1". * This could be a MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. Note that we * *don't* check for (INT_MIN / -1) here, because the CPU handles it * correctly. * * For: add-int, sub-int, mul-int, div-int, rem-int, and-int, or-int, * xor-int, shl-int, shr-int, ushr-int */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG(a1, a3) # a1 <- vCC GET_VREG(a0, a2) # a0 <- vBB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op srl a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_add_long: /* 0x9b */ /* File: mips/op_add_long.S */ /* * The compiler generates the following sequence for * [v1 v0] = [a1 a0] + [a3 a2]; * addu v0,a2,a0 * addu a1,a3,a1 * sltu v1,v0,a2 * addu v1,v1,a1 */ /* File: mips/binopWide.S */ /* * Generic 64-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a2-a3). Useful for integer division and modulus. * * for: add-long, sub-long, div-long, rem-long, and-long, or-long, * xor-long * * IMPORTANT: you may specify "chkzero" or "preinstr" but not both. */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64(a0, a1, a2) # a0/a1 <- vBB/vBB+1 LOAD64(a2, a3, t1) # a2/a3 <- vCC/vCC+1 .if 0 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST addu v0, a2, a0 # optional op addu a1, a3, a1; sltu v1, v0, a2; addu v1, v1, a1 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vAA/vAA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_sub_long: /* 0x9c */ /* File: mips/op_sub_long.S */ /* * For little endian the code sequence looks as follows: * subu v0,a0,a2 * subu v1,a1,a3 * sltu a0,a0,v0 * subu v1,v1,a0 */ /* File: mips/binopWide.S */ /* * Generic 64-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a2-a3). Useful for integer division and modulus. * * for: add-long, sub-long, div-long, rem-long, and-long, or-long, * xor-long * * IMPORTANT: you may specify "chkzero" or "preinstr" but not both. */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64(a0, a1, a2) # a0/a1 <- vBB/vBB+1 LOAD64(a2, a3, t1) # a2/a3 <- vCC/vCC+1 .if 0 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST subu v0, a0, a2 # optional op subu v1, a1, a3; sltu a0, a0, v0; subu v1, v1, a0 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vAA/vAA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_mul_long: /* 0x9d */ /* File: mips/op_mul_long.S */ /* * Signed 64-bit integer multiply. * a1 a0 * x a3 a2 * ------------- * a2a1 a2a0 * a3a0 * a3a1 (<= unused) * --------------- * v1 v0 */ /* mul-long vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB and t0, a0, 255 # a2 <- BB srl t1, a0, 8 # a3 <- CC EAS2(t0, rFP, t0) # t0 <- &fp[BB] LOAD64(a0, a1, t0) # a0/a1 <- vBB/vBB+1 EAS2(t1, rFP, t1) # t0 <- &fp[CC] LOAD64(a2, a3, t1) # a2/a3 <- vCC/vCC+1 mul v1, a3, a0 # v1= a3a0 #ifdef MIPS32REVGE6 mulu v0, a2, a0 # v0= a2a0 muhu t1, a2, a0 #else multu a2, a0 mfhi t1 mflo v0 # v0= a2a0 #endif mul t0, a2, a1 # t0= a2a1 addu v1, v1, t1 # v1+= hi(a2a0) addu v1, v1, t0 # v1= a3a0 + a2a1; GET_OPA(a0) # a0 <- AA FETCH_ADVANCE_INST(2) # advance rPC, load rINST b .Lop_mul_long_finish /* ------------------------------ */ .balign 128 .L_op_div_long: /* 0x9e */ /* File: mips/op_div_long.S */ /* File: mips/binopWide.S */ /* * Generic 64-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a2-a3). Useful for integer division and modulus. * * for: add-long, sub-long, div-long, rem-long, and-long, or-long, * xor-long * * IMPORTANT: you may specify "chkzero" or "preinstr" but not both. */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64(a0, a1, a2) # a0/a1 <- vBB/vBB+1 LOAD64(a2, a3, t1) # a2/a3 <- vCC/vCC+1 .if 1 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op JAL(__divdi3) # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vAA/vAA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_rem_long: /* 0x9f */ /* File: mips/op_rem_long.S */ /* File: mips/binopWide.S */ /* * Generic 64-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a2-a3). Useful for integer division and modulus. * * for: add-long, sub-long, div-long, rem-long, and-long, or-long, * xor-long * * IMPORTANT: you may specify "chkzero" or "preinstr" but not both. */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64(a0, a1, a2) # a0/a1 <- vBB/vBB+1 LOAD64(a2, a3, t1) # a2/a3 <- vCC/vCC+1 .if 1 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op JAL(__moddi3) # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vAA/vAA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_and_long: /* 0xa0 */ /* File: mips/op_and_long.S */ /* File: mips/binopWide.S */ /* * Generic 64-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a2-a3). Useful for integer division and modulus. * * for: add-long, sub-long, div-long, rem-long, and-long, or-long, * xor-long * * IMPORTANT: you may specify "chkzero" or "preinstr" but not both. */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64(a0, a1, a2) # a0/a1 <- vBB/vBB+1 LOAD64(a2, a3, t1) # a2/a3 <- vCC/vCC+1 .if 0 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST and a0, a0, a2 # optional op and a1, a1, a3 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, rOBJ, t0) # vAA/vAA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_or_long: /* 0xa1 */ /* File: mips/op_or_long.S */ /* File: mips/binopWide.S */ /* * Generic 64-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a2-a3). Useful for integer division and modulus. * * for: add-long, sub-long, div-long, rem-long, and-long, or-long, * xor-long * * IMPORTANT: you may specify "chkzero" or "preinstr" but not both. */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64(a0, a1, a2) # a0/a1 <- vBB/vBB+1 LOAD64(a2, a3, t1) # a2/a3 <- vCC/vCC+1 .if 0 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST or a0, a0, a2 # optional op or a1, a1, a3 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, rOBJ, t0) # vAA/vAA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_xor_long: /* 0xa2 */ /* File: mips/op_xor_long.S */ /* File: mips/binopWide.S */ /* * Generic 64-bit binary operation. Provide an "instr" line that * specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a2-a3). Useful for integer division and modulus. * * for: add-long, sub-long, div-long, rem-long, and-long, or-long, * xor-long * * IMPORTANT: you may specify "chkzero" or "preinstr" but not both. */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64(a0, a1, a2) # a0/a1 <- vBB/vBB+1 LOAD64(a2, a3, t1) # a2/a3 <- vCC/vCC+1 .if 0 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST xor a0, a0, a2 # optional op xor a1, a1, a3 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, rOBJ, t0) # vAA/vAA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_shl_long: /* 0xa3 */ /* File: mips/op_shl_long.S */ /* * Long integer shift. This is different from the generic 32/64-bit * binary operations because vAA/vBB are 64-bit but vCC (the shift * distance) is 32-bit. Also, Dalvik requires us to mask off the low * 6 bits of the shift distance. */ /* shl-long vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(t2) # t2 <- AA and a3, a0, 255 # a3 <- BB srl a0, a0, 8 # a0 <- CC EAS2(a3, rFP, a3) # a3 <- &fp[BB] GET_VREG(a2, a0) # a2 <- vCC LOAD64(a0, a1, a3) # a0/a1 <- vBB/vBB+1 FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST andi v1, a2, 0x20 # shift< shift & 0x20 sll v0, a0, a2 # rlo<- alo << (shift&31) bnez v1, .Lop_shl_long_finish not v1, a2 # rhi<- 31-shift (shift is 5b) srl a0, 1 srl a0, v1 # alo<- alo >> (32-(shift&31)) sll v1, a1, a2 # rhi<- ahi << (shift&31) or v1, a0 # rhi<- rhi | alo SET_VREG64_GOTO(v0, v1, t2, t0) # vAA/vAA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_shr_long: /* 0xa4 */ /* File: mips/op_shr_long.S */ /* * Long integer shift. This is different from the generic 32/64-bit * binary operations because vAA/vBB are 64-bit but vCC (the shift * distance) is 32-bit. Also, Dalvik requires us to mask off the low * 6 bits of the shift distance. */ /* shr-long vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(t3) # t3 <- AA and a3, a0, 255 # a3 <- BB srl a0, a0, 8 # a0 <- CC EAS2(a3, rFP, a3) # a3 <- &fp[BB] GET_VREG(a2, a0) # a2 <- vCC LOAD64(a0, a1, a3) # a0/a1 <- vBB/vBB+1 FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST andi v0, a2, 0x20 # shift & 0x20 sra v1, a1, a2 # rhi<- ahi >> (shift&31) bnez v0, .Lop_shr_long_finish srl v0, a0, a2 # rlo<- alo >> (shift&31) not a0, a2 # alo<- 31-shift (shift is 5b) sll a1, 1 sll a1, a0 # ahi<- ahi << (32-(shift&31)) or v0, a1 # rlo<- rlo | ahi SET_VREG64_GOTO(v0, v1, t3, t0) # vAA/VAA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_ushr_long: /* 0xa5 */ /* File: mips/op_ushr_long.S */ /* * Long integer shift. This is different from the generic 32/64-bit * binary operations because vAA/vBB are 64-bit but vCC (the shift * distance) is 32-bit. Also, Dalvik requires us to mask off the low * 6 bits of the shift distance. */ /* ushr-long vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a3, a0, 255 # a3 <- BB srl a0, a0, 8 # a0 <- CC EAS2(a3, rFP, a3) # a3 <- &fp[BB] GET_VREG(a2, a0) # a2 <- vCC LOAD64(a0, a1, a3) # a0/a1 <- vBB/vBB+1 FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST andi v0, a2, 0x20 # shift & 0x20 srl v1, a1, a2 # rhi<- ahi >> (shift&31) bnez v0, .Lop_ushr_long_finish srl v0, a0, a2 # rlo<- alo >> (shift&31) not a0, a2 # alo<- 31-n (shift is 5b) sll a1, 1 sll a1, a0 # ahi<- ahi << (32-(shift&31)) or v0, a1 # rlo<- rlo | ahi SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vAA/vAA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_add_float: /* 0xa6 */ /* File: mips/op_add_float.S */ /* File: mips/fbinop.S */ /* * Generic 32-bit binary float operation. * * For: add-fp, sub-fp, mul-fp, div-fp, rem-fp */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG_F(fa1, a3) # a1 <- vCC GET_VREG_F(fa0, a2) # a0 <- vBB FETCH_ADVANCE_INST(2) # advance rPC, load rINST add.s fv0, fa0, fa1 # f0 = result GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vAA <- fv0 /* ------------------------------ */ .balign 128 .L_op_sub_float: /* 0xa7 */ /* File: mips/op_sub_float.S */ /* File: mips/fbinop.S */ /* * Generic 32-bit binary float operation. * * For: add-fp, sub-fp, mul-fp, div-fp, rem-fp */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG_F(fa1, a3) # a1 <- vCC GET_VREG_F(fa0, a2) # a0 <- vBB FETCH_ADVANCE_INST(2) # advance rPC, load rINST sub.s fv0, fa0, fa1 # f0 = result GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vAA <- fv0 /* ------------------------------ */ .balign 128 .L_op_mul_float: /* 0xa8 */ /* File: mips/op_mul_float.S */ /* File: mips/fbinop.S */ /* * Generic 32-bit binary float operation. * * For: add-fp, sub-fp, mul-fp, div-fp, rem-fp */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG_F(fa1, a3) # a1 <- vCC GET_VREG_F(fa0, a2) # a0 <- vBB FETCH_ADVANCE_INST(2) # advance rPC, load rINST mul.s fv0, fa0, fa1 # f0 = result GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vAA <- fv0 /* ------------------------------ */ .balign 128 .L_op_div_float: /* 0xa9 */ /* File: mips/op_div_float.S */ /* File: mips/fbinop.S */ /* * Generic 32-bit binary float operation. * * For: add-fp, sub-fp, mul-fp, div-fp, rem-fp */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG_F(fa1, a3) # a1 <- vCC GET_VREG_F(fa0, a2) # a0 <- vBB FETCH_ADVANCE_INST(2) # advance rPC, load rINST div.s fv0, fa0, fa1 # f0 = result GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vAA <- fv0 /* ------------------------------ */ .balign 128 .L_op_rem_float: /* 0xaa */ /* File: mips/op_rem_float.S */ /* File: mips/fbinop.S */ /* * Generic 32-bit binary float operation. * * For: add-fp, sub-fp, mul-fp, div-fp, rem-fp */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA srl a3, a0, 8 # a3 <- CC and a2, a0, 255 # a2 <- BB GET_VREG_F(fa1, a3) # a1 <- vCC GET_VREG_F(fa0, a2) # a0 <- vBB FETCH_ADVANCE_INST(2) # advance rPC, load rINST JAL(fmodf) # f0 = result GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vAA <- fv0 /* ------------------------------ */ .balign 128 .L_op_add_double: /* 0xab */ /* File: mips/op_add_double.S */ /* File: mips/fbinopWide.S */ /* * Generic 64-bit floating-point binary operation. Provide an "instr" * line that specifies an instruction that performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * for: add-double, sub-double, mul-double, div-double, * rem-double * */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64_F(fa0, fa0f, a2) LOAD64_F(fa1, fa1f, t1) FETCH_ADVANCE_INST(2) # advance rPC, load rINST add.d fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vAA/vAA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_sub_double: /* 0xac */ /* File: mips/op_sub_double.S */ /* File: mips/fbinopWide.S */ /* * Generic 64-bit floating-point binary operation. Provide an "instr" * line that specifies an instruction that performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * for: add-double, sub-double, mul-double, div-double, * rem-double * */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64_F(fa0, fa0f, a2) LOAD64_F(fa1, fa1f, t1) FETCH_ADVANCE_INST(2) # advance rPC, load rINST sub.d fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vAA/vAA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_mul_double: /* 0xad */ /* File: mips/op_mul_double.S */ /* File: mips/fbinopWide.S */ /* * Generic 64-bit floating-point binary operation. Provide an "instr" * line that specifies an instruction that performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * for: add-double, sub-double, mul-double, div-double, * rem-double * */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64_F(fa0, fa0f, a2) LOAD64_F(fa1, fa1f, t1) FETCH_ADVANCE_INST(2) # advance rPC, load rINST mul.d fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vAA/vAA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_div_double: /* 0xae */ /* File: mips/op_div_double.S */ /* File: mips/fbinopWide.S */ /* * Generic 64-bit floating-point binary operation. Provide an "instr" * line that specifies an instruction that performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * for: add-double, sub-double, mul-double, div-double, * rem-double * */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64_F(fa0, fa0f, a2) LOAD64_F(fa1, fa1f, t1) FETCH_ADVANCE_INST(2) # advance rPC, load rINST div.d fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vAA/vAA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_rem_double: /* 0xaf */ /* File: mips/op_rem_double.S */ /* File: mips/fbinopWide.S */ /* * Generic 64-bit floating-point binary operation. Provide an "instr" * line that specifies an instruction that performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * for: add-double, sub-double, mul-double, div-double, * rem-double * */ /* binop vAA, vBB, vCC */ FETCH(a0, 1) # a0 <- CCBB GET_OPA(rOBJ) # rOBJ <- AA and a2, a0, 255 # a2 <- BB srl a3, a0, 8 # a3 <- CC EAS2(a2, rFP, a2) # a2 <- &fp[BB] EAS2(t1, rFP, a3) # a3 <- &fp[CC] LOAD64_F(fa0, fa0f, a2) LOAD64_F(fa1, fa1f, t1) FETCH_ADVANCE_INST(2) # advance rPC, load rINST JAL(fmod) GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vAA/vAA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_add_int_2addr: /* 0xb0 */ /* File: mips/op_add_int_2addr.S */ /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op addu a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_sub_int_2addr: /* 0xb1 */ /* File: mips/op_sub_int_2addr.S */ /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op subu a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_mul_int_2addr: /* 0xb2 */ /* File: mips/op_mul_int_2addr.S */ /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op mul a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_div_int_2addr: /* 0xb3 */ /* File: mips/op_div_int_2addr.S */ #ifdef MIPS32REVGE6 /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op div a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 #else /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST div zero, a0, a1 # optional op mflo a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 #endif /* ------------------------------ */ .balign 128 .L_op_rem_int_2addr: /* 0xb4 */ /* File: mips/op_rem_int_2addr.S */ #ifdef MIPS32REVGE6 /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op mod a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 #else /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST div zero, a0, a1 # optional op mfhi a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 #endif /* ------------------------------ */ .balign 128 .L_op_and_int_2addr: /* 0xb5 */ /* File: mips/op_and_int_2addr.S */ /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op and a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_or_int_2addr: /* 0xb6 */ /* File: mips/op_or_int_2addr.S */ /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op or a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_xor_int_2addr: /* 0xb7 */ /* File: mips/op_xor_int_2addr.S */ /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op xor a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_shl_int_2addr: /* 0xb8 */ /* File: mips/op_shl_int_2addr.S */ /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op sll a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_shr_int_2addr: /* 0xb9 */ /* File: mips/op_shr_int_2addr.S */ /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op sra a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_ushr_int_2addr: /* 0xba */ /* File: mips/op_ushr_int_2addr.S */ /* File: mips/binop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/2addr, sub-int/2addr, mul-int/2addr, div-int/2addr, * rem-int/2addr, and-int/2addr, or-int/2addr, xor-int/2addr, * shl-int/2addr, shr-int/2addr, ushr-int/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a0, rOBJ) # a0 <- vA GET_VREG(a1, a3) # a1 <- vB .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op srl a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_add_long_2addr: /* 0xbb */ /* File: mips/op_add_long_2addr.S */ /* * See op_add_long.S for details */ /* File: mips/binopWide2addr.S */ /* * Generic 64-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vB (a2-a3). Useful for integer division and modulus. * * For: add-long/2addr, sub-long/2addr, div-long/2addr, rem-long/2addr, * and-long/2addr, or-long/2addr, xor-long/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64(a2, a3, a1) # a2/a3 <- vB/vB+1 LOAD64(a0, a1, t0) # a0/a1 <- vA/vA+1 .if 0 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST addu v0, a2, a0 # optional op addu a1, a3, a1; sltu v1, v0, a2; addu v1, v1, a1 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vA/vA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_sub_long_2addr: /* 0xbc */ /* File: mips/op_sub_long_2addr.S */ /* * See op_sub_long.S for more details */ /* File: mips/binopWide2addr.S */ /* * Generic 64-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vB (a2-a3). Useful for integer division and modulus. * * For: add-long/2addr, sub-long/2addr, div-long/2addr, rem-long/2addr, * and-long/2addr, or-long/2addr, xor-long/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64(a2, a3, a1) # a2/a3 <- vB/vB+1 LOAD64(a0, a1, t0) # a0/a1 <- vA/vA+1 .if 0 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST subu v0, a0, a2 # optional op subu v1, a1, a3; sltu a0, a0, v0; subu v1, v1, a0 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vA/vA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_mul_long_2addr: /* 0xbd */ /* File: mips/op_mul_long_2addr.S */ /* * See op_mul_long.S for more details */ /* mul-long/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64(a0, a1, t0) # vAA.low / high GET_OPB(t1) # t1 <- B EAS2(t1, rFP, t1) # t1 <- &fp[B] LOAD64(a2, a3, t1) # vBB.low / high mul v1, a3, a0 # v1= a3a0 #ifdef MIPS32REVGE6 mulu v0, a2, a0 # v0= a2a0 muhu t1, a2, a0 #else multu a2, a0 mfhi t1 mflo v0 # v0= a2a0 #endif mul t2, a2, a1 # t2= a2a1 addu v1, v1, t1 # v1= a3a0 + hi(a2a0) addu v1, v1, t2 # v1= v1 + a2a1; FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_INST_OPCODE(t1) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, rOBJ, t1) # vA/vA+1 <- v0(low)/v1(high) /* ------------------------------ */ .balign 128 .L_op_div_long_2addr: /* 0xbe */ /* File: mips/op_div_long_2addr.S */ /* File: mips/binopWide2addr.S */ /* * Generic 64-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vB (a2-a3). Useful for integer division and modulus. * * For: add-long/2addr, sub-long/2addr, div-long/2addr, rem-long/2addr, * and-long/2addr, or-long/2addr, xor-long/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64(a2, a3, a1) # a2/a3 <- vB/vB+1 LOAD64(a0, a1, t0) # a0/a1 <- vA/vA+1 .if 1 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op JAL(__divdi3) # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vA/vA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_rem_long_2addr: /* 0xbf */ /* File: mips/op_rem_long_2addr.S */ /* File: mips/binopWide2addr.S */ /* * Generic 64-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vB (a2-a3). Useful for integer division and modulus. * * For: add-long/2addr, sub-long/2addr, div-long/2addr, rem-long/2addr, * and-long/2addr, or-long/2addr, xor-long/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64(a2, a3, a1) # a2/a3 <- vB/vB+1 LOAD64(a0, a1, t0) # a0/a1 <- vA/vA+1 .if 1 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST # optional op JAL(__moddi3) # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vA/vA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_and_long_2addr: /* 0xc0 */ /* File: mips/op_and_long_2addr.S */ /* File: mips/binopWide2addr.S */ /* * Generic 64-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vB (a2-a3). Useful for integer division and modulus. * * For: add-long/2addr, sub-long/2addr, div-long/2addr, rem-long/2addr, * and-long/2addr, or-long/2addr, xor-long/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64(a2, a3, a1) # a2/a3 <- vB/vB+1 LOAD64(a0, a1, t0) # a0/a1 <- vA/vA+1 .if 0 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST and a0, a0, a2 # optional op and a1, a1, a3 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, rOBJ, t0) # vA/vA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_or_long_2addr: /* 0xc1 */ /* File: mips/op_or_long_2addr.S */ /* File: mips/binopWide2addr.S */ /* * Generic 64-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vB (a2-a3). Useful for integer division and modulus. * * For: add-long/2addr, sub-long/2addr, div-long/2addr, rem-long/2addr, * and-long/2addr, or-long/2addr, xor-long/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64(a2, a3, a1) # a2/a3 <- vB/vB+1 LOAD64(a0, a1, t0) # a0/a1 <- vA/vA+1 .if 0 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST or a0, a0, a2 # optional op or a1, a1, a3 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, rOBJ, t0) # vA/vA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_xor_long_2addr: /* 0xc2 */ /* File: mips/op_xor_long_2addr.S */ /* File: mips/binopWide2addr.S */ /* * Generic 64-bit "/2addr" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0-a1 op a2-a3". * This could be a MIPS instruction or a function call. (If the result * comes back in a register pair other than a0-a1, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vB (a2-a3). Useful for integer division and modulus. * * For: add-long/2addr, sub-long/2addr, div-long/2addr, rem-long/2addr, * and-long/2addr, or-long/2addr, xor-long/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64(a2, a3, a1) # a2/a3 <- vB/vB+1 LOAD64(a0, a1, t0) # a0/a1 <- vA/vA+1 .if 0 or t0, a2, a3 # second arg (a2-a3) is zero? beqz t0, common_errDivideByZero .endif FETCH_ADVANCE_INST(1) # advance rPC, load rINST xor a0, a0, a2 # optional op xor a1, a1, a3 # result <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, rOBJ, t0) # vA/vA+1 <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_shl_long_2addr: /* 0xc3 */ /* File: mips/op_shl_long_2addr.S */ /* * Long integer shift, 2addr version. vA is 64-bit value/result, vB is * 32-bit shift distance. */ /* shl-long/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a2, a3) # a2 <- vB EAS2(t2, rFP, rOBJ) # t2 <- &fp[A] LOAD64(a0, a1, t2) # a0/a1 <- vA/vA+1 FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST andi v1, a2, 0x20 # shift< shift & 0x20 sll v0, a0, a2 # rlo<- alo << (shift&31) bnez v1, .Lop_shl_long_2addr_finish not v1, a2 # rhi<- 31-shift (shift is 5b) srl a0, 1 srl a0, v1 # alo<- alo >> (32-(shift&31)) sll v1, a1, a2 # rhi<- ahi << (shift&31) or v1, a0 # rhi<- rhi | alo SET_VREG64_GOTO(v0, v1, rOBJ, t0) # vA/vA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_shr_long_2addr: /* 0xc4 */ /* File: mips/op_shr_long_2addr.S */ /* * Long integer shift, 2addr version. vA is 64-bit value/result, vB is * 32-bit shift distance. */ /* shr-long/2addr vA, vB */ GET_OPA4(t2) # t2 <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a2, a3) # a2 <- vB EAS2(t0, rFP, t2) # t0 <- &fp[A] LOAD64(a0, a1, t0) # a0/a1 <- vA/vA+1 FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST andi v0, a2, 0x20 # shift & 0x20 sra v1, a1, a2 # rhi<- ahi >> (shift&31) bnez v0, .Lop_shr_long_2addr_finish srl v0, a0, a2 # rlo<- alo >> (shift&31) not a0, a2 # alo<- 31-shift (shift is 5b) sll a1, 1 sll a1, a0 # ahi<- ahi << (32-(shift&31)) or v0, a1 # rlo<- rlo | ahi SET_VREG64_GOTO(v0, v1, t2, t0) # vA/vA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_ushr_long_2addr: /* 0xc5 */ /* File: mips/op_ushr_long_2addr.S */ /* * Long integer shift, 2addr version. vA is 64-bit value/result, vB is * 32-bit shift distance. */ /* ushr-long/2addr vA, vB */ GET_OPA4(t3) # t3 <- A+ GET_OPB(a3) # a3 <- B GET_VREG(a2, a3) # a2 <- vB EAS2(t0, rFP, t3) # t0 <- &fp[A] LOAD64(a0, a1, t0) # a0/a1 <- vA/vA+1 FETCH_ADVANCE_INST(1) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST andi v0, a2, 0x20 # shift & 0x20 srl v1, a1, a2 # rhi<- ahi >> (shift&31) bnez v0, .Lop_ushr_long_2addr_finish srl v0, a0, a2 # rlo<- alo >> (shift&31) not a0, a2 # alo<- 31-n (shift is 5b) sll a1, 1 sll a1, a0 # ahi<- ahi << (32-(shift&31)) or v0, a1 # rlo<- rlo | ahi SET_VREG64_GOTO(v0, v1, t3, t0) # vA/vA+1 <- v0/v1 /* ------------------------------ */ .balign 128 .L_op_add_float_2addr: /* 0xc6 */ /* File: mips/op_add_float_2addr.S */ /* File: mips/fbinop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" * that specifies an instruction that performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * For: add-float/2addr, sub-float/2addr, mul-float/2addr, * div-float/2addr, rem-float/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG_F(fa0, rOBJ) GET_VREG_F(fa1, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST add.s fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vA <- result /* ------------------------------ */ .balign 128 .L_op_sub_float_2addr: /* 0xc7 */ /* File: mips/op_sub_float_2addr.S */ /* File: mips/fbinop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" * that specifies an instruction that performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * For: add-float/2addr, sub-float/2addr, mul-float/2addr, * div-float/2addr, rem-float/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG_F(fa0, rOBJ) GET_VREG_F(fa1, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST sub.s fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vA <- result /* ------------------------------ */ .balign 128 .L_op_mul_float_2addr: /* 0xc8 */ /* File: mips/op_mul_float_2addr.S */ /* File: mips/fbinop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" * that specifies an instruction that performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * For: add-float/2addr, sub-float/2addr, mul-float/2addr, * div-float/2addr, rem-float/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG_F(fa0, rOBJ) GET_VREG_F(fa1, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST mul.s fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vA <- result /* ------------------------------ */ .balign 128 .L_op_div_float_2addr: /* 0xc9 */ /* File: mips/op_div_float_2addr.S */ /* File: mips/fbinop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" * that specifies an instruction that performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * For: add-float/2addr, sub-float/2addr, mul-float/2addr, * div-float/2addr, rem-float/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG_F(fa0, rOBJ) GET_VREG_F(fa1, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST div.s fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vA <- result /* ------------------------------ */ .balign 128 .L_op_rem_float_2addr: /* 0xca */ /* File: mips/op_rem_float_2addr.S */ /* File: mips/fbinop2addr.S */ /* * Generic 32-bit "/2addr" binary operation. Provide an "instr" * that specifies an instruction that performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * For: add-float/2addr, sub-float/2addr, mul-float/2addr, * div-float/2addr, rem-float/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a3) # a3 <- B GET_VREG_F(fa0, rOBJ) GET_VREG_F(fa1, a3) FETCH_ADVANCE_INST(1) # advance rPC, load rINST JAL(fmodf) GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_F_GOTO(fv0, rOBJ, t0) # vA <- result /* ------------------------------ */ .balign 128 .L_op_add_double_2addr: /* 0xcb */ /* File: mips/op_add_double_2addr.S */ /* File: mips/fbinopWide2addr.S */ /* * Generic 64-bit floating-point "/2addr" binary operation. * Provide an "instr" line that specifies an instruction that * performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * For: add-double/2addr, sub-double/2addr, mul-double/2addr, * div-double/2addr, rem-double/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64_F(fa0, fa0f, t0) LOAD64_F(fa1, fa1f, a1) FETCH_ADVANCE_INST(1) # advance rPC, load rINST add.d fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vA/vA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_sub_double_2addr: /* 0xcc */ /* File: mips/op_sub_double_2addr.S */ /* File: mips/fbinopWide2addr.S */ /* * Generic 64-bit floating-point "/2addr" binary operation. * Provide an "instr" line that specifies an instruction that * performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * For: add-double/2addr, sub-double/2addr, mul-double/2addr, * div-double/2addr, rem-double/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64_F(fa0, fa0f, t0) LOAD64_F(fa1, fa1f, a1) FETCH_ADVANCE_INST(1) # advance rPC, load rINST sub.d fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vA/vA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_mul_double_2addr: /* 0xcd */ /* File: mips/op_mul_double_2addr.S */ /* File: mips/fbinopWide2addr.S */ /* * Generic 64-bit floating-point "/2addr" binary operation. * Provide an "instr" line that specifies an instruction that * performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * For: add-double/2addr, sub-double/2addr, mul-double/2addr, * div-double/2addr, rem-double/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64_F(fa0, fa0f, t0) LOAD64_F(fa1, fa1f, a1) FETCH_ADVANCE_INST(1) # advance rPC, load rINST mul.d fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vA/vA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_div_double_2addr: /* 0xce */ /* File: mips/op_div_double_2addr.S */ /* File: mips/fbinopWide2addr.S */ /* * Generic 64-bit floating-point "/2addr" binary operation. * Provide an "instr" line that specifies an instruction that * performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * For: add-double/2addr, sub-double/2addr, mul-double/2addr, * div-double/2addr, rem-double/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64_F(fa0, fa0f, t0) LOAD64_F(fa1, fa1f, a1) FETCH_ADVANCE_INST(1) # advance rPC, load rINST div.d fv0, fa0, fa1 GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vA/vA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_rem_double_2addr: /* 0xcf */ /* File: mips/op_rem_double_2addr.S */ /* File: mips/fbinopWide2addr.S */ /* * Generic 64-bit floating-point "/2addr" binary operation. * Provide an "instr" line that specifies an instruction that * performs "fv0 = fa0 op fa1". * This could be an MIPS instruction or a function call. * * For: add-double/2addr, sub-double/2addr, mul-double/2addr, * div-double/2addr, rem-double/2addr */ /* binop/2addr vA, vB */ GET_OPA4(rOBJ) # rOBJ <- A+ GET_OPB(a1) # a1 <- B EAS2(a1, rFP, a1) # a1 <- &fp[B] EAS2(t0, rFP, rOBJ) # t0 <- &fp[A] LOAD64_F(fa0, fa0f, t0) LOAD64_F(fa1, fa1f, a1) FETCH_ADVANCE_INST(1) # advance rPC, load rINST JAL(fmod) GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_F_GOTO(fv0, fv0f, rOBJ, t0) # vA/vA+1 <- fv0 /* ------------------------------ */ .balign 128 .L_op_add_int_lit16: /* 0xd0 */ /* File: mips/op_add_int_lit16.S */ /* File: mips/binopLit16.S */ /* * Generic 32-bit "lit16" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit16, rsub-int, mul-int/lit16, div-int/lit16, * rem-int/lit16, and-int/lit16, or-int/lit16, xor-int/lit16 */ /* binop/lit16 vA, vB, +CCCC */ FETCH_S(a1, 1) # a1 <- ssssCCCC (sign-extended) GET_OPB(a2) # a2 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG(a0, a2) # a0 <- vB .if 0 # cmp a1, 0; is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op addu a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_rsub_int: /* 0xd1 */ /* File: mips/op_rsub_int.S */ /* this op is "rsub-int", but can be thought of as "rsub-int/lit16" */ /* File: mips/binopLit16.S */ /* * Generic 32-bit "lit16" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit16, rsub-int, mul-int/lit16, div-int/lit16, * rem-int/lit16, and-int/lit16, or-int/lit16, xor-int/lit16 */ /* binop/lit16 vA, vB, +CCCC */ FETCH_S(a1, 1) # a1 <- ssssCCCC (sign-extended) GET_OPB(a2) # a2 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG(a0, a2) # a0 <- vB .if 0 # cmp a1, 0; is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op subu a0, a1, a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_mul_int_lit16: /* 0xd2 */ /* File: mips/op_mul_int_lit16.S */ /* File: mips/binopLit16.S */ /* * Generic 32-bit "lit16" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit16, rsub-int, mul-int/lit16, div-int/lit16, * rem-int/lit16, and-int/lit16, or-int/lit16, xor-int/lit16 */ /* binop/lit16 vA, vB, +CCCC */ FETCH_S(a1, 1) # a1 <- ssssCCCC (sign-extended) GET_OPB(a2) # a2 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG(a0, a2) # a0 <- vB .if 0 # cmp a1, 0; is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op mul a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_div_int_lit16: /* 0xd3 */ /* File: mips/op_div_int_lit16.S */ #ifdef MIPS32REVGE6 /* File: mips/binopLit16.S */ /* * Generic 32-bit "lit16" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit16, rsub-int, mul-int/lit16, div-int/lit16, * rem-int/lit16, and-int/lit16, or-int/lit16, xor-int/lit16 */ /* binop/lit16 vA, vB, +CCCC */ FETCH_S(a1, 1) # a1 <- ssssCCCC (sign-extended) GET_OPB(a2) # a2 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG(a0, a2) # a0 <- vB .if 1 # cmp a1, 0; is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op div a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 #else /* File: mips/binopLit16.S */ /* * Generic 32-bit "lit16" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit16, rsub-int, mul-int/lit16, div-int/lit16, * rem-int/lit16, and-int/lit16, or-int/lit16, xor-int/lit16 */ /* binop/lit16 vA, vB, +CCCC */ FETCH_S(a1, 1) # a1 <- ssssCCCC (sign-extended) GET_OPB(a2) # a2 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG(a0, a2) # a0 <- vB .if 1 # cmp a1, 0; is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST div zero, a0, a1 # optional op mflo a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 #endif /* ------------------------------ */ .balign 128 .L_op_rem_int_lit16: /* 0xd4 */ /* File: mips/op_rem_int_lit16.S */ #ifdef MIPS32REVGE6 /* File: mips/binopLit16.S */ /* * Generic 32-bit "lit16" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit16, rsub-int, mul-int/lit16, div-int/lit16, * rem-int/lit16, and-int/lit16, or-int/lit16, xor-int/lit16 */ /* binop/lit16 vA, vB, +CCCC */ FETCH_S(a1, 1) # a1 <- ssssCCCC (sign-extended) GET_OPB(a2) # a2 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG(a0, a2) # a0 <- vB .if 1 # cmp a1, 0; is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op mod a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 #else /* File: mips/binopLit16.S */ /* * Generic 32-bit "lit16" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit16, rsub-int, mul-int/lit16, div-int/lit16, * rem-int/lit16, and-int/lit16, or-int/lit16, xor-int/lit16 */ /* binop/lit16 vA, vB, +CCCC */ FETCH_S(a1, 1) # a1 <- ssssCCCC (sign-extended) GET_OPB(a2) # a2 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG(a0, a2) # a0 <- vB .if 1 # cmp a1, 0; is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST div zero, a0, a1 # optional op mfhi a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 #endif /* ------------------------------ */ .balign 128 .L_op_and_int_lit16: /* 0xd5 */ /* File: mips/op_and_int_lit16.S */ /* File: mips/binopLit16.S */ /* * Generic 32-bit "lit16" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit16, rsub-int, mul-int/lit16, div-int/lit16, * rem-int/lit16, and-int/lit16, or-int/lit16, xor-int/lit16 */ /* binop/lit16 vA, vB, +CCCC */ FETCH_S(a1, 1) # a1 <- ssssCCCC (sign-extended) GET_OPB(a2) # a2 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG(a0, a2) # a0 <- vB .if 0 # cmp a1, 0; is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op and a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_or_int_lit16: /* 0xd6 */ /* File: mips/op_or_int_lit16.S */ /* File: mips/binopLit16.S */ /* * Generic 32-bit "lit16" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit16, rsub-int, mul-int/lit16, div-int/lit16, * rem-int/lit16, and-int/lit16, or-int/lit16, xor-int/lit16 */ /* binop/lit16 vA, vB, +CCCC */ FETCH_S(a1, 1) # a1 <- ssssCCCC (sign-extended) GET_OPB(a2) # a2 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG(a0, a2) # a0 <- vB .if 0 # cmp a1, 0; is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op or a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_xor_int_lit16: /* 0xd7 */ /* File: mips/op_xor_int_lit16.S */ /* File: mips/binopLit16.S */ /* * Generic 32-bit "lit16" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit16, rsub-int, mul-int/lit16, div-int/lit16, * rem-int/lit16, and-int/lit16, or-int/lit16, xor-int/lit16 */ /* binop/lit16 vA, vB, +CCCC */ FETCH_S(a1, 1) # a1 <- ssssCCCC (sign-extended) GET_OPB(a2) # a2 <- B GET_OPA4(rOBJ) # rOBJ <- A+ GET_VREG(a0, a2) # a0 <- vB .if 0 # cmp a1, 0; is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op xor a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vA <- a0 /* ------------------------------ */ .balign 128 .L_op_add_int_lit8: /* 0xd8 */ /* File: mips/op_add_int_lit8.S */ /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op addu a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_rsub_int_lit8: /* 0xd9 */ /* File: mips/op_rsub_int_lit8.S */ /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op subu a0, a1, a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_mul_int_lit8: /* 0xda */ /* File: mips/op_mul_int_lit8.S */ /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op mul a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_div_int_lit8: /* 0xdb */ /* File: mips/op_div_int_lit8.S */ #ifdef MIPS32REVGE6 /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op div a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 #else /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST div zero, a0, a1 # optional op mflo a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 #endif /* ------------------------------ */ .balign 128 .L_op_rem_int_lit8: /* 0xdc */ /* File: mips/op_rem_int_lit8.S */ #ifdef MIPS32REVGE6 /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op mod a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 #else /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 1 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST div zero, a0, a1 # optional op mfhi a0 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 #endif /* ------------------------------ */ .balign 128 .L_op_and_int_lit8: /* 0xdd */ /* File: mips/op_and_int_lit8.S */ /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op and a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_or_int_lit8: /* 0xde */ /* File: mips/op_or_int_lit8.S */ /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op or a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_xor_int_lit8: /* 0xdf */ /* File: mips/op_xor_int_lit8.S */ /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op xor a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_shl_int_lit8: /* 0xe0 */ /* File: mips/op_shl_int_lit8.S */ /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op sll a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_shr_int_lit8: /* 0xe1 */ /* File: mips/op_shr_int_lit8.S */ /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op sra a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_ushr_int_lit8: /* 0xe2 */ /* File: mips/op_ushr_int_lit8.S */ /* File: mips/binopLit8.S */ /* * Generic 32-bit "lit8" binary operation. Provide an "instr" line * that specifies an instruction that performs "result = a0 op a1". * This could be an MIPS instruction or a function call. (If the result * comes back in a register other than a0, you can override "result".) * * If "chkzero" is set to 1, we perform a divide-by-zero check on * vCC (a1). Useful for integer division and modulus. * * For: add-int/lit8, rsub-int/lit8, mul-int/lit8, div-int/lit8, * rem-int/lit8, and-int/lit8, or-int/lit8, xor-int/lit8, * shl-int/lit8, shr-int/lit8, ushr-int/lit8 */ /* binop/lit8 vAA, vBB, +CC */ FETCH_S(a3, 1) # a3 <- ssssCCBB (sign-extended for CC) GET_OPA(rOBJ) # rOBJ <- AA and a2, a3, 255 # a2 <- BB GET_VREG(a0, a2) # a0 <- vBB sra a1, a3, 8 # a1 <- ssssssCC (sign extended) .if 0 # is second operand zero? beqz a1, common_errDivideByZero .endif FETCH_ADVANCE_INST(2) # advance rPC, load rINST # optional op srl a0, a0, a1 # a0 <- op, a0-a3 changed GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, rOBJ, t0) # vAA <- a0 /* ------------------------------ */ .balign 128 .L_op_iget_quick: /* 0xe3 */ /* File: mips/op_iget_quick.S */ /* For: iget-quick, iget-boolean-quick, iget-byte-quick, iget-char-quick, iget-short-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- object we're operating on FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) # check object for null beqz a3, common_errNullObject # object was null addu t0, a3, a1 lw a0, 0(t0) # a0 <- obj.field (8/16/32 bits) FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, a2, t0) # fp[A] <- a0 /* ------------------------------ */ .balign 128 .L_op_iget_wide_quick: /* 0xe4 */ /* File: mips/op_iget_wide_quick.S */ /* iget-wide-quick vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- object we're operating on FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) # check object for null beqz a3, common_errNullObject # object was null addu t0, a3, a1 # t0 <- a3 + a1 LOAD64(a0, a1, t0) # a0 <- obj.field (64 bits, aligned) FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(a0, a1, a2, t0) # fp[A] <- a0/a1 /* ------------------------------ */ .balign 128 .L_op_iget_object_quick: /* 0xe5 */ /* File: mips/op_iget_object_quick.S */ /* For: iget-object-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B FETCH(a1, 1) # a1 <- field byte offset EXPORT_PC() GET_VREG(a0, a2) # a0 <- object we're operating on JAL(artIGetObjectFromMterp) # v0 <- GetObj(obj, offset) lw a3, THREAD_EXCEPTION_OFFSET(rSELF) GET_OPA4(a2) # a2<- A+ PREFETCH_INST(2) # load rINST bnez a3, MterpPossibleException # bail out ADVANCE(2) # advance rPC GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_OBJECT_GOTO(v0, a2, t0) # fp[A] <- v0 /* ------------------------------ */ .balign 128 .L_op_iput_quick: /* 0xe6 */ /* File: mips/op_iput_quick.S */ /* For: iput-quick, iput-object-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- fp[B], the object pointer FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) beqz a3, common_errNullObject # object was null GET_VREG(a0, a2) # a0 <- fp[A] FETCH_ADVANCE_INST(2) # advance rPC, load rINST addu t0, a3, a1 GET_INST_OPCODE(t1) # extract opcode from rINST GET_OPCODE_TARGET(t1) sw a0, 0(t0) # obj.field (8/16/32 bits) <- a0 JR(t1) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_wide_quick: /* 0xe7 */ /* File: mips/op_iput_wide_quick.S */ /* iput-wide-quick vA, vB, offset@CCCC */ GET_OPA4(a0) # a0 <- A(+) GET_OPB(a1) # a1 <- B GET_VREG(a2, a1) # a2 <- fp[B], the object pointer # check object for null beqz a2, common_errNullObject # object was null EAS2(a3, rFP, a0) # a3 <- &fp[A] LOAD64(a0, a1, a3) # a0/a1 <- fp[A] FETCH(a3, 1) # a3 <- field byte offset FETCH_ADVANCE_INST(2) # advance rPC, load rINST addu a2, a2, a3 # obj.field (64 bits, aligned) <- a0/a1 GET_INST_OPCODE(t0) # extract opcode from rINST GET_OPCODE_TARGET(t0) STORE64(a0, a1, a2) # obj.field (64 bits, aligned) <- a0/a1 JR(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_object_quick: /* 0xe8 */ /* File: mips/op_iput_object_quick.S */ /* For: iput-object-quick */ /* op vA, vB, offset@CCCC */ EXPORT_PC() addu a0, rFP, OFF_FP_SHADOWFRAME move a1, rPC move a2, rINST JAL(MterpIputObjectQuick) beqz v0, MterpException FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_invoke_virtual_quick: /* 0xe9 */ /* File: mips/op_invoke_virtual_quick.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeVirtualQuick EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeVirtualQuick) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_invoke_virtual_range_quick: /* 0xea */ /* File: mips/op_invoke_virtual_range_quick.S */ /* File: mips/invoke.S */ /* * Generic invoke handler wrapper. */ /* op vB, {vD, vE, vF, vG, vA}, class@CCCC */ /* op {vCCCC..v(CCCC+AA-1)}, meth@BBBB */ .extern MterpInvokeVirtualQuickRange EXPORT_PC() move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rPC move a3, rINST JAL(MterpInvokeVirtualQuickRange) beqz v0, MterpException FETCH_ADVANCE_INST(3) JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* ------------------------------ */ .balign 128 .L_op_iput_boolean_quick: /* 0xeb */ /* File: mips/op_iput_boolean_quick.S */ /* File: mips/op_iput_quick.S */ /* For: iput-quick, iput-object-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- fp[B], the object pointer FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) beqz a3, common_errNullObject # object was null GET_VREG(a0, a2) # a0 <- fp[A] FETCH_ADVANCE_INST(2) # advance rPC, load rINST addu t0, a3, a1 GET_INST_OPCODE(t1) # extract opcode from rINST GET_OPCODE_TARGET(t1) sb a0, 0(t0) # obj.field (8/16/32 bits) <- a0 JR(t1) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_byte_quick: /* 0xec */ /* File: mips/op_iput_byte_quick.S */ /* File: mips/op_iput_quick.S */ /* For: iput-quick, iput-object-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- fp[B], the object pointer FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) beqz a3, common_errNullObject # object was null GET_VREG(a0, a2) # a0 <- fp[A] FETCH_ADVANCE_INST(2) # advance rPC, load rINST addu t0, a3, a1 GET_INST_OPCODE(t1) # extract opcode from rINST GET_OPCODE_TARGET(t1) sb a0, 0(t0) # obj.field (8/16/32 bits) <- a0 JR(t1) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_char_quick: /* 0xed */ /* File: mips/op_iput_char_quick.S */ /* File: mips/op_iput_quick.S */ /* For: iput-quick, iput-object-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- fp[B], the object pointer FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) beqz a3, common_errNullObject # object was null GET_VREG(a0, a2) # a0 <- fp[A] FETCH_ADVANCE_INST(2) # advance rPC, load rINST addu t0, a3, a1 GET_INST_OPCODE(t1) # extract opcode from rINST GET_OPCODE_TARGET(t1) sh a0, 0(t0) # obj.field (8/16/32 bits) <- a0 JR(t1) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iput_short_quick: /* 0xee */ /* File: mips/op_iput_short_quick.S */ /* File: mips/op_iput_quick.S */ /* For: iput-quick, iput-object-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- fp[B], the object pointer FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) beqz a3, common_errNullObject # object was null GET_VREG(a0, a2) # a0 <- fp[A] FETCH_ADVANCE_INST(2) # advance rPC, load rINST addu t0, a3, a1 GET_INST_OPCODE(t1) # extract opcode from rINST GET_OPCODE_TARGET(t1) sh a0, 0(t0) # obj.field (8/16/32 bits) <- a0 JR(t1) # jump to next instruction /* ------------------------------ */ .balign 128 .L_op_iget_boolean_quick: /* 0xef */ /* File: mips/op_iget_boolean_quick.S */ /* File: mips/op_iget_quick.S */ /* For: iget-quick, iget-boolean-quick, iget-byte-quick, iget-char-quick, iget-short-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- object we're operating on FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) # check object for null beqz a3, common_errNullObject # object was null addu t0, a3, a1 lbu a0, 0(t0) # a0 <- obj.field (8/16/32 bits) FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, a2, t0) # fp[A] <- a0 /* ------------------------------ */ .balign 128 .L_op_iget_byte_quick: /* 0xf0 */ /* File: mips/op_iget_byte_quick.S */ /* File: mips/op_iget_quick.S */ /* For: iget-quick, iget-boolean-quick, iget-byte-quick, iget-char-quick, iget-short-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- object we're operating on FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) # check object for null beqz a3, common_errNullObject # object was null addu t0, a3, a1 lb a0, 0(t0) # a0 <- obj.field (8/16/32 bits) FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, a2, t0) # fp[A] <- a0 /* ------------------------------ */ .balign 128 .L_op_iget_char_quick: /* 0xf1 */ /* File: mips/op_iget_char_quick.S */ /* File: mips/op_iget_quick.S */ /* For: iget-quick, iget-boolean-quick, iget-byte-quick, iget-char-quick, iget-short-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- object we're operating on FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) # check object for null beqz a3, common_errNullObject # object was null addu t0, a3, a1 lhu a0, 0(t0) # a0 <- obj.field (8/16/32 bits) FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, a2, t0) # fp[A] <- a0 /* ------------------------------ */ .balign 128 .L_op_iget_short_quick: /* 0xf2 */ /* File: mips/op_iget_short_quick.S */ /* File: mips/op_iget_quick.S */ /* For: iget-quick, iget-boolean-quick, iget-byte-quick, iget-char-quick, iget-short-quick */ /* op vA, vB, offset@CCCC */ GET_OPB(a2) # a2 <- B GET_VREG(a3, a2) # a3 <- object we're operating on FETCH(a1, 1) # a1 <- field byte offset GET_OPA4(a2) # a2 <- A(+) # check object for null beqz a3, common_errNullObject # object was null addu t0, a3, a1 lh a0, 0(t0) # a0 <- obj.field (8/16/32 bits) FETCH_ADVANCE_INST(2) # advance rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG_GOTO(a0, a2, t0) # fp[A] <- a0 /* ------------------------------ */ .balign 128 .L_op_unused_f3: /* 0xf3 */ /* File: mips/op_unused_f3.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_f4: /* 0xf4 */ /* File: mips/op_unused_f4.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_f5: /* 0xf5 */ /* File: mips/op_unused_f5.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_f6: /* 0xf6 */ /* File: mips/op_unused_f6.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_f7: /* 0xf7 */ /* File: mips/op_unused_f7.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_f8: /* 0xf8 */ /* File: mips/op_unused_f8.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_f9: /* 0xf9 */ /* File: mips/op_unused_f9.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_invoke_polymorphic: /* 0xfa */ /* Transfer stub to alternate interpreter */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_invoke_polymorphic_range: /* 0xfb */ /* Transfer stub to alternate interpreter */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_invoke_custom: /* 0xfc */ /* Transfer stub to alternate interpreter */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_invoke_custom_range: /* 0xfd */ /* Transfer stub to alternate interpreter */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_fe: /* 0xfe */ /* File: mips/op_unused_fe.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback /* ------------------------------ */ .balign 128 .L_op_unused_ff: /* 0xff */ /* File: mips/op_unused_ff.S */ /* File: mips/unused.S */ /* * Bail to reference interpreter to throw. */ b MterpFallback .balign 128 .size artMterpAsmInstructionStart, .-artMterpAsmInstructionStart .global artMterpAsmInstructionEnd artMterpAsmInstructionEnd: /* * =========================================================================== * Sister implementations * =========================================================================== */ .global artMterpAsmSisterStart .type artMterpAsmSisterStart, %function .text .balign 4 artMterpAsmSisterStart: /* continuation for op_float_to_long */ #ifndef MIPS32REVGE6 .Lop_float_to_long_get_opcode: GET_INST_OPCODE(t1) # extract opcode from rINST .Lop_float_to_long_set_vreg: SET_VREG64_GOTO(rRESULT0, rRESULT1, rOBJ, t1) # vA/vA+1 <- v0/v1 #endif /* continuation for op_double_to_long */ #ifndef MIPS32REVGE6 .Lop_double_to_long_get_opcode: GET_INST_OPCODE(t1) # extract opcode from rINST .Lop_double_to_long_set_vreg: SET_VREG64_GOTO(rRESULT0, rRESULT1, rOBJ, t1) # vA/vA+1 <- v0/v1 #endif /* continuation for op_mul_long */ .Lop_mul_long_finish: GET_INST_OPCODE(t0) # extract opcode from rINST SET_VREG64_GOTO(v0, v1, a0, t0) # vAA/vAA+1 <- v0(low)/v1(high) /* continuation for op_shl_long */ .Lop_shl_long_finish: SET_VREG64_GOTO(zero, v0, t2, t0) # vAA/vAA+1 <- rlo/rhi /* continuation for op_shr_long */ .Lop_shr_long_finish: sra a3, a1, 31 # a3<- sign(ah) SET_VREG64_GOTO(v1, a3, t3, t0) # vAA/VAA+1 <- rlo/rhi /* continuation for op_ushr_long */ .Lop_ushr_long_finish: SET_VREG64_GOTO(v1, zero, rOBJ, t0) # vAA/vAA+1 <- rlo/rhi /* continuation for op_shl_long_2addr */ .Lop_shl_long_2addr_finish: SET_VREG64_GOTO(zero, v0, rOBJ, t0) # vA/vA+1 <- rlo/rhi /* continuation for op_shr_long_2addr */ .Lop_shr_long_2addr_finish: sra a3, a1, 31 # a3<- sign(ah) SET_VREG64_GOTO(v1, a3, t2, t0) # vA/vA+1 <- rlo/rhi /* continuation for op_ushr_long_2addr */ .Lop_ushr_long_2addr_finish: SET_VREG64_GOTO(v1, zero, t3, t0) # vA/vA+1 <- rlo/rhi .size artMterpAsmSisterStart, .-artMterpAsmSisterStart .global artMterpAsmSisterEnd artMterpAsmSisterEnd: .global artMterpAsmAltInstructionStart .type artMterpAsmAltInstructionStart, %function .text artMterpAsmAltInstructionStart = .L_ALT_op_nop /* ------------------------------ */ .balign 128 .L_ALT_op_nop: /* 0x00 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (0 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move: /* 0x01 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (1 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_from16: /* 0x02 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (2 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_16: /* 0x03 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (3 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_wide: /* 0x04 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (4 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_wide_from16: /* 0x05 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (5 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_wide_16: /* 0x06 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (6 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_object: /* 0x07 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (7 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_object_from16: /* 0x08 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (8 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_object_16: /* 0x09 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (9 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_result: /* 0x0a */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (10 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_result_wide: /* 0x0b */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (11 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_result_object: /* 0x0c */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (12 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_move_exception: /* 0x0d */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (13 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_return_void: /* 0x0e */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (14 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_return: /* 0x0f */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (15 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_return_wide: /* 0x10 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (16 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_return_object: /* 0x11 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (17 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const_4: /* 0x12 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (18 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const_16: /* 0x13 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (19 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const: /* 0x14 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (20 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const_high16: /* 0x15 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (21 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const_wide_16: /* 0x16 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (22 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const_wide_32: /* 0x17 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (23 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const_wide: /* 0x18 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (24 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const_wide_high16: /* 0x19 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (25 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const_string: /* 0x1a */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (26 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const_string_jumbo: /* 0x1b */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (27 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_const_class: /* 0x1c */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (28 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_monitor_enter: /* 0x1d */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (29 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_monitor_exit: /* 0x1e */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (30 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_check_cast: /* 0x1f */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (31 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_instance_of: /* 0x20 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (32 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_array_length: /* 0x21 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (33 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_new_instance: /* 0x22 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (34 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_new_array: /* 0x23 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (35 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_filled_new_array: /* 0x24 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (36 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_filled_new_array_range: /* 0x25 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (37 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_fill_array_data: /* 0x26 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (38 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_throw: /* 0x27 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (39 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_goto: /* 0x28 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (40 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_goto_16: /* 0x29 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (41 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_goto_32: /* 0x2a */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (42 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_packed_switch: /* 0x2b */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (43 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sparse_switch: /* 0x2c */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (44 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_cmpl_float: /* 0x2d */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (45 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_cmpg_float: /* 0x2e */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (46 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_cmpl_double: /* 0x2f */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (47 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_cmpg_double: /* 0x30 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (48 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_cmp_long: /* 0x31 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (49 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_eq: /* 0x32 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (50 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_ne: /* 0x33 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (51 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_lt: /* 0x34 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (52 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_ge: /* 0x35 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (53 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_gt: /* 0x36 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (54 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_le: /* 0x37 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (55 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_eqz: /* 0x38 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (56 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_nez: /* 0x39 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (57 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_ltz: /* 0x3a */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (58 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_gez: /* 0x3b */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (59 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_gtz: /* 0x3c */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (60 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_if_lez: /* 0x3d */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (61 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_3e: /* 0x3e */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (62 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_3f: /* 0x3f */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (63 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_40: /* 0x40 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (64 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_41: /* 0x41 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (65 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_42: /* 0x42 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (66 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_43: /* 0x43 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (67 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aget: /* 0x44 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (68 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aget_wide: /* 0x45 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (69 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aget_object: /* 0x46 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (70 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aget_boolean: /* 0x47 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (71 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aget_byte: /* 0x48 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (72 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aget_char: /* 0x49 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (73 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aget_short: /* 0x4a */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (74 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aput: /* 0x4b */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (75 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aput_wide: /* 0x4c */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (76 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aput_object: /* 0x4d */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (77 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aput_boolean: /* 0x4e */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (78 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aput_byte: /* 0x4f */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (79 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aput_char: /* 0x50 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (80 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_aput_short: /* 0x51 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (81 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget: /* 0x52 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (82 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_wide: /* 0x53 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (83 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_object: /* 0x54 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (84 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_boolean: /* 0x55 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (85 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_byte: /* 0x56 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (86 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_char: /* 0x57 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (87 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_short: /* 0x58 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (88 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput: /* 0x59 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (89 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_wide: /* 0x5a */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (90 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_object: /* 0x5b */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (91 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_boolean: /* 0x5c */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (92 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_byte: /* 0x5d */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (93 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_char: /* 0x5e */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (94 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_short: /* 0x5f */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (95 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sget: /* 0x60 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (96 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sget_wide: /* 0x61 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (97 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sget_object: /* 0x62 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (98 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sget_boolean: /* 0x63 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (99 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sget_byte: /* 0x64 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (100 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sget_char: /* 0x65 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (101 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sget_short: /* 0x66 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (102 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sput: /* 0x67 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (103 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sput_wide: /* 0x68 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (104 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sput_object: /* 0x69 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (105 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sput_boolean: /* 0x6a */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (106 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sput_byte: /* 0x6b */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (107 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sput_char: /* 0x6c */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (108 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sput_short: /* 0x6d */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (109 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_virtual: /* 0x6e */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (110 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_super: /* 0x6f */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (111 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_direct: /* 0x70 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (112 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_static: /* 0x71 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (113 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_interface: /* 0x72 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (114 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_return_void_no_barrier: /* 0x73 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (115 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_virtual_range: /* 0x74 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (116 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_super_range: /* 0x75 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (117 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_direct_range: /* 0x76 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (118 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_static_range: /* 0x77 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (119 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_interface_range: /* 0x78 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (120 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_79: /* 0x79 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (121 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_7a: /* 0x7a */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (122 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_neg_int: /* 0x7b */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (123 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_not_int: /* 0x7c */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (124 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_neg_long: /* 0x7d */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (125 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_not_long: /* 0x7e */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (126 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_neg_float: /* 0x7f */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (127 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_neg_double: /* 0x80 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (128 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_int_to_long: /* 0x81 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (129 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_int_to_float: /* 0x82 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (130 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_int_to_double: /* 0x83 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (131 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_long_to_int: /* 0x84 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (132 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_long_to_float: /* 0x85 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (133 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_long_to_double: /* 0x86 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (134 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_float_to_int: /* 0x87 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (135 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_float_to_long: /* 0x88 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (136 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_float_to_double: /* 0x89 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (137 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_double_to_int: /* 0x8a */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (138 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_double_to_long: /* 0x8b */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (139 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_double_to_float: /* 0x8c */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (140 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_int_to_byte: /* 0x8d */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (141 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_int_to_char: /* 0x8e */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (142 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_int_to_short: /* 0x8f */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (143 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_add_int: /* 0x90 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (144 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sub_int: /* 0x91 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (145 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_mul_int: /* 0x92 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (146 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_div_int: /* 0x93 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (147 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rem_int: /* 0x94 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (148 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_and_int: /* 0x95 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (149 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_or_int: /* 0x96 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (150 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_xor_int: /* 0x97 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (151 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_shl_int: /* 0x98 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (152 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_shr_int: /* 0x99 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (153 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_ushr_int: /* 0x9a */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (154 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_add_long: /* 0x9b */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (155 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sub_long: /* 0x9c */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (156 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_mul_long: /* 0x9d */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (157 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_div_long: /* 0x9e */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (158 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rem_long: /* 0x9f */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (159 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_and_long: /* 0xa0 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (160 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_or_long: /* 0xa1 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (161 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_xor_long: /* 0xa2 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (162 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_shl_long: /* 0xa3 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (163 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_shr_long: /* 0xa4 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (164 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_ushr_long: /* 0xa5 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (165 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_add_float: /* 0xa6 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (166 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sub_float: /* 0xa7 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (167 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_mul_float: /* 0xa8 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (168 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_div_float: /* 0xa9 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (169 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rem_float: /* 0xaa */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (170 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_add_double: /* 0xab */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (171 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sub_double: /* 0xac */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (172 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_mul_double: /* 0xad */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (173 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_div_double: /* 0xae */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (174 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rem_double: /* 0xaf */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (175 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_add_int_2addr: /* 0xb0 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (176 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sub_int_2addr: /* 0xb1 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (177 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_mul_int_2addr: /* 0xb2 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (178 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_div_int_2addr: /* 0xb3 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (179 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rem_int_2addr: /* 0xb4 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (180 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_and_int_2addr: /* 0xb5 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (181 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_or_int_2addr: /* 0xb6 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (182 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_xor_int_2addr: /* 0xb7 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (183 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_shl_int_2addr: /* 0xb8 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (184 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_shr_int_2addr: /* 0xb9 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (185 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_ushr_int_2addr: /* 0xba */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (186 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_add_long_2addr: /* 0xbb */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (187 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sub_long_2addr: /* 0xbc */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (188 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_mul_long_2addr: /* 0xbd */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (189 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_div_long_2addr: /* 0xbe */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (190 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rem_long_2addr: /* 0xbf */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (191 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_and_long_2addr: /* 0xc0 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (192 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_or_long_2addr: /* 0xc1 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (193 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_xor_long_2addr: /* 0xc2 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (194 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_shl_long_2addr: /* 0xc3 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (195 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_shr_long_2addr: /* 0xc4 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (196 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_ushr_long_2addr: /* 0xc5 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (197 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_add_float_2addr: /* 0xc6 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (198 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sub_float_2addr: /* 0xc7 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (199 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_mul_float_2addr: /* 0xc8 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (200 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_div_float_2addr: /* 0xc9 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (201 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rem_float_2addr: /* 0xca */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (202 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_add_double_2addr: /* 0xcb */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (203 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_sub_double_2addr: /* 0xcc */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (204 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_mul_double_2addr: /* 0xcd */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (205 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_div_double_2addr: /* 0xce */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (206 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rem_double_2addr: /* 0xcf */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (207 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_add_int_lit16: /* 0xd0 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (208 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rsub_int: /* 0xd1 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (209 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_mul_int_lit16: /* 0xd2 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (210 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_div_int_lit16: /* 0xd3 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (211 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rem_int_lit16: /* 0xd4 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (212 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_and_int_lit16: /* 0xd5 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (213 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_or_int_lit16: /* 0xd6 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (214 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_xor_int_lit16: /* 0xd7 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (215 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_add_int_lit8: /* 0xd8 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (216 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rsub_int_lit8: /* 0xd9 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (217 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_mul_int_lit8: /* 0xda */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (218 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_div_int_lit8: /* 0xdb */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (219 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_rem_int_lit8: /* 0xdc */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (220 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_and_int_lit8: /* 0xdd */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (221 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_or_int_lit8: /* 0xde */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (222 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_xor_int_lit8: /* 0xdf */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (223 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_shl_int_lit8: /* 0xe0 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (224 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_shr_int_lit8: /* 0xe1 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (225 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_ushr_int_lit8: /* 0xe2 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (226 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_quick: /* 0xe3 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (227 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_wide_quick: /* 0xe4 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (228 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_object_quick: /* 0xe5 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (229 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_quick: /* 0xe6 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (230 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_wide_quick: /* 0xe7 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (231 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_object_quick: /* 0xe8 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (232 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_virtual_quick: /* 0xe9 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (233 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_virtual_range_quick: /* 0xea */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (234 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_boolean_quick: /* 0xeb */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (235 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_byte_quick: /* 0xec */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (236 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_char_quick: /* 0xed */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (237 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iput_short_quick: /* 0xee */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (238 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_boolean_quick: /* 0xef */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (239 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_byte_quick: /* 0xf0 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (240 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_char_quick: /* 0xf1 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (241 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_iget_short_quick: /* 0xf2 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (242 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_f3: /* 0xf3 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (243 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_f4: /* 0xf4 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (244 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_f5: /* 0xf5 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (245 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_f6: /* 0xf6 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (246 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_f7: /* 0xf7 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (247 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_f8: /* 0xf8 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (248 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_f9: /* 0xf9 */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (249 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_polymorphic: /* 0xfa */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (250 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_polymorphic_range: /* 0xfb */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (251 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_custom: /* 0xfc */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (252 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_invoke_custom_range: /* 0xfd */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (253 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_fe: /* 0xfe */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (254 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) /* ------------------------------ */ .balign 128 .L_ALT_op_unused_ff: /* 0xff */ /* File: mips/alt_stub.S */ /* * Inter-instruction transfer stub. Call out to MterpCheckBefore to handle * any interesting requests and then jump to the real instruction * handler. Note that the call to MterpCheckBefore is done as a tail call. */ .extern MterpCheckBefore la ra, artMterpAsmInstructionStart + (255 * 128) # Addr of primary handler lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) # refresh IBASE move a0, rSELF # arg0 addu a1, rFP, OFF_FP_SHADOWFRAME # arg1 move a2, rPC la t9, MterpCheckBefore jalr zero, t9 # Tail call to Mterp(self, shadow_frame, dex_pc_ptr) .balign 128 .size artMterpAsmAltInstructionStart, .-artMterpAsmAltInstructionStart .global artMterpAsmAltInstructionEnd artMterpAsmAltInstructionEnd: /* File: mips/footer.S */ /* * =========================================================================== * Common subroutines and data * =========================================================================== */ .text .align 2 /* * We've detected a condition that will result in an exception, but the exception * has not yet been thrown. Just bail out to the reference interpreter to deal with it. * TUNING: for consistency, we may want to just go ahead and handle these here. */ common_errDivideByZero: EXPORT_PC() #if MTERP_LOGGING move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME JAL(MterpLogDivideByZeroException) #endif b MterpCommonFallback common_errArrayIndex: EXPORT_PC() #if MTERP_LOGGING move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME JAL(MterpLogArrayIndexException) #endif b MterpCommonFallback common_errNegativeArraySize: EXPORT_PC() #if MTERP_LOGGING move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME JAL(MterpLogNegativeArraySizeException) #endif b MterpCommonFallback common_errNoSuchMethod: EXPORT_PC() #if MTERP_LOGGING move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME JAL(MterpLogNoSuchMethodException) #endif b MterpCommonFallback common_errNullObject: EXPORT_PC() #if MTERP_LOGGING move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME JAL(MterpLogNullObjectException) #endif b MterpCommonFallback common_exceptionThrown: EXPORT_PC() #if MTERP_LOGGING move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME JAL(MterpLogExceptionThrownException) #endif b MterpCommonFallback MterpSuspendFallback: EXPORT_PC() #if MTERP_LOGGING move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME lw a2, THREAD_FLAGS_OFFSET(rSELF) JAL(MterpLogSuspendFallback) #endif b MterpCommonFallback /* * If we're here, something is out of the ordinary. If there is a pending * exception, handle it. Otherwise, roll back and retry with the reference * interpreter. */ MterpPossibleException: lw a0, THREAD_EXCEPTION_OFFSET(rSELF) beqz a0, MterpFallback # If exception, fall back to reference interpreter. /* intentional fallthrough - handle pending exception. */ /* * On return from a runtime helper routine, we've found a pending exception. * Can we handle it here - or need to bail out to caller? * */ MterpException: move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME JAL(MterpHandleException) # (self, shadow_frame) beqz v0, MterpExceptionReturn # no local catch, back to caller. lw a0, OFF_FP_CODE_ITEM(rFP) lw a1, OFF_FP_DEX_PC(rFP) lw rIBASE, THREAD_CURRENT_IBASE_OFFSET(rSELF) addu rPC, a0, CODEITEM_INSNS_OFFSET sll a1, a1, 1 addu rPC, rPC, a1 # generate new dex_pc_ptr /* Do we need to switch interpreters? */ JAL(MterpShouldSwitchInterpreters) bnez v0, MterpFallback /* resume execution at catch block */ EXPORT_PC() FETCH_INST() GET_INST_OPCODE(t0) GOTO_OPCODE(t0) /* NOTE: no fallthrough */ /* * Common handling for branches with support for Jit profiling. * On entry: * rINST <= signed offset * rPROFILE <= signed hotness countdown (expanded to 32 bits) * * We have quite a few different cases for branch profiling, OSR detection and * suspend check support here. * * Taken backward branches: * If profiling active, do hotness countdown and report if we hit zero. * If in osr check mode, see if our target is a compiled loop header entry and do OSR if so. * Is there a pending suspend request? If so, suspend. * * Taken forward branches and not-taken backward branches: * If in osr check mode, see if our target is a compiled loop header entry and do OSR if so. * * Our most common case is expected to be a taken backward branch with active jit profiling, * but no full OSR check and no pending suspend request. * Next most common case is not-taken branch with no full OSR check. */ MterpCommonTakenBranchNoFlags: bgtz rINST, .L_forward_branch # don't add forward branches to hotness /* * We need to subtract 1 from positive values and we should not see 0 here, * so we may use the result of the comparison with -1. */ #if JIT_CHECK_OSR != -1 # error "JIT_CHECK_OSR must be -1." #endif li t0, JIT_CHECK_OSR beq rPROFILE, t0, .L_osr_check blt rPROFILE, t0, .L_resume_backward_branch subu rPROFILE, 1 beqz rPROFILE, .L_add_batch # counted down to zero - report .L_resume_backward_branch: lw ra, THREAD_FLAGS_OFFSET(rSELF) REFRESH_IBASE() addu a2, rINST, rINST # a2<- byte offset FETCH_ADVANCE_INST_RB(a2) # update rPC, load rINST and ra, THREAD_SUSPEND_OR_CHECKPOINT_REQUEST bnez ra, .L_suspend_request_pending GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction .L_suspend_request_pending: EXPORT_PC() move a0, rSELF JAL(MterpSuspendCheck) # (self) bnez v0, MterpFallback REFRESH_IBASE() # might have changed during suspend GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction .L_no_count_backwards: li t0, JIT_CHECK_OSR # check for possible OSR re-entry bne rPROFILE, t0, .L_resume_backward_branch .L_osr_check: move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rINST EXPORT_PC() JAL(MterpMaybeDoOnStackReplacement) # (self, shadow_frame, offset) bnez v0, MterpOnStackReplacement b .L_resume_backward_branch .L_forward_branch: li t0, JIT_CHECK_OSR # check for possible OSR re-entry beq rPROFILE, t0, .L_check_osr_forward .L_resume_forward_branch: add a2, rINST, rINST # a2<- byte offset FETCH_ADVANCE_INST_RB(a2) # update rPC, load rINST GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction .L_check_osr_forward: move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rINST EXPORT_PC() JAL(MterpMaybeDoOnStackReplacement) # (self, shadow_frame, offset) bnez v0, MterpOnStackReplacement b .L_resume_forward_branch .L_add_batch: addu a1, rFP, OFF_FP_SHADOWFRAME sh rPROFILE, SHADOWFRAME_HOTNESS_COUNTDOWN_OFFSET(a1) lw a0, OFF_FP_METHOD(rFP) move a2, rSELF JAL(MterpAddHotnessBatch) # (method, shadow_frame, self) move rPROFILE, v0 # restore new hotness countdown to rPROFILE b .L_no_count_backwards /* * Entered from the conditional branch handlers when OSR check request active on * not-taken path. All Dalvik not-taken conditional branch offsets are 2. */ .L_check_not_taken_osr: move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME li a2, 2 EXPORT_PC() JAL(MterpMaybeDoOnStackReplacement) # (self, shadow_frame, offset) bnez v0, MterpOnStackReplacement FETCH_ADVANCE_INST(2) GET_INST_OPCODE(t0) # extract opcode from rINST GOTO_OPCODE(t0) # jump to next instruction /* * On-stack replacement has happened, and now we've returned from the compiled method. */ MterpOnStackReplacement: #if MTERP_LOGGING move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rINST JAL(MterpLogOSR) #endif li v0, 1 # Signal normal return b MterpDone /* * Bail out to reference interpreter. */ MterpFallback: EXPORT_PC() #if MTERP_LOGGING move a0, rSELF addu a1, rFP, OFF_FP_SHADOWFRAME JAL(MterpLogFallback) #endif MterpCommonFallback: move v0, zero # signal retry with reference interpreter. b MterpDone /* * We pushed some registers on the stack in ExecuteMterpImpl, then saved * SP and LR. Here we restore SP, restore the registers, and then restore * LR to PC. * * On entry: * uint32_t* rFP (should still be live, pointer to base of vregs) */ MterpExceptionReturn: li v0, 1 # signal return to caller. b MterpDone MterpReturn: lw a2, OFF_FP_RESULT_REGISTER(rFP) sw v0, 0(a2) sw v1, 4(a2) li v0, 1 # signal return to caller. MterpDone: /* * At this point, we expect rPROFILE to be non-zero. If negative, hotness is disabled or we're * checking for OSR. If greater than zero, we might have unreported hotness to register * (the difference between the ending rPROFILE and the cached hotness counter). rPROFILE * should only reach zero immediately after a hotness decrement, and is then reset to either * a negative special state or the new non-zero countdown value. */ blez rPROFILE, .L_pop_and_return # if > 0, we may have some counts to report. MterpProfileActive: move rINST, v0 # stash return value /* Report cached hotness counts */ lw a0, OFF_FP_METHOD(rFP) addu a1, rFP, OFF_FP_SHADOWFRAME move a2, rSELF sh rPROFILE, SHADOWFRAME_HOTNESS_COUNTDOWN_OFFSET(a1) JAL(MterpAddHotnessBatch) # (method, shadow_frame, self) move v0, rINST # restore return value .L_pop_and_return: /* Restore from the stack and return. Frame size = STACK_SIZE */ STACK_LOAD_FULL() jalr zero, ra .end ExecuteMterpImpl