[bytebuffer] Rework ByteBuffer using templates (#7638)

This commit is contained in:
Clyde Stubbs 2024-10-29 09:08:29 +11:00 committed by GitHub
parent 22f30d42a6
commit 858d97ccef
No known key found for this signature in database
GPG Key ID: B5690EEEBB952194
13 changed files with 595 additions and 311 deletions

View File

@ -85,6 +85,7 @@ esphome/components/bmp581/* @kahrendt
esphome/components/bp1658cj/* @Cossid
esphome/components/bp5758d/* @Cossid
esphome/components/button/* @esphome/core
esphome/components/bytebuffer/* @clydebarrow
esphome/components/canbus/* @danielschramm @mvturnho
esphome/components/cap1188/* @mreditor97
esphome/components/captive_portal/* @OttoWinter

View File

@ -0,0 +1,5 @@
CODEOWNERS = ["@clydebarrow"]
# Allows bytebuffer to be configured in yaml, to allow use of the C++ api.
CONFIG_SCHEMA = {}

View File

@ -0,0 +1,421 @@
#pragma once
#include <utility>
#include <vector>
#include <cinttypes>
#include <cstddef>
#include "esphome/core/helpers.h"
namespace esphome {
namespace bytebuffer {
enum Endian { LITTLE, BIG };
/**
* A class modelled on the Java ByteBuffer class. It wraps a vector of bytes and permits putting and getting
* items of various sizes, with an automatically incremented position.
*
* There are three variables maintained pointing into the buffer:
*
* capacity: the maximum amount of data that can be stored - set on construction and cannot be changed
* limit: the limit of the data currently available to get or put
* position: the current insert or extract position
*
* 0 <= position <= limit <= capacity
*
* In addition a mark can be set to the current position with mark(). A subsequent call to reset() will restore
* the position to the mark.
*
* The buffer can be marked to be little-endian (default) or big-endian. All subsequent operations will use that order.
*
* The flip() operation will reset the position to 0 and limit to the current position. This is useful for reading
* data from a buffer after it has been written.
*
* The code is defined here in the header file rather than in a .cpp file, so that it does not get compiled if not used.
* The templated functions ensure that only those typed functions actually used are compiled. The functions
* are implicitly inline-able which will aid performance.
*/
class ByteBuffer {
public:
// Default constructor (compatibility with TEMPLATABLE_VALUE)
// Creates a zero-length ByteBuffer which is little use to anybody.
ByteBuffer() : ByteBuffer(std::vector<uint8_t>()) {}
/**
* Create a new Bytebuffer with the given capacity
*/
ByteBuffer(size_t capacity, Endian endianness = LITTLE)
: data_(std::vector<uint8_t>(capacity)), endianness_(endianness), limit_(capacity){};
// templated functions to implement putting and getting data of various types. There are two flavours of all
// functions - one that uses the position as the offset, and updates the position accordingly, and one that
// takes an explicit offset and does not update the position.
// Separate temnplates are provided for types that fit into 32 bits and those that are bigger. These delegate
// the actual put/get to common code based around those sizes.
// This reduces the code size and execution time for smaller types. A similar structure for e.g. 16 bits is unlikely
// to provide any further benefit given that all target platforms are native 32 bit.
template<typename T>
T get(typename std::enable_if<std::is_integral<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) <= sizeof(uint32_t)), T>::type * = 0) {
// integral types that fit into 32 bit
return static_cast<T>(this->get_uint32_(sizeof(T)));
}
template<typename T>
T get(size_t offset, typename std::enable_if<std::is_integral<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) <= sizeof(uint32_t)), T>::type * = 0) {
return static_cast<T>(this->get_uint32_(offset, sizeof(T)));
}
template<typename T>
void put(const T &value, typename std::enable_if<std::is_integral<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) <= sizeof(uint32_t)), T>::type * = 0) {
this->put_uint32_(static_cast<uint32_t>(value), sizeof(T));
}
template<typename T>
void put(const T &value, size_t offset, typename std::enable_if<std::is_integral<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) <= sizeof(uint32_t)), T>::type * = 0) {
this->put_uint32_(static_cast<uint32_t>(value), offset, sizeof(T));
}
// integral types that do not fit into 32 bit (basically only 64 bit types)
template<typename T>
T get(typename std::enable_if<std::is_integral<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) == sizeof(uint64_t)), T>::type * = 0) {
return static_cast<T>(this->get_uint64_(sizeof(T)));
}
template<typename T>
T get(size_t offset, typename std::enable_if<std::is_integral<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) == sizeof(uint64_t)), T>::type * = 0) {
return static_cast<T>(this->get_uint64_(offset, sizeof(T)));
}
template<typename T>
void put(const T &value, typename std::enable_if<std::is_integral<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) == sizeof(uint64_t)), T>::type * = 0) {
this->put_uint64_(value, sizeof(T));
}
template<typename T>
void put(const T &value, size_t offset, typename std::enable_if<std::is_integral<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) == sizeof(uint64_t)), T>::type * = 0) {
this->put_uint64_(static_cast<uint64_t>(value), offset, sizeof(T));
}
// floating point types. Caters for 32 and 64 bit floating point.
template<typename T>
T get(typename std::enable_if<std::is_floating_point<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) == sizeof(uint32_t)), T>::type * = 0) {
return bit_cast<T>(this->get_uint32_(sizeof(T)));
}
template<typename T>
T get(typename std::enable_if<std::is_floating_point<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) == sizeof(uint64_t)), T>::type * = 0) {
return bit_cast<T>(this->get_uint64_(sizeof(T)));
}
template<typename T>
T get(size_t offset, typename std::enable_if<std::is_floating_point<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) == sizeof(uint32_t)), T>::type * = 0) {
return bit_cast<T>(this->get_uint32_(offset, sizeof(T)));
}
template<typename T>
T get(size_t offset, typename std::enable_if<std::is_floating_point<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) == sizeof(uint64_t)), T>::type * = 0) {
return bit_cast<T>(this->get_uint64_(offset, sizeof(T)));
}
template<typename T>
void put(const T &value, typename std::enable_if<std::is_floating_point<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) <= sizeof(uint32_t)), T>::type * = 0) {
this->put_uint32_(bit_cast<uint32_t>(value), sizeof(T));
}
template<typename T>
void put(const T &value, typename std::enable_if<std::is_floating_point<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) == sizeof(uint64_t)), T>::type * = 0) {
this->put_uint64_(bit_cast<uint64_t>(value), sizeof(T));
}
template<typename T>
void put(const T &value, size_t offset, typename std::enable_if<std::is_floating_point<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) <= sizeof(uint32_t)), T>::type * = 0) {
this->put_uint32_(bit_cast<uint32_t>(value), offset, sizeof(T));
}
template<typename T>
void put(const T &value, size_t offset, typename std::enable_if<std::is_floating_point<T>::value, T>::type * = 0,
typename std::enable_if<(sizeof(T) == sizeof(uint64_t)), T>::type * = 0) {
this->put_uint64_(bit_cast<uint64_t>(value), offset, sizeof(T));
}
template<typename T> static ByteBuffer wrap(T value, Endian endianness = LITTLE) {
ByteBuffer buffer = ByteBuffer(sizeof(T), endianness);
buffer.put(value);
buffer.flip();
return buffer;
}
static ByteBuffer wrap(std::vector<uint8_t> const &data, Endian endianness = LITTLE) {
ByteBuffer buffer = {data};
buffer.endianness_ = endianness;
return buffer;
}
static ByteBuffer wrap(const uint8_t *ptr, size_t len, Endian endianness = LITTLE) {
return wrap(std::vector<uint8_t>(ptr, ptr + len), endianness);
}
// convenience functions with explicit types named..
void put_float(float value) { this->put(value); }
void put_double(double value) { this->put(value); }
uint8_t get_uint8() { return this->data_[this->position_++]; }
// Get a 16 bit unsigned value, increment by 2
uint16_t get_uint16() { return this->get<uint16_t>(); }
// Get a 24 bit unsigned value, increment by 3
uint32_t get_uint24() { return this->get_uint32_(3); };
// Get a 32 bit unsigned value, increment by 4
uint32_t get_uint32() { return this->get<uint32_t>(); };
// Get a 64 bit unsigned value, increment by 8
uint64_t get_uint64() { return this->get<uint64_t>(); };
// Signed versions of the get functions
uint8_t get_int8() { return static_cast<int8_t>(this->get_uint8()); };
int16_t get_int16() { return this->get<uint16_t>(); }
int32_t get_int32() { return this->get<int32_t>(); }
int64_t get_int64() { return this->get<int64_t>(); }
// Get a float value, increment by 4
float get_float() { return this->get<float>(); }
// Get a double value, increment by 8
double get_double() { return this->get<double>(); }
// Get a bool value, increment by 1
bool get_bool() { return static_cast<bool>(this->get_uint8()); }
uint32_t get_int24(size_t offset) {
auto value = this->get_uint24(offset);
uint32_t mask = (~static_cast<uint32_t>(0)) << 23;
if ((value & mask) != 0)
value |= mask;
return value;
}
uint32_t get_int24() {
auto value = this->get_uint24();
uint32_t mask = (~static_cast<uint32_t>(0)) << 23;
if ((value & mask) != 0)
value |= mask;
return value;
}
std::vector<uint8_t> get_vector(size_t length, size_t offset) {
auto start = this->data_.begin() + offset;
return {start, start + length};
}
std::vector<uint8_t> get_vector(size_t length) {
auto result = this->get_vector(length, this->position_);
this->position_ += length;
return result;
}
// Convenience named functions
void put_uint8(uint8_t value) { this->data_[this->position_++] = value; }
void put_uint16(uint16_t value) { this->put(value); }
void put_uint24(uint32_t value) { this->put_uint32_(value, 3); }
void put_uint32(uint32_t value) { this->put(value); }
void put_uint64(uint64_t value) { this->put(value); }
// Signed versions of the put functions
void put_int8(int8_t value) { this->put_uint8(static_cast<uint8_t>(value)); }
void put_int16(int16_t value) { this->put(value); }
void put_int24(int32_t value) { this->put_uint32_(value, 3); }
void put_int32(int32_t value) { this->put(value); }
void put_int64(int64_t value) { this->put(value); }
// Extra put functions
void put_bool(bool value) { this->put_uint8(value); }
// versions of the above with an offset, these do not update the position
uint64_t get_uint64(size_t offset) { return this->get<uint64_t>(offset); }
uint32_t get_uint24(size_t offset) { return this->get_uint32_(offset, 3); };
double get_double(size_t offset) { return get<double>(offset); }
// Get one byte from the buffer, increment position by 1
uint8_t get_uint8(size_t offset) { return this->data_[offset]; }
// Get a 16 bit unsigned value, increment by 2
uint16_t get_uint16(size_t offset) { return get<uint16_t>(offset); }
// Get a 24 bit unsigned value, increment by 3
uint32_t get_uint32(size_t offset) { return this->get<uint32_t>(offset); };
// Get a 64 bit unsigned value, increment by 8
uint8_t get_int8(size_t offset) { return get<int8_t>(offset); }
int16_t get_int16(size_t offset) { return get<int16_t>(offset); }
int32_t get_int32(size_t offset) { return get<int32_t>(offset); }
int64_t get_int64(size_t offset) { return get<int64_t>(offset); }
// Get a float value, increment by 4
float get_float(size_t offset) { return get<float>(offset); }
// Get a double value, increment by 8
// Get a bool value, increment by 1
bool get_bool(size_t offset) { return this->get_uint8(offset); }
void put_uint8(uint8_t value, size_t offset) { this->data_[offset] = value; }
void put_uint16(uint16_t value, size_t offset) { this->put(value, offset); }
void put_uint24(uint32_t value, size_t offset) { this->put(value, offset); }
void put_uint32(uint32_t value, size_t offset) { this->put(value, offset); }
void put_uint64(uint64_t value, size_t offset) { this->put(value, offset); }
// Signed versions of the put functions
void put_int8(int8_t value, size_t offset) { this->put_uint8(static_cast<uint8_t>(value), offset); }
void put_int16(int16_t value, size_t offset) { this->put(value, offset); }
void put_int24(int32_t value, size_t offset) { this->put_uint32_(value, offset, 3); }
void put_int32(int32_t value, size_t offset) { this->put(value, offset); }
void put_int64(int64_t value, size_t offset) { this->put(value, offset); }
// Extra put functions
void put_float(float value, size_t offset) { this->put(value, offset); }
void put_double(double value, size_t offset) { this->put(value, offset); }
void put_bool(bool value, size_t offset) { this->put_uint8(value, offset); }
void put(const std::vector<uint8_t> &value, size_t offset) {
std::copy(value.begin(), value.end(), this->data_.begin() + offset);
}
void put_vector(const std::vector<uint8_t> &value, size_t offset) { this->put(value, offset); }
void put(const std::vector<uint8_t> &value) {
this->put_vector(value, this->position_);
this->position_ += value.size();
}
void put_vector(const std::vector<uint8_t> &value) { this->put(value); }
// Getters
inline size_t get_capacity() const { return this->data_.size(); }
inline size_t get_position() const { return this->position_; }
inline size_t get_limit() const { return this->limit_; }
inline size_t get_remaining() const { return this->get_limit() - this->get_position(); }
inline Endian get_endianness() const { return this->endianness_; }
inline void mark() { this->mark_ = this->position_; }
inline void big_endian() { this->endianness_ = BIG; }
inline void little_endian() { this->endianness_ = LITTLE; }
// retrieve a pointer to the underlying data.
std::vector<uint8_t> get_data() { return this->data_; };
void get_bytes(void *dest, size_t length) {
std::copy(this->data_.begin() + this->position_, this->data_.begin() + this->position_ + length, (uint8_t *) dest);
this->position_ += length;
}
void get_bytes(void *dest, size_t length, size_t offset) {
std::copy(this->data_.begin() + offset, this->data_.begin() + offset + length, (uint8_t *) dest);
}
void rewind() { this->position_ = 0; }
void reset() { this->position_ = this->mark_; }
void set_limit(size_t limit) { this->limit_ = limit; }
void set_position(size_t position) { this->position_ = position; }
void clear() {
this->limit_ = this->get_capacity();
this->position_ = 0;
}
void flip() {
this->limit_ = this->position_;
this->position_ = 0;
}
protected:
uint64_t get_uint64_(size_t offset, size_t length) const {
uint64_t value = 0;
if (this->endianness_ == LITTLE) {
offset += length;
while (length-- != 0) {
value <<= 8;
value |= this->data_[--offset];
}
} else {
while (length-- != 0) {
value <<= 8;
value |= this->data_[offset++];
}
}
return value;
}
uint64_t get_uint64_(size_t length) {
auto result = this->get_uint64_(this->position_, length);
this->position_ += length;
return result;
}
uint32_t get_uint32_(size_t offset, size_t length) const {
uint32_t value = 0;
if (this->endianness_ == LITTLE) {
offset += length;
while (length-- != 0) {
value <<= 8;
value |= this->data_[--offset];
}
} else {
while (length-- != 0) {
value <<= 8;
value |= this->data_[offset++];
}
}
return value;
}
uint32_t get_uint32_(size_t length) {
auto result = this->get_uint32_(this->position_, length);
this->position_ += length;
return result;
}
/// Putters
void put_uint64_(uint64_t value, size_t length) {
this->put_uint64_(value, this->position_, length);
this->position_ += length;
}
void put_uint32_(uint32_t value, size_t length) {
this->put_uint32_(value, this->position_, length);
this->position_ += length;
}
void put_uint64_(uint64_t value, size_t offset, size_t length) {
if (this->endianness_ == LITTLE) {
while (length-- != 0) {
this->data_[offset++] = static_cast<uint8_t>(value);
value >>= 8;
}
} else {
offset += length;
while (length-- != 0) {
this->data_[--offset] = static_cast<uint8_t>(value);
value >>= 8;
}
}
}
void put_uint32_(uint32_t value, size_t offset, size_t length) {
if (this->endianness_ == LITTLE) {
while (length-- != 0) {
this->data_[offset++] = static_cast<uint8_t>(value);
value >>= 8;
}
} else {
offset += length;
while (length-- != 0) {
this->data_[--offset] = static_cast<uint8_t>(value);
value >>= 8;
}
}
}
ByteBuffer(std::vector<uint8_t> const &data) : data_(data), limit_(data.size()) {}
std::vector<uint8_t> data_;
Endian endianness_{LITTLE};
size_t position_{0};
size_t mark_{0};
size_t limit_{0};
};
} // namespace bytebuffer
} // namespace esphome

View File

@ -1,167 +0,0 @@
#include "bytebuffer.h"
#include <cassert>
#include "esphome/core/helpers.h"
#include <list>
#include <vector>
namespace esphome {
ByteBuffer ByteBuffer::wrap(const uint8_t *ptr, size_t len, Endian endianness) {
// there is a double copy happening here, could be optimized but at cost of clarity.
std::vector<uint8_t> data(ptr, ptr + len);
ByteBuffer buffer = {data};
buffer.endianness_ = endianness;
return buffer;
}
ByteBuffer ByteBuffer::wrap(std::vector<uint8_t> const &data, Endian endianness) {
ByteBuffer buffer = {data};
buffer.endianness_ = endianness;
return buffer;
}
ByteBuffer ByteBuffer::wrap(uint8_t value) {
ByteBuffer buffer = ByteBuffer(1);
buffer.put_uint8(value);
buffer.flip();
return buffer;
}
ByteBuffer ByteBuffer::wrap(uint16_t value, Endian endianness) {
ByteBuffer buffer = ByteBuffer(2, endianness);
buffer.put_uint16(value);
buffer.flip();
return buffer;
}
ByteBuffer ByteBuffer::wrap(uint32_t value, Endian endianness) {
ByteBuffer buffer = ByteBuffer(4, endianness);
buffer.put_uint32(value);
buffer.flip();
return buffer;
}
ByteBuffer ByteBuffer::wrap(uint64_t value, Endian endianness) {
ByteBuffer buffer = ByteBuffer(8, endianness);
buffer.put_uint64(value);
buffer.flip();
return buffer;
}
ByteBuffer ByteBuffer::wrap(float value, Endian endianness) {
ByteBuffer buffer = ByteBuffer(sizeof(float), endianness);
buffer.put_float(value);
buffer.flip();
return buffer;
}
ByteBuffer ByteBuffer::wrap(double value, Endian endianness) {
ByteBuffer buffer = ByteBuffer(sizeof(double), endianness);
buffer.put_double(value);
buffer.flip();
return buffer;
}
void ByteBuffer::set_limit(size_t limit) {
assert(limit <= this->get_capacity());
this->limit_ = limit;
}
void ByteBuffer::set_position(size_t position) {
assert(position <= this->get_limit());
this->position_ = position;
}
void ByteBuffer::clear() {
this->limit_ = this->get_capacity();
this->position_ = 0;
}
void ByteBuffer::flip() {
this->limit_ = this->position_;
this->position_ = 0;
}
/// Getters
uint8_t ByteBuffer::get_uint8() {
assert(this->get_remaining() >= 1);
return this->data_[this->position_++];
}
uint64_t ByteBuffer::get_uint(size_t length) {
assert(this->get_remaining() >= length);
uint64_t value = 0;
if (this->endianness_ == LITTLE) {
this->position_ += length;
auto index = this->position_;
while (length-- != 0) {
value <<= 8;
value |= this->data_[--index];
}
} else {
while (length-- != 0) {
value <<= 8;
value |= this->data_[this->position_++];
}
}
return value;
}
uint32_t ByteBuffer::get_int24() {
auto value = this->get_uint24();
uint32_t mask = (~static_cast<uint32_t>(0)) << 23;
if ((value & mask) != 0)
value |= mask;
return value;
}
float ByteBuffer::get_float() {
assert(this->get_remaining() >= sizeof(float));
return bit_cast<float>(this->get_uint32());
}
double ByteBuffer::get_double() {
assert(this->get_remaining() >= sizeof(double));
return bit_cast<double>(this->get_uint64());
}
std::vector<uint8_t> ByteBuffer::get_vector(size_t length) {
assert(this->get_remaining() >= length);
auto start = this->data_.begin() + this->position_;
this->position_ += length;
return {start, start + length};
}
/// Putters
void ByteBuffer::put_uint8(uint8_t value) {
assert(this->get_remaining() >= 1);
this->data_[this->position_++] = value;
}
void ByteBuffer::put_uint(uint64_t value, size_t length) {
assert(this->get_remaining() >= length);
if (this->endianness_ == LITTLE) {
while (length-- != 0) {
this->data_[this->position_++] = static_cast<uint8_t>(value);
value >>= 8;
}
} else {
this->position_ += length;
auto index = this->position_;
while (length-- != 0) {
this->data_[--index] = static_cast<uint8_t>(value);
value >>= 8;
}
}
}
void ByteBuffer::put_float(float value) {
static_assert(sizeof(float) == sizeof(uint32_t), "Float sizes other than 32 bit not supported");
assert(this->get_remaining() >= sizeof(float));
this->put_uint32(bit_cast<uint32_t>(value));
}
void ByteBuffer::put_double(double value) {
static_assert(sizeof(double) == sizeof(uint64_t), "Double sizes other than 64 bit not supported");
assert(this->get_remaining() >= sizeof(double));
this->put_uint64(bit_cast<uint64_t>(value));
}
void ByteBuffer::put_vector(const std::vector<uint8_t> &value) {
assert(this->get_remaining() >= value.size());
std::copy(value.begin(), value.end(), this->data_.begin() + this->position_);
this->position_ += value.size();
}
} // namespace esphome

View File

@ -1,144 +0,0 @@
#pragma once
#include <utility>
#include <vector>
#include <cinttypes>
#include <cstddef>
namespace esphome {
enum Endian { LITTLE, BIG };
/**
* A class modelled on the Java ByteBuffer class. It wraps a vector of bytes and permits putting and getting
* items of various sizes, with an automatically incremented position.
*
* There are three variables maintained pointing into the buffer:
*
* capacity: the maximum amount of data that can be stored - set on construction and cannot be changed
* limit: the limit of the data currently available to get or put
* position: the current insert or extract position
*
* 0 <= position <= limit <= capacity
*
* In addition a mark can be set to the current position with mark(). A subsequent call to reset() will restore
* the position to the mark.
*
* The buffer can be marked to be little-endian (default) or big-endian. All subsequent operations will use that order.
*
* The flip() operation will reset the position to 0 and limit to the current position. This is useful for reading
* data from a buffer after it has been written.
*
*/
class ByteBuffer {
public:
// Default constructor (compatibility with TEMPLATABLE_VALUE)
ByteBuffer() : ByteBuffer(std::vector<uint8_t>()) {}
/**
* Create a new Bytebuffer with the given capacity
*/
ByteBuffer(size_t capacity, Endian endianness = LITTLE)
: data_(std::vector<uint8_t>(capacity)), endianness_(endianness), limit_(capacity){};
/**
* Wrap an existing vector in a ByteBufffer
*/
static ByteBuffer wrap(std::vector<uint8_t> const &data, Endian endianness = LITTLE);
/**
* Wrap an existing array in a ByteBuffer. Note that this will create a copy of the data.
*/
static ByteBuffer wrap(const uint8_t *ptr, size_t len, Endian endianness = LITTLE);
// Convenience functions to create a ByteBuffer from a value
static ByteBuffer wrap(uint8_t value);
static ByteBuffer wrap(uint16_t value, Endian endianness = LITTLE);
static ByteBuffer wrap(uint32_t value, Endian endianness = LITTLE);
static ByteBuffer wrap(uint64_t value, Endian endianness = LITTLE);
static ByteBuffer wrap(int8_t value) { return wrap(static_cast<uint8_t>(value)); }
static ByteBuffer wrap(int16_t value, Endian endianness = LITTLE) {
return wrap(static_cast<uint16_t>(value), endianness);
}
static ByteBuffer wrap(int32_t value, Endian endianness = LITTLE) {
return wrap(static_cast<uint32_t>(value), endianness);
}
static ByteBuffer wrap(int64_t value, Endian endianness = LITTLE) {
return wrap(static_cast<uint64_t>(value), endianness);
}
static ByteBuffer wrap(float value, Endian endianness = LITTLE);
static ByteBuffer wrap(double value, Endian endianness = LITTLE);
static ByteBuffer wrap(bool value) { return wrap(static_cast<uint8_t>(value)); }
// Get an integral value from the buffer, increment position by length
uint64_t get_uint(size_t length);
// Get one byte from the buffer, increment position by 1
uint8_t get_uint8();
// Get a 16 bit unsigned value, increment by 2
uint16_t get_uint16() { return static_cast<uint16_t>(this->get_uint(sizeof(uint16_t))); };
// Get a 24 bit unsigned value, increment by 3
uint32_t get_uint24() { return static_cast<uint32_t>(this->get_uint(3)); };
// Get a 32 bit unsigned value, increment by 4
uint32_t get_uint32() { return static_cast<uint32_t>(this->get_uint(sizeof(uint32_t))); };
// Get a 64 bit unsigned value, increment by 8
uint64_t get_uint64() { return this->get_uint(sizeof(uint64_t)); };
// Signed versions of the get functions
uint8_t get_int8() { return static_cast<int8_t>(this->get_uint8()); };
int16_t get_int16() { return static_cast<int16_t>(this->get_uint(sizeof(int16_t))); }
uint32_t get_int24();
int32_t get_int32() { return static_cast<int32_t>(this->get_uint(sizeof(int32_t))); }
int64_t get_int64() { return static_cast<int64_t>(this->get_uint(sizeof(int64_t))); }
// Get a float value, increment by 4
float get_float();
// Get a double value, increment by 8
double get_double();
// Get a bool value, increment by 1
bool get_bool() { return this->get_uint8(); }
// Get vector of bytes, increment by length
std::vector<uint8_t> get_vector(size_t length);
// Put values into the buffer, increment the position accordingly
// put any integral value, length represents the number of bytes
void put_uint(uint64_t value, size_t length);
void put_uint8(uint8_t value);
void put_uint16(uint16_t value) { this->put_uint(value, sizeof(uint16_t)); }
void put_uint24(uint32_t value) { this->put_uint(value, 3); }
void put_uint32(uint32_t value) { this->put_uint(value, sizeof(uint32_t)); }
void put_uint64(uint64_t value) { this->put_uint(value, sizeof(uint64_t)); }
// Signed versions of the put functions
void put_int8(int8_t value) { this->put_uint8(static_cast<uint8_t>(value)); }
void put_int16(int32_t value) { this->put_uint(static_cast<uint16_t>(value), sizeof(uint16_t)); }
void put_int24(int32_t value) { this->put_uint(static_cast<uint32_t>(value), 3); }
void put_int32(int32_t value) { this->put_uint(static_cast<uint32_t>(value), sizeof(uint32_t)); }
void put_int64(int64_t value) { this->put_uint(static_cast<uint64_t>(value), sizeof(uint64_t)); }
// Extra put functions
void put_float(float value);
void put_double(double value);
void put_bool(bool value) { this->put_uint8(value); }
void put_vector(const std::vector<uint8_t> &value);
inline size_t get_capacity() const { return this->data_.size(); }
inline size_t get_position() const { return this->position_; }
inline size_t get_limit() const { return this->limit_; }
inline size_t get_remaining() const { return this->get_limit() - this->get_position(); }
inline Endian get_endianness() const { return this->endianness_; }
inline void mark() { this->mark_ = this->position_; }
inline void big_endian() { this->endianness_ = BIG; }
inline void little_endian() { this->endianness_ = LITTLE; }
void set_limit(size_t limit);
void set_position(size_t position);
// set position to 0, limit to capacity.
void clear();
// set limit to current position, postition to zero. Used when swapping from write to read operations.
void flip();
// retrieve a pointer to the underlying data.
std::vector<uint8_t> get_data() { return this->data_; };
void rewind() { this->position_ = 0; }
void reset() { this->position_ = this->mark_; }
protected:
ByteBuffer(std::vector<uint8_t> const &data) : data_(data), limit_(data.size()) {}
std::vector<uint8_t> data_;
Endian endianness_{LITTLE};
size_t position_{0};
size_t mark_{0};
size_t limit_{0};
};
} // namespace esphome

View File

@ -0,0 +1,161 @@
bytebuffer:
esphome:
on_boot:
- lambda: |-
using namespace bytebuffer;
auto buf = ByteBuffer(16);
assert(buf.get_endianness() == LITTLE);
assert(buf.get_remaining() == 16);
buf.set_limit(10);
assert(buf.get_capacity() == 16);
buf.put_uint8(1);
assert(buf.get_remaining() == 9);
buf.put_uint16(0xABCD);
auto da = buf.get_data();
assert(buf.get_uint8(0) == 1);
auto x = buf.get_uint16(1);
assert(buf.get_uint16(1) == 0xABCD);
assert(buf.get_remaining() == 7);
buf.put_uint32(0x12345678UL);
assert(buf.get_uint32(3) == 0x12345678UL);
assert(buf.get_remaining() == 3);
assert(buf.get_data()[1] == 0xCD);
assert(buf.get_data()[2] == 0xAB);
assert(buf.get_data()[3] == 0x78);
assert(buf.get_data()[4] == 0x56);
assert(buf.get_data()[5] == 0x34);
assert(buf.get_data()[6] == 0x12);
buf.flip();
assert(buf.get_capacity() == 16);
assert(buf.get_uint32(3) == 0x12345678UL);
assert(buf.get_uint8(0) == 1);
assert(buf.get_uint16(1) == 0xABCD);
buf.put_uint16(0x1234, 1);
assert(buf.get_uint16(1) == 0x1234);
assert(buf.get_remaining() == 7);
assert(buf.get_uint8() == 1);
assert(buf.get_uint16() == 0x1234);
assert(buf.get_uint32() == 0x12345678ul);
assert(buf.get_remaining() == 0);
assert(buf.get_remaining() == 0);
buf.rewind();
buf.big_endian();
assert(buf.get_remaining() == 7);
assert(buf.get_uint8() == 1);
assert(buf.get_uint16() == 0x3412);
buf.mark();
assert(buf.get_uint32() == 0x78563412ul);
assert(buf.get_remaining() == 0);
buf.reset();
assert(buf.get_remaining() == 4);
assert(buf.get_uint32() == 0x78563412ul);
auto buf1 = ByteBuffer::wrap(buf.get_data().data(), buf.get_limit());
buf.clear();
assert(buf.get_position() == 0);
assert(buf.get_capacity() == 16);
assert(buf.get_limit() == 16);
assert(buf1.get_remaining() == 7);
assert(buf1.get_capacity() == 7);
buf1.set_position(3);
assert(buf1.get_uint32() == 0x12345678ul);
buf1.clear();
assert(buf1.get_limit() == 7);
assert(buf1.get_capacity() == 7);
assert(buf1.get_position() == 0);
float f = 1.2345;
buf1.put_float(f);
buf1.flip();
assert(buf1.get_remaining() == 4);
assert(buf1.get_float() == f);
buf1.clear();
buf1.put_uint16(-32760);
buf1.put_uint24(-302760);
buf1.flip();
assert(buf1.get_int16() == -32760);
assert(buf1.get_int24() == -302760);
uint8_t arr[4] = {0x10, 0x20, 0x30, 0x40};
buf1 = ByteBuffer::wrap(arr, 4);
assert(buf1.get_capacity() == 4);
assert(buf1.get_limit() == 4);
assert(buf1.get_position() == 0);
assert(buf1.get_uint32() == 0x40302010UL);
assert(buf1.get_position() == 4);
assert(buf1.get_remaining() == 0);
std::vector<uint8_t> vec{};
vec.push_back(0x10);
vec.push_back(0x20);
vec.push_back(0x30);
vec.push_back(0x40);
buf1 = ByteBuffer::wrap(vec);
assert(buf1.get_capacity() == 4);
assert(buf1.get_limit() == 4);
assert(buf1.get_position() == 0);
buf1.mark();
buf1.reset();
assert(buf1.get_uint32() == 0x40302010UL);
buf = ByteBuffer::wrap(true);
assert(buf.get_bool() == true);
buf = ByteBuffer::wrap((uint8_t)0xFE);
assert(buf.get_uint8() == 0xFE);
buf = ByteBuffer::wrap((uint16_t)0xA5A6, BIG);
assert(buf.get_remaining() == 2);
assert(buf.get_position() == 0);
assert(buf.get_capacity() == 2);
assert(buf.get_endianness() == BIG);
assert(buf.get_data()[0] == 0xA5);
assert(buf.get_uint16() == 0xA5A6);
buf.flip();
buf.little_endian();
assert(buf.get_uint16() == 0xA6A5);
buf = ByteBuffer::wrap(f, BIG);
assert(buf.get_float() == f);
double d = 1.2345678E7;
buf = ByteBuffer::wrap(d, BIG);
assert(buf.get_double() == d);
buf = ByteBuffer::wrap({1, 2, 3, 4}, BIG);
assert(buf.get_endianness() == BIG);
assert(buf.get_remaining() == 4);
assert(buf.get_data()[2] == 3);
buf.little_endian();
assert(buf.get_data()[2] == 3);
assert(buf.get_uint16() == 0x0201);
buf.big_endian();
assert(buf.get_uint16() == 0x0304);
buf.rewind();
vec = buf.get_vector(3);
assert(buf.get_remaining() == 1);
assert(vec[0] == 1);
assert(vec.size() == 3);
buf = ByteBuffer(10);
buf.put_vector(vec);
assert(buf.get_remaining() == 7);
buf.flip();
assert(buf.get_remaining() == 3);
assert(buf.get_uint24() == 0x030201);
buf = ByteBuffer(64);
buf.put_uint8(1, 1);
buf.put_uint16(16, 2);
buf.put_uint32(1232, 4);
buf.put_uint64(123432ul, 8);
buf.put_float(1.2f, 16);
buf.put_int24(0x678, 20);
assert(buf.get_uint8(1) == 1);
assert(buf.get<uint8_t>(1) == 1);
assert(buf.get_uint16(2) == 16);
assert(buf.get<uint16_t>(2) == 16);
assert(buf.get_uint32(4) == 1232);
assert(buf.get<uint32_t>(4) == 1232);
assert(buf.get_uint64(8) == 123432ul);
assert(buf.get<uint64_t>(8) == 123432ul);
assert(buf.get_float(16) == 1.2f);
assert(buf.get<float>(16) == 1.2f);
assert(buf.get_int24(20) == 0x678);
buf.clear();
buf.put(1.234, 10);
double dx = buf.get<double>(10);
assert(dx == 1.234);
buf.put((uint16_t)1, 10);
assert(buf.get_uint16(10) == 1);
ESP_LOGD("bytebuffer", "******************** All tests succeeded");

View File

@ -0,0 +1 @@
!include common.yaml

View File

@ -0,0 +1 @@
!include common.yaml

View File

@ -0,0 +1 @@
!include common.yaml

View File

@ -0,0 +1 @@
!include common.yaml

View File

@ -0,0 +1 @@
!include common.yaml

View File

@ -0,0 +1 @@
!include common.yaml

View File

@ -0,0 +1 @@
!include common.yaml