blob: fa8fb2c357774fd3e2e585204086cf649fa661f4 [file] [log] [blame]
/*
* Porting to u-boot:
*
* (C) Copyright 2010
* Stefano Babic, DENX Software Engineering, sbabic@denx.de
*
* Linux IPU driver for MX51:
*
* (C) Copyright 2005-2010 Freescale Semiconductor, Inc.
*
* See file CREDITS for list of people who contributed to this
* project.
*
* 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
*/
/* #define DEBUG */
#include <common.h>
#include <linux/types.h>
#include <asm/errno.h>
#include <asm/io.h>
#include <asm/arch/imx-regs.h>
#include <asm/arch/sys_proto.h>
#include "ipu.h"
#include "ipu_regs.h"
enum csc_type_t {
RGB2YUV = 0,
YUV2RGB,
RGB2RGB,
YUV2YUV,
CSC_NONE,
CSC_NUM
};
struct dp_csc_param_t {
int mode;
void *coeff;
};
#define SYNC_WAVE 0
/* DC display ID assignments */
#define DC_DISP_ID_SYNC(di) (di)
#define DC_DISP_ID_SERIAL 2
#define DC_DISP_ID_ASYNC 3
int dmfc_type_setup;
static int dmfc_size_28, dmfc_size_29, dmfc_size_24, dmfc_size_27, dmfc_size_23;
int g_di1_tvout;
extern struct clk *g_ipu_clk;
extern struct clk *g_di_clk[2];
extern struct clk *g_pixel_clk[2];
extern unsigned char g_ipu_clk_enabled;
extern unsigned char g_dc_di_assignment[];
void ipu_dmfc_init(int dmfc_type, int first)
{
u32 dmfc_wr_chan, dmfc_dp_chan;
if (first) {
if (dmfc_type_setup > dmfc_type)
dmfc_type = dmfc_type_setup;
else
dmfc_type_setup = dmfc_type;
/* disable DMFC-IC channel*/
__raw_writel(0x2, DMFC_IC_CTRL);
} else if (dmfc_type_setup >= DMFC_HIGH_RESOLUTION_DC) {
printf("DMFC high resolution has set, will not change\n");
return;
} else
dmfc_type_setup = dmfc_type;
if (dmfc_type == DMFC_HIGH_RESOLUTION_DC) {
/* 1 - segment 0~3;
* 5B - segement 4, 5;
* 5F - segement 6, 7;
* 1C, 2C and 6B, 6F unused;
*/
debug("IPU DMFC DC HIGH RES: 1(0~3), 5B(4,5), 5F(6,7)\n");
dmfc_wr_chan = 0x00000088;
dmfc_dp_chan = 0x00009694;
dmfc_size_28 = 256 * 4;
dmfc_size_29 = 0;
dmfc_size_24 = 0;
dmfc_size_27 = 128 * 4;
dmfc_size_23 = 128 * 4;
} else if (dmfc_type == DMFC_HIGH_RESOLUTION_DP) {
/* 1 - segment 0, 1;
* 5B - segement 2~5;
* 5F - segement 6,7;
* 1C, 2C and 6B, 6F unused;
*/
debug("IPU DMFC DP HIGH RES: 1(0,1), 5B(2~5), 5F(6,7)\n");
dmfc_wr_chan = 0x00000090;
dmfc_dp_chan = 0x0000968a;
dmfc_size_28 = 128 * 4;
dmfc_size_29 = 0;
dmfc_size_24 = 0;
dmfc_size_27 = 128 * 4;
dmfc_size_23 = 256 * 4;
} else if (dmfc_type == DMFC_HIGH_RESOLUTION_ONLY_DP) {
/* 5B - segement 0~3;
* 5F - segement 4~7;
* 1, 1C, 2C and 6B, 6F unused;
*/
debug("IPU DMFC ONLY-DP HIGH RES: 5B(0~3), 5F(4~7)\n");
dmfc_wr_chan = 0x00000000;
dmfc_dp_chan = 0x00008c88;
dmfc_size_28 = 0;
dmfc_size_29 = 0;
dmfc_size_24 = 0;
dmfc_size_27 = 256 * 4;
dmfc_size_23 = 256 * 4;
} else {
/* 1 - segment 0, 1;
* 5B - segement 4, 5;
* 5F - segement 6, 7;
* 1C, 2C and 6B, 6F unused;
*/
debug("IPU DMFC NORMAL mode: 1(0~1), 5B(4,5), 5F(6,7)\n");
dmfc_wr_chan = 0x00000090;
dmfc_dp_chan = 0x00009694;
dmfc_size_28 = 128 * 4;
dmfc_size_29 = 0;
dmfc_size_24 = 0;
dmfc_size_27 = 128 * 4;
dmfc_size_23 = 128 * 4;
}
__raw_writel(dmfc_wr_chan, DMFC_WR_CHAN);
__raw_writel(0x202020F6, DMFC_WR_CHAN_DEF);
__raw_writel(dmfc_dp_chan, DMFC_DP_CHAN);
/* Enable chan 5 watermark set at 5 bursts and clear at 7 bursts */
__raw_writel(0x2020F6F6, DMFC_DP_CHAN_DEF);
}
void ipu_dmfc_set_wait4eot(int dma_chan, int width)
{
u32 dmfc_gen1 = __raw_readl(DMFC_GENERAL1);
if (width >= HIGH_RESOLUTION_WIDTH) {
if (dma_chan == 23)
ipu_dmfc_init(DMFC_HIGH_RESOLUTION_DP, 0);
else if (dma_chan == 28)
ipu_dmfc_init(DMFC_HIGH_RESOLUTION_DC, 0);
}
if (dma_chan == 23) { /*5B*/
if (dmfc_size_23 / width > 3)
dmfc_gen1 |= 1UL << 20;
else
dmfc_gen1 &= ~(1UL << 20);
} else if (dma_chan == 24) { /*6B*/
if (dmfc_size_24 / width > 1)
dmfc_gen1 |= 1UL << 22;
else
dmfc_gen1 &= ~(1UL << 22);
} else if (dma_chan == 27) { /*5F*/
if (dmfc_size_27 / width > 2)
dmfc_gen1 |= 1UL << 21;
else
dmfc_gen1 &= ~(1UL << 21);
} else if (dma_chan == 28) { /*1*/
if (dmfc_size_28 / width > 2)
dmfc_gen1 |= 1UL << 16;
else
dmfc_gen1 &= ~(1UL << 16);
} else if (dma_chan == 29) { /*6F*/
if (dmfc_size_29 / width > 1)
dmfc_gen1 |= 1UL << 23;
else
dmfc_gen1 &= ~(1UL << 23);
}
__raw_writel(dmfc_gen1, DMFC_GENERAL1);
}
static void ipu_di_data_wave_config(int di,
int wave_gen,
int access_size, int component_size)
{
u32 reg;
reg = (access_size << DI_DW_GEN_ACCESS_SIZE_OFFSET) |
(component_size << DI_DW_GEN_COMPONENT_SIZE_OFFSET);
__raw_writel(reg, DI_DW_GEN(di, wave_gen));
}
static void ipu_di_data_pin_config(int di, int wave_gen, int di_pin, int set,
int up, int down)
{
u32 reg;
reg = __raw_readl(DI_DW_GEN(di, wave_gen));
reg &= ~(0x3 << (di_pin * 2));
reg |= set << (di_pin * 2);
__raw_writel(reg, DI_DW_GEN(di, wave_gen));
__raw_writel((down << 16) | up, DI_DW_SET(di, wave_gen, set));
}
static void ipu_di_sync_config(int di, int wave_gen,
int run_count, int run_src,
int offset_count, int offset_src,
int repeat_count, int cnt_clr_src,
int cnt_polarity_gen_en,
int cnt_polarity_clr_src,
int cnt_polarity_trigger_src,
int cnt_up, int cnt_down)
{
u32 reg;
if ((run_count >= 0x1000) || (offset_count >= 0x1000) ||
(repeat_count >= 0x1000) ||
(cnt_up >= 0x400) || (cnt_down >= 0x400)) {
printf("DI%d counters out of range.\n", di);
return;
}
reg = (run_count << 19) | (++run_src << 16) |
(offset_count << 3) | ++offset_src;
__raw_writel(reg, DI_SW_GEN0(di, wave_gen));
reg = (cnt_polarity_gen_en << 29) | (++cnt_clr_src << 25) |
(++cnt_polarity_trigger_src << 12) | (++cnt_polarity_clr_src << 9);
reg |= (cnt_down << 16) | cnt_up;
if (repeat_count == 0) {
/* Enable auto reload */
reg |= 0x10000000;
}
__raw_writel(reg, DI_SW_GEN1(di, wave_gen));
reg = __raw_readl(DI_STP_REP(di, wave_gen));
reg &= ~(0xFFFF << (16 * ((wave_gen - 1) & 0x1)));
reg |= repeat_count << (16 * ((wave_gen - 1) & 0x1));
__raw_writel(reg, DI_STP_REP(di, wave_gen));
}
static void ipu_dc_map_config(int map, int byte_num, int offset, int mask)
{
int ptr = map * 3 + byte_num;
u32 reg;
reg = __raw_readl(DC_MAP_CONF_VAL(ptr));
reg &= ~(0xFFFF << (16 * (ptr & 0x1)));
reg |= ((offset << 8) | mask) << (16 * (ptr & 0x1));
__raw_writel(reg, DC_MAP_CONF_VAL(ptr));
reg = __raw_readl(DC_MAP_CONF_PTR(map));
reg &= ~(0x1F << ((16 * (map & 0x1)) + (5 * byte_num)));
reg |= ptr << ((16 * (map & 0x1)) + (5 * byte_num));
__raw_writel(reg, DC_MAP_CONF_PTR(map));
}
static void ipu_dc_map_clear(int map)
{
u32 reg = __raw_readl(DC_MAP_CONF_PTR(map));
__raw_writel(reg & ~(0xFFFF << (16 * (map & 0x1))),
DC_MAP_CONF_PTR(map));
}
static void ipu_dc_write_tmpl(int word, u32 opcode, u32 operand, int map,
int wave, int glue, int sync)
{
u32 reg;
int stop = 1;
reg = sync;
reg |= (glue << 4);
reg |= (++wave << 11);
reg |= (++map << 15);
reg |= (operand << 20) & 0xFFF00000;
__raw_writel(reg, ipu_dc_tmpl_reg + word * 2);
reg = (operand >> 12);
reg |= opcode << 4;
reg |= (stop << 9);
__raw_writel(reg, ipu_dc_tmpl_reg + word * 2 + 1);
}
static void ipu_dc_link_event(int chan, int event, int addr, int priority)
{
u32 reg;
reg = __raw_readl(DC_RL_CH(chan, event));
reg &= ~(0xFFFF << (16 * (event & 0x1)));
reg |= ((addr << 8) | priority) << (16 * (event & 0x1));
__raw_writel(reg, DC_RL_CH(chan, event));
}
/* Y = R * 1.200 + G * 2.343 + B * .453 + 0.250;
* U = R * -.672 + G * -1.328 + B * 2.000 + 512.250.;
* V = R * 2.000 + G * -1.672 + B * -.328 + 512.250.;
*/
static const int rgb2ycbcr_coeff[5][3] = {
{0x4D, 0x96, 0x1D},
{0x3D5, 0x3AB, 0x80},
{0x80, 0x395, 0x3EB},
{0x0000, 0x0200, 0x0200}, /* B0, B1, B2 */
{0x2, 0x2, 0x2}, /* S0, S1, S2 */
};
/* R = (1.164 * (Y - 16)) + (1.596 * (Cr - 128));
* G = (1.164 * (Y - 16)) - (0.392 * (Cb - 128)) - (0.813 * (Cr - 128));
* B = (1.164 * (Y - 16)) + (2.017 * (Cb - 128);
*/
static const int ycbcr2rgb_coeff[5][3] = {
{0x095, 0x000, 0x0CC},
{0x095, 0x3CE, 0x398},
{0x095, 0x0FF, 0x000},
{0x3E42, 0x010A, 0x3DD6}, /*B0,B1,B2 */
{0x1, 0x1, 0x1}, /*S0,S1,S2 */
};
#define mask_a(a) ((u32)(a) & 0x3FF)
#define mask_b(b) ((u32)(b) & 0x3FFF)
/* Pls keep S0, S1 and S2 as 0x2 by using this convertion */
static int rgb_to_yuv(int n, int red, int green, int blue)
{
int c;
c = red * rgb2ycbcr_coeff[n][0];
c += green * rgb2ycbcr_coeff[n][1];
c += blue * rgb2ycbcr_coeff[n][2];
c /= 16;
c += rgb2ycbcr_coeff[3][n] * 4;
c += 8;
c /= 16;
if (c < 0)
c = 0;
if (c > 255)
c = 255;
return c;
}
/*
* Row is for BG: RGB2YUV YUV2RGB RGB2RGB YUV2YUV CSC_NONE
* Column is for FG: RGB2YUV YUV2RGB RGB2RGB YUV2YUV CSC_NONE
*/
static struct dp_csc_param_t dp_csc_array[CSC_NUM][CSC_NUM] = {
{
{DP_COM_CONF_CSC_DEF_BOTH, &rgb2ycbcr_coeff},
{0, 0},
{0, 0},
{DP_COM_CONF_CSC_DEF_BG, &rgb2ycbcr_coeff},
{DP_COM_CONF_CSC_DEF_BG, &rgb2ycbcr_coeff}
},
{
{0, 0},
{DP_COM_CONF_CSC_DEF_BOTH, &ycbcr2rgb_coeff},
{DP_COM_CONF_CSC_DEF_BG, &ycbcr2rgb_coeff},
{0, 0},
{DP_COM_CONF_CSC_DEF_BG, &ycbcr2rgb_coeff}
},
{
{0, 0},
{DP_COM_CONF_CSC_DEF_FG, &ycbcr2rgb_coeff},
{0, 0},
{0, 0},
{0, 0}
},
{
{DP_COM_CONF_CSC_DEF_FG, &rgb2ycbcr_coeff},
{0, 0},
{0, 0},
{0, 0},
{0, 0}
},
{
{DP_COM_CONF_CSC_DEF_FG, &rgb2ycbcr_coeff},
{DP_COM_CONF_CSC_DEF_FG, &ycbcr2rgb_coeff},
{0, 0},
{0, 0},
{0, 0}
}
};
static enum csc_type_t fg_csc_type = CSC_NONE, bg_csc_type = CSC_NONE;
static int color_key_4rgb = 1;
void ipu_dp_csc_setup(int dp, struct dp_csc_param_t dp_csc_param,
unsigned char srm_mode_update)
{
u32 reg;
const int (*coeff)[5][3];
if (dp_csc_param.mode >= 0) {
reg = __raw_readl(DP_COM_CONF());
reg &= ~DP_COM_CONF_CSC_DEF_MASK;
reg |= dp_csc_param.mode;
__raw_writel(reg, DP_COM_CONF());
}
coeff = dp_csc_param.coeff;
if (coeff) {
__raw_writel(mask_a((*coeff)[0][0]) |
(mask_a((*coeff)[0][1]) << 16), DP_CSC_A_0());
__raw_writel(mask_a((*coeff)[0][2]) |
(mask_a((*coeff)[1][0]) << 16), DP_CSC_A_1());
__raw_writel(mask_a((*coeff)[1][1]) |
(mask_a((*coeff)[1][2]) << 16), DP_CSC_A_2());
__raw_writel(mask_a((*coeff)[2][0]) |
(mask_a((*coeff)[2][1]) << 16), DP_CSC_A_3());
__raw_writel(mask_a((*coeff)[2][2]) |
(mask_b((*coeff)[3][0]) << 16) |
((*coeff)[4][0] << 30), DP_CSC_0());
__raw_writel(mask_b((*coeff)[3][1]) | ((*coeff)[4][1] << 14) |
(mask_b((*coeff)[3][2]) << 16) |
((*coeff)[4][2] << 30), DP_CSC_1());
}
if (srm_mode_update) {
reg = __raw_readl(IPU_SRM_PRI2) | 0x8;
__raw_writel(reg, IPU_SRM_PRI2);
}
}
int ipu_dp_init(ipu_channel_t channel, uint32_t in_pixel_fmt,
uint32_t out_pixel_fmt)
{
int in_fmt, out_fmt;
int dp;
int partial = 0;
uint32_t reg;
if (channel == MEM_FG_SYNC) {
dp = DP_SYNC;
partial = 1;
} else if (channel == MEM_BG_SYNC) {
dp = DP_SYNC;
partial = 0;
} else if (channel == MEM_BG_ASYNC0) {
dp = DP_ASYNC0;
partial = 0;
} else {
return -EINVAL;
}
in_fmt = format_to_colorspace(in_pixel_fmt);
out_fmt = format_to_colorspace(out_pixel_fmt);
if (partial) {
if (in_fmt == RGB) {
if (out_fmt == RGB)
fg_csc_type = RGB2RGB;
else
fg_csc_type = RGB2YUV;
} else {
if (out_fmt == RGB)
fg_csc_type = YUV2RGB;
else
fg_csc_type = YUV2YUV;
}
} else {
if (in_fmt == RGB) {
if (out_fmt == RGB)
bg_csc_type = RGB2RGB;
else
bg_csc_type = RGB2YUV;
} else {
if (out_fmt == RGB)
bg_csc_type = YUV2RGB;
else
bg_csc_type = YUV2YUV;
}
}
/* Transform color key from rgb to yuv if CSC is enabled */
reg = __raw_readl(DP_COM_CONF());
if (color_key_4rgb && (reg & DP_COM_CONF_GWCKE) &&
(((fg_csc_type == RGB2YUV) && (bg_csc_type == YUV2YUV)) ||
((fg_csc_type == YUV2YUV) && (bg_csc_type == RGB2YUV)) ||
((fg_csc_type == YUV2YUV) && (bg_csc_type == YUV2YUV)) ||
((fg_csc_type == YUV2RGB) && (bg_csc_type == YUV2RGB)))) {
int red, green, blue;
int y, u, v;
uint32_t color_key = __raw_readl(DP_GRAPH_WIND_CTRL()) &
0xFFFFFFL;
debug("_ipu_dp_init color key 0x%x need change to yuv fmt!\n",
color_key);
red = (color_key >> 16) & 0xFF;
green = (color_key >> 8) & 0xFF;
blue = color_key & 0xFF;
y = rgb_to_yuv(0, red, green, blue);
u = rgb_to_yuv(1, red, green, blue);
v = rgb_to_yuv(2, red, green, blue);
color_key = (y << 16) | (u << 8) | v;
reg = __raw_readl(DP_GRAPH_WIND_CTRL()) & 0xFF000000L;
__raw_writel(reg | color_key, DP_GRAPH_WIND_CTRL());
color_key_4rgb = 0;
debug("_ipu_dp_init color key change to yuv fmt 0x%x!\n",
color_key);
}
ipu_dp_csc_setup(dp, dp_csc_array[bg_csc_type][fg_csc_type], 1);
return 0;
}
void ipu_dp_uninit(ipu_channel_t channel)
{
int dp;
int partial = 0;
if (channel == MEM_FG_SYNC) {
dp = DP_SYNC;
partial = 1;
} else if (channel == MEM_BG_SYNC) {
dp = DP_SYNC;
partial = 0;
} else if (channel == MEM_BG_ASYNC0) {
dp = DP_ASYNC0;
partial = 0;
} else {
return;
}
if (partial)
fg_csc_type = CSC_NONE;
else
bg_csc_type = CSC_NONE;
ipu_dp_csc_setup(dp, dp_csc_array[bg_csc_type][fg_csc_type], 0);
}
void ipu_dc_init(int dc_chan, int di, unsigned char interlaced)
{
u32 reg = 0;
if ((dc_chan == 1) || (dc_chan == 5)) {
if (interlaced) {
ipu_dc_link_event(dc_chan, DC_EVT_NL, 0, 3);
ipu_dc_link_event(dc_chan, DC_EVT_EOL, 0, 2);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_DATA, 0, 1);
} else {
if (di) {
ipu_dc_link_event(dc_chan, DC_EVT_NL, 2, 3);
ipu_dc_link_event(dc_chan, DC_EVT_EOL, 3, 2);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_DATA,
4, 1);
} else {
ipu_dc_link_event(dc_chan, DC_EVT_NL, 5, 3);
ipu_dc_link_event(dc_chan, DC_EVT_EOL, 6, 2);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_DATA,
7, 1);
}
}
ipu_dc_link_event(dc_chan, DC_EVT_NF, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NFIELD, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_EOF, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_EOFIELD, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_CHAN, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_ADDR, 0, 0);
reg = 0x2;
reg |= DC_DISP_ID_SYNC(di) << DC_WR_CH_CONF_PROG_DISP_ID_OFFSET;
reg |= di << 2;
if (interlaced)
reg |= DC_WR_CH_CONF_FIELD_MODE;
} else if ((dc_chan == 8) || (dc_chan == 9)) {
/* async channels */
ipu_dc_link_event(dc_chan, DC_EVT_NEW_DATA_W_0, 0x64, 1);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_DATA_W_1, 0x64, 1);
reg = 0x3;
reg |= DC_DISP_ID_SERIAL << DC_WR_CH_CONF_PROG_DISP_ID_OFFSET;
}
__raw_writel(reg, DC_WR_CH_CONF(dc_chan));
__raw_writel(0x00000000, DC_WR_CH_ADDR(dc_chan));
__raw_writel(0x00000084, DC_GEN);
}
void ipu_dc_uninit(int dc_chan)
{
if ((dc_chan == 1) || (dc_chan == 5)) {
ipu_dc_link_event(dc_chan, DC_EVT_NL, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_EOL, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_DATA, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NF, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NFIELD, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_EOF, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_EOFIELD, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_CHAN, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_ADDR, 0, 0);
} else if ((dc_chan == 8) || (dc_chan == 9)) {
ipu_dc_link_event(dc_chan, DC_EVT_NEW_ADDR_W_0, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_ADDR_W_1, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_CHAN_W_0, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_CHAN_W_1, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_DATA_W_0, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_DATA_W_1, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_ADDR_R_0, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_ADDR_R_1, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_CHAN_R_0, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_CHAN_R_1, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_DATA_R_0, 0, 0);
ipu_dc_link_event(dc_chan, DC_EVT_NEW_DATA_R_1, 0, 0);
}
}
int ipu_chan_is_interlaced(ipu_channel_t channel)
{
if (channel == MEM_DC_SYNC)
return !!(__raw_readl(DC_WR_CH_CONF_1) &
DC_WR_CH_CONF_FIELD_MODE);
else if ((channel == MEM_BG_SYNC) || (channel == MEM_FG_SYNC))
return !!(__raw_readl(DC_WR_CH_CONF_5) &
DC_WR_CH_CONF_FIELD_MODE);
return 0;
}
void ipu_dp_dc_enable(ipu_channel_t channel)
{
int di;
uint32_t reg;
uint32_t dc_chan;
if (channel == MEM_FG_SYNC)
dc_chan = 5;
if (channel == MEM_DC_SYNC)
dc_chan = 1;
else if (channel == MEM_BG_SYNC)
dc_chan = 5;
else
return;
if (channel == MEM_FG_SYNC) {
/* Enable FG channel */
reg = __raw_readl(DP_COM_CONF());
__raw_writel(reg | DP_COM_CONF_FG_EN, DP_COM_CONF());
reg = __raw_readl(IPU_SRM_PRI2) | 0x8;
__raw_writel(reg, IPU_SRM_PRI2);
return;
}
di = g_dc_di_assignment[dc_chan];
/* Make sure other DC sync channel is not assigned same DI */
reg = __raw_readl(DC_WR_CH_CONF(6 - dc_chan));
if ((di << 2) == (reg & DC_WR_CH_CONF_PROG_DI_ID)) {
reg &= ~DC_WR_CH_CONF_PROG_DI_ID;
reg |= di ? 0 : DC_WR_CH_CONF_PROG_DI_ID;
__raw_writel(reg, DC_WR_CH_CONF(6 - dc_chan));
}
reg = __raw_readl(DC_WR_CH_CONF(dc_chan));
reg |= 4 << DC_WR_CH_CONF_PROG_TYPE_OFFSET;
__raw_writel(reg, DC_WR_CH_CONF(dc_chan));
clk_enable(g_pixel_clk[di]);
}
static unsigned char dc_swap;
void ipu_dp_dc_disable(ipu_channel_t channel, unsigned char swap)
{
uint32_t reg;
uint32_t csc;
uint32_t dc_chan = 0;
int timeout = 50;
dc_swap = swap;
if (channel == MEM_DC_SYNC) {
dc_chan = 1;
} else if (channel == MEM_BG_SYNC) {
dc_chan = 5;
} else if (channel == MEM_FG_SYNC) {
/* Disable FG channel */
dc_chan = 5;
reg = __raw_readl(DP_COM_CONF());
csc = reg & DP_COM_CONF_CSC_DEF_MASK;
if (csc == DP_COM_CONF_CSC_DEF_FG)
reg &= ~DP_COM_CONF_CSC_DEF_MASK;
reg &= ~DP_COM_CONF_FG_EN;
__raw_writel(reg, DP_COM_CONF());
reg = __raw_readl(IPU_SRM_PRI2) | 0x8;
__raw_writel(reg, IPU_SRM_PRI2);
timeout = 50;
/*
* Wait for DC triple buffer to empty,
* this check is useful for tv overlay.
*/
if (g_dc_di_assignment[dc_chan] == 0)
while ((__raw_readl(DC_STAT) & 0x00000002)
!= 0x00000002) {
udelay(2000);
timeout -= 2;
if (timeout <= 0)
break;
}
else if (g_dc_di_assignment[dc_chan] == 1)
while ((__raw_readl(DC_STAT) & 0x00000020)
!= 0x00000020) {
udelay(2000);
timeout -= 2;
if (timeout <= 0)
break;
}
return;
} else {
return;
}
if (dc_swap) {
/* Swap DC channel 1 and 5 settings, and disable old dc chan */
reg = __raw_readl(DC_WR_CH_CONF(dc_chan));
__raw_writel(reg, DC_WR_CH_CONF(6 - dc_chan));
reg &= ~DC_WR_CH_CONF_PROG_TYPE_MASK;
reg ^= DC_WR_CH_CONF_PROG_DI_ID;
__raw_writel(reg, DC_WR_CH_CONF(dc_chan));
} else {
timeout = 50;
/* Wait for DC triple buffer to empty */
if (g_dc_di_assignment[dc_chan] == 0)
while ((__raw_readl(DC_STAT) & 0x00000002)
!= 0x00000002) {
udelay(2000);
timeout -= 2;
if (timeout <= 0)
break;
}
else if (g_dc_di_assignment[dc_chan] == 1)
while ((__raw_readl(DC_STAT) & 0x00000020)
!= 0x00000020) {
udelay(2000);
timeout -= 2;
if (timeout <= 0)
break;
}
reg = __raw_readl(DC_WR_CH_CONF(dc_chan));
reg &= ~DC_WR_CH_CONF_PROG_TYPE_MASK;
__raw_writel(reg, DC_WR_CH_CONF(dc_chan));
reg = __raw_readl(IPU_DISP_GEN);
if (g_dc_di_assignment[dc_chan])
reg &= ~DI1_COUNTER_RELEASE;
else
reg &= ~DI0_COUNTER_RELEASE;
__raw_writel(reg, IPU_DISP_GEN);
/* Clock is already off because it must be done quickly, but
we need to fix the ref count */
clk_disable(g_pixel_clk[g_dc_di_assignment[dc_chan]]);
}
}
void ipu_init_dc_mappings(void)
{
/* IPU_PIX_FMT_RGB24 */
ipu_dc_map_clear(0);
ipu_dc_map_config(0, 0, 7, 0xFF);
ipu_dc_map_config(0, 1, 15, 0xFF);
ipu_dc_map_config(0, 2, 23, 0xFF);
/* IPU_PIX_FMT_RGB666 */
ipu_dc_map_clear(1);
ipu_dc_map_config(1, 0, 5, 0xFC);
ipu_dc_map_config(1, 1, 11, 0xFC);
ipu_dc_map_config(1, 2, 17, 0xFC);
/* IPU_PIX_FMT_YUV444 */
ipu_dc_map_clear(2);
ipu_dc_map_config(2, 0, 15, 0xFF);
ipu_dc_map_config(2, 1, 23, 0xFF);
ipu_dc_map_config(2, 2, 7, 0xFF);
/* IPU_PIX_FMT_RGB565 */
ipu_dc_map_clear(3);
ipu_dc_map_config(3, 0, 4, 0xF8);
ipu_dc_map_config(3, 1, 10, 0xFC);
ipu_dc_map_config(3, 2, 15, 0xF8);
/* IPU_PIX_FMT_LVDS666 */
ipu_dc_map_clear(4);
ipu_dc_map_config(4, 0, 5, 0xFC);
ipu_dc_map_config(4, 1, 13, 0xFC);
ipu_dc_map_config(4, 2, 21, 0xFC);
}
int ipu_pixfmt_to_map(uint32_t fmt)
{
switch (fmt) {
case IPU_PIX_FMT_GENERIC:
case IPU_PIX_FMT_RGB24:
return 0;
case IPU_PIX_FMT_RGB666:
return 1;
case IPU_PIX_FMT_YUV444:
return 2;
case IPU_PIX_FMT_RGB565:
return 3;
case IPU_PIX_FMT_LVDS666:
return 4;
}
return -1;
}
/*
* This function is called to adapt synchronous LCD panel to IPU restriction.
*/
void adapt_panel_to_ipu_restricitions(uint32_t *pixel_clk,
uint16_t width, uint16_t height,
uint16_t h_start_width,
uint16_t h_end_width,
uint16_t v_start_width,
uint16_t *v_end_width)
{
if (*v_end_width < 2) {
uint16_t total_width = width + h_start_width + h_end_width;
uint16_t total_height_old = height + v_start_width +
(*v_end_width);
uint16_t total_height_new = height + v_start_width + 2;
*v_end_width = 2;
*pixel_clk = (*pixel_clk) * total_width * total_height_new /
(total_width * total_height_old);
printf("WARNING: adapt panel end blank lines\n");
}
}
/*
* This function is called to initialize a synchronous LCD panel.
*
* @param disp The DI the panel is attached to.
*
* @param pixel_clk Desired pixel clock frequency in Hz.
*
* @param pixel_fmt Input parameter for pixel format of buffer.
* Pixel format is a FOURCC ASCII code.
*
* @param width The width of panel in pixels.
*
* @param height The height of panel in pixels.
*
* @param hStartWidth The number of pixel clocks between the HSYNC
* signal pulse and the start of valid data.
*
* @param hSyncWidth The width of the HSYNC signal in units of pixel
* clocks.
*
* @param hEndWidth The number of pixel clocks between the end of
* valid data and the HSYNC signal for next line.
*
* @param vStartWidth The number of lines between the VSYNC
* signal pulse and the start of valid data.
*
* @param vSyncWidth The width of the VSYNC signal in units of lines
*
* @param vEndWidth The number of lines between the end of valid
* data and the VSYNC signal for next frame.
*
* @param sig Bitfield of signal polarities for LCD interface.
*
* @return This function returns 0 on success or negative error code on
* fail.
*/
int32_t ipu_init_sync_panel(int disp, uint32_t pixel_clk,
uint16_t width, uint16_t height,
uint32_t pixel_fmt,
uint16_t h_start_width, uint16_t h_sync_width,
uint16_t h_end_width, uint16_t v_start_width,
uint16_t v_sync_width, uint16_t v_end_width,
uint32_t v_to_h_sync, ipu_di_signal_cfg_t sig)
{
uint32_t reg;
uint32_t di_gen, vsync_cnt;
uint32_t div, rounded_pixel_clk;
uint32_t h_total, v_total;
int map;
struct clk *di_parent;
debug("panel size = %d x %d\n", width, height);
if ((v_sync_width == 0) || (h_sync_width == 0))
return EINVAL;
adapt_panel_to_ipu_restricitions(&pixel_clk, width, height,
h_start_width, h_end_width,
v_start_width, &v_end_width);
h_total = width + h_sync_width + h_start_width + h_end_width;
v_total = height + v_sync_width + v_start_width + v_end_width;
/* Init clocking */
debug("pixel clk = %d\n", pixel_clk);
if (sig.ext_clk) {
if (!(g_di1_tvout && (disp == 1))) { /*not round div for tvout*/
/*
* Set the PLL to be an even multiple
* of the pixel clock.
*/
if ((clk_get_usecount(g_pixel_clk[0]) == 0) &&
(clk_get_usecount(g_pixel_clk[1]) == 0)) {
di_parent = clk_get_parent(g_di_clk[disp]);
rounded_pixel_clk =
clk_round_rate(g_pixel_clk[disp],
pixel_clk);
div = clk_get_rate(di_parent) /
rounded_pixel_clk;
if (div % 2)
div++;
if (clk_get_rate(di_parent) != div *
rounded_pixel_clk)
clk_set_rate(di_parent,
div * rounded_pixel_clk);
udelay(10000);
clk_set_rate(g_di_clk[disp],
2 * rounded_pixel_clk);
udelay(10000);
}
}
clk_set_parent(g_pixel_clk[disp], g_di_clk[disp]);
} else {
if (clk_get_usecount(g_pixel_clk[disp]) != 0)
clk_set_parent(g_pixel_clk[disp], g_ipu_clk);
}
rounded_pixel_clk = clk_round_rate(g_pixel_clk[disp], pixel_clk);
clk_set_rate(g_pixel_clk[disp], rounded_pixel_clk);
udelay(5000);
/* Get integer portion of divider */
div = clk_get_rate(clk_get_parent(g_pixel_clk[disp])) /
rounded_pixel_clk;
ipu_di_data_wave_config(disp, SYNC_WAVE, div - 1, div - 1);
ipu_di_data_pin_config(disp, SYNC_WAVE, DI_PIN15, 3, 0, div * 2);
map = ipu_pixfmt_to_map(pixel_fmt);
if (map < 0) {
debug("IPU_DISP: No MAP\n");
return -EINVAL;
}
di_gen = __raw_readl(DI_GENERAL(disp));
if (sig.interlaced) {
/* Setup internal HSYNC waveform */
ipu_di_sync_config(
disp, /* display */
1, /* counter */
h_total / 2 - 1,/* run count */
DI_SYNC_CLK, /* run_resolution */
0, /* offset */
DI_SYNC_NONE, /* offset resolution */
0, /* repeat count */
DI_SYNC_NONE, /* CNT_CLR_SEL */
0, /* CNT_POLARITY_GEN_EN */
DI_SYNC_NONE, /* CNT_POLARITY_CLR_SEL */
DI_SYNC_NONE, /* CNT_POLARITY_TRIGGER_SEL */
0, /* COUNT UP */
0 /* COUNT DOWN */
);
/* Field 1 VSYNC waveform */
ipu_di_sync_config(
disp, /* display */
2, /* counter */
h_total - 1, /* run count */
DI_SYNC_CLK, /* run_resolution */
0, /* offset */
DI_SYNC_NONE, /* offset resolution */
0, /* repeat count */
DI_SYNC_NONE, /* CNT_CLR_SEL */
0, /* CNT_POLARITY_GEN_EN */
DI_SYNC_NONE, /* CNT_POLARITY_CLR_SEL */
DI_SYNC_NONE, /* CNT_POLARITY_TRIGGER_SEL */
0, /* COUNT UP */
4 /* COUNT DOWN */
);
/* Setup internal HSYNC waveform */
ipu_di_sync_config(
disp, /* display */
3, /* counter */
v_total * 2 - 1,/* run count */
DI_SYNC_INT_HSYNC, /* run_resolution */
1, /* offset */
DI_SYNC_INT_HSYNC, /* offset resolution */
0, /* repeat count */
DI_SYNC_NONE, /* CNT_CLR_SEL */
0, /* CNT_POLARITY_GEN_EN */
DI_SYNC_NONE, /* CNT_POLARITY_CLR_SEL */
DI_SYNC_NONE, /* CNT_POLARITY_TRIGGER_SEL */
0, /* COUNT UP */
4 /* COUNT DOWN */
);
/* Active Field ? */
ipu_di_sync_config(
disp, /* display */
4, /* counter */
v_total / 2 - 1,/* run count */
DI_SYNC_HSYNC, /* run_resolution */
v_start_width, /* offset */
DI_SYNC_HSYNC, /* offset resolution */
2, /* repeat count */
DI_SYNC_VSYNC, /* CNT_CLR_SEL */
0, /* CNT_POLARITY_GEN_EN */
DI_SYNC_NONE, /* CNT_POLARITY_CLR_SEL */
DI_SYNC_NONE, /* CNT_POLARITY_TRIGGER_SEL */
0, /* COUNT UP */
0 /* COUNT DOWN */
);
/* Active Line */
ipu_di_sync_config(
disp, /* display */
5, /* counter */
0, /* run count */
DI_SYNC_HSYNC, /* run_resolution */
0, /* offset */
DI_SYNC_NONE, /* offset resolution */
height / 2, /* repeat count */
4, /* CNT_CLR_SEL */
0, /* CNT_POLARITY_GEN_EN */
DI_SYNC_NONE, /* CNT_POLARITY_CLR_SEL */
DI_SYNC_NONE, /* CNT_POLARITY_TRIGGER_SEL */
0, /* COUNT UP */
0 /* COUNT DOWN */
);
/* Field 0 VSYNC waveform */
ipu_di_sync_config(
disp, /* display */
6, /* counter */
v_total - 1, /* run count */
DI_SYNC_HSYNC, /* run_resolution */
0, /* offset */
DI_SYNC_NONE, /* offset resolution */
0, /* repeat count */
DI_SYNC_NONE, /* CNT_CLR_SEL */
0, /* CNT_POLARITY_GEN_EN */
DI_SYNC_NONE, /* CNT_POLARITY_CLR_SEL */
DI_SYNC_NONE, /* CNT_POLARITY_TRIGGER_SEL */
0, /* COUNT UP */
0 /* COUNT DOWN */
);
/* DC VSYNC waveform */
vsync_cnt = 7;
ipu_di_sync_config(
disp, /* display */
7, /* counter */
v_total / 2 - 1,/* run count */
DI_SYNC_HSYNC, /* run_resolution */
9, /* offset */
DI_SYNC_HSYNC, /* offset resolution */
2, /* repeat count */
DI_SYNC_VSYNC, /* CNT_CLR_SEL */
0, /* CNT_POLARITY_GEN_EN */
DI_SYNC_NONE, /* CNT_POLARITY_CLR_SEL */
DI_SYNC_NONE, /* CNT_POLARITY_TRIGGER_SEL */
0, /* COUNT UP */
0 /* COUNT DOWN */
);
/* active pixel waveform */
ipu_di_sync_config(
disp, /* display */
8, /* counter */
0, /* run count */
DI_SYNC_CLK, /* run_resolution */
h_start_width, /* offset */
DI_SYNC_CLK, /* offset resolution */
width, /* repeat count */
5, /* CNT_CLR_SEL */
0, /* CNT_POLARITY_GEN_EN */
DI_SYNC_NONE, /* CNT_POLARITY_CLR_SEL */
DI_SYNC_NONE, /* CNT_POLARITY_TRIGGER_SEL */
0, /* COUNT UP */
0 /* COUNT DOWN */
);
ipu_di_sync_config(
disp, /* display */
9, /* counter */
v_total - 1, /* run count */
DI_SYNC_INT_HSYNC,/* run_resolution */
v_total / 2, /* offset */
DI_SYNC_INT_HSYNC,/* offset resolution */
0, /* repeat count */
DI_SYNC_HSYNC, /* CNT_CLR_SEL */
0, /* CNT_POLARITY_GEN_EN */
DI_SYNC_NONE, /* CNT_POLARITY_CLR_SEL */
DI_SYNC_NONE, /* CNT_POLARITY_TRIGGER_SEL */
0, /* COUNT UP */
4 /* COUNT DOWN */
);
/* set gentime select and tag sel */
reg = __raw_readl(DI_SW_GEN1(disp, 9));
reg &= 0x1FFFFFFF;
reg |= (3 - 1)<<29 | 0x00008000;
__raw_writel(reg, DI_SW_GEN1(disp, 9));
__raw_writel(v_total / 2 - 1, DI_SCR_CONF(disp));
/* set y_sel = 1 */
di_gen |= 0x10000000;
di_gen |= DI_GEN_POLARITY_5;
di_gen |= DI_GEN_POLARITY_8;
} else {
/* Setup internal HSYNC waveform */
ipu_di_sync_config(disp, 1, h_total - 1, DI_SYNC_CLK,
0, DI_SYNC_NONE, 0, DI_SYNC_NONE,
0, DI_SYNC_NONE,
DI_SYNC_NONE, 0, 0);
/* Setup external (delayed) HSYNC waveform */
ipu_di_sync_config(disp, DI_SYNC_HSYNC, h_total - 1,
DI_SYNC_CLK, div * v_to_h_sync, DI_SYNC_CLK,
0, DI_SYNC_NONE, 1, DI_SYNC_NONE,
DI_SYNC_CLK, 0, h_sync_width * 2);
/* Setup VSYNC waveform */
vsync_cnt = DI_SYNC_VSYNC;
ipu_di_sync_config(disp, DI_SYNC_VSYNC, v_total - 1,
DI_SYNC_INT_HSYNC, 0, DI_SYNC_NONE, 0,
DI_SYNC_NONE, 1, DI_SYNC_NONE,
DI_SYNC_INT_HSYNC, 0, v_sync_width * 2);
__raw_writel(v_total - 1, DI_SCR_CONF(disp));
/* Setup active data waveform to sync with DC */
ipu_di_sync_config(disp, 4, 0, DI_SYNC_HSYNC,
v_sync_width + v_start_width, DI_SYNC_HSYNC,
height,
DI_SYNC_VSYNC, 0, DI_SYNC_NONE,
DI_SYNC_NONE, 0, 0);
ipu_di_sync_config(disp, 5, 0, DI_SYNC_CLK,
h_sync_width + h_start_width, DI_SYNC_CLK,
width, 4, 0, DI_SYNC_NONE, DI_SYNC_NONE, 0,
0);
/* reset all unused counters */
__raw_writel(0, DI_SW_GEN0(disp, 6));
__raw_writel(0, DI_SW_GEN1(disp, 6));
__raw_writel(0, DI_SW_GEN0(disp, 7));
__raw_writel(0, DI_SW_GEN1(disp, 7));
__raw_writel(0, DI_SW_GEN0(disp, 8));
__raw_writel(0, DI_SW_GEN1(disp, 8));
__raw_writel(0, DI_SW_GEN0(disp, 9));
__raw_writel(0, DI_SW_GEN1(disp, 9));
reg = __raw_readl(DI_STP_REP(disp, 6));
reg &= 0x0000FFFF;
__raw_writel(reg, DI_STP_REP(disp, 6));
__raw_writel(0, DI_STP_REP(disp, 7));
__raw_writel(0, DI_STP_REP(disp, 9));
/* Init template microcode */
if (disp) {
ipu_dc_write_tmpl(2, WROD(0), 0, map, SYNC_WAVE, 8, 5);
ipu_dc_write_tmpl(3, WROD(0), 0, map, SYNC_WAVE, 4, 5);
ipu_dc_write_tmpl(4, WROD(0), 0, map, SYNC_WAVE, 0, 5);
} else {
ipu_dc_write_tmpl(5, WROD(0), 0, map, SYNC_WAVE, 8, 5);
ipu_dc_write_tmpl(6, WROD(0), 0, map, SYNC_WAVE, 4, 5);
ipu_dc_write_tmpl(7, WROD(0), 0, map, SYNC_WAVE, 0, 5);
}
if (sig.Hsync_pol)
di_gen |= DI_GEN_POLARITY_2;
if (sig.Vsync_pol)
di_gen |= DI_GEN_POLARITY_3;
if (sig.clk_pol)
di_gen |= DI_GEN_POL_CLK;
}
__raw_writel(di_gen, DI_GENERAL(disp));
__raw_writel((--vsync_cnt << DI_VSYNC_SEL_OFFSET) |
0x00000002, DI_SYNC_AS_GEN(disp));
reg = __raw_readl(DI_POL(disp));
reg &= ~(DI_POL_DRDY_DATA_POLARITY | DI_POL_DRDY_POLARITY_15);
if (sig.enable_pol)
reg |= DI_POL_DRDY_POLARITY_15;
if (sig.data_pol)
reg |= DI_POL_DRDY_DATA_POLARITY;
__raw_writel(reg, DI_POL(disp));
__raw_writel(width, DC_DISP_CONF2(DC_DISP_ID_SYNC(disp)));
return 0;
}
/*
* This function sets the foreground and background plane global alpha blending
* modes. This function also sets the DP graphic plane according to the
* parameter of IPUv3 DP channel.
*
* @param channel IPUv3 DP channel
*
* @param enable Boolean to enable or disable global alpha
* blending. If disabled, local blending is used.
*
* @param alpha Global alpha value.
*
* @return Returns 0 on success or negative error code on fail
*/
int32_t ipu_disp_set_global_alpha(ipu_channel_t channel, unsigned char enable,
uint8_t alpha)
{
uint32_t reg;
unsigned char bg_chan;
if (!((channel == MEM_BG_SYNC || channel == MEM_FG_SYNC) ||
(channel == MEM_BG_ASYNC0 || channel == MEM_FG_ASYNC0) ||
(channel == MEM_BG_ASYNC1 || channel == MEM_FG_ASYNC1)))
return -EINVAL;
if (channel == MEM_BG_SYNC || channel == MEM_BG_ASYNC0 ||
channel == MEM_BG_ASYNC1)
bg_chan = 1;
else
bg_chan = 0;
if (!g_ipu_clk_enabled)
clk_enable(g_ipu_clk);
if (bg_chan) {
reg = __raw_readl(DP_COM_CONF());
__raw_writel(reg & ~DP_COM_CONF_GWSEL, DP_COM_CONF());
} else {
reg = __raw_readl(DP_COM_CONF());
__raw_writel(reg | DP_COM_CONF_GWSEL, DP_COM_CONF());
}
if (enable) {
reg = __raw_readl(DP_GRAPH_WIND_CTRL()) & 0x00FFFFFFL;
__raw_writel(reg | ((uint32_t) alpha << 24),
DP_GRAPH_WIND_CTRL());
reg = __raw_readl(DP_COM_CONF());
__raw_writel(reg | DP_COM_CONF_GWAM, DP_COM_CONF());
} else {
reg = __raw_readl(DP_COM_CONF());
__raw_writel(reg & ~DP_COM_CONF_GWAM, DP_COM_CONF());
}
reg = __raw_readl(IPU_SRM_PRI2) | 0x8;
__raw_writel(reg, IPU_SRM_PRI2);
if (!g_ipu_clk_enabled)
clk_disable(g_ipu_clk);
return 0;
}
/*
* This function sets the transparent color key for SDC graphic plane.
*
* @param channel Input parameter for the logical channel ID.
*
* @param enable Boolean to enable or disable color key
*
* @param colorKey 24-bit RGB color for transparent color key.
*
* @return Returns 0 on success or negative error code on fail
*/
int32_t ipu_disp_set_color_key(ipu_channel_t channel, unsigned char enable,
uint32_t color_key)
{
uint32_t reg;
int y, u, v;
int red, green, blue;
if (!((channel == MEM_BG_SYNC || channel == MEM_FG_SYNC) ||
(channel == MEM_BG_ASYNC0 || channel == MEM_FG_ASYNC0) ||
(channel == MEM_BG_ASYNC1 || channel == MEM_FG_ASYNC1)))
return -EINVAL;
if (!g_ipu_clk_enabled)
clk_enable(g_ipu_clk);
color_key_4rgb = 1;
/* Transform color key from rgb to yuv if CSC is enabled */
if (((fg_csc_type == RGB2YUV) && (bg_csc_type == YUV2YUV)) ||
((fg_csc_type == YUV2YUV) && (bg_csc_type == RGB2YUV)) ||
((fg_csc_type == YUV2YUV) && (bg_csc_type == YUV2YUV)) ||
((fg_csc_type == YUV2RGB) && (bg_csc_type == YUV2RGB))) {
debug("color key 0x%x need change to yuv fmt\n", color_key);
red = (color_key >> 16) & 0xFF;
green = (color_key >> 8) & 0xFF;
blue = color_key & 0xFF;
y = rgb_to_yuv(0, red, green, blue);
u = rgb_to_yuv(1, red, green, blue);
v = rgb_to_yuv(2, red, green, blue);
color_key = (y << 16) | (u << 8) | v;
color_key_4rgb = 0;
debug("color key change to yuv fmt 0x%x\n", color_key);
}
if (enable) {
reg = __raw_readl(DP_GRAPH_WIND_CTRL()) & 0xFF000000L;
__raw_writel(reg | color_key, DP_GRAPH_WIND_CTRL());
reg = __raw_readl(DP_COM_CONF());
__raw_writel(reg | DP_COM_CONF_GWCKE, DP_COM_CONF());
} else {
reg = __raw_readl(DP_COM_CONF());
__raw_writel(reg & ~DP_COM_CONF_GWCKE, DP_COM_CONF());
}
reg = __raw_readl(IPU_SRM_PRI2) | 0x8;
__raw_writel(reg, IPU_SRM_PRI2);
if (!g_ipu_clk_enabled)
clk_disable(g_ipu_clk);
return 0;
}