arm/sunxi/sun6i_spi.c

1.8   thorpej /*	$NetBSD: sun6i_spi.c,v 1.8 2021/01/27 03:10:20 thorpej Exp $	*/
1.1  jakllsch
1.1  jakllsch /*
1.3       tnn  * Copyright (c) 2019 Tobias Nygren
1.1  jakllsch  * Copyright (c) 2018 Jonathan A. Kollasch
1.1  jakllsch  * All rights reserved.
1.1  jakllsch  *
1.1  jakllsch  * Redistribution and use in source and binary forms, with or without
1.1  jakllsch  * modification, are permitted provided that the following conditions
1.1  jakllsch  * are met:
1.1  jakllsch  * 1. Redistributions of source code must retain the above copyright
1.1  jakllsch  *    notice, this list of conditions and the following disclaimer.
1.1  jakllsch  * 2. Redistributions in binary form must reproduce the above copyright
1.1  jakllsch  *    notice, this list of conditions and the following disclaimer in the
1.1  jakllsch  *    documentation and/or other materials provided with the distribution.
1.1  jakllsch  *
1.1  jakllsch  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
1.1  jakllsch  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  jakllsch  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  jakllsch  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
1.1  jakllsch  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
1.1  jakllsch  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
1.1  jakllsch  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
1.1  jakllsch  * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
1.1  jakllsch  * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
1.1  jakllsch  * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
1.1  jakllsch  * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.1  jakllsch  */
1.1  jakllsch
1.1  jakllsch #include <sys/cdefs.h>
1.8   thorpej __KERNEL_RCSID(0, "$NetBSD: sun6i_spi.c,v 1.8 2021/01/27 03:10:20 thorpej Exp $");
1.1  jakllsch
1.1  jakllsch #include <sys/param.h>
1.1  jakllsch #include <sys/device.h>
1.1  jakllsch #include <sys/systm.h>
1.1  jakllsch #include <sys/bus.h>
1.1  jakllsch #include <sys/intr.h>
1.1  jakllsch #include <sys/kernel.h>
1.1  jakllsch
1.1  jakllsch #include <sys/bitops.h>
1.1  jakllsch #include <dev/spi/spivar.h>
1.1  jakllsch
1.1  jakllsch #include <arm/sunxi/sun6i_spireg.h>
1.1  jakllsch
1.1  jakllsch #include <dev/fdt/fdtvar.h>
1.1  jakllsch
1.1  jakllsch #include <arm/fdt/arm_fdtvar.h>
1.1  jakllsch
1.1  jakllsch #define SPI_IER_DEFAULT (SPI_IER_TC_INT_EN | SPI_IER_TF_UDR_INT_EN | \
1.1  jakllsch 	SPI_IER_TF_OVF_INT_EN | SPI_IER_RF_UDR_INT_EN | SPI_IER_RF_OVF_INT_EN)
1.1  jakllsch
1.1  jakllsch struct sun6ispi_softc {
1.1  jakllsch 	device_t		sc_dev;
1.1  jakllsch 	bus_space_tag_t		sc_iot;
1.1  jakllsch 	bus_space_handle_t	sc_ioh;
1.1  jakllsch 	void			*sc_intrh;
1.1  jakllsch 	struct spi_controller	sc_spi;
1.1  jakllsch 	SIMPLEQ_HEAD(,spi_transfer) sc_q;
1.1  jakllsch 	struct spi_transfer	*sc_transfer;
1.1  jakllsch 	struct spi_chunk	*sc_wchunk;
1.1  jakllsch 	struct spi_chunk	*sc_rchunk;
1.1  jakllsch 	uint32_t		sc_TCR;
1.1  jakllsch 	u_int			sc_modclkrate;
1.1  jakllsch 	volatile bool		sc_running;
1.1  jakllsch };
1.1  jakllsch
1.3       tnn #define SPIREG_READ(sc, reg) \
1.3       tnn     bus_space_read_4((sc)->sc_iot, (sc)->sc_ioh, (reg))
1.3       tnn #define SPIREG_WRITE(sc, reg, val) \
1.3       tnn     bus_space_write_4((sc)->sc_iot, (sc)->sc_ioh, (reg), (val))
1.3       tnn
1.1  jakllsch static int sun6ispi_match(device_t, cfdata_t, void *);
1.1  jakllsch static void sun6ispi_attach(device_t, device_t, void *);
1.1  jakllsch
1.1  jakllsch static int sun6ispi_configure(void *, int, int, int);
1.1  jakllsch static int sun6ispi_transfer(void *, struct spi_transfer *);
1.1  jakllsch
1.1  jakllsch static void sun6ispi_start(struct sun6ispi_softc * const);
1.1  jakllsch static int sun6ispi_intr(void *);
1.1  jakllsch
1.1  jakllsch static void sun6ispi_send(struct sun6ispi_softc * const);
1.1  jakllsch static void sun6ispi_recv(struct sun6ispi_softc * const);
1.1  jakllsch
1.1  jakllsch CFATTACH_DECL_NEW(sun6i_spi, sizeof(struct sun6ispi_softc),
1.1  jakllsch     sun6ispi_match, sun6ispi_attach, NULL, NULL);
1.1  jakllsch
1.8   thorpej static const struct device_compatible_entry compat_data[] = {
1.8   thorpej 	{ .compat = "allwinner,sun8i-h3-spi" },
1.8   thorpej 	DEVICE_COMPAT_EOL
1.8   thorpej };
1.8   thorpej
1.1  jakllsch static int
1.1  jakllsch sun6ispi_match(device_t parent, cfdata_t cf, void *aux)
1.1  jakllsch {
1.1  jakllsch 	struct fdt_attach_args * const faa = aux;
1.1  jakllsch
1.8   thorpej 	return of_compatible_match(faa->faa_phandle, compat_data);
1.1  jakllsch }
1.1  jakllsch
1.1  jakllsch static void
1.1  jakllsch sun6ispi_attach(device_t parent, device_t self, void *aux)
1.1  jakllsch {
1.1  jakllsch 	struct sun6ispi_softc * const sc = device_private(self);
1.1  jakllsch 	struct fdt_attach_args * const faa = aux;
1.1  jakllsch 	struct spibus_attach_args sba;
1.3       tnn 	const int phandle = faa->faa_phandle;
1.3       tnn 	bus_addr_t addr;
1.3       tnn 	bus_size_t size;
1.1  jakllsch 	struct fdtbus_reset *rst;
1.1  jakllsch 	struct clk *clk, *modclk;
1.1  jakllsch 	uint32_t gcr, isr;
1.1  jakllsch 	char intrstr[128];
1.1  jakllsch
1.1  jakllsch 	sc->sc_dev = self;
1.1  jakllsch 	sc->sc_iot = faa->faa_bst;
1.1  jakllsch 	SIMPLEQ_INIT(&sc->sc_q);
1.1  jakllsch
1.3       tnn 	if ((clk = fdtbus_clock_get_index(phandle, 0)) == NULL
1.3       tnn 	    || clk_enable(clk) != 0) {
1.3       tnn 		aprint_error(": couldn't enable clock\n");
1.1  jakllsch 		return;
1.1  jakllsch 	}
1.1  jakllsch
1.3       tnn 	/* 200MHz max on H3,H5 */
1.3       tnn 	if ((modclk = fdtbus_clock_get(phandle, "mod")) == NULL
1.3       tnn 	    || clk_set_rate(modclk, 200000000) != 0
1.3       tnn 	    || clk_enable(modclk) != 0) {
1.3       tnn 		aprint_error(": couldn't enable module clock\n");
1.1  jakllsch 		return;
1.1  jakllsch 	}
1.3       tnn 	sc->sc_modclkrate = clk_get_rate(modclk);
1.1  jakllsch
1.3       tnn 	if (fdtbus_get_reg(phandle, 0, &addr, &size) != 0
1.3       tnn 	    || bus_space_map(sc->sc_iot, addr, size, 0, &sc->sc_ioh) != 0) {
1.3       tnn 		aprint_error(": couldn't map registers\n");
1.3       tnn 		return;
1.1  jakllsch 	}
1.1  jakllsch
1.1  jakllsch 	if ((rst = fdtbus_reset_get_index(phandle, 0)) != NULL)
1.1  jakllsch 		if (fdtbus_reset_deassert(rst) != 0) {
1.1  jakllsch 			aprint_error(": couldn't de-assert reset\n");
1.1  jakllsch 			return;
1.1  jakllsch 		}
1.1  jakllsch
1.3       tnn 	isr = SPIREG_READ(sc, SPI_INT_STA);
1.3       tnn 	SPIREG_WRITE(sc, SPI_INT_STA, isr);
1.1  jakllsch
1.1  jakllsch 	if (!fdtbus_intr_str(phandle, 0, intrstr, sizeof(intrstr))) {
1.1  jakllsch 		aprint_error(": failed to decode interrupt\n");
1.1  jakllsch 		return;
1.1  jakllsch 	}
1.1  jakllsch
1.6  jmcneill 	sc->sc_intrh = fdtbus_intr_establish_xname(phandle, 0, IPL_VM, 0,
1.6  jmcneill 	    sun6ispi_intr, sc, device_xname(self));
1.1  jakllsch 	if (sc->sc_intrh == NULL) {
1.3       tnn 		aprint_error(": unable to establish interrupt\n");
1.1  jakllsch 		return;
1.1  jakllsch 	}
1.3       tnn
1.3       tnn 	aprint_naive("\n");
1.3       tnn 	aprint_normal(": SPI\n");
1.7  jmcneill
1.1  jakllsch 	aprint_normal_dev(self, "interrupting on %s\n", intrstr);
1.1  jakllsch
1.1  jakllsch 	gcr = SPI_GCR_SRST;
1.3       tnn 	SPIREG_WRITE(sc, SPI_GCR, gcr);
1.2  jakllsch 	for (u_int i = 0; ; i++) {
1.2  jakllsch 		if (i >= 1000000) {
1.2  jakllsch 			aprint_error_dev(self, "reset timeout\n");
1.2  jakllsch 			return;
1.2  jakllsch 		}
1.2  jakllsch 		gcr = bus_space_read_4(sc->sc_iot, sc->sc_ioh, SPI_GCR);
1.2  jakllsch 		if ((gcr & SPI_GCR_SRST) == 0)
1.2  jakllsch 			break;
1.2  jakllsch 		else
1.2  jakllsch 			DELAY(1);
1.2  jakllsch 	}
1.1  jakllsch 	gcr = SPI_GCR_TP_EN | SPI_GCR_MODE | SPI_GCR_EN;
1.3       tnn 	SPIREG_WRITE(sc, SPI_GCR, gcr);
1.1  jakllsch
1.3       tnn 	SPIREG_WRITE(sc, SPI_IER, SPI_IER_DEFAULT);
1.1  jakllsch
1.1  jakllsch 	sc->sc_spi.sct_cookie = sc;
1.1  jakllsch 	sc->sc_spi.sct_configure = sun6ispi_configure;
1.1  jakllsch 	sc->sc_spi.sct_transfer = sun6ispi_transfer;
1.1  jakllsch 	sc->sc_spi.sct_nslaves = 4;
1.1  jakllsch
1.5       tnn 	memset(&sba, 0, sizeof(sba));
1.1  jakllsch 	sba.sba_controller = &sc->sc_spi;
1.1  jakllsch
1.1  jakllsch 	(void) config_found_ia(self, "spibus", &sba, spibus_print);
1.1  jakllsch }
1.1  jakllsch
1.1  jakllsch static int
1.1  jakllsch sun6ispi_configure(void *cookie, int slave, int mode, int speed)
1.1  jakllsch {
1.1  jakllsch 	struct sun6ispi_softc * const sc = cookie;
1.1  jakllsch 	uint32_t tcr, cctl;
1.3       tnn 	uint32_t minfreq, maxfreq;
1.1  jakllsch
1.3       tnn 	minfreq = sc->sc_modclkrate >> 16;
1.3       tnn 	maxfreq = sc->sc_modclkrate >> 1;
1.1  jakllsch
1.3       tnn 	if (speed <= 0 || speed < minfreq || speed > maxfreq)
1.1  jakllsch 		return EINVAL;
1.1  jakllsch
1.3       tnn 	if (slave >= sc->sc_spi.sct_nslaves)
1.1  jakllsch 		return EINVAL;
1.7  jmcneill
1.3       tnn 	tcr = SPI_TCR_SS_LEVEL | SPI_TCR_SPOL;
1.1  jakllsch
1.1  jakllsch 	switch (mode) {
1.1  jakllsch 	case SPI_MODE_0:
1.1  jakllsch 		tcr |= 0;
1.1  jakllsch 		break;
1.1  jakllsch 	case SPI_MODE_1:
1.1  jakllsch 		tcr |= SPI_TCR_CPHA;
1.1  jakllsch 		break;
1.1  jakllsch 	case SPI_MODE_2:
1.1  jakllsch 		tcr |= SPI_TCR_CPOL;
1.1  jakllsch 		break;
1.1  jakllsch 	case SPI_MODE_3:
1.1  jakllsch 		tcr |= SPI_TCR_CPHA|SPI_TCR_CPOL;
1.1  jakllsch 		break;
1.1  jakllsch 	default:
1.1  jakllsch 		return EINVAL;
1.1  jakllsch 	}
1.1  jakllsch
1.1  jakllsch 	sc->sc_TCR = tcr;
1.1  jakllsch
1.3       tnn 	if (speed < sc->sc_modclkrate / 512) {
1.1  jakllsch 		for (cctl = 0; cctl <= __SHIFTOUT_MASK(SPI_CCTL_CDR1); cctl++) {
1.1  jakllsch 			if ((sc->sc_modclkrate / (1<<cctl)) <= speed)
1.1  jakllsch 				goto cdr1_found;
1.1  jakllsch 		}
1.1  jakllsch 		return EINVAL;
1.1  jakllsch cdr1_found:
1.1  jakllsch 		cctl = __SHIFTIN(cctl, SPI_CCTL_CDR1);
1.1  jakllsch 	} else {
1.1  jakllsch 		cctl = howmany(sc->sc_modclkrate, 2 * speed) - 1;
1.1  jakllsch 		cctl = SPI_CCTL_DRS|__SHIFTIN(cctl, SPI_CCTL_CDR2);
1.1  jakllsch 	}
1.1  jakllsch
1.3       tnn 	device_printf(sc->sc_dev, "tcr 0x%x, cctl 0x%x, CLK %uHz, SCLK %uHz\n",
1.3       tnn 	    tcr, cctl, sc->sc_modclkrate,
1.3       tnn 	    (cctl & SPI_CCTL_DRS)
1.3       tnn 	    ? (sc->sc_modclkrate / (u_int)(2 * (__SHIFTOUT(cctl, SPI_CCTL_CDR2) + 1)))
1.3       tnn 	    : (sc->sc_modclkrate >> (__SHIFTOUT(cctl, SPI_CCTL_CDR1) + 1))
1.3       tnn 	);
1.3       tnn
1.3       tnn 	SPIREG_WRITE(sc, SPI_CCTL, cctl);
1.1  jakllsch
1.1  jakllsch 	return 0;
1.1  jakllsch }
1.1  jakllsch
1.1  jakllsch static int
1.1  jakllsch sun6ispi_transfer(void *cookie, struct spi_transfer *st)
1.1  jakllsch {
1.1  jakllsch 	struct sun6ispi_softc * const sc = cookie;
1.1  jakllsch 	int s;
1.1  jakllsch
1.1  jakllsch 	s = splbio();
1.1  jakllsch 	spi_transq_enqueue(&sc->sc_q, st);
1.1  jakllsch 	if (sc->sc_running == false) {
1.1  jakllsch 		sun6ispi_start(sc);
1.1  jakllsch 	}
1.1  jakllsch 	splx(s);
1.1  jakllsch 	return 0;
1.1  jakllsch }
1.1  jakllsch
1.1  jakllsch static void
1.1  jakllsch sun6ispi_start(struct sun6ispi_softc * const sc)
1.1  jakllsch {
1.1  jakllsch 	struct spi_transfer *st;
1.1  jakllsch 	uint32_t isr, tcr;
1.3       tnn 	struct spi_chunk *chunk;
1.3       tnn 	size_t burstcount;
1.1  jakllsch
1.1  jakllsch 	while ((st = spi_transq_first(&sc->sc_q)) != NULL) {
1.1  jakllsch
1.1  jakllsch 		spi_transq_dequeue(&sc->sc_q);
1.1  jakllsch
1.1  jakllsch 		KASSERT(sc->sc_transfer == NULL);
1.1  jakllsch 		sc->sc_transfer = st;
1.1  jakllsch 		sc->sc_rchunk = sc->sc_wchunk = st->st_chunks;
1.1  jakllsch 		sc->sc_running = true;
1.1  jakllsch
1.3       tnn 		isr = SPIREG_READ(sc, SPI_INT_STA);
1.3       tnn 		SPIREG_WRITE(sc, SPI_INT_STA, isr);
1.1  jakllsch
1.3       tnn 		burstcount = 0;
1.3       tnn 		for (chunk = st->st_chunks; chunk; chunk = chunk->chunk_next) {
1.3       tnn 			burstcount += chunk->chunk_count;
1.3       tnn 		}
1.3       tnn 		KASSERT(burstcount <= SPI_BC_MBC);
1.3       tnn 		SPIREG_WRITE(sc, SPI_BC, __SHIFTIN(burstcount, SPI_BC_MBC));
1.3       tnn 		SPIREG_WRITE(sc, SPI_TC, __SHIFTIN(burstcount, SPI_TC_MWTC));
1.3       tnn 		SPIREG_WRITE(sc, SPI_BCC, __SHIFTIN(burstcount, SPI_BCC_STC));
1.1  jakllsch
1.1  jakllsch 		KASSERT(st->st_slave <= 3);
1.1  jakllsch 		tcr = sc->sc_TCR | __SHIFTIN(st->st_slave, SPI_TCR_SS_SEL);
1.1  jakllsch
1.1  jakllsch 		sun6ispi_send(sc);
1.1  jakllsch
1.1  jakllsch 		const uint32_t ier = SPI_IER_DEFAULT | SPI_IER_RF_RDY_INT_EN | SPI_IER_TX_ERQ_INT_EN;
1.3       tnn 		SPIREG_WRITE(sc, SPI_IER, ier);
1.1  jakllsch
1.3       tnn 		SPIREG_WRITE(sc, SPI_TCR, tcr|SPI_TCR_XCH);
1.1  jakllsch
1.1  jakllsch 		if (!cold)
1.1  jakllsch 			return;
1.1  jakllsch
1.1  jakllsch 		for (;;) {
1.1  jakllsch 			sun6ispi_intr(sc);
1.1  jakllsch 			if (ISSET(st->st_flags, SPI_F_DONE))
1.1  jakllsch 				break;
1.1  jakllsch 		}
1.1  jakllsch 	}
1.1  jakllsch
1.1  jakllsch 	sc->sc_running = false;
1.1  jakllsch }
1.1  jakllsch
1.1  jakllsch static void
1.1  jakllsch sun6ispi_send(struct sun6ispi_softc * const sc)
1.1  jakllsch {
1.1  jakllsch 	uint8_t fd;
1.1  jakllsch 	uint32_t fsr;
1.1  jakllsch 	struct spi_chunk *chunk;
1.1  jakllsch
1.1  jakllsch 	while ((chunk = sc->sc_wchunk) != NULL) {
1.1  jakllsch 		while (chunk->chunk_wresid) {
1.3       tnn 			fsr = SPIREG_READ(sc, SPI_FSR);
1.1  jakllsch 			if (__SHIFTOUT(fsr, SPI_FSR_TF_CNT) >= 64) {
1.1  jakllsch 				return;
1.1  jakllsch 			}
1.1  jakllsch 			if (chunk->chunk_wptr) {
1.1  jakllsch 				fd = *chunk->chunk_wptr++;
1.1  jakllsch 			} else {
1.1  jakllsch 				fd = '\0';
1.1  jakllsch 			}
1.1  jakllsch 			bus_space_write_1(sc->sc_iot, sc->sc_ioh, SPI_TXD, fd);
1.1  jakllsch 			chunk->chunk_wresid--;
1.1  jakllsch 		}
1.1  jakllsch 		sc->sc_wchunk = sc->sc_wchunk->chunk_next;
1.1  jakllsch 	}
1.1  jakllsch }
1.1  jakllsch
1.1  jakllsch static void
1.1  jakllsch sun6ispi_recv(struct sun6ispi_softc * const sc)
1.1  jakllsch {
1.1  jakllsch 	uint8_t fd;
1.1  jakllsch 	uint32_t fsr;
1.1  jakllsch 	struct spi_chunk *chunk;
1.1  jakllsch
1.1  jakllsch 	while ((chunk = sc->sc_rchunk) != NULL) {
1.1  jakllsch 		while (chunk->chunk_rresid) {
1.3       tnn 			fsr = SPIREG_READ(sc, SPI_FSR);
1.1  jakllsch 			if (__SHIFTOUT(fsr, SPI_FSR_RF_CNT) == 0) {
1.1  jakllsch 				return;
1.1  jakllsch 			}
1.1  jakllsch 			fd = bus_space_read_1(sc->sc_iot, sc->sc_ioh, SPI_RXD);
1.1  jakllsch 			if (chunk->chunk_rptr) {
1.1  jakllsch 				*chunk->chunk_rptr++ = fd;
1.1  jakllsch 			}
1.1  jakllsch 			chunk->chunk_rresid--;
1.1  jakllsch 		}
1.1  jakllsch 		sc->sc_rchunk = sc->sc_rchunk->chunk_next;
1.1  jakllsch 	}
1.1  jakllsch }
1.1  jakllsch
1.1  jakllsch static int
1.1  jakllsch sun6ispi_intr(void *cookie)
1.1  jakllsch {
1.1  jakllsch 	struct sun6ispi_softc * const sc = cookie;
1.1  jakllsch 	struct spi_transfer *st;
1.1  jakllsch 	uint32_t isr;
1.1  jakllsch
1.3       tnn 	isr = SPIREG_READ(sc, SPI_INT_STA);
1.3       tnn 	SPIREG_WRITE(sc, SPI_INT_STA, isr);
1.1  jakllsch
1.1  jakllsch 	if (ISSET(isr, SPI_ISR_RX_RDY)) {
1.1  jakllsch 		sun6ispi_recv(sc);
1.1  jakllsch 		sun6ispi_send(sc);
1.1  jakllsch 	}
1.1  jakllsch
1.1  jakllsch 	if (ISSET(isr, SPI_ISR_TC)) {
1.3       tnn 		SPIREG_WRITE(sc, SPI_IER, SPI_IER_DEFAULT);
1.1  jakllsch
1.1  jakllsch 		sc->sc_rchunk = sc->sc_wchunk = NULL;
1.1  jakllsch 		st = sc->sc_transfer;
1.1  jakllsch 		sc->sc_transfer = NULL;
1.1  jakllsch 		KASSERT(st != NULL);
1.1  jakllsch 		spi_done(st, 0);
1.1  jakllsch 		sc->sc_running = false;
1.1  jakllsch 	}
1.1  jakllsch
1.1  jakllsch 	return isr;
1.1  jakllsch }