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dart / sdk.git / refs/tags/1.9.0-dev.8.0 / . / runtime / vm / il_printer.cc
blob: c94497a5d146fa9f4e8fca4b69ba95465db71cd9 [file] [log] [blame]
// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#include "vm/il_printer.h"
#include "vm/flow_graph_range_analysis.h"
#include "vm/intermediate_language.h"
#include "vm/os.h"
#include "vm/parser.h"
namespace dart {
DEFINE_FLAG(bool, print_environments, false, "Print SSA environments.");
DEFINE_FLAG(charp, print_flow_graph_filter, NULL,
"Print only IR of functions with matching names");
void BufferFormatter::Print(const char* format, ...) {
va_list args;
va_start(args, format);
VPrint(format, args);
va_end(args);
}
void BufferFormatter::VPrint(const char* format, va_list args) {
intptr_t available = size_ - position_;
if (available <= 0) return;
intptr_t written =
OS::VSNPrint(buffer_ + position_, available, format, args);
if (written >= 0) {
position_ += (available <= written) ? available : written;
}
}
// Checks whether function's name matches the given filter, which is
// a comma-separated list of strings.
bool FlowGraphPrinter::PassesFilter(const char* filter,
const Function& function) {
if (filter == NULL) {
return true;
}
char* save_ptr; // Needed for strtok_r.
const char* function_name = function.ToFullyQualifiedCString();
intptr_t function_name_len = strlen(function_name);
intptr_t len = strlen(filter) + 1; // Length with \0.
char* filter_buffer = new char[len];
strncpy(filter_buffer, filter, len); // strtok modifies arg 1.
char* token = strtok_r(filter_buffer, ",", &save_ptr);
bool found = false;
while (token != NULL) {
if (strstr(function_name, token) != NULL) {
found = true;
break;
}
const intptr_t token_len = strlen(token);
if (token[token_len - 1] == '%') {
if (function_name_len > token_len) {
const char* suffix = function_name +
(function_name_len - token_len + 1);
if (strncmp(suffix, token, token_len - 1) == 0) {
found = true;
break;
}
}
}
token = strtok_r(NULL, ",", &save_ptr);
}
delete[] filter_buffer;
return found;
}
bool FlowGraphPrinter::ShouldPrint(const Function& function) {
return PassesFilter(FLAG_print_flow_graph_filter, function);
}
void FlowGraphPrinter::PrintGraph(const char* phase, FlowGraph* flow_graph) {
LogBlock lb(Isolate::Current());
ISL_Print("*** BEGIN CFG\n%s\n", phase);
FlowGraphPrinter printer(*flow_graph);
printer.PrintBlocks();
ISL_Print("*** END CFG\n");
fflush(stdout);
}
void FlowGraphPrinter::PrintBlock(BlockEntryInstr* block,
bool print_locations) {
// Print the block entry.
PrintOneInstruction(block, print_locations);
ISL_Print("\n");
// And all the successors in the block.
for (ForwardInstructionIterator it(block); !it.Done(); it.Advance()) {
Instruction* current = it.Current();
PrintOneInstruction(current, print_locations);
ISL_Print("\n");
}
}
void FlowGraphPrinter::PrintBlocks() {
if (!function_.IsNull()) {
ISL_Print("==== %s\n", function_.ToFullyQualifiedCString());
}
for (intptr_t i = 0; i < block_order_.length(); ++i) {
PrintBlock(block_order_[i], print_locations_);
}
}
void FlowGraphPrinter::PrintInstruction(Instruction* instr) {
PrintOneInstruction(instr, print_locations_);
}
void FlowGraphPrinter::PrintOneInstruction(Instruction* instr,
bool print_locations) {
char str[4000];
BufferFormatter f(str, sizeof(str));
instr->PrintTo(&f);
if (FLAG_print_environments && (instr->env() != NULL)) {
instr->env()->PrintTo(&f);
}
if (print_locations && (instr->HasLocs())) {
instr->locs()->PrintTo(&f);
}
if (instr->lifetime_position() != -1) {
ISL_Print("%3" Pd ": ", instr->lifetime_position());
}
if (!instr->IsBlockEntry()) ISL_Print(" ");
ISL_Print("%s", str);
}
void FlowGraphPrinter::PrintTypeCheck(const ParsedFunction& parsed_function,
intptr_t token_pos,
Value* value,
const AbstractType& dst_type,
const String& dst_name,
bool eliminated) {
const char* compile_type_name = "unknown";
if (value != NULL && value->reaching_type_ != NULL) {
compile_type_name = value->reaching_type_->ToCString();
}
ISL_Print("%s type check: compile type %s is %s specific than "
"type '%s' of '%s'.\n",
eliminated ? "Eliminated" : "Generated",
compile_type_name,
eliminated ? "more" : "not more",
String::Handle(dst_type.Name()).ToCString(),
dst_name.ToCString());
}
void CompileType::PrintTo(BufferFormatter* f) const {
const char* type_name = "?";
if ((cid_ != kIllegalCid) && (cid_ != kDynamicCid)) {
const Class& cls =
Class::Handle(Isolate::Current()->class_table()->At(cid_));
type_name = String::Handle(cls.PrettyName()).ToCString();
} else if (type_ != NULL &&
!type_->Equals(Type::Handle(Type::DynamicType()))) {
type_name = type_->ToCString();
} else if (!is_nullable()) {
type_name = "!null";
}
f->Print("T{%s%s}", type_name, is_nullable_ ? "?" : "");
}
const char* CompileType::ToCString() const {
char buffer[1024];
BufferFormatter f(buffer, sizeof(buffer));
PrintTo(&f);
return Isolate::Current()->current_zone()->MakeCopyOfString(buffer);
}
static void PrintICDataHelper(BufferFormatter* f, const ICData& ic_data) {
f->Print(" IC[");
if (ic_data.HasRangeFeedback()) {
f->Print("{%s",
ICData::RangeFeedbackToString(ic_data.DecodeRangeFeedbackAt(0)));
if (ic_data.NumArgsTested() == 2) {
f->Print(" x %s",
ICData::RangeFeedbackToString(ic_data.DecodeRangeFeedbackAt(1)));
}
f->Print("->%s} ",
ICData::RangeFeedbackToString(ic_data.DecodeRangeFeedbackAt(2)));
}
f->Print("%" Pd ": ", ic_data.NumberOfChecks());
Function& target = Function::Handle();
for (intptr_t i = 0; i < ic_data.NumberOfChecks(); i++) {
GrowableArray<intptr_t> class_ids;
ic_data.GetCheckAt(i, &class_ids, &target);
const intptr_t count = ic_data.GetCountAt(i);
if (i > 0) {
f->Print(" | ");
}
for (intptr_t k = 0; k < class_ids.length(); k++) {
if (k > 0) {
f->Print(", ");
}
const Class& cls =
Class::Handle(Isolate::Current()->class_table()->At(class_ids[k]));
f->Print("%s", String::Handle(cls.Name()).ToCString());
}
f->Print(" cnt:%" Pd " trgt:'%s'", count, target.ToQualifiedCString());
}
f->Print("]");
}
void FlowGraphPrinter::PrintICData(const ICData& ic_data) {
char buffer[1024];
BufferFormatter f(buffer, sizeof(buffer));
PrintICDataHelper(&f, ic_data);
ISL_Print("%s ", buffer);
const Array& a = Array::Handle(ic_data.arguments_descriptor());
ISL_Print(" arg-desc %" Pd "\n", a.Length());
}
static void PrintUse(BufferFormatter* f, const Definition& definition) {
if (definition.HasSSATemp()) {
if (definition.HasPairRepresentation()) {
f->Print("v%" Pd ", v%" Pd "", definition.ssa_temp_index(),
definition.ssa_temp_index() + 1);
} else {
f->Print("v%" Pd "", definition.ssa_temp_index());
}
} else if (definition.HasTemp()) {
f->Print("t%" Pd "", definition.temp_index());
}
}
const char* Instruction::ToCString() const {
char buffer[1024];
BufferFormatter f(buffer, sizeof(buffer));
PrintTo(&f);
return Isolate::Current()->current_zone()->MakeCopyOfString(buffer);
}
void Instruction::PrintTo(BufferFormatter* f) const {
if (GetDeoptId() != Isolate::kNoDeoptId) {
f->Print("%s:%" Pd "(", DebugName(), GetDeoptId());
} else {
f->Print("%s(", DebugName());
}
PrintOperandsTo(f);
f->Print(")");
}
void Instruction::PrintOperandsTo(BufferFormatter* f) const {
for (int i = 0; i < InputCount(); ++i) {
if (i > 0) f->Print(", ");
if (InputAt(i) != NULL) InputAt(i)->PrintTo(f);
}
}
void Definition::PrintTo(BufferFormatter* f) const {
PrintUse(f, *this);
if (HasSSATemp() || HasTemp()) f->Print(" <- ");
if (GetDeoptId() != Isolate::kNoDeoptId) {
f->Print("%s:%" Pd "(", DebugName(), GetDeoptId());
} else {
f->Print("%s(", DebugName());
}
PrintOperandsTo(f);
f->Print(")");
if (range_ != NULL) {
f->Print(" ");
range_->PrintTo(f);
}
if (type_ != NULL &&
((type_->ToNullableCid() != kDynamicCid) || !type_->is_nullable())) {
f->Print(" ");
type_->PrintTo(f);
}
}
void Definition::PrintOperandsTo(BufferFormatter* f) const {
for (int i = 0; i < InputCount(); ++i) {
if (i > 0) f->Print(", ");
if (InputAt(i) != NULL) {
InputAt(i)->PrintTo(f);
}
}
}
void Value::PrintTo(BufferFormatter* f) const {
PrintUse(f, *definition());
if ((reaching_type_ != NULL) &&
(reaching_type_ != definition()->type_)) {
f->Print(" ");
reaching_type_->PrintTo(f);
}
}
void ConstantInstr::PrintOperandsTo(BufferFormatter* f) const {
const char* cstr = value().ToCString();
const char* new_line = strchr(cstr, '\n');
if (new_line == NULL) {
f->Print("#%s", cstr);
} else {
const intptr_t pos = new_line - cstr;
char* buffer = Isolate::Current()->current_zone()->Alloc<char>(pos + 1);
strncpy(buffer, cstr, pos);
buffer[pos] = '\0';
f->Print("#%s\\n...", buffer);
}
}
void ConstraintInstr::PrintOperandsTo(BufferFormatter* f) const {
value()->PrintTo(f);
f->Print(" ^ ");
constraint()->PrintTo(f);
}
void Range::PrintTo(BufferFormatter* f) const {
f->Print("[");
min_.PrintTo(f);
f->Print(", ");
max_.PrintTo(f);
f->Print("]");
}
const char* Range::ToCString(const Range* range) {
if (range == NULL) return "[_|_, _|_]";
char buffer[256];
BufferFormatter f(buffer, sizeof(buffer));
range->PrintTo(&f);
return Isolate::Current()->current_zone()->MakeCopyOfString(buffer);
}
void RangeBoundary::PrintTo(BufferFormatter* f) const {
switch (kind_) {
case kSymbol:
f->Print("v%" Pd "",
reinterpret_cast<Definition*>(value_)->ssa_temp_index());
if (offset_ != 0) f->Print("%+" Pd64 "", offset_);
break;
case kNegativeInfinity:
f->Print("-inf");
break;
case kPositiveInfinity:
f->Print("+inf");
break;
case kConstant:
f->Print("%" Pd64 "", value_);
break;
case kUnknown:
f->Print("_|_");
break;
}
}
const char* RangeBoundary::ToCString() const {
char buffer[256];
BufferFormatter f(buffer, sizeof(buffer));
PrintTo(&f);
return Isolate::Current()->current_zone()->MakeCopyOfString(buffer);
}
void DropTempsInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%" Pd "", num_temps());
if (value() != NULL) {
f->Print(", ");
value()->PrintTo(f);
}
}
void AssertAssignableInstr::PrintOperandsTo(BufferFormatter* f) const {
value()->PrintTo(f);
f->Print(", %s, '%s'",
dst_type().ToCString(),
dst_name().ToCString());
f->Print(" instantiator(");
instantiator()->PrintTo(f);
f->Print(")");
f->Print(" instantiator_type_arguments(");
instantiator_type_arguments()->PrintTo(f);
f->Print(")");
}
void AssertBooleanInstr::PrintOperandsTo(BufferFormatter* f) const {
value()->PrintTo(f);
}
void ClosureCallInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print(" function=");
InputAt(0)->PrintTo(f);
for (intptr_t i = 0; i < ArgumentCount(); ++i) {
f->Print(", ");
PushArgumentAt(i)->value()->PrintTo(f);
}
}
void InstanceCallInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print(" %s", function_name().ToCString());
for (intptr_t i = 0; i < ArgumentCount(); ++i) {
f->Print(", ");
PushArgumentAt(i)->value()->PrintTo(f);
}
if (HasICData()) {
PrintICDataHelper(f, *ic_data());
}
}
void PolymorphicInstanceCallInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print(" %s", instance_call()->function_name().ToCString());
for (intptr_t i = 0; i < ArgumentCount(); ++i) {
f->Print(", ");
PushArgumentAt(i)->value()->PrintTo(f);
}
PrintICDataHelper(f, ic_data());
}
void StrictCompareInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", Token::Str(kind()));
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
if (needs_number_check()) {
f->Print(", with number check");
}
}
void TestCidsInstr::PrintOperandsTo(BufferFormatter* f) const {
left()->PrintTo(f);
f->Print(" %s [", Token::Str(kind()));
for (intptr_t i = 0; i < cid_results().length(); i += 2) {
f->Print("0x%" Px ":%s ",
cid_results()[i], cid_results()[i + 1] == 0 ? "false" : "true");
}
f->Print("] ");
}
void EqualityCompareInstr::PrintOperandsTo(BufferFormatter* f) const {
left()->PrintTo(f);
f->Print(" %s ", Token::Str(kind()));
right()->PrintTo(f);
}
void StaticCallInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print(" %s ", String::Handle(function().name()).ToCString());
for (intptr_t i = 0; i < ArgumentCount(); ++i) {
if (i > 0) f->Print(", ");
PushArgumentAt(i)->value()->PrintTo(f);
}
}
void LoadLocalInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s", local().name().ToCString());
}
void StoreLocalInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", local().name().ToCString());
value()->PrintTo(f);
}
void NativeCallInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s", native_name().ToCString());
}
void GuardFieldInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s %s, ",
String::Handle(field().name()).ToCString(),
field().GuardedPropertiesAsCString());
value()->PrintTo(f);
}
void StoreInstanceFieldInstr::PrintOperandsTo(BufferFormatter* f) const {
if (field().IsNull()) {
f->Print("{%" Pd "}, ", offset_in_bytes());
} else {
f->Print("%s {%" Pd "}, ",
String::Handle(field().name()).ToCString(),
field().Offset());
}
instance()->PrintTo(f);
f->Print(", ");
value()->PrintTo(f);
}
void IfThenElseInstr::PrintOperandsTo(BufferFormatter* f) const {
comparison()->PrintOperandsTo(f);
f->Print(" ? %" Pd " : %" Pd,
if_true_,
if_false_);
}
void LoadStaticFieldInstr::PrintOperandsTo(BufferFormatter* f) const {
field_value()->PrintTo(f);
}
void StoreStaticFieldInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", String::Handle(field().name()).ToCString());
value()->PrintTo(f);
}
void InstanceOfInstr::PrintOperandsTo(BufferFormatter* f) const {
value()->PrintTo(f);
f->Print(" %s %s",
negate_result() ? "ISNOT" : "IS",
String::Handle(type().Name()).ToCString());
f->Print(" instantiator(");
instantiator()->PrintTo(f);
f->Print(")");
f->Print(" type-arg(");
instantiator_type_arguments()->PrintTo(f);
f->Print(")");
}
void RelationalOpInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", Token::Str(kind()));
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
}
void AllocateObjectInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s", String::Handle(cls().PrettyName()).ToCString());
for (intptr_t i = 0; i < ArgumentCount(); i++) {
f->Print(", ");
PushArgumentAt(i)->value()->PrintTo(f);
}
if (Identity().IsNotAliased()) {
f->Print(" <not-aliased>");
}
}
void MaterializeObjectInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s", String::Handle(cls_.PrettyName()).ToCString());
for (intptr_t i = 0; i < InputCount(); i++) {
f->Print(", ");
f->Print("%s: ", slots_[i]->ToCString());
InputAt(i)->PrintTo(f);
}
}
void LoadFieldInstr::PrintOperandsTo(BufferFormatter* f) const {
instance()->PrintTo(f);
f->Print(", %" Pd, offset_in_bytes());
if (field() != NULL) {
f->Print(" {%s}", String::Handle(field()->name()).ToCString());
const char* expected = "?";
if (field()->guarded_cid() != kIllegalCid) {
const Class& cls = Class::Handle(
Isolate::Current()->class_table()->At(field()->guarded_cid()));
expected = String::Handle(cls.Name()).ToCString();
}
f->Print(" [%s %s]",
field()->is_nullable() ? "nullable" : "non-nullable",
expected);
}
f->Print(", immutable=%d", immutable_);
}
void InstantiateTypeInstr::PrintOperandsTo(BufferFormatter* f) const {
const String& type_name = String::Handle(type().Name());
f->Print("%s, ", type_name.ToCString());
instantiator()->PrintTo(f);
}
void InstantiateTypeArgumentsInstr::PrintOperandsTo(BufferFormatter* f) const {
const String& type_args = String::Handle(type_arguments().Name());
f->Print("%s, ", type_args.ToCString());
instantiator()->PrintTo(f);
}
void AllocateContextInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%" Pd "", num_context_variables());
}
void AllocateUninitializedContextInstr::PrintOperandsTo(
BufferFormatter* f) const {
f->Print("%" Pd "", num_context_variables());
if (Identity().IsNotAliased()) {
f->Print(" <not-aliased>");
}
}
void MathUnaryInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("'%s', ", MathUnaryInstr::KindToCString(kind()));
value()->PrintTo(f);
}
void MergedMathInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("'%s', ", MergedMathInstr::KindToCString(kind()));
Definition::PrintOperandsTo(f);
}
void ExtractNthOutputInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Extract %" Pd " from ", index());
Definition::PrintOperandsTo(f);
}
void UnaryIntegerOpInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", Token::Str(op_kind()));
value()->PrintTo(f);
}
void BinaryIntegerOpInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s", Token::Str(op_kind()));
if (is_truncating()) {
f->Print(" [tr]");
} else if (!can_overflow()) {
f->Print(" [-o]");
}
f->Print(", ");
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
}
void BinaryDoubleOpInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", Token::Str(op_kind()));
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
}
void BinaryFloat32x4OpInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", Token::Str(op_kind()));
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
}
void BinaryFloat64x2OpInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", Token::Str(op_kind()));
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
}
void Simd32x4ShuffleInstr::PrintOperandsTo(BufferFormatter* f) const {
// TODO(johnmccutchan): Add proper string enumeration of shuffle.
f->Print("%s, ", MethodRecognizer::KindToCString(op_kind()));
value()->PrintTo(f);
}
void Simd32x4ShuffleMixInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", MethodRecognizer::KindToCString(op_kind()));
xy()->PrintTo(f);
f->Print(", ");
zw()->PrintTo(f);
}
void Simd32x4GetSignMaskInstr::PrintOperandsTo(BufferFormatter* f) const {
if (op_kind() == MethodRecognizer::kFloat32x4GetSignMask) {
f->Print("Float32x4.getSignMask ");
} else {
ASSERT(op_kind() == MethodRecognizer::kInt32x4GetSignMask);
f->Print("Int32x4.getSignMask ");
}
value()->PrintTo(f);
}
void Float32x4SplatInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("SPLAT ");
value()->PrintTo(f);
}
void Float32x4ConstructorInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Float32x4(");
value0()->PrintTo(f);
f->Print(", ");
value1()->PrintTo(f);
f->Print(", ");
value2()->PrintTo(f);
f->Print(", ");
value3()->PrintTo(f);
f->Print(")");
}
void Float32x4ComparisonInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Float32x4 Comparison %s, ",
MethodRecognizer::KindToCString(op_kind()));
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
}
void Float32x4MinMaxInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", MethodRecognizer::KindToCString(op_kind()));
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
}
void Float32x4SqrtInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", MethodRecognizer::KindToCString(op_kind()));
left()->PrintTo(f);
}
void Float32x4ScaleInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", MethodRecognizer::KindToCString(op_kind()));
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
}
void Float32x4ZeroArgInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", MethodRecognizer::KindToCString(op_kind()));
left()->PrintTo(f);
}
void Float32x4ClampInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Float32x4.clamp, ");
left()->PrintTo(f);
}
void Float32x4WithInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", MethodRecognizer::KindToCString(op_kind()));
left()->PrintTo(f);
f->Print(", ");
replacement()->PrintTo(f);
}
void Float32x4ToInt32x4Instr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Float32x4.toInt32x4 ");
left()->PrintTo(f);
}
void Simd64x2ShuffleInstr::PrintOperandsTo(BufferFormatter* f) const {
// TODO(johnmccutchan): Add proper string enumeration of shuffle.
f->Print("%s, ", MethodRecognizer::KindToCString(op_kind()));
value()->PrintTo(f);
}
void Float64x2SplatInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Float64x2.splat ");
value()->PrintTo(f);
}
void Float64x2ConstructorInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Float64x2(");
value0()->PrintTo(f);
f->Print(", ");
value1()->PrintTo(f);
f->Print(")");
}
void Float32x4ToFloat64x2Instr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Float64x2.fromFloat32x4 ");
left()->PrintTo(f);
}
void Float64x2ToFloat32x4Instr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Float32x4.fromFloat64x2 ");
left()->PrintTo(f);
}
void Float64x2ZeroArgInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", MethodRecognizer::KindToCString(op_kind()));
left()->PrintTo(f);
}
void Float64x2OneArgInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s(", MethodRecognizer::KindToCString(op_kind()));
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
f->Print(")");
}
void Int32x4ConstructorInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Int32x4(");
value0()->PrintTo(f);
f->Print(", ");
value1()->PrintTo(f);
f->Print(", ");
value2()->PrintTo(f);
f->Print(", ");
value3()->PrintTo(f);
f->Print(")");
}
void Int32x4BoolConstructorInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Int32x4.bool(");
value0()->PrintTo(f);
f->Print(", ");
value1()->PrintTo(f);
f->Print(", ");
value2()->PrintTo(f);
f->Print(", ");
value3()->PrintTo(f);
f->Print(")");
}
void Int32x4GetFlagInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Int32x4.%s ", MethodRecognizer::KindToCString(op_kind()));
value()->PrintTo(f);
}
void Int32x4SetFlagInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Int32x4.%s ", MethodRecognizer::KindToCString(op_kind()));
value()->PrintTo(f);
f->Print(", ");
flagValue()->PrintTo(f);
}
void Int32x4SelectInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Int32x4.select ");
mask()->PrintTo(f);
f->Print(", ");
trueValue()->PrintTo(f);
f->Print(", ");
falseValue()->PrintTo(f);
}
void Int32x4ToFloat32x4Instr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("Int32x4.toFloat32x4 ");
left()->PrintTo(f);
}
void BinaryInt32x4OpInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", Token::Str(op_kind()));
left()->PrintTo(f);
f->Print(", ");
right()->PrintTo(f);
}
void UnaryDoubleOpInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", Token::Str(op_kind()));
value()->PrintTo(f);
}
void CheckClassIdInstr::PrintOperandsTo(BufferFormatter* f) const {
value()->PrintTo(f);
const Class& cls =
Class::Handle(Isolate::Current()->class_table()->At(cid()));
f->Print(", %s", String::Handle(cls.PrettyName()).ToCString());
}
void CheckClassInstr::PrintOperandsTo(BufferFormatter* f) const {
value()->PrintTo(f);
PrintICDataHelper(f, unary_checks());
if (IsNullCheck()) {
f->Print(" nullcheck");
}
}
void InvokeMathCFunctionInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s, ", MethodRecognizer::KindToCString(recognized_kind_));
Definition::PrintOperandsTo(f);
}
void GraphEntryInstr::PrintTo(BufferFormatter* f) const {
const GrowableArray<Definition*>& defns = initial_definitions_;
f->Print("B%" Pd "[graph]:%" Pd, block_id(), GetDeoptId());
if (defns.length() > 0) {
f->Print(" {");
for (intptr_t i = 0; i < defns.length(); ++i) {
Definition* def = defns[i];
f->Print("\n ");
def->PrintTo(f);
}
f->Print("\n}");
}
}
void JoinEntryInstr::PrintTo(BufferFormatter* f) const {
if (try_index() != CatchClauseNode::kInvalidTryIndex) {
f->Print("B%" Pd "[join try_idx %" Pd "]:%" Pd " pred(",
block_id(), try_index(), GetDeoptId());
} else {
f->Print("B%" Pd "[join]:%" Pd " pred(", block_id(), GetDeoptId());
}
for (intptr_t i = 0; i < predecessors_.length(); ++i) {
if (i > 0) f->Print(", ");
f->Print("B%" Pd, predecessors_[i]->block_id());
}
f->Print(")");
if (phis_ != NULL) {
f->Print(" {");
for (intptr_t i = 0; i < phis_->length(); ++i) {
if ((*phis_)[i] == NULL) continue;
f->Print("\n ");
(*phis_)[i]->PrintTo(f);
}
f->Print("\n}");
}
if (HasParallelMove()) {
f->Print(" ");
parallel_move()->PrintTo(f);
}
}
void IndirectEntryInstr::PrintTo(BufferFormatter* f) const {
ASSERT(try_index() == CatchClauseNode::kInvalidTryIndex);
f->Print("B%" Pd "[join indirect]:%" Pd " pred(", block_id(), GetDeoptId());
for (intptr_t i = 0; i < predecessors_.length(); ++i) {
if (i > 0) f->Print(", ");
f->Print("B%" Pd, predecessors_[i]->block_id());
}
f->Print(")");
if (phis_ != NULL) {
f->Print(" {");
for (intptr_t i = 0; i < phis_->length(); ++i) {
if ((*phis_)[i] == NULL) continue;
f->Print("\n ");
(*phis_)[i]->PrintTo(f);
}
f->Print("\n}");
}
if (HasParallelMove()) {
f->Print(" ");
parallel_move()->PrintTo(f);
}
}
static const char *RepresentationToCString(Representation rep) {
switch (rep) {
case kTagged:
return "tagged";
case kUntagged:
return "untagged";
case kUnboxedDouble:
return "double";
case kUnboxedInt32:
return "int32";
case kUnboxedUint32:
return "uint32";
case kUnboxedMint:
return "mint";
case kUnboxedFloat32x4:
return "float32x4";
case kUnboxedInt32x4:
return "int32x4";
case kUnboxedFloat64x2:
return "float64x2";
case kPairOfTagged:
return "tagged-pair";
case kPairOfUnboxedDouble:
return "double-pair";
case kNoRepresentation:
return "none";
case kNumRepresentations:
UNREACHABLE();
}
return "?";
}
void PhiInstr::PrintTo(BufferFormatter* f) const {
f->Print("v%" Pd " <- phi(", ssa_temp_index());
for (intptr_t i = 0; i < inputs_.length(); ++i) {
if (inputs_[i] != NULL) inputs_[i]->PrintTo(f);
if (i < inputs_.length() - 1) f->Print(", ");
}
f->Print(")");
if (is_alive()) {
f->Print(" alive");
} else {
f->Print(" dead");
}
if (range_ != NULL) {
f->Print(" ");
range_->PrintTo(f);
}
if (representation() != kNoRepresentation &&
representation() != kTagged) {
f->Print(" %s", RepresentationToCString(representation()));
}
if (type_ != NULL) {
f->Print(" ");
type_->PrintTo(f);
}
}
void UnboxIntegerInstr::PrintOperandsTo(BufferFormatter* f) const {
if (is_truncating()) {
f->Print("[tr], ");
}
Definition::PrintOperandsTo(f);
}
void UnboxedIntConverterInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%s->%s%s, ",
RepresentationToCString(from()),
RepresentationToCString(to()),
is_truncating() ? "[tr]" : "");
Definition::PrintOperandsTo(f);
}
void ParameterInstr::PrintOperandsTo(BufferFormatter* f) const {
f->Print("%" Pd, index());
}
void CheckStackOverflowInstr::PrintOperandsTo(BufferFormatter* f) const {
if (in_loop()) f->Print("depth %" Pd, loop_depth());
}
void TargetEntryInstr::PrintTo(BufferFormatter* f) const {
if (try_index() != CatchClauseNode::kInvalidTryIndex) {
f->Print("B%" Pd "[target try_idx %" Pd "]:%" Pd,
block_id(), try_index(), GetDeoptId());
} else {
f->Print("B%" Pd "[target]:%" Pd, block_id(), GetDeoptId());
}
if (HasParallelMove()) {
f->Print(" ");
parallel_move()->PrintTo(f);
}
}
void CatchBlockEntryInstr::PrintTo(BufferFormatter* f) const {
f->Print("B%" Pd "[target catch try_idx %" Pd " catch_try_idx %" Pd "]",
block_id(), try_index(), catch_try_index());
if (HasParallelMove()) {
f->Print("\n");
parallel_move()->PrintTo(f);
}
const GrowableArray<Definition*>& defns = initial_definitions_;
if (defns.length() > 0) {
f->Print(" {");
for (intptr_t i = 0; i < defns.length(); ++i) {
Definition* def = defns[i];
f->Print("\n ");
def->PrintTo(f);
}
f->Print("\n}");
}
}
void PushArgumentInstr::PrintOperandsTo(BufferFormatter* f) const {
value()->PrintTo(f);
}
void GotoInstr::PrintTo(BufferFormatter* f) const {
if (HasParallelMove()) {
parallel_move()->PrintTo(f);
f->Print(" ");
}
if (GetDeoptId() != Isolate::kNoDeoptId) {
f->Print("goto:%" Pd " %" Pd "", GetDeoptId(), successor()->block_id());
} else {
f->Print("goto: %" Pd "", successor()->block_id());
}
}
void IndirectGotoInstr::PrintTo(BufferFormatter* f) const {
if (GetDeoptId() != Isolate::kNoDeoptId) {
f->Print("igoto:%" Pd "(", GetDeoptId());
} else {
f->Print("igoto:(");
}
InputAt(0)->PrintTo(f);
f->Print(")");
}
void BranchInstr::PrintTo(BufferFormatter* f) const {
f->Print("%s ", DebugName());
f->Print("if ");
comparison()->PrintTo(f);
f->Print(" goto (%" Pd ", %" Pd ")",
true_successor()->block_id(),
false_successor()->block_id());
}
void ParallelMoveInstr::PrintTo(BufferFormatter* f) const {
f->Print("%s ", DebugName());
for (intptr_t i = 0; i < moves_.length(); i++) {
if (i != 0) f->Print(", ");
moves_[i]->dest().PrintTo(f);
f->Print(" <- ");
moves_[i]->src().PrintTo(f);
}
}
void Environment::PrintTo(BufferFormatter* f) const {
f->Print(" env={ ");
int arg_count = 0;
for (intptr_t i = 0; i < values_.length(); ++i) {
if (i > 0) f->Print(", ");
if (values_[i]->definition()->IsPushArgument()) {
f->Print("a%d", arg_count++);
} else {
values_[i]->PrintTo(f);
}
if ((locations_ != NULL) && !locations_[i].IsInvalid()) {
f->Print(" [");
locations_[i].PrintTo(f);
f->Print("]");
}
}
f->Print(" }");
if (outer_ != NULL) outer_->PrintTo(f);
}
const char* Environment::ToCString() const {
char buffer[1024];
BufferFormatter bf(buffer, 1024);
PrintTo(&bf);
return Isolate::Current()->current_zone()->MakeCopyOfString(buffer);
}
} // namespace dart