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v8/test/cctest/test-macro-assembler-mips64.cc
dusan.simicic d735f3ab12 MIPS: Fix trampoline emission after switch table generation 
Trampolines are generated when the value of pc_offset is greater than
next_buffer_check_ (attribute from Assembler class). This value
shouldn't be incremented in bind_to() method when internal reference
label is bound, because it is not decremented when the switch table is
generated (dd() method from Assemler class).

This patch fixes this problem. Regression test are also included for
mips and mips64 arch.

BUG=

Review-Url: https://codereview.chromium.org/2530143002
Cr-Commit-Position: refs/heads/master@{#41423}
2016-12-01 13:03:19 +00:00

1962 lines
70 KiB
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// Copyright 2013 the V8 project 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 Google Inc. 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 AND 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 <stdlib.h>
#include <iostream> // NOLINT(readability/streams)
#include "src/v8.h"
#include "test/cctest/cctest.h"
#include "src/base/utils/random-number-generator.h"
#include "src/macro-assembler.h"
#include "src/mips64/macro-assembler-mips64.h"
#include "src/mips64/simulator-mips64.h"
using namespace v8::internal;
typedef void* (*F)(int64_t x, int64_t y, int p2, int p3, int p4);
typedef Object* (*F1)(int x, int p1, int p2, int p3, int p4);
typedef Object* (*F3)(void* p, int p1, int p2, int p3, int p4);
#define __ masm->
TEST(BYTESWAP) {
DCHECK(kArchVariant == kMips64r6 || kArchVariant == kMips64r2);
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
struct T {
int64_t r1;
int64_t r2;
int64_t r3;
int64_t r4;
int64_t r5;
int64_t r6;
int64_t r7;
};
T t;
MacroAssembler assembler(isolate, NULL, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assembler;
__ ld(a4, MemOperand(a0, offsetof(T, r1)));
__ nop();
__ ByteSwapSigned(a4, a4, 8);
__ sd(a4, MemOperand(a0, offsetof(T, r1)));
__ ld(a4, MemOperand(a0, offsetof(T, r2)));
__ nop();
__ ByteSwapSigned(a4, a4, 4);
__ sd(a4, MemOperand(a0, offsetof(T, r2)));
__ ld(a4, MemOperand(a0, offsetof(T, r3)));
__ nop();
__ ByteSwapSigned(a4, a4, 2);
__ sd(a4, MemOperand(a0, offsetof(T, r3)));
__ ld(a4, MemOperand(a0, offsetof(T, r4)));
__ nop();
__ ByteSwapSigned(a4, a4, 1);
__ sd(a4, MemOperand(a0, offsetof(T, r4)));
__ ld(a4, MemOperand(a0, offsetof(T, r5)));
__ nop();
__ ByteSwapUnsigned(a4, a4, 1);
__ sd(a4, MemOperand(a0, offsetof(T, r5)));
__ ld(a4, MemOperand(a0, offsetof(T, r6)));
__ nop();
__ ByteSwapUnsigned(a4, a4, 2);
__ sd(a4, MemOperand(a0, offsetof(T, r6)));
__ ld(a4, MemOperand(a0, offsetof(T, r7)));
__ nop();
__ ByteSwapUnsigned(a4, a4, 4);
__ sd(a4, MemOperand(a0, offsetof(T, r7)));
__ jr(ra);
__ nop();
CodeDesc desc;
masm->GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
::F3 f = FUNCTION_CAST<::F3>(code->entry());
t.r1 = 0x5612FFCD9D327ACC;
t.r2 = 0x781A15C3;
t.r3 = 0xFCDE;
t.r4 = 0x9F;
t.r5 = 0x9F;
t.r6 = 0xFCDE;
t.r7 = 0xC81A15C3;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
CHECK_EQ(static_cast<int64_t>(0xCC7A329DCDFF1256), t.r1);
CHECK_EQ(static_cast<int64_t>(0xC3151A7800000000), t.r2);
CHECK_EQ(static_cast<int64_t>(0xDEFCFFFFFFFFFFFF), t.r3);
CHECK_EQ(static_cast<int64_t>(0x9FFFFFFFFFFFFFFF), t.r4);
CHECK_EQ(static_cast<int64_t>(0x9F00000000000000), t.r5);
CHECK_EQ(static_cast<int64_t>(0xDEFC000000000000), t.r6);
CHECK_EQ(static_cast<int64_t>(0xC3151AC800000000), t.r7);
}
TEST(LoadConstants) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope handles(isolate);
int64_t refConstants[64];
int64_t result[64];
int64_t mask = 1;
for (int i = 0; i < 64; i++) {
refConstants[i] = ~(mask << i);
}
MacroAssembler assembler(isolate, NULL, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assembler;
__ mov(a4, a0);
for (int i = 0; i < 64; i++) {
// Load constant.
__ li(a5, Operand(refConstants[i]));
__ sd(a5, MemOperand(a4));
__ Daddu(a4, a4, Operand(kPointerSize));
}
__ jr(ra);
__ nop();
CodeDesc desc;
masm->GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
::F f = FUNCTION_CAST< ::F>(code->entry());
(void)CALL_GENERATED_CODE(isolate, f, reinterpret_cast<int64_t>(result), 0, 0,
0, 0);
// Check results.
for (int i = 0; i < 64; i++) {
CHECK(refConstants[i] == result[i]);
}
}
TEST(LoadAddress) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope handles(isolate);
MacroAssembler assembler(isolate, NULL, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assembler;
Label to_jump, skip;
__ mov(a4, a0);
__ Branch(&skip);
__ bind(&to_jump);
__ nop();
__ nop();
__ jr(ra);
__ nop();
__ bind(&skip);
__ li(a4, Operand(masm->jump_address(&to_jump)), ADDRESS_LOAD);
int check_size = masm->InstructionsGeneratedSince(&skip);
CHECK_EQ(check_size, 4);
__ jr(a4);
__ nop();
__ stop("invalid");
__ stop("invalid");
__ stop("invalid");
__ stop("invalid");
__ stop("invalid");
CodeDesc desc;
masm->GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
::F f = FUNCTION_CAST< ::F>(code->entry());
(void)CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0);
// Check results.
}
TEST(jump_tables4) {
// Similar to test-assembler-mips jump_tables1, with extra test for branch
// trampoline required before emission of the dd table (where trampolines are
// blocked), and proper transition to long-branch mode.
// Regression test for v8:4294.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assembler(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assembler;
const int kNumCases = 512;
int values[kNumCases];
isolate->random_number_generator()->NextBytes(values, sizeof(values));
Label labels[kNumCases];
Label near_start, end, done;
__ Push(ra);
__ mov(v0, zero_reg);
__ Branch(&end);
__ bind(&near_start);
// Generate slightly less than 32K instructions, which will soon require
// trampoline for branch distance fixup.
for (int i = 0; i < 32768 - 256; ++i) {
__ addiu(v0, v0, 1);
}
__ GenerateSwitchTable(a0, kNumCases,
[&labels](size_t i) { return labels + i; });
for (int i = 0; i < kNumCases; ++i) {
__ bind(&labels[i]);
__ li(v0, values[i]);
__ Branch(&done);
}
__ bind(&done);
__ Pop(ra);
__ jr(ra);
__ nop();
__ bind(&end);
__ Branch(&near_start);
CodeDesc desc;
masm->GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F1 f = FUNCTION_CAST<F1>(code->entry());
for (int i = 0; i < kNumCases; ++i) {
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, i, 0, 0, 0, 0));
::printf("f(%d) = %" PRId64 "\n", i, res);
CHECK_EQ(values[i], res);
}
}
TEST(jump_tables5) {
if (kArchVariant != kMips64r6) return;
// Similar to test-assembler-mips jump_tables1, with extra test for emitting a
// compact branch instruction before emission of the dd table.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assembler(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assembler;
const int kNumCases = 512;
int values[kNumCases];
isolate->random_number_generator()->NextBytes(values, sizeof(values));
Label labels[kNumCases];
Label done;
__ Push(ra);
// Opposite of Align(8) as we have unaligned number of instructions in the
// following block before the first dd().
if ((masm->pc_offset() & 7) == 0) {
__ nop();
}
{
__ BlockTrampolinePoolFor(kNumCases * 2 + 6 + 1);
PredictableCodeSizeScope predictable(
masm, kNumCases * kPointerSize + ((6 + 1) * Assembler::kInstrSize));
__ addiupc(at, 6 + 1);
__ Dlsa(at, at, a0, 3);
__ ld(at, MemOperand(at));
__ jalr(at);
__ nop(); // Branch delay slot nop.
__ bc(&done);
// A nop instruction must be generated by the forbidden slot guard
// (Assembler::dd(Label*)) so the first label goes to an 8 bytes aligned
// location.
for (int i = 0; i < kNumCases; ++i) {
__ dd(&labels[i]);
}
}
for (int i = 0; i < kNumCases; ++i) {
__ bind(&labels[i]);
__ li(v0, values[i]);
__ jr(ra);
__ nop();
}
__ bind(&done);
__ Pop(ra);
__ jr(ra);
__ nop();
CodeDesc desc;
masm->GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F1 f = FUNCTION_CAST<F1>(code->entry());
for (int i = 0; i < kNumCases; ++i) {
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, i, 0, 0, 0, 0));
::printf("f(%d) = %" PRId64 "\n", i, res);
CHECK_EQ(values[i], res);
}
}
TEST(jump_tables6) {
// Similar to test-assembler-mips jump_tables1, with extra test for branch
// trampoline required after emission of the dd table (where trampolines are
// blocked). This test checks if number of really generated instructions is
// greater than number of counted instructions from code, as we are expecting
// generation of trampoline in this case (when number of kFillInstr
// instructions is close to 32K)
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assembler(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assembler;
const int kNumCases = 40;
const int kFillInstr = 32551;
const int kMaxBranchOffset = (1 << (18 - 1)) - 1;
const int kTrampolineSlotsSize = 2 * Instruction::kInstrSize;
const int kMaxOffsetForTrampolineStart =
kMaxBranchOffset - 16 * kTrampolineSlotsSize;
int values[kNumCases];
isolate->random_number_generator()->NextBytes(values, sizeof(values));
Label labels[kNumCases];
Label near_start, end, done;
__ Push(ra);
__ mov(v0, zero_reg);
int offs1 = masm->pc_offset();
int gen_insn = 0;
__ Branch(&end);
gen_insn += 2;
__ bind(&near_start);
// Generate slightly less than 32K instructions, which will soon require
// trampoline for branch distance fixup.
for (int i = 0; i < kFillInstr; ++i) {
__ addiu(v0, v0, 1);
}
gen_insn += kFillInstr;
__ GenerateSwitchTable(a0, kNumCases,
[&labels](size_t i) { return labels + i; });
gen_insn += (11 + 2 * kNumCases);
for (int i = 0; i < kNumCases; ++i) {
__ bind(&labels[i]);
__ li(v0, values[i]);
__ Branch(&done);
}
gen_insn += (4 * kNumCases);
// If offset from here to first branch instr is greater than max allowed
// offset for trampoline ...
CHECK_LT(kMaxOffsetForTrampolineStart, masm->pc_offset() - offs1);
// ... number of generated instructions must be greater then "gen_insn",
// as we are expecting trampoline generation
CHECK_LT(gen_insn, (masm->pc_offset() - offs1) / Instruction::kInstrSize);
__ bind(&done);
__ Pop(ra);
__ jr(ra);
__ nop();
__ bind(&end);
__ Branch(&near_start);
CodeDesc desc;
masm->GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F1 f = FUNCTION_CAST<F1>(code->entry());
for (int i = 0; i < kNumCases; ++i) {
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, i, 0, 0, 0, 0));
::printf("f(%d) = %" PRId64 "\n", i, res);
CHECK_EQ(values[i], res);
}
}
static uint64_t run_lsa(uint32_t rt, uint32_t rs, int8_t sa) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assembler(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assembler;
__ Lsa(v0, a0, a1, sa);
__ jr(ra);
__ nop();
CodeDesc desc;
assembler.GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
F1 f = FUNCTION_CAST<F1>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, rt, rs, 0, 0, 0));
return res;
}
TEST(Lsa) {
CcTest::InitializeVM();
struct TestCaseLsa {
int32_t rt;
int32_t rs;
uint8_t sa;
uint64_t expected_res;
};
struct TestCaseLsa tc[] = {// rt, rs, sa, expected_res
{0x4, 0x1, 1, 0x6},
{0x4, 0x1, 2, 0x8},
{0x4, 0x1, 3, 0xc},
{0x4, 0x1, 4, 0x14},
{0x4, 0x1, 5, 0x24},
{0x0, 0x1, 1, 0x2},
{0x0, 0x1, 2, 0x4},
{0x0, 0x1, 3, 0x8},
{0x0, 0x1, 4, 0x10},
{0x0, 0x1, 5, 0x20},
{0x4, 0x0, 1, 0x4},
{0x4, 0x0, 2, 0x4},
{0x4, 0x0, 3, 0x4},
{0x4, 0x0, 4, 0x4},
{0x4, 0x0, 5, 0x4},
// Shift overflow.
{0x4, INT32_MAX, 1, 0x2},
{0x4, INT32_MAX >> 1, 2, 0x0},
{0x4, INT32_MAX >> 2, 3, 0xfffffffffffffffc},
{0x4, INT32_MAX >> 3, 4, 0xfffffffffffffff4},
{0x4, INT32_MAX >> 4, 5, 0xffffffffffffffe4},
// Signed addition overflow.
{INT32_MAX - 1, 0x1, 1, 0xffffffff80000000},
{INT32_MAX - 3, 0x1, 2, 0xffffffff80000000},
{INT32_MAX - 7, 0x1, 3, 0xffffffff80000000},
{INT32_MAX - 15, 0x1, 4, 0xffffffff80000000},
{INT32_MAX - 31, 0x1, 5, 0xffffffff80000000},
// Addition overflow.
{-2, 0x1, 1, 0x0},
{-4, 0x1, 2, 0x0},
{-8, 0x1, 3, 0x0},
{-16, 0x1, 4, 0x0},
{-32, 0x1, 5, 0x0}};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseLsa);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_lsa(tc[i].rt, tc[i].rs, tc[i].sa);
PrintF("0x%" PRIx64 " =? 0x%" PRIx64 " == Lsa(v0, %x, %x, %hhu)\n",
tc[i].expected_res, res, tc[i].rt, tc[i].rs, tc[i].sa);
CHECK_EQ(tc[i].expected_res, res);
}
}
static uint64_t run_dlsa(uint64_t rt, uint64_t rs, int8_t sa) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assembler(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assembler;
__ Dlsa(v0, a0, a1, sa);
__ jr(ra);
__ nop();
CodeDesc desc;
assembler.GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
::F f = FUNCTION_CAST<::F>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, rt, rs, 0, 0, 0));
return res;
}
TEST(Dlsa) {
CcTest::InitializeVM();
struct TestCaseLsa {
int64_t rt;
int64_t rs;
uint8_t sa;
uint64_t expected_res;
};
struct TestCaseLsa tc[] = {// rt, rs, sa, expected_res
{0x4, 0x1, 1, 0x6},
{0x4, 0x1, 2, 0x8},
{0x4, 0x1, 3, 0xc},
{0x4, 0x1, 4, 0x14},
{0x4, 0x1, 5, 0x24},
{0x0, 0x1, 1, 0x2},
{0x0, 0x1, 2, 0x4},
{0x0, 0x1, 3, 0x8},
{0x0, 0x1, 4, 0x10},
{0x0, 0x1, 5, 0x20},
{0x4, 0x0, 1, 0x4},
{0x4, 0x0, 2, 0x4},
{0x4, 0x0, 3, 0x4},
{0x4, 0x0, 4, 0x4},
{0x4, 0x0, 5, 0x4},
// Shift overflow.
{0x4, INT64_MAX, 1, 0x2},
{0x4, INT64_MAX >> 1, 2, 0x0},
{0x4, INT64_MAX >> 2, 3, 0xfffffffffffffffc},
{0x4, INT64_MAX >> 3, 4, 0xfffffffffffffff4},
{0x4, INT64_MAX >> 4, 5, 0xffffffffffffffe4},
// Signed addition overflow.
{INT64_MAX - 1, 0x1, 1, 0x8000000000000000},
{INT64_MAX - 3, 0x1, 2, 0x8000000000000000},
{INT64_MAX - 7, 0x1, 3, 0x8000000000000000},
{INT64_MAX - 15, 0x1, 4, 0x8000000000000000},
{INT64_MAX - 31, 0x1, 5, 0x8000000000000000},
// Addition overflow.
{-2, 0x1, 1, 0x0},
{-4, 0x1, 2, 0x0},
{-8, 0x1, 3, 0x0},
{-16, 0x1, 4, 0x0},
{-32, 0x1, 5, 0x0}};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseLsa);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_dlsa(tc[i].rt, tc[i].rs, tc[i].sa);
PrintF("0x%" PRIx64 " =? 0x%" PRIx64 " == Dlsa(v0, %" PRIx64 ", %" PRIx64
", %hhu)\n",
tc[i].expected_res, res, tc[i].rt, tc[i].rs, tc[i].sa);
CHECK_EQ(tc[i].expected_res, res);
}
}
static const std::vector<uint32_t> cvt_trunc_uint32_test_values() {
static const uint32_t kValues[] = {0x00000000, 0x00000001, 0x00ffff00,
0x7fffffff, 0x80000000, 0x80000001,
0x80ffff00, 0x8fffffff, 0xffffffff};
return std::vector<uint32_t>(&kValues[0], &kValues[arraysize(kValues)]);
}
static const std::vector<int32_t> cvt_trunc_int32_test_values() {
static const int32_t kValues[] = {
static_cast<int32_t>(0x00000000), static_cast<int32_t>(0x00000001),
static_cast<int32_t>(0x00ffff00), static_cast<int32_t>(0x7fffffff),
static_cast<int32_t>(0x80000000), static_cast<int32_t>(0x80000001),
static_cast<int32_t>(0x80ffff00), static_cast<int32_t>(0x8fffffff),
static_cast<int32_t>(0xffffffff)};
return std::vector<int32_t>(&kValues[0], &kValues[arraysize(kValues)]);
}
static const std::vector<uint64_t> cvt_trunc_uint64_test_values() {
static const uint64_t kValues[] = {
0x0000000000000000, 0x0000000000000001, 0x0000ffffffff0000,
0x7fffffffffffffff, 0x8000000000000000, 0x8000000000000001,
0x8000ffffffff0000, 0x8fffffffffffffff, 0xffffffffffffffff};
return std::vector<uint64_t>(&kValues[0], &kValues[arraysize(kValues)]);
}
static const std::vector<int64_t> cvt_trunc_int64_test_values() {
static const int64_t kValues[] = {static_cast<int64_t>(0x0000000000000000),
static_cast<int64_t>(0x0000000000000001),
static_cast<int64_t>(0x0000ffffffff0000),
static_cast<int64_t>(0x7fffffffffffffff),
static_cast<int64_t>(0x8000000000000000),
static_cast<int64_t>(0x8000000000000001),
static_cast<int64_t>(0x8000ffffffff0000),
static_cast<int64_t>(0x8fffffffffffffff),
static_cast<int64_t>(0xffffffffffffffff)};
return std::vector<int64_t>(&kValues[0], &kValues[arraysize(kValues)]);
}
// Helper macros that can be used in FOR_INT32_INPUTS(i) { ... *i ... }
#define FOR_INPUTS(ctype, itype, var, test_vector) \
std::vector<ctype> var##_vec = test_vector(); \
for (std::vector<ctype>::iterator var = var##_vec.begin(); \
var != var##_vec.end(); ++var)
#define FOR_INPUTS2(ctype, itype, var, var2, test_vector) \
std::vector<ctype> var##_vec = test_vector(); \
std::vector<ctype>::iterator var; \
std::vector<ctype>::reverse_iterator var2; \
for (var = var##_vec.begin(), var2 = var##_vec.rbegin(); \
var != var##_vec.end(); ++var, ++var2)
#define FOR_ENUM_INPUTS(var, type, test_vector) \
FOR_INPUTS(enum type, type, var, test_vector)
#define FOR_STRUCT_INPUTS(var, type, test_vector) \
FOR_INPUTS(struct type, type, var, test_vector)
#define FOR_INT32_INPUTS(var, test_vector) \
FOR_INPUTS(int32_t, int32, var, test_vector)
#define FOR_INT32_INPUTS2(var, var2, test_vector) \
FOR_INPUTS2(int32_t, int32, var, var2, test_vector)
#define FOR_INT64_INPUTS(var, test_vector) \
FOR_INPUTS(int64_t, int64, var, test_vector)
#define FOR_UINT32_INPUTS(var, test_vector) \
FOR_INPUTS(uint32_t, uint32, var, test_vector)
#define FOR_UINT64_INPUTS(var, test_vector) \
FOR_INPUTS(uint64_t, uint64, var, test_vector)
template <typename RET_TYPE, typename IN_TYPE, typename Func>
RET_TYPE run_Cvt(IN_TYPE x, Func GenerateConvertInstructionFunc) {
typedef RET_TYPE (*F_CVT)(IN_TYPE x0, int x1, int x2, int x3, int x4);
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assm;
GenerateConvertInstructionFunc(masm);
__ dmfc1(v0, f2);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
F_CVT f = FUNCTION_CAST<F_CVT>(code->entry());
return reinterpret_cast<RET_TYPE>(
CALL_GENERATED_CODE(isolate, f, x, 0, 0, 0, 0));
}
TEST(Cvt_s_uw_Trunc_uw_s) {
CcTest::InitializeVM();
FOR_UINT32_INPUTS(i, cvt_trunc_uint32_test_values) {
uint32_t input = *i;
CHECK_EQ(static_cast<float>(input),
run_Cvt<uint64_t>(input, [](MacroAssembler* masm) {
__ Cvt_s_uw(f0, a0);
__ mthc1(zero_reg, f2);
__ Trunc_uw_s(f2, f0, f1);
}));
}
}
TEST(Cvt_s_ul_Trunc_ul_s) {
CcTest::InitializeVM();
FOR_UINT64_INPUTS(i, cvt_trunc_uint64_test_values) {
uint64_t input = *i;
CHECK_EQ(static_cast<float>(input),
run_Cvt<uint64_t>(input, [](MacroAssembler* masm) {
__ Cvt_s_ul(f0, a0);
__ Trunc_ul_s(f2, f0, f1, v0);
}));
}
}
TEST(Cvt_d_ul_Trunc_ul_d) {
CcTest::InitializeVM();
FOR_UINT64_INPUTS(i, cvt_trunc_uint64_test_values) {
uint64_t input = *i;
CHECK_EQ(static_cast<double>(input),
run_Cvt<uint64_t>(input, [](MacroAssembler* masm) {
__ Cvt_d_ul(f0, a0);
__ Trunc_ul_d(f2, f0, f1, v0);
}));
}
}
TEST(cvt_d_l_Trunc_l_d) {
CcTest::InitializeVM();
FOR_INT64_INPUTS(i, cvt_trunc_int64_test_values) {
int64_t input = *i;
CHECK_EQ(static_cast<double>(input),
run_Cvt<int64_t>(input, [](MacroAssembler* masm) {
__ dmtc1(a0, f4);
__ cvt_d_l(f0, f4);
__ Trunc_l_d(f2, f0);
}));
}
}
TEST(cvt_d_l_Trunc_l_ud) {
CcTest::InitializeVM();
FOR_INT64_INPUTS(i, cvt_trunc_int64_test_values) {
int64_t input = *i;
uint64_t abs_input = (input < 0) ? -input : input;
CHECK_EQ(static_cast<double>(abs_input),
run_Cvt<uint64_t>(input, [](MacroAssembler* masm) {
__ dmtc1(a0, f4);
__ cvt_d_l(f0, f4);
__ Trunc_l_ud(f2, f0, f6);
}));
}
}
TEST(cvt_d_w_Trunc_w_d) {
CcTest::InitializeVM();
FOR_INT32_INPUTS(i, cvt_trunc_int32_test_values) {
int32_t input = *i;
CHECK_EQ(static_cast<double>(input),
run_Cvt<int64_t>(input, [](MacroAssembler* masm) {
__ mtc1(a0, f4);
__ cvt_d_w(f0, f4);
__ Trunc_w_d(f2, f0);
__ mfc1(v1, f2);
__ dmtc1(v1, f2);
}));
}
}
static const std::vector<int32_t> overflow_int32_test_values() {
static const int32_t kValues[] = {
static_cast<int32_t>(0xf0000000), static_cast<int32_t>(0x00000001),
static_cast<int32_t>(0xff000000), static_cast<int32_t>(0x0000f000),
static_cast<int32_t>(0x0f000000), static_cast<int32_t>(0x991234ab),
static_cast<int32_t>(0xb0ffff01), static_cast<int32_t>(0x00006fff),
static_cast<int32_t>(0xffffffff)};
return std::vector<int32_t>(&kValues[0], &kValues[arraysize(kValues)]);
}
static const std::vector<int64_t> overflow_int64_test_values() {
static const int64_t kValues[] = {static_cast<int64_t>(0xf000000000000000),
static_cast<int64_t>(0x0000000000000001),
static_cast<int64_t>(0xff00000000000000),
static_cast<int64_t>(0x0000f00111111110),
static_cast<int64_t>(0x0f00001000000000),
static_cast<int64_t>(0x991234ab12a96731),
static_cast<int64_t>(0xb0ffff0f0f0f0f01),
static_cast<int64_t>(0x00006fffffffffff),
static_cast<int64_t>(0xffffffffffffffff)};
return std::vector<int64_t>(&kValues[0], &kValues[arraysize(kValues)]);
}
enum OverflowBranchType {
kAddBranchOverflow,
kSubBranchOverflow,
};
struct OverflowRegisterCombination {
Register dst;
Register left;
Register right;
Register scratch;
};
static const std::vector<enum OverflowBranchType> overflow_branch_type() {
static const enum OverflowBranchType kValues[] = {kAddBranchOverflow,
kSubBranchOverflow};
return std::vector<enum OverflowBranchType>(&kValues[0],
&kValues[arraysize(kValues)]);
}
static const std::vector<struct OverflowRegisterCombination>
overflow_register_combination() {
static const struct OverflowRegisterCombination kValues[] = {
{t0, t1, t2, t3}, {t0, t0, t2, t3}, {t0, t1, t0, t3}, {t0, t1, t1, t3}};
return std::vector<struct OverflowRegisterCombination>(
&kValues[0], &kValues[arraysize(kValues)]);
}
template <typename T>
static bool IsAddOverflow(T x, T y) {
DCHECK(std::numeric_limits<T>::is_integer);
T max = std::numeric_limits<T>::max();
T min = std::numeric_limits<T>::min();
return (x > 0 && y > (max - x)) || (x < 0 && y < (min - x));
}
template <typename T>
static bool IsSubOverflow(T x, T y) {
DCHECK(std::numeric_limits<T>::is_integer);
T max = std::numeric_limits<T>::max();
T min = std::numeric_limits<T>::min();
return (y > 0 && x < (min + y)) || (y < 0 && x > (max + y));
}
template <typename IN_TYPE, typename Func>
static bool runOverflow(IN_TYPE valLeft, IN_TYPE valRight,
Func GenerateOverflowInstructions) {
typedef int64_t (*F_CVT)(char* x0, int x1, int x2, int x3, int x4);
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assm;
GenerateOverflowInstructions(masm, valLeft, valRight);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
F_CVT f = FUNCTION_CAST<F_CVT>(code->entry());
int64_t r =
reinterpret_cast<int64_t>(CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
DCHECK(r == 0 || r == 1);
return r;
}
TEST(BranchOverflowInt32BothLabelsTrampoline) {
if (kArchVariant != kMips64r6) return;
static const int kMaxBranchOffset = (1 << (18 - 1)) - 1;
FOR_INT32_INPUTS(i, overflow_int32_test_values) {
FOR_INT32_INPUTS(j, overflow_int32_test_values) {
FOR_ENUM_INPUTS(br, OverflowBranchType, overflow_branch_type) {
FOR_STRUCT_INPUTS(regComb, OverflowRegisterCombination,
overflow_register_combination) {
int32_t ii = *i;
int32_t jj = *j;
enum OverflowBranchType branchType = *br;
struct OverflowRegisterCombination rc = *regComb;
// If left and right register are same then left and right
// test values must also be same, otherwise we skip the test
if (rc.left.code() == rc.right.code()) {
if (ii != jj) {
continue;
}
}
bool res1 = runOverflow<int32_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int32_t valLeft,
int32_t valRight) {
Label overflow, no_overflow, end;
__ li(rc.left, valLeft);
__ li(rc.right, valRight);
switch (branchType) {
case kAddBranchOverflow:
__ AddBranchOvf(rc.dst, rc.left, rc.right, &overflow,
&no_overflow, rc.scratch);
break;
case kSubBranchOverflow:
__ SubBranchOvf(rc.dst, rc.left, rc.right, &overflow,
&no_overflow, rc.scratch);
break;
}
Label done;
size_t nr_calls =
kMaxBranchOffset / (2 * Instruction::kInstrSize) + 2;
for (size_t i = 0; i < nr_calls; ++i) {
__ BranchShort(&done, eq, a0, Operand(a1));
}
__ bind(&done);
__ li(v0, 2);
__ Branch(&end);
__ bind(&overflow);
__ li(v0, 1);
__ Branch(&end);
__ bind(&no_overflow);
__ li(v0, 0);
__ bind(&end);
});
switch (branchType) {
case kAddBranchOverflow:
CHECK_EQ(IsAddOverflow<int32_t>(ii, jj), res1);
break;
case kSubBranchOverflow:
CHECK_EQ(IsSubOverflow<int32_t>(ii, jj), res1);
break;
default:
UNREACHABLE();
}
}
}
}
}
}
TEST(BranchOverflowInt32BothLabels) {
FOR_INT32_INPUTS(i, overflow_int32_test_values) {
FOR_INT32_INPUTS(j, overflow_int32_test_values) {
FOR_ENUM_INPUTS(br, OverflowBranchType, overflow_branch_type) {
FOR_STRUCT_INPUTS(regComb, OverflowRegisterCombination,
overflow_register_combination) {
int32_t ii = *i;
int32_t jj = *j;
enum OverflowBranchType branchType = *br;
struct OverflowRegisterCombination rc = *regComb;
// If left and right register are same then left and right
// test values must also be same, otherwise we skip the test
if (rc.left.code() == rc.right.code()) {
if (ii != jj) {
continue;
}
}
bool res1 = runOverflow<int32_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int32_t valLeft,
int32_t valRight) {
Label overflow, no_overflow, end;
__ li(rc.left, valLeft);
__ li(rc.right, valRight);
switch (branchType) {
case kAddBranchOverflow:
__ AddBranchOvf(rc.dst, rc.left, rc.right, &overflow,
&no_overflow, rc.scratch);
break;
case kSubBranchOverflow:
__ SubBranchOvf(rc.dst, rc.left, rc.right, &overflow,
&no_overflow, rc.scratch);
break;
}
__ li(v0, 2);
__ Branch(&end);
__ bind(&overflow);
__ li(v0, 1);
__ Branch(&end);
__ bind(&no_overflow);
__ li(v0, 0);
__ bind(&end);
});
bool res2 = runOverflow<int32_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int32_t valLeft,
int32_t valRight) {
Label overflow, no_overflow, end;
__ li(rc.left, valLeft);
switch (branchType) {
case kAddBranchOverflow:
__ AddBranchOvf(rc.dst, rc.left, Operand(valRight),
&overflow, &no_overflow, rc.scratch);
break;
case kSubBranchOverflow:
__ SubBranchOvf(rc.dst, rc.left, Operand(valRight),
&overflow, &no_overflow, rc.scratch);
break;
}
__ li(v0, 2);
__ Branch(&end);
__ bind(&overflow);
__ li(v0, 1);
__ Branch(&end);
__ bind(&no_overflow);
__ li(v0, 0);
__ bind(&end);
});
switch (branchType) {
case kAddBranchOverflow:
CHECK_EQ(IsAddOverflow<int32_t>(ii, jj), res1);
CHECK_EQ(IsAddOverflow<int32_t>(ii, jj), res2);
break;
case kSubBranchOverflow:
CHECK_EQ(IsSubOverflow<int32_t>(ii, jj), res1);
CHECK_EQ(IsSubOverflow<int32_t>(ii, jj), res2);
break;
default:
UNREACHABLE();
}
}
}
}
}
}
TEST(BranchOverflowInt32LeftLabel) {
FOR_INT32_INPUTS(i, overflow_int32_test_values) {
FOR_INT32_INPUTS(j, overflow_int32_test_values) {
FOR_ENUM_INPUTS(br, OverflowBranchType, overflow_branch_type) {
FOR_STRUCT_INPUTS(regComb, OverflowRegisterCombination,
overflow_register_combination) {
int32_t ii = *i;
int32_t jj = *j;
enum OverflowBranchType branchType = *br;
struct OverflowRegisterCombination rc = *regComb;
// If left and right register are same then left and right
// test values must also be same, otherwise we skip the test
if (rc.left.code() == rc.right.code()) {
if (ii != jj) {
continue;
}
}
bool res1 = runOverflow<int32_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int32_t valLeft,
int32_t valRight) {
Label overflow, end;
__ li(rc.left, valLeft);
__ li(rc.right, valRight);
switch (branchType) {
case kAddBranchOverflow:
__ AddBranchOvf(rc.dst, rc.left, rc.right, &overflow, NULL,
rc.scratch);
break;
case kSubBranchOverflow:
__ SubBranchOvf(rc.dst, rc.left, rc.right, &overflow, NULL,
rc.scratch);
break;
}
__ li(v0, 0);
__ Branch(&end);
__ bind(&overflow);
__ li(v0, 1);
__ bind(&end);
});
bool res2 = runOverflow<int32_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int32_t valLeft,
int32_t valRight) {
Label overflow, end;
__ li(rc.left, valLeft);
switch (branchType) {
case kAddBranchOverflow:
__ AddBranchOvf(rc.dst, rc.left, Operand(valRight),
&overflow, NULL, rc.scratch);
break;
case kSubBranchOverflow:
__ SubBranchOvf(rc.dst, rc.left, Operand(valRight),
&overflow, NULL, rc.scratch);
break;
}
__ li(v0, 0);
__ Branch(&end);
__ bind(&overflow);
__ li(v0, 1);
__ bind(&end);
});
switch (branchType) {
case kAddBranchOverflow:
CHECK_EQ(IsAddOverflow<int32_t>(ii, jj), res1);
CHECK_EQ(IsAddOverflow<int32_t>(ii, jj), res2);
break;
case kSubBranchOverflow:
CHECK_EQ(IsSubOverflow<int32_t>(ii, jj), res1);
CHECK_EQ(IsSubOverflow<int32_t>(ii, jj), res2);
break;
default:
UNREACHABLE();
}
}
}
}
}
}
TEST(BranchOverflowInt32RightLabel) {
FOR_INT32_INPUTS(i, overflow_int32_test_values) {
FOR_INT32_INPUTS(j, overflow_int32_test_values) {
FOR_ENUM_INPUTS(br, OverflowBranchType, overflow_branch_type) {
FOR_STRUCT_INPUTS(regComb, OverflowRegisterCombination,
overflow_register_combination) {
int32_t ii = *i;
int32_t jj = *j;
enum OverflowBranchType branchType = *br;
struct OverflowRegisterCombination rc = *regComb;
// If left and right register are same then left and right
// test values must also be same, otherwise we skip the test
if (rc.left.code() == rc.right.code()) {
if (ii != jj) {
continue;
}
}
bool res1 = runOverflow<int32_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int32_t valLeft,
int32_t valRight) {
Label no_overflow, end;
__ li(rc.left, valLeft);
__ li(rc.right, valRight);
switch (branchType) {
case kAddBranchOverflow:
__ AddBranchOvf(rc.dst, rc.left, rc.right, NULL,
&no_overflow, rc.scratch);
break;
case kSubBranchOverflow:
__ SubBranchOvf(rc.dst, rc.left, rc.right, NULL,
&no_overflow, rc.scratch);
break;
}
__ li(v0, 1);
__ Branch(&end);
__ bind(&no_overflow);
__ li(v0, 0);
__ bind(&end);
});
bool res2 = runOverflow<int32_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int32_t valLeft,
int32_t valRight) {
Label no_overflow, end;
__ li(rc.left, valLeft);
switch (branchType) {
case kAddBranchOverflow:
__ AddBranchOvf(rc.dst, rc.left, Operand(valRight), NULL,
&no_overflow, rc.scratch);
break;
case kSubBranchOverflow:
__ SubBranchOvf(rc.dst, rc.left, Operand(valRight), NULL,
&no_overflow, rc.scratch);
break;
}
__ li(v0, 1);
__ Branch(&end);
__ bind(&no_overflow);
__ li(v0, 0);
__ bind(&end);
});
switch (branchType) {
case kAddBranchOverflow:
CHECK_EQ(IsAddOverflow<int32_t>(ii, jj), res1);
CHECK_EQ(IsAddOverflow<int32_t>(ii, jj), res2);
break;
case kSubBranchOverflow:
CHECK_EQ(IsSubOverflow<int32_t>(ii, jj), res1);
CHECK_EQ(IsSubOverflow<int32_t>(ii, jj), res2);
break;
default:
UNREACHABLE();
}
}
}
}
}
}
TEST(BranchOverflowInt64BothLabels) {
FOR_INT64_INPUTS(i, overflow_int64_test_values) {
FOR_INT64_INPUTS(j, overflow_int64_test_values) {
FOR_ENUM_INPUTS(br, OverflowBranchType, overflow_branch_type) {
FOR_STRUCT_INPUTS(regComb, OverflowRegisterCombination,
overflow_register_combination) {
int64_t ii = *i;
int64_t jj = *j;
enum OverflowBranchType branchType = *br;
struct OverflowRegisterCombination rc = *regComb;
// If left and right register are same then left and right
// test values must also be same, otherwise we skip the test
if (rc.left.code() == rc.right.code()) {
if (ii != jj) {
continue;
}
}
bool res1 = runOverflow<int64_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int64_t valLeft,
int64_t valRight) {
Label overflow, no_overflow, end;
__ li(rc.left, valLeft);
__ li(rc.right, valRight);
switch (branchType) {
case kAddBranchOverflow:
__ DaddBranchOvf(rc.dst, rc.left, rc.right, &overflow,
&no_overflow, rc.scratch);
break;
case kSubBranchOverflow:
__ DsubBranchOvf(rc.dst, rc.left, rc.right, &overflow,
&no_overflow, rc.scratch);
break;
}
__ li(v0, 2);
__ Branch(&end);
__ bind(&overflow);
__ li(v0, 1);
__ Branch(&end);
__ bind(&no_overflow);
__ li(v0, 0);
__ bind(&end);
});
bool res2 = runOverflow<int64_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int64_t valLeft,
int64_t valRight) {
Label overflow, no_overflow, end;
__ li(rc.left, valLeft);
switch (branchType) {
case kAddBranchOverflow:
__ DaddBranchOvf(rc.dst, rc.left, Operand(valRight),
&overflow, &no_overflow, rc.scratch);
break;
case kSubBranchOverflow:
__ DsubBranchOvf(rc.dst, rc.left, Operand(valRight),
&overflow, &no_overflow, rc.scratch);
break;
}
__ li(v0, 2);
__ Branch(&end);
__ bind(&overflow);
__ li(v0, 1);
__ Branch(&end);
__ bind(&no_overflow);
__ li(v0, 0);
__ bind(&end);
});
switch (branchType) {
case kAddBranchOverflow:
CHECK_EQ(IsAddOverflow<int64_t>(ii, jj), res1);
CHECK_EQ(IsAddOverflow<int64_t>(ii, jj), res2);
break;
case kSubBranchOverflow:
CHECK_EQ(IsSubOverflow<int64_t>(ii, jj), res1);
CHECK_EQ(IsSubOverflow<int64_t>(ii, jj), res2);
break;
default:
UNREACHABLE();
}
}
}
}
}
}
TEST(BranchOverflowInt64LeftLabel) {
FOR_INT64_INPUTS(i, overflow_int64_test_values) {
FOR_INT64_INPUTS(j, overflow_int64_test_values) {
FOR_ENUM_INPUTS(br, OverflowBranchType, overflow_branch_type) {
FOR_STRUCT_INPUTS(regComb, OverflowRegisterCombination,
overflow_register_combination) {
int64_t ii = *i;
int64_t jj = *j;
enum OverflowBranchType branchType = *br;
struct OverflowRegisterCombination rc = *regComb;
// If left and right register are same then left and right
// test values must also be same, otherwise we skip the test
if (rc.left.code() == rc.right.code()) {
if (ii != jj) {
continue;
}
}
bool res1 = runOverflow<int64_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int64_t valLeft,
int64_t valRight) {
Label overflow, end;
__ li(rc.left, valLeft);
__ li(rc.right, valRight);
switch (branchType) {
case kAddBranchOverflow:
__ DaddBranchOvf(rc.dst, rc.left, rc.right, &overflow, NULL,
rc.scratch);
break;
case kSubBranchOverflow:
__ DsubBranchOvf(rc.dst, rc.left, rc.right, &overflow, NULL,
rc.scratch);
break;
}
__ li(v0, 0);
__ Branch(&end);
__ bind(&overflow);
__ li(v0, 1);
__ bind(&end);
});
bool res2 = runOverflow<int64_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int64_t valLeft,
int64_t valRight) {
Label overflow, end;
__ li(rc.left, valLeft);
switch (branchType) {
case kAddBranchOverflow:
__ DaddBranchOvf(rc.dst, rc.left, Operand(valRight),
&overflow, NULL, rc.scratch);
break;
case kSubBranchOverflow:
__ DsubBranchOvf(rc.dst, rc.left, Operand(valRight),
&overflow, NULL, rc.scratch);
break;
}
__ li(v0, 0);
__ Branch(&end);
__ bind(&overflow);
__ li(v0, 1);
__ bind(&end);
});
switch (branchType) {
case kAddBranchOverflow:
CHECK_EQ(IsAddOverflow<int64_t>(ii, jj), res1);
CHECK_EQ(IsAddOverflow<int64_t>(ii, jj), res2);
break;
case kSubBranchOverflow:
CHECK_EQ(IsSubOverflow<int64_t>(ii, jj), res1);
CHECK_EQ(IsSubOverflow<int64_t>(ii, jj), res2);
break;
default:
UNREACHABLE();
}
}
}
}
}
}
TEST(BranchOverflowInt64RightLabel) {
FOR_INT64_INPUTS(i, overflow_int64_test_values) {
FOR_INT64_INPUTS(j, overflow_int64_test_values) {
FOR_ENUM_INPUTS(br, OverflowBranchType, overflow_branch_type) {
FOR_STRUCT_INPUTS(regComb, OverflowRegisterCombination,
overflow_register_combination) {
int64_t ii = *i;
int64_t jj = *j;
enum OverflowBranchType branchType = *br;
struct OverflowRegisterCombination rc = *regComb;
// If left and right register are same then left and right
// test values must also be same, otherwise we skip the test
if (rc.left.code() == rc.right.code()) {
if (ii != jj) {
continue;
}
}
bool res1 = runOverflow<int64_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int64_t valLeft,
int64_t valRight) {
Label no_overflow, end;
__ li(rc.left, valLeft);
__ li(rc.right, valRight);
switch (branchType) {
case kAddBranchOverflow:
__ DaddBranchOvf(rc.dst, rc.left, rc.right, NULL,
&no_overflow, rc.scratch);
break;
case kSubBranchOverflow:
__ DsubBranchOvf(rc.dst, rc.left, rc.right, NULL,
&no_overflow, rc.scratch);
break;
}
__ li(v0, 1);
__ Branch(&end);
__ bind(&no_overflow);
__ li(v0, 0);
__ bind(&end);
});
bool res2 = runOverflow<int64_t>(
ii, jj, [branchType, rc](MacroAssembler* masm, int64_t valLeft,
int64_t valRight) {
Label no_overflow, end;
__ li(rc.left, valLeft);
switch (branchType) {
case kAddBranchOverflow:
__ DaddBranchOvf(rc.dst, rc.left, Operand(valRight), NULL,
&no_overflow, rc.scratch);
break;
case kSubBranchOverflow:
__ DsubBranchOvf(rc.dst, rc.left, Operand(valRight), NULL,
&no_overflow, rc.scratch);
break;
}
__ li(v0, 1);
__ Branch(&end);
__ bind(&no_overflow);
__ li(v0, 0);
__ bind(&end);
});
switch (branchType) {
case kAddBranchOverflow:
CHECK_EQ(IsAddOverflow<int64_t>(ii, jj), res1);
CHECK_EQ(IsAddOverflow<int64_t>(ii, jj), res2);
break;
case kSubBranchOverflow:
CHECK_EQ(IsSubOverflow<int64_t>(ii, jj), res1);
CHECK_EQ(IsSubOverflow<int64_t>(ii, jj), res2);
break;
default:
UNREACHABLE();
}
}
}
}
}
}
TEST(min_max_nan) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assembler(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assembler;
struct TestFloat {
double a;
double b;
double c;
double d;
float e;
float f;
float g;
float h;
};
TestFloat test;
const double dnan = std::numeric_limits<double>::quiet_NaN();
const double dinf = std::numeric_limits<double>::infinity();
const double dminf = -std::numeric_limits<double>::infinity();
const float fnan = std::numeric_limits<float>::quiet_NaN();
const float finf = std::numeric_limits<float>::infinity();
const float fminf = std::numeric_limits<float>::infinity();
const int kTableLength = 13;
double inputsa[kTableLength] = {2.0, 3.0, -0.0, 0.0, 42.0, dinf, dminf,
dinf, dnan, 3.0, dinf, dnan, dnan};
double inputsb[kTableLength] = {3.0, 2.0, 0.0, -0.0, dinf, 42.0, dinf,
dminf, 3.0, dnan, dnan, dinf, dnan};
double outputsdmin[kTableLength] = {2.0, 2.0, -0.0, -0.0, 42.0,
42.0, dminf, dminf, dnan, dnan,
dnan, dnan, dnan};
double outputsdmax[kTableLength] = {3.0, 3.0, 0.0, 0.0, dinf, dinf, dinf,
dinf, dnan, dnan, dnan, dnan, dnan};
float inputse[kTableLength] = {2.0, 3.0, -0.0, 0.0, 42.0, finf, fminf,
finf, fnan, 3.0, finf, fnan, fnan};
float inputsf[kTableLength] = {3.0, 2.0, 0.0, -0.0, finf, 42.0, finf,
fminf, 3.0, fnan, fnan, finf, fnan};
float outputsfmin[kTableLength] = {2.0, 2.0, -0.0, -0.0, 42.0, 42.0, fminf,
fminf, fnan, fnan, fnan, fnan, fnan};
float outputsfmax[kTableLength] = {3.0, 3.0, 0.0, 0.0, finf, finf, finf,
finf, fnan, fnan, fnan, fnan, fnan};
auto handle_dnan = [masm](FPURegister dst, Label* nan, Label* back) {
__ bind(nan);
__ LoadRoot(at, Heap::kNanValueRootIndex);
__ ldc1(dst, FieldMemOperand(at, HeapNumber::kValueOffset));
__ Branch(back);
};
auto handle_snan = [masm, fnan](FPURegister dst, Label* nan, Label* back) {
__ bind(nan);
__ Move(dst, fnan);
__ Branch(back);
};
Label handle_mind_nan, handle_maxd_nan, handle_mins_nan, handle_maxs_nan;
Label back_mind_nan, back_maxd_nan, back_mins_nan, back_maxs_nan;
__ push(s6);
__ InitializeRootRegister();
__ ldc1(f4, MemOperand(a0, offsetof(TestFloat, a)));
__ ldc1(f8, MemOperand(a0, offsetof(TestFloat, b)));
__ lwc1(f2, MemOperand(a0, offsetof(TestFloat, e)));
__ lwc1(f6, MemOperand(a0, offsetof(TestFloat, f)));
__ MinNaNCheck_d(f10, f4, f8, &handle_mind_nan);
__ bind(&back_mind_nan);
__ MaxNaNCheck_d(f12, f4, f8, &handle_maxd_nan);
__ bind(&back_maxd_nan);
__ MinNaNCheck_s(f14, f2, f6, &handle_mins_nan);
__ bind(&back_mins_nan);
__ MaxNaNCheck_s(f16, f2, f6, &handle_maxs_nan);
__ bind(&back_maxs_nan);
__ sdc1(f10, MemOperand(a0, offsetof(TestFloat, c)));
__ sdc1(f12, MemOperand(a0, offsetof(TestFloat, d)));
__ swc1(f14, MemOperand(a0, offsetof(TestFloat, g)));
__ swc1(f16, MemOperand(a0, offsetof(TestFloat, h)));
__ pop(s6);
__ jr(ra);
__ nop();
handle_dnan(f10, &handle_mind_nan, &back_mind_nan);
handle_dnan(f12, &handle_maxd_nan, &back_maxd_nan);
handle_snan(f14, &handle_mins_nan, &back_mins_nan);
handle_snan(f16, &handle_maxs_nan, &back_maxs_nan);
CodeDesc desc;
masm->GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
::F3 f = FUNCTION_CAST<::F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputsa[i];
test.b = inputsb[i];
test.e = inputse[i];
test.f = inputsf[i];
CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0);
CHECK_EQ(0, memcmp(&test.c, &outputsdmin[i], sizeof(test.c)));
CHECK_EQ(0, memcmp(&test.d, &outputsdmax[i], sizeof(test.d)));
CHECK_EQ(0, memcmp(&test.g, &outputsfmin[i], sizeof(test.g)));
CHECK_EQ(0, memcmp(&test.h, &outputsfmax[i], sizeof(test.h)));
}
}
template <typename IN_TYPE, typename Func>
bool run_Unaligned(char* memory_buffer, int32_t in_offset, int32_t out_offset,
IN_TYPE value, Func GenerateUnalignedInstructionFunc) {
typedef int32_t (*F_CVT)(char* x0, int x1, int x2, int x3, int x4);
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assm;
IN_TYPE res;
GenerateUnalignedInstructionFunc(masm, in_offset, out_offset);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
F_CVT f = FUNCTION_CAST<F_CVT>(code->entry());
MemCopy(memory_buffer + in_offset, &value, sizeof(IN_TYPE));
CALL_GENERATED_CODE(isolate, f, memory_buffer, 0, 0, 0, 0);
MemCopy(&res, memory_buffer + out_offset, sizeof(IN_TYPE));
return res == value;
}
static const std::vector<uint64_t> unsigned_test_values() {
static const uint64_t kValues[] = {
0x2180f18a06384414, 0x000a714532102277, 0xbc1acccf180649f0,
0x8000000080008000, 0x0000000000000001, 0xffffffffffffffff,
};
return std::vector<uint64_t>(&kValues[0], &kValues[arraysize(kValues)]);
}
static const std::vector<int32_t> unsigned_test_offset() {
static const int32_t kValues[] = {// value, offset
-132 * KB, -21 * KB, 0, 19 * KB, 135 * KB};
return std::vector<int32_t>(&kValues[0], &kValues[arraysize(kValues)]);
}
static const std::vector<int32_t> unsigned_test_offset_increment() {
static const int32_t kValues[] = {-5, -4, -3, -2, -1, 0, 1, 2, 3, 4, 5};
return std::vector<int32_t>(&kValues[0], &kValues[arraysize(kValues)]);
}
TEST(Ulh) {
CcTest::InitializeVM();
static const int kBufferSize = 300 * KB;
char memory_buffer[kBufferSize];
char* buffer_middle = memory_buffer + (kBufferSize / 2);
FOR_UINT64_INPUTS(i, unsigned_test_values) {
FOR_INT32_INPUTS2(j1, j2, unsigned_test_offset) {
FOR_INT32_INPUTS2(k1, k2, unsigned_test_offset_increment) {
uint16_t value = static_cast<uint64_t>(*i & 0xFFFF);
int32_t in_offset = *j1 + *k1;
int32_t out_offset = *j2 + *k2;
CHECK_EQ(true, run_Unaligned<uint16_t>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ Ulh(v0, MemOperand(a0, in_offset));
__ Ush(v0, MemOperand(a0, out_offset), v0);
}));
CHECK_EQ(true, run_Unaligned<uint16_t>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ mov(t0, a0);
__ Ulh(a0, MemOperand(a0, in_offset));
__ Ush(a0, MemOperand(t0, out_offset), v0);
}));
CHECK_EQ(true, run_Unaligned<uint16_t>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ mov(t0, a0);
__ Ulhu(a0, MemOperand(a0, in_offset));
__ Ush(a0, MemOperand(t0, out_offset), t1);
}));
CHECK_EQ(true, run_Unaligned<uint16_t>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ Ulhu(v0, MemOperand(a0, in_offset));
__ Ush(v0, MemOperand(a0, out_offset), t1);
}));
}
}
}
}
TEST(Ulh_bitextension) {
CcTest::InitializeVM();
static const int kBufferSize = 300 * KB;
char memory_buffer[kBufferSize];
char* buffer_middle = memory_buffer + (kBufferSize / 2);
FOR_UINT64_INPUTS(i, unsigned_test_values) {
FOR_INT32_INPUTS2(j1, j2, unsigned_test_offset) {
FOR_INT32_INPUTS2(k1, k2, unsigned_test_offset_increment) {
uint16_t value = static_cast<uint64_t>(*i & 0xFFFF);
int32_t in_offset = *j1 + *k1;
int32_t out_offset = *j2 + *k2;
CHECK_EQ(true, run_Unaligned<uint16_t>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
Label success, fail, end, different;
__ Ulh(t0, MemOperand(a0, in_offset));
__ Ulhu(t1, MemOperand(a0, in_offset));
__ Branch(&different, ne, t0, Operand(t1));
// If signed and unsigned values are same, check
// the upper bits to see if they are zero
__ sra(t0, t0, 15);
__ Branch(&success, eq, t0, Operand(zero_reg));
__ Branch(&fail);
// If signed and unsigned values are different,
// check that the upper bits are complementary
__ bind(&different);
__ sra(t1, t1, 15);
__ Branch(&fail, ne, t1, Operand(1));
__ sra(t0, t0, 15);
__ addiu(t0, t0, 1);
__ Branch(&fail, ne, t0, Operand(zero_reg));
// Fall through to success
__ bind(&success);
__ Ulh(t0, MemOperand(a0, in_offset));
__ Ush(t0, MemOperand(a0, out_offset), v0);
__ Branch(&end);
__ bind(&fail);
__ Ush(zero_reg, MemOperand(a0, out_offset), v0);
__ bind(&end);
}));
}
}
}
}
TEST(Ulw) {
CcTest::InitializeVM();
static const int kBufferSize = 300 * KB;
char memory_buffer[kBufferSize];
char* buffer_middle = memory_buffer + (kBufferSize / 2);
FOR_UINT64_INPUTS(i, unsigned_test_values) {
FOR_INT32_INPUTS2(j1, j2, unsigned_test_offset) {
FOR_INT32_INPUTS2(k1, k2, unsigned_test_offset_increment) {
uint32_t value = static_cast<uint32_t>(*i & 0xFFFFFFFF);
int32_t in_offset = *j1 + *k1;
int32_t out_offset = *j2 + *k2;
CHECK_EQ(true, run_Unaligned<uint32_t>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ Ulw(v0, MemOperand(a0, in_offset));
__ Usw(v0, MemOperand(a0, out_offset));
}));
CHECK_EQ(true,
run_Unaligned<uint32_t>(
buffer_middle, in_offset, out_offset, (uint32_t)value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ mov(t0, a0);
__ Ulw(a0, MemOperand(a0, in_offset));
__ Usw(a0, MemOperand(t0, out_offset));
}));
CHECK_EQ(true, run_Unaligned<uint32_t>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ Ulwu(v0, MemOperand(a0, in_offset));
__ Usw(v0, MemOperand(a0, out_offset));
}));
CHECK_EQ(true,
run_Unaligned<uint32_t>(
buffer_middle, in_offset, out_offset, (uint32_t)value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ mov(t0, a0);
__ Ulwu(a0, MemOperand(a0, in_offset));
__ Usw(a0, MemOperand(t0, out_offset));
}));
}
}
}
}
TEST(Ulw_extension) {
CcTest::InitializeVM();
static const int kBufferSize = 300 * KB;
char memory_buffer[kBufferSize];
char* buffer_middle = memory_buffer + (kBufferSize / 2);
FOR_UINT64_INPUTS(i, unsigned_test_values) {
FOR_INT32_INPUTS2(j1, j2, unsigned_test_offset) {
FOR_INT32_INPUTS2(k1, k2, unsigned_test_offset_increment) {
uint32_t value = static_cast<uint32_t>(*i & 0xFFFFFFFF);
int32_t in_offset = *j1 + *k1;
int32_t out_offset = *j2 + *k2;
CHECK_EQ(true, run_Unaligned<uint32_t>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
Label success, fail, end, different;
__ Ulw(t0, MemOperand(a0, in_offset));
__ Ulwu(t1, MemOperand(a0, in_offset));
__ Branch(&different, ne, t0, Operand(t1));
// If signed and unsigned values are same, check
// the upper bits to see if they are zero
__ dsra(t0, t0, 31);
__ Branch(&success, eq, t0, Operand(zero_reg));
__ Branch(&fail);
// If signed and unsigned values are different,
// check that the upper bits are complementary
__ bind(&different);
__ dsra(t1, t1, 31);
__ Branch(&fail, ne, t1, Operand(1));
__ dsra(t0, t0, 31);
__ daddiu(t0, t0, 1);
__ Branch(&fail, ne, t0, Operand(zero_reg));
// Fall through to success
__ bind(&success);
__ Ulw(t0, MemOperand(a0, in_offset));
__ Usw(t0, MemOperand(a0, out_offset));
__ Branch(&end);
__ bind(&fail);
__ Usw(zero_reg, MemOperand(a0, out_offset));
__ bind(&end);
}));
}
}
}
}
TEST(Uld) {
CcTest::InitializeVM();
static const int kBufferSize = 300 * KB;
char memory_buffer[kBufferSize];
char* buffer_middle = memory_buffer + (kBufferSize / 2);
FOR_UINT64_INPUTS(i, unsigned_test_values) {
FOR_INT32_INPUTS2(j1, j2, unsigned_test_offset) {
FOR_INT32_INPUTS2(k1, k2, unsigned_test_offset_increment) {
uint64_t value = *i;
int32_t in_offset = *j1 + *k1;
int32_t out_offset = *j2 + *k2;
CHECK_EQ(true, run_Unaligned<uint64_t>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ Uld(v0, MemOperand(a0, in_offset));
__ Usd(v0, MemOperand(a0, out_offset));
}));
CHECK_EQ(true,
run_Unaligned<uint64_t>(
buffer_middle, in_offset, out_offset, (uint32_t)value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ mov(t0, a0);
__ Uld(a0, MemOperand(a0, in_offset));
__ Usd(a0, MemOperand(t0, out_offset));
}));
}
}
}
}
TEST(Ulwc1) {
CcTest::InitializeVM();
static const int kBufferSize = 300 * KB;
char memory_buffer[kBufferSize];
char* buffer_middle = memory_buffer + (kBufferSize / 2);
FOR_UINT64_INPUTS(i, unsigned_test_values) {
FOR_INT32_INPUTS2(j1, j2, unsigned_test_offset) {
FOR_INT32_INPUTS2(k1, k2, unsigned_test_offset_increment) {
float value = static_cast<float>(*i & 0xFFFFFFFF);
int32_t in_offset = *j1 + *k1;
int32_t out_offset = *j2 + *k2;
CHECK_EQ(true, run_Unaligned<float>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ Ulwc1(f0, MemOperand(a0, in_offset), t0);
__ Uswc1(f0, MemOperand(a0, out_offset), t0);
}));
}
}
}
}
TEST(Uldc1) {
CcTest::InitializeVM();
static const int kBufferSize = 300 * KB;
char memory_buffer[kBufferSize];
char* buffer_middle = memory_buffer + (kBufferSize / 2);
FOR_UINT64_INPUTS(i, unsigned_test_values) {
FOR_INT32_INPUTS2(j1, j2, unsigned_test_offset) {
FOR_INT32_INPUTS2(k1, k2, unsigned_test_offset_increment) {
double value = static_cast<double>(*i);
int32_t in_offset = *j1 + *k1;
int32_t out_offset = *j2 + *k2;
CHECK_EQ(true, run_Unaligned<double>(
buffer_middle, in_offset, out_offset, value,
[](MacroAssembler* masm, int32_t in_offset,
int32_t out_offset) {
__ Uldc1(f0, MemOperand(a0, in_offset), t0);
__ Usdc1(f0, MemOperand(a0, out_offset), t0);
}));
}
}
}
}
static const std::vector<uint64_t> sltu_test_values() {
static const uint64_t kValues[] = {
0,
1,
0x7ffe,
0x7fff,
0x8000,
0x8001,
0xfffe,
0xffff,
0xffffffffffff7ffe,
0xffffffffffff7fff,
0xffffffffffff8000,
0xffffffffffff8001,
0xfffffffffffffffe,
0xffffffffffffffff,
};
return std::vector<uint64_t>(&kValues[0], &kValues[arraysize(kValues)]);
}
template <typename Func>
bool run_Sltu(uint64_t rs, uint64_t rd, Func GenerateSltuInstructionFunc) {
typedef int64_t (*F_CVT)(uint64_t x0, uint64_t x1, int x2, int x3, int x4);
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
MacroAssembler* masm = &assm;
GenerateSltuInstructionFunc(masm, rd);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(&desc);
Handle<Code> code = isolate->factory()->NewCode(
desc, Code::ComputeFlags(Code::STUB), Handle<Code>());
F_CVT f = FUNCTION_CAST<F_CVT>(code->entry());
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, rs, rd, 0, 0, 0));
return res == 1;
}
TEST(Sltu) {
CcTest::InitializeVM();
FOR_UINT64_INPUTS(i, sltu_test_values) {
FOR_UINT64_INPUTS(j, sltu_test_values) {
uint64_t rs = *i;
uint64_t rd = *j;
CHECK_EQ(rs < rd, run_Sltu(rs, rd,
[](MacroAssembler* masm, uint64_t imm) {
__ Sltu(v0, a0, Operand(imm));
}));
CHECK_EQ(rs < rd,
run_Sltu(rs, rd, [](MacroAssembler* masm,
uint64_t imm) { __ Sltu(v0, a0, a1); }));
}
}
}
#undef __
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