ide-dma.c - drivers/ide/ide-dma.c - Linux source code 2.3.99pre9

/*
 *  linux/drivers/ide/ide-dma.c		Version 4.09	April 23, 1999
 *
 *  Copyright (c) 1999  Andre Hedrick
 *  May be copied or modified under the terms of the GNU General Public License
 */

/*
 *  Special Thanks to Mark for his Six years of work.
 *
 *  Copyright (c) 1995-1998  Mark Lord
 *  May be copied or modified under the terms of the GNU General Public License
 */

/*
 * This module provides support for the bus-master IDE DMA functions
 * of various PCI chipsets, including the Intel PIIX (i82371FB for
 * the 430 FX chipset), the PIIX3 (i82371SB for the 430 HX/VX and 
 * 440 chipsets), and the PIIX4 (i82371AB for the 430 TX chipset)
 * ("PIIX" stands for "PCI ISA IDE Xcellerator").
 *
 * Pretty much the same code works for other IDE PCI bus-mastering chipsets.
 *
 * DMA is supported for all IDE devices (disk drives, cdroms, tapes, floppies).
 *
 * By default, DMA support is prepared for use, but is currently enabled only
 * for drives which already have DMA enabled (UltraDMA or mode 2 multi/single),
 * or which are recognized as "good" (see table below).  Drives with only mode0
 * or mode1 (multi/single) DMA should also work with this chipset/driver
 * (eg. MC2112A) but are not enabled by default.
 *
 * Use "hdparm -i" to view modes supported by a given drive.
 *
 * The hdparm-3.5 (or later) utility can be used for manually enabling/disabling
 * DMA support, but must be (re-)compiled against this kernel version or later.
 *
 * To enable DMA, use "hdparm -d1 /dev/hd?" on a per-drive basis after booting.
 * If problems arise, ide.c will disable DMA operation after a few retries.
 * This error recovery mechanism works and has been extremely well exercised.
 *
 * IDE drives, depending on their vintage, may support several different modes
 * of DMA operation.  The boot-time modes are indicated with a "*" in
 * the "hdparm -i" listing, and can be changed with *knowledgeable* use of
 * the "hdparm -X" feature.  There is seldom a need to do this, as drives
 * normally power-up with their "best" PIO/DMA modes enabled.
 *
 * Testing has been done with a rather extensive number of drives,
 * with Quantum & Western Digital models generally outperforming the pack,
 * and Fujitsu & Conner (and some Seagate which are really Conner) drives
 * showing more lackluster throughput.
 *
 * Keep an eye on /var/adm/messages for "DMA disabled" messages.
 *
 * Some people have reported trouble with Intel Zappa motherboards.
 * This can be fixed by upgrading the AMI BIOS to version 1.00.04.BS0,
 * available from ftp://ftp.intel.com/pub/bios/10004bs0.exe
 * (thanks to Glen Morrell <glen@spin.Stanford.edu> for researching this).
 *
 * Thanks to "Christopher J. Reimer" <reimer@doe.carleton.ca> for
 * fixing the problem with the BIOS on some Acer motherboards.
 *
 * Thanks to "Benoit Poulot-Cazajous" <poulot@chorus.fr> for testing
 * "TX" chipset compatibility and for providing patches for the "TX" chipset.
 *
 * Thanks to Christian Brunner <chb@muc.de> for taking a good first crack
 * at generic DMA -- his patches were referred to when preparing this code.
 *
 * Most importantly, thanks to Robert Bringman <rob@mars.trion.com>
 * for supplying a Promise UDMA board & WD UDMA drive for this work!
 *
 * And, yes, Intel Zappa boards really *do* use both PIIX IDE ports.
 *
 * ACARD ATP850UF Chipset "Modified SCSI Class" with other names
 *       AEC6210 U/UF
 *       SIIG's UltraIDE Pro CN-2449
 * TTI   HPT343 Chipset "Modified SCSI Class" but reports as an
 *       unknown storage device.
 * NEW	 check_drive_lists(ide_drive_t *drive, int good_bad)
 */

#include <linux/config.h>
#include <linux/types.h>
#include <linux/kernel.h>
#include <linux/timer.h>
#include <linux/mm.h>
#include <linux/interrupt.h>
#include <linux/pci.h>
#include <linux/init.h>
#include <linux/ide.h>

#include <asm/io.h>
#include <asm/irq.h>

extern char *ide_dmafunc_verbose(ide_dma_action_t dmafunc);

#ifdef CONFIG_IDEDMA_NEW_DRIVE_LISTINGS

struct drive_list_entry {
	char * id_model;
	char * id_firmware;
};

struct drive_list_entry drive_whitelist [] = {

	{ "Micropolis 2112A"	,       "ALL"		},
	{ "CONNER CTMA 4000"	,       "ALL"		},
	{ "CONNER CTT8000-A"	,       "ALL"		},
	{ "ST34342A"		,	"ALL"		},
	{ 0			,	0		}
};

struct drive_list_entry drive_blacklist [] = {

	{ "WDC AC11000H"	,	"ALL"		},
	{ "WDC AC22100H"	,	"ALL"		},
	{ "WDC AC32500H"	,	"ALL"		},
	{ "WDC AC33100H"	,	"ALL"		},
	{ "WDC AC31600H"	,	"ALL"		},
	{ "WDC AC32100H"	,	"24.09P07"	},
	{ "WDC AC23200L"	,	"21.10N21"	},
	{ 0			,	0		}

};

int in_drive_list(struct hd_driveid *id, struct drive_list_entry * drive_table)
{
	for ( ; drive_table->id_model ; drive_table++)
		if ((!strcmp(drive_table->id_model, id->model)) &&
		    ((!strstr(drive_table->id_firmware, id->fw_rev)) ||
		     (!strcmp(drive_table->id_firmware, "ALL"))))
			return 1;
	return 0;
}

#else /* !CONFIG_IDEDMA_NEW_DRIVE_LISTINGS */

/*
 * good_dma_drives() lists the model names (from "hdparm -i")
 * of drives which do not support mode2 DMA but which are
 * known to work fine with this interface under Linux.
 */
const char *good_dma_drives[] = {"Micropolis 2112A",
				 "CONNER CTMA 4000",
				 "CONNER CTT8000-A",
				 "ST34342A",	/* for Sun Ultra */
				 NULL};

/*
 * bad_dma_drives() lists the model names (from "hdparm -i")
 * of drives which supposedly support (U)DMA but which are
 * known to corrupt data with this interface under Linux.
 *
 * This is an empirical list. Its generated from bug reports. That means
 * while it reflects actual problem distributions it doesn't answer whether
 * the drive or the controller, or cabling, or software, or some combination
 * thereof is the fault. If you don't happen to agree with the kernel's 
 * opinion of your drive - use hdparm to turn DMA on.
 */
const char *bad_dma_drives[] = {"WDC AC11000H",
				"WDC AC22100H",
				"WDC AC32100H",
				"WDC AC32500H",
				"WDC AC33100H",
				"WDC AC31600H",
 				NULL};

#endif /* CONFIG_IDEDMA_NEW_DRIVE_LISTINGS */

/*
 * Our Physical Region Descriptor (PRD) table should be large enough
 * to handle the biggest I/O request we are likely to see.  Since requests
 * can have no more than 256 sectors, and since the typical blocksize is
 * two or more sectors, we could get by with a limit of 128 entries here for
 * the usual worst case.  Most requests seem to include some contiguous blocks,
 * further reducing the number of table entries required.
 *
 * The driver reverts to PIO mode for individual requests that exceed
 * this limit (possible with 512 byte blocksizes, eg. MSDOS f/s), so handling
 * 100% of all crazy scenarios here is not necessary.
 *
 * As it turns out though, we must allocate a full 4KB page for this,
 * so the two PRD tables (ide0 & ide1) will each get half of that,
 * allowing each to have about 256 entries (8 bytes each) from this.
 */
#define PRD_BYTES	8
#define PRD_ENTRIES	(PAGE_SIZE / (2 * PRD_BYTES))

/*
 * dma_intr() is the handler for disk read/write DMA interrupts
 */
ide_startstop_t ide_dma_intr (ide_drive_t *drive)
{
	int i;
	byte stat, dma_stat;

	dma_stat = HWIF(drive)->dmaproc(ide_dma_end, drive);
	stat = GET_STAT();			/* get drive status */
	if (OK_STAT(stat,DRIVE_READY,drive->bad_wstat|DRQ_STAT)) {
		if (!dma_stat) {
			struct request *rq = HWGROUP(drive)->rq;
			rq = HWGROUP(drive)->rq;
			for (i = rq->nr_sectors; i > 0;) {
				i -= rq->current_nr_sectors;
				ide_end_request(1, HWGROUP(drive));
			}
			return ide_stopped;
		}
		printk("%s: dma_intr: bad DMA status\n", drive->name);
	}
	return ide_error(drive, "dma_intr", stat);
}

static int ide_build_sglist (ide_hwif_t *hwif, struct request *rq)
{
	struct buffer_head *bh;
	struct scatterlist *sg = hwif->sg_table;
	int nents = 0;

	if (rq->cmd == READ)
		hwif->sg_dma_direction = PCI_DMA_FROMDEVICE;
	else
		hwif->sg_dma_direction = PCI_DMA_TODEVICE;
	bh = rq->bh;
	do {
		unsigned char *virt_addr = bh->b_data;
		unsigned int size = bh->b_size;

		while ((bh = bh->b_reqnext) != NULL) {
			if ((virt_addr + size) != (unsigned char *) bh->b_data)
				break;
			size += bh->b_size;
		}
		memset(&sg[nents], 0, sizeof(*sg));
		sg[nents].address = virt_addr;
		sg[nents].length = size;
		nents++;
	} while (bh != NULL);

	return pci_map_sg(hwif->pci_dev, sg, nents, hwif->sg_dma_direction);
}

/*
 * ide_build_dmatable() prepares a dma request.
 * Returns 0 if all went okay, returns 1 otherwise.
 * May also be invoked from trm290.c
 */
int ide_build_dmatable (ide_drive_t *drive, ide_dma_action_t func)
{
	unsigned int *table = HWIF(drive)->dmatable_cpu;
#ifdef CONFIG_BLK_DEV_TRM290
	unsigned int is_trm290_chipset = (HWIF(drive)->chipset == ide_trm290);
#else
	const int is_trm290_chipset = 0;
#endif
	unsigned int count = 0;
	int i;
	struct scatterlist *sg;

	HWIF(drive)->sg_nents = i = ide_build_sglist(HWIF(drive), HWGROUP(drive)->rq);

	sg = HWIF(drive)->sg_table;
	while (i && sg_dma_len(sg)) {
		u32 cur_addr;
		u32 cur_len;

		cur_addr = sg_dma_address(sg);
		cur_len = sg_dma_len(sg);

		while (cur_len) {
			if (++count >= PRD_ENTRIES) {
				printk("%s: DMA table too small\n", drive->name);
				pci_unmap_sg(HWIF(drive)->pci_dev,
					     HWIF(drive)->sg_table,
					     HWIF(drive)->sg_nents,
					     HWIF(drive)->sg_dma_direction);
				return 0; /* revert to PIO for this request */
			} else {
				u32 xcount, bcount = 0x10000 - (cur_addr & 0xffff);

				if (bcount > cur_len)
					bcount = cur_len;
				*table++ = cpu_to_le32(cur_addr);
				xcount = bcount & 0xffff;
				if (is_trm290_chipset)
					xcount = ((xcount >> 2) - 1) << 16;
				*table++ = cpu_to_le32(xcount);
				cur_addr += bcount;
				cur_len -= bcount;
			}
		}

		sg++;
		i--;
	}

	if (!count)
		printk("%s: empty DMA table?\n", drive->name);
	else if (!is_trm290_chipset)
		*--table |= cpu_to_le32(0x80000000);

	return count;
}

/* Teardown mappings after DMA has completed.  */
void ide_destroy_dmatable (ide_drive_t *drive)
{
	struct pci_dev *dev = HWIF(drive)->pci_dev;
	struct scatterlist *sg = HWIF(drive)->sg_table;
	int nents = HWIF(drive)->sg_nents;

	pci_unmap_sg(dev, sg, nents, HWIF(drive)->sg_dma_direction);
}

/*
 *  For both Blacklisted and Whitelisted drives.
 *  This is setup to be called as an extern for future support
 *  to other special driver code.
 */
int check_drive_lists (ide_drive_t *drive, int good_bad)
{
	struct hd_driveid *id = drive->id;

#ifdef CONFIG_IDEDMA_NEW_DRIVE_LISTINGS
	if (good_bad) {
		return in_drive_list(id, drive_whitelist);
	} else {
		int blacklist = in_drive_list(id, drive_blacklist);
		if (blacklist)
			printk("%s: Disabling (U)DMA for %s\n", drive->name, id->model);
		return(blacklist);
	}
#else /* !CONFIG_IDEDMA_NEW_DRIVE_LISTINGS */
	const char **list;

	if (good_bad) {
		/* Consult the list of known "good" drives */
		list = good_dma_drives;
		while (*list) {
			if (!strcmp(*list++,id->model))
				return 1;
		}
	} else {
		/* Consult the list of known "bad" drives */
		list = bad_dma_drives;
		while (*list) {
			if (!strcmp(*list++,id->model)) {
				printk("%s: Disabling (U)DMA for %s\n",
					drive->name, id->model);
				return 1;
			}
		}
	}
#endif /* CONFIG_IDEDMA_NEW_DRIVE_LISTINGS */
	return 0;
}

int report_drive_dmaing (ide_drive_t *drive)
{
	struct hd_driveid *id = drive->id;

	if ((id->field_valid & 4) && (id->hw_config & 0x2000) &&
	    (HWIF(drive)->udma_four) &&
	    (id->dma_ultra & (id->dma_ultra >> 11) & 3)) {
		if ((id->dma_ultra >> 12) & 1) {
			printk(", UDMA(66)");	/* UDMA BIOS-enabled! */
		} else {
			printk(", UDMA(44)");	/* UDMA BIOS-enabled! */
		}
	} else if ((id->field_valid & 4) &&
		   (id->dma_ultra & (id->dma_ultra >> 8) & 7)) {
		if ((id->dma_ultra >> 10) & 1) {
			printk(", UDMA(33)");	/* UDMA BIOS-enabled! */
		} else if ((id->dma_ultra >> 9) & 1) {
			printk(", UDMA(25)");	/* UDMA BIOS-enabled! */
		} else {
			printk(", UDMA(16)");	/* UDMA BIOS-enabled! */
		}
	} else if (id->field_valid & 4) {
		printk(", (U)DMA");	/* Can be BIOS-enabled! */
	} else {
		printk(", DMA");
	}
	return 1;
}

static int config_drive_for_dma (ide_drive_t *drive)
{
	struct hd_driveid *id = drive->id;
	ide_hwif_t *hwif = HWIF(drive);

	if (id && (id->capability & 1) && hwif->autodma) {
		/* Consult the list of known "bad" drives */
		if (ide_dmaproc(ide_dma_bad_drive, drive))
			return hwif->dmaproc(ide_dma_off, drive);

		/* Enable DMA on any drive that has UltraDMA (mode 3/4) enabled */
		if ((id->field_valid & 4) && (hwif->udma_four) && (id->hw_config & 0x2000))
			if ((id->dma_ultra & (id->dma_ultra >> 11) & 3))
				return hwif->dmaproc(ide_dma_on, drive);
		/* Enable DMA on any drive that has UltraDMA (mode 0/1/2) enabled */
		if (id->field_valid & 4)	/* UltraDMA */
			if ((id->dma_ultra & (id->dma_ultra >> 8) & 7))
				return hwif->dmaproc(ide_dma_on, drive);
		/* Enable DMA on any drive that has mode2 DMA (multi or single) enabled */
		if (id->field_valid & 2)	/* regular DMA */
			if ((id->dma_mword & 0x404) == 0x404 || (id->dma_1word & 0x404) == 0x404)
				return hwif->dmaproc(ide_dma_on, drive);
		/* Consult the list of known "good" drives */
		if (ide_dmaproc(ide_dma_good_drive, drive))
			return hwif->dmaproc(ide_dma_on, drive);
	}
	return hwif->dmaproc(ide_dma_off_quietly, drive);
}

/*
 * ide_dmaproc() initiates/aborts DMA read/write operations on a drive.
 *
 * The caller is assumed to have selected the drive and programmed the drive's
 * sector address using CHS or LBA.  All that remains is to prepare for DMA
 * and then issue the actual read/write DMA/PIO command to the drive.
 *
 * For ATAPI devices, we just prepare for DMA and return. The caller should
 * then issue the packet command to the drive and call us again with
 * ide_dma_begin afterwards.
 *
 * Returns 0 if all went well.
 * Returns 1 if DMA read/write could not be started, in which case
 * the caller should revert to PIO for the current request.
 * May also be invoked from trm290.c
 */
int ide_dmaproc (ide_dma_action_t func, ide_drive_t *drive)
{
	ide_hwif_t *hwif = HWIF(drive);
	unsigned long dma_base = hwif->dma_base;
	byte unit = (drive->select.b.unit & 0x01);
	unsigned int count, reading = 0;
	byte dma_stat;

	switch (func) {
		case ide_dma_off:
			printk("%s: DMA disabled\n", drive->name);
		case ide_dma_off_quietly:
			outb(inb(dma_base+2) & ~(1<<(5+unit)), dma_base+2);
		case ide_dma_on:
			drive->using_dma = (func == ide_dma_on);
			if (drive->using_dma)
				outb(inb(dma_base+2)|(1<<(5+unit)), dma_base+2);
			return 0;
		case ide_dma_check:
			return config_drive_for_dma (drive);
		case ide_dma_read:
			reading = 1 << 3;
		case ide_dma_write:
			if (!(count = ide_build_dmatable(drive, func)))
				return 1;	/* try PIO instead of DMA */
			outl(hwif->dmatable_dma, dma_base + 4); /* PRD table */
			outb(reading, dma_base);			/* specify r/w */
			outb(inb(dma_base+2)|6, dma_base+2);		/* clear INTR & ERROR flags */
			drive->waiting_for_dma = 1;
			if (drive->media != ide_disk)
				return 0;
			ide_set_handler(drive, &ide_dma_intr, WAIT_CMD, NULL);	/* issue cmd to drive */
			OUT_BYTE(reading ? WIN_READDMA : WIN_WRITEDMA, IDE_COMMAND_REG);
		case ide_dma_begin:
			/* Note that this is done *after* the cmd has
			 * been issued to the drive, as per the BM-IDE spec.
			 * The Promise Ultra33 doesn't work correctly when
			 * we do this part before issuing the drive cmd.
			 */
			outb(inb(dma_base)|1, dma_base);		/* start DMA */
			return 0;
		case ide_dma_end: /* returns 1 on error, 0 otherwise */
			drive->waiting_for_dma = 0;
			outb(inb(dma_base)&~1, dma_base);	/* stop DMA */
			dma_stat = inb(dma_base+2);		/* get DMA status */
			outb(dma_stat|6, dma_base+2);	/* clear the INTR & ERROR bits */
			ide_destroy_dmatable(drive);	/* purge DMA mappings */
			return (dma_stat & 7) != 4;	/* verify good DMA status */
		case ide_dma_test_irq: /* returns 1 if dma irq issued, 0 otherwise */
			dma_stat = inb(dma_base+2);
			return (dma_stat & 4) == 4;	/* return 1 if INTR asserted */
		case ide_dma_bad_drive:
		case ide_dma_good_drive:
			return check_drive_lists(drive, (func == ide_dma_good_drive));
		case ide_dma_verbose:
			return report_drive_dmaing(drive);
		case ide_dma_retune:
		case ide_dma_lostirq:
		case ide_dma_timeout:
			printk("ide_dmaproc: chipset supported %s func only: %d\n", ide_dmafunc_verbose(func),  func);
			return 1;
		default:
			printk("ide_dmaproc: unsupported %s func: %d\n", ide_dmafunc_verbose(func), func);
			return 1;
	}
}

/*
 * Needed for allowing full modular support of ide-driver
 */
int ide_release_dma (ide_hwif_t *hwif)
{
	if (hwif->dmatable_cpu) {
		pci_free_consistent(hwif->pci_dev,
				    PRD_ENTRIES * PRD_BYTES,
				    hwif->dmatable_cpu,
				    hwif->dmatable_dma);
		hwif->dmatable_cpu = NULL;
	}
	if (hwif->sg_table) {
		kfree(hwif->sg_table);
		hwif->sg_table = NULL;
	}
	if ((hwif->dma_extra) && (hwif->channel == 0))
		release_region((hwif->dma_base + 16), hwif->dma_extra);
	release_region(hwif->dma_base, 8);
	return 1;
}

/*
 *	This can be called for a dynamically installed interface. Don't __init it
 */
 
void ide_setup_dma (ide_hwif_t *hwif, unsigned long dma_base, unsigned int num_ports)
{
	printk("    %s: BM-DMA at 0x%04lx-0x%04lx", hwif->name, dma_base, dma_base + num_ports - 1);
	if (check_region(dma_base, num_ports)) {
		printk(" -- ERROR, PORT ADDRESSES ALREADY IN USE\n");
		return;
	}
	request_region(dma_base, num_ports, hwif->name);
	hwif->dma_base = dma_base;
	hwif->dmatable_cpu = pci_alloc_consistent(hwif->pci_dev,
						  PRD_ENTRIES * PRD_BYTES,
						  &hwif->dmatable_dma);
	if (hwif->dmatable_cpu == NULL)
		goto dma_alloc_failure;

	hwif->sg_table = kmalloc(sizeof(struct scatterlist) * PRD_ENTRIES,
				 GFP_KERNEL);
	if (hwif->sg_table == NULL) {
		pci_free_consistent(hwif->pci_dev, PRD_ENTRIES * PRD_BYTES,
				    hwif->dmatable_cpu, hwif->dmatable_dma);
		goto dma_alloc_failure;
	}

	hwif->dmaproc = &ide_dmaproc;

	if (hwif->chipset != ide_trm290) {
		byte dma_stat = inb(dma_base+2);
		printk(", BIOS settings: %s:%s, %s:%s",
		       hwif->drives[0].name, (dma_stat & 0x20) ? "DMA" : "pio",
		       hwif->drives[1].name, (dma_stat & 0x40) ? "DMA" : "pio");
	}
	printk("\n");
	return;

dma_alloc_failure:
	printk(" -- ERROR, UNABLE TO ALLOCATE DMA TABLES\n");
}

/*
 * Fetch the DMA Bus-Master-I/O-Base-Address (BMIBA) from PCI space:
 */
unsigned long __init ide_get_or_set_dma_base (ide_hwif_t *hwif, int extra, const char *name)
{
	unsigned long	dma_base = 0;
	struct pci_dev	*dev = hwif->pci_dev;

	if (hwif->mate && hwif->mate->dma_base) {
		dma_base = hwif->mate->dma_base - (hwif->channel ? 0 : 8);
	} else {
		dma_base = dev->resource[4].start;
		if (!dma_base || dma_base == PCI_BASE_ADDRESS_IO_MASK) {
			printk("%s: dma_base is invalid (0x%04lx)\n", name, dma_base);
			dma_base = 0;
		}
	}
	if (dma_base) {
		if (extra) /* PDC20246, PDC20262, HPT343, & HPT366 */
			request_region(dma_base+16, extra, name);
		dma_base += hwif->channel ? 8 : 0;
		hwif->dma_extra = extra;

		switch(dev->device) {
			case PCI_DEVICE_ID_AL_M5219:
			case PCI_DEVICE_ID_AMD_VIPER_7409:
			case PCI_DEVICE_ID_CMD_643:
				outb(inb(dma_base+2) & 0x60, dma_base+2);
				if (inb(dma_base+2) & 0x80) {
					printk("%s: simplex device: DMA forced\n", name);
				}
				break;
			default:
				/*
				 * If the device claims "simplex" DMA,
				 * this means only one of the two interfaces
				 * can be trusted with DMA at any point in time.
				 * So we should enable DMA only on one of the
				 * two interfaces.
				 */
				if ((inb(dma_base+2) & 0x80)) {	/* simplex device? */
					if ((!hwif->drives[0].present && !hwif->drives[1].present) ||
					    (hwif->mate && hwif->mate->dma_base)) {
						printk("%s: simplex device:  DMA disabled\n", name);
						dma_base = 0;
					}
				}
		}
	}
	return dma_base;
}