blob: ece9817f6811ba49e513b0c065c076c2bf4c589a [file] [log] [blame]
// Copyright (c) 2014 Google Inc. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "cobalt/base/circular_buffer_shell.h"
#include <stdint.h>
#include <algorithm>
#include "base/logging.h"
#include "build/build_config.h"
#if defined(STARBOARD)
#include "starboard/memory.h"
#define malloc SbMemoryAllocate
#define realloc SbMemoryReallocate
#define free SbMemoryDeallocate
#endif
static inline void* add_to_pointer(void* pointer, size_t amount) {
return static_cast<uint8_t*>(pointer) + amount;
}
static inline const void* add_to_pointer(const void* pointer, size_t amount) {
return static_cast<const uint8_t*>(pointer) + amount;
}
namespace base {
CircularBufferShell::CircularBufferShell(
size_t max_capacity, ReserveType reserve_type /*= kDoNotReserve*/)
: max_capacity_(max_capacity),
buffer_(NULL),
capacity_(0),
length_(0),
read_position_(0) {
if (reserve_type == kReserve) {
base::AutoLock l(lock_);
IncreaseCapacityTo_Locked(max_capacity_);
}
}
CircularBufferShell::~CircularBufferShell() { Clear(); }
void CircularBufferShell::Clear() {
base::AutoLock l(lock_);
if (buffer_ != NULL) {
free(buffer_);
buffer_ = NULL;
}
capacity_ = 0;
length_ = 0;
read_position_ = 0;
}
void CircularBufferShell::Read(void* destination, size_t length,
size_t* bytes_read) {
base::AutoLock l(lock_);
DCHECK(destination != NULL || length == 0);
if (destination == NULL) length = 0;
ReadAndAdvanceUnchecked_Locked(destination, length, bytes_read);
}
void CircularBufferShell::Peek(void* destination, size_t length,
size_t source_offset,
size_t* bytes_peeked) const {
base::AutoLock l(lock_);
DCHECK(destination != NULL || length == 0);
if (destination == NULL) length = 0;
ReadUnchecked_Locked(destination, length, source_offset, bytes_peeked);
}
void CircularBufferShell::Skip(size_t length, size_t* bytes_skipped) {
base::AutoLock l(lock_);
ReadAndAdvanceUnchecked_Locked(NULL, length, bytes_skipped);
}
bool CircularBufferShell::Write(const void* source, size_t length,
size_t* bytes_written) {
base::AutoLock l(lock_);
DCHECK(source != NULL || length == 0);
if (source == NULL) length = 0;
if (!EnsureCapacityToWrite_Locked(length)) {
return false;
}
size_t produced = 0;
while (true) {
size_t remaining = length - produced;
// In this pass, write up to the contiguous space left.
size_t to_write =
std::min(remaining, capacity_ - GetWritePosition_Locked());
if (to_write == 0) break;
// Copy this segment and do the accounting.
void* destination = GetWritePointer_Locked();
const void* src = add_to_pointer(source, produced);
SbMemoryCopy(destination, src, to_write);
length_ += to_write;
produced += to_write;
}
if (bytes_written) *bytes_written = produced;
return true;
}
size_t CircularBufferShell::GetLength() const {
base::AutoLock l(lock_);
return length_;
}
void CircularBufferShell::ReadUnchecked_Locked(void* destination,
size_t destination_length,
size_t source_offset,
size_t* bytes_read) const {
DCHECK(destination != NULL || bytes_read != NULL);
lock_.AssertAcquired();
size_t dummy = 0;
if (!bytes_read) {
bytes_read = &dummy;
}
// Return immediately if the CircularBuffer is empty or if |source_offset| is
// greater or equal than |length_|.
if (capacity_ == 0 || source_offset >= length_) {
*bytes_read = 0;
return;
}
size_t consumed = 0;
size_t source_length = length_ - source_offset;
size_t read_position = (read_position_ + source_offset) % capacity_;
while (true) {
size_t remaining = std::min(source_length, destination_length - consumed);
// In this pass, read the remaining data that is contiguous.
size_t to_read = std::min(remaining, capacity_ - read_position);
if (to_read == 0) break;
// Copy this segment and do the accounting.
const void* source = add_to_pointer(buffer_, read_position);
if (destination) {
void* dest = add_to_pointer(destination, consumed);
SbMemoryCopy(dest, source, to_read);
}
source_length -= to_read;
read_position = (read_position + to_read) % capacity_;
consumed += to_read;
}
*bytes_read = consumed;
}
void CircularBufferShell::ReadAndAdvanceUnchecked_Locked(
void* destination, size_t destination_length, size_t* bytes_read) {
lock_.AssertAcquired();
size_t dummy = 0;
if (!bytes_read) {
bytes_read = &dummy;
}
// Return immediately if the CircularBuffer is empty.
if (capacity_ == 0) {
*bytes_read = 0;
return;
}
ReadUnchecked_Locked(destination, destination_length, 0, bytes_read);
length_ -= *bytes_read;
read_position_ = (read_position_ + *bytes_read) % capacity_;
}
void* CircularBufferShell::GetWritePointer_Locked() const {
lock_.AssertAcquired();
return add_to_pointer(buffer_, GetWritePosition_Locked());
}
size_t CircularBufferShell::GetWritePosition_Locked() const {
lock_.AssertAcquired();
return (read_position_ + length_) % capacity_;
}
bool CircularBufferShell::EnsureCapacityToWrite_Locked(size_t length) {
lock_.AssertAcquired();
if (capacity_ - length_ < length) {
size_t capacity = std::max(2 * capacity_, length_ + length);
if (capacity > max_capacity_) capacity = max_capacity_;
// New capacity still won't be enough.
if (capacity - length_ < length) {
return false;
}
return IncreaseCapacityTo_Locked(capacity);
}
return true;
}
bool CircularBufferShell::IncreaseCapacityTo_Locked(size_t capacity) {
lock_.AssertAcquired();
if (capacity <= capacity_) {
return true;
}
// If the data isn't wrapped, we can just use realloc.
if (buffer_ != NULL && read_position_ + length_ <= capacity_) {
void* result = realloc(buffer_, capacity);
if (result == NULL) {
return false;
}
capacity_ = capacity;
buffer_ = result;
return true;
}
void* buffer = malloc(capacity);
if (buffer == NULL) {
return false;
}
// Read does everything we want, but it will trounce length_.
size_t length = length_;
// Copy the data over to the new buffer.
ReadUnchecked_Locked(buffer, length_, 0, NULL);
// Adjust the accounting.
length_ = length;
read_position_ = 0;
capacity_ = capacity;
free(buffer_);
buffer_ = buffer;
return true;
}
size_t CircularBufferShell::GetMaxCapacity() const {
base::AutoLock l(lock_);
return max_capacity_;
}
void CircularBufferShell::IncreaseMaxCapacityTo(size_t new_max_capacity) {
base::AutoLock l(lock_);
DCHECK_GT(new_max_capacity, max_capacity_);
if (new_max_capacity > max_capacity_) {
max_capacity_ = new_max_capacity;
}
}
} // namespace base