blob: b0e25b5f31a002abc8af8ec29ca2a0486407433b [file] [log] [blame]
// Copyright (c) 2016, 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 RUNTIME_VM_CANONICAL_TABLES_H_
#define RUNTIME_VM_CANONICAL_TABLES_H_
#include "platform/assert.h"
#include "vm/hash_table.h"
#include "vm/object.h"
namespace dart {
template <typename CharType>
class CharArray {
public:
CharArray(const CharType* data, intptr_t len) : data_(data), len_(len) {
hash_ = String::Hash(data, len);
}
StringPtr ToSymbol() const {
String& result = String::Handle(StringFrom(data_, len_, Heap::kOld));
result.SetCanonical();
result.SetHash(hash_);
return result.ptr();
}
bool Equals(const String& other) const {
ASSERT(other.HasHash());
if (other.Hash() != hash_) {
return false;
}
return other.Equals(data_, len_);
}
uword Hash() const { return hash_; }
private:
const CharType* data_;
intptr_t len_;
uword hash_;
};
typedef CharArray<uint8_t> Latin1Array;
typedef CharArray<uint16_t> UTF16Array;
typedef CharArray<int32_t> UTF32Array;
class StringSlice {
public:
StringSlice(const String& str, intptr_t begin_index, intptr_t length)
: str_(str), begin_index_(begin_index), len_(length) {
hash_ = is_all() ? str.Hash() : String::Hash(str, begin_index, length);
}
StringPtr ToSymbol() const;
bool Equals(const String& other) const {
ASSERT(other.HasHash());
if (other.Hash() != hash_) {
return false;
}
return other.Equals(str_, begin_index_, len_);
}
uword Hash() const { return hash_; }
private:
bool is_all() const { return begin_index_ == 0 && len_ == str_.Length(); }
const String& str_;
intptr_t begin_index_;
intptr_t len_;
uword hash_;
};
class ConcatString {
public:
ConcatString(const String& str1, const String& str2)
: str1_(str1), str2_(str2), hash_(String::HashConcat(str1, str2)) {}
StringPtr ToSymbol() const;
bool Equals(const String& other) const {
ASSERT(other.HasHash());
if (other.Hash() != hash_) {
return false;
}
return other.EqualsConcat(str1_, str2_);
}
uword Hash() const { return hash_; }
private:
const String& str1_;
const String& str2_;
uword hash_;
};
class SymbolTraits {
public:
static const char* Name() { return "SymbolTraits"; }
static bool ReportStats() { return false; }
static bool IsMatch(const Object& a, const Object& b) {
const String& a_str = String::Cast(a);
const String& b_str = String::Cast(b);
ASSERT(a_str.HasHash());
ASSERT(b_str.HasHash());
if (a_str.Hash() != b_str.Hash()) {
return false;
}
intptr_t a_len = a_str.Length();
if (a_len != b_str.Length()) {
return false;
}
// Use a comparison which does not consider the state of the canonical bit.
return a_str.Equals(b_str, 0, a_len);
}
template <typename CharType>
static bool IsMatch(const CharArray<CharType>& array, const Object& obj) {
return array.Equals(String::Cast(obj));
}
static bool IsMatch(const StringSlice& slice, const Object& obj) {
return slice.Equals(String::Cast(obj));
}
static bool IsMatch(const ConcatString& concat, const Object& obj) {
return concat.Equals(String::Cast(obj));
}
static uword Hash(const Object& key) { return String::Cast(key).Hash(); }
template <typename CharType>
static uword Hash(const CharArray<CharType>& array) {
return array.Hash();
}
static uword Hash(const StringSlice& slice) { return slice.Hash(); }
static uword Hash(const ConcatString& concat) { return concat.Hash(); }
template <typename CharType>
static ObjectPtr NewKey(const CharArray<CharType>& array) {
return array.ToSymbol();
}
static ObjectPtr NewKey(const StringSlice& slice) { return slice.ToSymbol(); }
static ObjectPtr NewKey(const ConcatString& concat) {
return concat.ToSymbol();
}
};
typedef UnorderedHashSet<SymbolTraits> CanonicalStringSet;
class CanonicalTypeKey {
public:
explicit CanonicalTypeKey(const Type& key) : key_(key) {}
bool Matches(const Type& arg) const { return key_.Equals(arg); }
uword Hash() const { return key_.Hash(); }
const Type& key_;
private:
DISALLOW_ALLOCATION();
};
// Traits for looking up Canonical Type based on its hash.
class CanonicalTypeTraits {
public:
static const char* Name() { return "CanonicalTypeTraits"; }
static bool ReportStats() { return false; }
// Called when growing the table.
static bool IsMatch(const Object& a, const Object& b) {
ASSERT(a.IsType() && b.IsType());
const Type& arg1 = Type::Cast(a);
const Type& arg2 = Type::Cast(b);
return arg1.Equals(arg2) && (arg1.Hash() == arg2.Hash());
}
static bool IsMatch(const CanonicalTypeKey& a, const Object& b) {
ASSERT(b.IsType());
return a.Matches(Type::Cast(b));
}
static uword Hash(const Object& key) {
ASSERT(key.IsType());
return Type::Cast(key).Hash();
}
static uword Hash(const CanonicalTypeKey& key) { return key.Hash(); }
static ObjectPtr NewKey(const CanonicalTypeKey& obj) {
return obj.key_.ptr();
}
};
typedef UnorderedHashSet<CanonicalTypeTraits> CanonicalTypeSet;
class CanonicalFunctionTypeKey {
public:
explicit CanonicalFunctionTypeKey(const FunctionType& key) : key_(key) {}
bool Matches(const FunctionType& arg) const { return key_.Equals(arg); }
uword Hash() const { return key_.Hash(); }
const FunctionType& key_;
private:
DISALLOW_ALLOCATION();
};
// Traits for looking up Canonical FunctionType based on its hash.
class CanonicalFunctionTypeTraits {
public:
static const char* Name() { return "CanonicalFunctionTypeTraits"; }
static bool ReportStats() { return false; }
// Called when growing the table.
static bool IsMatch(const Object& a, const Object& b) {
ASSERT(a.IsFunctionType() && b.IsFunctionType());
const FunctionType& arg1 = FunctionType::Cast(a);
const FunctionType& arg2 = FunctionType::Cast(b);
return arg1.Equals(arg2) && (arg1.Hash() == arg2.Hash());
}
static bool IsMatch(const CanonicalFunctionTypeKey& a, const Object& b) {
ASSERT(b.IsFunctionType());
return a.Matches(FunctionType::Cast(b));
}
static uword Hash(const Object& key) {
ASSERT(key.IsFunctionType());
return FunctionType::Cast(key).Hash();
}
static uword Hash(const CanonicalFunctionTypeKey& key) { return key.Hash(); }
static ObjectPtr NewKey(const CanonicalFunctionTypeKey& obj) {
return obj.key_.ptr();
}
};
typedef UnorderedHashSet<CanonicalFunctionTypeTraits> CanonicalFunctionTypeSet;
class CanonicalTypeParameterKey {
public:
explicit CanonicalTypeParameterKey(const TypeParameter& key) : key_(key) {}
bool Matches(const TypeParameter& arg) const { return key_.Equals(arg); }
uword Hash() const { return key_.Hash(); }
const TypeParameter& key_;
private:
DISALLOW_ALLOCATION();
};
// Traits for looking up Canonical TypeParameter based on its hash.
class CanonicalTypeParameterTraits {
public:
static const char* Name() { return "CanonicalTypeParameterTraits"; }
static bool ReportStats() { return false; }
// Called when growing the table.
static bool IsMatch(const Object& a, const Object& b) {
ASSERT(a.IsTypeParameter() && b.IsTypeParameter());
const TypeParameter& arg1 = TypeParameter::Cast(a);
const TypeParameter& arg2 = TypeParameter::Cast(b);
return arg1.Equals(arg2) && (arg1.Hash() == arg2.Hash());
}
static bool IsMatch(const CanonicalTypeParameterKey& a, const Object& b) {
ASSERT(b.IsTypeParameter());
return a.Matches(TypeParameter::Cast(b));
}
static uword Hash(const Object& key) {
ASSERT(key.IsTypeParameter());
return TypeParameter::Cast(key).Hash();
}
static uword Hash(const CanonicalTypeParameterKey& key) { return key.Hash(); }
static ObjectPtr NewKey(const CanonicalTypeParameterKey& obj) {
return obj.key_.ptr();
}
};
typedef UnorderedHashSet<CanonicalTypeParameterTraits>
CanonicalTypeParameterSet;
class CanonicalTypeArgumentsKey {
public:
explicit CanonicalTypeArgumentsKey(const TypeArguments& key) : key_(key) {}
bool Matches(const TypeArguments& arg) const {
return key_.Equals(arg) && (key_.Hash() == arg.Hash());
}
uword Hash() const { return key_.Hash(); }
const TypeArguments& key_;
private:
DISALLOW_ALLOCATION();
};
// Traits for looking up Canonical TypeArguments based on its hash.
class CanonicalTypeArgumentsTraits {
public:
static const char* Name() { return "CanonicalTypeArgumentsTraits"; }
static bool ReportStats() { return false; }
// Called when growing the table.
static bool IsMatch(const Object& a, const Object& b) {
ASSERT(a.IsTypeArguments() && b.IsTypeArguments());
const TypeArguments& arg1 = TypeArguments::Cast(a);
const TypeArguments& arg2 = TypeArguments::Cast(b);
return arg1.Equals(arg2) && (arg1.Hash() == arg2.Hash());
}
static bool IsMatch(const CanonicalTypeArgumentsKey& a, const Object& b) {
ASSERT(b.IsTypeArguments());
return a.Matches(TypeArguments::Cast(b));
}
static uword Hash(const Object& key) {
ASSERT(key.IsTypeArguments());
return TypeArguments::Cast(key).Hash();
}
static uword Hash(const CanonicalTypeArgumentsKey& key) { return key.Hash(); }
static ObjectPtr NewKey(const CanonicalTypeArgumentsKey& obj) {
return obj.key_.ptr();
}
};
typedef UnorderedHashSet<CanonicalTypeArgumentsTraits>
CanonicalTypeArgumentsSet;
class MetadataMapTraits {
public:
static const char* Name() { return "MetadataMapTraits"; }
static bool ReportStats() { return false; }
static bool IsMatch(const Object& a, const Object& b);
static uword Hash(const Object& key);
};
typedef UnorderedHashMap<MetadataMapTraits> MetadataMap;
} // namespace dart
#endif // RUNTIME_VM_CANONICAL_TABLES_H_