v8/test/cctest/wasm/test-liftoff-inspection.cc
Deepti Gandluri c4468c39f0 [wasm-simd] Remove simd lowering compilation env variable
Bug: v8:11613
Change-Id: I25bf720164129c3d95ebc07d0c2a0f6e6b8ee9af
Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/2847473
Reviewed-by: Zhi An Ng <zhin@chromium.org>
Commit-Queue: Deepti Gandluri <gdeepti@chromium.org>
Cr-Commit-Position: refs/heads/master@{#74131}
2021-04-22 23:40:58 +00:00

482 lines
17 KiB
C++

// Copyright 2019 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 "src/wasm/baseline/liftoff-compiler.h"
#include "src/wasm/wasm-debug.h"
#include "test/cctest/cctest.h"
#include "test/cctest/wasm/wasm-run-utils.h"
#include "test/common/wasm/test-signatures.h"
#include "test/common/wasm/wasm-macro-gen.h"
namespace v8 {
namespace internal {
namespace wasm {
namespace {
class LiftoffCompileEnvironment {
public:
LiftoffCompileEnvironment()
: isolate_(CcTest::InitIsolateOnce()),
handle_scope_(isolate_),
zone_(isolate_->allocator(), ZONE_NAME),
wasm_runner_(nullptr, TestExecutionTier::kLiftoff, 0,
kRuntimeExceptionSupport) {
// Add a table of length 1, for indirect calls.
wasm_runner_.builder().AddIndirectFunctionTable(nullptr, 1);
// Set tiered down such that we generate debugging code.
wasm_runner_.builder().SetTieredDown();
}
struct TestFunction {
WasmCode* code;
FunctionBody body;
};
void CheckDeterministicCompilation(
std::initializer_list<ValueType> return_types,
std::initializer_list<ValueType> param_types,
std::initializer_list<uint8_t> raw_function_bytes) {
auto test_func = AddFunction(return_types, param_types, raw_function_bytes);
// Now compile the function with Liftoff two times.
CompilationEnv env = wasm_runner_.builder().CreateCompilationEnv();
WasmFeatures detected1;
WasmFeatures detected2;
WasmCompilationResult result1 = ExecuteLiftoffCompilation(
isolate_->allocator(), &env, test_func.body, test_func.code->index(),
kNoDebugging, isolate_->counters(), &detected1);
WasmCompilationResult result2 = ExecuteLiftoffCompilation(
isolate_->allocator(), &env, test_func.body, test_func.code->index(),
kNoDebugging, isolate_->counters(), &detected2);
CHECK(result1.succeeded());
CHECK(result2.succeeded());
// Check that the generated code matches.
auto code1 =
VectorOf(result1.code_desc.buffer, result1.code_desc.instr_size);
auto code2 =
VectorOf(result2.code_desc.buffer, result2.code_desc.instr_size);
CHECK_EQ(code1, code2);
CHECK_EQ(detected1, detected2);
}
std::unique_ptr<DebugSideTable> GenerateDebugSideTable(
std::initializer_list<ValueType> return_types,
std::initializer_list<ValueType> param_types,
std::initializer_list<uint8_t> raw_function_bytes,
std::vector<int> breakpoints = {}) {
auto test_func = AddFunction(return_types, param_types, raw_function_bytes);
CompilationEnv env = wasm_runner_.builder().CreateCompilationEnv();
WasmFeatures detected;
std::unique_ptr<DebugSideTable> debug_side_table_via_compilation;
auto result = ExecuteLiftoffCompilation(
CcTest::i_isolate()->allocator(), &env, test_func.body, 0,
kForDebugging, nullptr, &detected, VectorOf(breakpoints),
&debug_side_table_via_compilation);
CHECK(result.succeeded());
// If there are no breakpoint, then {ExecuteLiftoffCompilation} should
// provide the same debug side table.
if (breakpoints.empty()) {
std::unique_ptr<DebugSideTable> debug_side_table =
GenerateLiftoffDebugSideTable(test_func.code);
CheckTableEquals(*debug_side_table, *debug_side_table_via_compilation);
}
return debug_side_table_via_compilation;
}
TestingModuleBuilder* builder() { return &wasm_runner_.builder(); }
private:
static void CheckTableEquals(const DebugSideTable& a,
const DebugSideTable& b) {
CHECK_EQ(a.num_locals(), b.num_locals());
CHECK_EQ(a.entries().size(), b.entries().size());
CHECK(std::equal(a.entries().begin(), a.entries().end(),
b.entries().begin(), b.entries().end(),
&CheckEntryEquals));
}
static bool CheckEntryEquals(const DebugSideTable::Entry& a,
const DebugSideTable::Entry& b) {
CHECK_EQ(a.pc_offset(), b.pc_offset());
CHECK_EQ(a.stack_height(), b.stack_height());
CHECK_EQ(a.changed_values(), b.changed_values());
return true;
}
FunctionSig* AddSig(std::initializer_list<ValueType> return_types,
std::initializer_list<ValueType> param_types) {
ValueType* storage =
zone_.NewArray<ValueType>(return_types.size() + param_types.size());
std::copy(return_types.begin(), return_types.end(), storage);
std::copy(param_types.begin(), param_types.end(),
storage + return_types.size());
FunctionSig* sig = zone_.New<FunctionSig>(return_types.size(),
param_types.size(), storage);
return sig;
}
TestFunction AddFunction(std::initializer_list<ValueType> return_types,
std::initializer_list<ValueType> param_types,
std::initializer_list<uint8_t> function_bytes) {
FunctionSig* sig = AddSig(return_types, param_types);
// Compile the function so we can get the WasmCode* which is later used to
// generate the debug side table lazily.
auto& func_compiler = wasm_runner_.NewFunction(sig, "f");
func_compiler.Build(function_bytes.begin(), function_bytes.end());
WasmCode* code =
wasm_runner_.builder().GetFunctionCode(func_compiler.function_index());
// Get the wire bytes created by the function compiler (including locals
// declaration and the trailing "end" opcode).
NativeModule* native_module = code->native_module();
auto* function = &native_module->module()->functions[code->index()];
Vector<const uint8_t> function_wire_bytes =
native_module->wire_bytes().SubVector(function->code.offset(),
function->code.end_offset());
FunctionBody body{sig, 0, function_wire_bytes.begin(),
function_wire_bytes.end()};
return {code, body};
}
Isolate* isolate_;
HandleScope handle_scope_;
Zone zone_;
// wasm_runner_ is used to build actual code objects needed to request lazy
// generation of debug side tables.
WasmRunnerBase wasm_runner_;
WasmCodeRefScope code_ref_scope_;
};
struct DebugSideTableEntry {
int stack_height;
std::vector<DebugSideTable::Entry::Value> changed_values;
// Construct via vector or implicitly via initializer list.
DebugSideTableEntry(int stack_height,
std::vector<DebugSideTable::Entry::Value> changed_values)
: stack_height(stack_height), changed_values(std::move(changed_values)) {}
DebugSideTableEntry(
int stack_height,
std::initializer_list<DebugSideTable::Entry::Value> changed_values)
: stack_height(stack_height), changed_values(changed_values) {}
bool operator==(const DebugSideTableEntry& other) const {
return stack_height == other.stack_height &&
std::equal(changed_values.begin(), changed_values.end(),
other.changed_values.begin(), other.changed_values.end(),
CheckValueEquals);
}
// Check for equality, but ignore exact register and stack offset.
static bool CheckValueEquals(const DebugSideTable::Entry::Value& a,
const DebugSideTable::Entry::Value& b) {
return a.index == b.index && a.type == b.type && a.storage == b.storage &&
(a.storage != DebugSideTable::Entry::kConstant ||
a.i32_const == b.i32_const);
}
};
// Debug builds will print the vector of DebugSideTableEntry.
#ifdef DEBUG
std::ostream& operator<<(std::ostream& out, const DebugSideTableEntry& entry) {
out << "stack height " << entry.stack_height << ", changed: {";
const char* comma = "";
for (auto& v : entry.changed_values) {
out << comma << v.index << ":" << v.type.name() << " ";
switch (v.storage) {
case DebugSideTable::Entry::kConstant:
out << "const:" << v.i32_const;
break;
case DebugSideTable::Entry::kRegister:
out << "reg";
break;
case DebugSideTable::Entry::kStack:
out << "stack";
break;
}
comma = ", ";
}
return out << "}";
}
std::ostream& operator<<(std::ostream& out,
const std::vector<DebugSideTableEntry>& entries) {
return out << PrintCollection(entries);
}
#endif // DEBUG
// Named constructors to make the tests more readable.
DebugSideTable::Entry::Value Constant(int index, ValueType type,
int32_t constant) {
DebugSideTable::Entry::Value value;
value.index = index;
value.type = type;
value.storage = DebugSideTable::Entry::kConstant;
value.i32_const = constant;
return value;
}
DebugSideTable::Entry::Value Register(int index, ValueType type) {
DebugSideTable::Entry::Value value;
value.index = index;
value.type = type;
value.storage = DebugSideTable::Entry::kRegister;
return value;
}
DebugSideTable::Entry::Value Stack(int index, ValueType type) {
DebugSideTable::Entry::Value value;
value.index = index;
value.type = type;
value.storage = DebugSideTable::Entry::kStack;
return value;
}
void CheckDebugSideTable(std::vector<DebugSideTableEntry> expected_entries,
const wasm::DebugSideTable* debug_side_table) {
std::vector<DebugSideTableEntry> entries;
for (auto& entry : debug_side_table->entries()) {
entries.emplace_back(
entry.stack_height(),
std::vector<DebugSideTable::Entry::Value>{
entry.changed_values().begin(), entry.changed_values().end()});
}
CHECK_EQ(expected_entries, entries);
}
} // namespace
TEST(Liftoff_deterministic_simple) {
LiftoffCompileEnvironment env;
env.CheckDeterministicCompilation(
{kWasmI32}, {kWasmI32, kWasmI32},
{WASM_I32_ADD(WASM_LOCAL_GET(0), WASM_LOCAL_GET(1))});
}
TEST(Liftoff_deterministic_call) {
LiftoffCompileEnvironment env;
env.CheckDeterministicCompilation(
{kWasmI32}, {kWasmI32},
{WASM_I32_ADD(WASM_CALL_FUNCTION(0, WASM_LOCAL_GET(0)),
WASM_LOCAL_GET(0))});
}
TEST(Liftoff_deterministic_indirect_call) {
LiftoffCompileEnvironment env;
env.CheckDeterministicCompilation(
{kWasmI32}, {kWasmI32},
{WASM_I32_ADD(WASM_CALL_INDIRECT(0, WASM_LOCAL_GET(0), WASM_I32V_1(47)),
WASM_LOCAL_GET(0))});
}
TEST(Liftoff_deterministic_loop) {
LiftoffCompileEnvironment env;
env.CheckDeterministicCompilation(
{kWasmI32}, {kWasmI32},
{WASM_LOOP(WASM_BR_IF(0, WASM_LOCAL_GET(0))), WASM_LOCAL_GET(0)});
}
TEST(Liftoff_deterministic_trap) {
LiftoffCompileEnvironment env;
env.CheckDeterministicCompilation(
{kWasmI32}, {kWasmI32, kWasmI32},
{WASM_I32_DIVS(WASM_LOCAL_GET(0), WASM_LOCAL_GET(1))});
}
TEST(Liftoff_debug_side_table_simple) {
LiftoffCompileEnvironment env;
auto debug_side_table = env.GenerateDebugSideTable(
{kWasmI32}, {kWasmI32, kWasmI32},
{WASM_I32_ADD(WASM_LOCAL_GET(0), WASM_LOCAL_GET(1))});
CheckDebugSideTable(
{
// function entry, locals in registers.
{2, {Register(0, kWasmI32), Register(1, kWasmI32)}},
// OOL stack check, locals spilled, stack still empty.
{2, {Stack(0, kWasmI32), Stack(1, kWasmI32)}},
},
debug_side_table.get());
}
TEST(Liftoff_debug_side_table_call) {
LiftoffCompileEnvironment env;
auto debug_side_table = env.GenerateDebugSideTable(
{kWasmI32}, {kWasmI32},
{WASM_I32_ADD(WASM_CALL_FUNCTION(0, WASM_LOCAL_GET(0)),
WASM_LOCAL_GET(0))});
CheckDebugSideTable(
{
// function entry, local in register.
{1, {Register(0, kWasmI32)}},
// call, local spilled, stack empty.
{1, {Stack(0, kWasmI32)}},
// OOL stack check, local spilled as before, stack empty.
{1, {}},
},
debug_side_table.get());
}
TEST(Liftoff_debug_side_table_call_const) {
LiftoffCompileEnvironment env;
constexpr int kConst = 13;
auto debug_side_table = env.GenerateDebugSideTable(
{kWasmI32}, {kWasmI32},
{WASM_LOCAL_SET(0, WASM_I32V_1(kConst)),
WASM_I32_ADD(WASM_CALL_FUNCTION(0, WASM_LOCAL_GET(0)),
WASM_LOCAL_GET(0))});
CheckDebugSideTable(
{
// function entry, local in register.
{1, {Register(0, kWasmI32)}},
// call, local is kConst.
{1, {Constant(0, kWasmI32, kConst)}},
// OOL stack check, local spilled.
{1, {Stack(0, kWasmI32)}},
},
debug_side_table.get());
}
TEST(Liftoff_debug_side_table_indirect_call) {
LiftoffCompileEnvironment env;
constexpr int kConst = 47;
auto debug_side_table = env.GenerateDebugSideTable(
{kWasmI32}, {kWasmI32},
{WASM_I32_ADD(WASM_CALL_INDIRECT(0, WASM_I32V_1(47), WASM_LOCAL_GET(0)),
WASM_LOCAL_GET(0))});
CheckDebugSideTable(
{
// function entry, local in register.
{1, {Register(0, kWasmI32)}},
// indirect call, local spilled, stack empty.
{1, {Stack(0, kWasmI32)}},
// OOL stack check, local still spilled.
{1, {}},
// OOL trap (invalid index), local still spilled, stack has {kConst}.
{2, {Constant(1, kWasmI32, kConst)}},
// OOL trap (sig mismatch), stack unmodified.
{2, {}},
},
debug_side_table.get());
}
TEST(Liftoff_debug_side_table_loop) {
LiftoffCompileEnvironment env;
constexpr int kConst = 42;
auto debug_side_table = env.GenerateDebugSideTable(
{kWasmI32}, {kWasmI32},
{WASM_I32V_1(kConst), WASM_LOOP(WASM_BR_IF(0, WASM_LOCAL_GET(0)))});
CheckDebugSideTable(
{
// function entry, local in register.
{1, {Register(0, kWasmI32)}},
// OOL stack check, local spilled, stack empty.
{1, {Stack(0, kWasmI32)}},
// OOL loop stack check, local still spilled, stack has {kConst}.
{2, {Constant(1, kWasmI32, kConst)}},
},
debug_side_table.get());
}
TEST(Liftoff_debug_side_table_trap) {
LiftoffCompileEnvironment env;
auto debug_side_table = env.GenerateDebugSideTable(
{kWasmI32}, {kWasmI32, kWasmI32},
{WASM_I32_DIVS(WASM_LOCAL_GET(0), WASM_LOCAL_GET(1))});
CheckDebugSideTable(
{
// function entry, locals in registers.
{2, {Register(0, kWasmI32), Register(1, kWasmI32)}},
// OOL stack check, local spilled, stack empty.
{2, {Stack(0, kWasmI32), Stack(1, kWasmI32)}},
// OOL trap (div by zero), stack as before.
{2, {}},
// OOL trap (unrepresentable), stack as before.
{2, {}},
},
debug_side_table.get());
}
TEST(Liftoff_breakpoint_simple) {
LiftoffCompileEnvironment env;
// Set two breakpoints. At both locations, values are live in registers.
auto debug_side_table = env.GenerateDebugSideTable(
{kWasmI32}, {kWasmI32, kWasmI32},
{WASM_I32_ADD(WASM_LOCAL_GET(0), WASM_LOCAL_GET(1))},
{
1, // break at beginning of function (first local.get)
5 // break at i32.add
});
CheckDebugSideTable(
{
// First break point, locals in registers.
{2, {Register(0, kWasmI32), Register(1, kWasmI32)}},
// Second break point, locals unchanged, two register stack values.
{4, {Register(2, kWasmI32), Register(3, kWasmI32)}},
// OOL stack check, locals spilled, stack empty.
{2, {Stack(0, kWasmI32), Stack(1, kWasmI32)}},
},
debug_side_table.get());
}
TEST(Liftoff_debug_side_table_catch_all) {
EXPERIMENTAL_FLAG_SCOPE(eh);
LiftoffCompileEnvironment env;
TestSignatures sigs;
int ex = env.builder()->AddException(sigs.v_v());
ValueType exception_type = ValueType::Ref(HeapType::kExtern, kNonNullable);
auto debug_side_table = env.GenerateDebugSideTable(
{}, {kWasmI32},
{WASM_TRY_CATCH_ALL_T(kWasmI32, WASM_STMTS(WASM_I32V(0), WASM_THROW(ex)),
WASM_I32V(1)),
WASM_DROP},
{
18 // Break at the end of the try block.
});
CheckDebugSideTable(
{
// function entry.
{1, {Register(0, kWasmI32)}},
// breakpoint.
{3,
{Stack(0, kWasmI32), Register(1, exception_type),
Constant(2, kWasmI32, 1)}},
{1, {}},
},
debug_side_table.get());
}
TEST(Regress1199526) {
EXPERIMENTAL_FLAG_SCOPE(eh);
LiftoffCompileEnvironment env;
ValueType exception_type = ValueType::Ref(HeapType::kExtern, kNonNullable);
auto debug_side_table = env.GenerateDebugSideTable(
{}, {},
{kExprTry, kVoidCode, kExprCallFunction, 0, kExprCatchAll, kExprLoop,
kVoidCode, kExprEnd, kExprEnd},
{});
CheckDebugSideTable(
{
// function entry.
{0, {}},
// break on entry.
{0, {}},
// function call.
{0, {}},
// loop stack check.
{1, {Stack(0, exception_type)}},
},
debug_side_table.get());
}
} // namespace wasm
} // namespace internal
} // namespace v8