/** * \file * \brief ATCA Hardware abstraction layer for SAMB11 I2C over ASF drivers. * * This code is structured in two parts. Part 1 is the connection of the ATCA HAL API to the physical I2C * implementation. Part 2 is the ASF I2C primitives to set up the interface. * * Prerequisite: add I2C Master Polled support to application in Atmel Studio * * \copyright (c) 2015-2020 Microchip Technology Inc. and its subsidiaries. * * \page License * * Subject to your compliance with these terms, you may use Microchip software * and any derivatives exclusively with Microchip products. It is your * responsibility to comply with third party license terms applicable to your * use of third party software (including open source software) that may * accompany Microchip software. * * THIS SOFTWARE IS SUPPLIED BY MICROCHIP "AS IS". NO WARRANTIES, WHETHER * EXPRESS, IMPLIED OR STATUTORY, APPLY TO THIS SOFTWARE, INCLUDING ANY IMPLIED * WARRANTIES OF NON-INFRINGEMENT, MERCHANTABILITY, AND FITNESS FOR A * PARTICULAR PURPOSE. IN NO EVENT WILL MICROCHIP BE LIABLE FOR ANY INDIRECT, * SPECIAL, PUNITIVE, INCIDENTAL OR CONSEQUENTIAL LOSS, DAMAGE, COST OR EXPENSE * OF ANY KIND WHATSOEVER RELATED TO THE SOFTWARE, HOWEVER CAUSED, EVEN IF * MICROCHIP HAS BEEN ADVISED OF THE POSSIBILITY OR THE DAMAGES ARE * FORESEEABLE. TO THE FULLEST EXTENT ALLOWED BY LAW, MICROCHIP'S TOTAL * LIABILITY ON ALL CLAIMS IN ANY WAY RELATED TO THIS SOFTWARE WILL NOT EXCEED * THE AMOUNT OF FEES, IF ANY, THAT YOU HAVE PAID DIRECTLY TO MICROCHIP FOR * THIS SOFTWARE. */ #include #include #include #include "atca_hal.h" #include "hal_samb11_i2c_asf.h" #include "atca_device.h" #include "atca_execution.h" /** \defgroup hal_ Hardware abstraction layer (hal_) * * \brief * These methods define the hardware abstraction layer for communicating with a CryptoAuth device * using I2C driver of ASF. * @{ */ /** \brief logical to physical bus mapping structure */ static ATCAI2CMaster_t i2c_hal_data[MAX_I2C_BUSES]; // map logical, 0-based bus number to index static struct i2c_master_config config_i2c_master; /** \brief discover i2c buses available for this hardware * this maintains a list of logical to physical bus mappings freeing the application * of the a-priori knowledge * \param[in] i2c_buses - an array of logical bus numbers * \param[in] max_buses - maximum number of buses the app wants to attempt to discover * \return ATCA_SUCCESS */ ATCA_STATUS hal_i2c_discover_buses(int i2c_buses[], int max_buses) { i2c_buses[0] = 0; // b11 bus for xplained pro dev board over EXT1 i2c_buses[1] = 1; // b11 bus for MR510CA return ATCA_SUCCESS; } /** \brief discover any CryptoAuth devices on a given logical bus number * \param[in] bus_num logical bus number on which to look for CryptoAuth devices * \param[out] cfg pointer to head of an array of interface config structures which get filled in by this method * \param[out] found number of devices found on this bus * \return ATCA_SUCCESS */ ATCA_STATUS hal_i2c_discover_devices(int bus_num, ATCAIfaceCfg cfg[], int *found) { ATCAIfaceCfg *head = cfg; uint8_t slaveAddress = 0x01; ATCADevice device; #ifdef ATCA_NO_HEAP struct atca_device disc_device; struct atca_command disc_command; struct atca_iface disc_iface; #endif ATCAPacket packet; ATCA_STATUS status; uint8_t revs608[][4] = { { 0x00, 0x00, 0x60, 0x01 }, { 0x00, 0x00, 0x60, 0x02 } }; uint8_t revs508[][4] = { { 0x00, 0x00, 0x50, 0x00 } }; uint8_t revs108[][4] = { { 0x80, 0x00, 0x10, 0x01 } }; uint8_t revs204[][4] = { { 0x00, 0x02, 0x00, 0x08 }, { 0x00, 0x02, 0x00, 0x09 }, { 0x00, 0x04, 0x05, 0x00 } }; int i; /** \brief default configuration, to be reused during discovery process */ ATCAIfaceCfg discoverCfg = { .iface_type = ATCA_I2C_IFACE, .devtype = ATECC508A, .atcai2c.slave_address = 0x07, .atcai2c.bus = bus_num, .atcai2c.baud = 400000, //.atcai2c.baud = 100000, .wake_delay = 800, .rx_retries = 3 }; if (bus_num < 0) { return ATCA_COMM_FAIL; } #ifdef ATCA_NO_HEAP disc_device.mCommands = &disc_command; disc_device.mIface = &disc_iface; status = initATCADevice(&discoverCfg, &disc_device); if (status != ATCA_SUCCESS) { return status; } device = &disc_device; #else device = newATCADevice(&discoverCfg); if (device == NULL) { return ATCA_COMM_FAIL; } #endif for (slaveAddress = 0x07; slaveAddress <= 0x78; slaveAddress++) { discoverCfg.atcai2c.slave_address = slaveAddress << 1; // turn it into an 8-bit address which is what the rest of the i2c HAL is expecting when a packet is sent memset(packet.data, 0x00, sizeof(packet.data)); // build an info command packet.param1 = INFO_MODE_REVISION; packet.param2 = 0; // get devrev info and set device type accordingly atInfo(device->mCommands, &packet); if ((status = atca_execute_command(&packet, device)) != ATCA_SUCCESS) { continue; } // determine device type from common info and dev rev response byte strings... start with unknown discoverCfg.devtype = ATCA_DEV_UNKNOWN; for (i = 0; i < (int)sizeof(revs608) / 4; i++) { if (memcmp(&packet.data[1], &revs608[i], 4) == 0) { discoverCfg.devtype = ATECC608A; break; } } for (i = 0; i < (int)sizeof(revs508) / 4; i++) { if (memcmp(&packet.data[1], &revs508[i], 4) == 0) { discoverCfg.devtype = ATECC508A; break; } } for (i = 0; i < (int)sizeof(revs204) / 4; i++) { if (memcmp(&packet.data[1], &revs204[i], 4) == 0) { discoverCfg.devtype = ATSHA204A; break; } } for (i = 0; i < (int)sizeof(revs108) / 4; i++) { if (memcmp(&packet.data[1], &revs108[i], 4) == 0) { discoverCfg.devtype = ATECC108A; break; } } if (discoverCfg.devtype != ATCA_DEV_UNKNOWN) { // now the device type is known, so update the caller's cfg array element with it (*found)++; memcpy( (uint8_t*)head, (uint8_t*)&discoverCfg, sizeof(ATCAIfaceCfg)); head->devtype = discoverCfg.devtype; head++; } atca_delay_ms(15); } #ifdef ATCA_NO_HEAP releaseATCADevice(device); #else deleteATCADevice(&device); #endif return ATCA_SUCCESS; } /** \brief - this HAL implementation assumes you've included the ASF I2C libraries in your project, otherwise, the HAL layer will not compile because the ASF I2C drivers are a dependency * */ /** \brief hal_i2c_init manages requests to initialize a physical interface. it manages use counts so when an interface * has released the physical layer, it will disable the interface for some other use. * You can have multiple ATCAIFace instances using the same bus, and you can have multiple ATCAIFace instances on * multiple i2c buses, so hal_i2c_init manages these things and ATCAIFace is abstracted from the physical details. */ /** \brief initialize an I2C interface using given config * \param[in] hal - opaque ptr to HAL data * \param[in] cfg - interface configuration * \return ATCA_SUCCESS on success, otherwise an error code. */ ATCA_STATUS hal_i2c_init(void *hal, ATCAIfaceCfg *cfg) { if (cfg->atcai2c.bus >= MAX_I2C_BUSES) { return ATCA_COMM_FAIL; } ATCAI2CMaster_t* data = &i2c_hal_data[cfg->atcai2c.bus]; if (data->ref_ct <= 0) { // Bus isn't being used, enable it i2c_master_get_config_defaults(&config_i2c_master); switch (cfg->atcai2c.bus) { case 0: config_i2c_master.pin_number_pad0 = PIN_LP_GPIO_8; config_i2c_master.pin_number_pad1 = PIN_LP_GPIO_9; config_i2c_master.pinmux_sel_pad0 = PINMUX_LP_GPIO_8_MUX2_I2C0_SDA; config_i2c_master.pinmux_sel_pad1 = PINMUX_LP_GPIO_9_MUX2_I2C0_SCL; data->i2c_sercom = I2C0; break; case 1: config_i2c_master.pin_number_pad0 = PIN_LP_GPIO_14; config_i2c_master.pin_number_pad1 = PIN_LP_GPIO_15; config_i2c_master.pinmux_sel_pad0 = PINMUX_LP_GPIO_14_MUX4_I2C1_SDA; config_i2c_master.pinmux_sel_pad1 = PINMUX_LP_GPIO_15_MUX4_I2C1_SCL; data->i2c_sercom = I2C1; break; default: return ATCA_COMM_FAIL; } i2c_master_init(&data->i2c_master_instance, data->i2c_sercom, &config_i2c_master); i2c_enable(data->i2c_master_instance.hw); // store this for use during the release phase data->bus_index = cfg->atcai2c.bus; // buses are shared, this is the first instance data->ref_ct = 1; } else { // Bus is already is use, increment reference counter data->ref_ct++; } ((ATCAHAL_t*)hal)->hal_data = data; return ATCA_SUCCESS; } /** \brief HAL implementation of I2C post init * \param[in] iface instance * \return ATCA_SUCCESS */ ATCA_STATUS hal_i2c_post_init(ATCAIface iface) { return ATCA_SUCCESS; } /** \brief HAL implementation of I2C send over ASF * \param[in] iface instance * \param[in] txdata pointer to space to bytes to send * \param[in] txlength number of bytes to send * \return ATCA_SUCCESS on success, otherwise an error code. */ ATCA_STATUS hal_i2c_send(ATCAIface iface, uint8_t *txdata, int txlength) { ATCAIfaceCfg *cfg = atgetifacecfg(iface); struct i2c_master_packet packet = { .address = cfg->atcai2c.slave_address >> 1, .data_length = txlength, .data = txdata, }; // for this implementation of I2C with CryptoAuth chips, txdata is assumed to have ATCAPacket format // other device types that don't require i/o tokens on the front end of a command need a different hal_i2c_send and wire it up instead of this one // this covers devices such as ATSHA204A and ATECCx08A that require a word address value pre-pended to the packet // txdata[0] is using _reserved byte of the ATCAPacket txdata[0] = 0x03; // insert the Word Address Value, Command token txlength++; // account for word address value byte. packet.data_length = txlength; if (i2c_master_write_packet_wait(&(i2c_hal_data[cfg->atcai2c.bus].i2c_master_instance), &packet) != STATUS_OK) { return ATCA_COMM_FAIL; } return ATCA_SUCCESS; } /** \brief HAL implementation of I2C receive function for ASF I2C * \param[in] iface Device to interact with. * \param[out] rxdata Data received will be returned here. * \param[inout] rxlength As input, the size of the rxdata buffer. * As output, the number of bytes received. * \return ATCA_SUCCESS on success, otherwise an error code. */ ATCA_STATUS hal_i2c_receive(ATCAIface iface, uint8_t *rxdata, uint16_t *rxlength) { ATCAIfaceCfg *cfg = atgetifacecfg(iface); int retries = cfg->rx_retries; int status = !ATCA_SUCCESS; uint16_t rxdata_max_size = *rxlength; struct i2c_master_packet packet = { .address = cfg->atcai2c.slave_address >> 1, .data_length = 1, .data = rxdata, }; *rxlength = 0; if (rxdata_max_size < 1) { return ATCA_SMALL_BUFFER; } while (retries-- > 0 && status != ATCA_SUCCESS) { if (i2c_master_read_packet_wait(&(i2c_hal_data[cfg->atcai2c.bus].i2c_master_instance), &packet) != STATUS_OK) { status = ATCA_COMM_FAIL; } else { status = ATCA_SUCCESS; } } if (status != ATCA_SUCCESS) { return status; } if (rxdata[0] < ATCA_RSP_SIZE_MIN) { return ATCA_INVALID_SIZE; } if (rxdata[0] > rxdata_max_size) { return ATCA_SMALL_BUFFER; } //Update receive length with first byte received and set to read rest of the data packet.data_length = rxdata[0] - 1; packet.data = &rxdata[1]; if (i2c_master_read_packet_wait(&(i2c_hal_data[cfg->atcai2c.bus].i2c_master_instance), &packet) != STATUS_OK) { status = ATCA_COMM_FAIL; } else { status = ATCA_SUCCESS; } if (status != ATCA_SUCCESS) { return status; } *rxlength = rxdata[0]; return ATCA_SUCCESS; } /** \brief wake up CryptoAuth device using I2C bus * \param[in] iface interface to logical device to wakeup * \return ATCA_SUCCESS on success, otherwise an error code. */ ATCA_STATUS hal_i2c_wake(ATCAIface iface) { ATCAIfaceCfg *cfg = atgetifacecfg(iface); int retries = cfg->rx_retries; int status = !STATUS_OK; uint8_t data[4]; // Send the wake by writing to an address of 0x00 struct i2c_master_packet packet = { .address = 0x00, .data_length = 0, .data = &data[0], }; // Send the 00 address as the wake pulse i2c_master_write_packet_wait(&(i2c_hal_data[cfg->atcai2c.bus].i2c_master_instance), &packet); // part will NACK, so don't check for status atca_delay_us(cfg->wake_delay); // wait tWHI + tWLO which is configured based on device type and configuration structure packet.address = cfg->atcai2c.slave_address >> 1; packet.data_length = 4; packet.data = data; while (retries-- > 0 && status != STATUS_OK) { status = i2c_master_read_packet_wait(&(i2c_hal_data[cfg->atcai2c.bus].i2c_master_instance), &packet); } if (status != STATUS_OK) { return ATCA_COMM_FAIL; } return hal_check_wake(data, 4); } /** \brief idle CryptoAuth device using I2C bus * \param[in] iface interface to logical device to idle * \return ATCA_SUCCESS on success, otherwise an error code. */ ATCA_STATUS hal_i2c_idle(ATCAIface iface) { ATCAIfaceCfg *cfg = atgetifacecfg(iface); uint8_t data[4]; struct i2c_master_packet packet = { .address = cfg->atcai2c.slave_address >> 1, .data_length = 1, .data = &data[0], }; data[0] = 0x02; // idle word address value if (i2c_master_write_packet_wait(&(i2c_hal_data[cfg->atcai2c.bus].i2c_master_instance), &packet) != STATUS_OK) { return ATCA_COMM_FAIL; } return ATCA_SUCCESS; } /** \brief sleep CryptoAuth device using I2C bus * \param[in] iface interface to logical device to sleep * \return ATCA_SUCCESS on success, otherwise an error code. */ ATCA_STATUS hal_i2c_sleep(ATCAIface iface) { ATCAIfaceCfg *cfg = atgetifacecfg(iface); uint8_t data[4]; struct i2c_master_packet packet = { .address = cfg->atcai2c.slave_address >> 1, .data_length = 1, .data = data, }; data[0] = 0x01; // sleep word address value if (i2c_master_write_packet_wait(&(i2c_hal_data[cfg->atcai2c.bus].i2c_master_instance), &packet) != STATUS_OK) { return ATCA_COMM_FAIL; } return ATCA_SUCCESS; } /** \brief manages reference count on given bus and releases resource if no more references exist * \param[in] hal_data - opaque pointer to hal data structure - known only to the HAL implementation * \return ATCA_SUCCESS */ ATCA_STATUS hal_i2c_release(void *hal_data) { ATCAI2CMaster_t *hal = (ATCAI2CMaster_t*)hal_data; // if the use count for this bus has gone to 0 references, disable it. protect against an unbracketed release if (hal && --(hal->ref_ct) <= 0) { i2c_master_reset(&(hal->i2c_master_instance)); hal->ref_ct = 0; } return ATCA_SUCCESS; } /** @} */