libdisplay-info/di-edid-decode.c
Simon Ser 407b309904 cta: add support for video capability data block
Signed-off-by: Simon Ser <contact@emersion.fr>
2022-09-05 18:11:56 +00:00

1070 lines
33 KiB
C

#include <assert.h>
#include <inttypes.h>
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <getopt.h>
#include <libdisplay-info/cta.h>
#include <libdisplay-info/edid.h>
#include <libdisplay-info/displayid.h>
#include <libdisplay-info/info.h>
static size_t num_detailed_timing_defs = 0;
static const struct option long_options[] = {
{ "help", no_argument, 0, 'h' },
{ 0, 0, 0, 0 }
};
static void usage(void)
{
fprintf(stderr, "Usage: di-edid-decode <options> [in]\n"
" [in]: EDID file to parse. Read from standard input (stdin),\n"
" if none given.\n"
"Example : di-edid-decode /sys/class/drm/card0-DP-2/edid \n"
"\nOptions:\n"
"-h, --help display the help message\n");
}
static const char *
standard_timing_aspect_ratio_name(enum di_edid_standard_timing_aspect_ratio aspect_ratio)
{
switch (aspect_ratio) {
case DI_EDID_STANDARD_TIMING_16_10:
return "16:10";
case DI_EDID_STANDARD_TIMING_4_3:
return "4:3";
case DI_EDID_STANDARD_TIMING_5_4:
return "5:4";
case DI_EDID_STANDARD_TIMING_16_9:
return "16:9";
}
abort();
}
static void
print_standard_timing(const struct di_edid_standard_timing *t)
{
int32_t vert_video;
uint8_t dmt_id;
vert_video = di_edid_standard_timing_get_vert_video(t);
dmt_id = di_edid_standard_timing_get_dmt_id(t);
/* TODO: GTF and CVT timings */
printf(" ");
printf("DMT 0x%02x:", dmt_id);
printf(" %5dx%-5d", t->horiz_video, vert_video);
printf(" %10.6f Hz", (float) t->refresh_rate_hz);
printf(" %s", standard_timing_aspect_ratio_name(t->aspect_ratio));
printf("\n");
}
static int
gcd(int a, int b)
{
int tmp;
while (b) {
tmp = b;
b = a % b;
a = tmp;
}
return a;
}
static void
compute_aspect_ratio(int width, int height, int *horiz_ratio, int *vert_ratio)
{
int d;
d = gcd(width, height);
if (d == 0) {
*horiz_ratio = *vert_ratio = 0;
} else {
*horiz_ratio = width / d;
*vert_ratio = height / d;
}
}
/**
* Join a list of strings into a comma-separated string.
*
* The list must be NULL-terminated.
*/
static char *
join_str(const char *l[])
{
char *out = NULL;
size_t out_size = 0, i;
FILE *f;
f = open_memstream(&out, &out_size);
if (!f) {
return NULL;
}
for (i = 0; l[i] != NULL; i++) {
if (i > 0) {
fprintf(f, ", ");
}
fprintf(f, "%s", l[i]);
}
fclose(f);
return out;
}
static bool
has_established_timings_i_ii(const struct di_edid_established_timings_i_ii *timings)
{
return timings->has_720x400_70hz || timings->has_720x400_88hz
|| timings->has_640x480_60hz || timings->has_640x480_67hz
|| timings->has_640x480_72hz || timings->has_640x480_75hz
|| timings->has_800x600_56hz || timings->has_800x600_60hz
|| timings->has_800x600_72hz || timings->has_800x600_75hz
|| timings->has_832x624_75hz || timings->has_1024x768_87hz_interlaced
|| timings->has_1024x768_60hz || timings->has_1024x768_70hz
|| timings->has_1024x768_75hz || timings->has_1280x1024_75hz
|| timings->has_1152x870_75hz;
}
static const char *
detailed_timing_def_stereo_name(enum di_edid_detailed_timing_def_stereo stereo)
{
switch (stereo) {
case DI_EDID_DETAILED_TIMING_DEF_STEREO_NONE:
return "none";
case DI_EDID_DETAILED_TIMING_DEF_STEREO_FIELD_SEQ_RIGHT:
return "field sequential L/R";
case DI_EDID_DETAILED_TIMING_DEF_STEREO_FIELD_SEQ_LEFT:
return "field sequential R/L";
case DI_EDID_DETAILED_TIMING_DEF_STEREO_2_WAY_INTERLEAVED_RIGHT:
return "interleaved right even";
case DI_EDID_DETAILED_TIMING_DEF_STEREO_2_WAY_INTERLEAVED_LEFT:
return "interleaved left even";
case DI_EDID_DETAILED_TIMING_DEF_STEREO_4_WAY_INTERLEAVED:
return "four way interleaved";
case DI_EDID_DETAILED_TIMING_DEF_STEREO_SIDE_BY_SIDE_INTERLEAVED:
return "side by side interleaved";
}
abort();
}
static const char *
detailed_timing_def_signal_type_name(enum di_edid_detailed_timing_def_signal_type type)
{
switch (type) {
case DI_EDID_DETAILED_TIMING_DEF_SIGNAL_ANALOG_COMPOSITE:
return "analog composite";
case DI_EDID_DETAILED_TIMING_DEF_SIGNAL_BIPOLAR_ANALOG_COMPOSITE:
return "bipolar analog composite";
case DI_EDID_DETAILED_TIMING_DEF_SIGNAL_DIGITAL_COMPOSITE:
return "digital composite";
case DI_EDID_DETAILED_TIMING_DEF_SIGNAL_DIGITAL_SEPARATE:
/* edid-decode doesn't print anything in this case */
return NULL;
}
abort();
}
static bool
detailed_timing_def_sync_serrations(const struct di_edid_detailed_timing_def *def)
{
switch (def->signal_type) {
case DI_EDID_DETAILED_TIMING_DEF_SIGNAL_ANALOG_COMPOSITE:
return def->analog_composite->sync_serrations;
case DI_EDID_DETAILED_TIMING_DEF_SIGNAL_BIPOLAR_ANALOG_COMPOSITE:
return def->bipolar_analog_composite->sync_serrations;
case DI_EDID_DETAILED_TIMING_DEF_SIGNAL_DIGITAL_COMPOSITE:
return def->digital_composite->sync_serrations;
default:
return false;
}
}
static bool
detailed_timing_def_sync_on_green(const struct di_edid_detailed_timing_def *def)
{
switch (def->signal_type) {
case DI_EDID_DETAILED_TIMING_DEF_SIGNAL_ANALOG_COMPOSITE:
return def->analog_composite->sync_on_green;
case DI_EDID_DETAILED_TIMING_DEF_SIGNAL_BIPOLAR_ANALOG_COMPOSITE:
return def->bipolar_analog_composite->sync_on_green;
default:
return false;
}
}
static const char *
detailed_timing_def_sync_polarity_name(enum di_edid_detailed_timing_def_sync_polarity polarity)
{
switch (polarity) {
case DI_EDID_DETAILED_TIMING_DEF_SYNC_NEGATIVE:
return "N";
case DI_EDID_DETAILED_TIMING_DEF_SYNC_POSITIVE:
return "P";
}
abort();
}
static void
print_detailed_timing_def(const struct di_edid_detailed_timing_def *def)
{
int hbl, vbl, horiz_total, vert_total;
int horiz_back_porch, vert_back_porch;
int horiz_ratio, vert_ratio;
double refresh, horiz_freq_hz;
const char *flags[32] = {0};
const char *signal_type_name;
char size_mm[64];
size_t flags_len = 0;
enum di_edid_detailed_timing_def_sync_polarity polarity;
hbl = def->horiz_blank - 2 * def->horiz_border;
vbl = def->vert_blank - 2 * def->vert_border;
horiz_total = def->horiz_video + hbl;
vert_total = def->vert_video + vbl;
refresh = (double) def->pixel_clock_hz / (horiz_total * vert_total);
horiz_freq_hz = (double) def->pixel_clock_hz / horiz_total;
compute_aspect_ratio(def->horiz_video, def->vert_video,
&horiz_ratio, &vert_ratio);
signal_type_name = detailed_timing_def_signal_type_name(def->signal_type);
if (signal_type_name != NULL) {
flags[flags_len++] = signal_type_name;
}
if (detailed_timing_def_sync_serrations(def)) {
flags[flags_len++] = "serrate";
}
if (detailed_timing_def_sync_on_green(def)) {
flags[flags_len++] = "sync-on-green";
}
if (def->stereo != DI_EDID_DETAILED_TIMING_DEF_STEREO_NONE) {
flags[flags_len++] = detailed_timing_def_stereo_name(def->stereo);
}
if (def->horiz_image_mm != 0 || def->vert_image_mm != 0) {
snprintf(size_mm, sizeof(size_mm), "%d mm x %d mm",
def->horiz_image_mm, def->vert_image_mm);
flags[flags_len++] = size_mm;
}
assert(flags_len < sizeof(flags) / sizeof(flags[0]));
printf(" DTD %zu:", ++num_detailed_timing_defs);
printf(" %5dx%-5d", def->horiz_video, def->vert_video);
if (def->interlaced) {
printf("i");
}
printf(" %10.6f Hz", refresh);
printf(" %3u:%-3u", horiz_ratio, vert_ratio);
printf(" %8.3f kHz %13.6f MHz", horiz_freq_hz / 1000,
(double) def->pixel_clock_hz / (1000 * 1000));
if (flags_len > 0) {
char *flags_str = join_str(flags);
printf(" (%s)", flags_str);
free(flags_str);
}
printf("\n");
horiz_back_porch = hbl - def->horiz_sync_pulse - def->horiz_front_porch;
printf(" Hfront %4d Hsync %3d Hback %4d",
def->horiz_front_porch, def->horiz_sync_pulse, horiz_back_porch);
if (def->horiz_border != 0) {
printf(" Hborder %d", def->horiz_border);
}
if (def->signal_type == DI_EDID_DETAILED_TIMING_DEF_SIGNAL_DIGITAL_COMPOSITE) {
polarity = def->digital_composite->sync_horiz_polarity;
printf(" Hpol %s", detailed_timing_def_sync_polarity_name(polarity));
} else if (def->signal_type == DI_EDID_DETAILED_TIMING_DEF_SIGNAL_DIGITAL_SEPARATE) {
polarity = def->digital_separate->sync_horiz_polarity;
printf(" Hpol %s", detailed_timing_def_sync_polarity_name(polarity));
}
printf("\n");
vert_back_porch = vbl - def->vert_sync_pulse - def->vert_front_porch;
printf(" Vfront %4u Vsync %3u Vback %4d",
def->vert_front_porch, def->vert_sync_pulse, vert_back_porch);
if (def->vert_border != 0) {
printf(" Vborder %d", def->vert_border);
}
if (def->signal_type == DI_EDID_DETAILED_TIMING_DEF_SIGNAL_DIGITAL_SEPARATE) {
polarity = def->digital_separate->sync_vert_polarity;
printf(" Vpol %s", detailed_timing_def_sync_polarity_name(polarity));
}
printf("\n");
}
static const char *
display_desc_tag_name(enum di_edid_display_descriptor_tag tag)
{
switch (tag) {
case DI_EDID_DISPLAY_DESCRIPTOR_PRODUCT_SERIAL:
return "Display Product Serial Number";
case DI_EDID_DISPLAY_DESCRIPTOR_DATA_STRING:
return "Alphanumeric Data String";
case DI_EDID_DISPLAY_DESCRIPTOR_RANGE_LIMITS:
return "Display Range Limits";
case DI_EDID_DISPLAY_DESCRIPTOR_PRODUCT_NAME:
return "Display Product Name";
case DI_EDID_DISPLAY_DESCRIPTOR_COLOR_POINT:
return "Color Point Data";
case DI_EDID_DISPLAY_DESCRIPTOR_STD_TIMING_IDS:
return "Standard Timing Identifications";
case DI_EDID_DISPLAY_DESCRIPTOR_DCM_DATA:
return "Display Color Management Data";
case DI_EDID_DISPLAY_DESCRIPTOR_CVT_TIMING_CODES:
return "CVT 3 Byte Timing Codes";
case DI_EDID_DISPLAY_DESCRIPTOR_ESTABLISHED_TIMINGS_III:
return "Established timings III";
case DI_EDID_DISPLAY_DESCRIPTOR_DUMMY:
return "Dummy Descriptor";
}
abort();
}
static const char *
display_range_limits_type_name(enum di_edid_display_range_limits_type type)
{
switch (type) {
case DI_EDID_DISPLAY_RANGE_LIMITS_BARE:
return "Bare Limits";
case DI_EDID_DISPLAY_RANGE_LIMITS_DEFAULT_GTF:
return "GTF";
case DI_EDID_DISPLAY_RANGE_LIMITS_SECONDARY_GTF:
return "Secondary GTF";
case DI_EDID_DISPLAY_RANGE_LIMITS_CVT:
return "CVT";
}
abort();
}
static void
print_display_desc(const struct di_edid *edid,
const struct di_edid_display_descriptor *desc)
{
enum di_edid_display_descriptor_tag tag;
const char *tag_name, *str;
const struct di_edid_display_range_limits *range_limits;
enum di_edid_display_range_limits_type range_limits_type;
const struct di_edid_standard_timing *const *standard_timings;
size_t i;
tag = di_edid_display_descriptor_get_tag(desc);
tag_name = display_desc_tag_name(tag);
printf(" %s:", tag_name);
switch (tag) {
case DI_EDID_DISPLAY_DESCRIPTOR_PRODUCT_SERIAL:
case DI_EDID_DISPLAY_DESCRIPTOR_DATA_STRING:
case DI_EDID_DISPLAY_DESCRIPTOR_PRODUCT_NAME:
str = di_edid_display_descriptor_get_string(desc);
printf(" '%s'", str);
break;
case DI_EDID_DISPLAY_DESCRIPTOR_RANGE_LIMITS:
range_limits = di_edid_display_descriptor_get_range_limits(desc);
range_limits_type = range_limits->type;
if (di_edid_get_revision(edid) < 4
&& range_limits_type == DI_EDID_DISPLAY_RANGE_LIMITS_BARE) {
/* edid-decode always prints "GTF" for EDID 1.3 and
* earlier even if the display doesn't support it */
range_limits_type = DI_EDID_DISPLAY_RANGE_LIMITS_DEFAULT_GTF;
}
printf("\n Monitor ranges (%s): %d-%d Hz V, %d-%d kHz H",
display_range_limits_type_name(range_limits_type),
range_limits->min_vert_rate_hz,
range_limits->max_vert_rate_hz,
range_limits->min_horiz_rate_hz / 1000,
range_limits->max_horiz_rate_hz / 1000);
if (range_limits->max_pixel_clock_hz != 0) {
printf(", max dotclock %d MHz",
range_limits->max_pixel_clock_hz / (1000 * 1000));
}
break;
case DI_EDID_DISPLAY_DESCRIPTOR_STD_TIMING_IDS:
standard_timings = di_edid_display_descriptor_get_standard_timings(desc);
for (i = 0; standard_timings[i] != NULL; i++) {
printf(" ");
print_standard_timing(standard_timings[i]);
}
break;
default:
break; /* TODO: print other tags */
}
printf("\n");
}
static const char *
ext_tag_name(enum di_edid_ext_tag tag)
{
switch (tag) {
case DI_EDID_EXT_CEA:
return "CTA-861 Extension Block";
case DI_EDID_EXT_VTB:
return "Video Timing Extension Block";
case DI_EDID_EXT_DI:
return "Display Information Extension Block";
case DI_EDID_EXT_LS:
return "Localized String Extension Block";
case DI_EDID_EXT_DPVL:
return "Digital Packet Video Link Extension";
case DI_EDID_EXT_BLOCK_MAP:
return "Block Map Extension Block";
case DI_EDID_EXT_VENDOR:
return "Manufacturer-Specific Extension Block";
case DI_EDID_EXT_DISPLAYID:
return "DisplayID Extension Block";
}
abort();
}
static const char *
analog_signal_level_std_name(enum di_edid_video_input_analog_signal_level_std std)
{
switch (std) {
case DI_EDID_VIDEO_INPUT_ANALOG_SIGNAL_LEVEL_0:
return "0.700 : 0.300 : 1.000 V p-p";
case DI_EDID_VIDEO_INPUT_ANALOG_SIGNAL_LEVEL_1:
return "0.714 : 0.286 : 1.000 V p-p";
case DI_EDID_VIDEO_INPUT_ANALOG_SIGNAL_LEVEL_2:
return "1.000 : 0.400 : 1.400 V p-p";
case DI_EDID_VIDEO_INPUT_ANALOG_SIGNAL_LEVEL_3:
return "0.700 : 0.000 : 0.700 V p-p";
}
abort();
}
static const char *
digital_interface_name(enum di_edid_video_input_digital_interface interface)
{
switch (interface) {
case DI_EDID_VIDEO_INPUT_DIGITAL_UNDEFINED:
return "Digital interface is not defined";
case DI_EDID_VIDEO_INPUT_DIGITAL_DVI:
return "DVI interface";
case DI_EDID_VIDEO_INPUT_DIGITAL_HDMI_A:
return "HDMI-a interface";
case DI_EDID_VIDEO_INPUT_DIGITAL_HDMI_B:
return "HDMI-b interface";
case DI_EDID_VIDEO_INPUT_DIGITAL_MDDI:
return "MDDI interface";
case DI_EDID_VIDEO_INPUT_DIGITAL_DISPLAYPORT:
return "DisplayPort interface";
}
abort();
}
static const char *
display_color_type_name(enum di_edid_display_color_type type)
{
switch (type) {
case DI_EDID_DISPLAY_COLOR_MONOCHROME:
return "Monochrome or grayscale display";
case DI_EDID_DISPLAY_COLOR_RGB:
return "RGB color display";
case DI_EDID_DISPLAY_COLOR_NON_RGB:
return "Non-RGB color display";
case DI_EDID_DISPLAY_COLOR_UNDEFINED:
return "Undefined display color type";
}
abort();
}
static void
printf_cta_svds(const struct di_cta_svd *const *svds)
{
size_t i;
const struct di_cta_svd *svd;
for (i = 0; svds[i] != NULL; i++) {
svd = svds[i];
printf(" VIC %3" PRIu8, svd->vic);
if (svd->native)
printf(" (native)");
printf("\n");
// TODO: print detailed mode info
}
}
static uint8_t
encode_max_luminance(float max)
{
if (max == 0)
return 0;
return (uint8_t) (log2f(max / 50) * 32);
}
static uint8_t
encode_min_luminance(float min, float max)
{
if (min == 0)
return 0;
return (uint8_t) (255 * sqrtf(min / max * 100));
}
static void
print_cta_hdr_static_metadata(const struct di_cta_hdr_static_metadata_block *metadata)
{
printf(" Electro optical transfer functions:\n");
if (metadata->eotfs->traditional_sdr)
printf(" Traditional gamma - SDR luminance range\n");
if (metadata->eotfs->traditional_hdr)
printf(" Traditional gamma - HDR luminance range\n");
if (metadata->eotfs->pq)
printf(" SMPTE ST2084\n");
if (metadata->eotfs->hlg)
printf(" Hybrid Log-Gamma\n");
printf(" Supported static metadata descriptors:\n");
if (metadata->descriptors->type1)
printf(" Static metadata type 1\n");
/* TODO: figure out a way to print raw values? */
if (metadata->desired_content_max_luminance != 0)
printf(" Desired content max luminance: %" PRIu8 " (%.3f cd/m^2)\n",
encode_max_luminance(metadata->desired_content_max_luminance),
metadata->desired_content_max_luminance);
if (metadata->desired_content_max_frame_avg_luminance != 0)
printf(" Desired content max frame-average luminance: %" PRIu8 " (%.3f cd/m^2)\n",
encode_max_luminance(metadata->desired_content_max_frame_avg_luminance),
metadata->desired_content_max_frame_avg_luminance);
if (metadata->desired_content_min_luminance != 0)
printf(" Desired content min luminance: %" PRIu8 " (%.3f cd/m^2)\n",
encode_min_luminance(metadata->desired_content_min_luminance,
metadata->desired_content_max_luminance),
metadata->desired_content_min_luminance);
}
static const char *
cta_data_block_tag_name(enum di_cta_data_block_tag tag)
{
switch (tag) {
case DI_CTA_DATA_BLOCK_AUDIO:
return "Audio Data Block";
case DI_CTA_DATA_BLOCK_VIDEO:
return "Video Data Block";
case DI_CTA_DATA_BLOCK_SPEAKER_ALLOC:
return "Speaker Allocation Data Block";
case DI_CTA_DATA_BLOCK_VESA_DISPLAY_TRANSFER_CHARACTERISTIC:
return "VESA Display Transfer Characteristic Data Block";
case DI_CTA_DATA_BLOCK_VIDEO_CAP:
return "Video Capability Data Block";
case DI_CTA_DATA_BLOCK_VESA_DISPLAY_DEVICE:
return "VESA Display Device Data Block";
case DI_CTA_DATA_BLOCK_COLORIMETRY:
return "Colorimetry Data Block";
case DI_CTA_DATA_BLOCK_HDR_STATIC_METADATA:
return "HDR Static Metadata Data Block";
case DI_CTA_DATA_BLOCK_HDR_DYNAMIC_METADATA:
return "HDR Dynamic Metadata Data Block";
case DI_CTA_DATA_BLOCK_VIDEO_FORMAT_PREF:
return "Video Format Preference Data Block";
case DI_CTA_DATA_BLOCK_YCBCR420:
return "YCbCr 4:2:0 Video Data Block";
case DI_CTA_DATA_BLOCK_YCBCR420_CAP_MAP:
return "YCbCr 4:2:0 Capability Map Data Block";
case DI_CTA_DATA_BLOCK_HDMI_AUDIO:
return "HDMI Audio Data Block";
case DI_CTA_DATA_BLOCK_ROOM_CONFIG:
return "Room Configuration Data Block";
case DI_CTA_DATA_BLOCK_SPEAKER_LOCATION:
return "Speaker Location Data Block";
case DI_CTA_DATA_BLOCK_INFOFRAME:
return "InfoFrame Data Block";
case DI_CTA_DATA_BLOCK_DISPLAYID_VIDEO_TIMING_VII:
return "DisplayID Type VII Video Timing Data Block";
case DI_CTA_DATA_BLOCK_DISPLAYID_VIDEO_TIMING_VIII:
return "DisplayID Type VIII Video Timing Data Block";
case DI_CTA_DATA_BLOCK_DISPLAYID_VIDEO_TIMING_X:
return "DisplayID Type X Video Timing Data Block";
case DI_CTA_DATA_BLOCK_HDMI_EDID_EXT_OVERRIDE :
return "HDMI Forum EDID Extension Override Data Block";
case DI_CTA_DATA_BLOCK_HDMI_SINK_CAP:
return "HDMI Forum Sink Capability Data Block";
}
return "Unknown CTA-861 Data Block";
}
static const char *
video_cap_over_underscan_name(enum di_cta_video_cap_over_underscan over_underscan,
const char *unknown)
{
switch (over_underscan) {
case DI_CTA_VIDEO_CAP_UNKNOWN_OVER_UNDERSCAN:
return unknown;
case DI_CTA_VIDEO_CAP_ALWAYS_OVERSCAN:
return "Always Overscanned";
case DI_CTA_VIDEO_CAP_ALWAYS_UNDERSCAN:
return "Always Underscanned";
case DI_CTA_VIDEO_CAP_BOTH_OVER_UNDERSCAN:
return "Supports both over- and underscan";
}
abort();
}
static void
print_cta(const struct di_edid_cta *cta)
{
const struct di_edid_cta_flags *cta_flags;
const struct di_cta_data_block *const *data_blocks;
const struct di_cta_data_block *data_block;
enum di_cta_data_block_tag data_block_tag;
const struct di_cta_svd *const *svds;
const struct di_cta_video_cap_block *video_cap;
const struct di_cta_colorimetry_block *colorimetry;
const struct di_cta_hdr_static_metadata_block *hdr_static_metadata;
size_t i;
const struct di_edid_detailed_timing_def *const *detailed_timing_defs;
printf(" Revision: %d\n", di_edid_cta_get_revision(cta));
cta_flags = di_edid_cta_get_flags(cta);
if (cta_flags->it_underscan) {
printf(" Underscans IT Video Formats by default\n");
}
if (cta_flags->basic_audio) {
printf(" Basic audio support\n");
}
if (cta_flags->ycc444) {
printf(" Supports YCbCr 4:4:4\n");
}
if (cta_flags->ycc422) {
printf(" Supports YCbCr 4:2:2\n");
}
printf(" Native detailed modes: %d\n", cta_flags->native_dtds);
data_blocks = di_edid_cta_get_data_blocks(cta);
for (i = 0; data_blocks[i] != NULL; i++) {
data_block = data_blocks[i];
data_block_tag = di_cta_data_block_get_tag(data_block);
printf(" %s:\n", cta_data_block_tag_name(data_block_tag));
switch (data_block_tag) {
case DI_CTA_DATA_BLOCK_VIDEO:
svds = di_cta_data_block_get_svds(data_block);
printf_cta_svds(svds);
break;
case DI_CTA_DATA_BLOCK_VIDEO_CAP:
video_cap = di_cta_data_block_get_video_cap(data_block);
printf(" YCbCr quantization: %s\n",
video_cap->selectable_ycc_quantization_range ?
"Selectable (via AVI YQ)" : "No Data");
printf(" RGB quantization: %s\n",
video_cap->selectable_ycc_quantization_range ?
"Selectable (via AVI Q)" : "No Data");
printf(" PT scan behavior: %s\n",
video_cap_over_underscan_name(video_cap->pt_over_underscan,
"No Data"));
printf(" IT scan behavior: %s\n",
video_cap_over_underscan_name(video_cap->it_over_underscan,
"IT video formats not supported"));
printf(" CE scan behavior: %s\n",
video_cap_over_underscan_name(video_cap->ce_over_underscan,
"CE video formats not supported"));
break;
case DI_CTA_DATA_BLOCK_COLORIMETRY:
colorimetry = di_cta_data_block_get_colorimetry(data_block);
if (colorimetry->xvycc_601)
printf(" xvYCC601\n");
if (colorimetry->xvycc_709)
printf(" xvYCC709\n");
if (colorimetry->sycc_601)
printf(" sYCC601\n");
if (colorimetry->opycc_601)
printf(" opYCC601\n");
if (colorimetry->oprgb)
printf(" opRGB\n");
if (colorimetry->bt2020_cycc)
printf(" BT2020cYCC\n");
if (colorimetry->bt2020_ycc)
printf(" BT2020YCC\n");
if (colorimetry->bt2020_rgb)
printf(" BT2020RGB\n");
if (colorimetry->ictcp)
printf(" ICtCp\n");
if (colorimetry->st2113_rgb)
printf(" ST2113RGB\n");
break;
case DI_CTA_DATA_BLOCK_HDR_STATIC_METADATA:
hdr_static_metadata = di_cta_data_block_get_hdr_static_metadata(data_block);
print_cta_hdr_static_metadata(hdr_static_metadata);
break;
default:
break; /* Ignore */
}
}
detailed_timing_defs = di_edid_cta_get_detailed_timing_defs(cta);
if (detailed_timing_defs[0]) {
printf(" Detailed Timing Descriptors:\n");
}
for (i = 0; detailed_timing_defs[i] != NULL; i++) {
print_detailed_timing_def(detailed_timing_defs[i]);
}
}
static void
print_displayid(const struct di_displayid *displayid)
{
printf(" Version: %d.%d\n", di_displayid_get_version(displayid),
di_displayid_get_revision(displayid));
}
static void
print_ext(const struct di_edid_ext *ext, size_t ext_index)
{
const char *tag_name;
tag_name = ext_tag_name(di_edid_ext_get_tag(ext));
printf("\n----------------\n\n");
printf("Block %zu, %s:\n", ext_index + 1, tag_name);
switch (di_edid_ext_get_tag(ext)) {
case DI_EDID_EXT_CEA:
print_cta(di_edid_ext_get_cta(ext));
break;
case DI_EDID_EXT_DISPLAYID:
print_displayid(di_edid_ext_get_displayid(ext));
break;
default:
break; /* Ignore */
}
}
static size_t
edid_checksum_index(size_t block_index)
{
return 128 * (block_index + 1) - 1;
}
static float
truncate_chromaticity_coord(float coord)
{
return floorf(coord * 10000) / 10000;
}
int
main(int argc, char *argv[])
{
FILE *in;
static uint8_t raw[32 * 1024];
size_t size = 0;
const struct di_edid *edid;
struct di_info *info;
const struct di_edid_vendor_product *vendor_product;
const struct di_edid_video_input_analog *video_input_analog;
const struct di_edid_video_input_digital *video_input_digital;
const struct di_edid_screen_size *screen_size;
float gamma;
const struct di_edid_dpms *dpms;
enum di_edid_display_color_type display_color_type;
const struct di_edid_color_encoding_formats *color_encoding_formats;
const struct di_edid_misc_features *misc_features;
const struct di_edid_chromaticity_coords *chromaticity_coords;
const struct di_edid_established_timings_i_ii *established_timings_i_ii;
const struct di_edid_standard_timing *const *standard_timings;
const struct di_edid_detailed_timing_def *const *detailed_timing_defs;
const struct di_edid_display_descriptor *const *display_descs;
const struct di_edid_ext *const *exts;
const char *failure_msg;
size_t i;
int opt;
in = stdin;
while (1) {
int option_index = 0;
opt = getopt_long(argc, argv, "h", long_options, &option_index);
if (opt == -1)
break;
switch (opt) {
case 'h':
usage();
return -1;
default:
usage();
return -1;
}
}
if (argc > 1) {
in = fopen(argv[1], "r");
if (!in) {
perror("failed to open input file");
return 1;
}
}
while (!feof(in)) {
size += fread(&raw[size], 1, sizeof(raw) - size, in);
if (ferror(in)) {
perror("fread failed");
return 1;
} else if (size >= sizeof(raw)) {
fprintf(stderr, "input too large\n");
return 1;
}
}
fclose(in);
info = di_info_parse_edid(raw, size);
if (!info) {
perror("di_edid_parse failed");
return 1;
}
edid = di_info_get_edid(info);
printf("Block 0, Base EDID:\n");
printf(" EDID Structure Version & Revision: %d.%d\n",
di_edid_get_version(edid), di_edid_get_revision(edid));
vendor_product = di_edid_get_vendor_product(edid);
printf(" Vendor & Product Identification:\n");
printf(" Manufacturer: %.3s\n", vendor_product->manufacturer);
printf(" Model: %" PRIu16 "\n", vendor_product->product);
if (vendor_product->serial != 0) {
printf(" Serial Number: %" PRIu32 "\n", vendor_product->serial);
}
if (vendor_product->model_year != 0) {
printf(" Model year: %d\n", vendor_product->model_year);
} else {
printf(" Made in: week %d of %d\n",
vendor_product->manufacture_week,
vendor_product->manufacture_year);
}
printf(" Basic Display Parameters & Features:\n");
video_input_analog = di_edid_get_video_input_analog(edid);
if (video_input_analog) {
printf(" Analog display\n");
printf(" Signal Level Standard: %s\n",
analog_signal_level_std_name(video_input_analog->signal_level_std));
switch (video_input_analog->video_setup) {
case DI_EDID_VIDEO_INPUT_ANALOG_BLANK_LEVEL_EQ_BLACK:
printf(" Blank-to-black setup/pedestal\n");
break;
case DI_EDID_VIDEO_INPUT_ANALOG_BLANK_TO_BLACK_SETUP_PEDESTAL:
printf(" Blank level equals black level\n");
break;
}
printf(" Sync:");
if (video_input_analog->sync_separate)
printf(" Separate");
if (video_input_analog->sync_composite)
printf(" Composite");
if (video_input_analog->sync_on_green)
printf(" SyncOnGreen");
if (video_input_analog->sync_serrations)
printf(" Serration");
printf("\n");
}
video_input_digital = di_edid_get_video_input_digital(edid);
if (video_input_digital) {
printf(" Digital display\n");
if (di_edid_get_revision(edid) >= 4) {
if (video_input_digital->color_bit_depth == 0) {
printf(" Color depth is undefined\n");
} else {
printf(" Bits per primary color channel: %d\n",
video_input_digital->color_bit_depth);
}
printf(" %s\n",
digital_interface_name(video_input_digital->interface));
}
if (video_input_digital->dfp1)
printf(" DFP 1.x compatible TMDS\n");
}
screen_size = di_edid_get_screen_size(edid);
if (screen_size->width_cm > 0) {
printf(" Maximum image size: %d cm x %d cm\n",
screen_size->width_cm, screen_size->height_cm);
} else if (screen_size->landscape_aspect_ratio > 0) {
printf(" Aspect ratio: %.2f (landscape)\n",
screen_size->landscape_aspect_ratio);
} else if (screen_size->portait_aspect_ratio > 0) {
printf(" Aspect ratio: %.2f (portrait)\n",
screen_size->portait_aspect_ratio);
} else {
printf(" Image size is variable\n");
}
gamma = di_edid_get_basic_gamma(edid);
if (gamma != 0) {
printf(" Gamma: %.2f\n", gamma);
} else {
printf(" Gamma is defined in an extension block\n");
}
dpms = di_edid_get_dpms(edid);
if (dpms->standby || dpms->suspend || dpms->off) {
printf(" DPMS levels:");
if (dpms->standby) {
printf(" Standby");
}
if (dpms->suspend) {
printf(" Suspend");
}
if (dpms->off) {
printf(" Off");
}
printf("\n");
}
if (!video_input_digital || di_edid_get_revision(edid) < 4) {
display_color_type = di_edid_get_display_color_type(edid);
printf(" %s\n", display_color_type_name(display_color_type));
}
color_encoding_formats = di_edid_get_color_encoding_formats(edid);
if (color_encoding_formats) {
assert(color_encoding_formats->rgb444);
printf(" Supported color formats: RGB 4:4:4");
if (color_encoding_formats->ycrcb444) {
printf(", YCrCb 4:4:4");
}
if (color_encoding_formats->ycrcb422) {
printf(", YCrCb 4:2:2");
}
printf("\n");
}
misc_features = di_edid_get_misc_features(edid);
if (misc_features->srgb_is_primary) {
printf(" Default (sRGB) color space is primary color space\n");
}
if (di_edid_get_revision(edid) >= 4) {
assert(misc_features->has_preferred_timing);
if (misc_features->preferred_timing_is_native) {
printf(" First detailed timing includes the native "
"pixel format and preferred refresh rate\n");
} else {
printf(" First detailed timing does not include the "
"native pixel format and preferred refresh rate\n");
}
} else {
if (misc_features->has_preferred_timing) {
printf(" First detailed timing is the preferred timing\n");
}
}
if (misc_features->continuous_freq) {
printf(" Display is continuous frequency\n");
}
if (misc_features->default_gtf) {
printf(" Supports GTF timings within operating range\n");
}
/* edid-decode truncates the result, but %f rounds it */
chromaticity_coords = di_edid_get_chromaticity_coords(edid);
printf(" Color Characteristics:\n");
printf(" Red : %.4f, %.4f\n",
truncate_chromaticity_coord(chromaticity_coords->red_x),
truncate_chromaticity_coord(chromaticity_coords->red_y));
printf(" Green: %.4f, %.4f\n",
truncate_chromaticity_coord(chromaticity_coords->green_x),
truncate_chromaticity_coord(chromaticity_coords->green_y));
printf(" Blue : %.4f, %.4f\n",
truncate_chromaticity_coord(chromaticity_coords->blue_x),
truncate_chromaticity_coord(chromaticity_coords->blue_y));
printf(" White: %.4f, %.4f\n",
truncate_chromaticity_coord(chromaticity_coords->white_x),
truncate_chromaticity_coord(chromaticity_coords->white_y));
printf(" Established Timings I & II:");
established_timings_i_ii = di_edid_get_established_timings_i_ii(edid);
if (!has_established_timings_i_ii(established_timings_i_ii)) {
printf(" none");
}
printf("\n");
if (established_timings_i_ii->has_720x400_70hz)
printf(" IBM : 720x400 70.081663 Hz 9:5 31.467 kHz 28.320000 MHz\n");
if (established_timings_i_ii->has_720x400_88hz)
printf(" IBM : 720x400 87.849542 Hz 9:5 39.444 kHz 35.500000 MHz\n");
if (established_timings_i_ii->has_640x480_60hz)
printf(" DMT 0x04: 640x480 59.940476 Hz 4:3 31.469 kHz 25.175000 MHz\n");
if (established_timings_i_ii->has_640x480_67hz)
printf(" Apple : 640x480 66.666667 Hz 4:3 35.000 kHz 30.240000 MHz\n");
if (established_timings_i_ii->has_640x480_72hz)
printf(" DMT 0x05: 640x480 72.808802 Hz 4:3 37.861 kHz 31.500000 MHz\n");
if (established_timings_i_ii->has_640x480_75hz)
printf(" DMT 0x06: 640x480 75.000000 Hz 4:3 37.500 kHz 31.500000 MHz\n");
if (established_timings_i_ii->has_800x600_56hz)
printf(" DMT 0x08: 800x600 56.250000 Hz 4:3 35.156 kHz 36.000000 MHz\n");
if (established_timings_i_ii->has_800x600_60hz)
printf(" DMT 0x09: 800x600 60.316541 Hz 4:3 37.879 kHz 40.000000 MHz\n");
if (established_timings_i_ii->has_800x600_72hz)
printf(" DMT 0x0a: 800x600 72.187572 Hz 4:3 48.077 kHz 50.000000 MHz\n");
if (established_timings_i_ii->has_800x600_75hz)
printf(" DMT 0x0b: 800x600 75.000000 Hz 4:3 46.875 kHz 49.500000 MHz\n");
if (established_timings_i_ii->has_832x624_75hz)
printf(" Apple : 832x624 74.551266 Hz 4:3 49.726 kHz 57.284000 MHz\n");
if (established_timings_i_ii->has_1024x768_87hz_interlaced)
printf(" DMT 0x0f: 1024x768i 86.957532 Hz 4:3 35.522 kHz 44.900000 MHz\n");
if (established_timings_i_ii->has_1024x768_60hz)
printf(" DMT 0x10: 1024x768 60.003840 Hz 4:3 48.363 kHz 65.000000 MHz\n");
if (established_timings_i_ii->has_1024x768_70hz)
printf(" DMT 0x11: 1024x768 70.069359 Hz 4:3 56.476 kHz 75.000000 MHz\n");
if (established_timings_i_ii->has_1024x768_75hz)
printf(" DMT 0x12: 1024x768 75.028582 Hz 4:3 60.023 kHz 78.750000 MHz\n");
if (established_timings_i_ii->has_1280x1024_75hz)
printf(" DMT 0x24: 1280x1024 75.024675 Hz 5:4 79.976 kHz 135.000000 MHz\n");
if (established_timings_i_ii->has_1152x870_75hz)
printf(" Apple : 1152x870 75.061550 Hz 192:145 68.681 kHz 100.000000 MHz\n");
printf(" Standard Timings:");
standard_timings = di_edid_get_standard_timings(edid);
if (standard_timings[0] == NULL) {
printf(" none");
}
printf("\n");
for (i = 0; standard_timings[i] != NULL; i++) {
print_standard_timing(standard_timings[i]);
}
printf(" Detailed Timing Descriptors:\n");
detailed_timing_defs = di_edid_get_detailed_timing_defs(edid);
for (i = 0; detailed_timing_defs[i] != NULL; i++) {
print_detailed_timing_def(detailed_timing_defs[i]);
}
display_descs = di_edid_get_display_descriptors(edid);
for (i = 0; display_descs[i] != NULL; i++) {
print_display_desc(edid, display_descs[i]);
}
exts = di_edid_get_extensions(edid);
for (i = 0; exts[i] != NULL; i++);
if (i > 0) {
printf(" Extension blocks: %zu\n", i);
}
printf("Checksum: 0x%02hhx\n", raw[edid_checksum_index(0)]);
for (i = 0; exts[i] != NULL; i++) {
print_ext(exts[i], i);
printf("Checksum: 0x%02hhx\n", raw[edid_checksum_index(i + 1)]);
}
printf("\n----------------\n\n");
failure_msg = di_info_get_failure_msg(info);
if (failure_msg) {
printf("Failures:\n\n%s", failure_msg);
printf("EDID conformity: FAIL\n");
} else {
printf("EDID conformity: PASS\n");
}
di_info_destroy(info);
return failure_msg ? 254 : 0;
}