esp-idf/examples/cxx/experimental/experimental_cpp_component/include/i2c_cxx.hpp
2021-09-10 13:03:03 +08:00

494 lines
17 KiB
C++

// Copyright 2020 Espressif Systems (Shanghai) PTE LTD
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#pragma once
#ifndef __cpp_exceptions
#error I2C class can only be used when __cpp_exceptions is enabled. Enable CONFIG_COMPILER_CXX_EXCEPTIONS in Kconfig
#endif
#include <exception>
#include <memory>
#include <chrono>
#include <vector>
#include <list>
#include <future>
#include "driver/i2c.h"
#include "esp_exception.hpp"
namespace idf {
struct I2CException : public ESPException {
I2CException(esp_err_t error);
};
struct I2CTransferException : public I2CException {
I2CTransferException(esp_err_t error);
};
/**
* Superclass for all transfer objects which are accepted by \c I2CMaster::transfer().
*/
template<typename TReturn>
class I2CTransfer {
protected:
/**
* Wrapper around i2c_cmd_handle_t, makes it exception-safe.
*/
struct I2CCommandLink {
I2CCommandLink();
~I2CCommandLink();
i2c_cmd_handle_t handle;
};
public:
/**
* Helper typedef to facilitate type resolution during calls to I2CMaster::transfer().
*/
typedef TReturn TransferReturnT;
/**
* @param driver_timeout The timeout used for calls like i2c_master_cmd_begin() to the underlying driver.
*/
I2CTransfer(std::chrono::milliseconds driver_timeout = std::chrono::milliseconds(1000));
virtual ~I2CTransfer() { }
/**
* Do all general parts of the I2C transfer:
* - initialize the command link
* - issuing a start to the command link queue
* - calling \c queue_cmd() in the subclass to issue specific commands to the command link queue
* - issuing a stop to the command link queue
* - executing the assembled commands on the I2C bus
* - calling \c process_result() to process the results of the commands or calling process_exception() if
* there was an exception
* - deleting the command link
* This method is normally called by I2CMaster, but can also be used stand-alone if the bus corresponding to
* \c i2c_num has be initialized.
*
* @throws I2CException for any particular I2C error
*/
TReturn do_transfer(i2c_port_t i2c_num, uint8_t i2c_addr);
protected:
/**
* Implementation of the I2C command is implemented by subclasses.
* The I2C command handle is initialized already at this stage.
* The first action is issuing the I2C address and the read/write bit, depending on what the subclass implements.
* On error, this method has to throw an instance of I2CException.
*
* @param handle the initialized command handle of the I2C driver.
* @param i2c_addr The slave's I2C address.
*
* @throw I2CException
*/
virtual void queue_cmd(i2c_cmd_handle_t handle, uint8_t i2c_addr) = 0;
/**
* Implementation of whatever neccessary action after successfully sending the I2C command.
* On error, this method has to throw an instance of I2CException.
*
* @throw I2CException
*/
virtual TReturn process_result() = 0;
/**
* For some calls to the underlying driver (e.g. \c i2c_master_cmd_begin() ), this general timeout will be passed.
*/
const TickType_t driver_timeout;
};
/**
* @brief Super class for any I2C master or slave
*/
class I2CBus {
public:
/*
* @brief Initialize I2C master bus.
*
* Initialize and install the bus driver in master mode.
*
* @param i2c_number The I2C port number.
*/
I2CBus(i2c_port_t i2c_number);
/**
* @brief uninstall the bus driver.
*/
virtual ~I2CBus();
/**
* The I2C port number.
*/
const i2c_port_t i2c_num;
};
/**
* @brief Simple I2C Master object
*
* This class provides to ways to issue I2C read and write requests. The simplest way is to use \c sync_write() and
* sync_read() to write and read, respectively. As the name suggests, they block during the whole transfer.
* For all asynchrounous transfers as well as combined write-read transfers, use \c transfer().
*/
class I2CMaster : public I2CBus {
public:
/**
* Initialize and install the driver of an I2C master peripheral.
*
* Initialize and install the bus driver in master mode. Pullups will be enabled for both pins. If you want a
* different configuration, use configure() and i2c_set_pin() of the underlying driver to disable one or both
* pullups.
*
* @param i2c_number The number of the I2C device.
* @param scl_gpio GPIO number of the SCL line.
* @param sda_gpio GPIO number of the SDA line.
* @param clock_speed The master clock speed.
* @param scl_pullup Enable SCL pullup.
* @param sda_pullup Enable SDA pullup.
*
* @throws I2CException with the corrsponding esp_err_t return value if something goes wrong
*/
I2CMaster(i2c_port_t i2c_number,
int scl_gpio,
int sda_gpio,
uint32_t clock_speed,
bool scl_pullup = true,
bool sda_pullup = true);
/**
* Delete the driver.
*/
virtual ~I2CMaster();
/**
* Issue an asynchronous I2C transfer which is executed in the background.
*
* This method uses a C++ \c std::future as mechanism to wait for the asynchronous return value.
* The return value can be accessed with \c future::get(). \c future::get() also synchronizes with the thread
* doing the work in the background, i.e. it waits until the return value has been issued.
*
* The actual implementation is delegated to the TransferT object. It will be given the I2C number to work
* with.
*
* Requirements for TransferT: It should implement or imitate the interface of I2CTransfer.
*
* @param xfer The transfer to execute. What the transfer does, depends on it's implementation in
* \c TransferT::do_transfer(). It also determines the future template of this function, indicated by
* \c TransferT::TransferReturnT.
*
* @param i2c_addr The address of the I2C slave device targeted by the transfer.
*
* @return A future with \c TransferT::TransferReturnT. It depends on which template type is used for xfer.
* In case of a simple write (I2CWrite), it's future<void>.
* In case of a read (I2CRead), it's future<vector<uint8_t> > corresponding to the length of the read
* operation.
* If TransferT is a combined transfer with repeated reads (I2CComposed), then the return type is
* future<vector<vector<uint8_t> > >, a vector of results corresponding to the queued read operations.
*
* @throws I2CException with the corrsponding esp_err_t return value if something goes wrong
* @throws std::exception for failures in libstdc++
*/
template<typename TransferT>
std::future<typename TransferT::TransferReturnT> transfer(std::shared_ptr<TransferT> xfer, uint8_t i2c_addr);
/**
* Do a synchronous write.
*
* All data in data will be written to the I2C device with i2c_addr at once.
* This method will block until the I2C write is complete.
*
* @param i2c_addr The address of the I2C device to which the data shall be sent.
* @param data The data to send (size to be sent is determined by data.size()).
*
* @throws I2CException with the corrsponding esp_err_t return value if something goes wrong
* @throws std::exception for failures in libstdc++
*/
void sync_write(uint8_t i2c_addr, const std::vector<uint8_t> &data);
/**
* Do a synchronous read.
* This method will block until the I2C read is complete.
*
* n_bytes bytes of data will be read from the I2C device with i2c_addr.
* While reading the last byte, the master finishes the reading by sending a NACK, before issuing a stop.
*
* @param i2c_addr The address of the I2C device from which to read.
* @param n_bytes The number of bytes to read.
*
* @return the read bytes
*
* @throws I2CException with the corrsponding esp_err_t return value if something goes wrong
* @throws std::exception for failures in libstdc++
*/
std::vector<uint8_t> sync_read(uint8_t i2c_addr, size_t n_bytes);
/**
* Do a simple asynchronous write-read transfer.
*
* First, \c write_data will be written to the bus, then a number of \c read_n_bytes will be read from the bus
* with a repeated start condition. The slave device is determined by \c i2c_addr.
* While reading the last byte, the master finishes the reading by sending a NACK, before issuing a stop.
* This method will block until the I2C transfer is complete.
*
* @param i2c_addr The address of the I2C device from which to read.
* @param write_data The data to write to the bus before reading.
* @param read_n_bytes The number of bytes to read.
*
* @return the read bytes
*
* @throws I2CException with the corrsponding esp_err_t return value if something goes wrong
* @throws std::exception for failures in libstdc++
*/
std::vector<uint8_t> sync_transfer(uint8_t i2c_addr,
const std::vector<uint8_t> &write_data,
size_t read_n_bytes);
};
/**
* @brief Responsible for initialization and de-initialization of an I2C slave peripheral.
*/
class I2CSlave : public I2CBus {
public:
/**
* Initialize and install the driver of an I2C slave peripheral.
*
* Initialize and install the bus driver in slave mode. Pullups will be enabled for both pins. If you want a
* different configuration, use configure() and i2c_set_pin() of the underlying driver to disable one or both
* pullups.
*
* @param i2c_number The number of the I2C device.
* @param scl_gpio GPIO number of the SCL line.
* @param sda_gpio GPIO number of the SDA line.
* @param slave_addr The address of the slave device on the I2C bus.
* @param rx_buf_len Receive buffer length.
* @param tx_buf_len Transmit buffer length.
* @param scl_pullup Enable SCL pullup.
* @param sda_pullup Enable SDA pullup.
*
* @throws
*/
I2CSlave(i2c_port_t i2c_number,
int scl_gpio,
int sda_gpio,
uint8_t slave_addr,
size_t rx_buf_len,
size_t tx_buf_len,
bool scl_pullup = true,
bool sda_pullup = true);
/**
* Delete the driver.
*/
virtual ~I2CSlave();
/**
* Schedule a raw data write once master is ready.
*
* The data is saved in a buffer, waiting for the master to pick it up.
*/
virtual int write_raw(const uint8_t* data, size_t data_len, std::chrono::milliseconds timeout);
/**
* Read raw data from the bus.
*
* The data is read directly from the buffer. Hence, it has to be written already by master.
*/
virtual int read_raw(uint8_t* buffer, size_t buffer_len, std::chrono::milliseconds timeout);
};
/**
* Implementation for simple I2C writes, which can be executed by \c I2CMaster::transfer().
* It stores the bytes to be written as a vector.
*/
class I2CWrite : public I2CTransfer<void> {
public:
/**
* @param bytes The bytes which should be written.
* @param driver_timeout The timeout used for calls like i2c_master_cmd_begin() to the underlying driver.
*/
I2CWrite(const std::vector<uint8_t> &bytes, std::chrono::milliseconds driver_timeout = std::chrono::milliseconds(1000));
protected:
/**
* Write the address and set the read bit to 0 to issue the address and request a write.
* Then write the bytes.
*
* @param handle The initialized I2C command handle.
* @param i2c_addr The I2C address of the slave.
*/
void queue_cmd(i2c_cmd_handle_t handle, uint8_t i2c_addr) override;
/**
* Set the value of the promise to unblock any callers waiting on it.
*/
void process_result() override;
private:
/**
* The bytes to write.
*/
std::vector<uint8_t> bytes;
};
/**
* Implementation for simple I2C reads, which can be executed by \c I2CMaster::transfer().
* It stores the bytes to be read as a vector to be returned later via a future.
*/
class I2CRead : public I2CTransfer<std::vector<uint8_t> > {
public:
/**
* @param The number of bytes to read.
* @param driver_timeout The timeout used for calls like i2c_master_cmd_begin() to the underlying driver.
*/
I2CRead(size_t size, std::chrono::milliseconds driver_timeout = std::chrono::milliseconds(1000));
protected:
/**
* Write the address and set the read bit to 1 to issue the address and request a read.
* Then read into bytes.
*
* @param handle The initialized I2C command handle.
* @param i2c_addr The I2C address of the slave.
*/
void queue_cmd(i2c_cmd_handle_t handle, uint8_t i2c_addr) override;
/**
* Set the return value of the promise to unblock any callers waiting on it.
*/
std::vector<uint8_t> process_result() override;
private:
/**
* The bytes to read.
*/
std::vector<uint8_t> bytes;
};
/**
* This kind of transfer uses repeated start conditions to chain transfers coherently.
* In particular, this can be used to chain multiple single write and read transfers into a single transfer with
* repeated starts as it is commonly done for I2C devices.
* The result is a vector of vectors representing the reads in the order of how they were added using add_read().
*/
class I2CComposed : public I2CTransfer<std::vector<std::vector<uint8_t> > > {
public:
I2CComposed(std::chrono::milliseconds driver_timeout = std::chrono::milliseconds(1000));
/**
* Add a read to the chain.
*
* @param size The size of the read in bytes.
*/
void add_read(size_t size);
/**
* Add a write to the chain.
*
* @param bytes The bytes to write; size will be bytes.size()
*/
void add_write(std::vector<uint8_t> bytes);
protected:
/**
* Write all chained transfers, including a repeated start issue after each but the last transfer.
*
* @param handle The initialized I2C command handle.
* @param i2c_addr The I2C address of the slave.
*/
void queue_cmd(i2c_cmd_handle_t handle, uint8_t i2c_addr) override;
/**
* Creates the vector with the vectors from all reads.
*/
std::vector<std::vector<uint8_t> > process_result() override;
private:
class CompTransferNode {
public:
virtual void queue_cmd(i2c_cmd_handle_t handle, uint8_t i2c_addr) = 0;
virtual void process_result(std::vector<std::vector<uint8_t> > &read_results) { }
};
class CompTransferNodeRead : public CompTransferNode {
public:
CompTransferNodeRead(size_t size) : bytes(size) { }
void queue_cmd(i2c_cmd_handle_t handle, uint8_t i2c_addr) override;
void process_result(std::vector<std::vector<uint8_t> > &read_results) override;
private:
std::vector<uint8_t> bytes;
};
class CompTransferNodeWrite : public CompTransferNode {
public:
CompTransferNodeWrite(std::vector<uint8_t> bytes) : bytes(bytes) { }
void queue_cmd(i2c_cmd_handle_t handle, uint8_t i2c_addr) override;
private:
std::vector<uint8_t> bytes;
};
/**
* The chained transfers.
*/
std::list<std::shared_ptr<CompTransferNode> > transfer_list;
};
template<typename TReturn>
I2CTransfer<TReturn>::I2CTransfer(std::chrono::milliseconds driver_timeout)
: driver_timeout(driver_timeout.count()) { }
template<typename TReturn>
I2CTransfer<TReturn>::I2CCommandLink::I2CCommandLink()
{
handle = i2c_cmd_link_create();
if (!handle) {
throw I2CException(ESP_ERR_NO_MEM);
}
}
template<typename TReturn>
I2CTransfer<TReturn>::I2CCommandLink::~I2CCommandLink()
{
i2c_cmd_link_delete(handle);
}
template<typename TReturn>
TReturn I2CTransfer<TReturn>::do_transfer(i2c_port_t i2c_num, uint8_t i2c_addr)
{
I2CCommandLink cmd_link;
queue_cmd(cmd_link.handle, i2c_addr);
CHECK_THROW_SPECIFIC(i2c_master_stop(cmd_link.handle), I2CException);
CHECK_THROW_SPECIFIC(i2c_master_cmd_begin(i2c_num, cmd_link.handle, driver_timeout / portTICK_RATE_MS), I2CTransferException);
return process_result();
}
template<typename TransferT>
std::future<typename TransferT::TransferReturnT> I2CMaster::transfer(std::shared_ptr<TransferT> xfer, uint8_t i2c_addr)
{
if (!xfer) throw I2CException(ESP_ERR_INVALID_ARG);
return std::async(std::launch::async, [this](std::shared_ptr<TransferT> xfer, uint8_t i2c_addr) {
return xfer->do_transfer(i2c_num, i2c_addr);
}, xfer, i2c_addr);
}
} // idf