/* * sysobj - https://github.com/bp0/verbose-spork * Copyright (C) 2018 Burt P. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * */ #define _GNU_SOURCE #include #include #include #include #include #include #include "gettext.h" #include "util_edid.h" #include "util_sysobj.h" #include "util_edid_svd_table.c" // TODO: find a better fix, I've seen a few EDID strings with bogus chars #if !GLIB_CHECK_VERSION(2,52,0) __attribute__ ((weak)) gchar *g_utf8_make_valid(const gchar *s, const gssize l) { if (l < 0) return g_strdup(s); else return g_strndup(s, (gsize)l); } #endif #define NOMASK (~0U) #define BFMASK(LSB, MASK) (MASK << LSB) #define DPTR(ADDY) (uint8_t*)(&((ADDY).e->u8[(ADDY).offset])) #define OFMT "@%03d" /* for addy.offset */ #define EDID_MSG_STDERR 0 #define edid_msg(e, msg, ...) {\ if (EDID_MSG_STDERR) fprintf (stderr, ">[%s;L%d] " msg "\n", __FUNCTION__, __LINE__, ##__VA_ARGS__); \ g_string_append_printf(e->msg_log, "[%s;L%d] " msg "\n", __FUNCTION__, __LINE__, ##__VA_ARGS__); } static int str_make_printable(char *str) { int rc = 0; char *p; for(p = str; *p; p++) { if (!isprint(*p)) { *p = '.'; rc++; } } return rc; } static inline uint32_t bf_value(uint32_t value, uint32_t mask) { uint32_t result = value & mask; if (result) while(!(mask & 1)) { result >>= 1; mask >>= 1; } return result; } static inline uint8_t bounds_check(edid *e, uint32_t offset) { if (!e) return 0; if (offset > e->len) return 0; return 1; } static inline char *rstr(edid *e, uint32_t offset, uint32_t len) { if (!bounds_check(e, offset+len)) return NULL; char *raw = malloc(len+1), *ret = NULL; strncpy(raw, (char*)&e->u8[offset], len); raw[len] = 0; ret = g_utf8_make_valid(raw, len); g_free(raw); return ret; } static inline char *rstr_strip(edid *e, uint32_t offset, uint32_t len) { if (!bounds_check(e, offset+len)) return NULL; char *raw = malloc(len+1), *ret = NULL; strncpy(raw, (char*)&e->u8[offset], len); raw[len] = 0; ret = g_strstrip(g_utf8_make_valid(raw, len)); g_free(raw); return ret; } static inline uint32_t r8(edid *e, uint32_t offset, uint32_t mask) { if (!bounds_check(e, offset)) return 0; return bf_value(e->u8[offset], mask); } static inline uint32_t r16le(edid *e, uint32_t offset, uint32_t mask) { if (!bounds_check(e, offset+1)) return 0; uint32_t v = (e->u8[offset+1] << 8) + e->u8[offset]; return bf_value(v, mask); } static inline uint32_t r16be(edid *e, uint32_t offset, uint32_t mask) { if (!bounds_check(e, offset+1)) return 0; uint32_t v = (e->u8[offset] << 8) + e->u8[offset+1]; return bf_value(v, mask); } static inline uint32_t r24le(edid *e, uint32_t offset, uint32_t mask) { if (!bounds_check(e, offset+2)) return 0; uint32_t v = (e->u8[offset+2] << 16) + (e->u8[offset+1] << 8) + e->u8[offset]; return bf_value(v, mask); } static inline uint32_t r24be(edid *e, uint32_t offset, uint32_t mask) { if (!bounds_check(e, offset+2)) return 0; uint32_t v = (e->u8[offset] << 16) + (e->u8[offset+1] << 8) + e->u8[offset+2]; return bf_value(v, mask); } static inline uint32_t r32le(edid *e, uint32_t offset, uint32_t mask) { if (!bounds_check(e, offset+3)) return 0; uint32_t v = (e->u8[offset+3] << 24) + (e->u8[offset+2] << 16) + (e->u8[offset+1] << 8) + e->u8[offset]; return bf_value(v, mask); } static inline uint32_t r32be(edid *e, uint32_t offset, uint32_t mask) { if (!bounds_check(e, offset+3)) return 0; uint32_t v = (e->u8[offset] << 24) + (e->u8[offset+1] << 16) + (e->u8[offset+2] << 8) + e->u8[offset+3]; return bf_value(v, mask); } static inline int rpnpcpy(edid_ven *dest, edid *e, uint32_t offset) { uint32_t pnp = r16be(e, offset, NOMASK); edid_ven ret = {.type = VEN_TYPE_INVALID}; if (pnp) { ret.type = VEN_TYPE_PNP; ret.pnp[2] = 64 + (pnp & 0x1f); ret.pnp[1] = 64 + ((pnp >> 5) & 0x1f); ret.pnp[0] = 64 + ((pnp >> 10) & 0x1f); *dest = ret; return 1; } return 0; } static inline int rouicpy(edid_ven *dest, edid *e, uint32_t offset) { edid_ven ret = {.type = VEN_TYPE_OUI}; ret.oui = r24le(e, offset, NOMASK); sprintf(ret.oui_str, "%02x%02x%02x", (ret.oui >> 16) & 0xff, (ret.oui >> 8) & 0xff, ret.oui & 0xff ); if (ret.oui) { *dest = ret; return 1; } return 0; } static int _block_check_n(const void *bytes, int len) { if (!bytes) return 0; uint8_t sum = 0; uint8_t *data = (uint8_t*)bytes; int i; for(i=0; iu8, len); } static int block_check(edid *e, uint32_t offset) { if (!bounds_check(e, offset+128)) return 0; return _block_check_n(e->u8, 128); } static char *hex_bytes(uint8_t *bytes, int count) { char *buffer = malloc(count*3+1), *p = buffer; memset(buffer, 0, count*3+1); int i; for(i = 0; i < count; i++) { sprintf(p, "%02x ", (unsigned int)bytes[i]); p += 3; } return buffer; } #define OUTPUT_CPY_SIZE(DEST, SRC) \ (DEST).horiz_cm = (SRC).horiz_cm; \ (DEST).vert_cm = (SRC).vert_cm; \ (DEST).diag_cm = (SRC).diag_cm; \ (DEST).diag_in = (SRC).diag_in; \ edid_output_fill(&(DEST)); static void edid_output_fill(edid_output *out) { out->diag_cm = sqrt( (out->horiz_cm * out->horiz_cm) + (out->vert_cm * out->vert_cm) ); out->diag_in = out->diag_cm / 2.54; if (out->is_interlaced) { if (out->vert_lines) out->vert_pixels = out->vert_lines * 2; else out->vert_lines = out->vert_pixels / 2; } else { if (out->vert_lines) out->vert_pixels = out->vert_lines; else out->vert_lines = out->vert_pixels; } if (!out->vert_freq_hz && out->pixel_clock_khz) { uint64_t h = out->horiz_pixels + out->horiz_blanking; uint64_t v = out->vert_lines + out->vert_blanking; if (h && v) { uint64_t work = out->pixel_clock_khz * 1000; work /= (h*v); out->vert_freq_hz = work; } } out->pixels = out->horiz_pixels; out->pixels *= out->vert_pixels; if (out->diag_in) { static const char *inlbl = "\u2033"; /* double prime */ sprintf(out->class_inch, "%0.1f%s", out->diag_in, inlbl); util_strchomp_float(out->class_inch); } } static void cea_block_decode(struct edid_cea_block *blk) { if (!blk) return; if (!blk->bounds_ok) blk->bounds_ok = bounds_check(blk->addy.e, blk->addy.offset + 1 + blk->len); if (!blk->bounds_ok) return; edid *e = blk->addy.e; static uint32_t h = 1; /* header size */ uint32_t a = blk->addy.offset; /* start of block, includes header */ uint8_t *ptr = DPTR(blk->addy); int i; switch(blk->type) { case 0x1: /* SADS */ for(i = h; i <= blk->len; i+=3) { struct edid_sad *sad = &e->sads[e->sad_count]; sad->v[0] = ptr[i]; sad->v[1] = ptr[i+1]; sad->v[2] = ptr[i+2]; sad->format = bf_value(sad->v[0], 0x78); sad->channels = 1 + bf_value(sad->v[0], 0x07); sad->freq_bits = sad->v[1]; if (sad->format == 1) { sad->depth_bits = sad->v[2]; } else if (sad->format >= 2 && sad->format <= 8) { sad->max_kbps = 8 * sad->v[2]; } e->sad_count++; } break; case 0x4: /* Speaker allocation */ e->speaker_alloc_bits = ptr[h]; break; case 0x2: /* SVDs */ for(i = h; i <= blk->len; i++) e->svds[e->svd_count++].v = ptr[i]; break; case 0x3: /* Vendor-specific */ rouicpy(&blk->ven, e, a+h); // TODO: break; default: break; } } static void did_block_decode(DisplayIDBlock *blk) { if (!blk) return; //printf("did_block_decode: %s\n", hex_bytes(DPTR(blk->addy), blk->len+3)); if (!blk->bounds_ok) blk->bounds_ok = bounds_check(blk->addy.e, blk->addy.offset + 3 + blk->len); if (!blk->bounds_ok) return; edid *e = blk->addy.e; static uint32_t h = 3; /* header size */ uint32_t a = blk->addy.offset; /* start of block, includes header */ uint8_t *u8 = DPTR(blk->addy); int b = h; edid_ven ven;// = {}; edid_output out;// = {}; memset(&ven,0,sizeof(edid_ven)); memset(&out,0,sizeof(edid_output)); if (blk) { switch(blk->type) { case 0: /* Product ID (1.x) */ /* UNTESTED */ if (rpnpcpy(&ven, e, a+h) ) e->ven = ven; if (u8[12] || u8[13]) { e->dom.week = u8[12]; e->dom.year = u8[13] + 2000; e->dom.is_model_year = (e->dom.week == 255); e->dom.std = STD_DISPLAYID; } e->did_strings[e->did_string_count].is_product_name = 1; e->did_strings[e->did_string_count].len = blk->len; e->did_strings[e->did_string_count].str = rstr_strip(e, a+h+12, u8[b+11]); e->name = e->did_strings[e->did_string_count].str; e->did_string_count++; break; case 0x20: /* Product ID */ /* UNTESTED */ if (rouicpy(&ven, e, a+h) ) e->ven = ven; if (u8[12] || u8[13]) { e->dom.week = u8[12]; e->dom.year = u8[13] + 2000; e->dom.is_model_year = (e->dom.week == 255); e->dom.std = STD_DISPLAYID20; } e->did_strings[e->did_string_count].is_product_name = 1; e->did_strings[e->did_string_count].len = blk->len; e->did_strings[e->did_string_count].str = rstr_strip(e, a+h+12, u8[b+11]); e->name = e->did_strings[e->did_string_count].str; e->did_string_count++; break; case 0x0a: /* Serial Number (ASCII String) */ e->did_strings[e->did_string_count].is_serial = 1; e->did_strings[e->did_string_count].len = blk->len; e->did_strings[e->did_string_count].str = rstr_strip(e, a+h, blk->len); e->serial = e->did_strings[e->did_string_count].str; e->did_string_count++; break; case 0x0b: /* General Purpose ASCII String */ e->did_strings[e->did_string_count].len = blk->len; e->did_strings[e->did_string_count].str = rstr(e, a+h, blk->len); e->did_string_count++; break; case 0x03: /* Type I Detailed timings */ out.pixel_clock_khz = 10 * r24le(e, a+h, NOMASK); out.horiz_pixels = 1 + (u8[b+5] << 8) + u8[b+4]; out.horiz_blanking = (u8[b+7] << 8) + u8[b+6]; out.vert_lines = 1 + (u8[b+13] << 8) + u8[b+12]; out.vert_blanking = (u8[b+15] << 8) + u8[b+14]; out.is_interlaced = bf_value(u8[b+3], BFMASK(4, 0x1)); out.stereo_mode = bf_value(u8[b+3], BFMASK(5, 0x3)); out.is_preferred = bf_value(u8[b+3], BFMASK(7, 0x1)); out.src = OUTSRC_DID_TYPE_I; edid_output_fill(&out); e->didts[e->didt_count++] = out; break; case 0x13: /* Type VI Detailed timings (super 0x03) */ /* UNTESTED */ out.pixel_clock_khz = (u8[b+2] << 16) & 0xa0; out.pixel_clock_khz += u8[b+1] << 8; out.pixel_clock_khz += u8[b]; out.horiz_pixels = ((u8[b+5] << 8) + u8[b+3]) & 0x7fff; out.vert_lines = ((u8[b+6] << 8) + u8[b+5]) & 0x7fff; // TODO: blanking... out.is_interlaced = (u8[b+13] >> 7) & 0x1; out.stereo_mode = (u8[b+13] >> 5) & 0x2; out.src = OUTSRC_DID_TYPE_VI; edid_output_fill(&out); e->didts[e->didt_count++] = out; break; case 0x22: /* Type VII Detailed timings (super 0x13) */ /* UNTESTED */ out.pixel_clock_khz = u8[b+2] << 16; out.pixel_clock_khz += u8[b+1] << 8; out.pixel_clock_khz += u8[b]; out.horiz_pixels = (u8[b+5] << 8) + u8[b+4]; out.horiz_blanking = (u8[b+7] << 8) + u8[b+6]; out.vert_lines = (u8[b+13] << 8) + u8[b+12]; out.vert_blanking = (u8[b+15] << 8) + u8[b+14]; out.is_interlaced = (u8[b+3] >> 4) & 0x1; out.stereo_mode = (u8[b+3] >> 5) & 0x2; out.is_preferred = (u8[b+3] >> 7) & 0x1; out.src = OUTSRC_DID_TYPE_VII; edid_output_fill(&out); e->didts[e->didt_count++] = out; break; case 0x7e: /* vendor specific data */ case 0x7f: /* vendor specific data */ rouicpy(&blk->ven, e, a+h); // TODO: break; case 0x81: /* CTA DisplayID, ... Embedded CEA Blocks */ while(b < blk->len) { int db_type = (u8[b] & 0xe0) >> 5; int db_size = u8[b] & 0x1f; e->cea_blocks[e->cea_block_count].addy.e = blk->addy.e; e->cea_blocks[e->cea_block_count].addy.offset = blk->addy.offset + b; e->cea_blocks[e->cea_block_count].type = db_type; e->cea_blocks[e->cea_block_count].len = db_size; cea_block_decode(&e->cea_blocks[e->cea_block_count]); e->cea_block_count++; b += db_size + 1; } break; default: break; } } } static edid_output edid_output_from_svd(uint8_t index) { int i; if (index >= 128 && index <= 192) index &= 0x7f; /* "native" flag for 0-64 */ for(i = 0; i < (int)G_N_ELEMENTS(cea_standard_timings); i++) { if (cea_standard_timings[i].index == index) { edid_output out;// = {}; memset(&out,0,sizeof(edid_output)); out.horiz_pixels = cea_standard_timings[i].horiz_active; out.vert_lines = cea_standard_timings[i].vert_active; if (strchr(cea_standard_timings[i].short_name, 'i')) out.is_interlaced = 1; out.pixel_clock_khz = cea_standard_timings[i].pixel_clock_mhz * 1000; out.vert_freq_hz = cea_standard_timings[i].vert_freq_hz; out.src = OUTSRC_SVD; edid_output_fill(&out); return out; } } return (edid_output){.src = OUTSRC_INVALID}; } edid *edid_new(const char *data, unsigned int len) { if (len < 128) return NULL; int i; edid *e = malloc(sizeof(edid)); memset(e, 0, sizeof(edid)); e->data = malloc(len); memcpy(e->data, data, len); e->len = len; e->ver_major = e->u8[18]; e->ver_minor = e->u8[19]; e->msg_log = g_string_new(NULL); #define RESERVE_COUNT 300 e->dtds = malloc(sizeof(struct edid_dtd) * RESERVE_COUNT); e->cea_blocks = malloc(sizeof(struct edid_cea_block) * RESERVE_COUNT); e->svds = malloc(sizeof(struct edid_svd) * RESERVE_COUNT); e->sads = malloc(sizeof(struct edid_sad) * RESERVE_COUNT); e->did_blocks = malloc(sizeof(DisplayIDBlock) * RESERVE_COUNT); e->didts = malloc(sizeof(edid_output) * RESERVE_COUNT); e->did_strings = malloc(sizeof(edid_output) * RESERVE_COUNT); memset(e->dtds, 0, sizeof(struct edid_dtd) * RESERVE_COUNT); memset(e->cea_blocks, 0, sizeof(struct edid_cea_block) * RESERVE_COUNT); memset(e->svds, 0, sizeof(struct edid_svd) * RESERVE_COUNT); memset(e->sads, 0, sizeof(struct edid_sad) * RESERVE_COUNT); memset(e->did_blocks, 0, sizeof(DisplayIDBlock) * RESERVE_COUNT); memset(e->didts, 0, sizeof(edid_output) * RESERVE_COUNT); memset(e->did_strings, 0, sizeof(edid_output) * RESERVE_COUNT); /* base product information */ rpnpcpy(&e->ven, e, 8); /* bytes 8-9 */ e->product = r16le(e, 10, NOMASK); /* bytes 10-11 */ e->n_serial = r32le(e, 12, NOMASK); /* bytes 12-15 */ e->dom.week = e->u8[16]; /* byte 16 */ e->dom.year = e->u8[17] + 1990; /* byte 17 */ e->dom.is_model_year = (e->dom.week == 255); e->dom.std = STD_EDID; e->a_or_d = (e->u8[20] & 0x80) ? 1 : 0; if (e->a_or_d == 1) { /* digital */ switch((e->u8[20] >> 4) & 0x7) { case 0x1: e->bpc = 6; break; case 0x2: e->bpc = 8; break; case 0x3: e->bpc = 10; break; case 0x4: e->bpc = 12; break; case 0x5: e->bpc = 14; break; case 0x6: e->bpc = 16; break; } e->interface = e->u8[20] & 0xf; } if (e->u8[21] && e->u8[22]) { e->img.horiz_cm = e->u8[21]; e->img.vert_cm = e->u8[22]; edid_output_fill(&e->img); e->img_max = e->img; } /* established timing bitmap */ #define ETB_CHECK(BYT, BIT, HP, VP, RF, IL) \ if (e->u8[BYT] & (1<etbs[e->etb_count] = e->img; \ e->etbs[e->etb_count].horiz_pixels = HP; \ e->etbs[e->etb_count].vert_pixels = VP; \ e->etbs[e->etb_count].vert_freq_hz = RF; \ e->etbs[e->etb_count].is_interlaced = IL;\ e->etbs[e->etb_count].src = OUTSRC_ETB; \ edid_output_fill(&e->etbs[e->etb_count]);\ e->etb_count++; }; ETB_CHECK(35, 7, 720, 400, 70, 0); //(VGA) ETB_CHECK(35, 6, 720, 400, 88, 0); //(XGA) ETB_CHECK(35, 5, 640, 480, 60, 0); //(VGA) ETB_CHECK(35, 4, 640, 480, 67, 0); //(Apple Macintosh II) ETB_CHECK(35, 3, 640, 480, 72, 0); ETB_CHECK(35, 2, 640, 480, 75, 0); ETB_CHECK(35, 1, 800, 600, 56, 0); ETB_CHECK(35, 0, 800, 600, 60, 0); ETB_CHECK(36, 7, 800, 600, 72, 0); ETB_CHECK(36, 6, 800, 600, 75, 0); ETB_CHECK(36, 5, 832, 624, 75, 0); //(Apple Macintosh II) ETB_CHECK(36, 4, 1024, 768, 87, 1); //(1024×768i) ETB_CHECK(36, 3, 1024, 768, 60, 0); ETB_CHECK(36, 2, 1024, 768, 70, 0); ETB_CHECK(36, 1, 1024, 768, 75, 0); ETB_CHECK(36, 0, 1280, 1024, 75, 0); ETB_CHECK(37, 7, 1152, 870, 75, 0); //(Apple Macintosh II) /* standard timings */ for(i = 38; i < 53; i+=2) { /* 0101 is unused */ if (e->u8[i] == 0x01 && e->u8[i+1] == 0x01) continue; /* 00.. is invalid/"reserved" */ if (e->u8[i] == 0x00) continue; double xres = (e->u8[i] + 31) * 8; double yres = 0; int iar = (e->u8[i+1] >> 6) & 0x3; int vf = (e->u8[i+1] & 0x3f) + 60; switch(iar) { case 0: /* 16:10 (v<1.3 1:1) */ if (e->ver_major == 1 && e->ver_minor < 3) yres = xres; else yres = xres*10/16; break; case 0x1: /* 4:3 */ yres = xres*4/3; break; case 0x2: /* 5:4 */ yres = xres*4/5; break; case 0x3: /* 16:9 */ yres = xres*9/16; break; } e->stds[e->std_count].ptr = &e->u8[i]; e->stds[e->std_count].out = e->img; /* inherit */ e->stds[e->std_count].out.horiz_pixels = xres; e->stds[e->std_count].out.vert_pixels = yres; e->stds[e->std_count].out.vert_freq_hz = vf; e->stds[e->std_count].out.src = OUTSRC_STD; edid_output_fill(&e->stds[e->std_count].out); e->std_count++; } uint16_t dh, dl; #define CHECK_DESCRIPTOR(INDEX, OFFSET) \ e->d[INDEX].addy.e = e; \ e->d[INDEX].addy.offset = OFFSET; \ if (e->u8[OFFSET] == 0) { \ dh = be16toh(e->u16[OFFSET/2]); \ dl = be16toh(e->u16[OFFSET/2+1]); \ e->d[INDEX].type = (dh << 16) + dl; \ switch(e->d[INDEX].type) { \ case 0xfc: case 0xff: case 0xfe: \ strncpy(e->d[INDEX].text, (char*)e->u8+OFFSET+5, 13); \ } \ } else e->dtds[e->dtd_count++].addy = e->d[INDEX].addy; CHECK_DESCRIPTOR(0, 54); CHECK_DESCRIPTOR(1, 72); CHECK_DESCRIPTOR(2, 90); CHECK_DESCRIPTOR(3, 108); e->checksum_ok = block_check(e, 0); /* first 128-byte block only */ if (len > 128) { /* check extension blocks */ int blocks = len / 128; blocks--; e->ext_blocks = blocks; e->ext_ok = malloc(sizeof(uint8_t) * blocks); for(; blocks; blocks--) { uint32_t offset = blocks * 128; uint8_t *u8 = e->u8 + offset; int r = block_check(e, offset); e->ext_ok[blocks-1] = r; if (r) e->ext_blocks_ok++; else e->ext_blocks_fail++; if (u8[0] == 0x40) { /* DI-EXT */ e->di.exists = 1; e->di.addy.e = e; e->di.addy.offset = offset; e->di.interface = r8(e, offset + 2, NOMASK); e->di.supports_hdcp = r8(e, offset + 3, 0x8); } if (u8[0] == 0x70) { /* DisplayID */ e->did.version = u8[1]; if (e->did.version >= 0x20) e->std = MAX(e->std, STD_DISPLAYID20); else e->std = MAX(e->std, STD_DISPLAYID); e->did.extension_length = u8[2]; e->did.primary_use_case = u8[3]; e->did.extension_count = u8[4]; e->did.checksum_ok = block_check_n(e, offset, e->did.extension_length + 5); int db_end = u8[2] + 5; int b = 5; while(b < db_end) { if (r24le(e, offset + b, NOMASK) == 0) break; int db_type = u8[b]; int db_revision = u8[b+1] & 0x7; int db_size = u8[b+2]; e->did_blocks[e->did_block_count].addy.e = e; e->did_blocks[e->did_block_count].addy.offset = offset + b; e->did_blocks[e->did_block_count].type = db_type; e->did_blocks[e->did_block_count].revision = db_revision; e->did_blocks[e->did_block_count].len = db_size; did_block_decode(&e->did_blocks[e->did_block_count]); e->did_block_count++; e->did.blocks++; b += db_size + 3; } if (b > db_end) edid_msg(e, "DID block overrun [in ext " OFMT "], expect to end at +%d, but last ends at +%d" , offset, db_end-1, b-1); //printf("DID: v:%02x el:%d uc:%d ec:%d, blocks:%d ok:%d\n", // e->did.version, e->did.extension_length, // e->did.primary_use_case, e->did.extension_count, // e->did.blocks, e->checksum_ok); } if (u8[0] == 0x02) { e->std = MAX(e->std, STD_EIACEA861); /* CEA extension */ int db_end = u8[2]; if (db_end) { int b = 4; while(b < db_end) { int db_type = (u8[b] & 0xe0) >> 5; int db_size = u8[b] & 0x1f; e->cea_blocks[e->cea_block_count].addy.e = e; e->cea_blocks[e->cea_block_count].addy.offset = offset + b; e->cea_blocks[e->cea_block_count].type = db_type; e->cea_blocks[e->cea_block_count].len = db_size; cea_block_decode(&e->cea_blocks[e->cea_block_count]); e->cea_block_count++; b += db_size + 1; } if (b > db_end) { b = db_end; edid_msg(e, "CEA block overrun [in ext " OFMT "], expect to end at +%d, but last ends at +%d" , offset, db_end-1, b-1); } /* DTDs */ while(b < 127) { if (u8[b]) { e->dtds[e->dtd_count].addy.e = e; e->dtds[e->dtd_count].addy.offset = offset + b; e->dtds[e->dtd_count].cea_ext = 1; e->dtd_count++; } b += 18; } } } } } if (e->ext_blocks_ok) { e->std = MAX(e->std, STD_EEDID); } /* strings */ for(i = 0; i < 4; i++) { g_strstrip(e->d[i].text); str_make_printable(e->d[i].text); switch(e->d[i].type) { case 0xfc: e->name = e->d[i].text; break; case 0xff: e->serial = e->d[i].text; break; case 0xfe: if (e->ut1) e->ut2 = e->d[i].text; else e->ut1 = e->d[i].text; break; } } /* quirks */ if (!e->name) { if (SEQ(e->ut1, "LG Display") && e->ut2) /* LG may use "uspecified text" for name and model */ e->name = e->ut2; else if (SEQ(e->ut1, "AUO") && e->ut2) /* Same with AUO */ e->name = e->ut2; else { if (e->ut1) e->name = e->ut1; if (e->ut2 && !e->serial) e->serial = e->ut2; } } if (!e->interface && e->di.interface) { if (e->di.interface >= 1 && e->di.interface <= 5) e->interface = 1; /* DVI */ } /* largest in ETB */ for (i = 0; i < e->etb_count; i++) { if (e->etbs[i].pixels > e->img.pixels) e->img = e->etbs[i]; if (e->etbs[i].pixels > e->img_max.pixels) e->img_max = e->etbs[i]; } /* largest in STDs */ for (i = 0; i < e->std_count; i++) { if (e->stds[i].out.pixels > e->img.pixels) e->img = e->stds[i].out; if (e->stds[i].out.pixels > e->img_max.pixels) e->img_max = e->stds[i].out; } /* dtds */ for(i = 0; i < e->dtd_count; i++) { edid_addy a = e->dtds[i].addy; if (!e->dtds[i].bounds_ok) e->dtds[i].bounds_ok = bounds_check(a.e, a.offset + 18); if (!e->dtds[i].bounds_ok) { printf("bounds fail\n"); exit(0); } uint8_t *u8 = DPTR(a); edid_output *out = &e->dtds[i].out; if (e->dtds[i].cea_ext) out->src = OUTSRC_CEA_DTD; else out->src = OUTSRC_DTD; out->pixel_clock_khz = 10 * r16le(a.e, a.offset, NOMASK); out->horiz_pixels = ((u8[4] & 0xf0) << 4) + u8[2]; out->vert_lines = ((u8[7] & 0xf0) << 4) + u8[5]; out->horiz_blanking = ((u8[4] & 0x0f) << 8) + u8[3]; out->vert_blanking = ((u8[7] & 0x0f) << 8) + u8[6]; out->horiz_cm = ((u8[14] & 0xf0) << 4) + u8[12]; out->horiz_cm /= 10; out->vert_cm = ((u8[14] & 0x0f) << 8) + u8[13]; out->vert_cm /= 10; out->is_interlaced = (u8[17] & 0x80) >> 7; out->stereo_mode = (u8[17] & 0x60) >> 4; out->stereo_mode += u8[17] & 0x01; edid_output_fill(out); } if (e->dtd_count) { /* first DTD is "preferred" */ e->img_max = e->dtds[0].out; } /* svds */ for(i = 0; i < e->svd_count; i++) { e->svds[i].out = edid_output_from_svd(e->svds[i].v); if (e->svds[i].out.src == OUTSRC_INVALID) continue; if (e->svds[i].v >= 128 && e->svds[i].v <= 192) { e->svds[i].is_native = 1; edid_output tmp = e->img_max; /* native res is max real res, right? */ e->img_max = e->svds[i].out; e->img_max.is_preferred = 1; OUTPUT_CPY_SIZE(e->img_max, tmp); } if (e->svds[i].out.pixels > e->img_svd.pixels || e->svds[i].is_native) { e->img_svd = e->svds[i].out; if (e->svds[i].is_native) e->img_svd.is_preferred = 1; OUTPUT_CPY_SIZE(e->img_svd, e->img_max); } } /* remove invalid SVDs */ int d = 0; for(i = 0; i < e->svd_count; i++) { if (d != i) e->svds[d].out = e->svds[i].out; if (e->svds[i].out.src != OUTSRC_INVALID) d++; } e->svd_count -= (i-d); /* didts */ for(i = 0; i < e->didt_count; i++) { int pref = e->didts[i].is_preferred; int max_pref = e->img_max.is_preferred; int bigger = (e->didts[i].pixels > e->img_max.pixels); int better = (e->didts[i].src > e->img_max.src); if ((bigger && !max_pref) || (pref && !max_pref) || (better)) { edid_output tmp = e->img_max; e->img_max = e->didts[i]; OUTPUT_CPY_SIZE(e->img_max, tmp); } } if (!e->speaker_alloc_bits && e->sad_count) { /* make an assumption */ if (e->sads[0].channels == 2) e->speaker_alloc_bits = 0x1; } /* squeeze lists */ #define SQUEEZE(C, L) \ if (!e->C) { free(e->L); e->L = NULL; } \ else { e->L = realloc(e->L, sizeof(e->L[0]) * (e->C)); } SQUEEZE(dtd_count, dtds); SQUEEZE(cea_block_count, cea_blocks); SQUEEZE(svd_count, svds); SQUEEZE(sad_count, sads); SQUEEZE(did_block_count, did_blocks); SQUEEZE(didt_count, didts); SQUEEZE(did_string_count, did_strings); return e; } void edid_free(edid *e) { int i; if (e) { g_free(e->ext_ok); g_free(e->cea_blocks); g_free(e->dtds); g_free(e->svds); g_free(e->sads); g_free(e->did_blocks); g_free(e->didts); for(i = 0; i < e->did_string_count; i++) g_free(e->did_strings[i].str); g_free(e->did_strings); g_free(e->data); g_string_free(e->msg_log, TRUE); g_free(e); } } edid *edid_new_from_hex(const char *hex_string) { int blen = strlen(hex_string) / 2; uint8_t *buffer = malloc(blen), *n = buffer; memset(buffer, 0, blen); int len = 0; const char *p = hex_string; char byte[3] = ".."; while(p && *p) { if (isxdigit(p[0]) && isxdigit(p[1])) { byte[0] = p[0]; byte[1] = p[1]; *n = strtol(byte, NULL, 16); n++; len++; p += 2; } else p++; } edid *e = edid_new((char*)buffer, len); free(buffer); return e; } edid *edid_new_from_file(const char *path) { char *bin = NULL; gsize len = 0; if (g_file_get_contents(path, &bin, &len, NULL) ) { edid *ret = edid_new(bin, len); g_free(bin); return ret; } return NULL; } char *edid_dump_hex(edid *e, int tabs, int breaks) { if (!e) return NULL; int lines = 1 + (e->len / 16); int blen = lines * 35 + 1; unsigned int pc = 0; char *ret = malloc(blen); memset(ret, 0, blen); uint8_t *u8 = e->u8; char *p = ret; for(; lines; lines--) { int i, d = MIN(16, (e->len - pc)); if (!d) break; for(i = 0; i < tabs; i++) sprintf(p++, "\t"); for(i = d; i; i--) { sprintf(p, "%02x", (unsigned int)*u8); p+=2; u8++; pc++; if (pc == e->len) { if (breaks) sprintf(p++, "\n"); goto edid_dump_hex_done; } } if (breaks) sprintf(p++, "\n"); } edid_dump_hex_done: return ret; } const char *edid_standard(int std) { switch(std) { case STD_EDID: return N_("VESA EDID"); case STD_EEDID: return N_("VESA E-EDID"); case STD_EIACEA861: return N_("EIA/CEA-861"); case STD_DISPLAYID: return N_("VESA DisplayID"); case STD_DISPLAYID20: return N_("VESA DisplayID 2.0"); }; return N_("unknown"); } const char *edid_output_src(int src) { switch(src) { case OUTSRC_EDID: return N_("VESA EDID"); case OUTSRC_ETB: return N_("VESA EDID ETB"); case OUTSRC_STD: return N_("VESA EDID STD"); case OUTSRC_DTD: return N_("VESA EDID DTD"); case OUTSRC_CEA_DTD: return N_("EIA/CEA-861 DTD"); case OUTSRC_SVD: return N_("EIA/CEA-861 SVD"); case OUTSRC_DID_TYPE_I: return N_("DisplayID Type I"); case OUTSRC_DID_TYPE_VI: return N_("DisplayID Type VI"); case OUTSRC_DID_TYPE_VII: return N_("DisplayID Type VII"); }; return N_("unknown"); } const char *edid_interface(int type) { switch(type) { case 0: return N_("undefined"); case 0x1: return N_("DVI"); case 0x2: return N_("HDMIa"); case 0x3: return N_("HDMIb"); case 0x4: return N_("MDDI"); case 0x5: return N_("DisplayPort"); }; return N_("unknown"); } const char *edid_di_interface(int type) { switch(type) { case 0: return N_("Analog"); case 0x1: return N_("DVI"); case 0x2: return N_("DVI - Single Link"); case 0x3: return N_("DVI - Dual Link (Hi-Resolution)"); case 0x4: return N_("DVI - Dual Link (Hi-Color)"); case 0x5: return N_("DVI for Consumer Electronics"); case 0x6: return N_("PnD"); case 0x7: return N_("DFP"); case 0x8: return N_("OpenLDI - Single Link"); case 0x9: return N_("OpenLDI - Dual Link"); case 0xa: return N_("OpenLDI for Consumer Electronics"); }; return N_("unknown"); } const char *edid_cea_audio_type(int type) { switch(type) { case 0: case 15: return N_("reserved"); case 1: return N_("LPCM"); case 2: return N_("AC-3"); case 3: return N_("MPEG1 (layers 1 and 2)"); case 4: return N_("MPEG1 layer 3"); case 5: return N_("MPEG2"); case 6: return N_("AAC"); case 7: return N_("DTS"); case 8: return N_("ATRAC"); case 9: return N_("DSD"); case 10: return N_("DD+"); case 11: return N_("DTS-HD"); case 12: return N_("MLP/Dolby TrueHD"); case 13: return N_("DST Audio"); case 14: return N_("WMA Pro"); } return N_("unknown type"); } const char *edid_cea_block_type(int type) { switch(type) { case 0x01: return N_("audio"); case 0x02: return N_("video"); case 0x03: return N_("vendor specific"); case 0x04: return N_("speaker allocation"); } return N_("unknown type"); } const char *edid_did_block_type(int type) { switch(type) { /* 1.x */ case 0x00: return N_("Product Identification (1.x)"); case 0x01: return N_("Display Parameters (1.x)"); case 0x02: return N_("Color Characteristics (1.x)"); case 0x03: return N_("Type I Timing - Detailed (1.x)"); case 0x04: return N_("Type II Timing - Detailed (1.x)"); case 0x05: return N_("Type III Timing - Short (1.x)"); case 0x06: return N_("Type IV Timing - DMT ID Code (1.x)"); case 0x07: return N_("VESA Timing Standard (1.x)"); case 0x08: return N_("CEA Timing Standard (1.x)"); case 0x09: return N_("Video Timing Range (1.x)"); case 0x0A: return N_("Product Serial Number (1.x)"); case 0x0B: return N_("General Purpose ASCII String (1.x)"); case 0x0C: return N_("Display Device Data (1.x)"); case 0x0D: return N_("Interface Power Sequencing (1.x)"); case 0x0E: return N_("Transfer Characteristics (1.x)"); case 0x0F: return N_("Display Interface Data (1.x)"); case 0x10: return N_("Stereo Display Interface (1.x)"); case 0x11: return N_("Type V Timing - Short (1.x)"); case 0x12: return N_("Tiled Display Topology (1.x)"); case 0x13: return N_("Type VI Timing - Detailed (1.x)"); case 0x7F: return N_("Vendor specific (1.x)"); /* 2.x */ case 0x20: return N_("Product Identification"); case 0x21: return N_("Display Parameters"); case 0x22: return N_("Type VII - Detailed Timing"); case 0x23: return N_("Type VIII - Enumerated Timing Code"); case 0x24: return N_("Type IX - Formula-based Timing"); case 0x25: return N_("Dynamic Video Timing Range Limits"); case 0x26: return N_("Display Interface Features"); case 0x27: return N_("Stereo Display Interface"); case 0x28: return N_("Tiled Display Topology"); case 0x29: return N_("ContainerID"); case 0x7E: return N_("Vendor specific"); case 0x81: return N_("CTA DisplayID"); } return N_("unknown type"); } const char *edid_ext_block_type(int type) { switch(type) { case 0x00: return N_("timing extension"); case 0x02: return N_("EIA/CEA-861 extension (CEA-EXT)"); case 0x10: return N_("Video Timing Block extension (VTB-EXT)"); case 0x20: return N_("EDID 2.0 extension"); case 0x40: return N_("Display Information extension (DI-EXT)"); case 0x50: return N_("Localized String extension (LS-EXT)"); case 0x60: return N_("Digital Packet Video Link extension (DPVL-EXT)"); case 0x70: return N_("DisplayID"); case 0xa7: case 0xaf: case 0xbf: return N_("display transfer characteristics data block"); case 0xf0: return N_("extension block map"); case 0xff: return N_("manufacturer-defined extension/display device data block"); } return N_("unknown block type"); } const char *edid_descriptor_type(int type) { switch(type) { case 0xff: return N_("display serial number"); case 0xfe: return N_("unspecified text"); case 0xfd: return N_("display range limits"); case 0xfc: return N_("display name"); case 0xfb: return N_("additional white point"); case 0xfa: return N_("additional standard timing identifiers"); case 0xf9: return N_("Display Color Management"); case 0xf8: return N_("CVT 3-byte timing codes"); case 0xf7: return N_("additional standard timing"); case 0x10: return N_("dummy"); } if (type && type < 0x0f) return N_("manufacturer reserved descriptor"); return N_("detailed timing descriptor"); } char *edid_cea_audio_describe(struct edid_sad *sad) { if (!sad) return NULL; if (!sad->format) return g_strdup_printf("format:([%x] %s)", sad->format, _(edid_cea_audio_type(sad->format)) ); gchar *ret = NULL; gchar *tmp[3] = {NULL,NULL,NULL}; #define appfreq(b, f) if (sad->freq_bits & (1 << b)) tmp[0] = appf(tmp[0], ", ", "%d", f); #define appdepth(b, d) if (sad->depth_bits & (1 << b)) tmp[1] = appf(tmp[1], ", ", "%d%s", d, _("-bit")); appfreq(0, 32); appfreq(1, 44); appfreq(2, 48); appfreq(3, 88); appfreq(4, 96); appfreq(5, 176); appfreq(6, 192); if (sad->format == 1) { appdepth(0, 16); appdepth(1, 20); appdepth(2, 24); tmp[2] = g_strdup_printf("depths: %s", tmp[1]); } else if (sad->format >= 2 && sad->format <= 8 ) { tmp[2] = g_strdup_printf("max_bitrate: %d %s", sad->max_kbps, _("kbps")); } else tmp[2] = g_strdup(""); ret = g_strdup_printf("format:([%x] %s) channels:%d rates:%s %s %s", sad->format, _(edid_cea_audio_type(sad->format)), sad->channels, tmp[0], _("kHz"), tmp[2]); g_free(tmp[0]); g_free(tmp[1]); g_free(tmp[2]); return ret; } char *edid_cea_speaker_allocation_describe(int bitfield, int short_version) { gchar *spk_list = NULL; #define appspk(b, sv, fv) if (bitfield & (1 << b)) \ spk_list = appf(spk_list, short_version ? ", " : "\n", "%s", short_version ? sv : fv); appspk(0, "FL+FR", _("Front left and right")); appspk(1, "LFE", _("Low-frequency effects")); appspk(2, "FC", _("Front center")); appspk(3, "RL+RR", _("Rear left and right")); appspk(4, "RC", _("Rear center")); appspk(5, "???", _("")); appspk(6, "???", _("")); return spk_list; } char *edid_cea_block_describe(struct edid_cea_block *blk) { gchar *ret = NULL; if (blk) { char *hb = hex_bytes(DPTR(blk->addy), blk->len+1); switch(blk->type) { case 0x1: /* SAD list */ ret = g_strdup_printf("([%x] %s) sads:%d", blk->type, _(edid_cea_block_type(blk->type)), blk->len/3); break; case 0x2: /* SVD list */ ret = g_strdup_printf("([%x] %s) svds:%d", blk->type, _(edid_cea_block_type(blk->type)), blk->len); break; case 0x4: /* speaker allocation */ ret = g_strdup_printf("([%x] %s) len:%d", blk->type, _(edid_cea_block_type(blk->type)), blk->len); break; case 0x3: /* vendor specific */ ret = g_strdup_printf("([%x] %s) len:%d (OUI:%s) -- %s", blk->type, _(edid_cea_block_type(blk->type)), blk->len, blk->ven.oui_str, hb); break; default: ret = g_strdup_printf("([%x] %s) len:%d -- %s", blk->type, _(edid_cea_block_type(blk->type)), blk->len, hb); break; } free(hb); } return ret; } char *edid_base_descriptor_describe(struct edid_descriptor *d) { gchar *ret = NULL; if (d) { char *hb = hex_bytes(DPTR(d->addy), 18); char *txt = NULL; switch(d->type) { case 0: /* DTD */ txt = "{...}"; /* displayed elsewhere */ break; case 0x10: /* dummy */ txt = ""; break; default: txt = (*d->text) ? d->text : hb; break; }; ret = g_strdup_printf("([%02x] %s) %s", d->type, _(edid_descriptor_type(d->type)), txt); free(hb); } return ret; } char *edid_did_block_describe(DisplayIDBlock *blk) { if (!blk) return NULL; gchar *ret = NULL; edid *e = blk->addy.e; uint32_t a = blk->addy.offset + 3; char *str = NULL; //printf("edid_did_block_describe: ((%d)) t:%02x a{%p, %d}...\n", blk->addy.e->did.extension_count, blk->type, blk->addy.e, blk->addy.offset); char *hb = hex_bytes(DPTR(blk->addy), blk->len+3); switch(blk->type) { case 0x0a: /* Product Serial ASCII string */ str = rstr_strip(e, a, blk->len); ret = g_strdup_printf("([%02x:r%02x] %s) len:%d \"%s\"", blk->type, blk->revision, _(edid_did_block_type(blk->type)), blk->len, str); break; case 0x0b: /* ASCII string */ str = rstr(e, a, blk->len); ret = g_strdup_printf("([%02x:r%02x] %s) len:%d \"%s\"", blk->type, blk->revision, _(edid_did_block_type(blk->type)), blk->len, str); break; default: ret = g_strdup_printf("([%02x:r%02x] %s) len:%d -- %s", blk->type, blk->revision, _(edid_did_block_type(blk->type)), blk->len, hb); break; } free(hb); return ret; } char *edid_output_describe(edid_output *out) { gchar *ret = NULL; if (out) { ret = g_strdup_printf("%dx%d@%.0f%s", out->horiz_pixels, out->vert_pixels, out->vert_freq_hz, _("Hz") ); if (out->diag_cm) ret = appfsp(ret, "%0.1fx%0.1f%s (%0.1f\")", out->horiz_cm, out->vert_cm, _("cm"), out->diag_in ); ret = appfsp(ret, "%s", out->is_interlaced ? "interlaced" : "progressive"); ret = appfsp(ret, "%s", out->stereo_mode ? "stereo" : "normal"); } return ret; } char *edid_dtd_describe(struct edid_dtd *dtd, int dump_bytes) { gchar *ret = NULL; if (dtd) { edid_output *out = &dtd->out; char *hb = hex_bytes(DPTR(dtd->addy), 18); ret = g_strdup_printf("%dx%d@%.0f%s, %0.1fx%0.1f%s (%0.1f\") %s %s (%s)%s%s", out->horiz_pixels, out->vert_lines, out->vert_freq_hz, _("Hz"), out->horiz_cm, out->vert_cm, _("cm"), out->diag_in, out->is_interlaced ? "interlaced" : "progressive", out->stereo_mode ? "stereo" : "normal", _(edid_output_src(out->src)), dump_bytes ? " -- " : "", dump_bytes ? hb : ""); free(hb); } return ret; } char *edid_manf_date_describe(struct edid_manf_date dom) { if (!dom.year) return g_strdup("unspecified"); if (dom.is_model_year) return g_strdup_printf(_("model year %d"), dom.year); if (dom.week && dom.week <= 53) return g_strdup_printf(_("week %d of %d"), dom.week, dom.year); return g_strdup_printf("%d", dom.year); } char *edid_dump2(edid *e) { char *ret = NULL; int i; if (!e) return NULL; ret = appfnl(ret, "edid version: %d.%d (%d bytes)", e->ver_major, e->ver_minor, e->len); if (e->std) ret = appfnl(ret, "extended to: %s", _(edid_standard(e->std)) ); ret = appfnl(ret, "mfg: %s, model: [%04x-%08x] %u-%u", e->ven.pnp, e->product, e->n_serial, e->product, e->n_serial); char *dom_desc = edid_manf_date_describe(e->dom); ret = appfnl(ret, "date: %s", dom_desc); g_free(dom_desc); if (e->name) ret = appfnl(ret, "product: %s", e->name); if (e->serial) ret = appfnl(ret, "serial: %s", e->serial); ret = appfnl(ret, "type: %s", e->a_or_d ? "digital" : "analog"); if (e->bpc) ret = appfnl(ret, "bits per color channel: %d", e->bpc); if (e->interface) ret = appfnl(ret, "interface: %s", _(edid_interface(e->interface))); if (e->di.exists) { ret = appfnl(ret, "interface_ext: %s", _(edid_di_interface(e->di.interface))); ret = appfnl(ret, "hdcp: %s", e->di.supports_hdcp ? "supported" : "no"); } char *desc = edid_output_describe(&e->img); char *desc_svd = edid_output_describe(&e->img_svd); char *desc_max = edid_output_describe(&e->img_max); ret = appfnl(ret, "base(%s): %s", _(edid_output_src(e->img.src)), desc); if (e->svd_count) ret = appfnl(ret, "svd(%s): %s", _(edid_output_src(e->img_svd.src)), desc_svd); ret = appfnl(ret, "max(%s): %s", _(edid_output_src(e->img_max.src)), desc_max); g_free(desc); g_free(desc_svd); g_free(desc_max); if (e->speaker_alloc_bits) { char *desc = edid_cea_speaker_allocation_describe(e->speaker_alloc_bits, 1); ret = appfnl(ret, "speakers: %s", desc); g_free(desc); } for(i = 0; i < e->etb_count; i++) { char *desc = edid_output_describe(&e->etbs[i]); ret = appfnl(ret, "etb[%d]: %s", i, desc); g_free(desc); } for(i = 0; i < e->std_count; i++) { char *desc = edid_output_describe(&e->stds[i].out); ret = appfnl(ret, "std[%d]: %s", i, desc); g_free(desc); } ret = appfnl(ret, "checksum %s", e->checksum_ok ? "ok" : "failed!"); if (e->ext_blocks_ok || e->ext_blocks_fail) ret = appf(ret, "", ", extension blocks: %d of %d ok", e->ext_blocks_ok, e->ext_blocks_ok + e->ext_blocks_fail); for(i = 0; i < 4; i++) { char *desc = edid_base_descriptor_describe(&e->d[i]); ret = appfnl(ret, "descriptor[%d] %s", i, desc); g_free(desc); } for(i = 0; i < e->ext_blocks; i++) { int type = e->u8[(i+1)*128]; int version = e->u8[(i+1)*128 + 1]; ret = appfnl(ret, "ext[%d] ([%02x:v%02x] %s) %s", i, type, version, _(edid_ext_block_type(type)), e->ext_ok[i] ? "ok" : "fail" ); } for(i = 0; i < e->dtd_count; i++) { char *desc = edid_dtd_describe(&e->dtds[i], 0); ret = appfnl(ret, "dtd[%d] %s", i, desc); free(desc); } for(i = 0; i < e->cea_block_count; i++) { char *desc = edid_cea_block_describe(&e->cea_blocks[i]); ret = appfnl(ret, "cea_block[%d] %s", i, desc); free(desc); } for(i = 0; i < e->svd_count; i++) { char *desc = edid_output_describe(&e->svds[i].out); ret = appfnl(ret, "svd[%d] [%02x] %s", i, e->svds[i].v, desc); free(desc); } for(i = 0; i < e->sad_count; i++) { char *desc = edid_cea_audio_describe(&e->sads[i]); ret = appfnl(ret, "sad[%d] [%02x%02x%02x] %s", i, e->sads[i].v[0], e->sads[i].v[1], e->sads[i].v[2], desc); free(desc); } for(i = 0; i < e->did_block_count; i++) { char *desc = edid_did_block_describe(&e->did_blocks[i]); ret = appfnl(ret, "did_block[%d] %s", i, desc); free(desc); } for(i = 0; i < e->didt_count; i++) { char *desc = edid_output_describe(&e->didts[i]); ret = appfnl(ret, "did_timing[%d]: %s", i, desc); g_free(desc); } for(i = 0; i < e->did_string_count; i++) { ret = appfnl(ret, "did_string[%d]: %s", i, e->did_strings[i].str); } ret = appfnl(ret, "parse messages:\n%s---", e->msg_log->str); return ret; }