/* Copyright (c) 2014 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ /* I2C port module for Chrome EC */ #include "clock.h" #include "clock_chip.h" #include "common.h" #include "console.h" #include "gpio.h" #include "hooks.h" #include "i2c.h" #include "i2c_chip.h" #include "registers.h" #include "task.h" #include "timer.h" #include "util.h" #if !(DEBUG_I2C) #define CPUTS(...) #define CPRINTS(...) #else #define CPUTS(outstr) cputs(CC_I2C, outstr) #define CPRINTS(format, args...) cprints(CC_I2C, format, ## args) #endif /* Timeout for device should be available after reset (SMBus spec. unit:ms) */ #define I2C_MAX_TIMEOUT 35 /* * Timeout for SCL held to low by slave device . (SMBus spec. unit:ms). * Some I2C devices may violate this timing and clock stretch for longer. * TODO: Consider increasing this timeout. */ #define I2C_MIN_TIMEOUT 25 /* Macro functions of I2C */ #define I2C_START(ctrl) SET_BIT(NPCX_SMBCTL1(ctrl), NPCX_SMBCTL1_START) #define I2C_STOP(ctrl) SET_BIT(NPCX_SMBCTL1(ctrl), NPCX_SMBCTL1_STOP) #define I2C_NACK(ctrl) SET_BIT(NPCX_SMBCTL1(ctrl), NPCX_SMBCTL1_ACK) #define I2C_STALL(ctrl) SET_BIT(NPCX_SMBCTL1(ctrl), NPCX_SMBCTL1_STASTRE) #define I2C_WRITE_BYTE(ctrl, data) (NPCX_SMBSDA(ctrl) = data) #define I2C_READ_BYTE(ctrl, data) (data = NPCX_SMBSDA(ctrl)) /* Error values that functions can return */ enum smb_error { SMB_OK = 0, /* No error */ SMB_CH_OCCUPIED, /* Channel is already occupied */ SMB_MEM_POOL_INIT_ERROR, /* Memory pool initialization error */ SMB_BUS_FREQ_ERROR, /* SMbus freq was not valid */ SMB_INVLAID_REGVALUE, /* Invalid SMbus register value */ SMB_UNEXIST_CH_ERROR, /* Channel does not exist */ SMB_NO_SUPPORT_PTL, /* Not support SMBus Protocol */ SMB_BUS_ERROR, /* Encounter bus error */ SMB_MASTER_NO_ADDRESS_MATCH,/* No slave address match (Master Mode)*/ SMB_READ_DATA_ERROR, /* Read data for SDA error */ SMB_READ_OVERFLOW_ERROR, /* Read data over than we predict */ SMB_TIMEOUT_ERROR, /* Timeout expired */ SMB_MODULE_ISBUSY, /* Module is occupied by other device */ SMB_BUS_BUSY, /* SMBus is occupied by other device */ }; /* * Internal SMBus Interface driver states values, which reflect events * which occurred on the bus */ enum smb_oper_state_t { SMB_IDLE, SMB_MASTER_START, SMB_WRITE_OPER, SMB_READ_OPER, SMB_DUMMY_READ_OPER, SMB_REPEAT_START, SMB_WRITE_SUSPEND, SMB_READ_SUSPEND, }; /* I2C controller state data */ struct i2c_status { int flags; /* Flags (I2C_XFER_*) */ const uint8_t *tx_buf; /* Entry pointer of transmit buffer */ uint8_t *rx_buf; /* Entry pointer of receive buffer */ uint16_t sz_txbuf; /* Size of Tx buffer in bytes */ uint16_t sz_rxbuf; /* Size of rx buffer in bytes */ uint16_t idx_buf; /* Current index of Tx/Rx buffer */ uint8_t slave_addr;/* Target slave address */ enum smb_oper_state_t oper_state;/* Smbus operation state */ enum smb_error err_code; /* Error code */ int task_waiting; /* Task waiting on controller */ uint32_t timeout_us;/* Transaction timeout */ }; /* I2C controller state data array */ struct i2c_status i2c_stsobjs[I2C_CONTROLLER_COUNT]; /* I2C timing setting */ struct i2c_timing { uint8_t clock; /* I2C source clock. (Unit: MHz)*/ uint8_t HLDT; /* I2C hold-time. (Unit: clocks) */ uint8_t k1; /* k1 = SCL low-time (Unit: clocks) */ uint8_t k2; /* k2 = SCL high-time (Unit: clocks) */ }; /* I2C timing setting array of 400K & 1M Hz */ static const struct i2c_timing i2c_400k_timings[] = { {20, 7, 32, 22}, {15, 7, 24, 18},}; const unsigned int i2c_400k_timing_used = ARRAY_SIZE(i2c_400k_timings); static const struct i2c_timing i2c_1m_timings[] = { {20, 7, 16, 10}, {15, 7, 14, 10},}; const unsigned int i2c_1m_timing_used = ARRAY_SIZE(i2c_1m_timings); /* IRQ for each port */ const uint32_t i2c_irqs[I2C_CONTROLLER_COUNT] = { NPCX_IRQ_SMB1, NPCX_IRQ_SMB2, NPCX_IRQ_SMB3, NPCX_IRQ_SMB4, #if defined(CHIP_FAMILY_NPCX7) NPCX_IRQ_SMB5, NPCX_IRQ_SMB6, NPCX_IRQ_SMB7, NPCX_IRQ_SMB8, #endif }; BUILD_ASSERT(ARRAY_SIZE(i2c_irqs) == I2C_CONTROLLER_COUNT); static void i2c_init_bus(int controller) { /* Enable module - before configuring CTL1 */ SET_BIT(NPCX_SMBCTL2(controller), NPCX_SMBCTL2_ENABLE); /* Enable SMB interrupt and New Address Match interrupt source */ SET_BIT(NPCX_SMBCTL1(controller), NPCX_SMBCTL1_NMINTE); SET_BIT(NPCX_SMBCTL1(controller), NPCX_SMBCTL1_INTEN); } int i2c_bus_busy(int controller) { return IS_BIT_SET(NPCX_SMBCST(controller), NPCX_SMBCST_BB) ? 1 : 0; } static int i2c_wait_stop_completed(int controller, int timeout) { if (timeout <= 0) return EC_ERROR_INVAL; /* Wait till STOP condition is generated. ie. I2C bus is idle. */ while (timeout > 0) { if (!IS_BIT_SET(NPCX_SMBCTL1(controller), NPCX_SMBCTL1_STOP)) break; if (--timeout > 0) msleep(1); } if (timeout) return EC_SUCCESS; else return EC_ERROR_TIMEOUT; } static void i2c_abort_data(int controller) { /* Clear NEGACK, STASTR and BER bits */ SET_BIT(NPCX_SMBST(controller), NPCX_SMBST_BER); SET_BIT(NPCX_SMBST(controller), NPCX_SMBST_STASTR); SET_BIT(NPCX_SMBST(controller), NPCX_SMBST_NEGACK); /* Wait till STOP condition is generated */ if (i2c_wait_stop_completed(controller, I2C_MAX_TIMEOUT) != EC_SUCCESS) { cprintf(CC_I2C, "Abort i2c %02x fail!\n", controller); /* Clear BB (BUS BUSY) bit */ SET_BIT(NPCX_SMBCST(controller), NPCX_SMBCST_BB); return; } /* Clear BB (BUS BUSY) bit */ SET_BIT(NPCX_SMBCST(controller), NPCX_SMBCST_BB); } static int i2c_reset(int controller) { uint16_t timeout = I2C_MAX_TIMEOUT; /* Disable the SMB module */ CLEAR_BIT(NPCX_SMBCTL2(controller), NPCX_SMBCTL2_ENABLE); while (--timeout) { /* WAIT FOR SCL & SDA IS HIGH */ if (IS_BIT_SET(NPCX_SMBCTL3(controller), NPCX_SMBCTL3_SCL_LVL) && IS_BIT_SET(NPCX_SMBCTL3(controller), NPCX_SMBCTL3_SDA_LVL)) break; msleep(1); } if (timeout == 0) { cprintf(CC_I2C, "Reset i2c %02x fail!\n", controller); return 0; } /* Init the SMB module again */ i2c_init_bus(controller); return 1; } static void i2c_recovery(int controller, volatile struct i2c_status *p_status) { CPRINTS("i2c %d recovery! error code is %d, current state is %d", controller, p_status->err_code, p_status->oper_state); /* Abort data, wait for STOP condition completed. */ i2c_abort_data(controller); /* Reset i2c controller by re-enable i2c controller*/ if (!i2c_reset(controller)) return; /* Restore to idle status */ p_status->oper_state = SMB_IDLE; } enum smb_error i2c_master_transaction(int controller) { /* Set i2c mode to object */ int events = 0; volatile struct i2c_status *p_status = i2c_stsobjs + controller; /* Assign current SMB status of controller */ if (p_status->oper_state == SMB_IDLE) { /* New transaction */ p_status->oper_state = SMB_MASTER_START; } else if (p_status->oper_state == SMB_WRITE_SUSPEND) { if (p_status->sz_txbuf == 0) { /* Read bytes from next transaction */ p_status->oper_state = SMB_REPEAT_START; CPUTS("R"); } else { /* Continue to write the other bytes */ p_status->oper_state = SMB_WRITE_OPER; I2C_WRITE_BYTE(controller, p_status->tx_buf[p_status->idx_buf++]); CPRINTS("-W(%02x)", p_status->tx_buf[p_status->idx_buf-1]); } } else if (p_status->oper_state == SMB_READ_SUSPEND) { /* * Do dummy read if read length is 1 and I2C_XFER_STOP is set * simultaneously. */ if (p_status->sz_rxbuf == 1 && (p_status->flags & I2C_XFER_STOP)) { /* * Since SCL is released after reading last byte from * previous transaction, adding a dummy byte for next * transaction which let ec sets NACK bit in time is * necessary. Or i2c master cannot generate STOP * when the last byte is ACK during receiving. */ p_status->sz_rxbuf++; p_status->oper_state = SMB_DUMMY_READ_OPER; } else /* Need to read the other bytes from next transaction */ p_status->oper_state = SMB_READ_OPER; } else cprintf(CC_I2C, "Unexpected i2c state machine! %d\n", p_status->oper_state); /* Generate a START condition */ if (p_status->oper_state == SMB_MASTER_START || p_status->oper_state == SMB_REPEAT_START) { I2C_START(controller); CPUTS("ST"); } /* Enable event and error interrupts */ task_enable_irq(i2c_irqs[controller]); /* Wait for transfer complete or timeout */ events = task_wait_event_mask(TASK_EVENT_I2C_IDLE, p_status->timeout_us); /* Disable event and error interrupts */ task_disable_irq(i2c_irqs[controller]); /* * If Stall-After-Start mode is still enabled since NACK or BUS error * occurs, disable it. */ if (IS_BIT_SET(NPCX_SMBCTL1(controller), NPCX_SMBCTL1_STASTRE)) CLEAR_BIT(NPCX_SMBCTL1(controller), NPCX_SMBCTL1_STASTRE); /* Handle bus timeout */ if ((events & TASK_EVENT_I2C_IDLE) == 0) { p_status->err_code = SMB_TIMEOUT_ERROR; /* Recovery I2C controller */ i2c_recovery(controller, p_status); } /* Recovery bus if we encounter bus error */ else if (p_status->err_code == SMB_BUS_ERROR) i2c_recovery(controller, p_status); /* Wait till STOP condition is generated for normal transaction */ if (p_status->err_code == SMB_OK && i2c_wait_stop_completed(controller, I2C_MIN_TIMEOUT) != EC_SUCCESS) { cprintf(CC_I2C, "STOP fail! scl %02x is held by slave device!\n", controller); p_status->err_code = SMB_TIMEOUT_ERROR; } return p_status->err_code; } /* Issue stop condition if necessary and end transaction */ void i2c_done(int controller) { volatile struct i2c_status *p_status = i2c_stsobjs + controller; /* need to STOP or not */ if (p_status->flags & I2C_XFER_STOP) { /* Issue a STOP condition on the bus */ I2C_STOP(controller); CPUTS("-SP"); /* Clear SDAST by writing dummy byte */ I2C_WRITE_BYTE(controller, 0xFF); } /* Set error code */ p_status->err_code = SMB_OK; /* Set SMB status if we need stall bus */ p_status->oper_state = (p_status->flags & I2C_XFER_STOP) ? SMB_IDLE : SMB_WRITE_SUSPEND; /* * Disable interrupt for i2c master stall SCL * and forbid SDAST generate interrupt * until common layer start other transactions */ if (p_status->oper_state == SMB_WRITE_SUSPEND) task_disable_irq(i2c_irqs[controller]); /* Notify upper layer */ task_set_event(p_status->task_waiting, TASK_EVENT_I2C_IDLE, 0); CPUTS("-END"); } static void i2c_handle_sda_irq(int controller) { volatile struct i2c_status *p_status = i2c_stsobjs + controller; /* 1 Issue Start is successful ie. write address byte */ if (p_status->oper_state == SMB_MASTER_START || p_status->oper_state == SMB_REPEAT_START) { uint8_t addr = p_status->slave_addr; /* Prepare address byte */ if (p_status->sz_txbuf == 0) {/* Receive mode */ p_status->oper_state = SMB_READ_OPER; /* * Receiving one or zero bytes - stall bus after START * condition. If there's no slave devices on bus, FW * needn't to set ACK bit. */ if (p_status->sz_rxbuf < 2) I2C_STALL(controller); /* Write the address to the bus R bit*/ I2C_WRITE_BYTE(controller, (addr | 0x1)); CPRINTS("-ARR-0x%02x", addr); } else {/* Transmit mode */ p_status->oper_state = SMB_WRITE_OPER; /* Write the address to the bus W bit*/ I2C_WRITE_BYTE(controller, addr); CPRINTS("-ARW-0x%02x", addr); } /* Completed handling START condition */ return; } /* 2 Handle master write operation */ else if (p_status->oper_state == SMB_WRITE_OPER) { /* all bytes have been written, in a pure write operation */ if (p_status->idx_buf == p_status->sz_txbuf) { /* no more message */ if (p_status->sz_rxbuf == 0) i2c_done(controller); /* need to restart & send slave address immediately */ else { uint8_t addr_byte = p_status->slave_addr; /* * Prepare address byte * and start to receive bytes */ p_status->oper_state = SMB_READ_OPER; /* Reset index of buffer */ p_status->idx_buf = 0; /* * Generate (Repeated) Start * upon next write to SDA */ I2C_START(controller); CPUTS("-RST"); /* * Receiving one byte only - set nack just * before writing address byte */ if (p_status->sz_rxbuf == 1 && (p_status->flags & I2C_XFER_STOP)) { I2C_NACK(controller); CPUTS("-GNA"); } /* Write the address to the bus R bit*/ I2C_WRITE_BYTE(controller, (addr_byte | 0x1)); CPUTS("-ARR"); } } /* write next byte (not last byte and not slave address */ else { I2C_WRITE_BYTE(controller, p_status->tx_buf[p_status->idx_buf++]); CPRINTS("-W(%02x)", p_status->tx_buf[p_status->idx_buf-1]); } } /* 3 Handle master read operation (read or after a write operation) */ else if (p_status->oper_state == SMB_READ_OPER || p_status->oper_state == SMB_DUMMY_READ_OPER) { uint8_t data; /* last byte is about to be read - end of transaction */ if (p_status->idx_buf == (p_status->sz_rxbuf - 1)) { /* need to STOP or not */ if (p_status->flags & I2C_XFER_STOP) { /* Stop should set before reading last byte */ I2C_STOP(controller); CPUTS("-SP"); } else { /* * Disable interrupt before i2c master read SDA * reg (stall SCL) and forbid SDAST generate * interrupt until starting other transactions */ task_disable_irq(i2c_irqs[controller]); } } /* Check if byte-before-last is about to be read */ else if (p_status->idx_buf == (p_status->sz_rxbuf - 2)) { /* * Set nack before reading byte-before-last, * so that nack will be generated after receive * of last byte */ if (p_status->flags & I2C_XFER_STOP) { I2C_NACK(controller); CPUTS("-GNA"); } } /* Read data for SMBSDA */ I2C_READ_BYTE(controller, data); CPRINTS("-R(%02x)", data); /* Read to buf. Skip last byte if meet SMB_DUMMY_READ_OPER */ if (p_status->oper_state == SMB_DUMMY_READ_OPER && p_status->idx_buf == (p_status->sz_rxbuf - 1)) p_status->idx_buf++; else p_status->rx_buf[p_status->idx_buf++] = data; /* last byte is read - end of transaction */ if (p_status->idx_buf == p_status->sz_rxbuf) { /* Set current status */ p_status->oper_state = (p_status->flags & I2C_XFER_STOP) ? SMB_IDLE : SMB_READ_SUSPEND; /* Set error code */ p_status->err_code = SMB_OK; /* Notify upper layer of missing data */ task_set_event(p_status->task_waiting, TASK_EVENT_I2C_IDLE, 0); CPUTS("-END"); } } } void i2c_master_int_handler (int controller) { volatile struct i2c_status *p_status = i2c_stsobjs + controller; /* Condition 1 : A Bus Error has been identified */ if (IS_BIT_SET(NPCX_SMBST(controller), NPCX_SMBST_BER)) { uint8_t __attribute__((unused)) data; /* Generate a STOP condition */ I2C_STOP(controller); CPUTS("-SP"); /* Clear BER Bit */ SET_BIT(NPCX_SMBST(controller), NPCX_SMBST_BER); /* Mask sure slave doesn't hold bus by dummy reading */ I2C_READ_BYTE(controller, data); /* Set error code */ p_status->err_code = SMB_BUS_ERROR; /* Notify upper layer */ p_status->oper_state = SMB_IDLE; task_set_event(p_status->task_waiting, TASK_EVENT_I2C_IDLE, 0); CPUTS("-BER"); /* * Disable smb's interrupts to forbid ec to enter ISR again * before executing error recovery. */ task_disable_irq(i2c_irqs[controller]); /* return for executing error recovery immediately */ return; } /* Condition 2: A negative acknowledge has occurred */ if (IS_BIT_SET(NPCX_SMBST(controller), NPCX_SMBST_NEGACK)) { /* Generate a STOP condition */ I2C_STOP(controller); CPUTS("-SP"); /* Clear NEGACK Bit */ SET_BIT(NPCX_SMBST(controller), NPCX_SMBST_NEGACK); /* Set error code */ p_status->err_code = SMB_MASTER_NO_ADDRESS_MATCH; /* Notify upper layer */ p_status->oper_state = SMB_IDLE; task_set_event(p_status->task_waiting, TASK_EVENT_I2C_IDLE, 0); CPUTS("-NA"); } /* Condition 3: A Stall after START has occurred for READ-BYTE */ if (IS_BIT_SET(NPCX_SMBST(controller), NPCX_SMBST_STASTR)) { CPUTS("-STL"); /* Disable Stall-After-Start mode first */ CLEAR_BIT(NPCX_SMBCTL1(controller), NPCX_SMBCTL1_STASTRE); /* * Generate stop condition and return success status since * ACK received on zero-byte transaction. */ if (p_status->sz_rxbuf == 0) i2c_done(controller); /* * Otherwise we have a one-byte transaction, so nack after * receiving next byte, if requested. */ else if (p_status->flags & I2C_XFER_STOP) I2C_NACK(controller); /* Clear STASTR to release SCL after setting NACK/STOP bits */ SET_BIT(NPCX_SMBST(controller), NPCX_SMBST_STASTR); } /* Condition 4: SDA status is set - transmit or receive */ if (IS_BIT_SET(NPCX_SMBST(controller), NPCX_SMBST_SDAST)) { i2c_handle_sda_irq(controller); #if DEBUG_I2C /* SDAST still issued with unexpected state machine */ if (IS_BIT_SET(NPCX_SMBST(controller), NPCX_SMBST_SDAST) && p_status->oper_state != SMB_WRITE_SUSPEND) { cprints(CC_I2C, "i2c %d unknown state %d, error %d\n", controller, p_status->oper_state, p_status->err_code); } #endif } } /** * Handle an interrupt on the specified controller. * * @param controller I2C controller generating interrupt */ void handle_interrupt(int controller) { i2c_master_int_handler(controller); } void i2c0_interrupt(void) { handle_interrupt(0); } void i2c1_interrupt(void) { handle_interrupt(1); } void i2c2_interrupt(void) { handle_interrupt(2); } void i2c3_interrupt(void) { handle_interrupt(3); } #if defined(CHIP_FAMILY_NPCX7) void i2c4_interrupt(void) { handle_interrupt(4); } void i2c5_interrupt(void) { handle_interrupt(5); } void i2c6_interrupt(void) { handle_interrupt(6); } void i2c7_interrupt(void) { handle_interrupt(7); } #endif DECLARE_IRQ(NPCX_IRQ_SMB1, i2c0_interrupt, 4); DECLARE_IRQ(NPCX_IRQ_SMB2, i2c1_interrupt, 4); DECLARE_IRQ(NPCX_IRQ_SMB3, i2c2_interrupt, 4); DECLARE_IRQ(NPCX_IRQ_SMB4, i2c3_interrupt, 4); #if defined(CHIP_FAMILY_NPCX7) DECLARE_IRQ(NPCX_IRQ_SMB5, i2c4_interrupt, 4); DECLARE_IRQ(NPCX_IRQ_SMB6, i2c5_interrupt, 4); DECLARE_IRQ(NPCX_IRQ_SMB7, i2c6_interrupt, 4); DECLARE_IRQ(NPCX_IRQ_SMB8, i2c7_interrupt, 4); #endif /*****************************************************************************/ /* IC specific low-level driver */ void i2c_set_timeout(int port, uint32_t timeout) { int ctrl = i2c_port_to_controller(port); /* Return if i2c_port_to_controller() returned an error */ if (ctrl < 0) return; /* Param is port, but timeout is stored by-controller. */ i2c_stsobjs[ctrl].timeout_us = timeout ? timeout : I2C_TIMEOUT_DEFAULT_US; } int chip_i2c_xfer(int port, int slave_addr, const uint8_t *out, int out_size, uint8_t *in, int in_size, int flags) { volatile struct i2c_status *p_status; int ctrl = i2c_port_to_controller(port); /* Return error if i2c_port_to_controller() returned an error */ if (ctrl < 0) return EC_ERROR_INVAL; /* Skip unnecessary transaction */ if (out_size == 0 && in_size == 0) return EC_SUCCESS; p_status = i2c_stsobjs + ctrl; /* Assign current task ID */ p_status->task_waiting = task_get_current(); /* Select port for multi-ports i2c controller */ i2c_select_port(port); /* Copy data to controller struct */ p_status->flags = flags; p_status->tx_buf = out; p_status->sz_txbuf = out_size; p_status->rx_buf = in; p_status->sz_rxbuf = in_size; #if I2C_7BITS_ADDR /* Set slave address from 7-bits to 8-bits */ p_status->slave_addr = (slave_addr<<1); #else /* Set slave address (8-bits) */ p_status->slave_addr = slave_addr; #endif /* Reset index & error */ p_status->idx_buf = 0; p_status->err_code = SMB_OK; /* Make sure we're in a good state to start */ if ((flags & I2C_XFER_START) && /* Ignore busy bus for repeated start */ p_status->oper_state != SMB_WRITE_SUSPEND && (i2c_bus_busy(ctrl) || (i2c_get_line_levels(port) != I2C_LINE_IDLE))) { int ret; /* Attempt to unwedge the i2c port */ ret = i2c_unwedge(port); if (ret) return ret; p_status->err_code = SMB_BUS_BUSY; /* recover i2c controller */ i2c_recovery(ctrl, p_status); /* Select port again for recovery */ i2c_select_port(port); } CPUTS("\n"); /* Start master transaction */ i2c_master_transaction(ctrl); /* Reset task ID */ p_status->task_waiting = TASK_ID_INVALID; CPRINTS("-Err:0x%02x\n", p_status->err_code); return (p_status->err_code == SMB_OK) ? EC_SUCCESS : EC_ERROR_UNKNOWN; } /** * Return raw I/O line levels (I2C_LINE_*) for a port when port is in alternate * function mode. * * @param port Port to check * @return State of SCL/SDA bit 0/1 */ int i2c_get_line_levels(int port) { return (i2c_raw_get_sda(port) ? I2C_LINE_SDA_HIGH : 0) | (i2c_raw_get_scl(port) ? I2C_LINE_SCL_HIGH : 0); } int i2c_raw_get_scl(int port) { enum gpio_signal g; /* * Check do we support this port of i2c and return gpio number of scl. * Please notice we cannot read voltage level from GPIO in M4 EC */ if (get_scl_from_i2c_port(port, &g) == EC_SUCCESS) { if (i2c_is_raw_mode(port)) return gpio_get_level(g); else return IS_BIT_SET(NPCX_SMBCTL3( i2c_port_to_controller(port)), NPCX_SMBCTL3_SCL_LVL); } /* If no SCL pin defined for this port, then return 1 to appear idle */ return 1; } int i2c_raw_get_sda(int port) { enum gpio_signal g; /* * Check do we support this port of i2c and return gpio number of scl. * Please notice we cannot read voltage level from GPIO in M4 EC */ if (get_sda_from_i2c_port(port, &g) == EC_SUCCESS) { if (i2c_is_raw_mode(port)) return gpio_get_level(g); else return IS_BIT_SET(NPCX_SMBCTL3( i2c_port_to_controller(port)), NPCX_SMBCTL3_SDA_LVL); } /* If no SDA pin defined for this port, then return 1 to appear idle */ return 1; } /*****************************************************************************/ /* Hooks */ static void i2c_freq_changed(void) { int freq, i, j; for (i = 0; i < i2c_ports_used; i++) { int bus_freq = i2c_ports[i].kbps; int ctrl = i2c_port_to_controller(i2c_ports[i].port); int scl_freq; if (ctrl < 2) #if defined(CHIP_FAMILY_NPCX7) /* SMB0/1 use APB3 clock */ freq = clock_get_apb3_freq(); #else /* SMB0/1 use core clock */ freq = clock_get_freq(); #endif else /* Other SMB controller use APB2 clock */ freq = clock_get_apb2_freq(); /* * Set SCL frequency by formula: * tSCL = 4 * SCLFRQ * tCLK * fSCL = fCLK / (4*SCLFRQ) * SCLFRQ = fSCL/(4*fSCL) */ scl_freq = (freq/1000) / (bus_freq*4); /* bus_freq is KHz */ /* Normal mode if i2c freq is under 100kHz */ if (bus_freq <= 100) { /* Set divider value of SCL */ SET_FIELD(NPCX_SMBCTL2(ctrl), NPCX_SMBCTL2_SCLFRQ7_FIELD , (scl_freq & 0x7F)); SET_FIELD(NPCX_SMBCTL3(ctrl), NPCX_SMBCTL3_SCLFRQ2_FIELD , (scl_freq >> 7)); } else { const struct i2c_timing *pTiming; int i2c_timing_used; /* use Fast Mode */ SET_BIT(NPCX_SMBCTL3(ctrl) , NPCX_SMBCTL3_400K); /* * Set SCLH(L)T and hold-time directly for best i2c * timing condition for all source clocks. Please refer * Section 7.5.9 "SMBus Timing - Fast Mode" for detail. */ if (bus_freq == 400) { pTiming = i2c_400k_timings; i2c_timing_used = i2c_400k_timing_used; } else if (bus_freq == 1000) { pTiming = i2c_1m_timings; i2c_timing_used = i2c_1m_timing_used; } else { /* Set value from formula */ NPCX_SMBSCLLT(ctrl) = scl_freq; NPCX_SMBSCLHT(ctrl) = scl_freq; cprints(CC_I2C, "Warning: Use 400K or 1MHz", "for better timing of I2c %d", ctrl); continue; } for (j = 0; j < i2c_timing_used; j++, pTiming++) { if (pTiming->clock == (freq/SECOND)) { /* Set SCLH(L)T and hold-time */ NPCX_SMBSCLLT(ctrl) = pTiming->k1/2; NPCX_SMBSCLHT(ctrl) = pTiming->k2/2; SET_FIELD(NPCX_SMBCTL4(ctrl), NPCX_SMBCTL4_HLDT_FIELD, pTiming->HLDT); break; } } if (j == i2c_timing_used) cprints(CC_I2C, "Error: Please make sure src ", "clock of i2c %d is supported", ctrl); } } } DECLARE_HOOK(HOOK_FREQ_CHANGE, i2c_freq_changed, HOOK_PRIO_DEFAULT); static void i2c_init(void) { int i; /* Configure pins from GPIOs to I2Cs */ gpio_config_module(MODULE_I2C, 1); /* Enable clock for I2C peripheral */ clock_enable_peripheral(CGC_OFFSET_I2C, CGC_I2C_MASK, CGC_MODE_RUN | CGC_MODE_SLEEP); #if defined(CHIP_FAMILY_NPCX7) clock_enable_peripheral(CGC_OFFSET_I2C2, CGC_I2C_MASK2, CGC_MODE_RUN | CGC_MODE_SLEEP); #endif /* Set I2C freq */ i2c_freq_changed(); /* * initialize smb status and register */ for (i = 0; i < i2c_ports_used; i++) { volatile struct i2c_status *p_status; int port = i2c_ports[i].port; int ctrl = i2c_port_to_controller(port); /* ignore the port if i2c_port_to_controller() failed */ if (ctrl < 0) continue; p_status = i2c_stsobjs + ctrl; /* status init */ p_status->oper_state = SMB_IDLE; /* Reset task ID */ p_status->task_waiting = TASK_ID_INVALID; /* Use default timeout. */ i2c_set_timeout(port, 0); /* Init the SMB module */ i2c_init_bus(ctrl); } } DECLARE_HOOK(HOOK_INIT, i2c_init, HOOK_PRIO_INIT_I2C);