381 lines
14 KiB
C++
381 lines
14 KiB
C++
// Copyright (c) 2010, Google Inc.
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// All rights reserved.
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//
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// Redistribution and use in source and binary forms, with or without
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// modification, are permitted provided that the following conditions are
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// met:
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//
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// * Redistributions of source code must retain the above copyright
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// notice, this list of conditions and the following disclaimer.
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// * Redistributions in binary form must reproduce the above
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// copyright notice, this list of conditions and the following disclaimer
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// in the documentation and/or other materials provided with the
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// distribution.
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// * Neither the name of Google Inc. nor the names of its
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// contributors may be used to endorse or promote products derived from
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// this software without specific prior written permission.
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//
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// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
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// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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// ---
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//
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// Provides classes shared by both sparse and dense hashtable.
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//
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// sh_hashtable_settings has parameters for growing and shrinking
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// a hashtable. It also packages zero-size functor (ie. hasher).
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//
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// Other functions and classes provide common code for serializing
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// and deserializing hashtables to a stream (such as a FILE*).
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#ifndef UTIL_GTL_HASHTABLE_COMMON_H_
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#define UTIL_GTL_HASHTABLE_COMMON_H_
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#include <deps/sparsehash/internal/sparseconfig.h>
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#include <assert.h>
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#include <stdio.h>
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#include <stddef.h> // for size_t
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#include <iosfwd>
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#include <stdexcept> // For length_error
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_START_GOOGLE_NAMESPACE_
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template <bool> struct SparsehashCompileAssert { };
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#define SPARSEHASH_COMPILE_ASSERT(expr, msg) \
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typedef SparsehashCompileAssert<(bool(expr))> msg[bool(expr) ? 1 : -1]
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namespace sparsehash_internal {
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// Adaptor methods for reading/writing data from an INPUT or OUPTUT
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// variable passed to serialize() or unserialize(). For now we
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// have implemented INPUT/OUTPUT for FILE*, istream*/ostream* (note
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// they are pointers, unlike typical use), or else a pointer to
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// something that supports a Read()/Write() method.
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//
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// For technical reasons, we implement read_data/write_data in two
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// stages. The actual work is done in *_data_internal, which takes
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// the stream argument twice: once as a template type, and once with
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// normal type information. (We only use the second version.) We do
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// this because of how C++ picks what function overload to use. If we
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// implemented this the naive way:
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// bool read_data(istream* is, const void* data, size_t length);
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// template<typename T> read_data(T* fp, const void* data, size_t length);
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// C++ would prefer the second version for every stream type except
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// istream. However, we want C++ to prefer the first version for
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// streams that are *subclasses* of istream, such as istringstream.
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// This is not possible given the way template types are resolved. So
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// we split the stream argument in two, one of which is templated and
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// one of which is not. The specialized functions (like the istream
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// version above) ignore the template arg and use the second, 'type'
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// arg, getting subclass matching as normal. The 'catch-all'
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// functions (the second version above) use the template arg to deduce
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// the type, and use a second, void* arg to achieve the desired
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// 'catch-all' semantics.
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// ----- low-level I/O for FILE* ----
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template<typename Ignored>
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inline bool read_data_internal(Ignored*, FILE* fp,
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void* data, size_t length) {
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return fread(data, length, 1, fp) == 1;
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}
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template<typename Ignored>
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inline bool write_data_internal(Ignored*, FILE* fp,
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const void* data, size_t length) {
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return fwrite(data, length, 1, fp) == 1;
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}
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// ----- low-level I/O for iostream ----
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// We want the caller to be responsible for #including <iostream>, not
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// us, because iostream is a big header! According to the standard,
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// it's only legal to delay the instantiation the way we want to if
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// the istream/ostream is a template type. So we jump through hoops.
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template<typename ISTREAM>
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inline bool read_data_internal_for_istream(ISTREAM* fp,
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void* data, size_t length) {
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return fp->read(reinterpret_cast<char*>(data), length).good();
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}
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template<typename Ignored>
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inline bool read_data_internal(Ignored*, std::istream* fp,
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void* data, size_t length) {
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return read_data_internal_for_istream(fp, data, length);
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}
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template<typename OSTREAM>
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inline bool write_data_internal_for_ostream(OSTREAM* fp,
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const void* data, size_t length) {
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return fp->write(reinterpret_cast<const char*>(data), length).good();
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}
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template<typename Ignored>
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inline bool write_data_internal(Ignored*, std::ostream* fp,
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const void* data, size_t length) {
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return write_data_internal_for_ostream(fp, data, length);
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}
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// ----- low-level I/O for custom streams ----
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// The INPUT type needs to support a Read() method that takes a
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// buffer and a length and returns the number of bytes read.
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template <typename INPUT>
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inline bool read_data_internal(INPUT* fp, void*,
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void* data, size_t length) {
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return static_cast<size_t>(fp->Read(data, length)) == length;
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}
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// The OUTPUT type needs to support a Write() operation that takes
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// a buffer and a length and returns the number of bytes written.
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template <typename OUTPUT>
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inline bool write_data_internal(OUTPUT* fp, void*,
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const void* data, size_t length) {
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return static_cast<size_t>(fp->Write(data, length)) == length;
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}
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// ----- low-level I/O: the public API ----
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template <typename INPUT>
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inline bool read_data(INPUT* fp, void* data, size_t length) {
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return read_data_internal(fp, fp, data, length);
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}
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template <typename OUTPUT>
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inline bool write_data(OUTPUT* fp, const void* data, size_t length) {
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return write_data_internal(fp, fp, data, length);
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}
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// Uses read_data() and write_data() to read/write an integer.
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// length is the number of bytes to read/write (which may differ
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// from sizeof(IntType), allowing us to save on a 32-bit system
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// and load on a 64-bit system). Excess bytes are taken to be 0.
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// INPUT and OUTPUT must match legal inputs to read/write_data (above).
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template <typename INPUT, typename IntType>
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bool read_bigendian_number(INPUT* fp, IntType* value, size_t length) {
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*value = 0;
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unsigned char byte;
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// We require IntType to be unsigned or else the shifting gets all screwy.
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SPARSEHASH_COMPILE_ASSERT(static_cast<IntType>(-1) > static_cast<IntType>(0),
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serializing_int_requires_an_unsigned_type);
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for (size_t i = 0; i < length; ++i) {
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if (!read_data(fp, &byte, sizeof(byte))) return false;
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*value |= static_cast<IntType>(byte) << ((length - 1 - i) * 8);
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}
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return true;
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}
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template <typename OUTPUT, typename IntType>
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bool write_bigendian_number(OUTPUT* fp, IntType value, size_t length) {
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unsigned char byte;
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// We require IntType to be unsigned or else the shifting gets all screwy.
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SPARSEHASH_COMPILE_ASSERT(static_cast<IntType>(-1) > static_cast<IntType>(0),
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serializing_int_requires_an_unsigned_type);
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for (size_t i = 0; i < length; ++i) {
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byte = (sizeof(value) <= length-1 - i)
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? 0 : static_cast<unsigned char>((value >> ((length-1 - i) * 8)) & 255);
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if (!write_data(fp, &byte, sizeof(byte))) return false;
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}
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return true;
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}
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// If your keys and values are simple enough, you can pass this
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// serializer to serialize()/unserialize(). "Simple enough" means
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// value_type is a POD type that contains no pointers. Note,
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// however, we don't try to normalize endianness.
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// This is the type used for NopointerSerializer.
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template <typename value_type> struct pod_serializer {
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template <typename INPUT>
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bool operator()(INPUT* fp, value_type* value) const {
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return read_data(fp, value, sizeof(*value));
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}
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template <typename OUTPUT>
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bool operator()(OUTPUT* fp, const value_type& value) const {
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return write_data(fp, &value, sizeof(value));
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}
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};
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// Settings contains parameters for growing and shrinking the table.
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// It also packages zero-size functor (ie. hasher).
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//
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// It does some munging of the hash value in cases where we think
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// (fear) the original hash function might not be very good. In
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// particular, the default hash of pointers is the identity hash,
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// so probably all the low bits are 0. We identify when we think
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// we're hashing a pointer, and chop off the low bits. Note this
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// isn't perfect: even when the key is a pointer, we can't tell
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// for sure that the hash is the identity hash. If it's not, this
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// is needless work (and possibly, though not likely, harmful).
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template<typename Key, typename HashFunc,
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typename SizeType, int HT_MIN_BUCKETS>
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class sh_hashtable_settings : public HashFunc {
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public:
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typedef Key key_type;
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typedef HashFunc hasher;
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typedef SizeType size_type;
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public:
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sh_hashtable_settings(const hasher& hf,
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const float ht_occupancy_flt,
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const float ht_empty_flt)
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: hasher(hf),
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enlarge_threshold_(0),
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shrink_threshold_(0),
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consider_shrink_(false),
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use_empty_(false),
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use_deleted_(false),
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num_ht_copies_(0) {
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set_enlarge_factor(ht_occupancy_flt);
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set_shrink_factor(ht_empty_flt);
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}
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size_type hash(const key_type& v) const {
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// We munge the hash value when we don't trust hasher::operator().
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return hash_munger<Key>::MungedHash(hasher::operator()(v));
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}
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float enlarge_factor() const {
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return enlarge_factor_;
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}
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void set_enlarge_factor(float f) {
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enlarge_factor_ = f;
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}
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float shrink_factor() const {
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return shrink_factor_;
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}
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void set_shrink_factor(float f) {
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shrink_factor_ = f;
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}
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size_type enlarge_threshold() const {
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return enlarge_threshold_;
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}
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void set_enlarge_threshold(size_type t) {
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enlarge_threshold_ = t;
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}
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size_type shrink_threshold() const {
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return shrink_threshold_;
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}
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void set_shrink_threshold(size_type t) {
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shrink_threshold_ = t;
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}
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size_type enlarge_size(size_type x) const {
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return static_cast<size_type>(x * enlarge_factor_);
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}
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size_type shrink_size(size_type x) const {
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return static_cast<size_type>(x * shrink_factor_);
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}
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bool consider_shrink() const {
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return consider_shrink_;
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}
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void set_consider_shrink(bool t) {
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consider_shrink_ = t;
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}
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bool use_empty() const {
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return use_empty_;
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}
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void set_use_empty(bool t) {
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use_empty_ = t;
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}
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bool use_deleted() const {
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return use_deleted_;
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}
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void set_use_deleted(bool t) {
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use_deleted_ = t;
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}
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size_type num_ht_copies() const {
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return static_cast<size_type>(num_ht_copies_);
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}
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void inc_num_ht_copies() {
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++num_ht_copies_;
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}
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// Reset the enlarge and shrink thresholds
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void reset_thresholds(size_type num_buckets) {
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set_enlarge_threshold(enlarge_size(num_buckets));
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set_shrink_threshold(shrink_size(num_buckets));
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// whatever caused us to reset already considered
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set_consider_shrink(false);
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}
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// Caller is resposible for calling reset_threshold right after
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// set_resizing_parameters.
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void set_resizing_parameters(float shrink, float grow) {
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assert(shrink >= 0.0);
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assert(grow <= 1.0);
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if (shrink > grow/2.0f)
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shrink = grow / 2.0f; // otherwise we thrash hashtable size
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set_shrink_factor(shrink);
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set_enlarge_factor(grow);
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}
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// This is the smallest size a hashtable can be without being too crowded
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// If you like, you can give a min #buckets as well as a min #elts
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size_type min_buckets(size_type num_elts, size_type min_buckets_wanted) {
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float enlarge = enlarge_factor();
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size_type sz = HT_MIN_BUCKETS; // min buckets allowed
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while ( sz < min_buckets_wanted ||
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num_elts >= static_cast<size_type>(sz * enlarge) ) {
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// This just prevents overflowing size_type, since sz can exceed
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// max_size() here.
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if (static_cast<size_type>(sz * 2) < sz) {
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throw std::length_error("resize overflow"); // protect against overflow
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}
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sz *= 2;
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}
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return sz;
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}
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private:
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template<class HashKey> class hash_munger {
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public:
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static size_t MungedHash(size_t hash) {
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return hash;
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}
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};
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// This matches when the hashtable key is a pointer.
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template<class HashKey> class hash_munger<HashKey*> {
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public:
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static size_t MungedHash(size_t hash) {
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// TODO(csilvers): consider rotating instead:
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// static const int shift = (sizeof(void *) == 4) ? 2 : 3;
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// return (hash << (sizeof(hash) * 8) - shift)) | (hash >> shift);
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// This matters if we ever change sparse/dense_hash_* to compare
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// hashes before comparing actual values. It's speedy on x86.
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return hash / sizeof(void*); // get rid of known-0 bits
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}
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};
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size_type enlarge_threshold_; // table.size() * enlarge_factor
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size_type shrink_threshold_; // table.size() * shrink_factor
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float enlarge_factor_; // how full before resize
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float shrink_factor_; // how empty before resize
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// consider_shrink=true if we should try to shrink before next insert
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bool consider_shrink_;
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bool use_empty_; // used only by densehashtable, not sparsehashtable
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bool use_deleted_; // false until delkey has been set
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// num_ht_copies is a counter incremented every Copy/Move
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unsigned int num_ht_copies_;
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};
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} // namespace sparsehash_internal
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#undef SPARSEHASH_COMPILE_ASSERT
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_END_GOOGLE_NAMESPACE_
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#endif // UTIL_GTL_HASHTABLE_COMMON_H_
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