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v8/test/cctest/wasm/test-run-wasm-interpreter.cc
Clemens Hammacher 1a8e7d13a1 [wasm] Reduce test-specific code 
This reduces the amount of special paths for testing.
Setup the memory used for testing exactly the same way as in real world.
Also, always connect the interpreter to the instance being executed,
and to the existing WasmInstance struct. This keeps information
synchronized between interpreter and test runner.
These changes allow us to execute e.g. GrowMemory from cctests either
in the interpreter or in compiled code.

R=ahaas@chromium.org

Change-Id: Id4726d061f3cdba789275350f500d769d27d2d63
Reviewed-on: https://chromium-review.googlesource.com/488561
Commit-Queue: Clemens Hammacher <clemensh@chromium.org>
Reviewed-by: Andreas Haas <ahaas@chromium.org>
Cr-Commit-Position: refs/heads/master@{#44966}
2017-04-28 09:00:32 +00:00

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// Copyright 2016 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <memory>
#include "src/assembler-inl.h"
#include "src/wasm/wasm-interpreter.h"
#include "test/cctest/cctest.h"
#include "test/cctest/compiler/value-helper.h"
#include "test/cctest/wasm/wasm-run-utils.h"
#include "test/common/wasm/test-signatures.h"
#include "test/common/wasm/wasm-macro-gen.h"
using namespace v8::base;
using namespace v8::internal;
using namespace v8::internal::compiler;
using namespace v8::internal::wasm;
namespace v8 {
namespace internal {
namespace wasm {
TEST(Run_WasmInt8Const_i) {
WasmRunner<int32_t> r(kExecuteInterpreted);
const byte kExpectedValue = 109;
// return(kExpectedValue)
BUILD(r, WASM_I32V_2(kExpectedValue));
CHECK_EQ(kExpectedValue, r.Call());
}
TEST(Run_WasmIfElse) {
WasmRunner<int32_t, int32_t> r(kExecuteInterpreted);
BUILD(r, WASM_IF_ELSE_I(WASM_GET_LOCAL(0), WASM_I32V_1(9), WASM_I32V_1(10)));
CHECK_EQ(10, r.Call(0));
CHECK_EQ(9, r.Call(1));
}
TEST(Run_WasmIfReturn) {
WasmRunner<int32_t, int32_t> r(kExecuteInterpreted);
BUILD(r, WASM_IF(WASM_GET_LOCAL(0), WASM_RETURN1(WASM_I32V_2(77))),
WASM_I32V_2(65));
CHECK_EQ(65, r.Call(0));
CHECK_EQ(77, r.Call(1));
}
TEST(Run_WasmNopsN) {
const int kMaxNops = 10;
byte code[kMaxNops + 2];
for (int nops = 0; nops < kMaxNops; nops++) {
byte expected = static_cast<byte>(20 + nops);
memset(code, kExprNop, sizeof(code));
code[nops] = kExprI32Const;
code[nops + 1] = expected;
WasmRunner<int32_t> r(kExecuteInterpreted);
r.Build(code, code + nops + 2);
CHECK_EQ(expected, r.Call());
}
}
TEST(Run_WasmConstsN) {
const int kMaxConsts = 5;
byte code[kMaxConsts * 3];
int32_t expected = 0;
for (int count = 1; count < kMaxConsts; count++) {
for (int i = 0; i < count; i++) {
byte val = static_cast<byte>(count * 10 + i);
code[i * 3] = kExprI32Const;
code[i * 3 + 1] = val;
if (i == (count - 1)) {
code[i * 3 + 2] = kExprNop;
expected = val;
} else {
code[i * 3 + 2] = kExprDrop;
}
}
WasmRunner<int32_t> r(kExecuteInterpreted);
r.Build(code, code + (count * 3));
CHECK_EQ(expected, r.Call());
}
}
TEST(Run_WasmBlocksN) {
const int kMaxNops = 10;
const int kExtra = 5;
byte code[kMaxNops + kExtra];
for (int nops = 0; nops < kMaxNops; nops++) {
byte expected = static_cast<byte>(30 + nops);
memset(code, kExprNop, sizeof(code));
code[0] = kExprBlock;
code[1] = kLocalI32;
code[2 + nops] = kExprI32Const;
code[2 + nops + 1] = expected;
code[2 + nops + 2] = kExprEnd;
WasmRunner<int32_t> r(kExecuteInterpreted);
r.Build(code, code + nops + kExtra);
CHECK_EQ(expected, r.Call());
}
}
TEST(Run_WasmBlockBreakN) {
const int kMaxNops = 10;
const int kExtra = 6;
int run = 0;
byte code[kMaxNops + kExtra];
for (int nops = 0; nops < kMaxNops; nops++) {
// Place the break anywhere within the block.
for (int index = 0; index < nops; index++) {
memset(code, kExprNop, sizeof(code));
code[0] = kExprBlock;
code[1] = kLocalI32;
code[sizeof(code) - 1] = kExprEnd;
int expected = run++;
code[2 + index + 0] = kExprI32Const;
code[2 + index + 1] = static_cast<byte>(expected);
code[2 + index + 2] = kExprBr;
code[2 + index + 3] = 0;
WasmRunner<int32_t> r(kExecuteInterpreted);
r.Build(code, code + kMaxNops + kExtra);
CHECK_EQ(expected, r.Call());
}
}
}
TEST(Run_Wasm_nested_ifs_i) {
WasmRunner<int32_t, int32_t, int32_t> r(kExecuteInterpreted);
BUILD(
r,
WASM_IF_ELSE_I(
WASM_GET_LOCAL(0),
WASM_IF_ELSE_I(WASM_GET_LOCAL(1), WASM_I32V_1(11), WASM_I32V_1(12)),
WASM_IF_ELSE_I(WASM_GET_LOCAL(1), WASM_I32V_1(13), WASM_I32V_1(14))));
CHECK_EQ(11, r.Call(1, 1));
CHECK_EQ(12, r.Call(1, 0));
CHECK_EQ(13, r.Call(0, 1));
CHECK_EQ(14, r.Call(0, 0));
}
// Make tests more robust by not hard-coding offsets of various operations.
// The {Find} method finds the offsets for the given bytecodes, returning
// the offsets in an array.
std::unique_ptr<int[]> Find(byte* code, size_t code_size, int n, ...) {
va_list vl;
va_start(vl, n);
std::unique_ptr<int[]> offsets(new int[n]);
for (int i = 0; i < n; i++) {
offsets[i] = -1;
}
int pos = 0;
WasmOpcode current = static_cast<WasmOpcode>(va_arg(vl, int));
for (size_t i = 0; i < code_size; i++) {
if (code[i] == current) {
offsets[pos++] = static_cast<int>(i);
if (pos == n) break;
current = static_cast<WasmOpcode>(va_arg(vl, int));
}
}
va_end(vl);
return offsets;
}
TEST(Breakpoint_I32Add) {
static const int kLocalsDeclSize = 1;
static const int kNumBreakpoints = 3;
byte code[] = {WASM_I32_ADD(WASM_GET_LOCAL(0), WASM_GET_LOCAL(1))};
std::unique_ptr<int[]> offsets =
Find(code, sizeof(code), kNumBreakpoints, kExprGetLocal, kExprGetLocal,
kExprI32Add);
WasmRunner<int32_t, uint32_t, uint32_t> r(kExecuteInterpreted);
r.Build(code, code + arraysize(code));
WasmInterpreter* interpreter = r.interpreter();
WasmInterpreter::Thread* thread = interpreter->GetThread(0);
for (int i = 0; i < kNumBreakpoints; i++) {
interpreter->SetBreakpoint(r.function(), kLocalsDeclSize + offsets[i],
true);
}
FOR_UINT32_INPUTS(a) {
for (uint32_t b = 11; b < 3000000000u; b += 1000000000u) {
thread->Reset();
WasmVal args[] = {WasmVal(*a), WasmVal(b)};
thread->InitFrame(r.function(), args);
for (int i = 0; i < kNumBreakpoints; i++) {
thread->Run(); // run to next breakpoint
// Check the thread stopped at the right pc.
CHECK_EQ(WasmInterpreter::PAUSED, thread->state());
CHECK_EQ(static_cast<size_t>(kLocalsDeclSize + offsets[i]),
thread->GetBreakpointPc());
}
thread->Run(); // run to completion
// Check the thread finished with the right value.
CHECK_EQ(WasmInterpreter::FINISHED, thread->state());
uint32_t expected = (*a) + (b);
CHECK_EQ(expected, thread->GetReturnValue().to<uint32_t>());
}
}
}
TEST(Step_I32Mul) {
static const int kTraceLength = 4;
byte code[] = {WASM_I32_MUL(WASM_GET_LOCAL(0), WASM_GET_LOCAL(1))};
WasmRunner<int32_t, uint32_t, uint32_t> r(kExecuteInterpreted);
r.Build(code, code + arraysize(code));
WasmInterpreter* interpreter = r.interpreter();
WasmInterpreter::Thread* thread = interpreter->GetThread(0);
FOR_UINT32_INPUTS(a) {
for (uint32_t b = 33; b < 3000000000u; b += 1000000000u) {
thread->Reset();
WasmVal args[] = {WasmVal(*a), WasmVal(b)};
thread->InitFrame(r.function(), args);
// Run instructions one by one.
for (int i = 0; i < kTraceLength - 1; i++) {
thread->Step();
// Check the thread stopped.
CHECK_EQ(WasmInterpreter::PAUSED, thread->state());
}
// Run last instruction.
thread->Step();
// Check the thread finished with the right value.
CHECK_EQ(WasmInterpreter::FINISHED, thread->state());
uint32_t expected = (*a) * (b);
CHECK_EQ(expected, thread->GetReturnValue().to<uint32_t>());
}
}
}
TEST(Breakpoint_I32And_disable) {
static const int kLocalsDeclSize = 1;
static const int kNumBreakpoints = 1;
byte code[] = {WASM_I32_AND(WASM_GET_LOCAL(0), WASM_GET_LOCAL(1))};
std::unique_ptr<int[]> offsets =
Find(code, sizeof(code), kNumBreakpoints, kExprI32And);
WasmRunner<int32_t, uint32_t, uint32_t> r(kExecuteInterpreted);
r.Build(code, code + arraysize(code));
WasmInterpreter* interpreter = r.interpreter();
WasmInterpreter::Thread* thread = interpreter->GetThread(0);
FOR_UINT32_INPUTS(a) {
for (uint32_t b = 11; b < 3000000000u; b += 1000000000u) {
// Run with and without breakpoints.
for (int do_break = 0; do_break < 2; do_break++) {
interpreter->SetBreakpoint(r.function(), kLocalsDeclSize + offsets[0],
do_break);
thread->Reset();
WasmVal args[] = {WasmVal(*a), WasmVal(b)};
thread->InitFrame(r.function(), args);
if (do_break) {
thread->Run(); // run to next breakpoint
// Check the thread stopped at the right pc.
CHECK_EQ(WasmInterpreter::PAUSED, thread->state());
CHECK_EQ(static_cast<size_t>(kLocalsDeclSize + offsets[0]),
thread->GetBreakpointPc());
}
thread->Run(); // run to completion
// Check the thread finished with the right value.
CHECK_EQ(WasmInterpreter::FINISHED, thread->state());
uint32_t expected = (*a) & (b);
CHECK_EQ(expected, thread->GetReturnValue().to<uint32_t>());
}
}
}
}
TEST(GrowMemory) {
{
WasmRunner<int32_t, uint32_t> r(kExecuteInterpreted);
r.module().AddMemory(WasmModule::kPageSize);
r.module().SetMaxMemPages(10);
BUILD(r, WASM_GROW_MEMORY(WASM_GET_LOCAL(0)));
CHECK_EQ(1, r.Call(1));
}
{
WasmRunner<int32_t, uint32_t> r(kExecuteInterpreted);
r.module().AddMemory(WasmModule::kPageSize);
r.module().SetMaxMemPages(10);
BUILD(r, WASM_GROW_MEMORY(WASM_GET_LOCAL(0)));
CHECK_EQ(-1, r.Call(11));
}
}
TEST(GrowMemoryPreservesData) {
int32_t index = 16;
int32_t value = 2335;
WasmRunner<int32_t, uint32_t> r(kExecuteInterpreted);
r.module().AddMemory(WasmModule::kPageSize);
BUILD(r, WASM_STORE_MEM(MachineType::Int32(), WASM_I32V(index),
WASM_I32V(value)),
WASM_GROW_MEMORY(WASM_GET_LOCAL(0)), WASM_DROP,
WASM_LOAD_MEM(MachineType::Int32(), WASM_I32V(index)));
CHECK_EQ(value, r.Call(1));
}
TEST(GrowMemoryInvalidSize) {
// Grow memory by an invalid amount without initial memory.
WasmRunner<int32_t, uint32_t> r(kExecuteInterpreted);
r.module().AddMemory(WasmModule::kPageSize);
BUILD(r, WASM_GROW_MEMORY(WASM_GET_LOCAL(0)));
CHECK_EQ(-1, r.Call(1048575));
}
TEST(TestPossibleNondeterminism) {
{
WasmRunner<int32_t, float> r(kExecuteInterpreted);
BUILD(r, WASM_I32_REINTERPRET_F32(WASM_GET_LOCAL(0)));
r.Call(1048575.5f);
CHECK(!r.possible_nondeterminism());
r.Call(std::numeric_limits<float>::quiet_NaN());
CHECK(r.possible_nondeterminism());
}
{
WasmRunner<int64_t, double> r(kExecuteInterpreted);
BUILD(r, WASM_I64_REINTERPRET_F64(WASM_GET_LOCAL(0)));
r.Call(16.0);
CHECK(!r.possible_nondeterminism());
r.Call(std::numeric_limits<double>::quiet_NaN());
CHECK(r.possible_nondeterminism());
}
{
WasmRunner<float, float> r(kExecuteInterpreted);
BUILD(r, WASM_F32_COPYSIGN(WASM_F32(42.0f), WASM_GET_LOCAL(0)));
r.Call(16.0f);
CHECK(!r.possible_nondeterminism());
r.Call(std::numeric_limits<double>::quiet_NaN());
CHECK(r.possible_nondeterminism());
}
{
WasmRunner<double, double> r(kExecuteInterpreted);
BUILD(r, WASM_F64_COPYSIGN(WASM_F64(42.0), WASM_GET_LOCAL(0)));
r.Call(16.0);
CHECK(!r.possible_nondeterminism());
r.Call(std::numeric_limits<double>::quiet_NaN());
CHECK(r.possible_nondeterminism());
}
{
int32_t index = 16;
WasmRunner<int32_t, float> r(kExecuteInterpreted);
r.module().AddMemory(WasmModule::kPageSize);
BUILD(r, WASM_STORE_MEM(MachineType::Float32(), WASM_I32V(index),
WASM_GET_LOCAL(0)),
WASM_I32V(index));
r.Call(1345.3456f);
CHECK(!r.possible_nondeterminism());
r.Call(std::numeric_limits<float>::quiet_NaN());
CHECK(r.possible_nondeterminism());
}
{
int32_t index = 16;
WasmRunner<int32_t, double> r(kExecuteInterpreted);
r.module().AddMemory(WasmModule::kPageSize);
BUILD(r, WASM_STORE_MEM(MachineType::Float64(), WASM_I32V(index),
WASM_GET_LOCAL(0)),
WASM_I32V(index));
r.Call(1345.3456);
CHECK(!r.possible_nondeterminism());
r.Call(std::numeric_limits<double>::quiet_NaN());
CHECK(r.possible_nondeterminism());
}
}
TEST(WasmInterpreterActivations) {
WasmRunner<void> r(kExecuteInterpreted);
Isolate* isolate = r.main_isolate();
BUILD(r, WASM_NOP);
WasmInterpreter* interpreter = r.interpreter();
WasmInterpreter::Thread* thread = interpreter->GetThread(0);
CHECK_EQ(0, thread->NumActivations());
uint32_t act0 = thread->StartActivation();
CHECK_EQ(0, act0);
thread->InitFrame(r.function(), nullptr);
uint32_t act1 = thread->StartActivation();
CHECK_EQ(1, act1);
thread->InitFrame(r.function(), nullptr);
CHECK_EQ(2, thread->NumActivations());
CHECK_EQ(2, thread->GetFrameCount());
isolate->set_pending_exception(Smi::kZero);
thread->HandleException(isolate);
CHECK_EQ(1, thread->GetFrameCount());
CHECK_EQ(2, thread->NumActivations());
thread->FinishActivation(act1);
CHECK_EQ(1, thread->GetFrameCount());
CHECK_EQ(1, thread->NumActivations());
thread->HandleException(isolate);
CHECK_EQ(0, thread->GetFrameCount());
CHECK_EQ(1, thread->NumActivations());
thread->FinishActivation(act0);
CHECK_EQ(0, thread->NumActivations());
}
TEST(InterpreterLoadWithoutMemory) {
WasmRunner<int32_t, int32_t> r(kExecuteInterpreted);
r.module().AddMemory(0);
BUILD(r, WASM_LOAD_MEM(MachineType::Int32(), WASM_GET_LOCAL(0)));
CHECK_TRAP32(r.Call(0));
}
} // namespace wasm
} // namespace internal
} // namespace v8
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