third_party/v8/src/builtins/builtins-intl-gen.cc - cobalt - Git at Google

 // Copyright 2017 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef V8_INTL_SUPPORT
 #error Internationalization is expected to be enabled.
 #endif  // V8_INTL_SUPPORT

 #include "src/builtins/builtins-iterator-gen.h"
 #include "src/builtins/builtins-utils-gen.h"
 #include "src/codegen/code-stub-assembler.h"
 #include "src/objects/js-list-format-inl.h"
 #include "src/objects/js-list-format.h"
 #include "src/objects/objects-inl.h"
 #include "src/objects/objects.h"

 namespace v8 {
 namespace internal {

 class IntlBuiltinsAssembler : public CodeStubAssembler {
  public:
   explicit IntlBuiltinsAssembler(compiler::CodeAssemblerState* state)
       : CodeStubAssembler(state) {}

   void ListFormatCommon(TNode<Context> context, TNode<Int32T> argc,
                         Runtime::FunctionId format_func_id,
                         const char* method_name);

   TNode<JSArray> AllocateEmptyJSArray(TNode<Context> context);

   TNode<IntPtrT> PointerToSeqStringData(TNode<String> seq_string) {
     CSA_ASSERT(this,
                IsSequentialStringInstanceType(LoadInstanceType(seq_string)));
     STATIC_ASSERT(SeqOneByteString::kHeaderSize ==
                   SeqTwoByteString::kHeaderSize);
     return IntPtrAdd(
         BitcastTaggedToWord(seq_string),
         IntPtrConstant(SeqOneByteString::kHeaderSize - kHeapObjectTag));
   }
 };

 TF_BUILTIN(StringToLowerCaseIntl, IntlBuiltinsAssembler) {
   const auto string = Parameter<String>(Descriptor::kString);

   Label call_c(this), return_string(this), runtime(this, Label::kDeferred);

   // Early exit on empty strings.
   const TNode<Uint32T> length = LoadStringLengthAsWord32(string);
   GotoIf(Word32Equal(length, Uint32Constant(0)), &return_string);

   // Unpack strings if possible, and bail to runtime unless we get a one-byte
   // flat string.
   ToDirectStringAssembler to_direct(
       state(), string, ToDirectStringAssembler::kDontUnpackSlicedStrings);
   to_direct.TryToDirect(&runtime);

   const TNode<Int32T> instance_type = to_direct.instance_type();
   CSA_ASSERT(this,
              Word32BinaryNot(IsIndirectStringInstanceType(instance_type)));
   GotoIfNot(IsOneByteStringInstanceType(instance_type), &runtime);

   // For short strings, do the conversion in CSA through the lookup table.

   const TNode<String> dst = AllocateSeqOneByteString(length);

   const int kMaxShortStringLength = 24;  // Determined empirically.
   GotoIf(Uint32GreaterThan(length, Uint32Constant(kMaxShortStringLength)),
          &call_c);

   {
     const TNode<IntPtrT> dst_ptr = PointerToSeqStringData(dst);
     TVARIABLE(IntPtrT, var_cursor, IntPtrConstant(0));

     const TNode<IntPtrT> start_address =
         ReinterpretCast<IntPtrT>(to_direct.PointerToData(&call_c));
     const TNode<IntPtrT> end_address =
         Signed(IntPtrAdd(start_address, ChangeUint32ToWord(length)));

     const TNode<ExternalReference> to_lower_table_addr =
         ExternalConstant(ExternalReference::intl_to_latin1_lower_table());

     TVARIABLE(Word32T, var_did_change, Int32Constant(0));

     VariableList push_vars({&var_cursor, &var_did_change}, zone());
     BuildFastLoop<IntPtrT>(
         push_vars, start_address, end_address,
         [&](TNode<IntPtrT> current) {
           TNode<Uint8T> c = Load<Uint8T>(current);
           TNode<Uint8T> lower =
               Load<Uint8T>(to_lower_table_addr, ChangeInt32ToIntPtr(c));
           StoreNoWriteBarrier(MachineRepresentation::kWord8, dst_ptr,
                               var_cursor.value(), lower);

           var_did_change =
               Word32Or(Word32NotEqual(c, lower), var_did_change.value());

           Increment(&var_cursor);
         },
         kCharSize, IndexAdvanceMode::kPost);

     // Return the original string if it remained unchanged in order to preserve
     // e.g. internalization and private symbols (such as the preserved object
     // hash) on the source string.
     GotoIfNot(var_did_change.value(), &return_string);

     Return(dst);
   }

   // Call into C for case conversion. The signature is:
   // String ConvertOneByteToLower(String src, String dst);
   BIND(&call_c);
   {
     const TNode<String> src = to_direct.string();

     const TNode<ExternalReference> function_addr =
         ExternalConstant(ExternalReference::intl_convert_one_byte_to_lower());

     MachineType type_tagged = MachineType::AnyTagged();

     const TNode<String> result = CAST(CallCFunction(
         function_addr, type_tagged, std::make_pair(type_tagged, src),
         std::make_pair(type_tagged, dst)));

     Return(result);
   }

   BIND(&return_string);
   Return(string);

   BIND(&runtime);
   {
     const TNode<Object> result = CallRuntime(Runtime::kStringToLowerCaseIntl,
                                              NoContextConstant(), string);
     Return(result);
   }
 }

 TF_BUILTIN(StringPrototypeToLowerCaseIntl, IntlBuiltinsAssembler) {
   auto maybe_string = Parameter<Object>(Descriptor::kReceiver);
   auto context = Parameter<Context>(Descriptor::kContext);

   TNode<String> string =
       ToThisString(context, maybe_string, "String.prototype.toLowerCase");

   Return(CallBuiltin(Builtins::kStringToLowerCaseIntl, context, string));
 }

 void IntlBuiltinsAssembler::ListFormatCommon(TNode<Context> context,
                                              TNode<Int32T> argc,
                                              Runtime::FunctionId format_func_id,
                                              const char* method_name) {
   CodeStubArguments args(this, argc);

   // Label has_list(this);
   // 1. Let lf be this value.
   // 2. If Type(lf) is not Object, throw a TypeError exception.
   TNode<Object> receiver = args.GetReceiver();

   // 3. If lf does not have an [[InitializedListFormat]] internal slot, throw a
   // TypeError exception.
   ThrowIfNotInstanceType(context, receiver, JS_LIST_FORMAT_TYPE, method_name);
   TNode<JSListFormat> list_format = CAST(receiver);

   TNode<Object> list = args.GetOptionalArgumentValue(0);
   {
     // 4. Let stringList be ? StringListFromIterable(list).
     TNode<Object> string_list =
         CallBuiltin(Builtins::kStringListFromIterable, context, list);

     // 6. Return ? FormatList(lf, stringList).
     args.PopAndReturn(
         CallRuntime(format_func_id, context, list_format, string_list));
   }
 }

 TNode<JSArray> IntlBuiltinsAssembler::AllocateEmptyJSArray(
     TNode<Context> context) {
   return CodeStubAssembler::AllocateJSArray(
       PACKED_ELEMENTS,
       LoadJSArrayElementsMap(PACKED_ELEMENTS, LoadNativeContext(context)),
       IntPtrConstant(0), SmiConstant(0));
 }

 TF_BUILTIN(ListFormatPrototypeFormat, IntlBuiltinsAssembler) {
   ListFormatCommon(
       Parameter<Context>(Descriptor::kContext),
       UncheckedParameter<Int32T>(Descriptor::kJSActualArgumentsCount),
       Runtime::kFormatList, "Intl.ListFormat.prototype.format");
 }

 TF_BUILTIN(ListFormatPrototypeFormatToParts, IntlBuiltinsAssembler) {
   ListFormatCommon(
       Parameter<Context>(Descriptor::kContext),
       UncheckedParameter<Int32T>(Descriptor::kJSActualArgumentsCount),
       Runtime::kFormatListToParts, "Intl.ListFormat.prototype.formatToParts");
 }

 }  // namespace internal
 }  // namespace v8
	// Copyright 2017 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef V8_INTL_SUPPORT
	#error Internationalization is expected to be enabled.
	#endif // V8_INTL_SUPPORT

	#include "src/builtins/builtins-iterator-gen.h"
	#include "src/builtins/builtins-utils-gen.h"
	#include "src/codegen/code-stub-assembler.h"
	#include "src/objects/js-list-format-inl.h"
	#include "src/objects/js-list-format.h"
	#include "src/objects/objects-inl.h"
	#include "src/objects/objects.h"

	namespace v8 {
	namespace internal {

	class IntlBuiltinsAssembler : public CodeStubAssembler {
	public:
	explicit IntlBuiltinsAssembler(compiler::CodeAssemblerState* state)
	: CodeStubAssembler(state) {}

	void ListFormatCommon(TNode<Context> context, TNode<Int32T> argc,
	Runtime::FunctionId format_func_id,
	const char* method_name);

	TNode<JSArray> AllocateEmptyJSArray(TNode<Context> context);

	TNode<IntPtrT> PointerToSeqStringData(TNode<String> seq_string) {
	CSA_ASSERT(this,
	IsSequentialStringInstanceType(LoadInstanceType(seq_string)));
	STATIC_ASSERT(SeqOneByteString::kHeaderSize ==
	SeqTwoByteString::kHeaderSize);
	return IntPtrAdd(
	BitcastTaggedToWord(seq_string),
	IntPtrConstant(SeqOneByteString::kHeaderSize - kHeapObjectTag));
	}
	};

	TF_BUILTIN(StringToLowerCaseIntl, IntlBuiltinsAssembler) {
	const auto string = Parameter<String>(Descriptor::kString);

	Label call_c(this), return_string(this), runtime(this, Label::kDeferred);

	// Early exit on empty strings.
	const TNode<Uint32T> length = LoadStringLengthAsWord32(string);
	GotoIf(Word32Equal(length, Uint32Constant(0)), &return_string);

	// Unpack strings if possible, and bail to runtime unless we get a one-byte
	// flat string.
	ToDirectStringAssembler to_direct(
	state(), string, ToDirectStringAssembler::kDontUnpackSlicedStrings);
	to_direct.TryToDirect(&runtime);

	const TNode<Int32T> instance_type = to_direct.instance_type();
	CSA_ASSERT(this,
	Word32BinaryNot(IsIndirectStringInstanceType(instance_type)));
	GotoIfNot(IsOneByteStringInstanceType(instance_type), &runtime);

	// For short strings, do the conversion in CSA through the lookup table.

	const TNode<String> dst = AllocateSeqOneByteString(length);

	const int kMaxShortStringLength = 24; // Determined empirically.
	GotoIf(Uint32GreaterThan(length, Uint32Constant(kMaxShortStringLength)),
	&call_c);

	{
	const TNode<IntPtrT> dst_ptr = PointerToSeqStringData(dst);
	TVARIABLE(IntPtrT, var_cursor, IntPtrConstant(0));

	const TNode<IntPtrT> start_address =
	ReinterpretCast<IntPtrT>(to_direct.PointerToData(&call_c));
	const TNode<IntPtrT> end_address =
	Signed(IntPtrAdd(start_address, ChangeUint32ToWord(length)));

	const TNode<ExternalReference> to_lower_table_addr =
	ExternalConstant(ExternalReference::intl_to_latin1_lower_table());

	TVARIABLE(Word32T, var_did_change, Int32Constant(0));

	VariableList push_vars({&var_cursor, &var_did_change}, zone());
	BuildFastLoop<IntPtrT>(
	push_vars, start_address, end_address,
	[&](TNode<IntPtrT> current) {
	TNode<Uint8T> c = Load<Uint8T>(current);
	TNode<Uint8T> lower =
	Load<Uint8T>(to_lower_table_addr, ChangeInt32ToIntPtr(c));
	StoreNoWriteBarrier(MachineRepresentation::kWord8, dst_ptr,
	var_cursor.value(), lower);

	var_did_change =
	Word32Or(Word32NotEqual(c, lower), var_did_change.value());

	Increment(&var_cursor);
	},
	kCharSize, IndexAdvanceMode::kPost);

	// Return the original string if it remained unchanged in order to preserve
	// e.g. internalization and private symbols (such as the preserved object
	// hash) on the source string.
	GotoIfNot(var_did_change.value(), &return_string);

	Return(dst);
	}

	// Call into C for case conversion. The signature is:
	// String ConvertOneByteToLower(String src, String dst);
	BIND(&call_c);
	{
	const TNode<String> src = to_direct.string();

	const TNode<ExternalReference> function_addr =
	ExternalConstant(ExternalReference::intl_convert_one_byte_to_lower());

	MachineType type_tagged = MachineType::AnyTagged();

	const TNode<String> result = CAST(CallCFunction(
	function_addr, type_tagged, std::make_pair(type_tagged, src),
	std::make_pair(type_tagged, dst)));

	Return(result);
	}

	BIND(&return_string);
	Return(string);

	BIND(&runtime);
	{
	const TNode<Object> result = CallRuntime(Runtime::kStringToLowerCaseIntl,
	NoContextConstant(), string);
	Return(result);
	}
	}

	TF_BUILTIN(StringPrototypeToLowerCaseIntl, IntlBuiltinsAssembler) {
	auto maybe_string = Parameter<Object>(Descriptor::kReceiver);
	auto context = Parameter<Context>(Descriptor::kContext);

	TNode<String> string =
	ToThisString(context, maybe_string, "String.prototype.toLowerCase");

	Return(CallBuiltin(Builtins::kStringToLowerCaseIntl, context, string));
	}

	void IntlBuiltinsAssembler::ListFormatCommon(TNode<Context> context,
	TNode<Int32T> argc,
	Runtime::FunctionId format_func_id,
	const char* method_name) {
	CodeStubArguments args(this, argc);

	// Label has_list(this);
	// 1. Let lf be this value.
	// 2. If Type(lf) is not Object, throw a TypeError exception.
	TNode<Object> receiver = args.GetReceiver();

	// 3. If lf does not have an [[InitializedListFormat]] internal slot, throw a
	// TypeError exception.
	ThrowIfNotInstanceType(context, receiver, JS_LIST_FORMAT_TYPE, method_name);
	TNode<JSListFormat> list_format = CAST(receiver);

	TNode<Object> list = args.GetOptionalArgumentValue(0);
	{
	// 4. Let stringList be ? StringListFromIterable(list).
	TNode<Object> string_list =
	CallBuiltin(Builtins::kStringListFromIterable, context, list);

	// 6. Return ? FormatList(lf, stringList).
	args.PopAndReturn(
	CallRuntime(format_func_id, context, list_format, string_list));
	}
	}

	TNode<JSArray> IntlBuiltinsAssembler::AllocateEmptyJSArray(
	TNode<Context> context) {
	return CodeStubAssembler::AllocateJSArray(
	PACKED_ELEMENTS,
	LoadJSArrayElementsMap(PACKED_ELEMENTS, LoadNativeContext(context)),
	IntPtrConstant(0), SmiConstant(0));
	}

	TF_BUILTIN(ListFormatPrototypeFormat, IntlBuiltinsAssembler) {
	ListFormatCommon(
	Parameter<Context>(Descriptor::kContext),
	UncheckedParameter<Int32T>(Descriptor::kJSActualArgumentsCount),
	Runtime::kFormatList, "Intl.ListFormat.prototype.format");
	}

	TF_BUILTIN(ListFormatPrototypeFormatToParts, IntlBuiltinsAssembler) {
	ListFormatCommon(
	Parameter<Context>(Descriptor::kContext),
	UncheckedParameter<Int32T>(Descriptor::kJSActualArgumentsCount),
	Runtime::kFormatListToParts, "Intl.ListFormat.prototype.formatToParts");
	}

	} // namespace internal
	} // namespace v8