src/third_party/v8/src/builtins/builtins-regexp-gen.h - 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_BUILTINS_BUILTINS_REGEXP_GEN_H_
 #define V8_BUILTINS_BUILTINS_REGEXP_GEN_H_

 #include "src/base/optional.h"
 #include "src/codegen/code-stub-assembler.h"
 #include "src/common/message-template.h"

 namespace v8 {
 namespace internal {

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

   TNode<Smi> SmiZero();
   TNode<IntPtrT> IntPtrZero();

   TNode<RawPtrT> LoadCodeObjectEntry(TNode<Code> code);

   // Allocate a RegExpResult with the given length (the number of captures,
   // including the match itself), index (the index where the match starts),
   // and input string.
   TNode<JSRegExpResult> AllocateRegExpResult(
       TNode<Context> context, TNode<Smi> length, TNode<Smi> index,
       TNode<String> input, TNode<JSRegExp> regexp, TNode<Number> last_index,
       TNode<FixedArray>* elements_out = nullptr);

   TNode<Object> FastLoadLastIndexBeforeSmiCheck(TNode<JSRegExp> regexp);
   TNode<Smi> FastLoadLastIndex(TNode<JSRegExp> regexp) {
     return CAST(FastLoadLastIndexBeforeSmiCheck(regexp));
   }
   TNode<Object> SlowLoadLastIndex(TNode<Context> context, TNode<Object> regexp);

   void FastStoreLastIndex(TNode<JSRegExp> regexp, TNode<Smi> value);
   void SlowStoreLastIndex(TNode<Context> context, TNode<Object> regexp,
                           TNode<Object> value);

   // Loads {var_string_start} and {var_string_end} with the corresponding
   // offsets into the given {string_data}.
   void GetStringPointers(TNode<RawPtrT> string_data, TNode<IntPtrT> offset,
                          TNode<IntPtrT> last_index,
                          TNode<IntPtrT> string_length,
                          String::Encoding encoding,
                          TVariable<RawPtrT>* var_string_start,
                          TVariable<RawPtrT>* var_string_end);

   // Low level logic around the actual call into pattern matching code.
   TNode<HeapObject> RegExpExecInternal(TNode<Context> context,
                                        TNode<JSRegExp> regexp,
                                        TNode<String> string,
                                        TNode<Number> last_index,
                                        TNode<RegExpMatchInfo> match_info);

   TNode<JSRegExpResult> ConstructNewResultFromMatchInfo(
       TNode<Context> context, TNode<JSRegExp> regexp,
       TNode<RegExpMatchInfo> match_info, TNode<String> string,
       TNode<Number> last_index);

   // Fast path check logic.
   //
   // Are you afraid? If not, you should be.
   //
   // It's complicated. Fast path checks protect certain assumptions, e.g. that
   // relevant properties on the regexp prototype (such as exec, @@split, global)
   // are unmodified.
   //
   // These assumptions differ by callsite. For example, RegExpPrototypeExec
   // cares whether the exec property has been modified; but it's totally fine
   // to modify other prototype properties. On the other hand,
   // StringPrototypeSplit does care very much whether @@split has been changed.
   //
   // We want to keep regexp execution on the fast path as much as possible.
   // Ideally, we could simply check if the regexp prototype has been modified;
   // yet common web frameworks routinely mutate it for various reasons. But most
   // of these mutations should happen in a way that still allows us to remain
   // on the fast path. To support this, the fast path check logic necessarily
   // becomes more involved.
   //
   // There are multiple knobs to twiddle for regexp fast path checks. We support
   // checks that completely ignore the prototype, checks that verify specific
   // properties on the prototype (the caller must ensure it passes in the right
   // ones), and strict checks that additionally ensure the prototype is
   // unchanged (we use these when we'd have to check multiple properties we
   // don't care too much about, e.g. all individual flag getters).

   using DescriptorIndexNameValue =
       PrototypeCheckAssembler::DescriptorIndexNameValue;

   void BranchIfFastRegExp(
       TNode<Context> context, TNode<HeapObject> object, TNode<Map> map,
       PrototypeCheckAssembler::Flags prototype_check_flags,
       base::Optional<DescriptorIndexNameValue> additional_property_to_check,
       Label* if_isunmodified, Label* if_ismodified);

   // Strict: Does not tolerate any changes to the prototype map.
   // Permissive: Allows changes to the prototype map except for the exec
   //             property.
   void BranchIfFastRegExp_Strict(TNode<Context> context,
                                  TNode<HeapObject> object,
                                  Label* if_isunmodified, Label* if_ismodified);
   void BranchIfFastRegExp_Permissive(TNode<Context> context,
                                      TNode<HeapObject> object,
                                      Label* if_isunmodified,
                                      Label* if_ismodified);

   // Performs fast path checks on the given object itself, but omits prototype
   // checks.
   TNode<BoolT> IsFastRegExpNoPrototype(TNode<Context> context,
                                        TNode<Object> object);
   TNode<BoolT> IsFastRegExpNoPrototype(TNode<Context> context,
                                        TNode<Object> object, TNode<Map> map);

   void BranchIfRegExpResult(const TNode<Context> context,
                             const TNode<Object> object, Label* if_isunmodified,
                             Label* if_ismodified);

   TNode<String> FlagsGetter(TNode<Context> context, TNode<Object> regexp,
                             const bool is_fastpath);

   TNode<BoolT> FastFlagGetter(TNode<JSRegExp> regexp, JSRegExp::Flag flag);
   TNode<BoolT> FastFlagGetterGlobal(TNode<JSRegExp> regexp) {
     return FastFlagGetter(regexp, JSRegExp::kGlobal);
   }
   TNode<BoolT> FastFlagGetterUnicode(TNode<JSRegExp> regexp) {
     return FastFlagGetter(regexp, JSRegExp::kUnicode);
   }
   TNode<BoolT> SlowFlagGetter(TNode<Context> context, TNode<Object> regexp,
                               JSRegExp::Flag flag);
   TNode<BoolT> FlagGetter(TNode<Context> context, TNode<Object> regexp,
                           JSRegExp::Flag flag, bool is_fastpath);

   TNode<Object> RegExpInitialize(const TNode<Context> context,
                                  const TNode<JSRegExp> regexp,
                                  const TNode<Object> maybe_pattern,
                                  const TNode<Object> maybe_flags);

   TNode<Number> AdvanceStringIndex(TNode<String> string, TNode<Number> index,
                                    TNode<BoolT> is_unicode, bool is_fastpath);

   TNode<Smi> AdvanceStringIndexFast(TNode<String> string, TNode<Smi> index,
                                     TNode<BoolT> is_unicode) {
     return CAST(AdvanceStringIndex(string, index, is_unicode, true));
   }

   TNode<Smi> AdvanceStringIndexSlow(TNode<String> string, TNode<Number> index,
                                     TNode<BoolT> is_unicode) {
     return CAST(AdvanceStringIndex(string, index, is_unicode, false));
   }

   TNode<JSArray> RegExpPrototypeSplitBody(TNode<Context> context,
                                           TNode<JSRegExp> regexp,
                                           const TNode<String> string,
                                           const TNode<Smi> limit);
 };

 class RegExpMatchAllAssembler : public RegExpBuiltinsAssembler {
  public:
   explicit RegExpMatchAllAssembler(compiler::CodeAssemblerState* state)
       : RegExpBuiltinsAssembler(state) {}

   TNode<Object> CreateRegExpStringIterator(TNode<NativeContext> native_context,
                                            TNode<Object> regexp,
                                            TNode<String> string,
                                            TNode<BoolT> global,
                                            TNode<BoolT> full_unicode);
 };

 }  // namespace internal
 }  // namespace v8

 #endif  // V8_BUILTINS_BUILTINS_REGEXP_GEN_H_
	// 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_BUILTINS_BUILTINS_REGEXP_GEN_H_
	#define V8_BUILTINS_BUILTINS_REGEXP_GEN_H_

	#include "src/base/optional.h"
	#include "src/codegen/code-stub-assembler.h"
	#include "src/common/message-template.h"

	namespace v8 {
	namespace internal {

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

	TNode<Smi> SmiZero();
	TNode<IntPtrT> IntPtrZero();

	TNode<RawPtrT> LoadCodeObjectEntry(TNode<Code> code);

	// Allocate a RegExpResult with the given length (the number of captures,
	// including the match itself), index (the index where the match starts),
	// and input string.
	TNode<JSRegExpResult> AllocateRegExpResult(
	TNode<Context> context, TNode<Smi> length, TNode<Smi> index,
	TNode<String> input, TNode<JSRegExp> regexp, TNode<Number> last_index,
	TNode<FixedArray>* elements_out = nullptr);

	TNode<Object> FastLoadLastIndexBeforeSmiCheck(TNode<JSRegExp> regexp);
	TNode<Smi> FastLoadLastIndex(TNode<JSRegExp> regexp) {
	return CAST(FastLoadLastIndexBeforeSmiCheck(regexp));
	}
	TNode<Object> SlowLoadLastIndex(TNode<Context> context, TNode<Object> regexp);

	void FastStoreLastIndex(TNode<JSRegExp> regexp, TNode<Smi> value);
	void SlowStoreLastIndex(TNode<Context> context, TNode<Object> regexp,
	TNode<Object> value);

	// Loads {var_string_start} and {var_string_end} with the corresponding
	// offsets into the given {string_data}.
	void GetStringPointers(TNode<RawPtrT> string_data, TNode<IntPtrT> offset,
	TNode<IntPtrT> last_index,
	TNode<IntPtrT> string_length,
	String::Encoding encoding,
	TVariable<RawPtrT>* var_string_start,
	TVariable<RawPtrT>* var_string_end);

	// Low level logic around the actual call into pattern matching code.
	TNode<HeapObject> RegExpExecInternal(TNode<Context> context,
	TNode<JSRegExp> regexp,
	TNode<String> string,
	TNode<Number> last_index,
	TNode<RegExpMatchInfo> match_info);

	TNode<JSRegExpResult> ConstructNewResultFromMatchInfo(
	TNode<Context> context, TNode<JSRegExp> regexp,
	TNode<RegExpMatchInfo> match_info, TNode<String> string,
	TNode<Number> last_index);

	// Fast path check logic.
	//
	// Are you afraid? If not, you should be.
	//
	// It's complicated. Fast path checks protect certain assumptions, e.g. that
	// relevant properties on the regexp prototype (such as exec, @@split, global)
	// are unmodified.
	//
	// These assumptions differ by callsite. For example, RegExpPrototypeExec
	// cares whether the exec property has been modified; but it's totally fine
	// to modify other prototype properties. On the other hand,
	// StringPrototypeSplit does care very much whether @@split has been changed.
	//
	// We want to keep regexp execution on the fast path as much as possible.
	// Ideally, we could simply check if the regexp prototype has been modified;
	// yet common web frameworks routinely mutate it for various reasons. But most
	// of these mutations should happen in a way that still allows us to remain
	// on the fast path. To support this, the fast path check logic necessarily
	// becomes more involved.
	//
	// There are multiple knobs to twiddle for regexp fast path checks. We support
	// checks that completely ignore the prototype, checks that verify specific
	// properties on the prototype (the caller must ensure it passes in the right
	// ones), and strict checks that additionally ensure the prototype is
	// unchanged (we use these when we'd have to check multiple properties we
	// don't care too much about, e.g. all individual flag getters).

	using DescriptorIndexNameValue =
	PrototypeCheckAssembler::DescriptorIndexNameValue;

	void BranchIfFastRegExp(
	TNode<Context> context, TNode<HeapObject> object, TNode<Map> map,
	PrototypeCheckAssembler::Flags prototype_check_flags,
	base::Optional<DescriptorIndexNameValue> additional_property_to_check,
	Label* if_isunmodified, Label* if_ismodified);

	// Strict: Does not tolerate any changes to the prototype map.
	// Permissive: Allows changes to the prototype map except for the exec
	// property.
	void BranchIfFastRegExp_Strict(TNode<Context> context,
	TNode<HeapObject> object,
	Label* if_isunmodified, Label* if_ismodified);
	void BranchIfFastRegExp_Permissive(TNode<Context> context,
	TNode<HeapObject> object,
	Label* if_isunmodified,
	Label* if_ismodified);

	// Performs fast path checks on the given object itself, but omits prototype
	// checks.
	TNode<BoolT> IsFastRegExpNoPrototype(TNode<Context> context,
	TNode<Object> object);
	TNode<BoolT> IsFastRegExpNoPrototype(TNode<Context> context,
	TNode<Object> object, TNode<Map> map);

	void BranchIfRegExpResult(const TNode<Context> context,
	const TNode<Object> object, Label* if_isunmodified,
	Label* if_ismodified);

	TNode<String> FlagsGetter(TNode<Context> context, TNode<Object> regexp,
	const bool is_fastpath);

	TNode<BoolT> FastFlagGetter(TNode<JSRegExp> regexp, JSRegExp::Flag flag);
	TNode<BoolT> FastFlagGetterGlobal(TNode<JSRegExp> regexp) {
	return FastFlagGetter(regexp, JSRegExp::kGlobal);
	}
	TNode<BoolT> FastFlagGetterUnicode(TNode<JSRegExp> regexp) {
	return FastFlagGetter(regexp, JSRegExp::kUnicode);
	}
	TNode<BoolT> SlowFlagGetter(TNode<Context> context, TNode<Object> regexp,
	JSRegExp::Flag flag);
	TNode<BoolT> FlagGetter(TNode<Context> context, TNode<Object> regexp,
	JSRegExp::Flag flag, bool is_fastpath);

	TNode<Object> RegExpInitialize(const TNode<Context> context,
	const TNode<JSRegExp> regexp,
	const TNode<Object> maybe_pattern,
	const TNode<Object> maybe_flags);

	TNode<Number> AdvanceStringIndex(TNode<String> string, TNode<Number> index,
	TNode<BoolT> is_unicode, bool is_fastpath);

	TNode<Smi> AdvanceStringIndexFast(TNode<String> string, TNode<Smi> index,
	TNode<BoolT> is_unicode) {
	return CAST(AdvanceStringIndex(string, index, is_unicode, true));
	}

	TNode<Smi> AdvanceStringIndexSlow(TNode<String> string, TNode<Number> index,
	TNode<BoolT> is_unicode) {
	return CAST(AdvanceStringIndex(string, index, is_unicode, false));
	}

	TNode<JSArray> RegExpPrototypeSplitBody(TNode<Context> context,
	TNode<JSRegExp> regexp,
	const TNode<String> string,
	const TNode<Smi> limit);
	};

	class RegExpMatchAllAssembler : public RegExpBuiltinsAssembler {
	public:
	explicit RegExpMatchAllAssembler(compiler::CodeAssemblerState* state)
	: RegExpBuiltinsAssembler(state) {}

	TNode<Object> CreateRegExpStringIterator(TNode<NativeContext> native_context,
	TNode<Object> regexp,
	TNode<String> string,
	TNode<BoolT> global,
	TNode<BoolT> full_unicode);
	};

	} // namespace internal
	} // namespace v8

	#endif // V8_BUILTINS_BUILTINS_REGEXP_GEN_H_