dev/sdmmc/sdhc.c

1.70  jmcneill /*	$NetBSD: sdhc.c,v 1.70 2015/08/02 11:28:01 jmcneill Exp $	*/
 1.1    nonaka /*	$OpenBSD: sdhc.c,v 1.25 2009/01/13 19:44:20 grange Exp $	*/
 1.1    nonaka
 1.1    nonaka /*
 1.1    nonaka  * Copyright (c) 2006 Uwe Stuehler <uwe (at) openbsd.org>
 1.1    nonaka  *
 1.1    nonaka  * Permission to use, copy, modify, and distribute this software for any
 1.1    nonaka  * purpose with or without fee is hereby granted, provided that the above
 1.1    nonaka  * copyright notice and this permission notice appear in all copies.
 1.1    nonaka  *
 1.1    nonaka  * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
 1.1    nonaka  * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
 1.1    nonaka  * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
 1.1    nonaka  * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
 1.1    nonaka  * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
 1.1    nonaka  * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
 1.1    nonaka  * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
 1.1    nonaka  */
 1.1    nonaka
 1.1    nonaka /*
 1.1    nonaka  * SD Host Controller driver based on the SD Host Controller Standard
 1.1    nonaka  * Simplified Specification Version 1.00 (www.sdcard.com).
 1.1    nonaka  */
 1.1    nonaka
 1.1    nonaka #include <sys/cdefs.h>
1.70  jmcneill __KERNEL_RCSID(0, "$NetBSD: sdhc.c,v 1.70 2015/08/02 11:28:01 jmcneill Exp $");
1.10    nonaka
1.10    nonaka #ifdef _KERNEL_OPT
1.10    nonaka #include "opt_sdmmc.h"
1.10    nonaka #endif
 1.1    nonaka
 1.1    nonaka #include <sys/param.h>
 1.1    nonaka #include <sys/device.h>
 1.1    nonaka #include <sys/kernel.h>
 1.1    nonaka #include <sys/malloc.h>
 1.1    nonaka #include <sys/systm.h>
 1.1    nonaka #include <sys/mutex.h>
 1.1    nonaka #include <sys/condvar.h>
 1.1    nonaka
 1.1    nonaka #include <dev/sdmmc/sdhcreg.h>
 1.1    nonaka #include <dev/sdmmc/sdhcvar.h>
 1.1    nonaka #include <dev/sdmmc/sdmmcchip.h>
 1.1    nonaka #include <dev/sdmmc/sdmmcreg.h>
 1.1    nonaka #include <dev/sdmmc/sdmmcvar.h>
 1.1    nonaka
 1.1    nonaka #ifdef SDHC_DEBUG
 1.1    nonaka int sdhcdebug = 1;
 1.1    nonaka #define DPRINTF(n,s)	do { if ((n) <= sdhcdebug) printf s; } while (0)
 1.1    nonaka void	sdhc_dump_regs(struct sdhc_host *);
 1.1    nonaka #else
 1.1    nonaka #define DPRINTF(n,s)	do {} while (0)
 1.1    nonaka #endif
 1.1    nonaka
 1.1    nonaka #define SDHC_COMMAND_TIMEOUT	hz
 1.1    nonaka #define SDHC_BUFFER_TIMEOUT	hz
 1.1    nonaka #define SDHC_TRANSFER_TIMEOUT	hz
1.61  jmcneill #define SDHC_DMA_TIMEOUT	(hz*3)
 1.1    nonaka
 1.1    nonaka struct sdhc_host {
 1.1    nonaka 	struct sdhc_softc *sc;		/* host controller device */
 1.1    nonaka
 1.1    nonaka 	bus_space_tag_t iot;		/* host register set tag */
 1.1    nonaka 	bus_space_handle_t ioh;		/* host register set handle */
1.36  jakllsch 	bus_size_t ios;			/* host register space size */
 1.1    nonaka 	bus_dma_tag_t dmat;		/* host DMA tag */
 1.1    nonaka
 1.1    nonaka 	device_t sdmmc;			/* generic SD/MMC device */
 1.1    nonaka
 1.1    nonaka 	u_int clkbase;			/* base clock frequency in KHz */
 1.1    nonaka 	int maxblklen;			/* maximum block length */
 1.1    nonaka 	uint32_t ocr;			/* OCR value from capabilities */
 1.1    nonaka
 1.1    nonaka 	uint8_t regs[14];		/* host controller state */
 1.1    nonaka
 1.1    nonaka 	uint16_t intr_status;		/* soft interrupt status */
 1.1    nonaka 	uint16_t intr_error_status;	/* soft error status */
1.65  jmcneill 	kmutex_t intr_lock;
1.65  jmcneill 	kcondvar_t intr_cv;
 1.1    nonaka
1.12    nonaka 	int specver;			/* spec. version */
1.12    nonaka
 1.1    nonaka 	uint32_t flags;			/* flags for this host */
 1.1    nonaka #define SHF_USE_DMA		0x0001
 1.1    nonaka #define SHF_USE_4BIT_MODE	0x0002
1.11      matt #define SHF_USE_8BIT_MODE	0x0004
1.55    bouyer #define SHF_MODE_DMAEN		0x0008 /* needs SDHC_DMA_ENABLE in mode */
1.63  jmcneill #define SHF_USE_ADMA2_32	0x0010
1.63  jmcneill #define SHF_USE_ADMA2_64	0x0020
1.63  jmcneill #define SHF_USE_ADMA2_MASK	0x0030
1.63  jmcneill
1.63  jmcneill 	bus_dmamap_t		adma_map;
1.63  jmcneill 	bus_dma_segment_t	adma_segs[1];
1.63  jmcneill 	void			*adma2;
 1.1    nonaka };
 1.1    nonaka
 1.1    nonaka #define HDEVNAME(hp)	(device_xname((hp)->sc->sc_dev))
 1.1    nonaka
1.11      matt static uint8_t
1.11      matt hread1(struct sdhc_host *hp, bus_size_t reg)
1.11      matt {
1.12    nonaka
1.11      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_32BIT_ACCESS))
1.11      matt 		return bus_space_read_1(hp->iot, hp->ioh, reg);
1.11      matt 	return bus_space_read_4(hp->iot, hp->ioh, reg & -4) >> (8 * (reg & 3));
1.11      matt }
1.11      matt
1.11      matt static uint16_t
1.11      matt hread2(struct sdhc_host *hp, bus_size_t reg)
1.11      matt {
1.12    nonaka
1.11      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_32BIT_ACCESS))
1.11      matt 		return bus_space_read_2(hp->iot, hp->ioh, reg);
1.11      matt 	return bus_space_read_4(hp->iot, hp->ioh, reg & -4) >> (8 * (reg & 2));
1.11      matt }
1.11      matt
1.11      matt #define HREAD1(hp, reg)		hread1(hp, reg)
1.11      matt #define HREAD2(hp, reg)		hread2(hp, reg)
1.11      matt #define HREAD4(hp, reg)		\
 1.1    nonaka 	(bus_space_read_4((hp)->iot, (hp)->ioh, (reg)))
1.11      matt
1.11      matt
1.11      matt static void
1.11      matt hwrite1(struct sdhc_host *hp, bus_size_t o, uint8_t val)
1.11      matt {
1.12    nonaka
1.11      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)) {
1.11      matt 		bus_space_write_1(hp->iot, hp->ioh, o, val);
1.11      matt 	} else {
1.11      matt 		const size_t shift = 8 * (o & 3);
1.11      matt 		o &= -4;
1.11      matt 		uint32_t tmp = bus_space_read_4(hp->iot, hp->ioh, o);
1.11      matt 		tmp = (val << shift) | (tmp & ~(0xff << shift));
1.11      matt 		bus_space_write_4(hp->iot, hp->ioh, o, tmp);
1.11      matt 	}
1.11      matt }
1.11      matt
1.11      matt static void
1.11      matt hwrite2(struct sdhc_host *hp, bus_size_t o, uint16_t val)
1.11      matt {
1.12    nonaka
1.11      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)) {
1.11      matt 		bus_space_write_2(hp->iot, hp->ioh, o, val);
1.11      matt 	} else {
1.11      matt 		const size_t shift = 8 * (o & 2);
1.11      matt 		o &= -4;
1.11      matt 		uint32_t tmp = bus_space_read_4(hp->iot, hp->ioh, o);
1.11      matt 		tmp = (val << shift) | (tmp & ~(0xffff << shift));
1.11      matt 		bus_space_write_4(hp->iot, hp->ioh, o, tmp);
1.11      matt 	}
1.11      matt }
1.11      matt
1.11      matt #define HWRITE1(hp, reg, val)		hwrite1(hp, reg, val)
1.11      matt #define HWRITE2(hp, reg, val)		hwrite2(hp, reg, val)
 1.1    nonaka #define HWRITE4(hp, reg, val)						\
 1.1    nonaka 	bus_space_write_4((hp)->iot, (hp)->ioh, (reg), (val))
1.11      matt
 1.1    nonaka #define HCLR1(hp, reg, bits)						\
1.11      matt 	do if (bits) HWRITE1((hp), (reg), HREAD1((hp), (reg)) & ~(bits)); while (0)
 1.1    nonaka #define HCLR2(hp, reg, bits)						\
1.11      matt 	do if (bits) HWRITE2((hp), (reg), HREAD2((hp), (reg)) & ~(bits)); while (0)
1.11      matt #define HCLR4(hp, reg, bits)						\
1.11      matt 	do if (bits) HWRITE4((hp), (reg), HREAD4((hp), (reg)) & ~(bits)); while (0)
 1.1    nonaka #define HSET1(hp, reg, bits)						\
1.11      matt 	do if (bits) HWRITE1((hp), (reg), HREAD1((hp), (reg)) | (bits)); while (0)
 1.1    nonaka #define HSET2(hp, reg, bits)						\
1.11      matt 	do if (bits) HWRITE2((hp), (reg), HREAD2((hp), (reg)) | (bits)); while (0)
1.11      matt #define HSET4(hp, reg, bits)						\
1.11      matt 	do if (bits) HWRITE4((hp), (reg), HREAD4((hp), (reg)) | (bits)); while (0)
 1.1    nonaka
 1.1    nonaka static int	sdhc_host_reset(sdmmc_chipset_handle_t);
 1.1    nonaka static int	sdhc_host_reset1(sdmmc_chipset_handle_t);
 1.1    nonaka static uint32_t	sdhc_host_ocr(sdmmc_chipset_handle_t);
 1.1    nonaka static int	sdhc_host_maxblklen(sdmmc_chipset_handle_t);
 1.1    nonaka static int	sdhc_card_detect(sdmmc_chipset_handle_t);
 1.1    nonaka static int	sdhc_write_protect(sdmmc_chipset_handle_t);
 1.1    nonaka static int	sdhc_bus_power(sdmmc_chipset_handle_t, uint32_t);
 1.1    nonaka static int	sdhc_bus_clock(sdmmc_chipset_handle_t, int);
 1.1    nonaka static int	sdhc_bus_width(sdmmc_chipset_handle_t, int);
 1.8  kiyohara static int	sdhc_bus_rod(sdmmc_chipset_handle_t, int);
 1.1    nonaka static void	sdhc_card_enable_intr(sdmmc_chipset_handle_t, int);
 1.1    nonaka static void	sdhc_card_intr_ack(sdmmc_chipset_handle_t);
 1.1    nonaka static void	sdhc_exec_command(sdmmc_chipset_handle_t,
 1.1    nonaka 		    struct sdmmc_command *);
 1.1    nonaka static int	sdhc_start_command(struct sdhc_host *, struct sdmmc_command *);
 1.1    nonaka static int	sdhc_wait_state(struct sdhc_host *, uint32_t, uint32_t);
 1.1    nonaka static int	sdhc_soft_reset(struct sdhc_host *, int);
 1.1    nonaka static int	sdhc_wait_intr(struct sdhc_host *, int, int);
 1.1    nonaka static void	sdhc_transfer_data(struct sdhc_host *, struct sdmmc_command *);
 1.7    nonaka static int	sdhc_transfer_data_dma(struct sdhc_host *, struct sdmmc_command *);
 1.1    nonaka static int	sdhc_transfer_data_pio(struct sdhc_host *, struct sdmmc_command *);
1.11      matt static void	sdhc_read_data_pio(struct sdhc_host *, uint8_t *, u_int);
1.11      matt static void	sdhc_write_data_pio(struct sdhc_host *, uint8_t *, u_int);
1.11      matt static void	esdhc_read_data_pio(struct sdhc_host *, uint8_t *, u_int);
1.11      matt static void	esdhc_write_data_pio(struct sdhc_host *, uint8_t *, u_int);
1.11      matt
 1.1    nonaka static struct sdmmc_chip_functions sdhc_functions = {
 1.1    nonaka 	/* host controller reset */
1.60     skrll 	.host_reset = sdhc_host_reset,
 1.1    nonaka
 1.1    nonaka 	/* host controller capabilities */
1.60     skrll 	.host_ocr = sdhc_host_ocr,
1.60     skrll 	.host_maxblklen = sdhc_host_maxblklen,
 1.1    nonaka
 1.1    nonaka 	/* card detection */
1.60     skrll 	.card_detect = sdhc_card_detect,
 1.1    nonaka
 1.1    nonaka 	/* write protect */
1.60     skrll 	.write_protect = sdhc_write_protect,
 1.1    nonaka
1.60     skrll 	/* bus power, clock frequency, width and ROD(OpenDrain/PushPull) */
1.60     skrll 	.bus_power = sdhc_bus_power,
1.60     skrll 	.bus_clock = sdhc_bus_clock,
1.60     skrll 	.bus_width = sdhc_bus_width,
1.60     skrll 	.bus_rod = sdhc_bus_rod,
 1.1    nonaka
 1.1    nonaka 	/* command execution */
1.60     skrll 	.exec_command = sdhc_exec_command,
 1.1    nonaka
 1.1    nonaka 	/* card interrupt */
1.60     skrll 	.card_enable_intr = sdhc_card_enable_intr,
1.60     skrll 	.card_intr_ack = sdhc_card_intr_ack
 1.1    nonaka };
 1.1    nonaka
1.17  jakllsch static int
1.17  jakllsch sdhc_cfprint(void *aux, const char *pnp)
1.17  jakllsch {
1.31     joerg 	const struct sdmmcbus_attach_args * const saa = aux;
1.17  jakllsch 	const struct sdhc_host * const hp = saa->saa_sch;
1.47     skrll
1.17  jakllsch 	if (pnp) {
1.17  jakllsch 		aprint_normal("sdmmc at %s", pnp);
1.17  jakllsch 	}
1.41  jakllsch 	for (size_t host = 0; host < hp->sc->sc_nhosts; host++) {
1.41  jakllsch 		if (hp->sc->sc_host[host] == hp) {
1.41  jakllsch 			aprint_normal(" slot %zu", host);
1.41  jakllsch 		}
1.41  jakllsch 	}
1.17  jakllsch
1.17  jakllsch 	return UNCONF;
1.17  jakllsch }
1.17  jakllsch
 1.1    nonaka /*
 1.1    nonaka  * Called by attachment driver.  For each SD card slot there is one SD
 1.1    nonaka  * host controller standard register set. (1.3)
 1.1    nonaka  */
 1.1    nonaka int
 1.1    nonaka sdhc_host_found(struct sdhc_softc *sc, bus_space_tag_t iot,
 1.1    nonaka     bus_space_handle_t ioh, bus_size_t iosize)
 1.1    nonaka {
 1.1    nonaka 	struct sdmmcbus_attach_args saa;
 1.1    nonaka 	struct sdhc_host *hp;
 1.1    nonaka 	uint32_t caps;
 1.1    nonaka 	uint16_t sdhcver;
1.63  jmcneill 	int error;
 1.1    nonaka
1.33  riastrad 	/* Allocate one more host structure. */
1.33  riastrad 	hp = malloc(sizeof(struct sdhc_host), M_DEVBUF, M_WAITOK|M_ZERO);
1.33  riastrad 	if (hp == NULL) {
1.33  riastrad 		aprint_error_dev(sc->sc_dev,
1.33  riastrad 		    "couldn't alloc memory (sdhc host)\n");
1.33  riastrad 		goto err1;
1.33  riastrad 	}
1.33  riastrad 	sc->sc_host[sc->sc_nhosts++] = hp;
1.33  riastrad
1.33  riastrad 	/* Fill in the new host structure. */
1.33  riastrad 	hp->sc = sc;
1.33  riastrad 	hp->iot = iot;
1.33  riastrad 	hp->ioh = ioh;
1.36  jakllsch 	hp->ios = iosize;
1.33  riastrad 	hp->dmat = sc->sc_dmat;
1.33  riastrad
1.65  jmcneill 	mutex_init(&hp->intr_lock, MUTEX_DEFAULT, IPL_SDMMC);
1.33  riastrad 	cv_init(&hp->intr_cv, "sdhcintr");
1.33  riastrad
1.52    nonaka 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.52    nonaka 		sdhcver = HREAD4(hp, SDHC_ESDHC_HOST_CTL_VERSION);
1.52    nonaka 	} else {
1.52    nonaka 		sdhcver = HREAD2(hp, SDHC_HOST_CTL_VERSION);
1.52    nonaka 	}
1.58  jmcneill 	aprint_normal_dev(sc->sc_dev, "SDHC ");
1.33  riastrad 	hp->specver = SDHC_SPEC_VERSION(sdhcver);
 1.1    nonaka 	switch (SDHC_SPEC_VERSION(sdhcver)) {
1.12    nonaka 	case SDHC_SPEC_VERS_100:
1.12    nonaka 		aprint_normal("1.0");
1.12    nonaka 		break;
1.12    nonaka
1.12    nonaka 	case SDHC_SPEC_VERS_200:
1.12    nonaka 		aprint_normal("2.0");
 1.1    nonaka 		break;
 1.1    nonaka
1.12    nonaka 	case SDHC_SPEC_VERS_300:
1.12    nonaka 		aprint_normal("3.0");
 1.9      matt 		break;
 1.9      matt
1.56  jmcneill 	case SDHC_SPEC_VERS_400:
1.56  jmcneill 		aprint_normal("4.0");
1.56  jmcneill 		break;
1.56  jmcneill
 1.1    nonaka 	default:
1.12    nonaka 		aprint_normal("unknown version(0x%x)",
1.12    nonaka 		    SDHC_SPEC_VERSION(sdhcver));
 1.1    nonaka 		break;
 1.1    nonaka 	}
1.58  jmcneill 	aprint_normal(", rev %u", SDHC_VENDOR_VERSION(sdhcver));
 1.1    nonaka
 1.1    nonaka 	/*
 1.3  uebayasi 	 * Reset the host controller and enable interrupts.
 1.1    nonaka 	 */
 1.1    nonaka 	(void)sdhc_host_reset(hp);
 1.1    nonaka
 1.1    nonaka 	/* Determine host capabilities. */
1.24     skrll 	if (ISSET(sc->sc_flags, SDHC_FLAG_HOSTCAPS)) {
1.24     skrll 		caps = sc->sc_caps;
1.24     skrll 	} else {
1.24     skrll 		caps = HREAD4(hp, SDHC_CAPABILITIES);
1.24     skrll 	}
 1.1    nonaka
1.55    bouyer 	/*
1.55    bouyer 	 * Use DMA if the host system and the controller support it.
1.55    bouyer 	 * Suports integrated or external DMA egine, with or without
1.55    bouyer 	 * SDHC_DMA_ENABLE in the command.
1.55    bouyer 	 */
1.28      matt 	if (ISSET(sc->sc_flags, SDHC_FLAG_FORCE_DMA) ||
1.27  jakllsch 	    (ISSET(sc->sc_flags, SDHC_FLAG_USE_DMA &&
1.28      matt 	     ISSET(caps, SDHC_DMA_SUPPORT)))) {
 1.1    nonaka 		SET(hp->flags, SHF_USE_DMA);
1.63  jmcneill
1.63  jmcneill 		if (ISSET(sc->sc_flags, SDHC_FLAG_USE_ADMA2) &&
1.63  jmcneill 		    ISSET(caps, SDHC_ADMA2_SUPP)) {
1.55    bouyer 			SET(hp->flags, SHF_MODE_DMAEN);
1.63  jmcneill 			/*
1.63  jmcneill 			 * 64-bit mode was present in the 2.00 spec, removed
1.63  jmcneill 			 * from 3.00, and re-added in 4.00 with a different
1.63  jmcneill 			 * descriptor layout. We only support 2.00 and 3.00
1.63  jmcneill 			 * descriptors for now.
1.63  jmcneill 			 */
1.63  jmcneill 			if (hp->specver == SDHC_SPEC_VERS_200 &&
1.63  jmcneill 			    ISSET(caps, SDHC_64BIT_SYS_BUS)) {
1.63  jmcneill 				SET(hp->flags, SHF_USE_ADMA2_64);
1.63  jmcneill 				aprint_normal(", 64-bit ADMA2");
1.63  jmcneill 			} else {
1.63  jmcneill 				SET(hp->flags, SHF_USE_ADMA2_32);
1.63  jmcneill 				aprint_normal(", 32-bit ADMA2");
1.63  jmcneill 			}
1.63  jmcneill 		} else {
1.63  jmcneill 			if (!ISSET(sc->sc_flags, SDHC_FLAG_EXTERNAL_DMA) ||
1.63  jmcneill 			    ISSET(sc->sc_flags, SDHC_FLAG_EXTDMA_DMAEN))
1.63  jmcneill 				SET(hp->flags, SHF_MODE_DMAEN);
1.64  jmcneill 			if (sc->sc_vendor_transfer_data_dma) {
1.64  jmcneill 				aprint_normal(", platform DMA");
1.64  jmcneill 			} else {
1.64  jmcneill 				aprint_normal(", SDMA");
1.64  jmcneill 			}
1.63  jmcneill 		}
1.58  jmcneill 	} else {
1.58  jmcneill 		aprint_normal(", PIO");
 1.1    nonaka 	}
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * Determine the base clock frequency. (2.2.24)
 1.1    nonaka 	 */
1.56  jmcneill 	if (hp->specver >= SDHC_SPEC_VERS_300) {
1.30      matt 		hp->clkbase = SDHC_BASE_V3_FREQ_KHZ(caps);
1.30      matt 	} else {
1.30      matt 		hp->clkbase = SDHC_BASE_FREQ_KHZ(caps);
1.30      matt 	}
1.56  jmcneill 	if (hp->clkbase == 0 ||
1.56  jmcneill 	    ISSET(sc->sc_flags, SDHC_FLAG_NO_CLKBASE)) {
 1.9      matt 		if (sc->sc_clkbase == 0) {
 1.9      matt 			/* The attachment driver must tell us. */
1.12    nonaka 			aprint_error_dev(sc->sc_dev,
1.12    nonaka 			    "unknown base clock frequency\n");
 1.9      matt 			goto err;
 1.9      matt 		}
 1.9      matt 		hp->clkbase = sc->sc_clkbase;
 1.9      matt 	}
 1.9      matt 	if (hp->clkbase < 10000 || hp->clkbase > 10000 * 256) {
 1.1    nonaka 		/* SDHC 1.0 supports only 10-63 MHz. */
 1.1    nonaka 		aprint_error_dev(sc->sc_dev,
 1.1    nonaka 		    "base clock frequency out of range: %u MHz\n",
 1.1    nonaka 		    hp->clkbase / 1000);
 1.1    nonaka 		goto err;
 1.1    nonaka 	}
1.58  jmcneill 	aprint_normal(", %u kHz", hp->clkbase);
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * XXX Set the data timeout counter value according to
 1.1    nonaka 	 * capabilities. (2.2.15)
 1.1    nonaka 	 */
 1.1    nonaka 	HWRITE1(hp, SDHC_TIMEOUT_CTL, SDHC_TIMEOUT_MAX);
1.29      matt #if 1
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED))
1.11      matt 		HWRITE4(hp, SDHC_NINTR_STATUS, SDHC_CMD_TIMEOUT_ERROR << 16);
1.11      matt #endif
 1.1    nonaka
1.58  jmcneill 	if (ISSET(caps, SDHC_EMBEDDED_SLOT))
1.58  jmcneill 		aprint_normal(", embedded slot");
1.58  jmcneill
 1.1    nonaka 	/*
 1.1    nonaka 	 * Determine SD bus voltage levels supported by the controller.
 1.1    nonaka 	 */
1.58  jmcneill 	aprint_normal(",");
1.66  jmcneill 	if (ISSET(caps, SDHC_HIGH_SPEED_SUPP)) {
1.66  jmcneill 		SET(hp->ocr, MMC_OCR_HCS);
1.66  jmcneill 		aprint_normal(" High-Speed");
1.66  jmcneill 	}
1.48  jmcneill 	if (ISSET(caps, SDHC_VOLTAGE_SUPP_1_8V) &&
1.48  jmcneill 	    (hp->specver < SDHC_SPEC_VERS_300 ||
1.48  jmcneill 	     ISSET(caps, SDHC_EMBEDDED_SLOT))) {
 1.1    nonaka 		SET(hp->ocr, MMC_OCR_1_7V_1_8V | MMC_OCR_1_8V_1_9V);
1.58  jmcneill 		aprint_normal(" 1.8V");
1.11      matt 	}
1.11      matt 	if (ISSET(caps, SDHC_VOLTAGE_SUPP_3_0V)) {
 1.1    nonaka 		SET(hp->ocr, MMC_OCR_2_9V_3_0V | MMC_OCR_3_0V_3_1V);
1.58  jmcneill 		aprint_normal(" 3.0V");
1.11      matt 	}
1.11      matt 	if (ISSET(caps, SDHC_VOLTAGE_SUPP_3_3V)) {
 1.1    nonaka 		SET(hp->ocr, MMC_OCR_3_2V_3_3V | MMC_OCR_3_3V_3_4V);
1.58  jmcneill 		aprint_normal(" 3.3V");
1.11      matt 	}
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * Determine the maximum block length supported by the host
 1.1    nonaka 	 * controller. (2.2.24)
 1.1    nonaka 	 */
 1.1    nonaka 	switch((caps >> SDHC_MAX_BLK_LEN_SHIFT) & SDHC_MAX_BLK_LEN_MASK) {
 1.1    nonaka 	case SDHC_MAX_BLK_LEN_512:
 1.1    nonaka 		hp->maxblklen = 512;
 1.1    nonaka 		break;
 1.1    nonaka
 1.1    nonaka 	case SDHC_MAX_BLK_LEN_1024:
 1.1    nonaka 		hp->maxblklen = 1024;
 1.1    nonaka 		break;
 1.1    nonaka
 1.1    nonaka 	case SDHC_MAX_BLK_LEN_2048:
 1.1    nonaka 		hp->maxblklen = 2048;
 1.1    nonaka 		break;
 1.1    nonaka
 1.9      matt 	case SDHC_MAX_BLK_LEN_4096:
 1.9      matt 		hp->maxblklen = 4096;
 1.9      matt 		break;
 1.9      matt
 1.1    nonaka 	default:
 1.1    nonaka 		aprint_error_dev(sc->sc_dev, "max block length unknown\n");
 1.1    nonaka 		goto err;
 1.1    nonaka 	}
1.58  jmcneill 	aprint_normal(", %u byte blocks", hp->maxblklen);
1.58  jmcneill 	aprint_normal("\n");
 1.1    nonaka
1.63  jmcneill 	if (ISSET(hp->flags, SHF_USE_ADMA2_MASK)) {
1.63  jmcneill 		int rseg;
1.63  jmcneill
1.63  jmcneill 		/* Allocate ADMA2 descriptor memory */
1.63  jmcneill 		error = bus_dmamem_alloc(sc->sc_dmat, PAGE_SIZE, PAGE_SIZE,
1.63  jmcneill 		    PAGE_SIZE, hp->adma_segs, 1, &rseg, BUS_DMA_WAITOK);
1.63  jmcneill 		if (error) {
1.63  jmcneill 			aprint_error_dev(sc->sc_dev,
1.63  jmcneill 			    "ADMA2 dmamem_alloc failed (%d)\n", error);
1.63  jmcneill 			goto adma_done;
1.63  jmcneill 		}
1.63  jmcneill 		error = bus_dmamem_map(sc->sc_dmat, hp->adma_segs, rseg,
1.63  jmcneill 		    PAGE_SIZE, (void **)&hp->adma2, BUS_DMA_WAITOK);
1.63  jmcneill 		if (error) {
1.63  jmcneill 			aprint_error_dev(sc->sc_dev,
1.63  jmcneill 			    "ADMA2 dmamem_map failed (%d)\n", error);
1.63  jmcneill 			goto adma_done;
1.63  jmcneill 		}
1.63  jmcneill 		error = bus_dmamap_create(sc->sc_dmat, PAGE_SIZE, 1, PAGE_SIZE,
1.63  jmcneill 		    0, BUS_DMA_WAITOK, &hp->adma_map);
1.63  jmcneill 		if (error) {
1.63  jmcneill 			aprint_error_dev(sc->sc_dev,
1.63  jmcneill 			    "ADMA2 dmamap_create failed (%d)\n", error);
1.63  jmcneill 			goto adma_done;
1.63  jmcneill 		}
1.63  jmcneill 		error = bus_dmamap_load(sc->sc_dmat, hp->adma_map,
1.63  jmcneill 		    hp->adma2, PAGE_SIZE, NULL,
1.63  jmcneill 		    BUS_DMA_WAITOK|BUS_DMA_WRITE);
1.63  jmcneill 		if (error) {
1.63  jmcneill 			aprint_error_dev(sc->sc_dev,
1.63  jmcneill 			    "ADMA2 dmamap_load failed (%d)\n", error);
1.63  jmcneill 			goto adma_done;
1.63  jmcneill 		}
1.63  jmcneill
1.63  jmcneill 		memset(hp->adma2, 0, PAGE_SIZE);
1.63  jmcneill
1.63  jmcneill adma_done:
1.63  jmcneill 		if (error)
1.63  jmcneill 			CLR(hp->flags, SHF_USE_ADMA2_MASK);
1.63  jmcneill 	}
1.63  jmcneill
 1.1    nonaka 	/*
 1.1    nonaka 	 * Attach the generic SD/MMC bus driver.  (The bus driver must
 1.1    nonaka 	 * not invoke any chipset functions before it is attached.)
 1.1    nonaka 	 */
 1.1    nonaka 	memset(&saa, 0, sizeof(saa));
 1.1    nonaka 	saa.saa_busname = "sdmmc";
 1.1    nonaka 	saa.saa_sct = &sdhc_functions;
 1.1    nonaka 	saa.saa_sch = hp;
 1.1    nonaka 	saa.saa_dmat = hp->dmat;
 1.1    nonaka 	saa.saa_clkmax = hp->clkbase;
1.11      matt 	if (ISSET(sc->sc_flags, SDHC_FLAG_HAVE_CGM))
1.38  jakllsch 		saa.saa_clkmin = hp->clkbase / 256 / 2046;
1.11      matt 	else if (ISSET(sc->sc_flags, SDHC_FLAG_HAVE_DVS))
1.38  jakllsch 		saa.saa_clkmin = hp->clkbase / 256 / 16;
1.38  jakllsch 	else if (hp->sc->sc_clkmsk != 0)
1.38  jakllsch 		saa.saa_clkmin = hp->clkbase / (hp->sc->sc_clkmsk >>
1.38  jakllsch 		    (ffs(hp->sc->sc_clkmsk) - 1));
1.56  jmcneill 	else if (hp->specver >= SDHC_SPEC_VERS_300)
1.38  jakllsch 		saa.saa_clkmin = hp->clkbase / 0x3ff;
1.38  jakllsch 	else
1.38  jakllsch 		saa.saa_clkmin = hp->clkbase / 256;
 1.1    nonaka 	saa.saa_caps = SMC_CAPS_4BIT_MODE|SMC_CAPS_AUTO_STOP;
1.11      matt 	if (ISSET(sc->sc_flags, SDHC_FLAG_8BIT_MODE))
1.11      matt 		saa.saa_caps |= SMC_CAPS_8BIT_MODE;
1.11      matt 	if (ISSET(caps, SDHC_HIGH_SPEED_SUPP))
1.11      matt 		saa.saa_caps |= SMC_CAPS_SD_HIGHSPEED;
1.26      matt 	if (ISSET(hp->flags, SHF_USE_DMA)) {
1.54    nonaka 		saa.saa_caps |= SMC_CAPS_DMA;
1.54    nonaka 		if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED))
1.54    nonaka 			saa.saa_caps |= SMC_CAPS_MULTI_SEG_DMA;
1.26      matt 	}
1.32  kiyohara 	if (ISSET(sc->sc_flags, SDHC_FLAG_SINGLE_ONLY))
1.32  kiyohara 		saa.saa_caps |= SMC_CAPS_SINGLE_ONLY;
1.17  jakllsch 	hp->sdmmc = config_found(sc->sc_dev, &saa, sdhc_cfprint);
 1.1    nonaka
 1.1    nonaka 	return 0;
 1.1    nonaka
 1.1    nonaka err:
 1.1    nonaka 	cv_destroy(&hp->intr_cv);
1.65  jmcneill 	mutex_destroy(&hp->intr_lock);
 1.1    nonaka 	free(hp, M_DEVBUF);
 1.1    nonaka 	sc->sc_host[--sc->sc_nhosts] = NULL;
 1.1    nonaka err1:
 1.1    nonaka 	return 1;
 1.1    nonaka }
 1.1    nonaka
 1.7    nonaka int
1.36  jakllsch sdhc_detach(struct sdhc_softc *sc, int flags)
 1.7    nonaka {
1.36  jakllsch 	struct sdhc_host *hp;
 1.7    nonaka 	int rv = 0;
 1.7    nonaka
1.36  jakllsch 	for (size_t n = 0; n < sc->sc_nhosts; n++) {
1.36  jakllsch 		hp = sc->sc_host[n];
1.36  jakllsch 		if (hp == NULL)
1.36  jakllsch 			continue;
1.36  jakllsch 		if (hp->sdmmc != NULL) {
1.36  jakllsch 			rv = config_detach(hp->sdmmc, flags);
1.36  jakllsch 			if (rv)
1.36  jakllsch 				break;
1.36  jakllsch 			hp->sdmmc = NULL;
1.36  jakllsch 		}
1.36  jakllsch 		/* disable interrupts */
1.36  jakllsch 		if ((flags & DETACH_FORCE) == 0) {
1.36  jakllsch 			if (ISSET(hp->sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)) {
1.36  jakllsch 				HWRITE4(hp, SDHC_NINTR_SIGNAL_EN, 0);
1.36  jakllsch 			} else {
1.36  jakllsch 				HWRITE2(hp, SDHC_NINTR_SIGNAL_EN, 0);
1.36  jakllsch 			}
1.36  jakllsch 			sdhc_soft_reset(hp, SDHC_RESET_ALL);
1.36  jakllsch 		}
1.36  jakllsch 		cv_destroy(&hp->intr_cv);
1.65  jmcneill 		mutex_destroy(&hp->intr_lock);
1.36  jakllsch 		if (hp->ios > 0) {
1.36  jakllsch 			bus_space_unmap(hp->iot, hp->ioh, hp->ios);
1.36  jakllsch 			hp->ios = 0;
1.36  jakllsch 		}
1.63  jmcneill 		if (ISSET(hp->flags, SHF_USE_ADMA2_MASK)) {
1.63  jmcneill 			bus_dmamap_unload(sc->sc_dmat, hp->adma_map);
1.63  jmcneill 			bus_dmamap_destroy(sc->sc_dmat, hp->adma_map);
1.63  jmcneill 			bus_dmamem_unmap(sc->sc_dmat, hp->adma2, PAGE_SIZE);
1.63  jmcneill 			bus_dmamem_free(sc->sc_dmat, hp->adma_segs, 1);
1.63  jmcneill 		}
1.36  jakllsch 		free(hp, M_DEVBUF);
1.36  jakllsch 		sc->sc_host[n] = NULL;
1.36  jakllsch 	}
 1.7    nonaka
 1.7    nonaka 	return rv;
 1.7    nonaka }
 1.7    nonaka
 1.1    nonaka bool
 1.6    dyoung sdhc_suspend(device_t dev, const pmf_qual_t *qual)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_softc *sc = device_private(dev);
 1.1    nonaka 	struct sdhc_host *hp;
1.12    nonaka 	size_t i;
 1.1    nonaka
 1.1    nonaka 	/* XXX poll for command completion or suspend command
 1.1    nonaka 	 * in progress */
 1.1    nonaka
 1.1    nonaka 	/* Save the host controller state. */
1.11      matt 	for (size_t n = 0; n < sc->sc_nhosts; n++) {
 1.1    nonaka 		hp = sc->sc_host[n];
1.11      matt 		if (ISSET(sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)) {
1.12    nonaka 			for (i = 0; i < sizeof hp->regs; i += 4) {
1.11      matt 				uint32_t v = HREAD4(hp, i);
1.12    nonaka 				hp->regs[i + 0] = (v >> 0);
1.12    nonaka 				hp->regs[i + 1] = (v >> 8);
1.13    bouyer 				if (i + 3 < sizeof hp->regs) {
1.13    bouyer 					hp->regs[i + 2] = (v >> 16);
1.13    bouyer 					hp->regs[i + 3] = (v >> 24);
1.13    bouyer 				}
1.11      matt 			}
1.11      matt 		} else {
1.12    nonaka 			for (i = 0; i < sizeof hp->regs; i++) {
1.11      matt 				hp->regs[i] = HREAD1(hp, i);
1.11      matt 			}
1.11      matt 		}
 1.1    nonaka 	}
 1.1    nonaka 	return true;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka bool
 1.6    dyoung sdhc_resume(device_t dev, const pmf_qual_t *qual)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_softc *sc = device_private(dev);
 1.1    nonaka 	struct sdhc_host *hp;
1.12    nonaka 	size_t i;
 1.1    nonaka
 1.1    nonaka 	/* Restore the host controller state. */
1.11      matt 	for (size_t n = 0; n < sc->sc_nhosts; n++) {
 1.1    nonaka 		hp = sc->sc_host[n];
 1.1    nonaka 		(void)sdhc_host_reset(hp);
1.11      matt 		if (ISSET(sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)) {
1.12    nonaka 			for (i = 0; i < sizeof hp->regs; i += 4) {
1.13    bouyer 				if (i + 3 < sizeof hp->regs) {
1.13    bouyer 					HWRITE4(hp, i,
1.13    bouyer 					    (hp->regs[i + 0] << 0)
1.13    bouyer 					    | (hp->regs[i + 1] << 8)
1.13    bouyer 					    | (hp->regs[i + 2] << 16)
1.13    bouyer 					    | (hp->regs[i + 3] << 24));
1.13    bouyer 				} else {
1.13    bouyer 					HWRITE4(hp, i,
1.13    bouyer 					    (hp->regs[i + 0] << 0)
1.13    bouyer 					    | (hp->regs[i + 1] << 8));
1.13    bouyer 				}
1.11      matt 			}
1.11      matt 		} else {
1.12    nonaka 			for (i = 0; i < sizeof hp->regs; i++) {
1.11      matt 				HWRITE1(hp, i, hp->regs[i]);
1.11      matt 			}
1.11      matt 		}
 1.1    nonaka 	}
 1.1    nonaka 	return true;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka bool
 1.1    nonaka sdhc_shutdown(device_t dev, int flags)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_softc *sc = device_private(dev);
 1.1    nonaka 	struct sdhc_host *hp;
 1.1    nonaka
 1.1    nonaka 	/* XXX chip locks up if we don't disable it before reboot. */
1.11      matt 	for (size_t i = 0; i < sc->sc_nhosts; i++) {
 1.1    nonaka 		hp = sc->sc_host[i];
 1.1    nonaka 		(void)sdhc_host_reset(hp);
 1.1    nonaka 	}
 1.1    nonaka 	return true;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka /*
 1.1    nonaka  * Reset the host controller.  Called during initialization, when
 1.1    nonaka  * cards are removed, upon resume, and during error recovery.
 1.1    nonaka  */
 1.1    nonaka static int
 1.1    nonaka sdhc_host_reset1(sdmmc_chipset_handle_t sch)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
1.11      matt 	uint32_t sdhcimask;
 1.1    nonaka 	int error;
 1.1    nonaka
1.65  jmcneill 	KASSERT(mutex_owned(&hp->intr_lock));
 1.1    nonaka
 1.1    nonaka 	/* Disable all interrupts. */
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)) {
1.11      matt 		HWRITE4(hp, SDHC_NINTR_SIGNAL_EN, 0);
1.11      matt 	} else {
1.11      matt 		HWRITE2(hp, SDHC_NINTR_SIGNAL_EN, 0);
1.11      matt 	}
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * Reset the entire host controller and wait up to 100ms for
 1.1    nonaka 	 * the controller to clear the reset bit.
 1.1    nonaka 	 */
 1.1    nonaka 	error = sdhc_soft_reset(hp, SDHC_RESET_ALL);
 1.1    nonaka 	if (error)
 1.1    nonaka 		goto out;
 1.1    nonaka
 1.1    nonaka 	/* Set data timeout counter value to max for now. */
 1.1    nonaka 	HWRITE1(hp, SDHC_TIMEOUT_CTL, SDHC_TIMEOUT_MAX);
1.29      matt #if 1
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED))
1.11      matt 		HWRITE4(hp, SDHC_NINTR_STATUS, SDHC_CMD_TIMEOUT_ERROR << 16);
1.11      matt #endif
 1.1    nonaka
 1.1    nonaka 	/* Enable interrupts. */
 1.1    nonaka 	sdhcimask = SDHC_CARD_REMOVAL | SDHC_CARD_INSERTION |
 1.1    nonaka 	    SDHC_BUFFER_READ_READY | SDHC_BUFFER_WRITE_READY |
 1.1    nonaka 	    SDHC_DMA_INTERRUPT | SDHC_BLOCK_GAP_EVENT |
 1.1    nonaka 	    SDHC_TRANSFER_COMPLETE | SDHC_COMMAND_COMPLETE;
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)) {
1.11      matt 		sdhcimask |= SDHC_EINTR_STATUS_MASK << 16;
1.11      matt 		HWRITE4(hp, SDHC_NINTR_STATUS_EN, sdhcimask);
1.11      matt 		sdhcimask ^=
1.11      matt 		    (SDHC_EINTR_STATUS_MASK ^ SDHC_EINTR_SIGNAL_MASK) << 16;
1.11      matt 		sdhcimask ^= SDHC_BUFFER_READ_READY ^ SDHC_BUFFER_WRITE_READY;
1.11      matt 		HWRITE4(hp, SDHC_NINTR_SIGNAL_EN, sdhcimask);
1.11      matt 	} else {
1.11      matt 		HWRITE2(hp, SDHC_NINTR_STATUS_EN, sdhcimask);
1.11      matt 		HWRITE2(hp, SDHC_EINTR_STATUS_EN, SDHC_EINTR_STATUS_MASK);
1.11      matt 		sdhcimask ^= SDHC_BUFFER_READ_READY ^ SDHC_BUFFER_WRITE_READY;
1.11      matt 		HWRITE2(hp, SDHC_NINTR_SIGNAL_EN, sdhcimask);
1.11      matt 		HWRITE2(hp, SDHC_EINTR_SIGNAL_EN, SDHC_EINTR_SIGNAL_MASK);
1.11      matt 	}
 1.1    nonaka
 1.1    nonaka out:
 1.1    nonaka 	return error;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static int
 1.1    nonaka sdhc_host_reset(sdmmc_chipset_handle_t sch)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
 1.1    nonaka 	int error;
 1.1    nonaka
1.65  jmcneill 	mutex_enter(&hp->intr_lock);
 1.1    nonaka 	error = sdhc_host_reset1(sch);
1.65  jmcneill 	mutex_exit(&hp->intr_lock);
 1.1    nonaka
 1.1    nonaka 	return error;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static uint32_t
 1.1    nonaka sdhc_host_ocr(sdmmc_chipset_handle_t sch)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
 1.1    nonaka
 1.1    nonaka 	return hp->ocr;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static int
 1.1    nonaka sdhc_host_maxblklen(sdmmc_chipset_handle_t sch)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
 1.1    nonaka
 1.1    nonaka 	return hp->maxblklen;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka /*
 1.1    nonaka  * Return non-zero if the card is currently inserted.
 1.1    nonaka  */
 1.1    nonaka static int
 1.1    nonaka sdhc_card_detect(sdmmc_chipset_handle_t sch)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
 1.1    nonaka 	int r;
 1.1    nonaka
1.32  kiyohara 	if (hp->sc->sc_vendor_card_detect)
1.32  kiyohara 		return (*hp->sc->sc_vendor_card_detect)(hp->sc);
1.32  kiyohara
 1.1    nonaka 	r = ISSET(HREAD4(hp, SDHC_PRESENT_STATE), SDHC_CARD_INSERTED);
 1.1    nonaka
1.11      matt 	return r ? 1 : 0;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka /*
 1.1    nonaka  * Return non-zero if the card is currently write-protected.
 1.1    nonaka  */
 1.1    nonaka static int
 1.1    nonaka sdhc_write_protect(sdmmc_chipset_handle_t sch)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
 1.1    nonaka 	int r;
 1.1    nonaka
1.32  kiyohara 	if (hp->sc->sc_vendor_write_protect)
1.32  kiyohara 		return (*hp->sc->sc_vendor_write_protect)(hp->sc);
1.32  kiyohara
 1.1    nonaka 	r = ISSET(HREAD4(hp, SDHC_PRESENT_STATE), SDHC_WRITE_PROTECT_SWITCH);
 1.1    nonaka
1.12    nonaka 	return r ? 0 : 1;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka /*
 1.1    nonaka  * Set or change SD bus voltage and enable or disable SD bus power.
 1.1    nonaka  * Return zero on success.
 1.1    nonaka  */
 1.1    nonaka static int
 1.1    nonaka sdhc_bus_power(sdmmc_chipset_handle_t sch, uint32_t ocr)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
 1.1    nonaka 	uint8_t vdd;
 1.1    nonaka 	int error = 0;
1.32  kiyohara 	const uint32_t pcmask =
1.32  kiyohara 	    ~(SDHC_BUS_POWER | (SDHC_VOLTAGE_MASK << SDHC_VOLTAGE_SHIFT));
 1.1    nonaka
1.65  jmcneill 	mutex_enter(&hp->intr_lock);
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * Disable bus power before voltage change.
 1.1    nonaka 	 */
1.11      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)
1.11      matt 	    && !ISSET(hp->sc->sc_flags, SDHC_FLAG_NO_PWR0))
 1.1    nonaka 		HWRITE1(hp, SDHC_POWER_CTL, 0);
 1.1    nonaka
 1.1    nonaka 	/* If power is disabled, reset the host and return now. */
 1.1    nonaka 	if (ocr == 0) {
 1.1    nonaka 		(void)sdhc_host_reset1(hp);
 1.1    nonaka 		goto out;
 1.1    nonaka 	}
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * Select the lowest voltage according to capabilities.
 1.1    nonaka 	 */
 1.1    nonaka 	ocr &= hp->ocr;
1.11      matt 	if (ISSET(ocr, MMC_OCR_1_7V_1_8V|MMC_OCR_1_8V_1_9V)) {
 1.1    nonaka 		vdd = SDHC_VOLTAGE_1_8V;
1.11      matt 	} else if (ISSET(ocr, MMC_OCR_2_9V_3_0V|MMC_OCR_3_0V_3_1V)) {
 1.1    nonaka 		vdd = SDHC_VOLTAGE_3_0V;
1.11      matt 	} else if (ISSET(ocr, MMC_OCR_3_2V_3_3V|MMC_OCR_3_3V_3_4V)) {
 1.1    nonaka 		vdd = SDHC_VOLTAGE_3_3V;
1.11      matt 	} else {
 1.1    nonaka 		/* Unsupported voltage level requested. */
 1.1    nonaka 		error = EINVAL;
 1.1    nonaka 		goto out;
 1.1    nonaka 	}
 1.1    nonaka
1.11      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 		/*
1.11      matt 		 * Enable bus power.  Wait at least 1 ms (or 74 clocks) plus
1.11      matt 		 * voltage ramp until power rises.
1.11      matt 		 */
1.57  jmcneill
1.57  jmcneill 		if (ISSET(hp->sc->sc_flags, SDHC_FLAG_SINGLE_POWER_WRITE)) {
1.57  jmcneill 			HWRITE1(hp, SDHC_POWER_CTL,
1.57  jmcneill 			    (vdd << SDHC_VOLTAGE_SHIFT) | SDHC_BUS_POWER);
1.57  jmcneill 		} else {
1.57  jmcneill 			HWRITE1(hp, SDHC_POWER_CTL,
1.57  jmcneill 			    HREAD1(hp, SDHC_POWER_CTL) & pcmask);
1.57  jmcneill 			sdmmc_delay(1);
1.57  jmcneill 			HWRITE1(hp, SDHC_POWER_CTL,
1.57  jmcneill 			    (vdd << SDHC_VOLTAGE_SHIFT));
1.57  jmcneill 			sdmmc_delay(1);
1.57  jmcneill 			HSET1(hp, SDHC_POWER_CTL, SDHC_BUS_POWER);
1.57  jmcneill 			sdmmc_delay(10000);
1.57  jmcneill 		}
 1.1    nonaka
1.11      matt 		/*
1.11      matt 		 * The host system may not power the bus due to battery low,
1.11      matt 		 * etc.  In that case, the host controller should clear the
1.11      matt 		 * bus power bit.
1.11      matt 		 */
1.11      matt 		if (!ISSET(HREAD1(hp, SDHC_POWER_CTL), SDHC_BUS_POWER)) {
1.11      matt 			error = ENXIO;
1.11      matt 			goto out;
1.11      matt 		}
 1.1    nonaka 	}
 1.1    nonaka
 1.1    nonaka out:
1.65  jmcneill 	mutex_exit(&hp->intr_lock);
 1.1    nonaka
 1.1    nonaka 	return error;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka /*
 1.1    nonaka  * Return the smallest possible base clock frequency divisor value
 1.1    nonaka  * for the CLOCK_CTL register to produce `freq' (KHz).
 1.1    nonaka  */
1.11      matt static bool
1.11      matt sdhc_clock_divisor(struct sdhc_host *hp, u_int freq, u_int *divp)
 1.1    nonaka {
1.11      matt 	u_int div;
 1.1    nonaka
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_HAVE_CGM)) {
1.11      matt 		for (div = hp->clkbase / freq; div <= 0x3ff; div++) {
1.11      matt 			if ((hp->clkbase / div) <= freq) {
1.11      matt 				*divp = SDHC_SDCLK_CGM
1.11      matt 				    | ((div & 0x300) << SDHC_SDCLK_XDIV_SHIFT)
1.11      matt 				    | ((div & 0x0ff) << SDHC_SDCLK_DIV_SHIFT);
1.18  jakllsch 				//freq = hp->clkbase / div;
1.11      matt 				return true;
1.11      matt 			}
1.11      matt 		}
1.11      matt 		/* No divisor found. */
1.11      matt 		return false;
1.11      matt 	}
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_HAVE_DVS)) {
1.11      matt 		u_int dvs = (hp->clkbase + freq - 1) / freq;
1.11      matt 		u_int roundup = dvs & 1;
1.11      matt 		for (dvs >>= 1, div = 1; div <= 256; div <<= 1, dvs >>= 1) {
1.11      matt 			if (dvs + roundup <= 16) {
1.11      matt 				dvs += roundup - 1;
1.11      matt 				*divp = (div << SDHC_SDCLK_DIV_SHIFT)
1.11      matt 				    |   (dvs << SDHC_SDCLK_DVS_SHIFT);
1.11      matt 				DPRINTF(2,
1.11      matt 				    ("%s: divisor for freq %u is %u * %u\n",
1.11      matt 				    HDEVNAME(hp), freq, div * 2, dvs + 1));
1.18  jakllsch 				//freq = hp->clkbase / (div * 2) * (dvs + 1);
1.11      matt 				return true;
 1.9      matt 			}
1.11      matt 			/*
1.11      matt 			 * If we drop bits, we need to round up the divisor.
1.11      matt 			 */
1.11      matt 			roundup |= dvs & 1;
 1.9      matt 		}
1.18  jakllsch 		/* No divisor found. */
1.18  jakllsch 		return false;
1.38  jakllsch 	}
1.38  jakllsch 	if (hp->sc->sc_clkmsk != 0) {
1.38  jakllsch 		div = howmany(hp->clkbase, freq);
1.38  jakllsch 		if (div > (hp->sc->sc_clkmsk >> (ffs(hp->sc->sc_clkmsk) - 1)))
1.38  jakllsch 			return false;
1.38  jakllsch 		*divp = div << (ffs(hp->sc->sc_clkmsk) - 1);
1.38  jakllsch 		//freq = hp->clkbase / div;
1.38  jakllsch 		return true;
1.38  jakllsch 	}
1.56  jmcneill 	if (hp->specver >= SDHC_SPEC_VERS_300) {
1.38  jakllsch 		div = howmany(hp->clkbase, freq);
1.50   mlelstv 		div = div > 1 ? howmany(div, 2) : 0;
1.38  jakllsch 		if (div > 0x3ff)
1.38  jakllsch 			return false;
1.38  jakllsch 		*divp = (((div >> 8) & SDHC_SDCLK_XDIV_MASK)
1.38  jakllsch 			 << SDHC_SDCLK_XDIV_SHIFT) |
1.38  jakllsch 			(((div >> 0) & SDHC_SDCLK_DIV_MASK)
1.38  jakllsch 			 << SDHC_SDCLK_DIV_SHIFT);
1.67   mlelstv 		//freq = hp->clkbase / (div ? div * 2 : 1);
1.38  jakllsch 		return true;
 1.9      matt 	} else {
1.38  jakllsch 		for (div = 1; div <= 256; div *= 2) {
1.38  jakllsch 			if ((hp->clkbase / div) <= freq) {
1.38  jakllsch 				*divp = (div / 2) << SDHC_SDCLK_DIV_SHIFT;
1.38  jakllsch 				//freq = hp->clkbase / div;
1.38  jakllsch 				return true;
1.38  jakllsch 			}
1.38  jakllsch 		}
1.38  jakllsch 		/* No divisor found. */
1.38  jakllsch 		return false;
 1.9      matt 	}
 1.1    nonaka 	/* No divisor found. */
1.11      matt 	return false;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka /*
 1.1    nonaka  * Set or change SDCLK frequency or disable the SD clock.
 1.1    nonaka  * Return zero on success.
 1.1    nonaka  */
 1.1    nonaka static int
 1.1    nonaka sdhc_bus_clock(sdmmc_chipset_handle_t sch, int freq)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
1.11      matt 	u_int div;
1.11      matt 	u_int timo;
1.32  kiyohara 	int16_t reg;
 1.1    nonaka 	int error = 0;
1.65  jmcneill 	bool present __diagused;
1.65  jmcneill
1.65  jmcneill 	mutex_enter(&hp->intr_lock);
1.65  jmcneill
 1.2    cegger #ifdef DIAGNOSTIC
1.12    nonaka 	present = ISSET(HREAD4(hp, SDHC_PRESENT_STATE), SDHC_CMD_INHIBIT_MASK);
 1.1    nonaka
 1.1    nonaka 	/* Must not stop the clock if commands are in progress. */
1.12    nonaka 	if (present && sdhc_card_detect(hp)) {
1.26      matt 		aprint_normal_dev(hp->sc->sc_dev,
1.26      matt 		    "%s: command in progress\n", __func__);
1.12    nonaka 	}
 1.1    nonaka #endif
 1.1    nonaka
1.34      matt 	if (hp->sc->sc_vendor_bus_clock) {
1.34      matt 		error = (*hp->sc->sc_vendor_bus_clock)(hp->sc, freq);
1.34      matt 		if (error != 0)
1.34      matt 			goto out;
1.34      matt 	}
1.34      matt
 1.1    nonaka 	/*
 1.1    nonaka 	 * Stop SD clock before changing the frequency.
 1.1    nonaka 	 */
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 		HCLR4(hp, SDHC_CLOCK_CTL, 0xfff8);
1.11      matt 		if (freq == SDMMC_SDCLK_OFF) {
1.11      matt 			HSET4(hp, SDHC_CLOCK_CTL, 0x80f0);
1.11      matt 			goto out;
1.11      matt 		}
1.11      matt 	} else {
1.32  kiyohara 		HCLR2(hp, SDHC_CLOCK_CTL, SDHC_SDCLK_ENABLE);
1.11      matt 		if (freq == SDMMC_SDCLK_OFF)
1.11      matt 			goto out;
1.11      matt 	}
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * Set the minimum base clock frequency divisor.
 1.1    nonaka 	 */
1.11      matt 	if (!sdhc_clock_divisor(hp, freq, &div)) {
 1.1    nonaka 		/* Invalid base clock frequency or `freq' value. */
1.68   mlelstv 		aprint_error_dev(hp->sc->sc_dev,
1.68   mlelstv 			"Invalid bus clock %d kHz\n", freq);
 1.1    nonaka 		error = EINVAL;
 1.1    nonaka 		goto out;
 1.1    nonaka 	}
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 		HWRITE4(hp, SDHC_CLOCK_CTL,
1.11      matt 		    div | (SDHC_TIMEOUT_MAX << 16));
1.11      matt 	} else {
1.32  kiyohara 		reg = HREAD2(hp, SDHC_CLOCK_CTL);
1.32  kiyohara 		reg &= (SDHC_INTCLK_STABLE | SDHC_INTCLK_ENABLE);
1.32  kiyohara 		HWRITE2(hp, SDHC_CLOCK_CTL, reg | div);
1.11      matt 	}
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * Start internal clock.  Wait 10ms for stabilization.
 1.1    nonaka 	 */
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 		sdmmc_delay(10000);
1.12    nonaka 		HSET4(hp, SDHC_CLOCK_CTL,
1.12    nonaka 		    8 | SDHC_INTCLK_ENABLE | SDHC_INTCLK_STABLE);
1.11      matt 	} else {
1.11      matt 		HSET2(hp, SDHC_CLOCK_CTL, SDHC_INTCLK_ENABLE);
1.11      matt 		for (timo = 1000; timo > 0; timo--) {
1.12    nonaka 			if (ISSET(HREAD2(hp, SDHC_CLOCK_CTL),
1.12    nonaka 			    SDHC_INTCLK_STABLE))
1.11      matt 				break;
1.11      matt 			sdmmc_delay(10);
1.11      matt 		}
1.11      matt 		if (timo == 0) {
1.11      matt 			error = ETIMEDOUT;
1.11      matt 			goto out;
1.11      matt 		}
 1.1    nonaka 	}
 1.1    nonaka
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 		HSET1(hp, SDHC_SOFTWARE_RESET, SDHC_INIT_ACTIVE);
1.11      matt 		/*
1.11      matt 		 * Sending 80 clocks at 400kHz takes 200us.
1.11      matt 		 * So delay for that time + slop and then
1.11      matt 		 * check a few times for completion.
1.11      matt 		 */
1.11      matt 		sdmmc_delay(210);
1.11      matt 		for (timo = 10; timo > 0; timo--) {
1.11      matt 			if (!ISSET(HREAD1(hp, SDHC_SOFTWARE_RESET),
1.11      matt 			    SDHC_INIT_ACTIVE))
1.11      matt 				break;
1.11      matt 			sdmmc_delay(10);
1.11      matt 		}
1.11      matt 		DPRINTF(2,("%s: %u init spins\n", __func__, 10 - timo));
1.12    nonaka
1.11      matt 		/*
1.11      matt 		 * Enable SD clock.
1.11      matt 		 */
1.11      matt 		HSET4(hp, SDHC_CLOCK_CTL, SDHC_SDCLK_ENABLE);
1.11      matt 	} else {
1.11      matt 		/*
1.11      matt 		 * Enable SD clock.
1.11      matt 		 */
1.11      matt 		HSET2(hp, SDHC_CLOCK_CTL, SDHC_SDCLK_ENABLE);
 1.1    nonaka
1.43  jmcneill 		if (freq > 25000 &&
1.43  jmcneill 		    !ISSET(hp->sc->sc_flags, SDHC_FLAG_NO_HS_BIT))
1.11      matt 			HSET1(hp, SDHC_HOST_CTL, SDHC_HIGH_SPEED);
1.11      matt 		else
1.11      matt 			HCLR1(hp, SDHC_HOST_CTL, SDHC_HIGH_SPEED);
1.11      matt 	}
 1.8  kiyohara
 1.1    nonaka out:
1.65  jmcneill 	mutex_exit(&hp->intr_lock);
 1.1    nonaka
 1.1    nonaka 	return error;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static int
 1.1    nonaka sdhc_bus_width(sdmmc_chipset_handle_t sch, int width)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
 1.1    nonaka 	int reg;
 1.1    nonaka
 1.1    nonaka 	switch (width) {
 1.1    nonaka 	case 1:
 1.1    nonaka 	case 4:
 1.1    nonaka 		break;
 1.1    nonaka
1.11      matt 	case 8:
1.11      matt 		if (ISSET(hp->sc->sc_flags, SDHC_FLAG_8BIT_MODE))
1.11      matt 			break;
1.11      matt 		/* FALLTHROUGH */
 1.1    nonaka 	default:
 1.1    nonaka 		DPRINTF(0,("%s: unsupported bus width (%d)\n",
 1.1    nonaka 		    HDEVNAME(hp), width));
 1.1    nonaka 		return 1;
 1.1    nonaka 	}
 1.1    nonaka
1.65  jmcneill 	mutex_enter(&hp->intr_lock);
1.65  jmcneill
 1.5  uebayasi 	reg = HREAD1(hp, SDHC_HOST_CTL);
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.12    nonaka 		reg &= ~(SDHC_4BIT_MODE|SDHC_ESDHC_8BIT_MODE);
1.11      matt 		if (width == 4)
1.11      matt 			reg |= SDHC_4BIT_MODE;
1.11      matt 		else if (width == 8)
1.12    nonaka 			reg |= SDHC_ESDHC_8BIT_MODE;
1.11      matt 	} else {
1.11      matt 		reg &= ~SDHC_4BIT_MODE;
1.59  jmcneill 		if (hp->specver >= SDHC_SPEC_VERS_300) {
1.59  jmcneill 			reg &= ~SDHC_8BIT_MODE;
1.59  jmcneill 		}
1.59  jmcneill 		if (width == 4) {
1.11      matt 			reg |= SDHC_4BIT_MODE;
1.59  jmcneill 		} else if (width == 8 && hp->specver >= SDHC_SPEC_VERS_300) {
1.59  jmcneill 			reg |= SDHC_8BIT_MODE;
1.59  jmcneill 		}
1.11      matt 	}
 1.5  uebayasi 	HWRITE1(hp, SDHC_HOST_CTL, reg);
1.65  jmcneill
1.65  jmcneill 	mutex_exit(&hp->intr_lock);
 1.1    nonaka
 1.1    nonaka 	return 0;
 1.1    nonaka }
 1.1    nonaka
 1.8  kiyohara static int
 1.8  kiyohara sdhc_bus_rod(sdmmc_chipset_handle_t sch, int on)
 1.8  kiyohara {
1.32  kiyohara 	struct sdhc_host *hp = (struct sdhc_host *)sch;
1.32  kiyohara
1.32  kiyohara 	if (hp->sc->sc_vendor_rod)
1.32  kiyohara 		return (*hp->sc->sc_vendor_rod)(hp->sc, on);
 1.8  kiyohara
 1.8  kiyohara 	return 0;
 1.8  kiyohara }
 1.8  kiyohara
 1.1    nonaka static void
 1.1    nonaka sdhc_card_enable_intr(sdmmc_chipset_handle_t sch, int enable)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
 1.1    nonaka
1.11      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.65  jmcneill 		mutex_enter(&hp->intr_lock);
1.11      matt 		if (enable) {
1.11      matt 			HSET2(hp, SDHC_NINTR_STATUS_EN, SDHC_CARD_INTERRUPT);
1.11      matt 			HSET2(hp, SDHC_NINTR_SIGNAL_EN, SDHC_CARD_INTERRUPT);
1.11      matt 		} else {
1.11      matt 			HCLR2(hp, SDHC_NINTR_SIGNAL_EN, SDHC_CARD_INTERRUPT);
1.11      matt 			HCLR2(hp, SDHC_NINTR_STATUS_EN, SDHC_CARD_INTERRUPT);
1.11      matt 		}
1.65  jmcneill 		mutex_exit(&hp->intr_lock);
 1.1    nonaka 	}
 1.1    nonaka }
 1.1    nonaka
1.47     skrll static void
 1.1    nonaka sdhc_card_intr_ack(sdmmc_chipset_handle_t sch)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
 1.1    nonaka
1.11      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.65  jmcneill 		mutex_enter(&hp->intr_lock);
1.11      matt 		HSET2(hp, SDHC_NINTR_STATUS_EN, SDHC_CARD_INTERRUPT);
1.65  jmcneill 		mutex_exit(&hp->intr_lock);
1.11      matt 	}
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static int
 1.1    nonaka sdhc_wait_state(struct sdhc_host *hp, uint32_t mask, uint32_t value)
 1.1    nonaka {
 1.1    nonaka 	uint32_t state;
 1.1    nonaka 	int timeout;
 1.1    nonaka
1.65  jmcneill 	for (timeout = 10000; timeout > 0; timeout--) {
 1.1    nonaka 		if (((state = HREAD4(hp, SDHC_PRESENT_STATE)) & mask) == value)
 1.1    nonaka 			return 0;
1.65  jmcneill 		sdmmc_delay(10);
 1.1    nonaka 	}
1.68   mlelstv 	aprint_error_dev(hp->sc->sc_dev, "timeout waiting for %x (state=%x)\n",
1.68   mlelstv 	    value, state);
 1.1    nonaka 	return ETIMEDOUT;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static void
 1.1    nonaka sdhc_exec_command(sdmmc_chipset_handle_t sch, struct sdmmc_command *cmd)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_host *hp = (struct sdhc_host *)sch;
 1.1    nonaka 	int error;
 1.1    nonaka
1.65  jmcneill 	mutex_enter(&hp->intr_lock);
1.65  jmcneill
1.26      matt 	if (cmd->c_data && ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 		const uint16_t ready = SDHC_BUFFER_READ_READY | SDHC_BUFFER_WRITE_READY;
1.11      matt 		if (ISSET(hp->flags, SHF_USE_DMA)) {
1.11      matt 			HCLR2(hp, SDHC_NINTR_SIGNAL_EN, ready);
1.11      matt 			HCLR2(hp, SDHC_NINTR_STATUS_EN, ready);
1.11      matt 		} else {
1.11      matt 			HSET2(hp, SDHC_NINTR_SIGNAL_EN, ready);
1.11      matt 			HSET2(hp, SDHC_NINTR_STATUS_EN, ready);
1.47     skrll 		}
1.11      matt 	}
1.11      matt
1.61  jmcneill 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_NO_TIMEOUT)) {
1.61  jmcneill 		const uint16_t eintr = SDHC_CMD_TIMEOUT_ERROR;
1.61  jmcneill 		if (cmd->c_data != NULL) {
1.61  jmcneill 			HCLR2(hp, SDHC_EINTR_SIGNAL_EN, eintr);
1.61  jmcneill 			HCLR2(hp, SDHC_EINTR_STATUS_EN, eintr);
1.61  jmcneill 		} else {
1.61  jmcneill 			HSET2(hp, SDHC_EINTR_SIGNAL_EN, eintr);
1.61  jmcneill 			HSET2(hp, SDHC_EINTR_STATUS_EN, eintr);
1.61  jmcneill 		}
1.61  jmcneill 	}
1.61  jmcneill
 1.1    nonaka 	/*
 1.1    nonaka 	 * Start the MMC command, or mark `cmd' as failed and return.
 1.1    nonaka 	 */
 1.1    nonaka 	error = sdhc_start_command(hp, cmd);
 1.1    nonaka 	if (error) {
 1.1    nonaka 		cmd->c_error = error;
 1.1    nonaka 		goto out;
 1.1    nonaka 	}
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * Wait until the command phase is done, or until the command
 1.1    nonaka 	 * is marked done for any other reason.
 1.1    nonaka 	 */
 1.1    nonaka 	if (!sdhc_wait_intr(hp, SDHC_COMMAND_COMPLETE, SDHC_COMMAND_TIMEOUT)) {
 1.1    nonaka 		cmd->c_error = ETIMEDOUT;
 1.1    nonaka 		goto out;
 1.1    nonaka 	}
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * The host controller removes bits [0:7] from the response
 1.1    nonaka 	 * data (CRC) and we pass the data up unchanged to the bus
 1.1    nonaka 	 * driver (without padding).
 1.1    nonaka 	 */
 1.1    nonaka 	if (cmd->c_error == 0 && ISSET(cmd->c_flags, SCF_RSP_PRESENT)) {
1.23      matt 		cmd->c_resp[0] = HREAD4(hp, SDHC_RESPONSE + 0);
1.23      matt 		if (ISSET(cmd->c_flags, SCF_RSP_136)) {
1.23      matt 			cmd->c_resp[1] = HREAD4(hp, SDHC_RESPONSE + 4);
1.23      matt 			cmd->c_resp[2] = HREAD4(hp, SDHC_RESPONSE + 8);
1.23      matt 			cmd->c_resp[3] = HREAD4(hp, SDHC_RESPONSE + 12);
1.32  kiyohara 			if (ISSET(hp->sc->sc_flags, SDHC_FLAG_RSP136_CRC)) {
1.32  kiyohara 				cmd->c_resp[0] = (cmd->c_resp[0] >> 8) |
1.32  kiyohara 				    (cmd->c_resp[1] << 24);
1.32  kiyohara 				cmd->c_resp[1] = (cmd->c_resp[1] >> 8) |
1.32  kiyohara 				    (cmd->c_resp[2] << 24);
1.32  kiyohara 				cmd->c_resp[2] = (cmd->c_resp[2] >> 8) |
1.32  kiyohara 				    (cmd->c_resp[3] << 24);
1.32  kiyohara 				cmd->c_resp[3] = (cmd->c_resp[3] >> 8);
1.32  kiyohara 			}
 1.1    nonaka 		}
 1.1    nonaka 	}
1.25      matt 	DPRINTF(1,("%s: resp = %08x\n", HDEVNAME(hp), cmd->c_resp[0]));
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * If the command has data to transfer in any direction,
 1.1    nonaka 	 * execute the transfer now.
 1.1    nonaka 	 */
 1.1    nonaka 	if (cmd->c_error == 0 && cmd->c_data != NULL)
 1.1    nonaka 		sdhc_transfer_data(hp, cmd);
1.42  jakllsch 	else if (ISSET(cmd->c_flags, SCF_RSP_BSY)) {
1.42  jakllsch 		if (!sdhc_wait_intr(hp, SDHC_TRANSFER_COMPLETE, hz * 10)) {
1.42  jakllsch 			cmd->c_error = ETIMEDOUT;
1.42  jakllsch 			goto out;
1.42  jakllsch 		}
1.42  jakllsch 	}
 1.1    nonaka
 1.1    nonaka out:
1.14      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)
1.14      matt 	    && !ISSET(hp->sc->sc_flags, SDHC_FLAG_NO_LED_ON)) {
1.11      matt 		/* Turn off the LED. */
1.11      matt 		HCLR1(hp, SDHC_HOST_CTL, SDHC_LED_ON);
1.11      matt 	}
 1.1    nonaka 	SET(cmd->c_flags, SCF_ITSDONE);
 1.1    nonaka
1.65  jmcneill 	mutex_exit(&hp->intr_lock);
1.65  jmcneill
 1.1    nonaka 	DPRINTF(1,("%s: cmd %d %s (flags=%08x error=%d)\n", HDEVNAME(hp),
 1.1    nonaka 	    cmd->c_opcode, (cmd->c_error == 0) ? "done" : "abort",
 1.1    nonaka 	    cmd->c_flags, cmd->c_error));
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static int
 1.1    nonaka sdhc_start_command(struct sdhc_host *hp, struct sdmmc_command *cmd)
 1.1    nonaka {
1.11      matt 	struct sdhc_softc * const sc = hp->sc;
 1.1    nonaka 	uint16_t blksize = 0;
 1.1    nonaka 	uint16_t blkcount = 0;
 1.1    nonaka 	uint16_t mode;
 1.1    nonaka 	uint16_t command;
 1.1    nonaka 	int error;
 1.1    nonaka
1.65  jmcneill 	KASSERT(mutex_owned(&hp->intr_lock));
1.65  jmcneill
1.11      matt 	DPRINTF(1,("%s: start cmd %d arg=%08x data=%p dlen=%d flags=%08x, status=%#x\n",
 1.7    nonaka 	    HDEVNAME(hp), cmd->c_opcode, cmd->c_arg, cmd->c_data,
1.11      matt 	    cmd->c_datalen, cmd->c_flags, HREAD4(hp, SDHC_NINTR_STATUS)));
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * The maximum block length for commands should be the minimum
 1.1    nonaka 	 * of the host buffer size and the card buffer size. (1.7.2)
 1.1    nonaka 	 */
 1.1    nonaka
 1.1    nonaka 	/* Fragment the data into proper blocks. */
 1.1    nonaka 	if (cmd->c_datalen > 0) {
 1.1    nonaka 		blksize = MIN(cmd->c_datalen, cmd->c_blklen);
 1.1    nonaka 		blkcount = cmd->c_datalen / blksize;
 1.1    nonaka 		if (cmd->c_datalen % blksize > 0) {
 1.1    nonaka 			/* XXX: Split this command. (1.7.4) */
1.11      matt 			aprint_error_dev(sc->sc_dev,
 1.1    nonaka 			    "data not a multiple of %u bytes\n", blksize);
 1.1    nonaka 			return EINVAL;
 1.1    nonaka 		}
 1.1    nonaka 	}
 1.1    nonaka
 1.1    nonaka 	/* Check limit imposed by 9-bit block count. (1.7.2) */
 1.1    nonaka 	if (blkcount > SDHC_BLOCK_COUNT_MAX) {
1.11      matt 		aprint_error_dev(sc->sc_dev, "too much data\n");
 1.1    nonaka 		return EINVAL;
 1.1    nonaka 	}
 1.1    nonaka
 1.1    nonaka 	/* Prepare transfer mode register value. (2.2.5) */
1.15  jakllsch 	mode = SDHC_BLOCK_COUNT_ENABLE;
 1.1    nonaka 	if (ISSET(cmd->c_flags, SCF_CMD_READ))
 1.1    nonaka 		mode |= SDHC_READ_MODE;
1.15  jakllsch 	if (blkcount > 1) {
1.15  jakllsch 		mode |= SDHC_MULTI_BLOCK_MODE;
1.15  jakllsch 		/* XXX only for memory commands? */
1.15  jakllsch 		mode |= SDHC_AUTO_CMD12_ENABLE;
 1.1    nonaka 	}
1.45  jakllsch 	if (cmd->c_dmamap != NULL && cmd->c_datalen > 0 &&
1.55    bouyer 	    ISSET(hp->flags,  SHF_MODE_DMAEN)) {
1.19  jakllsch 		mode |= SDHC_DMA_ENABLE;
 1.7    nonaka 	}
 1.1    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * Prepare command register value. (2.2.6)
 1.1    nonaka 	 */
1.12    nonaka 	command = (cmd->c_opcode & SDHC_COMMAND_INDEX_MASK) << SDHC_COMMAND_INDEX_SHIFT;
 1.1    nonaka
 1.1    nonaka 	if (ISSET(cmd->c_flags, SCF_RSP_CRC))
 1.1    nonaka 		command |= SDHC_CRC_CHECK_ENABLE;
 1.1    nonaka 	if (ISSET(cmd->c_flags, SCF_RSP_IDX))
 1.1    nonaka 		command |= SDHC_INDEX_CHECK_ENABLE;
 1.1    nonaka 	if (cmd->c_data != NULL)
 1.1    nonaka 		command |= SDHC_DATA_PRESENT_SELECT;
 1.1    nonaka
 1.1    nonaka 	if (!ISSET(cmd->c_flags, SCF_RSP_PRESENT))
 1.1    nonaka 		command |= SDHC_NO_RESPONSE;
 1.1    nonaka 	else if (ISSET(cmd->c_flags, SCF_RSP_136))
 1.1    nonaka 		command |= SDHC_RESP_LEN_136;
 1.1    nonaka 	else if (ISSET(cmd->c_flags, SCF_RSP_BSY))
 1.1    nonaka 		command |= SDHC_RESP_LEN_48_CHK_BUSY;
 1.1    nonaka 	else
 1.1    nonaka 		command |= SDHC_RESP_LEN_48;
 1.1    nonaka
 1.1    nonaka 	/* Wait until command and data inhibit bits are clear. (1.5) */
 1.1    nonaka 	error = sdhc_wait_state(hp, SDHC_CMD_INHIBIT_MASK, 0);
1.68   mlelstv 	if (error) {
1.68   mlelstv 		aprint_error_dev(sc->sc_dev, "command or data phase inhibited\n");
 1.1    nonaka 		return error;
1.68   mlelstv 	}
 1.1    nonaka
 1.1    nonaka 	DPRINTF(1,("%s: writing cmd: blksize=%d blkcnt=%d mode=%04x cmd=%04x\n",
 1.1    nonaka 	    HDEVNAME(hp), blksize, blkcount, mode, command));
 1.1    nonaka
1.44   hkenken 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.44   hkenken 		blksize |= (MAX(0, PAGE_SHIFT - 12) & SDHC_DMA_BOUNDARY_MASK) <<
1.44   hkenken 		    SDHC_DMA_BOUNDARY_SHIFT;	/* PAGE_SIZE DMA boundary */
1.44   hkenken 	}
1.19  jakllsch
1.11      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 		/* Alert the user not to remove the card. */
1.11      matt 		HSET1(hp, SDHC_HOST_CTL, SDHC_LED_ON);
1.11      matt 	}
 1.1    nonaka
 1.7    nonaka 	/* Set DMA start address. */
1.63  jmcneill 	if (ISSET(hp->flags, SHF_USE_ADMA2_MASK) && cmd->c_datalen > 0) {
1.63  jmcneill 		for (int seg = 0; seg < cmd->c_dmamap->dm_nsegs; seg++) {
1.69  jmcneill 			bus_addr_t paddr =
1.63  jmcneill 			    cmd->c_dmamap->dm_segs[seg].ds_addr;
1.63  jmcneill 			uint16_t len =
1.63  jmcneill 			    cmd->c_dmamap->dm_segs[seg].ds_len == 65536 ?
1.63  jmcneill 			    0 : cmd->c_dmamap->dm_segs[seg].ds_len;
1.63  jmcneill 			uint16_t attr =
1.63  jmcneill 			    SDHC_ADMA2_VALID | SDHC_ADMA2_ACT_TRANS;
1.63  jmcneill 			if (seg == cmd->c_dmamap->dm_nsegs - 1) {
1.63  jmcneill 				attr |= SDHC_ADMA2_END;
1.63  jmcneill 			}
1.63  jmcneill 			if (ISSET(hp->flags, SHF_USE_ADMA2_32)) {
1.63  jmcneill 				struct sdhc_adma2_descriptor32 *desc =
1.63  jmcneill 				    hp->adma2;
1.63  jmcneill 				desc[seg].attribute = htole16(attr);
1.63  jmcneill 				desc[seg].length = htole16(len);
1.63  jmcneill 				desc[seg].address = htole32(paddr);
1.63  jmcneill 			} else {
1.63  jmcneill 				struct sdhc_adma2_descriptor64 *desc =
1.63  jmcneill 				    hp->adma2;
1.63  jmcneill 				desc[seg].attribute = htole16(attr);
1.63  jmcneill 				desc[seg].length = htole16(len);
1.63  jmcneill 				desc[seg].address = htole32(paddr & 0xffffffff);
1.63  jmcneill 				desc[seg].address_hi = htole32(
1.63  jmcneill 				    (uint64_t)paddr >> 32);
1.63  jmcneill 			}
1.63  jmcneill 		}
1.63  jmcneill 		if (ISSET(hp->flags, SHF_USE_ADMA2_32)) {
1.63  jmcneill 			struct sdhc_adma2_descriptor32 *desc = hp->adma2;
1.63  jmcneill 			desc[cmd->c_dmamap->dm_nsegs].attribute = htole16(0);
1.63  jmcneill 		} else {
1.63  jmcneill 			struct sdhc_adma2_descriptor64 *desc = hp->adma2;
1.63  jmcneill 			desc[cmd->c_dmamap->dm_nsegs].attribute = htole16(0);
1.63  jmcneill 		}
1.63  jmcneill 		bus_dmamap_sync(sc->sc_dmat, hp->adma_map, 0, PAGE_SIZE,
1.63  jmcneill 		    BUS_DMASYNC_PREWRITE);
1.63  jmcneill 		HCLR1(hp, SDHC_HOST_CTL, SDHC_DMA_SELECT);
1.63  jmcneill 		HSET1(hp, SDHC_HOST_CTL, SDHC_DMA_SELECT_ADMA2);
1.63  jmcneill
1.70  jmcneill 		const bus_addr_t desc_addr = hp->adma_map->dm_segs[0].ds_addr;
1.63  jmcneill
1.63  jmcneill 		HWRITE4(hp, SDHC_ADMA_SYSTEM_ADDR, desc_addr & 0xffffffff);
1.63  jmcneill 		if (ISSET(hp->flags, SHF_USE_ADMA2_64)) {
1.63  jmcneill 			HWRITE4(hp, SDHC_ADMA_SYSTEM_ADDR + 4,
1.63  jmcneill 			    (uint64_t)desc_addr >> 32);
1.63  jmcneill 		}
1.63  jmcneill 	} else if (ISSET(mode, SDHC_DMA_ENABLE) &&
1.63  jmcneill 	    !ISSET(sc->sc_flags, SDHC_FLAG_EXTERNAL_DMA)) {
 1.7    nonaka 		HWRITE4(hp, SDHC_DMA_ADDR, cmd->c_dmamap->dm_segs[0].ds_addr);
1.63  jmcneill 	}
 1.7    nonaka
 1.1    nonaka 	/*
 1.1    nonaka 	 * Start a CPU data transfer.  Writing to the high order byte
 1.1    nonaka 	 * of the SDHC_COMMAND register triggers the SD command. (1.5)
 1.1    nonaka 	 */
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)) {
1.11      matt 		HWRITE4(hp, SDHC_BLOCK_SIZE, blksize | (blkcount << 16));
1.11      matt 		HWRITE4(hp, SDHC_ARGUMENT, cmd->c_arg);
1.11      matt 		HWRITE4(hp, SDHC_TRANSFER_MODE, mode | (command << 16));
1.11      matt 	} else {
1.11      matt 		HWRITE2(hp, SDHC_BLOCK_SIZE, blksize);
1.15  jakllsch 		HWRITE2(hp, SDHC_BLOCK_COUNT, blkcount);
1.11      matt 		HWRITE4(hp, SDHC_ARGUMENT, cmd->c_arg);
1.15  jakllsch 		HWRITE2(hp, SDHC_TRANSFER_MODE, mode);
1.11      matt 		HWRITE2(hp, SDHC_COMMAND, command);
1.11      matt 	}
 1.1    nonaka
 1.1    nonaka 	return 0;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static void
 1.1    nonaka sdhc_transfer_data(struct sdhc_host *hp, struct sdmmc_command *cmd)
 1.1    nonaka {
1.51  jmcneill 	struct sdhc_softc *sc = hp->sc;
 1.1    nonaka 	int error;
 1.1    nonaka
1.65  jmcneill 	KASSERT(mutex_owned(&hp->intr_lock));
1.65  jmcneill
 1.1    nonaka 	DPRINTF(1,("%s: data transfer: resp=%08x datalen=%u\n", HDEVNAME(hp),
 1.1    nonaka 	    MMC_R1(cmd->c_resp), cmd->c_datalen));
 1.1    nonaka
 1.1    nonaka #ifdef SDHC_DEBUG
 1.1    nonaka 	/* XXX I forgot why I wanted to know when this happens :-( */
 1.1    nonaka 	if ((cmd->c_opcode == 52 || cmd->c_opcode == 53) &&
 1.1    nonaka 	    ISSET(MMC_R1(cmd->c_resp), 0xcb00)) {
 1.1    nonaka 		aprint_error_dev(hp->sc->sc_dev,
 1.1    nonaka 		    "CMD52/53 error response flags %#x\n",
 1.1    nonaka 		    MMC_R1(cmd->c_resp) & 0xff00);
 1.1    nonaka 	}
 1.1    nonaka #endif
 1.1    nonaka
1.47     skrll 	if (cmd->c_dmamap != NULL) {
1.47     skrll 		if (hp->sc->sc_vendor_transfer_data_dma != NULL) {
1.51  jmcneill 			error = hp->sc->sc_vendor_transfer_data_dma(sc, cmd);
1.47     skrll 			if (error == 0 && !sdhc_wait_intr(hp,
1.61  jmcneill 			    SDHC_TRANSFER_COMPLETE, SDHC_DMA_TIMEOUT)) {
1.47     skrll 				error = ETIMEDOUT;
1.47     skrll 			}
1.47     skrll 		} else {
1.47     skrll 			error = sdhc_transfer_data_dma(hp, cmd);
1.47     skrll 		}
1.47     skrll 	} else
 1.7    nonaka 		error = sdhc_transfer_data_pio(hp, cmd);
 1.1    nonaka 	if (error)
 1.1    nonaka 		cmd->c_error = error;
 1.1    nonaka 	SET(cmd->c_flags, SCF_ITSDONE);
 1.1    nonaka
 1.1    nonaka 	DPRINTF(1,("%s: data transfer done (error=%d)\n",
 1.1    nonaka 	    HDEVNAME(hp), cmd->c_error));
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static int
 1.7    nonaka sdhc_transfer_data_dma(struct sdhc_host *hp, struct sdmmc_command *cmd)
 1.7    nonaka {
1.19  jakllsch 	bus_dma_segment_t *dm_segs = cmd->c_dmamap->dm_segs;
1.19  jakllsch 	bus_addr_t posaddr;
1.19  jakllsch 	bus_addr_t segaddr;
1.19  jakllsch 	bus_size_t seglen;
1.19  jakllsch 	u_int seg = 0;
 1.7    nonaka 	int error = 0;
1.19  jakllsch 	int status;
 1.7    nonaka
1.65  jmcneill 	KASSERT(mutex_owned(&hp->intr_lock));
1.11      matt 	KASSERT(HREAD2(hp, SDHC_NINTR_STATUS_EN) & SDHC_DMA_INTERRUPT);
1.11      matt 	KASSERT(HREAD2(hp, SDHC_NINTR_SIGNAL_EN) & SDHC_DMA_INTERRUPT);
1.11      matt 	KASSERT(HREAD2(hp, SDHC_NINTR_STATUS_EN) & SDHC_TRANSFER_COMPLETE);
1.11      matt 	KASSERT(HREAD2(hp, SDHC_NINTR_SIGNAL_EN) & SDHC_TRANSFER_COMPLETE);
1.11      matt
 1.7    nonaka 	for (;;) {
1.19  jakllsch 		status = sdhc_wait_intr(hp,
 1.7    nonaka 		    SDHC_DMA_INTERRUPT|SDHC_TRANSFER_COMPLETE,
1.19  jakllsch 		    SDHC_DMA_TIMEOUT);
1.19  jakllsch
1.19  jakllsch 		if (status & SDHC_TRANSFER_COMPLETE) {
1.19  jakllsch 			break;
1.19  jakllsch 		}
1.19  jakllsch 		if (!status) {
 1.7    nonaka 			error = ETIMEDOUT;
 1.7    nonaka 			break;
 1.7    nonaka 		}
1.63  jmcneill
1.63  jmcneill 		if (ISSET(hp->flags, SHF_USE_ADMA2_MASK)) {
1.63  jmcneill 			continue;
1.63  jmcneill 		}
1.63  jmcneill
1.19  jakllsch 		if ((status & SDHC_DMA_INTERRUPT) == 0) {
1.19  jakllsch 			continue;
1.19  jakllsch 		}
1.19  jakllsch
1.19  jakllsch 		/* DMA Interrupt (boundary crossing) */
 1.7    nonaka
1.19  jakllsch 		segaddr = dm_segs[seg].ds_addr;
1.19  jakllsch 		seglen = dm_segs[seg].ds_len;
1.19  jakllsch 		posaddr = HREAD4(hp, SDHC_DMA_ADDR);
 1.7    nonaka
1.19  jakllsch 		if ((seg == (cmd->c_dmamap->dm_nsegs-1)) && (posaddr == (segaddr + seglen))) {
1.37  jakllsch 			continue;
1.19  jakllsch 		}
1.19  jakllsch 		if ((posaddr >= segaddr) && (posaddr < (segaddr + seglen)))
1.19  jakllsch 			HWRITE4(hp, SDHC_DMA_ADDR, posaddr);
1.19  jakllsch 		else if ((posaddr >= segaddr) && (posaddr == (segaddr + seglen)) && (seg + 1) < cmd->c_dmamap->dm_nsegs)
1.19  jakllsch 			HWRITE4(hp, SDHC_DMA_ADDR, dm_segs[++seg].ds_addr);
1.19  jakllsch 		KASSERT(seg < cmd->c_dmamap->dm_nsegs);
 1.7    nonaka 	}
 1.7    nonaka
1.63  jmcneill 	if (ISSET(hp->flags, SHF_USE_ADMA2_MASK)) {
1.63  jmcneill 		bus_dmamap_sync(hp->sc->sc_dmat, hp->adma_map, 0,
1.63  jmcneill 		    PAGE_SIZE, BUS_DMASYNC_POSTWRITE);
1.63  jmcneill 	}
1.63  jmcneill
 1.7    nonaka 	return error;
 1.7    nonaka }
 1.7    nonaka
 1.7    nonaka static int
 1.1    nonaka sdhc_transfer_data_pio(struct sdhc_host *hp, struct sdmmc_command *cmd)
 1.1    nonaka {
 1.1    nonaka 	uint8_t *data = cmd->c_data;
1.12    nonaka 	void (*pio_func)(struct sdhc_host *, uint8_t *, u_int);
1.11      matt 	u_int len, datalen;
1.11      matt 	u_int imask;
1.11      matt 	u_int pmask;
 1.1    nonaka 	int error = 0;
 1.1    nonaka
1.11      matt 	if (ISSET(cmd->c_flags, SCF_CMD_READ)) {
1.11      matt 		imask = SDHC_BUFFER_READ_READY;
1.11      matt 		pmask = SDHC_BUFFER_READ_ENABLE;
1.11      matt 		if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 			pio_func = esdhc_read_data_pio;
1.11      matt 		} else {
1.11      matt 			pio_func = sdhc_read_data_pio;
1.11      matt 		}
1.11      matt 	} else {
1.11      matt 		imask = SDHC_BUFFER_WRITE_READY;
1.11      matt 		pmask = SDHC_BUFFER_WRITE_ENABLE;
1.11      matt 		if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 			pio_func = esdhc_write_data_pio;
1.11      matt 		} else {
1.11      matt 			pio_func = sdhc_write_data_pio;
1.11      matt 		}
1.11      matt 	}
 1.1    nonaka 	datalen = cmd->c_datalen;
 1.1    nonaka
1.65  jmcneill 	KASSERT(mutex_owned(&hp->intr_lock));
1.11      matt 	KASSERT(HREAD2(hp, SDHC_NINTR_STATUS_EN) & imask);
1.11      matt 	KASSERT(HREAD2(hp, SDHC_NINTR_STATUS_EN) & SDHC_TRANSFER_COMPLETE);
1.11      matt 	KASSERT(HREAD2(hp, SDHC_NINTR_SIGNAL_EN) & SDHC_TRANSFER_COMPLETE);
1.11      matt
 1.1    nonaka 	while (datalen > 0) {
1.11      matt 		if (!ISSET(HREAD4(hp, SDHC_PRESENT_STATE), imask)) {
1.11      matt 			if (ISSET(hp->sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)) {
1.11      matt 				HSET4(hp, SDHC_NINTR_SIGNAL_EN, imask);
1.11      matt 			} else {
1.11      matt 				HSET2(hp, SDHC_NINTR_SIGNAL_EN, imask);
1.11      matt 			}
1.11      matt 			if (!sdhc_wait_intr(hp, imask, SDHC_BUFFER_TIMEOUT)) {
1.11      matt 				error = ETIMEDOUT;
1.11      matt 				break;
1.11      matt 			}
1.11      matt
1.11      matt 			error = sdhc_wait_state(hp, pmask, pmask);
1.11      matt 			if (error)
1.11      matt 				break;
 1.1    nonaka 		}
 1.1    nonaka
 1.1    nonaka 		len = MIN(datalen, cmd->c_blklen);
1.11      matt 		(*pio_func)(hp, data, len);
1.11      matt 		DPRINTF(2,("%s: pio data transfer %u @ %p\n",
1.11      matt 		    HDEVNAME(hp), len, data));
 1.1    nonaka
 1.1    nonaka 		data += len;
 1.1    nonaka 		datalen -= len;
 1.1    nonaka 	}
 1.1    nonaka
 1.1    nonaka 	if (error == 0 && !sdhc_wait_intr(hp, SDHC_TRANSFER_COMPLETE,
 1.1    nonaka 	    SDHC_TRANSFER_TIMEOUT))
 1.1    nonaka 		error = ETIMEDOUT;
 1.1    nonaka
 1.1    nonaka 	return error;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static void
1.11      matt sdhc_read_data_pio(struct sdhc_host *hp, uint8_t *data, u_int datalen)
 1.1    nonaka {
 1.1    nonaka
 1.1    nonaka 	if (((__uintptr_t)data & 3) == 0) {
 1.1    nonaka 		while (datalen > 3) {
1.29      matt 			*(uint32_t *)data = le32toh(HREAD4(hp, SDHC_DATA));
 1.1    nonaka 			data += 4;
 1.1    nonaka 			datalen -= 4;
 1.1    nonaka 		}
 1.1    nonaka 		if (datalen > 1) {
1.29      matt 			*(uint16_t *)data = le16toh(HREAD2(hp, SDHC_DATA));
 1.1    nonaka 			data += 2;
 1.1    nonaka 			datalen -= 2;
 1.1    nonaka 		}
 1.1    nonaka 		if (datalen > 0) {
 1.1    nonaka 			*data = HREAD1(hp, SDHC_DATA);
 1.1    nonaka 			data += 1;
 1.1    nonaka 			datalen -= 1;
 1.1    nonaka 		}
 1.1    nonaka 	} else if (((__uintptr_t)data & 1) == 0) {
 1.1    nonaka 		while (datalen > 1) {
1.29      matt 			*(uint16_t *)data = le16toh(HREAD2(hp, SDHC_DATA));
 1.1    nonaka 			data += 2;
 1.1    nonaka 			datalen -= 2;
 1.1    nonaka 		}
 1.1    nonaka 		if (datalen > 0) {
 1.1    nonaka 			*data = HREAD1(hp, SDHC_DATA);
 1.1    nonaka 			data += 1;
 1.1    nonaka 			datalen -= 1;
 1.1    nonaka 		}
 1.1    nonaka 	} else {
 1.1    nonaka 		while (datalen > 0) {
 1.1    nonaka 			*data = HREAD1(hp, SDHC_DATA);
 1.1    nonaka 			data += 1;
 1.1    nonaka 			datalen -= 1;
 1.1    nonaka 		}
 1.1    nonaka 	}
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static void
1.11      matt sdhc_write_data_pio(struct sdhc_host *hp, uint8_t *data, u_int datalen)
 1.1    nonaka {
 1.1    nonaka
 1.1    nonaka 	if (((__uintptr_t)data & 3) == 0) {
 1.1    nonaka 		while (datalen > 3) {
1.29      matt 			HWRITE4(hp, SDHC_DATA, htole32(*(uint32_t *)data));
 1.1    nonaka 			data += 4;
 1.1    nonaka 			datalen -= 4;
 1.1    nonaka 		}
 1.1    nonaka 		if (datalen > 1) {
1.29      matt 			HWRITE2(hp, SDHC_DATA, htole16(*(uint16_t *)data));
 1.1    nonaka 			data += 2;
 1.1    nonaka 			datalen -= 2;
 1.1    nonaka 		}
 1.1    nonaka 		if (datalen > 0) {
 1.1    nonaka 			HWRITE1(hp, SDHC_DATA, *data);
 1.1    nonaka 			data += 1;
 1.1    nonaka 			datalen -= 1;
 1.1    nonaka 		}
 1.1    nonaka 	} else if (((__uintptr_t)data & 1) == 0) {
 1.1    nonaka 		while (datalen > 1) {
1.29      matt 			HWRITE2(hp, SDHC_DATA, htole16(*(uint16_t *)data));
 1.1    nonaka 			data += 2;
 1.1    nonaka 			datalen -= 2;
 1.1    nonaka 		}
 1.1    nonaka 		if (datalen > 0) {
 1.1    nonaka 			HWRITE1(hp, SDHC_DATA, *data);
 1.1    nonaka 			data += 1;
 1.1    nonaka 			datalen -= 1;
 1.1    nonaka 		}
 1.1    nonaka 	} else {
 1.1    nonaka 		while (datalen > 0) {
 1.1    nonaka 			HWRITE1(hp, SDHC_DATA, *data);
 1.1    nonaka 			data += 1;
 1.1    nonaka 			datalen -= 1;
 1.1    nonaka 		}
 1.1    nonaka 	}
 1.1    nonaka }
 1.1    nonaka
1.11      matt static void
1.11      matt esdhc_read_data_pio(struct sdhc_host *hp, uint8_t *data, u_int datalen)
1.11      matt {
1.11      matt 	uint16_t status = HREAD2(hp, SDHC_NINTR_STATUS);
1.12    nonaka 	uint32_t v;
1.12    nonaka
1.23      matt 	const size_t watermark = (HREAD4(hp, SDHC_WATERMARK_LEVEL) >> SDHC_WATERMARK_READ_SHIFT) & SDHC_WATERMARK_READ_MASK;
1.23      matt 	size_t count = 0;
1.23      matt
1.11      matt 	while (datalen > 3 && !ISSET(status, SDHC_TRANSFER_COMPLETE)) {
1.23      matt 		if (count == 0) {
1.23      matt 			/*
1.23      matt 			 * If we've drained "watermark" words, we need to wait
1.23      matt 			 * a little bit so the read FIFO can refill.
1.23      matt 			 */
1.23      matt 			sdmmc_delay(10);
1.23      matt 			count = watermark;
1.23      matt 		}
1.12    nonaka 		v = HREAD4(hp, SDHC_DATA);
1.11      matt 		v = le32toh(v);
1.11      matt 		*(uint32_t *)data = v;
1.11      matt 		data += 4;
1.11      matt 		datalen -= 4;
1.11      matt 		status = HREAD2(hp, SDHC_NINTR_STATUS);
1.23      matt 		count--;
1.11      matt 	}
1.11      matt 	if (datalen > 0 && !ISSET(status, SDHC_TRANSFER_COMPLETE)) {
1.23      matt 		if (count == 0) {
1.23      matt 			sdmmc_delay(10);
1.23      matt 		}
1.12    nonaka 		v = HREAD4(hp, SDHC_DATA);
1.11      matt 		v = le32toh(v);
1.11      matt 		do {
1.11      matt 			*data++ = v;
1.11      matt 			v >>= 8;
1.11      matt 		} while (--datalen > 0);
1.11      matt 	}
1.11      matt }
1.11      matt
1.11      matt static void
1.11      matt esdhc_write_data_pio(struct sdhc_host *hp, uint8_t *data, u_int datalen)
1.11      matt {
1.11      matt 	uint16_t status = HREAD2(hp, SDHC_NINTR_STATUS);
1.12    nonaka 	uint32_t v;
1.12    nonaka
1.23      matt 	const size_t watermark = (HREAD4(hp, SDHC_WATERMARK_LEVEL) >> SDHC_WATERMARK_WRITE_SHIFT) & SDHC_WATERMARK_WRITE_MASK;
1.23      matt 	size_t count = watermark;
1.23      matt
1.11      matt 	while (datalen > 3 && !ISSET(status, SDHC_TRANSFER_COMPLETE)) {
1.23      matt 		if (count == 0) {
1.23      matt 			sdmmc_delay(10);
1.23      matt 			count = watermark;
1.23      matt 		}
1.12    nonaka 		v = *(uint32_t *)data;
1.11      matt 		v = htole32(v);
1.11      matt 		HWRITE4(hp, SDHC_DATA, v);
1.11      matt 		data += 4;
1.11      matt 		datalen -= 4;
1.11      matt 		status = HREAD2(hp, SDHC_NINTR_STATUS);
1.23      matt 		count--;
1.11      matt 	}
1.11      matt 	if (datalen > 0 && !ISSET(status, SDHC_TRANSFER_COMPLETE)) {
1.23      matt 		if (count == 0) {
1.23      matt 			sdmmc_delay(10);
1.23      matt 		}
1.12    nonaka 		v = *(uint32_t *)data;
1.11      matt 		v = htole32(v);
1.11      matt 		HWRITE4(hp, SDHC_DATA, v);
1.11      matt 	}
1.11      matt }
1.11      matt
 1.1    nonaka /* Prepare for another command. */
 1.1    nonaka static int
 1.1    nonaka sdhc_soft_reset(struct sdhc_host *hp, int mask)
 1.1    nonaka {
 1.1    nonaka 	int timo;
 1.1    nonaka
 1.1    nonaka 	DPRINTF(1,("%s: software reset reg=%08x\n", HDEVNAME(hp), mask));
 1.1    nonaka
1.35  riastrad 	/* Request the reset.  */
 1.1    nonaka 	HWRITE1(hp, SDHC_SOFTWARE_RESET, mask);
1.35  riastrad
1.35  riastrad 	/*
1.35  riastrad 	 * If necessary, wait for the controller to set the bits to
1.35  riastrad 	 * acknowledge the reset.
1.35  riastrad 	 */
1.35  riastrad 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_WAIT_RESET) &&
1.35  riastrad 	    ISSET(mask, (SDHC_RESET_DAT | SDHC_RESET_CMD))) {
1.35  riastrad 		for (timo = 10000; timo > 0; timo--) {
1.35  riastrad 			if (ISSET(HREAD1(hp, SDHC_SOFTWARE_RESET), mask))
1.35  riastrad 				break;
1.35  riastrad 			/* Short delay because I worry we may miss it...  */
1.35  riastrad 			sdmmc_delay(1);
1.35  riastrad 		}
1.35  riastrad 		if (timo == 0)
1.35  riastrad 			return ETIMEDOUT;
1.35  riastrad 	}
1.35  riastrad
1.35  riastrad 	/*
1.35  riastrad 	 * Wait for the controller to clear the bits to indicate that
1.35  riastrad 	 * the reset has completed.
1.35  riastrad 	 */
 1.1    nonaka 	for (timo = 10; timo > 0; timo--) {
 1.1    nonaka 		if (!ISSET(HREAD1(hp, SDHC_SOFTWARE_RESET), mask))
 1.1    nonaka 			break;
 1.1    nonaka 		sdmmc_delay(10000);
 1.1    nonaka 	}
 1.1    nonaka 	if (timo == 0) {
 1.1    nonaka 		DPRINTF(1,("%s: timeout reg=%08x\n", HDEVNAME(hp),
 1.1    nonaka 		    HREAD1(hp, SDHC_SOFTWARE_RESET)));
 1.1    nonaka 		return ETIMEDOUT;
 1.1    nonaka 	}
 1.1    nonaka
1.11      matt 	if (ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.53    nonaka 		HSET4(hp, SDHC_DMA_CTL, SDHC_DMA_SNOOP);
1.11      matt 	}
1.11      matt
 1.1    nonaka 	return 0;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka static int
 1.1    nonaka sdhc_wait_intr(struct sdhc_host *hp, int mask, int timo)
 1.1    nonaka {
 1.1    nonaka 	int status;
 1.1    nonaka
1.65  jmcneill 	KASSERT(mutex_owned(&hp->intr_lock));
1.65  jmcneill
 1.1    nonaka 	mask |= SDHC_ERROR_INTERRUPT;
 1.1    nonaka
 1.1    nonaka 	status = hp->intr_status & mask;
 1.1    nonaka 	while (status == 0) {
1.65  jmcneill 		if (cv_timedwait(&hp->intr_cv, &hp->intr_lock, timo)
 1.1    nonaka 		    == EWOULDBLOCK) {
 1.1    nonaka 			status |= SDHC_ERROR_INTERRUPT;
 1.1    nonaka 			break;
 1.1    nonaka 		}
 1.1    nonaka 		status = hp->intr_status & mask;
 1.1    nonaka 	}
 1.1    nonaka 	hp->intr_status &= ~status;
 1.1    nonaka
 1.1    nonaka 	DPRINTF(2,("%s: intr status %#x error %#x\n", HDEVNAME(hp), status,
 1.1    nonaka 	    hp->intr_error_status));
1.47     skrll
 1.1    nonaka 	/* Command timeout has higher priority than command complete. */
1.11      matt 	if (ISSET(status, SDHC_ERROR_INTERRUPT) || hp->intr_error_status) {
 1.1    nonaka 		hp->intr_error_status = 0;
1.11      matt 		hp->intr_status &= ~SDHC_ERROR_INTERRUPT;
1.11      matt 		if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 		    (void)sdhc_soft_reset(hp, SDHC_RESET_DAT|SDHC_RESET_CMD);
1.11      matt 		}
 1.1    nonaka 		status = 0;
 1.1    nonaka 	}
 1.1    nonaka
 1.1    nonaka 	return status;
 1.1    nonaka }
 1.1    nonaka
 1.1    nonaka /*
 1.1    nonaka  * Established by attachment driver at interrupt priority IPL_SDMMC.
 1.1    nonaka  */
 1.1    nonaka int
 1.1    nonaka sdhc_intr(void *arg)
 1.1    nonaka {
 1.1    nonaka 	struct sdhc_softc *sc = (struct sdhc_softc *)arg;
 1.1    nonaka 	struct sdhc_host *hp;
 1.1    nonaka 	int done = 0;
 1.1    nonaka 	uint16_t status;
 1.1    nonaka 	uint16_t error;
 1.1    nonaka
 1.1    nonaka 	/* We got an interrupt, but we don't know from which slot. */
1.11      matt 	for (size_t host = 0; host < sc->sc_nhosts; host++) {
 1.1    nonaka 		hp = sc->sc_host[host];
 1.1    nonaka 		if (hp == NULL)
 1.1    nonaka 			continue;
 1.1    nonaka
1.65  jmcneill 		mutex_enter(&hp->intr_lock);
1.65  jmcneill
1.11      matt 		if (ISSET(sc->sc_flags, SDHC_FLAG_32BIT_ACCESS)) {
1.11      matt 			/* Find out which interrupts are pending. */
1.11      matt 			uint32_t xstatus = HREAD4(hp, SDHC_NINTR_STATUS);
1.11      matt 			status = xstatus;
1.11      matt 			error = xstatus >> 16;
1.22      matt 			if (error)
1.22      matt 				xstatus |= SDHC_ERROR_INTERRUPT;
1.22      matt 			else if (!ISSET(status, SDHC_NINTR_STATUS_MASK))
1.65  jmcneill 				goto next_port; /* no interrupt for us */
1.11      matt 			/* Acknowledge the interrupts we are about to handle. */
1.11      matt 			HWRITE4(hp, SDHC_NINTR_STATUS, xstatus);
1.11      matt 		} else {
1.11      matt 			/* Find out which interrupts are pending. */
1.11      matt 			error = 0;
1.11      matt 			status = HREAD2(hp, SDHC_NINTR_STATUS);
1.11      matt 			if (!ISSET(status, SDHC_NINTR_STATUS_MASK))
1.65  jmcneill 				goto next_port; /* no interrupt for us */
1.11      matt 			/* Acknowledge the interrupts we are about to handle. */
1.11      matt 			HWRITE2(hp, SDHC_NINTR_STATUS, status);
1.11      matt 			if (ISSET(status, SDHC_ERROR_INTERRUPT)) {
1.11      matt 				/* Acknowledge error interrupts. */
1.11      matt 				error = HREAD2(hp, SDHC_EINTR_STATUS);
1.11      matt 				HWRITE2(hp, SDHC_EINTR_STATUS, error);
1.11      matt 			}
1.11      matt 		}
1.47     skrll
1.11      matt 		DPRINTF(2,("%s: interrupt status=%x error=%x\n", HDEVNAME(hp),
1.11      matt 		    status, error));
 1.1    nonaka
 1.1    nonaka 		/* Claim this interrupt. */
 1.1    nonaka 		done = 1;
 1.1    nonaka
1.63  jmcneill 		if (ISSET(error, SDHC_ADMA_ERROR)) {
1.63  jmcneill 			uint8_t adma_err = HREAD1(hp, SDHC_ADMA_ERROR_STATUS);
1.63  jmcneill 			printf("%s: ADMA error, status %02x\n", HDEVNAME(hp),
1.63  jmcneill 			    adma_err);
1.63  jmcneill 		}
1.63  jmcneill
 1.1    nonaka 		/*
 1.1    nonaka 		 * Service error interrupts.
 1.1    nonaka 		 */
1.11      matt 		if (ISSET(error, SDHC_CMD_TIMEOUT_ERROR|
1.11      matt 		    SDHC_DATA_TIMEOUT_ERROR)) {
1.11      matt 			hp->intr_error_status |= error;
1.11      matt 			hp->intr_status |= status;
1.11      matt 			cv_broadcast(&hp->intr_cv);
 1.1    nonaka 		}
 1.1    nonaka
 1.1    nonaka 		/*
 1.1    nonaka 		 * Wake up the sdmmc event thread to scan for cards.
 1.1    nonaka 		 */
 1.9      matt 		if (ISSET(status, SDHC_CARD_REMOVAL|SDHC_CARD_INSERTION)) {
1.46  jakllsch 			if (hp->sdmmc != NULL) {
1.46  jakllsch 				sdmmc_needs_discover(hp->sdmmc);
1.46  jakllsch 			}
1.11      matt 			if (ISSET(sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 				HCLR4(hp, SDHC_NINTR_STATUS_EN,
1.11      matt 				    status & (SDHC_CARD_REMOVAL|SDHC_CARD_INSERTION));
1.11      matt 				HCLR4(hp, SDHC_NINTR_SIGNAL_EN,
1.11      matt 				    status & (SDHC_CARD_REMOVAL|SDHC_CARD_INSERTION));
1.11      matt 			}
 1.9      matt 		}
 1.1    nonaka
 1.1    nonaka 		/*
 1.1    nonaka 		 * Wake up the blocking process to service command
 1.1    nonaka 		 * related interrupt(s).
 1.1    nonaka 		 */
1.11      matt 		if (ISSET(status, SDHC_COMMAND_COMPLETE|
1.11      matt 		    SDHC_BUFFER_READ_READY|SDHC_BUFFER_WRITE_READY|
 1.1    nonaka 		    SDHC_TRANSFER_COMPLETE|SDHC_DMA_INTERRUPT)) {
 1.1    nonaka 			hp->intr_status |= status;
1.11      matt 			if (ISSET(sc->sc_flags, SDHC_FLAG_ENHANCED)) {
1.11      matt 				HCLR4(hp, SDHC_NINTR_SIGNAL_EN,
1.11      matt 				    status & (SDHC_BUFFER_READ_READY|SDHC_BUFFER_WRITE_READY));
1.11      matt 			}
 1.1    nonaka 			cv_broadcast(&hp->intr_cv);
 1.1    nonaka 		}
 1.1    nonaka
 1.1    nonaka 		/*
 1.1    nonaka 		 * Service SD card interrupts.
 1.1    nonaka 		 */
1.11      matt 		if (!ISSET(sc->sc_flags, SDHC_FLAG_ENHANCED)
1.11      matt 		    && ISSET(status, SDHC_CARD_INTERRUPT)) {
 1.1    nonaka 			DPRINTF(0,("%s: card interrupt\n", HDEVNAME(hp)));
 1.1    nonaka 			HCLR2(hp, SDHC_NINTR_STATUS_EN, SDHC_CARD_INTERRUPT);
 1.1    nonaka 			sdmmc_card_intr(hp->sdmmc);
 1.1    nonaka 		}
1.65  jmcneill next_port:
1.65  jmcneill 		mutex_exit(&hp->intr_lock);
 1.1    nonaka 	}
 1.1    nonaka
 1.1    nonaka 	return done;
 1.1    nonaka }
 1.1    nonaka
1.65  jmcneill kmutex_t *
1.65  jmcneill sdhc_host_lock(struct sdhc_host *hp)
1.65  jmcneill {
1.65  jmcneill 	return &hp->intr_lock;
1.65  jmcneill }
1.65  jmcneill
 1.1    nonaka #ifdef SDHC_DEBUG
 1.1    nonaka void
 1.1    nonaka sdhc_dump_regs(struct sdhc_host *hp)
 1.1    nonaka {
 1.1    nonaka
 1.1    nonaka 	printf("0x%02x PRESENT_STATE:    %x\n", SDHC_PRESENT_STATE,
 1.1    nonaka 	    HREAD4(hp, SDHC_PRESENT_STATE));
1.11      matt 	if (!ISSET(hp->sc->sc_flags, SDHC_FLAG_ENHANCED))
1.11      matt 		printf("0x%02x POWER_CTL:        %x\n", SDHC_POWER_CTL,
1.11      matt 		    HREAD1(hp, SDHC_POWER_CTL));
 1.1    nonaka 	printf("0x%02x NINTR_STATUS:     %x\n", SDHC_NINTR_STATUS,
 1.1    nonaka 	    HREAD2(hp, SDHC_NINTR_STATUS));
 1.1    nonaka 	printf("0x%02x EINTR_STATUS:     %x\n", SDHC_EINTR_STATUS,
 1.1    nonaka 	    HREAD2(hp, SDHC_EINTR_STATUS));
 1.1    nonaka 	printf("0x%02x NINTR_STATUS_EN:  %x\n", SDHC_NINTR_STATUS_EN,
 1.1    nonaka 	    HREAD2(hp, SDHC_NINTR_STATUS_EN));
 1.1    nonaka 	printf("0x%02x EINTR_STATUS_EN:  %x\n", SDHC_EINTR_STATUS_EN,
 1.1    nonaka 	    HREAD2(hp, SDHC_EINTR_STATUS_EN));
 1.1    nonaka 	printf("0x%02x NINTR_SIGNAL_EN:  %x\n", SDHC_NINTR_SIGNAL_EN,
 1.1    nonaka 	    HREAD2(hp, SDHC_NINTR_SIGNAL_EN));
 1.1    nonaka 	printf("0x%02x EINTR_SIGNAL_EN:  %x\n", SDHC_EINTR_SIGNAL_EN,
 1.1    nonaka 	    HREAD2(hp, SDHC_EINTR_SIGNAL_EN));
 1.1    nonaka 	printf("0x%02x CAPABILITIES:     %x\n", SDHC_CAPABILITIES,
 1.1    nonaka 	    HREAD4(hp, SDHC_CAPABILITIES));
 1.1    nonaka 	printf("0x%02x MAX_CAPABILITIES: %x\n", SDHC_MAX_CAPABILITIES,
 1.1    nonaka 	    HREAD4(hp, SDHC_MAX_CAPABILITIES));
 1.1    nonaka }
 1.1    nonaka #endif