/* * Copyright 1998 by Egbert Eich * Copyright 2007 Red Hat, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. * * interpret_edid.c: interpret a primary EDID block */ #ifdef HAVE_XORG_CONFIG_H #include #endif #include "misc.h" #include "xf86.h" #include "xf86_OSproc.h" #define _PARSE_EDID_ #include "xf86DDC.h" #include static void get_vendor_section(Uchar *, struct vendor *); static void get_version_section(Uchar *, struct edid_version *); static void get_display_section(Uchar *, struct disp_features *, struct edid_version *); static void get_established_timing_section(Uchar *, struct established_timings *); static void get_std_timing_section(Uchar *, struct std_timings *, struct edid_version *); static void fetch_detailed_block(Uchar * c, struct edid_version *ver, struct detailed_monitor_section *det_mon); static void get_dt_md_section(Uchar *, struct edid_version *, struct detailed_monitor_section *det_mon); static void copy_string(Uchar *, Uchar *); static void get_dst_timing_section(Uchar *, struct std_timings *, struct edid_version *); static void get_monitor_ranges(Uchar *, struct monitor_ranges *); static void get_whitepoint_section(Uchar *, struct whitePoints *); static void get_detailed_timing_section(Uchar *, struct detailed_timings *); static Bool validate_version(int scrnIndex, struct edid_version *); static void find_ranges_section(struct detailed_monitor_section *det, void *ranges) { if (det->type == DS_RANGES && det->section.ranges.max_clock) *(struct monitor_ranges **) ranges = &det->section.ranges; } static void find_max_detailed_clock(struct detailed_monitor_section *det, void *ret) { if (det->type == DT) { *(int *) ret = max(*((int *) ret), det->section.d_timings.clock); } } static void handle_edid_quirks(xf86MonPtr m) { struct monitor_ranges *ranges = NULL; /* * max_clock is only encoded in EDID in tens of MHz, so occasionally we * find a monitor claiming a max of 160 with a mode requiring 162, or * similar. Strictly we should refuse to round up too far, but let's * see how well this works. */ /* Try to find Monitor Range and max clock, then re-set range value */ xf86ForEachDetailedBlock(m, find_ranges_section, &ranges); if (ranges && ranges->max_clock) { int clock = 0; xf86ForEachDetailedBlock(m, find_max_detailed_clock, &clock); if (clock && (ranges->max_clock * 1e6 < clock)) { xf86Msg(X_WARNING, "EDID timing clock %.2f exceeds claimed max " "%dMHz, fixing\n", clock / 1.0e6, ranges->max_clock); ranges->max_clock = (clock + 999999) / 1e6; } } } struct det_hv_parameter { int real_hsize; int real_vsize; float target_aspect; }; static void handle_detailed_hvsize(struct detailed_monitor_section *det_mon, void *data) { struct det_hv_parameter *p = (struct det_hv_parameter *) data; float timing_aspect; if (det_mon->type == DT) { struct detailed_timings *timing; timing = &det_mon->section.d_timings; if (!timing->v_size) return; timing_aspect = (float) timing->h_size / timing->v_size; if (fabs(1 - (timing_aspect / p->target_aspect)) < 0.05) { p->real_hsize = max(p->real_hsize, timing->h_size); p->real_vsize = max(p->real_vsize, timing->v_size); } } } static void encode_aspect_ratio(xf86MonPtr m) { /* * some monitors encode the aspect ratio instead of the physical size. * try to find the largest detailed timing that matches that aspect * ratio and use that to fill in the feature section. */ if ((m->features.hsize == 16 && m->features.vsize == 9) || (m->features.hsize == 16 && m->features.vsize == 10) || (m->features.hsize == 4 && m->features.vsize == 3) || (m->features.hsize == 5 && m->features.vsize == 4)) { struct det_hv_parameter p; p.real_hsize = 0; p.real_vsize = 0; p.target_aspect = (float) m->features.hsize / m->features.vsize; xf86ForEachDetailedBlock(m, handle_detailed_hvsize, &p); if (!p.real_hsize || !p.real_vsize) { m->features.hsize = m->features.vsize = 0; } else if ((m->features.hsize * 10 == p.real_hsize) && (m->features.vsize * 10 == p.real_vsize)) { /* exact match is just unlikely, should do a better check though */ m->features.hsize = m->features.vsize = 0; } else { /* convert mm to cm */ m->features.hsize = (p.real_hsize + 5) / 10; m->features.vsize = (p.real_vsize + 5) / 10; } xf86Msg(X_INFO, "Quirked EDID physical size to %dx%d cm\n", m->features.hsize, m->features.vsize); } } xf86MonPtr xf86InterpretEDID(int scrnIndex, Uchar * block) { xf86MonPtr m; if (!block) return NULL; if (!(m = xnfcalloc(1, sizeof(xf86Monitor)))) return NULL; m->scrnIndex = scrnIndex; m->rawData = block; get_vendor_section(SECTION(VENDOR_SECTION, block), &m->vendor); get_version_section(SECTION(VERSION_SECTION, block), &m->ver); if (!validate_version(scrnIndex, &m->ver)) goto error; get_display_section(SECTION(DISPLAY_SECTION, block), &m->features, &m->ver); get_established_timing_section(SECTION(ESTABLISHED_TIMING_SECTION, block), &m->timings1); get_std_timing_section(SECTION(STD_TIMING_SECTION, block), m->timings2, &m->ver); get_dt_md_section(SECTION(DET_TIMING_SECTION, block), &m->ver, m->det_mon); m->no_sections = (int) *(char *) SECTION(NO_EDID, block); handle_edid_quirks(m); encode_aspect_ratio(m); return m; error: free(m); return NULL; } static int get_cea_detail_timing(Uchar * blk, xf86MonPtr mon, struct detailed_monitor_section *det_mon) { int dt_num; int dt_offset = ((struct cea_ext_body *) blk)->dt_offset; dt_num = 0; if (dt_offset < CEA_EXT_MIN_DATA_OFFSET) return dt_num; for (; dt_offset < (CEA_EXT_MAX_DATA_OFFSET - DET_TIMING_INFO_LEN) && dt_num < CEA_EXT_DET_TIMING_NUM; _NEXT_DT_MD_SECTION(dt_offset)) { fetch_detailed_block(blk + dt_offset, &mon->ver, det_mon + dt_num); dt_num = dt_num + 1; } return dt_num; } static void handle_cea_detail_block(Uchar * ext, xf86MonPtr mon, handle_detailed_fn fn, void *data) { int i; struct detailed_monitor_section det_mon[CEA_EXT_DET_TIMING_NUM]; int det_mon_num; det_mon_num = get_cea_detail_timing(ext, mon, det_mon); for (i = 0; i < det_mon_num; i++) fn(det_mon + i, data); } void xf86ForEachDetailedBlock(xf86MonPtr mon, handle_detailed_fn fn, void *data) { int i; Uchar *ext; if (mon == NULL) return; for (i = 0; i < DET_TIMINGS; i++) fn(mon->det_mon + i, data); for (i = 0; i < mon->no_sections; i++) { ext = mon->rawData + EDID1_LEN * (i + 1); switch (ext[EXT_TAG]) { case CEA_EXT: handle_cea_detail_block(ext, mon, fn, data); break; case VTB_EXT: case DI_EXT: case LS_EXT: case MI_EXT: break; } } } static struct cea_data_block * extract_cea_data_block(Uchar * ext, int data_type) { struct cea_ext_body *cea; struct cea_data_block *data_collection; struct cea_data_block *data_end; cea = (struct cea_ext_body *) ext; if (cea->dt_offset <= CEA_EXT_MIN_DATA_OFFSET) return NULL; data_collection = &cea->data_collection; data_end = (struct cea_data_block *) (cea->dt_offset + ext); for (; data_collection < data_end;) { if (data_type == data_collection->tag) { return data_collection; } data_collection = (void *) ((unsigned char *) data_collection + data_collection->len + 1); } return NULL; } static void handle_cea_video_block(Uchar * ext, handle_video_fn fn, void *data) { struct cea_video_block *video; struct cea_video_block *video_end; struct cea_data_block *data_collection; data_collection = extract_cea_data_block(ext, CEA_VIDEO_BLK); if (data_collection == NULL) return; video = &data_collection->u.video; video_end = (struct cea_video_block *) ((Uchar *) video + data_collection->len); for (; video < video_end; video = video + 1) { fn(video, data); } } void xf86ForEachVideoBlock(xf86MonPtr mon, handle_video_fn fn, void *data) { int i; Uchar *ext; if (mon == NULL) return; for (i = 0; i < mon->no_sections; i++) { ext = mon->rawData + EDID1_LEN * (i + 1); switch (ext[EXT_TAG]) { case CEA_EXT: handle_cea_video_block(ext, fn, data); break; case VTB_EXT: case DI_EXT: case LS_EXT: case MI_EXT: break; } } } static Bool cea_db_offsets(Uchar *cea, int *start, int *end) { /* Data block offset in CEA extension block */ *start = CEA_EXT_MIN_DATA_OFFSET; *end = cea[2]; if (*end == 0) *end = CEA_EXT_MAX_DATA_OFFSET; if (*end < CEA_EXT_MIN_DATA_OFFSET || *end > CEA_EXT_MAX_DATA_OFFSET) return FALSE; return TRUE; } static int cea_db_len(Uchar *db) { return db[0] & 0x1f; } static int cea_db_tag(Uchar *db) { return db[0] >> 5; } typedef void (*handle_cea_db_fn) (Uchar *, void *); static void cea_for_each_db(xf86MonPtr mon, handle_cea_db_fn fn, void *data) { int i; if (!mon) return; if (!(mon->flags & EDID_COMPLETE_RAWDATA)) return; if (!mon->no_sections) return; if (!mon->rawData) return; for (i = 0; i < mon->no_sections; i++) { int start, end, offset; Uchar *ext; ext = mon->rawData + EDID1_LEN * (i + 1); if (ext[EXT_TAG] != CEA_EXT) continue; if (!cea_db_offsets(ext, &start, &end)) continue; for (offset = start; offset < end && offset + cea_db_len(&ext[offset]) < end; offset += cea_db_len(&ext[offset]) + 1) fn(&ext[offset], data); } } struct find_hdmi_block_data { struct cea_data_block *hdmi; }; static void find_hdmi_block(Uchar *db, void *data) { struct find_hdmi_block_data *result = data; int oui; if (cea_db_tag(db) != CEA_VENDOR_BLK) return; if (cea_db_len(db) < 5) return; oui = (db[3] << 16) | (db[2] << 8) | db[1]; if (oui == IEEE_ID_HDMI) result->hdmi = (struct cea_data_block *)db; } struct cea_data_block *xf86MonitorFindHDMIBlock(xf86MonPtr mon) { struct find_hdmi_block_data result = { NULL }; cea_for_each_db(mon, find_hdmi_block, &result); return result.hdmi; } xf86MonPtr xf86InterpretEEDID(int scrnIndex, Uchar * block) { xf86MonPtr m; m = xf86InterpretEDID(scrnIndex, block); if (!m) return NULL; /* extension parse */ return m; } static void get_vendor_section(Uchar * c, struct vendor *r) { r->name[0] = L1; r->name[1] = L2; r->name[2] = L3; r->name[3] = '\0'; r->prod_id = PROD_ID; r->serial = SERIAL_NO; r->week = WEEK; r->year = YEAR; } static void get_version_section(Uchar * c, struct edid_version *r) { r->version = VERSION; r->revision = REVISION; } static void get_display_section(Uchar * c, struct disp_features *r, struct edid_version *v) { r->input_type = INPUT_TYPE; if (!DIGITAL(r->input_type)) { r->input_voltage = INPUT_VOLTAGE; r->input_setup = SETUP; r->input_sync = SYNC; } else if (v->revision == 2 || v->revision == 3) { r->input_dfp = DFP; } else if (v->revision >= 4) { r->input_bpc = BPC; r->input_interface = DIGITAL_INTERFACE; } r->hsize = HSIZE_MAX; r->vsize = VSIZE_MAX; r->gamma = GAMMA; r->dpms = DPMS; r->display_type = DISPLAY_TYPE; r->msc = MSC; r->redx = REDX; r->redy = REDY; r->greenx = GREENX; r->greeny = GREENY; r->bluex = BLUEX; r->bluey = BLUEY; r->whitex = WHITEX; r->whitey = WHITEY; } static void get_established_timing_section(Uchar * c, struct established_timings *r) { r->t1 = T1; r->t2 = T2; r->t_manu = T_MANU; } static void get_cvt_timing_section(Uchar * c, struct cvt_timings *r) { int i; for (i = 0; i < 4; i++) { if (c[0] && c[1] && c[2]) { r[i].height = (c[0] + ((c[1] & 0xF0) << 8) + 1) * 2; switch (c[1] & 0xc0) { case 0x00: r[i].width = r[i].height * 4 / 3; break; case 0x40: r[i].width = r[i].height * 16 / 9; break; case 0x80: r[i].width = r[i].height * 16 / 10; break; case 0xc0: r[i].width = r[i].height * 15 / 9; break; } switch (c[2] & 0x60) { case 0x00: r[i].rate = 50; break; case 0x20: r[i].rate = 60; break; case 0x40: r[i].rate = 75; break; case 0x60: r[i].rate = 85; break; } r[i].rates = c[2] & 0x1f; } else { return; } c += 3; } } static void get_std_timing_section(Uchar * c, struct std_timings *r, struct edid_version *v) { int i; for (i = 0; i < STD_TIMINGS; i++) { if (VALID_TIMING) { r[i].hsize = HSIZE1; VSIZE1(r[i].vsize); r[i].refresh = REFRESH_R; r[i].id = STD_TIMING_ID; } else { r[i].hsize = r[i].vsize = r[i].refresh = r[i].id = 0; } NEXT_STD_TIMING; } } static const unsigned char empty_block[18]; static void fetch_detailed_block(Uchar * c, struct edid_version *ver, struct detailed_monitor_section *det_mon) { if (ver->version == 1 && ver->revision >= 1 && IS_MONITOR_DESC) { switch (MONITOR_DESC_TYPE) { case SERIAL_NUMBER: det_mon->type = DS_SERIAL; copy_string(c, det_mon->section.serial); break; case ASCII_STR: det_mon->type = DS_ASCII_STR; copy_string(c, det_mon->section.ascii_data); break; case MONITOR_RANGES: det_mon->type = DS_RANGES; get_monitor_ranges(c, &det_mon->section.ranges); break; case MONITOR_NAME: det_mon->type = DS_NAME; copy_string(c, det_mon->section.name); break; case ADD_COLOR_POINT: det_mon->type = DS_WHITE_P; get_whitepoint_section(c, det_mon->section.wp); break; case ADD_STD_TIMINGS: det_mon->type = DS_STD_TIMINGS; get_dst_timing_section(c, det_mon->section.std_t, ver); break; case COLOR_MANAGEMENT_DATA: det_mon->type = DS_CMD; break; case CVT_3BYTE_DATA: det_mon->type = DS_CVT; get_cvt_timing_section(c, det_mon->section.cvt); break; case ADD_EST_TIMINGS: det_mon->type = DS_EST_III; memcpy(det_mon->section.est_iii, c + 6, 6); break; case ADD_DUMMY: det_mon->type = DS_DUMMY; break; default: det_mon->type = DS_UNKOWN; break; } if (c[3] <= 0x0F && memcmp(c, empty_block, sizeof(empty_block))) { det_mon->type = DS_VENDOR + c[3]; } } else { det_mon->type = DT; get_detailed_timing_section(c, &det_mon->section.d_timings); } } static void get_dt_md_section(Uchar * c, struct edid_version *ver, struct detailed_monitor_section *det_mon) { int i; for (i = 0; i < DET_TIMINGS; i++) { fetch_detailed_block(c, ver, det_mon + i); NEXT_DT_MD_SECTION; } } static void copy_string(Uchar * c, Uchar * s) { int i; c = c + 5; for (i = 0; (i < 13 && *c != 0x0A); i++) *(s++) = *(c++); *s = 0; while (i-- && (*--s == 0x20)) *s = 0; } static void get_dst_timing_section(Uchar * c, struct std_timings *t, struct edid_version *v) { int j; c = c + 5; for (j = 0; j < 5; j++) { t[j].hsize = HSIZE1; VSIZE1(t[j].vsize); t[j].refresh = REFRESH_R; t[j].id = STD_TIMING_ID; NEXT_STD_TIMING; } } static void get_monitor_ranges(Uchar * c, struct monitor_ranges *r) { r->min_v = MIN_V; r->max_v = MAX_V; r->min_h = MIN_H; r->max_h = MAX_H; r->max_clock = 0; if (MAX_CLOCK != 0xff) /* is specified? */ r->max_clock = MAX_CLOCK * 10 + 5; r->display_range_timing_flags = c[10]; if (HAVE_2ND_GTF) { r->gtf_2nd_f = F_2ND_GTF; r->gtf_2nd_c = C_2ND_GTF; r->gtf_2nd_m = M_2ND_GTF; r->gtf_2nd_k = K_2ND_GTF; r->gtf_2nd_j = J_2ND_GTF; } else { r->gtf_2nd_f = 0; } if (HAVE_CVT) { r->max_clock_khz = MAX_CLOCK_KHZ; r->max_clock = r->max_clock_khz / 1000; r->maxwidth = MAXWIDTH; r->supported_aspect = SUPPORTED_ASPECT; r->preferred_aspect = PREFERRED_ASPECT; r->supported_blanking = SUPPORTED_BLANKING; r->supported_scaling = SUPPORTED_SCALING; r->preferred_refresh = PREFERRED_REFRESH; } else { r->max_clock_khz = 0; } } static void get_whitepoint_section(Uchar * c, struct whitePoints *wp) { wp[0].white_x = WHITEX1; wp[0].white_y = WHITEY1; wp[1].white_x = WHITEX2; wp[1].white_y = WHITEY2; wp[0].index = WHITE_INDEX1; wp[1].index = WHITE_INDEX2; wp[0].white_gamma = WHITE_GAMMA1; wp[1].white_gamma = WHITE_GAMMA2; } static void get_detailed_timing_section(Uchar * c, struct detailed_timings *r) { r->clock = PIXEL_CLOCK; r->h_active = H_ACTIVE; r->h_blanking = H_BLANK; r->v_active = V_ACTIVE; r->v_blanking = V_BLANK; r->h_sync_off = H_SYNC_OFF; r->h_sync_width = H_SYNC_WIDTH; r->v_sync_off = V_SYNC_OFF; r->v_sync_width = V_SYNC_WIDTH; r->h_size = H_SIZE; r->v_size = V_SIZE; r->h_border = H_BORDER; r->v_border = V_BORDER; r->interlaced = INTERLACED; r->stereo = STEREO; r->stereo_1 = STEREO1; r->sync = SYNC_T; r->misc = MISC; } #define MAX_EDID_MINOR 4 static Bool validate_version(int scrnIndex, struct edid_version *r) { if (r->version != 1) { xf86DrvMsg(scrnIndex, X_ERROR, "Unknown EDID version %d\n", r->version); return FALSE; } if (r->revision > MAX_EDID_MINOR) xf86DrvMsg(scrnIndex, X_WARNING, "Assuming version 1.%d is compatible with 1.%d\n", r->revision, MAX_EDID_MINOR); return TRUE; } Bool gtf_supported(xf86MonPtr mon) { int i; if (!mon) return FALSE; if ((mon->ver.version == 1) && (mon->ver.revision < 4)) { if (mon->features.msc & 0x1) return TRUE; } else { for (i = 0; i < DET_TIMINGS; i++) { struct detailed_monitor_section *det_timing_des = &(mon->det_mon[i]); if (det_timing_des && (det_timing_des->type == DS_RANGES) && (mon->features.msc & 0x1) && (det_timing_des->section.ranges.display_range_timing_flags == DR_DEFAULT_GTF || det_timing_des->section.ranges.display_range_timing_flags == DR_SECONDARY_GTF)) return TRUE; } } return FALSE; } /* * Returns true if HDMI, false if definitely not or unknown. */ Bool xf86MonitorIsHDMI(xf86MonPtr mon) { return xf86MonitorFindHDMIBlock(mon) != NULL; }