v8/src/codegen.cc

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// Copyright 2009 the V8 project authors. All rights reserved.
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following
// disclaimer in the documentation and/or other materials provided
// with the distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "v8.h"
#include "bootstrapper.h"
#include "codegen-inl.h"
#include "compiler.h"
#include "debug.h"
#include "liveedit.h"
#include "oprofile-agent.h"
#include "prettyprinter.h"
#include "register-allocator-inl.h"
#include "rewriter.h"
#include "runtime.h"
#include "scopeinfo.h"
#include "stub-cache.h"
namespace v8 {
namespace internal {
#define __ ACCESS_MASM(masm_)
#ifdef DEBUG
Comment::Comment(MacroAssembler* masm, const char* msg)
: masm_(masm), msg_(msg) {
__ RecordComment(msg);
}
Comment::~Comment() {
if (msg_[0] == '[') __ RecordComment("]");
}
#endif // DEBUG
#undef __
CodeGenerator* CodeGeneratorScope::top_ = NULL;
DeferredCode::DeferredCode()
: masm_(CodeGeneratorScope::Current()->masm()),
statement_position_(masm_->current_statement_position()),
position_(masm_->current_position()) {
ASSERT(statement_position_ != RelocInfo::kNoPosition);
ASSERT(position_ != RelocInfo::kNoPosition);
CodeGeneratorScope::Current()->AddDeferred(this);
#ifdef DEBUG
comment_ = "";
#endif
// Copy the register locations from the code generator's frame.
// These are the registers that will be spilled on entry to the
// deferred code and restored on exit.
VirtualFrame* frame = CodeGeneratorScope::Current()->frame();
int sp_offset = frame->fp_relative(frame->stack_pointer_);
for (int i = 0; i < RegisterAllocator::kNumRegisters; i++) {
int loc = frame->register_location(i);
if (loc == VirtualFrame::kIllegalIndex) {
registers_[i] = kIgnore;
} else if (frame->elements_[loc].is_synced()) {
// Needs to be restored on exit but not saved on entry.
registers_[i] = frame->fp_relative(loc) | kSyncedFlag;
} else {
int offset = frame->fp_relative(loc);
registers_[i] = (offset < sp_offset) ? kPush : offset;
}
}
}
void CodeGenerator::ProcessDeferred() {
while (!deferred_.is_empty()) {
DeferredCode* code = deferred_.RemoveLast();
ASSERT(masm_ == code->masm());
// Record position of deferred code stub.
masm_->RecordStatementPosition(code->statement_position());
if (code->position() != RelocInfo::kNoPosition) {
masm_->RecordPosition(code->position());
}
// Generate the code.
Comment cmnt(masm_, code->comment());
masm_->bind(code->entry_label());
code->SaveRegisters();
code->Generate();
code->RestoreRegisters();
masm_->jmp(code->exit_label());
}
}
void CodeGenerator::SetFrame(VirtualFrame* new_frame,
RegisterFile* non_frame_registers) {
RegisterFile saved_counts;
if (has_valid_frame()) {
frame_->DetachFromCodeGenerator();
// The remaining register reference counts are the non-frame ones.
allocator_->SaveTo(&saved_counts);
}
if (new_frame != NULL) {
// Restore the non-frame register references that go with the new frame.
allocator_->RestoreFrom(non_frame_registers);
new_frame->AttachToCodeGenerator();
}
frame_ = new_frame;
saved_counts.CopyTo(non_frame_registers);
}
void CodeGenerator::DeleteFrame() {
if (has_valid_frame()) {
frame_->DetachFromCodeGenerator();
frame_ = NULL;
}
}
void CodeGenerator::MakeCodePrologue(CompilationInfo* info) {
#ifdef DEBUG
bool print_source = false;
bool print_ast = false;
bool print_json_ast = false;
const char* ftype;
if (Bootstrapper::IsActive()) {
print_source = FLAG_print_builtin_source;
print_ast = FLAG_print_builtin_ast;
print_json_ast = FLAG_print_builtin_json_ast;
ftype = "builtin";
} else {
print_source = FLAG_print_source;
print_ast = FLAG_print_ast;
print_json_ast = FLAG_print_json_ast;
ftype = "user-defined";
}
if (FLAG_trace_codegen || print_source || print_ast) {
PrintF("*** Generate code for %s function: ", ftype);
info->function()->name()->ShortPrint();
PrintF(" ***\n");
}
if (print_source) {
PrintF("--- Source from AST ---\n%s\n",
PrettyPrinter().PrintProgram(info->function()));
}
if (print_ast) {
PrintF("--- AST ---\n%s\n",
AstPrinter().PrintProgram(info->function()));
}
if (print_json_ast) {
JsonAstBuilder builder;
PrintF("%s", builder.BuildProgram(info->function()));
}
#endif // DEBUG
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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}
Handle<Code> CodeGenerator::MakeCodeEpilogue(MacroAssembler* masm,
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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Code::Flags flags,
CompilationInfo* info) {
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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// Allocate and install the code.
CodeDesc desc;
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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masm->GetCode(&desc);
ZoneScopeInfo sinfo(info->scope());
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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Handle<Code> code =
Factory::NewCode(desc, &sinfo, flags, masm->CodeObject());
#ifdef ENABLE_DISASSEMBLER
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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bool print_code = Bootstrapper::IsActive()
? FLAG_print_builtin_code
: FLAG_print_code;
if (print_code) {
// Print the source code if available.
Handle<Script> script = info->script();
FunctionLiteral* function = info->function();
if (!script->IsUndefined() && !script->source()->IsUndefined()) {
PrintF("--- Raw source ---\n");
StringInputBuffer stream(String::cast(script->source()));
stream.Seek(function->start_position());
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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// fun->end_position() points to the last character in the stream. We
// need to compensate by adding one to calculate the length.
int source_len =
function->end_position() - function->start_position() + 1;
for (int i = 0; i < source_len; i++) {
if (stream.has_more()) PrintF("%c", stream.GetNext());
}
PrintF("\n\n");
}
PrintF("--- Code ---\n");
code->Disassemble(*function->name()->ToCString());
}
#endif // ENABLE_DISASSEMBLER
if (!code.is_null()) {
Counters::total_compiled_code_size.Increment(code->instruction_size());
}
return code;
}
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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// Generate the code. Takes a function literal, generates code for it, assemble
// all the pieces into a Code object. This function is only to be called by
// the compiler.cc code.
Handle<Code> CodeGenerator::MakeCode(CompilationInfo* info) {
LiveEditFunctionTracker live_edit_tracker(info->function());
Handle<Script> script = info->script();
if (!script->IsUndefined() && !script->source()->IsUndefined()) {
int len = String::cast(script->source())->length();
Counters::total_old_codegen_source_size.Increment(len);
}
MakeCodePrologue(info);
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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// Generate code.
const int kInitialBufferSize = 4 * KB;
MacroAssembler masm(NULL, kInitialBufferSize);
CodeGenerator cgen(&masm);
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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CodeGeneratorScope scope(&cgen);
live_edit_tracker.RecordFunctionScope(info->function()->scope());
cgen.Generate(info);
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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if (cgen.HasStackOverflow()) {
ASSERT(!Top::has_pending_exception());
return Handle<Code>::null();
}
InLoopFlag in_loop = (cgen.loop_nesting() != 0) ? IN_LOOP : NOT_IN_LOOP;
Code::Flags flags = Code::ComputeFlags(Code::FUNCTION, in_loop);
Handle<Code> result = MakeCodeEpilogue(cgen.masm(), flags, info);
live_edit_tracker.RecordFunctionCode(result);
return result;
Initial infrastructure for fast compilation of top-level code. The fast code generator is optimized for compilation time and code size. Currently it is only implemented on IA32. It is potentially triggered for any code in the global scope (including code eval'd in the global scope). It performs a syntactic check and chooses to compile in fast mode if the AST contains only supported constructs and matches some other constraints. Initially supported constructs are * ExpressionStatement, * ReturnStatement, * VariableProxy (variable references) to parameters and stack-allocated locals, * Assignment with lhs a parameter or stack-allocated local, and * Literal This allows compilation of literals at the top level and not much else. All intermediate values are allocated to temporaries and the stack is used for all temporaries. The extra memory traffic is a known issue. The code generated for 'true' is: 0 push ebp 1 mov ebp,esp 3 push esi 4 push edi 5 push 0xf5cca135 ;; object: 0xf5cca135 <undefined> 10 cmp esp,[0x8277efc] 16 jnc 27 (0xf5cbbb1b) 22 call 0xf5cac960 ;; code: STUB, StackCheck, minor: 0 27 push 0xf5cca161 ;; object: 0xf5cca161 <true> 32 mov eax,[esp] 35 mov [ebp+0xf4],eax 38 pop eax 39 mov eax,[ebp+0xf4] 42 mov esp,ebp ;; js return 44 pop ebp 45 ret 0x4 48 mov eax,0xf5cca135 ;; object: 0xf5cca135 <undefined> 53 mov esp,ebp ;; js return 55 pop ebp 56 ret 0x4 Review URL: http://codereview.chromium.org/273050 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@3067 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
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}
#ifdef ENABLE_LOGGING_AND_PROFILING
bool CodeGenerator::ShouldGenerateLog(Expression* type) {
ASSERT(type != NULL);
if (!Logger::is_logging()) return false;
Handle<String> name = Handle<String>::cast(type->AsLiteral()->handle());
if (FLAG_log_regexp) {
static Vector<const char> kRegexp = CStrVector("regexp");
if (name->IsEqualTo(kRegexp))
return true;
}
return false;
}
#endif
Handle<Code> CodeGenerator::ComputeCallInitialize(
int argc,
InLoopFlag in_loop) {
if (in_loop == IN_LOOP) {
// Force the creation of the corresponding stub outside loops,
// because it may be used when clearing the ICs later - it is
// possible for a series of IC transitions to lose the in-loop
// information, and the IC clearing code can't generate a stub
// that it needs so we need to ensure it is generated already.
ComputeCallInitialize(argc, NOT_IN_LOOP);
}
CALL_HEAP_FUNCTION(StubCache::ComputeCallInitialize(argc, in_loop), Code);
}
void CodeGenerator::ProcessDeclarations(ZoneList<Declaration*>* declarations) {
int length = declarations->length();
int globals = 0;
for (int i = 0; i < length; i++) {
Declaration* node = declarations->at(i);
Variable* var = node->proxy()->var();
Slot* slot = var->slot();
// If it was not possible to allocate the variable at compile
// time, we need to "declare" it at runtime to make sure it
// actually exists in the local context.
if ((slot != NULL && slot->type() == Slot::LOOKUP) || !var->is_global()) {
VisitDeclaration(node);
} else {
// Count global variables and functions for later processing
globals++;
}
}
// Return in case of no declared global functions or variables.
if (globals == 0) return;
// Compute array of global variable and function declarations.
Handle<FixedArray> array = Factory::NewFixedArray(2 * globals, TENURED);
for (int j = 0, i = 0; i < length; i++) {
Declaration* node = declarations->at(i);
Variable* var = node->proxy()->var();
Slot* slot = var->slot();
if ((slot != NULL && slot->type() == Slot::LOOKUP) || !var->is_global()) {
// Skip - already processed.
} else {
array->set(j++, *(var->name()));
if (node->fun() == NULL) {
if (var->mode() == Variable::CONST) {
// In case this is const property use the hole.
array->set_the_hole(j++);
} else {
array->set_undefined(j++);
}
} else {
Handle<JSFunction> function =
Compiler::BuildBoilerplate(node->fun(), script(), this);
// Check for stack-overflow exception.
if (HasStackOverflow()) return;
array->set(j++, *function);
}
}
}
// Invoke the platform-dependent code generator to do the actual
// declaration the global variables and functions.
DeclareGlobals(array);
}
// Special cases: These 'runtime calls' manipulate the current
// frame and are only used 1 or two places, so we generate them
// inline instead of generating calls to them. They are used
// for implementing Function.prototype.call() and
// Function.prototype.apply().
CodeGenerator::InlineRuntimeLUT CodeGenerator::kInlineRuntimeLUT[] = {
{&CodeGenerator::GenerateIsSmi, "_IsSmi"},
{&CodeGenerator::GenerateIsNonNegativeSmi, "_IsNonNegativeSmi"},
{&CodeGenerator::GenerateIsArray, "_IsArray"},
{&CodeGenerator::GenerateIsRegExp, "_IsRegExp"},
{&CodeGenerator::GenerateIsConstructCall, "_IsConstructCall"},
{&CodeGenerator::GenerateArgumentsLength, "_ArgumentsLength"},
{&CodeGenerator::GenerateArgumentsAccess, "_Arguments"},
{&CodeGenerator::GenerateClassOf, "_ClassOf"},
{&CodeGenerator::GenerateValueOf, "_ValueOf"},
{&CodeGenerator::GenerateSetValueOf, "_SetValueOf"},
{&CodeGenerator::GenerateFastCharCodeAt, "_FastCharCodeAt"},
{&CodeGenerator::GenerateObjectEquals, "_ObjectEquals"},
{&CodeGenerator::GenerateLog, "_Log"},
{&CodeGenerator::GenerateRandomPositiveSmi, "_RandomPositiveSmi"},
{&CodeGenerator::GenerateIsObject, "_IsObject"},
{&CodeGenerator::GenerateIsFunction, "_IsFunction"},
{&CodeGenerator::GenerateIsUndetectableObject, "_IsUndetectableObject"},
{&CodeGenerator::GenerateStringAdd, "_StringAdd"},
{&CodeGenerator::GenerateSubString, "_SubString"},
{&CodeGenerator::GenerateStringCompare, "_StringCompare"},
{&CodeGenerator::GenerateRegExpExec, "_RegExpExec"},
{&CodeGenerator::GenerateNumberToString, "_NumberToString"},
};
CodeGenerator::InlineRuntimeLUT* CodeGenerator::FindInlineRuntimeLUT(
Handle<String> name) {
const int entries_count =
sizeof(kInlineRuntimeLUT) / sizeof(InlineRuntimeLUT);
for (int i = 0; i < entries_count; i++) {
InlineRuntimeLUT* entry = &kInlineRuntimeLUT[i];
if (name->IsEqualTo(CStrVector(entry->name))) {
return entry;
}
}
return NULL;
}
bool CodeGenerator::CheckForInlineRuntimeCall(CallRuntime* node) {
ZoneList<Expression*>* args = node->arguments();
Handle<String> name = node->name();
if (name->length() > 0 && name->Get(0) == '_') {
InlineRuntimeLUT* entry = FindInlineRuntimeLUT(name);
if (entry != NULL) {
((*this).*(entry->method))(args);
return true;
}
}
return false;
}
bool CodeGenerator::PatchInlineRuntimeEntry(Handle<String> name,
const CodeGenerator::InlineRuntimeLUT& new_entry,
CodeGenerator::InlineRuntimeLUT* old_entry) {
InlineRuntimeLUT* entry = FindInlineRuntimeLUT(name);
if (entry == NULL) return false;
if (old_entry != NULL) {
old_entry->name = entry->name;
old_entry->method = entry->method;
}
entry->name = new_entry.name;
entry->method = new_entry.method;
return true;
}
// Simple condition analysis. ALWAYS_TRUE and ALWAYS_FALSE represent a
// known result for the test expression, with no side effects.
CodeGenerator::ConditionAnalysis CodeGenerator::AnalyzeCondition(
Expression* cond) {
if (cond == NULL) return ALWAYS_TRUE;
Literal* lit = cond->AsLiteral();
if (lit == NULL) return DONT_KNOW;
if (lit->IsTrue()) {
return ALWAYS_TRUE;
} else if (lit->IsFalse()) {
return ALWAYS_FALSE;
}
return DONT_KNOW;
}
void CodeGenerator::RecordPositions(MacroAssembler* masm, int pos) {
if (pos != RelocInfo::kNoPosition) {
masm->RecordStatementPosition(pos);
masm->RecordPosition(pos);
}
}
void CodeGenerator::CodeForFunctionPosition(FunctionLiteral* fun) {
if (FLAG_debug_info) RecordPositions(masm(), fun->start_position());
}
void CodeGenerator::CodeForReturnPosition(FunctionLiteral* fun) {
if (FLAG_debug_info) RecordPositions(masm(), fun->end_position());
}
void CodeGenerator::CodeForStatementPosition(Statement* stmt) {
if (FLAG_debug_info) RecordPositions(masm(), stmt->statement_pos());
}
void CodeGenerator::CodeForDoWhileConditionPosition(DoWhileStatement* stmt) {
if (FLAG_debug_info) RecordPositions(masm(), stmt->condition_position());
}
void CodeGenerator::CodeForSourcePosition(int pos) {
if (FLAG_debug_info && pos != RelocInfo::kNoPosition) {
masm()->RecordPosition(pos);
}
}
const char* GenericUnaryOpStub::GetName() {
switch (op_) {
case Token::SUB:
return overwrite_
? "GenericUnaryOpStub_SUB_Overwrite"
: "GenericUnaryOpStub_SUB_Alloc";
case Token::BIT_NOT:
return overwrite_
? "GenericUnaryOpStub_BIT_NOT_Overwrite"
: "GenericUnaryOpStub_BIT_NOT_Alloc";
default:
UNREACHABLE();
return "<unknown>";
}
}
void ArgumentsAccessStub::Generate(MacroAssembler* masm) {
switch (type_) {
case READ_LENGTH: GenerateReadLength(masm); break;
case READ_ELEMENT: GenerateReadElement(masm); break;
case NEW_OBJECT: GenerateNewObject(masm); break;
}
}
int CEntryStub::MinorKey() {
ASSERT(result_size_ <= 2);
#ifdef _WIN64
return ExitFrameModeBits::encode(mode_)
| IndirectResultBits::encode(result_size_ > 1);
#else
return ExitFrameModeBits::encode(mode_);
#endif
}
bool ApiGetterEntryStub::GetCustomCache(Code** code_out) {
Object* cache = info()->load_stub_cache();
if (cache->IsUndefined()) {
return false;
} else {
*code_out = Code::cast(cache);
return true;
}
}
void ApiGetterEntryStub::SetCustomCache(Code* value) {
info()->set_load_stub_cache(value);
}
} } // namespace v8::internal