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unplugged-kernel/drivers/misc/mediatek/video/mt6779/dispsys/ddp_rdma_ex.c

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// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (c) 2019 MediaTek Inc.
*/
#define LOG_TAG "RDMA"
#include "ddp_log.h"
#include "ddp_clkmgr.h"
#include <linux/delay.h>
#include "ddp_info.h"
#include "ddp_reg.h"
#include "ddp_matrix_para.h"
#include "ddp_rdma.h"
#include "ddp_rdma_ex.h"
#include "ddp_dump.h"
#include "lcm_drv.h"
#include "primary_display.h"
#include "ddp_m4u.h"
#include "disp_lowpower.h"
#include "ddp_mmp.h"
#include "ddp_misc.h"
#include "ddp_reg_mmsys.h"
#include <ion_sec_heap.h>
#ifdef CONFIG_MTK_TRUSTED_MEMORY_SUBSYSTEM
#include "trusted_mem_api.h"
#endif
#define MMSYS_CLK_LOW (0)
#define MMSYS_CLK_HIGH (1)
static unsigned int rdma_fps[RDMA_INSTANCES] = { 60, 60 };
static struct golden_setting_context *rdma_golden_setting;
struct RDMA_CONFIG_STRUCT g_primary_rdma_cfg;
unsigned int rdma_index(enum DISP_MODULE_ENUM module)
{
int idx = 0;
switch (module) {
case DISP_MODULE_RDMA0:
idx = 0;
break;
case DISP_MODULE_RDMA1:
idx = 1;
break;
default:
DDP_PR_ERR("invalid rdma module=%d\n", module);
ASSERT(0);
break;
}
ASSERT((idx >= 0) && (idx < RDMA_INSTANCES));
return idx;
}
void rdma_set_target_line(enum DISP_MODULE_ENUM module, unsigned int line,
void *handle)
{
unsigned int idx = rdma_index(module);
DISP_REG_SET(handle, idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_TARGET_LINE, line);
}
int rdma_init(enum DISP_MODULE_ENUM module, void *handle)
{
return rdma_clock_on(module, handle);
}
int rdma_deinit(enum DISP_MODULE_ENUM module, void *handle)
{
return rdma_clock_off(module, handle);
}
void rdma_get_address(enum DISP_MODULE_ENUM module, unsigned long *addr)
{
unsigned int idx = rdma_index(module);
*addr = DISP_REG_GET(DISP_REG_RDMA_MEM_START_ADDR +
DISP_RDMA_INDEX_OFFSET * idx);
}
static inline unsigned long rdma_to_cmdq_engine(enum DISP_MODULE_ENUM module)
{
switch (module) {
case DISP_MODULE_RDMA0:
return CMDQ_ENG_DISP_RDMA0;
case DISP_MODULE_RDMA1:
return CMDQ_ENG_DISP_RDMA1;
default:
DDP_PR_ERR("invalid rdma module=%d,rdma to cmdq engine fail\n",
module);
ASSERT(0);
return DISP_MODULE_UNKNOWN;
}
return 0;
}
static inline unsigned long
rdma_to_cmdq_event_nonsec_end(enum DISP_MODULE_ENUM module)
{
switch (module) {
case DISP_MODULE_RDMA0:
return CMDQ_SYNC_DISP_RDMA0_2NONSEC_END;
case DISP_MODULE_RDMA1:
return CMDQ_SYNC_DISP_RDMA1_2NONSEC_END;
default:
DDP_PR_ERR("invalid rdma module=%d,rmda to cmdq event fail\n",
module);
ASSERT(0);
return DISP_MODULE_UNKNOWN;
}
return 0;
}
int rdma_enable_irq(enum DISP_MODULE_ENUM module, void *handle,
enum DDP_IRQ_LEVEL irq_level)
{
unsigned int idx = rdma_index(module);
ASSERT(idx <= RDMA_INSTANCES);
switch (irq_level) {
case DDP_IRQ_LEVEL_ALL:
DISP_REG_SET(handle, idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_INT_ENABLE, 0x1E);
break;
case DDP_IRQ_LEVEL_ERROR:
DISP_REG_SET(handle, idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_INT_ENABLE, 0x18);
break;
case DDP_IRQ_LEVEL_NONE:
DISP_REG_SET(handle, idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_INT_ENABLE, 0x0);
break;
default:
break;
}
return 0;
}
int rdma_start(enum DISP_MODULE_ENUM module, void *handle)
{
unsigned int idx = rdma_index(module);
unsigned int regval;
unsigned int value = 0, mask = 0;
ASSERT(idx <= RDMA_INSTANCES);
regval = REG_FLD_VAL(INT_STATUS_FLD_REG_UPDATE_INT_FLAG, 0) |
REG_FLD_VAL(INT_STATUS_FLD_FRAME_START_INT_FLAG, 1) |
REG_FLD_VAL(INT_STATUS_FLD_FRAME_END_INT_FLAG, 1) |
REG_FLD_VAL(INT_STATUS_FLD_EOF_ABNORMAL_INT_FLAG, 1) |
REG_FLD_VAL(INT_STATUS_FLD_FIFO_UNDERFLOW_INT_FLAG, 1) |
REG_FLD_VAL(INT_STATUS_FLD_TARGET_LINE_INT_FLAG, 0) |
REG_FLD_VAL(INT_STATUS_FLD_FIFO_EMPTY_INT_FLAG, 0);
DISP_REG_SET(handle, idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_INT_ENABLE, regval);
DISP_REG_SET_FIELD(handle, GLOBAL_CON_FLD_ENGINE_EN,
idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_GLOBAL_CON, 1);
if (idx == 0) {
value = 0;
mask = 0;
SET_VAL_MASK(value, mask, 0, FLD_SODI_REQ_MASKEN_CG_RDMA0);
SET_VAL_MASK(value, mask, 1, FLD_DVFS_HALT_MASK_RDMA0);
DISP_REG_MASK(handle, DISP_REG_CONFIG_MMSYS_SODI_REQ_MASK,
value, mask);
} else {
value = 0;
mask = 0;
SET_VAL_MASK(value, mask, 0, FLD_SODI_REQ_MASKEN_CG_RDMA1);
SET_VAL_MASK(value, mask, 1, FLD_DVFS_HALT_MASK_RDMA1);
DISP_REG_MASK(handle, DISP_REG_CONFIG_MMSYS_SODI_REQ_MASK,
value, mask);
}
return 0;
}
int rdma_stop(enum DISP_MODULE_ENUM module, void *handle)
{
unsigned int idx = rdma_index(module);
unsigned int value = 0, mask = 0;
ASSERT(idx <= RDMA_INSTANCES);
DISP_REG_SET_FIELD(handle, GLOBAL_CON_FLD_ENGINE_EN,
idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_GLOBAL_CON, 0);
DISP_REG_SET(handle, idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_INT_ENABLE, 0);
DISP_REG_SET(handle, idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_INT_STATUS, 0);
if (idx == 0) {
value = 0;
mask = 0;
SET_VAL_MASK(value, mask, 1, FLD_SODI_REQ_MASKEN_CG_RDMA0);
SET_VAL_MASK(value, mask, 0, FLD_DVFS_HALT_MASK_RDMA0);
DISP_REG_MASK(handle, DISP_REG_CONFIG_MMSYS_SODI_REQ_MASK,
value, mask);
} else {
value = 0;
mask = 0;
SET_VAL_MASK(value, mask, 1, FLD_SODI_REQ_MASKEN_CG_RDMA1);
SET_VAL_MASK(value, mask, 0, FLD_DVFS_HALT_MASK_RDMA1);
DISP_REG_MASK(handle, DISP_REG_CONFIG_MMSYS_SODI_REQ_MASK,
value, mask);
}
return 0;
}
int rdma_reset_by_cmdq(enum DISP_MODULE_ENUM module, void *handle)
{
int ret = 0;
unsigned int idx = rdma_index(module);
ASSERT(idx <= RDMA_INSTANCES);
DISP_REG_SET_FIELD(handle, GLOBAL_CON_FLD_SOFT_RESET,
idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_GLOBAL_CON, 1);
DISP_REG_SET_FIELD(handle, GLOBAL_CON_FLD_SOFT_RESET,
idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_GLOBAL_CON, 0);
DISP_REG_CMDQ_POLLING(handle, idx * DISP_RDMA_INDEX_OFFSET +
DISP_REG_RDMA_GLOBAL_CON, 0x100, 0x700);
return ret;
}
int rdma_reset(enum DISP_MODULE_ENUM module, void *handle)
{
unsigned int delay_cnt = 0;
int ret = 0, offset = 0;
unsigned int idx = rdma_index(module);
const int len = 160;
char msg[len];
int n = 0;
ASSERT(idx <= RDMA_INSTANCES);
offset = idx * DISP_RDMA_INDEX_OFFSET;
DISP_REG_SET_FIELD(handle, GLOBAL_CON_FLD_SOFT_RESET, offset +
DISP_REG_RDMA_GLOBAL_CON, 1);
while ((DISP_REG_GET(offset + DISP_REG_RDMA_GLOBAL_CON) & 0x700) ==
0x100) {
delay_cnt++;
udelay(10);
if (delay_cnt > 10000) {
ret = -1;
n = scnprintf(msg, len,
"rdma%d_reset timeout, stage 1! ", idx);
n += scnprintf(msg + n, len - n,
"DISP_REG_RDMA_GLOBAL_CON=0x%x\n",
DISP_REG_GET(offset +
DISP_REG_RDMA_GLOBAL_CON));
DDP_PR_ERR("%s", msg);
break;
}
}
DISP_REG_SET_FIELD(handle, GLOBAL_CON_FLD_SOFT_RESET, offset +
DISP_REG_RDMA_GLOBAL_CON, 0);
delay_cnt = 0;
while ((DISP_REG_GET(offset + DISP_REG_RDMA_GLOBAL_CON) & 0x700) !=
0x100) {
delay_cnt++;
udelay(10);
if (delay_cnt <= 10000)
continue;
ret = -1;
n = scnprintf(msg, len,
"rdma%d_reset timeout, stage 2! ", idx);
n += scnprintf(msg + n, len - n,
"DISP_REG_RDMA_GLOBAL_CON=0x%x\n",
DISP_REG_GET(offset + DISP_REG_RDMA_GLOBAL_CON));
DDP_PR_ERR("%s", msg);
break;
}
return ret;
}
/* TODO RDMA1, wrot sram */
void rdma_cal_golden_setting(unsigned int idx, unsigned int bpp,
struct golden_setting_context *gsc, unsigned int *gs,
unsigned int is_vdo)
{
/* fixed variable */
unsigned int mmsys_clk = 315;
unsigned int pre_ultra_low_us = 245, pre_ultra_high_us = 255;
unsigned int ultra_low_us = 230, ultra_high_us = 245;
unsigned int if_fps = 60;
unsigned int FP = 1000;
/* input variable */
unsigned int is_wrot_sram = gsc->is_wrot_sram;
unsigned long long width = gsc->dst_width, height = gsc->dst_height;
unsigned int Bpp = bpp / 8;
bool is_dc = gsc->is_dc;
unsigned int fill_rate = 0; /* 100 times */
unsigned long long consume_rate = 0; /* 100 times */
/* critical variable calc */
if (is_dc)
fill_rate = 96 * mmsys_clk; /* FIFO depth / us */
else
fill_rate = 96 * mmsys_clk * 3 / 16; /* FIFO depth / us */
consume_rate = width * height * if_fps * Bpp;
do_div(consume_rate, 1000);
consume_rate *= 125;
do_div(consume_rate, 16 * 1000);
/* RDMA golden setting calculation */
/* DISP_RDMA_MEM_GMC_SETTING_0 */
gs[GS_RDMA_PRE_ULTRA_TH_LOW] = DIV_ROUND_UP(
consume_rate * (pre_ultra_low_us), FP);
gs[GS_RDMA_PRE_ULTRA_TH_HIGH] = DIV_ROUND_UP(
consume_rate * (pre_ultra_high_us), FP);
if (is_vdo) {
gs[GS_RDMA_VALID_TH_FORCE_PRE_ULTRA] = 0;
gs[GS_RDMA_VDE_FORCE_PRE_ULTRA] = 1;
} else {
gs[GS_RDMA_VALID_TH_FORCE_PRE_ULTRA] = 1;
gs[GS_RDMA_VDE_FORCE_PRE_ULTRA] = 0;
}
/* DISP_RDMA_MEM_GMC_SETTING_1 */
gs[GS_RDMA_ULTRA_TH_LOW] = DIV_ROUND_UP(
consume_rate * (ultra_low_us), FP);
gs[GS_RDMA_ULTRA_TH_HIGH] = gs[GS_RDMA_PRE_ULTRA_TH_LOW];
if (is_vdo) {
gs[GS_RDMA_VALID_TH_BLOCK_ULTRA] = 0;
gs[GS_RDMA_VDE_BLOCK_ULTRA] = 1;
} else {
gs[GS_RDMA_VALID_TH_BLOCK_ULTRA] = 1;
gs[GS_RDMA_VDE_BLOCK_ULTRA] = 0;
}
/* DISP_RDMA_FIFO_CON */
if (is_vdo)
gs[GS_RDMA_OUTPUT_VALID_FIFO_TH] = 0;
else
gs[GS_RDMA_OUTPUT_VALID_FIFO_TH] =
gs[GS_RDMA_PRE_ULTRA_TH_LOW];
if (is_wrot_sram == 0)
gs[GS_RDMA_FIFO_SIZE] = 1536;
else
gs[GS_RDMA_FIFO_SIZE] = 3584;
gs[GS_RDMA_FIFO_UNDERFLOW_EN] = 1;
/* DISP_RDMA_MEM_GMC_SETTING_2 */
/* do not min this value with 256 to avoid hrt fail in
* dc mode under SODI CG mode
*/
gs[GS_RDMA_ISSUE_REQ_TH] =
gs[GS_RDMA_FIFO_SIZE] - gs[GS_RDMA_PRE_ULTRA_TH_LOW];
/* DISP_RDMA_THRESHOLD_FOR_SODI */
gs[GS_RDMA_TH_LOW_FOR_SODI] = DIV_ROUND_UP(
consume_rate * (ultra_low_us + 50), FP);
gs[GS_RDMA_TH_HIGH_FOR_SODI] = DIV_ROUND_UP(gs[GS_RDMA_FIFO_SIZE] *
FP - (fill_rate - consume_rate) * 12, FP);
if (gs[GS_RDMA_TH_HIGH_FOR_SODI] < gs[GS_RDMA_PRE_ULTRA_TH_HIGH])
gs[GS_RDMA_TH_HIGH_FOR_SODI] = gs[GS_RDMA_PRE_ULTRA_TH_HIGH];
/* DISP_RDMA_THRESHOLD_FOR_DVFS */
gs[GS_RDMA_TH_LOW_FOR_DVFS] = gs[GS_RDMA_PRE_ULTRA_TH_LOW];
gs[GS_RDMA_TH_HIGH_FOR_DVFS] = gs[GS_RDMA_PRE_ULTRA_TH_LOW] + 1;
/* DISP_RDMA_SRAM_SEL */
if (is_wrot_sram == 0)
gs[GS_RDMA_SRAM_SEL] = 0;
else
gs[GS_RDMA_SRAM_SEL] = 7;
/* DISP_RDMA_DVFS_SETTING_PREULTRA */
gs[GS_RDMA_DVFS_PRE_ULTRA_TH_LOW] = DIV_ROUND_UP(
consume_rate * (pre_ultra_low_us + 40), FP);
gs[GS_RDMA_DVFS_PRE_ULTRA_TH_HIGH] = DIV_ROUND_UP(
consume_rate * (pre_ultra_high_us + 40), FP);
/* DISP_RDMA_DVFS_SETTING_ULTRA */
gs[GS_RDMA_DVFS_ULTRA_TH_LOW] = DIV_ROUND_UP(
consume_rate * (ultra_low_us + 40), FP);
gs[GS_RDMA_DVFS_ULTRA_TH_HIGH] = gs[GS_RDMA_DVFS_PRE_ULTRA_TH_LOW];
/* DISP_RDMA_LEAVE_DRS_SETTING */
gs[GS_RDMA_IS_DRS_STATUS_TH_LOW] = DIV_ROUND_UP(
consume_rate * (pre_ultra_low_us + 20), FP);
gs[GS_RDMA_IS_DRS_STATUS_TH_HIGH] = DIV_ROUND_UP(
consume_rate * (pre_ultra_low_us + 20), FP);
/* DISP_RDMA_ENTER_DRS_SETTING */
gs[GS_RDMA_NOT_DRS_STATUS_TH_LOW] = DIV_ROUND_UP(
consume_rate * (ultra_high_us + 40), FP);
gs[GS_RDMA_NOT_DRS_STATUS_TH_HIGH] = DIV_ROUND_UP(
consume_rate * (ultra_high_us + 40), FP);
/* DISP_RDMA_MEM_GMC_SETTING_3 */
gs[GS_RDMA_URGENT_TH_LOW] = DIV_ROUND_UP(
consume_rate * 113, FP);
gs[GS_RDMA_URGENT_TH_HIGH] = DIV_ROUND_UP(
consume_rate * 117, FP);
/* DISP_RDMA_SRAM_CASCADE */
gs[GS_RDMA_SELF_FIFO_SIZE] = 1536;
gs[GS_RDMA_RSZ_FIFO_SIZE] = 1536;
}
/* Set register with value from rdma_cal_golden_setting.
* Do not do any math here!
*/
static void rdma_set_ultra_l(unsigned int idx, unsigned int bpp, void *handle,
struct golden_setting_context *gsc)
{
unsigned int gs[GS_RDMA_FLD_NUM] = {0};
unsigned int val = 0;
unsigned int offset = idx * DISP_RDMA_INDEX_OFFSET;
if (idx == 1) {
DDPMSG("RDMA1 golden setting not support yet\n");
return;
}
if (!gsc) {
DDPMSG("golden setting is null, %s,%d\n",
__FILE__, __LINE__);
ASSERT(0);
return;
}
rdma_golden_setting = gsc;
/* calculate golden setting */
rdma_cal_golden_setting(idx, bpp, gsc, gs,
primary_display_is_video_mode());
/* set golden setting */
val = gs[GS_RDMA_PRE_ULTRA_TH_LOW] +
(gs[GS_RDMA_PRE_ULTRA_TH_HIGH] << 16) +
(gs[GS_RDMA_VALID_TH_FORCE_PRE_ULTRA] << 30) +
(gs[GS_RDMA_VDE_FORCE_PRE_ULTRA] << 31);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_MEM_GMC_SETTING_0, val);
val = gs[GS_RDMA_ULTRA_TH_LOW] +
(gs[GS_RDMA_ULTRA_TH_HIGH] << 16) +
(gs[GS_RDMA_VALID_TH_BLOCK_ULTRA] << 30) +
(gs[GS_RDMA_VDE_BLOCK_ULTRA] << 31);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_MEM_GMC_SETTING_1, val);
val = gs[GS_RDMA_ISSUE_REQ_TH];
DISP_REG_SET(handle, offset + DISP_REG_RDMA_MEM_GMC_SETTING_2, val);
val = gs[GS_RDMA_OUTPUT_VALID_FIFO_TH] +
(gs[GS_RDMA_FIFO_SIZE] << 16) +
(gs[GS_RDMA_FIFO_UNDERFLOW_EN] << 31);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_FIFO_CON, val);
val = gs[GS_RDMA_TH_LOW_FOR_SODI] +
(gs[GS_RDMA_TH_HIGH_FOR_SODI] << 16);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_THRESHOLD_FOR_SODI, val);
val = gs[GS_RDMA_TH_LOW_FOR_DVFS] +
(gs[GS_RDMA_TH_HIGH_FOR_DVFS] << 16);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_THRESHOLD_FOR_DVFS, val);
if (idx == 0)
DISP_REG_SET(handle, DISP_REG_RDMA_SRAM_SEL,
gs[GS_RDMA_SRAM_SEL]);
val = gs[GS_RDMA_DVFS_PRE_ULTRA_TH_LOW] +
(gs[GS_RDMA_DVFS_PRE_ULTRA_TH_HIGH] << 16);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_DVFS_SETTING_PRE, val);
val = gs[GS_RDMA_DVFS_ULTRA_TH_LOW] +
(gs[GS_RDMA_DVFS_ULTRA_TH_HIGH] << 16);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_DVFS_SETTING_ULTRA, val);
val = gs[GS_RDMA_IS_DRS_STATUS_TH_LOW] +
(gs[GS_RDMA_IS_DRS_STATUS_TH_HIGH] << 16);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_LEAVE_DRS_SETTING, val);
val = gs[GS_RDMA_NOT_DRS_STATUS_TH_LOW] +
(gs[GS_RDMA_NOT_DRS_STATUS_TH_HIGH] << 16);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_ENTER_DRS_SETTING, val);
val = gs[GS_RDMA_URGENT_TH_LOW] +
(gs[GS_RDMA_URGENT_TH_HIGH] << 16);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_MEM_GMC_SETTING_3, val);
val = gs[GS_RDMA_SELF_FIFO_SIZE] +
(gs[GS_RDMA_RSZ_FIFO_SIZE] << 16);
DISP_REG_SET(handle, offset + DISP_RDMA_SRAM_CASCADE, val);
}
static int rdma_config(enum DISP_MODULE_ENUM module, enum RDMA_MODE mode,
unsigned long address, enum UNIFIED_COLOR_FMT inFormat,
unsigned int pitch, unsigned int width,
unsigned int height, unsigned int ufoe_enable,
enum DISP_BUFFER_TYPE sec, struct ion_handle *ion_hnd,
unsigned int yuv_range,
struct rdma_bg_ctrl_t *bg_ctrl, void *handle,
struct golden_setting_context *p_golden_setting,
unsigned int bpp)
{
unsigned int output_is_yuv = 0;
unsigned int input_is_yuv = !UFMT_GET_RGB(inFormat);
unsigned int input_swap = UFMT_GET_BYTESWAP(inFormat);
unsigned int input_format = UFMT_GET_FORMAT(inFormat);
unsigned int idx = rdma_index(module);
unsigned int matrix_en;
unsigned int color_matrix;
unsigned int val, offset;
unsigned int size_con_0_value = 0, size_con_0_mask = 0;
unsigned int value = 0, mask = 0;
DDPDBG("%s:%s,mode:%s,addr:0x%08lx,fmt:%s,pitch:%u,wh(%ux%u),sec:%d\n",
__func__, ddp_get_module_name(module), mode ? "MEM" : "DL",
address, unified_color_fmt_name(inFormat), pitch,
width, height, sec);
ASSERT(idx <= RDMA_INSTANCES);
if ((width > RDMA_MAX_WIDTH) || (height > RDMA_MAX_HEIGHT))
DDP_PR_ERR("RDMA input overflow,w=%d,h=%d,max_w=%d,max_h=%d\n",
width, height, RDMA_MAX_WIDTH, RDMA_MAX_HEIGHT);
offset = idx * DISP_RDMA_INDEX_OFFSET;
if (input_is_yuv == 1 && output_is_yuv == 0) {
matrix_en = 1;
switch (yuv_range) {
case 0:
color_matrix = 4;
break; /* BT601_full */
case 1:
color_matrix = 6;
break; /* BT601 */
case 2:
color_matrix = 7;
break; /* BT709 */
default:
DDP_PR_ERR("%s,un-recognized yuv_range=%d!\n",
__func__, yuv_range);
color_matrix = 4;
break;
}
} else if (input_is_yuv == 0 && output_is_yuv == 1) {
matrix_en = 1;
color_matrix = 0x2; /* 0x0010, RGB_TO_BT601 */
} else {
matrix_en = 0;
color_matrix = 0;
}
SET_VAL_MASK(size_con_0_value, size_con_0_mask, matrix_en,
SIZE_CON_0_FLD_MATRIX_ENABLE);
SET_VAL_MASK(size_con_0_value, size_con_0_mask, color_matrix,
SIZE_CON_0_FLD_MATRIX_INT_MTX_SEL);
if (mode == RDMA_MODE_DIRECT_LINK) {
value = 0;
mask = 0;
SET_VAL_MASK(value, mask, 0,
MEM_CON_FLD_MEM_MODE_INPUT_FORMAT);
SET_VAL_MASK(value, mask, 0,
MEM_CON_FLD_MEM_MODE_INPUT_SWAP);
} else {
value = 0;
mask = 0;
SET_VAL_MASK(value, mask, (input_format & 0xf),
MEM_CON_FLD_MEM_MODE_INPUT_FORMAT);
SET_VAL_MASK(value, mask, input_swap,
MEM_CON_FLD_MEM_MODE_INPUT_SWAP);
}
DISP_REG_MASK(handle, offset + DISP_REG_RDMA_MEM_CON, value, mask);
if (sec != DISP_SECURE_BUFFER) {
DISP_REG_SET(handle, offset + DISP_REG_RDMA_MEM_START_ADDR,
address);
} else {
int m4u_port;
unsigned int size = pitch * height;
int sec = -1, sec_id = -1;
ion_phys_addr_t sec_hdl = 0;
enum TRUSTED_MEM_REQ_TYPE mem_type = -1;
m4u_port = idx == 0 ? DISP_M4U_PORT_DISP_RDMA0 :
DISP_M4U_PORT_DISP_RDMA1;
/*
* for sec layer, addr variable stores sec handle
* we need to pass this handle and offset to cmdq driver
* cmdq sec driver will help to convert handle to
* correct address
*/
if (unlikely(!ion_hnd)) {
DISP_LOG_E("%s #%d NULL handle for secure layer\n",
__func__, __LINE__);
return 0;
}
mem_type = ion_hdl2sec_type(ion_hnd, &sec, &sec_id, &sec_hdl);
if (mem_type == -1) {
DISP_LOG_E("normal memory set as secure\n");
return 0;
}
cmdqRecWriteSecureMetaData(handle, disp_addr_convert(offset +
DISP_REG_RDMA_MEM_START_ADDR),
CMDQ_SAM_H_2_MVA, address, 0, size, m4u_port, mem_type);
}
DISP_REG_SET(handle, offset + DISP_REG_RDMA_MEM_SRC_PITCH, pitch);
SET_VAL_MASK(size_con_0_value, size_con_0_mask, width,
SIZE_CON_0_FLD_OUTPUT_FRAME_WIDTH);
DISP_REG_MASK(handle, offset + DISP_REG_RDMA_SIZE_CON_0,
size_con_0_value, size_con_0_mask);
DISP_REG_SET_FIELD(handle, SIZE_CON_1_FLD_OUTPUT_FRAME_HEIGHT,
offset + DISP_REG_RDMA_SIZE_CON_1, height);
/* RDMA bg control */
/* DISP_REG_RDMA_BG_CON_0 */
val = REG_FLD_VAL(RDMA_BG_CON_0_LEFT, bg_ctrl->left);
val |= REG_FLD_VAL(RDMA_BG_CON_0_RIGHT, bg_ctrl->right);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_BG_CON_0, val);
/* DISP_REG_RDMA_BG_CON_1 */
val = REG_FLD_VAL(RDMA_BG_CON_1_TOP, bg_ctrl->top);
val |= REG_FLD_VAL(RDMA_BG_CON_1_BOTTOM, bg_ctrl->bottom);
DISP_REG_SET(handle, offset + DISP_REG_RDMA_BG_CON_1, val);
DISP_REG_SET_FIELD(handle, GLOBAL_CON_FLD_MODE_SEL,
offset + DISP_REG_RDMA_GLOBAL_CON, mode);
set_rdma_width_height(width, height);
rdma_set_ultra_l(idx, bpp, handle, p_golden_setting);
return 0;
}
int rdma_clock_on(enum DISP_MODULE_ENUM module, void *handle)
{
ddp_clk_prepare_enable(ddp_get_module_clk_id(module));
return 0;
}
int rdma_clock_off(enum DISP_MODULE_ENUM module, void *handle)
{
ddp_clk_disable_unprepare(ddp_get_module_clk_id(module));
return 0;
}
void rdma_dump_golden_setting_context(enum DISP_MODULE_ENUM module)
{
if (!rdma_golden_setting)
return;
DDPDUMP("-- %s Golden Setting Context --\n",
ddp_get_module_name(module));
DDPDUMP("fifo_mode=%d\n", rdma_golden_setting->fifo_mode);
DDPDUMP("hrt_num=%d\n", rdma_golden_setting->hrt_num);
DDPDUMP("is_display_idle=%d\n", rdma_golden_setting->is_display_idle);
DDPDUMP("is_wrot_sram=%d\n", rdma_golden_setting->is_wrot_sram);
DDPDUMP("is_dc=%d\n", rdma_golden_setting->is_dc);
DDPDUMP("mmsys_clk=%d\n", rdma_golden_setting->mmsys_clk);
DDPDUMP("fps=%d\n", rdma_golden_setting->fps);
DDPDUMP("is_one_layer=%d\n", rdma_golden_setting->is_one_layer);
DDPDUMP("rdma_width=%d\n", rdma_golden_setting->dst_width);
DDPDUMP("rdma_height=%d\n", rdma_golden_setting->dst_height);
}
void rdma_dump_golden_setting(enum DISP_MODULE_ENUM module)
{
unsigned int idx = rdma_index(module);
unsigned int offset = DISP_RDMA_INDEX_OFFSET * idx;
DDPDUMP("-- %s Golden Setting --\n", ddp_get_module_name(module));
DDPDUMP("0x%03x:0x%08x 0x%03x:0x%08x 0x%03x:0x%08x 0x%03x:0x%08x\n",
0x30, DISP_REG_GET(DISP_REG_RDMA_MEM_GMC_SETTING_0 + offset),
0x34, DISP_REG_GET(DISP_REG_RDMA_MEM_GMC_SETTING_1 + offset),
0x3c, DISP_REG_GET(DISP_REG_RDMA_MEM_GMC_SETTING_2 + offset),
0x40, DISP_REG_GET(DISP_REG_RDMA_FIFO_CON + offset));
DDPDUMP("0x%03x:0x%08x 0x%03x:0x%08x 0x%03x:0x%08x 0x%03x:0x%08x\n",
0xa8, DISP_REG_GET(DISP_REG_RDMA_THRESHOLD_FOR_SODI + offset),
0xac, DISP_REG_GET(DISP_REG_RDMA_THRESHOLD_FOR_DVFS + offset),
0xb0, DISP_REG_GET(DISP_REG_RDMA_SRAM_SEL + offset),
0xc8, DISP_REG_GET(DISP_RDMA_SRAM_CASCADE + offset));
DDPDUMP("0x%03x:0x%08x 0x%08x 0x%08x 0x%08x\n",
0xd0, DISP_REG_GET(DISP_REG_RDMA_DVFS_SETTING_PRE + offset),
DISP_REG_GET(DISP_REG_RDMA_DVFS_SETTING_ULTRA + offset),
DISP_REG_GET(DISP_REG_RDMA_LEAVE_DRS_SETTING + offset),
DISP_REG_GET(DISP_REG_RDMA_ENTER_DRS_SETTING + offset));
DDPDUMP("0x%03x:0x%08x\n",
0xe8, DISP_REG_GET(DISP_REG_RDMA_MEM_GMC_SETTING_3 + offset));
DDPDUMP("GMC_SETTING_0 [11:0]:%u [27:16]:%u [30]:%u [31]:%u\n",
DISP_REG_GET_FIELD(
MEM_GMC_SETTING_0_FLD_PRE_ULTRA_THRESHOLD_LOW,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_0),
DISP_REG_GET_FIELD(
MEM_GMC_SETTING_0_FLD_PRE_ULTRA_THRESHOLD_HIGH,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_0),
DISP_REG_GET_FIELD(
MEM_GMC_SETTING_0_FLD_RG_VALID_THRESHOLD_FORCE_PREULTRA,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_0),
DISP_REG_GET_FIELD(
MEM_GMC_SETTING_0_FLD_RG_VDE_FORCE_PREULTRA,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_0));
DDPDUMP("GMC_SETTING_1 [11:0]:%u [27:16]:%u [30]:%u [31]:%u\n",
DISP_REG_GET_FIELD(MEM_GMC_SETTING_1_FLD_ULTRA_THRESHOLD_LOW,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_1),
DISP_REG_GET_FIELD(MEM_GMC_SETTING_1_FLD_ULTRA_THRESHOLD_HIGH,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_1),
DISP_REG_GET_FIELD(
MEM_GMC_SETTING_1_FLD_RG_VALID_THRESHOLD_BLOCK_ULTRA,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_1),
DISP_REG_GET_FIELD(MEM_GMC_SETTING_1_FLD_RG_VDE_BLOCK_ULTRA,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_1));
DDPDUMP("GMC_SETTING_2 [11:0]:%u\n",
DISP_REG_GET_FIELD(MEM_GMC_SETTING_2_FLD_ISSUE_REQ_THRESHOLD,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_2));
DDPDUMP("FIFO_CON [11:0]:%u [27:16]:%d [31]:%u\n",
DISP_REG_GET_FIELD(FIFO_CON_FLD_OUTPUT_VALID_FIFO_THRESHOLD,
offset + DISP_REG_RDMA_FIFO_CON),
DISP_REG_GET_FIELD(FIFO_CON_FLD_FIFO_PSEUDO_SIZE,
offset + DISP_REG_RDMA_FIFO_CON),
DISP_REG_GET_FIELD(FIFO_CON_FLD_FIFO_UNDERFLOW_EN,
offset + DISP_REG_RDMA_FIFO_CON));
DDPDUMP("THRSHOLD_SODI [11:0]:%u [27:16]:%u\n",
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_LOW,
offset + DISP_REG_RDMA_THRESHOLD_FOR_SODI),
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_HIGH,
offset + DISP_REG_RDMA_THRESHOLD_FOR_SODI));
DDPDUMP("THRSHOLD_DVFS [11:0]:%u [27:16]:%u\n",
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_LOW,
offset + DISP_REG_RDMA_THRESHOLD_FOR_DVFS),
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_HIGH,
offset + DISP_REG_RDMA_THRESHOLD_FOR_DVFS));
DDPDUMP("SRAM_SEL [0]:%u\n",
DISP_REG_GET(offset + DISP_REG_RDMA_SRAM_SEL));
DDPDUMP("SRAM_CASCADE [13:0]:%u [27:16]:%u\n",
DISP_REG_GET_FIELD(RG_DISP_RDMA_FIFO_SIZE,
offset + DISP_RDMA_SRAM_CASCADE),
DISP_REG_GET_FIELD(RG_DISP_RDMA_RSZ_FIFO_SIZE,
offset + DISP_RDMA_SRAM_CASCADE));
DDPDUMP("DVFS_SETTING_PREULTRA [11:0]:%u [27:16]:%u\n",
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_LOW,
offset + DISP_REG_RDMA_DVFS_SETTING_PRE),
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_HIGH,
offset + DISP_REG_RDMA_DVFS_SETTING_PRE));
DDPDUMP("DVFS_SETTING_ULTRA [11:0]:%u [27:16]:%u\n",
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_LOW,
offset + DISP_REG_RDMA_DVFS_SETTING_ULTRA),
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_HIGH,
offset + DISP_REG_RDMA_DVFS_SETTING_ULTRA));
DDPDUMP("LEAVE_DRS_SETTING [11:0]:%u [27:16]:%u\n",
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_LOW,
offset + DISP_REG_RDMA_LEAVE_DRS_SETTING),
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_HIGH,
offset + DISP_REG_RDMA_LEAVE_DRS_SETTING));
DDPDUMP("ENTER_DRS_SETTING [11:0]:%u [27:16]:%u\n",
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_LOW,
offset + DISP_REG_RDMA_ENTER_DRS_SETTING),
DISP_REG_GET_FIELD(RDMA_THRESHOLD_FOR_DVFS_FLD_HIGH,
offset + DISP_REG_RDMA_ENTER_DRS_SETTING));
DDPDUMP("GMC_SETTING_3 [11:0]:%u [27:16]:%u\n",
DISP_REG_GET_FIELD(FLD_LOW_FOR_URGENT,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_3),
DISP_REG_GET_FIELD(FLD_HIGH_FOR_URGENT,
offset + DISP_REG_RDMA_MEM_GMC_SETTING_3));
}
void rdma_dump_reg(enum DISP_MODULE_ENUM module)
{
unsigned int idx = rdma_index(module);
unsigned int offset = DISP_RDMA_INDEX_OFFSET * idx;
DDPDUMP("== DISP %s REGS ==\n", ddp_get_module_name(module));
DDPDUMP("0x%03x:0x%08x 0x%08x\n",
0x00, DISP_REG_GET(DISP_REG_RDMA_INT_ENABLE + offset),
DISP_REG_GET(DISP_REG_RDMA_INT_STATUS + offset));
DDPDUMP("0x%03x:0x%08x 0x%08x 0x%08x 0x%08x\n",
0x10, DISP_REG_GET(DISP_REG_RDMA_GLOBAL_CON + offset),
DISP_REG_GET(DISP_REG_RDMA_SIZE_CON_0 + offset),
DISP_REG_GET(DISP_REG_RDMA_SIZE_CON_1 + offset),
DISP_REG_GET(DISP_REG_RDMA_TARGET_LINE + offset));
DDPDUMP("0x%03x:0x%08x 0x%03x:0x%08x 0x%03x:0x%08x\n",
0xf00, DISP_REG_GET(DISP_REG_RDMA_MEM_START_ADDR + offset),
0x24, DISP_REG_GET(DISP_REG_RDMA_MEM_CON + offset),
0x2c, DISP_REG_GET(DISP_REG_RDMA_MEM_SRC_PITCH + offset));
DDPDUMP("0x%03x:0x%08x 0x%03x:0x%08x\n",
0x38, DISP_REG_GET(DISP_REG_RDMA_MEM_SLOW_CON + offset),
0x44, DISP_REG_GET(DISP_REG_RDMA_FIFO_LOG + offset));
DDPDUMP("0x%03x:0x%08x 0x%08x 0x%03x:0x%08x\n",
0x78, DISP_REG_GET(DISP_REG_RDMA_PRE_ADD_0 + offset),
DISP_REG_GET(DISP_REG_RDMA_PRE_ADD_1 + offset),
0x80, DISP_REG_GET(DISP_REG_RDMA_PRE_ADD_2 + offset));
DDPDUMP("0x%03x:0x%08x 0x%08x 0x%08x\n",
0x84, DISP_REG_GET(DISP_REG_RDMA_POST_ADD_0 + offset),
DISP_REG_GET(DISP_REG_RDMA_POST_ADD_1 + offset),
DISP_REG_GET(DISP_REG_RDMA_POST_ADD_2 + offset));
DDPDUMP("0x%03x:0x%08x 0x%08x 0x%03x:0x%08x 0x%08x\n",
0x90, DISP_REG_GET(DISP_REG_RDMA_DUMMY + offset),
DISP_REG_GET(DISP_REG_RDMA_DEBUG_OUT_SEL + offset),
0xa0, DISP_REG_GET(DISP_REG_RDMA_BG_CON_0 + offset),
DISP_REG_GET(DISP_REG_RDMA_BG_CON_1 + offset));
DDPDUMP("0x%03x:0x%08x 0x%03x:0x%08x\n",
0xb4, DISP_REG_GET(DISP_REG_RDMA_STALL_CG_CON + offset),
0xbc, DISP_REG_GET(DISP_REG_RDMA_SHADOW_UPDATE + offset));
DDPDUMP("0x%03x:0x%08x 0x%08x 0x%08x 0x%08x\n",
0xf0, DISP_REG_GET(DISP_REG_RDMA_IN_P_CNT + offset),
DISP_REG_GET(DISP_REG_RDMA_IN_LINE_CNT + offset),
DISP_REG_GET(DISP_REG_RDMA_OUT_P_CNT + offset),
DISP_REG_GET(DISP_REG_RDMA_OUT_LINE_CNT + offset));
rdma_dump_golden_setting(module);
}
void rdma_dump_analysis(enum DISP_MODULE_ENUM module)
{
unsigned int idx = rdma_index(module);
unsigned int offset = idx * DISP_RDMA_INDEX_OFFSET;
unsigned int global_ctrl;
unsigned int bg0 = DISP_REG_GET(offset + DISP_REG_RDMA_BG_CON_0);
unsigned int bg1 = DISP_REG_GET(offset + DISP_REG_RDMA_BG_CON_1);
unsigned int fifo = DISP_REG_GET(offset + DISP_REG_RDMA_FIFO_CON);
const int len = 200;
char msg[len];
int n = 0;
global_ctrl = DISP_REG_GET(DISP_REG_RDMA_GLOBAL_CON + offset);
DDPDUMP("== DISP %s ANALYSIS ==\n", ddp_get_module_name(module));
n = scnprintf(msg, len,
"en=%d,mode:%s,smi_busy:%d,wh(%dx%d),pitch=%d,",
REG_FLD_VAL_GET(GLOBAL_CON_FLD_ENGINE_EN + offset, global_ctrl),
REG_FLD_VAL_GET(GLOBAL_CON_FLD_MODE_SEL + offset,
global_ctrl) ? "mem" : "DL",
REG_FLD_VAL_GET(GLOBAL_CON_FLD_SMI_BUSY + offset, global_ctrl),
DISP_REG_GET(DISP_REG_RDMA_SIZE_CON_0 + offset) & 0xfff,
DISP_REG_GET(DISP_REG_RDMA_SIZE_CON_1 + offset) & 0xfffff,
DISP_REG_GET(DISP_REG_RDMA_MEM_SRC_PITCH + offset));
n += scnprintf(msg + n, len - n,
"addr=0x%08x,fmt=%s,fifo_sz=%u,",
DISP_REG_GET(DISP_REG_RDMA_MEM_START_ADDR + offset),
unified_color_fmt_name(display_fmt_reg_to_unified_fmt(
(DISP_REG_GET(DISP_REG_RDMA_MEM_CON +
offset) >> 4) & 0xf,
(DISP_REG_GET(DISP_REG_RDMA_MEM_CON +
offset) >> 8) & 0x1, 0)),
REG_FLD_VAL_GET(FIFO_CON_FLD_FIFO_PSEUDO_SIZE, fifo));
n += scnprintf(msg + n, len - n,
"output_valid_threshold=%u,fifo_min=%d\n",
REG_FLD_VAL_GET(FIFO_CON_FLD_OUTPUT_VALID_FIFO_THRESHOLD, fifo),
DISP_REG_GET(DISP_REG_RDMA_FIFO_LOG + offset));
DDPDUMP("%s", msg);
n = scnprintf(msg, len,
"pos:in(%d,%d)out(%d,%d),bg(t%d,b%d,l%d,r%d),",
DISP_REG_GET(DISP_REG_RDMA_IN_P_CNT + offset),
DISP_REG_GET(DISP_REG_RDMA_IN_LINE_CNT + offset),
DISP_REG_GET(DISP_REG_RDMA_OUT_P_CNT + offset),
DISP_REG_GET(DISP_REG_RDMA_OUT_LINE_CNT + offset),
REG_FLD_VAL_GET(RDMA_BG_CON_1_TOP + offset, bg1),
REG_FLD_VAL_GET(RDMA_BG_CON_1_BOTTOM + offset, bg1),
REG_FLD_VAL_GET(RDMA_BG_CON_0_LEFT + offset, bg0),
REG_FLD_VAL_GET(RDMA_BG_CON_0_RIGHT + offset, bg0));
n += scnprintf(msg + n, len - n,
"start=%lld ns,end=%lld ns\n",
rdma_start_time[idx], rdma_end_time[idx]);
DDPDUMP("%s", msg);
DDPDUMP("irq cnt:start=%d,end=%d,underflow=%d,targetline=%d\n",
rdma_start_irq_cnt[idx], rdma_done_irq_cnt[idx],
rdma_underflow_irq_cnt[idx], rdma_targetline_irq_cnt[idx]);
rdma_dump_golden_setting_context(module);
}
static int rdma_dump(enum DISP_MODULE_ENUM module, int level)
{
rdma_dump_analysis(module);
rdma_dump_reg(module);
return 0;
}
void rdma_get_info(int idx, struct RDMA_BASIC_STRUCT *info)
{
struct RDMA_BASIC_STRUCT *p = info;
unsigned int offset = idx * DISP_RDMA_INDEX_OFFSET;
p->addr = DISP_REG_GET(DISP_REG_RDMA_MEM_START_ADDR + offset);
p->src_w = DISP_REG_GET(DISP_REG_RDMA_SIZE_CON_0 + offset) & 0xfff;
p->src_h = DISP_REG_GET(DISP_REG_RDMA_SIZE_CON_1 + offset) & 0xfffff;
p->bpp = UFMT_GET_bpp(display_fmt_reg_to_unified_fmt(
(DISP_REG_GET(DISP_REG_RDMA_MEM_CON +
offset) >> 4) & 0xf,
(DISP_REG_GET(DISP_REG_RDMA_MEM_CON +
offset) >> 8) & 0x1, 0)) / 8;
}
static inline enum RDMA_MODE get_rdma_mode(enum DISP_MODULE_ENUM module)
{
unsigned int idx = rdma_index(module);
return DISP_REG_GET_FIELD(GLOBAL_CON_FLD_MODE_SEL,
(DISP_RDMA_INDEX_OFFSET * idx) +
DISP_REG_RDMA_GLOBAL_CON);
}
static inline enum RDMA_MODE rdma_config_mode(unsigned long address)
{
return address ? RDMA_MODE_MEMORY : RDMA_MODE_DIRECT_LINK;
}
static int do_rdma_config_l(enum DISP_MODULE_ENUM module,
struct disp_ddp_path_config *pConfig, void *handle)
{
struct RDMA_CONFIG_STRUCT *cfg = &pConfig->rdma_config;
enum RDMA_MODE mode = rdma_config_mode(cfg->address);
struct LCM_PARAMS *lcm_param = &pConfig->dispif_config;
unsigned int width;
unsigned int height;
struct golden_setting_context *p_golden_setting;
enum UNIFIED_COLOR_FMT inFormat = cfg->inputFormat;
enum UNIFIED_COLOR_FMT bwFormat;
unsigned int bwBpp;
unsigned long long rdma_bw;
width = pConfig->dst_dirty ? pConfig->dst_w : cfg->width;
height = pConfig->dst_dirty ? pConfig->dst_h : cfg->height;
p_golden_setting = pConfig->p_golden_setting_context;
if (module == DISP_MODULE_RDMA0)
memcpy(&g_primary_rdma_cfg, cfg,
sizeof(struct RDMA_CONFIG_STRUCT));
if (pConfig->fps)
rdma_fps[rdma_index(module)] = pConfig->fps / 100;
if (mode == RDMA_MODE_DIRECT_LINK &&
cfg->security != DISP_NORMAL_BUFFER)
DDP_PR_ERR("%s: rdma directlink BUT is sec ??!!\n", __func__);
if (mode == RDMA_MODE_DIRECT_LINK) {
cfg->bg_ctrl.top = 0;
cfg->bg_ctrl.bottom = 0;
cfg->bg_ctrl.left = 0;
cfg->bg_ctrl.right = 0;
} else if (mode == RDMA_MODE_MEMORY) {
cfg->bg_ctrl.top = cfg->dst_y;
cfg->bg_ctrl.bottom = cfg->dst_h - cfg->dst_y - height;
cfg->bg_ctrl.left = cfg->dst_x;
cfg->bg_ctrl.right = cfg->dst_w - cfg->dst_x - width;
}
DDPDBG("%s:(t%u,b%u,l%u,r%u),r.dst(%u,%u,%ux%u),width=%u,height=%u\n",
__func__, cfg->bg_ctrl.top, cfg->bg_ctrl.bottom,
cfg->bg_ctrl.left, cfg->bg_ctrl.right,
cfg->dst_x, cfg->dst_y,
cfg->dst_w, cfg->dst_h, width, height);
/* PARGB..etc need convert to ARGB..etc */
ufmt_disable_P(cfg->inputFormat, &inFormat);
rdma_config(module, mode,
(mode == RDMA_MODE_DIRECT_LINK) ? 0 : cfg->address,
(mode == RDMA_MODE_DIRECT_LINK) ? UFMT_RGB888 : inFormat,
(mode == RDMA_MODE_DIRECT_LINK) ? 0 : cfg->pitch,
width, height, lcm_param->dsi.ufoe_enable,
cfg->security, cfg->hnd,
cfg->yuv_range,
&cfg->bg_ctrl, handle, p_golden_setting,
pConfig->lcm_bpp);
/* calculate bandwidth */
bwFormat = (mode == RDMA_MODE_DIRECT_LINK) ? UFMT_RGB888 : inFormat;
bwBpp = ufmt_get_Bpp(bwFormat);
rdma_bw = (unsigned long long)width * height * bwBpp;
do_div(rdma_bw, 1000);
rdma_bw *= 1250;
do_div(rdma_bw, 1000);
DDPDBG("R:width=%u,height=%u,Bpp:%u,bw:%llu\n",
width, height, bwBpp, rdma_bw);
/* bandwidth report */
if (module == DISP_MODULE_RDMA0)
DISP_SLOT_SET(handle, DISPSYS_SLOT_BASE,
DISP_SLOT_RDMA0_BW, (unsigned int)rdma_bw);
return 0;
}
static int rdma_is_sec[2];
static inline int rdma_switch_to_sec(enum DISP_MODULE_ENUM module, void *handle)
{
unsigned int rdma_idx = rdma_index(module);
enum CMDQ_ENG_ENUM cmdq_engine;
cmdq_engine = rdma_to_cmdq_engine(module);
cmdqRecSetSecure(handle, 1);
/* set engine as sec port */
cmdqRecSecureEnablePortSecurity(handle, (1LL << cmdq_engine));
/* cmdqRecSecureEnableDAPC(handle, (1LL << cmdq_engine)); */
if (rdma_is_sec[rdma_idx] == 0) {
DDPSVPMSG("[SVP] switch rdma%d to sec\n", rdma_idx);
mmprofile_log_ex(ddp_mmp_get_events()->svp_module[module],
MMPROFILE_FLAG_START, 0, 0);
}
rdma_is_sec[rdma_idx] = 1;
return 0;
}
int rdma_switch_to_nonsec(enum DISP_MODULE_ENUM module,
struct disp_ddp_path_config *pConfig, void *handle)
{
unsigned int rdma_idx = rdma_index(module);
enum CMDQ_ENG_ENUM cmdq_engine;
cmdq_engine = rdma_to_cmdq_engine(module);
if (rdma_is_sec[rdma_idx] == 1) {
/* RDMA is in sec stat, we need to switch it to nonsec */
struct cmdqRecStruct *nonsec_switch_handle = NULL;
int ret;
ret = cmdqRecCreate(
CMDQ_SCENARIO_DISP_PRIMARY_DISABLE_SECURE_PATH,
&(nonsec_switch_handle));
if (ret)
DDPAEE("[SVP]fail to create disable handle %s ret=%d\n",
__func__, ret);
cmdqRecReset(nonsec_switch_handle);
if (rdma_idx == 0) {
/* Primary Decouple Mode */
_cmdq_insert_wait_frame_done_token_mira(
nonsec_switch_handle);
} else {
/* External Mode */
/* OVL1->RDMA1, do not use. */
_cmdq_insert_wait_frame_done_token_mira(
nonsec_switch_handle);
}
cmdqRecSetSecure(nonsec_switch_handle, 1);
/*
* ugly workaround by kzhang !!
* will remove when cmdq delete disable scenario.
* To avoid translation fault like OVL (see notes in ovl.c)
* check the mode now, bypass the frame during DL->DC(),
* avoid hang when VDO mode.
*/
if (get_rdma_mode(module) == RDMA_MODE_MEMORY)
do_rdma_config_l(module, pConfig, nonsec_switch_handle);
/* in fact, dapc/port_sec will be disabled by cmdq */
cmdqRecSecureEnablePortSecurity(nonsec_switch_handle,
(1LL << cmdq_engine));
if (handle) {
/* Async Flush method */
enum CMDQ_EVENT_ENUM cmdq_event_nonsec_end;
cmdq_event_nonsec_end =
rdma_to_cmdq_event_nonsec_end(module);
cmdqRecSetEventToken(nonsec_switch_handle,
cmdq_event_nonsec_end);
cmdqRecFlushAsync(nonsec_switch_handle);
cmdqRecWait(handle, cmdq_event_nonsec_end);
} else {
/* Sync Flush method */
cmdqRecFlush(nonsec_switch_handle);
}
cmdqRecDestroy(nonsec_switch_handle);
DDPSVPMSG("[SVP] switch rdma%d to nonsec\n", rdma_idx);
mmprofile_log_ex(ddp_mmp_get_events()->svp_module[module],
MMPROFILE_FLAG_END, 0, 0);
}
rdma_is_sec[rdma_idx] = 0;
return 0;
}
int rdma_wait_sec_done(enum DISP_MODULE_ENUM module,
struct disp_ddp_path_config *pConfig, void *handle)
{
unsigned int rdma_idx = rdma_index(module);
enum CMDQ_ENG_ENUM cmdq_engine;
struct cmdqRecStruct *wait_handle;
int ret;
if (rdma_is_sec[rdma_idx] == 0)
return 0;
cmdq_engine = rdma_to_cmdq_engine(module);
/* rdma is in sec stat, we need to switch it to nonsec */
ret = cmdqRecCreate(CMDQ_SCENARIO_PRIMARY_DISP,
&(wait_handle));
if (ret)
DDPAEE("[SVP]fail to create disable handle %s ret=%d\n",
__func__, ret);
cmdqRecReset(wait_handle);
cmdqRecSetSecure(wait_handle, 1);
cmdqRecSecureEnablePortSecurity(wait_handle,
(1LL << cmdq_engine));
if (handle != NULL) {
/*Async Flush method*/
enum CMDQ_EVENT_ENUM cmdq_event_nonsec_end;
cmdq_event_nonsec_end = rdma_to_cmdq_event_nonsec_end(module);
cmdqRecSetEventToken(wait_handle, cmdq_event_nonsec_end);
cmdqRecFlushAsync(wait_handle);
cmdqRecWait(handle, cmdq_event_nonsec_end);
} else {
/*Sync Flush method*/
cmdqRecFlush(wait_handle);
}
cmdqRecDestroy(wait_handle);
mmprofile_log_ex(ddp_mmp_get_events()->svp_module[module],
MMPROFILE_FLAG_END, 0, 0);
/* MMProfileLogEx(ddp_mmp_get_events()->svp_module[module],
* MMProfileFlagPulse, 1, 1);
*/
return 0;
}
static int setup_rdma_sec(enum DISP_MODULE_ENUM module,
struct disp_ddp_path_config *pConfig, void *handle)
{
int ret;
int is_engine_sec = 0;
enum RDMA_MODE mode = rdma_config_mode(pConfig->rdma_config.address);
if (pConfig->rdma_config.security == DISP_SECURE_BUFFER)
is_engine_sec = 1;
if (!handle) {
DDPDBG("[SVP] bypass rdma sec setting sec=%d,handle=NULL\n",
is_engine_sec);
return 0;
}
/* sec setting makes sense only in memory mode! */
if (mode == RDMA_MODE_MEMORY) {
if (is_engine_sec == 1)
ret = rdma_switch_to_sec(module, handle);
else
/* handle = NULL, use the sync flush method */
ret = rdma_switch_to_nonsec(module, pConfig, NULL);
if (ret)
DDPAEE("[SVP]fail to %s: ret=%d\n",
__func__, ret);
} else {
rdma_wait_sec_done(module, pConfig, NULL);
}
return is_engine_sec;
}
static int rdma_config_l(enum DISP_MODULE_ENUM module,
struct disp_ddp_path_config *pConfig, void *handle)
{
if (pConfig->dst_dirty || pConfig->rdma_dirty) {
setup_rdma_sec(module, pConfig, handle);
do_rdma_config_l(module, pConfig, handle);
}
return 0;
}
void rdma_enable_color_transform(enum DISP_MODULE_ENUM module)
{
unsigned int idx = rdma_index(module);
unsigned int offset = DISP_RDMA_INDEX_OFFSET * idx;
UINT32 value = DISP_REG_GET(DISP_REG_RDMA_SIZE_CON_0 + offset);
value = value | REG_FLD_VAL((SIZE_CON_0_FLD_MATRIX_EXT_MTX_EN), 1) |
REG_FLD_VAL((SIZE_CON_0_FLD_MATRIX_ENABLE), 1);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_SIZE_CON_0, value);
}
void rdma_disable_color_transform(enum DISP_MODULE_ENUM module)
{
unsigned int idx = rdma_index(module);
unsigned int offset = DISP_RDMA_INDEX_OFFSET * idx;
UINT32 value = DISP_REG_GET(DISP_REG_RDMA_SIZE_CON_0 + offset);
value = value & ~(REG_FLD_VAL((SIZE_CON_0_FLD_MATRIX_EXT_MTX_EN), 1) |
REG_FLD_VAL((SIZE_CON_0_FLD_MATRIX_ENABLE), 1));
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_SIZE_CON_0, value);
}
void rdma_set_color_matrix(enum DISP_MODULE_ENUM module,
struct rdma_color_matrix *matrix,
struct rdma_color_pre *pre,
struct rdma_color_post *post)
{
unsigned int idx = rdma_index(module);
unsigned int offset = DISP_RDMA_INDEX_OFFSET * idx;
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_C00, matrix->C00);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_C01, matrix->C01);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_C02, matrix->C02);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_C10, matrix->C10);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_C11, matrix->C11);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_C12, matrix->C12);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_C20, matrix->C20);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_C21, matrix->C21);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_C22, matrix->C22);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_PRE_ADD_0, pre->ADD0);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_PRE_ADD_1, pre->ADD1);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_PRE_ADD_2, pre->ADD2);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_POST_ADD_0, post->ADD0);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_POST_ADD_1, post->ADD1);
DISP_REG_SET(NULL, offset + DISP_REG_RDMA_POST_ADD_2, post->ADD2);
}
static int _rdma_partial_update(enum DISP_MODULE_ENUM module, void *arg,
void *handle)
{
struct disp_rect *roi = (struct disp_rect *)arg;
int width = roi->width;
int height = roi->height;
unsigned int idx = rdma_index(module);
unsigned int offset = DISP_RDMA_INDEX_OFFSET * idx;
DISP_REG_SET_FIELD(handle, SIZE_CON_0_FLD_OUTPUT_FRAME_WIDTH,
offset + DISP_REG_RDMA_SIZE_CON_0, width);
DISP_REG_SET_FIELD(handle, SIZE_CON_1_FLD_OUTPUT_FRAME_HEIGHT,
offset + DISP_REG_RDMA_SIZE_CON_1, height);
return 0;
}
int rdma_ioctl(enum DISP_MODULE_ENUM module, void *cmdq_handle,
unsigned int ioctl_cmd, unsigned long *params)
{
int ret = 0;
enum DDP_IOCTL_NAME ioctl = (enum DDP_IOCTL_NAME)ioctl_cmd;
unsigned int idx = rdma_index(module);
switch (ioctl) {
case DDP_RDMA_GOLDEN_SETTING:
{
struct disp_ddp_path_config *pConfig;
struct golden_setting_context *p_golden_setting;
pConfig = (struct disp_ddp_path_config *)params;
p_golden_setting = pConfig->p_golden_setting_context;
rdma_set_ultra_l(idx, pConfig->lcm_bpp, cmdq_handle,
p_golden_setting);
break;
}
case DDP_PARTIAL_UPDATE:
_rdma_partial_update(module, params, cmdq_handle);
break;
default:
break;
}
return ret;
}
static int rdma_build_cmdq(enum DISP_MODULE_ENUM module, void *handle,
enum CMDQ_STATE state)
{
if (handle == NULL) {
DDP_PR_ERR("cmdq_trigger_handle is NULL\n");
return -1;
}
if (state == CMDQ_RESET_AFTER_STREAM_EOF) {
/*
* if RDMA frame done with underflow,
* rdma will hold dvfs request forever
* we reset here to solve this issue
*/
rdma_reset_by_cmdq(module, handle);
}
return 0;
}
/* for mmpath */
inline bool MMPathIsPrimaryDL(void)
{
return (rdma_golden_setting->is_dc == 0);
}
unsigned int MMPathTracePrimaryRDMA(char *str, unsigned int strlen,
unsigned int n)
{
n += scnprintf(str + n, strlen - n,
"in=0x%lx, in_width=%d, in_height=%d, in_fmt=%s, in_Bpp=%u, ",
g_primary_rdma_cfg.address,
g_primary_rdma_cfg.width,
g_primary_rdma_cfg.height,
unified_color_fmt_name(g_primary_rdma_cfg.inputFormat),
ufmt_get_Bpp(g_primary_rdma_cfg.inputFormat));
return n;
}
struct DDP_MODULE_DRIVER ddp_driver_rdma = {
.init = rdma_init,
.deinit = rdma_deinit,
.config = rdma_config_l,
.start = rdma_start,
.trigger = NULL,
.stop = rdma_stop,
.reset = rdma_reset,
.power_on = rdma_clock_on,
.power_off = rdma_clock_off,
.is_idle = NULL,
.is_busy = NULL,
.dump_info = rdma_dump,
.bypass = NULL,
.build_cmdq = rdma_build_cmdq,
.set_lcm_utils = NULL,
.enable_irq = rdma_enable_irq,
.ioctl = (int (*)(enum DISP_MODULE_ENUM, void *,
enum DDP_IOCTL_NAME, void *))rdma_ioctl,
.switch_to_nonsec = NULL,
};
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