“RA MCU眾測寶典”中I2C/SPI通信與顯示驅(qū)動專題更新了。這次我們聚焦瑞薩【CPKCOR-RA8D1B核心板】開發(fā)板，一步步實現(xiàn)QSPI讀取外部Flash。

開啟寶典

QSPI是Queued SPI的簡寫，是Motorola公司推出的SPI接口的擴展，比SPI應(yīng)用更加廣泛。在SPI協(xié)議的基礎(chǔ)上，Motorola公司對其功能進行了增強，增加了隊列傳輸機制，推出了隊列串行外圍接口協(xié)議（即QSPI協(xié)議）。

QSPI是一種專用的通信接口，連接單、雙或四（條數(shù)據(jù)線）SPI Flash存儲介質(zhì)。QSPI是一個內(nèi)存控制器，用于連接具有SPI兼容接口的串行ROM（非易失性存儲器）。

我們看一下核心板上的外擴Flash：

外擴的Flash的型號是AT25SF128B。

QSPI使用6個信號連接Flash，分別是四個數(shù)據(jù)線QIO0~QIO3，一個時鐘輸出CLK，一個片選輸出（低電平有效）QSSL，它們的作用介紹如下：

QSSL：片選輸出（低電平有效），適用于FLASH 1。如果QSPI始終在雙閃存模式下工作，則其也可用于FLASH 2從設(shè)備選擇信號線。QSPI通訊以QSSL線置低電平為開始信號，以QSSL線被拉高作為結(jié)束信號。

CLK：時鐘輸出，適用于兩個存儲器，用于通訊數(shù)據(jù)同步。它由通訊主機產(chǎn)生，決定了通訊的速率，不同的設(shè)備支持的最高時鐘頻率不一樣，兩個設(shè)備之間通訊時，通訊速率受限于低速設(shè)備。

QIO0QIO0~QIO3：四線模式中為雙向IO。

接下來進行軟件配置：

添加OSPI功能模塊：

接下來我們配置一下引腳：

一共是6個引腳，接下來配置模塊信息：

下面是部分Flash的命令，我們可以初始化這些內(nèi)容：

接下來我們代碼測試一下QSPI的功能。

我們定義了一些基礎(chǔ)功能測試：

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uint8_tg_read_data [OSPI_B_APP_DATA_SIZE] = {RESET_VALUE};
uint8_tg_write_data [OSPI_B_APP_DATA_SIZE] = {0x00,0x01,0x02,0x03,0x04,0x05,0x06,0x07,0x08,0x09,0x0A,0x0B,0x0C,0x0D,0x0E,0x0F,0x10,0x11,0x12,0x13,0x14,0x15,0x16,0x17,0x18,0x19,0x1A,0x1B,0x1C,0x1D,0x1E,0x1F,0x20,0x21,0x22,0x23,0x24,0x25,0x26,0x27,0x28,0x29,0x2A,0x2B,0x2C,0x2D,0x2E,0x2F,0x30,0x31,0x32,0x33,0x34,0x35,0x36,0x37,0x38,0x39,0x3A,0x3B,0x3C,0x3D,0x3E,0x3F,};spi_flash_direct_transfer_tg_ospi_b_direct_transfer [OSPI_B_TRANSFER_MAX] ={/* Transfer structure for SPI mode */ [OSPI_B_TRANSFER_WRITE_ENABLE_SPI] = { .command = OSPI_B_COMMAND_WRITE_ENABLE_SPI, .address = OSPI_B_ADDRESS_DUMMY, .data = OSPI_B_DATA_DUMMY, .command_length = OSPI_B_COMMAND_LENGTH_SPI, .address_length = OSPI_B_ADDRESS_LENGTH_ZERO, .data_length = OSPI_B_DATA_LENGTH_ZERO, .dummy_cycles = OSPI_B_DUMMY_CYCLE_WRITE_SPI }, [OSPI_B_TRANSFER_READ_STATUS_SPI] = { .command = OSPI_B_COMMAND_READ_STATUS_SPI, .address = OSPI_B_ADDRESS_DUMMY, .data = OSPI_B_DATA_DUMMY, .command_length = OSPI_B_COMMAND_LENGTH_SPI, .address_length = OSPI_B_ADDRESS_LENGTH_ZERO, .data_length = OSPI_B_DATA_LENGTH_ONE, .dummy_cycles = OSPI_B_DUMMY_CYCLE_READ_STATUS_SPI }, [OSPI_B_TRANSFER_READ_DEVICE_ID_SPI] = { .command = OSPI_B_COMMAND_READ_DEVICE_ID_SPI, //0x9f .address = OSPI_B_ADDRESS_DUMMY, //0 .data = OSPI_B_DATA_DUMMY, //0 .command_length = OSPI_B_COMMAND_LENGTH_SPI, //1 .address_length = OSPI_B_ADDRESS_LENGTH_ZERO, //0 .data_length = OSPI_B_DATA_LENGTH_FOUR, //4 .dummy_cycles = OSPI_B_DUMMY_CYCLE_READ_STATUS_SPI //0 }};fsp_err_tospi_b_read_device_id(uint32_t*constp_id){fsp_err_t err = FSP_SUCCESS;spi_flash_direct_transfer_ttransfer = {RESET_VALUE};/* Read and check flash device ID */ transfer = g_ospi_b_direct_transfer[OSPI_B_TRANSFER_READ_DEVICE_ID_SPI]; err =R_OSPI_B_DirectTransfer(&g_qspi0_flash_ctrl, &transfer, SPI_FLASH_DIRECT_TRANSFER_DIR_READ);if(err!=FSP_SUCCESS) {printf("R_OSPI_B_DirectTransfer API FAILED \r\n"); }/* Get flash device ID */ *p_id = transfer.data;returnerr;}staticfsp_err_tospi_b_write_enable(void){fsp_err_t err = FSP_SUCCESS;spi_flash_direct_transfer_ttransfer = {RESET_VALUE};/* Transfer write enable command */ transfer = g_ospi_b_direct_transfer[OSPI_B_TRANSFER_WRITE_ENABLE_SPI]; err =R_OSPI_B_DirectTransfer(&g_qspi0_flash_ctrl, &transfer, SPI_FLASH_DIRECT_TRANSFER_DIR_WRITE); assert(FSP_SUCCESS == err);/* Read Status Register */ transfer = g_ospi_b_direct_transfer[OSPI_B_TRANSFER_READ_STATUS_SPI]; err =R_OSPI_B_DirectTransfer(&g_qspi0_flash_ctrl, &transfer, SPI_FLASH_DIRECT_TRANSFER_DIR_READ); assert(FSP_SUCCESS == err);/* Check Write Enable bit in Status Register */if(OSPI_B_WEN_BIT_MASK != (transfer.data & OSPI_B_WEN_BIT_MASK)) {printf("Write enable FAILED\r\n"); }returnerr;}staticfsp_err_tospi_b_wait_operation(uint32_ttimeout){fsp_err_t err = FSP_SUCCESS;spi_flash_status_tstatus = {RESET_VALUE}; status.write_in_progress =true;while(status.write_in_progress) {/* Get device status */ R_OSPI_B_StatusGet(&g_qspi0_flash_ctrl, &status);if(RESET_VALUE == timeout) {printf("OSPI time out occurred\r\n"); } R_BSP_SoftwareDelay(1, OSPI_B_TIME_UNIT); timeout --; }returnerr;}staticfsp_err_tospi_b_erase_operation(uint8_t*constp_address){fsp_err_t err = FSP_SUCCESS;uint32_t sector_size = RESET_VALUE;uint32_t erase_timeout = RESET_VALUE;/* Check sector size according to input address pointer, described in S28HS512T data sheet */if(OSPI_B_SECTOR_4K_END_ADDRESS < (uint32_t)p_address)? ? {? ? ? ? sector_size = OSPI_B_SECTOR_SIZE_256K;? ? ? ? erase_timeout = OSPI_B_TIME_ERASE_256K;? ? }else? ? {? ? ? ? sector_size = OSPI_B_SECTOR_SIZE_4K;? ? ? ? erase_timeout = OSPI_B_TIME_ERASE_4K;? ? }/* Performs erase sector */? ? err =?R_OSPI_B_Erase(&g_qspi0_flash_ctrl, p_address, sector_size);/* Wait till operation completes */? ? err =?ospi_b_wait_operation(erase_timeout);return?err;}staticfsp_err_tospi_b_write_operation(uint8_t?*?const?p_address,uint8_t?*pdata,?uint16_t?len){fsp_err_t? ?err ? ? ? ? = FSP_SUCCESS;/* Erase sector before write data to flash device */? ? err =?ospi_b_erase_operation(p_address);/* Write data to flash device */? ? err =?R_OSPI_B_Write(&g_qspi0_flash_ctrl, pdata, p_address, len);/* Wait until write operation completes */? ? err =?ospi_b_wait_operation(OSPI_B_TIME_WRITE);return?err;}staticfsp_err_tospi_b_read_operation(uint8_t?*?const?p_address,uint8_t?*pdata,?uint16_t?len){fsp_err_t?err = FSP_SUCCESS;/* Clean read buffer */memset(pdata, RESET_VALUE, len);/* Read data from flash device */memcpy(pdata, p_address, len);return?err;
}

在main中我們需要先初始化：

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voidqspi_FlashInit(void){
/* Open the OSPI instance. */ fsp_err_terr=R_OSPI_B_Open(&g_qspi0_flash_ctrl, &g_qspi0_flash_cfg); assert(FSP_SUCCESS == err); /* Switch OSPI module to 1S-1S-1S mode to configure flash device */ err = R_OSPI_B_SpiProtocolSet(&g_qspi0_flash_ctrl, SPI_FLASH_PROTOCOL_EXTENDED_SPI); assert(FSP_SUCCESS == err); /* Reset flash device by driving OM_RESET pin */ R_XSPI->LIOCTL_b.RSTCS0 =0; R_BSP_SoftwareDelay(OSPI_B_TIME_RESET_PULSE, OSPI_B_TIME_UNIT); R_XSPI->LIOCTL_b.RSTCS1 =1; R_BSP_SoftwareDelay(OSPI_B_TIME_RESET_SETUP, OSPI_B_TIME_UNIT); ospi_b_write_enable();
}

然后直接初始化階段測試QSPI，我們寫入一頁數(shù)據(jù)，但是之讀取其中的16個，并通過串口打印：

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fsp_err_tospi_b_Testoperation(uint8_t*p_address){
fsp_err_t err =FSP_SUCCESS; uint16_t i=0; err=ospi_b_erase_operation(p_address); err=ospi_b_write_operation (p_address,g_write_data,OSPI_B_APP_DATA_SIZE); if(err==FSP_SUCCESS) { /* Print execution time */ printf("Write %d bytes completed successfully\r\n", (int)(OSPI_B_APP_DATA_SIZE)); } else { printf("Write operation failure\r\n"); } printf("Write Data:\r\n"); for(i=0;i<=OSPI_B_APP_DATA_SIZE-1;i++)? ? {? ? ? ? printf("%d ",g_write_data[i]);? ? }? ? err?=?ospi_b_read_operation (p_address,g_read_data,16);? ? if(err==FSP_SUCCESS)? ? {? ? ? ? /* Print execution time */? ? ? ? printf("\r\nRead %d bytes completed successfully\r\n", (int)(OSPI_B_APP_DATA_SIZE));? ? }? ? else? ? {? ? ? ? printf("\r\nRead operation failure\r\n");? ? }? ? printf("Read Data:\r\n");? ? for(i=0;i<=sizeof(g_read_data)-1;i++)? ? {? ? ? ? printf("%d ",g_read_data[i]);? ? }? ? /* Compare data read and date written */? ? if(RESET_VALUE?==?memcmp(&g_read_data,?&g_write_data, (size_t)16))? ? {? ? ? ? printf("\r\nData read matched data written\r\n");? ? ? ? printf("flash讀寫數(shù)據(jù)成功\r\n");? ? }? ? else? ? {? ? ? ? printf("\r\nData read does not match data written\r\n");? ? ? ? printf("flash讀寫數(shù)據(jù)失敗\r\n");? ? }? ? /* Performs OSPI erase operation */? ? err?=?ospi_b_erase_operation(p_address);? ? if(err==FSP_SUCCESS)? ? {? ? ? ? /* Print execution time */? ? ? ? printf("Erase sector completed successfully\r\n");? ? }? ? else? ? {? ? ? ? printf("erase operation failure\r\n");? ? }? ? return?err;
}

串口打印結(jié)果如下：

從QSPI的六引腳配置、OSPI功能模塊添加，到命令集定義、Flash讀寫擦除的代碼實現(xiàn)，再到串口打印驗證數(shù)據(jù)匹配。我們不僅掌握了不同通信協(xié)議的配置邏輯，還摸清了它們在存儲外設(shè)交互中的核心應(yīng)用——這次通過QSPI實現(xiàn)Flash的讀寫擦除與數(shù)據(jù)驗證，正是高速通信在存儲場景的典型落地。

I2C/SPI通信與顯示驅(qū)動專題的技能專題還在持續(xù)拓展！如果你在實操中對QSPI的協(xié)議時序、Flash命令配置有新的感悟，或是想分享更多通信驅(qū)動的實戰(zhàn)場景，歡迎在評論區(qū)交流。