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cobalt / cobalt / 3da06c67874e20fcbbefe517442f256057ad9e27 / . / src / third_party / v8 / src / wasm / wasm-debug.cc
blob: 5da55250457688d12e88783d85dd7c74fed82082 [file] [log] [blame]
// 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 "src/wasm/wasm-debug.h"
#include <iomanip>
#include <unordered_map>
#include "src/base/optional.h"
#include "src/codegen/assembler-inl.h"
#include "src/common/assert-scope.h"
#include "src/compiler/wasm-compiler.h"
#include "src/debug/debug-scopes.h"
#include "src/debug/debug.h"
#include "src/execution/frames-inl.h"
#include "src/execution/isolate.h"
#include "src/heap/factory.h"
#include "src/wasm/baseline/liftoff-compiler.h"
#include "src/wasm/baseline/liftoff-register.h"
#include "src/wasm/module-decoder.h"
#include "src/wasm/value-type.h"
#include "src/wasm/wasm-code-manager.h"
#include "src/wasm/wasm-limits.h"
#include "src/wasm/wasm-module.h"
#include "src/wasm/wasm-objects-inl.h"
#include "src/wasm/wasm-opcodes-inl.h"
#include "src/wasm/wasm-subtyping.h"
#include "src/wasm/wasm-value.h"
#include "src/zone/accounting-allocator.h"
namespace v8 {
namespace internal {
namespace wasm {
namespace {
template <bool internal, typename... Args>
Handle<String> PrintFToOneByteString(Isolate* isolate, const char* format,
Args... args) {
// Maximum length of a formatted value name ("arg#%d", "local#%d",
// "global#%d", i32 constants, i64 constants), including null character.
static constexpr int kMaxStrLen = 21;
EmbeddedVector<char, kMaxStrLen> value;
int len = SNPrintF(value, format, args...);
CHECK(len > 0 && len < value.length());
Vector<const uint8_t> name =
Vector<const uint8_t>::cast(value.SubVector(0, len));
return internal
? isolate->factory()->InternalizeString(name)
: isolate->factory()->NewStringFromOneByte(name).ToHandleChecked();
}
Handle<Object> WasmValueToValueObject(Isolate* isolate, WasmValue value) {
Handle<ByteArray> bytes;
switch (value.type().kind()) {
case ValueType::kI32: {
int32_t val = value.to_i32();
bytes = isolate->factory()->NewByteArray(sizeof(val));
memcpy(bytes->GetDataStartAddress(), &val, sizeof(val));
break;
}
case ValueType::kI64: {
int64_t val = value.to_i64();
bytes = isolate->factory()->NewByteArray(sizeof(val));
memcpy(bytes->GetDataStartAddress(), &val, sizeof(val));
break;
}
case ValueType::kF32: {
float val = value.to_f32();
bytes = isolate->factory()->NewByteArray(sizeof(val));
memcpy(bytes->GetDataStartAddress(), &val, sizeof(val));
break;
}
case ValueType::kF64: {
double val = value.to_f64();
bytes = isolate->factory()->NewByteArray(sizeof(val));
memcpy(bytes->GetDataStartAddress(), &val, sizeof(val));
break;
}
case ValueType::kS128: {
Simd128 s128 = value.to_s128();
bytes = isolate->factory()->NewByteArray(kSimd128Size);
memcpy(bytes->GetDataStartAddress(), s128.bytes(), kSimd128Size);
break;
}
case ValueType::kOptRef: {
if (value.type().is_reference_to(HeapType::kExtern)) {
return isolate->factory()->NewWasmValue(
static_cast<int32_t>(HeapType::kExtern), value.to_externref());
} else {
// TODO(7748): Implement.
UNIMPLEMENTED();
}
}
default: {
// TODO(7748): Implement.
UNIMPLEMENTED();
}
}
return isolate->factory()->NewWasmValue(
static_cast<int32_t>(value.type().kind()), bytes);
}
MaybeHandle<String> GetLocalNameString(Isolate* isolate,
NativeModule* native_module,
int func_index, int local_index) {
WireBytesRef name_ref =
native_module->GetDebugInfo()->GetLocalName(func_index, local_index);
ModuleWireBytes wire_bytes{native_module->wire_bytes()};
// Bounds were checked during decoding.
DCHECK(wire_bytes.BoundsCheck(name_ref));
WasmName name = wire_bytes.GetNameOrNull(name_ref);
if (name.size() == 0) return {};
return isolate->factory()->NewStringFromUtf8(name);
}
enum ReturnLocation { kAfterBreakpoint, kAfterWasmCall };
Address FindNewPC(WasmFrame* frame, WasmCode* wasm_code, int byte_offset,
ReturnLocation return_location) {
Vector<const uint8_t> new_pos_table = wasm_code->source_positions();
DCHECK_LE(0, byte_offset);
// Find the size of the call instruction by computing the distance from the
// source position entry to the return address.
WasmCode* old_code = frame->wasm_code();
int pc_offset = static_cast<int>(frame->pc() - old_code->instruction_start());
Vector<const uint8_t> old_pos_table = old_code->source_positions();
SourcePositionTableIterator old_it(old_pos_table);
int call_offset = -1;
while (!old_it.done() && old_it.code_offset() < pc_offset) {
call_offset = old_it.code_offset();
old_it.Advance();
}
DCHECK_LE(0, call_offset);
int call_instruction_size = pc_offset - call_offset;
// If {return_location == kAfterBreakpoint} we search for the first code
// offset which is marked as instruction (i.e. not the breakpoint).
// If {return_location == kAfterWasmCall} we return the last code offset
// associated with the byte offset.
SourcePositionTableIterator it(new_pos_table);
while (!it.done() && it.source_position().ScriptOffset() != byte_offset) {
it.Advance();
}
if (return_location == kAfterBreakpoint) {
while (!it.is_statement()) it.Advance();
DCHECK_EQ(byte_offset, it.source_position().ScriptOffset());
return wasm_code->instruction_start() + it.code_offset() +
call_instruction_size;
}
DCHECK_EQ(kAfterWasmCall, return_location);
int code_offset;
do {
code_offset = it.code_offset();
it.Advance();
} while (!it.done() && it.source_position().ScriptOffset() == byte_offset);
return wasm_code->instruction_start() + code_offset + call_instruction_size;
}
} // namespace
void DebugSideTable::Print(std::ostream& os) const {
os << "Debug side table (" << num_locals_ << " locals, " << entries_.size()
<< " entries):\n";
for (auto& entry : entries_) entry.Print(os);
os << "\n";
}
void DebugSideTable::Entry::Print(std::ostream& os) const {
os << std::setw(6) << std::hex << pc_offset_ << std::dec << " [";
for (auto& value : values_) {
os << " " << value.type.name() << ":";
switch (value.kind) {
case kConstant:
os << "const#" << value.i32_const;
break;
case kRegister:
os << "reg#" << value.reg_code;
break;
case kStack:
os << "stack#" << value.stack_offset;
break;
}
}
os << " ]\n";
}
Handle<JSObject> GetModuleScopeObject(Handle<WasmInstanceObject> instance) {
Isolate* isolate = instance->GetIsolate();
Handle<JSObject> module_scope_object =
isolate->factory()->NewJSObjectWithNullProto();
Handle<String> instance_name =
isolate->factory()->InternalizeString(StaticCharVector("instance"));
JSObject::AddProperty(isolate, module_scope_object, instance_name, instance,
NONE);
if (instance->has_memory_object()) {
Handle<String> name;
// TODO(duongn): extend the logic when multiple memories are supported.
const uint32_t memory_index = 0;
if (!WasmInstanceObject::GetMemoryNameOrNull(isolate, instance,
memory_index)
.ToHandle(&name)) {
const char* label = "memory%d";
name = PrintFToOneByteString<true>(isolate, label, memory_index);
}
Handle<JSArrayBuffer> memory_buffer(
instance->memory_object().array_buffer(), isolate);
Handle<JSTypedArray> uint8_array = isolate->factory()->NewJSTypedArray(
kExternalUint8Array, memory_buffer, 0, memory_buffer->byte_length());
JSObject::AddProperty(isolate, module_scope_object, name, uint8_array,
NONE);
}
auto& globals = instance->module()->globals;
if (globals.size() > 0) {
Handle<JSObject> globals_obj =
isolate->factory()->NewJSObjectWithNullProto();
Handle<String> globals_name =
isolate->factory()->InternalizeString(StaticCharVector("globals"));
JSObject::AddProperty(isolate, module_scope_object, globals_name,
globals_obj, NONE);
for (uint32_t i = 0; i < globals.size(); ++i) {
Handle<String> name;
if (!WasmInstanceObject::GetGlobalNameOrNull(isolate, instance, i)
.ToHandle(&name)) {
const char* label = "global%d";
name = PrintFToOneByteString<true>(isolate, label, i);
}
WasmValue value =
WasmInstanceObject::GetGlobalValue(instance, globals[i]);
Handle<Object> value_obj = WasmValueToValueObject(isolate, value);
JSObject::AddProperty(isolate, globals_obj, name, value_obj, NONE);
}
}
return module_scope_object;
}
class DebugInfoImpl {
public:
explicit DebugInfoImpl(NativeModule* native_module)
: native_module_(native_module) {}
DebugInfoImpl(const DebugInfoImpl&) = delete;
DebugInfoImpl& operator=(const DebugInfoImpl&) = delete;
int GetNumLocals(Address pc) {
FrameInspectionScope scope(this, pc);
if (!scope.is_inspectable()) return 0;
return scope.debug_side_table->num_locals();
}
WasmValue GetLocalValue(int local, Address pc, Address fp,
Address debug_break_fp) {
FrameInspectionScope scope(this, pc);
return GetValue(scope.debug_side_table_entry, local, fp, debug_break_fp);
}
int GetStackDepth(Address pc) {
FrameInspectionScope scope(this, pc);
if (!scope.is_inspectable()) return 0;
int num_locals = static_cast<int>(scope.debug_side_table->num_locals());
int value_count = scope.debug_side_table_entry->num_values();
return value_count - num_locals;
}
WasmValue GetStackValue(int index, Address pc, Address fp,
Address debug_break_fp) {
FrameInspectionScope scope(this, pc);
int num_locals = static_cast<int>(scope.debug_side_table->num_locals());
int value_count = scope.debug_side_table_entry->num_values();
if (num_locals + index >= value_count) return {};
return GetValue(scope.debug_side_table_entry, num_locals + index, fp,
debug_break_fp);
}
const WasmFunction& GetFunctionAtAddress(Address pc) {
FrameInspectionScope scope(this, pc);
auto* module = native_module_->module();
return module->functions[scope.code->index()];
}
Handle<JSObject> GetLocalScopeObject(Isolate* isolate, Address pc, Address fp,
Address debug_break_fp) {
FrameInspectionScope scope(this, pc);
Handle<JSObject> local_scope_object =
isolate->factory()->NewJSObjectWithNullProto();
if (!scope.is_inspectable()) return local_scope_object;
auto* module = native_module_->module();
auto* function = &module->functions[scope.code->index()];
// Fill parameters and locals.
int num_locals = static_cast<int>(scope.debug_side_table->num_locals());
DCHECK_LE(static_cast<int>(function->sig->parameter_count()), num_locals);
for (int i = 0; i < num_locals; ++i) {
Handle<Name> name;
if (!GetLocalNameString(isolate, native_module_, function->func_index, i)
.ToHandle(&name)) {
name = PrintFToOneByteString<true>(isolate, "var%d", i);
}
WasmValue value =
GetValue(scope.debug_side_table_entry, i, fp, debug_break_fp);
Handle<Object> value_obj = WasmValueToValueObject(isolate, value);
// {name} can be a string representation of an element index.
LookupIterator::Key lookup_key{isolate, name};
LookupIterator it(isolate, local_scope_object, lookup_key,
local_scope_object,
LookupIterator::OWN_SKIP_INTERCEPTOR);
if (it.IsFound()) continue;
Object::AddDataProperty(&it, value_obj, NONE,
Just(ShouldThrow::kThrowOnError),
StoreOrigin::kNamed)
.Check();
}
return local_scope_object;
}
Handle<JSObject> GetStackScopeObject(Isolate* isolate, Address pc, Address fp,
Address debug_break_fp) {
FrameInspectionScope scope(this, pc);
Handle<JSObject> stack_scope_obj =
isolate->factory()->NewJSObjectWithNullProto();
if (!scope.is_inspectable()) return stack_scope_obj;
// Fill stack values.
// Use an object without prototype instead of an Array, for nicer displaying
// in DevTools. For Arrays, the length field and prototype is displayed,
// which does not make too much sense here.
int num_locals = static_cast<int>(scope.debug_side_table->num_locals());
int value_count = scope.debug_side_table_entry->num_values();
for (int i = num_locals; i < value_count; ++i) {
WasmValue value =
GetValue(scope.debug_side_table_entry, i, fp, debug_break_fp);
Handle<Object> value_obj = WasmValueToValueObject(isolate, value);
JSObject::AddDataElement(stack_scope_obj,
static_cast<uint32_t>(i - num_locals), value_obj,
NONE);
}
return stack_scope_obj;
}
WireBytesRef GetLocalName(int func_index, int local_index) {
base::MutexGuard guard(&mutex_);
if (!local_names_) {
local_names_ = std::make_unique<LocalNames>(
DecodeLocalNames(native_module_->wire_bytes()));
}
return local_names_->GetName(func_index, local_index);
}
// If the top frame is a Wasm frame and its position is not in the list of
// breakpoints, return that position. Return 0 otherwise.
// This is used to generate a "dead breakpoint" in Liftoff, which is necessary
// for OSR to find the correct return address.
int DeadBreakpoint(int func_index, std::vector<int>& breakpoints,
Isolate* isolate) {
StackTraceFrameIterator it(isolate);
if (it.done() || !it.is_wasm()) return 0;
WasmFrame* frame = WasmFrame::cast(it.frame());
const auto& function = native_module_->module()->functions[func_index];
int offset = frame->position() - function.code.offset();
if (std::binary_search(breakpoints.begin(), breakpoints.end(), offset)) {
return 0;
}
return offset;
}
WasmCode* RecompileLiftoffWithBreakpoints(int func_index, Vector<int> offsets,
int dead_breakpoint) {
DCHECK(!mutex_.TryLock()); // Mutex is held externally.
// Recompile the function with Liftoff, setting the new breakpoints.
// Not thread-safe. The caller is responsible for locking {mutex_}.
CompilationEnv env = native_module_->CreateCompilationEnv();
auto* function = &native_module_->module()->functions[func_index];
Vector<const uint8_t> wire_bytes = native_module_->wire_bytes();
FunctionBody body{function->sig, function->code.offset(),
wire_bytes.begin() + function->code.offset(),
wire_bytes.begin() + function->code.end_offset()};
std::unique_ptr<DebugSideTable> debug_sidetable;
ForDebugging for_debugging = offsets.size() == 1 && offsets[0] == 0
? kForStepping
: kWithBreakpoints;
Counters* counters = nullptr;
WasmFeatures unused_detected;
WasmCompilationResult result = ExecuteLiftoffCompilation(
native_module_->engine()->allocator(), &env, body, func_index,
for_debugging, counters, &unused_detected, offsets, &debug_sidetable,
dead_breakpoint);
// Liftoff compilation failure is a FATAL error. We rely on complete Liftoff
// support for debugging.
if (!result.succeeded()) FATAL("Liftoff compilation failed");
DCHECK_NOT_NULL(debug_sidetable);
WasmCode* new_code = native_module_->PublishCode(
native_module_->AddCompiledCode(std::move(result)));
DCHECK(new_code->is_inspectable());
{
base::MutexGuard lock(&debug_side_tables_mutex_);
DCHECK_EQ(0, debug_side_tables_.count(new_code));
debug_side_tables_.emplace(new_code, std::move(debug_sidetable));
}
return new_code;
}
void SetBreakpoint(int func_index, int offset, Isolate* isolate) {
// Put the code ref scope outside of the mutex, so we don't unnecessarily
// hold the mutex while freeing code.
WasmCodeRefScope wasm_code_ref_scope;
// Hold the mutex while modifying breakpoints, to ensure consistency when
// multiple isolates set/remove breakpoints at the same time.
base::MutexGuard guard(&mutex_);
// offset == 0 indicates flooding and should not happen here.
DCHECK_NE(0, offset);
// Get the set of previously set breakpoints, to check later whether a new
// breakpoint was actually added.
std::vector<int> all_breakpoints = FindAllBreakpoints(func_index);
auto& isolate_data = per_isolate_data_[isolate];
std::vector<int>& breakpoints =
isolate_data.breakpoints_per_function[func_index];
auto insertion_point =
std::lower_bound(breakpoints.begin(), breakpoints.end(), offset);
if (insertion_point != breakpoints.end() && *insertion_point == offset) {
// The breakpoint is already set for this isolate.
return;
}
breakpoints.insert(insertion_point, offset);
DCHECK(std::is_sorted(all_breakpoints.begin(), all_breakpoints.end()));
// Find the insertion position within {all_breakpoints}.
insertion_point = std::lower_bound(all_breakpoints.begin(),
all_breakpoints.end(), offset);
bool breakpoint_exists =
insertion_point != all_breakpoints.end() && *insertion_point == offset;
// If the breakpoint was already set before, then we can just reuse the old
// code. Otherwise, recompile it. In any case, rewrite this isolate's stack
// to make sure that it uses up-to-date code containing the breakpoint.
WasmCode* new_code;
if (breakpoint_exists) {
new_code = native_module_->GetCode(func_index);
} else {
all_breakpoints.insert(insertion_point, offset);
int dead_breakpoint =
DeadBreakpoint(func_index, all_breakpoints, isolate);
new_code = RecompileLiftoffWithBreakpoints(
func_index, VectorOf(all_breakpoints), dead_breakpoint);
}
UpdateReturnAddresses(isolate, new_code, isolate_data.stepping_frame);
}
std::vector<int> FindAllBreakpoints(int func_index) {
DCHECK(!mutex_.TryLock()); // Mutex must be held externally.
std::set<int> breakpoints;
for (auto& data : per_isolate_data_) {
auto it = data.second.breakpoints_per_function.find(func_index);
if (it == data.second.breakpoints_per_function.end()) continue;
for (int offset : it->second) breakpoints.insert(offset);
}
return {breakpoints.begin(), breakpoints.end()};
}
void UpdateBreakpoints(int func_index, Vector<int> breakpoints,
Isolate* isolate, StackFrameId stepping_frame,
int dead_breakpoint) {
DCHECK(!mutex_.TryLock()); // Mutex is held externally.
WasmCode* new_code = RecompileLiftoffWithBreakpoints(
func_index, breakpoints, dead_breakpoint);
UpdateReturnAddresses(isolate, new_code, stepping_frame);
}
void FloodWithBreakpoints(WasmFrame* frame, ReturnLocation return_location) {
// 0 is an invalid offset used to indicate flooding.
int offset = 0;
WasmCodeRefScope wasm_code_ref_scope;
DCHECK(frame->wasm_code()->is_liftoff());
// Generate an additional source position for the current byte offset.
base::MutexGuard guard(&mutex_);
WasmCode* new_code = RecompileLiftoffWithBreakpoints(
frame->function_index(), VectorOf(&offset, 1), 0);
UpdateReturnAddress(frame, new_code, return_location);
}
void PrepareStep(Isolate* isolate, StackFrameId break_frame_id) {
StackTraceFrameIterator it(isolate, break_frame_id);
DCHECK(!it.done());
DCHECK(it.frame()->is_wasm());
WasmFrame* frame = WasmFrame::cast(it.frame());
StepAction step_action = isolate->debug()->last_step_action();
// If we are flooding the top frame, the return location is after a
// breakpoints. Otherwise, it's after a call.
ReturnLocation return_location = kAfterBreakpoint;
// If we are at a return instruction, then any stepping action is equivalent
// to StepOut, and we need to flood the parent function.
if (IsAtReturn(frame) || step_action == StepOut) {
it.Advance();
if (it.done() || !it.frame()->is_wasm()) return;
frame = WasmFrame::cast(it.frame());
return_location = kAfterWasmCall;
}
FloodWithBreakpoints(frame, return_location);
base::MutexGuard guard(&mutex_);
per_isolate_data_[isolate].stepping_frame = frame->id();
}
void ClearStepping(Isolate* isolate) {
base::MutexGuard guard(&mutex_);
auto it = per_isolate_data_.find(isolate);
if (it != per_isolate_data_.end()) it->second.stepping_frame = NO_ID;
}
bool IsStepping(WasmFrame* frame) {
Isolate* isolate = frame->wasm_instance().GetIsolate();
if (isolate->debug()->last_step_action() == StepIn) return true;
base::MutexGuard guard(&mutex_);
auto it = per_isolate_data_.find(isolate);
return it != per_isolate_data_.end() &&
it->second.stepping_frame == frame->id();
}
void RemoveBreakpoint(int func_index, int position, Isolate* isolate) {
// Put the code ref scope outside of the mutex, so we don't unnecessarily
// hold the mutex while freeing code.
WasmCodeRefScope wasm_code_ref_scope;
// Hold the mutex while modifying breakpoints, to ensure consistency when
// multiple isolates set/remove breakpoints at the same time.
base::MutexGuard guard(&mutex_);
const auto& function = native_module_->module()->functions[func_index];
int offset = position - function.code.offset();
auto& isolate_data = per_isolate_data_[isolate];
std::vector<int>& breakpoints =
isolate_data.breakpoints_per_function[func_index];
DCHECK_LT(0, offset);
auto insertion_point =
std::lower_bound(breakpoints.begin(), breakpoints.end(), offset);
if (insertion_point == breakpoints.end()) return;
if (*insertion_point != offset) return;
breakpoints.erase(insertion_point);
std::vector<int> remaining = FindAllBreakpoints(func_index);
// If the breakpoint is still set in another isolate, don't remove it.
DCHECK(std::is_sorted(remaining.begin(), remaining.end()));
if (std::binary_search(remaining.begin(), remaining.end(), offset)) return;
int dead_breakpoint = DeadBreakpoint(func_index, remaining, isolate);
UpdateBreakpoints(func_index, VectorOf(remaining), isolate,
isolate_data.stepping_frame, dead_breakpoint);
}
void RemoveDebugSideTables(Vector<WasmCode* const> codes) {
base::MutexGuard guard(&debug_side_tables_mutex_);
for (auto* code : codes) {
debug_side_tables_.erase(code);
}
}
DebugSideTable* GetDebugSideTableIfExists(const WasmCode* code) const {
base::MutexGuard guard(&debug_side_tables_mutex_);
auto it = debug_side_tables_.find(code);
return it == debug_side_tables_.end() ? nullptr : it->second.get();
}
static bool HasRemovedBreakpoints(const std::vector<int>& removed,
const std::vector<int>& remaining) {
DCHECK(std::is_sorted(remaining.begin(), remaining.end()));
for (int offset : removed) {
// Return true if we removed a breakpoint which is not part of remaining.
if (!std::binary_search(remaining.begin(), remaining.end(), offset)) {
return true;
}
}
return false;
}
void RemoveIsolate(Isolate* isolate) {
// Put the code ref scope outside of the mutex, so we don't unnecessarily
// hold the mutex while freeing code.
WasmCodeRefScope wasm_code_ref_scope;
base::MutexGuard guard(&mutex_);
auto per_isolate_data_it = per_isolate_data_.find(isolate);
if (per_isolate_data_it == per_isolate_data_.end()) return;
std::unordered_map<int, std::vector<int>> removed_per_function =
std::move(per_isolate_data_it->second.breakpoints_per_function);
per_isolate_data_.erase(per_isolate_data_it);
for (auto& entry : removed_per_function) {
int func_index = entry.first;
std::vector<int>& removed = entry.second;
std::vector<int> remaining = FindAllBreakpoints(func_index);
if (HasRemovedBreakpoints(removed, remaining)) {
RecompileLiftoffWithBreakpoints(func_index, VectorOf(remaining), 0);
}
}
}
private:
struct FrameInspectionScope {
FrameInspectionScope(DebugInfoImpl* debug_info, Address pc)
: code(debug_info->native_module_->engine()->code_manager()->LookupCode(
pc)),
pc_offset(static_cast<int>(pc - code->instruction_start())),
debug_side_table(
code->is_inspectable()
? debug_info->GetDebugSideTable(
code, debug_info->native_module_->engine()->allocator())
: nullptr),
debug_side_table_entry(debug_side_table
? debug_side_table->GetEntry(pc_offset)
: nullptr) {
DCHECK_IMPLIES(code->is_inspectable(), debug_side_table_entry != nullptr);
}
bool is_inspectable() const { return debug_side_table_entry; }
wasm::WasmCodeRefScope wasm_code_ref_scope;
wasm::WasmCode* code;
int pc_offset;
const DebugSideTable* debug_side_table;
const DebugSideTable::Entry* debug_side_table_entry;
};
const DebugSideTable* GetDebugSideTable(WasmCode* code,
AccountingAllocator* allocator) {
DCHECK(code->is_inspectable());
{
// Only hold the mutex temporarily. We can't hold it while generating the
// debug side table, because compilation takes the {NativeModule} lock.
base::MutexGuard guard(&debug_side_tables_mutex_);
auto it = debug_side_tables_.find(code);
if (it != debug_side_tables_.end()) return it->second.get();
}
// Otherwise create the debug side table now.
auto* module = native_module_->module();
auto* function = &module->functions[code->index()];
ModuleWireBytes wire_bytes{native_module_->wire_bytes()};
Vector<const byte> function_bytes = wire_bytes.GetFunctionBytes(function);
CompilationEnv env = native_module_->CreateCompilationEnv();
FunctionBody func_body{function->sig, 0, function_bytes.begin(),
function_bytes.end()};
std::unique_ptr<DebugSideTable> debug_side_table =
GenerateLiftoffDebugSideTable(allocator, &env, func_body,
code->index());
DebugSideTable* ret = debug_side_table.get();
// Check cache again, maybe another thread concurrently generated a debug
// side table already.
{
base::MutexGuard guard(&debug_side_tables_mutex_);
auto& slot = debug_side_tables_[code];
if (slot != nullptr) return slot.get();
slot = std::move(debug_side_table);
}
// Print the code together with the debug table, if requested.
code->MaybePrint();
return ret;
}
// Get the value of a local (including parameters) or stack value. Stack
// values follow the locals in the same index space.
WasmValue GetValue(const DebugSideTable::Entry* debug_side_table_entry,
int index, Address stack_frame_base,
Address debug_break_fp) const {
ValueType type = debug_side_table_entry->value_type(index);
if (debug_side_table_entry->is_constant(index)) {
DCHECK(type == kWasmI32 || type == kWasmI64);
return type == kWasmI32
? WasmValue(debug_side_table_entry->i32_constant(index))
: WasmValue(
int64_t{debug_side_table_entry->i32_constant(index)});
}
if (debug_side_table_entry->is_register(index)) {
LiftoffRegister reg = LiftoffRegister::from_liftoff_code(
debug_side_table_entry->register_code(index));
auto gp_addr = [debug_break_fp](Register reg) {
return debug_break_fp +
WasmDebugBreakFrameConstants::GetPushedGpRegisterOffset(
reg.code());
};
if (reg.is_gp_pair()) {
DCHECK_EQ(kWasmI64, type);
uint32_t low_word = ReadUnalignedValue<uint32_t>(gp_addr(reg.low_gp()));
uint32_t high_word =
ReadUnalignedValue<uint32_t>(gp_addr(reg.high_gp()));
return WasmValue((uint64_t{high_word} << 32) | low_word);
}
if (reg.is_gp()) {
return type == kWasmI32
? WasmValue(ReadUnalignedValue<uint32_t>(gp_addr(reg.gp())))
: WasmValue(ReadUnalignedValue<uint64_t>(gp_addr(reg.gp())));
}
DCHECK(reg.is_fp() || reg.is_fp_pair());
// ifdef here to workaround unreachable code for is_fp_pair.
#ifdef V8_TARGET_ARCH_ARM
int code = reg.is_fp_pair() ? reg.low_fp().code() : reg.fp().code();
#else
int code = reg.fp().code();
#endif
Address spilled_addr =
debug_break_fp +
WasmDebugBreakFrameConstants::GetPushedFpRegisterOffset(code);
if (type == kWasmF32) {
return WasmValue(ReadUnalignedValue<float>(spilled_addr));
} else if (type == kWasmF64) {
return WasmValue(ReadUnalignedValue<double>(spilled_addr));
} else if (type == kWasmS128) {
return WasmValue(Simd128(ReadUnalignedValue<int16>(spilled_addr)));
} else {
// All other cases should have been handled above.
UNREACHABLE();
}
}
// Otherwise load the value from the stack.
Address stack_address =
stack_frame_base - debug_side_table_entry->stack_offset(index);
switch (type.kind()) {
case ValueType::kI32:
return WasmValue(ReadUnalignedValue<int32_t>(stack_address));
case ValueType::kI64:
return WasmValue(ReadUnalignedValue<int64_t>(stack_address));
case ValueType::kF32:
return WasmValue(ReadUnalignedValue<float>(stack_address));
case ValueType::kF64:
return WasmValue(ReadUnalignedValue<double>(stack_address));
case ValueType::kS128: {
return WasmValue(Simd128(ReadUnalignedValue<int16>(stack_address)));
}
default:
UNIMPLEMENTED();
}
}
// After installing a Liftoff code object with a different set of breakpoints,
// update return addresses on the stack so that execution resumes in the new
// code. The frame layout itself should be independent of breakpoints.
void UpdateReturnAddresses(Isolate* isolate, WasmCode* new_code,
StackFrameId stepping_frame) {
// The first return location is after the breakpoint, others are after wasm
// calls.
ReturnLocation return_location = kAfterBreakpoint;
for (StackTraceFrameIterator it(isolate); !it.done();
it.Advance(), return_location = kAfterWasmCall) {
// We still need the flooded function for stepping.
if (it.frame()->id() == stepping_frame) continue;
if (!it.is_wasm()) continue;
WasmFrame* frame = WasmFrame::cast(it.frame());
if (frame->native_module() != new_code->native_module()) continue;
if (frame->function_index() != new_code->index()) continue;
if (!frame->wasm_code()->is_liftoff()) continue;
UpdateReturnAddress(frame, new_code, return_location);
}
}
void UpdateReturnAddress(WasmFrame* frame, WasmCode* new_code,
ReturnLocation return_location) {
DCHECK(new_code->is_liftoff());
DCHECK_EQ(frame->function_index(), new_code->index());
DCHECK_EQ(frame->native_module(), new_code->native_module());
DCHECK(frame->wasm_code()->is_liftoff());
#ifdef DEBUG
int old_position = frame->position();
#endif
Address new_pc =
FindNewPC(frame, new_code, frame->byte_offset(), return_location);
PointerAuthentication::ReplacePC(frame->pc_address(), new_pc,
kSystemPointerSize);
// The frame position should still be the same after OSR.
DCHECK_EQ(old_position, frame->position());
}
bool IsAtReturn(WasmFrame* frame) {
DisallowHeapAllocation no_gc;
int position = frame->position();
NativeModule* native_module =
frame->wasm_instance().module_object().native_module();
uint8_t opcode = native_module->wire_bytes()[position];
if (opcode == kExprReturn) return true;
// Another implicit return is at the last kExprEnd in the function body.
int func_index = frame->function_index();
WireBytesRef code = native_module->module()->functions[func_index].code;
return static_cast<size_t>(position) == code.end_offset() - 1;
}
// Isolate-specific data, for debugging modules that are shared by multiple
// isolates.
struct PerIsolateDebugData {
// Keeps track of the currently set breakpoints (by offset within that
// function).
std::unordered_map<int, std::vector<int>> breakpoints_per_function;
// Store the frame ID when stepping, to avoid overwriting that frame when
// setting or removing a breakpoint.
StackFrameId stepping_frame = NO_ID;
};
NativeModule* const native_module_;
mutable base::Mutex debug_side_tables_mutex_;
// DebugSideTable per code object, lazily initialized.
std::unordered_map<const WasmCode*, std::unique_ptr<DebugSideTable>>
debug_side_tables_;
// {mutex_} protects all fields below.
mutable base::Mutex mutex_;
// Names of locals, lazily decoded from the wire bytes.
std::unique_ptr<LocalNames> local_names_;
// Isolate-specific data.
std::unordered_map<Isolate*, PerIsolateDebugData> per_isolate_data_;
};
DebugInfo::DebugInfo(NativeModule* native_module)
: impl_(std::make_unique<DebugInfoImpl>(native_module)) {}
DebugInfo::~DebugInfo() = default;
int DebugInfo::GetNumLocals(Address pc) { return impl_->GetNumLocals(pc); }
WasmValue DebugInfo::GetLocalValue(int local, Address pc, Address fp,
Address debug_break_fp) {
return impl_->GetLocalValue(local, pc, fp, debug_break_fp);
}
int DebugInfo::GetStackDepth(Address pc) { return impl_->GetStackDepth(pc); }
WasmValue DebugInfo::GetStackValue(int index, Address pc, Address fp,
Address debug_break_fp) {
return impl_->GetStackValue(index, pc, fp, debug_break_fp);
}
const wasm::WasmFunction& DebugInfo::GetFunctionAtAddress(Address pc) {
return impl_->GetFunctionAtAddress(pc);
}
Handle<JSObject> DebugInfo::GetLocalScopeObject(Isolate* isolate, Address pc,
Address fp,
Address debug_break_fp) {
return impl_->GetLocalScopeObject(isolate, pc, fp, debug_break_fp);
}
Handle<JSObject> DebugInfo::GetStackScopeObject(Isolate* isolate, Address pc,
Address fp,
Address debug_break_fp) {
return impl_->GetStackScopeObject(isolate, pc, fp, debug_break_fp);
}
WireBytesRef DebugInfo::GetLocalName(int func_index, int local_index) {
return impl_->GetLocalName(func_index, local_index);
}
void DebugInfo::SetBreakpoint(int func_index, int offset,
Isolate* current_isolate) {
impl_->SetBreakpoint(func_index, offset, current_isolate);
}
void DebugInfo::PrepareStep(Isolate* isolate, StackFrameId break_frame_id) {
impl_->PrepareStep(isolate, break_frame_id);
}
void DebugInfo::ClearStepping(Isolate* isolate) {
impl_->ClearStepping(isolate);
}
bool DebugInfo::IsStepping(WasmFrame* frame) {
return impl_->IsStepping(frame);
}
void DebugInfo::RemoveBreakpoint(int func_index, int offset,
Isolate* current_isolate) {
impl_->RemoveBreakpoint(func_index, offset, current_isolate);
}
void DebugInfo::RemoveDebugSideTables(Vector<WasmCode* const> code) {
impl_->RemoveDebugSideTables(code);
}
DebugSideTable* DebugInfo::GetDebugSideTableIfExists(
const WasmCode* code) const {
return impl_->GetDebugSideTableIfExists(code);
}
void DebugInfo::RemoveIsolate(Isolate* isolate) {
return impl_->RemoveIsolate(isolate);
}
} // namespace wasm
namespace {
// Return the next breakable position at or after {offset_in_func} in function
// {func_index}, or 0 if there is none.
// Note that 0 is never a breakable position in wasm, since the first byte
// contains the locals count for the function.
int FindNextBreakablePosition(wasm::NativeModule* native_module, int func_index,
int offset_in_func) {
AccountingAllocator alloc;
Zone tmp(&alloc, ZONE_NAME);
wasm::BodyLocalDecls locals(&tmp);
const byte* module_start = native_module->wire_bytes().begin();
const wasm::WasmFunction& func =
native_module->module()->functions[func_index];
wasm::BytecodeIterator iterator(module_start + func.code.offset(),
module_start + func.code.end_offset(),
&locals);
DCHECK_LT(0, locals.encoded_size);
if (offset_in_func < 0) return 0;
for (; iterator.has_next(); iterator.next()) {
if (iterator.pc_offset() < static_cast<uint32_t>(offset_in_func)) continue;
if (!wasm::WasmOpcodes::IsBreakable(iterator.current())) continue;
return static_cast<int>(iterator.pc_offset());
}
return 0;
}
} // namespace
// static
bool WasmScript::SetBreakPoint(Handle<Script> script, int* position,
Handle<BreakPoint> break_point) {
// Find the function for this breakpoint.
const wasm::WasmModule* module = script->wasm_native_module()->module();
int func_index = GetContainingWasmFunction(module, *position);
if (func_index < 0) return false;
const wasm::WasmFunction& func = module->functions[func_index];
int offset_in_func = *position - func.code.offset();
int breakable_offset = FindNextBreakablePosition(script->wasm_native_module(),
func_index, offset_in_func);
if (breakable_offset == 0) return false;
*position = func.code.offset() + breakable_offset;
return WasmScript::SetBreakPointForFunction(script, func_index,
breakable_offset, break_point);
}
// static
bool WasmScript::SetBreakPointOnFirstBreakableForFunction(
Handle<Script> script, int func_index, Handle<BreakPoint> break_point) {
if (func_index < 0) return false;
int offset_in_func = 0;
int breakable_offset = FindNextBreakablePosition(script->wasm_native_module(),
func_index, offset_in_func);
if (breakable_offset == 0) return false;
return WasmScript::SetBreakPointForFunction(script, func_index,
breakable_offset, break_point);
}
// static
bool WasmScript::SetBreakPointForFunction(Handle<Script> script, int func_index,
int offset,
Handle<BreakPoint> break_point) {
Isolate* isolate = script->GetIsolate();
DCHECK_LE(0, func_index);
DCHECK_NE(0, offset);
// Find the function for this breakpoint.
wasm::NativeModule* native_module = script->wasm_native_module();
const wasm::WasmModule* module = native_module->module();
const wasm::WasmFunction& func = module->functions[func_index];
// Insert new break point into {wasm_breakpoint_infos} of the script.
WasmScript::AddBreakpointToInfo(script, func.code.offset() + offset,
break_point);
native_module->GetDebugInfo()->SetBreakpoint(func_index, offset, isolate);
return true;
}
namespace {
int GetBreakpointPos(Isolate* isolate, Object break_point_info_or_undef) {
if (break_point_info_or_undef.IsUndefined(isolate)) return kMaxInt;
return BreakPointInfo::cast(break_point_info_or_undef).source_position();
}
int FindBreakpointInfoInsertPos(Isolate* isolate,
Handle<FixedArray> breakpoint_infos,
int position) {
// Find insert location via binary search, taking care of undefined values on
// the right. Position is always greater than zero.
DCHECK_LT(0, position);
int left = 0; // inclusive
int right = breakpoint_infos->length(); // exclusive
while (right - left > 1) {
int mid = left + (right - left) / 2;
Object mid_obj = breakpoint_infos->get(mid);
if (GetBreakpointPos(isolate, mid_obj) <= position) {
left = mid;
} else {
right = mid;
}
}
int left_pos = GetBreakpointPos(isolate, breakpoint_infos->get(left));
return left_pos < position ? left + 1 : left;
}
} // namespace
// static
bool WasmScript::ClearBreakPoint(Handle<Script> script, int position,
Handle<BreakPoint> break_point) {
if (!script->has_wasm_breakpoint_infos()) return false;
Isolate* isolate = script->GetIsolate();
Handle<FixedArray> breakpoint_infos(script->wasm_breakpoint_infos(), isolate);
int pos = FindBreakpointInfoInsertPos(isolate, breakpoint_infos, position);
// Does a BreakPointInfo object already exist for this position?
if (pos == breakpoint_infos->length()) return false;
Handle<BreakPointInfo> info(BreakPointInfo::cast(breakpoint_infos->get(pos)),
isolate);
BreakPointInfo::ClearBreakPoint(isolate, info, break_point);
// Check if there are no more breakpoints at this location.
if (info->GetBreakPointCount(isolate) == 0) {
// Update array by moving breakpoints up one position.
for (int i = pos; i < breakpoint_infos->length() - 1; i++) {
Object entry = breakpoint_infos->get(i + 1);
breakpoint_infos->set(i, entry);
if (entry.IsUndefined(isolate)) break;
}
// Make sure last array element is empty as a result.
breakpoint_infos->set_undefined(breakpoint_infos->length() - 1);
}
// Remove the breakpoint from DebugInfo and recompile.
wasm::NativeModule* native_module = script->wasm_native_module();
const wasm::WasmModule* module = native_module->module();
int func_index = GetContainingWasmFunction(module, position);
native_module->GetDebugInfo()->RemoveBreakpoint(func_index, position,
isolate);
return true;
}
// static
bool WasmScript::ClearBreakPointById(Handle<Script> script, int breakpoint_id) {
if (!script->has_wasm_breakpoint_infos()) {
return false;
}
Isolate* isolate = script->GetIsolate();
Handle<FixedArray> breakpoint_infos(script->wasm_breakpoint_infos(), isolate);
// If the array exists, it should not be empty.
DCHECK_LT(0, breakpoint_infos->length());
for (int i = 0, e = breakpoint_infos->length(); i < e; ++i) {
Handle<Object> obj(breakpoint_infos->get(i), isolate);
if (obj->IsUndefined(isolate)) {
continue;
}
Handle<BreakPointInfo> breakpoint_info = Handle<BreakPointInfo>::cast(obj);
Handle<BreakPoint> breakpoint;
if (BreakPointInfo::GetBreakPointById(isolate, breakpoint_info,
breakpoint_id)
.ToHandle(&breakpoint)) {
DCHECK(breakpoint->id() == breakpoint_id);
return WasmScript::ClearBreakPoint(
script, breakpoint_info->source_position(), breakpoint);
}
}
return false;
}
// static
void WasmScript::ClearAllBreakpoints(Script script) {
script.set_wasm_breakpoint_infos(
ReadOnlyRoots(script.GetIsolate()).empty_fixed_array());
}
// static
void WasmScript::AddBreakpointToInfo(Handle<Script> script, int position,
Handle<BreakPoint> break_point) {
Isolate* isolate = script->GetIsolate();
Handle<FixedArray> breakpoint_infos;
if (script->has_wasm_breakpoint_infos()) {
breakpoint_infos = handle(script->wasm_breakpoint_infos(), isolate);
} else {
breakpoint_infos =
isolate->factory()->NewFixedArray(4, AllocationType::kOld);
script->set_wasm_breakpoint_infos(*breakpoint_infos);
}
int insert_pos =
FindBreakpointInfoInsertPos(isolate, breakpoint_infos, position);
// If a BreakPointInfo object already exists for this position, add the new
// breakpoint object and return.
if (insert_pos < breakpoint_infos->length() &&
GetBreakpointPos(isolate, breakpoint_infos->get(insert_pos)) ==
position) {
Handle<BreakPointInfo> old_info(
BreakPointInfo::cast(breakpoint_infos->get(insert_pos)), isolate);
BreakPointInfo::SetBreakPoint(isolate, old_info, break_point);
return;
}
// Enlarge break positions array if necessary.
bool need_realloc = !breakpoint_infos->get(breakpoint_infos->length() - 1)
.IsUndefined(isolate);
Handle<FixedArray> new_breakpoint_infos = breakpoint_infos;
if (need_realloc) {
new_breakpoint_infos = isolate->factory()->NewFixedArray(
2 * breakpoint_infos->length(), AllocationType::kOld);
script->set_wasm_breakpoint_infos(*new_breakpoint_infos);
// Copy over the entries [0, insert_pos).
for (int i = 0; i < insert_pos; ++i)
new_breakpoint_infos->set(i, breakpoint_infos->get(i));
}
// Move elements [insert_pos, ...] up by one.
for (int i = breakpoint_infos->length() - 1; i >= insert_pos; --i) {
Object entry = breakpoint_infos->get(i);
if (entry.IsUndefined(isolate)) continue;
new_breakpoint_infos->set(i + 1, entry);
}
// Generate new BreakpointInfo.
Handle<BreakPointInfo> breakpoint_info =
isolate->factory()->NewBreakPointInfo(position);
BreakPointInfo::SetBreakPoint(isolate, breakpoint_info, break_point);
// Now insert new position at insert_pos.
new_breakpoint_infos->set(insert_pos, *breakpoint_info);
}
// static
bool WasmScript::GetPossibleBreakpoints(
wasm::NativeModule* native_module, const v8::debug::Location& start,
const v8::debug::Location& end,
std::vector<v8::debug::BreakLocation>* locations) {
DisallowHeapAllocation no_gc;
const wasm::WasmModule* module = native_module->module();
const std::vector<wasm::WasmFunction>& functions = module->functions;
if (start.GetLineNumber() != 0 || start.GetColumnNumber() < 0 ||
(!end.IsEmpty() &&
(end.GetLineNumber() != 0 || end.GetColumnNumber() < 0 ||
end.GetColumnNumber() < start.GetColumnNumber())))
return false;
// start_func_index, start_offset and end_func_index is inclusive.
// end_offset is exclusive.
// start_offset and end_offset are module-relative byte offsets.
// We set strict to false because offsets may be between functions.
int start_func_index =
GetNearestWasmFunction(module, start.GetColumnNumber());
if (start_func_index < 0) return false;
uint32_t start_offset = start.GetColumnNumber();
int end_func_index;
uint32_t end_offset;
if (end.IsEmpty()) {
// Default: everything till the end of the Script.
end_func_index = static_cast<uint32_t>(functions.size() - 1);
end_offset = functions[end_func_index].code.end_offset();
} else {
// If end is specified: Use it and check for valid input.
end_offset = end.GetColumnNumber();
end_func_index = GetNearestWasmFunction(module, end_offset);
DCHECK_GE(end_func_index, start_func_index);
}
if (start_func_index == end_func_index &&
start_offset > functions[end_func_index].code.end_offset())
return false;
AccountingAllocator alloc;
Zone tmp(&alloc, ZONE_NAME);
const byte* module_start = native_module->wire_bytes().begin();
for (int func_idx = start_func_index; func_idx <= end_func_index;
++func_idx) {
const wasm::WasmFunction& func = functions[func_idx];
if (func.code.length() == 0) continue;
wasm::BodyLocalDecls locals(&tmp);
wasm::BytecodeIterator iterator(module_start + func.code.offset(),
module_start + func.code.end_offset(),
&locals);
DCHECK_LT(0u, locals.encoded_size);
for (; iterator.has_next(); iterator.next()) {
uint32_t total_offset = func.code.offset() + iterator.pc_offset();
if (total_offset >= end_offset) {
DCHECK_EQ(end_func_index, func_idx);
break;
}
if (total_offset < start_offset) continue;
if (!wasm::WasmOpcodes::IsBreakable(iterator.current())) continue;
locations->emplace_back(0, total_offset, debug::kCommonBreakLocation);
}
}
return true;
}
// static
MaybeHandle<FixedArray> WasmScript::CheckBreakPoints(Isolate* isolate,
Handle<Script> script,
int position) {
if (!script->has_wasm_breakpoint_infos()) return {};
Handle<FixedArray> breakpoint_infos(script->wasm_breakpoint_infos(), isolate);
int insert_pos =
FindBreakpointInfoInsertPos(isolate, breakpoint_infos, position);
if (insert_pos >= breakpoint_infos->length()) return {};
Handle<Object> maybe_breakpoint_info(breakpoint_infos->get(insert_pos),
isolate);
if (maybe_breakpoint_info->IsUndefined(isolate)) return {};
Handle<BreakPointInfo> breakpoint_info =
Handle<BreakPointInfo>::cast(maybe_breakpoint_info);
if (breakpoint_info->source_position() != position) return {};
// There is no support for conditional break points. Just assume that every
// break point always hits.
Handle<Object> break_points(breakpoint_info->break_points(), isolate);
if (break_points->IsFixedArray()) {
return Handle<FixedArray>::cast(break_points);
}
Handle<FixedArray> break_points_hit = isolate->factory()->NewFixedArray(1);
break_points_hit->set(0, *break_points);
return break_points_hit;
}
} // namespace internal
} // namespace v8