/* SPDX-License-Identifier: GPL-2.0-only */ /* This file is part of the coreboot project. */ #include #include #include #include #include #include #include #include #include #include #include static void i2c_disable(I2C_REGS *regs) { uint32_t status; uint32_t timeout; /* Disable I2C controller */ regs->ic_enable = 0; /* Wait for the enable bit to clear */ timeout = 1 * 1000 * 1000; status = regs->ic_enable_status; while (status & IC_ENABLE_CONTROLLER) { udelay(1); if (--timeout == 0) die_with_post_code(POST_HW_INIT_FAILURE, "ERROR - I2C failed to disable!\n"); status = regs->ic_enable_status; } /* Clear any pending interrupts */ status = regs->ic_clr_intr; } static int platform_i2c_write(uint32_t restart, uint8_t *tx_buffer, int length, uint32_t stop, uint8_t *rx_buffer, struct stopwatch *timeout) { int bytes_transferred; uint32_t cmd; I2C_REGS *regs; uint32_t status; ASSERT(tx_buffer != NULL); ASSERT(timeout != NULL); regs = get_i2c_address(); /* Fill the FIFO with the write operation */ bytes_transferred = 0; do { status = regs->ic_raw_intr_stat; /* Check for errors */ if (status & (IC_INTR_RX_OVER | IC_INTR_RX_UNDER | IC_INTR_TX_ABRT | IC_INTR_TX_OVER)) { i2c_disable(regs); if (CONFIG(I2C_DEBUG)) printk(BIOS_ERR, "0x%08x: ic_raw_intr_stat, I2C write error!\n", status); return -1; } /* Check for timeout */ if (stopwatch_expired(timeout)) { if (CONFIG(I2C_DEBUG)) printk(BIOS_ERR, "0x%08x: ic_raw_intr_stat, I2C write timeout!\n", status); return -1; } /* Receive any available data */ status = regs->ic_status; if (rx_buffer != NULL) { while (status & IC_STATUS_RFNE) { *rx_buffer++ = (uint8_t)regs->ic_data_cmd; bytes_transferred++; status = regs->ic_status; } } /* Determine if space is available in the FIFO */ if (status & IC_STATUS_TFNF) { /* End of the transaction? */ cmd = IC_DATA_CMD_WRITE | *tx_buffer++ | restart; if (length == 1) cmd |= stop; restart = 0; /* Place a data byte into the FIFO */ regs->ic_data_cmd = cmd; length--; bytes_transferred++; } else udelay(1); } while (length > 0); return bytes_transferred; } static int platform_i2c_read(uint32_t restart, uint8_t *rx_buffer, int length, uint32_t stop, struct stopwatch *timeout) { int bytes_transferred; uint32_t cmd; int fifo_bytes; I2C_REGS *regs; uint32_t status; ASSERT(rx_buffer != NULL); ASSERT(timeout != NULL); regs = get_i2c_address(); /* Empty the FIFO */ status = regs->ic_status; while (status & IC_STATUS_RFNE) { (void)regs->ic_data_cmd; status = regs->ic_status; } /* Fill the FIFO with read commands */ fifo_bytes = MIN(length, 16); bytes_transferred = 0; while (length > 0) { status = regs->ic_raw_intr_stat; /* Check for errors */ if (status & (IC_INTR_RX_OVER | IC_INTR_RX_UNDER | IC_INTR_TX_ABRT | IC_INTR_TX_OVER)) { i2c_disable(regs); if (CONFIG(I2C_DEBUG)) printk(BIOS_ERR, "0x%08x: ic_raw_intr_stat, I2C read error!\n", status); return -1; } /* Check for timeout */ if (stopwatch_expired(timeout)) { if (CONFIG(I2C_DEBUG)) printk(BIOS_ERR, "0x%08x: ic_raw_intr_stat, I2C read timeout!\n", status); return -1; } /* Receive any available data */ status = regs->ic_status; if (status & IC_STATUS_RFNE) { /* Save the next data byte, removed from the RX FIFO */ *rx_buffer++ = (uint8_t)regs->ic_data_cmd; bytes_transferred++; } if ((status & IC_STATUS_TFNF) || ((status & IC_STATUS_RFNE) && (fifo_bytes > 0))) { /* End of the transaction? */ cmd = IC_DATA_CMD_READ | restart; if (length == 1) cmd |= stop; restart = 0; /* Place a read command into the TX FIFO */ regs->ic_data_cmd = cmd; if (fifo_bytes > 0) fifo_bytes--; length--; } else udelay(1); } return bytes_transferred; } int platform_i2c_transfer(unsigned int bus, struct i2c_msg *segment, int seg_count) { int bytes_transferred; uint8_t chip; uint32_t cmd; int data_bytes; int index; int length; I2C_REGS *regs; uint32_t restart; uint8_t *rx_buffer; uint32_t status; uint32_t stop; struct stopwatch timeout; int total_bytes; uint8_t *tx_buffer; int tx_bytes; if (CONFIG(I2C_DEBUG)) { for (index = 0; index < seg_count;) { if (index == 0) printk(BIOS_ERR, "I2C Start\n"); printk(BIOS_ERR, "I2C segment[%d]: %s 0x%02x %s %p, 0x%08x bytes\n", index, (segment[index].flags & I2C_M_RD) ? "Read from" : "Write to", segment[index].slave, (segment[index].flags & I2C_M_RD) ? "to " : "from", segment[index].buf, segment[index].len); printk(BIOS_ERR, "I2C %s\n", (++index >= seg_count) ? "Stop" : "Restart"); } } regs = get_i2c_address(); /* Disable the I2C controller to get access to the registers */ i2c_disable(regs); /* Set the slave address */ ASSERT(seg_count > 0); ASSERT(segment != NULL); /* Clear the start and stop detection */ status = regs->ic_clr_start_det; status = regs->ic_clr_stop_det; /* Set addressing mode to 7-bit and fast mode */ cmd = regs->ic_con; cmd &= ~(IC_CON_10B | IC_CON_SPEED); cmd |= IC_CON_RESTART_EN | IC_CON_7B | IC_CON_SPEED_400_KHz | IC_CON_MASTER_MODE; regs->ic_con = cmd; /* Set the target chip address */ chip = segment->slave; regs->ic_tar = chip; /* Enable the I2C controller */ regs->ic_enable = IC_ENABLE_CONTROLLER; /* Clear the interrupts */ status = regs->ic_clr_rx_under; status = regs->ic_clr_rx_over; status = regs->ic_clr_tx_over; status = regs->ic_clr_tx_abrt; /* Start the timeout */ stopwatch_init_msecs_expire(&timeout, 1000); /* Process each of the segments */ total_bytes = 0; tx_bytes = 0; bytes_transferred = 0; rx_buffer = NULL; restart = 0; index = 0; while (index++ < seg_count) { length = segment->len; total_bytes += length; ASSERT(segment->buf != NULL); ASSERT(length >= 1); ASSERT(segment->slave == chip); /* Determine if this is the last segment of the transaction */ stop = (index == seg_count) ? IC_DATA_CMD_STOP : 0; /* Fill the FIFO with the necessary command bytes */ if (segment->flags & I2C_M_RD) { /* Place read commands into the FIFO */ rx_buffer = segment->buf; data_bytes = platform_i2c_read(restart, rx_buffer, length, stop, &timeout); /* Return any detected error */ if (data_bytes < 0) { if (CONFIG(I2C_DEBUG)) printk(BIOS_ERR, "I2C segment[%d] failed\n", index); return data_bytes; } bytes_transferred += data_bytes; } else { /* Write the data into the FIFO */ tx_buffer = segment->buf; tx_bytes += length; data_bytes = platform_i2c_write(restart, tx_buffer, length, stop, rx_buffer, &timeout); /* Return any detected error */ if (data_bytes < 0) { if (CONFIG(I2C_DEBUG)) printk(BIOS_ERR, "I2C segment[%d] failed\n", index); return data_bytes; } bytes_transferred += data_bytes; } segment++; restart = IC_DATA_CMD_RESTART; } /* Wait for the end of the transaction */ if (rx_buffer != NULL) rx_buffer += bytes_transferred - tx_bytes; do { /* Receive any available data */ status = regs->ic_status; if ((rx_buffer != NULL) && (status & IC_STATUS_RFNE)) { *rx_buffer++ = (uint8_t)regs->ic_data_cmd; bytes_transferred++; } else { status = regs->ic_raw_intr_stat; if ((total_bytes == bytes_transferred) && (status & IC_INTR_STOP_DET)) break; /* Check for errors */ if (status & (IC_INTR_RX_OVER | IC_INTR_RX_UNDER | IC_INTR_TX_ABRT | IC_INTR_TX_OVER)) { i2c_disable(regs); if (CONFIG(I2C_DEBUG)) { printk(BIOS_ERR, "0x%08x: ic_raw_intr_stat, I2C read error!\n", status); printk(BIOS_ERR, "I2C segment[%d] failed\n", seg_count - 1); } return -1; } /* Check for timeout */ if (stopwatch_expired(&timeout)) { if (CONFIG(I2C_DEBUG)) { printk(BIOS_ERR, "0x%08x: ic_raw_intr_stat, I2C read timeout!\n", status); printk(BIOS_ERR, "I2C segment[%d] failed\n", seg_count - 1); } return -1; } /* Delay for a while */ udelay(1); } } while (1); i2c_disable(regs); regs->ic_tar = 0; /* Return the number of bytes transferred */ if (CONFIG(I2C_DEBUG)) printk(BIOS_ERR, "0x%08x: bytes transferred\n", bytes_transferred); return bytes_transferred; }