linux/drivers/dma/fsldma.h

/*
 * Copyright (C) 2007-2010 Freescale Semiconductor, Inc. All rights reserved.
 *
 * Author:
 *   Zhang Wei <wei.zhang@freescale.com>, Jul 2007
 *   Ebony Zhu <ebony.zhu@freescale.com>, May 2007
 *
 * This is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 2 of the License, or
 * (at your option) any later version.
 *
 */
#ifndef __DMA_FSLDMA_H
#define __DMA_FSLDMA_H

#include <linux/device.h>
#include <linux/dmapool.h>
#include <linux/dmaengine.h>

/* Define data structures needed by Freescale
 * MPC8540 and MPC8349 DMA controller.
 */
#define FSL_DMA_MR_CS		0x00000001
#define FSL_DMA_MR_CC		0x00000002
#define FSL_DMA_MR_CA		0x00000008
#define FSL_DMA_MR_EIE		0x00000040
#define FSL_DMA_MR_XFE		0x00000020
#define FSL_DMA_MR_EOLNIE	0x00000100
#define FSL_DMA_MR_EOLSIE	0x00000080
#define FSL_DMA_MR_EOSIE	0x00000200
#define FSL_DMA_MR_CDSM		0x00000010
#define FSL_DMA_MR_CTM		0x00000004
#define FSL_DMA_MR_EMP_EN	0x00200000
#define FSL_DMA_MR_EMS_EN	0x00040000
#define FSL_DMA_MR_DAHE		0x00002000
#define FSL_DMA_MR_SAHE		0x00001000

/*
 * Bandwidth/pause control determines how many bytes a given
 * channel is allowed to transfer before the DMA engine pauses
 * the current channel and switches to the next channel
 */
#define FSL_DMA_MR_BWC         0x0A000000

/* Special MR definition for MPC8349 */
#define FSL_DMA_MR_EOTIE	0x00000080
#define FSL_DMA_MR_PRC_RM	0x00000800

#define FSL_DMA_SR_CH		0x00000020
#define FSL_DMA_SR_PE		0x00000010
#define FSL_DMA_SR_CB		0x00000004
#define FSL_DMA_SR_TE		0x00000080
#define FSL_DMA_SR_EOSI		0x00000002
#define FSL_DMA_SR_EOLSI	0x00000001
#define FSL_DMA_SR_EOCDI	0x00000001
#define FSL_DMA_SR_EOLNI	0x00000008

#define FSL_DMA_SATR_SBPATMU			0x20000000
#define FSL_DMA_SATR_STRANSINT_RIO		0x00c00000
#define FSL_DMA_SATR_SREADTYPE_SNOOP_READ	0x00050000
#define FSL_DMA_SATR_SREADTYPE_BP_IORH		0x00020000
#define FSL_DMA_SATR_SREADTYPE_BP_NREAD		0x00040000
#define FSL_DMA_SATR_SREADTYPE_BP_MREAD		0x00070000

#define FSL_DMA_DATR_DBPATMU			0x20000000
#define FSL_DMA_DATR_DTRANSINT_RIO		0x00c00000
#define FSL_DMA_DATR_DWRITETYPE_SNOOP_WRITE	0x00050000
#define FSL_DMA_DATR_DWRITETYPE_BP_FLUSH	0x00010000

#define FSL_DMA_EOL		((u64)0x1)
#define FSL_DMA_SNEN		((u64)0x10)
#define FSL_DMA_EOSIE		0x8
#define FSL_DMA_NLDA_MASK	(~(u64)0x1f)

#define FSL_DMA_BCR_MAX_CNT	0x03ffffffu

#define FSL_DMA_DGSR_TE		0x80
#define FSL_DMA_DGSR_CH		0x20
#define FSL_DMA_DGSR_PE		0x10
#define FSL_DMA_DGSR_EOLNI	0x08
#define FSL_DMA_DGSR_CB		0x04
#define FSL_DMA_DGSR_EOSI	0x02
#define FSL_DMA_DGSR_EOLSI	0x01

#define FSL_DMA_BUSWIDTHS	(BIT(DMA_SLAVE_BUSWIDTH_1_BYTE) | \
				BIT(DMA_SLAVE_BUSWIDTH_2_BYTES) | \
				BIT(DMA_SLAVE_BUSWIDTH_4_BYTES) | \
				BIT(DMA_SLAVE_BUSWIDTH_8_BYTES))
typedef u64 __bitwise v64;
typedef u32 __bitwise v32;

struct fsl_dma_ld_hw {
	v64 src_addr;
	v64 dst_addr;
	v64 next_ln_addr;
	v32 count;
	v32 reserve;
} __attribute__((aligned(32)));

struct fsl_desc_sw {
	struct fsl_dma_ld_hw hw;
	struct list_head node;
	struct list_head tx_list;
	struct dma_async_tx_descriptor async_tx;
} __attribute__((aligned(32)));

struct fsldma_chan_regs {
	u32 mr;		/* 0x00 - Mode Register */
	u32 sr;		/* 0x04 - Status Register */
	u64 cdar;	/* 0x08 - Current descriptor address register */
	u64 sar;	/* 0x10 - Source Address Register */
	u64 dar;	/* 0x18 - Destination Address Register */
	u32 bcr;	/* 0x20 - Byte Count Register */
	u64 ndar;	/* 0x24 - Next Descriptor Address Register */
};

struct fsldma_chan;
#define FSL_DMA_MAX_CHANS_PER_DEVICE 8

struct fsldma_device {
	void __iomem *regs;	/* DGSR register base */
	struct device *dev;
	struct dma_device common;
	struct fsldma_chan *chan[FSL_DMA_MAX_CHANS_PER_DEVICE];
	u32 feature;		/* The same as DMA channels */
	int irq;		/* Channel IRQ */
};

/* Define macros for fsldma_chan->feature property */
#define FSL_DMA_LITTLE_ENDIAN	0x00000000
#define FSL_DMA_BIG_ENDIAN	0x00000001

#define FSL_DMA_IP_MASK		0x00000ff0
#define FSL_DMA_IP_85XX		0x00000010
#define FSL_DMA_IP_83XX		0x00000020

#define FSL_DMA_CHAN_PAUSE_EXT	0x00001000
#define FSL_DMA_CHAN_START_EXT	0x00002000

#ifdef CONFIG_PM
struct fsldma_chan_regs_save {
	u32 mr;
};

enum fsldma_pm_state {
	RUNNING = 0,
	SUSPENDED,
};
#endif

struct fsldma_chan {
	char name[8];			/* Channel name */
	struct fsldma_chan_regs __iomem *regs;
	spinlock_t desc_lock;		/* Descriptor operation lock */
	/*
	 * Descriptors which are queued to run, but have not yet been
	 * submitted to the hardware for execution
	 */
	struct list_head ld_pending;
	/*
	 * Descriptors which are currently being executed by the hardware
	 */
	struct list_head ld_running;
	/*
	 * Descriptors which have finished execution by the hardware. These
	 * descriptors have already had their cleanup actions run. They are
	 * waiting for the ACK bit to be set by the async_tx API.
	 */
	struct list_head ld_completed;	/* Link descriptors queue */
	struct dma_chan common;		/* DMA common channel */
	struct dma_pool *desc_pool;	/* Descriptors pool */
	struct device *dev;		/* Channel device */
	int irq;			/* Channel IRQ */
	int id;				/* Raw id of this channel */
	struct tasklet_struct tasklet;
	u32 feature;
	bool idle;			/* DMA controller is idle */
#ifdef CONFIG_PM
	struct fsldma_chan_regs_save regs_save;
	enum fsldma_pm_state pm_state;
#endif

	void (*toggle_ext_pause)(struct fsldma_chan *fsl_chan, int enable);
	void (*toggle_ext_start)(struct fsldma_chan *fsl_chan, int enable);
	void (*set_src_loop_size)(struct fsldma_chan *fsl_chan, int size);
	void (*set_dst_loop_size)(struct fsldma_chan *fsl_chan, int size);
	void (*set_request_count)(struct fsldma_chan *fsl_chan, int size);
};

#define to_fsl_chan(chan) container_of(chan, struct fsldma_chan, common)
#define to_fsl_desc(lh) container_of(lh, struct fsl_desc_sw, node)
#define tx_to_fsl_desc(tx) container_of(tx, struct fsl_desc_sw, async_tx)

#ifndef __powerpc64__
static u64 in_be64(const u64 __iomem *addr)
{
	return ((u64)in_be32((u32 __iomem *)addr) << 32) |
		(in_be32((u32 __iomem *)addr + 1));
}

static void out_be64(u64 __iomem *addr, u64 val)
{
	out_be32((u32 __iomem *)addr, val >> 32);
	out_be32((u32 __iomem *)addr + 1, (u32)val);
}

/* There is no asm instructions for 64 bits reverse loads and stores */
static u64 in_le64(const u64 __iomem *addr)
{
	return ((u64)in_le32((u32 __iomem *)addr + 1) << 32) |
		(in_le32((u32 __iomem *)addr));
}

static void out_le64(u64 __iomem *addr, u64 val)
{
	out_le32((u32 __iomem *)addr + 1, val >> 32);
	out_le32((u32 __iomem *)addr, (u32)val);
}
#endif

#define DMA_IN(fsl_chan, addr, width)					\
		(((fsl_chan)->feature & FSL_DMA_BIG_ENDIAN) ?		\
			in_be##width(addr) : in_le##width(addr))
#define DMA_OUT(fsl_chan, addr, val, width)				\
		(((fsl_chan)->feature & FSL_DMA_BIG_ENDIAN) ?		\
			out_be##width(addr, val) : out_le##width(addr, val))

#define DMA_TO_CPU(fsl_chan, d, width)					\
		(((fsl_chan)->feature & FSL_DMA_BIG_ENDIAN) ?		\
			be##width##_to_cpu((__force __be##width)(v##width)d) : \
			le##width##_to_cpu((__force __le##width)(v##width)d))
#define CPU_TO_DMA(fsl_chan, c, width)					\
		(((fsl_chan)->feature & FSL_DMA_BIG_ENDIAN) ?		\
			(__force v##width)cpu_to_be##width(c) :		\
			(__force v##width)cpu_to_le##width(c))

#endif	/* __DMA_FSLDMA_H */