/* SPDX-License-Identifier: GPL-2.0-only */ /* * Derived from Cavium's BSD-3 Clause OCTEONTX-SDK-6.2.0. */ #include #include #include #include #include #include #include #include #include #define TWSI_THP 24 #define TWSI_SW_TWSI 0x1000 #define TWSI_TWSI_SW 0x1008 #define TWSI_INT 0x1010 #define TWSI_SW_TWSI_EXT 0x1018 union twsx_sw_twsi { u64 u; struct { u64 data:32; u64 eop_ia:3; u64 ia:5; u64 addr:10; u64 scr:2; u64 size:3; u64 sovr:1; u64 r:1; u64 op:4; u64 eia:1; u64 slonly:1; u64 v:1; } s; }; union twsx_sw_twsi_ext { u64 u; struct { u64 data:32; u64 ia:8; u64 :24; } s; }; union twsx_int { u64 u; struct { u64 st_int:1; /** TWSX_SW_TWSI register update int */ u64 ts_int:1; /** TWSX_TWSI_SW register update int */ u64 core_int:1; /** TWSI core interrupt, ignored for HLC */ u64 :5; /** Reserved */ u64 sda_ovr:1; /** SDA testing override */ u64 scl_ovr:1; /** SCL testing override */ u64 sda:1; /** SDA signal */ u64 scl:1; /** SCL signal */ u64 :52; /** Reserved */ } s; }; enum { TWSI_OP_WRITE = 0, TWSI_OP_READ = 1, }; enum { TWSI_EOP_SLAVE_ADDR = 0, TWSI_EOP_CLK_CTL = 3, TWSI_SW_EOP_IA = 6, }; enum { TWSI_SLAVEADD = 0, TWSI_DATA = 1, TWSI_CTL = 2, TWSI_CLKCTL = 3, TWSI_STAT = 3, TWSI_SLAVEADD_EXT = 4, TWSI_RST = 7, }; enum { TWSI_CTL_AAK = (1 << 2), TWSI_CTL_IFLG = (1 << 3), TWSI_CTL_STP = (1 << 4), TWSI_CTL_STA = (1 << 5), TWSI_CTL_ENAB = (1 << 6), TWSI_CTL_CE = (1 << 7), }; enum { /** Bus error */ TWSI_STAT_BUS_ERROR = 0x00, /** Start condition transmitted */ TWSI_STAT_START = 0x08, /** Repeat start condition transmitted */ TWSI_STAT_RSTART = 0x10, /** Address + write bit transmitted, ACK received */ TWSI_STAT_TXADDR_ACK = 0x18, /** Address + write bit transmitted, /ACK received */ TWSI_STAT_TXADDR_NAK = 0x20, /** Data byte transmitted in master mode, ACK received */ TWSI_STAT_TXDATA_ACK = 0x28, /** Data byte transmitted in master mode, ACK received */ TWSI_STAT_TXDATA_NAK = 0x30, /** Arbitration lost in address or data byte */ TWSI_STAT_TX_ARB_LOST = 0x38, /** Address + read bit transmitted, ACK received */ TWSI_STAT_RXADDR_ACK = 0x40, /** Address + read bit transmitted, /ACK received */ TWSI_STAT_RXADDR_NAK = 0x48, /** Data byte received in master mode, ACK transmitted */ TWSI_STAT_RXDATA_ACK_SENT = 0x50, /** Data byte received, NACK transmitted */ TWSI_STAT_RXDATA_NAK_SENT = 0x58, /** Slave address received, sent ACK */ TWSI_STAT_SLAVE_RXADDR_ACK = 0x60, /** * Arbitration lost in address as master, slave address + write bit * received, ACK transmitted */ TWSI_STAT_TX_ACK_ARB_LOST = 0x68, /** General call address received, ACK transmitted */ TWSI_STAT_RX_GEN_ADDR_ACK = 0x70, /** * Arbitration lost in address as master, general call address * received, ACK transmitted */ TWSI_STAT_RX_GEN_ADDR_ARB_LOST = 0x78, /** Data byte received after slave address received, ACK transmitted */ TWSI_STAT_SLAVE_RXDATA_ACK = 0x80, /** Data byte received after slave address received, /ACK transmitted */ TWSI_STAT_SLAVE_RXDATA_NAK = 0x88, /** * Data byte received after general call address received, ACK * transmitted */ TWSI_STAT_GEN_RXADDR_ACK = 0x90, /** * Data byte received after general call address received, /ACK * transmitted */ TWSI_STAT_GEN_RXADDR_NAK = 0x98, /** STOP or repeated START condition received in slave mode */ TWSI_STAT_STOP_MULTI_START = 0xA0, /** Slave address + read bit received, ACK transmitted */ TWSI_STAT_SLAVE_RXADDR2_ACK = 0xA8, /** * Arbitration lost in address as master, slave address + read bit * received, ACK transmitted */ TWSI_STAT_RXDATA_ACK_ARB_LOST = 0xB0, /** Data byte transmitted in slave mode, ACK received */ TWSI_STAT_SLAVE_TXDATA_ACK = 0xB8, /** Data byte transmitted in slave mode, /ACK received */ TWSI_STAT_SLAVE_TXDATA_NAK = 0xC0, /** Last byte transmitted in slave mode, ACK received */ TWSI_STAT_SLAVE_TXDATA_END_ACK = 0xC8, /** Second address byte + write bit transmitted, ACK received */ TWSI_STAT_TXADDR2DATA_ACK = 0xD0, /** Second address byte + write bit transmitted, /ACK received */ TWSI_STAT_TXADDR2DATA_NAK = 0xD8, /** No relevant status information */ TWSI_STAT_IDLE = 0xF8 }; /** * Returns true if we lost arbitration * * @param code status code * @param final_read true if this is the final read operation * * @return true if arbitration has been lost, false if it hasn't been lost. */ static int twsi_i2c_lost_arb(u8 code, int final_read) { switch (code) { /* Arbitration lost */ case TWSI_STAT_TX_ARB_LOST: case TWSI_STAT_TX_ACK_ARB_LOST: case TWSI_STAT_RX_GEN_ADDR_ARB_LOST: case TWSI_STAT_RXDATA_ACK_ARB_LOST: return -1; /* Being addressed as slave, should back off and listen */ case TWSI_STAT_SLAVE_RXADDR_ACK: case TWSI_STAT_RX_GEN_ADDR_ACK: case TWSI_STAT_GEN_RXADDR_ACK: case TWSI_STAT_GEN_RXADDR_NAK: return -1; /* Core busy as slave */ case TWSI_STAT_SLAVE_RXDATA_ACK: case TWSI_STAT_SLAVE_RXDATA_NAK: case TWSI_STAT_STOP_MULTI_START: case TWSI_STAT_SLAVE_RXADDR2_ACK: case TWSI_STAT_SLAVE_TXDATA_ACK: case TWSI_STAT_SLAVE_TXDATA_NAK: case TWSI_STAT_SLAVE_TXDATA_END_ACK: return -1; /* Ack allowed on pre-terminal bytes only */ case TWSI_STAT_RXDATA_ACK_SENT: if (!final_read) return 0; return -1; /* NAK allowed on terminal byte only */ case TWSI_STAT_RXDATA_NAK_SENT: if (!final_read) return 0; return -1; case TWSI_STAT_TXDATA_NAK: case TWSI_STAT_TXADDR_NAK: case TWSI_STAT_RXADDR_NAK: case TWSI_STAT_TXADDR2DATA_NAK: return -1; } return 0; } #define RST_BOOT_PNR_MUL(Val) ((Val >> 33) & 0x1F) /** * Writes to the MIO_TWS(0..5)_SW_TWSI register * * @param baseaddr Base address of i2c registers * @param sw_twsi value to write * * @return 0 for success, otherwise error */ static u64 twsi_write_sw(void *baseaddr, union twsx_sw_twsi sw_twsi) { unsigned long timeout = 500000; sw_twsi.s.r = 0; sw_twsi.s.v = 1; printk(BIOS_SPEW, "%s(%p, 0x%llx)\n", __func__, baseaddr, sw_twsi.u); write64(baseaddr + TWSI_SW_TWSI, sw_twsi.u); do { sw_twsi.u = read64(baseaddr + TWSI_SW_TWSI); timeout--; } while (sw_twsi.s.v != 0 && timeout > 0); if (sw_twsi.s.v) printk(BIOS_ERR, "%s: timed out\n", __func__); return sw_twsi.u; } /** * Reads the MIO_TWS(0..5)_SW_TWSI register * * @param baseaddr Base address of i2c registers * @param sw_twsi value for eia and op, etc. to read * * @return value of the register */ static u64 twsi_read_sw(void *baseaddr, union twsx_sw_twsi sw_twsi) { unsigned long timeout = 500000; sw_twsi.s.r = 1; sw_twsi.s.v = 1; printk(BIOS_SPEW, "%s(%p, 0x%llx)\n", __func__, baseaddr, sw_twsi.u); write64(baseaddr + TWSI_SW_TWSI, sw_twsi.u); do { sw_twsi.u = read64(baseaddr + TWSI_SW_TWSI); timeout--; } while (sw_twsi.s.v != 0 && timeout > 0); if (sw_twsi.s.v) printk(BIOS_ERR, "%s: Error writing 0x%llx\n", __func__, sw_twsi.u); printk(BIOS_SPEW, "%s: Returning 0x%llx\n", __func__, sw_twsi.u); return sw_twsi.u; } /** * Write control register * * @param baseaddr Base address for i2c registers * @param data data to write */ static void twsi_write_ctl(void *baseaddr, const u8 data) { union twsx_sw_twsi twsi_sw; printk(BIOS_SPEW, "%s(%p, 0x%x)\n", __func__, baseaddr, data); twsi_sw.u = 0; twsi_sw.s.op = TWSI_SW_EOP_IA; twsi_sw.s.eop_ia = TWSI_CTL; twsi_sw.s.data = data; twsi_write_sw(baseaddr, twsi_sw); } /** * Reads the TWSI Control Register * * @param[in] baseaddr Base address for i2c * * @return 8-bit TWSI control register */ static u32 twsi_read_ctl(void *baseaddr) { union twsx_sw_twsi sw_twsi; sw_twsi.u = 0; sw_twsi.s.op = TWSI_SW_EOP_IA; sw_twsi.s.eop_ia = TWSI_CTL; sw_twsi.u = twsi_read_sw(baseaddr, sw_twsi); printk(BIOS_SPEW, "%s(%p): 0x%x\n", __func__, baseaddr, sw_twsi.s.data); return sw_twsi.s.data; } /** * Read i2c status register * * @param baseaddr Base address of i2c registers * * @return value of status register */ static u8 twsi_read_status(void *baseaddr) { union twsx_sw_twsi twsi_sw; twsi_sw.u = 0; twsi_sw.s.op = TWSI_SW_EOP_IA; twsi_sw.s.eop_ia = TWSI_STAT; return twsi_read_sw(baseaddr, twsi_sw); } /** * Waits for an i2c operation to complete * * @param baseaddr Base address of registers * * @return 0 for success, 1 if timeout */ static int twsi_wait(void *baseaddr, struct stopwatch *timeout) { u8 twsi_ctl; printk(BIOS_SPEW, "%s(%p)\n", __func__, baseaddr); do { twsi_ctl = twsi_read_ctl(baseaddr); twsi_ctl &= TWSI_CTL_IFLG; } while (!twsi_ctl && !stopwatch_expired(timeout)); printk(BIOS_SPEW, " return: %u\n", !twsi_ctl); return !twsi_ctl; } /** * Sends an i2c stop condition * * @param baseaddr register base address * * @return 0 for success, -1 if error */ static int twsi_stop(void *baseaddr) { u8 stat; twsi_write_ctl(baseaddr, TWSI_CTL_STP | TWSI_CTL_ENAB); stat = twsi_read_status(baseaddr); if (stat != TWSI_STAT_IDLE) { printk(BIOS_ERR, "%s: Bad status on bus@%p\n", __func__, baseaddr); return -1; } return 0; } /** * Manually clear the I2C bus and send a stop */ static void twsi_unblock(void *baseaddr) { int i; union twsx_int int_reg; int_reg.u = 0; for (i = 0; i < 9; i++) { int_reg.s.scl_ovr = 0; write64(baseaddr + TWSI_INT, int_reg.u); udelay(5); int_reg.s.scl_ovr = 1; write64(baseaddr + TWSI_INT, int_reg.u); udelay(5); } int_reg.s.sda_ovr = 1; write64(baseaddr + TWSI_INT, int_reg.u); udelay(5); int_reg.s.scl_ovr = 0; write64(baseaddr + TWSI_INT, int_reg.u); udelay(5); int_reg.u = 0; write64(baseaddr + TWSI_INT, int_reg.u); udelay(5); } /** * Unsticks the i2c bus * * @param baseaddr base address of registers */ static int twsi_start_unstick(void *baseaddr) { twsi_stop(baseaddr); twsi_unblock(baseaddr); return 0; } /** * Sends an i2c start condition * * @param baseaddr base address of registers * * @return 0 for success, otherwise error */ static int twsi_start(void *baseaddr) { int result; u8 stat; struct stopwatch timeout; printk(BIOS_SPEW, "%s(%p)\n", __func__, baseaddr); stopwatch_init_usecs_expire(&timeout, CONFIG_I2C_TRANSFER_TIMEOUT_US); twsi_write_ctl(baseaddr, TWSI_CTL_STA | TWSI_CTL_ENAB); result = twsi_wait(baseaddr, &timeout); if (result) { stat = twsi_read_status(baseaddr); printk(BIOS_SPEW, "%s: result: 0x%x, status: 0x%x\n", __func__, result, stat); switch (stat) { case TWSI_STAT_START: case TWSI_STAT_RSTART: return 0; case TWSI_STAT_RXADDR_ACK: default: return twsi_start_unstick(baseaddr); } } printk(BIOS_SPEW, "%s: success\n", __func__); return 0; } /** * Writes data to the i2c bus * * @param baseraddr register base address * @param slave_addr address of slave to write to * @param buffer Pointer to buffer to write * @param length Number of bytes in buffer to write * * @return 0 for success, otherwise error */ static int twsi_write_data(void *baseaddr, const u8 slave_addr, const u8 *buffer, const unsigned int length) { union twsx_sw_twsi twsi_sw; unsigned int curr = 0; int result; struct stopwatch timeout; printk(BIOS_SPEW, "%s(%p, 0x%x, %p, 0x%x)\n", __func__, baseaddr, slave_addr, buffer, length); stopwatch_init_usecs_expire(&timeout, CONFIG_I2C_TRANSFER_TIMEOUT_US); result = twsi_start(baseaddr); if (result) { printk(BIOS_ERR, "%s: Could not start BUS transaction\n", __func__); return -1; } result = twsi_wait(baseaddr, &timeout); if (result) { printk(BIOS_ERR, "%s: wait failed\n", __func__); return result; } twsi_sw.u = 0; twsi_sw.s.op = TWSI_SW_EOP_IA; twsi_sw.s.eop_ia = TWSI_DATA; twsi_sw.s.data = (u32) (slave_addr << 1) | TWSI_OP_WRITE; twsi_write_sw(baseaddr, twsi_sw); twsi_write_ctl(baseaddr, TWSI_CTL_ENAB); printk(BIOS_SPEW, "%s: Waiting\n", __func__); result = twsi_wait(baseaddr, &timeout); if (result) { printk(BIOS_ERR, "%s: Timed out writing slave address 0x%x\n", __func__, slave_addr); return result; } result = twsi_read_status(baseaddr); if ((result = twsi_read_status(baseaddr)) != TWSI_STAT_TXADDR_ACK) { twsi_stop(baseaddr); return twsi_i2c_lost_arb(result, 0); } while (curr < length) { twsi_sw.u = 0; twsi_sw.s.op = TWSI_SW_EOP_IA; twsi_sw.s.eop_ia = TWSI_DATA; twsi_sw.s.data = buffer[curr++]; twsi_write_sw(baseaddr, twsi_sw); twsi_write_ctl(baseaddr, TWSI_CTL_ENAB); result = twsi_wait(baseaddr, &timeout); if (result) { printk(BIOS_ERR, "%s: Timed out writing data to 0x%x\n", __func__, slave_addr); return result; } } printk(BIOS_SPEW, "%s: Stopping\n", __func__); return twsi_stop(baseaddr); } /** * Performs a read transaction on the i2c bus * * @param baseaddr Base address of twsi registers * @param slave_addr i2c bus address to read from * @param buffer buffer to read into * @param length number of bytes to read * * @return 0 for success, otherwise error */ static int twsi_read_data(void *baseaddr, const u8 slave_addr, u8 *buffer, const unsigned int length) { union twsx_sw_twsi twsi_sw; unsigned int curr = 0; int result; struct stopwatch timeout; printk(BIOS_SPEW, "%s(%p, 0x%x, %p, %u)\n", __func__, baseaddr, slave_addr, buffer, length); stopwatch_init_usecs_expire(&timeout, CONFIG_I2C_TRANSFER_TIMEOUT_US); result = twsi_start(baseaddr); if (result) { printk(BIOS_ERR, "%s: start failed\n", __func__); return result; } result = twsi_wait(baseaddr, &timeout); if (result) { printk(BIOS_ERR, "%s: wait failed\n", __func__); return result; } twsi_sw.u = 0; twsi_sw.s.op = TWSI_SW_EOP_IA; twsi_sw.s.eop_ia = TWSI_DATA; twsi_sw.s.data = (u32) (slave_addr << 1) | TWSI_OP_READ; twsi_write_sw(baseaddr, twsi_sw); twsi_write_ctl(baseaddr, TWSI_CTL_ENAB); result = twsi_wait(baseaddr, &timeout); if (result) { printk(BIOS_ERR, "%s: waiting for sending addr failed\n", __func__); return result; } result = twsi_read_status(baseaddr); if (result != TWSI_STAT_RXADDR_ACK) { twsi_stop(baseaddr); return twsi_i2c_lost_arb(result, 0); } while (curr < length) { twsi_write_ctl(baseaddr, TWSI_CTL_ENAB | ((curr < length - 1) ? TWSI_CTL_AAK : 0)); result = twsi_wait(baseaddr, &timeout); if (result) { printk(BIOS_ERR, "%s: waiting for data failed\n", __func__); return result; } twsi_sw.u = twsi_read_sw(baseaddr, twsi_sw); buffer[curr++] = twsi_sw.s.data; } twsi_stop(baseaddr); return 0; } static int twsi_set_speed(void *baseaddr, const unsigned int speed) { u64 io_clock_hz; int n_div; int m_div; union twsx_sw_twsi sw_twsi; io_clock_hz = thunderx_get_io_clock(); /* Set the TWSI clock to a conservative TWSI_BUS_FREQ. Compute the * clocks M divider based on the SCLK. * TWSI freq = (core freq) / (20 x (M+1) x (thp+1) x 2^N) * M = ((core freq) / (20 x (TWSI freq) x (thp+1) x 2^N)) - 1 */ for (n_div = 0; n_div < 8; n_div++) { m_div = io_clock_hz / (20 * speed * (TWSI_THP + 1)); m_div /= 1 << n_div; m_div -= 1; if (m_div < 16) break; } if (m_div >= 16) return -1; sw_twsi.u = 0; sw_twsi.s.v = 1; sw_twsi.s.op = 0x6; /* See EOP field */ sw_twsi.s.r = 0; /* Select CLKCTL when R = 0 */ sw_twsi.s.eop_ia = 3; /* R=0 selects CLKCTL, R=1 selects STAT */ sw_twsi.s.data = ((m_div & 0xf) << 3) | ((n_div & 0x7) << 0); twsi_write_sw(baseaddr, sw_twsi); return 0; } int twsi_init(unsigned int bus, enum i2c_speed hz) { void *baseaddr = (void *)MIO_TWSx_PF_BAR0(bus); if (!baseaddr) return -1; if (twsi_set_speed(baseaddr, hz) < 0) return -1; /* Enable TWSI, HLC disable, STOP, NAK */ twsi_write_ctl(baseaddr, TWSI_CTL_ENAB); return 0; } int platform_i2c_transfer(unsigned int bus, struct i2c_msg *segments, int seg_count) { int result; void *baseaddr = (void *)MIO_TWSx_PF_BAR0(bus); if (!baseaddr) return -1; printk(BIOS_SPEW, "%s: %d messages\n", __func__, seg_count); for (; seg_count > 0; seg_count--, segments++) { if (segments->flags & I2C_M_RD) { result = twsi_read_data(baseaddr, segments->slave, segments->buf, segments->len); } else { result = twsi_write_data(baseaddr, segments->slave, segments->buf, segments->len); } if (result) { printk(BIOS_ERR, "%s: error transmitting data\n", __func__); return -1; } } return 0; }