arm/imx/imxspi.c

1.3  hkenken /*	$NetBSD: imxspi.c,v 1.3 2017/08/07 09:24:43 hkenken Exp $	*/
1.1  hkenken
1.1  hkenken /*-
1.1  hkenken  * Copyright (c) 2014  Genetec Corporation.  All rights reserved.
1.1  hkenken  * Written by Hashimoto Kenichi for Genetec Corporation.
1.1  hkenken  *
1.1  hkenken  * Redistribution and use in source and binary forms, with or without
1.1  hkenken  * modification, are permitted provided that the following conditions
1.1  hkenken  * are met:
1.1  hkenken  * 1. Redistributions of source code must retain the above copyright
1.1  hkenken  *    notice, this list of conditions and the following disclaimer.
1.1  hkenken  * 2. Redistributions in binary form must reproduce the above copyright
1.1  hkenken  *    notice, this list of conditions and the following disclaimer in the
1.1  hkenken  *    documentation and/or other materials provided with the distribution.
1.1  hkenken  *
1.1  hkenken  * THIS SOFTWARE IS PROVIDED BY GENETEC CORPORATION ``AS IS'' AND
1.1  hkenken  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  hkenken  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  hkenken  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL GENETEC CORPORATION
1.1  hkenken  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  hkenken  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  hkenken  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  hkenken  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  hkenken  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  hkenken  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1  hkenken  * POSSIBILITY OF SUCH DAMAGE.
1.1  hkenken  */
1.1  hkenken
1.1  hkenken /*
1.1  hkenken  * this module support CSPI and eCSPI.
1.1  hkenken  * i.MX51 have 2 eCSPI and 1 CSPI modules.
1.1  hkenken  */
1.1  hkenken
1.1  hkenken #include <sys/cdefs.h>
1.3  hkenken __KERNEL_RCSID(0, "$NetBSD: imxspi.c,v 1.3 2017/08/07 09:24:43 hkenken Exp $");
1.1  hkenken
1.1  hkenken #include "opt_imx.h"
1.1  hkenken #include "opt_imxspi.h"
1.1  hkenken
1.1  hkenken #include <sys/param.h>
1.1  hkenken #include <sys/systm.h>
1.1  hkenken #include <sys/kernel.h>
1.1  hkenken #include <sys/device.h>
1.1  hkenken #include <sys/errno.h>
1.1  hkenken #include <sys/proc.h>
1.1  hkenken #include <sys/intr.h>
1.1  hkenken
1.1  hkenken #include <sys/bus.h>
1.1  hkenken #include <machine/cpu.h>
1.1  hkenken #include <machine/intr.h>
1.1  hkenken
1.1  hkenken #include <arm/imx/imxspivar.h>
1.1  hkenken #include <arm/imx/imxspireg.h>
1.1  hkenken
1.1  hkenken /* SPI service routines */
1.1  hkenken static int imxspi_configure_enhanced(void *, int, int, int);
1.1  hkenken static int imxspi_configure(void *, int, int, int);
1.1  hkenken static int imxspi_transfer(void *, struct spi_transfer *);
1.1  hkenken static int imxspi_intr(void *);
1.1  hkenken
1.1  hkenken /* internal stuff */
1.1  hkenken void imxspi_done(struct imxspi_softc *, int);
1.1  hkenken void imxspi_send(struct imxspi_softc *);
1.1  hkenken void imxspi_recv(struct imxspi_softc *);
1.1  hkenken void imxspi_sched(struct imxspi_softc *);
1.1  hkenken
1.1  hkenken #define	IMXSPI(x)							      \
1.1  hkenken 	((sc->sc_enhanced) ? __CONCAT(ECSPI_, x) : __CONCAT(CSPI_, x))
1.1  hkenken #define	READ_REG(sc, x)							      \
1.1  hkenken 	bus_space_read_4(sc->sc_iot, sc->sc_ioh, IMXSPI(x))
1.1  hkenken #define	WRITE_REG(sc, x, v)						      \
1.1  hkenken 	bus_space_write_4(sc->sc_iot, sc->sc_ioh, IMXSPI(x), (v))
1.1  hkenken
1.1  hkenken #ifdef IMXSPI_DEBUG
1.1  hkenken int imxspi_debug = IMXSPI_DEBUG;
1.1  hkenken #define	DPRINTFN(n,x)   if (imxspi_debug>(n)) printf x;
1.1  hkenken #else
1.1  hkenken #define	DPRINTFN(n,x)
1.1  hkenken #endif
1.1  hkenken
1.1  hkenken int
1.1  hkenken imxspi_attach_common(device_t parent, struct imxspi_softc *sc, void *aux)
1.1  hkenken {
1.1  hkenken 	struct imxspi_attach_args *saa = aux;
1.1  hkenken 	struct spibus_attach_args sba;
1.1  hkenken 	bus_addr_t addr = saa->saa_addr;
1.1  hkenken 	bus_size_t size = saa->saa_size;
1.1  hkenken
1.1  hkenken 	sc->sc_iot = saa->saa_iot;
1.1  hkenken 	sc->sc_freq = saa->saa_freq;
1.1  hkenken 	sc->sc_tag = saa->saa_tag;
1.1  hkenken 	sc->sc_enhanced = saa->saa_enhanced;
1.1  hkenken 	if (size <= 0)
1.1  hkenken 		size = SPI_SIZE;
1.1  hkenken
1.1  hkenken 	if (bus_space_map(sc->sc_iot, addr, size, 0, &sc->sc_ioh)) {
1.1  hkenken 		aprint_error_dev(sc->sc_dev, "couldn't map registers\n");
1.1  hkenken 		return 1;
1.1  hkenken 	}
1.1  hkenken
1.1  hkenken 	aprint_normal(": i.MX %sCSPI Controller (clock %ld Hz)\n",
1.1  hkenken 	    ((sc->sc_enhanced) ? "e" : ""), sc->sc_freq);
1.1  hkenken
1.1  hkenken 	/* Initialize SPI controller */
1.1  hkenken 	sc->sc_spi.sct_cookie = sc;
1.1  hkenken 	if (sc->sc_enhanced)
1.1  hkenken 		sc->sc_spi.sct_configure = imxspi_configure_enhanced;
1.1  hkenken 	else
1.1  hkenken 		sc->sc_spi.sct_configure = imxspi_configure;
1.1  hkenken 	sc->sc_spi.sct_transfer = imxspi_transfer;
1.1  hkenken
1.1  hkenken 	/* sc->sc_spi.sct_nslaves must have been initialized by machdep code */
1.1  hkenken 	sc->sc_spi.sct_nslaves = saa->saa_nslaves;
1.1  hkenken 	if (!sc->sc_spi.sct_nslaves)
1.1  hkenken 		aprint_error_dev(sc->sc_dev, "no slaves!\n");
1.1  hkenken
1.1  hkenken 	sba.sba_controller = &sc->sc_spi;
1.1  hkenken
1.1  hkenken 	/* initialize the queue */
1.1  hkenken 	SIMPLEQ_INIT(&sc->sc_q);
1.1  hkenken
1.1  hkenken 	/* configure SPI */
1.1  hkenken 	/* Setup Control Register */
1.1  hkenken 	WRITE_REG(sc, CONREG, __SHIFTIN(0, IMXSPI(CON_DRCTL)) |
1.1  hkenken 	    __SHIFTIN(8 - 1, IMXSPI(CON_BITCOUNT)) |
1.1  hkenken 	    __SHIFTIN(0xf, IMXSPI(CON_MODE)) | IMXSPI(CON_ENABLE));
1.1  hkenken
1.1  hkenken 	/* TC and RR interruption */
1.1  hkenken 	WRITE_REG(sc, INTREG,  (IMXSPI(INTR_TC_EN) | IMXSPI(INTR_RR_EN)));
1.1  hkenken 	WRITE_REG(sc, STATREG, IMXSPI(STAT_CLR));
1.1  hkenken
1.1  hkenken 	WRITE_REG(sc, PERIODREG, 0x0);
1.1  hkenken
1.1  hkenken 	/* enable device interrupts */
1.1  hkenken 	sc->sc_ih = intr_establish(saa->saa_irq, IPL_BIO, IST_LEVEL,
1.1  hkenken 	    imxspi_intr, sc);
1.1  hkenken
1.1  hkenken 	/* attach slave devices */
1.1  hkenken 	(void)config_found_ia(sc->sc_dev, "spibus", &sba, spibus_print);
1.1  hkenken
1.1  hkenken 	return 0;
1.1  hkenken }
1.1  hkenken
1.1  hkenken static int
1.1  hkenken imxspi_configure(void *arg, int slave, int mode, int speed)
1.1  hkenken {
1.1  hkenken 	struct imxspi_softc *sc = arg;
1.1  hkenken 	uint32_t div_cnt = 0;
1.1  hkenken 	uint32_t div;
1.1  hkenken 	uint32_t contrl = 0;
1.1  hkenken
1.1  hkenken 	div = (sc->sc_freq + (speed - 1)) / speed;
1.1  hkenken 	div = div - 1;
1.1  hkenken 	for (div_cnt = 0; div > 0; div_cnt++)
1.1  hkenken 		div >>= 1;
1.1  hkenken
1.1  hkenken 	div_cnt = div_cnt - 2;
1.1  hkenken 	if (div_cnt >= 7)
1.1  hkenken 		div_cnt = 7;
1.1  hkenken
1.1  hkenken 	contrl = READ_REG(sc, CONREG);
1.1  hkenken 	contrl &= ~CSPI_CON_DIV;
1.1  hkenken 	contrl |= __SHIFTIN(div_cnt, CSPI_CON_DIV);
1.1  hkenken
1.1  hkenken 	contrl &= ~(CSPI_CON_POL | CSPI_CON_PHA);
1.1  hkenken 	switch (mode) {
1.1  hkenken 	case SPI_MODE_0:
1.1  hkenken 		/* CPHA = 0, CPOL = 0 */
1.1  hkenken 		break;
1.1  hkenken 	case SPI_MODE_1:
1.1  hkenken 		/* CPHA = 1, CPOL = 0 */
1.1  hkenken 		contrl |= CSPI_CON_PHA;
1.1  hkenken 		break;
1.1  hkenken 	case SPI_MODE_2:
1.1  hkenken 		/* CPHA = 0, CPOL = 1 */
1.1  hkenken 		contrl |= CSPI_CON_POL;
1.1  hkenken 		break;
1.1  hkenken 	case SPI_MODE_3:
1.1  hkenken 		/* CPHA = 1, CPOL = 1 */
1.1  hkenken 		contrl |= CSPI_CON_POL;
1.1  hkenken 		contrl |= CSPI_CON_PHA;
1.1  hkenken 		break;
1.1  hkenken 	default:
1.1  hkenken 		return EINVAL;
1.1  hkenken 	}
1.1  hkenken 	WRITE_REG(sc, CONREG, contrl);
1.1  hkenken
1.1  hkenken 	DPRINTFN(3, ("%s: slave %d mode %d speed %d\n",
1.1  hkenken 		__func__, slave, mode, speed));
1.1  hkenken
1.1  hkenken 	return 0;
1.1  hkenken }
1.1  hkenken
1.1  hkenken static int
1.1  hkenken imxspi_configure_enhanced(void *arg, int slave, int mode, int speed)
1.1  hkenken {
1.1  hkenken 	struct imxspi_softc *sc = arg;
1.1  hkenken 	uint32_t div_cnt = 0;
1.1  hkenken 	uint32_t div;
1.1  hkenken 	uint32_t contrl = 0;
1.1  hkenken 	uint32_t config = 0;
1.1  hkenken
1.1  hkenken 	div = (sc->sc_freq + (speed - 1)) / speed;
1.1  hkenken 	for (div_cnt = 0; div > 0; div_cnt++)
1.1  hkenken 		div >>= 1;
1.1  hkenken
1.1  hkenken 	if (div_cnt >= 15)
1.1  hkenken 		div_cnt = 15;
1.1  hkenken
1.1  hkenken 	contrl = READ_REG(sc, CONREG);
1.1  hkenken 	contrl |= __SHIFTIN(div_cnt, ECSPI_CON_DIV);
1.1  hkenken 	contrl |= __SHIFTIN(slave, ECSPI_CON_CS);
1.1  hkenken 	contrl |= __SHIFTIN(__BIT(slave), ECSPI_CON_MODE);
1.1  hkenken 	WRITE_REG(sc, CONREG, contrl);
1.1  hkenken
1.1  hkenken 	config = bus_space_read_4(sc->sc_iot, sc->sc_ioh, ECSPI_CONFIGREG);
1.1  hkenken 	config &= ~(__SHIFTIN(__BIT(slave), ECSPI_CONFIG_SCLK_POL) |
1.1  hkenken 	    __SHIFTIN(__BIT(slave), ECSPI_CONFIG_SCLK_PHA));
1.1  hkenken 	switch (mode) {
1.1  hkenken 	case SPI_MODE_0:
1.1  hkenken 		/* CPHA = 0, CPOL = 0 */
1.1  hkenken 		break;
1.1  hkenken 	case SPI_MODE_1:
1.1  hkenken 		/* CPHA = 1, CPOL = 0 */
1.1  hkenken 		config |= __SHIFTIN(__BIT(slave), ECSPI_CONFIG_SCLK_PHA);
1.1  hkenken 		break;
1.1  hkenken 	case SPI_MODE_2:
1.1  hkenken 		/* CPHA = 0, CPOL = 1 */
1.1  hkenken 		config |= __SHIFTIN(__BIT(slave), ECSPI_CONFIG_SCLK_POL);
1.1  hkenken 		break;
1.1  hkenken 	case SPI_MODE_3:
1.1  hkenken 		/* CPHA = 1, CPOL = 1 */
1.1  hkenken 		config |= __SHIFTIN(__BIT(slave), ECSPI_CONFIG_SCLK_PHA);
1.1  hkenken 		config |= __SHIFTIN(__BIT(slave), ECSPI_CONFIG_SCLK_POL);
1.1  hkenken 		break;
1.1  hkenken 	default:
1.1  hkenken 		return EINVAL;
1.1  hkenken 	}
1.1  hkenken 	config |= __SHIFTIN(__BIT(slave), ECSPI_CONFIG_SSB_CTL);
1.1  hkenken 	bus_space_write_4(sc->sc_iot, sc->sc_ioh, ECSPI_CONFIGREG, config);
1.1  hkenken
1.1  hkenken 	DPRINTFN(3, ("%s: slave %d mode %d speed %d\n",
1.1  hkenken 		__func__, slave, mode, speed));
1.1  hkenken
1.1  hkenken 	return 0;
1.1  hkenken }
1.1  hkenken
1.1  hkenken void
1.1  hkenken imxspi_send(struct imxspi_softc *sc)
1.1  hkenken {
1.1  hkenken 	uint32_t data;
1.1  hkenken 	struct spi_chunk *chunk;
1.1  hkenken
1.1  hkenken 	/* fill the fifo */
1.1  hkenken 	while ((chunk = sc->sc_wchunk) != NULL) {
1.1  hkenken 		while (chunk->chunk_wresid) {
1.1  hkenken 			/* transmit fifo full? */
1.1  hkenken 			if (READ_REG(sc, STATREG) & IMXSPI(STAT_TF))
1.3  hkenken 				goto out;
1.1  hkenken
1.1  hkenken 			if (chunk->chunk_wptr) {
1.1  hkenken 				data = *chunk->chunk_wptr;
1.1  hkenken 				chunk->chunk_wptr++;
1.1  hkenken 			} else {
1.1  hkenken 				data = 0xff;
1.1  hkenken 			}
1.1  hkenken 			chunk->chunk_wresid--;
1.1  hkenken
1.1  hkenken 			WRITE_REG(sc, TXDATA, data);
1.1  hkenken 		}
1.1  hkenken 		/* advance to next transfer */
1.1  hkenken 		sc->sc_wchunk = sc->sc_wchunk->chunk_next;
1.1  hkenken 	}
1.3  hkenken out:
1.1  hkenken 	if (!(READ_REG(sc, STATREG) & IMXSPI(INTR_TE_EN)))
1.1  hkenken 		WRITE_REG(sc, CONREG, READ_REG(sc, CONREG) | IMXSPI(CON_XCH));
1.1  hkenken }
1.1  hkenken
1.1  hkenken void
1.1  hkenken imxspi_recv(struct imxspi_softc *sc)
1.1  hkenken {
1.1  hkenken 	uint32_t		data;
1.1  hkenken 	struct spi_chunk	*chunk;
1.1  hkenken
1.1  hkenken 	while ((chunk = sc->sc_rchunk) != NULL) {
1.1  hkenken 		while (chunk->chunk_rresid) {
1.1  hkenken 			/* rx fifo empty? */
1.1  hkenken 			if ((!(READ_REG(sc, STATREG) & IMXSPI(STAT_RR))))
1.1  hkenken 				return;
1.1  hkenken
1.1  hkenken 			/* collect rx data */
1.1  hkenken 			data = READ_REG(sc, RXDATA);
1.1  hkenken 			if (chunk->chunk_rptr) {
1.1  hkenken 				*chunk->chunk_rptr = data & 0xff;
1.1  hkenken 				chunk->chunk_rptr++;
1.1  hkenken 			}
1.1  hkenken
1.1  hkenken 			chunk->chunk_rresid--;
1.1  hkenken 		}
1.1  hkenken 		/* advance next to next transfer */
1.1  hkenken 		sc->sc_rchunk = sc->sc_rchunk->chunk_next;
1.1  hkenken 	}
1.1  hkenken }
1.1  hkenken
1.1  hkenken
1.1  hkenken void
1.1  hkenken imxspi_sched(struct imxspi_softc *sc)
1.1  hkenken {
1.1  hkenken 	struct spi_transfer *st;
1.1  hkenken 	uint32_t chipselect;
1.1  hkenken
1.1  hkenken 	while ((st = spi_transq_first(&sc->sc_q)) != NULL) {
1.1  hkenken 		/* remove the item */
1.1  hkenken 		spi_transq_dequeue(&sc->sc_q);
1.1  hkenken
1.1  hkenken 		/* note that we are working on it */
1.1  hkenken 		sc->sc_transfer = st;
1.1  hkenken
1.1  hkenken 		/* chip slect */
1.1  hkenken 		if (sc->sc_tag->spi_cs_enable != NULL)
1.1  hkenken 			sc->sc_tag->spi_cs_enable(sc->sc_tag->cookie,
1.1  hkenken 			    st->st_slave);
1.1  hkenken
1.3  hkenken 		/* chip slect */
1.1  hkenken 		chipselect = READ_REG(sc, CONREG);
1.1  hkenken 		chipselect &= ~IMXSPI(CON_CS);
1.1  hkenken 		chipselect |= __SHIFTIN(st->st_slave, IMXSPI(CON_CS));
1.1  hkenken 		WRITE_REG(sc, CONREG, chipselect);
1.1  hkenken
1.1  hkenken 		delay(1);
1.1  hkenken
1.1  hkenken 		/* setup chunks */
1.1  hkenken 		sc->sc_rchunk = sc->sc_wchunk = st->st_chunks;
1.1  hkenken
1.1  hkenken 		/* now kick the master start to get the chip running */
1.1  hkenken 		imxspi_send(sc);
1.1  hkenken
1.1  hkenken 		sc->sc_running = TRUE;
1.1  hkenken 		return;
1.1  hkenken 	}
1.1  hkenken
1.1  hkenken 	DPRINTFN(2, ("%s: nothing to do anymore\n", __func__));
1.1  hkenken 	sc->sc_running = FALSE;
1.1  hkenken }
1.1  hkenken
1.1  hkenken void
1.1  hkenken imxspi_done(struct imxspi_softc *sc, int err)
1.1  hkenken {
1.1  hkenken 	struct spi_transfer *st;
1.1  hkenken
1.1  hkenken 	/* called from interrupt handler */
1.1  hkenken 	if ((st = sc->sc_transfer) != NULL) {
1.1  hkenken 		if (sc->sc_tag->spi_cs_disable != NULL)
1.1  hkenken 			sc->sc_tag->spi_cs_disable(sc->sc_tag->cookie,
1.1  hkenken 			    st->st_slave);
1.1  hkenken
1.1  hkenken 		sc->sc_transfer = NULL;
1.1  hkenken 		spi_done(st, err);
1.1  hkenken 	}
1.1  hkenken 	/* make sure we clear these bits out */
1.1  hkenken 	sc->sc_wchunk = sc->sc_rchunk = NULL;
1.1  hkenken 	imxspi_sched(sc);
1.1  hkenken }
1.1  hkenken
1.1  hkenken static int
1.1  hkenken imxspi_intr(void *arg)
1.1  hkenken {
1.1  hkenken 	struct imxspi_softc *sc = arg;
1.1  hkenken 	uint32_t intr, sr;
1.1  hkenken 	int err = 0;
1.1  hkenken
1.1  hkenken 	if ((intr = READ_REG(sc, INTREG)) == 0) {
1.1  hkenken 		/* interrupts are not enabled, get out */
1.1  hkenken 		DPRINTFN(4, ("%s: interrupts are not enabled\n", __func__));
1.1  hkenken 		return 0;
1.1  hkenken 	}
1.1  hkenken
1.1  hkenken 	sr = READ_REG(sc, STATREG);
1.1  hkenken 	if (!(sr & intr)) {
1.1  hkenken 		/* interrupt did not happen, get out */
1.1  hkenken 		DPRINTFN(3, ("%s: interrupts did not happen\n", __func__));
1.1  hkenken 		return 0;
1.1  hkenken 	}
1.1  hkenken
1.3  hkenken 	/* RXFIFO ready? */
1.3  hkenken 	if (sr & IMXSPI(INTR_RR_EN)) {
1.3  hkenken 		imxspi_recv(sc);
1.3  hkenken 		if (sc->sc_wchunk == NULL && sc->sc_rchunk == NULL)
1.3  hkenken 			imxspi_done(sc, err);
1.3  hkenken 	}
1.3  hkenken
1.1  hkenken 	/* Transfer Conplete? */
1.1  hkenken 	if (sr & IMXSPI(INTR_TC_EN)) {
1.1  hkenken 		/* complete TX */
1.1  hkenken 		imxspi_send(sc);
1.1  hkenken 	}
1.1  hkenken
1.1  hkenken 	/* status register clear */
1.1  hkenken 	WRITE_REG(sc, STATREG, sr);
1.1  hkenken
1.1  hkenken 	return 1;
1.1  hkenken }
1.1  hkenken
1.1  hkenken int
1.1  hkenken imxspi_transfer(void *arg, struct spi_transfer *st)
1.1  hkenken {
1.1  hkenken 	struct imxspi_softc *sc = arg;
1.1  hkenken 	int s;
1.1  hkenken
1.1  hkenken 	/* make sure we select the right chip */
1.2  hkenken 	s = splbio();
1.1  hkenken 	spi_transq_enqueue(&sc->sc_q, st);
1.1  hkenken 	if (sc->sc_running == FALSE)
1.1  hkenken 		imxspi_sched(sc);
1.1  hkenken 	splx(s);
1.1  hkenken
1.1  hkenken 	return 0;
1.1  hkenken }
1.1  hkenken