/* ----------------------------------------------------------------------- n32.S - Copyright (c) 1996, 1998, 2005 Red Hat, Inc. MIPS Foreign Function Interface Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the ``Software''), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED ``AS IS'', WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. ----------------------------------------------------------------------- */ #define LIBFFI_ASM #include <fficonfig.h> #include <ffi.h> /* Only build this code if we are compiling for n32 */ #if defined(FFI_MIPS_N32) #define callback a0 #define bytes a2 #define flags a3 #define raddr a4 #define fn a5 #define SIZEOF_FRAME ( 8 * FFI_SIZEOF_ARG ) .abicalls .text .align 2 .globl ffi_call_N32 .ent ffi_call_N32 ffi_call_N32: .LFB3: .frame $fp, SIZEOF_FRAME, ra .mask 0xc0000000,-FFI_SIZEOF_ARG .fmask 0x00000000,0 # Prologue SUBU $sp, SIZEOF_FRAME # Frame size .LCFI0: REG_S $fp, SIZEOF_FRAME - 2*FFI_SIZEOF_ARG($sp) # Save frame pointer REG_S ra, SIZEOF_FRAME - 1*FFI_SIZEOF_ARG($sp) # Save return address .LCFI1: move $fp, $sp .LCFI3: move t9, callback # callback function pointer REG_S bytes, 2*FFI_SIZEOF_ARG($fp) # bytes REG_S flags, 3*FFI_SIZEOF_ARG($fp) # flags REG_S raddr, 4*FFI_SIZEOF_ARG($fp) # raddr REG_S fn, 5*FFI_SIZEOF_ARG($fp) # fn # Allocate at least 4 words in the argstack move v0, bytes bge bytes, 4 * FFI_SIZEOF_ARG, bigger LI v0, 4 * FFI_SIZEOF_ARG b sixteen bigger: ADDU t4, v0, 2 * FFI_SIZEOF_ARG -1 # make sure it is aligned and v0, t4, -2 * FFI_SIZEOF_ARG # to a proper boundry. sixteen: SUBU $sp, $sp, v0 # move the stack pointer to reflect the # arg space move a0, $sp # 4 * FFI_SIZEOF_ARG ADDU a3, $fp, 3 * FFI_SIZEOF_ARG # Call ffi_prep_args jal t9 # Copy the stack pointer to t9 move t9, $sp # Fix the stack if there are more than 8 64bit slots worth # of arguments. # Load the number of bytes REG_L t6, 2*FFI_SIZEOF_ARG($fp) # Is it bigger than 8 * FFI_SIZEOF_ARG? daddiu t8, t6, -(8 * FFI_SIZEOF_ARG) bltz t8, loadregs ADDU t9, t9, t8 loadregs: REG_L t6, 3*FFI_SIZEOF_ARG($fp) # load the flags word into t6. and t4, t6, ((1<<FFI_FLAG_BITS)-1) bnez t4, arg1_floatp REG_L a0, 0*FFI_SIZEOF_ARG(t9) b arg1_next arg1_floatp: bne t4, FFI_TYPE_FLOAT, arg1_doublep l.s $f12, 0*FFI_SIZEOF_ARG(t9) b arg1_next arg1_doublep: l.d $f12, 0*FFI_SIZEOF_ARG(t9) arg1_next: SRL t4, t6, 1*FFI_FLAG_BITS and t4, ((1<<FFI_FLAG_BITS)-1) bnez t4, arg2_floatp REG_L a1, 1*FFI_SIZEOF_ARG(t9) b arg2_next arg2_floatp: bne t4, FFI_TYPE_FLOAT, arg2_doublep l.s $f13, 1*FFI_SIZEOF_ARG(t9) b arg2_next arg2_doublep: l.d $f13, 1*FFI_SIZEOF_ARG(t9) arg2_next: SRL t4, t6, 2*FFI_FLAG_BITS and t4, ((1<<FFI_FLAG_BITS)-1) bnez t4, arg3_floatp REG_L a2, 2*FFI_SIZEOF_ARG(t9) b arg3_next arg3_floatp: bne t4, FFI_TYPE_FLOAT, arg3_doublep l.s $f14, 2*FFI_SIZEOF_ARG(t9) b arg3_next arg3_doublep: l.d $f14, 2*FFI_SIZEOF_ARG(t9) arg3_next: SRL t4, t6, 3*FFI_FLAG_BITS and t4, ((1<<FFI_FLAG_BITS)-1) bnez t4, arg4_floatp REG_L a3, 3*FFI_SIZEOF_ARG(t9) b arg4_next arg4_floatp: bne t4, FFI_TYPE_FLOAT, arg4_doublep l.s $f15, 3*FFI_SIZEOF_ARG(t9) b arg4_next arg4_doublep: l.d $f15, 3*FFI_SIZEOF_ARG(t9) arg4_next: SRL t4, t6, 4*FFI_FLAG_BITS and t4, ((1<<FFI_FLAG_BITS)-1) bnez t4, arg5_floatp REG_L a4, 4*FFI_SIZEOF_ARG(t9) b arg5_next arg5_floatp: bne t4, FFI_TYPE_FLOAT, arg5_doublep l.s $f16, 4*FFI_SIZEOF_ARG(t9) b arg5_next arg5_doublep: l.d $f16, 4*FFI_SIZEOF_ARG(t9) arg5_next: SRL t4, t6, 5*FFI_FLAG_BITS and t4, ((1<<FFI_FLAG_BITS)-1) bnez t4, arg6_floatp REG_L a5, 5*FFI_SIZEOF_ARG(t9) b arg6_next arg6_floatp: bne t4, FFI_TYPE_FLOAT, arg6_doublep l.s $f17, 5*FFI_SIZEOF_ARG(t9) b arg6_next arg6_doublep: l.d $f17, 5*FFI_SIZEOF_ARG(t9) arg6_next: SRL t4, t6, 6*FFI_FLAG_BITS and t4, ((1<<FFI_FLAG_BITS)-1) bnez t4, arg7_floatp REG_L a6, 6*FFI_SIZEOF_ARG(t9) b arg7_next arg7_floatp: bne t4, FFI_TYPE_FLOAT, arg7_doublep l.s $f18, 6*FFI_SIZEOF_ARG(t9) b arg7_next arg7_doublep: l.d $f18, 6*FFI_SIZEOF_ARG(t9) arg7_next: SRL t4, t6, 7*FFI_FLAG_BITS and t4, ((1<<FFI_FLAG_BITS)-1) bnez t4, arg8_floatp REG_L a7, 7*FFI_SIZEOF_ARG(t9) b arg8_next arg8_floatp: bne t4, FFI_TYPE_FLOAT, arg8_doublep l.s $f19, 7*FFI_SIZEOF_ARG(t9) b arg8_next arg8_doublep: l.d $f19, 7*FFI_SIZEOF_ARG(t9) arg8_next: callit: # Load the function pointer REG_L t9, 5*FFI_SIZEOF_ARG($fp) # If the return value pointer is NULL, assume no return value. REG_L t5, 4*FFI_SIZEOF_ARG($fp) beqz t5, noretval # Shift the return type flag over SRL t6, 8*FFI_FLAG_BITS bne t6, FFI_TYPE_INT, retfloat jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) REG_S v0, 0(t4) b epilogue retfloat: bne t6, FFI_TYPE_FLOAT, retdouble jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) s.s $f0, 0(t4) b epilogue retdouble: bne t6, FFI_TYPE_DOUBLE, retstruct_d jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) s.d $f0, 0(t4) b epilogue retstruct_d: bne t6, FFI_TYPE_STRUCT_D, retstruct_f jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) s.d $f0, 0(t4) b epilogue retstruct_f: bne t6, FFI_TYPE_STRUCT_F, retstruct_d_d jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) s.s $f0, 0(t4) b epilogue retstruct_d_d: bne t6, FFI_TYPE_STRUCT_DD, retstruct_f_f jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) s.d $f0, 0(t4) s.d $f2, 8(t4) b epilogue retstruct_f_f: bne t6, FFI_TYPE_STRUCT_FF, retstruct_d_f jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) s.s $f0, 0(t4) s.s $f2, 4(t4) b epilogue retstruct_d_f: bne t6, FFI_TYPE_STRUCT_DF, retstruct_f_d jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) s.d $f0, 0(t4) s.s $f2, 8(t4) b epilogue retstruct_f_d: bne t6, FFI_TYPE_STRUCT_FD, retstruct_small jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) s.s $f0, 0(t4) s.d $f2, 8(t4) b epilogue retstruct_small: bne t6, FFI_TYPE_STRUCT_SMALL, retstruct_small2 jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) REG_S v0, 0(t4) b epilogue retstruct_small2: bne t6, FFI_TYPE_STRUCT_SMALL2, retstruct jal t9 REG_L t4, 4*FFI_SIZEOF_ARG($fp) REG_S v0, 0(t4) REG_S v1, 8(t4) b epilogue retstruct: noretval: jal t9 # Epilogue epilogue: move $sp, $fp REG_L $fp, SIZEOF_FRAME - 2*FFI_SIZEOF_ARG($sp) # Restore frame pointer REG_L ra, SIZEOF_FRAME - 1*FFI_SIZEOF_ARG($sp) # Restore return address ADDU $sp, SIZEOF_FRAME # Fix stack pointer j ra .LFE3: .end ffi_call_N32 /* ffi_closure_N32. Expects address of the passed-in ffi_closure in t0 ($12). Stores any arguments passed in registers onto the stack, then calls ffi_closure_mips_inner_N32, which then decodes them. Stack layout: 20 - Start of parameters, original sp 19 - Called function a7 save 18 - Called function a6 save 17 - Called function a5 save 16 - Called function a4 save 15 - Called function a3 save 14 - Called function a2 save 13 - Called function a1 save 12 - Called function a0 save 11 - Called function f19 10 - Called function f18 9 - Called function f17 8 - Called function f16 7 - Called function f15 6 - Called function f14 5 - Called function f13 4 - Called function f12 3 - return value high (v1 or $f2) 2 - return value low (v0 or $f0) 1 - ra save 0 - gp save our sp points here */ #define SIZEOF_FRAME2 (20 * FFI_SIZEOF_ARG) #define A7_OFF2 (19 * FFI_SIZEOF_ARG) #define A6_OFF2 (18 * FFI_SIZEOF_ARG) #define A5_OFF2 (17 * FFI_SIZEOF_ARG) #define A4_OFF2 (16 * FFI_SIZEOF_ARG) #define A3_OFF2 (15 * FFI_SIZEOF_ARG) #define A2_OFF2 (14 * FFI_SIZEOF_ARG) #define A1_OFF2 (13 * FFI_SIZEOF_ARG) #define A0_OFF2 (12 * FFI_SIZEOF_ARG) #define F19_OFF2 (11 * FFI_SIZEOF_ARG) #define F18_OFF2 (10 * FFI_SIZEOF_ARG) #define F17_OFF2 (9 * FFI_SIZEOF_ARG) #define F16_OFF2 (8 * FFI_SIZEOF_ARG) #define F15_OFF2 (7 * FFI_SIZEOF_ARG) #define F14_OFF2 (6 * FFI_SIZEOF_ARG) #define F13_OFF2 (5 * FFI_SIZEOF_ARG) #define F12_OFF2 (4 * FFI_SIZEOF_ARG) #define V1_OFF2 (3 * FFI_SIZEOF_ARG) #define V0_OFF2 (2 * FFI_SIZEOF_ARG) #define RA_OFF2 (1 * FFI_SIZEOF_ARG) #define GP_OFF2 (0 * FFI_SIZEOF_ARG) .align 2 .globl ffi_closure_N32 .ent ffi_closure_N32 ffi_closure_N32: .LFB2: .frame $sp, SIZEOF_FRAME2, ra .mask 0x90000000,-(SIZEOF_FRAME2 - RA_OFF2) .fmask 0x00000000,0 SUBU $sp, SIZEOF_FRAME2 .LCFI5: .cpsetup t9, GP_OFF2, ffi_closure_N32 REG_S ra, RA_OFF2($sp) # Save return address .LCFI6: # Store all possible argument registers. If there are more than # fit in registers, then they were stored on the stack. REG_S a0, A0_OFF2($sp) REG_S a1, A1_OFF2($sp) REG_S a2, A2_OFF2($sp) REG_S a3, A3_OFF2($sp) REG_S a4, A4_OFF2($sp) REG_S a5, A5_OFF2($sp) REG_S a6, A6_OFF2($sp) REG_S a7, A7_OFF2($sp) # Store all possible float/double registers. s.d $f12, F12_OFF2($sp) s.d $f13, F13_OFF2($sp) s.d $f14, F14_OFF2($sp) s.d $f15, F15_OFF2($sp) s.d $f16, F16_OFF2($sp) s.d $f17, F17_OFF2($sp) s.d $f18, F18_OFF2($sp) s.d $f19, F19_OFF2($sp) # Call ffi_closure_mips_inner_N32 to do the real work. LA t9, ffi_closure_mips_inner_N32 move a0, $12 # Pointer to the ffi_closure ADDU a1, $sp, V0_OFF2 ADDU a2, $sp, A0_OFF2 ADDU a3, $sp, F12_OFF2 jalr t9 # Return flags are in v0 bne v0, FFI_TYPE_INT, cls_retfloat REG_L v0, V0_OFF2($sp) b cls_epilogue cls_retfloat: bne v0, FFI_TYPE_FLOAT, cls_retdouble l.s $f0, V0_OFF2($sp) b cls_epilogue cls_retdouble: bne v0, FFI_TYPE_DOUBLE, cls_retstruct_d l.d $f0, V0_OFF2($sp) b cls_epilogue cls_retstruct_d: bne v0, FFI_TYPE_STRUCT_D, cls_retstruct_f l.d $f0, V0_OFF2($sp) b cls_epilogue cls_retstruct_f: bne v0, FFI_TYPE_STRUCT_F, cls_retstruct_d_d l.s $f0, V0_OFF2($sp) b cls_epilogue cls_retstruct_d_d: bne v0, FFI_TYPE_STRUCT_DD, cls_retstruct_f_f l.d $f0, V0_OFF2($sp) l.d $f2, V1_OFF2($sp) b cls_epilogue cls_retstruct_f_f: bne v0, FFI_TYPE_STRUCT_FF, cls_retstruct_d_f l.s $f0, V0_OFF2($sp) l.s $f2, V1_OFF2($sp) b cls_epilogue cls_retstruct_d_f: bne v0, FFI_TYPE_STRUCT_DF, cls_retstruct_f_d l.d $f0, V0_OFF2($sp) l.s $f2, V1_OFF2($sp) b cls_epilogue cls_retstruct_f_d: bne v0, FFI_TYPE_STRUCT_FD, cls_retstruct_small2 l.s $f0, V0_OFF2($sp) l.d $f2, V1_OFF2($sp) b cls_epilogue cls_retstruct_small2: REG_L v0, V0_OFF2($sp) REG_L v1, V1_OFF2($sp) # Epilogue cls_epilogue: REG_L ra, RA_OFF2($sp) # Restore return address .cpreturn ADDU $sp, SIZEOF_FRAME2 j ra .LFE2: .end ffi_closure_N32 .section .eh_frame,"aw",@progbits .Lframe1: .4byte .LECIE1-.LSCIE1 # length .LSCIE1: .4byte 0x0 # CIE .byte 0x1 # Version 1 .ascii "\000" # Augmentation .uleb128 0x1 # Code alignment 1 .sleb128 -4 # Data alignment -4 .byte 0x1f # Return Address $31 .byte 0xc # DW_CFA_def_cfa .uleb128 0x1d # in $sp .uleb128 0x0 # offset 0 .align EH_FRAME_ALIGN .LECIE1: .LSFDE1: .4byte .LEFDE1-.LASFDE1 # length. .LASFDE1: .4byte .LASFDE1-.Lframe1 # CIE_pointer. FDE_ADDR_BYTES .LFB3 # initial_location. FDE_ADDR_BYTES .LFE3-.LFB3 # address_range. .byte 0x4 # DW_CFA_advance_loc4 .4byte .LCFI0-.LFB3 # to .LCFI0 .byte 0xe # DW_CFA_def_cfa_offset .uleb128 SIZEOF_FRAME # adjust stack.by SIZEOF_FRAME .byte 0x4 # DW_CFA_advance_loc4 .4byte .LCFI1-.LCFI0 # to .LCFI1 .byte 0x9e # DW_CFA_offset of $fp .uleb128 2*FFI_SIZEOF_ARG/4 # .byte 0x9f # DW_CFA_offset of ra .uleb128 1*FFI_SIZEOF_ARG/4 # .byte 0x4 # DW_CFA_advance_loc4 .4byte .LCFI3-.LCFI1 # to .LCFI3 .byte 0xd # DW_CFA_def_cfa_register .uleb128 0x1e # in $fp .align EH_FRAME_ALIGN .LEFDE1: .LSFDE3: .4byte .LEFDE3-.LASFDE3 # length .LASFDE3: .4byte .LASFDE3-.Lframe1 # CIE_pointer. FDE_ADDR_BYTES .LFB2 # initial_location. FDE_ADDR_BYTES .LFE2-.LFB2 # address_range. .byte 0x4 # DW_CFA_advance_loc4 .4byte .LCFI5-.LFB2 # to .LCFI5 .byte 0xe # DW_CFA_def_cfa_offset .uleb128 SIZEOF_FRAME2 # adjust stack.by SIZEOF_FRAME .byte 0x4 # DW_CFA_advance_loc4 .4byte .LCFI6-.LCFI5 # to .LCFI6 .byte 0x9c # DW_CFA_offset of $gp ($28) .uleb128 (SIZEOF_FRAME2 - GP_OFF2)/4 .byte 0x9f # DW_CFA_offset of ra ($31) .uleb128 (SIZEOF_FRAME2 - RA_OFF2)/4 .align EH_FRAME_ALIGN .LEFDE3: #endif