// Copyright 2017, VIXL authors // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are met: // // * Redistributions of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // * Neither the name of ARM Limited nor the names of its contributors may be // used to endorse or promote products derived from this software without // specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS CONTRIBUTORS "AS IS" AND // ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED // WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE // DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE // FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL // DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR // SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER // CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, // OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. #include "test-runner.h" #ifdef VIXL_INCLUDE_TARGET_AARCH32 #include "aarch32/macro-assembler-aarch32.h" #include "aarch32/test-utils-aarch32.h" #endif #ifdef VIXL_INCLUDE_TARGET_AARCH64 #include "aarch64/macro-assembler-aarch64.h" #endif #define TEST(name) TEST_(SCOPES_##name) #ifdef VIXL_INCLUDE_TARGET_A32 #define TEST_A32(name) TEST(name) #else // Do not add this test to the harness. #define TEST_A32(name) void Test##name() #endif #define __ masm. namespace vixl { // This file contains tests for code generation scopes. #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST(CodeBufferCheckScope_basic_32) { aarch32::MacroAssembler masm; { CodeBufferCheckScope scope(&masm, aarch32::kA32InstructionSizeInBytes); __ Mov(aarch32::r0, 0); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(CodeBufferCheckScope_basic_64) { aarch64::MacroAssembler masm; { CodeBufferCheckScope scope(&masm, aarch64::kInstructionSize); __ Mov(aarch64::x0, 0); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST(CodeBufferCheckScope_assembler_use_32) { aarch32::MacroAssembler masm; { CodeBufferCheckScope scope(&masm, 2 * aarch32::kA32InstructionSizeInBytes); __ Mov(aarch32::r0, 0); __ mov(aarch32::r1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(CodeBufferCheckScope_assembler_use_64) { aarch64::MacroAssembler masm; { CodeBufferCheckScope scope(&masm, 2 * aarch64::kInstructionSize); __ Mov(aarch64::x0, 0); __ movz(aarch64::x1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST(CodeBufferCheckScope_Open_32) { aarch32::MacroAssembler masm; { CodeBufferCheckScope scope; __ Mov(aarch32::r0, 0); scope.Open(&masm, aarch32::kA32InstructionSizeInBytes); __ Mov(aarch32::r1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(CodeBufferCheckScope_Open_64) { aarch64::MacroAssembler masm; { CodeBufferCheckScope scope; __ Mov(aarch64::x0, 0); scope.Open(&masm, aarch64::kInstructionSize); __ Mov(aarch64::x1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST(CodeBufferCheckScope_Close_32) { aarch32::MacroAssembler masm; { CodeBufferCheckScope scope(&masm, aarch32::kA32InstructionSizeInBytes); __ Mov(aarch32::r0, 0); scope.Close(); __ Mov(aarch32::r1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(CodeBufferCheckScope_Close_64) { aarch64::MacroAssembler masm; { CodeBufferCheckScope scope(&masm, aarch64::kInstructionSize); __ Mov(aarch64::x0, 0); scope.Close(); __ Mov(aarch64::x1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST(CodeBufferCheckScope_Open_Close_32) { aarch32::MacroAssembler masm; { CodeBufferCheckScope scope; __ Mov(aarch32::r0, 0); scope.Open(&masm, aarch32::kA32InstructionSizeInBytes); __ Mov(aarch32::r1, 1); scope.Close(); __ Mov(aarch32::r2, 2); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(CodeBufferCheckScope_Open_Close_64) { aarch64::MacroAssembler masm; { CodeBufferCheckScope scope; __ Mov(aarch64::x0, 0); scope.Open(&masm, aarch64::kInstructionSize); __ Mov(aarch64::x1, 1); scope.Close(); __ Mov(aarch64::x2, 2); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST(EmissionCheckScope_basic_32) { aarch32::MacroAssembler masm; { EmissionCheckScope scope(&masm, aarch32::kA32InstructionSizeInBytes); __ Mov(aarch32::r0, 0); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(EmissionCheckScope_basic_64) { aarch64::MacroAssembler masm; { EmissionCheckScope scope(&masm, aarch64::kInstructionSize); __ Mov(aarch64::x0, 0); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST(EmissionCheckScope_Open_32) { aarch32::MacroAssembler masm; { EmissionCheckScope scope; __ Mov(aarch32::r0, 0); scope.Open(&masm, aarch32::kA32InstructionSizeInBytes); __ Mov(aarch32::r1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(EmissionCheckScope_Open_64) { aarch64::MacroAssembler masm; { EmissionCheckScope scope; __ Mov(aarch64::x0, 0); scope.Open(&masm, aarch64::kInstructionSize); __ Mov(aarch64::x1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST(EmissionCheckScope_Close_32) { aarch32::MacroAssembler masm; { EmissionCheckScope scope(&masm, aarch32::kA32InstructionSizeInBytes); __ Mov(aarch32::r0, 0); scope.Close(); __ Mov(aarch32::r1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(EmissionCheckScope_Close_64) { aarch64::MacroAssembler masm; { EmissionCheckScope scope(&masm, aarch64::kInstructionSize); __ Mov(aarch64::x0, 0); scope.Close(); __ Mov(aarch64::x1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST(EmissionCheckScope_Open_Close_32) { aarch32::MacroAssembler masm; { EmissionCheckScope scope; __ Mov(aarch32::r0, 0); scope.Open(&masm, aarch32::kA32InstructionSizeInBytes); __ Mov(aarch32::r1, 1); scope.Close(); __ Mov(aarch32::r2, 2); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(EmissionCheckScope_Open_Close_64) { aarch64::MacroAssembler masm; { EmissionCheckScope scope; __ Mov(aarch64::x0, 0); scope.Open(&masm, aarch64::kInstructionSize); __ Mov(aarch64::x1, 1); scope.Close(); __ Mov(aarch64::x2, 2); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 #define ASSERT_LITERAL_POOL_SIZE_32(expected) \ { \ aarch32::TestMacroAssembler test(&masm); \ VIXL_CHECK((expected) == test.GetPoolSize()); \ } TEST_A32(EmissionCheckScope_emit_pool_32) { aarch32::MacroAssembler masm; // Make sure the pool is empty; masm.EmitLiteralPool(PoolManager<int32_t>::kBranchRequired); ASSERT_LITERAL_POOL_SIZE_32(0); __ Ldrd(aarch32::r0, aarch32::r1, 0x1234567890abcdef); ASSERT_LITERAL_POOL_SIZE_32(8); const int kLdrdRange = 255; const int kLessThanLdrdRange = 100; { // Check that opening the scope with a reserved space well below the limit // at which can generate the literal pool does not force the emission of // the pool. EmissionCheckScope scope(&masm, kLessThanLdrdRange, EmissionCheckScope::kMaximumSize); ASSERT_LITERAL_POOL_SIZE_32(8); } { // Check that the scope forces emission of the pool if necessary. EmissionCheckScope scope(&masm, kLdrdRange + 1, EmissionCheckScope::kMaximumSize); ASSERT_LITERAL_POOL_SIZE_32(0); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 #define ASSERT_LITERAL_POOL_SIZE_64(expected) \ VIXL_CHECK((expected + aarch64::kInstructionSize) == \ masm.GetLiteralPoolSize()) TEST(EmissionCheckScope_emit_pool_64) { aarch64::MacroAssembler masm; // Make sure the pool is empty; masm.EmitLiteralPool(aarch64::LiteralPool::kBranchRequired); ASSERT_LITERAL_POOL_SIZE_64(0); __ Ldr(aarch64::x0, 0x1234567890abcdef); ASSERT_LITERAL_POOL_SIZE_64(8); { // Check that opening the scope with a reserved space well below the limit // at which can generate the literal pool does not force the emission of // the pool. EmissionCheckScope scope(&masm, 10 * aarch64::kInstructionSize, EmissionCheckScope::kMaximumSize); ASSERT_LITERAL_POOL_SIZE_64(8); } { // Check that the scope forces emission of the pool if necessary. EmissionCheckScope scope(&masm, aarch64::kMaxLoadLiteralRange + 1, EmissionCheckScope::kMaximumSize); ASSERT_LITERAL_POOL_SIZE_64(0); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST_A32(EmissionCheckScope_emit_pool_on_Open_32) { aarch32::MacroAssembler masm; // Make sure the pool is empty; masm.EmitLiteralPool(PoolManager<int32_t>::kBranchRequired); ASSERT_LITERAL_POOL_SIZE_32(0); __ Ldrd(aarch32::r0, aarch32::r1, 0x1234567890abcdef); ASSERT_LITERAL_POOL_SIZE_32(8); const int kLdrdRange = 255; const int kLessThanLdrdRange = 100; { // Check that opening the scope with a reserved space well below the limit // at which can generate the literal pool does not force the emission of // the pool. EmissionCheckScope scope(&masm, kLessThanLdrdRange, EmissionCheckScope::kMaximumSize); ASSERT_LITERAL_POOL_SIZE_32(8); } { // Check that the scope forces emission of the pool if necessary. EmissionCheckScope scope(&masm, kLdrdRange + 1, EmissionCheckScope::kMaximumSize); ASSERT_LITERAL_POOL_SIZE_32(0); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(EmissionCheckScope_emit_pool_on_Open_64) { aarch64::MacroAssembler masm; // Make sure the pool is empty; masm.EmitLiteralPool(aarch64::LiteralPool::kBranchRequired); ASSERT_LITERAL_POOL_SIZE_64(0); __ Ldr(aarch64::x0, 0x1234567890abcdef); ASSERT_LITERAL_POOL_SIZE_64(8); { // Check that opening the scope with a reserved space well below the limit // at which can generate the literal pool does not force the emission of // the pool. EmissionCheckScope scope; scope.Open(&masm, 10 * aarch64::kInstructionSize, EmissionCheckScope::kMaximumSize); ASSERT_LITERAL_POOL_SIZE_64(8); } { // Check that the scope forces emission of the pool if necessary. EmissionCheckScope scope; scope.Open(&masm, aarch64::kMaxLoadLiteralRange + 1, EmissionCheckScope::kMaximumSize); ASSERT_LITERAL_POOL_SIZE_64(0); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST_A32(ExactAssemblyScope_basic_32) { aarch32::MacroAssembler masm; { ExactAssemblyScope scope(&masm, aarch32::kA32InstructionSizeInBytes); __ nop(); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(ExactAssemblyScope_basic_64) { aarch64::MacroAssembler masm; { ExactAssemblyScope scope(&masm, aarch64::kInstructionSize); __ nop(); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST_A32(ExactAssemblyScope_Open_32) { aarch32::MacroAssembler masm; { ExactAssemblyScope scope; __ Mov(aarch32::r0, 0); scope.Open(&masm, aarch32::kA32InstructionSizeInBytes); __ mov(aarch32::r1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(ExactAssemblyScope_Open_64) { aarch64::MacroAssembler masm; { ExactAssemblyScope scope; __ Mov(aarch64::x0, 0); scope.Open(&masm, aarch64::kInstructionSize); __ movz(aarch64::x1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST_A32(ExactAssemblyScope_Close_32) { aarch32::MacroAssembler masm; { ExactAssemblyScope scope(&masm, aarch32::kA32InstructionSizeInBytes); __ mov(aarch32::r0, 0); scope.Close(); __ Mov(aarch32::r1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(ExactAssemblyScope_Close_64) { aarch64::MacroAssembler masm; { ExactAssemblyScope scope(&masm, aarch64::kInstructionSize); __ movz(aarch64::x0, 0); scope.Close(); __ Mov(aarch64::x1, 1); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST_A32(ExactAssemblyScope_Open_Close_32) { aarch32::MacroAssembler masm; { ExactAssemblyScope scope; __ Mov(aarch32::r0, 0); scope.Open(&masm, aarch32::kA32InstructionSizeInBytes); __ mov(aarch32::r1, 1); scope.Close(); __ Mov(aarch32::r2, 2); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(ExactAssemblyScope_Open_Close_64) { aarch64::MacroAssembler masm; { ExactAssemblyScope scope; __ Mov(aarch64::x0, 0); scope.Open(&masm, aarch64::kInstructionSize); __ movz(aarch64::x1, 1); scope.Close(); __ Mov(aarch64::x2, 2); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST_A32(ExactAssemblyScope_32) { aarch32::MacroAssembler masm; // By default macro instructions are allowed. VIXL_CHECK(!masm.ArePoolsBlocked()); VIXL_ASSERT(!masm.AllowAssembler()); VIXL_ASSERT(masm.AllowMacroInstructions()); { ExactAssemblyScope scope1(&masm, 2 * aarch32::kA32InstructionSizeInBytes); VIXL_CHECK(masm.ArePoolsBlocked()); VIXL_ASSERT(masm.AllowAssembler()); VIXL_ASSERT(!masm.AllowMacroInstructions()); __ nop(); { ExactAssemblyScope scope2(&masm, 1 * aarch32::kA32InstructionSizeInBytes); VIXL_CHECK(masm.ArePoolsBlocked()); VIXL_ASSERT(masm.AllowAssembler()); VIXL_ASSERT(!masm.AllowMacroInstructions()); __ nop(); } VIXL_CHECK(masm.ArePoolsBlocked()); VIXL_ASSERT(masm.AllowAssembler()); VIXL_ASSERT(!masm.AllowMacroInstructions()); } VIXL_CHECK(!masm.ArePoolsBlocked()); VIXL_ASSERT(!masm.AllowAssembler()); VIXL_ASSERT(masm.AllowMacroInstructions()); { ExactAssemblyScope scope(&masm, 2 * aarch32::kA32InstructionSizeInBytes); __ add(aarch32::r0, aarch32::r0, aarch32::r0); __ sub(aarch32::r0, aarch32::r0, aarch32::r0); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(ExactAssemblyScope_64) { aarch64::MacroAssembler masm; // By default macro instructions are allowed. VIXL_CHECK(!masm.ArePoolsBlocked()); VIXL_ASSERT(!masm.AllowAssembler()); VIXL_ASSERT(masm.AllowMacroInstructions()); { ExactAssemblyScope scope1(&masm, 2 * aarch64::kInstructionSize); VIXL_CHECK(masm.ArePoolsBlocked()); VIXL_ASSERT(masm.AllowAssembler()); VIXL_ASSERT(!masm.AllowMacroInstructions()); __ nop(); { ExactAssemblyScope scope2(&masm, 1 * aarch64::kInstructionSize); VIXL_CHECK(masm.ArePoolsBlocked()); VIXL_ASSERT(masm.AllowAssembler()); VIXL_ASSERT(!masm.AllowMacroInstructions()); __ nop(); } VIXL_CHECK(masm.ArePoolsBlocked()); VIXL_ASSERT(masm.AllowAssembler()); VIXL_ASSERT(!masm.AllowMacroInstructions()); } VIXL_CHECK(!masm.ArePoolsBlocked()); VIXL_ASSERT(!masm.AllowAssembler()); VIXL_ASSERT(masm.AllowMacroInstructions()); { ExactAssemblyScope scope(&masm, 2 * aarch64::kInstructionSize); __ add(aarch64::x0, aarch64::x0, aarch64::x0); __ sub(aarch64::x0, aarch64::x0, aarch64::x0); } masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 #ifdef VIXL_INCLUDE_TARGET_AARCH32 TEST_A32(ExactAssemblyScope_scope_with_pools_32) { aarch32::MacroAssembler masm; ASSERT_LITERAL_POOL_SIZE_32(0); __ Ldrd(aarch32::r0, aarch32::r1, 0x1234567890abcdef); ASSERT_LITERAL_POOL_SIZE_32(8); const int32_t kLdrdRange = 255; const int32_t n_nops = (kLdrdRange / aarch32::kA32InstructionSizeInBytes) + 1; { // The literal pool should be generated when opening this scope, as // otherwise the `Ldrd` will run out of range when we generate the `nop` // instructions below. ExactAssemblyScope scope(&masm, n_nops * aarch32::kA32InstructionSizeInBytes); // Although it must be, we do not check that the literal pool size is zero // here, because we want this regression test to fail while or after we // generate the nops. for (int32_t i = 0; i < n_nops; ++i) { __ nop(); } } ASSERT_LITERAL_POOL_SIZE_32(0); masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH32 #ifdef VIXL_INCLUDE_TARGET_AARCH64 TEST(ExactAssemblyScope_scope_with_pools_64) { aarch64::MacroAssembler masm; ASSERT_LITERAL_POOL_SIZE_64(0); __ Ldr(aarch64::x10, 0x1234567890abcdef); ASSERT_LITERAL_POOL_SIZE_64(8); const int64_t n_nops = aarch64::kMaxLoadLiteralRange / aarch64::kInstructionSize; { // The literal pool should be generated when opening this scope, as // otherwise the `Ldr` will run out of range when we generate the `nop` // instructions below. ExactAssemblyScope scope(&masm, n_nops * aarch64::kInstructionSize); // Although it must be, we do not check that the literal pool size is zero // here, because we want this regression test to fail while or after we // generate the nops. for (int64_t i = 0; i < n_nops; ++i) { __ nop(); } } ASSERT_LITERAL_POOL_SIZE_64(0); masm.FinalizeCode(); } #endif // VIXL_INCLUDE_TARGET_AARCH64 } // namespace vixl