// SPDX-License-Identifier: (GPL-2.0+ OR MIT)
/*
* Copyright (c) 2019 Fuzhou Rockchip Electronics Co., Ltd
*
* author:
* Alpha Lin, alpha.lin@rock-chips.com
* Randy Li, randy.li@rock-chips.com
* Ding Wei, leo.ding@rock-chips.com
*
*/
#include <asm/cacheflush.h>
#include <linux/clk.h>
#include <linux/delay.h>
#include <linux/iopoll.h>
#include <linux/interrupt.h>
#include <linux/module.h>
#include <linux/types.h>
#include <linux/of_platform.h>
#include <linux/slab.h>
#include <linux/uaccess.h>
#include <linux/regmap.h>
#include <linux/proc_fs.h>
#include <soc/rockchip/pm_domains.h>
#include "mpp_debug.h"
#include "mpp_common.h"
#include "mpp_iommu.h"
#define VDPU1_DRIVER_NAME "mpp_vdpu1"
#define VDPU1_SESSION_MAX_BUFFERS 40
/* The maximum registers number of all the version */
#define VDPU1_REG_NUM 60
#define VDPU1_REG_HW_ID_INDEX 0
#define VDPU1_REG_START_INDEX 0
#define VDPU1_REG_END_INDEX 59
#define VDPU1_REG_PP_NUM 101
#define VDPU1_REG_PP_START_INDEX 0
#define VDPU1_REG_PP_END_INDEX 100
#define VDPU1_REG_DEC_INT_EN 0x004
#define VDPU1_REG_DEC_INT_EN_INDEX (1)
/* B slice detected, used in 8190 decoder and later */
#define VDPU1_INT_PIC_INF BIT(24)
#define VDPU1_INT_TIMEOUT BIT(18)
#define VDPU1_INT_SLICE BIT(17)
#define VDPU1_INT_STRM_ERROR BIT(16)
#define VDPU1_INT_ASO_ERROR BIT(15)
#define VDPU1_INT_BUF_EMPTY BIT(14)
#define VDPU1_INT_BUS_ERROR BIT(13)
#define VDPU1_DEC_INT BIT(12)
#define VDPU1_DEC_INT_RAW BIT(8)
#define VDPU1_DEC_IRQ_DIS BIT(4)
#define VDPU1_DEC_START BIT(0)
/* NOTE: Don't enable it or decoding AVC would meet problem at rk3288 */
#define VDPU1_REG_DEC_EN 0x008
#define VDPU1_CLOCK_GATE_EN BIT(10)
#define VDPU1_REG_SYS_CTRL 0x00c
#define VDPU1_REG_SYS_CTRL_INDEX (3)
#define VDPU1_RGE_WIDTH_INDEX (4)
#define VDPU1_GET_FORMAT(x) (((x) >> 28) & 0xf)
#define VDPU1_GET_PROD_NUM(x) (((x) >> 16) & 0xffff)
#define VDPU1_GET_WIDTH(x) (((x) & 0xff800000) >> 19)
#define VDPU1_FMT_H264D 0
#define VDPU1_FMT_MPEG4D 1
#define VDPU1_FMT_H263D 2
#define VDPU1_FMT_JPEGD 3
#define VDPU1_FMT_VC1D 4
#define VDPU1_FMT_MPEG2D 5
#define VDPU1_FMT_MPEG1D 6
#define VDPU1_FMT_VP6D 7
#define VDPU1_FMT_RESERVED 8
#define VDPU1_FMT_VP7D 9
#define VDPU1_FMT_VP8D 10
#define VDPU1_FMT_AVSD 11
#define VDPU1_REG_STREAM_RLC_BASE 0x030
#define VDPU1_REG_STREAM_RLC_BASE_INDEX (12)
#define VDPU1_REG_DIR_MV_BASE 0x0a4
#define VDPU1_REG_DIR_MV_BASE_INDEX (41)
#define VDPU1_REG_CLR_CACHE_BASE 0x810
#define to_vdpu_task(task) \
container_of(task, struct vdpu_task, mpp_task)
#define to_vdpu_dev(dev) \
container_of(dev, struct vdpu_dev, mpp)
enum VPUD1_HW_ID {
VDPU1_ID_0102 = 0x0102,
VDPU1_ID_9190 = 0x6731,
};
struct vdpu_task {
struct mpp_task mpp_task;
/* enable of post process */
bool pp_enable;
enum MPP_CLOCK_MODE clk_mode;
u32 reg[VDPU1_REG_PP_NUM];
struct reg_offset_info off_inf;
u32 strm_addr;
u32 irq_status;
/* req for current task */
u32 w_req_cnt;
struct mpp_request w_reqs[MPP_MAX_MSG_NUM];
u32 r_req_cnt;
struct mpp_request r_reqs[MPP_MAX_MSG_NUM];
};
struct vdpu_dev {
struct mpp_dev mpp;
struct mpp_clk_info aclk_info;
struct mpp_clk_info hclk_info;
#ifdef CONFIG_ROCKCHIP_MPP_PROC_FS
struct proc_dir_entry *procfs;
#endif
struct reset_control *rst_a;
struct reset_control *rst_h;
};
static struct mpp_hw_info vdpu_v1_hw_info = {
.reg_num = VDPU1_REG_NUM,
.reg_id = VDPU1_REG_HW_ID_INDEX,
.reg_start = VDPU1_REG_START_INDEX,
.reg_end = VDPU1_REG_END_INDEX,
.reg_en = VDPU1_REG_DEC_INT_EN_INDEX,
};
static struct mpp_hw_info vdpu_pp_v1_hw_info = {
.reg_num = VDPU1_REG_PP_NUM,
.reg_id = VDPU1_REG_HW_ID_INDEX,
.reg_start = VDPU1_REG_PP_START_INDEX,
.reg_end = VDPU1_REG_PP_END_INDEX,
.reg_en = VDPU1_REG_DEC_INT_EN_INDEX,
};
/*
* file handle translate information
*/
static const u16 trans_tbl_avsd[] = {
12, 13, 14, 15, 16, 17, 40, 41, 45
};
static const u16 trans_tbl_default[] = {
12, 13, 14, 15, 16, 17, 40, 41
};
static const u16 trans_tbl_jpegd[] = {
12, 13, 14, 40, 66, 67
};
static const u16 trans_tbl_h264d[] = {
12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27,
28, 29, 40
};
static const u16 trans_tbl_vc1d[] = {
12, 13, 14, 15, 16, 17, 27, 41
};
static const u16 trans_tbl_vp6d[] = {
12, 13, 14, 18, 27, 40
};
static const u16 trans_tbl_vp8d[] = {
10, 12, 13, 14, 18, 19, 22, 23, 24, 25, 26, 27, 28, 29, 40
};
static struct mpp_trans_info vdpu_v1_trans[] = {
[VDPU1_FMT_H264D] = {
.count = ARRAY_SIZE(trans_tbl_h264d),
.table = trans_tbl_h264d,
},
[VDPU1_FMT_H263D] = {
.count = ARRAY_SIZE(trans_tbl_default),
.table = trans_tbl_default,
},
[VDPU1_FMT_MPEG4D] = {
.count = ARRAY_SIZE(trans_tbl_default),
.table = trans_tbl_default,
},
[VDPU1_FMT_JPEGD] = {
.count = ARRAY_SIZE(trans_tbl_jpegd),
.table = trans_tbl_jpegd,
},
[VDPU1_FMT_VC1D] = {
.count = ARRAY_SIZE(trans_tbl_vc1d),
.table = trans_tbl_vc1d,
},
[VDPU1_FMT_MPEG2D] = {
.count = ARRAY_SIZE(trans_tbl_default),
.table = trans_tbl_default,
},
[VDPU1_FMT_MPEG1D] = {
.count = ARRAY_SIZE(trans_tbl_default),
.table = trans_tbl_default,
},
[VDPU1_FMT_VP6D] = {
.count = ARRAY_SIZE(trans_tbl_vp6d),
.table = trans_tbl_vp6d,
},
[VDPU1_FMT_RESERVED] = {
.count = 0,
.table = NULL,
},
[VDPU1_FMT_VP7D] = {
.count = ARRAY_SIZE(trans_tbl_default),
.table = trans_tbl_default,
},
[VDPU1_FMT_VP8D] = {
.count = ARRAY_SIZE(trans_tbl_vp8d),
.table = trans_tbl_vp8d,
},
[VDPU1_FMT_AVSD] = {
.count = ARRAY_SIZE(trans_tbl_avsd),
.table = trans_tbl_avsd,
},
};
static int vdpu_process_reg_fd(struct mpp_session *session,
struct vdpu_task *task,
struct mpp_task_msgs *msgs)
{
int ret = 0;
int fmt = VDPU1_GET_FORMAT(task->reg[VDPU1_REG_SYS_CTRL_INDEX]);
ret = mpp_translate_reg_address(session, &task->mpp_task,
fmt, task->reg, &task->off_inf);
if (ret)
return ret;
/*
* special offset scale case
*
* This translation is for fd + offset translation.
* One register has 32bits. We need to transfer both buffer file
* handle and the start address offset so we packet file handle
* and offset together using below format.
*
* 0~9 bit for buffer file handle range 0 ~ 1023
* 10~31 bit for offset range 0 ~ 4M
*
* But on 4K case the offset can be larger the 4M
*/
if (likely(fmt == VDPU1_FMT_H264D)) {
int fd;
u32 offset;
dma_addr_t iova = 0;
u32 idx = VDPU1_REG_DIR_MV_BASE_INDEX;
struct mpp_mem_region *mem_region = NULL;
if (session->msg_flags & MPP_FLAGS_REG_NO_OFFSET) {
fd = task->reg[idx];
offset = 0;
} else {
fd = task->reg[idx] & 0x3ff;
offset = task->reg[idx] >> 10 << 4;
}
mem_region = mpp_task_attach_fd(&task->mpp_task, fd);
if (IS_ERR(mem_region)) {
mpp_err("reg[%03d]: %08x fd %d attach failed\n",
idx, task->reg[idx], fd);
goto fail;
}
iova = mem_region->iova;
mpp_debug(DEBUG_IOMMU, "DMV[%3d]: %3d => %pad + offset %10d\n",
idx, fd, &iova, offset);
task->reg[idx] = iova + offset;
}
mpp_translate_reg_offset_info(&task->mpp_task,
&task->off_inf, task->reg);
return 0;
fail:
return -EFAULT;
}
static int vdpu_extract_task_msg(struct vdpu_task *task,
struct mpp_task_msgs *msgs)
{
u32 i;
int ret;
struct mpp_request *req;
struct mpp_hw_info *hw_info = task->mpp_task.hw_info;
for (i = 0; i < msgs->req_cnt; i++) {
u32 off_s, off_e;
req = &msgs->reqs[i];
if (!req->size)
continue;
switch (req->cmd) {
case MPP_CMD_SET_REG_WRITE: {
off_s = hw_info->reg_start * sizeof(u32);
off_e = hw_info->reg_end * sizeof(u32);
ret = mpp_check_req(req, 0, sizeof(task->reg),
off_s, off_e);
if (ret)
continue;
if (copy_from_user((u8 *)task->reg + req->offset,
req->data, req->size)) {
mpp_err("copy_from_user reg failed\n");
return -EIO;
}
memcpy(&task->w_reqs[task->w_req_cnt++],
req, sizeof(*req));
} break;
case MPP_CMD_SET_REG_READ: {
off_s = hw_info->reg_start * sizeof(u32);
off_e = hw_info->reg_end * sizeof(u32);
ret = mpp_check_req(req, 0, sizeof(task->reg),
off_s, off_e);
if (ret)
continue;
memcpy(&task->r_reqs[task->r_req_cnt++],
req, sizeof(*req));
} break;
case MPP_CMD_SET_REG_ADDR_OFFSET: {
mpp_extract_reg_offset_info(&task->off_inf, req);
} break;
default:
break;
}
}
mpp_debug(DEBUG_TASK_INFO, "w_req_cnt %d, r_req_cnt %d\n",
task->w_req_cnt, task->r_req_cnt);
return 0;
}
static void *vdpu_alloc_task(struct mpp_session *session,
struct mpp_task_msgs *msgs)
{
int ret;
struct mpp_task *mpp_task = NULL;
struct vdpu_task *task = NULL;
struct mpp_dev *mpp = session->mpp;
mpp_debug_enter();
task = kzalloc(sizeof(*task), GFP_KERNEL);
if (!task)
return NULL;
mpp_task = &task->mpp_task;
mpp_task_init(session, mpp_task);
if (session->device_type == MPP_DEVICE_VDPU1_PP) {
task->pp_enable = true;
mpp_task->hw_info = &vdpu_pp_v1_hw_info;
} else {
mpp_task->hw_info = mpp->var->hw_info;
}
mpp_task->reg = task->reg;
/* extract reqs for current task */
ret = vdpu_extract_task_msg(task, msgs);
if (ret)
goto fail;
/* process fd in register */
if (!(msgs->flags & MPP_FLAGS_REG_FD_NO_TRANS)) {
ret = vdpu_process_reg_fd(session, task, msgs);
if (ret)
goto fail;
}
task->strm_addr = task->reg[VDPU1_REG_STREAM_RLC_BASE_INDEX];
task->clk_mode = CLK_MODE_NORMAL;
mpp_debug_leave();
return mpp_task;
fail:
mpp_task_dump_mem_region(mpp, mpp_task);
mpp_task_dump_reg(mpp, mpp_task);
mpp_task_finalize(session, mpp_task);
kfree(task);
return NULL;
}
static int vdpu_run(struct mpp_dev *mpp,
struct mpp_task *mpp_task)
{
u32 i;
u32 reg_en;
struct vdpu_task *task = to_vdpu_task(mpp_task);
u32 timing_en = mpp->srv->timing_en;
mpp_debug_enter();
/* clear cache */
mpp_write_relaxed(mpp, VDPU1_REG_CLR_CACHE_BASE, 1);
/* set registers for hardware */
reg_en = mpp_task->hw_info->reg_en;
for (i = 0; i < task->w_req_cnt; i++) {
struct mpp_request *req = &task->w_reqs[i];
int s = req->offset / sizeof(u32);
int e = s + req->size / sizeof(u32);
mpp_write_req(mpp, task->reg, s, e, reg_en);
}
/* init current task */
mpp->cur_task = mpp_task;
mpp_task_run_begin(mpp_task, timing_en, MPP_WORK_TIMEOUT_DELAY);
/* Flush the register before the start the device */
wmb();
mpp_write(mpp, VDPU1_REG_DEC_INT_EN,
task->reg[reg_en] | VDPU1_DEC_START);
mpp_task_run_end(mpp_task, timing_en);
mpp_debug_leave();
return 0;
}
static int vdpu_finish(struct mpp_dev *mpp,
struct mpp_task *mpp_task)
{
u32 i;
u32 s, e;
u32 dec_get;
s32 dec_length;
struct mpp_request *req;
struct vdpu_task *task = to_vdpu_task(mpp_task);
mpp_debug_enter();
/* read register after running */
for (i = 0; i < task->r_req_cnt; i++) {
req = &task->r_reqs[i];
s = req->offset / sizeof(u32);
e = s + req->size / sizeof(u32);
mpp_read_req(mpp, task->reg, s, e);
}
/* revert hack for irq status */
task->reg[VDPU1_REG_DEC_INT_EN_INDEX] = task->irq_status;
/* revert hack for decoded length */
dec_get = mpp_read_relaxed(mpp, VDPU1_REG_STREAM_RLC_BASE);
dec_length = dec_get - task->strm_addr;
task->reg[VDPU1_REG_STREAM_RLC_BASE_INDEX] = dec_length << 10;
mpp_debug(DEBUG_REGISTER,
"dec_get %08x dec_length %d\n", dec_get, dec_length);
mpp_debug_leave();
return 0;
}
static int vdpu_result(struct mpp_dev *mpp,
struct mpp_task *mpp_task,
struct mpp_task_msgs *msgs)
{
u32 i;
struct mpp_request *req;
struct vdpu_task *task = to_vdpu_task(mpp_task);
/* FIXME may overflow the kernel */
for (i = 0; i < task->r_req_cnt; i++) {
req = &task->r_reqs[i];
if (copy_to_user(req->data,
(u8 *)task->reg + req->offset,
req->size)) {
mpp_err("copy_to_user reg fail\n");
return -EIO;
}
}
return 0;
}
static int vdpu_free_task(struct mpp_session *session,
struct mpp_task *mpp_task)
{
struct vdpu_task *task = to_vdpu_task(mpp_task);
mpp_task_finalize(session, mpp_task);
kfree(task);
return 0;
}
#ifdef CONFIG_ROCKCHIP_MPP_PROC_FS
static int vdpu_procfs_remove(struct mpp_dev *mpp)
{
struct vdpu_dev *dec = to_vdpu_dev(mpp);
if (dec->procfs) {
proc_remove(dec->procfs);
dec->procfs = NULL;
}
return 0;
}
static int vdpu_procfs_init(struct mpp_dev *mpp)
{
struct vdpu_dev *dec = to_vdpu_dev(mpp);
dec->procfs = proc_mkdir(mpp->dev->of_node->name, mpp->srv->procfs);
if (IS_ERR_OR_NULL(dec->procfs)) {
mpp_err("failed on open procfs\n");
dec->procfs = NULL;
return -EIO;
}
/* for common mpp_dev options */
mpp_procfs_create_common(dec->procfs, mpp);
mpp_procfs_create_u32("aclk", 0644,
dec->procfs, &dec->aclk_info.debug_rate_hz);
mpp_procfs_create_u32("session_buffers", 0644,
dec->procfs, &mpp->session_max_buffers);
return 0;
}
#else
static inline int vdpu_procfs_remove(struct mpp_dev *mpp)
{
return 0;
}
static inline int vdpu_procfs_init(struct mpp_dev *mpp)
{
return 0;
}
#endif
static int vdpu_init(struct mpp_dev *mpp)
{
int ret;
struct vdpu_dev *dec = to_vdpu_dev(mpp);
mpp->grf_info = &mpp->srv->grf_infos[MPP_DRIVER_VDPU1];
/* Get clock info from dtsi */
ret = mpp_get_clk_info(mpp, &dec->aclk_info, "aclk_vcodec");
if (ret)
mpp_err("failed on clk_get aclk_vcodec\n");
ret = mpp_get_clk_info(mpp, &dec->hclk_info, "hclk_vcodec");
if (ret)
mpp_err("failed on clk_get hclk_vcodec\n");
/* Set default rates */
mpp_set_clk_info_rate_hz(&dec->aclk_info, CLK_MODE_DEFAULT, 300 * MHZ);
/* Get reset control from dtsi */
dec->rst_a = mpp_reset_control_get(mpp, RST_TYPE_A, "video_a");
if (!dec->rst_a)
mpp_err("No aclk reset resource define\n");
dec->rst_h = mpp_reset_control_get(mpp, RST_TYPE_H, "video_h");
if (!dec->rst_h)
mpp_err("No hclk reset resource define\n");
return 0;
}
static int vdpu_clk_on(struct mpp_dev *mpp)
{
struct vdpu_dev *dec = to_vdpu_dev(mpp);
mpp_clk_safe_enable(dec->aclk_info.clk);
mpp_clk_safe_enable(dec->hclk_info.clk);
return 0;
}
static int vdpu_clk_off(struct mpp_dev *mpp)
{
struct vdpu_dev *dec = to_vdpu_dev(mpp);
mpp_clk_safe_disable(dec->aclk_info.clk);
mpp_clk_safe_disable(dec->hclk_info.clk);
return 0;
}
static int vdpu_3288_get_freq(struct mpp_dev *mpp,
struct mpp_task *mpp_task)
{
u32 width;
struct vdpu_task *task = to_vdpu_task(mpp_task);
width = VDPU1_GET_WIDTH(task->reg[VDPU1_RGE_WIDTH_INDEX]);
if (width > 2560)
task->clk_mode = CLK_MODE_ADVANCED;
return 0;
}
static int vdpu_3368_get_freq(struct mpp_dev *mpp,
struct mpp_task *mpp_task)
{
u32 width;
struct vdpu_task *task = to_vdpu_task(mpp_task);
width = VDPU1_GET_WIDTH(task->reg[VDPU1_RGE_WIDTH_INDEX]);
if (width > 2560)
task->clk_mode = CLK_MODE_ADVANCED;
return 0;
}
static int vdpu_set_freq(struct mpp_dev *mpp,
struct mpp_task *mpp_task)
{
struct vdpu_dev *dec = to_vdpu_dev(mpp);
struct vdpu_task *task = to_vdpu_task(mpp_task);
mpp_clk_set_rate(&dec->aclk_info, task->clk_mode);
return 0;
}
static int vdpu_reduce_freq(struct mpp_dev *mpp)
{
struct vdpu_dev *dec = to_vdpu_dev(mpp);
mpp_clk_set_rate(&dec->aclk_info, CLK_MODE_REDUCE);
return 0;
}
static int vdpu_irq(struct mpp_dev *mpp)
{
mpp->irq_status = mpp_read(mpp, VDPU1_REG_DEC_INT_EN);
if (!(mpp->irq_status & VDPU1_DEC_INT_RAW))
return IRQ_NONE;
mpp_write(mpp, VDPU1_REG_DEC_INT_EN, 0);
/* set clock gating to save power */
mpp_write(mpp, VDPU1_REG_DEC_EN, VDPU1_CLOCK_GATE_EN);
return IRQ_WAKE_THREAD;
}
static int vdpu_isr(struct mpp_dev *mpp)
{
u32 err_mask;
struct vdpu_task *task = NULL;
struct mpp_task *mpp_task = mpp->cur_task;
/* FIXME use a spin lock here */
if (!mpp_task) {
dev_err(mpp->dev, "no current task\n");
return IRQ_HANDLED;
}
mpp_time_diff(mpp_task, 0);
mpp->cur_task = NULL;
task = to_vdpu_task(mpp_task);
task->irq_status = mpp->irq_status;
mpp_debug(DEBUG_IRQ_STATUS, "irq_status: %08x\n",
task->irq_status);
err_mask = VDPU1_INT_TIMEOUT
| VDPU1_INT_STRM_ERROR
| VDPU1_INT_ASO_ERROR
| VDPU1_INT_BUF_EMPTY
| VDPU1_INT_BUS_ERROR;
if (err_mask & task->irq_status)
atomic_inc(&mpp->reset_request);
mpp_task_finish(mpp_task->session, mpp_task);
mpp_debug_leave();
return IRQ_HANDLED;
}
static int vdpu_reset(struct mpp_dev *mpp)
{
struct vdpu_dev *dec = to_vdpu_dev(mpp);
if (dec->rst_a && dec->rst_h) {
mpp_debug(DEBUG_RESET, "reset in\n");
/* Don't skip this or iommu won't work after reset */
mpp_pmu_idle_request(mpp, true);
mpp_safe_reset(dec->rst_a);
mpp_safe_reset(dec->rst_h);
udelay(5);
mpp_safe_unreset(dec->rst_a);
mpp_safe_unreset(dec->rst_h);
mpp_pmu_idle_request(mpp, false);
mpp_debug(DEBUG_RESET, "reset out\n");
}
mpp_write(mpp, VDPU1_REG_DEC_INT_EN, 0);
return 0;
}
static struct mpp_hw_ops vdpu_v1_hw_ops = {
.init = vdpu_init,
.clk_on = vdpu_clk_on,
.clk_off = vdpu_clk_off,
.set_freq = vdpu_set_freq,
.reduce_freq = vdpu_reduce_freq,
.reset = vdpu_reset,
};
static struct mpp_hw_ops vdpu_3288_hw_ops = {
.init = vdpu_init,
.clk_on = vdpu_clk_on,
.clk_off = vdpu_clk_off,
.get_freq = vdpu_3288_get_freq,
.set_freq = vdpu_set_freq,
.reduce_freq = vdpu_reduce_freq,
.reset = vdpu_reset,
};
static struct mpp_hw_ops vdpu_3368_hw_ops = {
.init = vdpu_init,
.clk_on = vdpu_clk_on,
.clk_off = vdpu_clk_off,
.get_freq = vdpu_3368_get_freq,
.set_freq = vdpu_set_freq,
.reduce_freq = vdpu_reduce_freq,
.reset = vdpu_reset,
};
static struct mpp_dev_ops vdpu_v1_dev_ops = {
.alloc_task = vdpu_alloc_task,
.run = vdpu_run,
.irq = vdpu_irq,
.isr = vdpu_isr,
.finish = vdpu_finish,
.result = vdpu_result,
.free_task = vdpu_free_task,
};
static const struct mpp_dev_var vdpu_v1_data = {
.device_type = MPP_DEVICE_VDPU1,
.hw_info = &vdpu_v1_hw_info,
.trans_info = vdpu_v1_trans,
.hw_ops = &vdpu_v1_hw_ops,
.dev_ops = &vdpu_v1_dev_ops,
};
static const struct mpp_dev_var vdpu_3288_data = {
.device_type = MPP_DEVICE_VDPU1,
.hw_info = &vdpu_v1_hw_info,
.trans_info = vdpu_v1_trans,
.hw_ops = &vdpu_3288_hw_ops,
.dev_ops = &vdpu_v1_dev_ops,
};
static const struct mpp_dev_var vdpu_3368_data = {
.device_type = MPP_DEVICE_VDPU1,
.hw_info = &vdpu_v1_hw_info,
.trans_info = vdpu_v1_trans,
.hw_ops = &vdpu_3368_hw_ops,
.dev_ops = &vdpu_v1_dev_ops,
};
static const struct mpp_dev_var avsd_plus_data = {
.device_type = MPP_DEVICE_AVSPLUS_DEC,
.hw_info = &vdpu_v1_hw_info,
.trans_info = vdpu_v1_trans,
.hw_ops = &vdpu_v1_hw_ops,
.dev_ops = &vdpu_v1_dev_ops,
};
static const struct of_device_id mpp_vdpu1_dt_match[] = {
{
.compatible = "rockchip,vpu-decoder-v1",
.data = &vdpu_v1_data,
},
#ifdef CONFIG_CPU_RK3288
{
.compatible = "rockchip,vpu-decoder-rk3288",
.data = &vdpu_3288_data,
},
#endif
#ifdef CONFIG_CPU_RK3368
{
.compatible = "rockchip,vpu-decoder-rk3368",
.data = &vdpu_3368_data,
},
#endif
#ifdef CONFIG_CPU_RK3328
{
.compatible = "rockchip,avs-plus-decoder",
.data = &avsd_plus_data,
},
#endif
{},
};
static int vdpu_probe(struct platform_device *pdev)
{
struct device *dev = &pdev->dev;
struct vdpu_dev *dec = NULL;
struct mpp_dev *mpp = NULL;
const struct of_device_id *match = NULL;
int ret = 0;
dev_info(dev, "probe device\n");
dec = devm_kzalloc(dev, sizeof(struct vdpu_dev), GFP_KERNEL);
if (!dec)
return -ENOMEM;
mpp = &dec->mpp;
platform_set_drvdata(pdev, mpp);
if (pdev->dev.of_node) {
match = of_match_node(mpp_vdpu1_dt_match, pdev->dev.of_node);
if (match)
mpp->var = (struct mpp_dev_var *)match->data;
mpp->core_id = of_alias_get_id(pdev->dev.of_node, "vdpu");
}
ret = mpp_dev_probe(mpp, pdev);
if (ret) {
dev_err(dev, "probe sub driver failed\n");
return -EINVAL;
}
ret = devm_request_threaded_irq(dev, mpp->irq,
mpp_dev_irq,
mpp_dev_isr_sched,
IRQF_SHARED,
dev_name(dev), mpp);
if (ret) {
dev_err(dev, "register interrupter runtime failed\n");
return -EINVAL;
}
if (mpp->var->device_type == MPP_DEVICE_VDPU1) {
mpp->srv->sub_devices[MPP_DEVICE_VDPU1_PP] = mpp;
set_bit(MPP_DEVICE_VDPU1_PP, &mpp->srv->hw_support);
}
mpp->session_max_buffers = VDPU1_SESSION_MAX_BUFFERS;
vdpu_procfs_init(mpp);
/* register current device to mpp service */
mpp_dev_register_srv(mpp, mpp->srv);
dev_info(dev, "probing finish\n");
return 0;
}
static int vdpu_remove(struct platform_device *pdev)
{
struct device *dev = &pdev->dev;
struct mpp_dev *mpp = dev_get_drvdata(dev);
dev_info(dev, "remove device\n");
mpp_dev_remove(mpp);
vdpu_procfs_remove(mpp);
return 0;
}
struct platform_driver rockchip_vdpu1_driver = {
.probe = vdpu_probe,
.remove = vdpu_remove,
.shutdown = mpp_dev_shutdown,
.driver = {
.name = VDPU1_DRIVER_NAME,
.of_match_table = of_match_ptr(mpp_vdpu1_dt_match),
},
};
EXPORT_SYMBOL(rockchip_vdpu1_driver);
Orange Pi5 kernel
Deprecated Linux kernel 5.10.110 for OrangePi 5/5B/5+ boards
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