// SPDX-License-Identifier: BSD-2-Clause /* * Copyright 2021 NXP * * Driver for DSPI Controller * */ #include #include #include #include #include #include #include #include #include #include /* SPI register offset */ #define DSPI_MCR 0x0 /* Module Configuration Register */ #define DSPI_TCR 0x8 /* Transfer Count Register */ #define DSPI_CTAR0 \ 0xC /* Clock and Transfer Attributes Register (in Master mode) */ #define DSPI_CTAR1 \ 0x10 /* Clock and Transfer Attributes Register (in Master mode) */ #define DSPI_SR 0x2C /* Status Register */ #define DSPI_RSER 0x30 /* DMA/Interrupt Request Select and Enable Register */ #define DSPI_PUSHR 0x34 /* PUSH TX FIFO Register In Master Mode */ #define DSPI_POPR 0x38 /* POP RX FIFO Register */ #define DSPI_TXFR0 0x3C /* Transmit FIFO Registers */ #define DSPI_TXFR1 0x40 /* Transmit FIFO Registers */ #define DSPI_TXFR2 0x44 /* Transmit FIFO Registers */ #define DSPI_TXFR3 0x48 /* Transmit FIFO Registers */ #define DSPI_RXFR0 0x7C /* Receive FIFO Registers */ #define DSPI_RXFR1 0x80 /* Receive FIFO Registers */ #define DSPI_RXFR2 0x84 /* Receive FIFO Registers */ #define DSPI_RXFR3 0x88 /* Receive FIFO Registers */ #define DSPI_CTARE0 0x11C /* Clock and Transfer Attributes Register Extended */ #define DSPI_CTARE1 0x120 /* Clock and Transfer Attributes Register Extended */ #define DSPI_SREX 0x13C /* Status Register Extended */ /* Module configuration */ #define DSPI_MCR_MSTR 0x80000000 /* Master/Slave Mode Select [0] */ #define DSPI_MCR_CSCK 0x40000000 /* Continuous SCK Enable [1] */ #define DSPI_MCR_DCONF(x) (((x) & 0x03) << 28) /* SPI Configuration [2-3] */ #define DSPI_MCR_ROOE \ 0x01000000 /* Receive FIFO Overflow Overwrite Enable[7] */ #define DSPI_MCR_PCSIS(x) \ (1 << (16 + (x))) /* Peripheral Chip Select x Inactive State [12-15] */ #define DSPI_MCR_PCSIS_MASK (0xff << 16) #define DSPI_MCR_MDIS 0x00004000 /* Module Disable [17] */ #define DSPI_MCR_DTXF 0x00002000 /* Disable Transmit FIFO [18] */ #define DSPI_MCR_DRXF 0x00001000 /* Disable Receive FIFO [19] */ #define DSPI_MCR_CTXF 0x00000800 /* Clear TX FIFO [20] */ #define DSPI_MCR_CRXF 0x00000400 /* Clear RX FIFO [21] */ #define DPSI_XSPI 0x00000008 /* Extended SPI Mode [28] */ #define DSPI_MCR_PES 0x00000002 /* Parity Error Stop [30] */ #define DSPI_MCR_HALT 0x00000001 /* Halt [31] */ #define DPSI_ENABLE 0x0 #define DSPI_DISABLE 0x1 /* Transfer count */ #define DSPI_TCR_SPI_TCNT(x) (((x) & 0x0000FFFF) << 16) /* Status */ #define DSPI_SR_TXRXS 0x40000000 /* TX and RX Status [1] */ #define DSPI_SR_TXCTR(x) \ (((x) & 0x0000F000) >> 12) /* TX FIFO Counter [16-19] */ #define DSPI_SR_RXCTR(x) \ (((x) & 0x000000F0) >> 4) /* RX FIFO Counter [24-27] */ #define DSPI_DATA_8BIT SHIFT_U32(8, 0) #define DSPI_DATA_16BIT SHIFT_U32(0xF, 0) #define DSPI_TFR_CONT (0x80000000) #define DSPI_TFR_CTAS(x) (((x) & 0x07) << 12) #define DSPI_TFR_PCS(x) (((1 << (x)) & 0x0000003f) << 16) #define DSPI_IDLE_DATA 0x0 /* tx/rx data wait timeout value, unit: us */ #define DSPI_TXRX_WAIT_TIMEOUT 1000000 /* Transfer Fifo */ #define DSPI_TFR_TXDATA(x) (((x) & 0x0000FFFF)) /* Bit definitions and macros for DRFR */ #define DSPI_RFR_RXDATA(x) (((x) & 0x0000FFFF)) /* CTAR register pre-configure mask */ #define DSPI_CTAR_SET_MODE_MASK \ (DSPI_CTAR_FMSZ(15) | DSPI_CTAR_PCS_SCK(3) | DSPI_CTAR_PA_SCK(3) | \ DSPI_CTAR_P_DT(3) | DSPI_CTAR_CS_SCK(15) | DSPI_CTAR_A_SCK(15) | \ DSPI_CTAR_A_DT(15)) /* SPI mode flags */ #define SPI_CPHA BIT(0) /* clock phase */ #define SPI_CPOL BIT(1) /* clock polarity */ #define SPI_CS_HIGH BIT(2) /* CS active high */ #define SPI_LSB_FIRST BIT(3) /* per-word bits-on-wire */ #define SPI_CONT BIT(4) /* Continuous CS mode */ /* default SCK frequency, unit: HZ */ #define PLATFORM_CLK 650000000 #define DSPI_DEFAULT_SCK_FREQ 10000000 #define DSPI_CLK_DIV 4 /* prescaler divisor */ #define DSPI_CLK (PLATFORM_CLK / DSPI_CLK_DIV) /* DSPI clock */ #define CS_SPEED_MAX_HZ 1000000 /* Slave max speed */ /* * Calculate the divide scaler value between expected SCK frequency * and input clk frequency * req_pbr: pre-scaler value of baud rate for slave * req_br: scaler value of baud rate for slave * speed_hz: speed value of slave * clkrate: clock value of slave */ static TEE_Result dspi_convert_hz_to_baud(unsigned int *req_pbr, unsigned int *req_br, unsigned int speed_hz, unsigned int clkrate) { /* Valid pre-scaler values for baud rate*/ static const unsigned int pbr_val[4] = { 2, 3, 5, 7 }; /* Valid baud rate scaler values*/ static const unsigned int brs_val[16] = { 2, 4, 6, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 4096, 8192, 16384, 32768 }; unsigned int tmp_val = 0; unsigned int curr_val = 0; unsigned int i = 0; unsigned int j = 0; tmp_val = clkrate / speed_hz; for (i = 0; i < ARRAY_SIZE(pbr_val); i++) { for (j = 0; j < ARRAY_SIZE(brs_val); j++) { curr_val = pbr_val[i] * brs_val[j]; if (curr_val >= tmp_val) { *req_pbr = i; *req_br = j; return TEE_SUCCESS; } } } EMSG("Can not find valid baud rate, speed_hz is %d, ", speed_hz); EMSG("clkrate is %d, using max prescaler value", clkrate); return TEE_ERROR_ITEM_NOT_FOUND; } /* * Configure speed of slave * dspi_data: DSPI controller chip instance * speed: speed of slave */ static void dspi_setup_speed(struct ls_dspi_data *dspi_data, unsigned int speed) { TEE_Result status = TEE_ERROR_GENERIC; unsigned int bus_setup = 0; unsigned int bus_clock = 0; unsigned int req_i = 0; unsigned int req_j = 0; bus_clock = dspi_data->bus_clk_hz; DMSG("DSPI set_speed: expected SCK speed %u, bus_clk %u", speed, bus_clock); bus_setup = io_read32(dspi_data->base + DSPI_CTAR0); bus_setup &= ~(DSPI_CTAR_BRD | DSPI_CTAR_BRP(0x3) | DSPI_CTAR_BR(0xf)); status = dspi_convert_hz_to_baud(&req_i, &req_j, speed, bus_clock); /* In case of failure scenario with max speed, setting default speed */ if (status == TEE_ERROR_ITEM_NOT_FOUND) { speed = dspi_data->speed_hz; status = dspi_convert_hz_to_baud(&req_i, &req_j, speed, bus_clock); } if (status == TEE_SUCCESS) { bus_setup |= (DSPI_CTAR_BRP(req_i) | DSPI_CTAR_BR(req_j)); io_write32(dspi_data->base + DSPI_CTAR0, bus_setup); dspi_data->speed_hz = speed; } else { EMSG("Unable to set speed"); } } /* * Transferred data to TX FIFO * dspi_data: DSPI controller chip instance */ static void dspi_tx(struct ls_dspi_data *dspi_data, uint32_t ctrl, uint16_t data) { int timeout = DSPI_TXRX_WAIT_TIMEOUT; uint32_t dspi_val_addr = dspi_data->base + DSPI_PUSHR; uint32_t dspi_val = ctrl | data; /* wait for empty entries in TXFIFO or timeout */ while (DSPI_SR_TXCTR(io_read32(dspi_data->base + DSPI_SR)) >= 4 && timeout--) udelay(1); if (timeout >= 0) io_write32(dspi_val_addr, dspi_val); else EMSG("waiting timeout!"); } /* * Read data from RX FIFO * dspi_data: DSPI controller chip instance */ static uint16_t dspi_rx(struct ls_dspi_data *dspi_data) { int timeout = DSPI_TXRX_WAIT_TIMEOUT; uint32_t dspi_val_addr = dspi_data->base + DSPI_POPR; /* wait for valid entries in RXFIFO or timeout */ while (DSPI_SR_RXCTR(io_read32(dspi_data->base + DSPI_SR)) == 0 && timeout--) udelay(1); if (timeout >= 0) return (uint16_t)DSPI_RFR_RXDATA(io_read32(dspi_val_addr)); EMSG("waiting timeout!"); return 0xFFFF; } /* * Transfer and Receive 8-bit data * chip: spi_chip instance * wdata: TX data queue * rdata: RX data queue * num_pkts: number of data packets */ static enum spi_result ls_dspi_txrx8(struct spi_chip *chip, uint8_t *wdata, uint8_t *rdata, size_t num_pkts) { uint8_t *spi_rd = NULL; uint8_t *spi_wr = NULL; uint32_t ctrl = 0; struct ls_dspi_data *data = container_of(chip, struct ls_dspi_data, chip); unsigned int cs = data->slave_cs; spi_wr = wdata; spi_rd = rdata; /* * Assert PCSn signals between transfers * select which CTAR register and slave to be used for TX * CTAS selects which CTAR to be used, here we are using CTAR0 * PCS (peripheral chip select) is selecting the slave. */ ctrl = DSPI_TFR_CTAS(data->ctar_sel) | DSPI_TFR_PCS(cs); if (data->slave_mode & SPI_CONT) ctrl |= DSPI_TFR_CONT; if (data->slave_data_size_bits != 8) { EMSG("data_size_bits should be 8, not %u", data->slave_data_size_bits); return SPI_ERR_CFG; } while (num_pkts) { if (wdata && rdata) { dspi_tx(data, ctrl, *spi_wr++); *spi_rd++ = dspi_rx(data); } else if (wdata) { dspi_tx(data, ctrl, *spi_wr++); dspi_rx(data); } else if (rdata) { dspi_tx(data, ctrl, DSPI_IDLE_DATA); *spi_rd++ = dspi_rx(data); } num_pkts = num_pkts - 1; } return SPI_OK; } /* * Transfer and Receive 16-bit data * chip: spi_chip instance * wdata: TX data queue * rdata: RX data queue * num_pkts: number of data packets */ static enum spi_result ls_dspi_txrx16(struct spi_chip *chip, uint16_t *wdata, uint16_t *rdata, size_t num_pkts) { uint32_t ctrl = 0; uint16_t *spi_rd = NULL; uint16_t *spi_wr = NULL; struct ls_dspi_data *data = container_of(chip, struct ls_dspi_data, chip); unsigned int cs = data->slave_cs; spi_wr = wdata; spi_rd = rdata; /* * Assert PCSn signals between transfers * select which CTAR register and slave to be used for TX * CTAS selects which CTAR to be used, here we are using CTAR0 * PCS (peripheral chip select) is selecting the slave. */ ctrl = DSPI_TFR_CTAS(data->ctar_sel) | DSPI_TFR_PCS(cs); if (data->slave_mode & SPI_CONT) ctrl |= DSPI_TFR_CONT; if (data->slave_data_size_bits != 16) { EMSG("data_size_bits should be 16, not %u", data->slave_data_size_bits); return SPI_ERR_CFG; } while (num_pkts) { if (wdata && rdata) { dspi_tx(data, ctrl, *spi_wr++); *spi_rd++ = dspi_rx(data); } else if (wdata) { dspi_tx(data, ctrl, *spi_wr++); dspi_rx(data); } else if (rdata) { dspi_tx(data, ctrl, DSPI_IDLE_DATA); *spi_rd++ = dspi_rx(data); } num_pkts = num_pkts - 1; } return SPI_OK; } /* * Statrt DSPI module * chip: spi_chip instance */ static void ls_dspi_start(struct spi_chip *chip) { struct ls_dspi_data *data = container_of(chip, struct ls_dspi_data, chip); DMSG("Start DSPI Module"); io_clrbits32(data->base + DSPI_MCR, DSPI_MCR_HALT); } /* * Stop DSPI module * chip: spi_chip instance */ static void ls_dspi_end(struct spi_chip *chip) { struct ls_dspi_data *data = container_of(chip, struct ls_dspi_data, chip); /* De-assert PCSn if in CONT mode */ if (data->slave_mode & SPI_CONT) { unsigned int cs = data->slave_cs; unsigned int ctrl = DSPI_TFR_CTAS(data->ctar_sel) | DSPI_TFR_PCS(cs); /* Dummy read to deassert */ dspi_tx(data, ctrl, DSPI_IDLE_DATA); dspi_rx(data); } DMSG("Stop DSPI Module"); io_setbits32(data->base + DSPI_MCR, DSPI_MCR_HALT); } /* * Clear RX and TX FIFO * dspi_data: DSPI controller chip instance */ void dspi_flush_fifo(struct ls_dspi_data *dspi_data) { unsigned int mcr_val = 0; mcr_val = io_read32(dspi_data->base + DSPI_MCR); /* flush RX and TX FIFO */ mcr_val |= (DSPI_MCR_CTXF | DSPI_MCR_CRXF); io_write32(dspi_data->base + DSPI_MCR, mcr_val); } /* * Configure active state of slave * dspi_data: DSPI controller chip instance * cs: chip select value of slave * state: slave mode */ static void dspi_set_cs_active_state(struct ls_dspi_data *dspi_data, unsigned int cs, unsigned int state) { DMSG("Set CS active state cs=%d state=%d", cs, state); if (state & SPI_CS_HIGH) /* CSx inactive state is low */ io_clrbits32(dspi_data->base + DSPI_MCR, DSPI_MCR_PCSIS(cs)); else /* CSx inactive state is high */ io_setbits32(dspi_data->base + DSPI_MCR, DSPI_MCR_PCSIS(cs)); } /* * Configure transfer state of slave * dspi_data: DSPI controller chip instance * state: slave mode */ static void dspi_set_transfer_state(struct ls_dspi_data *dspi_data, unsigned int state) { unsigned int bus_setup = 0; DMSG("Set transfer state=%d bits=%d", state, dspi_data->slave_data_size_bits); bus_setup = io_read32(dspi_data->base + DSPI_CTAR0); bus_setup &= ~DSPI_CTAR_SET_MODE_MASK; bus_setup |= dspi_data->ctar_val; bus_setup &= ~(DSPI_CTAR_CPOL | DSPI_CTAR_CPHA | DSPI_CTAR_LSBFE); if (state & SPI_CPOL) bus_setup |= DSPI_CTAR_CPOL; if (state & SPI_CPHA) bus_setup |= DSPI_CTAR_CPHA; if (state & SPI_LSB_FIRST) bus_setup |= DSPI_CTAR_LSBFE; if (dspi_data->slave_data_size_bits == 8) bus_setup |= DSPI_CTAR_FMSZ(7); else if (dspi_data->slave_data_size_bits == 16) bus_setup |= DSPI_CTAR_FMSZ(15); if (dspi_data->ctar_sel == 0) io_write32(dspi_data->base + DSPI_CTAR0, bus_setup); else io_write32(dspi_data->base + DSPI_CTAR1, bus_setup); } /* * Configure speed of slave * dspi_data: DSPI controller chip instance * speed_max_hz: maximum speed for slave */ static void dspi_set_speed(struct ls_dspi_data *dspi_data, unsigned int speed_max_hz) { dspi_setup_speed(dspi_data, speed_max_hz); } /* * Configure slave for DSPI controller * dspi_data: DSPI controller chip instance * cs: chip select value of slave * speed_max_hz: maximum speed of slave * state: slave mode */ static void dspi_config_slave_state(struct ls_dspi_data *dspi_data, unsigned int cs, unsigned int speed_max_hz, unsigned int state) { unsigned int sr_val = 0; /* configure speed */ dspi_set_speed(dspi_data, speed_max_hz); /* configure transfer state */ dspi_set_transfer_state(dspi_data, state); /* configure active state of CSX */ dspi_set_cs_active_state(dspi_data, cs, state); /* clear FIFO */ dspi_flush_fifo(dspi_data); /* check module TX and RX status */ sr_val = io_read32(dspi_data->base + DSPI_SR); if ((sr_val & DSPI_SR_TXRXS) != DSPI_SR_TXRXS) EMSG("DSPI RX/TX not ready"); } /* * Configure master for DSPI controller * dspi_data: DSPI controller chip instance * mcr_val: value of master configuration register */ static void dspi_set_master_state(struct ls_dspi_data *dspi_data, unsigned int mcr_val) { DMSG("Set master state val=0x%x", mcr_val); io_write32(dspi_data->base + DSPI_MCR, mcr_val); } /* * Configure DSPI controller * chip: spi_chip instance */ static void ls_dspi_configure(struct spi_chip *chip) { struct ls_dspi_data *data = container_of(chip, struct ls_dspi_data, chip); unsigned int mcr_cfg_val = 0; mcr_cfg_val = DSPI_MCR_MSTR | DSPI_MCR_PCSIS_MASK | DSPI_MCR_CRXF | DSPI_MCR_CTXF; /* Configure Master */ dspi_set_master_state(data, mcr_cfg_val); /* Configure DSPI slave */ dspi_config_slave_state(data, data->slave_cs, data->slave_speed_max_hz, data->slave_mode); } /* * Extract information for DSPI Controller from the DTB * dspi_data: DSPI controller chip instance */ static TEE_Result get_info_from_device_tree(struct ls_dspi_data *dspi_data) { const fdt32_t *bus_num = NULL; const fdt32_t *chip_select_num = NULL; size_t size = 0; int node = 0; vaddr_t ctrl_base = 0; void *fdt = NULL; /* * First get the DSPI Controller base address from the DTB * if DTB present and if the DSPI Controller defined in it. */ fdt = get_dt(); if (!fdt) { EMSG("Unable to get DTB, DSPI init failed\n"); return TEE_ERROR_ITEM_NOT_FOUND; } node = 0; while (node != -FDT_ERR_NOTFOUND) { node = fdt_node_offset_by_compatible(fdt, node, "fsl,lx2160a-dspi"); if (!(_fdt_get_status(fdt, node) & DT_STATUS_OK_SEC)) continue; bus_num = fdt_getprop(fdt, node, "bus-num", NULL); if (bus_num && dspi_data->slave_bus == (unsigned int)fdt32_to_cpu(*bus_num)) { if (dt_map_dev(fdt, node, &ctrl_base, &size, DT_MAP_AUTO) < 0) { EMSG("Unable to get virtual address"); return TEE_ERROR_GENERIC; } break; } } dspi_data->base = ctrl_base; dspi_data->bus_clk_hz = DSPI_CLK; chip_select_num = fdt_getprop(fdt, node, "spi-num-chipselects", NULL); if (chip_select_num) dspi_data->num_chipselect = (int)fdt32_to_cpu(*chip_select_num); else return TEE_ERROR_ITEM_NOT_FOUND; dspi_data->speed_hz = DSPI_DEFAULT_SCK_FREQ; return TEE_SUCCESS; } static const struct spi_ops ls_dspi_ops = { .configure = ls_dspi_configure, .start = ls_dspi_start, .txrx8 = ls_dspi_txrx8, .txrx16 = ls_dspi_txrx16, .end = ls_dspi_end, }; DECLARE_KEEP_PAGER(ls_dspi_ops); TEE_Result ls_dspi_init(struct ls_dspi_data *dspi_data) { TEE_Result status = TEE_ERROR_GENERIC; /* * First get the DSPI Controller base address from the DTB, * if DTB present and if the DSPI Controller defined in it. */ if (dspi_data) status = get_info_from_device_tree(dspi_data); if (status == TEE_SUCCESS) /* generic DSPI chip handle */ dspi_data->chip.ops = &ls_dspi_ops; else EMSG("Unable to get info from device tree"); return status; }