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gerrit-public.fairphone.software / kernel / lk / refs/tags/FP3-REL-Q-3.A.0107 / . / platform / msm_shared / mdss_hdmi.c
blob: 00bf5f10443ee5d711df69d3239d68518f3c5df6 [file] [log] [blame]
/* Copyright (c) 2010-2016, The Linux Foundation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided
* with the distribution.
* * Neither the name of The Linux Foundation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
* OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
* IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
*/
#include <err.h>
#include <debug.h>
#include <reg.h>
#include <malloc.h>
#include <string.h>
#include <msm_panel.h>
#include <platform/timer.h>
#include <platform/clock.h>
#include "mdp5.h"
#include <platform/iomap.h>
#include "mdss_hdmi.h"
#include <target/display.h>
static struct msm_fb_panel_data panel;
extern int msm_display_init(struct msm_fb_panel_data *pdata);
static bool hdmi_power_enabled;
static bool hdmi_panel_clock_enabled;
static bool hdmi_pll_clock_enabled;
/* Supported HDMI Audio channels */
#define MSM_HDMI_AUDIO_CHANNEL_2 1
#define MSM_HDMI_AUDIO_CHANNEL_MAX 8
enum msm_hdmi_supported_audio_sample_rates {
AUDIO_SAMPLE_RATE_32KHZ,
AUDIO_SAMPLE_RATE_44_1KHZ,
AUDIO_SAMPLE_RATE_48KHZ,
AUDIO_SAMPLE_RATE_88_2KHZ,
AUDIO_SAMPLE_RATE_96KHZ,
AUDIO_SAMPLE_RATE_176_4KHZ,
AUDIO_SAMPLE_RATE_192KHZ,
AUDIO_SAMPLE_RATE_MAX
};
struct hdmi_msm_audio_acr {
uint32_t n; /* N parameter for clock regeneration */
uint32_t cts; /* CTS parameter for clock regeneration */
};
struct hdmi_msm_audio_arcs {
uint32_t pclk;
struct hdmi_msm_audio_acr lut[AUDIO_SAMPLE_RATE_MAX];
};
#define HDMI_MSM_AUDIO_ARCS(pclk, ...) { pclk, __VA_ARGS__ }
/* Audio constants lookup table for hdmi_msm_audio_acr_setup */
/* Valid Pixel-Clock rates: 25.2MHz, 27MHz, 27.03MHz, 74.25MHz, 148.5MHz */
static struct hdmi_msm_audio_arcs hdmi_audio_acr_lut[] = {
/* 25.200MHz */
HDMI_MSM_AUDIO_ARCS(25200, {
{4096, 25200}, {6272, 28000}, {6144, 25200}, {12544, 28000},
{12288, 25200}, {25088, 28000}, {24576, 25200} }),
/* 27.000MHz */
HDMI_MSM_AUDIO_ARCS(27000, {
{4096, 27000}, {6272, 30000}, {6144, 27000}, {12544, 30000},
{12288, 27000}, {25088, 30000}, {24576, 27000} }),
/* 27.027MHz */
HDMI_MSM_AUDIO_ARCS(27030, {
{4096, 27027}, {6272, 30030}, {6144, 27027}, {12544, 30030},
{12288, 27027}, {25088, 30030}, {24576, 27027} }),
/* 74.250MHz */
HDMI_MSM_AUDIO_ARCS(74250, {
{4096, 74250}, {6272, 82500}, {6144, 74250}, {12544, 82500},
{12288, 74250}, {25088, 82500}, {24576, 74250} }),
/* 148.500MHz */
HDMI_MSM_AUDIO_ARCS(148500, {
{4096, 148500}, {6272, 165000}, {6144, 148500}, {12544, 165000},
{12288, 148500}, {25088, 165000}, {24576, 148500} }),
/* 297.000MHz */
HDMI_MSM_AUDIO_ARCS(297000, {
{3072, 222750}, {4704, 247500}, {5120, 247500}, {9408, 247500},
{10240, 247500}, {18816, 247500}, {20480, 247500} }),
/* 594.000MHz */
HDMI_MSM_AUDIO_ARCS(594000, {{3072, 445500}, {9408, 990000}, {6144, 594000},
{18816, 990000}, {12288, 594000}, {37632, 990000},
{24576, 594000} } ),
};
extern int msm_display_init(struct msm_fb_panel_data *pdata);
/* AVI INFOFRAME DATA */
#define NUM_MODES_AVI 20
#define AVI_MAX_DATA_BYTES 13
enum {
DATA_BYTE_1,
DATA_BYTE_2,
DATA_BYTE_3,
DATA_BYTE_4,
DATA_BYTE_5,
DATA_BYTE_6,
DATA_BYTE_7,
DATA_BYTE_8,
DATA_BYTE_9,
DATA_BYTE_10,
DATA_BYTE_11,
DATA_BYTE_12,
DATA_BYTE_13,
};
#define IFRAME_PACKET_OFFSET 0x80
/*
* InfoFrame Type Code:
* 0x0 - Reserved
* 0x1 - Vendor Specific
* 0x2 - Auxiliary Video Information
* 0x3 - Source Product Description
* 0x4 - AUDIO
* 0x5 - MPEG Source
* 0x6 - NTSC VBI
* 0x7 - 0xFF - Reserved
*/
#define AVI_IFRAME_TYPE 0x2
#define AVI_IFRAME_VERSION 0x2
#define AVI_IFRAME_LINE_NUMBER 1
#define LEFT_SHIFT_BYTE(x) ((x) << 8)
#define LEFT_SHIFT_WORD(x) ((x) << 16)
#define LEFT_SHIFT_24BITS(x) ((x) << 24)
#define MAX_AUDIO_DATA_BLOCK_SIZE 0x80
#define DBC_START_OFFSET 4
#define VIC_INDEX 3
#define HDMI_VIC_STR_MAX 4
#define MAX_EDID_BLOCK_SIZE 0x80
enum edid_data_block_type {
RESERVED_DATA_BLOCK1 = 0,
AUDIO_DATA_BLOCK,
VIDEO_DATA_BLOCK,
VENDOR_SPECIFIC_DATA_BLOCK,
SPEAKER_ALLOCATION_DATA_BLOCK,
VESA_DTC_DATA_BLOCK,
RESERVED_DATA_BLOCK2,
USE_EXTENDED_TAG
};
/* video formats defined by CEA 861D */
#define HDMI_VFRMT_UNKNOWN 0
#define HDMI_VFRMT_640x480p60_4_3 1
#define HDMI_VFRMT_1280x720p60_16_9 4
#define HDMI_VFRMT_1920x1080p60_16_9 16
#define HDMI_VFRMT_4096x2160p24_256_135 98
#define HDMI_VFRMT_4096x2160p25_256_135 99
#define HDMI_VFRMT_4096x2160p30_256_135 100
#define HDMI_VFRMT_3840x2160p24_64_27 103
#define HDMI_VFRMT_3840x2160p25_64_27 104
#define HDMI_VFRMT_3840x2160p30_64_27 105
#define HDMI_EVFRMT_4096x2160p24_16_9 131
#define HDMI_VFRMT_4096x2160p60_256_135 102
#define HDMI_VFRMT_COUNT 11
#define HDMI_VFRMT_END 127
#define HDMI_VSDB_3D_EVF_DATA_OFFSET(vsd) \
(!((vsd)[8] & BIT(7)) ? 9 : (!((vsd)[8] & BIT(6)) ? 11 : 13))
#define MSM_MDP_MAX_PIPE_WIDTH 2560
/* TX major version that supports scrambling */
#define HDMI_TX_SCRAMBLER_MIN_TX_VERSION 0x04
#define HDMI_TX_SCRAMBLER_THRESHOLD_RATE_KHZ 340000
#define HDMI_TX_SCRAMBLER_TIMEOUT_MSEC 200
/* default hsyncs for 4k@60 for 200ms */
#define HDMI_DEFAULT_TIMEOUT_HSYNC 28571
#define HDMI_SCDC_TMDS_CONFIG 0x20
#define HDMI_SCDC_CONFIG_0 0x30
#define HDMI_SCDC_UNKNOWN_REGISTER "Unknown register"
#define HDMI_SEC_TO_MS 1000
#define HDMI_MS_TO_US 1000
#define HDMI_SEC_TO_US (HDMI_SEC_TO_MS * HDMI_MS_TO_US)
#define HDMI_KHZ_TO_HZ 1000
#define HDMI_DDC_TRANSACTION_DELAY_US 468
static uint8_t mdss_hdmi_video_formats[HDMI_VFRMT_COUNT];
static uint8_t mdss_hdmi_mode_count;
#define DEFAULT_RESOLUTION HDMI_VFRMT_1920x1080p60_16_9
static uint8_t mdss_hdmi_video_fmt = HDMI_VFRMT_UNKNOWN;
static uint8_t mdss_hdmi_pref_fmt = HDMI_VFRMT_UNKNOWN;
static uint8_t pt_scan_info;
static uint8_t it_scan_info;
static uint8_t ce_scan_info;
static uint8_t mdss_hdmi_edid_buf[MAX_EDID_BLOCK_SIZE];
enum scdc_access_type {
SCDC_SCRAMBLING_STATUS,
SCDC_SCRAMBLING_ENABLE,
SCDC_TMDS_BIT_CLOCK_RATIO_UPDATE,
SCDC_CLOCK_DET_STATUS,
SCDC_CH0_LOCK_STATUS,
SCDC_CH1_LOCK_STATUS,
SCDC_CH2_LOCK_STATUS,
SCDC_CH0_ERROR_COUNT,
SCDC_CH1_ERROR_COUNT,
SCDC_CH2_ERROR_COUNT,
SCDC_READ_ENABLE,
SCDC_MAX,
};
enum ddc_timer_type {
DDC_TIMER_HDCP2P2_RD_MSG,
DDC_TIMER_SCRAMBLER_STATUS,
DDC_TIMER_UPDATE_FLAGS,
DDC_TIMER_STATUS_FLAGS,
DDC_TIMER_CED,
DDC_TIMER_MAX,
};
struct hdmi_tx_ddc_data {
char *what;
uint8_t *data_buf;
uint32_t data_len;
uint32_t dev_addr;
uint32_t offset;
uint32_t request_len;
uint32_t retry_align;
uint32_t hard_timeout;
uint32_t timeout_left;
int retry;
};
enum trigger_mode {
TRIGGER_WRITE,
TRIGGER_READ
};
enum aspect_ratio {
HDMI_RES_AR_INVALID,
HDMI_RES_AR_4_3,
HDMI_RES_AR_5_4,
HDMI_RES_AR_16_9,
HDMI_RES_AR_64_27,
HDMI_RES_AR_16_10,
HDMI_RES_AR_256_135,
HDMI_RES_AR_MAX,
};
enum hdmi_quantization_range {
HDMI_QUANTIZATION_DEFAULT,
HDMI_QUANTIZATION_LIMITED_RANGE,
HDMI_QUANTIZATION_FULL_RANGE
};
enum hdmi_scaling_info {
HDMI_SCALING_NONE,
HDMI_SCALING_HORZ,
HDMI_SCALING_VERT,
HDMI_SCALING_HORZ_VERT,
};
struct hdmi_avi_iframe_bar_info {
bool vert_binfo_present;
bool horz_binfo_present;
uint32_t end_of_top_bar;
uint32_t start_of_bottom_bar;
uint32_t end_of_left_bar;
uint32_t start_of_right_bar;
};
struct hdmi_avi_infoframe_config {
uint32_t pixel_format;
uint32_t scan_info;
bool act_fmt_info_present;
uint32_t colorimetry_info;
uint32_t ext_colorimetry_info;
uint32_t rgb_quantization_range;
uint32_t yuv_quantization_range;
uint32_t scaling_info;
bool is_it_content;
uint8_t content_type;
uint8_t pixel_rpt_factor;
struct hdmi_avi_iframe_bar_info bar_info;
};
struct mdss_hdmi_timing_info {
uint32_t video_format;
uint32_t active_h;
uint32_t front_porch_h;
uint32_t pulse_width_h;
uint32_t back_porch_h;
uint32_t active_low_h;
uint32_t active_v;
uint32_t front_porch_v;
uint32_t pulse_width_v;
uint32_t back_porch_v;
uint32_t active_low_v;
/* Must divide by 1000 to get the actual frequency in MHZ */
uint32_t pixel_freq;
/* Must divide by 1000 to get the actual frequency in HZ */
uint32_t refresh_rate;
uint32_t interlaced;
uint32_t supported;
enum aspect_ratio ar;
};
#define HDMI_VFRMT_640x480p60_4_3_TIMING \
{HDMI_VFRMT_640x480p60_4_3, 640, 16, 96, 48, true, \
480, 10, 2, 33, true, 25200, 60000, false, true, HDMI_RES_AR_4_3}
#define HDMI_VFRMT_1280x720p60_16_9_TIMING \
{HDMI_VFRMT_1280x720p60_16_9, 1280, 110, 40, 220, false, \
720, 5, 5, 20, false, 74250, 60000, false, true, HDMI_RES_AR_16_9}
#define HDMI_VFRMT_1920x1080p60_16_9_TIMING \
{HDMI_VFRMT_1920x1080p60_16_9, 1920, 88, 44, 148, false, \
1080, 4, 5, 36, false, 148500, 60000, false, true, HDMI_RES_AR_16_9}
#define HDMI_VFRMT_4096x2160p24_256_135_TIMING \
{HDMI_VFRMT_4096x2160p24_256_135, 4096, 1020, 88, 296, false, \
2160, 8, 10, 72, false, 297000, 24000, false, true, \
HDMI_RES_AR_256_135}
#define HDMI_VFRMT_4096x2160p25_256_135_TIMING \
{HDMI_VFRMT_4096x2160p25_256_135, 4096, 968, 88, 128, false, \
2160, 8, 10, 72, false, 297000, 25000, false, true, \
HDMI_RES_AR_256_135}
#define HDMI_VFRMT_4096x2160p30_256_135_TIMING \
{HDMI_VFRMT_4096x2160p30_256_135, 4096, 88, 88, 128, false, \
2160, 8, 10, 72, false, 297000, 30000, false, true, \
HDMI_RES_AR_256_135}
#define HDMI_EVFRMT_4096x2160p24_16_9_TIMING \
{HDMI_EVFRMT_4096x2160p24_16_9, 4096, 1020, 88, 296, false, \
2160, 8, 10, 72, false, 297000, 24000, false, true, \
HDMI_RES_AR_16_9}
#define HDMI_VFRMT_3840x2160p24_64_27_TIMING \
{HDMI_VFRMT_3840x2160p24_64_27, 3840, 1276, 88, 296, false, \
2160, 8, 10, 72, false, 297000, 24000, false, true, \
HDMI_RES_AR_64_27}
#define HDMI_VFRMT_3840x2160p25_64_27_TIMING \
{HDMI_VFRMT_3840x2160p25_64_27, 3840, 1056, 88, 296, false, \
2160, 8, 10, 72, false, 297000, 25000, false, true, \
HDMI_RES_AR_64_27}
#define HDMI_VFRMT_3840x2160p30_64_27_TIMING \
{HDMI_VFRMT_3840x2160p30_64_27, 3840, 176, 88, 296, false, \
2160, 8, 10, 72, false, 297000, 30000, false, true, \
HDMI_RES_AR_64_27}
#define HDMI_VFRMT_4096x2160p60_256_135_TIMING \
{HDMI_VFRMT_4096x2160p60_256_135, 4096, 88, 88, 128, false, \
2160, 8, 10, 72, false, 594000, 60000, false, true, \
HDMI_RES_AR_256_135}
#define MSM_HDMI_MODES_GET_DETAILS(mode, MODE) do { \
struct mdss_hdmi_timing_info info = MODE##_TIMING; \
*mode = info; \
} while (0)
static inline int mdss_hdmi_get_timing_info(
struct mdss_hdmi_timing_info *mode, int id)
{
int ret = 0;
switch (id) {
case HDMI_VFRMT_640x480p60_4_3:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_VFRMT_640x480p60_4_3);
break;
case HDMI_VFRMT_1280x720p60_16_9:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_VFRMT_1280x720p60_16_9);
break;
case HDMI_VFRMT_1920x1080p60_16_9:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_VFRMT_1920x1080p60_16_9);
break;
case HDMI_VFRMT_4096x2160p24_256_135:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_VFRMT_4096x2160p24_256_135);
break;
case HDMI_VFRMT_4096x2160p25_256_135:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_VFRMT_4096x2160p25_256_135);
break;
case HDMI_VFRMT_4096x2160p30_256_135:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_VFRMT_4096x2160p30_256_135);
break;
case HDMI_EVFRMT_4096x2160p24_16_9:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_EVFRMT_4096x2160p24_16_9);
break;
case HDMI_VFRMT_3840x2160p24_64_27:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_VFRMT_3840x2160p24_64_27);
break;
case HDMI_VFRMT_3840x2160p25_64_27:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_VFRMT_3840x2160p25_64_27);
break;
case HDMI_VFRMT_3840x2160p30_64_27:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_VFRMT_3840x2160p30_64_27);
break;
case HDMI_VFRMT_4096x2160p60_256_135:
MSM_HDMI_MODES_GET_DETAILS(mode, HDMI_VFRMT_4096x2160p60_256_135);
break;
default:
ret = ERROR;
}
return ret;
}
static void mdss_hdmi_audio_acr_setup(uint32_t sample_rate)
{
/* Read first before writing */
uint32_t acr_pck_ctrl_reg = readl(HDMI_ACR_PKT_CTRL);
struct mdss_hdmi_timing_info tinfo = {0};
uint32_t ret = mdss_hdmi_get_timing_info(&tinfo, mdss_hdmi_video_fmt);
struct hdmi_msm_audio_arcs *audio_acr = &hdmi_audio_acr_lut[0];
uint32_t lut_size = sizeof(hdmi_audio_acr_lut)
/ sizeof(*hdmi_audio_acr_lut);
uint32_t i, n, cts, layout, multiplier, aud_pck_ctrl_2_reg;
uint32_t channel_num = MSM_HDMI_AUDIO_CHANNEL_2;
if (ret || !tinfo.supported) {
dprintf(CRITICAL, "%s: video format %d not supported\n",
__func__, mdss_hdmi_video_fmt);
return;
}
for (i = 0; i < lut_size; audio_acr = &hdmi_audio_acr_lut[++i]) {
if (audio_acr->pclk == tinfo.pixel_freq)
break;
}
if (i >= lut_size) {
dprintf(CRITICAL, "%s: pixel clk %d not supported\n", __func__,
tinfo.pixel_freq);
return;
}
n = audio_acr->lut[sample_rate].n;
cts = audio_acr->lut[sample_rate].cts;
layout = (MSM_HDMI_AUDIO_CHANNEL_2 == channel_num) ? 0 : 1;
if ((AUDIO_SAMPLE_RATE_192KHZ == sample_rate) ||
(AUDIO_SAMPLE_RATE_176_4KHZ == sample_rate)) {
multiplier = 4;
n >>= 2; /* divide N by 4 and use multiplier */
} else if ((AUDIO_SAMPLE_RATE_96KHZ == sample_rate) ||
(AUDIO_SAMPLE_RATE_88_2KHZ == sample_rate)) {
multiplier = 2;
n >>= 1; /* divide N by 2 and use multiplier */
} else {
multiplier = 1;
}
dprintf(SPEW, "%s: n=%u, cts=%u, layout=%u\n", __func__, n, cts,
layout);
/* AUDIO_PRIORITY | SOURCE */
acr_pck_ctrl_reg |= 0x80000100;
/* Reset multiplier bits */
acr_pck_ctrl_reg &= ~(7 << 16);
/* N_MULTIPLE(multiplier) */
acr_pck_ctrl_reg |= (multiplier & 7) << 16;
if ((AUDIO_SAMPLE_RATE_48KHZ == sample_rate) ||
(AUDIO_SAMPLE_RATE_96KHZ == sample_rate) ||
(AUDIO_SAMPLE_RATE_192KHZ == sample_rate)) {
/* SELECT(3) */
acr_pck_ctrl_reg |= 3 << 4;
/* CTS_48 */
cts <<= 12;
/* CTS: need to determine how many fractional bits */
writel(cts, HDMI_ACR_48_0);
/* N */
writel(n, HDMI_ACR_48_1);
} else if ((AUDIO_SAMPLE_RATE_44_1KHZ == sample_rate) ||
(AUDIO_SAMPLE_RATE_88_2KHZ == sample_rate) ||
(AUDIO_SAMPLE_RATE_176_4KHZ == sample_rate)) {
/* SELECT(2) */
acr_pck_ctrl_reg |= 2 << 4;
/* CTS_44 */
cts <<= 12;
/* CTS: need to determine how many fractional bits */
writel(cts, HDMI_ACR_44_0);
/* N */
writel(n, HDMI_ACR_44_1);
} else { /* default to 32k */
/* SELECT(1) */
acr_pck_ctrl_reg |= 1 << 4;
/* CTS_32 */
cts <<= 12;
/* CTS: need to determine how many fractional bits */
writel(cts, HDMI_ACR_32_0);
/* N */
writel(n, HDMI_ACR_32_1);
}
/* Payload layout depends on number of audio channels */
/* LAYOUT_SEL(layout) */
aud_pck_ctrl_2_reg = 1 | (layout << 1);
/* override | layout */
writel(aud_pck_ctrl_2_reg, HDMI_AUDIO_PKT_CTRL2);
/* SEND | CONT */
acr_pck_ctrl_reg |= 0x00000003;
writel(acr_pck_ctrl_reg, HDMI_ACR_PKT_CTRL);
}
static void mdss_hdmi_audio_info_setup(void)
{
uint32_t channel_count = MSM_HDMI_AUDIO_CHANNEL_2;
uint32_t channel_allocation = 0;
uint32_t level_shift = 0;
uint32_t down_mix = 0;
uint32_t check_sum, audio_info_0_reg, audio_info_1_reg;
uint32_t audio_info_ctrl_reg;
uint32_t aud_pck_ctrl_2_reg;
uint32_t layout;
layout = (MSM_HDMI_AUDIO_CHANNEL_2 == channel_count) ? 0 : 1;;
aud_pck_ctrl_2_reg = 1 | (layout << 1);
writel(aud_pck_ctrl_2_reg, HDMI_AUDIO_PKT_CTRL2);
/* Read first then write because it is bundled with other controls */
audio_info_ctrl_reg = readl(HDMI_INFOFRAME_CTRL0);
channel_allocation = 0; /* Default to FR,FL */
/* Program the Channel-Speaker allocation */
audio_info_1_reg = 0;
/* CA(channel_allocation) */
audio_info_1_reg |= channel_allocation & 0xff;
/* Program the Level shifter */
/* LSV(level_shift) */
audio_info_1_reg |= (level_shift << 11) & 0x00007800;
/* Program the Down-mix Inhibit Flag */
/* DM_INH(down_mix) */
audio_info_1_reg |= (down_mix << 15) & 0x00008000;
writel(audio_info_1_reg, HDMI_AUDIO_INFO1);
check_sum = 0;
/* HDMI_AUDIO_INFO_FRAME_PACKET_HEADER_TYPE[0x84] */
check_sum += 0x84;
/* HDMI_AUDIO_INFO_FRAME_PACKET_HEADER_VERSION[0x01] */
check_sum += 1;
/* HDMI_AUDIO_INFO_FRAME_PACKET_LENGTH[0x0A] */
check_sum += 0x0A;
check_sum += channel_count;
check_sum += channel_allocation;
/* See Table 8.5 in HDMI spec */
check_sum += (level_shift & 0xF) << 3 | (down_mix & 0x1) << 7;
check_sum &= 0xFF;
check_sum = (256 - check_sum);
audio_info_0_reg = 0;
/* CHECKSUM(check_sum) */
audio_info_0_reg |= check_sum & 0xff;
/* CC(channel_count) */
audio_info_0_reg |= (channel_count << 8) & 0x00000700;
writel(audio_info_0_reg, HDMI_AUDIO_INFO0);
/* Set these flags */
/* AUDIO_INFO_UPDATE | AUDIO_INFO_SOURCE | AUDIO_INFO_CONT
| AUDIO_INFO_SEND */
audio_info_ctrl_reg |= 0xF0;
/* HDMI_INFOFRAME_CTRL0[0x002C] */
writel(audio_info_ctrl_reg, HDMI_INFOFRAME_CTRL0);
}
static uint8_t* hdmi_edid_find_block(uint32_t start_offset,
uint8_t type, uint8_t *len)
{
/* the start of data block collection, start of Video Data Block */
uint8_t *in_buf = mdss_hdmi_edid_buf;
uint32_t offset = start_offset;
uint32_t end_dbc_offset = in_buf[2];
*len = 0;
/*
* edid buffer 1, byte 2 being 4 means no non-DTD/Data block collection
* present.
* edid buffer 1, byte 2 being 0 means no non-DTD/DATA block collection
* present and no DTD data present.
*/
if ((end_dbc_offset == 0) || (end_dbc_offset == 4) ||
(end_dbc_offset >= MAX_EDID_BLOCK_SIZE))
return NULL;
while (offset < end_dbc_offset) {
uint8_t block_len = in_buf[offset] & 0x1F;
if ((in_buf[offset] >> 5) == type) {
*len = block_len;
dprintf(SPEW,
"EDID: block=%d found @ %d with length=%d\n",
type, offset, block_len);
return in_buf + offset;
}
offset += 1 + block_len;
}
return NULL;
}
static bool mdss_hdmi_is_audio_freq_supported(uint32_t freq)
{
uint8_t *in_buf = mdss_hdmi_edid_buf;
const uint8_t *adb = NULL;
uint32_t adb_size = 0;
uint8_t len = 0, count = 0;
uint32_t next_offset = DBC_START_OFFSET;
uint8_t audio_data_block[MAX_AUDIO_DATA_BLOCK_SIZE];
do {
adb = hdmi_edid_find_block(next_offset,
AUDIO_DATA_BLOCK, &len);
if ((adb_size + len) > MAX_AUDIO_DATA_BLOCK_SIZE) {
dprintf(INFO, "%s: invalid adb length\n", __func__);
break;
}
if (!adb)
break;
memcpy((audio_data_block + adb_size), adb + 1, len);
next_offset = (adb - in_buf) + 1 + len;
adb_size += len;
} while (adb);
count = adb_size/3;
adb = audio_data_block;
while (count--) {
uint8_t freq_lst = *(adb + 1) & 0xFF;
if (freq_lst & BIT(freq))
return true;
adb += 3;
}
return false;
}
static void mdss_hdmi_audio_playback(void)
{
char *base_addr;
uint32_t sample_rate;
base_addr = (char *) memalign(4096, 0x1000);
if (base_addr == NULL) {
dprintf(CRITICAL, "%s: Error audio buffer alloc\n", __func__);
return;
}
memset(base_addr, 0, 0x1000);
writel(0x00000010, HDMI_AUDIO_PKT_CTRL);
writel(0x00000080, HDMI_AUDIO_CFG);
writel(0x0000096E, LPASS_LPAIF_RDDMA_CTL0);
writel(0x00000A6E, LPASS_LPAIF_RDDMA_CTL0);
writel(0x00002000, HDMI_VBI_PKT_CTRL);
writel(0x00000000, HDMI_GEN_PKT_CTRL);
writel(0x0000096E, LPASS_LPAIF_RDDMA_CTL0);
writel((uint32_t) base_addr, LPASS_LPAIF_RDDMA_BASE0);
writel(0x000005FF, LPASS_LPAIF_RDDMA_BUFF_LEN0);
writel(0x000005FF, LPASS_LPAIF_RDDMA_PER_LEN0);
writel(0x0000096F, LPASS_LPAIF_RDDMA_CTL0);
writel(0x00000010, LPASS_LPAIF_DEBUG_CTL);
writel(0x00000000, HDMI_GC);
writel(0x00002030, HDMI_VBI_PKT_CTRL);
writel(0x00002030, HDMI_VBI_PKT_CTRL);
writel(0x00002030, HDMI_VBI_PKT_CTRL);
if (mdss_hdmi_is_audio_freq_supported(AUDIO_SAMPLE_RATE_48KHZ))
sample_rate = AUDIO_SAMPLE_RATE_48KHZ;
else
sample_rate = AUDIO_SAMPLE_RATE_32KHZ;
mdss_hdmi_audio_acr_setup(sample_rate);
mdss_hdmi_audio_info_setup();
writel(0x00000010, HDMI_AUDIO_PKT_CTRL);
writel(0x00000080, HDMI_AUDIO_CFG);
writel(0x00000011, HDMI_AUDIO_PKT_CTRL);
writel(0x00000081, HDMI_AUDIO_CFG);
dprintf(SPEW, "audio sample rate %s\n",
sample_rate == AUDIO_SAMPLE_RATE_48KHZ ? "48KHz" : "32KHz");
}
static uint32_t mdss_hdmi_panel_clock(uint8_t enable, struct msm_panel_info *pinfo)
{
int ret = NO_ERROR;
if (hdmi_panel_clock_enabled)
return ret;
ret = target_hdmi_panel_clock(enable, pinfo);
hdmi_panel_clock_enabled = enable;
return ret;
}
static uint32_t mdss_hdmi_pll_clock(uint8_t enable, struct msm_panel_info *pinfo)
{
int ret = NO_ERROR;
if (hdmi_pll_clock_enabled)
return ret;
ret = target_hdmi_pll_clock(enable, pinfo);
hdmi_pll_clock_enabled = enable;
return ret;
}
static int mdss_hdmi_enable_power(uint8_t enable, struct msm_panel_info *pinfo)
{
int ret = NO_ERROR;
if (hdmi_power_enabled)
return ret;
ret = target_hdmi_regulator_ctrl(enable);
if (ret) {
dprintf(CRITICAL, "hdmi regulator control enable failed\n");
goto bail_regulator_fail;
}
ret = target_hdmi_gpio_ctrl(enable);
if (ret) {
dprintf(CRITICAL, "hdmi gpio control enable failed\n");
goto bail_gpio_fail;
}
hdmi_power_enabled = enable;
dprintf(SPEW, "HDMI Panel power %s done\n", enable ? "on" : "off");
return ret;
bail_gpio_fail:
target_hdmi_regulator_ctrl(0);
bail_regulator_fail:
return ret;
}
static bool mdss_hdmi_is_dvi_mode(void)
{
uint8_t len;
uint32_t ieee_tag;
const uint8_t *vsd = NULL;
vsd = hdmi_edid_find_block(DBC_START_OFFSET,
VENDOR_SPECIFIC_DATA_BLOCK, &len);
if (vsd == NULL || len == 0) {
dprintf(SPEW, "%s: Invalid VSDB\n", __func__);
return false;
}
ieee_tag = ((uint32_t) vsd[3] << 16) + ((uint32_t) vsd[2] << 8) +
(uint32_t) vsd[1];
if (ieee_tag == 0x0c03)
return false;
else
return true;
}
static void mdss_hdmi_set_mode(bool on)
{
uint32_t val = 0;
if (on) {
/* tx on */
val |= BIT(0);
/* hdcp legacy mode*/
val |= BIT(31);
if (!mdss_hdmi_is_dvi_mode())
val |= BIT(1);
}
writel(val, HDMI_CTRL);
}
static int mdss_hdmi_read_edid(void)
{
uint8_t ndx;
uint32_t reg_val;
uint32_t dev_addr = 0xA0;
uint32_t len = 0x80;
uint32_t offset = 0x80;
uint32_t time_out;
uint32_t retry = 5;
dev_addr &= 0xFE;
again:
time_out = 10;
writel(readl(HDMI_DDC_ARBITRATION) & ~BIT(4), HDMI_DDC_ARBITRATION);
/* Enable DDC Interrupts */
writel(BIT(1) | BIT(2), HDMI_DDC_INT_CTRL);
/* config DDC to read CEA block */
writel((10 << 16) | (2 << 0), HDMI_DDC_SPEED);
writel(0xFF000000, HDMI_DDC_SETUP);
writel((1 << 16) | (19 << 0), HDMI_DDC_REF);
writel(BIT(31) | (dev_addr << 8), HDMI_DDC_DATA);
writel(offset << 8, HDMI_DDC_DATA);
writel((dev_addr | BIT(0)) << 8, HDMI_DDC_DATA);
writel(BIT(12) | BIT(16), HDMI_DDC_TRANS0);
writel(BIT(0) | BIT(12) | BIT(13) | (len << 16), HDMI_DDC_TRANS1);
writel(BIT(0) | BIT(20), HDMI_DDC_CTRL);
/* poll for 100ms for read to complete */
reg_val = readl(HDMI_DDC_INT_CTRL);
while (!(reg_val & BIT(0)) && time_out) {
reg_val = readl(HDMI_DDC_INT_CTRL);
time_out--;
mdelay(10);
}
if (!time_out) {
dprintf(CRITICAL, "%s: Timeout reading EDID\n", __func__);
if (retry--)
goto again;
else
return ERROR;
}
/* clear interrupts */
writel(BIT(1), HDMI_DDC_INT_CTRL);
reg_val = readl(HDMI_DDC_SW_STATUS);
reg_val &= BIT(12) | BIT(13) | BIT(14) | BIT(15);
/* Check if any NACK occurred */
if (reg_val) {
/* SW_STATUS_RESET */
writel(BIT(3), HDMI_DDC_CTRL);
/* SOFT_RESET */
writel(BIT(1), HDMI_DDC_CTRL);
dprintf(CRITICAL, "%s: NACK reading EDID\n", __func__);
if (retry--)
goto again;
else
return ERROR;
}
/* Write this data to DDC buffer */
writel(BIT(0) | (3 << 16) | BIT(31), HDMI_DDC_DATA);
/* Discard first byte */
readl(HDMI_DDC_DATA);
for (ndx = 0; ndx < 0x80; ndx++) {
reg_val = readl(HDMI_DDC_DATA);
mdss_hdmi_edid_buf[ndx] = (uint8_t)((reg_val & 0x0000FF00) >> 8);
}
dprintf(INFO, "%s: EDID read successful\n", __func__);
return NO_ERROR;
}
static void mdss_hdmi_add_video_format(uint32_t video_format)
{
if (mdss_hdmi_mode_count >= HDMI_VFRMT_COUNT) {
dprintf(SPEW, "%s: unsupported format (%d)", __func__,
video_format);
return;
}
dprintf(SPEW, "%s: vic=%d\n", __func__, video_format);
mdss_hdmi_video_formats[mdss_hdmi_mode_count] = video_format;
mdss_hdmi_mode_count++;
}
static void mdss_hdmi_get_extended_video_formats()
{
uint8_t db_len, offset, i;
uint8_t hdmi_vic_len;
uint32_t video_format;
const uint8_t *vsd = NULL;
vsd = hdmi_edid_find_block(DBC_START_OFFSET,
VENDOR_SPECIFIC_DATA_BLOCK, &db_len);
if (!vsd || db_len == 0) {
dprintf(SPEW, "%s: No/Invalid Vendor Specific Data Block\n",
__func__);
return;
}
/* check if HDMI_Video_present flag is set or not */
if (!(vsd[8] & BIT(5))) {
dprintf(SPEW, "%s: extended vfmts not supported by the sink.\n",
__func__);
return;
}
offset = HDMI_VSDB_3D_EVF_DATA_OFFSET(vsd);
hdmi_vic_len = vsd[offset + 1] >> 5;
if (hdmi_vic_len) {
for (i = 0; i < hdmi_vic_len; i++) {
struct mdss_hdmi_timing_info tinfo = {0};
uint32_t ret = 0;
video_format = HDMI_VFRMT_END + vsd[offset + 2 + i];
ret = mdss_hdmi_get_timing_info(&tinfo, video_format);
if (ret || !tinfo.supported)
continue;
mdss_hdmi_add_video_format(video_format);
}
}
}
static void mdss_hdmi_get_cea_video_formats()
{
uint8_t len, i;
uint32_t video_format;
uint8_t *svd = hdmi_edid_find_block(DBC_START_OFFSET,
VIDEO_DATA_BLOCK, &len);
if (!svd || len == 0) {
dprintf(SPEW, "%s: No/Invalid Video Data Block\n",
__func__);
return;
}
++svd;
for (i = 0; i < len; ++i, ++svd) {
struct mdss_hdmi_timing_info tinfo = {0};
uint32_t ret = 0;
video_format = (*svd & 0x7F);
if (i == 0)
mdss_hdmi_pref_fmt = video_format;
ret = mdss_hdmi_get_timing_info(&tinfo, video_format);
if (ret || !tinfo.supported)
continue;
mdss_hdmi_add_video_format(video_format);
}
}
static void mdss_hdmi_parse_res(void)
{
int index, ret;
uint8_t current_video_format;
struct mdss_hdmi_timing_info current_timing_info = {0};
mdss_hdmi_mode_count = 0;
mdss_hdmi_video_fmt = DEFAULT_RESOLUTION;
current_video_format = mdss_hdmi_video_fmt;
mdss_hdmi_get_timing_info(&current_timing_info, mdss_hdmi_video_fmt);
mdss_hdmi_get_extended_video_formats();
mdss_hdmi_get_cea_video_formats();
for (index = 0; index < mdss_hdmi_mode_count; index++) {
struct mdss_hdmi_timing_info new_timing_info = {0};
if (!mdss_hdmi_video_formats[index])
break;
ret = mdss_hdmi_get_timing_info(&new_timing_info, mdss_hdmi_video_formats[index]);
if (ret || !new_timing_info.supported)
continue;
if (new_timing_info.active_h > current_timing_info.active_h) {
current_video_format = mdss_hdmi_video_formats[index];
} else if (new_timing_info.active_h ==
current_timing_info.active_h) {
if (new_timing_info.active_v >
current_timing_info.active_v) {
current_video_format = mdss_hdmi_video_formats[index];
} else if (new_timing_info.active_v ==
current_timing_info.active_v) {
if (new_timing_info.refresh_rate >
current_timing_info.refresh_rate) {
current_video_format = mdss_hdmi_video_formats[index];
}
}
}
mdss_hdmi_get_timing_info(&current_timing_info, current_video_format);
}
if (mdss_hdmi_video_fmt != current_video_format)
mdss_hdmi_video_fmt = current_video_format;
}
void mdss_hdmi_get_vic(char *buf)
{
struct mdss_hdmi_timing_info tinfo = {0};
uint32_t ret = mdss_hdmi_get_timing_info(&tinfo, mdss_hdmi_video_fmt);
if (ret)
snprintf(buf, HDMI_VIC_STR_MAX, "%d", HDMI_VFRMT_UNKNOWN);
else
snprintf(buf, HDMI_VIC_STR_MAX, "%d", tinfo.video_format);
}
static void mdss_hdmi_panel_init(struct msm_panel_info *pinfo)
{
struct mdss_hdmi_timing_info tinfo = {0};
uint32_t ret = mdss_hdmi_get_timing_info(&tinfo, mdss_hdmi_video_fmt);
if (!pinfo || ret)
return;
pinfo->xres = tinfo.active_h;
pinfo->yres = tinfo.active_v;
pinfo->bpp = 24;
pinfo->type = HDMI_PANEL;
pinfo->clk_rate = tinfo.pixel_freq * 1000;
pinfo->lcdc.h_back_porch = tinfo.back_porch_h;
pinfo->lcdc.h_front_porch = tinfo.front_porch_h;
pinfo->lcdc.h_pulse_width = tinfo.pulse_width_h;
pinfo->lcdc.v_back_porch = tinfo.back_porch_v;
pinfo->lcdc.v_front_porch = tinfo.front_porch_v;
pinfo->lcdc.v_pulse_width = tinfo.pulse_width_v;
pinfo->lcdc.hsync_skew = 0;
pinfo->lcdc.xres_pad = 0;
pinfo->lcdc.yres_pad = 0;
/* Add dual pipe configuration for resultions greater than
* MSM_MDP_MAX_PIPE_WIDTH.
*/
if (pinfo->xres > MSM_MDP_MAX_PIPE_WIDTH) {
pinfo->lcdc.dual_pipe = 1;
pinfo->lm_split[0] = pinfo->xres / 2;
pinfo->lm_split[1] = pinfo->xres - pinfo->lm_split[0];
}
}
static uint8_t mdss_hdmi_cable_status(void)
{
uint32_t reg_val;
uint8_t cable_status;
mdss_hdmi_set_mode(true);
/* Enable USEC REF timer */
writel(0x0001001B, HDMI_USEC_REFTIMER);
/* set timeout to 4.1ms (max) for hardware debounce */
reg_val = readl(HDMI_HPD_CTRL) | 0x1FFF;
/* enable HPD circuit */
writel(reg_val | BIT(28), HDMI_HPD_CTRL);
writel(BIT(2) | BIT(1), HDMI_HPD_INT_CTRL);
/* Toggle HPD circuit to trigger HPD sense */
reg_val = readl(HDMI_HPD_CTRL) | 0x1FFF;
writel(reg_val & ~BIT(28), HDMI_HPD_CTRL);
writel(reg_val & BIT(28), HDMI_HPD_CTRL);
mdelay(20);
cable_status = (readl(HDMI_HPD_INT_STATUS) & BIT(1)) >> 1;
dprintf(INFO, "hdmi cable %s\n",
cable_status ? "connected" : "not connected");
writel(BIT(0), HDMI_HPD_INT_CTRL);
writel(reg_val & ~BIT(28), HDMI_HPD_CTRL);
mdss_hdmi_set_mode(false);
return cable_status;
}
static int mdss_hdmi_update_panel_info(void)
{
mdss_hdmi_set_mode(true);
if (!mdss_hdmi_read_edid())
mdss_hdmi_parse_res();
else
mdss_hdmi_video_fmt = DEFAULT_RESOLUTION;
mdss_hdmi_set_mode(false);
mdss_hdmi_panel_init(&(panel.panel_info));
panel.fb.width = panel.panel_info.xres;
panel.fb.height = panel.panel_info.yres;
panel.fb.stride = panel.panel_info.xres;
panel.fb.bpp = panel.panel_info.bpp;
panel.fb.format = FB_FORMAT_RGB888;
return NO_ERROR;
}
void mdss_hdmi_display_init(uint32_t rev, void *base)
{
panel.power_func = mdss_hdmi_enable_power;
panel.clk_func = mdss_hdmi_panel_clock;
panel.update_panel_info = mdss_hdmi_update_panel_info;
panel.pll_clk_func = mdss_hdmi_pll_clock;
panel.fb.base = base;
panel.mdp_rev = rev;
msm_display_init(&panel);
}
static int mdss_hdmi_video_setup(void)
{
uint32_t total_v = 0;
uint32_t total_h = 0;
uint32_t start_h = 0;
uint32_t end_h = 0;
uint32_t start_v = 0;
uint32_t end_v = 0;
struct mdss_hdmi_timing_info tinfo = {0};
uint32_t ret = mdss_hdmi_get_timing_info(&tinfo, mdss_hdmi_video_fmt);
if (ret)
return ERROR;
dprintf(INFO, "hdmi resolution %dx%d@p%dHz (%d)\n",
tinfo.active_h, tinfo.active_v, tinfo.refresh_rate/1000,
mdss_hdmi_video_fmt);
total_h = tinfo.active_h + tinfo.front_porch_h +
tinfo.back_porch_h + tinfo.pulse_width_h - 1;
total_v = tinfo.active_v + tinfo.front_porch_v +
tinfo.back_porch_v + tinfo.pulse_width_v - 1;
if (((total_v << 16) & 0xE0000000) || (total_h & 0xFFFFE000)) {
dprintf(CRITICAL,
"%s: total v=%d or h=%d is larger than supported\n",
__func__, total_v, total_h);
return ERROR;
}
writel((total_v << 16) | (total_h << 0), HDMI_TOTAL);
start_h = tinfo.back_porch_h + tinfo.pulse_width_h;
end_h = (total_h + 1) - tinfo.front_porch_h;
if (((end_h << 16) & 0xE0000000) || (start_h & 0xFFFFE000)) {
dprintf(CRITICAL,
"%s: end_h=%d or start_h=%d is larger than supported\n",
__func__, end_h, start_h);
return ERROR;
}
writel((end_h << 16) | (start_h << 0), HDMI_ACTIVE_H);
start_v = tinfo.back_porch_v + tinfo.pulse_width_v - 1;
end_v = total_v - tinfo.front_porch_v;
if (((end_v << 16) & 0xE0000000) || (start_v & 0xFFFFE000)) {
dprintf(CRITICAL,
"%s: end_v=%d or start_v=%d is larger than supported\n",
__func__, end_v, start_v);
return ERROR;
}
writel((end_v << 16) | (start_v << 0), HDMI_ACTIVE_V);
if (tinfo.interlaced) {
writel((total_v + 1) << 0, HDMI_V_TOTAL_F2);
writel(((end_v + 1) << 16) | ((start_v + 1) << 0),
HDMI_ACTIVE_V_F2);
} else {
writel(0, HDMI_V_TOTAL_F2);
writel(0, HDMI_ACTIVE_V_F2);
}
writel(((tinfo.interlaced << 31) & 0x80000000) |
((tinfo.active_low_h << 29) & 0x20000000) |
((tinfo.active_low_v << 28) & 0x10000000), HDMI_FRAME_CTRL);
return 0;
}
static void mdss_hdmi_extract_extended_data_blocks(void)
{
uint8_t len = 0;
uint32_t start_offset = DBC_START_OFFSET;
uint8_t const *etag = NULL;
uint8_t *in_buf = mdss_hdmi_edid_buf;
do {
/* A Tage code of 7 identifies extended data blocks */
etag = hdmi_edid_find_block(start_offset,
USE_EXTENDED_TAG, &len);
start_offset = etag - in_buf + len + 1;
/* The extended data block should at least be 2 bytes long */
if (len < 2) {
dprintf(SPEW, "%s: data block of len < 2 bytes\n",
__func__);
continue;
}
/*
* The second byte of the extended data block has the
* extended tag code
*/
switch (etag[1]) {
case 0:
/*
* Check if the sink specifies underscan
* support for:
* BIT 5: preferred video format
* BIT 3: IT video format
* BIT 1: CE video format
*/
pt_scan_info = (etag[2] & (BIT(4) | BIT(5))) >> 4;
it_scan_info = (etag[2] & (BIT(3) | BIT(2))) >> 2;
ce_scan_info = etag[2] & (BIT(1) | BIT(0));
dprintf(INFO, "scan Info (pt|it|ce): (%d|%d|%d)\n",
pt_scan_info, it_scan_info, ce_scan_info);
break;
default:
dprintf(SPEW, "%s: Tag Code %d not supported\n",
__func__, etag[1]);
break;
}
} while (etag != NULL);
}
/*
* If the sink specified support for both underscan/overscan then, by default,
* set the underscan bit. Only checking underscan support for preferred
* format and cea formats.
*/
uint8_t mdss_hdmi_get_scan_info(void)
{
uint8_t scaninfo = 0;
bool use_ce_scan_info = true;
mdss_hdmi_extract_extended_data_blocks();
if (mdss_hdmi_video_fmt == mdss_hdmi_pref_fmt) {
use_ce_scan_info = false;
switch (pt_scan_info) {
case 0:
use_ce_scan_info = true;
break;
case 3:
scaninfo = BIT(1);
break;
default:
break;
}
}
if (use_ce_scan_info) {
if (3 == ce_scan_info)
scaninfo |= BIT(1);
}
return scaninfo;
}
void mdss_hdmi_avi_info_frame(void)
{
uint32_t sum;
uint32_t reg_val;
uint8_t checksum;
uint32_t i;
struct hdmi_avi_infoframe_config avi_info = {0};
struct mdss_hdmi_timing_info tinfo = {0};
uint8_t avi_iframe[AVI_MAX_DATA_BYTES] = {0};
mdss_hdmi_get_timing_info(&tinfo, mdss_hdmi_video_fmt);
/* Setup AVI Infoframe content */
avi_info.scan_info = mdss_hdmi_get_scan_info();
avi_info.bar_info.end_of_top_bar = 0x0;
avi_info.bar_info.start_of_bottom_bar = tinfo.active_v + 1;
avi_info.bar_info.end_of_left_bar = 0;
avi_info.bar_info.start_of_right_bar = tinfo.active_h + 1;
avi_info.act_fmt_info_present = true;
avi_info.rgb_quantization_range = HDMI_QUANTIZATION_DEFAULT;
avi_info.yuv_quantization_range = HDMI_QUANTIZATION_DEFAULT;
avi_info.scaling_info = HDMI_SCALING_NONE;
avi_info.colorimetry_info = 0;
avi_info.ext_colorimetry_info = 0;
avi_info.pixel_rpt_factor = 0;
/*
* BYTE - 1:
* 0:1 - Scan Information
* 2:3 - Bar Info
* 4 - Active Format Info present
* 5:6 - Pixel format type;
* 7 - Reserved;
*/
avi_iframe[0] = (avi_info.scan_info & 0x3) |
(avi_info.bar_info.vert_binfo_present ? BIT(2) : 0) |
(avi_info.bar_info.horz_binfo_present ? BIT(3) : 0) |
(avi_info.act_fmt_info_present ? BIT(4) : 0);
/*
* BYTE - 2:
* 0:3 - Active format info
* 4:5 - Picture aspect ratio
* 6:7 - Colorimetry info
*/
avi_iframe[1] |= 0x08;
if (tinfo.ar == HDMI_RES_AR_4_3)
avi_iframe[1] |= (0x1 << 4);
else if (tinfo.ar == HDMI_RES_AR_16_9)
avi_iframe[1] |= (0x2 << 4);
avi_iframe[1] |= (avi_info.colorimetry_info & 0x3) << 6;
/*
* BYTE - 3:
* 0:1 - Scaling info
* 2:3 - Quantization range
* 4:6 - Extended Colorimetry
* 7 - IT content
*/
avi_iframe[2] |= (avi_info.scaling_info & 0x3) |
((avi_info.rgb_quantization_range & 0x3) << 2) |
((avi_info.ext_colorimetry_info & 0x7) << 4) |
((avi_info.is_it_content ? 0x1 : 0x0) << 7);
/*
* BYTE - 4:
* 0:7 - VIC
*/
if (tinfo.video_format < HDMI_VFRMT_END)
avi_iframe[3] = tinfo.video_format;
/*
* BYTE - 5:
* 0:3 - Pixel Repeat factor
* 4:5 - Content type
* 6:7 - YCC Quantization range
*/
avi_iframe[4] = (avi_info.pixel_rpt_factor & 0xF) |
((avi_info.content_type & 0x3) << 4) |
((avi_info.yuv_quantization_range & 0x3) << 6);
/* BYTE - 6,7: End of top bar */
avi_iframe[5] = avi_info.bar_info.end_of_top_bar & 0xFF;
avi_iframe[6] = ((avi_info.bar_info.end_of_top_bar & 0xFF00) >> 8);
/* BYTE - 8,9: Start of bottom bar */
avi_iframe[7] = avi_info.bar_info.start_of_bottom_bar & 0xFF;
avi_iframe[8] = ((avi_info.bar_info.start_of_bottom_bar & 0xFF00) >> 8);
/* BYTE - 10,11: Endof of left bar */
avi_iframe[9] = avi_info.bar_info.end_of_left_bar & 0xFF;
avi_iframe[10] = ((avi_info.bar_info.end_of_left_bar & 0xFF00) >> 8);
/* BYTE - 12,13: Start of right bar */
avi_iframe[11] = avi_info.bar_info.start_of_right_bar & 0xFF;
avi_iframe[12] = ((avi_info.bar_info.start_of_right_bar & 0xFF00) >> 8);
sum = IFRAME_PACKET_OFFSET + AVI_IFRAME_TYPE +
AVI_IFRAME_VERSION + AVI_MAX_DATA_BYTES;
for (i = 0; i < AVI_MAX_DATA_BYTES; i++)
sum += avi_iframe[i];
sum &= 0xFF;
sum = 256 - sum;
checksum = (uint8_t) sum;
reg_val = checksum |
LEFT_SHIFT_BYTE(avi_iframe[DATA_BYTE_1]) |
LEFT_SHIFT_WORD(avi_iframe[DATA_BYTE_2]) |
LEFT_SHIFT_24BITS(avi_iframe[DATA_BYTE_3]);
writel(reg_val, HDMI_AVI_INFO0);
reg_val = avi_iframe[DATA_BYTE_4] |
LEFT_SHIFT_BYTE(avi_iframe[DATA_BYTE_5]) |
LEFT_SHIFT_WORD(avi_iframe[DATA_BYTE_6]) |
LEFT_SHIFT_24BITS(avi_iframe[DATA_BYTE_7]);
writel(reg_val, HDMI_AVI_INFO1);
reg_val = avi_iframe[DATA_BYTE_8] |
LEFT_SHIFT_BYTE(avi_iframe[DATA_BYTE_9]) |
LEFT_SHIFT_WORD(avi_iframe[DATA_BYTE_10]) |
LEFT_SHIFT_24BITS(avi_iframe[DATA_BYTE_11]);
writel(reg_val, HDMI_AVI_INFO2);
reg_val = avi_iframe[DATA_BYTE_12] |
LEFT_SHIFT_BYTE(avi_iframe[DATA_BYTE_13]) |
LEFT_SHIFT_24BITS(AVI_IFRAME_VERSION);
writel(reg_val, HDMI_AVI_INFO3);
/* AVI InfFrame enable (every frame) */
writel(readl(HDMI_INFOFRAME_CTRL0) | BIT(1) | BIT(0),
HDMI_INFOFRAME_CTRL0);
reg_val = readl(HDMI_INFOFRAME_CTRL1);
reg_val &= ~0x3F;
reg_val |= AVI_IFRAME_LINE_NUMBER;
writel(reg_val, HDMI_INFOFRAME_CTRL1);
}
static int mdss_hdmi_ddc_check_status(char *what)
{
uint32_t reg_val;
int rc = 0;
/* Read DDC status */
reg_val = readl(HDMI_DDC_SW_STATUS);
reg_val &= BIT(12) | BIT(13) | BIT(14) | BIT(15);
/* Check if any NACK occurred */
if (reg_val) {
dprintf(SPEW, "%s: %s: NACK: HDMI_DDC_SW_STATUS 0x%x\n",
__func__, what, reg_val);
/* SW_STATUS_RESET, SOFT_RESET */
reg_val = BIT(3) | BIT(1);
writel(reg_val, HDMI_DDC_CTRL);
rc = ERROR;
}
return rc;
}
static void mdss_hdmi_ddc_trigger(struct hdmi_tx_ddc_data *ddc_data,
enum trigger_mode mode, bool seg)
{
uint32_t const seg_addr = 0x60, seg_num = 0x01;
uint32_t ddc_ctrl_reg_val;
ddc_data->dev_addr &= 0xFE;
if (mode == TRIGGER_READ && seg) {
writel(BIT(31) | (seg_addr << 8), HDMI_DDC_DATA);
writel(seg_num << 8, HDMI_DDC_DATA);
}
/* handle portion #1 */
writel(BIT(31) | (ddc_data->dev_addr << 8), HDMI_DDC_DATA);
/* handle portion #2 */
writel(ddc_data->offset << 8, HDMI_DDC_DATA);
if (mode == TRIGGER_READ) {
/* handle portion #3 */
writel((ddc_data->dev_addr | BIT(0)) << 8, HDMI_DDC_DATA);
/* HDMI_I2C_TRANSACTION0 */
writel(BIT(12) | BIT(16), HDMI_DDC_TRANS0);
/* Write to HDMI_I2C_TRANSACTION1 */
if (seg) {
writel(BIT(12) | BIT(16), HDMI_DDC_TRANS1);
writel(BIT(0) | BIT(12) | BIT(13) |
(ddc_data->request_len << 16), HDMI_DDC_TRANS2);
ddc_ctrl_reg_val = BIT(0) | BIT(21);
} else {
writel(BIT(0) | BIT(12) | BIT(13) |
(ddc_data->request_len << 16), HDMI_DDC_TRANS1);
ddc_ctrl_reg_val = BIT(0) | BIT(20);
}
} else {
uint32_t ndx;
/* write buffer */
for (ndx = 0; ndx < ddc_data->data_len; ++ndx)
writel(((uint32_t)ddc_data->data_buf[ndx]) << 8,
HDMI_DDC_DATA);
writel((ddc_data->data_len + 1) << 16 | BIT(12) | BIT(13),
HDMI_DDC_TRANS0);
ddc_ctrl_reg_val = BIT(0);
}
/* Trigger the I2C transfer */
writel(ddc_ctrl_reg_val, HDMI_DDC_CTRL);
}
static int mdss_hdmi_ddc_clear_irq(char *what)
{
uint32_t ddc_int_ctrl, ddc_status, in_use, timeout;
uint32_t sw_done_mask = BIT(2);
uint32_t sw_done_ack = BIT(1);
uint32_t in_use_by_sw = BIT(0);
uint32_t in_use_by_hw = BIT(1);
/* clear and enable interrutps */
ddc_int_ctrl = sw_done_mask | sw_done_ack;
writel(ddc_int_ctrl, HDMI_DDC_INT_CTRL);
/* wait until DDC HW is free */
timeout = 100;
do {
ddc_status = readl(HDMI_DDC_HW_STATUS);
in_use = ddc_status & (in_use_by_sw | in_use_by_hw);
if (in_use) {
dprintf(INFO, "%s: ddc is in use by %s, timeout(%d)\n",
__func__,
ddc_status & in_use_by_sw ? "sw" : "hw",
timeout);
udelay(100);
}
} while (in_use && --timeout);
if (!timeout) {
dprintf(CRITICAL, "%s: %s: timed out\n", __func__, what);
return ERROR;
}
return 0;
}
static int mdss_hdmi_ddc_read_retry(struct hdmi_tx_ddc_data *ddc_data)
{
uint32_t reg_val, ndx;
int status, rc;
if (!ddc_data) {
dprintf(CRITICAL, "%s: invalid input\n", __func__);
return ERROR;
}
if (!ddc_data->data_buf) {
status = ERROR;
dprintf(CRITICAL, "%s: %s: invalid buf\n",
__func__, ddc_data->what);
goto error;
}
if (ddc_data->retry < 0) {
dprintf(CRITICAL, "%s: invalid no. of retries %d\n",
__func__, ddc_data->retry);
status = ERROR;
goto error;
}
do {
status = mdss_hdmi_ddc_clear_irq(ddc_data->what);
if (status)
continue;
mdss_hdmi_ddc_trigger(ddc_data, TRIGGER_READ, false);
dprintf(SPEW, "%s: ddc read done\n", __func__);
rc = mdss_hdmi_ddc_check_status(ddc_data->what);
if (!status)
status = rc;
udelay(HDMI_DDC_TRANSACTION_DELAY_US);
} while (status && ddc_data->retry--);
if (status)
goto error;
/* Write data to DDC buffer */
writel(BIT(0) | (3 << 16) | BIT(31), HDMI_DDC_DATA);
/* Discard first byte */
readl(HDMI_DDC_DATA);
for (ndx = 0; ndx < ddc_data->data_len; ++ndx) {
reg_val = readl(HDMI_DDC_DATA);
ddc_data->data_buf[ndx] = (uint8_t)((reg_val & 0x0000FF00) >> 8);
}
dprintf(SPEW, "%s: %s: success\n", __func__, ddc_data->what);
error:
return status;
}
static int mdss_hdmi_ddc_read(struct hdmi_tx_ddc_data *ddc_data)
{
int rc = 0;
int retry;
if (!ddc_data) {
dprintf(CRITICAL, "%s: invalid ddc data\n", __func__);
return ERROR;
}
retry = ddc_data->retry;
rc = mdss_hdmi_ddc_read_retry(ddc_data);
if (!rc)
return rc;
if (ddc_data->retry_align) {
ddc_data->retry = retry;
ddc_data->request_len = 32 * ((ddc_data->data_len + 31) / 32);
rc = mdss_hdmi_ddc_read_retry(ddc_data);
}
return rc;
}
static int mdss_hdmi_ddc_write(struct hdmi_tx_ddc_data *ddc_data)
{
int status, rc;
if (!ddc_data->data_buf) {
status = ERROR;
dprintf(CRITICAL, "%s: %s: invalid buf\n",
__func__, ddc_data->what);
goto error;
}
if (ddc_data->retry < 0) {
dprintf(CRITICAL, "%s: invalid no. of retries %d\n",
__func__, ddc_data->retry);
status = ERROR;
goto error;
}
do {
status = mdss_hdmi_ddc_clear_irq(ddc_data->what);
if (status)
continue;
mdss_hdmi_ddc_trigger(ddc_data, TRIGGER_WRITE, false);
dprintf(SPEW, "%s: DDC write done\n", __func__);
rc = mdss_hdmi_ddc_check_status(ddc_data->what);
if (!status)
status = rc;
udelay(HDMI_DDC_TRANSACTION_DELAY_US);
} while (status && ddc_data->retry--);
if (status)
goto error;
dprintf(SPEW, "%s: %s: success\n", __func__, ddc_data->what);
error:
return status;
}
static inline char *mdss_hdmi_scdc_reg2string(uint32_t type)
{
switch (type) {
case SCDC_SCRAMBLING_STATUS:
return "SCDC_SCRAMBLING_STATUS";
case SCDC_SCRAMBLING_ENABLE:
return "SCDC_SCRAMBLING_ENABLE";
case SCDC_TMDS_BIT_CLOCK_RATIO_UPDATE:
return "SCDC_TMDS_BIT_CLOCK_RATIO_UPDATE";
case SCDC_CLOCK_DET_STATUS:
return "SCDC_CLOCK_DET_STATUS";
case SCDC_CH0_LOCK_STATUS:
return "SCDC_CH0_LOCK_STATUS";
case SCDC_CH1_LOCK_STATUS:
return "SCDC_CH1_LOCK_STATUS";
case SCDC_CH2_LOCK_STATUS:
return "SCDC_CH2_LOCK_STATUS";
case SCDC_CH0_ERROR_COUNT:
return "SCDC_CH0_ERROR_COUNT";
case SCDC_CH1_ERROR_COUNT:
return "SCDC_CH1_ERROR_COUNT";
case SCDC_CH2_ERROR_COUNT:
return "SCDC_CH2_ERROR_COUNT";
case SCDC_READ_ENABLE:
return"SCDC_READ_ENABLE";
default:
return HDMI_SCDC_UNKNOWN_REGISTER;
}
}
static int mdss_hdmi_scdc_write(uint32_t data_type, uint32_t val)
{
struct hdmi_tx_ddc_data data = {0};
struct hdmi_tx_ddc_data rdata = {0};
int rc = 0;
uint8_t data_buf[2] = {0};
uint8_t read_val = 0;
if (data_type >= SCDC_MAX) {
dprintf(CRITICAL, "Unsupported data type\n");
return ERROR;
}
data.what = mdss_hdmi_scdc_reg2string(data_type);
data.dev_addr = 0xA8;
data.retry = 1;
data.data_buf = data_buf;
switch (data_type) {
case SCDC_SCRAMBLING_ENABLE:
case SCDC_TMDS_BIT_CLOCK_RATIO_UPDATE:
rdata.what = "TMDS CONFIG";
rdata.dev_addr = 0xA8;
rdata.retry = 2;
rdata.data_buf = &read_val;
rdata.data_len = 1;
rdata.offset = HDMI_SCDC_TMDS_CONFIG;
rdata.request_len = 1;
rc = mdss_hdmi_ddc_read(&rdata);
if (rc) {
dprintf(CRITICAL, "scdc read failed\n");
return rc;
}
if (data_type == SCDC_SCRAMBLING_ENABLE) {
data_buf[0] = ((((uint8_t)(read_val & 0xFF)) & (~BIT(0))) |
((uint8_t)(val & BIT(0))));
} else {
data_buf[0] = ((((uint8_t)(read_val & 0xFF)) & (~BIT(1))) |
(((uint8_t)(val & BIT(0))) << 1));
}
data.data_len = 1;
data.request_len = 1;
data.offset = HDMI_SCDC_TMDS_CONFIG;
break;
case SCDC_READ_ENABLE:
data.data_len = 1;
data.request_len = 1;
data.offset = HDMI_SCDC_CONFIG_0;
data_buf[0] = (uint8_t)(val & 0x1);
break;
default:
dprintf(CRITICAL, "Cannot write to read only reg (%d)\n",
data_type);
return ERROR;
}
rc = mdss_hdmi_ddc_write(&data);
if (rc) {
dprintf(CRITICAL, "DDC Read failed for %s\n", data.what);
return rc;
}
return 0;
}
static inline int mdss_hdmi_get_v_total(const struct mdss_hdmi_timing_info *t)
{
if (t) {
return t->active_v + t->front_porch_v + t->pulse_width_v +
t->back_porch_v;
}
return 0;
}
static int mdss_hdmi_get_timeout_in_hysnc(struct mdss_hdmi_timing_info *timing,
uint32_t timeout_ms)
{
uint32_t fps, v_total;
uint32_t time_taken_by_one_line_us, lines_needed_for_given_time;
if (!timing || !timeout_ms) {
dprintf(CRITICAL, "invalid input\n");
return ERROR;
}
fps = timing->refresh_rate / HDMI_KHZ_TO_HZ;
v_total = mdss_hdmi_get_v_total(timing);
/*
* pixel clock = h_total * v_total * fps
* 1 sec = pixel clock number of pixels are transmitted.
* time taken by one line (h_total) = 1 / (v_total * fps).
*/
time_taken_by_one_line_us = HDMI_SEC_TO_US / (v_total * fps);
lines_needed_for_given_time = (timeout_ms * HDMI_MS_TO_US) /
time_taken_by_one_line_us;
return lines_needed_for_given_time;
}
static void mdss_hdmi_scrambler_ddc_reset()
{
uint32_t reg_val;
/* clear ack and disable interrupts */
reg_val = BIT(14) | BIT(9) | BIT(5) | BIT(1);
writel(reg_val, HDMI_DDC_INT_CTRL2);
/* Reset DDC timers */
reg_val = BIT(0) | readl(HDMI_SCRAMBLER_STATUS_DDC_CTRL);
writel(reg_val, HDMI_SCRAMBLER_STATUS_DDC_CTRL);
reg_val = readl(HDMI_SCRAMBLER_STATUS_DDC_CTRL);
reg_val &= ~BIT(0);
writel(reg_val, HDMI_SCRAMBLER_STATUS_DDC_CTRL);
}
static void mdss_hdmi_scrambler_ddc_disable()
{
uint32_t reg_val;
mdss_hdmi_scrambler_ddc_reset();
/* Disable HW DDC access to RxStatus register */
reg_val = readl(HDMI_HW_DDC_CTRL);
reg_val &= ~(BIT(8) | BIT(9));
writel(reg_val, HDMI_HW_DDC_CTRL);
}
static int mdss_hdmi_scrambler_ddc_check_status()
{
int rc = 0;
uint32_t reg_val;
/* check for errors and clear status */
reg_val = readl(HDMI_SCRAMBLER_STATUS_DDC_STATUS);
if (reg_val & BIT(4)) {
dprintf(CRITICAL, "ddc aborted\n");
reg_val |= BIT(5);
rc = ERROR;
}
if (reg_val & BIT(8)) {
dprintf(CRITICAL, "timed out\n");
reg_val |= BIT(9);
rc = ERROR;
}
if (reg_val & BIT(12)) {
dprintf(CRITICAL, "NACK0\n");
reg_val |= BIT(13);
rc = ERROR;
}
if (reg_val & BIT(14)) {
dprintf(CRITICAL, "NACK1\n");
reg_val |= BIT(15);
rc = ERROR;
}
writel(reg_val, HDMI_SCRAMBLER_STATUS_DDC_STATUS);
return rc;
}
static int mdss_hdmi_scrambler_status_timer_setup(uint32_t timeout_hsync)
{
uint32_t reg_val;
int rc;
mdss_hdmi_ddc_clear_irq("scrambler");
writel(timeout_hsync, HDMI_SCRAMBLER_STATUS_DDC_TIMER_CTRL);
writel(timeout_hsync, HDMI_SCRAMBLER_STATUS_DDC_TIMER_CTRL2);
reg_val = readl(HDMI_DDC_INT_CTRL5);
reg_val |= BIT(10);
writel(reg_val, HDMI_DDC_INT_CTRL5);
reg_val = readl(HDMI_DDC_INT_CTRL2);
/* Trigger interrupt if scrambler status is 0 or DDC failure */
reg_val |= BIT(10);
reg_val &= ~(BIT(15) | BIT(16));
reg_val |= BIT(16);
writel(reg_val, HDMI_DDC_INT_CTRL2);
/* Enable DDC access */
reg_val = readl(HDMI_HW_DDC_CTRL);
reg_val &= ~(BIT(8) | BIT(9));
reg_val |= BIT(8);
writel(reg_val, HDMI_HW_DDC_CTRL);
/* WAIT for 200ms as per HDMI 2.0 standard for sink to respond */
udelay(2000);
/* clear the scrambler status */
rc = mdss_hdmi_scrambler_ddc_check_status();
if (rc)
dprintf(CRITICAL, "scrambling ddc error %d\n", rc);
mdss_hdmi_scrambler_ddc_disable();
return rc;
}
static int mdss_hdmi_setup_ddc_timers(uint32_t type, uint32_t to_in_num_lines)
{
if (type >= DDC_TIMER_MAX) {
dprintf(CRITICAL, "Invalid timer type %d\n", type);
return ERROR;
}
switch (type) {
case DDC_TIMER_SCRAMBLER_STATUS:
mdss_hdmi_scrambler_status_timer_setup(to_in_num_lines);
break;
default:
dprintf(CRITICAL, "%d type not supported\n", type);
return ERROR;
}
return 0;
}
static int mdss_hdmi_setup_scrambler()
{
int rc = 0;
uint32_t reg_val = 0;
uint32_t tmds_clock_ratio = 0;
bool scrambler_on = false;
struct mdss_hdmi_timing_info timing = {0};
mdss_hdmi_get_timing_info(&timing, mdss_hdmi_video_fmt);
int timeout_hsync;
/* Scrambling is supported from HDMI TX 4.0 */
reg_val = readl(HDMI_VERSION);
reg_val = (reg_val & 0xF0000000) >> 28;
if (reg_val < HDMI_TX_SCRAMBLER_MIN_TX_VERSION) {
dprintf(INFO, "%s: HDMI TX does not support scrambling\n",
__func__);
return 0;
}
if (timing.pixel_freq > HDMI_TX_SCRAMBLER_THRESHOLD_RATE_KHZ) {
scrambler_on = true;
tmds_clock_ratio = 1;
}
dprintf(SPEW, "%s: freq=%d, scrambler=%d, clock_ratio=%d\n",
__func__, timing.pixel_freq, scrambler_on,
tmds_clock_ratio);
if (scrambler_on) {
rc = mdss_hdmi_scdc_write(SCDC_TMDS_BIT_CLOCK_RATIO_UPDATE,
tmds_clock_ratio);
if (rc) {
dprintf(CRITICAL, "%s: TMDS CLK RATIO ERR\n", __func__);
return rc;
}
reg_val = readl(HDMI_CTRL);
reg_val |= BIT(31); /* Enable Update DATAPATH_MODE */
reg_val |= BIT(28); /* Set SCRAMBLER_EN bit */
writel(reg_val, HDMI_CTRL);
rc = mdss_hdmi_scdc_write(SCDC_SCRAMBLING_ENABLE, 0x1);
if (rc) {
dprintf(CRITICAL, "%s: failed to enable scrambling\n",
__func__);
return rc;
}
/*
* Setup hardware to periodically check for scrambler
* status bit on the sink. Sink should set this bit
* with in 200ms after scrambler is enabled.
*/
timeout_hsync = mdss_hdmi_get_timeout_in_hysnc(&timing,
HDMI_TX_SCRAMBLER_TIMEOUT_MSEC);
if (timeout_hsync <= 0) {
dprintf(CRITICAL, "%s: err in timeout hsync calc\n",
__func__);
timeout_hsync = HDMI_DEFAULT_TIMEOUT_HSYNC;
}
dprintf(SPEW, "%s: timeout for scrambling en: %d hsyncs\n",
__func__, timeout_hsync);
rc = mdss_hdmi_setup_ddc_timers(DDC_TIMER_SCRAMBLER_STATUS,
timeout_hsync);
} else {
mdss_hdmi_scdc_write(SCDC_SCRAMBLING_ENABLE, 0x0);
}
return rc;
}
int mdss_hdmi_init(void)
{
bool is_dvi_mode = mdss_hdmi_is_dvi_mode();
mdss_hdmi_set_mode(false);
/* Enable USEC REF timer */
writel(0x0001001B, HDMI_USEC_REFTIMER);
/* Audio settings */
if (!is_dvi_mode)
mdss_hdmi_audio_playback();
/* Video settings */
mdss_hdmi_video_setup();
/* AVI info settings */
if (!is_dvi_mode)
mdss_hdmi_avi_info_frame();
/* Enable HDMI */
mdss_hdmi_set_mode(true);
mdss_hdmi_setup_scrambler();
return 0;
}