/* * SPDX-FileCopyrightText: 2022-2023 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ /******************************************************************************* * NOTICE * The ll is not public api, don't use in application code. * See readme.md in soc/include/hal/readme.md ******************************************************************************/ // The Lowlevel layer for SPI Flash #pragma once #include #include // For MIN/MAX #include #include #include "soc/spi_periph.h" #include "soc/spi_mem_struct.h" #include "hal/assert.h" #include "hal/spi_types.h" #include "hal/spi_flash_types.h" #ifdef __cplusplus extern "C" { #endif //TODO: IDF-7499 #define spimem_flash_ll_get_hw(host_id) (((host_id)==SPI1_HOST ? &SPIMEM1 : NULL )) #define spimem_flash_ll_hw_get_id(dev) ((dev) == (void*)&SPIMEM1? SPI1_HOST: -1) #define SPIMEM_FLASH_LL_SPI0_MAX_LOCK_VAL_MSPI_TICKS (0x1f) typedef typeof(SPIMEM1.clock.val) spimem_flash_ll_clock_reg_t; /*------------------------------------------------------------------------------ * Control *----------------------------------------------------------------------------*/ /** * Reset peripheral registers before configuration and starting control * * @param dev Beginning address of the peripheral registers. */ static inline void spimem_flash_ll_reset(spi_mem_dev_t *dev) { dev->user.val = 0; dev->ctrl.val = 0; } /** * Check whether the previous operation is done. * * @param dev Beginning address of the peripheral registers. * * @return true if last command is done, otherwise false. */ static inline bool spimem_flash_ll_cmd_is_done(const spi_mem_dev_t *dev) { return (dev->cmd.val == 0); } /** * Erase the flash chip. * * @param dev Beginning address of the peripheral registers. */ static inline void spimem_flash_ll_erase_chip(spi_mem_dev_t *dev) { dev->cmd.flash_ce = 1; } /** * Erase the sector, the address should be set by spimem_flash_ll_set_address. * * @param dev Beginning address of the peripheral registers. */ static inline void spimem_flash_ll_erase_sector(spi_mem_dev_t *dev) { dev->ctrl.val = 0; dev->cmd.flash_se = 1; } /** * Erase the block, the address should be set by spimem_flash_ll_set_address. * * @param dev Beginning address of the peripheral registers. */ static inline void spimem_flash_ll_erase_block(spi_mem_dev_t *dev) { dev->cmd.flash_be = 1; } /** * Suspend erase/program operation. * * @param dev Beginning address of the peripheral registers. */ static inline void spimem_flash_ll_suspend(spi_mem_dev_t *dev) { dev->flash_sus_ctrl.flash_pes = 1; } /** * Resume suspended erase/program operation. * * @param dev Beginning address of the peripheral registers. */ static inline void spimem_flash_ll_resume(spi_mem_dev_t *dev) { dev->flash_sus_ctrl.flash_per = 1; } /** * Initialize auto suspend mode, and esp32c3 doesn't support disable auto-suspend. * * @param dev Beginning address of the peripheral registers. * @param auto_sus Enable/disable Flash Auto-Suspend. */ static inline void spimem_flash_ll_auto_suspend_init(spi_mem_dev_t *dev, bool auto_sus) { dev->flash_sus_ctrl.flash_pes_en = auto_sus; } /** * Initialize auto resume mode * * @param dev Beginning address of the peripheral registers. * @param auto_res Enable/Disable Flash Auto-Resume. * */ static inline void spimem_flash_ll_auto_resume_init(spi_mem_dev_t *dev, bool auto_res) { dev->flash_sus_ctrl.pes_per_en = auto_res; } /** * Setup the flash suspend command, may vary from chips to chips. * * @param dev Beginning address of the peripheral registers. * @param sus_cmd Flash suspend command. * */ static inline void spimem_flash_ll_suspend_cmd_setup(spi_mem_dev_t *dev, uint32_t sus_cmd) { HAL_FORCE_MODIFY_U32_REG_FIELD(dev->flash_sus_cmd, flash_pes_command, sus_cmd); } /** * Setup the flash resume command, may vary from chips to chips. * * @param dev Beginning address of the peripheral registers. * @param res_cmd Flash resume command. * */ static inline void spimem_flash_ll_resume_cmd_setup(spi_mem_dev_t *dev, uint32_t res_cmd) { HAL_FORCE_MODIFY_U32_REG_FIELD(dev->sus_status, flash_per_command, res_cmd); } /** * Setup the flash read suspend status command, may vary from chips to chips. * * @param dev Beginning address of the peripheral registers. * @param pesr_cmd Flash read suspend status command. * */ static inline void spimem_flash_ll_rd_sus_cmd_setup(spi_mem_dev_t *dev, uint32_t pesr_cmd) { HAL_FORCE_MODIFY_U32_REG_FIELD(dev->flash_sus_cmd, wait_pesr_command, pesr_cmd); } /** * Setup to check SUS/SUS1/SUS2 to ensure the suspend status of flashs. * * @param dev Beginning address of the peripheral registers. * @param sus_check_sus_en 1: enable, 0: disable. * */ static inline void spimem_flash_ll_sus_check_sus_setup(spi_mem_dev_t *dev, bool sus_check_sus_en) { dev->flash_sus_ctrl.sus_timeout_cnt = 5; dev->flash_sus_ctrl.pes_end_en = sus_check_sus_en; } /** * Setup to check SUS/SUS1/SUS2 to ensure the resume status of flashs. * * @param dev Beginning address of the peripheral registers. * @param sus_check_sus_en 1: enable, 0: disable. * */ static inline void spimem_flash_ll_res_check_sus_setup(spi_mem_dev_t *dev, bool res_check_sus_en) { dev->flash_sus_ctrl.sus_timeout_cnt = 5; dev->flash_sus_ctrl.per_end_en = res_check_sus_en; } /** * Set 8 bit command to read suspend status * * @param dev Beginning address of the peripheral registers. */ static inline void spimem_flash_ll_set_read_sus_status(spi_mem_dev_t *dev, uint32_t sus_conf) { dev->flash_sus_ctrl.frd_sus_2b = 0; HAL_FORCE_MODIFY_U32_REG_FIELD(dev->flash_sus_ctrl, pesr_end_msk, sus_conf); } /** * Configure the delay after Suspend/Resume * * @param dev Beginning address of the peripheral registers. * @param dly_val delay time */ static inline void spimem_flash_ll_set_sus_delay(spi_mem_dev_t *dev, uint32_t dly_val) { // dev->ctrl1.cs_hold_dly_res = dly_val; // dev->sus_status.pes_dly_128 = 1; // dev->sus_status.per_dly_128 = 1; abort(); } /** * Configure the cs hold delay time(used to set the minimum CS high time tSHSL) * * @param dev Beginning address of the peripheral registers. * @param cs_hold_delay cs hold delay time */ static inline void spimem_flash_set_cs_hold_delay(spi_mem_dev_t *dev, uint32_t cs_hold_delay) { // SPIMEM0.ctrl2.cs_hold_delay = cs_hold_delay; abort(); } /** * Initialize auto wait idle mode * * @param dev Beginning address of the peripheral registers. * @param auto_waiti Enable/disable auto wait-idle function */ static inline void spimem_flash_ll_auto_wait_idle_init(spi_mem_dev_t *dev, bool auto_waiti) { HAL_FORCE_MODIFY_U32_REG_FIELD(dev->flash_waiti_ctrl, waiti_cmd, 0x05); dev->flash_sus_ctrl.flash_per_wait_en = auto_waiti; dev->flash_sus_ctrl.flash_pes_wait_en = auto_waiti; } /** * Return the suspend status of erase or program operations. * * @param dev Beginning address of the peripheral registers. * * @return true if suspended, otherwise false. */ static inline bool spimem_flash_ll_sus_status(spi_mem_dev_t *dev) { return dev->sus_status.flash_sus; } /** * @brief Set lock for SPI0 so that spi0 can request new cache request after a cache transfer. * * @param dev Beginning address of the peripheral registers. * @param lock_time Lock delay time */ static inline void spimem_flash_ll_sus_set_spi0_lock_trans(spi_mem_dev_t *dev, uint32_t lock_time) { // dev->sus_status.spi0_lock_en = 1; // SPIMEM0.fsm.cspi_lock_delay_time = lock_time; abort(); } /** * @brief Get tsus unit values in SPI_CLK cycles * * @param dev Beginning address of the peripheral registers. * @return uint32_t tsus unit values */ static inline uint32_t spimem_flash_ll_get_tsus_unit_in_cycles(spi_mem_dev_t *dev) { // uint32_t tsus_unit = 0; // if (dev->sus_status.pes_dly_128 == 1) { // tsus_unit = 128; // } else { // tsus_unit = 4; // } // return tsus_unit; abort(); } /** * Enable/disable write protection for the flash chip. * * @param dev Beginning address of the peripheral registers. * @param wp true to enable the protection, false to disable (write enable). */ static inline void spimem_flash_ll_set_write_protect(spi_mem_dev_t *dev, bool wp) { if (wp) { dev->cmd.flash_wrdi = 1; } else { dev->cmd.flash_wren = 1; } } /** * Get the read data from the buffer after ``spimem_flash_ll_read`` is done. * * @param dev Beginning address of the peripheral registers. * @param buffer Buffer to hold the output data * @param read_len Length to get out of the buffer */ static inline void spimem_flash_ll_get_buffer_data(spi_mem_dev_t *dev, void *buffer, uint32_t read_len) { if (((intptr_t)buffer % 4 == 0) && (read_len % 4 == 0)) { // If everything is word-aligned, do a faster memcpy memcpy(buffer, (void *)dev->data_buf, read_len); } else { // Otherwise, slow(er) path copies word by word int copy_len = read_len; for (int i = 0; i < (read_len + 3) / 4; i++) { int word_len = MIN(sizeof(uint32_t), copy_len); uint32_t word = dev->data_buf[i]; memcpy(buffer, &word, word_len); buffer = (void *)((intptr_t)buffer + word_len); copy_len -= word_len; } } } /** * Set the data to be written in the data buffer. * * @param dev Beginning address of the peripheral registers. * @param buffer Buffer holding the data * @param length Length of data in bytes. */ static inline void spimem_flash_ll_set_buffer_data(spi_mem_dev_t *dev, const void *buffer, uint32_t length) { // Load data registers, word at a time int num_words = (length + 3) / 4; for (int i = 0; i < num_words; i++) { uint32_t word = 0; uint32_t word_len = MIN(length, sizeof(word)); memcpy(&word, buffer, word_len); dev->data_buf[i] = word; length -= word_len; buffer = (void *)((intptr_t)buffer + word_len); } } /** * Program a page of the flash chip. Call ``spimem_flash_ll_set_address`` before * this to set the address to program. * * @param dev Beginning address of the peripheral registers. * @param buffer Buffer holding the data to program * @param length Length to program. */ static inline void spimem_flash_ll_program_page(spi_mem_dev_t *dev, const void *buffer, uint32_t length) { dev->user.usr_dummy = 0; spimem_flash_ll_set_buffer_data(dev, buffer, length); dev->cmd.flash_pp = 1; } /** * Trigger a user defined transaction. All phases, including command, address, dummy, and the data phases, * should be configured before this is called. * * @param dev Beginning address of the peripheral registers. */ static inline void spimem_flash_ll_user_start(spi_mem_dev_t *dev) { dev->cmd.usr = 1; } /** * In user mode, it is set to indicate that program/erase operation will be triggered. * This function is combined with `spimem_flash_ll_user_start`. The pe_bit will be cleared automatically once the operation done. * * @param dev Beginning address of the peripheral registers. */ static inline void spimem_flash_ll_set_pe_bit(spi_mem_dev_t *dev) { dev->cmd.flash_pe = 1; } /** * Check whether the host is idle to perform new commands. * * @param dev Beginning address of the peripheral registers. * * @return true if the host is idle, otherwise false */ static inline bool spimem_flash_ll_host_idle(const spi_mem_dev_t *dev) { return dev->cmd.mst_st == 0; } /** * Set phases for user-defined transaction to read * * @param dev Beginning address of the peripheral registers. */ static inline void spimem_flash_ll_read_phase(spi_mem_dev_t *dev) { typeof (dev->user) user = { .usr_command = 1, .usr_mosi = 0, .usr_miso = 1, .usr_addr = 1, }; dev->user = user; } /*------------------------------------------------------------------------------ * Configs *----------------------------------------------------------------------------*/ /** * Select which pin to use for the flash * * @param dev Beginning address of the peripheral registers. * @param pin Pin ID to use, 0-2. Set to other values to disable all the CS pins. */ static inline void spimem_flash_ll_set_cs_pin(spi_mem_dev_t *dev, int pin) { dev->misc.cs0_dis = (pin == 0) ? 0 : 1; dev->misc.cs1_dis = (pin == 1) ? 0 : 1; } /** * Set the read io mode. * * @param dev Beginning address of the peripheral registers. * @param read_mode I/O mode to use in the following transactions. */ static inline void spimem_flash_ll_set_read_mode(spi_mem_dev_t *dev, esp_flash_io_mode_t read_mode) { typeof (dev->ctrl) ctrl = dev->ctrl; ctrl.val &= ~(SPI_MEM_FREAD_QIO_M | SPI_MEM_FREAD_QUAD_M | SPI_MEM_FREAD_DIO_M | SPI_MEM_FREAD_DUAL_M); ctrl.val |= SPI_MEM_FASTRD_MODE_M; switch (read_mode) { case SPI_FLASH_FASTRD: //the default option break; case SPI_FLASH_QIO: ctrl.fread_qio = 1; break; case SPI_FLASH_QOUT: ctrl.fread_quad = 1; break; case SPI_FLASH_DIO: ctrl.fread_dio = 1; break; case SPI_FLASH_DOUT: ctrl.fread_dual = 1; break; case SPI_FLASH_SLOWRD: ctrl.fastrd_mode = 0; break; default: abort(); } dev->ctrl = ctrl; } /** * Set clock frequency to work at. * * @param dev Beginning address of the peripheral registers. * @param clock_val pointer to the clock value to set */ static inline void spimem_flash_ll_set_clock(spi_mem_dev_t *dev, spimem_flash_ll_clock_reg_t *clock_val) { dev->clock.val = *clock_val; } /** * Set the input length, in bits. * * @param dev Beginning address of the peripheral registers. * @param bitlen Length of input, in bits. */ static inline void spimem_flash_ll_set_miso_bitlen(spi_mem_dev_t *dev, uint32_t bitlen) { dev->user.usr_miso = bitlen > 0; dev->miso_dlen.usr_miso_bit_len = bitlen ? (bitlen - 1) : 0; } /** * Set the output length, in bits (not including command, address and dummy * phases) * * @param dev Beginning address of the peripheral registers. * @param bitlen Length of output, in bits. */ static inline void spimem_flash_ll_set_mosi_bitlen(spi_mem_dev_t *dev, uint32_t bitlen) { dev->user.usr_mosi = bitlen > 0; dev->mosi_dlen.usr_mosi_bit_len = bitlen ? (bitlen - 1) : 0; } /** * Set the command. * * @param dev Beginning address of the peripheral registers. * @param command Command to send * @param bitlen Length of the command */ static inline void spimem_flash_ll_set_command(spi_mem_dev_t *dev, uint32_t command, uint32_t bitlen) { dev->user.usr_command = 1; typeof(dev->user2) user2 = { .usr_command_value = command, .usr_command_bitlen = (bitlen - 1), }; dev->user2 = user2; } /** * Get the address length that is set in register, in bits. * * @param dev Beginning address of the peripheral registers. * */ static inline int spimem_flash_ll_get_addr_bitlen(spi_mem_dev_t *dev) { return dev->user.usr_addr ? dev->user1.usr_addr_bitlen + 1 : 0; } /** * Set the address length to send, in bits. Should be called before commands that requires the address e.g. erase sector, read, write... * * @param dev Beginning address of the peripheral registers. * @param bitlen Length of the address, in bits */ static inline void spimem_flash_ll_set_addr_bitlen(spi_mem_dev_t *dev, uint32_t bitlen) { dev->user1.usr_addr_bitlen = (bitlen - 1); dev->user.usr_addr = bitlen ? 1 : 0; } /** * Set extra address for bits M0-M7 in DIO/QIO mode. * * @param dev Beginning address of the peripheral registers. * @param extra_addr extra address(M0-M7) to send. */ static inline void spimem_flash_ll_set_extra_address(spi_mem_dev_t *dev, uint32_t extra_addr) { dev->cache_fctrl.usr_addr_4byte = 0; dev->rd_status.wb_mode = extra_addr; } /** * Set the address to send. Should be called before commands that requires the address e.g. erase sector, read, write... * * @param dev Beginning address of the peripheral registers. * @param addr Address to send */ static inline void spimem_flash_ll_set_address(spi_mem_dev_t *dev, uint32_t addr) { dev->addr = addr; } /** * Set the address to send in user mode. Should be called before commands that requires the address e.g. erase sector, read, write... * * @param dev Beginning address of the peripheral registers. * @param addr Address to send */ static inline void spimem_flash_ll_set_usr_address(spi_mem_dev_t *dev, uint32_t addr, uint32_t bitlen) { (void)bitlen; spimem_flash_ll_set_address(dev, addr); } /** * Set the length of dummy cycles. * * @param dev Beginning address of the peripheral registers. * @param dummy_n Cycles of dummy phases */ static inline void spimem_flash_ll_set_dummy(spi_mem_dev_t *dev, uint32_t dummy_n) { dev->user.usr_dummy = dummy_n ? 1 : 0; dev->user1.usr_dummy_cyclelen = dummy_n - 1; } /** * Set CS hold time. * * @param dev Beginning address of the peripheral registers. * @param hold_n CS hold time config used by the host. */ static inline void spimem_flash_ll_set_hold(spi_mem_dev_t *dev, uint32_t hold_n) { if (hold_n > 0) { dev->ctrl2.cs_hold_time = hold_n - 1; } dev->user.cs_hold = hold_n > 0; } /** * Set CS setup time * * @param dev Beginning address of the peripheral registers. * @param cs_setup_time CS setup time */ static inline void spimem_flash_ll_set_cs_setup(spi_mem_dev_t *dev, uint32_t cs_setup_time) { if (cs_setup_time > 0) { dev->ctrl2.cs_setup_time = cs_setup_time - 1; } dev->user.cs_setup = (cs_setup_time > 0 ? 1 : 0); } /** * Get the spi flash source clock frequency. Used for calculating * the divider parameters. * * @param None * * @return the frequency of spi flash clock source.(MHz) */ static inline uint8_t spimem_flash_ll_get_source_freq_mhz(void) { return 80; } /** * Calculate spi_flash clock frequency division parameters for register. * * @param clkdiv frequency division factor * * @return Register setting for the given clock division factor. */ static inline uint32_t spimem_flash_ll_calculate_clock_reg(uint8_t clkdiv) { uint32_t div_parameter; // See comments of `clock` in `spi_mem_struct.h` if (clkdiv == 1) { div_parameter = (1 << 31); } else { div_parameter = ((clkdiv - 1) | (((clkdiv - 1) / 2 & 0xff) << 8 ) | (((clkdiv - 1) & 0xff) << 16)); } return div_parameter; } #ifdef __cplusplus } #endif