Commit 6391987d authored by Dan Williams's avatar Dan Williams

Merge branches 'dma40', 'pl08x', 'fsldma', 'imx' and 'intel-mid' into dmaengine

...@@ -27,6 +27,8 @@ ...@@ -27,6 +27,8 @@
#define imx_has_dma_v1() (cpu_is_mx1() || cpu_is_mx21() || cpu_is_mx27()) #define imx_has_dma_v1() (cpu_is_mx1() || cpu_is_mx21() || cpu_is_mx27())
#include <mach/dma.h>
#define IMX_DMA_CHANNELS 16 #define IMX_DMA_CHANNELS 16
#define DMA_MODE_READ 0 #define DMA_MODE_READ 0
...@@ -96,12 +98,6 @@ int imx_dma_request(int channel, const char *name); ...@@ -96,12 +98,6 @@ int imx_dma_request(int channel, const char *name);
void imx_dma_free(int channel); void imx_dma_free(int channel);
enum imx_dma_prio {
DMA_PRIO_HIGH = 0,
DMA_PRIO_MEDIUM = 1,
DMA_PRIO_LOW = 2
};
int imx_dma_request_by_prio(const char *name, enum imx_dma_prio prio); int imx_dma_request_by_prio(const char *name, enum imx_dma_prio prio);
#endif /* __MACH_DMA_V1_H__ */ #endif /* __MACH_DMA_V1_H__ */
/*
* Copyright 2004-2009 Freescale Semiconductor, Inc. All Rights Reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*/
#ifndef __ASM_ARCH_MXC_DMA_H__
#define __ASM_ARCH_MXC_DMA_H__
#include <linux/scatterlist.h>
#include <linux/device.h>
#include <linux/dmaengine.h>
/*
* This enumerates peripheral types. Used for SDMA.
*/
enum sdma_peripheral_type {
IMX_DMATYPE_SSI, /* MCU domain SSI */
IMX_DMATYPE_SSI_SP, /* Shared SSI */
IMX_DMATYPE_MMC, /* MMC */
IMX_DMATYPE_SDHC, /* SDHC */
IMX_DMATYPE_UART, /* MCU domain UART */
IMX_DMATYPE_UART_SP, /* Shared UART */
IMX_DMATYPE_FIRI, /* FIRI */
IMX_DMATYPE_CSPI, /* MCU domain CSPI */
IMX_DMATYPE_CSPI_SP, /* Shared CSPI */
IMX_DMATYPE_SIM, /* SIM */
IMX_DMATYPE_ATA, /* ATA */
IMX_DMATYPE_CCM, /* CCM */
IMX_DMATYPE_EXT, /* External peripheral */
IMX_DMATYPE_MSHC, /* Memory Stick Host Controller */
IMX_DMATYPE_MSHC_SP, /* Shared Memory Stick Host Controller */
IMX_DMATYPE_DSP, /* DSP */
IMX_DMATYPE_MEMORY, /* Memory */
IMX_DMATYPE_FIFO_MEMORY,/* FIFO type Memory */
IMX_DMATYPE_SPDIF, /* SPDIF */
IMX_DMATYPE_IPU_MEMORY, /* IPU Memory */
IMX_DMATYPE_ASRC, /* ASRC */
IMX_DMATYPE_ESAI, /* ESAI */
};
enum imx_dma_prio {
DMA_PRIO_HIGH = 0,
DMA_PRIO_MEDIUM = 1,
DMA_PRIO_LOW = 2
};
struct imx_dma_data {
int dma_request; /* DMA request line */
enum sdma_peripheral_type peripheral_type;
int priority;
};
static inline int imx_dma_is_ipu(struct dma_chan *chan)
{
return !strcmp(dev_name(chan->device->dev), "ipu-core");
}
static inline int imx_dma_is_general_purpose(struct dma_chan *chan)
{
return !strcmp(dev_name(chan->device->dev), "imx-sdma") ||
!strcmp(dev_name(chan->device->dev), "imx-dma");
}
#endif
#ifndef __MACH_MXC_SDMA_H__
#define __MACH_MXC_SDMA_H__
/**
* struct sdma_platform_data - platform specific data for SDMA engine
*
* @sdma_version The version of this SDMA engine
* @cpu_name used to generate the firmware name
* @to_version CPU Tape out version
*/
struct sdma_platform_data {
int sdma_version;
char *cpu_name;
int to_version;
};
#endif /* __MACH_MXC_SDMA_H__ */
/*
* Freescale MPC83XX / MPC85XX DMA Controller
*
* Copyright (c) 2009 Ira W. Snyder <iws@ovro.caltech.edu>
*
* This file is licensed under the terms of the GNU General Public License
* version 2. This program is licensed "as is" without any warranty of any
* kind, whether express or implied.
*/
#ifndef __ARCH_POWERPC_ASM_FSLDMA_H__
#define __ARCH_POWERPC_ASM_FSLDMA_H__
#include <linux/slab.h>
#include <linux/dmaengine.h>
/*
* Definitions for the Freescale DMA controller's DMA_SLAVE implemention
*
* The Freescale DMA_SLAVE implementation was designed to handle many-to-many
* transfers. An example usage would be an accelerated copy between two
* scatterlists. Another example use would be an accelerated copy from
* multiple non-contiguous device buffers into a single scatterlist.
*
* A DMA_SLAVE transaction is defined by a struct fsl_dma_slave. This
* structure contains a list of hardware addresses that should be copied
* to/from the scatterlist passed into device_prep_slave_sg(). The structure
* also has some fields to enable hardware-specific features.
*/
/**
* struct fsl_dma_hw_addr
* @entry: linked list entry
* @address: the hardware address
* @length: length to transfer
*
* Holds a single physical hardware address / length pair for use
* with the DMAEngine DMA_SLAVE API.
*/
struct fsl_dma_hw_addr {
struct list_head entry;
dma_addr_t address;
size_t length;
};
/**
* struct fsl_dma_slave
* @addresses: a linked list of struct fsl_dma_hw_addr structures
* @request_count: value for DMA request count
* @src_loop_size: setup and enable constant source-address DMA transfers
* @dst_loop_size: setup and enable constant destination address DMA transfers
* @external_start: enable externally started DMA transfers
* @external_pause: enable externally paused DMA transfers
*
* Holds a list of address / length pairs for use with the DMAEngine
* DMA_SLAVE API implementation for the Freescale DMA controller.
*/
struct fsl_dma_slave {
/* List of hardware address/length pairs */
struct list_head addresses;
/* Support for extra controller features */
unsigned int request_count;
unsigned int src_loop_size;
unsigned int dst_loop_size;
bool external_start;
bool external_pause;
};
/**
* fsl_dma_slave_append - add an address/length pair to a struct fsl_dma_slave
* @slave: the &struct fsl_dma_slave to add to
* @address: the hardware address to add
* @length: the length of bytes to transfer from @address
*
* Add a hardware address/length pair to a struct fsl_dma_slave. Returns 0 on
* success, -ERRNO otherwise.
*/
static inline int fsl_dma_slave_append(struct fsl_dma_slave *slave,
dma_addr_t address, size_t length)
{
struct fsl_dma_hw_addr *addr;
addr = kzalloc(sizeof(*addr), GFP_ATOMIC);
if (!addr)
return -ENOMEM;
INIT_LIST_HEAD(&addr->entry);
addr->address = address;
addr->length = length;
list_add_tail(&addr->entry, &slave->addresses);
return 0;
}
/**
* fsl_dma_slave_free - free a struct fsl_dma_slave
* @slave: the struct fsl_dma_slave to free
*
* Free a struct fsl_dma_slave and all associated address/length pairs
*/
static inline void fsl_dma_slave_free(struct fsl_dma_slave *slave)
{
struct fsl_dma_hw_addr *addr, *tmp;
if (slave) {
list_for_each_entry_safe(addr, tmp, &slave->addresses, entry) {
list_del(&addr->entry);
kfree(addr);
}
kfree(slave);
}
}
/**
* fsl_dma_slave_alloc - allocate a struct fsl_dma_slave
* @gfp: the flags to pass to kmalloc when allocating this structure
*
* Allocate a struct fsl_dma_slave for use by the DMA_SLAVE API. Returns a new
* struct fsl_dma_slave on success, or NULL on failure.
*/
static inline struct fsl_dma_slave *fsl_dma_slave_alloc(gfp_t gfp)
{
struct fsl_dma_slave *slave;
slave = kzalloc(sizeof(*slave), gfp);
if (!slave)
return NULL;
INIT_LIST_HEAD(&slave->addresses);
return slave;
}
#endif /* __ARCH_POWERPC_ASM_FSLDMA_H__ */
...@@ -49,6 +49,14 @@ config INTEL_MID_DMAC ...@@ -49,6 +49,14 @@ config INTEL_MID_DMAC
config ASYNC_TX_DISABLE_CHANNEL_SWITCH config ASYNC_TX_DISABLE_CHANNEL_SWITCH
bool bool
config AMBA_PL08X
bool "ARM PrimeCell PL080 or PL081 support"
depends on ARM_AMBA && EXPERIMENTAL
select DMA_ENGINE
help
Platform has a PL08x DMAC device
which can provide DMA engine support
config INTEL_IOATDMA config INTEL_IOATDMA
tristate "Intel I/OAT DMA support" tristate "Intel I/OAT DMA support"
depends on PCI && X86 depends on PCI && X86
...@@ -195,6 +203,22 @@ config PCH_DMA ...@@ -195,6 +203,22 @@ config PCH_DMA
help help
Enable support for the Topcliff PCH DMA engine. Enable support for the Topcliff PCH DMA engine.
config IMX_SDMA
tristate "i.MX SDMA support"
depends on ARCH_MX25 || ARCH_MX3 || ARCH_MX5
select DMA_ENGINE
help
Support the i.MX SDMA engine. This engine is integrated into
Freescale i.MX25/31/35/51 chips.
config IMX_DMA
tristate "i.MX DMA support"
depends on ARCH_MX1 || ARCH_MX21 || MACH_MX27
select DMA_ENGINE
help
Support the i.MX DMA engine. This engine is integrated into
Freescale i.MX1/21/27 chips.
config DMA_ENGINE config DMA_ENGINE
bool bool
......
...@@ -21,7 +21,10 @@ obj-$(CONFIG_TXX9_DMAC) += txx9dmac.o ...@@ -21,7 +21,10 @@ obj-$(CONFIG_TXX9_DMAC) += txx9dmac.o
obj-$(CONFIG_SH_DMAE) += shdma.o obj-$(CONFIG_SH_DMAE) += shdma.o
obj-$(CONFIG_COH901318) += coh901318.o coh901318_lli.o obj-$(CONFIG_COH901318) += coh901318.o coh901318_lli.o
obj-$(CONFIG_AMCC_PPC440SPE_ADMA) += ppc4xx/ obj-$(CONFIG_AMCC_PPC440SPE_ADMA) += ppc4xx/
obj-$(CONFIG_IMX_SDMA) += imx-sdma.o
obj-$(CONFIG_IMX_DMA) += imx-dma.o
obj-$(CONFIG_TIMB_DMA) += timb_dma.o obj-$(CONFIG_TIMB_DMA) += timb_dma.o
obj-$(CONFIG_STE_DMA40) += ste_dma40.o ste_dma40_ll.o obj-$(CONFIG_STE_DMA40) += ste_dma40.o ste_dma40_ll.o
obj-$(CONFIG_PL330_DMA) += pl330.o obj-$(CONFIG_PL330_DMA) += pl330.o
obj-$(CONFIG_PCH_DMA) += pch_dma.o obj-$(CONFIG_PCH_DMA) += pch_dma.o
obj-$(CONFIG_AMBA_PL08X) += amba-pl08x.o
/*
* Copyright (c) 2006 ARM Ltd.
* Copyright (c) 2010 ST-Ericsson SA
*
* Author: Peter Pearse <peter.pearse@arm.com>
* Author: Linus Walleij <linus.walleij@stericsson.com>
*
* This program 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.
*
* This program is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License along with
* this program; if not, write to the Free Software Foundation, Inc., 59
* Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*
* The full GNU General Public License is iin this distribution in the
* file called COPYING.
*
* Documentation: ARM DDI 0196G == PL080
* Documentation: ARM DDI 0218E == PL081
*
* PL080 & PL081 both have 16 sets of DMA signals that can be routed to
* any channel.
*
* The PL080 has 8 channels available for simultaneous use, and the PL081
* has only two channels. So on these DMA controllers the number of channels
* and the number of incoming DMA signals are two totally different things.
* It is usually not possible to theoretically handle all physical signals,
* so a multiplexing scheme with possible denial of use is necessary.
*
* The PL080 has a dual bus master, PL081 has a single master.
*
* Memory to peripheral transfer may be visualized as
* Get data from memory to DMAC
* Until no data left
* On burst request from peripheral
* Destination burst from DMAC to peripheral
* Clear burst request
* Raise terminal count interrupt
*
* For peripherals with a FIFO:
* Source burst size == half the depth of the peripheral FIFO
* Destination burst size == the depth of the peripheral FIFO
*
* (Bursts are irrelevant for mem to mem transfers - there are no burst
* signals, the DMA controller will simply facilitate its AHB master.)
*
* ASSUMES default (little) endianness for DMA transfers
*
* Only DMAC flow control is implemented
*
* Global TODO:
* - Break out common code from arch/arm/mach-s3c64xx and share
*/
#include <linux/device.h>
#include <linux/init.h>
#include <linux/module.h>
#include <linux/pci.h>
#include <linux/interrupt.h>
#include <linux/slab.h>
#include <linux/dmapool.h>
#include <linux/amba/bus.h>
#include <linux/dmaengine.h>
#include <linux/amba/pl08x.h>
#include <linux/debugfs.h>
#include <linux/seq_file.h>
#include <asm/hardware/pl080.h>
#include <asm/dma.h>
#include <asm/mach/dma.h>
#include <asm/atomic.h>
#include <asm/processor.h>
#include <asm/cacheflush.h>
#define DRIVER_NAME "pl08xdmac"
/**
* struct vendor_data - vendor-specific config parameters
* for PL08x derivates
* @name: the name of this specific variant
* @channels: the number of channels available in this variant
* @dualmaster: whether this version supports dual AHB masters
* or not.
*/
struct vendor_data {
char *name;
u8 channels;
bool dualmaster;
};
/*
* PL08X private data structures
* An LLI struct - see pl08x TRM
* Note that next uses bit[0] as a bus bit,
* start & end do not - their bus bit info
* is in cctl
*/
struct lli {
dma_addr_t src;
dma_addr_t dst;
dma_addr_t next;
u32 cctl;
};
/**
* struct pl08x_driver_data - the local state holder for the PL08x
* @slave: slave engine for this instance
* @memcpy: memcpy engine for this instance
* @base: virtual memory base (remapped) for the PL08x
* @adev: the corresponding AMBA (PrimeCell) bus entry
* @vd: vendor data for this PL08x variant
* @pd: platform data passed in from the platform/machine
* @phy_chans: array of data for the physical channels
* @pool: a pool for the LLI descriptors
* @pool_ctr: counter of LLIs in the pool
* @lock: a spinlock for this struct
*/
struct pl08x_driver_data {
struct dma_device slave;
struct dma_device memcpy;
void __iomem *base;
struct amba_device *adev;
struct vendor_data *vd;
struct pl08x_platform_data *pd;
struct pl08x_phy_chan *phy_chans;
struct dma_pool *pool;
int pool_ctr;
spinlock_t lock;
};
/*
* PL08X specific defines
*/
/*
* Memory boundaries: the manual for PL08x says that the controller
* cannot read past a 1KiB boundary, so these defines are used to
* create transfer LLIs that do not cross such boundaries.
*/
#define PL08X_BOUNDARY_SHIFT (10) /* 1KB 0x400 */
#define PL08X_BOUNDARY_SIZE (1 << PL08X_BOUNDARY_SHIFT)
/* Minimum period between work queue runs */
#define PL08X_WQ_PERIODMIN 20
/* Size (bytes) of each LLI buffer allocated for one transfer */
# define PL08X_LLI_TSFR_SIZE 0x2000
/* Maximimum times we call dma_pool_alloc on this pool without freeing */
#define PL08X_MAX_ALLOCS 0x40
#define MAX_NUM_TSFR_LLIS (PL08X_LLI_TSFR_SIZE/sizeof(struct lli))
#define PL08X_ALIGN 8
static inline struct pl08x_dma_chan *to_pl08x_chan(struct dma_chan *chan)
{
return container_of(chan, struct pl08x_dma_chan, chan);
}
/*
* Physical channel handling
*/
/* Whether a certain channel is busy or not */
static int pl08x_phy_channel_busy(struct pl08x_phy_chan *ch)
{
unsigned int val;
val = readl(ch->base + PL080_CH_CONFIG);
return val & PL080_CONFIG_ACTIVE;
}
/*
* Set the initial DMA register values i.e. those for the first LLI
* The next lli pointer and the configuration interrupt bit have
* been set when the LLIs were constructed
*/
static void pl08x_set_cregs(struct pl08x_driver_data *pl08x,
struct pl08x_phy_chan *ch)
{
/* Wait for channel inactive */
while (pl08x_phy_channel_busy(ch))
;
dev_vdbg(&pl08x->adev->dev,
"WRITE channel %d: csrc=%08x, cdst=%08x, "
"cctl=%08x, clli=%08x, ccfg=%08x\n",
ch->id,
ch->csrc,
ch->cdst,
ch->cctl,
ch->clli,
ch->ccfg);
writel(ch->csrc, ch->base + PL080_CH_SRC_ADDR);
writel(ch->cdst, ch->base + PL080_CH_DST_ADDR);
writel(ch->clli, ch->base + PL080_CH_LLI);
writel(ch->cctl, ch->base + PL080_CH_CONTROL);
writel(ch->ccfg, ch->base + PL080_CH_CONFIG);
}
static inline void pl08x_config_phychan_for_txd(struct pl08x_dma_chan *plchan)
{
struct pl08x_channel_data *cd = plchan->cd;
struct pl08x_phy_chan *phychan = plchan->phychan;
struct pl08x_txd *txd = plchan->at;
/* Copy the basic control register calculated at transfer config */
phychan->csrc = txd->csrc;
phychan->cdst = txd->cdst;
phychan->clli = txd->clli;
phychan->cctl = txd->cctl;
/* Assign the signal to the proper control registers */
phychan->ccfg = cd->ccfg;
phychan->ccfg &= ~PL080_CONFIG_SRC_SEL_MASK;
phychan->ccfg &= ~PL080_CONFIG_DST_SEL_MASK;
/* If it wasn't set from AMBA, ignore it */
if (txd->direction == DMA_TO_DEVICE)
/* Select signal as destination */
phychan->ccfg |=
(phychan->signal << PL080_CONFIG_DST_SEL_SHIFT);
else if (txd->direction == DMA_FROM_DEVICE)
/* Select signal as source */
phychan->ccfg |=
(phychan->signal << PL080_CONFIG_SRC_SEL_SHIFT);
/* Always enable error interrupts */
phychan->ccfg |= PL080_CONFIG_ERR_IRQ_MASK;
/* Always enable terminal interrupts */
phychan->ccfg |= PL080_CONFIG_TC_IRQ_MASK;
}
/*
* Enable the DMA channel
* Assumes all other configuration bits have been set
* as desired before this code is called
*/
static void pl08x_enable_phy_chan(struct pl08x_driver_data *pl08x,
struct pl08x_phy_chan *ch)
{
u32 val;
/*
* Do not access config register until channel shows as disabled
*/
while (readl(pl08x->base + PL080_EN_CHAN) & (1 << ch->id))
;
/*
* Do not access config register until channel shows as inactive
*/
val = readl(ch->base + PL080_CH_CONFIG);
while ((val & PL080_CONFIG_ACTIVE) || (val & PL080_CONFIG_ENABLE))
val = readl(ch->base + PL080_CH_CONFIG);
writel(val | PL080_CONFIG_ENABLE, ch->base + PL080_CH_CONFIG);
}
/*
* Overall DMAC remains enabled always.
*
* Disabling individual channels could lose data.
*
* Disable the peripheral DMA after disabling the DMAC
* in order to allow the DMAC FIFO to drain, and
* hence allow the channel to show inactive
*
*/
static void pl08x_pause_phy_chan(struct pl08x_phy_chan *ch)
{
u32 val;
/* Set the HALT bit and wait for the FIFO to drain */
val = readl(ch->base + PL080_CH_CONFIG);
val |= PL080_CONFIG_HALT;
writel(val, ch->base + PL080_CH_CONFIG);
/* Wait for channel inactive */
while (pl08x_phy_channel_busy(ch))
;
}
static void pl08x_resume_phy_chan(struct pl08x_phy_chan *ch)
{
u32 val;
/* Clear the HALT bit */
val = readl(ch->base + PL080_CH_CONFIG);
val &= ~PL080_CONFIG_HALT;
writel(val, ch->base + PL080_CH_CONFIG);
}
/* Stops the channel */
static void pl08x_stop_phy_chan(struct pl08x_phy_chan *ch)
{
u32 val;
pl08x_pause_phy_chan(ch);
/* Disable channel */
val = readl(ch->base + PL080_CH_CONFIG);
val &= ~PL080_CONFIG_ENABLE;
val &= ~PL080_CONFIG_ERR_IRQ_MASK;
val &= ~PL080_CONFIG_TC_IRQ_MASK;
writel(val, ch->base + PL080_CH_CONFIG);
}
static inline u32 get_bytes_in_cctl(u32 cctl)
{
/* The source width defines the number of bytes */
u32 bytes = cctl & PL080_CONTROL_TRANSFER_SIZE_MASK;
switch (cctl >> PL080_CONTROL_SWIDTH_SHIFT) {
case PL080_WIDTH_8BIT:
break;
case PL080_WIDTH_16BIT:
bytes *= 2;
break;
case PL080_WIDTH_32BIT:
bytes *= 4;
break;
}
return bytes;
}
/* The channel should be paused when calling this */
static u32 pl08x_getbytes_chan(struct pl08x_dma_chan *plchan)
{
struct pl08x_phy_chan *ch;
struct pl08x_txd *txdi = NULL;
struct pl08x_txd *txd;
unsigned long flags;
u32 bytes = 0;
spin_lock_irqsave(&plchan->lock, flags);
ch = plchan->phychan;
txd = plchan->at;
/*
* Next follow the LLIs to get the number of pending bytes in the
* currently active transaction.
*/
if (ch && txd) {
struct lli *llis_va = txd->llis_va;
struct lli *llis_bus = (struct lli *) txd->llis_bus;
u32 clli = readl(ch->base + PL080_CH_LLI);
/* First get the bytes in the current active LLI */
bytes = get_bytes_in_cctl(readl(ch->base + PL080_CH_CONTROL));
if (clli) {
int i = 0;
/* Forward to the LLI pointed to by clli */
while ((clli != (u32) &(llis_bus[i])) &&
(i < MAX_NUM_TSFR_LLIS))
i++;
while (clli) {
bytes += get_bytes_in_cctl(llis_va[i].cctl);
/*
* A clli of 0x00000000 will terminate the
* LLI list
*/
clli = llis_va[i].next;
i++;
}
}
}
/* Sum up all queued transactions */
if (!list_empty(&plchan->desc_list)) {
list_for_each_entry(txdi, &plchan->desc_list, node) {
bytes += txdi->len;
}
}
spin_unlock_irqrestore(&plchan->lock, flags);
return bytes;
}
/*
* Allocate a physical channel for a virtual channel
*/
static struct pl08x_phy_chan *
pl08x_get_phy_channel(struct pl08x_driver_data *pl08x,
struct pl08x_dma_chan *virt_chan)
{
struct pl08x_phy_chan *ch = NULL;
unsigned long flags;
int i;
/*
* Try to locate a physical channel to be used for
* this transfer. If all are taken return NULL and
* the requester will have to cope by using some fallback
* PIO mode or retrying later.
*/
for (i = 0; i < pl08x->vd->channels; i++) {
ch = &pl08x->phy_chans[i];
spin_lock_irqsave(&ch->lock, flags);
if (!ch->serving) {
ch->serving = virt_chan;
ch->signal = -1;
spin_unlock_irqrestore(&ch->lock, flags);
break;
}
spin_unlock_irqrestore(&ch->lock, flags);
}
if (i == pl08x->vd->channels) {
/* No physical channel available, cope with it */
return NULL;
}
return ch;
}
static inline void pl08x_put_phy_channel(struct pl08x_driver_data *pl08x,
struct pl08x_phy_chan *ch)
{
unsigned long flags;
/* Stop the channel and clear its interrupts */
pl08x_stop_phy_chan(ch);
writel((1 << ch->id), pl08x->base + PL080_ERR_CLEAR);
writel((1 << ch->id), pl08x->base + PL080_TC_CLEAR);
/* Mark it as free */
spin_lock_irqsave(&ch->lock, flags);
ch->serving = NULL;
spin_unlock_irqrestore(&ch->lock, flags);
}
/*
* LLI handling
*/
static inline unsigned int pl08x_get_bytes_for_cctl(unsigned int coded)
{
switch (coded) {
case PL080_WIDTH_8BIT:
return 1;
case PL080_WIDTH_16BIT:
return 2;
case PL080_WIDTH_32BIT:
return 4;
default:
break;
}
BUG();
return 0;
}
static inline u32 pl08x_cctl_bits(u32 cctl, u8 srcwidth, u8 dstwidth,
u32 tsize)
{
u32 retbits = cctl;
/* Remove all src, dst and transfersize bits */
retbits &= ~PL080_CONTROL_DWIDTH_MASK;
retbits &= ~PL080_CONTROL_SWIDTH_MASK;
retbits &= ~PL080_CONTROL_TRANSFER_SIZE_MASK;
/* Then set the bits according to the parameters */
switch (srcwidth) {
case 1:
retbits |= PL080_WIDTH_8BIT << PL080_CONTROL_SWIDTH_SHIFT;
break;
case 2:
retbits |= PL080_WIDTH_16BIT << PL080_CONTROL_SWIDTH_SHIFT;
break;
case 4:
retbits |= PL080_WIDTH_32BIT << PL080_CONTROL_SWIDTH_SHIFT;
break;
default:
BUG();
break;
}
switch (dstwidth) {
case 1:
retbits |= PL080_WIDTH_8BIT << PL080_CONTROL_DWIDTH_SHIFT;
break;
case 2:
retbits |= PL080_WIDTH_16BIT << PL080_CONTROL_DWIDTH_SHIFT;
break;
case 4:
retbits |= PL080_WIDTH_32BIT << PL080_CONTROL_DWIDTH_SHIFT;
break;
default:
BUG();
break;
}
retbits |= tsize << PL080_CONTROL_TRANSFER_SIZE_SHIFT;
return retbits;
}
/*
* Autoselect a master bus to use for the transfer
* this prefers the destination bus if both available
* if fixed address on one bus the other will be chosen
*/
void pl08x_choose_master_bus(struct pl08x_bus_data *src_bus,
struct pl08x_bus_data *dst_bus, struct pl08x_bus_data **mbus,
struct pl08x_bus_data **sbus, u32 cctl)
{
if (!(cctl & PL080_CONTROL_DST_INCR)) {
*mbus = src_bus;
*sbus = dst_bus;
} else if (!(cctl & PL080_CONTROL_SRC_INCR)) {
*mbus = dst_bus;
*sbus = src_bus;
} else {
if (dst_bus->buswidth == 4) {
*mbus = dst_bus;
*sbus = src_bus;
} else if (src_bus->buswidth == 4) {
*mbus = src_bus;
*sbus = dst_bus;
} else if (dst_bus->buswidth == 2) {
*mbus = dst_bus;
*sbus = src_bus;
} else if (src_bus->buswidth == 2) {
*mbus = src_bus;
*sbus = dst_bus;
} else {
/* src_bus->buswidth == 1 */
*mbus = dst_bus;
*sbus = src_bus;
}
}
}
/*
* Fills in one LLI for a certain transfer descriptor
* and advance the counter
*/
int pl08x_fill_lli_for_desc(struct pl08x_driver_data *pl08x,
struct pl08x_txd *txd, int num_llis, int len,
u32 cctl, u32 *remainder)
{
struct lli *llis_va = txd->llis_va;
struct lli *llis_bus = (struct lli *) txd->llis_bus;
BUG_ON(num_llis >= MAX_NUM_TSFR_LLIS);
llis_va[num_llis].cctl = cctl;
llis_va[num_llis].src = txd->srcbus.addr;
llis_va[num_llis].dst = txd->dstbus.addr;
/*
* On versions with dual masters, you can optionally AND on
* PL080_LLI_LM_AHB2 to the LLI to tell the hardware to read
* in new LLIs with that controller, but we always try to
* choose AHB1 to point into memory. The idea is to have AHB2
* fixed on the peripheral and AHB1 messing around in the
* memory. So we don't manipulate this bit currently.
*/
llis_va[num_llis].next =
(dma_addr_t)((u32) &(llis_bus[num_llis + 1]));
if (cctl & PL080_CONTROL_SRC_INCR)
txd->srcbus.addr += len;
if (cctl & PL080_CONTROL_DST_INCR)
txd->dstbus.addr += len;
*remainder -= len;
return num_llis + 1;
}
/*
* Return number of bytes to fill to boundary, or len
*/
static inline u32 pl08x_pre_boundary(u32 addr, u32 len)
{
u32 boundary;
boundary = ((addr >> PL08X_BOUNDARY_SHIFT) + 1)
<< PL08X_BOUNDARY_SHIFT;
if (boundary < addr + len)
return boundary - addr;
else
return len;
}
/*
* This fills in the table of LLIs for the transfer descriptor
* Note that we assume we never have to change the burst sizes
* Return 0 for error
*/
static int pl08x_fill_llis_for_desc(struct pl08x_driver_data *pl08x,
struct pl08x_txd *txd)
{
struct pl08x_channel_data *cd = txd->cd;
struct pl08x_bus_data *mbus, *sbus;
u32 remainder;
int num_llis = 0;
u32 cctl;
int max_bytes_per_lli;
int total_bytes = 0;
struct lli *llis_va;
struct lli *llis_bus;
if (!txd) {
dev_err(&pl08x->adev->dev, "%s no descriptor\n", __func__);
return 0;
}
txd->llis_va = dma_pool_alloc(pl08x->pool, GFP_NOWAIT,
&txd->llis_bus);
if (!txd->llis_va) {
dev_err(&pl08x->adev->dev, "%s no memory for llis\n", __func__);
return 0;
}
pl08x->pool_ctr++;
/*
* Initialize bus values for this transfer
* from the passed optimal values
*/
if (!cd) {
dev_err(&pl08x->adev->dev, "%s no channel data\n", __func__);
return 0;
}
/* Get the default CCTL from the platform data */
cctl = cd->cctl;
/*
* On the PL080 we have two bus masters and we
* should select one for source and one for
* destination. We try to use AHB2 for the
* bus which does not increment (typically the
* peripheral) else we just choose something.
*/
cctl &= ~(PL080_CONTROL_DST_AHB2 | PL080_CONTROL_SRC_AHB2);
if (pl08x->vd->dualmaster) {
if (cctl & PL080_CONTROL_SRC_INCR)
/* Source increments, use AHB2 for destination */
cctl |= PL080_CONTROL_DST_AHB2;
else if (cctl & PL080_CONTROL_DST_INCR)
/* Destination increments, use AHB2 for source */
cctl |= PL080_CONTROL_SRC_AHB2;
else
/* Just pick something, source AHB1 dest AHB2 */
cctl |= PL080_CONTROL_DST_AHB2;
}
/* Find maximum width of the source bus */
txd->srcbus.maxwidth =
pl08x_get_bytes_for_cctl((cctl & PL080_CONTROL_SWIDTH_MASK) >>
PL080_CONTROL_SWIDTH_SHIFT);
/* Find maximum width of the destination bus */
txd->dstbus.maxwidth =
pl08x_get_bytes_for_cctl((cctl & PL080_CONTROL_DWIDTH_MASK) >>
PL080_CONTROL_DWIDTH_SHIFT);
/* Set up the bus widths to the maximum */
txd->srcbus.buswidth = txd->srcbus.maxwidth;
txd->dstbus.buswidth = txd->dstbus.maxwidth;
dev_vdbg(&pl08x->adev->dev,
"%s source bus is %d bytes wide, dest bus is %d bytes wide\n",
__func__, txd->srcbus.buswidth, txd->dstbus.buswidth);
/*
* Bytes transferred == tsize * MIN(buswidths), not max(buswidths)
*/
max_bytes_per_lli = min(txd->srcbus.buswidth, txd->dstbus.buswidth) *
PL080_CONTROL_TRANSFER_SIZE_MASK;
dev_vdbg(&pl08x->adev->dev,
"%s max bytes per lli = %d\n",
__func__, max_bytes_per_lli);
/* We need to count this down to zero */
remainder = txd->len;
dev_vdbg(&pl08x->adev->dev,
"%s remainder = %d\n",
__func__, remainder);
/*
* Choose bus to align to
* - prefers destination bus if both available
* - if fixed address on one bus chooses other
* - modifies cctl to choose an apropriate master
*/
pl08x_choose_master_bus(&txd->srcbus, &txd->dstbus,
&mbus, &sbus, cctl);
/*
* The lowest bit of the LLI register
* is also used to indicate which master to
* use for reading the LLIs.
*/
if (txd->len < mbus->buswidth) {
/*
* Less than a bus width available
* - send as single bytes
*/
while (remainder) {
dev_vdbg(&pl08x->adev->dev,
"%s single byte LLIs for a transfer of "
"less than a bus width (remain %08x)\n",
__func__, remainder);
cctl = pl08x_cctl_bits(cctl, 1, 1, 1);
num_llis =
pl08x_fill_lli_for_desc(pl08x, txd, num_llis, 1,
cctl, &remainder);
total_bytes++;
}
} else {
/*
* Make one byte LLIs until master bus is aligned
* - slave will then be aligned also
*/
while ((mbus->addr) % (mbus->buswidth)) {
dev_vdbg(&pl08x->adev->dev,
"%s adjustment lli for less than bus width "
"(remain %08x)\n",
__func__, remainder);
cctl = pl08x_cctl_bits(cctl, 1, 1, 1);
num_llis = pl08x_fill_lli_for_desc
(pl08x, txd, num_llis, 1, cctl, &remainder);
total_bytes++;
}
/*
* Master now aligned
* - if slave is not then we must set its width down
*/
if (sbus->addr % sbus->buswidth) {
dev_dbg(&pl08x->adev->dev,
"%s set down bus width to one byte\n",
__func__);
sbus->buswidth = 1;
}
/*
* Make largest possible LLIs until less than one bus
* width left
*/
while (remainder > (mbus->buswidth - 1)) {
int lli_len, target_len;
int tsize;
int odd_bytes;
/*
* If enough left try to send max possible,
* otherwise try to send the remainder
*/
target_len = remainder;
if (remainder > max_bytes_per_lli)
target_len = max_bytes_per_lli;
/*
* Set bus lengths for incrementing busses
* to number of bytes which fill to next memory
* boundary
*/
if (cctl & PL080_CONTROL_SRC_INCR)
txd->srcbus.fill_bytes =
pl08x_pre_boundary(
txd->srcbus.addr,
remainder);
else
txd->srcbus.fill_bytes =
max_bytes_per_lli;
if (cctl & PL080_CONTROL_DST_INCR)
txd->dstbus.fill_bytes =
pl08x_pre_boundary(
txd->dstbus.addr,
remainder);
else
txd->dstbus.fill_bytes =
max_bytes_per_lli;
/*
* Find the nearest
*/
lli_len = min(txd->srcbus.fill_bytes,
txd->dstbus.fill_bytes);
BUG_ON(lli_len > remainder);
if (lli_len <= 0) {
dev_err(&pl08x->adev->dev,
"%s lli_len is %d, <= 0\n",
__func__, lli_len);
return 0;
}
if (lli_len == target_len) {
/*
* Can send what we wanted
*/
/*
* Maintain alignment
*/
lli_len = (lli_len/mbus->buswidth) *
mbus->buswidth;
odd_bytes = 0;
} else {
/*
* So now we know how many bytes to transfer
* to get to the nearest boundary
* The next lli will past the boundary
* - however we may be working to a boundary
* on the slave bus
* We need to ensure the master stays aligned
*/
odd_bytes = lli_len % mbus->buswidth;
/*
* - and that we are working in multiples
* of the bus widths
*/
lli_len -= odd_bytes;
}
if (lli_len) {
/*
* Check against minimum bus alignment:
* Calculate actual transfer size in relation
* to bus width an get a maximum remainder of
* the smallest bus width - 1
*/
/* FIXME: use round_down()? */
tsize = lli_len / min(mbus->buswidth,
sbus->buswidth);
lli_len = tsize * min(mbus->buswidth,
sbus->buswidth);
if (target_len != lli_len) {
dev_vdbg(&pl08x->adev->dev,
"%s can't send what we want. Desired %08x, lli of %08x bytes in txd of %08x\n",
__func__, target_len, lli_len, txd->len);
}
cctl = pl08x_cctl_bits(cctl,
txd->srcbus.buswidth,
txd->dstbus.buswidth,
tsize);
dev_vdbg(&pl08x->adev->dev,
"%s fill lli with single lli chunk of size %08x (remainder %08x)\n",
__func__, lli_len, remainder);
num_llis = pl08x_fill_lli_for_desc(pl08x, txd,
num_llis, lli_len, cctl,
&remainder);
total_bytes += lli_len;
}
if (odd_bytes) {
/*
* Creep past the boundary,
* maintaining master alignment
*/
int j;
for (j = 0; (j < mbus->buswidth)
&& (remainder); j++) {
cctl = pl08x_cctl_bits(cctl, 1, 1, 1);
dev_vdbg(&pl08x->adev->dev,
"%s align with boundardy, single byte (remain %08x)\n",
__func__, remainder);
num_llis =
pl08x_fill_lli_for_desc(pl08x,
txd, num_llis, 1,
cctl, &remainder);
total_bytes++;
}
}
}
/*
* Send any odd bytes
*/
if (remainder < 0) {
dev_err(&pl08x->adev->dev, "%s remainder not fitted 0x%08x bytes\n",
__func__, remainder);
return 0;
}
while (remainder) {
cctl = pl08x_cctl_bits(cctl, 1, 1, 1);
dev_vdbg(&pl08x->adev->dev,
"%s align with boundardy, single odd byte (remain %d)\n",
__func__, remainder);
num_llis = pl08x_fill_lli_for_desc(pl08x, txd, num_llis,
1, cctl, &remainder);
total_bytes++;
}
}
if (total_bytes != txd->len) {
dev_err(&pl08x->adev->dev,
"%s size of encoded lli:s don't match total txd, transferred 0x%08x from size 0x%08x\n",
__func__, total_bytes, txd->len);
return 0;
}
if (num_llis >= MAX_NUM_TSFR_LLIS) {
dev_err(&pl08x->adev->dev,
"%s need to increase MAX_NUM_TSFR_LLIS from 0x%08x\n",
__func__, (u32) MAX_NUM_TSFR_LLIS);
return 0;
}
/*
* Decide whether this is a loop or a terminated transfer
*/
llis_va = txd->llis_va;
llis_bus = (struct lli *) txd->llis_bus;
if (cd->circular_buffer) {
/*
* Loop the circular buffer so that the next element
* points back to the beginning of the LLI.
*/
llis_va[num_llis - 1].next =
(dma_addr_t)((unsigned int)&(llis_bus[0]));
} else {
/*
* On non-circular buffers, the final LLI terminates
* the LLI.
*/
llis_va[num_llis - 1].next = 0;
/*
* The final LLI element shall also fire an interrupt
*/
llis_va[num_llis - 1].cctl |= PL080_CONTROL_TC_IRQ_EN;
}
/* Now store the channel register values */
txd->csrc = llis_va[0].src;
txd->cdst = llis_va[0].dst;
if (num_llis > 1)
txd->clli = llis_va[0].next;
else
txd->clli = 0;
txd->cctl = llis_va[0].cctl;
/* ccfg will be set at physical channel allocation time */
#ifdef VERBOSE_DEBUG
{
int i;
for (i = 0; i < num_llis; i++) {
dev_vdbg(&pl08x->adev->dev,
"lli %d @%p: csrc=%08x, cdst=%08x, cctl=%08x, clli=%08x\n",
i,
&llis_va[i],
llis_va[i].src,
llis_va[i].dst,
llis_va[i].cctl,
llis_va[i].next
);
}
}
#endif
return num_llis;
}
/* You should call this with the struct pl08x lock held */
static void pl08x_free_txd(struct pl08x_driver_data *pl08x,
struct pl08x_txd *txd)
{
if (!txd)
dev_err(&pl08x->adev->dev,
"%s no descriptor to free\n",
__func__);
/* Free the LLI */
dma_pool_free(pl08x->pool, txd->llis_va,
txd->llis_bus);
pl08x->pool_ctr--;
kfree(txd);
}
static void pl08x_free_txd_list(struct pl08x_driver_data *pl08x,
struct pl08x_dma_chan *plchan)
{
struct pl08x_txd *txdi = NULL;
struct pl08x_txd *next;
if (!list_empty(&plchan->desc_list)) {
list_for_each_entry_safe(txdi,
next, &plchan->desc_list, node) {
list_del(&txdi->node);
pl08x_free_txd(pl08x, txdi);
}
}
}
/*
* The DMA ENGINE API
*/
static int pl08x_alloc_chan_resources(struct dma_chan *chan)
{
return 0;
}
static void pl08x_free_chan_resources(struct dma_chan *chan)
{
}
/*
* This should be called with the channel plchan->lock held
*/
static int prep_phy_channel(struct pl08x_dma_chan *plchan,
struct pl08x_txd *txd)
{
struct pl08x_driver_data *pl08x = plchan->host;
struct pl08x_phy_chan *ch;
int ret;
/* Check if we already have a channel */
if (plchan->phychan)
return 0;
ch = pl08x_get_phy_channel(pl08x, plchan);
if (!ch) {
/* No physical channel available, cope with it */
dev_dbg(&pl08x->adev->dev, "no physical channel available for xfer on %s\n", plchan->name);
return -EBUSY;
}
/*
* OK we have a physical channel: for memcpy() this is all we
* need, but for slaves the physical signals may be muxed!
* Can the platform allow us to use this channel?
*/
if (plchan->slave &&
ch->signal < 0 &&
pl08x->pd->get_signal) {
ret = pl08x->pd->get_signal(plchan);
if (ret < 0) {
dev_dbg(&pl08x->adev->dev,
"unable to use physical channel %d for transfer on %s due to platform restrictions\n",
ch->id, plchan->name);
/* Release physical channel & return */
pl08x_put_phy_channel(pl08x, ch);
return -EBUSY;
}
ch->signal = ret;
}
dev_dbg(&pl08x->adev->dev, "allocated physical channel %d and signal %d for xfer on %s\n",
ch->id,
ch->signal,
plchan->name);
plchan->phychan = ch;
return 0;
}
static dma_cookie_t pl08x_tx_submit(struct dma_async_tx_descriptor *tx)
{
struct pl08x_dma_chan *plchan = to_pl08x_chan(tx->chan);
atomic_inc(&plchan->last_issued);
tx->cookie = atomic_read(&plchan->last_issued);
/* This unlock follows the lock in the prep() function */
spin_unlock_irqrestore(&plchan->lock, plchan->lockflags);
return tx->cookie;
}
static struct dma_async_tx_descriptor *pl08x_prep_dma_interrupt(
struct dma_chan *chan, unsigned long flags)
{
struct dma_async_tx_descriptor *retval = NULL;
return retval;
}
/*
* Code accessing dma_async_is_complete() in a tight loop
* may give problems - could schedule where indicated.
* If slaves are relying on interrupts to signal completion this
* function must not be called with interrupts disabled
*/
static enum dma_status
pl08x_dma_tx_status(struct dma_chan *chan,
dma_cookie_t cookie,
struct dma_tx_state *txstate)
{
struct pl08x_dma_chan *plchan = to_pl08x_chan(chan);
dma_cookie_t last_used;
dma_cookie_t last_complete;
enum dma_status ret;
u32 bytesleft = 0;
last_used = atomic_read(&plchan->last_issued);
last_complete = plchan->lc;
ret = dma_async_is_complete(cookie, last_complete, last_used);
if (ret == DMA_SUCCESS) {
dma_set_tx_state(txstate, last_complete, last_used, 0);
return ret;
}
/*
* schedule(); could be inserted here
*/
/*
* This cookie not complete yet
*/
last_used = atomic_read(&plchan->last_issued);
last_complete = plchan->lc;
/* Get number of bytes left in the active transactions and queue */
bytesleft = pl08x_getbytes_chan(plchan);
dma_set_tx_state(txstate, last_complete, last_used,
bytesleft);
if (plchan->state == PL08X_CHAN_PAUSED)
return DMA_PAUSED;
/* Whether waiting or running, we're in progress */
return DMA_IN_PROGRESS;
}
/* PrimeCell DMA extension */
struct burst_table {
int burstwords;
u32 reg;
};
static const struct burst_table burst_sizes[] = {
{
.burstwords = 256,
.reg = (PL080_BSIZE_256 << PL080_CONTROL_SB_SIZE_SHIFT) |
(PL080_BSIZE_256 << PL080_CONTROL_DB_SIZE_SHIFT),
},
{
.burstwords = 128,
.reg = (PL080_BSIZE_128 << PL080_CONTROL_SB_SIZE_SHIFT) |
(PL080_BSIZE_128 << PL080_CONTROL_DB_SIZE_SHIFT),
},
{
.burstwords = 64,
.reg = (PL080_BSIZE_64 << PL080_CONTROL_SB_SIZE_SHIFT) |
(PL080_BSIZE_64 << PL080_CONTROL_DB_SIZE_SHIFT),
},
{
.burstwords = 32,
.reg = (PL080_BSIZE_32 << PL080_CONTROL_SB_SIZE_SHIFT) |
(PL080_BSIZE_32 << PL080_CONTROL_DB_SIZE_SHIFT),
},
{
.burstwords = 16,
.reg = (PL080_BSIZE_16 << PL080_CONTROL_SB_SIZE_SHIFT) |
(PL080_BSIZE_16 << PL080_CONTROL_DB_SIZE_SHIFT),
},
{
.burstwords = 8,
.reg = (PL080_BSIZE_8 << PL080_CONTROL_SB_SIZE_SHIFT) |
(PL080_BSIZE_8 << PL080_CONTROL_DB_SIZE_SHIFT),
},
{
.burstwords = 4,
.reg = (PL080_BSIZE_4 << PL080_CONTROL_SB_SIZE_SHIFT) |
(PL080_BSIZE_4 << PL080_CONTROL_DB_SIZE_SHIFT),
},
{
.burstwords = 1,
.reg = (PL080_BSIZE_1 << PL080_CONTROL_SB_SIZE_SHIFT) |
(PL080_BSIZE_1 << PL080_CONTROL_DB_SIZE_SHIFT),
},
};
static void dma_set_runtime_config(struct dma_chan *chan,
struct dma_slave_config *config)
{
struct pl08x_dma_chan *plchan = to_pl08x_chan(chan);
struct pl08x_driver_data *pl08x = plchan->host;
struct pl08x_channel_data *cd = plchan->cd;
enum dma_slave_buswidth addr_width;
u32 maxburst;
u32 cctl = 0;
/* Mask out all except src and dst channel */
u32 ccfg = cd->ccfg & 0x000003DEU;
int i = 0;
/* Transfer direction */
plchan->runtime_direction = config->direction;
if (config->direction == DMA_TO_DEVICE) {
plchan->runtime_addr = config->dst_addr;
cctl |= PL080_CONTROL_SRC_INCR;
ccfg |= PL080_FLOW_MEM2PER << PL080_CONFIG_FLOW_CONTROL_SHIFT;
addr_width = config->dst_addr_width;
maxburst = config->dst_maxburst;
} else if (config->direction == DMA_FROM_DEVICE) {
plchan->runtime_addr = config->src_addr;
cctl |= PL080_CONTROL_DST_INCR;
ccfg |= PL080_FLOW_PER2MEM << PL080_CONFIG_FLOW_CONTROL_SHIFT;
addr_width = config->src_addr_width;
maxburst = config->src_maxburst;
} else {
dev_err(&pl08x->adev->dev,
"bad runtime_config: alien transfer direction\n");
return;
}
switch (addr_width) {
case DMA_SLAVE_BUSWIDTH_1_BYTE:
cctl |= (PL080_WIDTH_8BIT << PL080_CONTROL_SWIDTH_SHIFT) |
(PL080_WIDTH_8BIT << PL080_CONTROL_DWIDTH_SHIFT);
break;
case DMA_SLAVE_BUSWIDTH_2_BYTES:
cctl |= (PL080_WIDTH_16BIT << PL080_CONTROL_SWIDTH_SHIFT) |
(PL080_WIDTH_16BIT << PL080_CONTROL_DWIDTH_SHIFT);
break;
case DMA_SLAVE_BUSWIDTH_4_BYTES:
cctl |= (PL080_WIDTH_32BIT << PL080_CONTROL_SWIDTH_SHIFT) |
(PL080_WIDTH_32BIT << PL080_CONTROL_DWIDTH_SHIFT);
break;
default:
dev_err(&pl08x->adev->dev,
"bad runtime_config: alien address width\n");
return;
}
/*
* Now decide on a maxburst:
* If this channel will only request single transfers, set
* this down to ONE element.
*/
if (plchan->cd->single) {
cctl |= (PL080_BSIZE_1 << PL080_CONTROL_SB_SIZE_SHIFT) |
(PL080_BSIZE_1 << PL080_CONTROL_DB_SIZE_SHIFT);
} else {
while (i < ARRAY_SIZE(burst_sizes)) {
if (burst_sizes[i].burstwords <= maxburst)
break;
i++;
}
cctl |= burst_sizes[i].reg;
}
/* Access the cell in privileged mode, non-bufferable, non-cacheable */
cctl &= ~PL080_CONTROL_PROT_MASK;
cctl |= PL080_CONTROL_PROT_SYS;
/* Modify the default channel data to fit PrimeCell request */
cd->cctl = cctl;
cd->ccfg = ccfg;
dev_dbg(&pl08x->adev->dev,
"configured channel %s (%s) for %s, data width %d, "
"maxburst %d words, LE, CCTL=%08x, CCFG=%08x\n",
dma_chan_name(chan), plchan->name,
(config->direction == DMA_FROM_DEVICE) ? "RX" : "TX",
addr_width,
maxburst,
cctl, ccfg);
}
/*
* Slave transactions callback to the slave device to allow
* synchronization of slave DMA signals with the DMAC enable
*/
static void pl08x_issue_pending(struct dma_chan *chan)
{
struct pl08x_dma_chan *plchan = to_pl08x_chan(chan);
struct pl08x_driver_data *pl08x = plchan->host;
unsigned long flags;
spin_lock_irqsave(&plchan->lock, flags);
/* Something is already active */
if (plchan->at) {
spin_unlock_irqrestore(&plchan->lock, flags);
return;
}
/* Didn't get a physical channel so waiting for it ... */
if (plchan->state == PL08X_CHAN_WAITING)
return;
/* Take the first element in the queue and execute it */
if (!list_empty(&plchan->desc_list)) {
struct pl08x_txd *next;
next = list_first_entry(&plchan->desc_list,
struct pl08x_txd,
node);
list_del(&next->node);
plchan->at = next;
plchan->state = PL08X_CHAN_RUNNING;
/* Configure the physical channel for the active txd */
pl08x_config_phychan_for_txd(plchan);
pl08x_set_cregs(pl08x, plchan->phychan);
pl08x_enable_phy_chan(pl08x, plchan->phychan);
}
spin_unlock_irqrestore(&plchan->lock, flags);
}
static int pl08x_prep_channel_resources(struct pl08x_dma_chan *plchan,
struct pl08x_txd *txd)
{
int num_llis;
struct pl08x_driver_data *pl08x = plchan->host;
int ret;
num_llis = pl08x_fill_llis_for_desc(pl08x, txd);
if (!num_llis)
return -EINVAL;
spin_lock_irqsave(&plchan->lock, plchan->lockflags);
/*
* If this device is not using a circular buffer then
* queue this new descriptor for transfer.
* The descriptor for a circular buffer continues
* to be used until the channel is freed.
*/
if (txd->cd->circular_buffer)
dev_err(&pl08x->adev->dev,
"%s attempting to queue a circular buffer\n",
__func__);
else
list_add_tail(&txd->node,
&plchan->desc_list);
/*
* See if we already have a physical channel allocated,
* else this is the time to try to get one.
*/
ret = prep_phy_channel(plchan, txd);
if (ret) {
/*
* No physical channel available, we will
* stack up the memcpy channels until there is a channel
* available to handle it whereas slave transfers may
* have been denied due to platform channel muxing restrictions
* and since there is no guarantee that this will ever be
* resolved, and since the signal must be aquired AFTER
* aquiring the physical channel, we will let them be NACK:ed
* with -EBUSY here. The drivers can alway retry the prep()
* call if they are eager on doing this using DMA.
*/
if (plchan->slave) {
pl08x_free_txd_list(pl08x, plchan);
spin_unlock_irqrestore(&plchan->lock, plchan->lockflags);
return -EBUSY;
}
/* Do this memcpy whenever there is a channel ready */
plchan->state = PL08X_CHAN_WAITING;
plchan->waiting = txd;
} else
/*
* Else we're all set, paused and ready to roll,
* status will switch to PL08X_CHAN_RUNNING when
* we call issue_pending(). If there is something
* running on the channel already we don't change
* its state.
*/
if (plchan->state == PL08X_CHAN_IDLE)
plchan->state = PL08X_CHAN_PAUSED;
/*
* Notice that we leave plchan->lock locked on purpose:
* it will be unlocked in the subsequent tx_submit()
* call. This is a consequence of the current API.
*/
return 0;
}
/*
* Initialize a descriptor to be used by memcpy submit
*/
static struct dma_async_tx_descriptor *pl08x_prep_dma_memcpy(
struct dma_chan *chan, dma_addr_t dest, dma_addr_t src,
size_t len, unsigned long flags)
{
struct pl08x_dma_chan *plchan = to_pl08x_chan(chan);
struct pl08x_driver_data *pl08x = plchan->host;
struct pl08x_txd *txd;
int ret;
txd = kzalloc(sizeof(struct pl08x_txd), GFP_NOWAIT);
if (!txd) {
dev_err(&pl08x->adev->dev,
"%s no memory for descriptor\n", __func__);
return NULL;
}
dma_async_tx_descriptor_init(&txd->tx, chan);
txd->direction = DMA_NONE;
txd->srcbus.addr = src;
txd->dstbus.addr = dest;
/* Set platform data for m2m */
txd->cd = &pl08x->pd->memcpy_channel;
/* Both to be incremented or the code will break */
txd->cd->cctl |= PL080_CONTROL_SRC_INCR | PL080_CONTROL_DST_INCR;
txd->tx.tx_submit = pl08x_tx_submit;
txd->tx.callback = NULL;
txd->tx.callback_param = NULL;
txd->len = len;
INIT_LIST_HEAD(&txd->node);
ret = pl08x_prep_channel_resources(plchan, txd);
if (ret)
return NULL;
/*
* NB: the channel lock is held at this point so tx_submit()
* must be called in direct succession.
*/
return &txd->tx;
}
struct dma_async_tx_descriptor *pl08x_prep_slave_sg(
struct dma_chan *chan, struct scatterlist *sgl,
unsigned int sg_len, enum dma_data_direction direction,
unsigned long flags)
{
struct pl08x_dma_chan *plchan = to_pl08x_chan(chan);
struct pl08x_driver_data *pl08x = plchan->host;
struct pl08x_txd *txd;
int ret;
/*
* Current implementation ASSUMES only one sg
*/
if (sg_len != 1) {
dev_err(&pl08x->adev->dev, "%s prepared too long sglist\n",
__func__);
BUG();
}
dev_dbg(&pl08x->adev->dev, "%s prepare transaction of %d bytes from %s\n",
__func__, sgl->length, plchan->name);
txd = kzalloc(sizeof(struct pl08x_txd), GFP_NOWAIT);
if (!txd) {
dev_err(&pl08x->adev->dev, "%s no txd\n", __func__);
return NULL;
}
dma_async_tx_descriptor_init(&txd->tx, chan);
if (direction != plchan->runtime_direction)
dev_err(&pl08x->adev->dev, "%s DMA setup does not match "
"the direction configured for the PrimeCell\n",
__func__);
/*
* Set up addresses, the PrimeCell configured address
* will take precedence since this may configure the
* channel target address dynamically at runtime.
*/
txd->direction = direction;
if (direction == DMA_TO_DEVICE) {
txd->srcbus.addr = sgl->dma_address;
if (plchan->runtime_addr)
txd->dstbus.addr = plchan->runtime_addr;
else
txd->dstbus.addr = plchan->cd->addr;
} else if (direction == DMA_FROM_DEVICE) {
if (plchan->runtime_addr)
txd->srcbus.addr = plchan->runtime_addr;
else
txd->srcbus.addr = plchan->cd->addr;
txd->dstbus.addr = sgl->dma_address;
} else {
dev_err(&pl08x->adev->dev,
"%s direction unsupported\n", __func__);
return NULL;
}
txd->cd = plchan->cd;
txd->tx.tx_submit = pl08x_tx_submit;
txd->tx.callback = NULL;
txd->tx.callback_param = NULL;
txd->len = sgl->length;
INIT_LIST_HEAD(&txd->node);
ret = pl08x_prep_channel_resources(plchan, txd);
if (ret)
return NULL;
/*
* NB: the channel lock is held at this point so tx_submit()
* must be called in direct succession.
*/
return &txd->tx;
}
static int pl08x_control(struct dma_chan *chan, enum dma_ctrl_cmd cmd,
unsigned long arg)
{
struct pl08x_dma_chan *plchan = to_pl08x_chan(chan);
struct pl08x_driver_data *pl08x = plchan->host;
unsigned long flags;
int ret = 0;
/* Controls applicable to inactive channels */
if (cmd == DMA_SLAVE_CONFIG) {
dma_set_runtime_config(chan,
(struct dma_slave_config *)
arg);
return 0;
}
/*
* Anything succeeds on channels with no physical allocation and
* no queued transfers.
*/
spin_lock_irqsave(&plchan->lock, flags);
if (!plchan->phychan && !plchan->at) {
spin_unlock_irqrestore(&plchan->lock, flags);
return 0;
}
switch (cmd) {
case DMA_TERMINATE_ALL:
plchan->state = PL08X_CHAN_IDLE;
if (plchan->phychan) {
pl08x_stop_phy_chan(plchan->phychan);
/*
* Mark physical channel as free and free any slave
* signal
*/
if ((plchan->phychan->signal >= 0) &&
pl08x->pd->put_signal) {
pl08x->pd->put_signal(plchan);
plchan->phychan->signal = -1;
}
pl08x_put_phy_channel(pl08x, plchan->phychan);
plchan->phychan = NULL;
}
/* Stop any pending tasklet */
tasklet_disable(&plchan->tasklet);
/* Dequeue jobs and free LLIs */
if (plchan->at) {
pl08x_free_txd(pl08x, plchan->at);
plchan->at = NULL;
}
/* Dequeue jobs not yet fired as well */
pl08x_free_txd_list(pl08x, plchan);
break;
case DMA_PAUSE:
pl08x_pause_phy_chan(plchan->phychan);
plchan->state = PL08X_CHAN_PAUSED;
break;
case DMA_RESUME:
pl08x_resume_phy_chan(plchan->phychan);
plchan->state = PL08X_CHAN_RUNNING;
break;
default:
/* Unknown command */
ret = -ENXIO;
break;
}
spin_unlock_irqrestore(&plchan->lock, flags);
return ret;
}
bool pl08x_filter_id(struct dma_chan *chan, void *chan_id)
{
struct pl08x_dma_chan *plchan = to_pl08x_chan(chan);
char *name = chan_id;
/* Check that the channel is not taken! */
if (!strcmp(plchan->name, name))
return true;
return false;
}
/*
* Just check that the device is there and active
* TODO: turn this bit on/off depending on the number of
* physical channels actually used, if it is zero... well
* shut it off. That will save some power. Cut the clock
* at the same time.
*/
static void pl08x_ensure_on(struct pl08x_driver_data *pl08x)
{
u32 val;
val = readl(pl08x->base + PL080_CONFIG);
val &= ~(PL080_CONFIG_M2_BE | PL080_CONFIG_M1_BE | PL080_CONFIG_ENABLE);
/* We implictly clear bit 1 and that means little-endian mode */
val |= PL080_CONFIG_ENABLE;
writel(val, pl08x->base + PL080_CONFIG);
}
static void pl08x_tasklet(unsigned long data)
{
struct pl08x_dma_chan *plchan = (struct pl08x_dma_chan *) data;
struct pl08x_phy_chan *phychan = plchan->phychan;
struct pl08x_driver_data *pl08x = plchan->host;
if (!plchan)
BUG();
spin_lock(&plchan->lock);
if (plchan->at) {
dma_async_tx_callback callback =
plchan->at->tx.callback;
void *callback_param =
plchan->at->tx.callback_param;
/*
* Update last completed
*/
plchan->lc =
(plchan->at->tx.cookie);
/*
* Callback to signal completion
*/
if (callback)
callback(callback_param);
/*
* Device callbacks should NOT clear
* the current transaction on the channel
* Linus: sometimes they should?
*/
if (!plchan->at)
BUG();
/*
* Free the descriptor if it's not for a device
* using a circular buffer
*/
if (!plchan->at->cd->circular_buffer) {
pl08x_free_txd(pl08x, plchan->at);
plchan->at = NULL;
}
/*
* else descriptor for circular
* buffers only freed when
* client has disabled dma
*/
}
/*
* If a new descriptor is queued, set it up
* plchan->at is NULL here
*/
if (!list_empty(&plchan->desc_list)) {
struct pl08x_txd *next;
next = list_first_entry(&plchan->desc_list,
struct pl08x_txd,
node);
list_del(&next->node);
plchan->at = next;
/* Configure the physical channel for the next txd */
pl08x_config_phychan_for_txd(plchan);
pl08x_set_cregs(pl08x, plchan->phychan);
pl08x_enable_phy_chan(pl08x, plchan->phychan);
} else {
struct pl08x_dma_chan *waiting = NULL;
/*
* No more jobs, so free up the physical channel
* Free any allocated signal on slave transfers too
*/
if ((phychan->signal >= 0) && pl08x->pd->put_signal) {
pl08x->pd->put_signal(plchan);
phychan->signal = -1;
}
pl08x_put_phy_channel(pl08x, phychan);
plchan->phychan = NULL;
plchan->state = PL08X_CHAN_IDLE;
/*
* And NOW before anyone else can grab that free:d
* up physical channel, see if there is some memcpy
* pending that seriously needs to start because of
* being stacked up while we were choking the
* physical channels with data.
*/
list_for_each_entry(waiting, &pl08x->memcpy.channels,
chan.device_node) {
if (waiting->state == PL08X_CHAN_WAITING &&
waiting->waiting != NULL) {
int ret;
/* This should REALLY not fail now */
ret = prep_phy_channel(waiting,
waiting->waiting);
BUG_ON(ret);
waiting->state = PL08X_CHAN_RUNNING;
waiting->waiting = NULL;
pl08x_issue_pending(&waiting->chan);
break;
}
}
}
spin_unlock(&plchan->lock);
}
static irqreturn_t pl08x_irq(int irq, void *dev)
{
struct pl08x_driver_data *pl08x = dev;
u32 mask = 0;
u32 val;
int i;
val = readl(pl08x->base + PL080_ERR_STATUS);
if (val) {
/*
* An error interrupt (on one or more channels)
*/
dev_err(&pl08x->adev->dev,
"%s error interrupt, register value 0x%08x\n",
__func__, val);
/*
* Simply clear ALL PL08X error interrupts,
* regardless of channel and cause
* FIXME: should be 0x00000003 on PL081 really.
*/
writel(0x000000FF, pl08x->base + PL080_ERR_CLEAR);
}
val = readl(pl08x->base + PL080_INT_STATUS);
for (i = 0; i < pl08x->vd->channels; i++) {
if ((1 << i) & val) {
/* Locate physical channel */
struct pl08x_phy_chan *phychan = &pl08x->phy_chans[i];
struct pl08x_dma_chan *plchan = phychan->serving;
/* Schedule tasklet on this channel */
tasklet_schedule(&plchan->tasklet);
mask |= (1 << i);
}
}
/*
* Clear only the terminal interrupts on channels we processed
*/
writel(mask, pl08x->base + PL080_TC_CLEAR);
return mask ? IRQ_HANDLED : IRQ_NONE;
}
/*
* Initialise the DMAC memcpy/slave channels.
* Make a local wrapper to hold required data
*/
static int pl08x_dma_init_virtual_channels(struct pl08x_driver_data *pl08x,
struct dma_device *dmadev,
unsigned int channels,
bool slave)
{
struct pl08x_dma_chan *chan;
int i;
INIT_LIST_HEAD(&dmadev->channels);
/*
* Register as many many memcpy as we have physical channels,
* we won't always be able to use all but the code will have
* to cope with that situation.
*/
for (i = 0; i < channels; i++) {
chan = kzalloc(sizeof(struct pl08x_dma_chan), GFP_KERNEL);
if (!chan) {
dev_err(&pl08x->adev->dev,
"%s no memory for channel\n", __func__);
return -ENOMEM;
}
chan->host = pl08x;
chan->state = PL08X_CHAN_IDLE;
if (slave) {
chan->slave = true;
chan->name = pl08x->pd->slave_channels[i].bus_id;
chan->cd = &pl08x->pd->slave_channels[i];
} else {
chan->cd = &pl08x->pd->memcpy_channel;
chan->name = kasprintf(GFP_KERNEL, "memcpy%d", i);
if (!chan->name) {
kfree(chan);
return -ENOMEM;
}
}
dev_info(&pl08x->adev->dev,
"initialize virtual channel \"%s\"\n",
chan->name);
chan->chan.device = dmadev;
atomic_set(&chan->last_issued, 0);
chan->lc = atomic_read(&chan->last_issued);
spin_lock_init(&chan->lock);
INIT_LIST_HEAD(&chan->desc_list);
tasklet_init(&chan->tasklet, pl08x_tasklet,
(unsigned long) chan);
list_add_tail(&chan->chan.device_node, &dmadev->channels);
}
dev_info(&pl08x->adev->dev, "initialized %d virtual %s channels\n",
i, slave ? "slave" : "memcpy");
return i;
}
static void pl08x_free_virtual_channels(struct dma_device *dmadev)
{
struct pl08x_dma_chan *chan = NULL;
struct pl08x_dma_chan *next;
list_for_each_entry_safe(chan,
next, &dmadev->channels, chan.device_node) {
list_del(&chan->chan.device_node);
kfree(chan);
}
}
#ifdef CONFIG_DEBUG_FS
static const char *pl08x_state_str(enum pl08x_dma_chan_state state)
{
switch (state) {
case PL08X_CHAN_IDLE:
return "idle";
case PL08X_CHAN_RUNNING:
return "running";
case PL08X_CHAN_PAUSED:
return "paused";
case PL08X_CHAN_WAITING:
return "waiting";
default:
break;
}
return "UNKNOWN STATE";
}
static int pl08x_debugfs_show(struct seq_file *s, void *data)
{
struct pl08x_driver_data *pl08x = s->private;
struct pl08x_dma_chan *chan;
struct pl08x_phy_chan *ch;
unsigned long flags;
int i;
seq_printf(s, "PL08x physical channels:\n");
seq_printf(s, "CHANNEL:\tUSER:\n");
seq_printf(s, "--------\t-----\n");
for (i = 0; i < pl08x->vd->channels; i++) {
struct pl08x_dma_chan *virt_chan;
ch = &pl08x->phy_chans[i];
spin_lock_irqsave(&ch->lock, flags);
virt_chan = ch->serving;
seq_printf(s, "%d\t\t%s\n",
ch->id, virt_chan ? virt_chan->name : "(none)");
spin_unlock_irqrestore(&ch->lock, flags);
}
seq_printf(s, "\nPL08x virtual memcpy channels:\n");
seq_printf(s, "CHANNEL:\tSTATE:\n");
seq_printf(s, "--------\t------\n");
list_for_each_entry(chan, &pl08x->memcpy.channels, chan.device_node) {
seq_printf(s, "%s\t\t\%s\n", chan->name,
pl08x_state_str(chan->state));
}
seq_printf(s, "\nPL08x virtual slave channels:\n");
seq_printf(s, "CHANNEL:\tSTATE:\n");
seq_printf(s, "--------\t------\n");
list_for_each_entry(chan, &pl08x->slave.channels, chan.device_node) {
seq_printf(s, "%s\t\t\%s\n", chan->name,
pl08x_state_str(chan->state));
}
return 0;
}
static int pl08x_debugfs_open(struct inode *inode, struct file *file)
{
return single_open(file, pl08x_debugfs_show, inode->i_private);
}
static const struct file_operations pl08x_debugfs_operations = {
.open = pl08x_debugfs_open,
.read = seq_read,
.llseek = seq_lseek,
.release = single_release,
};
static void init_pl08x_debugfs(struct pl08x_driver_data *pl08x)
{
/* Expose a simple debugfs interface to view all clocks */
(void) debugfs_create_file(dev_name(&pl08x->adev->dev), S_IFREG | S_IRUGO,
NULL, pl08x,
&pl08x_debugfs_operations);
}
#else
static inline void init_pl08x_debugfs(struct pl08x_driver_data *pl08x)
{
}
#endif
static int pl08x_probe(struct amba_device *adev, struct amba_id *id)
{
struct pl08x_driver_data *pl08x;
struct vendor_data *vd = id->data;
int ret = 0;
int i;
ret = amba_request_regions(adev, NULL);
if (ret)
return ret;
/* Create the driver state holder */
pl08x = kzalloc(sizeof(struct pl08x_driver_data), GFP_KERNEL);
if (!pl08x) {
ret = -ENOMEM;
goto out_no_pl08x;
}
/* Initialize memcpy engine */
dma_cap_set(DMA_MEMCPY, pl08x->memcpy.cap_mask);
pl08x->memcpy.dev = &adev->dev;
pl08x->memcpy.device_alloc_chan_resources = pl08x_alloc_chan_resources;
pl08x->memcpy.device_free_chan_resources = pl08x_free_chan_resources;
pl08x->memcpy.device_prep_dma_memcpy = pl08x_prep_dma_memcpy;
pl08x->memcpy.device_prep_dma_interrupt = pl08x_prep_dma_interrupt;
pl08x->memcpy.device_tx_status = pl08x_dma_tx_status;
pl08x->memcpy.device_issue_pending = pl08x_issue_pending;
pl08x->memcpy.device_control = pl08x_control;
/* Initialize slave engine */
dma_cap_set(DMA_SLAVE, pl08x->slave.cap_mask);
pl08x->slave.dev = &adev->dev;
pl08x->slave.device_alloc_chan_resources = pl08x_alloc_chan_resources;
pl08x->slave.device_free_chan_resources = pl08x_free_chan_resources;
pl08x->slave.device_prep_dma_interrupt = pl08x_prep_dma_interrupt;
pl08x->slave.device_tx_status = pl08x_dma_tx_status;
pl08x->slave.device_issue_pending = pl08x_issue_pending;
pl08x->slave.device_prep_slave_sg = pl08x_prep_slave_sg;
pl08x->slave.device_control = pl08x_control;
/* Get the platform data */
pl08x->pd = dev_get_platdata(&adev->dev);
if (!pl08x->pd) {
dev_err(&adev->dev, "no platform data supplied\n");
goto out_no_platdata;
}
/* Assign useful pointers to the driver state */
pl08x->adev = adev;
pl08x->vd = vd;
/* A DMA memory pool for LLIs, align on 1-byte boundary */
pl08x->pool = dma_pool_create(DRIVER_NAME, &pl08x->adev->dev,
PL08X_LLI_TSFR_SIZE, PL08X_ALIGN, 0);
if (!pl08x->pool) {
ret = -ENOMEM;
goto out_no_lli_pool;
}
spin_lock_init(&pl08x->lock);
pl08x->base = ioremap(adev->res.start, resource_size(&adev->res));
if (!pl08x->base) {
ret = -ENOMEM;
goto out_no_ioremap;
}
/* Turn on the PL08x */
pl08x_ensure_on(pl08x);
/*
* Attach the interrupt handler
*/
writel(0x000000FF, pl08x->base + PL080_ERR_CLEAR);
writel(0x000000FF, pl08x->base + PL080_TC_CLEAR);
ret = request_irq(adev->irq[0], pl08x_irq, IRQF_DISABLED,
vd->name, pl08x);
if (ret) {
dev_err(&adev->dev, "%s failed to request interrupt %d\n",
__func__, adev->irq[0]);
goto out_no_irq;
}
/* Initialize physical channels */
pl08x->phy_chans = kmalloc((vd->channels * sizeof(struct pl08x_phy_chan)),
GFP_KERNEL);
if (!pl08x->phy_chans) {
dev_err(&adev->dev, "%s failed to allocate "
"physical channel holders\n",
__func__);
goto out_no_phychans;
}
for (i = 0; i < vd->channels; i++) {
struct pl08x_phy_chan *ch = &pl08x->phy_chans[i];
ch->id = i;
ch->base = pl08x->base + PL080_Cx_BASE(i);
spin_lock_init(&ch->lock);
ch->serving = NULL;
ch->signal = -1;
dev_info(&adev->dev,
"physical channel %d is %s\n", i,
pl08x_phy_channel_busy(ch) ? "BUSY" : "FREE");
}
/* Register as many memcpy channels as there are physical channels */
ret = pl08x_dma_init_virtual_channels(pl08x, &pl08x->memcpy,
pl08x->vd->channels, false);
if (ret <= 0) {
dev_warn(&pl08x->adev->dev,
"%s failed to enumerate memcpy channels - %d\n",
__func__, ret);
goto out_no_memcpy;
}
pl08x->memcpy.chancnt = ret;
/* Register slave channels */
ret = pl08x_dma_init_virtual_channels(pl08x, &pl08x->slave,
pl08x->pd->num_slave_channels,
true);
if (ret <= 0) {
dev_warn(&pl08x->adev->dev,
"%s failed to enumerate slave channels - %d\n",
__func__, ret);
goto out_no_slave;
}
pl08x->slave.chancnt = ret;
ret = dma_async_device_register(&pl08x->memcpy);
if (ret) {
dev_warn(&pl08x->adev->dev,
"%s failed to register memcpy as an async device - %d\n",
__func__, ret);
goto out_no_memcpy_reg;
}
ret = dma_async_device_register(&pl08x->slave);
if (ret) {
dev_warn(&pl08x->adev->dev,
"%s failed to register slave as an async device - %d\n",
__func__, ret);
goto out_no_slave_reg;
}
amba_set_drvdata(adev, pl08x);
init_pl08x_debugfs(pl08x);
dev_info(&pl08x->adev->dev, "ARM(R) %s DMA block initialized @%08x\n",
vd->name, adev->res.start);
return 0;
out_no_slave_reg:
dma_async_device_unregister(&pl08x->memcpy);
out_no_memcpy_reg:
pl08x_free_virtual_channels(&pl08x->slave);
out_no_slave:
pl08x_free_virtual_channels(&pl08x->memcpy);
out_no_memcpy:
kfree(pl08x->phy_chans);
out_no_phychans:
free_irq(adev->irq[0], pl08x);
out_no_irq:
iounmap(pl08x->base);
out_no_ioremap:
dma_pool_destroy(pl08x->pool);
out_no_lli_pool:
out_no_platdata:
kfree(pl08x);
out_no_pl08x:
amba_release_regions(adev);
return ret;
}
/* PL080 has 8 channels and the PL080 have just 2 */
static struct vendor_data vendor_pl080 = {
.name = "PL080",
.channels = 8,
.dualmaster = true,
};
static struct vendor_data vendor_pl081 = {
.name = "PL081",
.channels = 2,
.dualmaster = false,
};
static struct amba_id pl08x_ids[] = {
/* PL080 */
{
.id = 0x00041080,
.mask = 0x000fffff,
.data = &vendor_pl080,
},
/* PL081 */
{
.id = 0x00041081,
.mask = 0x000fffff,
.data = &vendor_pl081,
},
/* Nomadik 8815 PL080 variant */
{
.id = 0x00280880,
.mask = 0x00ffffff,
.data = &vendor_pl080,
},
{ 0, 0 },
};
static struct amba_driver pl08x_amba_driver = {
.drv.name = DRIVER_NAME,
.id_table = pl08x_ids,
.probe = pl08x_probe,
};
static int __init pl08x_init(void)
{
int retval;
retval = amba_driver_register(&pl08x_amba_driver);
if (retval)
printk(KERN_WARNING DRIVER_NAME
"failed to register as an amba device (%d)\n",
retval);
return retval;
}
subsys_initcall(pl08x_init);
...@@ -690,8 +690,12 @@ int dma_async_device_register(struct dma_device *device) ...@@ -690,8 +690,12 @@ int dma_async_device_register(struct dma_device *device)
!device->device_prep_dma_memset); !device->device_prep_dma_memset);
BUG_ON(dma_has_cap(DMA_INTERRUPT, device->cap_mask) && BUG_ON(dma_has_cap(DMA_INTERRUPT, device->cap_mask) &&
!device->device_prep_dma_interrupt); !device->device_prep_dma_interrupt);
BUG_ON(dma_has_cap(DMA_SG, device->cap_mask) &&
!device->device_prep_dma_sg);
BUG_ON(dma_has_cap(DMA_SLAVE, device->cap_mask) && BUG_ON(dma_has_cap(DMA_SLAVE, device->cap_mask) &&
!device->device_prep_slave_sg); !device->device_prep_slave_sg);
BUG_ON(dma_has_cap(DMA_CYCLIC, device->cap_mask) &&
!device->device_prep_dma_cyclic);
BUG_ON(dma_has_cap(DMA_SLAVE, device->cap_mask) && BUG_ON(dma_has_cap(DMA_SLAVE, device->cap_mask) &&
!device->device_control); !device->device_control);
......
...@@ -35,9 +35,10 @@ ...@@ -35,9 +35,10 @@
#include <linux/dmapool.h> #include <linux/dmapool.h>
#include <linux/of_platform.h> #include <linux/of_platform.h>
#include <asm/fsldma.h>
#include "fsldma.h" #include "fsldma.h"
static const char msg_ld_oom[] = "No free memory for link descriptor\n";
static void dma_init(struct fsldma_chan *chan) static void dma_init(struct fsldma_chan *chan)
{ {
/* Reset the channel */ /* Reset the channel */
...@@ -499,7 +500,7 @@ fsl_dma_prep_interrupt(struct dma_chan *dchan, unsigned long flags) ...@@ -499,7 +500,7 @@ fsl_dma_prep_interrupt(struct dma_chan *dchan, unsigned long flags)
new = fsl_dma_alloc_descriptor(chan); new = fsl_dma_alloc_descriptor(chan);
if (!new) { if (!new) {
dev_err(chan->dev, "No free memory for link descriptor\n"); dev_err(chan->dev, msg_ld_oom);
return NULL; return NULL;
} }
...@@ -536,8 +537,7 @@ static struct dma_async_tx_descriptor *fsl_dma_prep_memcpy( ...@@ -536,8 +537,7 @@ static struct dma_async_tx_descriptor *fsl_dma_prep_memcpy(
/* Allocate the link descriptor from DMA pool */ /* Allocate the link descriptor from DMA pool */
new = fsl_dma_alloc_descriptor(chan); new = fsl_dma_alloc_descriptor(chan);
if (!new) { if (!new) {
dev_err(chan->dev, dev_err(chan->dev, msg_ld_oom);
"No free memory for link descriptor\n");
goto fail; goto fail;
} }
#ifdef FSL_DMA_LD_DEBUG #ifdef FSL_DMA_LD_DEBUG
...@@ -583,223 +583,205 @@ static struct dma_async_tx_descriptor *fsl_dma_prep_memcpy( ...@@ -583,223 +583,205 @@ static struct dma_async_tx_descriptor *fsl_dma_prep_memcpy(
return NULL; return NULL;
} }
/** static struct dma_async_tx_descriptor *fsl_dma_prep_sg(struct dma_chan *dchan,
* fsl_dma_prep_slave_sg - prepare descriptors for a DMA_SLAVE transaction struct scatterlist *dst_sg, unsigned int dst_nents,
* @chan: DMA channel struct scatterlist *src_sg, unsigned int src_nents,
* @sgl: scatterlist to transfer to/from unsigned long flags)
* @sg_len: number of entries in @scatterlist
* @direction: DMA direction
* @flags: DMAEngine flags
*
* Prepare a set of descriptors for a DMA_SLAVE transaction. Following the
* DMA_SLAVE API, this gets the device-specific information from the
* chan->private variable.
*/
static struct dma_async_tx_descriptor *fsl_dma_prep_slave_sg(
struct dma_chan *dchan, struct scatterlist *sgl, unsigned int sg_len,
enum dma_data_direction direction, unsigned long flags)
{ {
struct fsldma_chan *chan;
struct fsl_desc_sw *first = NULL, *prev = NULL, *new = NULL; struct fsl_desc_sw *first = NULL, *prev = NULL, *new = NULL;
struct fsl_dma_slave *slave; struct fsldma_chan *chan = to_fsl_chan(dchan);
size_t copy; size_t dst_avail, src_avail;
dma_addr_t dst, src;
int i; size_t len;
struct scatterlist *sg;
size_t sg_used;
size_t hw_used;
struct fsl_dma_hw_addr *hw;
dma_addr_t dma_dst, dma_src;
if (!dchan) /* basic sanity checks */
if (dst_nents == 0 || src_nents == 0)
return NULL; return NULL;
if (!dchan->private) if (dst_sg == NULL || src_sg == NULL)
return NULL; return NULL;
chan = to_fsl_chan(dchan); /*
slave = dchan->private; * TODO: should we check that both scatterlists have the same
* TODO: number of bytes in total? Is that really an error?
*/
if (list_empty(&slave->addresses)) /* get prepared for the loop */
return NULL; dst_avail = sg_dma_len(dst_sg);
src_avail = sg_dma_len(src_sg);
hw = list_first_entry(&slave->addresses, struct fsl_dma_hw_addr, entry); /* run until we are out of scatterlist entries */
hw_used = 0; while (true) {
/* /* create the largest transaction possible */
* Build the hardware transaction to copy from the scatterlist to len = min_t(size_t, src_avail, dst_avail);
* the hardware, or from the hardware to the scatterlist len = min_t(size_t, len, FSL_DMA_BCR_MAX_CNT);
* if (len == 0)
* If you are copying from the hardware to the scatterlist and it goto fetch;
* takes two hardware entries to fill an entire page, then both
* hardware entries will be coalesced into the same page dst = sg_dma_address(dst_sg) + sg_dma_len(dst_sg) - dst_avail;
* src = sg_dma_address(src_sg) + sg_dma_len(src_sg) - src_avail;
* If you are copying from the scatterlist to the hardware and a
* single page can fill two hardware entries, then the data will /* allocate and populate the descriptor */
* be read out of the page into the first hardware entry, and so on new = fsl_dma_alloc_descriptor(chan);
*/ if (!new) {
for_each_sg(sgl, sg, sg_len, i) { dev_err(chan->dev, msg_ld_oom);
sg_used = 0; goto fail;
}
/* Loop until the entire scatterlist entry is used */
while (sg_used < sg_dma_len(sg)) {
/*
* If we've used up the current hardware address/length
* pair, we need to load a new one
*
* This is done in a while loop so that descriptors with
* length == 0 will be skipped
*/
while (hw_used >= hw->length) {
/*
* If the current hardware entry is the last
* entry in the list, we're finished
*/
if (list_is_last(&hw->entry, &slave->addresses))
goto finished;
/* Get the next hardware address/length pair */
hw = list_entry(hw->entry.next,
struct fsl_dma_hw_addr, entry);
hw_used = 0;
}
/* Allocate the link descriptor from DMA pool */
new = fsl_dma_alloc_descriptor(chan);
if (!new) {
dev_err(chan->dev, "No free memory for "
"link descriptor\n");
goto fail;
}
#ifdef FSL_DMA_LD_DEBUG #ifdef FSL_DMA_LD_DEBUG
dev_dbg(chan->dev, "new link desc alloc %p\n", new); dev_dbg(chan->dev, "new link desc alloc %p\n", new);
#endif #endif
/* set_desc_cnt(chan, &new->hw, len);
* Calculate the maximum number of bytes to transfer, set_desc_src(chan, &new->hw, src);
* making sure it is less than the DMA controller limit set_desc_dst(chan, &new->hw, dst);
*/
copy = min_t(size_t, sg_dma_len(sg) - sg_used,
hw->length - hw_used);
copy = min_t(size_t, copy, FSL_DMA_BCR_MAX_CNT);
/*
* DMA_FROM_DEVICE
* from the hardware to the scatterlist
*
* DMA_TO_DEVICE
* from the scatterlist to the hardware
*/
if (direction == DMA_FROM_DEVICE) {
dma_src = hw->address + hw_used;
dma_dst = sg_dma_address(sg) + sg_used;
} else {
dma_src = sg_dma_address(sg) + sg_used;
dma_dst = hw->address + hw_used;
}
/* Fill in the descriptor */
set_desc_cnt(chan, &new->hw, copy);
set_desc_src(chan, &new->hw, dma_src);
set_desc_dst(chan, &new->hw, dma_dst);
/*
* If this is not the first descriptor, chain the
* current descriptor after the previous descriptor
*/
if (!first) {
first = new;
} else {
set_desc_next(chan, &prev->hw,
new->async_tx.phys);
}
new->async_tx.cookie = 0;
async_tx_ack(&new->async_tx);
prev = new;
sg_used += copy;
hw_used += copy;
/* Insert the link descriptor into the LD ring */
list_add_tail(&new->node, &first->tx_list);
}
}
finished: if (!first)
first = new;
else
set_desc_next(chan, &prev->hw, new->async_tx.phys);
/* All of the hardware address/length pairs had length == 0 */ new->async_tx.cookie = 0;
if (!first || !new) async_tx_ack(&new->async_tx);
return NULL; prev = new;
new->async_tx.flags = flags; /* Insert the link descriptor to the LD ring */
new->async_tx.cookie = -EBUSY; list_add_tail(&new->node, &first->tx_list);
/* Set End-of-link to the last link descriptor of new list */ /* update metadata */
set_ld_eol(chan, new); dst_avail -= len;
src_avail -= len;
fetch:
/* fetch the next dst scatterlist entry */
if (dst_avail == 0) {
/* no more entries: we're done */
if (dst_nents == 0)
break;
/* fetch the next entry: if there are no more: done */
dst_sg = sg_next(dst_sg);
if (dst_sg == NULL)
break;
dst_nents--;
dst_avail = sg_dma_len(dst_sg);
}
/* Enable extra controller features */ /* fetch the next src scatterlist entry */
if (chan->set_src_loop_size) if (src_avail == 0) {
chan->set_src_loop_size(chan, slave->src_loop_size);
if (chan->set_dst_loop_size) /* no more entries: we're done */
chan->set_dst_loop_size(chan, slave->dst_loop_size); if (src_nents == 0)
break;
if (chan->toggle_ext_start) /* fetch the next entry: if there are no more: done */
chan->toggle_ext_start(chan, slave->external_start); src_sg = sg_next(src_sg);
if (src_sg == NULL)
break;
if (chan->toggle_ext_pause) src_nents--;
chan->toggle_ext_pause(chan, slave->external_pause); src_avail = sg_dma_len(src_sg);
}
}
if (chan->set_request_count) new->async_tx.flags = flags; /* client is in control of this ack */
chan->set_request_count(chan, slave->request_count); new->async_tx.cookie = -EBUSY;
/* Set End-of-link to the last link descriptor of new list */
set_ld_eol(chan, new);
return &first->async_tx; return &first->async_tx;
fail: fail:
/* If first was not set, then we failed to allocate the very first
* descriptor, and we're done */
if (!first) if (!first)
return NULL; return NULL;
fsldma_free_desc_list_reverse(chan, &first->tx_list);
return NULL;
}
/**
* fsl_dma_prep_slave_sg - prepare descriptors for a DMA_SLAVE transaction
* @chan: DMA channel
* @sgl: scatterlist to transfer to/from
* @sg_len: number of entries in @scatterlist
* @direction: DMA direction
* @flags: DMAEngine flags
*
* Prepare a set of descriptors for a DMA_SLAVE transaction. Following the
* DMA_SLAVE API, this gets the device-specific information from the
* chan->private variable.
*/
static struct dma_async_tx_descriptor *fsl_dma_prep_slave_sg(
struct dma_chan *dchan, struct scatterlist *sgl, unsigned int sg_len,
enum dma_data_direction direction, unsigned long flags)
{
/* /*
* First is set, so all of the descriptors we allocated have been added * This operation is not supported on the Freescale DMA controller
* to first->tx_list, INCLUDING "first" itself. Therefore we
* must traverse the list backwards freeing each descriptor in turn
* *
* We're re-using variables for the loop, oh well * However, we need to provide the function pointer to allow the
* device_control() method to work.
*/ */
fsldma_free_desc_list_reverse(chan, &first->tx_list);
return NULL; return NULL;
} }
static int fsl_dma_device_control(struct dma_chan *dchan, static int fsl_dma_device_control(struct dma_chan *dchan,
enum dma_ctrl_cmd cmd, unsigned long arg) enum dma_ctrl_cmd cmd, unsigned long arg)
{ {
struct dma_slave_config *config;
struct fsldma_chan *chan; struct fsldma_chan *chan;
unsigned long flags; unsigned long flags;
int size;
/* Only supports DMA_TERMINATE_ALL */
if (cmd != DMA_TERMINATE_ALL)
return -ENXIO;
if (!dchan) if (!dchan)
return -EINVAL; return -EINVAL;
chan = to_fsl_chan(dchan); chan = to_fsl_chan(dchan);
/* Halt the DMA engine */ switch (cmd) {
dma_halt(chan); case DMA_TERMINATE_ALL:
/* Halt the DMA engine */
dma_halt(chan);
spin_lock_irqsave(&chan->desc_lock, flags); spin_lock_irqsave(&chan->desc_lock, flags);
/* Remove and free all of the descriptors in the LD queue */ /* Remove and free all of the descriptors in the LD queue */
fsldma_free_desc_list(chan, &chan->ld_pending); fsldma_free_desc_list(chan, &chan->ld_pending);
fsldma_free_desc_list(chan, &chan->ld_running); fsldma_free_desc_list(chan, &chan->ld_running);
spin_unlock_irqrestore(&chan->desc_lock, flags); spin_unlock_irqrestore(&chan->desc_lock, flags);
return 0;
case DMA_SLAVE_CONFIG:
config = (struct dma_slave_config *)arg;
/* make sure the channel supports setting burst size */
if (!chan->set_request_count)
return -ENXIO;
/* we set the controller burst size depending on direction */
if (config->direction == DMA_TO_DEVICE)
size = config->dst_addr_width * config->dst_maxburst;
else
size = config->src_addr_width * config->src_maxburst;
chan->set_request_count(chan, size);
return 0;
case FSLDMA_EXTERNAL_START:
/* make sure the channel supports external start */
if (!chan->toggle_ext_start)
return -ENXIO;
chan->toggle_ext_start(chan, arg);
return 0;
default:
return -ENXIO;
}
return 0; return 0;
} }
...@@ -1327,11 +1309,13 @@ static int __devinit fsldma_of_probe(struct platform_device *op, ...@@ -1327,11 +1309,13 @@ static int __devinit fsldma_of_probe(struct platform_device *op,
dma_cap_set(DMA_MEMCPY, fdev->common.cap_mask); dma_cap_set(DMA_MEMCPY, fdev->common.cap_mask);
dma_cap_set(DMA_INTERRUPT, fdev->common.cap_mask); dma_cap_set(DMA_INTERRUPT, fdev->common.cap_mask);
dma_cap_set(DMA_SG, fdev->common.cap_mask);
dma_cap_set(DMA_SLAVE, fdev->common.cap_mask); dma_cap_set(DMA_SLAVE, fdev->common.cap_mask);
fdev->common.device_alloc_chan_resources = fsl_dma_alloc_chan_resources; fdev->common.device_alloc_chan_resources = fsl_dma_alloc_chan_resources;
fdev->common.device_free_chan_resources = fsl_dma_free_chan_resources; fdev->common.device_free_chan_resources = fsl_dma_free_chan_resources;
fdev->common.device_prep_dma_interrupt = fsl_dma_prep_interrupt; fdev->common.device_prep_dma_interrupt = fsl_dma_prep_interrupt;
fdev->common.device_prep_dma_memcpy = fsl_dma_prep_memcpy; fdev->common.device_prep_dma_memcpy = fsl_dma_prep_memcpy;
fdev->common.device_prep_dma_sg = fsl_dma_prep_sg;
fdev->common.device_tx_status = fsl_tx_status; fdev->common.device_tx_status = fsl_tx_status;
fdev->common.device_issue_pending = fsl_dma_memcpy_issue_pending; fdev->common.device_issue_pending = fsl_dma_memcpy_issue_pending;
fdev->common.device_prep_slave_sg = fsl_dma_prep_slave_sg; fdev->common.device_prep_slave_sg = fsl_dma_prep_slave_sg;
......
/*
* drivers/dma/imx-dma.c
*
* This file contains a driver for the Freescale i.MX DMA engine
* found on i.MX1/21/27
*
* Copyright 2010 Sascha Hauer, Pengutronix <s.hauer@pengutronix.de>
*
* The code contained herein is licensed under the GNU General Public
* License. You may obtain a copy of the GNU General Public License
* Version 2 or later at the following locations:
*
* http://www.opensource.org/licenses/gpl-license.html
* http://www.gnu.org/copyleft/gpl.html
*/
#include <linux/init.h>
#include <linux/types.h>
#include <linux/mm.h>
#include <linux/interrupt.h>
#include <linux/spinlock.h>
#include <linux/device.h>
#include <linux/dma-mapping.h>
#include <linux/slab.h>
#include <linux/platform_device.h>
#include <linux/dmaengine.h>
#include <asm/irq.h>
#include <mach/dma-v1.h>
#include <mach/hardware.h>
struct imxdma_channel {
struct imxdma_engine *imxdma;
unsigned int channel;
unsigned int imxdma_channel;
enum dma_slave_buswidth word_size;
dma_addr_t per_address;
u32 watermark_level;
struct dma_chan chan;
spinlock_t lock;
struct dma_async_tx_descriptor desc;
dma_cookie_t last_completed;
enum dma_status status;
int dma_request;
struct scatterlist *sg_list;
};
#define MAX_DMA_CHANNELS 8
struct imxdma_engine {
struct device *dev;
struct dma_device dma_device;
struct imxdma_channel channel[MAX_DMA_CHANNELS];
};
static struct imxdma_channel *to_imxdma_chan(struct dma_chan *chan)
{
return container_of(chan, struct imxdma_channel, chan);
}
static void imxdma_handle(struct imxdma_channel *imxdmac)
{
if (imxdmac->desc.callback)
imxdmac->desc.callback(imxdmac->desc.callback_param);
imxdmac->last_completed = imxdmac->desc.cookie;
}
static void imxdma_irq_handler(int channel, void *data)
{
struct imxdma_channel *imxdmac = data;
imxdmac->status = DMA_SUCCESS;
imxdma_handle(imxdmac);
}
static void imxdma_err_handler(int channel, void *data, int error)
{
struct imxdma_channel *imxdmac = data;
imxdmac->status = DMA_ERROR;
imxdma_handle(imxdmac);
}
static void imxdma_progression(int channel, void *data,
struct scatterlist *sg)
{
struct imxdma_channel *imxdmac = data;
imxdmac->status = DMA_SUCCESS;
imxdma_handle(imxdmac);
}
static int imxdma_control(struct dma_chan *chan, enum dma_ctrl_cmd cmd,
unsigned long arg)
{
struct imxdma_channel *imxdmac = to_imxdma_chan(chan);
struct dma_slave_config *dmaengine_cfg = (void *)arg;
int ret;
unsigned int mode = 0;
switch (cmd) {
case DMA_TERMINATE_ALL:
imxdmac->status = DMA_ERROR;
imx_dma_disable(imxdmac->imxdma_channel);
return 0;
case DMA_SLAVE_CONFIG:
if (dmaengine_cfg->direction == DMA_FROM_DEVICE) {
imxdmac->per_address = dmaengine_cfg->src_addr;
imxdmac->watermark_level = dmaengine_cfg->src_maxburst;
imxdmac->word_size = dmaengine_cfg->src_addr_width;
} else {
imxdmac->per_address = dmaengine_cfg->dst_addr;
imxdmac->watermark_level = dmaengine_cfg->dst_maxburst;
imxdmac->word_size = dmaengine_cfg->dst_addr_width;
}
switch (imxdmac->word_size) {
case DMA_SLAVE_BUSWIDTH_1_BYTE:
mode = IMX_DMA_MEMSIZE_8;
break;
case DMA_SLAVE_BUSWIDTH_2_BYTES:
mode = IMX_DMA_MEMSIZE_16;
break;
default:
case DMA_SLAVE_BUSWIDTH_4_BYTES:
mode = IMX_DMA_MEMSIZE_32;
break;
}
ret = imx_dma_config_channel(imxdmac->imxdma_channel,
mode | IMX_DMA_TYPE_FIFO,
IMX_DMA_MEMSIZE_32 | IMX_DMA_TYPE_LINEAR,
imxdmac->dma_request, 1);
if (ret)
return ret;
imx_dma_config_burstlen(imxdmac->imxdma_channel, imxdmac->watermark_level);
return 0;
default:
return -ENOSYS;
}
return -EINVAL;
}
static enum dma_status imxdma_tx_status(struct dma_chan *chan,
dma_cookie_t cookie,
struct dma_tx_state *txstate)
{
struct imxdma_channel *imxdmac = to_imxdma_chan(chan);
dma_cookie_t last_used;
enum dma_status ret;
last_used = chan->cookie;
ret = dma_async_is_complete(cookie, imxdmac->last_completed, last_used);
dma_set_tx_state(txstate, imxdmac->last_completed, last_used, 0);
return ret;
}
static dma_cookie_t imxdma_assign_cookie(struct imxdma_channel *imxdma)
{
dma_cookie_t cookie = imxdma->chan.cookie;
if (++cookie < 0)
cookie = 1;
imxdma->chan.cookie = cookie;
imxdma->desc.cookie = cookie;
return cookie;
}
static dma_cookie_t imxdma_tx_submit(struct dma_async_tx_descriptor *tx)
{
struct imxdma_channel *imxdmac = to_imxdma_chan(tx->chan);
dma_cookie_t cookie;
spin_lock_irq(&imxdmac->lock);
cookie = imxdma_assign_cookie(imxdmac);
imx_dma_enable(imxdmac->imxdma_channel);
spin_unlock_irq(&imxdmac->lock);
return cookie;
}
static int imxdma_alloc_chan_resources(struct dma_chan *chan)
{
struct imxdma_channel *imxdmac = to_imxdma_chan(chan);
struct imx_dma_data *data = chan->private;
imxdmac->dma_request = data->dma_request;
dma_async_tx_descriptor_init(&imxdmac->desc, chan);
imxdmac->desc.tx_submit = imxdma_tx_submit;
/* txd.flags will be overwritten in prep funcs */
imxdmac->desc.flags = DMA_CTRL_ACK;
imxdmac->status = DMA_SUCCESS;
return 0;
}
static void imxdma_free_chan_resources(struct dma_chan *chan)
{
struct imxdma_channel *imxdmac = to_imxdma_chan(chan);
imx_dma_disable(imxdmac->imxdma_channel);
if (imxdmac->sg_list) {
kfree(imxdmac->sg_list);
imxdmac->sg_list = NULL;
}
}
static struct dma_async_tx_descriptor *imxdma_prep_slave_sg(
struct dma_chan *chan, struct scatterlist *sgl,
unsigned int sg_len, enum dma_data_direction direction,
unsigned long flags)
{
struct imxdma_channel *imxdmac = to_imxdma_chan(chan);
struct scatterlist *sg;
int i, ret, dma_length = 0;
unsigned int dmamode;
if (imxdmac->status == DMA_IN_PROGRESS)
return NULL;
imxdmac->status = DMA_IN_PROGRESS;
for_each_sg(sgl, sg, sg_len, i) {
dma_length += sg->length;
}
if (direction == DMA_FROM_DEVICE)
dmamode = DMA_MODE_READ;
else
dmamode = DMA_MODE_WRITE;
ret = imx_dma_setup_sg(imxdmac->imxdma_channel, sgl, sg_len,
dma_length, imxdmac->per_address, dmamode);
if (ret)
return NULL;
return &imxdmac->desc;
}
static struct dma_async_tx_descriptor *imxdma_prep_dma_cyclic(
struct dma_chan *chan, dma_addr_t dma_addr, size_t buf_len,
size_t period_len, enum dma_data_direction direction)
{
struct imxdma_channel *imxdmac = to_imxdma_chan(chan);
struct imxdma_engine *imxdma = imxdmac->imxdma;
int i, ret;
unsigned int periods = buf_len / period_len;
unsigned int dmamode;
dev_dbg(imxdma->dev, "%s channel: %d buf_len=%d period_len=%d\n",
__func__, imxdmac->channel, buf_len, period_len);
if (imxdmac->status == DMA_IN_PROGRESS)
return NULL;
imxdmac->status = DMA_IN_PROGRESS;
ret = imx_dma_setup_progression_handler(imxdmac->imxdma_channel,
imxdma_progression);
if (ret) {
dev_err(imxdma->dev, "Failed to setup the DMA handler\n");
return NULL;
}
if (imxdmac->sg_list)
kfree(imxdmac->sg_list);
imxdmac->sg_list = kcalloc(periods + 1,
sizeof(struct scatterlist), GFP_KERNEL);
if (!imxdmac->sg_list)
return NULL;
sg_init_table(imxdmac->sg_list, periods);
for (i = 0; i < periods; i++) {
imxdmac->sg_list[i].page_link = 0;
imxdmac->sg_list[i].offset = 0;
imxdmac->sg_list[i].dma_address = dma_addr;
imxdmac->sg_list[i].length = period_len;
dma_addr += period_len;
}
/* close the loop */
imxdmac->sg_list[periods].offset = 0;
imxdmac->sg_list[periods].length = 0;
imxdmac->sg_list[periods].page_link =
((unsigned long)imxdmac->sg_list | 0x01) & ~0x02;
if (direction == DMA_FROM_DEVICE)
dmamode = DMA_MODE_READ;
else
dmamode = DMA_MODE_WRITE;
ret = imx_dma_setup_sg(imxdmac->imxdma_channel, imxdmac->sg_list, periods,
IMX_DMA_LENGTH_LOOP, imxdmac->per_address, dmamode);
if (ret)
return NULL;
return &imxdmac->desc;
}
static void imxdma_issue_pending(struct dma_chan *chan)
{
/*
* Nothing to do. We only have a single descriptor
*/
}
static int __init imxdma_probe(struct platform_device *pdev)
{
struct imxdma_engine *imxdma;
int ret, i;
imxdma = kzalloc(sizeof(*imxdma), GFP_KERNEL);
if (!imxdma)
return -ENOMEM;
INIT_LIST_HEAD(&imxdma->dma_device.channels);
/* Initialize channel parameters */
for (i = 0; i < MAX_DMA_CHANNELS; i++) {
struct imxdma_channel *imxdmac = &imxdma->channel[i];
imxdmac->imxdma_channel = imx_dma_request_by_prio("dmaengine",
DMA_PRIO_MEDIUM);
if (imxdmac->channel < 0)
goto err_init;
imx_dma_setup_handlers(imxdmac->imxdma_channel,
imxdma_irq_handler, imxdma_err_handler, imxdmac);
imxdmac->imxdma = imxdma;
spin_lock_init(&imxdmac->lock);
dma_cap_set(DMA_SLAVE, imxdma->dma_device.cap_mask);
dma_cap_set(DMA_CYCLIC, imxdma->dma_device.cap_mask);
imxdmac->chan.device = &imxdma->dma_device;
imxdmac->chan.chan_id = i;
imxdmac->channel = i;
/* Add the channel to the DMAC list */
list_add_tail(&imxdmac->chan.device_node, &imxdma->dma_device.channels);
}
imxdma->dev = &pdev->dev;
imxdma->dma_device.dev = &pdev->dev;
imxdma->dma_device.device_alloc_chan_resources = imxdma_alloc_chan_resources;
imxdma->dma_device.device_free_chan_resources = imxdma_free_chan_resources;
imxdma->dma_device.device_tx_status = imxdma_tx_status;
imxdma->dma_device.device_prep_slave_sg = imxdma_prep_slave_sg;
imxdma->dma_device.device_prep_dma_cyclic = imxdma_prep_dma_cyclic;
imxdma->dma_device.device_control = imxdma_control;
imxdma->dma_device.device_issue_pending = imxdma_issue_pending;
platform_set_drvdata(pdev, imxdma);
ret = dma_async_device_register(&imxdma->dma_device);
if (ret) {
dev_err(&pdev->dev, "unable to register\n");
goto err_init;
}
return 0;
err_init:
while (i-- >= 0) {
struct imxdma_channel *imxdmac = &imxdma->channel[i];
imx_dma_free(imxdmac->imxdma_channel);
}
kfree(imxdma);
return ret;
}
static int __exit imxdma_remove(struct platform_device *pdev)
{
struct imxdma_engine *imxdma = platform_get_drvdata(pdev);
int i;
dma_async_device_unregister(&imxdma->dma_device);
for (i = 0; i < MAX_DMA_CHANNELS; i++) {
struct imxdma_channel *imxdmac = &imxdma->channel[i];
imx_dma_free(imxdmac->imxdma_channel);
}
kfree(imxdma);
return 0;
}
static struct platform_driver imxdma_driver = {
.driver = {
.name = "imx-dma",
},
.remove = __exit_p(imxdma_remove),
};
static int __init imxdma_module_init(void)
{
return platform_driver_probe(&imxdma_driver, imxdma_probe);
}
subsys_initcall(imxdma_module_init);
MODULE_AUTHOR("Sascha Hauer, Pengutronix <s.hauer@pengutronix.de>");
MODULE_DESCRIPTION("i.MX dma driver");
MODULE_LICENSE("GPL");
/*
* drivers/dma/imx-sdma.c
*
* This file contains a driver for the Freescale Smart DMA engine
*
* Copyright 2010 Sascha Hauer, Pengutronix <s.hauer@pengutronix.de>
*
* Based on code from Freescale:
*
* Copyright 2004-2009 Freescale Semiconductor, Inc. All Rights Reserved.
*
* The code contained herein is licensed under the GNU General Public
* License. You may obtain a copy of the GNU General Public License
* Version 2 or later at the following locations:
*
* http://www.opensource.org/licenses/gpl-license.html
* http://www.gnu.org/copyleft/gpl.html
*/
#include <linux/init.h>
#include <linux/types.h>
#include <linux/mm.h>
#include <linux/interrupt.h>
#include <linux/clk.h>
#include <linux/wait.h>
#include <linux/sched.h>
#include <linux/semaphore.h>
#include <linux/spinlock.h>
#include <linux/device.h>
#include <linux/dma-mapping.h>
#include <linux/firmware.h>
#include <linux/slab.h>
#include <linux/platform_device.h>
#include <linux/dmaengine.h>
#include <asm/irq.h>
#include <mach/sdma.h>
#include <mach/dma.h>
#include <mach/hardware.h>
/* SDMA registers */
#define SDMA_H_C0PTR 0x000
#define SDMA_H_INTR 0x004
#define SDMA_H_STATSTOP 0x008
#define SDMA_H_START 0x00c
#define SDMA_H_EVTOVR 0x010
#define SDMA_H_DSPOVR 0x014
#define SDMA_H_HOSTOVR 0x018
#define SDMA_H_EVTPEND 0x01c
#define SDMA_H_DSPENBL 0x020
#define SDMA_H_RESET 0x024
#define SDMA_H_EVTERR 0x028
#define SDMA_H_INTRMSK 0x02c
#define SDMA_H_PSW 0x030
#define SDMA_H_EVTERRDBG 0x034
#define SDMA_H_CONFIG 0x038
#define SDMA_ONCE_ENB 0x040
#define SDMA_ONCE_DATA 0x044
#define SDMA_ONCE_INSTR 0x048
#define SDMA_ONCE_STAT 0x04c
#define SDMA_ONCE_CMD 0x050
#define SDMA_EVT_MIRROR 0x054
#define SDMA_ILLINSTADDR 0x058
#define SDMA_CHN0ADDR 0x05c
#define SDMA_ONCE_RTB 0x060
#define SDMA_XTRIG_CONF1 0x070
#define SDMA_XTRIG_CONF2 0x074
#define SDMA_CHNENBL0_V2 0x200
#define SDMA_CHNENBL0_V1 0x080
#define SDMA_CHNPRI_0 0x100
/*
* Buffer descriptor status values.
*/
#define BD_DONE 0x01
#define BD_WRAP 0x02
#define BD_CONT 0x04
#define BD_INTR 0x08
#define BD_RROR 0x10
#define BD_LAST 0x20
#define BD_EXTD 0x80
/*
* Data Node descriptor status values.
*/
#define DND_END_OF_FRAME 0x80
#define DND_END_OF_XFER 0x40
#define DND_DONE 0x20
#define DND_UNUSED 0x01
/*
* IPCV2 descriptor status values.
*/
#define BD_IPCV2_END_OF_FRAME 0x40
#define IPCV2_MAX_NODES 50
/*
* Error bit set in the CCB status field by the SDMA,
* in setbd routine, in case of a transfer error
*/
#define DATA_ERROR 0x10000000
/*
* Buffer descriptor commands.
*/
#define C0_ADDR 0x01
#define C0_LOAD 0x02
#define C0_DUMP 0x03
#define C0_SETCTX 0x07
#define C0_GETCTX 0x03
#define C0_SETDM 0x01
#define C0_SETPM 0x04
#define C0_GETDM 0x02
#define C0_GETPM 0x08
/*
* Change endianness indicator in the BD command field
*/
#define CHANGE_ENDIANNESS 0x80
/*
* Mode/Count of data node descriptors - IPCv2
*/
struct sdma_mode_count {
u32 count : 16; /* size of the buffer pointed by this BD */
u32 status : 8; /* E,R,I,C,W,D status bits stored here */
u32 command : 8; /* command mostlky used for channel 0 */
};
/*
* Buffer descriptor
*/
struct sdma_buffer_descriptor {
struct sdma_mode_count mode;
u32 buffer_addr; /* address of the buffer described */
u32 ext_buffer_addr; /* extended buffer address */
} __attribute__ ((packed));
/**
* struct sdma_channel_control - Channel control Block
*
* @current_bd_ptr current buffer descriptor processed
* @base_bd_ptr first element of buffer descriptor array
* @unused padding. The SDMA engine expects an array of 128 byte
* control blocks
*/
struct sdma_channel_control {
u32 current_bd_ptr;
u32 base_bd_ptr;
u32 unused[2];
} __attribute__ ((packed));
/**
* struct sdma_state_registers - SDMA context for a channel
*
* @pc: program counter
* @t: test bit: status of arithmetic & test instruction
* @rpc: return program counter
* @sf: source fault while loading data
* @spc: loop start program counter
* @df: destination fault while storing data
* @epc: loop end program counter
* @lm: loop mode
*/
struct sdma_state_registers {
u32 pc :14;
u32 unused1: 1;
u32 t : 1;
u32 rpc :14;
u32 unused0: 1;
u32 sf : 1;
u32 spc :14;
u32 unused2: 1;
u32 df : 1;
u32 epc :14;
u32 lm : 2;
} __attribute__ ((packed));
/**
* struct sdma_context_data - sdma context specific to a channel
*
* @channel_state: channel state bits
* @gReg: general registers
* @mda: burst dma destination address register
* @msa: burst dma source address register
* @ms: burst dma status register
* @md: burst dma data register
* @pda: peripheral dma destination address register
* @psa: peripheral dma source address register
* @ps: peripheral dma status register
* @pd: peripheral dma data register
* @ca: CRC polynomial register
* @cs: CRC accumulator register
* @dda: dedicated core destination address register
* @dsa: dedicated core source address register
* @ds: dedicated core status register
* @dd: dedicated core data register
*/
struct sdma_context_data {
struct sdma_state_registers channel_state;
u32 gReg[8];
u32 mda;
u32 msa;
u32 ms;
u32 md;
u32 pda;
u32 psa;
u32 ps;
u32 pd;
u32 ca;
u32 cs;
u32 dda;
u32 dsa;
u32 ds;
u32 dd;
u32 scratch0;
u32 scratch1;
u32 scratch2;
u32 scratch3;
u32 scratch4;
u32 scratch5;
u32 scratch6;
u32 scratch7;
} __attribute__ ((packed));
#define NUM_BD (int)(PAGE_SIZE / sizeof(struct sdma_buffer_descriptor))
struct sdma_engine;
/**
* struct sdma_channel - housekeeping for a SDMA channel
*
* @sdma pointer to the SDMA engine for this channel
* @channel the channel number, matches dmaengine chan_id
* @direction transfer type. Needed for setting SDMA script
* @peripheral_type Peripheral type. Needed for setting SDMA script
* @event_id0 aka dma request line
* @event_id1 for channels that use 2 events
* @word_size peripheral access size
* @buf_tail ID of the buffer that was processed
* @done channel completion
* @num_bd max NUM_BD. number of descriptors currently handling
*/
struct sdma_channel {
struct sdma_engine *sdma;
unsigned int channel;
enum dma_data_direction direction;
enum sdma_peripheral_type peripheral_type;
unsigned int event_id0;
unsigned int event_id1;
enum dma_slave_buswidth word_size;
unsigned int buf_tail;
struct completion done;
unsigned int num_bd;
struct sdma_buffer_descriptor *bd;
dma_addr_t bd_phys;
unsigned int pc_from_device, pc_to_device;
unsigned long flags;
dma_addr_t per_address;
u32 event_mask0, event_mask1;
u32 watermark_level;
u32 shp_addr, per_addr;
struct dma_chan chan;
spinlock_t lock;
struct dma_async_tx_descriptor desc;
dma_cookie_t last_completed;
enum dma_status status;
};
#define IMX_DMA_SG_LOOP (1 << 0)
#define MAX_DMA_CHANNELS 32
#define MXC_SDMA_DEFAULT_PRIORITY 1
#define MXC_SDMA_MIN_PRIORITY 1
#define MXC_SDMA_MAX_PRIORITY 7
/**
* struct sdma_script_start_addrs - SDMA script start pointers
*
* start addresses of the different functions in the physical
* address space of the SDMA engine.
*/
struct sdma_script_start_addrs {
u32 ap_2_ap_addr;
u32 ap_2_bp_addr;
u32 ap_2_ap_fixed_addr;
u32 bp_2_ap_addr;
u32 loopback_on_dsp_side_addr;
u32 mcu_interrupt_only_addr;
u32 firi_2_per_addr;
u32 firi_2_mcu_addr;
u32 per_2_firi_addr;
u32 mcu_2_firi_addr;
u32 uart_2_per_addr;
u32 uart_2_mcu_addr;
u32 per_2_app_addr;
u32 mcu_2_app_addr;
u32 per_2_per_addr;
u32 uartsh_2_per_addr;
u32 uartsh_2_mcu_addr;
u32 per_2_shp_addr;
u32 mcu_2_shp_addr;
u32 ata_2_mcu_addr;
u32 mcu_2_ata_addr;
u32 app_2_per_addr;
u32 app_2_mcu_addr;
u32 shp_2_per_addr;
u32 shp_2_mcu_addr;
u32 mshc_2_mcu_addr;
u32 mcu_2_mshc_addr;
u32 spdif_2_mcu_addr;
u32 mcu_2_spdif_addr;
u32 asrc_2_mcu_addr;
u32 ext_mem_2_ipu_addr;
u32 descrambler_addr;
u32 dptc_dvfs_addr;
u32 utra_addr;
u32 ram_code_start_addr;
};
#define SDMA_FIRMWARE_MAGIC 0x414d4453
/**
* struct sdma_firmware_header - Layout of the firmware image
*
* @magic "SDMA"
* @version_major increased whenever layout of struct sdma_script_start_addrs
* changes.
* @version_minor firmware minor version (for binary compatible changes)
* @script_addrs_start offset of struct sdma_script_start_addrs in this image
* @num_script_addrs Number of script addresses in this image
* @ram_code_start offset of SDMA ram image in this firmware image
* @ram_code_size size of SDMA ram image
* @script_addrs Stores the start address of the SDMA scripts
* (in SDMA memory space)
*/
struct sdma_firmware_header {
u32 magic;
u32 version_major;
u32 version_minor;
u32 script_addrs_start;
u32 num_script_addrs;
u32 ram_code_start;
u32 ram_code_size;
};
struct sdma_engine {
struct device *dev;
struct sdma_channel channel[MAX_DMA_CHANNELS];
struct sdma_channel_control *channel_control;
void __iomem *regs;
unsigned int version;
unsigned int num_events;
struct sdma_context_data *context;
dma_addr_t context_phys;
struct dma_device dma_device;
struct clk *clk;
struct sdma_script_start_addrs *script_addrs;
};
#define SDMA_H_CONFIG_DSPDMA (1 << 12) /* indicates if the DSPDMA is used */
#define SDMA_H_CONFIG_RTD_PINS (1 << 11) /* indicates if Real-Time Debug pins are enabled */
#define SDMA_H_CONFIG_ACR (1 << 4) /* indicates if AHB freq /core freq = 2 or 1 */
#define SDMA_H_CONFIG_CSM (3) /* indicates which context switch mode is selected*/
static inline u32 chnenbl_ofs(struct sdma_engine *sdma, unsigned int event)
{
u32 chnenbl0 = (sdma->version == 2 ? SDMA_CHNENBL0_V2 : SDMA_CHNENBL0_V1);
return chnenbl0 + event * 4;
}
static int sdma_config_ownership(struct sdma_channel *sdmac,
bool event_override, bool mcu_override, bool dsp_override)
{
struct sdma_engine *sdma = sdmac->sdma;
int channel = sdmac->channel;
u32 evt, mcu, dsp;
if (event_override && mcu_override && dsp_override)
return -EINVAL;
evt = __raw_readl(sdma->regs + SDMA_H_EVTOVR);
mcu = __raw_readl(sdma->regs + SDMA_H_HOSTOVR);
dsp = __raw_readl(sdma->regs + SDMA_H_DSPOVR);
if (dsp_override)
dsp &= ~(1 << channel);
else
dsp |= (1 << channel);
if (event_override)
evt &= ~(1 << channel);
else
evt |= (1 << channel);
if (mcu_override)
mcu &= ~(1 << channel);
else
mcu |= (1 << channel);
__raw_writel(evt, sdma->regs + SDMA_H_EVTOVR);
__raw_writel(mcu, sdma->regs + SDMA_H_HOSTOVR);
__raw_writel(dsp, sdma->regs + SDMA_H_DSPOVR);
return 0;
}
/*
* sdma_run_channel - run a channel and wait till it's done
*/
static int sdma_run_channel(struct sdma_channel *sdmac)
{
struct sdma_engine *sdma = sdmac->sdma;
int channel = sdmac->channel;
int ret;
init_completion(&sdmac->done);
__raw_writel(1 << channel, sdma->regs + SDMA_H_START);
ret = wait_for_completion_timeout(&sdmac->done, HZ);
return ret ? 0 : -ETIMEDOUT;
}
static int sdma_load_script(struct sdma_engine *sdma, void *buf, int size,
u32 address)
{
struct sdma_buffer_descriptor *bd0 = sdma->channel[0].bd;
void *buf_virt;
dma_addr_t buf_phys;
int ret;
buf_virt = dma_alloc_coherent(NULL,
size,
&buf_phys, GFP_KERNEL);
if (!buf_virt)
return -ENOMEM;
bd0->mode.command = C0_SETPM;
bd0->mode.status = BD_DONE | BD_INTR | BD_WRAP | BD_EXTD;
bd0->mode.count = size / 2;
bd0->buffer_addr = buf_phys;
bd0->ext_buffer_addr = address;
memcpy(buf_virt, buf, size);
ret = sdma_run_channel(&sdma->channel[0]);
dma_free_coherent(NULL, size, buf_virt, buf_phys);
return ret;
}
static void sdma_event_enable(struct sdma_channel *sdmac, unsigned int event)
{
struct sdma_engine *sdma = sdmac->sdma;
int channel = sdmac->channel;
u32 val;
u32 chnenbl = chnenbl_ofs(sdma, event);
val = __raw_readl(sdma->regs + chnenbl);
val |= (1 << channel);
__raw_writel(val, sdma->regs + chnenbl);
}
static void sdma_event_disable(struct sdma_channel *sdmac, unsigned int event)
{
struct sdma_engine *sdma = sdmac->sdma;
int channel = sdmac->channel;
u32 chnenbl = chnenbl_ofs(sdma, event);
u32 val;
val = __raw_readl(sdma->regs + chnenbl);
val &= ~(1 << channel);
__raw_writel(val, sdma->regs + chnenbl);
}
static void sdma_handle_channel_loop(struct sdma_channel *sdmac)
{
struct sdma_buffer_descriptor *bd;
/*
* loop mode. Iterate over descriptors, re-setup them and
* call callback function.
*/
while (1) {
bd = &sdmac->bd[sdmac->buf_tail];
if (bd->mode.status & BD_DONE)
break;
if (bd->mode.status & BD_RROR)
sdmac->status = DMA_ERROR;
else
sdmac->status = DMA_SUCCESS;
bd->mode.status |= BD_DONE;
sdmac->buf_tail++;
sdmac->buf_tail %= sdmac->num_bd;
if (sdmac->desc.callback)
sdmac->desc.callback(sdmac->desc.callback_param);
}
}
static void mxc_sdma_handle_channel_normal(struct sdma_channel *sdmac)
{
struct sdma_buffer_descriptor *bd;
int i, error = 0;
/*
* non loop mode. Iterate over all descriptors, collect
* errors and call callback function
*/
for (i = 0; i < sdmac->num_bd; i++) {
bd = &sdmac->bd[i];
if (bd->mode.status & (BD_DONE | BD_RROR))
error = -EIO;
}
if (error)
sdmac->status = DMA_ERROR;
else
sdmac->status = DMA_SUCCESS;
if (sdmac->desc.callback)
sdmac->desc.callback(sdmac->desc.callback_param);
sdmac->last_completed = sdmac->desc.cookie;
}
static void mxc_sdma_handle_channel(struct sdma_channel *sdmac)
{
complete(&sdmac->done);
/* not interested in channel 0 interrupts */
if (sdmac->channel == 0)
return;
if (sdmac->flags & IMX_DMA_SG_LOOP)
sdma_handle_channel_loop(sdmac);
else
mxc_sdma_handle_channel_normal(sdmac);
}
static irqreturn_t sdma_int_handler(int irq, void *dev_id)
{
struct sdma_engine *sdma = dev_id;
u32 stat;
stat = __raw_readl(sdma->regs + SDMA_H_INTR);
__raw_writel(stat, sdma->regs + SDMA_H_INTR);
while (stat) {
int channel = fls(stat) - 1;
struct sdma_channel *sdmac = &sdma->channel[channel];
mxc_sdma_handle_channel(sdmac);
stat &= ~(1 << channel);
}
return IRQ_HANDLED;
}
/*
* sets the pc of SDMA script according to the peripheral type
*/
static void sdma_get_pc(struct sdma_channel *sdmac,
enum sdma_peripheral_type peripheral_type)
{
struct sdma_engine *sdma = sdmac->sdma;
int per_2_emi = 0, emi_2_per = 0;
/*
* These are needed once we start to support transfers between
* two peripherals or memory-to-memory transfers
*/
int per_2_per = 0, emi_2_emi = 0;
sdmac->pc_from_device = 0;
sdmac->pc_to_device = 0;
switch (peripheral_type) {
case IMX_DMATYPE_MEMORY:
emi_2_emi = sdma->script_addrs->ap_2_ap_addr;
break;
case IMX_DMATYPE_DSP:
emi_2_per = sdma->script_addrs->bp_2_ap_addr;
per_2_emi = sdma->script_addrs->ap_2_bp_addr;
break;
case IMX_DMATYPE_FIRI:
per_2_emi = sdma->script_addrs->firi_2_mcu_addr;
emi_2_per = sdma->script_addrs->mcu_2_firi_addr;
break;
case IMX_DMATYPE_UART:
per_2_emi = sdma->script_addrs->uart_2_mcu_addr;
emi_2_per = sdma->script_addrs->mcu_2_app_addr;
break;
case IMX_DMATYPE_UART_SP:
per_2_emi = sdma->script_addrs->uartsh_2_mcu_addr;
emi_2_per = sdma->script_addrs->mcu_2_shp_addr;
break;
case IMX_DMATYPE_ATA:
per_2_emi = sdma->script_addrs->ata_2_mcu_addr;
emi_2_per = sdma->script_addrs->mcu_2_ata_addr;
break;
case IMX_DMATYPE_CSPI:
case IMX_DMATYPE_EXT:
case IMX_DMATYPE_SSI:
per_2_emi = sdma->script_addrs->app_2_mcu_addr;
emi_2_per = sdma->script_addrs->mcu_2_app_addr;
break;
case IMX_DMATYPE_SSI_SP:
case IMX_DMATYPE_MMC:
case IMX_DMATYPE_SDHC:
case IMX_DMATYPE_CSPI_SP:
case IMX_DMATYPE_ESAI:
case IMX_DMATYPE_MSHC_SP:
per_2_emi = sdma->script_addrs->shp_2_mcu_addr;
emi_2_per = sdma->script_addrs->mcu_2_shp_addr;
break;
case IMX_DMATYPE_ASRC:
per_2_emi = sdma->script_addrs->asrc_2_mcu_addr;
emi_2_per = sdma->script_addrs->asrc_2_mcu_addr;
per_2_per = sdma->script_addrs->per_2_per_addr;
break;
case IMX_DMATYPE_MSHC:
per_2_emi = sdma->script_addrs->mshc_2_mcu_addr;
emi_2_per = sdma->script_addrs->mcu_2_mshc_addr;
break;
case IMX_DMATYPE_CCM:
per_2_emi = sdma->script_addrs->dptc_dvfs_addr;
break;
case IMX_DMATYPE_SPDIF:
per_2_emi = sdma->script_addrs->spdif_2_mcu_addr;
emi_2_per = sdma->script_addrs->mcu_2_spdif_addr;
break;
case IMX_DMATYPE_IPU_MEMORY:
emi_2_per = sdma->script_addrs->ext_mem_2_ipu_addr;
break;
default:
break;
}
sdmac->pc_from_device = per_2_emi;
sdmac->pc_to_device = emi_2_per;
}
static int sdma_load_context(struct sdma_channel *sdmac)
{
struct sdma_engine *sdma = sdmac->sdma;
int channel = sdmac->channel;
int load_address;
struct sdma_context_data *context = sdma->context;
struct sdma_buffer_descriptor *bd0 = sdma->channel[0].bd;
int ret;
if (sdmac->direction == DMA_FROM_DEVICE) {
load_address = sdmac->pc_from_device;
} else {
load_address = sdmac->pc_to_device;
}
if (load_address < 0)
return load_address;
dev_dbg(sdma->dev, "load_address = %d\n", load_address);
dev_dbg(sdma->dev, "wml = 0x%08x\n", sdmac->watermark_level);
dev_dbg(sdma->dev, "shp_addr = 0x%08x\n", sdmac->shp_addr);
dev_dbg(sdma->dev, "per_addr = 0x%08x\n", sdmac->per_addr);
dev_dbg(sdma->dev, "event_mask0 = 0x%08x\n", sdmac->event_mask0);
dev_dbg(sdma->dev, "event_mask1 = 0x%08x\n", sdmac->event_mask1);
memset(context, 0, sizeof(*context));
context->channel_state.pc = load_address;
/* Send by context the event mask,base address for peripheral
* and watermark level
*/
context->gReg[0] = sdmac->event_mask1;
context->gReg[1] = sdmac->event_mask0;
context->gReg[2] = sdmac->per_addr;
context->gReg[6] = sdmac->shp_addr;
context->gReg[7] = sdmac->watermark_level;
bd0->mode.command = C0_SETDM;
bd0->mode.status = BD_DONE | BD_INTR | BD_WRAP | BD_EXTD;
bd0->mode.count = sizeof(*context) / 4;
bd0->buffer_addr = sdma->context_phys;
bd0->ext_buffer_addr = 2048 + (sizeof(*context) / 4) * channel;
ret = sdma_run_channel(&sdma->channel[0]);
return ret;
}
static void sdma_disable_channel(struct sdma_channel *sdmac)
{
struct sdma_engine *sdma = sdmac->sdma;
int channel = sdmac->channel;
__raw_writel(1 << channel, sdma->regs + SDMA_H_STATSTOP);
sdmac->status = DMA_ERROR;
}
static int sdma_config_channel(struct sdma_channel *sdmac)
{
int ret;
sdma_disable_channel(sdmac);
sdmac->event_mask0 = 0;
sdmac->event_mask1 = 0;
sdmac->shp_addr = 0;
sdmac->per_addr = 0;
if (sdmac->event_id0) {
if (sdmac->event_id0 > 32)
return -EINVAL;
sdma_event_enable(sdmac, sdmac->event_id0);
}
switch (sdmac->peripheral_type) {
case IMX_DMATYPE_DSP:
sdma_config_ownership(sdmac, false, true, true);
break;
case IMX_DMATYPE_MEMORY:
sdma_config_ownership(sdmac, false, true, false);
break;
default:
sdma_config_ownership(sdmac, true, true, false);
break;
}
sdma_get_pc(sdmac, sdmac->peripheral_type);
if ((sdmac->peripheral_type != IMX_DMATYPE_MEMORY) &&
(sdmac->peripheral_type != IMX_DMATYPE_DSP)) {
/* Handle multiple event channels differently */
if (sdmac->event_id1) {
sdmac->event_mask1 = 1 << (sdmac->event_id1 % 32);
if (sdmac->event_id1 > 31)
sdmac->watermark_level |= 1 << 31;
sdmac->event_mask0 = 1 << (sdmac->event_id0 % 32);
if (sdmac->event_id0 > 31)
sdmac->watermark_level |= 1 << 30;
} else {
sdmac->event_mask0 = 1 << sdmac->event_id0;
sdmac->event_mask1 = 1 << (sdmac->event_id0 - 32);
}
/* Watermark Level */
sdmac->watermark_level |= sdmac->watermark_level;
/* Address */
sdmac->shp_addr = sdmac->per_address;
} else {
sdmac->watermark_level = 0; /* FIXME: M3_BASE_ADDRESS */
}
ret = sdma_load_context(sdmac);
return ret;
}
static int sdma_set_channel_priority(struct sdma_channel *sdmac,
unsigned int priority)
{
struct sdma_engine *sdma = sdmac->sdma;
int channel = sdmac->channel;
if (priority < MXC_SDMA_MIN_PRIORITY
|| priority > MXC_SDMA_MAX_PRIORITY) {
return -EINVAL;
}
__raw_writel(priority, sdma->regs + SDMA_CHNPRI_0 + 4 * channel);
return 0;
}
static int sdma_request_channel(struct sdma_channel *sdmac)
{
struct sdma_engine *sdma = sdmac->sdma;
int channel = sdmac->channel;
int ret = -EBUSY;
sdmac->bd = dma_alloc_coherent(NULL, PAGE_SIZE, &sdmac->bd_phys, GFP_KERNEL);
if (!sdmac->bd) {
ret = -ENOMEM;
goto out;
}
memset(sdmac->bd, 0, PAGE_SIZE);
sdma->channel_control[channel].base_bd_ptr = sdmac->bd_phys;
sdma->channel_control[channel].current_bd_ptr = sdmac->bd_phys;
clk_enable(sdma->clk);
sdma_set_channel_priority(sdmac, MXC_SDMA_DEFAULT_PRIORITY);
init_completion(&sdmac->done);
sdmac->buf_tail = 0;
return 0;
out:
return ret;
}
static void sdma_enable_channel(struct sdma_engine *sdma, int channel)
{
__raw_writel(1 << channel, sdma->regs + SDMA_H_START);
}
static dma_cookie_t sdma_assign_cookie(struct sdma_channel *sdma)
{
dma_cookie_t cookie = sdma->chan.cookie;
if (++cookie < 0)
cookie = 1;
sdma->chan.cookie = cookie;
sdma->desc.cookie = cookie;
return cookie;
}
static struct sdma_channel *to_sdma_chan(struct dma_chan *chan)
{
return container_of(chan, struct sdma_channel, chan);
}
static dma_cookie_t sdma_tx_submit(struct dma_async_tx_descriptor *tx)
{
struct sdma_channel *sdmac = to_sdma_chan(tx->chan);
struct sdma_engine *sdma = sdmac->sdma;
dma_cookie_t cookie;
spin_lock_irq(&sdmac->lock);
cookie = sdma_assign_cookie(sdmac);
sdma_enable_channel(sdma, tx->chan->chan_id);
spin_unlock_irq(&sdmac->lock);
return cookie;
}
static int sdma_alloc_chan_resources(struct dma_chan *chan)
{
struct sdma_channel *sdmac = to_sdma_chan(chan);
struct imx_dma_data *data = chan->private;
int prio, ret;
/* No need to execute this for internal channel 0 */
if (chan->chan_id == 0)
return 0;
if (!data)
return -EINVAL;
switch (data->priority) {
case DMA_PRIO_HIGH:
prio = 3;
break;
case DMA_PRIO_MEDIUM:
prio = 2;
break;
case DMA_PRIO_LOW:
default:
prio = 1;
break;
}
sdmac->peripheral_type = data->peripheral_type;
sdmac->event_id0 = data->dma_request;
ret = sdma_set_channel_priority(sdmac, prio);
if (ret)
return ret;
ret = sdma_request_channel(sdmac);
if (ret)
return ret;
dma_async_tx_descriptor_init(&sdmac->desc, chan);
sdmac->desc.tx_submit = sdma_tx_submit;
/* txd.flags will be overwritten in prep funcs */
sdmac->desc.flags = DMA_CTRL_ACK;
return 0;
}
static void sdma_free_chan_resources(struct dma_chan *chan)
{
struct sdma_channel *sdmac = to_sdma_chan(chan);
struct sdma_engine *sdma = sdmac->sdma;
sdma_disable_channel(sdmac);
if (sdmac->event_id0)
sdma_event_disable(sdmac, sdmac->event_id0);
if (sdmac->event_id1)
sdma_event_disable(sdmac, sdmac->event_id1);
sdmac->event_id0 = 0;
sdmac->event_id1 = 0;
sdma_set_channel_priority(sdmac, 0);
dma_free_coherent(NULL, PAGE_SIZE, sdmac->bd, sdmac->bd_phys);
clk_disable(sdma->clk);
}
static struct dma_async_tx_descriptor *sdma_prep_slave_sg(
struct dma_chan *chan, struct scatterlist *sgl,
unsigned int sg_len, enum dma_data_direction direction,
unsigned long flags)
{
struct sdma_channel *sdmac = to_sdma_chan(chan);
struct sdma_engine *sdma = sdmac->sdma;
int ret, i, count;
int channel = chan->chan_id;
struct scatterlist *sg;
if (sdmac->status == DMA_IN_PROGRESS)
return NULL;
sdmac->status = DMA_IN_PROGRESS;
sdmac->flags = 0;
dev_dbg(sdma->dev, "setting up %d entries for channel %d.\n",
sg_len, channel);
sdmac->direction = direction;
ret = sdma_load_context(sdmac);
if (ret)
goto err_out;
if (sg_len > NUM_BD) {
dev_err(sdma->dev, "SDMA channel %d: maximum number of sg exceeded: %d > %d\n",
channel, sg_len, NUM_BD);
ret = -EINVAL;
goto err_out;
}
for_each_sg(sgl, sg, sg_len, i) {
struct sdma_buffer_descriptor *bd = &sdmac->bd[i];
int param;
bd->buffer_addr = sgl->dma_address;
count = sg->length;
if (count > 0xffff) {
dev_err(sdma->dev, "SDMA channel %d: maximum bytes for sg entry exceeded: %d > %d\n",
channel, count, 0xffff);
ret = -EINVAL;
goto err_out;
}
bd->mode.count = count;
if (sdmac->word_size > DMA_SLAVE_BUSWIDTH_4_BYTES) {
ret = -EINVAL;
goto err_out;
}
if (sdmac->word_size == DMA_SLAVE_BUSWIDTH_4_BYTES)
bd->mode.command = 0;
else
bd->mode.command = sdmac->word_size;
param = BD_DONE | BD_EXTD | BD_CONT;
if (sdmac->flags & IMX_DMA_SG_LOOP) {
param |= BD_INTR;
if (i + 1 == sg_len)
param |= BD_WRAP;
}
if (i + 1 == sg_len)
param |= BD_INTR;
dev_dbg(sdma->dev, "entry %d: count: %d dma: 0x%08x %s%s\n",
i, count, sg->dma_address,
param & BD_WRAP ? "wrap" : "",
param & BD_INTR ? " intr" : "");
bd->mode.status = param;
}
sdmac->num_bd = sg_len;
sdma->channel_control[channel].current_bd_ptr = sdmac->bd_phys;
return &sdmac->desc;
err_out:
return NULL;
}
static struct dma_async_tx_descriptor *sdma_prep_dma_cyclic(
struct dma_chan *chan, dma_addr_t dma_addr, size_t buf_len,
size_t period_len, enum dma_data_direction direction)
{
struct sdma_channel *sdmac = to_sdma_chan(chan);
struct sdma_engine *sdma = sdmac->sdma;
int num_periods = buf_len / period_len;
int channel = chan->chan_id;
int ret, i = 0, buf = 0;
dev_dbg(sdma->dev, "%s channel: %d\n", __func__, channel);
if (sdmac->status == DMA_IN_PROGRESS)
return NULL;
sdmac->status = DMA_IN_PROGRESS;
sdmac->flags |= IMX_DMA_SG_LOOP;
sdmac->direction = direction;
ret = sdma_load_context(sdmac);
if (ret)
goto err_out;
if (num_periods > NUM_BD) {
dev_err(sdma->dev, "SDMA channel %d: maximum number of sg exceeded: %d > %d\n",
channel, num_periods, NUM_BD);
goto err_out;
}
if (period_len > 0xffff) {
dev_err(sdma->dev, "SDMA channel %d: maximum period size exceeded: %d > %d\n",
channel, period_len, 0xffff);
goto err_out;
}
while (buf < buf_len) {
struct sdma_buffer_descriptor *bd = &sdmac->bd[i];
int param;
bd->buffer_addr = dma_addr;
bd->mode.count = period_len;
if (sdmac->word_size > DMA_SLAVE_BUSWIDTH_4_BYTES)
goto err_out;
if (sdmac->word_size == DMA_SLAVE_BUSWIDTH_4_BYTES)
bd->mode.command = 0;
else
bd->mode.command = sdmac->word_size;
param = BD_DONE | BD_EXTD | BD_CONT | BD_INTR;
if (i + 1 == num_periods)
param |= BD_WRAP;
dev_dbg(sdma->dev, "entry %d: count: %d dma: 0x%08x %s%s\n",
i, period_len, dma_addr,
param & BD_WRAP ? "wrap" : "",
param & BD_INTR ? " intr" : "");
bd->mode.status = param;
dma_addr += period_len;
buf += period_len;
i++;
}
sdmac->num_bd = num_periods;
sdma->channel_control[channel].current_bd_ptr = sdmac->bd_phys;
return &sdmac->desc;
err_out:
sdmac->status = DMA_ERROR;
return NULL;
}
static int sdma_control(struct dma_chan *chan, enum dma_ctrl_cmd cmd,
unsigned long arg)
{
struct sdma_channel *sdmac = to_sdma_chan(chan);
struct dma_slave_config *dmaengine_cfg = (void *)arg;
switch (cmd) {
case DMA_TERMINATE_ALL:
sdma_disable_channel(sdmac);
return 0;
case DMA_SLAVE_CONFIG:
if (dmaengine_cfg->direction == DMA_FROM_DEVICE) {
sdmac->per_address = dmaengine_cfg->src_addr;
sdmac->watermark_level = dmaengine_cfg->src_maxburst;
sdmac->word_size = dmaengine_cfg->src_addr_width;
} else {
sdmac->per_address = dmaengine_cfg->dst_addr;
sdmac->watermark_level = dmaengine_cfg->dst_maxburst;
sdmac->word_size = dmaengine_cfg->dst_addr_width;
}
return sdma_config_channel(sdmac);
default:
return -ENOSYS;
}
return -EINVAL;
}
static enum dma_status sdma_tx_status(struct dma_chan *chan,
dma_cookie_t cookie,
struct dma_tx_state *txstate)
{
struct sdma_channel *sdmac = to_sdma_chan(chan);
dma_cookie_t last_used;
enum dma_status ret;
last_used = chan->cookie;
ret = dma_async_is_complete(cookie, sdmac->last_completed, last_used);
dma_set_tx_state(txstate, sdmac->last_completed, last_used, 0);
return ret;
}
static void sdma_issue_pending(struct dma_chan *chan)
{
/*
* Nothing to do. We only have a single descriptor
*/
}
static int __init sdma_init(struct sdma_engine *sdma,
void *ram_code, int ram_code_size)
{
int i, ret;
dma_addr_t ccb_phys;
switch (sdma->version) {
case 1:
sdma->num_events = 32;
break;
case 2:
sdma->num_events = 48;
break;
default:
dev_err(sdma->dev, "Unknown version %d. aborting\n", sdma->version);
return -ENODEV;
}
clk_enable(sdma->clk);
/* Be sure SDMA has not started yet */
__raw_writel(0, sdma->regs + SDMA_H_C0PTR);
sdma->channel_control = dma_alloc_coherent(NULL,
MAX_DMA_CHANNELS * sizeof (struct sdma_channel_control) +
sizeof(struct sdma_context_data),
&ccb_phys, GFP_KERNEL);
if (!sdma->channel_control) {
ret = -ENOMEM;
goto err_dma_alloc;
}
sdma->context = (void *)sdma->channel_control +
MAX_DMA_CHANNELS * sizeof (struct sdma_channel_control);
sdma->context_phys = ccb_phys +
MAX_DMA_CHANNELS * sizeof (struct sdma_channel_control);
/* Zero-out the CCB structures array just allocated */
memset(sdma->channel_control, 0,
MAX_DMA_CHANNELS * sizeof (struct sdma_channel_control));
/* disable all channels */
for (i = 0; i < sdma->num_events; i++)
__raw_writel(0, sdma->regs + chnenbl_ofs(sdma, i));
/* All channels have priority 0 */
for (i = 0; i < MAX_DMA_CHANNELS; i++)
__raw_writel(0, sdma->regs + SDMA_CHNPRI_0 + i * 4);
ret = sdma_request_channel(&sdma->channel[0]);
if (ret)
goto err_dma_alloc;
sdma_config_ownership(&sdma->channel[0], false, true, false);
/* Set Command Channel (Channel Zero) */
__raw_writel(0x4050, sdma->regs + SDMA_CHN0ADDR);
/* Set bits of CONFIG register but with static context switching */
/* FIXME: Check whether to set ACR bit depending on clock ratios */
__raw_writel(0, sdma->regs + SDMA_H_CONFIG);
__raw_writel(ccb_phys, sdma->regs + SDMA_H_C0PTR);
/* download the RAM image for SDMA */
sdma_load_script(sdma, ram_code,
ram_code_size,
sdma->script_addrs->ram_code_start_addr);
/* Set bits of CONFIG register with given context switching mode */
__raw_writel(SDMA_H_CONFIG_CSM, sdma->regs + SDMA_H_CONFIG);
/* Initializes channel's priorities */
sdma_set_channel_priority(&sdma->channel[0], 7);
clk_disable(sdma->clk);
return 0;
err_dma_alloc:
clk_disable(sdma->clk);
dev_err(sdma->dev, "initialisation failed with %d\n", ret);
return ret;
}
static int __init sdma_probe(struct platform_device *pdev)
{
int ret;
const struct firmware *fw;
const struct sdma_firmware_header *header;
const struct sdma_script_start_addrs *addr;
int irq;
unsigned short *ram_code;
struct resource *iores;
struct sdma_platform_data *pdata = pdev->dev.platform_data;
char *fwname;
int i;
dma_cap_mask_t mask;
struct sdma_engine *sdma;
sdma = kzalloc(sizeof(*sdma), GFP_KERNEL);
if (!sdma)
return -ENOMEM;
sdma->dev = &pdev->dev;
iores = platform_get_resource(pdev, IORESOURCE_MEM, 0);
irq = platform_get_irq(pdev, 0);
if (!iores || irq < 0 || !pdata) {
ret = -EINVAL;
goto err_irq;
}
if (!request_mem_region(iores->start, resource_size(iores), pdev->name)) {
ret = -EBUSY;
goto err_request_region;
}
sdma->clk = clk_get(&pdev->dev, NULL);
if (IS_ERR(sdma->clk)) {
ret = PTR_ERR(sdma->clk);
goto err_clk;
}
sdma->regs = ioremap(iores->start, resource_size(iores));
if (!sdma->regs) {
ret = -ENOMEM;
goto err_ioremap;
}
ret = request_irq(irq, sdma_int_handler, 0, "sdma", sdma);
if (ret)
goto err_request_irq;
fwname = kasprintf(GFP_KERNEL, "sdma-%s-to%d.bin",
pdata->cpu_name, pdata->to_version);
if (!fwname) {
ret = -ENOMEM;
goto err_cputype;
}
ret = request_firmware(&fw, fwname, &pdev->dev);
if (ret) {
dev_err(&pdev->dev, "request firmware \"%s\" failed with %d\n",
fwname, ret);
kfree(fwname);
goto err_cputype;
}
kfree(fwname);
if (fw->size < sizeof(*header))
goto err_firmware;
header = (struct sdma_firmware_header *)fw->data;
if (header->magic != SDMA_FIRMWARE_MAGIC)
goto err_firmware;
if (header->ram_code_start + header->ram_code_size > fw->size)
goto err_firmware;
addr = (void *)header + header->script_addrs_start;
ram_code = (void *)header + header->ram_code_start;
sdma->script_addrs = kmalloc(sizeof(*addr), GFP_KERNEL);
if (!sdma->script_addrs)
goto err_firmware;
memcpy(sdma->script_addrs, addr, sizeof(*addr));
sdma->version = pdata->sdma_version;
INIT_LIST_HEAD(&sdma->dma_device.channels);
/* Initialize channel parameters */
for (i = 0; i < MAX_DMA_CHANNELS; i++) {
struct sdma_channel *sdmac = &sdma->channel[i];
sdmac->sdma = sdma;
spin_lock_init(&sdmac->lock);
dma_cap_set(DMA_SLAVE, sdma->dma_device.cap_mask);
dma_cap_set(DMA_CYCLIC, sdma->dma_device.cap_mask);
sdmac->chan.device = &sdma->dma_device;
sdmac->chan.chan_id = i;
sdmac->channel = i;
/* Add the channel to the DMAC list */
list_add_tail(&sdmac->chan.device_node, &sdma->dma_device.channels);
}
ret = sdma_init(sdma, ram_code, header->ram_code_size);
if (ret)
goto err_init;
sdma->dma_device.dev = &pdev->dev;
sdma->dma_device.device_alloc_chan_resources = sdma_alloc_chan_resources;
sdma->dma_device.device_free_chan_resources = sdma_free_chan_resources;
sdma->dma_device.device_tx_status = sdma_tx_status;
sdma->dma_device.device_prep_slave_sg = sdma_prep_slave_sg;
sdma->dma_device.device_prep_dma_cyclic = sdma_prep_dma_cyclic;
sdma->dma_device.device_control = sdma_control;
sdma->dma_device.device_issue_pending = sdma_issue_pending;
ret = dma_async_device_register(&sdma->dma_device);
if (ret) {
dev_err(&pdev->dev, "unable to register\n");
goto err_init;
}
dev_info(&pdev->dev, "initialized (firmware %d.%d)\n",
header->version_major,
header->version_minor);
/* request channel 0. This is an internal control channel
* to the SDMA engine and not available to clients.
*/
dma_cap_zero(mask);
dma_cap_set(DMA_SLAVE, mask);
dma_request_channel(mask, NULL, NULL);
release_firmware(fw);
return 0;
err_init:
kfree(sdma->script_addrs);
err_firmware:
release_firmware(fw);
err_cputype:
free_irq(irq, sdma);
err_request_irq:
iounmap(sdma->regs);
err_ioremap:
clk_put(sdma->clk);
err_clk:
release_mem_region(iores->start, resource_size(iores));
err_request_region:
err_irq:
kfree(sdma);
return 0;
}
static int __exit sdma_remove(struct platform_device *pdev)
{
return -EBUSY;
}
static struct platform_driver sdma_driver = {
.driver = {
.name = "imx-sdma",
},
.remove = __exit_p(sdma_remove),
};
static int __init sdma_module_init(void)
{
return platform_driver_probe(&sdma_driver, sdma_probe);
}
subsys_initcall(sdma_module_init);
MODULE_AUTHOR("Sascha Hauer, Pengutronix <s.hauer@pengutronix.de>");
MODULE_DESCRIPTION("i.MX SDMA driver");
MODULE_LICENSE("GPL");
...@@ -25,6 +25,7 @@ ...@@ -25,6 +25,7 @@
*/ */
#include <linux/pci.h> #include <linux/pci.h>
#include <linux/interrupt.h> #include <linux/interrupt.h>
#include <linux/pm_runtime.h>
#include <linux/intel_mid_dma.h> #include <linux/intel_mid_dma.h>
#define MAX_CHAN 4 /*max ch across controllers*/ #define MAX_CHAN 4 /*max ch across controllers*/
...@@ -91,13 +92,13 @@ static int get_block_ts(int len, int tx_width, int block_size) ...@@ -91,13 +92,13 @@ static int get_block_ts(int len, int tx_width, int block_size)
int byte_width = 0, block_ts = 0; int byte_width = 0, block_ts = 0;
switch (tx_width) { switch (tx_width) {
case LNW_DMA_WIDTH_8BIT: case DMA_SLAVE_BUSWIDTH_1_BYTE:
byte_width = 1; byte_width = 1;
break; break;
case LNW_DMA_WIDTH_16BIT: case DMA_SLAVE_BUSWIDTH_2_BYTES:
byte_width = 2; byte_width = 2;
break; break;
case LNW_DMA_WIDTH_32BIT: case DMA_SLAVE_BUSWIDTH_4_BYTES:
default: default:
byte_width = 4; byte_width = 4;
break; break;
...@@ -247,16 +248,17 @@ static void midc_dostart(struct intel_mid_dma_chan *midc, ...@@ -247,16 +248,17 @@ static void midc_dostart(struct intel_mid_dma_chan *midc,
struct middma_device *mid = to_middma_device(midc->chan.device); struct middma_device *mid = to_middma_device(midc->chan.device);
/* channel is idle */ /* channel is idle */
if (midc->in_use && test_ch_en(midc->dma_base, midc->ch_id)) { if (midc->busy && test_ch_en(midc->dma_base, midc->ch_id)) {
/*error*/ /*error*/
pr_err("ERR_MDMA: channel is busy in start\n"); pr_err("ERR_MDMA: channel is busy in start\n");
/* The tasklet will hopefully advance the queue... */ /* The tasklet will hopefully advance the queue... */
return; return;
} }
midc->busy = true;
/*write registers and en*/ /*write registers and en*/
iowrite32(first->sar, midc->ch_regs + SAR); iowrite32(first->sar, midc->ch_regs + SAR);
iowrite32(first->dar, midc->ch_regs + DAR); iowrite32(first->dar, midc->ch_regs + DAR);
iowrite32(first->lli_phys, midc->ch_regs + LLP);
iowrite32(first->cfg_hi, midc->ch_regs + CFG_HIGH); iowrite32(first->cfg_hi, midc->ch_regs + CFG_HIGH);
iowrite32(first->cfg_lo, midc->ch_regs + CFG_LOW); iowrite32(first->cfg_lo, midc->ch_regs + CFG_LOW);
iowrite32(first->ctl_lo, midc->ch_regs + CTL_LOW); iowrite32(first->ctl_lo, midc->ch_regs + CTL_LOW);
...@@ -264,9 +266,9 @@ static void midc_dostart(struct intel_mid_dma_chan *midc, ...@@ -264,9 +266,9 @@ static void midc_dostart(struct intel_mid_dma_chan *midc,
pr_debug("MDMA:TX SAR %x,DAR %x,CFGL %x,CFGH %x,CTLH %x, CTLL %x\n", pr_debug("MDMA:TX SAR %x,DAR %x,CFGL %x,CFGH %x,CTLH %x, CTLL %x\n",
(int)first->sar, (int)first->dar, first->cfg_hi, (int)first->sar, (int)first->dar, first->cfg_hi,
first->cfg_lo, first->ctl_hi, first->ctl_lo); first->cfg_lo, first->ctl_hi, first->ctl_lo);
first->status = DMA_IN_PROGRESS;
iowrite32(ENABLE_CHANNEL(midc->ch_id), mid->dma_base + DMA_CHAN_EN); iowrite32(ENABLE_CHANNEL(midc->ch_id), mid->dma_base + DMA_CHAN_EN);
first->status = DMA_IN_PROGRESS;
} }
/** /**
...@@ -283,20 +285,36 @@ static void midc_descriptor_complete(struct intel_mid_dma_chan *midc, ...@@ -283,20 +285,36 @@ static void midc_descriptor_complete(struct intel_mid_dma_chan *midc,
{ {
struct dma_async_tx_descriptor *txd = &desc->txd; struct dma_async_tx_descriptor *txd = &desc->txd;
dma_async_tx_callback callback_txd = NULL; dma_async_tx_callback callback_txd = NULL;
struct intel_mid_dma_lli *llitem;
void *param_txd = NULL; void *param_txd = NULL;
midc->completed = txd->cookie; midc->completed = txd->cookie;
callback_txd = txd->callback; callback_txd = txd->callback;
param_txd = txd->callback_param; param_txd = txd->callback_param;
list_move(&desc->desc_node, &midc->free_list); if (desc->lli != NULL) {
/*clear the DONE bit of completed LLI in memory*/
llitem = desc->lli + desc->current_lli;
llitem->ctl_hi &= CLEAR_DONE;
if (desc->current_lli < desc->lli_length-1)
(desc->current_lli)++;
else
desc->current_lli = 0;
}
spin_unlock_bh(&midc->lock); spin_unlock_bh(&midc->lock);
if (callback_txd) { if (callback_txd) {
pr_debug("MDMA: TXD callback set ... calling\n"); pr_debug("MDMA: TXD callback set ... calling\n");
callback_txd(param_txd); callback_txd(param_txd);
spin_lock_bh(&midc->lock); }
return; if (midc->raw_tfr) {
desc->status = DMA_SUCCESS;
if (desc->lli != NULL) {
pci_pool_free(desc->lli_pool, desc->lli,
desc->lli_phys);
pci_pool_destroy(desc->lli_pool);
}
list_move(&desc->desc_node, &midc->free_list);
midc->busy = false;
} }
spin_lock_bh(&midc->lock); spin_lock_bh(&midc->lock);
...@@ -317,14 +335,89 @@ static void midc_scan_descriptors(struct middma_device *mid, ...@@ -317,14 +335,89 @@ static void midc_scan_descriptors(struct middma_device *mid,
/*tx is complete*/ /*tx is complete*/
list_for_each_entry_safe(desc, _desc, &midc->active_list, desc_node) { list_for_each_entry_safe(desc, _desc, &midc->active_list, desc_node) {
if (desc->status == DMA_IN_PROGRESS) { if (desc->status == DMA_IN_PROGRESS)
desc->status = DMA_SUCCESS;
midc_descriptor_complete(midc, desc); midc_descriptor_complete(midc, desc);
}
} }
return; return;
} }
/**
* midc_lli_fill_sg - Helper function to convert
* SG list to Linked List Items.
*@midc: Channel
*@desc: DMA descriptor
*@sglist: Pointer to SG list
*@sglen: SG list length
*@flags: DMA transaction flags
*
* Walk through the SG list and convert the SG list into Linked
* List Items (LLI).
*/
static int midc_lli_fill_sg(struct intel_mid_dma_chan *midc,
struct intel_mid_dma_desc *desc,
struct scatterlist *sglist,
unsigned int sglen,
unsigned int flags)
{
struct intel_mid_dma_slave *mids;
struct scatterlist *sg;
dma_addr_t lli_next, sg_phy_addr;
struct intel_mid_dma_lli *lli_bloc_desc;
union intel_mid_dma_ctl_lo ctl_lo;
union intel_mid_dma_ctl_hi ctl_hi;
int i;
pr_debug("MDMA: Entered midc_lli_fill_sg\n");
mids = midc->mid_slave;
lli_bloc_desc = desc->lli;
lli_next = desc->lli_phys;
ctl_lo.ctl_lo = desc->ctl_lo;
ctl_hi.ctl_hi = desc->ctl_hi;
for_each_sg(sglist, sg, sglen, i) {
/*Populate CTL_LOW and LLI values*/
if (i != sglen - 1) {
lli_next = lli_next +
sizeof(struct intel_mid_dma_lli);
} else {
/*Check for circular list, otherwise terminate LLI to ZERO*/
if (flags & DMA_PREP_CIRCULAR_LIST) {
pr_debug("MDMA: LLI is configured in circular mode\n");
lli_next = desc->lli_phys;
} else {
lli_next = 0;
ctl_lo.ctlx.llp_dst_en = 0;
ctl_lo.ctlx.llp_src_en = 0;
}
}
/*Populate CTL_HI values*/
ctl_hi.ctlx.block_ts = get_block_ts(sg->length,
desc->width,
midc->dma->block_size);
/*Populate SAR and DAR values*/
sg_phy_addr = sg_phys(sg);
if (desc->dirn == DMA_TO_DEVICE) {
lli_bloc_desc->sar = sg_phy_addr;
lli_bloc_desc->dar = mids->dma_slave.dst_addr;
} else if (desc->dirn == DMA_FROM_DEVICE) {
lli_bloc_desc->sar = mids->dma_slave.src_addr;
lli_bloc_desc->dar = sg_phy_addr;
}
/*Copy values into block descriptor in system memroy*/
lli_bloc_desc->llp = lli_next;
lli_bloc_desc->ctl_lo = ctl_lo.ctl_lo;
lli_bloc_desc->ctl_hi = ctl_hi.ctl_hi;
lli_bloc_desc++;
}
/*Copy very first LLI values to descriptor*/
desc->ctl_lo = desc->lli->ctl_lo;
desc->ctl_hi = desc->lli->ctl_hi;
desc->sar = desc->lli->sar;
desc->dar = desc->lli->dar;
return 0;
}
/***************************************************************************** /*****************************************************************************
DMA engine callback Functions*/ DMA engine callback Functions*/
/** /**
...@@ -349,12 +442,12 @@ static dma_cookie_t intel_mid_dma_tx_submit(struct dma_async_tx_descriptor *tx) ...@@ -349,12 +442,12 @@ static dma_cookie_t intel_mid_dma_tx_submit(struct dma_async_tx_descriptor *tx)
desc->txd.cookie = cookie; desc->txd.cookie = cookie;
if (list_empty(&midc->active_list)) { if (list_empty(&midc->active_list))
midc_dostart(midc, desc);
list_add_tail(&desc->desc_node, &midc->active_list); list_add_tail(&desc->desc_node, &midc->active_list);
} else { else
list_add_tail(&desc->desc_node, &midc->queue); list_add_tail(&desc->desc_node, &midc->queue);
}
midc_dostart(midc, desc);
spin_unlock_bh(&midc->lock); spin_unlock_bh(&midc->lock);
return cookie; return cookie;
...@@ -414,6 +507,23 @@ static enum dma_status intel_mid_dma_tx_status(struct dma_chan *chan, ...@@ -414,6 +507,23 @@ static enum dma_status intel_mid_dma_tx_status(struct dma_chan *chan,
return ret; return ret;
} }
static int dma_slave_control(struct dma_chan *chan, unsigned long arg)
{
struct intel_mid_dma_chan *midc = to_intel_mid_dma_chan(chan);
struct dma_slave_config *slave = (struct dma_slave_config *)arg;
struct intel_mid_dma_slave *mid_slave;
BUG_ON(!midc);
BUG_ON(!slave);
pr_debug("MDMA: slave control called\n");
mid_slave = to_intel_mid_dma_slave(slave);
BUG_ON(!mid_slave);
midc->mid_slave = mid_slave;
return 0;
}
/** /**
* intel_mid_dma_device_control - DMA device control * intel_mid_dma_device_control - DMA device control
* @chan: chan for DMA control * @chan: chan for DMA control
...@@ -428,49 +538,41 @@ static int intel_mid_dma_device_control(struct dma_chan *chan, ...@@ -428,49 +538,41 @@ static int intel_mid_dma_device_control(struct dma_chan *chan,
struct intel_mid_dma_chan *midc = to_intel_mid_dma_chan(chan); struct intel_mid_dma_chan *midc = to_intel_mid_dma_chan(chan);
struct middma_device *mid = to_middma_device(chan->device); struct middma_device *mid = to_middma_device(chan->device);
struct intel_mid_dma_desc *desc, *_desc; struct intel_mid_dma_desc *desc, *_desc;
LIST_HEAD(list); union intel_mid_dma_cfg_lo cfg_lo;
if (cmd == DMA_SLAVE_CONFIG)
return dma_slave_control(chan, arg);
if (cmd != DMA_TERMINATE_ALL) if (cmd != DMA_TERMINATE_ALL)
return -ENXIO; return -ENXIO;
spin_lock_bh(&midc->lock); spin_lock_bh(&midc->lock);
if (midc->in_use == false) { if (midc->busy == false) {
spin_unlock_bh(&midc->lock); spin_unlock_bh(&midc->lock);
return 0; return 0;
} }
list_splice_init(&midc->free_list, &list); /*Suspend and disable the channel*/
midc->descs_allocated = 0; cfg_lo.cfg_lo = ioread32(midc->ch_regs + CFG_LOW);
midc->slave = NULL; cfg_lo.cfgx.ch_susp = 1;
iowrite32(cfg_lo.cfg_lo, midc->ch_regs + CFG_LOW);
iowrite32(DISABLE_CHANNEL(midc->ch_id), mid->dma_base + DMA_CHAN_EN);
midc->busy = false;
/* Disable interrupts */ /* Disable interrupts */
disable_dma_interrupt(midc); disable_dma_interrupt(midc);
midc->descs_allocated = 0;
spin_unlock_bh(&midc->lock); spin_unlock_bh(&midc->lock);
list_for_each_entry_safe(desc, _desc, &list, desc_node) { list_for_each_entry_safe(desc, _desc, &midc->active_list, desc_node) {
pr_debug("MDMA: freeing descriptor %p\n", desc); if (desc->lli != NULL) {
pci_pool_free(mid->dma_pool, desc, desc->txd.phys); pci_pool_free(desc->lli_pool, desc->lli,
desc->lli_phys);
pci_pool_destroy(desc->lli_pool);
}
list_move(&desc->desc_node, &midc->free_list);
} }
return 0; return 0;
} }
/**
* intel_mid_dma_prep_slave_sg - Prep slave sg txn
* @chan: chan for DMA transfer
* @sgl: scatter gather list
* @sg_len: length of sg txn
* @direction: DMA transfer dirtn
* @flags: DMA flags
*
* Do DMA sg txn: NOT supported now
*/
static struct dma_async_tx_descriptor *intel_mid_dma_prep_slave_sg(
struct dma_chan *chan, struct scatterlist *sgl,
unsigned int sg_len, enum dma_data_direction direction,
unsigned long flags)
{
/*not supported now*/
return NULL;
}
/** /**
* intel_mid_dma_prep_memcpy - Prep memcpy txn * intel_mid_dma_prep_memcpy - Prep memcpy txn
...@@ -495,23 +597,24 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy( ...@@ -495,23 +597,24 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy(
union intel_mid_dma_ctl_hi ctl_hi; union intel_mid_dma_ctl_hi ctl_hi;
union intel_mid_dma_cfg_lo cfg_lo; union intel_mid_dma_cfg_lo cfg_lo;
union intel_mid_dma_cfg_hi cfg_hi; union intel_mid_dma_cfg_hi cfg_hi;
enum intel_mid_dma_width width = 0; enum dma_slave_buswidth width;
pr_debug("MDMA: Prep for memcpy\n"); pr_debug("MDMA: Prep for memcpy\n");
WARN_ON(!chan); BUG_ON(!chan);
if (!len) if (!len)
return NULL; return NULL;
mids = chan->private;
WARN_ON(!mids);
midc = to_intel_mid_dma_chan(chan); midc = to_intel_mid_dma_chan(chan);
WARN_ON(!midc); BUG_ON(!midc);
mids = midc->mid_slave;
BUG_ON(!mids);
pr_debug("MDMA:called for DMA %x CH %d Length %zu\n", pr_debug("MDMA:called for DMA %x CH %d Length %zu\n",
midc->dma->pci_id, midc->ch_id, len); midc->dma->pci_id, midc->ch_id, len);
pr_debug("MDMA:Cfg passed Mode %x, Dirn %x, HS %x, Width %x\n", pr_debug("MDMA:Cfg passed Mode %x, Dirn %x, HS %x, Width %x\n",
mids->cfg_mode, mids->dirn, mids->hs_mode, mids->src_width); mids->cfg_mode, mids->dma_slave.direction,
mids->hs_mode, mids->dma_slave.src_addr_width);
/*calculate CFG_LO*/ /*calculate CFG_LO*/
if (mids->hs_mode == LNW_DMA_SW_HS) { if (mids->hs_mode == LNW_DMA_SW_HS) {
...@@ -530,13 +633,13 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy( ...@@ -530,13 +633,13 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy(
if (midc->dma->pimr_mask) { if (midc->dma->pimr_mask) {
cfg_hi.cfgx.protctl = 0x0; /*default value*/ cfg_hi.cfgx.protctl = 0x0; /*default value*/
cfg_hi.cfgx.fifo_mode = 1; cfg_hi.cfgx.fifo_mode = 1;
if (mids->dirn == DMA_TO_DEVICE) { if (mids->dma_slave.direction == DMA_TO_DEVICE) {
cfg_hi.cfgx.src_per = 0; cfg_hi.cfgx.src_per = 0;
if (mids->device_instance == 0) if (mids->device_instance == 0)
cfg_hi.cfgx.dst_per = 3; cfg_hi.cfgx.dst_per = 3;
if (mids->device_instance == 1) if (mids->device_instance == 1)
cfg_hi.cfgx.dst_per = 1; cfg_hi.cfgx.dst_per = 1;
} else if (mids->dirn == DMA_FROM_DEVICE) { } else if (mids->dma_slave.direction == DMA_FROM_DEVICE) {
if (mids->device_instance == 0) if (mids->device_instance == 0)
cfg_hi.cfgx.src_per = 2; cfg_hi.cfgx.src_per = 2;
if (mids->device_instance == 1) if (mids->device_instance == 1)
...@@ -552,7 +655,8 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy( ...@@ -552,7 +655,8 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy(
/*calculate CTL_HI*/ /*calculate CTL_HI*/
ctl_hi.ctlx.reser = 0; ctl_hi.ctlx.reser = 0;
width = mids->src_width; ctl_hi.ctlx.done = 0;
width = mids->dma_slave.src_addr_width;
ctl_hi.ctlx.block_ts = get_block_ts(len, width, midc->dma->block_size); ctl_hi.ctlx.block_ts = get_block_ts(len, width, midc->dma->block_size);
pr_debug("MDMA:calc len %d for block size %d\n", pr_debug("MDMA:calc len %d for block size %d\n",
...@@ -560,21 +664,21 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy( ...@@ -560,21 +664,21 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy(
/*calculate CTL_LO*/ /*calculate CTL_LO*/
ctl_lo.ctl_lo = 0; ctl_lo.ctl_lo = 0;
ctl_lo.ctlx.int_en = 1; ctl_lo.ctlx.int_en = 1;
ctl_lo.ctlx.dst_tr_width = mids->dst_width; ctl_lo.ctlx.dst_tr_width = mids->dma_slave.dst_addr_width;
ctl_lo.ctlx.src_tr_width = mids->src_width; ctl_lo.ctlx.src_tr_width = mids->dma_slave.src_addr_width;
ctl_lo.ctlx.dst_msize = mids->src_msize; ctl_lo.ctlx.dst_msize = mids->dma_slave.src_maxburst;
ctl_lo.ctlx.src_msize = mids->dst_msize; ctl_lo.ctlx.src_msize = mids->dma_slave.dst_maxburst;
if (mids->cfg_mode == LNW_DMA_MEM_TO_MEM) { if (mids->cfg_mode == LNW_DMA_MEM_TO_MEM) {
ctl_lo.ctlx.tt_fc = 0; ctl_lo.ctlx.tt_fc = 0;
ctl_lo.ctlx.sinc = 0; ctl_lo.ctlx.sinc = 0;
ctl_lo.ctlx.dinc = 0; ctl_lo.ctlx.dinc = 0;
} else { } else {
if (mids->dirn == DMA_TO_DEVICE) { if (mids->dma_slave.direction == DMA_TO_DEVICE) {
ctl_lo.ctlx.sinc = 0; ctl_lo.ctlx.sinc = 0;
ctl_lo.ctlx.dinc = 2; ctl_lo.ctlx.dinc = 2;
ctl_lo.ctlx.tt_fc = 1; ctl_lo.ctlx.tt_fc = 1;
} else if (mids->dirn == DMA_FROM_DEVICE) { } else if (mids->dma_slave.direction == DMA_FROM_DEVICE) {
ctl_lo.ctlx.sinc = 2; ctl_lo.ctlx.sinc = 2;
ctl_lo.ctlx.dinc = 0; ctl_lo.ctlx.dinc = 0;
ctl_lo.ctlx.tt_fc = 2; ctl_lo.ctlx.tt_fc = 2;
...@@ -597,7 +701,10 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy( ...@@ -597,7 +701,10 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy(
desc->ctl_lo = ctl_lo.ctl_lo; desc->ctl_lo = ctl_lo.ctl_lo;
desc->ctl_hi = ctl_hi.ctl_hi; desc->ctl_hi = ctl_hi.ctl_hi;
desc->width = width; desc->width = width;
desc->dirn = mids->dirn; desc->dirn = mids->dma_slave.direction;
desc->lli_phys = 0;
desc->lli = NULL;
desc->lli_pool = NULL;
return &desc->txd; return &desc->txd;
err_desc_get: err_desc_get:
...@@ -605,6 +712,85 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy( ...@@ -605,6 +712,85 @@ static struct dma_async_tx_descriptor *intel_mid_dma_prep_memcpy(
midc_desc_put(midc, desc); midc_desc_put(midc, desc);
return NULL; return NULL;
} }
/**
* intel_mid_dma_prep_slave_sg - Prep slave sg txn
* @chan: chan for DMA transfer
* @sgl: scatter gather list
* @sg_len: length of sg txn
* @direction: DMA transfer dirtn
* @flags: DMA flags
*
* Prepares LLI based periphral transfer
*/
static struct dma_async_tx_descriptor *intel_mid_dma_prep_slave_sg(
struct dma_chan *chan, struct scatterlist *sgl,
unsigned int sg_len, enum dma_data_direction direction,
unsigned long flags)
{
struct intel_mid_dma_chan *midc = NULL;
struct intel_mid_dma_slave *mids = NULL;
struct intel_mid_dma_desc *desc = NULL;
struct dma_async_tx_descriptor *txd = NULL;
union intel_mid_dma_ctl_lo ctl_lo;
pr_debug("MDMA: Prep for slave SG\n");
if (!sg_len) {
pr_err("MDMA: Invalid SG length\n");
return NULL;
}
midc = to_intel_mid_dma_chan(chan);
BUG_ON(!midc);
mids = midc->mid_slave;
BUG_ON(!mids);
if (!midc->dma->pimr_mask) {
pr_debug("MDMA: SG list is not supported by this controller\n");
return NULL;
}
pr_debug("MDMA: SG Length = %d, direction = %d, Flags = %#lx\n",
sg_len, direction, flags);
txd = intel_mid_dma_prep_memcpy(chan, 0, 0, sgl->length, flags);
if (NULL == txd) {
pr_err("MDMA: Prep memcpy failed\n");
return NULL;
}
desc = to_intel_mid_dma_desc(txd);
desc->dirn = direction;
ctl_lo.ctl_lo = desc->ctl_lo;
ctl_lo.ctlx.llp_dst_en = 1;
ctl_lo.ctlx.llp_src_en = 1;
desc->ctl_lo = ctl_lo.ctl_lo;
desc->lli_length = sg_len;
desc->current_lli = 0;
/* DMA coherent memory pool for LLI descriptors*/
desc->lli_pool = pci_pool_create("intel_mid_dma_lli_pool",
midc->dma->pdev,
(sizeof(struct intel_mid_dma_lli)*sg_len),
32, 0);
if (NULL == desc->lli_pool) {
pr_err("MID_DMA:LLI pool create failed\n");
return NULL;
}
desc->lli = pci_pool_alloc(desc->lli_pool, GFP_KERNEL, &desc->lli_phys);
if (!desc->lli) {
pr_err("MID_DMA: LLI alloc failed\n");
pci_pool_destroy(desc->lli_pool);
return NULL;
}
midc_lli_fill_sg(midc, desc, sgl, sg_len, flags);
if (flags & DMA_PREP_INTERRUPT) {
iowrite32(UNMASK_INTR_REG(midc->ch_id),
midc->dma_base + MASK_BLOCK);
pr_debug("MDMA:Enabled Block interrupt\n");
}
return &desc->txd;
}
/** /**
* intel_mid_dma_free_chan_resources - Frees dma resources * intel_mid_dma_free_chan_resources - Frees dma resources
...@@ -618,11 +804,11 @@ static void intel_mid_dma_free_chan_resources(struct dma_chan *chan) ...@@ -618,11 +804,11 @@ static void intel_mid_dma_free_chan_resources(struct dma_chan *chan)
struct middma_device *mid = to_middma_device(chan->device); struct middma_device *mid = to_middma_device(chan->device);
struct intel_mid_dma_desc *desc, *_desc; struct intel_mid_dma_desc *desc, *_desc;
if (true == midc->in_use) { if (true == midc->busy) {
/*trying to free ch in use!!!!!*/ /*trying to free ch in use!!!!!*/
pr_err("ERR_MDMA: trying to free ch in use\n"); pr_err("ERR_MDMA: trying to free ch in use\n");
} }
pm_runtime_put(&mid->pdev->dev);
spin_lock_bh(&midc->lock); spin_lock_bh(&midc->lock);
midc->descs_allocated = 0; midc->descs_allocated = 0;
list_for_each_entry_safe(desc, _desc, &midc->active_list, desc_node) { list_for_each_entry_safe(desc, _desc, &midc->active_list, desc_node) {
...@@ -639,6 +825,7 @@ static void intel_mid_dma_free_chan_resources(struct dma_chan *chan) ...@@ -639,6 +825,7 @@ static void intel_mid_dma_free_chan_resources(struct dma_chan *chan)
} }
spin_unlock_bh(&midc->lock); spin_unlock_bh(&midc->lock);
midc->in_use = false; midc->in_use = false;
midc->busy = false;
/* Disable CH interrupts */ /* Disable CH interrupts */
iowrite32(MASK_INTR_REG(midc->ch_id), mid->dma_base + MASK_BLOCK); iowrite32(MASK_INTR_REG(midc->ch_id), mid->dma_base + MASK_BLOCK);
iowrite32(MASK_INTR_REG(midc->ch_id), mid->dma_base + MASK_ERR); iowrite32(MASK_INTR_REG(midc->ch_id), mid->dma_base + MASK_ERR);
...@@ -659,11 +846,20 @@ static int intel_mid_dma_alloc_chan_resources(struct dma_chan *chan) ...@@ -659,11 +846,20 @@ static int intel_mid_dma_alloc_chan_resources(struct dma_chan *chan)
dma_addr_t phys; dma_addr_t phys;
int i = 0; int i = 0;
pm_runtime_get_sync(&mid->pdev->dev);
if (mid->state == SUSPENDED) {
if (dma_resume(mid->pdev)) {
pr_err("ERR_MDMA: resume failed");
return -EFAULT;
}
}
/* ASSERT: channel is idle */ /* ASSERT: channel is idle */
if (test_ch_en(mid->dma_base, midc->ch_id)) { if (test_ch_en(mid->dma_base, midc->ch_id)) {
/*ch is not idle*/ /*ch is not idle*/
pr_err("ERR_MDMA: ch not idle\n"); pr_err("ERR_MDMA: ch not idle\n");
pm_runtime_put(&mid->pdev->dev);
return -EIO; return -EIO;
} }
midc->completed = chan->cookie = 1; midc->completed = chan->cookie = 1;
...@@ -674,6 +870,7 @@ static int intel_mid_dma_alloc_chan_resources(struct dma_chan *chan) ...@@ -674,6 +870,7 @@ static int intel_mid_dma_alloc_chan_resources(struct dma_chan *chan)
desc = pci_pool_alloc(mid->dma_pool, GFP_KERNEL, &phys); desc = pci_pool_alloc(mid->dma_pool, GFP_KERNEL, &phys);
if (!desc) { if (!desc) {
pr_err("ERR_MDMA: desc failed\n"); pr_err("ERR_MDMA: desc failed\n");
pm_runtime_put(&mid->pdev->dev);
return -ENOMEM; return -ENOMEM;
/*check*/ /*check*/
} }
...@@ -686,7 +883,8 @@ static int intel_mid_dma_alloc_chan_resources(struct dma_chan *chan) ...@@ -686,7 +883,8 @@ static int intel_mid_dma_alloc_chan_resources(struct dma_chan *chan)
list_add_tail(&desc->desc_node, &midc->free_list); list_add_tail(&desc->desc_node, &midc->free_list);
} }
spin_unlock_bh(&midc->lock); spin_unlock_bh(&midc->lock);
midc->in_use = false; midc->in_use = true;
midc->busy = false;
pr_debug("MID_DMA: Desc alloc done ret: %d desc\n", i); pr_debug("MID_DMA: Desc alloc done ret: %d desc\n", i);
return i; return i;
} }
...@@ -715,7 +913,7 @@ static void dma_tasklet(unsigned long data) ...@@ -715,7 +913,7 @@ static void dma_tasklet(unsigned long data)
{ {
struct middma_device *mid = NULL; struct middma_device *mid = NULL;
struct intel_mid_dma_chan *midc = NULL; struct intel_mid_dma_chan *midc = NULL;
u32 status; u32 status, raw_tfr, raw_block;
int i; int i;
mid = (struct middma_device *)data; mid = (struct middma_device *)data;
...@@ -724,8 +922,9 @@ static void dma_tasklet(unsigned long data) ...@@ -724,8 +922,9 @@ static void dma_tasklet(unsigned long data)
return; return;
} }
pr_debug("MDMA: in tasklet for device %x\n", mid->pci_id); pr_debug("MDMA: in tasklet for device %x\n", mid->pci_id);
status = ioread32(mid->dma_base + RAW_TFR); raw_tfr = ioread32(mid->dma_base + RAW_TFR);
pr_debug("MDMA:RAW_TFR %x\n", status); raw_block = ioread32(mid->dma_base + RAW_BLOCK);
status = raw_tfr | raw_block;
status &= mid->intr_mask; status &= mid->intr_mask;
while (status) { while (status) {
/*txn interrupt*/ /*txn interrupt*/
...@@ -741,15 +940,23 @@ static void dma_tasklet(unsigned long data) ...@@ -741,15 +940,23 @@ static void dma_tasklet(unsigned long data)
} }
pr_debug("MDMA:Tx complete interrupt %x, Ch No %d Index %d\n", pr_debug("MDMA:Tx complete interrupt %x, Ch No %d Index %d\n",
status, midc->ch_id, i); status, midc->ch_id, i);
midc->raw_tfr = raw_tfr;
midc->raw_block = raw_block;
spin_lock_bh(&midc->lock);
/*clearing this interrupts first*/ /*clearing this interrupts first*/
iowrite32((1 << midc->ch_id), mid->dma_base + CLEAR_TFR); iowrite32((1 << midc->ch_id), mid->dma_base + CLEAR_TFR);
iowrite32((1 << midc->ch_id), mid->dma_base + CLEAR_BLOCK); if (raw_block) {
iowrite32((1 << midc->ch_id),
spin_lock_bh(&midc->lock); mid->dma_base + CLEAR_BLOCK);
}
midc_scan_descriptors(mid, midc); midc_scan_descriptors(mid, midc);
pr_debug("MDMA:Scan of desc... complete, unmasking\n"); pr_debug("MDMA:Scan of desc... complete, unmasking\n");
iowrite32(UNMASK_INTR_REG(midc->ch_id), iowrite32(UNMASK_INTR_REG(midc->ch_id),
mid->dma_base + MASK_TFR); mid->dma_base + MASK_TFR);
if (raw_block) {
iowrite32(UNMASK_INTR_REG(midc->ch_id),
mid->dma_base + MASK_BLOCK);
}
spin_unlock_bh(&midc->lock); spin_unlock_bh(&midc->lock);
} }
...@@ -804,9 +1011,14 @@ static void dma_tasklet2(unsigned long data) ...@@ -804,9 +1011,14 @@ static void dma_tasklet2(unsigned long data)
static irqreturn_t intel_mid_dma_interrupt(int irq, void *data) static irqreturn_t intel_mid_dma_interrupt(int irq, void *data)
{ {
struct middma_device *mid = data; struct middma_device *mid = data;
u32 status; u32 tfr_status, err_status;
int call_tasklet = 0; int call_tasklet = 0;
tfr_status = ioread32(mid->dma_base + RAW_TFR);
err_status = ioread32(mid->dma_base + RAW_ERR);
if (!tfr_status && !err_status)
return IRQ_NONE;
/*DMA Interrupt*/ /*DMA Interrupt*/
pr_debug("MDMA:Got an interrupt on irq %d\n", irq); pr_debug("MDMA:Got an interrupt on irq %d\n", irq);
if (!mid) { if (!mid) {
...@@ -814,19 +1026,18 @@ static irqreturn_t intel_mid_dma_interrupt(int irq, void *data) ...@@ -814,19 +1026,18 @@ static irqreturn_t intel_mid_dma_interrupt(int irq, void *data)
return -EINVAL; return -EINVAL;
} }
status = ioread32(mid->dma_base + RAW_TFR); pr_debug("MDMA: Status %x, Mask %x\n", tfr_status, mid->intr_mask);
pr_debug("MDMA: Status %x, Mask %x\n", status, mid->intr_mask); tfr_status &= mid->intr_mask;
status &= mid->intr_mask; if (tfr_status) {
if (status) {
/*need to disable intr*/ /*need to disable intr*/
iowrite32((status << 8), mid->dma_base + MASK_TFR); iowrite32((tfr_status << INT_MASK_WE), mid->dma_base + MASK_TFR);
pr_debug("MDMA: Calling tasklet %x\n", status); iowrite32((tfr_status << INT_MASK_WE), mid->dma_base + MASK_BLOCK);
pr_debug("MDMA: Calling tasklet %x\n", tfr_status);
call_tasklet = 1; call_tasklet = 1;
} }
status = ioread32(mid->dma_base + RAW_ERR); err_status &= mid->intr_mask;
status &= mid->intr_mask; if (err_status) {
if (status) { iowrite32(MASK_INTR_REG(err_status), mid->dma_base + MASK_ERR);
iowrite32(MASK_INTR_REG(status), mid->dma_base + MASK_ERR);
call_tasklet = 1; call_tasklet = 1;
} }
if (call_tasklet) if (call_tasklet)
...@@ -856,7 +1067,6 @@ static int mid_setup_dma(struct pci_dev *pdev) ...@@ -856,7 +1067,6 @@ static int mid_setup_dma(struct pci_dev *pdev)
{ {
struct middma_device *dma = pci_get_drvdata(pdev); struct middma_device *dma = pci_get_drvdata(pdev);
int err, i; int err, i;
unsigned int irq_level;
/* DMA coherent memory pool for DMA descriptor allocations */ /* DMA coherent memory pool for DMA descriptor allocations */
dma->dma_pool = pci_pool_create("intel_mid_dma_desc_pool", pdev, dma->dma_pool = pci_pool_create("intel_mid_dma_desc_pool", pdev,
...@@ -884,6 +1094,7 @@ static int mid_setup_dma(struct pci_dev *pdev) ...@@ -884,6 +1094,7 @@ static int mid_setup_dma(struct pci_dev *pdev)
pr_debug("MDMA:Adding %d channel for this controller\n", dma->max_chan); pr_debug("MDMA:Adding %d channel for this controller\n", dma->max_chan);
/*init CH structures*/ /*init CH structures*/
dma->intr_mask = 0; dma->intr_mask = 0;
dma->state = RUNNING;
for (i = 0; i < dma->max_chan; i++) { for (i = 0; i < dma->max_chan; i++) {
struct intel_mid_dma_chan *midch = &dma->ch[i]; struct intel_mid_dma_chan *midch = &dma->ch[i];
...@@ -943,7 +1154,6 @@ static int mid_setup_dma(struct pci_dev *pdev) ...@@ -943,7 +1154,6 @@ static int mid_setup_dma(struct pci_dev *pdev)
/*register irq */ /*register irq */
if (dma->pimr_mask) { if (dma->pimr_mask) {
irq_level = IRQF_SHARED;
pr_debug("MDMA:Requesting irq shared for DMAC1\n"); pr_debug("MDMA:Requesting irq shared for DMAC1\n");
err = request_irq(pdev->irq, intel_mid_dma_interrupt1, err = request_irq(pdev->irq, intel_mid_dma_interrupt1,
IRQF_SHARED, "INTEL_MID_DMAC1", dma); IRQF_SHARED, "INTEL_MID_DMAC1", dma);
...@@ -951,10 +1161,9 @@ static int mid_setup_dma(struct pci_dev *pdev) ...@@ -951,10 +1161,9 @@ static int mid_setup_dma(struct pci_dev *pdev)
goto err_irq; goto err_irq;
} else { } else {
dma->intr_mask = 0x03; dma->intr_mask = 0x03;
irq_level = 0;
pr_debug("MDMA:Requesting irq for DMAC2\n"); pr_debug("MDMA:Requesting irq for DMAC2\n");
err = request_irq(pdev->irq, intel_mid_dma_interrupt2, err = request_irq(pdev->irq, intel_mid_dma_interrupt2,
0, "INTEL_MID_DMAC2", dma); IRQF_SHARED, "INTEL_MID_DMAC2", dma);
if (0 != err) if (0 != err)
goto err_irq; goto err_irq;
} }
...@@ -1070,6 +1279,9 @@ static int __devinit intel_mid_dma_probe(struct pci_dev *pdev, ...@@ -1070,6 +1279,9 @@ static int __devinit intel_mid_dma_probe(struct pci_dev *pdev,
if (err) if (err)
goto err_dma; goto err_dma;
pm_runtime_set_active(&pdev->dev);
pm_runtime_enable(&pdev->dev);
pm_runtime_allow(&pdev->dev);
return 0; return 0;
err_dma: err_dma:
...@@ -1104,6 +1316,85 @@ static void __devexit intel_mid_dma_remove(struct pci_dev *pdev) ...@@ -1104,6 +1316,85 @@ static void __devexit intel_mid_dma_remove(struct pci_dev *pdev)
pci_disable_device(pdev); pci_disable_device(pdev);
} }
/* Power Management */
/*
* dma_suspend - PCI suspend function
*
* @pci: PCI device structure
* @state: PM message
*
* This function is called by OS when a power event occurs
*/
int dma_suspend(struct pci_dev *pci, pm_message_t state)
{
int i;
struct middma_device *device = pci_get_drvdata(pci);
pr_debug("MDMA: dma_suspend called\n");
for (i = 0; i < device->max_chan; i++) {
if (device->ch[i].in_use)
return -EAGAIN;
}
device->state = SUSPENDED;
pci_set_drvdata(pci, device);
pci_save_state(pci);
pci_disable_device(pci);
pci_set_power_state(pci, PCI_D3hot);
return 0;
}
/**
* dma_resume - PCI resume function
*
* @pci: PCI device structure
*
* This function is called by OS when a power event occurs
*/
int dma_resume(struct pci_dev *pci)
{
int ret;
struct middma_device *device = pci_get_drvdata(pci);
pr_debug("MDMA: dma_resume called\n");
pci_set_power_state(pci, PCI_D0);
pci_restore_state(pci);
ret = pci_enable_device(pci);
if (ret) {
pr_err("MDMA: device cant be enabled for %x\n", pci->device);
return ret;
}
device->state = RUNNING;
iowrite32(REG_BIT0, device->dma_base + DMA_CFG);
pci_set_drvdata(pci, device);
return 0;
}
static int dma_runtime_suspend(struct device *dev)
{
struct pci_dev *pci_dev = to_pci_dev(dev);
return dma_suspend(pci_dev, PMSG_SUSPEND);
}
static int dma_runtime_resume(struct device *dev)
{
struct pci_dev *pci_dev = to_pci_dev(dev);
return dma_resume(pci_dev);
}
static int dma_runtime_idle(struct device *dev)
{
struct pci_dev *pdev = to_pci_dev(dev);
struct middma_device *device = pci_get_drvdata(pdev);
int i;
for (i = 0; i < device->max_chan; i++) {
if (device->ch[i].in_use)
return -EAGAIN;
}
return pm_schedule_suspend(dev, 0);
}
/****************************************************************************** /******************************************************************************
* PCI stuff * PCI stuff
*/ */
...@@ -1116,11 +1407,24 @@ static struct pci_device_id intel_mid_dma_ids[] = { ...@@ -1116,11 +1407,24 @@ static struct pci_device_id intel_mid_dma_ids[] = {
}; };
MODULE_DEVICE_TABLE(pci, intel_mid_dma_ids); MODULE_DEVICE_TABLE(pci, intel_mid_dma_ids);
static const struct dev_pm_ops intel_mid_dma_pm = {
.runtime_suspend = dma_runtime_suspend,
.runtime_resume = dma_runtime_resume,
.runtime_idle = dma_runtime_idle,
};
static struct pci_driver intel_mid_dma_pci = { static struct pci_driver intel_mid_dma_pci = {
.name = "Intel MID DMA", .name = "Intel MID DMA",
.id_table = intel_mid_dma_ids, .id_table = intel_mid_dma_ids,
.probe = intel_mid_dma_probe, .probe = intel_mid_dma_probe,
.remove = __devexit_p(intel_mid_dma_remove), .remove = __devexit_p(intel_mid_dma_remove),
#ifdef CONFIG_PM
.suspend = dma_suspend,
.resume = dma_resume,
.driver = {
.pm = &intel_mid_dma_pm,
},
#endif
}; };
static int __init intel_mid_dma_init(void) static int __init intel_mid_dma_init(void)
......
...@@ -29,11 +29,12 @@ ...@@ -29,11 +29,12 @@
#include <linux/dmapool.h> #include <linux/dmapool.h>
#include <linux/pci_ids.h> #include <linux/pci_ids.h>
#define INTEL_MID_DMA_DRIVER_VERSION "1.0.5" #define INTEL_MID_DMA_DRIVER_VERSION "1.1.0"
#define REG_BIT0 0x00000001 #define REG_BIT0 0x00000001
#define REG_BIT8 0x00000100 #define REG_BIT8 0x00000100
#define INT_MASK_WE 0x8
#define CLEAR_DONE 0xFFFFEFFF
#define UNMASK_INTR_REG(chan_num) \ #define UNMASK_INTR_REG(chan_num) \
((REG_BIT0 << chan_num) | (REG_BIT8 << chan_num)) ((REG_BIT0 << chan_num) | (REG_BIT8 << chan_num))
#define MASK_INTR_REG(chan_num) (REG_BIT8 << chan_num) #define MASK_INTR_REG(chan_num) (REG_BIT8 << chan_num)
...@@ -41,6 +42,9 @@ ...@@ -41,6 +42,9 @@
#define ENABLE_CHANNEL(chan_num) \ #define ENABLE_CHANNEL(chan_num) \
((REG_BIT0 << chan_num) | (REG_BIT8 << chan_num)) ((REG_BIT0 << chan_num) | (REG_BIT8 << chan_num))
#define DISABLE_CHANNEL(chan_num) \
(REG_BIT8 << chan_num)
#define DESCS_PER_CHANNEL 16 #define DESCS_PER_CHANNEL 16
/*DMA Registers*/ /*DMA Registers*/
/*registers associated with channel programming*/ /*registers associated with channel programming*/
...@@ -50,6 +54,7 @@ ...@@ -50,6 +54,7 @@
/*CH X REG = (DMA_CH_SIZE)*CH_NO + REG*/ /*CH X REG = (DMA_CH_SIZE)*CH_NO + REG*/
#define SAR 0x00 /* Source Address Register*/ #define SAR 0x00 /* Source Address Register*/
#define DAR 0x08 /* Destination Address Register*/ #define DAR 0x08 /* Destination Address Register*/
#define LLP 0x10 /* Linked List Pointer Register*/
#define CTL_LOW 0x18 /* Control Register*/ #define CTL_LOW 0x18 /* Control Register*/
#define CTL_HIGH 0x1C /* Control Register*/ #define CTL_HIGH 0x1C /* Control Register*/
#define CFG_LOW 0x40 /* Configuration Register Low*/ #define CFG_LOW 0x40 /* Configuration Register Low*/
...@@ -112,8 +117,8 @@ union intel_mid_dma_ctl_lo { ...@@ -112,8 +117,8 @@ union intel_mid_dma_ctl_lo {
union intel_mid_dma_ctl_hi { union intel_mid_dma_ctl_hi {
struct { struct {
u32 block_ts:12; /*block transfer size*/ u32 block_ts:12; /*block transfer size*/
/*configured by DMAC*/ u32 done:1; /*Done - updated by DMAC*/
u32 reser:20; u32 reser:19; /*configured by DMAC*/
} ctlx; } ctlx;
u32 ctl_hi; u32 ctl_hi;
...@@ -152,6 +157,7 @@ union intel_mid_dma_cfg_hi { ...@@ -152,6 +157,7 @@ union intel_mid_dma_cfg_hi {
u32 cfg_hi; u32 cfg_hi;
}; };
/** /**
* struct intel_mid_dma_chan - internal mid representation of a DMA channel * struct intel_mid_dma_chan - internal mid representation of a DMA channel
* @chan: dma_chan strcture represetation for mid chan * @chan: dma_chan strcture represetation for mid chan
...@@ -166,7 +172,10 @@ union intel_mid_dma_cfg_hi { ...@@ -166,7 +172,10 @@ union intel_mid_dma_cfg_hi {
* @slave: dma slave struture * @slave: dma slave struture
* @descs_allocated: total number of decsiptors allocated * @descs_allocated: total number of decsiptors allocated
* @dma: dma device struture pointer * @dma: dma device struture pointer
* @busy: bool representing if ch is busy (active txn) or not
* @in_use: bool representing if ch is in use or not * @in_use: bool representing if ch is in use or not
* @raw_tfr: raw trf interrupt recieved
* @raw_block: raw block interrupt recieved
*/ */
struct intel_mid_dma_chan { struct intel_mid_dma_chan {
struct dma_chan chan; struct dma_chan chan;
...@@ -178,10 +187,13 @@ struct intel_mid_dma_chan { ...@@ -178,10 +187,13 @@ struct intel_mid_dma_chan {
struct list_head active_list; struct list_head active_list;
struct list_head queue; struct list_head queue;
struct list_head free_list; struct list_head free_list;
struct intel_mid_dma_slave *slave;
unsigned int descs_allocated; unsigned int descs_allocated;
struct middma_device *dma; struct middma_device *dma;
bool busy;
bool in_use; bool in_use;
u32 raw_tfr;
u32 raw_block;
struct intel_mid_dma_slave *mid_slave;
}; };
static inline struct intel_mid_dma_chan *to_intel_mid_dma_chan( static inline struct intel_mid_dma_chan *to_intel_mid_dma_chan(
...@@ -190,6 +202,10 @@ static inline struct intel_mid_dma_chan *to_intel_mid_dma_chan( ...@@ -190,6 +202,10 @@ static inline struct intel_mid_dma_chan *to_intel_mid_dma_chan(
return container_of(chan, struct intel_mid_dma_chan, chan); return container_of(chan, struct intel_mid_dma_chan, chan);
} }
enum intel_mid_dma_state {
RUNNING = 0,
SUSPENDED,
};
/** /**
* struct middma_device - internal representation of a DMA device * struct middma_device - internal representation of a DMA device
* @pdev: PCI device * @pdev: PCI device
...@@ -205,6 +221,7 @@ static inline struct intel_mid_dma_chan *to_intel_mid_dma_chan( ...@@ -205,6 +221,7 @@ static inline struct intel_mid_dma_chan *to_intel_mid_dma_chan(
* @max_chan: max number of chs supported (from drv_data) * @max_chan: max number of chs supported (from drv_data)
* @block_size: Block size of DMA transfer supported (from drv_data) * @block_size: Block size of DMA transfer supported (from drv_data)
* @pimr_mask: MMIO register addr for periphral interrupt (from drv_data) * @pimr_mask: MMIO register addr for periphral interrupt (from drv_data)
* @state: dma PM device state
*/ */
struct middma_device { struct middma_device {
struct pci_dev *pdev; struct pci_dev *pdev;
...@@ -220,6 +237,7 @@ struct middma_device { ...@@ -220,6 +237,7 @@ struct middma_device {
int max_chan; int max_chan;
int block_size; int block_size;
unsigned int pimr_mask; unsigned int pimr_mask;
enum intel_mid_dma_state state;
}; };
static inline struct middma_device *to_middma_device(struct dma_device *common) static inline struct middma_device *to_middma_device(struct dma_device *common)
...@@ -238,14 +256,27 @@ struct intel_mid_dma_desc { ...@@ -238,14 +256,27 @@ struct intel_mid_dma_desc {
u32 cfg_lo; u32 cfg_lo;
u32 ctl_lo; u32 ctl_lo;
u32 ctl_hi; u32 ctl_hi;
struct pci_pool *lli_pool;
struct intel_mid_dma_lli *lli;
dma_addr_t lli_phys;
unsigned int lli_length;
unsigned int current_lli;
dma_addr_t next; dma_addr_t next;
enum dma_data_direction dirn; enum dma_data_direction dirn;
enum dma_status status; enum dma_status status;
enum intel_mid_dma_width width; /*width of DMA txn*/ enum dma_slave_buswidth width; /*width of DMA txn*/
enum intel_mid_dma_mode cfg_mode; /*mode configuration*/ enum intel_mid_dma_mode cfg_mode; /*mode configuration*/
}; };
struct intel_mid_dma_lli {
dma_addr_t sar;
dma_addr_t dar;
dma_addr_t llp;
u32 ctl_lo;
u32 ctl_hi;
} __attribute__ ((packed));
static inline int test_ch_en(void __iomem *dma, u32 ch_no) static inline int test_ch_en(void __iomem *dma, u32 ch_no)
{ {
u32 en_reg = ioread32(dma + DMA_CHAN_EN); u32 en_reg = ioread32(dma + DMA_CHAN_EN);
...@@ -257,4 +288,14 @@ static inline struct intel_mid_dma_desc *to_intel_mid_dma_desc ...@@ -257,4 +288,14 @@ static inline struct intel_mid_dma_desc *to_intel_mid_dma_desc
{ {
return container_of(txd, struct intel_mid_dma_desc, txd); return container_of(txd, struct intel_mid_dma_desc, txd);
} }
static inline struct intel_mid_dma_slave *to_intel_mid_dma_slave
(struct dma_slave_config *slave)
{
return container_of(slave, struct intel_mid_dma_slave, dma_slave);
}
int dma_resume(struct pci_dev *pci);
#endif /*__INTEL_MID_DMAC_REGS_H__*/ #endif /*__INTEL_MID_DMAC_REGS_H__*/
...@@ -162,7 +162,7 @@ static int mv_is_err_intr(u32 intr_cause) ...@@ -162,7 +162,7 @@ static int mv_is_err_intr(u32 intr_cause)
static void mv_xor_device_clear_eoc_cause(struct mv_xor_chan *chan) static void mv_xor_device_clear_eoc_cause(struct mv_xor_chan *chan)
{ {
u32 val = (1 << (1 + (chan->idx * 16))); u32 val = ~(1 << (chan->idx * 16));
dev_dbg(chan->device->common.dev, "%s, val 0x%08x\n", __func__, val); dev_dbg(chan->device->common.dev, "%s, val 0x%08x\n", __func__, val);
__raw_writel(val, XOR_INTR_CAUSE(chan)); __raw_writel(val, XOR_INTR_CAUSE(chan));
} }
......
...@@ -580,7 +580,6 @@ static struct dma_async_tx_descriptor *sh_dmae_prep_slave_sg( ...@@ -580,7 +580,6 @@ static struct dma_async_tx_descriptor *sh_dmae_prep_slave_sg(
sh_chan = to_sh_chan(chan); sh_chan = to_sh_chan(chan);
param = chan->private; param = chan->private;
slave_addr = param->config->addr;
/* Someone calling slave DMA on a public channel? */ /* Someone calling slave DMA on a public channel? */
if (!param || !sg_len) { if (!param || !sg_len) {
...@@ -589,6 +588,8 @@ static struct dma_async_tx_descriptor *sh_dmae_prep_slave_sg( ...@@ -589,6 +588,8 @@ static struct dma_async_tx_descriptor *sh_dmae_prep_slave_sg(
return NULL; return NULL;
} }
slave_addr = param->config->addr;
/* /*
* if (param != NULL), this is a successfully requested slave channel, * if (param != NULL), this is a successfully requested slave channel,
* therefore param->config != NULL too. * therefore param->config != NULL too.
......
...@@ -1903,6 +1903,18 @@ static struct dma_async_tx_descriptor *d40_prep_memcpy(struct dma_chan *chan, ...@@ -1903,6 +1903,18 @@ static struct dma_async_tx_descriptor *d40_prep_memcpy(struct dma_chan *chan,
return NULL; return NULL;
} }
static struct dma_async_tx_descriptor *
d40_prep_sg(struct dma_chan *chan,
struct scatterlist *dst_sg, unsigned int dst_nents,
struct scatterlist *src_sg, unsigned int src_nents,
unsigned long dma_flags)
{
if (dst_nents != src_nents)
return NULL;
return stedma40_memcpy_sg(chan, dst_sg, src_sg, dst_nents, dma_flags);
}
static int d40_prep_slave_sg_log(struct d40_desc *d40d, static int d40_prep_slave_sg_log(struct d40_desc *d40d,
struct d40_chan *d40c, struct d40_chan *d40c,
struct scatterlist *sgl, struct scatterlist *sgl,
...@@ -2325,6 +2337,7 @@ static int __init d40_dmaengine_init(struct d40_base *base, ...@@ -2325,6 +2337,7 @@ static int __init d40_dmaengine_init(struct d40_base *base,
base->dma_slave.device_alloc_chan_resources = d40_alloc_chan_resources; base->dma_slave.device_alloc_chan_resources = d40_alloc_chan_resources;
base->dma_slave.device_free_chan_resources = d40_free_chan_resources; base->dma_slave.device_free_chan_resources = d40_free_chan_resources;
base->dma_slave.device_prep_dma_memcpy = d40_prep_memcpy; base->dma_slave.device_prep_dma_memcpy = d40_prep_memcpy;
base->dma_slave.device_prep_dma_sg = d40_prep_sg;
base->dma_slave.device_prep_slave_sg = d40_prep_slave_sg; base->dma_slave.device_prep_slave_sg = d40_prep_slave_sg;
base->dma_slave.device_tx_status = d40_tx_status; base->dma_slave.device_tx_status = d40_tx_status;
base->dma_slave.device_issue_pending = d40_issue_pending; base->dma_slave.device_issue_pending = d40_issue_pending;
...@@ -2345,10 +2358,12 @@ static int __init d40_dmaengine_init(struct d40_base *base, ...@@ -2345,10 +2358,12 @@ static int __init d40_dmaengine_init(struct d40_base *base,
dma_cap_zero(base->dma_memcpy.cap_mask); dma_cap_zero(base->dma_memcpy.cap_mask);
dma_cap_set(DMA_MEMCPY, base->dma_memcpy.cap_mask); dma_cap_set(DMA_MEMCPY, base->dma_memcpy.cap_mask);
dma_cap_set(DMA_SG, base->dma_slave.cap_mask);
base->dma_memcpy.device_alloc_chan_resources = d40_alloc_chan_resources; base->dma_memcpy.device_alloc_chan_resources = d40_alloc_chan_resources;
base->dma_memcpy.device_free_chan_resources = d40_free_chan_resources; base->dma_memcpy.device_free_chan_resources = d40_free_chan_resources;
base->dma_memcpy.device_prep_dma_memcpy = d40_prep_memcpy; base->dma_memcpy.device_prep_dma_memcpy = d40_prep_memcpy;
base->dma_slave.device_prep_dma_sg = d40_prep_sg;
base->dma_memcpy.device_prep_slave_sg = d40_prep_slave_sg; base->dma_memcpy.device_prep_slave_sg = d40_prep_slave_sg;
base->dma_memcpy.device_tx_status = d40_tx_status; base->dma_memcpy.device_tx_status = d40_tx_status;
base->dma_memcpy.device_issue_pending = d40_issue_pending; base->dma_memcpy.device_issue_pending = d40_issue_pending;
...@@ -2375,10 +2390,12 @@ static int __init d40_dmaengine_init(struct d40_base *base, ...@@ -2375,10 +2390,12 @@ static int __init d40_dmaengine_init(struct d40_base *base,
dma_cap_zero(base->dma_both.cap_mask); dma_cap_zero(base->dma_both.cap_mask);
dma_cap_set(DMA_SLAVE, base->dma_both.cap_mask); dma_cap_set(DMA_SLAVE, base->dma_both.cap_mask);
dma_cap_set(DMA_MEMCPY, base->dma_both.cap_mask); dma_cap_set(DMA_MEMCPY, base->dma_both.cap_mask);
dma_cap_set(DMA_SG, base->dma_slave.cap_mask);
base->dma_both.device_alloc_chan_resources = d40_alloc_chan_resources; base->dma_both.device_alloc_chan_resources = d40_alloc_chan_resources;
base->dma_both.device_free_chan_resources = d40_free_chan_resources; base->dma_both.device_free_chan_resources = d40_free_chan_resources;
base->dma_both.device_prep_dma_memcpy = d40_prep_memcpy; base->dma_both.device_prep_dma_memcpy = d40_prep_memcpy;
base->dma_slave.device_prep_dma_sg = d40_prep_sg;
base->dma_both.device_prep_slave_sg = d40_prep_slave_sg; base->dma_both.device_prep_slave_sg = d40_prep_slave_sg;
base->dma_both.device_tx_status = d40_tx_status; base->dma_both.device_tx_status = d40_tx_status;
base->dma_both.device_issue_pending = d40_issue_pending; base->dma_both.device_issue_pending = d40_issue_pending;
......
/*
* linux/amba/pl08x.h - ARM PrimeCell DMA Controller driver
*
* Copyright (C) 2005 ARM Ltd
* Copyright (C) 2010 ST-Ericsson SA
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*
* pl08x information required by platform code
*
* Please credit ARM.com
* Documentation: ARM DDI 0196D
*
*/
#ifndef AMBA_PL08X_H
#define AMBA_PL08X_H
/* We need sizes of structs from this header */
#include <linux/dmaengine.h>
#include <linux/interrupt.h>
/**
* struct pl08x_channel_data - data structure to pass info between
* platform and PL08x driver regarding channel configuration
* @bus_id: name of this device channel, not just a device name since
* devices may have more than one channel e.g. "foo_tx"
* @min_signal: the minimum DMA signal number to be muxed in for this
* channel (for platforms supporting muxed signals). If you have
* static assignments, make sure this is set to the assigned signal
* number, PL08x have 16 possible signals in number 0 thru 15 so
* when these are not enough they often get muxed (in hardware)
* disabling simultaneous use of the same channel for two devices.
* @max_signal: the maximum DMA signal number to be muxed in for
* the channel. Set to the same as min_signal for
* devices with static assignments
* @muxval: a number usually used to poke into some mux regiser to
* mux in the signal to this channel
* @cctl_opt: default options for the channel control register
* @addr: source/target address in physical memory for this DMA channel,
* can be the address of a FIFO register for burst requests for example.
* This can be left undefined if the PrimeCell API is used for configuring
* this.
* @circular_buffer: whether the buffer passed in is circular and
* shall simply be looped round round (like a record baby round
* round round round)
* @single: the device connected to this channel will request single
* DMA transfers, not bursts. (Bursts are default.)
*/
struct pl08x_channel_data {
char *bus_id;
int min_signal;
int max_signal;
u32 muxval;
u32 cctl;
u32 ccfg;
dma_addr_t addr;
bool circular_buffer;
bool single;
};
/**
* Struct pl08x_bus_data - information of source or destination
* busses for a transfer
* @addr: current address
* @maxwidth: the maximum width of a transfer on this bus
* @buswidth: the width of this bus in bytes: 1, 2 or 4
* @fill_bytes: bytes required to fill to the next bus memory
* boundary
*/
struct pl08x_bus_data {
dma_addr_t addr;
u8 maxwidth;
u8 buswidth;
u32 fill_bytes;
};
/**
* struct pl08x_phy_chan - holder for the physical channels
* @id: physical index to this channel
* @lock: a lock to use when altering an instance of this struct
* @signal: the physical signal (aka channel) serving this
* physical channel right now
* @serving: the virtual channel currently being served by this
* physical channel
*/
struct pl08x_phy_chan {
unsigned int id;
void __iomem *base;
spinlock_t lock;
int signal;
struct pl08x_dma_chan *serving;
u32 csrc;
u32 cdst;
u32 clli;
u32 cctl;
u32 ccfg;
};
/**
* struct pl08x_txd - wrapper for struct dma_async_tx_descriptor
* @llis_bus: DMA memory address (physical) start for the LLIs
* @llis_va: virtual memory address start for the LLIs
*/
struct pl08x_txd {
struct dma_async_tx_descriptor tx;
struct list_head node;
enum dma_data_direction direction;
struct pl08x_bus_data srcbus;
struct pl08x_bus_data dstbus;
int len;
dma_addr_t llis_bus;
void *llis_va;
struct pl08x_channel_data *cd;
bool active;
/*
* Settings to be put into the physical channel when we
* trigger this txd
*/
u32 csrc;
u32 cdst;
u32 clli;
u32 cctl;
};
/**
* struct pl08x_dma_chan_state - holds the PL08x specific virtual
* channel states
* @PL08X_CHAN_IDLE: the channel is idle
* @PL08X_CHAN_RUNNING: the channel has allocated a physical transport
* channel and is running a transfer on it
* @PL08X_CHAN_PAUSED: the channel has allocated a physical transport
* channel, but the transfer is currently paused
* @PL08X_CHAN_WAITING: the channel is waiting for a physical transport
* channel to become available (only pertains to memcpy channels)
*/
enum pl08x_dma_chan_state {
PL08X_CHAN_IDLE,
PL08X_CHAN_RUNNING,
PL08X_CHAN_PAUSED,
PL08X_CHAN_WAITING,
};
/**
* struct pl08x_dma_chan - this structure wraps a DMA ENGINE channel
* @chan: wrappped abstract channel
* @phychan: the physical channel utilized by this channel, if there is one
* @tasklet: tasklet scheduled by the IRQ to handle actual work etc
* @name: name of channel
* @cd: channel platform data
* @runtime_addr: address for RX/TX according to the runtime config
* @runtime_direction: current direction of this channel according to
* runtime config
* @lc: last completed transaction on this channel
* @desc_list: queued transactions pending on this channel
* @at: active transaction on this channel
* @lockflags: sometimes we let a lock last between two function calls,
* especially prep/submit, and then we need to store the IRQ flags
* in the channel state, here
* @lock: a lock for this channel data
* @host: a pointer to the host (internal use)
* @state: whether the channel is idle, paused, running etc
* @slave: whether this channel is a device (slave) or for memcpy
* @waiting: a TX descriptor on this channel which is waiting for
* a physical channel to become available
*/
struct pl08x_dma_chan {
struct dma_chan chan;
struct pl08x_phy_chan *phychan;
struct tasklet_struct tasklet;
char *name;
struct pl08x_channel_data *cd;
dma_addr_t runtime_addr;
enum dma_data_direction runtime_direction;
atomic_t last_issued;
dma_cookie_t lc;
struct list_head desc_list;
struct pl08x_txd *at;
unsigned long lockflags;
spinlock_t lock;
void *host;
enum pl08x_dma_chan_state state;
bool slave;
struct pl08x_txd *waiting;
};
/**
* struct pl08x_platform_data - the platform configuration for the
* PL08x PrimeCells.
* @slave_channels: the channels defined for the different devices on the
* platform, all inclusive, including multiplexed channels. The available
* physical channels will be multiplexed around these signals as they
* are requested, just enumerate all possible channels.
* @get_signal: request a physical signal to be used for a DMA
* transfer immediately: if there is some multiplexing or similar blocking
* the use of the channel the transfer can be denied by returning
* less than zero, else it returns the allocated signal number
* @put_signal: indicate to the platform that this physical signal is not
* running any DMA transfer and multiplexing can be recycled
* @bus_bit_lli: Bit[0] of the address indicated which AHB bus master the
* LLI addresses are on 0/1 Master 1/2.
*/
struct pl08x_platform_data {
struct pl08x_channel_data *slave_channels;
unsigned int num_slave_channels;
struct pl08x_channel_data memcpy_channel;
int (*get_signal)(struct pl08x_dma_chan *);
void (*put_signal)(struct pl08x_dma_chan *);
};
#ifdef CONFIG_AMBA_PL08X
bool pl08x_filter_id(struct dma_chan *chan, void *chan_id);
#else
static inline bool pl08x_filter_id(struct dma_chan *chan, void *chan_id)
{
return false;
}
#endif
#endif /* AMBA_PL08X_H */
...@@ -64,13 +64,15 @@ enum dma_transaction_type { ...@@ -64,13 +64,15 @@ enum dma_transaction_type {
DMA_PQ_VAL, DMA_PQ_VAL,
DMA_MEMSET, DMA_MEMSET,
DMA_INTERRUPT, DMA_INTERRUPT,
DMA_SG,
DMA_PRIVATE, DMA_PRIVATE,
DMA_ASYNC_TX, DMA_ASYNC_TX,
DMA_SLAVE, DMA_SLAVE,
DMA_CYCLIC,
}; };
/* last transaction type for creation of the capabilities mask */ /* last transaction type for creation of the capabilities mask */
#define DMA_TX_TYPE_END (DMA_SLAVE + 1) #define DMA_TX_TYPE_END (DMA_CYCLIC + 1)
/** /**
...@@ -119,12 +121,15 @@ enum dma_ctrl_flags { ...@@ -119,12 +121,15 @@ enum dma_ctrl_flags {
* configuration data in statically from the platform). An additional * configuration data in statically from the platform). An additional
* argument of struct dma_slave_config must be passed in with this * argument of struct dma_slave_config must be passed in with this
* command. * command.
* @FSLDMA_EXTERNAL_START: this command will put the Freescale DMA controller
* into external start mode.
*/ */
enum dma_ctrl_cmd { enum dma_ctrl_cmd {
DMA_TERMINATE_ALL, DMA_TERMINATE_ALL,
DMA_PAUSE, DMA_PAUSE,
DMA_RESUME, DMA_RESUME,
DMA_SLAVE_CONFIG, DMA_SLAVE_CONFIG,
FSLDMA_EXTERNAL_START,
}; };
/** /**
...@@ -422,6 +427,9 @@ struct dma_tx_state { ...@@ -422,6 +427,9 @@ struct dma_tx_state {
* @device_prep_dma_memset: prepares a memset operation * @device_prep_dma_memset: prepares a memset operation
* @device_prep_dma_interrupt: prepares an end of chain interrupt operation * @device_prep_dma_interrupt: prepares an end of chain interrupt operation
* @device_prep_slave_sg: prepares a slave dma operation * @device_prep_slave_sg: prepares a slave dma operation
* @device_prep_dma_cyclic: prepare a cyclic dma operation suitable for audio.
* The function takes a buffer of size buf_len. The callback function will
* be called after period_len bytes have been transferred.
* @device_control: manipulate all pending operations on a channel, returns * @device_control: manipulate all pending operations on a channel, returns
* zero or error code * zero or error code
* @device_tx_status: poll for transaction completion, the optional * @device_tx_status: poll for transaction completion, the optional
...@@ -473,11 +481,19 @@ struct dma_device { ...@@ -473,11 +481,19 @@ struct dma_device {
unsigned long flags); unsigned long flags);
struct dma_async_tx_descriptor *(*device_prep_dma_interrupt)( struct dma_async_tx_descriptor *(*device_prep_dma_interrupt)(
struct dma_chan *chan, unsigned long flags); struct dma_chan *chan, unsigned long flags);
struct dma_async_tx_descriptor *(*device_prep_dma_sg)(
struct dma_chan *chan,
struct scatterlist *dst_sg, unsigned int dst_nents,
struct scatterlist *src_sg, unsigned int src_nents,
unsigned long flags);
struct dma_async_tx_descriptor *(*device_prep_slave_sg)( struct dma_async_tx_descriptor *(*device_prep_slave_sg)(
struct dma_chan *chan, struct scatterlist *sgl, struct dma_chan *chan, struct scatterlist *sgl,
unsigned int sg_len, enum dma_data_direction direction, unsigned int sg_len, enum dma_data_direction direction,
unsigned long flags); unsigned long flags);
struct dma_async_tx_descriptor *(*device_prep_dma_cyclic)(
struct dma_chan *chan, dma_addr_t buf_addr, size_t buf_len,
size_t period_len, enum dma_data_direction direction);
int (*device_control)(struct dma_chan *chan, enum dma_ctrl_cmd cmd, int (*device_control)(struct dma_chan *chan, enum dma_ctrl_cmd cmd,
unsigned long arg); unsigned long arg);
...@@ -487,6 +503,40 @@ struct dma_device { ...@@ -487,6 +503,40 @@ struct dma_device {
void (*device_issue_pending)(struct dma_chan *chan); void (*device_issue_pending)(struct dma_chan *chan);
}; };
static inline int dmaengine_device_control(struct dma_chan *chan,
enum dma_ctrl_cmd cmd,
unsigned long arg)
{
return chan->device->device_control(chan, cmd, arg);
}
static inline int dmaengine_slave_config(struct dma_chan *chan,
struct dma_slave_config *config)
{
return dmaengine_device_control(chan, DMA_SLAVE_CONFIG,
(unsigned long)config);
}
static inline int dmaengine_terminate_all(struct dma_chan *chan)
{
return dmaengine_device_control(chan, DMA_TERMINATE_ALL, 0);
}
static inline int dmaengine_pause(struct dma_chan *chan)
{
return dmaengine_device_control(chan, DMA_PAUSE, 0);
}
static inline int dmaengine_resume(struct dma_chan *chan)
{
return dmaengine_device_control(chan, DMA_RESUME, 0);
}
static inline int dmaengine_submit(struct dma_async_tx_descriptor *desc)
{
return desc->tx_submit(desc);
}
static inline bool dmaengine_check_align(u8 align, size_t off1, size_t off2, size_t len) static inline bool dmaengine_check_align(u8 align, size_t off1, size_t off2, size_t len)
{ {
size_t mask; size_t mask;
...@@ -548,7 +598,7 @@ static inline bool dma_dev_has_pq_continue(struct dma_device *dma) ...@@ -548,7 +598,7 @@ static inline bool dma_dev_has_pq_continue(struct dma_device *dma)
return (dma->max_pq & DMA_HAS_PQ_CONTINUE) == DMA_HAS_PQ_CONTINUE; return (dma->max_pq & DMA_HAS_PQ_CONTINUE) == DMA_HAS_PQ_CONTINUE;
} }
static unsigned short dma_dev_to_maxpq(struct dma_device *dma) static inline unsigned short dma_dev_to_maxpq(struct dma_device *dma)
{ {
return dma->max_pq & ~DMA_HAS_PQ_CONTINUE; return dma->max_pq & ~DMA_HAS_PQ_CONTINUE;
} }
......
...@@ -27,14 +27,7 @@ ...@@ -27,14 +27,7 @@
#include <linux/dmaengine.h> #include <linux/dmaengine.h>
/*DMA transaction width, src and dstn width would be same #define DMA_PREP_CIRCULAR_LIST (1 << 10)
The DMA length must be width aligned,
for 32 bit width the length must be 32 bit (4bytes) aligned only*/
enum intel_mid_dma_width {
LNW_DMA_WIDTH_8BIT = 0x0,
LNW_DMA_WIDTH_16BIT = 0x1,
LNW_DMA_WIDTH_32BIT = 0x2,
};
/*DMA mode configurations*/ /*DMA mode configurations*/
enum intel_mid_dma_mode { enum intel_mid_dma_mode {
...@@ -69,18 +62,15 @@ enum intel_mid_dma_msize { ...@@ -69,18 +62,15 @@ enum intel_mid_dma_msize {
* @cfg_mode: DMA data transfer mode (per-per/mem-per/mem-mem) * @cfg_mode: DMA data transfer mode (per-per/mem-per/mem-mem)
* @src_msize: Source DMA burst size * @src_msize: Source DMA burst size
* @dst_msize: Dst DMA burst size * @dst_msize: Dst DMA burst size
* @per_addr: Periphral address
* @device_instance: DMA peripheral device instance, we can have multiple * @device_instance: DMA peripheral device instance, we can have multiple
* peripheral device connected to single DMAC * peripheral device connected to single DMAC
*/ */
struct intel_mid_dma_slave { struct intel_mid_dma_slave {
enum dma_data_direction dirn;
enum intel_mid_dma_width src_width; /*width of DMA src txn*/
enum intel_mid_dma_width dst_width; /*width of DMA dst txn*/
enum intel_mid_dma_hs_mode hs_mode; /*handshaking*/ enum intel_mid_dma_hs_mode hs_mode; /*handshaking*/
enum intel_mid_dma_mode cfg_mode; /*mode configuration*/ enum intel_mid_dma_mode cfg_mode; /*mode configuration*/
enum intel_mid_dma_msize src_msize; /*size if src burst*/
enum intel_mid_dma_msize dst_msize; /*size of dst burst*/
unsigned int device_instance; /*0, 1 for periphral instance*/ unsigned int device_instance; /*0, 1 for periphral instance*/
struct dma_slave_config dma_slave;
}; };
#endif /*__INTEL_MID_DMA_H__*/ #endif /*__INTEL_MID_DMA_H__*/
Markdown is supported
0%
or
You are about to add 0 people to the discussion. Proceed with caution.
Finish editing this message first!
Please register or to comment