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dart / sdk.git / refs/tags/1.21.0-dev.11.2 / . / runtime / vm / jit_optimizer.cc
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// Copyright (c) 2013, 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.
#ifndef DART_PRECOMPILED_RUNTIME
#include "vm/jit_optimizer.h"
#include "vm/bit_vector.h"
#include "vm/branch_optimizer.h"
#include "vm/cha.h"
#include "vm/compiler.h"
#include "vm/cpu.h"
#include "vm/dart_entry.h"
#include "vm/exceptions.h"
#include "vm/flow_graph_builder.h"
#include "vm/flow_graph_compiler.h"
#include "vm/flow_graph_inliner.h"
#include "vm/flow_graph_range_analysis.h"
#include "vm/hash_map.h"
#include "vm/il_printer.h"
#include "vm/intermediate_language.h"
#include "vm/object_store.h"
#include "vm/parser.h"
#include "vm/resolver.h"
#include "vm/scopes.h"
#include "vm/stack_frame.h"
#include "vm/symbols.h"
namespace dart {
// Quick access to the current isolate and zone.
#define I (isolate())
#define Z (zone())
static bool ShouldInlineSimd() {
return FlowGraphCompiler::SupportsUnboxedSimd128();
}
static bool CanUnboxDouble() {
return FlowGraphCompiler::SupportsUnboxedDoubles();
}
static bool CanConvertUnboxedMintToDouble() {
return FlowGraphCompiler::CanConvertUnboxedMintToDouble();
}
// Optimize instance calls using ICData.
void JitOptimizer::ApplyICData() {
VisitBlocks();
}
// Optimize instance calls using cid. This is called after optimizer
// converted instance calls to instructions. Any remaining
// instance calls are either megamorphic calls, cannot be optimized or
// have no runtime type feedback collected.
// Attempts to convert an instance call (IC call) using propagated class-ids,
// e.g., receiver class id, guarded-cid, or by guessing cid-s.
void JitOptimizer::ApplyClassIds() {
ASSERT(current_iterator_ == NULL);
for (BlockIterator block_it = flow_graph_->reverse_postorder_iterator();
!block_it.Done(); block_it.Advance()) {
ForwardInstructionIterator it(block_it.Current());
current_iterator_ = ⁢
for (; !it.Done(); it.Advance()) {
Instruction* instr = it.Current();
if (instr->IsInstanceCall()) {
InstanceCallInstr* call = instr->AsInstanceCall();
if (call->HasICData()) {
if (TryCreateICData(call)) {
VisitInstanceCall(call);
}
}
} else if (instr->IsPolymorphicInstanceCall()) {
SpecializePolymorphicInstanceCall(instr->AsPolymorphicInstanceCall());
}
}
current_iterator_ = NULL;
}
}
// TODO(srdjan): Test/support other number types as well.
static bool IsNumberCid(intptr_t cid) {
return (cid == kSmiCid) || (cid == kDoubleCid);
}
bool JitOptimizer::TryCreateICData(InstanceCallInstr* call) {
ASSERT(call->HasICData());
if (call->ic_data()->NumberOfUsedChecks() > 0) {
// This occurs when an instance call has too many checks, will be converted
// to megamorphic call.
return false;
}
GrowableArray<intptr_t> class_ids(call->ic_data()->NumArgsTested());
ASSERT(call->ic_data()->NumArgsTested() <= call->ArgumentCount());
for (intptr_t i = 0; i < call->ic_data()->NumArgsTested(); i++) {
class_ids.Add(call->PushArgumentAt(i)->value()->Type()->ToCid());
}
const Token::Kind op_kind = call->token_kind();
if (Token::IsRelationalOperator(op_kind) ||
Token::IsEqualityOperator(op_kind) || Token::IsBinaryOperator(op_kind)) {
// Guess cid: if one of the inputs is a number assume that the other
// is a number of same type.
if (FLAG_guess_icdata_cid) {
const intptr_t cid_0 = class_ids[0];
const intptr_t cid_1 = class_ids[1];
if ((cid_0 == kDynamicCid) && (IsNumberCid(cid_1))) {
class_ids[0] = cid_1;
} else if (IsNumberCid(cid_0) && (cid_1 == kDynamicCid)) {
class_ids[1] = cid_0;
}
}
}
bool all_cids_known = true;
for (intptr_t i = 0; i < class_ids.length(); i++) {
if (class_ids[i] == kDynamicCid) {
// Not all cid-s known.
all_cids_known = false;
break;
}
}
if (all_cids_known) {
const Class& receiver_class =
Class::Handle(Z, isolate()->class_table()->At(class_ids[0]));
if (!receiver_class.is_finalized()) {
// Do not eagerly finalize classes. ResolveDynamicForReceiverClass can
// cause class finalization, since callee's receiver class may not be
// finalized yet.
return false;
}
const Array& args_desc_array =
Array::Handle(Z, ArgumentsDescriptor::New(call->ArgumentCount(),
call->argument_names()));
ArgumentsDescriptor args_desc(args_desc_array);
const Function& function =
Function::Handle(Z, Resolver::ResolveDynamicForReceiverClass(
receiver_class, call->function_name(),
args_desc, false /* allow add */));
if (function.IsNull()) {
return false;
}
// Create new ICData, do not modify the one attached to the instruction
// since it is attached to the assembly instruction itself.
// TODO(srdjan): Prevent modification of ICData object that is
// referenced in assembly code.
const ICData& ic_data = ICData::ZoneHandle(
Z, ICData::NewFrom(*call->ic_data(), class_ids.length()));
if (class_ids.length() > 1) {
ic_data.AddCheck(class_ids, function);
} else {
ASSERT(class_ids.length() == 1);
ic_data.AddReceiverCheck(class_ids[0], function);
}
call->set_ic_data(&ic_data);
return true;
}
// Check if getter or setter in function's class and class is currently leaf.
if (FLAG_guess_icdata_cid && ((call->token_kind() == Token::kGET) ||
(call->token_kind() == Token::kSET))) {
const Class& owner_class = Class::Handle(Z, function().Owner());
if (!owner_class.is_abstract() && !CHA::HasSubclasses(owner_class) &&
!CHA::IsImplemented(owner_class)) {
const Array& args_desc_array =
Array::Handle(Z, ArgumentsDescriptor::New(call->ArgumentCount(),
call->argument_names()));
ArgumentsDescriptor args_desc(args_desc_array);
const Function& function =
Function::Handle(Z, Resolver::ResolveDynamicForReceiverClass(
owner_class, call->function_name(), args_desc,
false /* allow_add */));
if (!function.IsNull()) {
const ICData& ic_data = ICData::ZoneHandle(
Z, ICData::NewFrom(*call->ic_data(), class_ids.length()));
ic_data.AddReceiverCheck(owner_class.id(), function);
call->set_ic_data(&ic_data);
return true;
}
}
}
return false;
}
const ICData& JitOptimizer::TrySpecializeICData(const ICData& ic_data,
intptr_t cid) {
ASSERT(ic_data.NumArgsTested() == 1);
if ((ic_data.NumberOfUsedChecks() == 1) && ic_data.HasReceiverClassId(cid)) {
return ic_data; // Nothing to do
}
const Function& function =
Function::Handle(Z, ic_data.GetTargetForReceiverClassId(cid));
// TODO(fschneider): Try looking up the function on the class if it is
// not found in the ICData.
if (!function.IsNull()) {
const ICData& new_ic_data = ICData::ZoneHandle(
Z, ICData::New(Function::Handle(Z, ic_data.Owner()),
String::Handle(Z, ic_data.target_name()),
Object::empty_array(), // Dummy argument descriptor.
ic_data.deopt_id(), ic_data.NumArgsTested(), false));
new_ic_data.SetDeoptReasons(ic_data.DeoptReasons());
new_ic_data.AddReceiverCheck(cid, function);
return new_ic_data;
}
return ic_data;
}
void JitOptimizer::SpecializePolymorphicInstanceCall(
PolymorphicInstanceCallInstr* call) {
if (!FLAG_polymorphic_with_deopt) {
// Specialization adds receiver checks which can lead to deoptimization.
return;
}
if (!call->with_checks()) {
return; // Already specialized.
}
const intptr_t receiver_cid =
call->PushArgumentAt(0)->value()->Type()->ToCid();
if (receiver_cid == kDynamicCid) {
return; // No information about receiver was infered.
}
const ICData& ic_data = TrySpecializeICData(call->ic_data(), receiver_cid);
if (ic_data.raw() == call->ic_data().raw()) {
// No specialization.
return;
}
const bool with_checks = false;
const bool complete = false;
PolymorphicInstanceCallInstr* specialized =
new (Z) PolymorphicInstanceCallInstr(call->instance_call(), ic_data,
with_checks, complete);
call->ReplaceWith(specialized, current_iterator());
}
static bool ClassIdIsOneOf(intptr_t class_id,
const GrowableArray<intptr_t>& class_ids) {
for (intptr_t i = 0; i < class_ids.length(); i++) {
ASSERT(class_ids[i] != kIllegalCid);
if (class_ids[i] == class_id) {
return true;
}
}
return false;
}
// Returns true if ICData tests two arguments and all ICData cids are in the
// required sets 'receiver_class_ids' or 'argument_class_ids', respectively.
static bool ICDataHasOnlyReceiverArgumentClassIds(
const ICData& ic_data,
const GrowableArray<intptr_t>& receiver_class_ids,
const GrowableArray<intptr_t>& argument_class_ids) {
if (ic_data.NumArgsTested() != 2) {
return false;
}
const intptr_t len = ic_data.NumberOfChecks();
GrowableArray<intptr_t> class_ids;
for (intptr_t i = 0; i < len; i++) {
if (ic_data.IsUsedAt(i)) {
ic_data.GetClassIdsAt(i, &class_ids);
ASSERT(class_ids.length() == 2);
if (!ClassIdIsOneOf(class_ids[0], receiver_class_ids) ||
!ClassIdIsOneOf(class_ids[1], argument_class_ids)) {
return false;
}
}
}
return true;
}
static bool ICDataHasReceiverArgumentClassIds(const ICData& ic_data,
intptr_t receiver_class_id,
intptr_t argument_class_id) {
if (ic_data.NumArgsTested() != 2) {
return false;
}
const intptr_t len = ic_data.NumberOfChecks();
for (intptr_t i = 0; i < len; i++) {
if (ic_data.IsUsedAt(i)) {
GrowableArray<intptr_t> class_ids;
ic_data.GetClassIdsAt(i, &class_ids);
ASSERT(class_ids.length() == 2);
if ((class_ids[0] == receiver_class_id) &&
(class_ids[1] == argument_class_id)) {
return true;
}
}
}
return false;
}
static bool HasOnlyOneSmi(const ICData& ic_data) {
return (ic_data.NumberOfUsedChecks() == 1) &&
ic_data.HasReceiverClassId(kSmiCid);
}
static bool HasOnlySmiOrMint(const ICData& ic_data) {
if (ic_data.NumberOfUsedChecks() == 1) {
return ic_data.HasReceiverClassId(kSmiCid) ||
ic_data.HasReceiverClassId(kMintCid);
}
return (ic_data.NumberOfUsedChecks() == 2) &&
ic_data.HasReceiverClassId(kSmiCid) &&
ic_data.HasReceiverClassId(kMintCid);
}
static bool HasOnlyTwoOf(const ICData& ic_data, intptr_t cid) {
if (ic_data.NumberOfUsedChecks() != 1) {
return false;
}
GrowableArray<intptr_t> first;
GrowableArray<intptr_t> second;
ic_data.GetUsedCidsForTwoArgs(&first, &second);
return (first[0] == cid) && (second[0] == cid);
}
// Returns false if the ICData contains anything other than the 4 combinations
// of Mint and Smi for the receiver and argument classes.
static bool HasTwoMintOrSmi(const ICData& ic_data) {
GrowableArray<intptr_t> first;
GrowableArray<intptr_t> second;
ic_data.GetUsedCidsForTwoArgs(&first, &second);
for (intptr_t i = 0; i < first.length(); i++) {
if ((first[i] != kSmiCid) && (first[i] != kMintCid)) {
return false;
}
if ((second[i] != kSmiCid) && (second[i] != kMintCid)) {
return false;
}
}
return true;
}
// Returns false if the ICData contains anything other than the 4 combinations
// of Double and Smi for the receiver and argument classes.
static bool HasTwoDoubleOrSmi(const ICData& ic_data) {
GrowableArray<intptr_t> class_ids(2);
class_ids.Add(kSmiCid);
class_ids.Add(kDoubleCid);
return ICDataHasOnlyReceiverArgumentClassIds(ic_data, class_ids, class_ids);
}
static bool HasOnlyOneDouble(const ICData& ic_data) {
return (ic_data.NumberOfUsedChecks() == 1) &&
ic_data.HasReceiverClassId(kDoubleCid);
}
static bool ShouldSpecializeForDouble(const ICData& ic_data) {
// Don't specialize for double if we can't unbox them.
if (!CanUnboxDouble()) {
return false;
}
// Unboxed double operation can't handle case of two smis.
if (ICDataHasReceiverArgumentClassIds(ic_data, kSmiCid, kSmiCid)) {
return false;
}
// Check that it have seen only smis and doubles.
return HasTwoDoubleOrSmi(ic_data);
}
void JitOptimizer::ReplaceCall(Definition* call, Definition* replacement) {
// Remove the original push arguments.
for (intptr_t i = 0; i < call->ArgumentCount(); ++i) {
PushArgumentInstr* push = call->PushArgumentAt(i);
push->ReplaceUsesWith(push->value()->definition());
push->RemoveFromGraph();
}
call->ReplaceWith(replacement, current_iterator());
}
void JitOptimizer::AddCheckSmi(Definition* to_check,
intptr_t deopt_id,
Environment* deopt_environment,
Instruction* insert_before) {
if (to_check->Type()->ToCid() != kSmiCid) {
InsertBefore(insert_before,
new (Z) CheckSmiInstr(new (Z) Value(to_check), deopt_id,
insert_before->token_pos()),
deopt_environment, FlowGraph::kEffect);
}
}
Instruction* JitOptimizer::GetCheckClass(Definition* to_check,
const ICData& unary_checks,
intptr_t deopt_id,
TokenPosition token_pos) {
if ((unary_checks.NumberOfUsedChecks() == 1) &&
unary_checks.HasReceiverClassId(kSmiCid)) {
return new (Z) CheckSmiInstr(new (Z) Value(to_check), deopt_id, token_pos);
}
return new (Z) CheckClassInstr(new (Z) Value(to_check), deopt_id,
unary_checks, token_pos);
}
void JitOptimizer::AddCheckClass(Definition* to_check,
const ICData& unary_checks,
intptr_t deopt_id,
Environment* deopt_environment,
Instruction* insert_before) {
// Type propagation has not run yet, we cannot eliminate the check.
Instruction* check = GetCheckClass(to_check, unary_checks, deopt_id,
insert_before->token_pos());
InsertBefore(insert_before, check, deopt_environment, FlowGraph::kEffect);
}
void JitOptimizer::AddReceiverCheck(InstanceCallInstr* call) {
AddCheckClass(call->ArgumentAt(0),
ICData::ZoneHandle(Z, call->ic_data()->AsUnaryClassChecks()),
call->deopt_id(), call->env(), call);
}
static bool ArgIsAlways(intptr_t cid,
const ICData& ic_data,
intptr_t arg_number) {
ASSERT(ic_data.NumArgsTested() > arg_number);
if (ic_data.NumberOfUsedChecks() == 0) {
return false;
}
const intptr_t num_checks = ic_data.NumberOfChecks();
for (intptr_t i = 0; i < num_checks; i++) {
if (ic_data.IsUsedAt(i) && ic_data.GetClassIdAt(i, arg_number) != cid) {
return false;
}
}
return true;
}
bool JitOptimizer::TryReplaceWithIndexedOp(InstanceCallInstr* call) {
// Check for monomorphic IC data.
if (!call->HasICData()) return false;
const ICData& ic_data =
ICData::Handle(Z, call->ic_data()->AsUnaryClassChecks());
if (ic_data.NumberOfChecks() != 1) {
return false;
}
return FlowGraphInliner::TryReplaceInstanceCallWithInline(
flow_graph_, current_iterator(), call);
}
// Return true if d is a string of length one (a constant or result from
// from string-from-char-code instruction.
static bool IsLengthOneString(Definition* d) {
if (d->IsConstant()) {
const Object& obj = d->AsConstant()->value();
if (obj.IsString()) {
return String::Cast(obj).Length() == 1;
} else {
return false;
}
} else {
return d->IsOneByteStringFromCharCode();
}
}
// Returns true if the string comparison was converted into char-code
// comparison. Conversion is only possible for strings of length one.
// E.g., detect str[x] == "x"; and use an integer comparison of char-codes.
// TODO(srdjan): Expand for two-byte and external strings.
bool JitOptimizer::TryStringLengthOneEquality(InstanceCallInstr* call,
Token::Kind op_kind) {
ASSERT(HasOnlyTwoOf(*call->ic_data(), kOneByteStringCid));
// Check that left and right are length one strings (either string constants
// or results of string-from-char-code.
Definition* left = call->ArgumentAt(0);
Definition* right = call->ArgumentAt(1);
Value* left_val = NULL;
Definition* to_remove_left = NULL;
if (IsLengthOneString(right)) {
// Swap, since we know that both arguments are strings
Definition* temp = left;
left = right;
right = temp;
}
if (IsLengthOneString(left)) {
// Optimize if left is a string with length one (either constant or
// result of string-from-char-code.
if (left->IsConstant()) {
ConstantInstr* left_const = left->AsConstant();
const String& str = String::Cast(left_const->value());
ASSERT(str.Length() == 1);
ConstantInstr* char_code_left = flow_graph()->GetConstant(
Smi::ZoneHandle(Z, Smi::New(static_cast<intptr_t>(str.CharAt(0)))));
left_val = new (Z) Value(char_code_left);
} else if (left->IsOneByteStringFromCharCode()) {
// Use input of string-from-charcode as left value.
OneByteStringFromCharCodeInstr* instr =
left->AsOneByteStringFromCharCode();
left_val = new (Z) Value(instr->char_code()->definition());
to_remove_left = instr;
} else {
// IsLengthOneString(left) should have been false.
UNREACHABLE();
}
Definition* to_remove_right = NULL;
Value* right_val = NULL;
if (right->IsOneByteStringFromCharCode()) {
// Skip string-from-char-code, and use its input as right value.
OneByteStringFromCharCodeInstr* right_instr =
right->AsOneByteStringFromCharCode();
right_val = new (Z) Value(right_instr->char_code()->definition());
to_remove_right = right_instr;
} else {
const ICData& unary_checks_1 =
ICData::ZoneHandle(Z, call->ic_data()->AsUnaryClassChecksForArgNr(1));
AddCheckClass(right, unary_checks_1, call->deopt_id(), call->env(), call);
// String-to-char-code instructions returns -1 (illegal charcode) if
// string is not of length one.
StringToCharCodeInstr* char_code_right = new (Z)
StringToCharCodeInstr(new (Z) Value(right), kOneByteStringCid);
InsertBefore(call, char_code_right, call->env(), FlowGraph::kValue);
right_val = new (Z) Value(char_code_right);
}
// Comparing char-codes instead of strings.
EqualityCompareInstr* comp =
new (Z) EqualityCompareInstr(call->token_pos(), op_kind, left_val,
right_val, kSmiCid, call->deopt_id());
ReplaceCall(call, comp);
// Remove dead instructions.
if ((to_remove_left != NULL) &&
(to_remove_left->input_use_list() == NULL)) {
to_remove_left->ReplaceUsesWith(flow_graph()->constant_null());
to_remove_left->RemoveFromGraph();
}
if ((to_remove_right != NULL) &&
(to_remove_right->input_use_list() == NULL)) {
to_remove_right->ReplaceUsesWith(flow_graph()->constant_null());
to_remove_right->RemoveFromGraph();
}
return true;
}
return false;
}
static bool SmiFitsInDouble() {
return kSmiBits < 53;
}
bool JitOptimizer::TryReplaceWithEqualityOp(InstanceCallInstr* call,
Token::Kind op_kind) {
const ICData& ic_data = *call->ic_data();
ASSERT(ic_data.NumArgsTested() == 2);
ASSERT(call->ArgumentCount() == 2);
Definition* left = call->ArgumentAt(0);
Definition* right = call->ArgumentAt(1);
intptr_t cid = kIllegalCid;
if (HasOnlyTwoOf(ic_data, kOneByteStringCid)) {
if (TryStringLengthOneEquality(call, op_kind)) {
return true;
} else {
return false;
}
} else if (HasOnlyTwoOf(ic_data, kSmiCid)) {
InsertBefore(call,
new (Z) CheckSmiInstr(new (Z) Value(left), call->deopt_id(),
call->token_pos()),
call->env(), FlowGraph::kEffect);
InsertBefore(call,
new (Z) CheckSmiInstr(new (Z) Value(right), call->deopt_id(),
call->token_pos()),
call->env(), FlowGraph::kEffect);
cid = kSmiCid;
} else if (HasTwoMintOrSmi(ic_data) &&
FlowGraphCompiler::SupportsUnboxedMints()) {
cid = kMintCid;
} else if (HasTwoDoubleOrSmi(ic_data) && CanUnboxDouble()) {
// Use double comparison.
if (SmiFitsInDouble()) {
cid = kDoubleCid;
} else {
if (ICDataHasReceiverArgumentClassIds(ic_data, kSmiCid, kSmiCid)) {
// We cannot use double comparison on two smis. Need polymorphic
// call.
return false;
} else {
InsertBefore(call, new (Z) CheckEitherNonSmiInstr(new (Z) Value(left),
new (Z) Value(right),
call->deopt_id()),
call->env(), FlowGraph::kEffect);
cid = kDoubleCid;
}
}
} else {
// Check if ICDData contains checks with Smi/Null combinations. In that case
// we can still emit the optimized Smi equality operation but need to add
// checks for null or Smi.
GrowableArray<intptr_t> smi_or_null(2);
smi_or_null.Add(kSmiCid);
smi_or_null.Add(kNullCid);
if (ICDataHasOnlyReceiverArgumentClassIds(ic_data, smi_or_null,
smi_or_null)) {
const ICData& unary_checks_0 =
ICData::ZoneHandle(Z, call->ic_data()->AsUnaryClassChecks());
AddCheckClass(left, unary_checks_0, call->deopt_id(), call->env(), call);
const ICData& unary_checks_1 =
ICData::ZoneHandle(Z, call->ic_data()->AsUnaryClassChecksForArgNr(1));
AddCheckClass(right, unary_checks_1, call->deopt_id(), call->env(), call);
cid = kSmiCid;
} else {
// Shortcut for equality with null.
ConstantInstr* right_const = right->AsConstant();
ConstantInstr* left_const = left->AsConstant();
if ((right_const != NULL && right_const->value().IsNull()) ||
(left_const != NULL && left_const->value().IsNull())) {
StrictCompareInstr* comp = new (Z)
StrictCompareInstr(call->token_pos(), Token::kEQ_STRICT,
new (Z) Value(left), new (Z) Value(right),
false); // No number check.
ReplaceCall(call, comp);
return true;
}
return false;
}
}
ASSERT(cid != kIllegalCid);
EqualityCompareInstr* comp = new (Z)
EqualityCompareInstr(call->token_pos(), op_kind, new (Z) Value(left),
new (Z) Value(right), cid, call->deopt_id());
ReplaceCall(call, comp);
return true;
}
bool JitOptimizer::TryReplaceWithRelationalOp(InstanceCallInstr* call,
Token::Kind op_kind) {
const ICData& ic_data = *call->ic_data();
ASSERT(ic_data.NumArgsTested() == 2);
ASSERT(call->ArgumentCount() == 2);
Definition* left = call->ArgumentAt(0);
Definition* right = call->ArgumentAt(1);
intptr_t cid = kIllegalCid;
if (HasOnlyTwoOf(ic_data, kSmiCid)) {
InsertBefore(call,
new (Z) CheckSmiInstr(new (Z) Value(left), call->deopt_id(),
call->token_pos()),
call->env(), FlowGraph::kEffect);
InsertBefore(call,
new (Z) CheckSmiInstr(new (Z) Value(right), call->deopt_id(),
call->token_pos()),
call->env(), FlowGraph::kEffect);
cid = kSmiCid;
} else if (HasTwoMintOrSmi(ic_data) &&
FlowGraphCompiler::SupportsUnboxedMints()) {
cid = kMintCid;
} else if (HasTwoDoubleOrSmi(ic_data) && CanUnboxDouble()) {
// Use double comparison.
if (SmiFitsInDouble()) {
cid = kDoubleCid;
} else {
if (ICDataHasReceiverArgumentClassIds(ic_data, kSmiCid, kSmiCid)) {
// We cannot use double comparison on two smis. Need polymorphic
// call.
return false;
} else {
InsertBefore(call, new (Z) CheckEitherNonSmiInstr(new (Z) Value(left),
new (Z) Value(right),
call->deopt_id()),
call->env(), FlowGraph::kEffect);
cid = kDoubleCid;
}
}
} else {
return false;
}
ASSERT(cid != kIllegalCid);
RelationalOpInstr* comp =
new (Z) RelationalOpInstr(call->token_pos(), op_kind, new (Z) Value(left),
new (Z) Value(right), cid, call->deopt_id());
ReplaceCall(call, comp);
return true;
}
bool JitOptimizer::TryReplaceWithBinaryOp(InstanceCallInstr* call,
Token::Kind op_kind) {
intptr_t operands_type = kIllegalCid;
ASSERT(call->HasICData());
const ICData& ic_data = *call->ic_data();
switch (op_kind) {
case Token::kADD:
case Token::kSUB:
case Token::kMUL:
if (HasOnlyTwoOf(ic_data, kSmiCid)) {
// Don't generate smi code if the IC data is marked because
// of an overflow.
operands_type = ic_data.HasDeoptReason(ICData::kDeoptBinarySmiOp)
? kMintCid
: kSmiCid;
} else if (HasTwoMintOrSmi(ic_data) &&
FlowGraphCompiler::SupportsUnboxedMints()) {
// Don't generate mint code if the IC data is marked because of an
// overflow.
if (ic_data.HasDeoptReason(ICData::kDeoptBinaryMintOp)) return false;
operands_type = kMintCid;
} else if (ShouldSpecializeForDouble(ic_data)) {
operands_type = kDoubleCid;
} else if (HasOnlyTwoOf(ic_data, kFloat32x4Cid)) {
operands_type = kFloat32x4Cid;
} else if (HasOnlyTwoOf(ic_data, kInt32x4Cid)) {
ASSERT(op_kind != Token::kMUL); // Int32x4 doesn't have a multiply op.
operands_type = kInt32x4Cid;
} else if (HasOnlyTwoOf(ic_data, kFloat64x2Cid)) {
operands_type = kFloat64x2Cid;
} else {
return false;
}
break;
case Token::kDIV:
if (!FlowGraphCompiler::SupportsHardwareDivision()) return false;
if (ShouldSpecializeForDouble(ic_data) ||
HasOnlyTwoOf(ic_data, kSmiCid)) {
operands_type = kDoubleCid;
} else if (HasOnlyTwoOf(ic_data, kFloat32x4Cid)) {
operands_type = kFloat32x4Cid;
} else if (HasOnlyTwoOf(ic_data, kFloat64x2Cid)) {
operands_type = kFloat64x2Cid;
} else {
return false;
}
break;
case Token::kBIT_AND:
case Token::kBIT_OR:
case Token::kBIT_XOR:
if (HasOnlyTwoOf(ic_data, kSmiCid)) {
operands_type = kSmiCid;
} else if (HasTwoMintOrSmi(ic_data)) {
operands_type = kMintCid;
} else if (HasOnlyTwoOf(ic_data, kInt32x4Cid)) {
operands_type = kInt32x4Cid;
} else {
return false;
}
break;
case Token::kSHR:
case Token::kSHL:
if (HasOnlyTwoOf(ic_data, kSmiCid)) {
// Left shift may overflow from smi into mint or big ints.
// Don't generate smi code if the IC data is marked because
// of an overflow.
if (ic_data.HasDeoptReason(ICData::kDeoptBinaryMintOp)) {
return false;
}
operands_type = ic_data.HasDeoptReason(ICData::kDeoptBinarySmiOp)
? kMintCid
: kSmiCid;
} else if (HasTwoMintOrSmi(ic_data) &&
HasOnlyOneSmi(ICData::Handle(
Z, ic_data.AsUnaryClassChecksForArgNr(1)))) {
// Don't generate mint code if the IC data is marked because of an
// overflow.
if (ic_data.HasDeoptReason(ICData::kDeoptBinaryMintOp)) {
return false;
}
// Check for smi/mint << smi or smi/mint >> smi.
operands_type = kMintCid;
} else {
return false;
}
break;
case Token::kMOD:
case Token::kTRUNCDIV:
if (!FlowGraphCompiler::SupportsHardwareDivision()) return false;
if (HasOnlyTwoOf(ic_data, kSmiCid)) {
if (ic_data.HasDeoptReason(ICData::kDeoptBinarySmiOp)) {
return false;
}
operands_type = kSmiCid;
} else {
return false;
}
break;
default:
UNREACHABLE();
}
ASSERT(call->ArgumentCount() == 2);
Definition* left = call->ArgumentAt(0);
Definition* right = call->ArgumentAt(1);
if (operands_type == kDoubleCid) {
if (!CanUnboxDouble()) {
return false;
}
// Check that either left or right are not a smi. Result of a
// binary operation with two smis is a smi not a double, except '/' which
// returns a double for two smis.
if (op_kind != Token::kDIV) {
InsertBefore(call, new (Z) CheckEitherNonSmiInstr(new (Z) Value(left),
new (Z) Value(right),
call->deopt_id()),
call->env(), FlowGraph::kEffect);
}
BinaryDoubleOpInstr* double_bin_op = new (Z)
BinaryDoubleOpInstr(op_kind, new (Z) Value(left), new (Z) Value(right),
call->deopt_id(), call->token_pos());
ReplaceCall(call, double_bin_op);
} else if (operands_type == kMintCid) {
if (!FlowGraphCompiler::SupportsUnboxedMints()) return false;
if ((op_kind == Token::kSHR) || (op_kind == Token::kSHL)) {
ShiftMintOpInstr* shift_op = new (Z) ShiftMintOpInstr(
op_kind, new (Z) Value(left), new (Z) Value(right), call->deopt_id());
ReplaceCall(call, shift_op);
} else {
BinaryMintOpInstr* bin_op = new (Z) BinaryMintOpInstr(
op_kind, new (Z) Value(left), new (Z) Value(right), call->deopt_id());
ReplaceCall(call, bin_op);
}
} else if (operands_type == kFloat32x4Cid) {
return InlineFloat32x4BinaryOp(call, op_kind);
} else if (operands_type == kInt32x4Cid) {
return InlineInt32x4BinaryOp(call, op_kind);
} else if (operands_type == kFloat64x2Cid) {
return InlineFloat64x2BinaryOp(call, op_kind);
} else if (op_kind == Token::kMOD) {
ASSERT(operands_type == kSmiCid);
if (right->IsConstant()) {
const Object& obj = right->AsConstant()->value();
if (obj.IsSmi() && Utils::IsPowerOfTwo(Smi::Cast(obj).Value())) {
// Insert smi check and attach a copy of the original environment
// because the smi operation can still deoptimize.
InsertBefore(call,
new (Z) CheckSmiInstr(new (Z) Value(left),
call->deopt_id(), call->token_pos()),
call->env(), FlowGraph::kEffect);
ConstantInstr* constant = flow_graph()->GetConstant(
Smi::Handle(Z, Smi::New(Smi::Cast(obj).Value() - 1)));
BinarySmiOpInstr* bin_op =
new (Z) BinarySmiOpInstr(Token::kBIT_AND, new (Z) Value(left),
new (Z) Value(constant), call->deopt_id());
ReplaceCall(call, bin_op);
return true;
}
}
// Insert two smi checks and attach a copy of the original
// environment because the smi operation can still deoptimize.
AddCheckSmi(left, call->deopt_id(), call->env(), call);
AddCheckSmi(right, call->deopt_id(), call->env(), call);
BinarySmiOpInstr* bin_op = new (Z) BinarySmiOpInstr(
op_kind, new (Z) Value(left), new (Z) Value(right), call->deopt_id());
ReplaceCall(call, bin_op);
} else {
ASSERT(operands_type == kSmiCid);
// Insert two smi checks and attach a copy of the original
// environment because the smi operation can still deoptimize.
AddCheckSmi(left, call->deopt_id(), call->env(), call);
AddCheckSmi(right, call->deopt_id(), call->env(), call);
if (left->IsConstant() &&
((op_kind == Token::kADD) || (op_kind == Token::kMUL))) {
// Constant should be on the right side.
Definition* temp = left;
left = right;
right = temp;
}
BinarySmiOpInstr* bin_op = new (Z) BinarySmiOpInstr(
op_kind, new (Z) Value(left), new (Z) Value(right), call->deopt_id());
ReplaceCall(call, bin_op);
}
return true;
}
bool JitOptimizer::TryReplaceWithUnaryOp(InstanceCallInstr* call,
Token::Kind op_kind) {
ASSERT(call->ArgumentCount() == 1);
Definition* input = call->ArgumentAt(0);
Definition* unary_op = NULL;
if (HasOnlyOneSmi(*call->ic_data())) {
InsertBefore(call,
new (Z) CheckSmiInstr(new (Z) Value(input), call->deopt_id(),
call->token_pos()),
call->env(), FlowGraph::kEffect);
unary_op = new (Z)
UnarySmiOpInstr(op_kind, new (Z) Value(input), call->deopt_id());
} else if ((op_kind == Token::kBIT_NOT) &&
HasOnlySmiOrMint(*call->ic_data()) &&
FlowGraphCompiler::SupportsUnboxedMints()) {
unary_op = new (Z)
UnaryMintOpInstr(op_kind, new (Z) Value(input), call->deopt_id());
} else if (HasOnlyOneDouble(*call->ic_data()) &&
(op_kind == Token::kNEGATE) && CanUnboxDouble()) {
AddReceiverCheck(call);
unary_op = new (Z) UnaryDoubleOpInstr(Token::kNEGATE, new (Z) Value(input),
call->deopt_id());
} else {
return false;
}
ASSERT(unary_op != NULL);
ReplaceCall(call, unary_op);
return true;
}
// Using field class.
RawField* JitOptimizer::GetField(intptr_t class_id, const String& field_name) {
Class& cls = Class::Handle(Z, isolate()->class_table()->At(class_id));
Field& field = Field::Handle(Z);
while (!cls.IsNull()) {
field = cls.LookupInstanceField(field_name);
if (!field.IsNull()) {
if (Compiler::IsBackgroundCompilation() ||
FLAG_force_clone_compiler_objects) {
return field.CloneFromOriginal();
} else {
return field.raw();
}
}
cls = cls.SuperClass();
}
return Field::null();
}
bool JitOptimizer::InlineImplicitInstanceGetter(InstanceCallInstr* call) {
ASSERT(call->HasICData());
const ICData& ic_data = *call->ic_data();
ASSERT(ic_data.HasOneTarget());
GrowableArray<intptr_t> class_ids;
ic_data.GetClassIdsAt(0, &class_ids);
ASSERT(class_ids.length() == 1);
// Inline implicit instance getter.
const String& field_name =
String::Handle(Z, Field::NameFromGetter(call->function_name()));
const Field& field = Field::ZoneHandle(Z, GetField(class_ids[0], field_name));
ASSERT(!field.IsNull());
if (flow_graph()->InstanceCallNeedsClassCheck(call,
RawFunction::kImplicitGetter)) {
AddReceiverCheck(call);
}
LoadFieldInstr* load = new (Z) LoadFieldInstr(
new (Z) Value(call->ArgumentAt(0)), &field,
AbstractType::ZoneHandle(Z, field.type()), call->token_pos());
load->set_is_immutable(field.is_final());
if (field.guarded_cid() != kIllegalCid) {
if (!field.is_nullable() || (field.guarded_cid() == kNullCid)) {
load->set_result_cid(field.guarded_cid());
}
flow_graph()->parsed_function().AddToGuardedFields(&field);
}
// Discard the environment from the original instruction because the load
// can't deoptimize.
call->RemoveEnvironment();
ReplaceCall(call, load);
if (load->result_cid() != kDynamicCid) {
// Reset value types if guarded_cid was used.
for (Value::Iterator it(load->input_use_list()); !it.Done(); it.Advance()) {
it.Current()->SetReachingType(NULL);
}
}
return true;
}
bool JitOptimizer::InlineFloat32x4BinaryOp(InstanceCallInstr* call,
Token::Kind op_kind) {
if (!ShouldInlineSimd()) {
return false;
}
ASSERT(call->ArgumentCount() == 2);
Definition* left = call->ArgumentAt(0);
Definition* right = call->ArgumentAt(1);
// Type check left.
AddCheckClass(left, ICData::ZoneHandle(
Z, call->ic_data()->AsUnaryClassChecksForArgNr(0)),
call->deopt_id(), call->env(), call);
// Type check right.
AddCheckClass(right, ICData::ZoneHandle(
Z, call->ic_data()->AsUnaryClassChecksForArgNr(1)),
call->deopt_id(), call->env(), call);
// Replace call.
BinaryFloat32x4OpInstr* float32x4_bin_op = new (Z) BinaryFloat32x4OpInstr(
op_kind, new (Z) Value(left), new (Z) Value(right), call->deopt_id());
ReplaceCall(call, float32x4_bin_op);
return true;
}
bool JitOptimizer::InlineInt32x4BinaryOp(InstanceCallInstr* call,
Token::Kind op_kind) {
if (!ShouldInlineSimd()) {
return false;
}
ASSERT(call->ArgumentCount() == 2);
Definition* left = call->ArgumentAt(0);
Definition* right = call->ArgumentAt(1);
// Type check left.
AddCheckClass(left, ICData::ZoneHandle(
Z, call->ic_data()->AsUnaryClassChecksForArgNr(0)),
call->deopt_id(), call->env(), call);
// Type check right.
AddCheckClass(right, ICData::ZoneHandle(
Z, call->ic_data()->AsUnaryClassChecksForArgNr(1)),
call->deopt_id(), call->env(), call);
// Replace call.
BinaryInt32x4OpInstr* int32x4_bin_op = new (Z) BinaryInt32x4OpInstr(
op_kind, new (Z) Value(left), new (Z) Value(right), call->deopt_id());
ReplaceCall(call, int32x4_bin_op);
return true;
}
bool JitOptimizer::InlineFloat64x2BinaryOp(InstanceCallInstr* call,
Token::Kind op_kind) {
if (!ShouldInlineSimd()) {
return false;
}
ASSERT(call->ArgumentCount() == 2);
Definition* left = call->ArgumentAt(0);
Definition* right = call->ArgumentAt(1);
// Type check left.
AddCheckClass(
left, ICData::ZoneHandle(call->ic_data()->AsUnaryClassChecksForArgNr(0)),
call->deopt_id(), call->env(), call);
// Type check right.
AddCheckClass(
right, ICData::ZoneHandle(call->ic_data()->AsUnaryClassChecksForArgNr(1)),
call->deopt_id(), call->env(), call);
// Replace call.
BinaryFloat64x2OpInstr* float64x2_bin_op = new (Z) BinaryFloat64x2OpInstr(
op_kind, new (Z) Value(left), new (Z) Value(right), call->deopt_id());
ReplaceCall(call, float64x2_bin_op);
return true;
}
// Only unique implicit instance getters can be currently handled.
bool JitOptimizer::TryInlineInstanceGetter(InstanceCallInstr* call) {
ASSERT(call->HasICData());
const ICData& ic_data = *call->ic_data();
if (ic_data.NumberOfUsedChecks() == 0) {
// No type feedback collected.
return false;
}
if (!ic_data.HasOneTarget()) {
// Polymorphic sites are inlined like normal methods by conventional
// inlining in FlowGraphInliner.
return false;
}
const Function& target = Function::Handle(Z, ic_data.GetTargetAt(0));
if (target.kind() != RawFunction::kImplicitGetter) {
// Non-implicit getters are inlined like normal methods by conventional
// inlining in FlowGraphInliner.
return false;
}
return InlineImplicitInstanceGetter(call);
}
void JitOptimizer::ReplaceWithMathCFunction(
InstanceCallInstr* call,
MethodRecognizer::Kind recognized_kind) {
AddReceiverCheck(call);
ZoneGrowableArray<Value*>* args =
new (Z) ZoneGrowableArray<Value*>(call->ArgumentCount());
for (intptr_t i = 0; i < call->ArgumentCount(); i++) {
args->Add(new (Z) Value(call->ArgumentAt(i)));
}
InvokeMathCFunctionInstr* invoke = new (Z) InvokeMathCFunctionInstr(
args, call->deopt_id(), recognized_kind, call->token_pos());
ReplaceCall(call, invoke);
}
// Inline only simple, frequently called core library methods.
bool JitOptimizer::TryInlineInstanceMethod(InstanceCallInstr* call) {
ASSERT(call->HasICData());
const ICData& ic_data = *call->ic_data();
if (ic_data.NumberOfUsedChecks() != 1) {
// No type feedback collected or multiple targets found.
return false;
}
Function& target = Function::Handle(Z);
GrowableArray<intptr_t> class_ids;
ic_data.GetCheckAt(0, &class_ids, &target);
MethodRecognizer::Kind recognized_kind =
MethodRecognizer::RecognizeKind(target);
if (CanUnboxDouble() &&
(recognized_kind == MethodRecognizer::kIntegerToDouble)) {
if (class_ids[0] == kSmiCid) {
AddReceiverCheck(call);
ReplaceCall(call,
new (Z) SmiToDoubleInstr(new (Z) Value(call->ArgumentAt(0)),
call->token_pos()));
return true;
} else if ((class_ids[0] == kMintCid) && CanConvertUnboxedMintToDouble()) {
AddReceiverCheck(call);
ReplaceCall(call,
new (Z) MintToDoubleInstr(new (Z) Value(call->ArgumentAt(0)),
call->deopt_id()));
return true;
}
}
if (class_ids[0] == kDoubleCid) {
if (!CanUnboxDouble()) {
return false;
}
switch (recognized_kind) {
case MethodRecognizer::kDoubleToInteger: {
AddReceiverCheck(call);
ASSERT(call->HasICData());
const ICData& ic_data = *call->ic_data();
Definition* input = call->ArgumentAt(0);
Definition* d2i_instr = NULL;
if (ic_data.HasDeoptReason(ICData::kDeoptDoubleToSmi)) {
// Do not repeatedly deoptimize because result didn't fit into Smi.
d2i_instr = new (Z) DoubleToIntegerInstr(new (Z) Value(input), call);
} else {
// Optimistically assume result fits into Smi.
d2i_instr =
new (Z) DoubleToSmiInstr(new (Z) Value(input), call->deopt_id());
}
ReplaceCall(call, d2i_instr);
return true;
}
case MethodRecognizer::kDoubleMod:
case MethodRecognizer::kDoubleRound:
ReplaceWithMathCFunction(call, recognized_kind);
return true;
case MethodRecognizer::kDoubleTruncate:
case MethodRecognizer::kDoubleFloor:
case MethodRecognizer::kDoubleCeil:
if (!TargetCPUFeatures::double_truncate_round_supported()) {
ReplaceWithMathCFunction(call, recognized_kind);
} else {
AddReceiverCheck(call);
DoubleToDoubleInstr* d2d_instr =
new (Z) DoubleToDoubleInstr(new (Z) Value(call->ArgumentAt(0)),
recognized_kind, call->deopt_id());
ReplaceCall(call, d2d_instr);
}
return true;
default:
break;
}
}
return FlowGraphInliner::TryReplaceInstanceCallWithInline(
flow_graph_, current_iterator(), call);
}
// If type tests specified by 'ic_data' do not depend on type arguments,
// return mapping cid->result in 'results' (i : cid; i + 1: result).
// If all tests yield the same result, return it otherwise return Bool::null.
// If no mapping is possible, 'results' is empty.
// An instance-of test returning all same results can be converted to a class
// check.
RawBool* JitOptimizer::InstanceOfAsBool(
const ICData& ic_data,
const AbstractType& type,
ZoneGrowableArray<intptr_t>* results) const {
ASSERT(results->is_empty());
ASSERT(ic_data.NumArgsTested() == 1); // Unary checks only.
if (type.IsFunctionType() || type.IsDartFunctionType() ||
!type.IsInstantiated() || type.IsMalformedOrMalbounded()) {
return Bool::null();
}
const Class& type_class = Class::Handle(Z, type.type_class());
const intptr_t num_type_args = type_class.NumTypeArguments();
if (num_type_args > 0) {
// Only raw types can be directly compared, thus disregarding type
// arguments.
const intptr_t num_type_params = type_class.NumTypeParameters();
const intptr_t from_index = num_type_args - num_type_params;
const TypeArguments& type_arguments =
TypeArguments::Handle(Z, type.arguments());
const bool is_raw_type = type_arguments.IsNull() ||
type_arguments.IsRaw(from_index, num_type_params);
if (!is_raw_type) {
// Unknown result.
return Bool::null();
}
}
const ClassTable& class_table = *isolate()->class_table();
Bool& prev = Bool::Handle(Z);
Class& cls = Class::Handle(Z);
bool results_differ = false;
for (int i = 0; i < ic_data.NumberOfChecks(); i++) {
cls = class_table.At(ic_data.GetReceiverClassIdAt(i));
if (cls.NumTypeArguments() > 0) {
return Bool::null();
}
const bool is_subtype =
cls.IsSubtypeOf(TypeArguments::Handle(Z), type_class,
TypeArguments::Handle(Z), NULL, NULL, Heap::kOld);
results->Add(cls.id());
results->Add(is_subtype);
if (prev.IsNull()) {
prev = Bool::Get(is_subtype).raw();
} else {
if (is_subtype != prev.value()) {
results_differ = true;
}
}
}
return results_differ ? Bool::null() : prev.raw();
}
// Returns true if checking against this type is a direct class id comparison.
bool JitOptimizer::TypeCheckAsClassEquality(const AbstractType& type) {
ASSERT(type.IsFinalized() && !type.IsMalformedOrMalbounded());
// Requires CHA.
if (!type.IsInstantiated()) return false;
// Function types have different type checking rules.
if (type.IsFunctionType()) return false;
const Class& type_class = Class::Handle(type.type_class());
// Could be an interface check?
if (CHA::IsImplemented(type_class)) return false;
// Check if there are subclasses.
if (CHA::HasSubclasses(type_class)) {
return false;
}
// Private classes cannot be subclassed by later loaded libs.
if (!type_class.IsPrivate()) {
if (FLAG_use_cha_deopt || isolate()->all_classes_finalized()) {
if (FLAG_trace_cha) {
THR_Print(
" **(CHA) Typecheck as class equality since no "
"subclasses: %s\n",
type_class.ToCString());
}
if (FLAG_use_cha_deopt) {
thread()->cha()->AddToGuardedClasses(type_class, /*subclass_count=*/0);
}
} else {
return false;
}
}
const intptr_t num_type_args = type_class.NumTypeArguments();
if (num_type_args > 0) {
// Only raw types can be directly compared, thus disregarding type
// arguments.
const intptr_t num_type_params = type_class.NumTypeParameters();
const intptr_t from_index = num_type_args - num_type_params;
const TypeArguments& type_arguments =
TypeArguments::Handle(type.arguments());
const bool is_raw_type = type_arguments.IsNull() ||
type_arguments.IsRaw(from_index, num_type_params);
return is_raw_type;
}
return true;
}
static bool CidTestResultsContains(const ZoneGrowableArray<intptr_t>& results,
intptr_t test_cid) {
for (intptr_t i = 0; i < results.length(); i += 2) {
if (results[i] == test_cid) return true;
}
return false;
}
static void TryAddTest(ZoneGrowableArray<intptr_t>* results,
intptr_t test_cid,
bool result) {
if (!CidTestResultsContains(*results, test_cid)) {
results->Add(test_cid);
results->Add(result);
}
}
// Tries to add cid tests to 'results' so that no deoptimization is
// necessary.
// TODO(srdjan): Do also for other than 'int' type.
static bool TryExpandTestCidsResult(ZoneGrowableArray<intptr_t>* results,
const AbstractType& type) {
ASSERT(results->length() >= 2); // At least on eentry.
const ClassTable& class_table = *Isolate::Current()->class_table();
if ((*results)[0] != kSmiCid) {
const Class& cls = Class::Handle(class_table.At(kSmiCid));
const Class& type_class = Class::Handle(type.type_class());
const bool smi_is_subtype =
cls.IsSubtypeOf(TypeArguments::Handle(), type_class,
TypeArguments::Handle(), NULL, NULL, Heap::kOld);
results->Add((*results)[results->length() - 2]);
results->Add((*results)[results->length() - 2]);
for (intptr_t i = results->length() - 3; i > 1; --i) {
(*results)[i] = (*results)[i - 2];
}
(*results)[0] = kSmiCid;
(*results)[1] = smi_is_subtype;
}
ASSERT(type.IsInstantiated() && !type.IsMalformedOrMalbounded());
ASSERT(results->length() >= 2);
if (type.IsIntType()) {
ASSERT((*results)[0] == kSmiCid);
TryAddTest(results, kMintCid, true);
TryAddTest(results, kBigintCid, true);
// Cannot deoptimize since all tests returning true have been added.
return false;
}
return true; // May deoptimize since we have not identified all 'true' tests.
}
// Tells whether the function of the call matches the core private name.
static bool matches_core(InstanceCallInstr* call, const String& name) {
return call->function_name().raw() == Library::PrivateCoreLibName(name).raw();
}
// TODO(srdjan): Use ICData to check if always true or false.
void JitOptimizer::ReplaceWithInstanceOf(InstanceCallInstr* call) {
ASSERT(Token::IsTypeTestOperator(call->token_kind()));
Definition* left = call->ArgumentAt(0);
Definition* type_args = NULL;
AbstractType& type = AbstractType::ZoneHandle(Z);
bool negate = false;
if (call->ArgumentCount() == 2) {
type_args = flow_graph()->constant_null();
if (matches_core(call, Symbols::_simpleInstanceOf())) {
type =
AbstractType::Cast(call->ArgumentAt(1)->AsConstant()->value()).raw();
negate = false; // Just to be sure.
} else {
if (matches_core(call, Symbols::_instanceOfNum())) {
type = Type::Number();
} else if (matches_core(call, Symbols::_instanceOfInt())) {
type = Type::IntType();
} else if (matches_core(call, Symbols::_instanceOfSmi())) {
type = Type::SmiType();
} else if (matches_core(call, Symbols::_instanceOfDouble())) {
type = Type::Double();
} else if (matches_core(call, Symbols::_instanceOfString())) {
type = Type::StringType();
} else {
UNIMPLEMENTED();
}
negate =
Bool::Cast(
call->ArgumentAt(1)->OriginalDefinition()->AsConstant()->value())
.value();
}
} else {
type_args = call->ArgumentAt(1);
type = AbstractType::Cast(call->ArgumentAt(2)->AsConstant()->value()).raw();
negate =
Bool::Cast(
call->ArgumentAt(3)->OriginalDefinition()->AsConstant()->value())
.value();
}
const ICData& unary_checks =
ICData::ZoneHandle(Z, call->ic_data()->AsUnaryClassChecks());
if ((unary_checks.NumberOfChecks() > 0) &&
(unary_checks.NumberOfChecks() <= FLAG_max_polymorphic_checks)) {
ZoneGrowableArray<intptr_t>* results =
new (Z) ZoneGrowableArray<intptr_t>(unary_checks.NumberOfChecks() * 2);
Bool& as_bool =
Bool::ZoneHandle(Z, InstanceOfAsBool(unary_checks, type, results));
if (as_bool.IsNull()) {
if (results->length() == unary_checks.NumberOfChecks() * 2) {
const bool can_deopt = TryExpandTestCidsResult(results, type);
TestCidsInstr* test_cids = new (Z) TestCidsInstr(
call->token_pos(), negate ? Token::kISNOT : Token::kIS,
new (Z) Value(left), *results,
can_deopt ? call->deopt_id() : Thread::kNoDeoptId);
// Remove type.
ReplaceCall(call, test_cids);
return;
}
} else {
// TODO(srdjan): Use TestCidsInstr also for this case.
// One result only.
AddReceiverCheck(call);
if (negate) {
as_bool = Bool::Get(!as_bool.value()).raw();
}
ConstantInstr* bool_const = flow_graph()->GetConstant(as_bool);
for (intptr_t i = 0; i < call->ArgumentCount(); ++i) {
PushArgumentInstr* push = call->PushArgumentAt(i);
push->ReplaceUsesWith(push->value()->definition());
push->RemoveFromGraph();
}
call->ReplaceUsesWith(bool_const);
ASSERT(current_iterator()->Current() == call);
current_iterator()->RemoveCurrentFromGraph();
return;
}
}
if (TypeCheckAsClassEquality(type)) {
LoadClassIdInstr* left_cid = new (Z) LoadClassIdInstr(new (Z) Value(left));
InsertBefore(call, left_cid, NULL, FlowGraph::kValue);
const intptr_t type_cid = Class::Handle(Z, type.type_class()).id();
ConstantInstr* cid =
flow_graph()->GetConstant(Smi::Handle(Z, Smi::New(type_cid)));
StrictCompareInstr* check_cid = new (Z) StrictCompareInstr(
call->token_pos(), negate ? Token::kNE_STRICT : Token::kEQ_STRICT,
new (Z) Value(left_cid), new (Z) Value(cid),
false); // No number check.
ReplaceCall(call, check_cid);
return;
}
InstanceOfInstr* instance_of = new (Z)
InstanceOfInstr(call->token_pos(), new (Z) Value(left),
new (Z) Value(type_args), type, negate, call->deopt_id());
ReplaceCall(call, instance_of);
}
// TODO(srdjan): Apply optimizations as in ReplaceWithInstanceOf (TestCids).
void JitOptimizer::ReplaceWithTypeCast(InstanceCallInstr* call) {
ASSERT(Token::IsTypeCastOperator(call->token_kind()));
Definition* left = call->ArgumentAt(0);
Definition* type_args = call->ArgumentAt(1);
const AbstractType& type =
AbstractType::Cast(call->ArgumentAt(2)->AsConstant()->value());
ASSERT(!type.IsMalformedOrMalbounded());
const ICData& unary_checks =
ICData::ZoneHandle(Z, call->ic_data()->AsUnaryClassChecks());
if ((unary_checks.NumberOfChecks() > 0) &&
(unary_checks.NumberOfChecks() <= FLAG_max_polymorphic_checks)) {
ZoneGrowableArray<intptr_t>* results =
new (Z) ZoneGrowableArray<intptr_t>(unary_checks.NumberOfChecks() * 2);
const Bool& as_bool =
Bool::ZoneHandle(Z, InstanceOfAsBool(unary_checks, type, results));
if (as_bool.raw() == Bool::True().raw()) {
AddReceiverCheck(call);
// Remove the original push arguments.
for (intptr_t i = 0; i < call->ArgumentCount(); ++i) {
PushArgumentInstr* push = call->PushArgumentAt(i);
push->ReplaceUsesWith(push->value()->definition());
push->RemoveFromGraph();
}
// Remove call, replace it with 'left'.
call->ReplaceUsesWith(left);
ASSERT(current_iterator()->Current() == call);
current_iterator()->RemoveCurrentFromGraph();
return;
}
}
AssertAssignableInstr* assert_as = new (Z) AssertAssignableInstr(
call->token_pos(), new (Z) Value(left), new (Z) Value(type_args), type,
Symbols::InTypeCast(), call->deopt_id());
ReplaceCall(call, assert_as);
}
// Tries to optimize instance call by replacing it with a faster instruction
// (e.g, binary op, field load, ..).
void JitOptimizer::VisitInstanceCall(InstanceCallInstr* instr) {
if (!instr->HasICData() || (instr->ic_data()->NumberOfUsedChecks() == 0)) {
return;
}
const Token::Kind op_kind = instr->token_kind();
// Type test is special as it always gets converted into inlined code.
if (Token::IsTypeTestOperator(op_kind)) {
ReplaceWithInstanceOf(instr);
return;
}
if (Token::IsTypeCastOperator(op_kind)) {
ReplaceWithTypeCast(instr);
return;
}
const ICData& unary_checks =
ICData::ZoneHandle(Z, instr->ic_data()->AsUnaryClassChecks());
const bool is_dense = CheckClassInstr::IsDenseCidRange(unary_checks);
const intptr_t max_checks = (op_kind == Token::kEQ)
? FLAG_max_equality_polymorphic_checks
: FLAG_max_polymorphic_checks;
if ((unary_checks.NumberOfChecks() > max_checks) && !is_dense &&
flow_graph()->InstanceCallNeedsClassCheck(
instr, RawFunction::kRegularFunction)) {
// Too many checks, it will be megamorphic which needs unary checks.
instr->set_ic_data(&unary_checks);
return;
}
if ((op_kind == Token::kASSIGN_INDEX) && TryReplaceWithIndexedOp(instr)) {
return;
}
if ((op_kind == Token::kINDEX) && TryReplaceWithIndexedOp(instr)) {
return;
}
if (op_kind == Token::kEQ && TryReplaceWithEqualityOp(instr, op_kind)) {
return;
}
if (Token::IsRelationalOperator(op_kind) &&
TryReplaceWithRelationalOp(instr, op_kind)) {
return;
}
if (Token::IsBinaryOperator(op_kind) &&
TryReplaceWithBinaryOp(instr, op_kind)) {
return;
}
if (Token::IsUnaryOperator(op_kind) &&
TryReplaceWithUnaryOp(instr, op_kind)) {
return;
}
if ((op_kind == Token::kGET) && TryInlineInstanceGetter(instr)) {
return;
}
if ((op_kind == Token::kSET) &&
TryInlineInstanceSetter(instr, unary_checks)) {
return;
}
if (TryInlineInstanceMethod(instr)) {
return;
}
bool has_one_target = unary_checks.HasOneTarget();
if (has_one_target) {
// Check if the single target is a polymorphic target, if it is,
// we don't have one target.
const Function& target = Function::Handle(Z, unary_checks.GetTargetAt(0));
if (target.recognized_kind() == MethodRecognizer::kObjectRuntimeType) {
has_one_target = PolymorphicInstanceCallInstr::ComputeRuntimeType(
unary_checks) != Type::null();
} else {
const bool polymorphic_target =
MethodRecognizer::PolymorphicTarget(target);
has_one_target = !polymorphic_target;
}
}
if (has_one_target) {
const Function& target = Function::Handle(Z, unary_checks.GetTargetAt(0));
const RawFunction::Kind function_kind = target.kind();
if (!flow_graph()->InstanceCallNeedsClassCheck(instr, function_kind)) {
PolymorphicInstanceCallInstr* call =
new (Z) PolymorphicInstanceCallInstr(instr, unary_checks,
/* call_with_checks = */ false,
/* complete = */ false);
instr->ReplaceWith(call, current_iterator());
return;
}
}
if ((unary_checks.NumberOfChecks() <= FLAG_max_polymorphic_checks) ||
(has_one_target && is_dense)) {
bool call_with_checks;
if (has_one_target && FLAG_polymorphic_with_deopt) {
// Type propagation has not run yet, we cannot eliminate the check.
AddReceiverCheck(instr);
// Call can still deoptimize, do not detach environment from instr.
call_with_checks = false;
} else {
call_with_checks = true;
}
PolymorphicInstanceCallInstr* call = new (Z)
PolymorphicInstanceCallInstr(instr, unary_checks, call_with_checks,
/* complete = */ false);
instr->ReplaceWith(call, current_iterator());
}
}
void JitOptimizer::VisitStaticCall(StaticCallInstr* call) {
MethodRecognizer::Kind recognized_kind =
MethodRecognizer::RecognizeKind(call->function());
switch (recognized_kind) {
case MethodRecognizer::kObjectConstructor:
case MethodRecognizer::kObjectArrayAllocate:
case MethodRecognizer::kFloat32x4Zero:
case MethodRecognizer::kFloat32x4Splat:
case MethodRecognizer::kFloat32x4Constructor:
case MethodRecognizer::kFloat32x4FromFloat64x2:
case MethodRecognizer::kFloat64x2Constructor:
case MethodRecognizer::kFloat64x2Zero:
case MethodRecognizer::kFloat64x2Splat:
case MethodRecognizer::kFloat64x2FromFloat32x4:
case MethodRecognizer::kInt32x4BoolConstructor:
case MethodRecognizer::kInt32x4Constructor:
case MethodRecognizer::kMathSqrt:
case MethodRecognizer::kMathDoublePow:
case MethodRecognizer::kMathSin:
case MethodRecognizer::kMathCos:
case MethodRecognizer::kMathTan:
case MethodRecognizer::kMathAsin:
case MethodRecognizer::kMathAcos:
case MethodRecognizer::kMathAtan:
case MethodRecognizer::kMathAtan2:
FlowGraphInliner::TryReplaceStaticCallWithInline(
flow_graph_, current_iterator(), call);
break;
case MethodRecognizer::kMathMin:
case MethodRecognizer::kMathMax: {
// We can handle only monomorphic min/max call sites with both arguments
// being either doubles or smis.
if (CanUnboxDouble() && call->HasICData() &&
(call->ic_data()->NumberOfChecks() == 1)) {
const ICData& ic_data = *call->ic_data();
intptr_t result_cid = kIllegalCid;
if (ICDataHasReceiverArgumentClassIds(ic_data, kDoubleCid,
kDoubleCid)) {
result_cid = kDoubleCid;
} else if (ICDataHasReceiverArgumentClassIds(ic_data, kSmiCid,
kSmiCid)) {
result_cid = kSmiCid;
}
if (result_cid != kIllegalCid) {
MathMinMaxInstr* min_max = new (Z) MathMinMaxInstr(
recognized_kind, new (Z) Value(call->ArgumentAt(0)),
new (Z) Value(call->ArgumentAt(1)), call->deopt_id(), result_cid);
const ICData& unary_checks =
ICData::ZoneHandle(Z, ic_data.AsUnaryClassChecks());
AddCheckClass(min_max->left()->definition(), unary_checks,
call->deopt_id(), call->env(), call);
AddCheckClass(min_max->right()->definition(), unary_checks,
call->deopt_id(), call->env(), call);
ReplaceCall(call, min_max);
}
}
break;
}
case MethodRecognizer::kDoubleFromInteger: {
if (call->HasICData() && (call->ic_data()->NumberOfChecks() == 1)) {
const ICData& ic_data = *call->ic_data();
if (CanUnboxDouble()) {
if (ArgIsAlways(kSmiCid, ic_data, 1)) {
Definition* arg = call->ArgumentAt(1);
AddCheckSmi(arg, call->deopt_id(), call->env(), call);
ReplaceCall(call, new (Z) SmiToDoubleInstr(new (Z) Value(arg),
call->token_pos()));
} else if (ArgIsAlways(kMintCid, ic_data, 1) &&
CanConvertUnboxedMintToDouble()) {
Definition* arg = call->ArgumentAt(1);
ReplaceCall(call, new (Z) MintToDoubleInstr(new (Z) Value(arg),
call->deopt_id()));
}
}
}
break;
}
default:
break;
}
}
void JitOptimizer::VisitStoreInstanceField(StoreInstanceFieldInstr* instr) {
if (instr->IsUnboxedStore()) {
// Determine if this field should be unboxed based on the usage of getter
// and setter functions: The heuristic requires that the setter has a
// usage count of at least 1/kGetterSetterRatio of the getter usage count.
// This is to avoid unboxing fields where the setter is never or rarely
// executed.
const Field& field = instr->field();
const String& field_name = String::Handle(Z, field.name());
const Class& owner = Class::Handle(Z, field.Owner());
const Function& getter =
Function::Handle(Z, owner.LookupGetterFunction(field_name));
const Function& setter =
Function::Handle(Z, owner.LookupSetterFunction(field_name));
bool unboxed_field = false;
if (!getter.IsNull() && !setter.IsNull()) {
if (field.is_double_initialized()) {
unboxed_field = true;
} else if ((setter.usage_counter() > 0) &&
((FLAG_getter_setter_ratio * setter.usage_counter()) >=
getter.usage_counter())) {
unboxed_field = true;
}
}
if (!unboxed_field) {
// TODO(srdjan): Instead of aborting pass this field to the mutator thread
// so that it can:
// - set it to unboxed
// - deoptimize dependent code.
if (Compiler::IsBackgroundCompilation()) {
isolate()->AddDeoptimizingBoxedField(field);
Compiler::AbortBackgroundCompilation(
Thread::kNoDeoptId, "Unboxing instance field while compiling");
UNREACHABLE();
}
if (FLAG_trace_optimization || FLAG_trace_field_guards) {
THR_Print("Disabling unboxing of %s\n", field.ToCString());
if (!setter.IsNull()) {
OS::Print(" setter usage count: %" Pd "\n", setter.usage_counter());
}
if (!getter.IsNull()) {
OS::Print(" getter usage count: %" Pd "\n", getter.usage_counter());
}
}
ASSERT(field.IsOriginal());
field.set_is_unboxing_candidate(false);
field.DeoptimizeDependentCode();
} else {
flow_graph()->parsed_function().AddToGuardedFields(&field);
}
}
}
void JitOptimizer::VisitAllocateContext(AllocateContextInstr* instr) {
// Replace generic allocation with a sequence of inlined allocation and
// explicit initalizing stores.
AllocateUninitializedContextInstr* replacement =
new AllocateUninitializedContextInstr(instr->token_pos(),
instr->num_context_variables());
instr->ReplaceWith(replacement, current_iterator());
StoreInstanceFieldInstr* store = new (Z)
StoreInstanceFieldInstr(Context::parent_offset(), new Value(replacement),
new Value(flow_graph_->constant_null()),
kNoStoreBarrier, instr->token_pos());
// Storing into uninitialized memory; remember to prevent dead store
// elimination and ensure proper GC barrier.
store->set_is_initialization(true);
flow_graph_->InsertAfter(replacement, store, NULL, FlowGraph::kEffect);
Definition* cursor = store;
for (intptr_t i = 0; i < instr->num_context_variables(); ++i) {
store = new (Z) StoreInstanceFieldInstr(
Context::variable_offset(i), new Value(replacement),
new Value(flow_graph_->constant_null()), kNoStoreBarrier,
instr->token_pos());
// Storing into uninitialized memory; remember to prevent dead store
// elimination and ensure proper GC barrier.
store->set_is_initialization(true);
flow_graph_->InsertAfter(cursor, store, NULL, FlowGraph::kEffect);
cursor = store;
}
}
void JitOptimizer::VisitLoadCodeUnits(LoadCodeUnitsInstr* instr) {
// TODO(zerny): Use kUnboxedUint32 once it is fully supported/optimized.
#if defined(TARGET_ARCH_IA32) || defined(TARGET_ARCH_ARM)
if (!instr->can_pack_into_smi()) instr->set_representation(kUnboxedMint);
#endif
}
bool JitOptimizer::TryInlineInstanceSetter(InstanceCallInstr* instr,
const ICData& unary_ic_data) {
ASSERT((unary_ic_data.NumberOfChecks() > 0) &&
(unary_ic_data.NumArgsTested() == 1));
if (I->type_checks()) {
// Checked mode setters are inlined like normal methods by conventional
// inlining.
return false;
}
ASSERT(instr->HasICData());
if (unary_ic_data.NumberOfChecks() == 0) {
// No type feedback collected.
return false;
}
if (!unary_ic_data.HasOneTarget()) {
// Polymorphic sites are inlined like normal method calls by conventional
// inlining.
return false;
}
Function& target = Function::Handle(Z);
intptr_t class_id;
unary_ic_data.GetOneClassCheckAt(0, &class_id, &target);
if (target.kind() != RawFunction::kImplicitSetter) {
// Non-implicit setter are inlined like normal method calls.
return false;
}
// Inline implicit instance setter.
const String& field_name =
String::Handle(Z, Field::NameFromSetter(instr->function_name()));
const Field& field = Field::ZoneHandle(Z, GetField(class_id, field_name));
ASSERT(!field.IsNull());
if (flow_graph()->InstanceCallNeedsClassCheck(instr,
RawFunction::kImplicitSetter)) {
AddReceiverCheck(instr);
}
if (field.guarded_cid() != kDynamicCid) {
ASSERT(FLAG_use_field_guards);
InsertBefore(
instr, new (Z) GuardFieldClassInstr(new (Z) Value(instr->ArgumentAt(1)),
field, instr->deopt_id()),
instr->env(), FlowGraph::kEffect);
}
if (field.needs_length_check()) {
ASSERT(FLAG_use_field_guards);
InsertBefore(instr, new (Z) GuardFieldLengthInstr(
new (Z) Value(instr->ArgumentAt(1)), field,
instr->deopt_id()),
instr->env(), FlowGraph::kEffect);
}
// Field guard was detached.
StoreInstanceFieldInstr* store = new (Z)
StoreInstanceFieldInstr(field, new (Z) Value(instr->ArgumentAt(0)),
new (Z) Value(instr->ArgumentAt(1)),
kEmitStoreBarrier, instr->token_pos());
if (store->IsUnboxedStore()) {
flow_graph()->parsed_function().AddToGuardedFields(&field);
}
// Discard the environment from the original instruction because the store
// can't deoptimize.
instr->RemoveEnvironment();
ReplaceCall(instr, store);
return true;
}
} // namespace dart
#endif // DART_PRECOMPILED_RUNTIME