// Copyright (c) 2011 The Chromium 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 "base/pickle.h" #include <stdlib.h> #include <algorithm> // for max() #include <limits> //------------------------------------------------------------------------------ // static const int Pickle::kPayloadUnit = 64; // We mark a read only pickle with a special capacity_. static const size_t kCapacityReadOnly = std::numeric_limits<size_t>::max(); // Payload is uint32 aligned. Pickle::Pickle() : header_(NULL), header_size_(sizeof(Header)), capacity_(0), variable_buffer_offset_(0) { Resize(kPayloadUnit); header_->payload_size = 0; } Pickle::Pickle(int header_size) : header_(NULL), header_size_(AlignInt(header_size, sizeof(uint32))), capacity_(0), variable_buffer_offset_(0) { DCHECK_GE(static_cast<size_t>(header_size), sizeof(Header)); DCHECK(header_size <= kPayloadUnit); Resize(kPayloadUnit); header_->payload_size = 0; } Pickle::Pickle(const char* data, int data_len) : header_(reinterpret_cast<Header*>(const_cast<char*>(data))), header_size_(0), capacity_(kCapacityReadOnly), variable_buffer_offset_(0) { if (data_len >= static_cast<int>(sizeof(Header))) header_size_ = data_len - header_->payload_size; if (header_size_ > static_cast<unsigned int>(data_len)) header_size_ = 0; if (header_size_ != AlignInt(header_size_, sizeof(uint32))) header_size_ = 0; // If there is anything wrong with the data, we're not going to use it. if (!header_size_) header_ = NULL; } Pickle::Pickle(const Pickle& other) : header_(NULL), header_size_(other.header_size_), capacity_(0), variable_buffer_offset_(other.variable_buffer_offset_) { size_t payload_size = header_size_ + other.header_->payload_size; bool resized = Resize(payload_size); CHECK(resized); // Realloc failed. memcpy(header_, other.header_, payload_size); } Pickle::~Pickle() { if (capacity_ != kCapacityReadOnly) free(header_); } Pickle& Pickle::operator=(const Pickle& other) { if (this == &other) { NOTREACHED(); return *this; } if (capacity_ == kCapacityReadOnly) { header_ = NULL; capacity_ = 0; } if (header_size_ != other.header_size_) { free(header_); header_ = NULL; header_size_ = other.header_size_; } bool resized = Resize(other.header_size_ + other.header_->payload_size); CHECK(resized); // Realloc failed. memcpy(header_, other.header_, other.header_size_ + other.header_->payload_size); variable_buffer_offset_ = other.variable_buffer_offset_; return *this; } bool Pickle::ReadBool(void** iter, bool* result) const { DCHECK(iter); int tmp; if (!ReadInt(iter, &tmp)) return false; DCHECK(0 == tmp || 1 == tmp); *result = tmp ? true : false; return true; } bool Pickle::ReadInt(void** iter, int* result) const { DCHECK(iter); if (!*iter) *iter = const_cast<char*>(payload()); if (!IteratorHasRoomFor(*iter, sizeof(*result))) return false; // TODO(jar): http://crbug.com/13108 Pickle should be cleaned up, and not // dependent on alignment. // Next line is otherwise the same as: memcpy(result, *iter, sizeof(*result)); *result = *reinterpret_cast<int*>(*iter); UpdateIter(iter, sizeof(*result)); return true; } bool Pickle::ReadLong(void** iter, long* result) const { DCHECK(iter); if (!*iter) *iter = const_cast<char*>(payload()); if (!IteratorHasRoomFor(*iter, sizeof(*result))) return false; // TODO(jar): http://crbug.com/13108 Pickle should be cleaned up, and not // dependent on alignment. memcpy(result, *iter, sizeof(*result)); UpdateIter(iter, sizeof(*result)); return true; } bool Pickle::ReadSize(void** iter, size_t* result) const { DCHECK(iter); if (!*iter) *iter = const_cast<char*>(payload()); if (!IteratorHasRoomFor(*iter, sizeof(*result))) return false; // TODO(jar): http://crbug.com/13108 Pickle should be cleaned up, and not // dependent on alignment. // Next line is otherwise the same as: memcpy(result, *iter, sizeof(*result)); *result = *reinterpret_cast<size_t*>(*iter); UpdateIter(iter, sizeof(*result)); return true; } bool Pickle::ReadUInt16(void** iter, uint16* result) const { DCHECK(iter); if (!*iter) *iter = const_cast<char*>(payload()); if (!IteratorHasRoomFor(*iter, sizeof(*result))) return false; memcpy(result, *iter, sizeof(*result)); UpdateIter(iter, sizeof(*result)); return true; } bool Pickle::ReadUInt32(void** iter, uint32* result) const { DCHECK(iter); if (!*iter) *iter = const_cast<char*>(payload()); if (!IteratorHasRoomFor(*iter, sizeof(*result))) return false; memcpy(result, *iter, sizeof(*result)); UpdateIter(iter, sizeof(*result)); return true; } bool Pickle::ReadInt64(void** iter, int64* result) const { DCHECK(iter); if (!*iter) *iter = const_cast<char*>(payload()); if (!IteratorHasRoomFor(*iter, sizeof(*result))) return false; memcpy(result, *iter, sizeof(*result)); UpdateIter(iter, sizeof(*result)); return true; } bool Pickle::ReadUInt64(void** iter, uint64* result) const { DCHECK(iter); if (!*iter) *iter = const_cast<char*>(payload()); if (!IteratorHasRoomFor(*iter, sizeof(*result))) return false; memcpy(result, *iter, sizeof(*result)); UpdateIter(iter, sizeof(*result)); return true; } bool Pickle::ReadString(void** iter, std::string* result) const { DCHECK(iter); int len; if (!ReadLength(iter, &len)) return false; if (!IteratorHasRoomFor(*iter, len)) return false; char* chars = reinterpret_cast<char*>(*iter); result->assign(chars, len); UpdateIter(iter, len); return true; } bool Pickle::ReadWString(void** iter, std::wstring* result) const { DCHECK(iter); int len; if (!ReadLength(iter, &len)) return false; // Avoid integer overflow. if (len > INT_MAX / static_cast<int>(sizeof(wchar_t))) return false; if (!IteratorHasRoomFor(*iter, len * sizeof(wchar_t))) return false; wchar_t* chars = reinterpret_cast<wchar_t*>(*iter); result->assign(chars, len); UpdateIter(iter, len * sizeof(wchar_t)); return true; } bool Pickle::ReadString16(void** iter, string16* result) const { DCHECK(iter); int len; if (!ReadLength(iter, &len)) return false; if (!IteratorHasRoomFor(*iter, len * sizeof(char16))) return false; char16* chars = reinterpret_cast<char16*>(*iter); result->assign(chars, len); UpdateIter(iter, len * sizeof(char16)); return true; } bool Pickle::ReadData(void** iter, const char** data, int* length) const { DCHECK(iter); DCHECK(data); DCHECK(length); *length = 0; *data = 0; if (!ReadLength(iter, length)) return false; return ReadBytes(iter, data, *length); } bool Pickle::ReadBytes(void** iter, const char** data, int length) const { DCHECK(iter); DCHECK(data); *data = 0; if (!*iter) *iter = const_cast<char*>(payload()); if (!IteratorHasRoomFor(*iter, length)) return false; *data = reinterpret_cast<const char*>(*iter); UpdateIter(iter, length); return true; } bool Pickle::ReadLength(void** iter, int* result) const { if (!ReadInt(iter, result)) return false; return ((*result) >= 0); } bool Pickle::WriteString(const std::string& value) { if (!WriteInt(static_cast<int>(value.size()))) return false; return WriteBytes(value.data(), static_cast<int>(value.size())); } bool Pickle::WriteWString(const std::wstring& value) { if (!WriteInt(static_cast<int>(value.size()))) return false; return WriteBytes(value.data(), static_cast<int>(value.size() * sizeof(wchar_t))); } bool Pickle::WriteString16(const string16& value) { if (!WriteInt(static_cast<int>(value.size()))) return false; return WriteBytes(value.data(), static_cast<int>(value.size()) * sizeof(char16)); } bool Pickle::WriteData(const char* data, int length) { return length >= 0 && WriteInt(length) && WriteBytes(data, length); } bool Pickle::WriteBytes(const void* data, int data_len) { DCHECK(capacity_ != kCapacityReadOnly) << "oops: pickle is readonly"; char* dest = BeginWrite(data_len); if (!dest) return false; memcpy(dest, data, data_len); EndWrite(dest, data_len); return true; } char* Pickle::BeginWriteData(int length) { DCHECK_EQ(variable_buffer_offset_, 0U) << "There can only be one variable buffer in a Pickle"; if (length < 0 || !WriteInt(length)) return NULL; char *data_ptr = BeginWrite(length); if (!data_ptr) return NULL; variable_buffer_offset_ = data_ptr - reinterpret_cast<char*>(header_) - sizeof(int); // EndWrite doesn't necessarily have to be called after the write operation, // so we call it here to pad out what the caller will eventually write. EndWrite(data_ptr, length); return data_ptr; } void Pickle::TrimWriteData(int new_length) { DCHECK_NE(variable_buffer_offset_, 0U); // Fetch the the variable buffer size int* cur_length = reinterpret_cast<int*>( reinterpret_cast<char*>(header_) + variable_buffer_offset_); if (new_length < 0 || new_length > *cur_length) { NOTREACHED() << "Invalid length in TrimWriteData."; return; } // Update the payload size and variable buffer size header_->payload_size -= (*cur_length - new_length); *cur_length = new_length; } char* Pickle::BeginWrite(size_t length) { // write at a uint32-aligned offset from the beginning of the header size_t offset = AlignInt(header_->payload_size, sizeof(uint32)); size_t new_size = offset + length; size_t needed_size = header_size_ + new_size; if (needed_size > capacity_ && !Resize(std::max(capacity_ * 2, needed_size))) return NULL; #ifdef ARCH_CPU_64_BITS DCHECK_LE(length, std::numeric_limits<uint32>::max()); #endif header_->payload_size = static_cast<uint32>(new_size); return payload() + offset; } void Pickle::EndWrite(char* dest, int length) { // Zero-pad to keep tools like purify from complaining about uninitialized // memory. if (length % sizeof(uint32)) memset(dest + length, 0, sizeof(uint32) - (length % sizeof(uint32))); } bool Pickle::Resize(size_t new_capacity) { new_capacity = AlignInt(new_capacity, kPayloadUnit); CHECK_NE(capacity_, kCapacityReadOnly); void* p = realloc(header_, new_capacity); if (!p) return false; header_ = reinterpret_cast<Header*>(p); capacity_ = new_capacity; return true; } // static const char* Pickle::FindNext(size_t header_size, const char* start, const char* end) { DCHECK(header_size == AlignInt(header_size, sizeof(uint32))); DCHECK(header_size <= static_cast<size_t>(kPayloadUnit)); if (static_cast<size_t>(end - start) < sizeof(Header)) return NULL; const Header* hdr = reinterpret_cast<const Header*>(start); const char* payload_base = start + header_size; const char* payload_end = payload_base + hdr->payload_size; if (payload_end < payload_base) return NULL; return (payload_end > end) ? NULL : payload_end; }