/* * Copyright (c) 2016 - 2021, Broadcom * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include /* Max instances */ #define MAX_I2C 2U /* Transaction error codes defined in Master command register (0x30) */ #define MSTR_STS_XACT_SUCCESS 0U #define MSTR_STS_LOST_ARB 1U #define MSTR_STS_NACK_FIRST_BYTE 2U /* NACK on a byte other than the first byte */ #define MSTR_STS_NACK_NON_FIRST_BYTE 3U #define MSTR_STS_TTIMEOUT_EXCEEDED 4U #define MSTR_STS_TX_TLOW_MEXT_EXCEEDED 5U #define MSTR_STS_RX_TLOW_MEXT_EXCEEDED 6U /* SMBUS protocol values defined in register 0x30 */ #define SMBUS_PROT_QUICK_CMD 0U #define SMBUS_PROT_SEND_BYTE 1U #define SMBUS_PROT_RECV_BYTE 2U #define SMBUS_PROT_WR_BYTE 3U #define SMBUS_PROT_RD_BYTE 4U #define SMBUS_PROT_WR_WORD 5U #define SMBUS_PROT_RD_WORD 6U #define SMBUS_PROT_BLK_WR 7U #define SMBUS_PROT_BLK_RD 8U #define SMBUS_PROT_PROC_CALL 9U #define SMBUS_PROT_BLK_WR_BLK_RD_PROC_CALL 10U /* Number can be changed later */ #define BUS_BUSY_COUNT 100000U #define IPROC_I2C_INVALID_ADDR 0xFFU #define I2C_SMBUS_BLOCK_MAX 32U /* * Enum to specify clock speed. The user will provide it during initialization. * If needed, it can be changed dynamically */ typedef enum iproc_smb_clk_freq { IPROC_SMB_SPEED_100KHz = 0, IPROC_SMB_SPEED_400KHz = 1, IPROC_SMB_SPEED_INVALID = 255 } smb_clk_freq_t; /* Structure used to pass information to read/write functions. */ struct iproc_xact_info { /* Bus Identifier */ uint32_t bus_id; /* Device Address */ uint8_t devaddr; /* Passed by caller to send SMBus command cod e*/ uint8_t command; /* actual data passed by the caller */ uint8_t *data; /* Size of data buffer passed */ uint32_t size; /* Sent by caller specifying PEC, 10-bit addresses */ uint16_t flags; /* SMBus protocol to use to perform transaction */ uint8_t smb_proto; /* true if command field below is valid. Otherwise, false */ uint32_t cmd_valid; }; static const uintptr_t smbus_base_reg_addr[MAX_I2C] = { SMBUS0_REGS_BASE, SMBUS1_REGS_BASE }; /* Function to read a value from specified register. */ static uint32_t iproc_i2c_reg_read(uint32_t bus_id, unsigned long reg_addr) { uint32_t val; uintptr_t smbus; smbus = smbus_base_reg_addr[bus_id]; val = mmio_read_32(smbus + reg_addr); VERBOSE("i2c %u: reg %p read 0x%x\n", bus_id, (void *)(smbus + reg_addr), val); return val; } /* Function to write a value ('val') in to a specified register. */ static void iproc_i2c_reg_write(uint32_t bus_id, unsigned long reg_addr, uint32_t val) { uintptr_t smbus; smbus = smbus_base_reg_addr[bus_id]; mmio_write_32((smbus + reg_addr), val); VERBOSE("i2c %u: reg %p wrote 0x%x\n", bus_id, (void *)(smbus + reg_addr), val); } /* Function to clear and set bits in a specified register. */ static void iproc_i2c_reg_clearset(uint32_t bus_id, unsigned long reg_addr, uint32_t clear, uint32_t set) { uintptr_t smbus; smbus = smbus_base_reg_addr[bus_id]; mmio_clrsetbits_32((smbus + reg_addr), clear, set); VERBOSE("i2c %u: reg %p clear 0x%x, set 0x%x\n", bus_id, (void *)(smbus + reg_addr), clear, set); } /* Function to dump all SMBUS register */ #ifdef BCM_I2C_DEBUG static int iproc_dump_i2c_regs(uint32_t bus_id) { uint32_t regval; if (bus_id > MAX_I2C) { return -1; } INFO("----------------------------------------------\n"); INFO("%s: Dumping SMBus %u registers...\n", __func__, bus_id); regval = iproc_i2c_reg_read(bus_id, SMB_CFG_REG); INFO("SMB_CFG_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_TIMGCFG_REG); INFO("SMB_TIMGCFG_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_ADDR_REG); INFO("SMB_ADDR_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_MSTRFIFOCTL_REG); INFO("SMB_MSTRFIFOCTL_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_SLVFIFOCTL_REG); INFO("SMB_SLVFIFOCTL_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_BITBANGCTL_REG); INFO("SMB_BITBANGCTL_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_MSTRCMD_REG); INFO("SMB_MSTRCMD_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_SLVCMD_REG); INFO("SMB_SLVCMD_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_EVTEN_REG); INFO("SMB_EVTEN_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_EVTSTS_REG); INFO("SMB_EVTSTS_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_MSTRDATAWR_REG); INFO("SMB_MSTRDATAWR_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_MSTRDATARD_REG); INFO("SMB_MSTRDATARD_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_SLVDATAWR_REG); INFO("SMB_SLVDATAWR_REG=0x%x\n", regval); regval = iproc_i2c_reg_read(bus_id, SMB_SLVDATARD_REG); INFO("SMB_SLVDATARD_REG=0x%x\n", regval); INFO("----------------------------------------------\n"); return 0; } #endif /* * Function to ensure that the previous transaction was completed before * initiating a new transaction. It can also be used in polling mode to * check status of completion of a command */ static int iproc_i2c_startbusy_wait(uint32_t bus_id) { uint32_t regval; uint32_t retry = 0U; /* * Check if an operation is in progress. During probe it won't be. * Want to make sure that the transaction in progress is completed. */ do { udelay(1U); regval = iproc_i2c_reg_read(bus_id, SMB_MSTRCMD_REG); regval &= SMB_MSTRSTARTBUSYCMD_MASK; if (retry++ > BUS_BUSY_COUNT) { ERROR("%s: START_BUSY bit didn't clear, exiting\n", __func__); return -1; } } while (regval != 0U); return 0; } /* * This function copies data to SMBus's Tx FIFO. Valid for write transactions * info: Data to copy in to Tx FIFO. For read commands, the size should be * set to zero by the caller */ static void iproc_i2c_write_trans_data(struct iproc_xact_info *info) { uint32_t regval; uint8_t devaddr; uint32_t i; uint32_t num_data_bytes = 0U; #ifdef BCM_I2C_DEBUG INFO("%s:dev_addr=0x%x,cmd_valid=%d, cmd=0x%x, size=%u proto=%d\n", __func__, info->devaddr, info->cmd_valid, info->command, info->size, info->smb_proto); #endif /* Shift devaddr by 1 bit since SMBus uses the low bit[0] for R/W_n */ devaddr = (info->devaddr << 1); /* * Depending on the SMBus protocol, we need to write additional * transaction data in to Tx FIFO. Refer to section 5.5 of SMBus spec * for sequence for a transaction */ switch (info->smb_proto) { case SMBUS_PROT_RECV_BYTE: /* No additional data to be written */ iproc_i2c_reg_write(info->bus_id, SMB_MSTRDATAWR_REG, devaddr | 0x1U | SMB_MSTRWRSTS_MASK); break; case SMBUS_PROT_SEND_BYTE: num_data_bytes = info->size; iproc_i2c_reg_write(info->bus_id, SMB_MSTRDATAWR_REG, devaddr); break; case SMBUS_PROT_RD_BYTE: case SMBUS_PROT_RD_WORD: case SMBUS_PROT_BLK_RD: /* Write slave address with R/W~ set (bit #0) */ iproc_i2c_reg_write(info->bus_id, SMB_MSTRDATAWR_REG, devaddr | 0x1U); break; case SMBUS_PROT_BLK_WR_BLK_RD_PROC_CALL: iproc_i2c_reg_write(info->bus_id, SMB_MSTRDATAWR_REG, devaddr | 0x1U | SMB_MSTRWRSTS_MASK); break; case SMBUS_PROT_WR_BYTE: case SMBUS_PROT_WR_WORD: iproc_i2c_reg_write(info->bus_id, SMB_MSTRDATAWR_REG, devaddr); /* * No additional bytes to be written. Data portion is written * in the 'for' loop below */ num_data_bytes = info->size; break; case SMBUS_PROT_BLK_WR: iproc_i2c_reg_write(info->bus_id, SMB_MSTRDATAWR_REG, devaddr); /* 3rd byte is byte count */ iproc_i2c_reg_write(info->bus_id, SMB_MSTRDATAWR_REG, info->size); num_data_bytes = info->size; break; default: return; } /* If the protocol needs command code, copy it */ if (info->cmd_valid) { iproc_i2c_reg_write(info->bus_id, SMB_MSTRDATAWR_REG, info->command); } /* * Copy actual data from caller. In general, for reads, * no data is copied. */ for (i = 0U; num_data_bytes; --num_data_bytes, i++) { /* For the last byte, set MASTER_WR_STATUS bit */ regval = (num_data_bytes == 1U) ? info->data[i] | SMB_MSTRWRSTS_MASK : info->data[i]; iproc_i2c_reg_write(info->bus_id, SMB_MSTRDATAWR_REG, regval); } } /* * This function writes to the master command register and * then polls for completion */ static int iproc_i2c_write_master_command(uint32_t mastercmd, struct iproc_xact_info *info) { uint32_t retry = 0U; uint32_t regval; iproc_i2c_reg_write(info->bus_id, SMB_MSTRCMD_REG, mastercmd); /* Check for Master Busy status */ regval = iproc_i2c_reg_read(info->bus_id, SMB_MSTRCMD_REG); while ((regval & SMB_MSTRSTARTBUSYCMD_MASK) != 0U) { udelay(1U); if (retry++ > BUS_BUSY_COUNT) { ERROR("%s: START_BUSY bit didn't clear, exiting\n", __func__); return -1; } regval = iproc_i2c_reg_read(info->bus_id, SMB_MSTRCMD_REG); } /* If start_busy bit cleared, check if there are any errors */ if (!(regval & SMB_MSTRSTARTBUSYCMD_MASK)) { /* start_busy bit cleared, check master_status field now */ regval &= SMB_MSTRSTS_MASK; regval >>= SMB_MSTRSTS_SHIFT; if (regval != MSTR_STS_XACT_SUCCESS) { /* Error We can flush Tx FIFO here */ ERROR("%s: ERROR: %u exiting\n", __func__, regval); return -1; } } return 0; } /* Function to initiate data send and verify completion status */ static int iproc_i2c_data_send(struct iproc_xact_info *info) { int rc; uint32_t mastercmd; /* Make sure the previous transaction completed */ rc = iproc_i2c_startbusy_wait(info->bus_id); if (rc < 0) { WARN("%s: Send: bus is busy, exiting\n", __func__); return rc; } /* Write transaction bytes to Tx FIFO */ iproc_i2c_write_trans_data(info); /* * Program master command register (0x30) with protocol type and set * start_busy_command bit to initiate the write transaction */ mastercmd = (info->smb_proto << SMB_MSTRSMBUSPROTO_SHIFT) | SMB_MSTRSTARTBUSYCMD_MASK; if (iproc_i2c_write_master_command(mastercmd, info)) { return -1; } return 0; } /* * Function to initiate data receive, verify completion status, * and read from SMBUS Read FIFO */ static int iproc_i2c_data_recv(struct iproc_xact_info *info, uint32_t *num_bytes_read) { int rc; uint32_t mastercmd; uint32_t regval; /* Make sure the previous transaction completed */ rc = iproc_i2c_startbusy_wait(info->bus_id); if (rc < 0) { WARN("%s: Receive: Bus is busy, exiting\n", __func__); return rc; } /* Program all transaction bytes into master Tx FIFO */ iproc_i2c_write_trans_data(info); /* * Program master command register (0x30) with protocol type and set * start_busy_command bit to initiate the write transaction */ mastercmd = (info->smb_proto << SMB_MSTRSMBUSPROTO_SHIFT) | SMB_MSTRSTARTBUSYCMD_MASK | info->size; if (iproc_i2c_write_master_command(mastercmd, info)) { return -1; } /* Read received byte(s), after TX out address etc */ regval = iproc_i2c_reg_read(info->bus_id, SMB_MSTRDATARD_REG); /* For block read, protocol (hw) returns byte count,as the first byte */ if (info->smb_proto == SMBUS_PROT_BLK_RD) { uint32_t i; *num_bytes_read = regval & SMB_MSTRRDDATA_MASK; /* * Limit to reading a max of 32 bytes only; just a safeguard. * If # bytes read is a number > 32, check transaction set up, * and contact hw engg. * Assumption: PEC is disabled */ for (i = 0U; (i < *num_bytes_read) && (i < I2C_SMBUS_BLOCK_MAX); i++) { /* Read Rx FIFO for data bytes */ regval = iproc_i2c_reg_read(info->bus_id, SMB_MSTRDATARD_REG); info->data[i] = regval & SMB_MSTRRDDATA_MASK; } } else { /* 1 Byte data */ *info->data = regval & SMB_MSTRRDDATA_MASK; *num_bytes_read = 1U; } return 0; } /* * This function set clock frequency for SMBus block. As per hardware * engineering, the clock frequency can be changed dynamically. */ static int iproc_i2c_set_clk_freq(uint32_t bus_id, smb_clk_freq_t freq) { uint32_t val; switch (freq) { case IPROC_SMB_SPEED_100KHz: val = 0U; break; case IPROC_SMB_SPEED_400KHz: val = 1U; break; default: return -1; } iproc_i2c_reg_clearset(bus_id, SMB_TIMGCFG_REG, SMB_TIMGCFG_MODE400_MASK, val << SMB_TIMGCFG_MODE400_SHIFT); return 0; } /* Helper function to fill the iproc_xact_info structure */ static void iproc_i2c_fill_info(struct iproc_xact_info *info, uint32_t bus_id, uint8_t devaddr, uint8_t cmd, uint8_t *value, uint8_t smb_proto, uint32_t cmd_valid) { info->bus_id = bus_id; info->devaddr = devaddr; info->command = (uint8_t)cmd; info->smb_proto = smb_proto; info->data = value; info->size = 1U; info->flags = 0U; info->cmd_valid = cmd_valid; } /* This function initializes the SMBUS */ static void iproc_i2c_init(uint32_t bus_id, int speed) { uint32_t regval; #ifdef BCM_I2C_DEBUG INFO("%s: Enter Init\n", __func__); #endif /* Put controller in reset */ regval = iproc_i2c_reg_read(bus_id, SMB_CFG_REG); regval |= BIT(SMB_CFG_RST_SHIFT); regval &= ~(BIT(SMB_CFG_SMBEN_SHIFT)); iproc_i2c_reg_write(bus_id, SMB_CFG_REG, regval); /* Wait 100 usec per spec */ udelay(100U); /* Bring controller out of reset */ regval &= ~(BIT(SMB_CFG_RST_SHIFT)); iproc_i2c_reg_write(bus_id, SMB_CFG_REG, regval); /* * Flush Tx, Rx FIFOs. Note we are setting the Rx FIFO threshold to 0. * May be OK since we are setting RX_EVENT and RX_FIFO_FULL interrupts */ regval = SMB_MSTRRXFIFOFLSH_MASK | SMB_MSTRTXFIFOFLSH_MASK; iproc_i2c_reg_write(bus_id, SMB_MSTRFIFOCTL_REG, regval); /* * Enable SMbus block. Note, we are setting MASTER_RETRY_COUNT to zero * since there will be only one master */ regval = iproc_i2c_reg_read(bus_id, SMB_CFG_REG); regval |= SMB_CFG_SMBEN_MASK; iproc_i2c_reg_write(bus_id, SMB_CFG_REG, regval); /* Wait a minimum of 50 Usec, as per SMB hw doc. But we wait longer */ mdelay(10U); /* If error then set default speed */ if (i2c_set_bus_speed(bus_id, speed)) { i2c_set_bus_speed(bus_id, I2C_SPEED_DEFAULT); } /* Disable intrs */ regval = 0x0U; iproc_i2c_reg_write(bus_id, SMB_EVTEN_REG, regval); /* Clear intrs (W1TC) */ regval = iproc_i2c_reg_read(bus_id, SMB_EVTSTS_REG); iproc_i2c_reg_write(bus_id, SMB_EVTSTS_REG, regval); #ifdef BCM_I2C_DEBUG iproc_dump_i2c_regs(bus_id); INFO("%s: Exit Init Successfully\n", __func__); #endif } /* * Function Name: i2c_init * * Description: * This function initializes the SMBUS. * * Parameters: * bus_id - I2C bus ID * speed - I2C bus speed in Hz * * Return: * 0 on success, or -1 on failure. */ int i2c_init(uint32_t bus_id, int speed) { if (bus_id > MAX_I2C) { WARN("%s: Invalid Bus %u\n", __func__, bus_id); return -1; } iproc_i2c_init(bus_id, speed); return 0U; } /* * Function Name: i2c_probe * * Description: * This function probes the I2C bus for the existence of the specified * device. * * Parameters: * bus_id - I2C bus ID * devaddr - Device Address * * Return: * 0 on success, or -1 on failure. */ int i2c_probe(uint32_t bus_id, uint8_t devaddr) { uint32_t regval; int rc; /* * i2c_init() Initializes internal regs, disable intrs (and then clear intrs), * set fifo thresholds, etc. * Shift devaddr by 1 bit since SMBus uses the low bit[0] for R/W_n */ regval = (devaddr << 1U); iproc_i2c_reg_write(bus_id, SMB_MSTRDATAWR_REG, regval); regval = ((SMBUS_PROT_QUICK_CMD << SMB_MSTRSMBUSPROTO_SHIFT) | SMB_MSTRSTARTBUSYCMD_MASK); iproc_i2c_reg_write(bus_id, SMB_MSTRCMD_REG, regval); rc = iproc_i2c_startbusy_wait(bus_id); if (rc < 0) { WARN("%s: Probe: bus is busy, exiting\n", __func__); return rc; } regval = iproc_i2c_reg_read(bus_id, SMB_MSTRCMD_REG); if (((regval & SMB_MSTRSTS_MASK) >> SMB_MSTRSTS_SHIFT) == 0) VERBOSE("i2c device address: 0x%x\n", devaddr); else return -1; #ifdef BCM_I2C_DEBUG iproc_dump_i2c_regs(bus_id); #endif return 0; } /* * Function Name: i2c_recv_byte * * Description: * This function reads I2C data from a device without specifying * a command regsiter. * * Parameters: * bus_id - I2C bus ID * devaddr - Device Address * value - Data Read * * Return: * 0 on success, or -1 on failure. */ int i2c_recv_byte(uint32_t bus_id, uint8_t devaddr, uint8_t *value) { int rc; struct iproc_xact_info info; uint32_t num_bytes_read = 0; iproc_i2c_fill_info(&info, bus_id, devaddr, 0U, value, SMBUS_PROT_RECV_BYTE, 0U); /* Refer to i2c_smbus_read_byte for params passed. */ rc = iproc_i2c_data_recv(&info, &num_bytes_read); if (rc < 0) { printf("%s: %s error accessing device 0x%x\n", __func__, "Read", devaddr); } return rc; } /* * Function Name: i2c_send_byte * * Description: * This function send I2C data to a device without specifying * a command regsiter. * * Parameters: * bus_id - I2C bus ID * devaddr - Device Address * value - Data Send * * Return: * 0 on success, or -1 on failure. */ int i2c_send_byte(uint32_t bus_id, uint8_t devaddr, uint8_t value) { int rc; struct iproc_xact_info info; iproc_i2c_fill_info(&info, bus_id, devaddr, 0U, &value, SMBUS_PROT_SEND_BYTE, 0U); /* Refer to i2c_smbus_write_byte params passed. */ rc = iproc_i2c_data_send(&info); if (rc < 0) { ERROR("%s: %s error accessing device 0x%x\n", __func__, "Write", devaddr); } return rc; } /* Helper function to read a single byte */ static int i2c_read_byte(uint32_t bus_id, uint8_t devaddr, uint8_t regoffset, uint8_t *value) { int rc; struct iproc_xact_info info; uint32_t num_bytes_read = 0U; iproc_i2c_fill_info(&info, bus_id, devaddr, regoffset, value, SMBUS_PROT_RD_BYTE, 1U); /* Refer to i2c_smbus_read_byte for params passed. */ rc = iproc_i2c_data_recv(&info, &num_bytes_read); if (rc < 0) { ERROR("%s: %s error accessing device 0x%x\n", __func__, "Read", devaddr); } return rc; } /* * Function Name: i2c_read * * Description: * This function reads I2C data from a device with a designated * command register * * Parameters: * bus_id - I2C bus ID * devaddr - Device Address * addr - Register Offset * alen - Address Length, 1 for byte, 2 for word (not supported) * buffer - Data Buffer * len - Data Length in bytes * * Return: * 0 on success, or -1 on failure. */ int i2c_read(uint32_t bus_id, uint8_t devaddr, uint32_t addr, int alen, uint8_t *buffer, int len) { uint32_t i; if (alen > 1) { WARN("I2C read: addr len %d not supported\n", alen); return -1; } if (addr + len > 256) { WARN("I2C read: address out of range\n"); return -1; } for (i = 0U; i < len; i++) { if (i2c_read_byte(bus_id, devaddr, addr + i, &buffer[i])) { ERROR("I2C read: I/O error\n"); iproc_i2c_init(bus_id, i2c_get_bus_speed(bus_id)); return -1; } } return 0; } /* Helper function to write a single byte */ static int i2c_write_byte(uint32_t bus_id, uint8_t devaddr, uint8_t regoffset, uint8_t value) { int rc; struct iproc_xact_info info; iproc_i2c_fill_info(&info, bus_id, devaddr, regoffset, &value, SMBUS_PROT_WR_BYTE, 1U); /* Refer to i2c_smbus_write_byte params passed. */ rc = iproc_i2c_data_send(&info); if (rc < 0) { ERROR("%s: %s error accessing device 0x%x\n", __func__, "Write", devaddr); return -1; } return 0; } /* * Function Name: i2c_write * * Description: * This function write I2C data to a device with a designated * command register * * Parameters: * bus_id - I2C bus ID * devaddr - Device Address * addr - Register Offset * alen - Address Length, 1 for byte, 2 for word (not supported) * buffer - Data Buffer * len - Data Length in bytes * * Return: * 0 on success, or -1 on failure. */ int i2c_write(uint32_t bus_id, uint8_t devaddr, uint32_t addr, int alen, uint8_t *buffer, int len) { uint32_t i; if (alen > 1) { WARN("I2C write: addr len %d not supported\n", alen); return -1; } if (addr + len > 256U) { WARN("I2C write: address out of range\n"); return -1; } for (i = 0U; i < len; i++) { if (i2c_write_byte(bus_id, devaddr, addr + i, buffer[i])) { ERROR("I2C write: I/O error\n"); iproc_i2c_init(bus_id, i2c_get_bus_speed(bus_id)); return -1; } } return 0; } /* * Function Name: i2c_set_bus_speed * * Description: * This function configures the SMBUS speed * * Parameters: * bus_id - I2C bus ID * speed - I2C bus speed in Hz * * Return: * 0 on success, or -1 on failure. */ int i2c_set_bus_speed(uint32_t bus_id, uint32_t speed) { switch (speed) { case I2C_SPEED_100KHz: iproc_i2c_set_clk_freq(bus_id, IPROC_SMB_SPEED_100KHz); break; case I2C_SPEED_400KHz: iproc_i2c_set_clk_freq(bus_id, IPROC_SMB_SPEED_400KHz); break; default: return -1; } return 0; } /* * Function Name: i2c_get_bus_speed * * Description: * This function returns the SMBUS speed. * * Parameters: * bus_id - I2C bus ID * * Return: * Bus speed in Hz, 0 on failure */ uint32_t i2c_get_bus_speed(uint32_t bus_id) { uint32_t regval; uint32_t retval = 0U; regval = iproc_i2c_reg_read(bus_id, SMB_TIMGCFG_REG); regval &= SMB_TIMGCFG_MODE400_MASK; regval >>= SMB_TIMGCFG_MODE400_SHIFT; switch (regval) { case IPROC_SMB_SPEED_100KHz: retval = I2C_SPEED_100KHz; break; case IPROC_SMB_SPEED_400KHz: retval = I2C_SPEED_400KHz; break; default: break; } return retval; }