linux/drivers/dma/mic_x100_dma.h

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/* SPDX-License-Identifier: GPL-2.0-only */
/*
* Intel MIC Platform Software Stack (MPSS)
*
* Copyright(c) 2014 Intel Corporation.
*
* Intel MIC X100 DMA Driver.
*
* Adapted from IOAT dma driver.
*/
#ifndef _MIC_X100_DMA_H_
#define _MIC_X100_DMA_H_
#include <linux/kernel.h>
#include <linux/delay.h>
#include <linux/sched.h>
#include <linux/debugfs.h>
#include <linux/slab.h>
#include <linux/interrupt.h>
#include <linux/mic_bus.h>
#include "dmaengine.h"
/*
* MIC has a total of 8 dma channels.
* Four channels are assigned for host SW use & the remaining for MIC SW.
* MIC DMA transfer size & addresses need to be 64 byte aligned.
*/
#define MIC_DMA_MAX_NUM_CHAN 8
#define MIC_DMA_NUM_CHAN 4
#define MIC_DMA_ALIGN_SHIFT DMAENGINE_ALIGN_64_BYTES
#define MIC_DMA_ALIGN_BYTES (1 << MIC_DMA_ALIGN_SHIFT)
#define MIC_DMA_DESC_RX_SIZE (128 * 1024 - 4)
/*
* Register descriptions
* All the registers are 32 bit registers.
* DCR is a global register and all others are per-channel.
* DCR - bits 0, 2, 4, 6, 8, 10, 12, 14 - enable bits for channels 0 to 7
* bits 1, 3, 5, 7, 9, 11, 13, 15 - owner bits for channels 0 to 7
* DCAR - bit 24 & 25 interrupt masks for mic owned & host owned channels
* DHPR - head of the descriptor ring updated by s/w
* DTPR - tail of the descriptor ring updated by h/w
* DRAR_LO - lower 32 bits of descriptor ring's mic address
* DRAR_HI - 3:0 - remaining 4 bits of descriptor ring's mic address
* 20:4 descriptor ring size
* 25:21 mic smpt entry number
* DSTAT - 16:0 h/w completion count; 31:28 dma engine status
* DCHERR - this register is non-zero on error
* DCHERRMSK - interrupt mask register
*/
#define MIC_DMA_HW_CMP_CNT_MASK 0x1ffff
#define MIC_DMA_CHAN_QUIESCE 0x20000000
#define MIC_DMA_SBOX_BASE 0x00010000
#define MIC_DMA_SBOX_DCR 0x0000A280
#define MIC_DMA_SBOX_CH_BASE 0x0001A000
#define MIC_DMA_SBOX_CHAN_OFF 0x40
#define MIC_DMA_SBOX_DCAR_IM0 (0x1 << 24)
#define MIC_DMA_SBOX_DCAR_IM1 (0x1 << 25)
#define MIC_DMA_SBOX_DRARHI_SYS_MASK (0x1 << 26)
#define MIC_DMA_REG_DCAR 0
#define MIC_DMA_REG_DHPR 4
#define MIC_DMA_REG_DTPR 8
#define MIC_DMA_REG_DRAR_LO 20
#define MIC_DMA_REG_DRAR_HI 24
#define MIC_DMA_REG_DSTAT 32
#define MIC_DMA_REG_DCHERR 44
#define MIC_DMA_REG_DCHERRMSK 48
/* HW dma desc */
struct mic_dma_desc {
u64 qw0;
u64 qw1;
};
enum mic_dma_chan_owner {
MIC_DMA_CHAN_MIC = 0,
MIC_DMA_CHAN_HOST
};
/*
* mic_dma_chan - channel specific information
* @ch_num: channel number
* @owner: owner of this channel
* @last_tail: cached value of descriptor ring tail
* @head: index of next descriptor in desc_ring
* @issued: hardware notification point
* @submitted: index that will be used to submit descriptors to h/w
* @api_ch: dma engine api channel
* @desc_ring: dma descriptor ring
* @desc_ring_micpa: mic physical address of desc_ring
* @status_dest: destination for status (fence) descriptor
* @status_dest_micpa: mic address for status_dest,
* DMA controller uses this address
* @tx_array: array of async_tx
* @cleanup_lock: lock held when processing completed tx
* @prep_lock: lock held in prep_memcpy & released in tx_submit
* @issue_lock: lock used to synchronize writes to head
* @cookie: mic_irq cookie used with mic irq request
*/
struct mic_dma_chan {
int ch_num;
enum mic_dma_chan_owner owner;
u32 last_tail;
u32 head;
u32 issued;
u32 submitted;
struct dma_chan api_ch;
struct mic_dma_desc *desc_ring;
dma_addr_t desc_ring_micpa;
u64 *status_dest;
dma_addr_t status_dest_micpa;
struct dma_async_tx_descriptor *tx_array;
spinlock_t cleanup_lock;
spinlock_t prep_lock;
spinlock_t issue_lock;
struct mic_irq *cookie;
};
/*
* struct mic_dma_device - per mic device
* @mic_ch: dma channels
* @dma_dev: underlying dma device
* @mbdev: mic bus dma device
* @mmio: virtual address of the mmio space
* @dbg_dir: debugfs directory
* @start_ch: first channel number that can be used
* @max_xfer_size: maximum transfer size per dma descriptor
*/
struct mic_dma_device {
struct mic_dma_chan mic_ch[MIC_DMA_MAX_NUM_CHAN];
struct dma_device dma_dev;
struct mbus_device *mbdev;
void __iomem *mmio;
struct dentry *dbg_dir;
int start_ch;
size_t max_xfer_size;
};
static inline struct mic_dma_chan *to_mic_dma_chan(struct dma_chan *ch)
{
return container_of(ch, struct mic_dma_chan, api_ch);
}
static inline struct mic_dma_device *to_mic_dma_dev(struct mic_dma_chan *ch)
{
return
container_of((const typeof(((struct mic_dma_device *)0)->mic_ch)*)
(ch - ch->ch_num), struct mic_dma_device, mic_ch);
}
static inline struct mbus_device *to_mbus_device(struct mic_dma_chan *ch)
{
return to_mic_dma_dev(ch)->mbdev;
}
static inline struct mbus_hw_ops *to_mbus_hw_ops(struct mic_dma_chan *ch)
{
return to_mbus_device(ch)->hw_ops;
}
static inline struct device *mic_dma_ch_to_device(struct mic_dma_chan *ch)
{
return to_mic_dma_dev(ch)->dma_dev.dev;
}
static inline void __iomem *mic_dma_chan_to_mmio(struct mic_dma_chan *ch)
{
return to_mic_dma_dev(ch)->mmio;
}
static inline u32 mic_dma_read_reg(struct mic_dma_chan *ch, u32 reg)
{
return ioread32(mic_dma_chan_to_mmio(ch) + MIC_DMA_SBOX_CH_BASE +
ch->ch_num * MIC_DMA_SBOX_CHAN_OFF + reg);
}
static inline void mic_dma_write_reg(struct mic_dma_chan *ch, u32 reg, u32 val)
{
iowrite32(val, mic_dma_chan_to_mmio(ch) + MIC_DMA_SBOX_CH_BASE +
ch->ch_num * MIC_DMA_SBOX_CHAN_OFF + reg);
}
static inline u32 mic_dma_mmio_read(struct mic_dma_chan *ch, u32 offset)
{
return ioread32(mic_dma_chan_to_mmio(ch) + offset);
}
static inline void mic_dma_mmio_write(struct mic_dma_chan *ch, u32 val,
u32 offset)
{
iowrite32(val, mic_dma_chan_to_mmio(ch) + offset);
}
static inline u32 mic_dma_read_cmp_cnt(struct mic_dma_chan *ch)
{
return mic_dma_read_reg(ch, MIC_DMA_REG_DSTAT) &
MIC_DMA_HW_CMP_CNT_MASK;
}
static inline void mic_dma_chan_set_owner(struct mic_dma_chan *ch)
{
u32 dcr = mic_dma_mmio_read(ch, MIC_DMA_SBOX_BASE + MIC_DMA_SBOX_DCR);
u32 chan_num = ch->ch_num;
dcr = (dcr & ~(0x1 << (chan_num * 2))) | (ch->owner << (chan_num * 2));
mic_dma_mmio_write(ch, dcr, MIC_DMA_SBOX_BASE + MIC_DMA_SBOX_DCR);
}
static inline void mic_dma_enable_chan(struct mic_dma_chan *ch)
{
u32 dcr = mic_dma_mmio_read(ch, MIC_DMA_SBOX_BASE + MIC_DMA_SBOX_DCR);
dcr |= 2 << (ch->ch_num << 1);
mic_dma_mmio_write(ch, dcr, MIC_DMA_SBOX_BASE + MIC_DMA_SBOX_DCR);
}
static inline void mic_dma_disable_chan(struct mic_dma_chan *ch)
{
u32 dcr = mic_dma_mmio_read(ch, MIC_DMA_SBOX_BASE + MIC_DMA_SBOX_DCR);
dcr &= ~(2 << (ch->ch_num << 1));
mic_dma_mmio_write(ch, dcr, MIC_DMA_SBOX_BASE + MIC_DMA_SBOX_DCR);
}
static void mic_dma_chan_set_desc_ring(struct mic_dma_chan *ch)
{
u32 drar_hi;
dma_addr_t desc_ring_micpa = ch->desc_ring_micpa;
drar_hi = (MIC_DMA_DESC_RX_SIZE & 0x1ffff) << 4;
if (MIC_DMA_CHAN_MIC == ch->owner) {
drar_hi |= (desc_ring_micpa >> 32) & 0xf;
} else {
drar_hi |= MIC_DMA_SBOX_DRARHI_SYS_MASK;
drar_hi |= ((desc_ring_micpa >> 34)
& 0x1f) << 21;
drar_hi |= (desc_ring_micpa >> 32) & 0x3;
}
mic_dma_write_reg(ch, MIC_DMA_REG_DRAR_LO, (u32) desc_ring_micpa);
mic_dma_write_reg(ch, MIC_DMA_REG_DRAR_HI, drar_hi);
}
static inline void mic_dma_chan_mask_intr(struct mic_dma_chan *ch)
{
u32 dcar = mic_dma_read_reg(ch, MIC_DMA_REG_DCAR);
if (MIC_DMA_CHAN_MIC == ch->owner)
dcar |= MIC_DMA_SBOX_DCAR_IM0;
else
dcar |= MIC_DMA_SBOX_DCAR_IM1;
mic_dma_write_reg(ch, MIC_DMA_REG_DCAR, dcar);
}
static inline void mic_dma_chan_unmask_intr(struct mic_dma_chan *ch)
{
u32 dcar = mic_dma_read_reg(ch, MIC_DMA_REG_DCAR);
if (MIC_DMA_CHAN_MIC == ch->owner)
dcar &= ~MIC_DMA_SBOX_DCAR_IM0;
else
dcar &= ~MIC_DMA_SBOX_DCAR_IM1;
mic_dma_write_reg(ch, MIC_DMA_REG_DCAR, dcar);
}
static void mic_dma_ack_interrupt(struct mic_dma_chan *ch)
{
if (MIC_DMA_CHAN_MIC == ch->owner) {
/* HW errata */
mic_dma_chan_mask_intr(ch);
mic_dma_chan_unmask_intr(ch);
}
to_mbus_hw_ops(ch)->ack_interrupt(to_mbus_device(ch), ch->ch_num);
}
#endif