/* SPDX-License-Identifier: GPL-2.0-only */ //TODO needs work #include #include #include #include #include #include "spi_internal.h" static struct fu740_spi_ctrl *fu740_spi_ctrls[] = { (struct fu740_spi_ctrl *)FU740_QSPI0, (struct fu740_spi_ctrl *)FU740_QSPI1, (struct fu740_spi_ctrl *)FU740_QSPI2 }; // Wait until SPI is ready for transmission and transmit byte. static void fu740_spi_tx(volatile struct fu740_spi_ctrl *spictrl_reg, uint8_t in) { #if __riscv_atomic int32_t r; do { asm volatile ( "amoor.w %0, %2, %1\n" : "=r" (r), "+A" (spictrl_reg->txdata.raw_bits) : "r" (in) ); } while (r < 0); #else while ((int32_t) spictrl_reg->txdata.raw_bits < 0) ; spictrl_reg->txdata.data = in; #endif } // Wait until SPI receive queue has data and read byte. static uint8_t fu740_spi_rx(volatile struct fu740_spi_ctrl *spictrl_reg) { int32_t out; while ((out = (int32_t) spictrl_reg->rxdata.raw_bits) < 0) ; return (uint8_t) out; } static int fu740_spi_xfer(const struct spi_slave *slave, const void *dout, size_t bytesout, void *din, size_t bytesin) { printk(BIOS_DEBUG, "%s 0, bytesin: %zu, bytesout: %zu, din: %p\n", __func__, bytesin, bytesout, din); hexdump(dout, bytesout); struct fu740_spi_ctrl *spictrl_reg = fu740_spi_ctrls[slave->bus]; union fu740_spi_reg_fmt fmt; fmt.raw_bits = read32(&spictrl_reg->fmt.raw_bits); if (fmt.proto == FU740_SPI_PROTO_S) { // working in full-duplex mode // receiving data needs to be triggered by sending data while (bytesout || bytesin) { uint8_t in, out = 0; if (bytesout) { out = *(uint8_t *)dout++; bytesout--; } fu740_spi_tx(spictrl_reg, out); in = fu740_spi_rx(spictrl_reg); if (bytesin) { *(uint8_t *)din++ = in; bytesin--; } } } else { // Working in half duplex // send and receive can be done separately if (dout && din) return -1; if (dout) { while (bytesout) { fu740_spi_tx(spictrl_reg, *(uint8_t *)dout++); bytesout--; } } if (din) { while (bytesin) { *(uint8_t *)din++ = fu740_spi_rx(spictrl_reg); bytesin--; } } } return 0; } static int fu740_spi_claim_bus(const struct spi_slave *slave) { struct fu740_spi_ctrl *spictrl = fu740_spi_ctrls[slave->bus]; union fu740_spi_reg_csmode csmode; csmode.raw_bits = 0; csmode.mode = FU740_SPI_CSMODE_HOLD; write32(&spictrl->csmode.raw_bits, csmode.raw_bits); return 0; } static void fu740_spi_release_bus(const struct spi_slave *slave) { struct fu740_spi_ctrl *spictrl = fu740_spi_ctrls[slave->bus]; union fu740_spi_reg_csmode csmode; csmode.raw_bits = 0; csmode.mode = FU740_SPI_CSMODE_OFF; write32(&spictrl->csmode.raw_bits, csmode.raw_bits); } // reset spi flash chip static void fu740_spi_reset(volatile struct fu740_spi_ctrl *spictrl_reg) { fu740_spi_tx(spictrl_reg, 0x66); fu740_spi_tx(spictrl_reg, 0x99); } // setup the ffmt (SPI flash instruction format) register __maybe_unused static int fu740_spi_setup_ffmt(volatile struct fu740_spi_ctrl *spictrl_reg, const struct fu740_spi_config *config) { //union fu740_spi_reg_fctrl fctrl; union fu740_spi_reg_ffmt ffmt; printk(BIOS_DEBUG, "config->data_proto: %d, config->cmd_code: %d\n", config->ffmt_config.data_proto, config->ffmt_config.cmd_code); //TODO test without this here fu740_spi_reset(spictrl_reg); ffmt.raw_bits = 0; ffmt.cmd_en = 1; // enable sending of command ffmt.addr_len = 3; // number of address bytes (0-4) ffmt.pad_cnt = 0; // number of dummy cycles TODO maybe not working ffmt.cmd_proto = FU740_SPI_PROTO_S; // protocol for transmitting command ffmt.addr_proto = FU740_SPI_PROTO_S; // protocol for transmitting address and padding ffmt.data_proto = config->ffmt_config.data_proto; // protocol for receiving data bytes ffmt.cmd_code = config->ffmt_config.cmd_code; // value of command byte ffmt.pad_code = 0; // First 8 bits to transmit during dummy cycles write32(&spictrl_reg->ffmt.raw_bits, ffmt.raw_bits); return 0; } int fu740_spi_setup(const struct spi_slave *slave) { union fu740_spi_reg_csmode csmode; union fu740_spi_reg_fctrl fctrl; struct fu740_spi_ctrl *spictrl_reg = fu740_spi_ctrls[slave->bus]; struct fu740_spi_config *config = &fu740_spi_configs[slave->bus]; if ((config->pha > 1) || (config->pol > 1) || (config->fmt_config.protocol > 2) || (config->fmt_config.endianness > 1) || (config->fmt_config.bits_per_frame > 8)) return -1; write32(&spictrl_reg->sckdiv, fu740_spi_min_clk_divisor(clock_get_pclk(), config->freq)); /* disable direct memory-mapped spi flash mode */ //TODO test if we need to disable it before changing the settings fctrl.raw_bits = 0; fctrl.en = 0; write32(&spictrl_reg->fctrl.raw_bits, fctrl.raw_bits); csmode.raw_bits = 0; csmode.mode = FU740_SPI_CSMODE_HOLD; write32(&spictrl_reg->csmode.raw_bits, csmode.raw_bits); char din[10]; char dout[10] = { 0x66 }; slave->ctrlr->xfer(slave, dout, 1, din, 0); dout[0] = 0x99; slave->ctrlr->xfer(slave, dout, 1, din, 0); int addr = 0x200; dout[0] = 0x03; dout[1] = (addr >> 16) & 0xFF; dout[2] = (addr >> 8) & 0xFF; dout[3] = addr & 0xFF; slave->ctrlr->xfer(slave, dout, 4, din, 10); csmode.mode = FU740_SPI_CSMODE_AUTO; write32(&spictrl_reg->csmode.raw_bits, csmode.raw_bits); din[9] = 0; return 0; } struct spi_ctrlr fu740_spi_ctrlr = { .xfer = fu740_spi_xfer, .setup = fu740_spi_setup, .claim_bus = fu740_spi_claim_bus, .release_bus = fu740_spi_release_bus, .max_xfer_size = SPI_CTRLR_DEFAULT_MAX_XFER_SIZE, }; const struct spi_ctrlr_buses spi_ctrlr_bus_map[] = { { .bus_start = 0, .bus_end = 2, .ctrlr = &fu740_spi_ctrlr, } }; const size_t spi_ctrlr_bus_map_count = ARRAY_SIZE(spi_ctrlr_bus_map);