string.tq

// Copyright 2019 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.

#include 'src/builtins/builtins-string-gen.h'

@abstract
@generateCppClass
@reserveBitsInInstanceType(6)
extern class String extends Name {
  macro StringInstanceType(): StringInstanceType {
    return %RawDownCast<StringInstanceType>(
        Convert<uint16>(this.map.instance_type));
  }

  const length: int32;
}

extern enum StringRepresentationTag extends uint32 {
  kSeqStringTag,
  kConsStringTag,
  kExternalStringTag,
  kSlicedStringTag,
  kThinStringTag
}

bitfield struct StringInstanceType extends uint16 {
  representation: StringRepresentationTag: 3 bit;
  is_one_byte: bool: 1 bit;
  is_uncached: bool: 1 bit;
  is_not_internalized: bool: 1 bit;
}

@generateCppClass
@generateBodyDescriptor
@doNotGenerateCast
extern class ConsString extends String {
  // Corresponds to String::IsFlat() in the C++ runtime.
  macro IsFlat(): bool {
    return this.second.length == 0;
  }

  macro IsOneByteRepresentation(): bool {
    return this.StringInstanceType().is_one_byte;
  }

  first: String;
  second: String;
}

@abstract
@doNotGenerateCast
extern class ExternalString extends String {
  resource: ExternalPointer;
  // WARNING: This field is missing for uncached external strings.
  resource_data: ExternalPointer;
}

extern operator '.resource_ptr' macro LoadExternalStringResourcePtr(
    ExternalString): RawPtr;
extern operator '.resource_data_ptr' macro LoadExternalStringResourceDataPtr(
    ExternalString): RawPtr;
extern operator '.resource_data_ptr' macro LoadExternalStringResourceDataPtr(
    ExternalOneByteString): RawPtr<char8>;
extern operator '.resource_data_ptr' macro LoadExternalStringResourceDataPtr(
    ExternalTwoByteString): RawPtr<char16>;

extern macro ExternalOneByteStringGetChars(ExternalOneByteString):
    RawPtr<char8>;
extern macro ExternalTwoByteStringGetChars(ExternalTwoByteString):
    RawPtr<char16>;

@doNotGenerateCast
extern class ExternalOneByteString extends ExternalString {
  macro GetChars(): RawPtr<char8> {
    if (this.StringInstanceType().is_uncached) {
      return ExternalOneByteStringGetChars(this);
    } else {
      return this.resource_data_ptr;
    }
  }
}

@doNotGenerateCast
extern class ExternalTwoByteString extends ExternalString {
  macro GetChars(): RawPtr<char16> {
    if (this.StringInstanceType().is_uncached) {
      return ExternalTwoByteStringGetChars(this);
    } else {
      return this.resource_data_ptr;
    }
  }
}

@generateCppClass
@doNotGenerateCast
extern class InternalizedString extends String {
}

@abstract
@generateCppClass
@doNotGenerateCast
extern class SeqString extends String {
}
@generateCppClass
@generateBodyDescriptor
@doNotGenerateCast
extern class SeqOneByteString extends SeqString {
  const chars[length]: char8;
}
@generateCppClass
@generateBodyDescriptor
@doNotGenerateCast
extern class SeqTwoByteString extends SeqString {
  const chars[length]: char16;
}

@generateCppClass
@generateBodyDescriptor
@doNotGenerateCast
extern class SlicedString extends String {
  parent: String;
  offset: Smi;
}

@generateCppClass
@generateBodyDescriptor
@doNotGenerateCast
extern class ThinString extends String {
  actual: String;
}

// A direct string can be accessed directly through CSA without going into the
// C++ runtime. See also: ToDirectStringAssembler.
type DirectString extends String;

macro AllocateNonEmptySeqOneByteString<Iterator: type>(
    length: uint32, content: Iterator): SeqOneByteString {
  assert(length != 0 && length <= kStringMaxLength);
  return new SeqOneByteString{
    map: kOneByteStringMap,
    raw_hash_field: kNameEmptyHashField,
    length: Signed(length),
    chars: ...content
  };
}

macro AllocateNonEmptySeqTwoByteString<Iterator: type>(
    length: uint32, content: Iterator): SeqTwoByteString {
  assert(length > 0 && length <= kStringMaxLength);
  return new SeqTwoByteString{
    map: kStringMap,
    raw_hash_field: kNameEmptyHashField,
    length: Signed(length),
    chars: ...content
  };
}

macro AllocateNonEmptySeqOneByteString(length: uint32): SeqOneByteString {
  return AllocateNonEmptySeqOneByteString(length, UninitializedIterator{});
}
macro AllocateNonEmptySeqTwoByteString(length: uint32): SeqTwoByteString {
  return AllocateNonEmptySeqTwoByteString(length, UninitializedIterator{});
}

macro AllocateSeqOneByteString<Iterator: type>(
    length: uint32, content: Iterator): SeqOneByteString|EmptyString {
  if (length == 0) return kEmptyString;
  return AllocateNonEmptySeqOneByteString(length, content);
}

macro AllocateSeqTwoByteString<Iterator: type>(
    length: uint32, content: Iterator): SeqTwoByteString|EmptyString {
  if (length == 0) return kEmptyString;
  return AllocateNonEmptySeqTwoByteString(length, content);
}

@export
macro AllocateSeqOneByteString(length: uint32): SeqOneByteString|EmptyString {
  return AllocateSeqOneByteString(length, UninitializedIterator{});
}

@export
macro AllocateSeqTwoByteString(length: uint32): SeqTwoByteString|EmptyString {
  return AllocateSeqTwoByteString(length, UninitializedIterator{});
}

extern macro StringWriteToFlatOneByte(String, RawPtr<char8>, int32, int32);
extern macro StringWriteToFlatTwoByte(String, RawPtr<char16>, int32, int32);

// Corresponds to String::SlowFlatten in the C++ runtime.
builtin StringSlowFlatten(cons: ConsString): String {
  // TurboFan can create cons strings with empty first parts.
  let cons = cons;
  while (cons.first.length == 0) {
    // We do not want to call this function recursively. Therefore we call
    // String::Flatten only in those cases where String::SlowFlatten is not
    // called again.
    try {
      const second = Cast<ConsString>(cons.second) otherwise FoundFlatString;
      if (second.IsFlat()) goto FoundFlatString;
      cons = second;
    } label FoundFlatString {
      return Flatten(cons.second);
    }
  }

  let flat: String;
  if (cons.IsOneByteRepresentation()) {
    const allocated = AllocateNonEmptySeqOneByteString(Unsigned(cons.length));
    StringWriteToFlatOneByte(
        cons, (&allocated.chars).GCUnsafeStartPointer(), 0, cons.length);
    flat = allocated;
  } else {
    const allocated = UnsafeCast<SeqTwoByteString>(
        AllocateNonEmptySeqTwoByteString(Unsigned(cons.length)));
    StringWriteToFlatTwoByte(
        cons, (&allocated.chars).GCUnsafeStartPointer(), 0, cons.length);
    flat = allocated;
  }
  cons.first = flat;
  cons.second = kEmptyString;
  return flat;
}

// Corresponds to String::Flatten in the C++ runtime.
macro Flatten(string: String): String {
  typeswitch (string) {
    case (cons: ConsString): {
      return Flatten(cons);
    }
    case (thin: ThinString): {
      assert(!Is<ConsString>(thin.actual));
      return thin.actual;
    }
    case (other: String): {
      return other;
    }
  }
}
macro Flatten(cons: ConsString): String {
  if (cons.IsFlat()) return cons.first;
  return StringSlowFlatten(cons);
}

// Get a slice to the string data, flatten only if unavoidable for this.
macro StringToSlice(string: String): never labels OneByte(ConstSlice<char8>),
    TwoByte(ConstSlice<char16>) {
  let string = string;
  let offset: intptr = 0;
  const length = Convert<intptr>(string.length);
  while (true) {
    typeswitch (string) {
      case (s: SeqOneByteString): {
        goto OneByte(Subslice(&s.chars, offset, length) otherwise unreachable);
      }
      case (s: SeqTwoByteString): {
        goto TwoByte(Subslice(&s.chars, offset, length) otherwise unreachable);
      }
      case (s: ThinString): {
        string = s.actual;
      }
      case (s: ConsString): {
        string = Flatten(s);
      }
      case (s: SlicedString): {
        offset += Convert<intptr>(s.offset);
        string = s.parent;
      }
      case (s: ExternalOneByteString): {
        const data = torque_internal::unsafe::NewOffHeapConstSlice(
            s.GetChars(), Convert<intptr>(s.length));
        goto OneByte(Subslice(data, offset, length) otherwise unreachable);
      }
      case (s: ExternalTwoByteString): {
        const data = torque_internal::unsafe::NewOffHeapConstSlice(
            s.GetChars(), Convert<intptr>(s.length));
        goto TwoByte(Subslice(data, offset, length) otherwise unreachable);
      }
      case (String): {
        unreachable;
      }
    }
  }
  VerifiedUnreachable();
}

// Dispatch on the slice type of two different strings.
macro TwoStringsToSlices<Result: type, Functor: type>(
    s1: String, s2: String, f: Functor): Result {
  try {
    StringToSlice(s1) otherwise FirstOneByte, FirstTwoByte;
  } label FirstOneByte(s1Slice: ConstSlice<char8>) {
    try {
      StringToSlice(s2) otherwise SecondOneByte, SecondTwoByte;
    } label SecondOneByte(s2Slice: ConstSlice<char8>) {
      return Call(f, s1Slice, s2Slice);
    } label SecondTwoByte(s2Slice: ConstSlice<char16>) {
      return Call(f, s1Slice, s2Slice);
    }
  } label FirstTwoByte(s1Slice: ConstSlice<char16>) {
    try {
      StringToSlice(s2) otherwise SecondOneByte, SecondTwoByte;
    } label SecondOneByte(s2Slice: ConstSlice<char8>) {
      return Call(f, s1Slice, s2Slice);
    } label SecondTwoByte(s2Slice: ConstSlice<char16>) {
      return Call(f, s1Slice, s2Slice);
    }
  }
}

macro StaticAssertStringLengthFitsSmi(): void {
  const kMaxStringLengthFitsSmi: constexpr bool =
      kStringMaxLengthUintptr < kSmiMaxValue;
  static_assert(kMaxStringLengthFitsSmi);
}

extern macro StringBuiltinsAssembler::SearchOneByteStringInTwoByteString(
    RawPtr<char16>, intptr, RawPtr<char8>, intptr, intptr): intptr;
extern macro StringBuiltinsAssembler::SearchOneByteStringInOneByteString(
    RawPtr<char8>, intptr, RawPtr<char8>, intptr, intptr): intptr;
extern macro StringBuiltinsAssembler::SearchTwoByteStringInTwoByteString(
    RawPtr<char16>, intptr, RawPtr<char16>, intptr, intptr): intptr;
extern macro StringBuiltinsAssembler::SearchTwoByteStringInOneByteString(
    RawPtr<char8>, intptr, RawPtr<char16>, intptr, intptr): intptr;
extern macro StringBuiltinsAssembler::SearchOneByteInOneByteString(
    RawPtr<char8>, intptr, RawPtr<char8>, intptr): intptr;

macro AbstractStringIndexOf(
    subject: RawPtr<char16>, subjectLen: intptr, search: RawPtr<char8>,
    searchLen: intptr, fromIndex: intptr): intptr {
  return SearchOneByteStringInTwoByteString(
      subject, subjectLen, search, searchLen, fromIndex);
}
macro AbstractStringIndexOf(
    subject: RawPtr<char8>, subjectLen: intptr, search: RawPtr<char8>,
    searchLen: intptr, fromIndex: intptr): intptr {
  if (searchLen == 1) {
    return SearchOneByteInOneByteString(subject, subjectLen, search, fromIndex);
  }
  return SearchOneByteStringInOneByteString(
      subject, subjectLen, search, searchLen, fromIndex);
}
macro AbstractStringIndexOf(
    subject: RawPtr<char16>, subjectLen: intptr, search: RawPtr<char16>,
    searchLen: intptr, fromIndex: intptr): intptr {
  return SearchTwoByteStringInTwoByteString(
      subject, subjectLen, search, searchLen, fromIndex);
}
macro AbstractStringIndexOf(
    subject: RawPtr<char8>, subjectLen: intptr, search: RawPtr<char16>,
    searchLen: intptr, fromIndex: intptr): intptr {
  return SearchTwoByteStringInOneByteString(
      subject, subjectLen, search, searchLen, fromIndex);
}

struct AbstractStringIndexOfFunctor {
  fromIndex: Smi;
}
// Ideally, this would be a method of AbstractStringIndexOfFunctor, but
// currently methods don't support templates.
macro Call<A: type, B: type>(
    self: AbstractStringIndexOfFunctor, string: ConstSlice<A>,
    searchStr: ConstSlice<B>): Smi {
  return Convert<Smi>(AbstractStringIndexOf(
      string.GCUnsafeStartPointer(), string.length,
      searchStr.GCUnsafeStartPointer(), searchStr.length,
      Convert<intptr>(self.fromIndex)));
}

macro AbstractStringIndexOf(implicit context: Context)(
    string: String, searchString: String, fromIndex: Smi): Smi {
  // Special case the empty string.
  const searchStringLength = searchString.length_intptr;
  const stringLength = string.length_intptr;
  if (searchStringLength == 0 && SmiUntag(fromIndex) <= stringLength) {
    return fromIndex;
  }

  // Don't bother to search if the searchString would go past the end
  // of the string. This is actually necessary because of runtime
  // checks.
  if (SmiUntag(fromIndex) + searchStringLength > stringLength) {
    return -1;
  }

  return TwoStringsToSlices<Smi>(
      string, searchString, AbstractStringIndexOfFunctor{fromIndex: fromIndex});
}

builtin StringIndexOf(implicit context: Context)(
    s: String, searchString: String, start: Smi): Smi {
  return AbstractStringIndexOf(s, searchString, SmiMax(start, 0));
}