/* SPDX-License-Identifier: MIT */ #include "display.h" #include "adt.h" #include "assert.h" #include "dcp.h" #include "dcp_iboot.h" #include "fb.h" #include "memory.h" #include "soc.h" #include "string.h" #include "utils.h" #include "xnuboot.h" #define DISPLAY_STATUS_DELAY 100 #define DISPLAY_STATUS_RETRIES 20 #define COMPARE(a, b) \ if ((a) > (b)) { \ *best = modes[i]; \ continue; \ } else if ((a) < (b)) { \ continue; \ } static dcp_dev_t *dcp; static dcp_iboot_if_t *iboot; static u64 fb_dva; static u64 fb_size; bool display_is_external; #define abs(x) ((x) >= 0 ? (x) : -(x)) u64 display_mode_fb_size(dcp_timing_mode_t *mode) { // assume 4 byte per pixel (either BGRA x2r10b10g10) return mode->width * mode->height * 4; } static void display_choose_timing_mode(dcp_timing_mode_t *modes, int cnt, dcp_timing_mode_t *best, dcp_timing_mode_t *want) { *best = modes[0]; for (int i = 1; i < cnt; i++) { COMPARE(modes[i].valid, best->valid); if (want && want->valid) { COMPARE(modes[i].width == want->width && modes[i].height == want->height, best->width == want->width && best->height == want->height); COMPARE(-abs((long)modes[i].fps - (long)want->fps), -abs((long)best->fps - (long)want->fps)); } else { COMPARE(display_mode_fb_size(&modes[i]) <= fb_size, display_mode_fb_size(best) <= fb_size); } COMPARE(modes[i].width <= 1920, best->width <= 1920); COMPARE(modes[i].height <= 1200, best->height <= 1200); COMPARE(modes[i].fps <= 60 << 16, best->fps <= 60 << 16); COMPARE(modes[i].width, best->width); COMPARE(modes[i].height, best->height); COMPARE(modes[i].fps, best->fps); } printf("display: timing mode: valid=%d %dx%d %d.%02d Hz\n", best->valid, best->width, best->height, best->fps >> 16, ((best->fps & 0xffff) * 100 + 0x7fff) >> 16); } static void display_choose_color_mode(dcp_color_mode_t *modes, int cnt, dcp_color_mode_t *best) { *best = modes[0]; for (int i = 1; i < cnt; i++) { COMPARE(modes[i].valid, best->valid); COMPARE(modes[i].bpp <= 32, best->bpp <= 32); COMPARE(modes[i].bpp, best->bpp); COMPARE(-modes[i].colorimetry, -best->colorimetry); COMPARE(-modes[i].encoding, -best->encoding); COMPARE(-modes[i].eotf, -best->eotf); } printf("display: color mode: valid=%d colorimetry=%d eotf=%d encoding=%d bpp=%d\n", best->valid, best->colorimetry, best->eotf, best->encoding, best->bpp); } int display_get_vram(u64 *paddr, u64 *size) { int ret = 0; int adt_path[4]; int node = adt_path_offset_trace(adt, "/vram", adt_path); if (node < 0) { printf("display: '/vram' not found\n"); return -1; } int pp = 0; while (adt_path[pp]) pp++; adt_path[pp + 1] = 0; ret = adt_get_reg(adt, adt_path, "reg", 0, paddr, size); if (ret < 0) { printf("display: failed to read /vram/reg\n"); return -1; } if (*paddr != cur_boot_args.video.base) { printf("display: vram does not match boot_args.video.base\n"); return -1; } return 0; } static uintptr_t display_map_fb(uintptr_t iova, u64 paddr, u64 size) { if (iova == 0) { u64 iova_disp0 = 0; u64 iova_dcp = 0; // start scanning for free iova space on vm-base iova_dcp = dart_find_iova(dcp->dart_dcp, dart_vm_base(dcp->dart_dcp), size); if (DART_IS_ERR(iova_dcp)) { printf("display: failed to find IOVA for fb of %06zx bytes (dcp)\n", size); return iova_dcp; } // try to map the fb to the same IOVA on disp0 iova_disp0 = dart_find_iova(dcp->dart_disp, iova_dcp, size); if (DART_IS_ERR(iova_disp0)) { printf("display: failed to find IOVA for fb of %06zx bytes (disp0)\n", size); return iova_disp0; } // assume this results in the same IOVA, not sure if this is required but matches what iboot // does on other models. if (iova_disp0 != iova_dcp) { printf("display: IOVA mismatch for fb between dcp (%08lx) and disp0 (%08lx)\n", (u64)iova_dcp, (u64)iova_disp0); return DART_PTR_ERR; } iova = iova_dcp; } int ret = dart_map(dcp->dart_disp, iova, (void *)paddr, size); if (ret < 0) { printf("display: failed to map fb to dart-disp0\n"); return DART_PTR_ERR; } ret = dart_map(dcp->dart_dcp, iova, (void *)paddr, size); if (ret < 0) { printf("display: failed to map fb to dart-dcp\n"); dart_unmap(dcp->dart_disp, iova, size); return DART_PTR_ERR; } return iova; } int display_start_dcp(void) { if (iboot) return 0; dcp = dcp_init("/arm-io/dcp", "/arm-io/dart-dcp", "/arm-io/dart-disp0"); if (!dcp) { printf("display: failed to initialize DCP\n"); return -1; } // determine frame buffer PA and size from "/vram" u64 pa, size; if (display_get_vram(&pa, &size)) { // use a safe fb_size fb_size = cur_boot_args.video.stride * cur_boot_args.video.height * ((cur_boot_args.video.depth + 7) / 8); } else { fb_size = size; } // Find the framebuffer DVA fb_dva = dart_search(dcp->dart_disp, (void *)cur_boot_args.video.base); // framebuffer is not mapped on the M1 Ultra Mac Studio if (DART_IS_ERR(fb_dva)) fb_dva = display_map_fb(0, pa, size); if (DART_IS_ERR(fb_dva)) { printf("display: failed to find display DVA\n"); fb_dva = 0; dcp_shutdown(dcp, false); return -1; } iboot = dcp_ib_init(dcp); if (!iboot) { printf("display: failed to initialize DCP iBoot interface\n"); dcp_shutdown(dcp, false); return -1; } return 0; } struct display_options { bool retina; }; int display_parse_mode(const char *config, dcp_timing_mode_t *mode, struct display_options *opts) { memset(mode, 0, sizeof(*mode)); if (!config || !strcmp(config, "auto")) return 0; const char *s_w = config; const char *s_h = strchr(config, 'x'); const char *s_fps = strchr(config, '@'); if (s_w && s_h) { mode->width = atol(s_w); mode->height = atol(s_h + 1); mode->valid = mode->width && mode->height; } if (s_fps) { mode->fps = atol(s_fps + 1) << 16; const char *s_fps_frac = strchr(s_fps + 1, '.'); if (s_fps_frac) { // Assumes two decimals... mode->fps += (atol(s_fps_frac + 1) << 16) / 100; } } const char *option = config; while (option && opts) { if (!strncmp(option + 1, "retina", 6)) opts->retina = true; option = strchr(option + 1, ','); } printf("display: want mode: valid=%d %dx%d %d.%02d Hz\n", mode->valid, mode->width, mode->height, mode->fps >> 16, ((mode->fps & 0xffff) * 100 + 0x7fff) >> 16); return mode->valid; } static int display_swap(u64 iova, u32 stride, u32 width, u32 height) { int ret; dcp_layer_t layer = { .planes = {{ .addr = iova, .stride = stride, .addr_format = ADDR_PLANAR, }}, .plane_cnt = 1, .width = width, .height = height, .surface_fmt = FMT_w30r, .colorspace = 2, .eotf = EOTF_GAMMA_SDR, .transform = XFRM_NONE, }; if ((ret = dcp_ib_set_surface(iboot, &layer)) < 0) { printf("display: failed to set surface\n"); return -1; } return 0; } int display_configure(const char *config) { dcp_timing_mode_t want; struct display_options opts = {0}; display_parse_mode(config, &want, &opts); u64 start_time = get_ticks(); int ret = display_start_dcp(); if (ret < 0) return ret; // Power on if ((ret = dcp_ib_set_power(iboot, true)) < 0) { printf("display: failed to set power\n"); return ret; } // Detect if display is connected int timing_cnt, color_cnt; int hpd = 0, retries = 0; /* After boot DCP does not immediately report a connected display. Retry getting display * information for 2 seconds. */ while (retries++ < DISPLAY_STATUS_RETRIES) { hpd = dcp_ib_get_hpd(iboot, &timing_cnt, &color_cnt); if (hpd < 0) ret = hpd; else if (hpd && timing_cnt && color_cnt) break; if (retries < DISPLAY_STATUS_RETRIES) mdelay(DISPLAY_STATUS_DELAY); } printf("display: waited %d ms for display status\n", (retries - 1) * DISPLAY_STATUS_DELAY); if (ret < 0) { printf("display: failed to get display status\n"); return 0; } printf("display: connected:%d timing_cnt:%d color_cnt:%d\n", hpd, timing_cnt, color_cnt); if (!hpd || !timing_cnt || !color_cnt) return 0; // Find best modes dcp_timing_mode_t *tmodes, tbest; if ((ret = dcp_ib_get_timing_modes(iboot, &tmodes)) < 0) { printf("display: failed to get timing modes\n"); return -1; } assert(ret == timing_cnt); display_choose_timing_mode(tmodes, timing_cnt, &tbest, &want); dcp_color_mode_t *cmodes, cbest; if ((ret = dcp_ib_get_color_modes(iboot, &cmodes)) < 0) { printf("display: failed to get color modes\n"); return -1; } assert(ret == color_cnt); display_choose_color_mode(cmodes, color_cnt, &cbest); // Set mode if ((ret = dcp_ib_set_mode(iboot, &tbest, &cbest)) < 0) { printf("display: failed to set mode\n"); return -1; } u64 fb_pa = cur_boot_args.video.base; u64 tmp_dva = 0; size_t size = ALIGN_UP(tbest.width * tbest.height * ((cbest.bpp + 7) / 8) + 24 * SZ_16K, SZ_16K); if (fb_size < size) { printf("display: current framebuffer is too small for new mode\n"); /* rtkit uses 0x10000000 as DVA offset, FB starts in the first page */ if ((s64)size > 7 * SZ_32M) { printf("display: not enough reserved L2 DVA space for fb size 0x%zx\n", size); return -1; } fb_pa = top_of_memory_alloc(size); memset((void *)fb_pa, 0, size); tmp_dva = iova_alloc(dcp->iovad_dcp, size); tmp_dva = display_map_fb(tmp_dva, fb_pa, size); if (DART_IS_ERR(tmp_dva)) { printf("display: failed to map new fb\n"); return -1; } // Swap! u32 stride = tbest.width * 4; ret = display_swap(tmp_dva, stride, tbest.width, tbest.height); if (ret < 0) return ret; /* wait for swap durations + 1ms */ u32 delay = (((1000 << 16) + tbest.fps - 1) / tbest.fps) + 1; mdelay(delay); dart_unmap(dcp->dart_disp, fb_dva, fb_size); dart_unmap(dcp->dart_dcp, fb_dva, fb_size); fb_dva = display_map_fb(fb_dva, fb_pa, size); if (DART_IS_ERR(fb_dva)) { printf("display: failed to map new fb\n"); fb_dva = 0; return -1; } fb_size = size; mmu_map_framebuffer(fb_pa, fb_size); /* update ADT with the physical address of the new framebuffer */ u64 fb_reg[2] = {fb_pa, size}; int node = adt_path_offset(adt, "vram"); if (node >= 0) { // TODO: adt_set_reg(adt, node, "vram", fb_pa, size);? ret = adt_setprop(adt, node, "reg", &fb_reg, sizeof(fb_reg)); if (ret < 0) printf("display: failed to update '/vram'\n"); } node = adt_path_offset(adt, "/chosen/carveout-memory-map"); if (node >= 0) { // TODO: adt_set_reg(adt, node, "vram", fb_pa, size);? ret = adt_setprop(adt, node, "region-id-14", &fb_reg, sizeof(fb_reg)); if (ret < 0) printf("display: failed to update '/chosen/carveout-memory-map/region-id-14'\n"); } } // Swap! u32 stride = tbest.width * 4; ret = display_swap(fb_dva, stride, tbest.width, tbest.height); if (ret < 0) return ret; printf("display: swapped! (swap_id=%d)\n", ret); if (fb_pa != cur_boot_args.video.base || cur_boot_args.video.stride != stride || cur_boot_args.video.width != tbest.width || cur_boot_args.video.height != tbest.height || cur_boot_args.video.depth != 30) { cur_boot_args.video.base = fb_pa; cur_boot_args.video.stride = stride; cur_boot_args.video.width = tbest.width; cur_boot_args.video.height = tbest.height; cur_boot_args.video.depth = 30 | (opts.retina ? FB_DEPTH_FLAG_RETINA : 0); fb_reinit(); } /* Update for python / subsequent stages */ memcpy((void *)boot_args_addr, &cur_boot_args, sizeof(cur_boot_args)); if (tmp_dva) { // unmap / free temporary dva dart_unmap(dcp->dart_disp, tmp_dva, size); dart_unmap(dcp->dart_dcp, tmp_dva, size); iova_free(dcp->iovad_dcp, tmp_dva, size); } u64 msecs = ticks_to_msecs(get_ticks() - start_time); printf("display: Modeset took %ld ms\n", msecs); return 1; } int display_init(void) { int node = adt_path_offset(adt, "/arm-io/disp0"); if (node < 0) { printf("DISP0 node not found!\n"); return -1; } display_is_external = adt_getprop(adt, node, "external", NULL); if (display_is_external) printf("display: Display is external\n"); else printf("display: Display is internal\n"); // HACK: disable non-working display config on j473/j474s/etc if (display_is_external) { switch (chip_id) { case T8112: case T6020 ... T6022: printf("display: skipping init on non-supported M2+ platform\n"); return 0; break; } } if (cur_boot_args.video.width == 640 && cur_boot_args.video.height == 1136) { printf("display: Dummy framebuffer found, initializing display\n"); return display_configure(NULL); } else if (display_is_external) { printf("display: External display found, reconfiguring\n"); return display_configure(NULL); } else { printf("display: Display is already initialized (%ldx%ld)\n", cur_boot_args.video.width, cur_boot_args.video.height); return 0; } } void display_shutdown(dcp_shutdown_mode mode) { if (iboot) { dcp_ib_shutdown(iboot); switch (mode) { case DCP_QUIESCED: printf("display: Quiescing DCP (unconditional)\n"); dcp_shutdown(dcp, false); break; case DCP_SLEEP_IF_EXTERNAL: if (!display_is_external) printf("display: Quiescing DCP (internal)\n"); else printf("display: Sleeping DCP (external)\n"); dcp_shutdown(dcp, display_is_external); break; case DCP_SLEEP: printf("display: Sleeping DCP (unconditional)\n"); dcp_shutdown(dcp, true); break; } iboot = NULL; } }