/* * Copyright (c) 2020 Raspberry Pi (Trading) Ltd. * * SPDX-License-Identifier: BSD-3-Clause */ #include "hardware/i2c.h" #include "hardware/resets.h" #include "hardware/clocks.h" #include "pico/timeout_helper.h" check_hw_layout(i2c_hw_t, enable, I2C_IC_ENABLE_OFFSET); check_hw_layout(i2c_hw_t, clr_restart_det, I2C_IC_CLR_RESTART_DET_OFFSET); i2c_inst_t i2c0_inst = {i2c0_hw, false}; i2c_inst_t i2c1_inst = {i2c1_hw, false}; static inline void i2c_reset(i2c_inst_t *i2c) { invalid_params_if(HARDWARE_I2C, i2c != i2c0 && i2c != i2c1); reset_block_num(i2c == i2c0 ? RESET_I2C0 : RESET_I2C1); } static inline void i2c_unreset(i2c_inst_t *i2c) { invalid_params_if(HARDWARE_I2C, i2c != i2c0 && i2c != i2c1); unreset_block_num_wait_blocking(i2c == i2c0 ? RESET_I2C0 : RESET_I2C1); } // Addresses of the form 000 0xxx or 111 1xxx are reserved. No slave should // have these addresses. #define i2c_reserved_addr(addr) (((addr) & 0x78) == 0 || ((addr) & 0x78) == 0x78) uint i2c_init(i2c_inst_t *i2c, uint baudrate) { i2c_reset(i2c); i2c_unreset(i2c); i2c->restart_on_next = false; i2c->hw->enable = 0; // Configure as a fast-mode master with RepStart support, 7-bit addresses i2c->hw->con = I2C_IC_CON_SPEED_VALUE_FAST << I2C_IC_CON_SPEED_LSB | I2C_IC_CON_MASTER_MODE_BITS | I2C_IC_CON_IC_SLAVE_DISABLE_BITS | I2C_IC_CON_IC_RESTART_EN_BITS | I2C_IC_CON_TX_EMPTY_CTRL_BITS; // Set FIFO watermarks to 1 to make things simpler. This is encoded by a register value of 0. i2c->hw->tx_tl = 0; i2c->hw->rx_tl = 0; // Always enable the DREQ signalling -- harmless if DMA isn't listening i2c->hw->dma_cr = I2C_IC_DMA_CR_TDMAE_BITS | I2C_IC_DMA_CR_RDMAE_BITS; // Re-sets i2c->hw->enable upon returning: return i2c_set_baudrate(i2c, baudrate); } void i2c_deinit(i2c_inst_t *i2c) { i2c_reset(i2c); } uint i2c_set_baudrate(i2c_inst_t *i2c, uint baudrate) { invalid_params_if(HARDWARE_I2C, baudrate == 0); // I2C is synchronous design that runs from clk_sys uint freq_in = clock_get_hz(clk_sys); // TODO there are some subtleties to I2C timing which we are completely ignoring here uint period = (freq_in + baudrate / 2) / baudrate; uint lcnt = period * 3 / 5; // oof this one hurts uint hcnt = period - lcnt; // Check for out-of-range divisors: invalid_params_if(HARDWARE_I2C, hcnt > I2C_IC_FS_SCL_HCNT_IC_FS_SCL_HCNT_BITS); invalid_params_if(HARDWARE_I2C, lcnt > I2C_IC_FS_SCL_LCNT_IC_FS_SCL_LCNT_BITS); invalid_params_if(HARDWARE_I2C, hcnt < 8); invalid_params_if(HARDWARE_I2C, lcnt < 8); // Per I2C-bus specification a device in standard or fast mode must // internally provide a hold time of at least 300ns for the SDA signal to // bridge the undefined region of the falling edge of SCL. A smaller hold // time of 120ns is used for fast mode plus. uint sda_tx_hold_count; if (baudrate < 1000000) { // sda_tx_hold_count = freq_in [cycles/s] * 300ns * (1s / 1e9ns) // Reduce 300/1e9 to 3/1e7 to avoid numbers that don't fit in uint. // Add 1 to avoid division truncation. sda_tx_hold_count = ((freq_in * 3) / 10000000) + 1; } else { // sda_tx_hold_count = freq_in [cycles/s] * 120ns * (1s / 1e9ns) // Reduce 120/1e9 to 3/25e6 to avoid numbers that don't fit in uint. // Add 1 to avoid division truncation. sda_tx_hold_count = ((freq_in * 3) / 25000000) + 1; } assert(sda_tx_hold_count <= lcnt - 2); i2c->hw->enable = 0; // Always use "fast" mode (<= 400 kHz, works fine for standard mode too) hw_write_masked(&i2c->hw->con, I2C_IC_CON_SPEED_VALUE_FAST << I2C_IC_CON_SPEED_LSB, I2C_IC_CON_SPEED_BITS ); i2c->hw->fs_scl_hcnt = hcnt; i2c->hw->fs_scl_lcnt = lcnt; i2c->hw->fs_spklen = lcnt < 16 ? 1 : lcnt / 16; hw_write_masked(&i2c->hw->sda_hold, sda_tx_hold_count << I2C_IC_SDA_HOLD_IC_SDA_TX_HOLD_LSB, I2C_IC_SDA_HOLD_IC_SDA_TX_HOLD_BITS); i2c->hw->enable = 1; return freq_in / period; } void i2c_set_slave_mode(i2c_inst_t *i2c, bool slave, uint8_t addr) { invalid_params_if(HARDWARE_I2C, addr >= 0x80); // 7-bit addresses invalid_params_if(HARDWARE_I2C, i2c_reserved_addr(addr)); i2c->hw->enable = 0; uint32_t ctrl_set_if_master = I2C_IC_CON_MASTER_MODE_BITS | I2C_IC_CON_IC_SLAVE_DISABLE_BITS; uint32_t ctrl_set_if_slave = I2C_IC_CON_RX_FIFO_FULL_HLD_CTRL_BITS; if (slave) { hw_write_masked(&i2c->hw->con, ctrl_set_if_slave, ctrl_set_if_master | ctrl_set_if_slave ); i2c->hw->sar = addr; } else { hw_write_masked(&i2c->hw->con, ctrl_set_if_master, ctrl_set_if_master | ctrl_set_if_slave ); } i2c->hw->enable = 1; } static int i2c_write_blocking_internal(i2c_inst_t *i2c, uint8_t addr, const uint8_t *src, size_t len, bool nostop, check_timeout_fn timeout_check, struct timeout_state *ts) { invalid_params_if(HARDWARE_I2C, addr >= 0x80); // 7-bit addresses invalid_params_if(HARDWARE_I2C, i2c_reserved_addr(addr)); // Synopsys hw accepts start/stop flags alongside data items in the same // FIFO word, so no 0 byte transfers. invalid_params_if(HARDWARE_I2C, len == 0); invalid_params_if(HARDWARE_I2C, ((int)len) < 0); i2c->hw->enable = 0; i2c->hw->tar = addr; i2c->hw->enable = 1; bool abort = false; bool timeout = false; uint32_t abort_reason = 0; int byte_ctr; int ilen = (int)len; for (byte_ctr = 0; byte_ctr < ilen; ++byte_ctr) { bool first = byte_ctr == 0; bool last = byte_ctr == ilen - 1; if (timeout_check) { timeout_check(ts, true); // for per iteration checks, this will reset the timeout } i2c->hw->data_cmd = bool_to_bit(first && i2c->restart_on_next) << I2C_IC_DATA_CMD_RESTART_LSB | bool_to_bit(last && !nostop) << I2C_IC_DATA_CMD_STOP_LSB | *src++; // Wait until the transmission of the address/data from the internal // shift register has completed. For this to function correctly, the // TX_EMPTY_CTRL flag in IC_CON must be set. The TX_EMPTY_CTRL flag // was set in i2c_init. do { if (timeout_check) { timeout = timeout_check(ts, false); abort |= timeout; } tight_loop_contents(); } while (!timeout && !(i2c->hw->raw_intr_stat & I2C_IC_RAW_INTR_STAT_TX_EMPTY_BITS)); // If there was a timeout, don't attempt to do anything else. if (!timeout) { abort_reason = i2c->hw->tx_abrt_source; if (abort_reason) { // Note clearing the abort flag also clears the reason, and // this instance of flag is clear-on-read! Note also the // IC_CLR_TX_ABRT register always reads as 0. i2c->hw->clr_tx_abrt; abort = true; } if (abort || (last && !nostop)) { // If the transaction was aborted or if it completed // successfully wait until the STOP condition has occurred. // TODO Could there be an abort while waiting for the STOP // condition here? If so, additional code would be needed here // to take care of the abort. do { if (timeout_check) { timeout = timeout_check(ts, false); abort |= timeout; } tight_loop_contents(); } while (!timeout && !(i2c->hw->raw_intr_stat & I2C_IC_RAW_INTR_STAT_STOP_DET_BITS)); // If there was a timeout, don't attempt to do anything else. if (!timeout) { i2c->hw->clr_stop_det; } } } // Note the hardware issues a STOP automatically on an abort condition. // Note also the hardware clears RX FIFO as well as TX on abort, // because we set hwparam IC_AVOID_RX_FIFO_FLUSH_ON_TX_ABRT to 0. if (abort) break; } int rval; // A lot of things could have just happened due to the ingenious and // creative design of I2C. Try to figure things out. if (abort) { if (timeout) rval = PICO_ERROR_TIMEOUT; else if (!abort_reason || abort_reason & I2C_IC_TX_ABRT_SOURCE_ABRT_7B_ADDR_NOACK_BITS) { // No reported errors - seems to happen if there is nothing connected to the bus. // Address byte not acknowledged rval = PICO_ERROR_GENERIC; } else if (abort_reason & I2C_IC_TX_ABRT_SOURCE_ABRT_TXDATA_NOACK_BITS) { // Address acknowledged, some data not acknowledged rval = byte_ctr; } else { //panic("Unknown abort from I2C instance @%08x: %08x\n", (uint32_t) i2c->hw, abort_reason); rval = PICO_ERROR_GENERIC; } } else { rval = byte_ctr; } // nostop means we are now at the end of a *message* but not the end of a *transfer* i2c->restart_on_next = nostop; return rval; } int i2c_write_blocking(i2c_inst_t *i2c, uint8_t addr, const uint8_t *src, size_t len, bool nostop) { return i2c_write_blocking_internal(i2c, addr, src, len, nostop, NULL, NULL); } int i2c_write_blocking_until(i2c_inst_t *i2c, uint8_t addr, const uint8_t *src, size_t len, bool nostop, absolute_time_t until) { timeout_state_t ts; return i2c_write_blocking_internal(i2c, addr, src, len, nostop, init_single_timeout_until(&ts, until), &ts); } int i2c_write_timeout_per_char_us(i2c_inst_t *i2c, uint8_t addr, const uint8_t *src, size_t len, bool nostop, uint timeout_per_char_us) { timeout_state_t ts; return i2c_write_blocking_internal(i2c, addr, src, len, nostop, init_per_iteration_timeout_us(&ts, timeout_per_char_us), &ts); } int i2c_write_burst_blocking(i2c_inst_t *i2c, uint8_t addr, const uint8_t *src, size_t len) { int rc = i2c_write_blocking_internal(i2c, addr, src, len, true, NULL, NULL); i2c->restart_on_next = false; return rc; } static int i2c_read_blocking_internal(i2c_inst_t *i2c, uint8_t addr, uint8_t *dst, size_t len, bool nostop, check_timeout_fn timeout_check, timeout_state_t *ts) { invalid_params_if(HARDWARE_I2C, addr >= 0x80); // 7-bit addresses invalid_params_if(HARDWARE_I2C, i2c_reserved_addr(addr)); invalid_params_if(HARDWARE_I2C, len == 0); invalid_params_if(HARDWARE_I2C, ((int)len) < 0); i2c->hw->enable = 0; i2c->hw->tar = addr; i2c->hw->enable = 1; bool abort = false; bool timeout = false; uint32_t abort_reason; int byte_ctr; int ilen = (int)len; for (byte_ctr = 0; byte_ctr < ilen; ++byte_ctr) { bool first = byte_ctr == 0; bool last = byte_ctr == ilen - 1; if (timeout_check) { timeout_check(ts, true); // for per iteration checks, this will reset the timeout } while (!i2c_get_write_available(i2c)) tight_loop_contents(); i2c->hw->data_cmd = bool_to_bit(first && i2c->restart_on_next) << I2C_IC_DATA_CMD_RESTART_LSB | bool_to_bit(last && !nostop) << I2C_IC_DATA_CMD_STOP_LSB | I2C_IC_DATA_CMD_CMD_BITS; // -> 1 for read do { abort_reason = i2c->hw->tx_abrt_source; abort = (bool) i2c->hw->clr_tx_abrt; if (timeout_check) { timeout = timeout_check(ts, false); abort |= timeout; } } while (!abort && !i2c_get_read_available(i2c)); if (abort) break; *dst++ = (uint8_t) i2c->hw->data_cmd; } int rval; if (abort) { if (timeout) rval = PICO_ERROR_TIMEOUT; else if (!abort_reason || abort_reason & I2C_IC_TX_ABRT_SOURCE_ABRT_7B_ADDR_NOACK_BITS) { // No reported errors - seems to happen if there is nothing connected to the bus. // Address byte not acknowledged rval = PICO_ERROR_GENERIC; } else { // panic("Unknown abort from I2C instance @%08x: %08x\n", (uint32_t) i2c->hw, abort_reason); rval = PICO_ERROR_GENERIC; } } else { rval = byte_ctr; } i2c->restart_on_next = nostop; return rval; } int i2c_read_blocking(i2c_inst_t *i2c, uint8_t addr, uint8_t *dst, size_t len, bool nostop) { return i2c_read_blocking_internal(i2c, addr, dst, len, nostop, NULL, NULL); } int i2c_read_blocking_until(i2c_inst_t *i2c, uint8_t addr, uint8_t *dst, size_t len, bool nostop, absolute_time_t until) { timeout_state_t ts; return i2c_read_blocking_internal(i2c, addr, dst, len, nostop, init_single_timeout_until(&ts, until), &ts); } int i2c_read_timeout_per_char_us(i2c_inst_t *i2c, uint8_t addr, uint8_t *dst, size_t len, bool nostop, uint timeout_per_char_us) { timeout_state_t ts; return i2c_read_blocking_internal(i2c, addr, dst, len, nostop, init_per_iteration_timeout_us(&ts, timeout_per_char_us), &ts); } int i2c_read_burst_blocking(i2c_inst_t *i2c, uint8_t addr, uint8_t *dst, size_t len) { int rc = i2c_read_blocking_internal(i2c, addr, dst, len, true, NULL, NULL); i2c->restart_on_next = false; return rc; }