nuclear@0: /* nuclear@0: * Copyright 2007 Red Hat, Inc. nuclear@0: * nuclear@0: * Permission is hereby granted, free of charge, to any person obtaining a nuclear@0: * copy of this software and associated documentation files (the "Software"), nuclear@0: * to deal in the Software without restriction, including without limitation nuclear@0: * on the rights to use, copy, modify, merge, publish, distribute, sub nuclear@0: * license, and/or sell copies of the Software, and to permit persons to whom nuclear@0: * the Software is furnished to do so, subject to the following conditions: nuclear@0: * nuclear@0: * The above copyright notice and this permission notice (including the next nuclear@0: * paragraph) shall be included in all copies or substantial portions of the nuclear@0: * Software. nuclear@0: * nuclear@0: * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR nuclear@0: * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, nuclear@0: * FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN NO EVENT SHALL nuclear@0: * THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER nuclear@0: * IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN nuclear@0: * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. nuclear@0: */ nuclear@0: nuclear@0: /* Author: Soren Sandmann */ nuclear@0: #include "edid.h" nuclear@0: #include nuclear@0: #include nuclear@0: #include nuclear@0: #include nuclear@0: nuclear@0: nuclear@0: static int get_bit(int in, int bit) { nuclear@0: return (in & (1 << bit)) >> bit; nuclear@0: } nuclear@0: nuclear@0: static int get_bits(int in, int begin, int end) { nuclear@0: int mask = (1 << (end - begin + 1)) - 1; nuclear@0: nuclear@0: return (in >> begin) & mask; nuclear@0: } nuclear@0: nuclear@0: static bool decode_header(const uint8_t *edid) { nuclear@0: if (memcmp(edid, "\x00\xff\xff\xff\xff\xff\xff\x00", 8) == 0) nuclear@0: return true; nuclear@0: return false; nuclear@0: } nuclear@0: nuclear@0: static int decode_vendor_and_product_identification(const uint8_t *edid, MonitorInfo *info) { nuclear@0: nuclear@0: /* Manufacturer Code */ nuclear@0: info->manufacturer_code[0] = get_bits(edid[0x08], 2, 6); nuclear@0: info->manufacturer_code[1] = get_bits(edid[0x08], 0, 1) << 3; nuclear@0: info->manufacturer_code[1] |= get_bits(edid[0x09], 5, 7); nuclear@0: info->manufacturer_code[2] = get_bits(edid[0x09], 0, 4); nuclear@0: info->manufacturer_code[3] = '\0'; nuclear@0: nuclear@0: info->manufacturer_code[0] += 'A' - 1; nuclear@0: info->manufacturer_code[1] += 'A' - 1; nuclear@0: info->manufacturer_code[2] += 'A' - 1; nuclear@0: nuclear@0: /* Product Code */ nuclear@0: info->product_code = edid[0x0b] << 8 | edid[0x0a]; nuclear@0: nuclear@0: /* Serial Number */ nuclear@0: info->serial_number = edid[0x0c] | edid[0x0d] << 8 | edid[0x0e] << 16 | edid[0x0f] << 24; nuclear@0: nuclear@0: /* Week and Year */ nuclear@0: bool is_model_year = false; nuclear@0: switch (edid[0x10]) { nuclear@0: case 0x00: nuclear@0: info->production_week = -1; nuclear@0: break; nuclear@0: nuclear@0: case 0xff: nuclear@0: info->production_week = -1; nuclear@0: is_model_year = true; nuclear@0: break; nuclear@0: nuclear@0: default: nuclear@0: info->production_week = edid[0x10]; nuclear@0: break; nuclear@0: } nuclear@0: nuclear@0: if (is_model_year) { nuclear@0: info->production_year = -1; nuclear@0: info->model_year = 1990 + edid[0x11]; nuclear@0: } else { nuclear@0: info->production_year = 1990 + edid[0x11]; nuclear@0: info->model_year = -1; nuclear@0: } nuclear@0: nuclear@0: return true; nuclear@0: } nuclear@0: nuclear@0: static bool decode_edid_version(const uint8_t *edid, MonitorInfo *info) { nuclear@0: info->major_version = edid[0x12]; nuclear@0: info->minor_version = edid[0x13]; nuclear@0: return true; nuclear@0: } nuclear@0: nuclear@0: static bool decode_display_parameters(const uint8_t *edid, MonitorInfo *info) { nuclear@0: /* Digital vs Analog */ nuclear@0: info->is_digital = get_bit(edid[0x14], 7); nuclear@0: nuclear@0: if (info->is_digital) { nuclear@0: static const int bit_depth[8] = { -1, 6, 8, 10, 12, 14, 16, -1 }; nuclear@0: static const Interface interfaces[6] = { UNDEFINED, DVI, HDMI_A, HDMI_B, MDDI, DISPLAY_PORT }; nuclear@0: nuclear@0: int bits = get_bits(edid[0x14], 4, 6); nuclear@0: info->connector.digital.bits_per_primary = bit_depth[bits]; nuclear@0: nuclear@0: bits = get_bits(edid[0x14], 0, 3); nuclear@0: if (bits <= 5) nuclear@0: info->connector.digital.interface = interfaces[bits]; nuclear@0: else nuclear@0: info->connector.digital.interface = UNDEFINED; nuclear@0: } else { nuclear@0: int bits = get_bits(edid[0x14], 5, 6); nuclear@0: static const double levels[][3] = { // nuclear@0: { 0.7, 0.3, 1.0 }, // nuclear@0: { 0.714, 0.286, 1.0 }, // nuclear@0: { 1.0, 0.4, 1.4 }, // nuclear@0: { 0.7, 0.0, 0.7 }, // nuclear@0: }; nuclear@0: nuclear@0: info->connector.analog.video_signal_level = levels[bits][0]; nuclear@0: info->connector.analog.sync_signal_level = levels[bits][1]; nuclear@0: info->connector.analog.total_signal_level = levels[bits][2]; nuclear@0: info->connector.analog.blank_to_black = get_bit(edid[0x14], 4); nuclear@0: info->connector.analog.separate_hv_sync = get_bit(edid[0x14], 3); nuclear@0: info->connector.analog.composite_sync_on_h = get_bit(edid[0x14], 2); nuclear@0: info->connector.analog.composite_sync_on_green = get_bit(edid[0x14], 1); nuclear@0: info->connector.analog.serration_on_vsync = get_bit(edid[0x14], 0); nuclear@0: } nuclear@0: nuclear@0: /* Screen Size / Aspect Ratio */ nuclear@0: if (edid[0x15] == 0 && edid[0x16] == 0) { nuclear@0: info->width_mm = -1; nuclear@0: info->height_mm = -1; nuclear@0: info->aspect_ratio = -1.0; nuclear@0: } else if (edid[0x16] == 0) { nuclear@0: info->width_mm = -1; nuclear@0: info->height_mm = -1; nuclear@0: info->aspect_ratio = 100.0 / (edid[0x15] + 99); nuclear@0: } else if (edid[0x15] == 0) { nuclear@0: info->width_mm = -1; nuclear@0: info->height_mm = -1; nuclear@0: info->aspect_ratio = 100.0 / (edid[0x16] + 99); nuclear@0: info->aspect_ratio = 1 / info->aspect_ratio; /* portrait */ nuclear@0: } else { nuclear@0: info->width_mm = 10 * edid[0x15]; nuclear@0: info->height_mm = 10 * edid[0x16]; nuclear@0: } nuclear@0: nuclear@0: /* Gamma */ nuclear@0: if (edid[0x17] == 0xFF) nuclear@0: info->gamma = -1.0; nuclear@0: else nuclear@0: info->gamma = (edid[0x17] + 100.0) / 100.0; nuclear@0: nuclear@0: /* Features */ nuclear@0: info->standby = get_bit(edid[0x18], 7); nuclear@0: info->suspend = get_bit(edid[0x18], 6); nuclear@0: info->active_off = get_bit(edid[0x18], 5); nuclear@0: nuclear@0: if (info->is_digital) { nuclear@0: info->connector.digital.rgb444 = 1; nuclear@0: if (get_bit(edid[0x18], 3)) nuclear@0: info->connector.digital.ycrcb444 = 1; nuclear@0: if (get_bit(edid[0x18], 4)) nuclear@0: info->connector.digital.ycrcb422 = 1; nuclear@0: } else { nuclear@0: int bits = get_bits(edid[0x18], 3, 4); nuclear@0: ColorType color_type[4] = { MONOCHROME, RGB, OTHER_COLOR, UNDEFINED_COLOR }; nuclear@0: nuclear@0: info->connector.analog.color_type = color_type[bits]; nuclear@0: } nuclear@0: nuclear@0: info->srgb_is_standard = get_bit(edid[0x18], 2); nuclear@0: nuclear@0: /* In 1.3 this is called "has preferred timing" */ nuclear@0: info->preferred_timing_includes_native = get_bit(edid[0x18], 1); nuclear@0: nuclear@0: /* FIXME: In 1.3 this indicates whether the monitor accepts GTF */ nuclear@0: info->continuous_frequency = get_bit(edid[0x18], 0); nuclear@0: return true; nuclear@0: } nuclear@0: nuclear@0: static double decode_fraction(int high, int low) { nuclear@0: double result = 0.0; nuclear@0: high = (high << 2) | low; nuclear@0: for (int i = 0; i < 10; ++i) nuclear@0: result += get_bit(high, i) * pow(2, i - 10); nuclear@0: return result; nuclear@0: } nuclear@0: nuclear@0: static bool decode_color_characteristics(const uint8_t *edid, MonitorInfo *info) { nuclear@0: info->red_x = decode_fraction(edid[0x1b], get_bits(edid[0x19], 6, 7)); nuclear@0: info->red_y = decode_fraction(edid[0x1c], get_bits(edid[0x19], 5, 4)); nuclear@0: info->green_x = decode_fraction(edid[0x1d], get_bits(edid[0x19], 2, 3)); nuclear@0: info->green_y = decode_fraction(edid[0x1e], get_bits(edid[0x19], 0, 1)); nuclear@0: info->blue_x = decode_fraction(edid[0x1f], get_bits(edid[0x1a], 6, 7)); nuclear@0: info->blue_y = decode_fraction(edid[0x20], get_bits(edid[0x1a], 4, 5)); nuclear@0: info->white_x = decode_fraction(edid[0x21], get_bits(edid[0x1a], 2, 3)); nuclear@0: info->white_y = decode_fraction(edid[0x22], get_bits(edid[0x1a], 0, 1)); nuclear@0: nuclear@0: return true; nuclear@0: } nuclear@0: nuclear@0: static bool decode_established_timings(const uint8_t *edid, MonitorInfo *info) { nuclear@0: static const Timing established[][8] = { // nuclear@0: { { 800, 600, 60 }, { 800, 600, 56 }, // nuclear@0: { 640, 480, 75 }, { 640, 480, 72 }, // nuclear@0: { 640, 480, 67 }, { 640, 480, 60 }, // nuclear@0: { 720, 400, 88 }, { 720, 400, 70 } }, // nuclear@0: { { 1280, 1024, 75 }, { 1024, 768, 75 }, // nuclear@0: { 1024, 768, 70 }, { 1024, 768, 60 }, // nuclear@0: { 1024, 768, 87 }, { 832, 624, 75 }, // nuclear@0: { 800, 600, 75 }, { 800, 600, 72 } }, // nuclear@0: { { 0, 0, 0 }, { 0, 0, 0 }, { 0, 0, 0 }, { 0, 0, 0 }, // nuclear@0: { 0, 0, 0 }, { 0, 0, 0 }, { 0, 0, 0 }, { 1152, 870, 75 } }, // nuclear@0: }; nuclear@0: nuclear@0: int idx = 0; nuclear@0: for (int i = 0; i < 3; ++i) { nuclear@0: for (int j = 0; j < 8; ++j) { nuclear@0: int byte = edid[0x23 + i]; nuclear@0: nuclear@0: if (get_bit(byte, j) && established[i][j].frequency != 0) nuclear@0: info->established[idx++] = established[i][j]; nuclear@0: } nuclear@0: } nuclear@0: return true; nuclear@0: } nuclear@0: nuclear@0: static bool decode_standard_timings(const uint8_t *edid, MonitorInfo *info) { nuclear@0: int i; nuclear@0: nuclear@0: for (i = 0; i < 8; i++) { nuclear@0: int first = edid[0x26 + 2 * i]; nuclear@0: int second = edid[0x27 + 2 * i]; nuclear@0: nuclear@0: if (first != 0x01 && second != 0x01) { nuclear@0: int w = 8 * (first + 31); nuclear@0: int h = 0; nuclear@0: nuclear@0: switch (get_bits(second, 6, 7)) { nuclear@0: case 0x00: nuclear@0: h = (w / 16) * 10; nuclear@0: break; nuclear@0: case 0x01: nuclear@0: h = (w / 4) * 3; nuclear@0: break; nuclear@0: case 0x02: nuclear@0: h = (w / 5) * 4; nuclear@0: break; nuclear@0: case 0x03: nuclear@0: h = (w / 16) * 9; nuclear@0: break; nuclear@0: } nuclear@0: nuclear@0: info->standard[i].width = w; nuclear@0: info->standard[i].height = h; nuclear@0: info->standard[i].frequency = get_bits(second, 0, 5) + 60; nuclear@0: } nuclear@0: } nuclear@0: nuclear@0: return true; nuclear@0: } nuclear@0: nuclear@0: static void decode_lf_string(const uint8_t *s, int n_chars, char *result) { nuclear@0: int i; nuclear@0: for (i = 0; i < n_chars; ++i) { nuclear@0: if (s[i] == 0x0a) { nuclear@0: *result++ = '\0'; nuclear@0: break; nuclear@0: } else if (s[i] == 0x00) { nuclear@0: /* Convert embedded 0's to spaces */ nuclear@0: *result++ = ' '; nuclear@0: } else { nuclear@0: *result++ = s[i]; nuclear@0: } nuclear@0: } nuclear@0: } nuclear@0: nuclear@0: static void decode_display_descriptor(const uint8_t *desc, MonitorInfo *info) { nuclear@0: switch (desc[0x03]) { nuclear@0: case 0xFC: nuclear@0: decode_lf_string(desc + 5, 13, info->dsc_product_name); nuclear@0: break; nuclear@0: case 0xFF: nuclear@0: decode_lf_string(desc + 5, 13, info->dsc_serial_number); nuclear@0: break; nuclear@0: case 0xFE: nuclear@0: decode_lf_string(desc + 5, 13, info->dsc_string); nuclear@0: break; nuclear@0: case 0xFD: nuclear@0: /* Range Limits */ nuclear@0: break; nuclear@0: case 0xFB: nuclear@0: /* Color Point */ nuclear@0: break; nuclear@0: case 0xFA: nuclear@0: /* Timing Identifications */ nuclear@0: break; nuclear@0: case 0xF9: nuclear@0: /* Color Management */ nuclear@0: break; nuclear@0: case 0xF8: nuclear@0: /* Timing Codes */ nuclear@0: break; nuclear@0: case 0xF7: nuclear@0: /* Established Timings */ nuclear@0: break; nuclear@0: case 0x10: nuclear@0: break; nuclear@0: } nuclear@0: } nuclear@0: nuclear@0: static void decode_detailed_timing(const uint8_t *timing, DetailedTiming *detailed) { nuclear@0: int bits; nuclear@0: StereoType stereo[] = { // nuclear@0: NO_STEREO, NO_STEREO, // nuclear@0: FIELD_RIGHT, FIELD_LEFT, // nuclear@0: TWO_WAY_RIGHT_ON_EVEN, TWO_WAY_LEFT_ON_EVEN, // nuclear@0: FOUR_WAY_INTERLEAVED, // nuclear@0: SIDE_BY_SIDE // nuclear@0: }; nuclear@0: nuclear@0: detailed->pixel_clock = (timing[0x00] | timing[0x01] << 8) * 10000; nuclear@0: detailed->h_addr = timing[0x02] | ((timing[0x04] & 0xf0) << 4); nuclear@0: detailed->h_blank = timing[0x03] | ((timing[0x04] & 0x0f) << 8); nuclear@0: detailed->v_addr = timing[0x05] | ((timing[0x07] & 0xf0) << 4); nuclear@0: detailed->v_blank = timing[0x06] | ((timing[0x07] & 0x0f) << 8); nuclear@0: detailed->h_front_porch = timing[0x08] | get_bits(timing[0x0b], 6, 7) << 8; nuclear@0: detailed->h_sync = timing[0x09] | get_bits(timing[0x0b], 4, 5) << 8; nuclear@0: detailed->v_front_porch = get_bits(timing[0x0a], 4, 7) | get_bits(timing[0x0b], 2, 3) << 4; nuclear@0: detailed->v_sync = get_bits(timing[0x0a], 0, 3) | get_bits(timing[0x0b], 0, 1) << 4; nuclear@0: detailed->width_mm = timing[0x0c] | get_bits(timing[0x0e], 4, 7) << 8; nuclear@0: detailed->height_mm = timing[0x0d] | get_bits(timing[0x0e], 0, 3) << 8; nuclear@0: detailed->right_border = timing[0x0f]; nuclear@0: detailed->top_border = timing[0x10]; nuclear@0: detailed->interlaced = get_bit(timing[0x11], 7); nuclear@0: nuclear@0: /* Stereo */ nuclear@0: bits = get_bits(timing[0x11], 5, 6) << 1 | get_bit(timing[0x11], 0); nuclear@0: detailed->stereo = stereo[bits]; nuclear@0: nuclear@0: /* Sync */ nuclear@0: bits = timing[0x11]; nuclear@0: nuclear@0: detailed->digital_sync = get_bit(bits, 4); nuclear@0: if (detailed->digital_sync) { nuclear@0: detailed->connector.digital.composite = !get_bit(bits, 3); nuclear@0: if (detailed->connector.digital.composite) { nuclear@0: detailed->connector.digital.serrations = get_bit(bits, 2); nuclear@0: detailed->connector.digital.negative_vsync = 0; nuclear@0: } else { nuclear@0: detailed->connector.digital.serrations = 0; nuclear@0: detailed->connector.digital.negative_vsync = !get_bit(bits, 2); nuclear@0: } nuclear@0: detailed->connector.digital.negative_hsync = !get_bit(bits, 0); nuclear@0: } else { nuclear@0: detailed->connector.analog.bipolar = get_bit(bits, 3); nuclear@0: detailed->connector.analog.serrations = get_bit(bits, 2); nuclear@0: detailed->connector.analog.sync_on_green = !get_bit(bits, 1); nuclear@0: } nuclear@0: } nuclear@0: nuclear@0: static bool decode_descriptors(const uint8_t *edid, MonitorInfo *info) { nuclear@0: int timing_idx = 0; nuclear@0: for (int i = 0; i < 4; ++i) { nuclear@0: int index = 0x36 + i * 18; nuclear@0: if (edid[index + 0] == 0x00 && edid[index + 1] == 0x00) { nuclear@0: decode_display_descriptor(edid + index, info); nuclear@0: } else { nuclear@0: decode_detailed_timing(edid + index, &(info->detailed_timings[timing_idx++])); nuclear@0: } nuclear@0: } nuclear@0: info->n_detailed_timings = timing_idx; nuclear@0: return true; nuclear@0: } nuclear@0: nuclear@0: static void decode_check_sum(const uint8_t *edid, MonitorInfo *info) { nuclear@0: uint8_t check = 0; nuclear@0: for (int i = 0; i < 128; ++i) nuclear@0: check += edid[i]; nuclear@0: info->checksum = check; nuclear@0: } nuclear@0: nuclear@0: MonitorInfo * decode_edid(const uint8_t *edid) { nuclear@0: MonitorInfo *info = new MonitorInfo(); nuclear@0: decode_check_sum(edid, info); nuclear@0: if (decode_header(edid) && // nuclear@0: decode_vendor_and_product_identification(edid, info) && // nuclear@0: decode_edid_version(edid, info) && // nuclear@0: decode_display_parameters(edid, info) && // nuclear@0: decode_color_characteristics(edid, info) && // nuclear@0: decode_established_timings(edid, info) && // nuclear@0: decode_standard_timings(edid, info) && // nuclear@0: decode_descriptors(edid, info)) { nuclear@0: return info; nuclear@0: } else { nuclear@0: delete info; nuclear@0: return 0; nuclear@0: } nuclear@0: } nuclear@0: nuclear@0: static uint8_t * get_property(Display *dpy, RROutput output, Atom atom, int *len) { nuclear@0: unsigned char *prop; nuclear@0: int actual_format; nuclear@0: unsigned long nitems, bytes_after; nuclear@0: Atom actual_type; nuclear@0: uint8_t *result = NULL; nuclear@0: nuclear@0: XRRGetOutputProperty(dpy, output, atom, 0, 100, False, False, nuclear@0: AnyPropertyType, &actual_type, &actual_format, &nitems, &bytes_after, &prop); nuclear@0: nuclear@0: if (actual_type == XA_INTEGER && actual_format == 8) { nuclear@0: result = new uint8_t[nitems]; nuclear@0: memcpy(result, prop, nitems); nuclear@0: if (len) nuclear@0: *len = nitems; nuclear@0: } nuclear@0: XFree(prop); nuclear@0: return result; nuclear@0: } nuclear@0: nuclear@0: MonitorInfo * read_edid_data(Display * disp, RROutput id) { nuclear@0: int len; nuclear@0: Atom edid_atom = XInternAtom(disp, "EDID", false); nuclear@0: uint8_t *edid = get_property(disp, id, edid_atom, &len); nuclear@0: if (!edid) { nuclear@0: edid_atom = XInternAtom(disp, "EDID_DATA", false); nuclear@0: edid = get_property(disp, id, edid_atom, &len); nuclear@0: } nuclear@0: nuclear@0: MonitorInfo * result = 0; nuclear@0: if (edid) { nuclear@0: if (len % 128 == 0) { nuclear@0: result = decode_edid(edid); nuclear@0: } nuclear@0: delete[] edid; nuclear@0: } nuclear@0: nuclear@0: return result; nuclear@0: }