esp-idf/components/soc/include/hal/spi_hal.h

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// Copyright 2015-2019 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.
/*******************************************************************************
* NOTICE
* The hal is not public api, don't use in application code.
* See readme.md in soc/include/hal/readme.md
******************************************************************************/
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// The HAL layer for SPI master (common part)
// SPI HAL usages:
// 1. initialize the bus
// 2. initialize the DMA descriptors if DMA used
// 3. setup the clock speed (since this takes long time)
// 4. call setup_device to update parameters for the specific device
// 5. call setup_trans to update parameters for the specific transaction
// 6. prepare data to send, and prepare the receiving buffer
// 7. trigger user defined SPI transaction to start
// 8. wait until the user transaction is done
// 9. fetch the received data
// Parameter to be updated only during ``setup_device`` will be highlighted in the
// field comments.
#pragma once
#include "hal/spi_ll.h"
#include <esp_err.h>
#include "soc/lldesc.h"
#include "soc/spi_caps.h"
/**
* Timing configuration structure that should be calculated by
* ``spi_hal_setup_clock`` at initialization and hold. Filled into the
* ``timing_conf`` member of the context of HAL before setup a device.
*/
typedef struct {
spi_ll_clock_val_t clock_reg; ///< Register value used by the LL layer
int timing_dummy; ///< Extra dummy needed to compensate the timing
int timing_miso_delay; ///< Extra miso delay clocks to compensate the timing
} spi_hal_timing_conf_t;
/**
* Context that should be maintained by both the driver and the HAL.
*/
typedef struct {
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/* configured by driver at initialization, don't touch */
spi_dev_t *hw; ///< Beginning address of the peripheral registers.
/* should be configured by driver at initialization */
lldesc_t *dmadesc_tx; /**< Array of DMA descriptor used by the TX DMA.
* The amount should be larger than dmadesc_n. The driver should ensure that
* the data to be sent is shorter than the descriptors can hold.
*/
lldesc_t *dmadesc_rx; /**< Array of DMA descriptor used by the RX DMA.
* The amount should be larger than dmadesc_n. The driver should ensure that
* the data to be sent is shorter than the descriptors can hold.
*/
int dmadesc_n; ///< The amount of descriptors of both ``dmadesc_tx`` and ``dmadesc_rx`` that the HAL can use.
/*
* Device specific, all these parameters will be updated to the peripheral
* only when ``spi_hal_setup_device``. They may not get updated when
* ``spi_hal_setup_trans``.
*/
int mode; ///< SPI mode, device specific
int cs_setup; ///< Setup time of CS active edge before the first SPI clock, device specific
int cs_hold; ///< Hold time of CS inactive edge after the last SPI clock, device specific
int cs_pin_id; ///< CS pin to use, 0-2, otherwise all the CS pins are not used. Device specific
spi_hal_timing_conf_t *timing_conf; /**< Pointer to an structure holding
* the pre-calculated timing configuration for the device at initialization,
* device specific
*/
struct {
uint32_t sio : 1; ///< Whether to use SIO mode, device specific
uint32_t half_duplex : 1; ///< Whether half duplex mode is used, device specific
uint32_t tx_lsbfirst : 1; ///< Whether LSB is sent first for TX data, device specific
uint32_t rx_lsbfirst : 1; ///< Whether LSB is received first for RX data, device specific
uint32_t dma_enabled : 1; ///< Whether the DMA is enabled, do not update after initialization
uint32_t no_compensate : 1; ///< No need to add dummy to compensate the timing, device specific
#ifdef SOC_SPI_SUPPORT_AS_CS
uint32_t as_cs : 1; ///< Whether to toggle the CS while the clock toggles, device specific
#endif
uint32_t positive_cs : 1; ///< Whether the postive CS feature is abled, device specific
};//boolean configurations
/*
* Transaction specific (data), all these parameters will be updated to the
* peripheral every transaction.
*/
uint16_t cmd; ///< Command value to be sent
int cmd_bits; ///< Length (in bits) of the command phase
int addr_bits; ///< Length (in bits) of the address phase
int dummy_bits; ///< Base length (in bits) of the dummy phase. Note when the compensation is enabled, some extra dummy bits may be appended.
int tx_bitlen; ///< TX length, in bits
int rx_bitlen; ///< RX length, in bits
uint64_t addr; ///< Address value to be sent
uint8_t *send_buffer; ///< Data to be sent
uint8_t *rcv_buffer; ///< Buffer to hold the receive data.
spi_ll_io_mode_t io_mode; ///< IO mode of the master
} spi_hal_context_t;
/**
* Init the peripheral and the context.
*
* @param hal Context of the HAL layer.
* @param host_id Index of the SPI peripheral. 0 for SPI1, 1 for HSPI (SPI2) and 2 for VSPI (SPI3).
*/
void spi_hal_init(spi_hal_context_t *hal, int host_id);
/**
* Deinit the peripheral (and the context if needed).
*
* @param hal Context of the HAL layer.
*/
void spi_hal_deinit(spi_hal_context_t *hal);
/**
* Setup device-related configurations according to the settings in the context.
*
* @param hal Context of the HAL layer.
*/
void spi_hal_setup_device(const spi_hal_context_t *hal);
/**
* Setup transaction related configurations according to the settings in the context.
*
* @param hal Context of the HAL layer.
*/
void spi_hal_setup_trans(const spi_hal_context_t *hal);
/**
* Prepare the data for the current transaction.
*
* @param hal Context of the HAL layer.
*/
void spi_hal_prepare_data(const spi_hal_context_t *hal);
/**
* Trigger start a user-defined transaction.
*
* @param hal Context of the HAL layer.
*/
void spi_hal_user_start(const spi_hal_context_t *hal);
/**
* Check whether the transaction is done (trans_done is set).
*
* @param hal Context of the HAL layer.
*/
bool spi_hal_usr_is_done(const spi_hal_context_t *hal);
/**
* Post transaction operations, mainly fetch data from the buffer.
*
* @param hal Context of the HAL layer.
*/
void spi_hal_fetch_result(const spi_hal_context_t *hal);
/*----------------------------------------------------------
* Utils
* ---------------------------------------------------------*/
/**
* Get the configuration of clock and timing. The configuration will be used when ``spi_hal_setup_device``.
*
* It is highly suggested to do this at initialization, since it takes long time.
*
* @param hal Context of the HAL layer.
* @param speed_hz Desired frequency.
* @param duty_cycle Desired duty cycle of SPI clock
* @param use_gpio true if the GPIO matrix is used, otherwise false
* @param input_delay_ns Maximum delay between SPI launch clock and the data to
* be valid. This is used to compensate/calculate the maximum frequency
* allowed. Left 0 if not known.
* @param out_freq Output of the actual frequency, left NULL if not required.
* @param timing_conf Output of the timing configuration.
*
* @return ESP_OK if desired is available, otherwise fail.
*/
esp_err_t spi_hal_get_clock_conf(const spi_hal_context_t *hal, int speed_hz, int duty_cycle, bool use_gpio, int input_delay_ns, int *out_freq, spi_hal_timing_conf_t *timing_conf);
/**
* Get the frequency actual used.
*
* @param hal Context of the HAL layer.
* @param fapb APB clock frequency.
* @param hz Desired frequencyc.
* @param duty_cycle Desired duty cycle.
*/
int spi_hal_master_cal_clock(int fapb, int hz, int duty_cycle);
/**
* Get the timing configuration for given parameters.
*
* @param eff_clk Actual SPI clock frequency
* @param gpio_is_used true if the GPIO matrix is used, otherwise false.
* @param input_delay_ns Maximum delay between SPI launch clock and the data to
* be valid. This is used to compensate/calculate the maximum frequency
* allowed. Left 0 if not known.
* @param dummy_n Dummy cycles required to correctly read the data.
* @param miso_delay_n suggested delay on the MISO line, in APB clocks.
*/
void spi_hal_cal_timing(int eff_clk, bool gpio_is_used, int input_delay_ns, int *dummy_n, int *miso_delay_n);
/**
* Get the maximum frequency allowed to read if no compensation is used.
*
* @param gpio_is_used true if the GPIO matrix is used, otherwise false.
* @param input_delay_ns Maximum delay between SPI launch clock and the data to
* be valid. This is used to compensate/calculate the maximum frequency
* allowed. Left 0 if not known.
*/
int spi_hal_get_freq_limit(bool gpio_is_used, int input_delay_ns);