arch/blackfin/kernel/bfin_dma.c - linux - Git at Google

 /*
  * bfin_dma.c - Blackfin DMA implementation
  *
  * Copyright 2004-2008 Analog Devices Inc.
  *
  * Licensed under the GPL-2 or later.
  */

 #include <linux/errno.h>
 #include <linux/interrupt.h>
 #include <linux/kernel.h>
 #include <linux/module.h>
 #include <linux/param.h>
 #include <linux/proc_fs.h>
 #include <linux/sched.h>
 #include <linux/seq_file.h>
 #include <linux/spinlock.h>

 #include <asm/blackfin.h>
 #include <asm/cacheflush.h>
 #include <asm/dma.h>
 #include <asm/uaccess.h>
 #include <asm/early_printk.h>

 /*
  * To make sure we work around 05000119 - we always check DMA_DONE bit,
  * never the DMA_RUN bit
  */

 struct dma_channel dma_ch[MAX_DMA_CHANNELS];
 EXPORT_SYMBOL(dma_ch);

 static int __init blackfin_dma_init(void)
 {
 	int i;

 	printk(KERN_INFO "Blackfin DMA Controller\n");


 #if ANOMALY_05000480
 	bfin_write_DMAC_TC_PER(0x0111);
 #endif

 	for (i = 0; i < MAX_DMA_CHANNELS; i++) {
 		atomic_set(&dma_ch[i].chan_status, 0);
 		dma_ch[i].regs = dma_io_base_addr[i];
 	}
 #if defined(CH_MEM_STREAM3_SRC) && defined(CONFIG_BF60x)
 	/* Mark MEMDMA Channel 3 as requested since we're using it internally */
 	request_dma(CH_MEM_STREAM3_DEST, "Blackfin dma_memcpy");
 	request_dma(CH_MEM_STREAM3_SRC, "Blackfin dma_memcpy");
 #else
 	/* Mark MEMDMA Channel 0 as requested since we're using it internally */
 	request_dma(CH_MEM_STREAM0_DEST, "Blackfin dma_memcpy");
 	request_dma(CH_MEM_STREAM0_SRC, "Blackfin dma_memcpy");
 #endif

 #if defined(CONFIG_DEB_DMA_URGENT)
 	bfin_write_EBIU_DDRQUE(bfin_read_EBIU_DDRQUE()
 			 | DEB1_URGENT | DEB2_URGENT | DEB3_URGENT);
 #endif

 	return 0;
 }
 arch_initcall(blackfin_dma_init);

 #ifdef CONFIG_PROC_FS
 static int proc_dma_show(struct seq_file *m, void *v)
 {
 	int i;

 	for (i = 0; i < MAX_DMA_CHANNELS; ++i)
 		if (dma_channel_active(i))
 			seq_printf(m, "%2d: %s\n", i, dma_ch[i].device_id);

 	return 0;
 }

 static int proc_dma_open(struct inode *inode, struct file *file)
 {
 	return single_open(file, proc_dma_show, NULL);
 }

 static const struct file_operations proc_dma_operations = {
 	.open		= proc_dma_open,
 	.read		= seq_read,
 	.llseek		= seq_lseek,
 	.release	= single_release,
 };

 static int __init proc_dma_init(void)
 {
 	proc_create("dma", 0, NULL, &proc_dma_operations);
 	return 0;
 }
 late_initcall(proc_dma_init);
 #endif

 static void set_dma_peripheral_map(unsigned int channel, const char *device_id)
 {
 #ifdef CONFIG_BF54x
 	unsigned int per_map;

 	switch (channel) {
 		case CH_UART2_RX: per_map = 0xC << 12; break;
 		case CH_UART2_TX: per_map = 0xD << 12; break;
 		case CH_UART3_RX: per_map = 0xE << 12; break;
 		case CH_UART3_TX: per_map = 0xF << 12; break;
 		default:          return;
 	}

 	if (strncmp(device_id, "BFIN_UART", 9) == 0)
 		dma_ch[channel].regs->peripheral_map = per_map;
 #endif
 }

 /**
  *	request_dma - request a DMA channel
  *
  * Request the specific DMA channel from the system if it's available.
  */
 int request_dma(unsigned int channel, const char *device_id)
 {
 	pr_debug("request_dma() : BEGIN\n");

 	if (device_id == NULL)
 		printk(KERN_WARNING "request_dma(%u): no device_id given\n", channel);

 #if defined(CONFIG_BF561) && ANOMALY_05000182
 	if (channel >= CH_IMEM_STREAM0_DEST && channel <= CH_IMEM_STREAM1_DEST) {
 		if (get_cclk() > 500000000) {
 			printk(KERN_WARNING
 			       "Request IMDMA failed due to ANOMALY 05000182\n");
 			return -EFAULT;
 		}
 	}
 #endif

 	if (atomic_cmpxchg(&dma_ch[channel].chan_status, 0, 1)) {
 		pr_debug("DMA CHANNEL IN USE\n");
 		return -EBUSY;
 	}

 	set_dma_peripheral_map(channel, device_id);
 	dma_ch[channel].device_id = device_id;
 	dma_ch[channel].irq = 0;

 	/* This is to be enabled by putting a restriction -
 	 * you have to request DMA, before doing any operations on
 	 * descriptor/channel
 	 */
 	pr_debug("request_dma() : END\n");
 	return 0;
 }
 EXPORT_SYMBOL(request_dma);

 int set_dma_callback(unsigned int channel, irq_handler_t callback, void *data)
 {
 	int ret;
 	unsigned int irq;

 	BUG_ON(channel >= MAX_DMA_CHANNELS || !callback ||
 			!atomic_read(&dma_ch[channel].chan_status));

 	irq = channel2irq(channel);
 	ret = request_irq(irq, callback, 0, dma_ch[channel].device_id, data);
 	if (ret)
 		return ret;

 	dma_ch[channel].irq = irq;
 	dma_ch[channel].data = data;

 	return 0;
 }
 EXPORT_SYMBOL(set_dma_callback);

 /**
  *	clear_dma_buffer - clear DMA fifos for specified channel
  *
  * Set the Buffer Clear bit in the Configuration register of specific DMA
  * channel. This will stop the descriptor based DMA operation.
  */
 static void clear_dma_buffer(unsigned int channel)
 {
 	dma_ch[channel].regs->cfg |= RESTART;
 	SSYNC();
 	dma_ch[channel].regs->cfg &= ~RESTART;
 }

 void free_dma(unsigned int channel)
 {
 	pr_debug("freedma() : BEGIN\n");
 	BUG_ON(channel >= MAX_DMA_CHANNELS ||
 			!atomic_read(&dma_ch[channel].chan_status));

 	/* Halt the DMA */
 	disable_dma(channel);
 	clear_dma_buffer(channel);

 	if (dma_ch[channel].irq)
 		free_irq(dma_ch[channel].irq, dma_ch[channel].data);

 	/* Clear the DMA Variable in the Channel */
 	atomic_set(&dma_ch[channel].chan_status, 0);

 	pr_debug("freedma() : END\n");
 }
 EXPORT_SYMBOL(free_dma);

 #ifdef CONFIG_PM
 # ifndef MAX_DMA_SUSPEND_CHANNELS
 #  define MAX_DMA_SUSPEND_CHANNELS MAX_DMA_CHANNELS
 # endif
 # ifndef CONFIG_BF60x
 int blackfin_dma_suspend(void)
 {
 	int i;

 	for (i = 0; i < MAX_DMA_CHANNELS; ++i) {
 		if (dma_ch[i].regs->cfg & DMAEN) {
 			printk(KERN_ERR "DMA Channel %d failed to suspend\n", i);
 			return -EBUSY;
 		}
 		if (i < MAX_DMA_SUSPEND_CHANNELS)
 			dma_ch[i].saved_peripheral_map = dma_ch[i].regs->peripheral_map;
 	}

 #if ANOMALY_05000480
 	bfin_write_DMAC_TC_PER(0x0);
 #endif
 	return 0;
 }

 void blackfin_dma_resume(void)
 {
 	int i;

 	for (i = 0; i < MAX_DMA_CHANNELS; ++i) {
 		dma_ch[i].regs->cfg = 0;
 		if (i < MAX_DMA_SUSPEND_CHANNELS)
 			dma_ch[i].regs->peripheral_map = dma_ch[i].saved_peripheral_map;
 	}
 #if ANOMALY_05000480
 	bfin_write_DMAC_TC_PER(0x0111);
 #endif
 }
 # else
 int blackfin_dma_suspend(void)
 {
 	return 0;
 }

 void blackfin_dma_resume(void)
 {
 }
 #endif
 #endif

 /**
  *	blackfin_dma_early_init - minimal DMA init
  *
  * Setup a few DMA registers so we can safely do DMA transfers early on in
  * the kernel booting process.  Really this just means using dma_memcpy().
  */
 void __init blackfin_dma_early_init(void)
 {
 	early_shadow_stamp();
 	bfin_write_MDMA_S0_CONFIG(0);
 	bfin_write_MDMA_S1_CONFIG(0);
 }

 void __init early_dma_memcpy(void *pdst, const void *psrc, size_t size)
 {
 	unsigned long dst = (unsigned long)pdst;
 	unsigned long src = (unsigned long)psrc;
 	struct dma_register *dst_ch, *src_ch;

 	early_shadow_stamp();

 	/* We assume that everything is 4 byte aligned, so include
 	 * a basic sanity check
 	 */
 	BUG_ON(dst % 4);
 	BUG_ON(src % 4);
 	BUG_ON(size % 4);

 	src_ch = 0;
 	/* Find an avalible memDMA channel */
 	while (1) {
 		if (src_ch == (struct dma_register *)MDMA_S0_NEXT_DESC_PTR) {
 			dst_ch = (struct dma_register *)MDMA_D1_NEXT_DESC_PTR;
 			src_ch = (struct dma_register *)MDMA_S1_NEXT_DESC_PTR;
 		} else {
 			dst_ch = (struct dma_register *)MDMA_D0_NEXT_DESC_PTR;
 			src_ch = (struct dma_register *)MDMA_S0_NEXT_DESC_PTR;
 		}

 		if (!DMA_MMR_READ(&src_ch->cfg))
 			break;
 		else if (DMA_MMR_READ(&dst_ch->irq_status) & DMA_DONE) {
 			DMA_MMR_WRITE(&src_ch->cfg, 0);
 			break;
 		}
 	}

 	/* Force a sync in case a previous config reset on this channel
 	 * occurred.  This is needed so subsequent writes to DMA registers
 	 * are not spuriously lost/corrupted.
 	 */
 	__builtin_bfin_ssync();

 	/* Destination */
 	bfin_write32(&dst_ch->start_addr, dst);
 	DMA_MMR_WRITE(&dst_ch->x_count, size >> 2);
 	DMA_MMR_WRITE(&dst_ch->x_modify, 1 << 2);
 	DMA_MMR_WRITE(&dst_ch->irq_status, DMA_DONE | DMA_ERR);

 	/* Source */
 	bfin_write32(&src_ch->start_addr, src);
 	DMA_MMR_WRITE(&src_ch->x_count, size >> 2);
 	DMA_MMR_WRITE(&src_ch->x_modify, 1 << 2);
 	DMA_MMR_WRITE(&src_ch->irq_status, DMA_DONE | DMA_ERR);

 	/* Enable */
 	DMA_MMR_WRITE(&src_ch->cfg, DMAEN | WDSIZE_32);
 	DMA_MMR_WRITE(&dst_ch->cfg, WNR | DI_EN_X | DMAEN | WDSIZE_32);

 	/* Since we are atomic now, don't use the workaround ssync */
 	__builtin_bfin_ssync();

 #ifdef CONFIG_BF60x
 	/* Work around a possible MDMA anomaly. Running 2 MDMA channels to
 	 * transfer DDR data to L1 SRAM may corrupt data.
 	 * Should be reverted after this issue is root caused.
 	 */
 	while (!(DMA_MMR_READ(&dst_ch->irq_status) & DMA_DONE))
 		continue;
 #endif
 }

 void __init early_dma_memcpy_done(void)
 {
 	early_shadow_stamp();

 	while ((bfin_read_MDMA_S0_CONFIG() && !(bfin_read_MDMA_D0_IRQ_STATUS() & DMA_DONE)) ||
 	       (bfin_read_MDMA_S1_CONFIG() && !(bfin_read_MDMA_D1_IRQ_STATUS() & DMA_DONE)))
 		continue;

 	bfin_write_MDMA_D0_IRQ_STATUS(DMA_DONE | DMA_ERR);
 	bfin_write_MDMA_D1_IRQ_STATUS(DMA_DONE | DMA_ERR);
 	/*
 	 * Now that DMA is done, we would normally flush cache, but
 	 * i/d cache isn't running this early, so we don't bother,
 	 * and just clear out the DMA channel for next time
 	 */
 	bfin_write_MDMA_S0_CONFIG(0);
 	bfin_write_MDMA_S1_CONFIG(0);
 	bfin_write_MDMA_D0_CONFIG(0);
 	bfin_write_MDMA_D1_CONFIG(0);

 	__builtin_bfin_ssync();
 }

 #if defined(CH_MEM_STREAM3_SRC) && defined(CONFIG_BF60x)
 #define bfin_read_MDMA_S_CONFIG bfin_read_MDMA_S3_CONFIG
 #define bfin_write_MDMA_S_CONFIG bfin_write_MDMA_S3_CONFIG
 #define bfin_write_MDMA_S_START_ADDR bfin_write_MDMA_S3_START_ADDR
 #define bfin_write_MDMA_S_IRQ_STATUS bfin_write_MDMA_S3_IRQ_STATUS
 #define bfin_write_MDMA_S_X_COUNT bfin_write_MDMA_S3_X_COUNT
 #define bfin_write_MDMA_S_X_MODIFY bfin_write_MDMA_S3_X_MODIFY
 #define bfin_write_MDMA_S_Y_COUNT bfin_write_MDMA_S3_Y_COUNT
 #define bfin_write_MDMA_S_Y_MODIFY bfin_write_MDMA_S3_Y_MODIFY
 #define bfin_write_MDMA_D_CONFIG bfin_write_MDMA_D3_CONFIG
 #define bfin_write_MDMA_D_START_ADDR bfin_write_MDMA_D3_START_ADDR
 #define bfin_read_MDMA_D_IRQ_STATUS bfin_read_MDMA_D3_IRQ_STATUS
 #define bfin_write_MDMA_D_IRQ_STATUS bfin_write_MDMA_D3_IRQ_STATUS
 #define bfin_write_MDMA_D_X_COUNT bfin_write_MDMA_D3_X_COUNT
 #define bfin_write_MDMA_D_X_MODIFY bfin_write_MDMA_D3_X_MODIFY
 #define bfin_write_MDMA_D_Y_COUNT bfin_write_MDMA_D3_Y_COUNT
 #define bfin_write_MDMA_D_Y_MODIFY bfin_write_MDMA_D3_Y_MODIFY
 #else
 #define bfin_read_MDMA_S_CONFIG bfin_read_MDMA_S0_CONFIG
 #define bfin_write_MDMA_S_CONFIG bfin_write_MDMA_S0_CONFIG
 #define bfin_write_MDMA_S_START_ADDR bfin_write_MDMA_S0_START_ADDR
 #define bfin_write_MDMA_S_IRQ_STATUS bfin_write_MDMA_S0_IRQ_STATUS
 #define bfin_write_MDMA_S_X_COUNT bfin_write_MDMA_S0_X_COUNT
 #define bfin_write_MDMA_S_X_MODIFY bfin_write_MDMA_S0_X_MODIFY
 #define bfin_write_MDMA_S_Y_COUNT bfin_write_MDMA_S0_Y_COUNT
 #define bfin_write_MDMA_S_Y_MODIFY bfin_write_MDMA_S0_Y_MODIFY
 #define bfin_write_MDMA_D_CONFIG bfin_write_MDMA_D0_CONFIG
 #define bfin_write_MDMA_D_START_ADDR bfin_write_MDMA_D0_START_ADDR
 #define bfin_read_MDMA_D_IRQ_STATUS bfin_read_MDMA_D0_IRQ_STATUS
 #define bfin_write_MDMA_D_IRQ_STATUS bfin_write_MDMA_D0_IRQ_STATUS
 #define bfin_write_MDMA_D_X_COUNT bfin_write_MDMA_D0_X_COUNT
 #define bfin_write_MDMA_D_X_MODIFY bfin_write_MDMA_D0_X_MODIFY
 #define bfin_write_MDMA_D_Y_COUNT bfin_write_MDMA_D0_Y_COUNT
 #define bfin_write_MDMA_D_Y_MODIFY bfin_write_MDMA_D0_Y_MODIFY
 #endif

 /**
  *	__dma_memcpy - program the MDMA registers
  *
  * Actually program MDMA0 and wait for the transfer to finish.  Disable IRQs
  * while programming registers so that everything is fully configured.  Wait
  * for DMA to finish with IRQs enabled.  If interrupted, the initial DMA_DONE
  * check will make sure we don't clobber any existing transfer.
  */
 static void __dma_memcpy(u32 daddr, s16 dmod, u32 saddr, s16 smod, size_t cnt, u32 conf)
 {
 	static DEFINE_SPINLOCK(mdma_lock);
 	unsigned long flags;

 	spin_lock_irqsave(&mdma_lock, flags);

 	/* Force a sync in case a previous config reset on this channel
 	 * occurred.  This is needed so subsequent writes to DMA registers
 	 * are not spuriously lost/corrupted.  Do it under irq lock and
 	 * without the anomaly version (because we are atomic already).
 	 */
 	__builtin_bfin_ssync();

 	if (bfin_read_MDMA_S_CONFIG())
 		while (!(bfin_read_MDMA_D_IRQ_STATUS() & DMA_DONE))
 			continue;

 	if (conf & DMA2D) {
 		/* For larger bit sizes, we've already divided down cnt so it
 		 * is no longer a multiple of 64k.  So we have to break down
 		 * the limit here so it is a multiple of the incoming size.
 		 * There is no limitation here in terms of total size other
 		 * than the hardware though as the bits lost in the shift are
 		 * made up by MODIFY (== we can hit the whole address space).
 		 * X: (2^(16 - 0)) * 1 == (2^(16 - 1)) * 2 == (2^(16 - 2)) * 4
 		 */
 		u32 shift = abs(dmod) >> 1;
 		size_t ycnt = cnt >> (16 - shift);
 		cnt = 1 << (16 - shift);
 		bfin_write_MDMA_D_Y_COUNT(ycnt);
 		bfin_write_MDMA_S_Y_COUNT(ycnt);
 		bfin_write_MDMA_D_Y_MODIFY(dmod);
 		bfin_write_MDMA_S_Y_MODIFY(smod);
 	}

 	bfin_write_MDMA_D_START_ADDR(daddr);
 	bfin_write_MDMA_D_X_COUNT(cnt);
 	bfin_write_MDMA_D_X_MODIFY(dmod);
 	bfin_write_MDMA_D_IRQ_STATUS(DMA_DONE | DMA_ERR);

 	bfin_write_MDMA_S_START_ADDR(saddr);
 	bfin_write_MDMA_S_X_COUNT(cnt);
 	bfin_write_MDMA_S_X_MODIFY(smod);
 	bfin_write_MDMA_S_IRQ_STATUS(DMA_DONE | DMA_ERR);

 	bfin_write_MDMA_S_CONFIG(DMAEN | conf);
 	if (conf & DMA2D)
 		bfin_write_MDMA_D_CONFIG(WNR | DI_EN_Y | DMAEN | conf);
 	else
 		bfin_write_MDMA_D_CONFIG(WNR | DI_EN_X | DMAEN | conf);

 	spin_unlock_irqrestore(&mdma_lock, flags);

 	SSYNC();

 	while (!(bfin_read_MDMA_D_IRQ_STATUS() & DMA_DONE))
 		if (bfin_read_MDMA_S_CONFIG())
 			continue;
 		else
 			return;

 	bfin_write_MDMA_D_IRQ_STATUS(DMA_DONE | DMA_ERR);

 	bfin_write_MDMA_S_CONFIG(0);
 	bfin_write_MDMA_D_CONFIG(0);
 }

 /**
  *	_dma_memcpy - translate C memcpy settings into MDMA settings
  *
  * Handle all the high level steps before we touch the MDMA registers.  So
  * handle direction, tweaking of sizes, and formatting of addresses.
  */
 static void *_dma_memcpy(void *pdst, const void *psrc, size_t size)
 {
 	u32 conf, shift;
 	s16 mod;
 	unsigned long dst = (unsigned long)pdst;
 	unsigned long src = (unsigned long)psrc;

 	if (size == 0)
 		return NULL;

 	if (dst % 4 == 0 && src % 4 == 0 && size % 4 == 0) {
 		conf = WDSIZE_32;
 		shift = 2;
 	} else if (dst % 2 == 0 && src % 2 == 0 && size % 2 == 0) {
 		conf = WDSIZE_16;
 		shift = 1;
 	} else {
 		conf = WDSIZE_8;
 		shift = 0;
 	}

 	/* If the two memory regions have a chance of overlapping, make
 	 * sure the memcpy still works as expected.  Do this by having the
 	 * copy run backwards instead.
 	 */
 	mod = 1 << shift;
 	if (src < dst) {
 		mod *= -1;
 		dst += size + mod;
 		src += size + mod;
 	}
 	size >>= shift;

 #ifndef DMA_MMR_SIZE_32
 	if (size > 0x10000)
 		conf |= DMA2D;
 #endif

 	__dma_memcpy(dst, mod, src, mod, size, conf);

 	return pdst;
 }

 /**
  *	dma_memcpy - DMA memcpy under mutex lock
  *
  * Do not check arguments before starting the DMA memcpy.  Break the transfer
  * up into two pieces.  The first transfer is in multiples of 64k and the
  * second transfer is the piece smaller than 64k.
  */
 void *dma_memcpy(void *pdst, const void *psrc, size_t size)
 {
 	unsigned long dst = (unsigned long)pdst;
 	unsigned long src = (unsigned long)psrc;

 	if (bfin_addr_dcacheable(src))
 		blackfin_dcache_flush_range(src, src + size);

 	if (bfin_addr_dcacheable(dst))
 		blackfin_dcache_invalidate_range(dst, dst + size);

 	return dma_memcpy_nocache(pdst, psrc, size);
 }
 EXPORT_SYMBOL(dma_memcpy);

 /**
  *	dma_memcpy_nocache - DMA memcpy under mutex lock
  *	- No cache flush/invalidate
  *
  * Do not check arguments before starting the DMA memcpy.  Break the transfer
  * up into two pieces.  The first transfer is in multiples of 64k and the
  * second transfer is the piece smaller than 64k.
  */
 void *dma_memcpy_nocache(void *pdst, const void *psrc, size_t size)
 {
 #ifdef DMA_MMR_SIZE_32
 	_dma_memcpy(pdst, psrc, size);
 #else
 	size_t bulk, rest;

 	bulk = size & ~0xffff;
 	rest = size - bulk;
 	if (bulk)
 		_dma_memcpy(pdst, psrc, bulk);
 	_dma_memcpy(pdst + bulk, psrc + bulk, rest);
 #endif
 	return pdst;
 }
 EXPORT_SYMBOL(dma_memcpy_nocache);

 /**
  *	safe_dma_memcpy - DMA memcpy w/argument checking
  *
  * Verify arguments are safe before heading to dma_memcpy().
  */
 void *safe_dma_memcpy(void *dst, const void *src, size_t size)
 {
 	if (!access_ok(VERIFY_WRITE, dst, size))
 		return NULL;
 	if (!access_ok(VERIFY_READ, src, size))
 		return NULL;
 	return dma_memcpy(dst, src, size);
 }
 EXPORT_SYMBOL(safe_dma_memcpy);

 static void _dma_out(unsigned long addr, unsigned long buf, unsigned DMA_MMR_SIZE_TYPE len,
                      u16 size, u16 dma_size)
 {
 	blackfin_dcache_flush_range(buf, buf + len * size);
 	__dma_memcpy(addr, 0, buf, size, len, dma_size);
 }

 static void _dma_in(unsigned long addr, unsigned long buf, unsigned DMA_MMR_SIZE_TYPE len,
                     u16 size, u16 dma_size)
 {
 	blackfin_dcache_invalidate_range(buf, buf + len * size);
 	__dma_memcpy(buf, size, addr, 0, len, dma_size);
 }

 #define MAKE_DMA_IO(io, bwl, isize, dmasize, cnst) \
 void dma_##io##s##bwl(unsigned long addr, cnst void *buf, unsigned DMA_MMR_SIZE_TYPE len) \
 { \
 	_dma_##io(addr, (unsigned long)buf, len, isize, WDSIZE_##dmasize); \
 } \
 EXPORT_SYMBOL(dma_##io##s##bwl)
 MAKE_DMA_IO(out, b, 1,  8, const);
 MAKE_DMA_IO(in,  b, 1,  8, );
 MAKE_DMA_IO(out, w, 2, 16, const);
 MAKE_DMA_IO(in,  w, 2, 16, );
 MAKE_DMA_IO(out, l, 4, 32, const);
 MAKE_DMA_IO(in,  l, 4, 32, );
	/*
	* bfin_dma.c - Blackfin DMA implementation
	*
	* Copyright 2004-2008 Analog Devices Inc.
	*
	* Licensed under the GPL-2 or later.
	*/

	#include <linux/errno.h>
	#include <linux/interrupt.h>
	#include <linux/kernel.h>
	#include <linux/module.h>
	#include <linux/param.h>
	#include <linux/proc_fs.h>
	#include <linux/sched.h>
	#include <linux/seq_file.h>
	#include <linux/spinlock.h>

	#include <asm/blackfin.h>
	#include <asm/cacheflush.h>
	#include <asm/dma.h>
	#include <asm/uaccess.h>
	#include <asm/early_printk.h>

	/*
	* To make sure we work around 05000119 - we always check DMA_DONE bit,
	* never the DMA_RUN bit
	*/

	struct dma_channel dma_ch[MAX_DMA_CHANNELS];
	EXPORT_SYMBOL(dma_ch);

	static int __init blackfin_dma_init(void)
	{
	int i;

	printk(KERN_INFO "Blackfin DMA Controller\n");


	#if ANOMALY_05000480
	bfin_write_DMAC_TC_PER(0x0111);
	#endif

	for (i = 0; i < MAX_DMA_CHANNELS; i++) {
	atomic_set(&dma_ch[i].chan_status, 0);
	dma_ch[i].regs = dma_io_base_addr[i];
	}
	#if defined(CH_MEM_STREAM3_SRC) && defined(CONFIG_BF60x)
	/* Mark MEMDMA Channel 3 as requested since we're using it internally */
	request_dma(CH_MEM_STREAM3_DEST, "Blackfin dma_memcpy");
	request_dma(CH_MEM_STREAM3_SRC, "Blackfin dma_memcpy");
	#else
	/* Mark MEMDMA Channel 0 as requested since we're using it internally */
	request_dma(CH_MEM_STREAM0_DEST, "Blackfin dma_memcpy");
	request_dma(CH_MEM_STREAM0_SRC, "Blackfin dma_memcpy");
	#endif

	#if defined(CONFIG_DEB_DMA_URGENT)
	bfin_write_EBIU_DDRQUE(bfin_read_EBIU_DDRQUE()
	\| DEB1_URGENT \| DEB2_URGENT \| DEB3_URGENT);
	#endif

	return 0;
	}
	arch_initcall(blackfin_dma_init);

	#ifdef CONFIG_PROC_FS
	static int proc_dma_show(struct seq_file m, void v)
	{
	int i;

	for (i = 0; i < MAX_DMA_CHANNELS; ++i)
	if (dma_channel_active(i))
	seq_printf(m, "%2d: %s\n", i, dma_ch[i].device_id);

	return 0;
	}

	static int proc_dma_open(struct inode inode, struct file file)
	{
	return single_open(file, proc_dma_show, NULL);
	}

	static const struct file_operations proc_dma_operations = {
	.open = proc_dma_open,
	.read = seq_read,
	.llseek = seq_lseek,
	.release = single_release,
	};

	static int __init proc_dma_init(void)
	{
	proc_create("dma", 0, NULL, &proc_dma_operations);
	return 0;
	}
	late_initcall(proc_dma_init);
	#endif

	static void set_dma_peripheral_map(unsigned int channel, const char *device_id)
	{
	#ifdef CONFIG_BF54x
	unsigned int per_map;

	switch (channel) {
	case CH_UART2_RX: per_map = 0xC << 12; break;
	case CH_UART2_TX: per_map = 0xD << 12; break;
	case CH_UART3_RX: per_map = 0xE << 12; break;
	case CH_UART3_TX: per_map = 0xF << 12; break;
	default: return;
	}

	if (strncmp(device_id, "BFIN_UART", 9) == 0)
	dma_ch[channel].regs->peripheral_map = per_map;
	#endif
	}

	/**
	* request_dma - request a DMA channel
	*
	* Request the specific DMA channel from the system if it's available.
	*/
	int request_dma(unsigned int channel, const char *device_id)
	{
	pr_debug("request_dma() : BEGIN\n");

	if (device_id == NULL)
	printk(KERN_WARNING "request_dma(%u): no device_id given\n", channel);

	#if defined(CONFIG_BF561) && ANOMALY_05000182
	if (channel >= CH_IMEM_STREAM0_DEST && channel <= CH_IMEM_STREAM1_DEST) {
	if (get_cclk() > 500000000) {
	printk(KERN_WARNING
	"Request IMDMA failed due to ANOMALY 05000182\n");
	return -EFAULT;
	}
	}
	#endif

	if (atomic_cmpxchg(&dma_ch[channel].chan_status, 0, 1)) {
	pr_debug("DMA CHANNEL IN USE\n");
	return -EBUSY;
	}

	set_dma_peripheral_map(channel, device_id);
	dma_ch[channel].device_id = device_id;
	dma_ch[channel].irq = 0;

	/* This is to be enabled by putting a restriction -
	* you have to request DMA, before doing any operations on
	* descriptor/channel
	*/
	pr_debug("request_dma() : END\n");
	return 0;
	}
	EXPORT_SYMBOL(request_dma);

	int set_dma_callback(unsigned int channel, irq_handler_t callback, void *data)
	{
	int ret;
	unsigned int irq;

	BUG_ON(channel >= MAX_DMA_CHANNELS \|\| !callback \|\|
	!atomic_read(&dma_ch[channel].chan_status));

	irq = channel2irq(channel);
	ret = request_irq(irq, callback, 0, dma_ch[channel].device_id, data);
	if (ret)
	return ret;

	dma_ch[channel].irq = irq;
	dma_ch[channel].data = data;

	return 0;
	}
	EXPORT_SYMBOL(set_dma_callback);

	/**
	* clear_dma_buffer - clear DMA fifos for specified channel
	*
	* Set the Buffer Clear bit in the Configuration register of specific DMA
	* channel. This will stop the descriptor based DMA operation.
	*/
	static void clear_dma_buffer(unsigned int channel)
	{
	dma_ch[channel].regs->cfg \|= RESTART;
	SSYNC();
	dma_ch[channel].regs->cfg &= ~RESTART;
	}

	void free_dma(unsigned int channel)
	{
	pr_debug("freedma() : BEGIN\n");
	BUG_ON(channel >= MAX_DMA_CHANNELS \|\|
	!atomic_read(&dma_ch[channel].chan_status));

	/* Halt the DMA */
	disable_dma(channel);
	clear_dma_buffer(channel);

	if (dma_ch[channel].irq)
	free_irq(dma_ch[channel].irq, dma_ch[channel].data);

	/* Clear the DMA Variable in the Channel */
	atomic_set(&dma_ch[channel].chan_status, 0);

	pr_debug("freedma() : END\n");
	}
	EXPORT_SYMBOL(free_dma);

	#ifdef CONFIG_PM
	# ifndef MAX_DMA_SUSPEND_CHANNELS
	# define MAX_DMA_SUSPEND_CHANNELS MAX_DMA_CHANNELS
	# endif
	# ifndef CONFIG_BF60x
	int blackfin_dma_suspend(void)
	{
	int i;

	for (i = 0; i < MAX_DMA_CHANNELS; ++i) {
	if (dma_ch[i].regs->cfg & DMAEN) {
	printk(KERN_ERR "DMA Channel %d failed to suspend\n", i);
	return -EBUSY;
	}
	if (i < MAX_DMA_SUSPEND_CHANNELS)
	dma_ch[i].saved_peripheral_map = dma_ch[i].regs->peripheral_map;
	}

	#if ANOMALY_05000480
	bfin_write_DMAC_TC_PER(0x0);
	#endif
	return 0;
	}

	void blackfin_dma_resume(void)
	{
	int i;

	for (i = 0; i < MAX_DMA_CHANNELS; ++i) {
	dma_ch[i].regs->cfg = 0;
	if (i < MAX_DMA_SUSPEND_CHANNELS)
	dma_ch[i].regs->peripheral_map = dma_ch[i].saved_peripheral_map;
	}
	#if ANOMALY_05000480
	bfin_write_DMAC_TC_PER(0x0111);
	#endif
	}
	# else
	int blackfin_dma_suspend(void)
	{
	return 0;
	}

	void blackfin_dma_resume(void)
	{
	}
	#endif
	#endif

	/**
	* blackfin_dma_early_init - minimal DMA init
	*
	* Setup a few DMA registers so we can safely do DMA transfers early on in
	* the kernel booting process. Really this just means using dma_memcpy().
	*/
	void __init blackfin_dma_early_init(void)
	{
	early_shadow_stamp();
	bfin_write_MDMA_S0_CONFIG(0);
	bfin_write_MDMA_S1_CONFIG(0);
	}

	void __init early_dma_memcpy(void pdst, const void psrc, size_t size)
	{
	unsigned long dst = (unsigned long)pdst;
	unsigned long src = (unsigned long)psrc;
	struct dma_register dst_ch, src_ch;

	early_shadow_stamp();

	/* We assume that everything is 4 byte aligned, so include
	* a basic sanity check
	*/
	BUG_ON(dst % 4);
	BUG_ON(src % 4);
	BUG_ON(size % 4);

	src_ch = 0;
	/* Find an avalible memDMA channel */
	while (1) {
	if (src_ch == (struct dma_register *)MDMA_S0_NEXT_DESC_PTR) {
	dst_ch = (struct dma_register *)MDMA_D1_NEXT_DESC_PTR;
	src_ch = (struct dma_register *)MDMA_S1_NEXT_DESC_PTR;
	} else {
	dst_ch = (struct dma_register *)MDMA_D0_NEXT_DESC_PTR;
	src_ch = (struct dma_register *)MDMA_S0_NEXT_DESC_PTR;
	}

	if (!DMA_MMR_READ(&src_ch->cfg))
	break;
	else if (DMA_MMR_READ(&dst_ch->irq_status) & DMA_DONE) {
	DMA_MMR_WRITE(&src_ch->cfg, 0);
	break;
	}
	}

	/* Force a sync in case a previous config reset on this channel
	* occurred. This is needed so subsequent writes to DMA registers
	* are not spuriously lost/corrupted.
	*/
	__builtin_bfin_ssync();

	/* Destination */
	bfin_write32(&dst_ch->start_addr, dst);
	DMA_MMR_WRITE(&dst_ch->x_count, size >> 2);
	DMA_MMR_WRITE(&dst_ch->x_modify, 1 << 2);
	DMA_MMR_WRITE(&dst_ch->irq_status, DMA_DONE \| DMA_ERR);

	/* Source */
	bfin_write32(&src_ch->start_addr, src);
	DMA_MMR_WRITE(&src_ch->x_count, size >> 2);
	DMA_MMR_WRITE(&src_ch->x_modify, 1 << 2);
	DMA_MMR_WRITE(&src_ch->irq_status, DMA_DONE \| DMA_ERR);

	/* Enable */
	DMA_MMR_WRITE(&src_ch->cfg, DMAEN \| WDSIZE_32);
	DMA_MMR_WRITE(&dst_ch->cfg, WNR \| DI_EN_X \| DMAEN \| WDSIZE_32);

	/* Since we are atomic now, don't use the workaround ssync */
	__builtin_bfin_ssync();

	#ifdef CONFIG_BF60x
	/* Work around a possible MDMA anomaly. Running 2 MDMA channels to
	* transfer DDR data to L1 SRAM may corrupt data.
	* Should be reverted after this issue is root caused.
	*/
	while (!(DMA_MMR_READ(&dst_ch->irq_status) & DMA_DONE))
	continue;
	#endif
	}

	void __init early_dma_memcpy_done(void)
	{
	early_shadow_stamp();

	while ((bfin_read_MDMA_S0_CONFIG() && !(bfin_read_MDMA_D0_IRQ_STATUS() & DMA_DONE)) \|\|
	(bfin_read_MDMA_S1_CONFIG() && !(bfin_read_MDMA_D1_IRQ_STATUS() & DMA_DONE)))
	continue;

	bfin_write_MDMA_D0_IRQ_STATUS(DMA_DONE \| DMA_ERR);
	bfin_write_MDMA_D1_IRQ_STATUS(DMA_DONE \| DMA_ERR);
	/*
	* Now that DMA is done, we would normally flush cache, but
	* i/d cache isn't running this early, so we don't bother,
	* and just clear out the DMA channel for next time
	*/
	bfin_write_MDMA_S0_CONFIG(0);
	bfin_write_MDMA_S1_CONFIG(0);
	bfin_write_MDMA_D0_CONFIG(0);
	bfin_write_MDMA_D1_CONFIG(0);

	__builtin_bfin_ssync();
	}

	#if defined(CH_MEM_STREAM3_SRC) && defined(CONFIG_BF60x)
	#define bfin_read_MDMA_S_CONFIG bfin_read_MDMA_S3_CONFIG
	#define bfin_write_MDMA_S_CONFIG bfin_write_MDMA_S3_CONFIG
	#define bfin_write_MDMA_S_START_ADDR bfin_write_MDMA_S3_START_ADDR
	#define bfin_write_MDMA_S_IRQ_STATUS bfin_write_MDMA_S3_IRQ_STATUS
	#define bfin_write_MDMA_S_X_COUNT bfin_write_MDMA_S3_X_COUNT
	#define bfin_write_MDMA_S_X_MODIFY bfin_write_MDMA_S3_X_MODIFY
	#define bfin_write_MDMA_S_Y_COUNT bfin_write_MDMA_S3_Y_COUNT
	#define bfin_write_MDMA_S_Y_MODIFY bfin_write_MDMA_S3_Y_MODIFY
	#define bfin_write_MDMA_D_CONFIG bfin_write_MDMA_D3_CONFIG
	#define bfin_write_MDMA_D_START_ADDR bfin_write_MDMA_D3_START_ADDR
	#define bfin_read_MDMA_D_IRQ_STATUS bfin_read_MDMA_D3_IRQ_STATUS
	#define bfin_write_MDMA_D_IRQ_STATUS bfin_write_MDMA_D3_IRQ_STATUS
	#define bfin_write_MDMA_D_X_COUNT bfin_write_MDMA_D3_X_COUNT
	#define bfin_write_MDMA_D_X_MODIFY bfin_write_MDMA_D3_X_MODIFY
	#define bfin_write_MDMA_D_Y_COUNT bfin_write_MDMA_D3_Y_COUNT
	#define bfin_write_MDMA_D_Y_MODIFY bfin_write_MDMA_D3_Y_MODIFY
	#else
	#define bfin_read_MDMA_S_CONFIG bfin_read_MDMA_S0_CONFIG
	#define bfin_write_MDMA_S_CONFIG bfin_write_MDMA_S0_CONFIG
	#define bfin_write_MDMA_S_START_ADDR bfin_write_MDMA_S0_START_ADDR
	#define bfin_write_MDMA_S_IRQ_STATUS bfin_write_MDMA_S0_IRQ_STATUS
	#define bfin_write_MDMA_S_X_COUNT bfin_write_MDMA_S0_X_COUNT
	#define bfin_write_MDMA_S_X_MODIFY bfin_write_MDMA_S0_X_MODIFY
	#define bfin_write_MDMA_S_Y_COUNT bfin_write_MDMA_S0_Y_COUNT
	#define bfin_write_MDMA_S_Y_MODIFY bfin_write_MDMA_S0_Y_MODIFY
	#define bfin_write_MDMA_D_CONFIG bfin_write_MDMA_D0_CONFIG
	#define bfin_write_MDMA_D_START_ADDR bfin_write_MDMA_D0_START_ADDR
	#define bfin_read_MDMA_D_IRQ_STATUS bfin_read_MDMA_D0_IRQ_STATUS
	#define bfin_write_MDMA_D_IRQ_STATUS bfin_write_MDMA_D0_IRQ_STATUS
	#define bfin_write_MDMA_D_X_COUNT bfin_write_MDMA_D0_X_COUNT
	#define bfin_write_MDMA_D_X_MODIFY bfin_write_MDMA_D0_X_MODIFY
	#define bfin_write_MDMA_D_Y_COUNT bfin_write_MDMA_D0_Y_COUNT
	#define bfin_write_MDMA_D_Y_MODIFY bfin_write_MDMA_D0_Y_MODIFY
	#endif

	/**
	* __dma_memcpy - program the MDMA registers
	*
	* Actually program MDMA0 and wait for the transfer to finish. Disable IRQs
	* while programming registers so that everything is fully configured. Wait
	* for DMA to finish with IRQs enabled. If interrupted, the initial DMA_DONE
	* check will make sure we don't clobber any existing transfer.
	*/
	static void __dma_memcpy(u32 daddr, s16 dmod, u32 saddr, s16 smod, size_t cnt, u32 conf)
	{
	static DEFINE_SPINLOCK(mdma_lock);
	unsigned long flags;

	spin_lock_irqsave(&mdma_lock, flags);

	/* Force a sync in case a previous config reset on this channel
	* occurred. This is needed so subsequent writes to DMA registers
	* are not spuriously lost/corrupted. Do it under irq lock and
	* without the anomaly version (because we are atomic already).
	*/
	__builtin_bfin_ssync();

	if (bfin_read_MDMA_S_CONFIG())
	while (!(bfin_read_MDMA_D_IRQ_STATUS() & DMA_DONE))
	continue;

	if (conf & DMA2D) {
	/* For larger bit sizes, we've already divided down cnt so it
	* is no longer a multiple of 64k. So we have to break down
	* the limit here so it is a multiple of the incoming size.
	* There is no limitation here in terms of total size other
	* than the hardware though as the bits lost in the shift are
	* made up by MODIFY (== we can hit the whole address space).
	* X: (2^(16 - 0)) * 1 == (2^(16 - 1)) * 2 == (2^(16 - 2)) * 4
	*/
	u32 shift = abs(dmod) >> 1;
	size_t ycnt = cnt >> (16 - shift);
	cnt = 1 << (16 - shift);
	bfin_write_MDMA_D_Y_COUNT(ycnt);
	bfin_write_MDMA_S_Y_COUNT(ycnt);
	bfin_write_MDMA_D_Y_MODIFY(dmod);
	bfin_write_MDMA_S_Y_MODIFY(smod);
	}

	bfin_write_MDMA_D_START_ADDR(daddr);
	bfin_write_MDMA_D_X_COUNT(cnt);
	bfin_write_MDMA_D_X_MODIFY(dmod);
	bfin_write_MDMA_D_IRQ_STATUS(DMA_DONE \| DMA_ERR);

	bfin_write_MDMA_S_START_ADDR(saddr);
	bfin_write_MDMA_S_X_COUNT(cnt);
	bfin_write_MDMA_S_X_MODIFY(smod);
	bfin_write_MDMA_S_IRQ_STATUS(DMA_DONE \| DMA_ERR);

	bfin_write_MDMA_S_CONFIG(DMAEN \| conf);
	if (conf & DMA2D)
	bfin_write_MDMA_D_CONFIG(WNR \| DI_EN_Y \| DMAEN \| conf);
	else
	bfin_write_MDMA_D_CONFIG(WNR \| DI_EN_X \| DMAEN \| conf);

	spin_unlock_irqrestore(&mdma_lock, flags);

	SSYNC();

	while (!(bfin_read_MDMA_D_IRQ_STATUS() & DMA_DONE))
	if (bfin_read_MDMA_S_CONFIG())
	continue;
	else
	return;

	bfin_write_MDMA_D_IRQ_STATUS(DMA_DONE \| DMA_ERR);

	bfin_write_MDMA_S_CONFIG(0);
	bfin_write_MDMA_D_CONFIG(0);
	}

	/**
	* _dma_memcpy - translate C memcpy settings into MDMA settings
	*
	* Handle all the high level steps before we touch the MDMA registers. So
	* handle direction, tweaking of sizes, and formatting of addresses.
	*/
	static void _dma_memcpy(void pdst, const void *psrc, size_t size)
	{
	u32 conf, shift;
	s16 mod;
	unsigned long dst = (unsigned long)pdst;
	unsigned long src = (unsigned long)psrc;

	if (size == 0)
	return NULL;

	if (dst % 4 == 0 && src % 4 == 0 && size % 4 == 0) {
	conf = WDSIZE_32;
	shift = 2;
	} else if (dst % 2 == 0 && src % 2 == 0 && size % 2 == 0) {
	conf = WDSIZE_16;
	shift = 1;
	} else {
	conf = WDSIZE_8;
	shift = 0;
	}

	/* If the two memory regions have a chance of overlapping, make
	* sure the memcpy still works as expected. Do this by having the
	* copy run backwards instead.
	*/
	mod = 1 << shift;
	if (src < dst) {
	mod *= -1;
	dst += size + mod;
	src += size + mod;
	}
	size >>= shift;

	#ifndef DMA_MMR_SIZE_32
	if (size > 0x10000)
	conf \|= DMA2D;
	#endif

	__dma_memcpy(dst, mod, src, mod, size, conf);

	return pdst;
	}

	/**
	* dma_memcpy - DMA memcpy under mutex lock
	*
	* Do not check arguments before starting the DMA memcpy. Break the transfer
	* up into two pieces. The first transfer is in multiples of 64k and the
	* second transfer is the piece smaller than 64k.
	*/
	void dma_memcpy(void pdst, const void *psrc, size_t size)
	{
	unsigned long dst = (unsigned long)pdst;
	unsigned long src = (unsigned long)psrc;

	if (bfin_addr_dcacheable(src))
	blackfin_dcache_flush_range(src, src + size);

	if (bfin_addr_dcacheable(dst))
	blackfin_dcache_invalidate_range(dst, dst + size);

	return dma_memcpy_nocache(pdst, psrc, size);
	}
	EXPORT_SYMBOL(dma_memcpy);

	/**
	* dma_memcpy_nocache - DMA memcpy under mutex lock
	* - No cache flush/invalidate
	*
	* Do not check arguments before starting the DMA memcpy. Break the transfer
	* up into two pieces. The first transfer is in multiples of 64k and the
	* second transfer is the piece smaller than 64k.
	*/
	void dma_memcpy_nocache(void pdst, const void *psrc, size_t size)
	{
	#ifdef DMA_MMR_SIZE_32
	_dma_memcpy(pdst, psrc, size);
	#else
	size_t bulk, rest;

	bulk = size & ~0xffff;
	rest = size - bulk;
	if (bulk)
	_dma_memcpy(pdst, psrc, bulk);
	_dma_memcpy(pdst + bulk, psrc + bulk, rest);
	#endif
	return pdst;
	}
	EXPORT_SYMBOL(dma_memcpy_nocache);

	/**
	* safe_dma_memcpy - DMA memcpy w/argument checking
	*
	* Verify arguments are safe before heading to dma_memcpy().
	*/
	void safe_dma_memcpy(void dst, const void *src, size_t size)
	{
	if (!access_ok(VERIFY_WRITE, dst, size))
	return NULL;
	if (!access_ok(VERIFY_READ, src, size))
	return NULL;
	return dma_memcpy(dst, src, size);
	}
	EXPORT_SYMBOL(safe_dma_memcpy);

	static void _dma_out(unsigned long addr, unsigned long buf, unsigned DMA_MMR_SIZE_TYPE len,
	u16 size, u16 dma_size)
	{
	blackfin_dcache_flush_range(buf, buf + len * size);
	__dma_memcpy(addr, 0, buf, size, len, dma_size);
	}

	static void _dma_in(unsigned long addr, unsigned long buf, unsigned DMA_MMR_SIZE_TYPE len,
	u16 size, u16 dma_size)
	{
	blackfin_dcache_invalidate_range(buf, buf + len * size);
	__dma_memcpy(buf, size, addr, 0, len, dma_size);
	}

	#define MAKE_DMA_IO(io, bwl, isize, dmasize, cnst) \
	void dma_##io##s##bwl(unsigned long addr, cnst void *buf, unsigned DMA_MMR_SIZE_TYPE len) \
	{ \
	_dma_##io(addr, (unsigned long)buf, len, isize, WDSIZE_##dmasize); \
	} \
	EXPORT_SYMBOL(dma_##io##s##bwl)
	MAKE_DMA_IO(out, b, 1, 8, const);
	MAKE_DMA_IO(in, b, 1, 8, );
	MAKE_DMA_IO(out, w, 2, 16, const);
	MAKE_DMA_IO(in, w, 2, 16, );
	MAKE_DMA_IO(out, l, 4, 32, const);
	MAKE_DMA_IO(in, l, 4, 32, );