mbed library sources. Supersedes mbed-src.
Dependents: Nucleo_Hello_Encoder BLE_iBeaconScan AM1805_DEMO DISCO-F429ZI_ExportTemplate1 ... more
drivers/QSPI.h
- Committer:
- AnnaBridge
- Date:
- 2018-11-08
- Revision:
- 188:bcfe06ba3d64
- Child:
- 189:f392fc9709a3
File content as of revision 188:bcfe06ba3d64:
/* mbed Microcontroller Library * Copyright (c) 2006-2018 ARM Limited * * 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. */ #ifndef MBED_QSPI_H #define MBED_QSPI_H #include "platform/platform.h" #if defined (DEVICE_QSPI) || defined(DOXYGEN_ONLY) #include "hal/qspi_api.h" #include "platform/PlatformMutex.h" #include "platform/SingletonPtr.h" #include "platform/NonCopyable.h" #define ONE_MHZ 1000000 namespace mbed { /** \addtogroup drivers */ /** A QSPI Driver, used for communicating with QSPI slave devices * * The default format is set to Quad-SPI(1-1-1), and a clock frequency of 1MHz * Most QSPI devices will also require Chip Select which is indicated by ssel. * * @note Synchronization level: Thread safe * * Example: * @code * // Write 4 byte array to a QSPI slave, and read the response, note that each device will have its specific read/write/alt values defined * * #include "mbed.h" * * #define CMD_WRITE 0x02 * #define CMD_READ 0x03 * #define ADDRESS 0x1000 * * // hardware ssel (where applicable) * QSPI qspi_device(QSPI_FLASH1_IO0, QSPI_FLASH1_IO1, QSPI_FLASH1_IO2, QSPI_FLASH1_IO3, QSPI_FLASH1_SCK, QSPI_FLASH1_CSN); // io0, io1, io2, io3, sclk, ssel * * * int main() { * char tx_buf[] = { 0x11, 0x22, 0x33, 0x44 }; * char rx_buf[4]; * int buf_len = sizeof(tx_buf); * * qspi_status_t result = qspi_device.write(CMD_WRITE, 0, ADDRESS, tx_buf, &buf_len); * if (result != QSPI_STATUS_OK) { * printf("Write failed"); * } * result = qspi_device.read(CMD_READ, 0, ADDRESS, rx_buf, &buf_len); * if (result != QSPI_STATUS_OK) { * printf("Read failed"); * } * * } * @endcode * @ingroup drivers */ class QSPI : private NonCopyable<QSPI> { public: /** Create a QSPI master connected to the specified pins * * io0-io3 is used to specify the Pins used for Quad SPI mode * * @param io0 1st IO pin used for sending/receiving data during data phase of a transaction * @param io1 2nd IO pin used for sending/receiving data during data phase of a transaction * @param io2 3rd IO pin used for sending/receiving data during data phase of a transaction * @param io3 4th IO pin used for sending/receiving data during data phase of a transaction * @param sclk QSPI Clock pin * @param ssel QSPI chip select pin * @param mode Clock polarity and phase mode (0 - 3) of SPI * (Default: Mode=0 uses CPOL=0, CPHA=0, Mode=1 uses CPOL=1, CPHA=1) * */ QSPI(PinName io0, PinName io1, PinName io2, PinName io3, PinName sclk, PinName ssel = NC, int mode = 0); virtual ~QSPI() { } /** Configure the data transmission format * * @param inst_width Bus width used by instruction phase(Valid values are QSPI_CFG_BUS_SINGLE, QSPI_CFG_BUS_DUAL, QSPI_CFG_BUS_QUAD) * @param address_width Bus width used by address phase(Valid values are QSPI_CFG_BUS_SINGLE, QSPI_CFG_BUS_DUAL, QSPI_CFG_BUS_QUAD) * @param address_size Size in bits used by address phase(Valid values are QSPI_CFG_ADDR_SIZE_8, QSPI_CFG_ADDR_SIZE_16, QSPI_CFG_ADDR_SIZE_24, QSPI_CFG_ADDR_SIZE_32) * @param alt_width Bus width used by alt phase(Valid values are QSPI_CFG_BUS_SINGLE, QSPI_CFG_BUS_DUAL, QSPI_CFG_BUS_QUAD) * @param alt_size Size in bits used by alt phase(Valid values are QSPI_CFG_ALT_SIZE_8, QSPI_CFG_ALT_SIZE_16, QSPI_CFG_ALT_SIZE_24, QSPI_CFG_ALT_SIZE_32) * @param data_width Bus width used by data phase(Valid values are QSPI_CFG_BUS_SINGLE, QSPI_CFG_BUS_DUAL, QSPI_CFG_BUS_QUAD) * @param dummy_cycles Number of dummy clock cycles to be used after alt phase * */ qspi_status_t configure_format(qspi_bus_width_t inst_width, qspi_bus_width_t address_width, qspi_address_size_t address_size, qspi_bus_width_t alt_width, qspi_alt_size_t alt_size, qspi_bus_width_t data_width, int dummy_cycles); /** Set the qspi bus clock frequency * * @param hz SCLK frequency in hz (default = 1MHz) * @returns * Returns QSPI_STATUS_SUCCESS on successful, fails if the interface is already init-ed */ qspi_status_t set_frequency(int hz = ONE_MHZ); /** Read from QSPI peripheral with the preset read_instruction and alt_value * * @param address Address to be accessed in QSPI peripheral * @param rx_buffer Buffer for data to be read from the peripheral * @param rx_length Pointer to a variable containing the length of rx_buffer, and on return this variable will be updated with the actual number of bytes read * * @returns * Returns QSPI_STATUS_SUCCESS on successful reads and QSPI_STATUS_ERROR on failed reads. */ qspi_status_t read(int address, char *rx_buffer, size_t *rx_length); /** Write to QSPI peripheral using custom write instruction * * @param address Address to be accessed in QSPI peripheral * @param tx_buffer Buffer containing data to be sent to peripheral * @param tx_length Pointer to a variable containing the length of data to be transmitted, and on return this variable will be updated with the actual number of bytes written * * @returns * Returns QSPI_STATUS_SUCCESS on successful reads and QSPI_STATUS_ERROR on failed reads. */ qspi_status_t write(int address, const char *tx_buffer, size_t *tx_length); /** Read from QSPI peripheral using custom read instruction, alt values * * @param instruction Instruction value to be used in instruction phase * @param alt Alt value to be used in Alternate-byte phase. Use -1 for ignoring Alternate-byte phase * @param address Address to be accessed in QSPI peripheral * @param rx_buffer Buffer for data to be read from the peripheral * @param rx_length Pointer to a variable containing the length of rx_buffer, and on return this variable will be updated with the actual number of bytes read * * @returns * Returns QSPI_STATUS_SUCCESS on successful reads and QSPI_STATUS_ERROR on failed reads. */ qspi_status_t read(int instruction, int alt, int address, char *rx_buffer, size_t *rx_length); /** Write to QSPI peripheral using custom write instruction, alt values * * @param instruction Instruction value to be used in instruction phase * @param alt Alt value to be used in Alternate-byte phase. Use -1 for ignoring Alternate-byte phase * @param address Address to be accessed in QSPI peripheral * @param tx_buffer Buffer containing data to be sent to peripheral * @param tx_length Pointer to a variable containing the length of data to be transmitted, and on return this variable will be updated with the actual number of bytes written * * @returns * Returns QSPI_STATUS_SUCCESS on successful reads and QSPI_STATUS_ERROR on failed reads. */ qspi_status_t write(int instruction, int alt, int address, const char *tx_buffer, size_t *tx_length); /** Perform a transaction to write to an address(a control register) and get the status results * * @param instruction Instruction value to be used in instruction phase * @param address Some instruction might require address. Use -1 if no address * @param tx_buffer Buffer containing data to be sent to peripheral * @param tx_length Pointer to a variable containing the length of data to be transmitted, and on return this variable will be updated with the actual number of bytes written * @param rx_buffer Buffer for data to be read from the peripheral * @param rx_length Pointer to a variable containing the length of rx_buffer, and on return this variable will be updated with the actual number of bytes read * * @returns * Returns QSPI_STATUS_SUCCESS on successful reads and QSPI_STATUS_ERROR on failed reads. */ qspi_status_t command_transfer(int instruction, int address, const char *tx_buffer, size_t tx_length, const char *rx_buffer, size_t rx_length); #if !defined(DOXYGEN_ONLY) protected: /** Acquire exclusive access to this SPI bus */ virtual void lock(void); /** Release exclusive access to this SPI bus */ virtual void unlock(void); qspi_t _qspi; bool acquire(void); static QSPI *_owner; static SingletonPtr<PlatformMutex> _mutex; qspi_bus_width_t _inst_width; //Bus width for Instruction phase qspi_bus_width_t _address_width; //Bus width for Address phase qspi_address_size_t _address_size; qspi_bus_width_t _alt_width; //Bus width for Alt phase qspi_alt_size_t _alt_size; qspi_bus_width_t _data_width; //Bus width for Data phase qspi_command_t _qspi_command; //QSPI Hal command struct unsigned int _num_dummy_cycles; //Number of dummy cycles to be used int _hz; //Bus Frequency int _mode; //SPI mode bool _initialized; PinName _qspi_io0, _qspi_io1, _qspi_io2, _qspi_io3, _qspi_clk, _qspi_cs; //IO lines, clock and chip select private: /* Private acquire function without locking/unlocking * Implemented in order to avoid duplicate locking and boost performance */ bool _acquire(void); bool _initialize(); /* * This function builds the qspi command struct to be send to Hal */ inline void _build_qspi_command(int instruction, int address, int alt); #endif }; } // namespace mbed #endif #endif