/* * 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. * * Authors: * Dave Airlie * */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* for xf86InterpretEDID */ #include "sna.h" #include "sna_reg.h" #include "fb/fbpict.h" #include "intel_options.h" #if 0 #define __DBG DBG #else #define __DBG(x) #endif struct sna_crtc { struct drm_mode_modeinfo kmode; struct kgem_bo *bo; uint32_t cursor; bool shadow; bool fallback_shadow; uint8_t id; uint8_t pipe; uint8_t plane; struct list link; }; struct sna_property { drmModePropertyPtr mode_prop; uint64_t value; int num_atoms; /* if range prop, num_atoms == 1; if enum prop, num_atoms == num_enums + 1 */ Atom *atoms; }; struct sna_output { int id; drmModeConnectorPtr mode_output; int num_props; struct sna_property *props; bool has_panel_limits; int panel_hdisplay; int panel_vdisplay; int dpms_mode; char *backlight_iface; int backlight_active_level; int backlight_max; struct list link; }; static inline struct sna_crtc *to_sna_crtc(xf86CrtcPtr crtc) { return crtc->driver_private; } #define BACKLIGHT_CLASS "/sys/class/backlight" /* Enough for 10 digits of backlight + '\n' + '\0' */ #define BACKLIGHT_VALUE_LEN 12 static inline uint32_t fb_id(struct kgem_bo *bo) { return bo->delta; } int sna_crtc_id(xf86CrtcPtr crtc) { return to_sna_crtc(crtc)->id; } int sna_crtc_to_pipe(xf86CrtcPtr crtc) { return to_sna_crtc(crtc)->pipe; } int sna_crtc_to_plane(xf86CrtcPtr crtc) { return to_sna_crtc(crtc)->plane; } static unsigned get_fb(struct sna *sna, struct kgem_bo *bo, int width, int height) { ScrnInfoPtr scrn = sna->scrn; struct drm_mode_fb_cmd arg; assert(bo->proxy == NULL); if (bo->delta) { DBG(("%s: reusing fb=%d for handle=%d\n", __FUNCTION__, bo->delta, bo->handle)); return bo->delta; } DBG(("%s: create fb %dx%d@%d/%d\n", __FUNCTION__, width, height, scrn->depth, scrn->bitsPerPixel)); assert(bo->tiling != I915_TILING_Y); VG_CLEAR(arg); arg.width = width; arg.height = height; arg.pitch = bo->pitch; arg.bpp = scrn->bitsPerPixel; arg.depth = scrn->depth; arg.handle = bo->handle; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_ADDFB, &arg)) { xf86DrvMsg(scrn->scrnIndex, X_ERROR, "%s: failed to add fb: %dx%d depth=%d, bpp=%d, pitch=%d: %d\n", __FUNCTION__, width, height, scrn->depth, scrn->bitsPerPixel, bo->pitch, errno); return 0; } bo->scanout = true; return bo->delta = arg.fb_id; } static uint32_t gem_create(int fd, int size) { struct drm_i915_gem_create create; VG_CLEAR(create); create.handle = 0; create.size = ALIGN(size, 4096); (void)drmIoctl(fd, DRM_IOCTL_I915_GEM_CREATE, &create); return create.handle; } static void gem_close(int fd, uint32_t handle) { struct drm_gem_close close; VG_CLEAR(close); close.handle = handle; (void)drmIoctl(fd, DRM_IOCTL_GEM_CLOSE, &close); } static void sna_output_backlight_set(xf86OutputPtr output, int level) { struct sna_output *sna_output = output->driver_private; char path[1024], val[BACKLIGHT_VALUE_LEN]; int fd, len, ret; DBG(("%s: level=%d\n", __FUNCTION__, level)); if (level > sna_output->backlight_max) level = sna_output->backlight_max; if (!sna_output->backlight_iface || level < 0) return; len = snprintf(val, BACKLIGHT_VALUE_LEN, "%d\n", level); sprintf(path, "%s/%s/brightness", BACKLIGHT_CLASS, sna_output->backlight_iface); fd = open(path, O_RDWR); if (fd == -1) { xf86DrvMsg(output->scrn->scrnIndex, X_ERROR, "failed to open %s for backlight " "control: %s\n", path, strerror(errno)); return; } ret = write(fd, val, len); if (ret == -1) { xf86DrvMsg(output->scrn->scrnIndex, X_ERROR, "write to %s for backlight " "control failed: %s\n", path, strerror(errno)); } close(fd); } static int sna_output_backlight_get(xf86OutputPtr output) { struct sna_output *sna_output = output->driver_private; char path[1024], val[BACKLIGHT_VALUE_LEN]; int fd, level; sprintf(path, "%s/%s/actual_brightness", BACKLIGHT_CLASS, sna_output->backlight_iface); fd = open(path, O_RDONLY); if (fd == -1) { xf86DrvMsg(output->scrn->scrnIndex, X_ERROR, "failed to open %s " "for backlight control: %s\n", path, strerror(errno)); return -1; } memset(val, 0, sizeof(val)); if (read(fd, val, BACKLIGHT_VALUE_LEN) == -1) { close(fd); return -1; } close(fd); level = atoi(val); DBG(("%s: level=%d (max=%d)\n", __FUNCTION__, level, sna_output->backlight_max)); if (level > sna_output->backlight_max) level = sna_output->backlight_max; else if (level < 0) level = -1; return level; } static int sna_output_backlight_get_max(xf86OutputPtr output) { struct sna_output *sna_output = output->driver_private; char path[1024], val[BACKLIGHT_VALUE_LEN]; int fd, max = 0; sprintf(path, "%s/%s/max_brightness", BACKLIGHT_CLASS, sna_output->backlight_iface); fd = open(path, O_RDONLY); if (fd == -1) { xf86DrvMsg(output->scrn->scrnIndex, X_ERROR, "failed to open %s " "for backlight control: %s\n", path, strerror(errno)); return -1; } memset(val, 0, sizeof(val)); if (read(fd, val, BACKLIGHT_VALUE_LEN) == -1) { close(fd); return -1; } close(fd); max = atoi(val); if (max <= 0) max = -1; return max; } enum { FIRMWARE, PLATFORM, RAW, NAMED, }; static void sna_output_backlight_init(xf86OutputPtr output) { static const char *known_interfaces[] = { "asus-laptop", "asus-nb-wmi", "eeepc", "thinkpad_screen", "mbp_backlight", "fujitsu-laptop", "sony", "samsung", "acpi_video1", "acpi_video0", "intel_backlight", }; struct sna_output *sna_output = output->driver_private; char *best_iface; int best_type; DIR *dir; struct dirent *de; best_iface = NULL; best_type = INT_MAX; dir = opendir(BACKLIGHT_CLASS); if (dir == NULL) return; while ((de = readdir(dir))) { char path[1024]; char buf[100]; int fd, v; if (*de->d_name == '.') continue; snprintf(path, sizeof(path), "%s/%s/type", BACKLIGHT_CLASS, de->d_name); v = -1; fd = open(path, O_RDONLY); if (fd >= 0) { v = read(fd, buf, sizeof(buf)-1); close(fd); } if (v > 0) { while (v > 0 && isspace(buf[v-1])) v--; buf[v] = '\0'; if (strcmp(buf, "raw") == 0) v = RAW; else if (strcmp(buf, "platform") == 0) v = PLATFORM; else if (strcmp(buf, "firmware") == 0) v = FIRMWARE; else v = NAMED; } else v = NAMED; /* Fallback to priority list of known iface for old kernels */ if (v == NAMED) { int i; for (i = 0; i < ARRAY_SIZE(known_interfaces); i++) { if (strcmp(de->d_name, known_interfaces[i]) == 0) break; } v += i; } if (v < best_type) { char *copy; int max; /* XXX detect right backlight for multi-GPU/panels */ sna_output->backlight_iface = de->d_name; max = sna_output_backlight_get_max(output); if (max <= 0) continue; copy = strdup(de->d_name); if (copy) { free(best_iface); best_iface = copy; best_type = v; } } } closedir(dir); sna_output->backlight_iface = NULL; if (best_iface) { const char *str; sna_output->backlight_iface = best_iface; sna_output->backlight_max = sna_output_backlight_get_max(output); sna_output->backlight_active_level = sna_output_backlight_get(output); switch (best_type) { case FIRMWARE: str = "firmware"; break; case PLATFORM: str = "platform"; break; case RAW: str = "raw"; break; default: str = "unknown"; break; } xf86DrvMsg(output->scrn->scrnIndex, X_INFO, "found backlight control interface %s (type '%s')\n", best_iface, str); } } static void mode_from_kmode(ScrnInfoPtr scrn, drmModeModeInfoPtr kmode, DisplayModePtr mode) { memset(mode, 0, sizeof(DisplayModeRec)); mode->status = MODE_OK; mode->Clock = kmode->clock; mode->HDisplay = kmode->hdisplay; mode->HSyncStart = kmode->hsync_start; mode->HSyncEnd = kmode->hsync_end; mode->HTotal = kmode->htotal; mode->HSkew = kmode->hskew; mode->VDisplay = kmode->vdisplay; mode->VSyncStart = kmode->vsync_start; mode->VSyncEnd = kmode->vsync_end; mode->VTotal = kmode->vtotal; mode->VScan = kmode->vscan; mode->Flags = kmode->flags; //& FLAG_BITS; mode->name = strdup(kmode->name); if (kmode->type & DRM_MODE_TYPE_DRIVER) mode->type = M_T_DRIVER; if (kmode->type & DRM_MODE_TYPE_PREFERRED) mode->type |= M_T_PREFERRED; xf86SetModeCrtc (mode, scrn->adjustFlags); } static void mode_to_kmode(struct drm_mode_modeinfo *kmode, DisplayModePtr mode) { memset(kmode, 0, sizeof(*kmode)); kmode->clock = mode->Clock; kmode->hdisplay = mode->HDisplay; kmode->hsync_start = mode->HSyncStart; kmode->hsync_end = mode->HSyncEnd; kmode->htotal = mode->HTotal; kmode->hskew = mode->HSkew; kmode->vdisplay = mode->VDisplay; kmode->vsync_start = mode->VSyncStart; kmode->vsync_end = mode->VSyncEnd; kmode->vtotal = mode->VTotal; kmode->vscan = mode->VScan; kmode->flags = mode->Flags; //& FLAG_BITS; if (mode->name) strncpy(kmode->name, mode->name, DRM_DISPLAY_MODE_LEN); kmode->name[DRM_DISPLAY_MODE_LEN-1] = 0; } static bool sna_crtc_is_bound(struct sna *sna, xf86CrtcPtr crtc) { struct sna_crtc *sna_crtc = to_sna_crtc(crtc); struct drm_mode_crtc mode; if (!sna_crtc->bo) return false; VG_CLEAR(mode); mode.crtc_id = sna_crtc->id; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETCRTC, &mode)) return false; DBG(("%s: crtc=%d, mode valid?=%d, fb attached?=%d\n", __FUNCTION__, mode.crtc_id, mode.mode_valid, fb_id(sna_crtc->bo) == mode.fb_id)); return mode.mode_valid && fb_id(sna_crtc->bo) == mode.fb_id; } static void sna_crtc_force_outputs_on(xf86CrtcPtr crtc) { xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(crtc->scrn); int i; /* DPMS handling by the kernel is inconsistent, so after setting a * mode on an output presume that we intend for it to be on, or that * the kernel will force it on. * * So force DPMS to be on for all connected outputs, and restore * the backlight. */ for (i = 0; i < xf86_config->num_output; i++) { xf86OutputPtr output = xf86_config->output[i]; if (output->crtc != crtc) continue; output->funcs->dpms(output, DPMSModeOn); } } static bool sna_crtc_apply(xf86CrtcPtr crtc) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(crtc->scrn); struct drm_mode_crtc arg; uint32_t output_ids[16]; int output_count = 0; int i; DBG(("%s\n", __FUNCTION__)); kgem_bo_submit(&sna->kgem, sna_crtc->bo); assert(xf86_config->num_output < ARRAY_SIZE(output_ids)); for (i = 0; i < xf86_config->num_output; i++) { xf86OutputPtr output = xf86_config->output[i]; struct sna_output *sna_output; if (output->crtc != crtc) continue; sna_output = output->driver_private; output_ids[output_count] = sna_output->mode_output->connector_id; output_count++; } VG_CLEAR(arg); arg.crtc_id = sna_crtc->id; arg.fb_id = fb_id(sna_crtc->bo); if (sna_crtc->shadow) { arg.x = 0; arg.y = 0; } else { arg.x = crtc->x; arg.y = crtc->y; } arg.set_connectors_ptr = (uintptr_t)output_ids; arg.count_connectors = output_count; arg.mode = sna_crtc->kmode; arg.mode_valid = 1; DBG(("%s: applying crtc [%d] mode=%dx%d+%d+%d@%d, fb=%d%s update to %d outputs\n", __FUNCTION__, sna_crtc->id, arg.mode.hdisplay, arg.mode.vdisplay, arg.x, arg.y, arg.mode.clock, arg.fb_id, sna_crtc->shadow ? " [shadow]" : "", output_count)); if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_SETCRTC, &arg)) return false; sna_crtc_force_outputs_on(crtc); return true; } static bool sna_mode_enable_shadow(struct sna *sna) { ScreenPtr screen = sna->scrn->pScreen; DBG(("%s\n", __FUNCTION__)); assert(sna->mode.shadow == NULL); assert(sna->mode.shadow_damage == NULL); assert(sna->mode.shadow_active == 0); sna->mode.shadow_damage = DamageCreate(NULL, NULL, DamageReportNone, TRUE, screen, screen); if (!sna->mode.shadow_damage) return false; DamageRegister(&sna->front->drawable, sna->mode.shadow_damage); return true; } static void sna_mode_disable_shadow(struct sna *sna) { if (!sna->mode.shadow_damage) return; DBG(("%s\n", __FUNCTION__)); DamageUnregister(&sna->front->drawable, sna->mode.shadow_damage); DamageDestroy(sna->mode.shadow_damage); sna->mode.shadow_damage = NULL; if (sna->mode.shadow) { kgem_bo_destroy(&sna->kgem, sna->mode.shadow); sna->mode.shadow = NULL; } sna->mode.shadow_active = 0; } static bool sna_crtc_enable_shadow(struct sna *sna, struct sna_crtc *crtc) { if (crtc->shadow) { assert(sna->mode.shadow_damage && sna->mode.shadow_active); return true; } DBG(("%s: enabling for crtc %d\n", __FUNCTION__, crtc->id)); if (!sna->mode.shadow_active) { if (!sna_mode_enable_shadow(sna)) return false; assert(sna->mode.shadow_damage); assert(sna->mode.shadow == NULL); } crtc->shadow = true; sna->mode.shadow_active++; return true; } static void sna_crtc_disable_shadow(struct sna *sna, struct sna_crtc *crtc) { crtc->fallback_shadow = false; if (!crtc->shadow) return; DBG(("%s: disabling for crtc %d\n", __FUNCTION__, crtc->id)); assert(sna->mode.shadow_active > 0); if (!--sna->mode.shadow_active) sna_mode_disable_shadow(sna); crtc->shadow = false; } static void sna_crtc_disable(xf86CrtcPtr crtc) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); struct drm_mode_crtc arg; DBG(("%s: disabling crtc [%d]\n", __FUNCTION__, sna_crtc->id)); memset(&arg, 0, sizeof(arg)); arg.crtc_id = sna_crtc->id; (void)drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_SETCRTC, &arg); sna_crtc_disable_shadow(sna, sna_crtc); if (sna_crtc->bo) { kgem_bo_destroy(&sna->kgem, sna_crtc->bo); sna_crtc->bo = NULL; } } static void sna_crtc_dpms(xf86CrtcPtr crtc, int mode) { DBG(("%s(pipe %d, dpms mode -> %d):= active=%d\n", __FUNCTION__, to_sna_crtc(crtc)->pipe, mode, mode == DPMSModeOn)); } void sna_mode_disable_unused(struct sna *sna) { xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(sna->scrn); int i; DBG(("%s\n", __FUNCTION__)); /* Force consistency between kernel and ourselves */ for (i = 0; i < xf86_config->num_crtc; i++) { if (!xf86_config->crtc[i]->enabled) sna_crtc_disable(xf86_config->crtc[i]); } } static struct kgem_bo *sna_create_bo_for_fbcon(struct sna *sna, const struct drm_mode_fb_cmd *fbcon) { struct drm_gem_flink flink; struct kgem_bo *bo; int ret; /* Create a new reference for the fbcon so that we can track it * using a normal bo and so that when we call gem_close on it we * delete our reference and not fbcon's! */ VG_CLEAR(flink); flink.handle = fbcon->handle; ret = drmIoctl(sna->kgem.fd, DRM_IOCTL_GEM_FLINK, &flink); if (ret) return NULL; bo = kgem_create_for_name(&sna->kgem, flink.name); if (bo == NULL) return NULL; bo->pitch = fbcon->pitch; return bo; } /* Copy the current framebuffer contents into the front-buffer for a seamless * transition from e.g. plymouth. */ void sna_copy_fbcon(struct sna *sna) { xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(sna->scrn); struct drm_mode_fb_cmd fbcon; PixmapPtr scratch; struct sna_pixmap *priv; struct kgem_bo *bo; BoxRec box; bool ok; int sx, sy; int dx, dy; int i; if (wedged(sna)) return; DBG(("%s\n", __FUNCTION__)); /* Scan the connectors for a framebuffer and assume that is the fbcon */ VG_CLEAR(fbcon); fbcon.fb_id = 0; for (i = 0; i < xf86_config->num_crtc; i++) { struct sna_crtc *crtc = to_sna_crtc(xf86_config->crtc[i]); struct drm_mode_crtc mode; VG_CLEAR(mode); mode.crtc_id = crtc->id; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETCRTC, &mode)) continue; if (!mode.fb_id) continue; fbcon.fb_id = mode.fb_id; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETFB, &fbcon)) { fbcon.fb_id = 0; continue; } break; } if (fbcon.fb_id == 0) { DBG(("%s: no fbcon found\n", __FUNCTION__)); return; } /* Wrap the fbcon in a pixmap so that we select the right formats * in the render copy in case we need to preserve the fbcon * across a depth change upon starting X. */ scratch = GetScratchPixmapHeader(sna->scrn->pScreen, fbcon.width, fbcon.height, fbcon.depth, fbcon.bpp, 0, NULL); if (scratch == NullPixmap) return; box.x1 = box.y1 = 0; box.x2 = min(fbcon.width, sna->front->drawable.width); box.y2 = min(fbcon.height, sna->front->drawable.height); bo = sna_create_bo_for_fbcon(sna, &fbcon); if (bo == NULL) goto cleanup_scratch; DBG(("%s: fbcon handle=%d\n", __FUNCTION__, bo->handle)); priv = sna_pixmap(sna->front); assert(priv && priv->gpu_bo); sx = dx = 0; if (box.x2 < (uint16_t)fbcon.width) sx = (fbcon.width - box.x2) / 2; if (box.x2 < sna->front->drawable.width) dx = (sna->front->drawable.width - box.x2) / 2; sy = dy = 0; if (box.y2 < (uint16_t)fbcon.height) sy = (fbcon.height - box.y2) / 2; if (box.y2 < sna->front->drawable.height) dy = (sna->front->drawable.height - box.y2) / 2; ok = sna->render.copy_boxes(sna, GXcopy, scratch, bo, sx, sy, sna->front, priv->gpu_bo, dx, dy, &box, 1, 0); if (!DAMAGE_IS_ALL(priv->gpu_damage)) sna_damage_add_box(&priv->gpu_damage, &box); kgem_bo_destroy(&sna->kgem, bo); sna->scrn->pScreen->canDoBGNoneRoot = ok; cleanup_scratch: FreeScratchPixmapHeader(scratch); } static void update_flush_interval(struct sna *sna) { xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(sna->scrn); int i, max_vrefresh = 0; for (i = 0; i < xf86_config->num_crtc; i++) { if (!xf86_config->crtc[i]->enabled) continue; max_vrefresh = max(max_vrefresh, xf86ModeVRefresh(&xf86_config->crtc[i]->mode)); } if (max_vrefresh == 0) sna->vblank_interval = 0; else sna->vblank_interval = 1000 / max_vrefresh; /* Hz -> ms */ DBG(("max_vrefresh=%d, vblank_interval=%d ms\n", max_vrefresh, sna->vblank_interval)); } static bool use_shadow(struct sna *sna, xf86CrtcPtr crtc) { RRTransformPtr transform; PictTransform crtc_to_fb; struct pict_f_transform f_crtc_to_fb, f_fb_to_crtc; BoxRec b; assert(sna->scrn->virtualX && sna->scrn->virtualY); if (sna->flags & SNA_FORCE_SHADOW) { DBG(("%s: forcing shadow\n", __FUNCTION__)); return true; } if (to_sna_crtc(crtc)->fallback_shadow) { DBG(("%s: fallback shadow\n", __FUNCTION__)); return true; } if (sna->scrn->virtualX > sna->mode.kmode->max_width || sna->scrn->virtualY > sna->mode.kmode->max_height) { DBG(("%s: framebuffer too large (%dx%d) > (%dx%d)\n", __FUNCTION__, sna->scrn->virtualX, sna->scrn->virtualY, sna->mode.kmode->max_width, sna->mode.kmode->max_height)); return true; } transform = NULL; if (crtc->transformPresent) transform = &crtc->transform; if (RRTransformCompute(crtc->x, crtc->y, crtc->mode.HDisplay, crtc->mode.VDisplay, crtc->rotation, transform, &crtc_to_fb, &f_crtc_to_fb, &f_fb_to_crtc)) { DBG(("%s: RandR transform present\n", __FUNCTION__)); return true; } /* And finally check that it is entirely visible */ b.x1 = b.y1 = 0; b.x2 = crtc->mode.HDisplay; b.y2 = crtc->mode.VDisplay; pixman_f_transform_bounds(&f_crtc_to_fb, &b); DBG(("%s? bounds (%d, %d), (%d, %d), framebufer %dx%d\n", __FUNCTION__, b.x1, b.y1, b.x2, b.y2, sna->scrn->virtualX, sna->scrn->virtualY)); if (b.x1 < 0 || b.y1 < 0 || b.x2 > sna->scrn->virtualX || b.y2 > sna->scrn->virtualY) { DBG(("%s: scanout is partly outside the framebuffer\n", __FUNCTION__)); return true; } return false; } static struct kgem_bo *sna_crtc_attach(xf86CrtcPtr crtc) { struct sna_crtc *sna_crtc = to_sna_crtc(crtc); ScrnInfoPtr scrn = crtc->scrn; struct sna *sna = to_sna(scrn); struct kgem_bo *bo; if (use_shadow(sna, crtc)) { if (!sna_crtc_enable_shadow(sna, sna_crtc)) return NULL; DBG(("%s: attaching to per-crtc pixmap %dx%d\n", __FUNCTION__, crtc->mode.HDisplay, crtc->mode.VDisplay)); bo = kgem_create_2d(&sna->kgem, crtc->mode.HDisplay, crtc->mode.VDisplay, scrn->bitsPerPixel, I915_TILING_X, CREATE_SCANOUT); if (bo == NULL) return NULL; if (!get_fb(sna, bo, crtc->mode.HDisplay, crtc->mode.VDisplay)) { kgem_bo_destroy(&sna->kgem, bo); return NULL; } return bo; } else if (sna->flags & SNA_TEAR_FREE) { DBG(("%s: tear-free updates requested\n", __FUNCTION__)); if (!sna_crtc_enable_shadow(sna, sna_crtc)) return NULL; DBG(("%s: attaching to single shadow pixmap\n", __FUNCTION__)); if (sna->mode.shadow == NULL) { bo = kgem_create_2d(&sna->kgem, sna->scrn->virtualX, sna->scrn->virtualY, scrn->bitsPerPixel, I915_TILING_X, CREATE_SCANOUT); if (bo == NULL) return NULL; if (!get_fb(sna, bo, sna->scrn->virtualX, sna->scrn->virtualY)) { kgem_bo_destroy(&sna->kgem, bo); return NULL; } sna->mode.shadow = bo; } return kgem_bo_reference(sna->mode.shadow); } else { DBG(("%s: attaching to framebuffer\n", __FUNCTION__)); sna_crtc_disable_shadow(sna, sna_crtc); bo = sna_pixmap_pin(sna->front); if (!get_fb(sna, bo, scrn->virtualX, scrn->virtualY)) return NULL; return kgem_bo_reference(bo); } } static void sna_crtc_randr(xf86CrtcPtr crtc) { struct sna_crtc *sna_crtc = to_sna_crtc(crtc); struct pict_f_transform f_crtc_to_fb, f_fb_to_crtc; PictTransform crtc_to_fb; PictFilterPtr filter; xFixed *params; int nparams; RRTransformPtr transform; transform = NULL; if (crtc->transformPresent) transform = &crtc->transform; RRTransformCompute(crtc->x, crtc->y, crtc->mode.HDisplay, crtc->mode.VDisplay, crtc->rotation, transform, &crtc_to_fb, &f_crtc_to_fb, &f_fb_to_crtc); filter = NULL; params = NULL; nparams = 0; if (sna_crtc->shadow) { #ifdef RANDR_12_INTERFACE if (transform) { if (transform->nparams) { params = malloc(transform->nparams * sizeof(xFixed)); if (params) { memcpy(params, transform->params, transform->nparams * sizeof(xFixed)); nparams = transform->nparams; filter = transform->filter; } } else filter = transform->filter; } #endif crtc->transform_in_use = TRUE; } else crtc->transform_in_use = FALSE; crtc->crtc_to_framebuffer = crtc_to_fb; crtc->f_crtc_to_framebuffer = f_crtc_to_fb; crtc->f_framebuffer_to_crtc = f_fb_to_crtc; free(crtc->params); crtc->params = params; crtc->nparams = nparams; crtc->filter = filter; if (filter) { crtc->filter_width = filter->width; crtc->filter_height = filter->height; } else { crtc->filter_width = 0; crtc->filter_height = 0; } crtc->bounds.x1 = 0; crtc->bounds.x2 = crtc->mode.HDisplay; crtc->bounds.y1 = 0; crtc->bounds.y2 = crtc->mode.VDisplay; pixman_f_transform_bounds(&f_crtc_to_fb, &crtc->bounds); DBG(("%s: transform? %d, bounds (%d, %d), (%d, %d)\n", __FUNCTION__, crtc->transform_in_use, crtc->bounds.x1, crtc->bounds.y1, crtc->bounds.x2, crtc->bounds.y2)); } static void sna_crtc_damage(xf86CrtcPtr crtc) { ScreenPtr screen = crtc->scrn->pScreen; struct sna *sna = to_sna(crtc->scrn); RegionRec region, *damage; region.extents = crtc->bounds; region.data = NULL; if (region.extents.x1 < 0) region.extents.x1 = 0; if (region.extents.y1 < 0) region.extents.y1 = 0; if (region.extents.x2 > screen->width) region.extents.x2 = screen->width; if (region.extents.y2 > screen->height) region.extents.y2 = screen->height; DBG(("%s: marking crtc %d as completely damaged (%d, %d), (%d, %d)\n", __FUNCTION__, to_sna_crtc(crtc)->id, region.extents.x1, region.extents.y1, region.extents.x2, region.extents.y2)); assert(sna->mode.shadow_damage && sna->mode.shadow_active); damage = DamageRegion(sna->mode.shadow_damage); RegionUnion(damage, damage, ®ion); } static Bool sna_crtc_set_mode_major(xf86CrtcPtr crtc, DisplayModePtr mode, Rotation rotation, int x, int y) { ScrnInfoPtr scrn = crtc->scrn; struct sna *sna = to_sna(scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); struct kgem_bo *saved_bo, *bo; struct drm_mode_modeinfo saved_kmode; xf86DrvMsg(crtc->scrn->scrnIndex, X_INFO, "switch to mode %dx%d on crtc %d (pipe %d)\n", mode->HDisplay, mode->VDisplay, sna_crtc->id, sna_crtc->pipe); DBG(("%s(crtc=%d [pipe=%d] rotation=%d, x=%d, y=%d, mode=%dx%d@%d)\n", __FUNCTION__, sna_crtc->id, sna_crtc->pipe, rotation, x, y, mode->HDisplay, mode->VDisplay, mode->Clock)); assert(mode->HDisplay <= sna->mode.kmode->max_width && mode->VDisplay <= sna->mode.kmode->max_height); crtc->funcs->gamma_set(crtc, crtc->gamma_red, crtc->gamma_green, crtc->gamma_blue, crtc->gamma_size); saved_kmode = sna_crtc->kmode; saved_bo = sna_crtc->bo; sna_crtc->fallback_shadow = false; retry: /* Attach per-crtc pixmap or direct */ bo = sna_crtc_attach(crtc); if (bo == NULL) return FALSE; sna_crtc->bo = bo; mode_to_kmode(&sna_crtc->kmode, mode); if (!sna_crtc_apply(crtc)) { kgem_bo_destroy(&sna->kgem, bo); if (!sna_crtc->shadow) { sna_crtc->fallback_shadow = true; goto retry; } xf86DrvMsg(crtc->scrn->scrnIndex, X_ERROR, "failed to set mode: %s\n", strerror(errno)); sna_crtc->bo = saved_bo; sna_crtc->kmode = saved_kmode; return FALSE; } if (saved_bo) kgem_bo_destroy(&sna->kgem, saved_bo); update_flush_interval(sna); sna_crtc_randr(crtc); if (sna_crtc->shadow) sna_crtc_damage(crtc); if (scrn->pScreen) xf86_reload_cursors(scrn->pScreen); return TRUE; } void sna_mode_adjust_frame(struct sna *sna, int x, int y) { xf86CrtcConfigPtr config = XF86_CRTC_CONFIG_PTR(sna->scrn); xf86OutputPtr output = config->output[config->compat_output]; xf86CrtcPtr crtc = output->crtc; if (crtc && crtc->enabled) { int saved_x = crtc->x; int saved_y = crtc->y; crtc->x = x; crtc->y = y; if (!sna_crtc_set_mode_major(crtc, &crtc->mode, crtc->rotation, x, y)) { crtc->x = saved_x; crtc->y = saved_y; } } } static void sna_crtc_hide_cursor(xf86CrtcPtr crtc) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); struct drm_mode_cursor arg; __DBG(("%s: CRTC:%d\n", __FUNCTION__, sna_crtc->id)); VG_CLEAR(arg); arg.flags = DRM_MODE_CURSOR_BO; arg.crtc_id = sna_crtc->id; arg.width = arg.height = 64; arg.handle = 0; (void)drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_CURSOR, &arg); } static void sna_crtc_show_cursor(xf86CrtcPtr crtc) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); struct drm_mode_cursor arg; __DBG(("%s: CRTC:%d\n", __FUNCTION__, sna_crtc->id)); VG_CLEAR(arg); arg.flags = DRM_MODE_CURSOR_BO; arg.crtc_id = sna_crtc->id; arg.width = arg.height = 64; arg.handle = sna_crtc->cursor; (void)drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_CURSOR, &arg); } static void sna_crtc_set_cursor_colors(xf86CrtcPtr crtc, int bg, int fg) { __DBG(("%s: CRTC:%d (bg=%x, fg=%x)\n", __FUNCTION__, to_sna_crtc(crtc)->id, bg, fg)); } static void sna_crtc_set_cursor_position(xf86CrtcPtr crtc, int x, int y) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); struct drm_mode_cursor arg; __DBG(("%s: CRTC:%d (%d, %d)\n", __FUNCTION__, sna_crtc->id, x, y)); VG_CLEAR(arg); arg.flags = DRM_MODE_CURSOR_MOVE; arg.crtc_id = sna_crtc->id; arg.x = x; arg.y = y; arg.handle = sna_crtc->cursor; (void)drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_CURSOR, &arg); } static void sna_crtc_load_cursor_argb(xf86CrtcPtr crtc, CARD32 *image) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); struct drm_i915_gem_pwrite pwrite; __DBG(("%s: CRTC:%d\n", __FUNCTION__, sna_crtc->id)); VG_CLEAR(pwrite); pwrite.handle = sna_crtc->cursor; pwrite.offset = 0; pwrite.size = 64*64*4; pwrite.data_ptr = (uintptr_t)image; (void)drmIoctl(sna->kgem.fd, DRM_IOCTL_I915_GEM_PWRITE, &pwrite); } static void sna_crtc_gamma_set(xf86CrtcPtr crtc, CARD16 *red, CARD16 *green, CARD16 *blue, int size) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); drmModeCrtcSetGamma(sna->kgem.fd, sna_crtc->id, size, red, green, blue); } static void sna_crtc_destroy(xf86CrtcPtr crtc) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); sna_crtc_hide_cursor(crtc); gem_close(sna->kgem.fd, sna_crtc->cursor); list_del(&sna_crtc->link); free(sna_crtc); crtc->driver_private = NULL; } static const xf86CrtcFuncsRec sna_crtc_funcs = { .dpms = sna_crtc_dpms, .set_mode_major = sna_crtc_set_mode_major, .set_cursor_colors = sna_crtc_set_cursor_colors, .set_cursor_position = sna_crtc_set_cursor_position, .show_cursor = sna_crtc_show_cursor, .hide_cursor = sna_crtc_hide_cursor, .load_cursor_argb = sna_crtc_load_cursor_argb, .gamma_set = sna_crtc_gamma_set, .destroy = sna_crtc_destroy, }; static uint32_t sna_crtc_find_plane(struct sna *sna, int pipe) { struct drm_mode_get_plane_res r; uint32_t *planes, id = 0; int i; VG_CLEAR(r); r.count_planes = 0; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETPLANERESOURCES, &r)) return 0; if (!r.count_planes) return 0; planes = malloc(sizeof(uint32_t)*r.count_planes); if (planes == NULL) return 0; r.plane_id_ptr = (uintptr_t)planes; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETPLANERESOURCES, &r)) r.count_planes = 0; for (i = 0; i < r.count_planes; i++) { struct drm_mode_get_plane p; VG_CLEAR(p); p.plane_id = planes[i]; p.count_format_types = 0; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETPLANE, &p) == 0) { if (p.possible_crtcs & (1 << pipe)) { id = p.plane_id; break; } } } free(planes); return id; } static void sna_crtc_init(ScrnInfoPtr scrn, struct sna_mode *mode, int num) { struct sna *sna = to_sna(scrn); xf86CrtcPtr crtc; struct sna_crtc *sna_crtc; struct drm_i915_get_pipe_from_crtc_id get_pipe; DBG(("%s\n", __FUNCTION__)); sna_crtc = calloc(sizeof(struct sna_crtc), 1); if (sna_crtc == NULL) return; sna_crtc->id = mode->kmode->crtcs[num]; VG_CLEAR(get_pipe); get_pipe.pipe = 0; get_pipe.crtc_id = sna_crtc->id; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_I915_GET_PIPE_FROM_CRTC_ID, &get_pipe)) { free(sna_crtc); return; } sna_crtc->pipe = get_pipe.pipe; sna_crtc->plane = sna_crtc_find_plane(sna, sna_crtc->pipe); if (xf86IsEntityShared(scrn->entityList[0]) && scrn->confScreen->device->screen != sna_crtc->pipe) { free(sna_crtc); return; } crtc = xf86CrtcCreate(scrn, &sna_crtc_funcs); if (crtc == NULL) { free(sna_crtc); return; } crtc->driver_private = sna_crtc; sna_crtc->cursor = gem_create(sna->kgem.fd, 64*64*4); DBG(("%s: created handle=%d for cursor on CRTC:%d\n", __FUNCTION__, sna_crtc->cursor, sna_crtc->id)); list_add(&sna_crtc->link, &mode->crtcs); DBG(("%s: attached crtc[%d] id=%d, pipe=%d\n", __FUNCTION__, num, sna_crtc->id, sna_crtc->pipe)); } static bool is_panel(int type) { return (type == DRM_MODE_CONNECTOR_LVDS || type == DRM_MODE_CONNECTOR_eDP); } static xf86OutputStatus sna_output_detect(xf86OutputPtr output) { /* go to the hw and retrieve a new output struct */ struct sna *sna = to_sna(output->scrn); struct sna_output *sna_output = output->driver_private; xf86OutputStatus status; DBG(("%s\n", __FUNCTION__)); drmModeFreeConnector(sna_output->mode_output); sna_output->mode_output = drmModeGetConnector(sna->kgem.fd, sna_output->id); switch (sna_output->mode_output->connection) { case DRM_MODE_CONNECTED: status = XF86OutputStatusConnected; break; case DRM_MODE_DISCONNECTED: status = XF86OutputStatusDisconnected; break; default: case DRM_MODE_UNKNOWNCONNECTION: status = XF86OutputStatusUnknown; break; } return status; } static Bool sna_output_mode_valid(xf86OutputPtr output, DisplayModePtr mode) { struct sna_output *sna_output = output->driver_private; struct sna *sna = to_sna(output->scrn); if (mode->HDisplay > sna->mode.kmode->max_width) return MODE_VIRTUAL_X; if (mode->VDisplay > sna->mode.kmode->max_height) return MODE_VIRTUAL_Y; /* Check that we can successfully pin this into the global GTT */ if ((kgem_can_create_2d(&sna->kgem, mode->HDisplay, mode->VDisplay, sna->scrn->bitsPerPixel) & KGEM_CAN_CREATE_GTT) == 0) return MODE_MEM_VIRT; /* * If the connector type is a panel, we will use the panel limit to * verfiy whether the mode is valid. */ if (sna_output->has_panel_limits) { if (mode->HDisplay > sna_output->panel_hdisplay || mode->VDisplay > sna_output->panel_vdisplay) return MODE_PANEL; } return MODE_OK; } static void sna_output_attach_edid(xf86OutputPtr output) { struct sna *sna = to_sna(output->scrn); struct sna_output *sna_output = output->driver_private; drmModeConnectorPtr koutput = sna_output->mode_output; void *raw = NULL; int raw_length = 0; xf86MonPtr mon = NULL; int i; /* look for an EDID property */ for (i = 0; i < koutput->count_props; i++) { struct drm_mode_get_property prop; struct drm_mode_get_blob blob; void *tmp; VG_CLEAR(prop); prop.prop_id = koutput->props[i]; prop.count_values = 0; prop.count_enum_blobs = 0; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETPROPERTY, &prop)) continue; if (!(prop.flags & DRM_MODE_PROP_BLOB)) continue; if (strcmp(prop.name, "EDID")) continue; VG_CLEAR(blob); blob.length = 0; blob.data =0; blob.blob_id = koutput->prop_values[i]; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETPROPBLOB, &blob)) continue; DBG(("%s: retreiving blob (property %d, id=%d, value=%ld), length=%d\n", __FUNCTION__, i, koutput->props[i], (long)koutput->prop_values[i], blob.length)); tmp = malloc(blob.length); if (tmp == NULL) continue; VG(memset(tmp, 0, blob.length)); blob.data = (uintptr_t)tmp; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETPROPBLOB, &blob)) { free(tmp); continue; } free(raw); raw = tmp; raw_length = blob.length; } if (raw) { mon = xf86InterpretEDID(output->scrn->scrnIndex, raw); if (mon && raw_length > 128) mon->flags |= MONITOR_EDID_COMPLETE_RAWDATA; } xf86OutputSetEDID(output, mon); free(raw); } static DisplayModePtr sna_output_panel_edid(xf86OutputPtr output, DisplayModePtr modes) { xf86MonPtr mon = output->MonInfo; if (!mon || !GTF_SUPPORTED(mon->features.msc)) { DisplayModePtr i, m, p = NULL; int max_x = 0, max_y = 0; float max_vrefresh = 0.0; for (m = modes; m; m = m->next) { if (m->type & M_T_PREFERRED) p = m; max_x = max(max_x, m->HDisplay); max_y = max(max_y, m->VDisplay); max_vrefresh = max(max_vrefresh, xf86ModeVRefresh(m)); } max_vrefresh = max(max_vrefresh, 60.0); max_vrefresh *= (1 + SYNC_TOLERANCE); m = xf86GetDefaultModes(); xf86ValidateModesSize(output->scrn, m, max_x, max_y, 0); for (i = m; i; i = i->next) { if (xf86ModeVRefresh(i) > max_vrefresh) i->status = MODE_VSYNC; if (p && i->HDisplay >= p->HDisplay && i->VDisplay >= p->VDisplay && xf86ModeVRefresh(i) >= xf86ModeVRefresh(p)) i->status = MODE_VSYNC; } xf86PruneInvalidModes(output->scrn, &m, FALSE); modes = xf86ModesAdd(modes, m); } return modes; } static DisplayModePtr sna_output_get_modes(xf86OutputPtr output) { struct sna_output *sna_output = output->driver_private; drmModeConnectorPtr koutput = sna_output->mode_output; DisplayModePtr Modes = NULL; int i; DBG(("%s\n", __FUNCTION__)); sna_output_attach_edid(output); /* modes should already be available */ for (i = 0; i < koutput->count_modes; i++) { DisplayModePtr Mode; Mode = calloc(1, sizeof(DisplayModeRec)); if (Mode) { mode_from_kmode(output->scrn, &koutput->modes[i], Mode); Modes = xf86ModesAdd(Modes, Mode); } } /* * If the connector type is a panel, we will traverse the kernel mode to * get the panel limit. And then add all the standard modes to fake * the fullscreen experience. * If it is incorrect, please fix me. */ sna_output->has_panel_limits = false; if (is_panel(koutput->connector_type)) { for (i = 0; i < koutput->count_modes; i++) { drmModeModeInfo *mode_ptr; mode_ptr = &koutput->modes[i]; if (mode_ptr->hdisplay > sna_output->panel_hdisplay) sna_output->panel_hdisplay = mode_ptr->hdisplay; if (mode_ptr->vdisplay > sna_output->panel_vdisplay) sna_output->panel_vdisplay = mode_ptr->vdisplay; } sna_output->has_panel_limits = sna_output->panel_hdisplay && sna_output->panel_vdisplay; Modes = sna_output_panel_edid(output, Modes); } return Modes; } static void sna_output_destroy(xf86OutputPtr output) { struct sna_output *sna_output = output->driver_private; int i; for (i = 0; i < sna_output->num_props; i++) { drmModeFreeProperty(sna_output->props[i].mode_prop); free(sna_output->props[i].atoms); } free(sna_output->props); drmModeFreeConnector(sna_output->mode_output); sna_output->mode_output = NULL; free(sna_output->backlight_iface); list_del(&sna_output->link); free(sna_output); output->driver_private = NULL; } static void sna_output_dpms_backlight(xf86OutputPtr output, int oldmode, int mode) { struct sna_output *sna_output = output->driver_private; if (!sna_output->backlight_iface) return; if (mode == DPMSModeOn) { /* If we're going from off->on we may need to turn on the backlight. */ if (oldmode != DPMSModeOn) sna_output_backlight_set(output, sna_output->backlight_active_level); } else { /* Only save the current backlight value if we're going from on to off. */ if (oldmode == DPMSModeOn) sna_output->backlight_active_level = sna_output_backlight_get(output); sna_output_backlight_set(output, 0); } } static void sna_output_dpms(xf86OutputPtr output, int dpms) { struct sna *sna = to_sna(output->scrn); struct sna_output *sna_output = output->driver_private; drmModeConnectorPtr koutput = sna_output->mode_output; int i; DBG(("%s: dpms=%d\n", __FUNCTION__, dpms)); for (i = 0; i < koutput->count_props; i++) { struct drm_mode_get_property prop; VG_CLEAR(prop); prop.prop_id = koutput->props[i]; prop.count_values = 0; prop.count_enum_blobs = 0; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETPROPERTY, &prop)) continue; if (strcmp(prop.name, "DPMS")) continue; /* Record thevalue of the backlight before turning * off the display, and reset if after turnging it on. * Order is important as the kernel may record and also * reset the backlight across DPMS. Hence we need to * record the value before the kernel modifies it * and reapply it afterwards. */ if (dpms == DPMSModeOff) sna_output_dpms_backlight(output, sna_output->dpms_mode, dpms); drmModeConnectorSetProperty(sna->kgem.fd, sna_output->id, prop.prop_id, dpms); if (dpms != DPMSModeOff) sna_output_dpms_backlight(output, sna_output->dpms_mode, dpms); sna_output->dpms_mode = dpms; break; } } static bool sna_property_ignore(drmModePropertyPtr prop) { if (!prop) return true; /* ignore blob prop */ if (prop->flags & DRM_MODE_PROP_BLOB) return true; /* ignore standard property */ if (!strcmp(prop->name, "EDID") || !strcmp(prop->name, "DPMS")) return true; return false; } static void sna_output_create_ranged_atom(xf86OutputPtr output, Atom *atom, const char *name, INT32 min, INT32 max, uint64_t value, Bool immutable) { int err; INT32 atom_range[2]; atom_range[0] = min; atom_range[1] = max; *atom = MakeAtom(name, strlen(name), TRUE); err = RRConfigureOutputProperty(output->randr_output, *atom, FALSE, TRUE, immutable, 2, atom_range); if (err != 0) xf86DrvMsg(output->scrn->scrnIndex, X_ERROR, "RRConfigureOutputProperty error, %d\n", err); err = RRChangeOutputProperty(output->randr_output, *atom, XA_INTEGER, 32, PropModeReplace, 1, &value, FALSE, TRUE); if (err != 0) xf86DrvMsg(output->scrn->scrnIndex, X_ERROR, "RRChangeOutputProperty error, %d\n", err); } #define BACKLIGHT_NAME "Backlight" #define BACKLIGHT_DEPRECATED_NAME "BACKLIGHT" static Atom backlight_atom, backlight_deprecated_atom; static void sna_output_create_resources(xf86OutputPtr output) { struct sna *sna = to_sna(output->scrn); struct sna_output *sna_output = output->driver_private; drmModeConnectorPtr mode_output = sna_output->mode_output; int i, j, err; sna_output->props = calloc(mode_output->count_props, sizeof(struct sna_property)); if (!sna_output->props) return; sna_output->num_props = 0; for (i = j = 0; i < mode_output->count_props; i++) { drmModePropertyPtr drmmode_prop; drmmode_prop = drmModeGetProperty(sna->kgem.fd, mode_output->props[i]); if (sna_property_ignore(drmmode_prop)) { drmModeFreeProperty(drmmode_prop); continue; } sna_output->props[j].mode_prop = drmmode_prop; sna_output->props[j].value = mode_output->prop_values[i]; j++; } sna_output->num_props = j; for (i = 0; i < sna_output->num_props; i++) { struct sna_property *p = &sna_output->props[i]; drmModePropertyPtr drmmode_prop = p->mode_prop; if (drmmode_prop->flags & DRM_MODE_PROP_RANGE) { p->num_atoms = 1; p->atoms = calloc(p->num_atoms, sizeof(Atom)); if (!p->atoms) continue; sna_output_create_ranged_atom(output, &p->atoms[0], drmmode_prop->name, drmmode_prop->values[0], drmmode_prop->values[1], p->value, drmmode_prop->flags & DRM_MODE_PROP_IMMUTABLE ? TRUE : FALSE); } else if (drmmode_prop->flags & DRM_MODE_PROP_ENUM) { p->num_atoms = drmmode_prop->count_enums + 1; p->atoms = calloc(p->num_atoms, sizeof(Atom)); if (!p->atoms) continue; p->atoms[0] = MakeAtom(drmmode_prop->name, strlen(drmmode_prop->name), TRUE); for (j = 1; j <= drmmode_prop->count_enums; j++) { struct drm_mode_property_enum *e = &drmmode_prop->enums[j-1]; p->atoms[j] = MakeAtom(e->name, strlen(e->name), TRUE); } err = RRConfigureOutputProperty(output->randr_output, p->atoms[0], FALSE, FALSE, drmmode_prop->flags & DRM_MODE_PROP_IMMUTABLE ? TRUE : FALSE, p->num_atoms - 1, (INT32 *)&p->atoms[1]); if (err != 0) { xf86DrvMsg(output->scrn->scrnIndex, X_ERROR, "RRConfigureOutputProperty error, %d\n", err); } for (j = 0; j < drmmode_prop->count_enums; j++) if (drmmode_prop->enums[j].value == p->value) break; /* there's always a matching value */ err = RRChangeOutputProperty(output->randr_output, p->atoms[0], XA_ATOM, 32, PropModeReplace, 1, &p->atoms[j+1], FALSE, TRUE); if (err != 0) { xf86DrvMsg(output->scrn->scrnIndex, X_ERROR, "RRChangeOutputProperty error, %d\n", err); } } } if (sna_output->backlight_iface) { /* Set up the backlight property, which takes effect * immediately and accepts values only within the * backlight_range. */ sna_output_create_ranged_atom(output, &backlight_atom, BACKLIGHT_NAME, 0, sna_output->backlight_max, sna_output->backlight_active_level, FALSE); sna_output_create_ranged_atom(output, &backlight_deprecated_atom, BACKLIGHT_DEPRECATED_NAME, 0, sna_output->backlight_max, sna_output->backlight_active_level, FALSE); } } static Bool sna_output_set_property(xf86OutputPtr output, Atom property, RRPropertyValuePtr value) { struct sna *sna = to_sna(output->scrn); struct sna_output *sna_output = output->driver_private; int i; if (property == backlight_atom || property == backlight_deprecated_atom) { INT32 val; if (value->type != XA_INTEGER || value->format != 32 || value->size != 1) { return FALSE; } val = *(INT32 *)value->data; if (val < 0 || val > sna_output->backlight_max) return FALSE; if (sna_output->dpms_mode == DPMSModeOn) sna_output_backlight_set(output, val); sna_output->backlight_active_level = val; return TRUE; } for (i = 0; i < sna_output->num_props; i++) { struct sna_property *p = &sna_output->props[i]; if (p->atoms[0] != property) continue; if (p->mode_prop->flags & DRM_MODE_PROP_RANGE) { uint32_t val; if (value->type != XA_INTEGER || value->format != 32 || value->size != 1) return FALSE; val = *(uint32_t *)value->data; drmModeConnectorSetProperty(sna->kgem.fd, sna_output->id, p->mode_prop->prop_id, (uint64_t)val); return TRUE; } else if (p->mode_prop->flags & DRM_MODE_PROP_ENUM) { Atom atom; const char *name; int j; if (value->type != XA_ATOM || value->format != 32 || value->size != 1) return FALSE; memcpy(&atom, value->data, 4); name = NameForAtom(atom); if (name == NULL) return FALSE; /* search for matching name string, then set its value down */ for (j = 0; j < p->mode_prop->count_enums; j++) { if (!strcmp(p->mode_prop->enums[j].name, name)) { drmModeConnectorSetProperty(sna->kgem.fd, sna_output->id, p->mode_prop->prop_id, p->mode_prop->enums[j].value); return TRUE; } } return FALSE; } } /* We didn't recognise this property, just report success in order * to allow the set to continue, otherwise we break setting of * common properties like EDID. */ return TRUE; } static Bool sna_output_get_property(xf86OutputPtr output, Atom property) { struct sna_output *sna_output = output->driver_private; int err; if (property == backlight_atom || property == backlight_deprecated_atom) { INT32 val; if (! sna_output->backlight_iface) return FALSE; val = sna_output_backlight_get(output); if (val < 0) return FALSE; err = RRChangeOutputProperty(output->randr_output, property, XA_INTEGER, 32, PropModeReplace, 1, &val, FALSE, TRUE); if (err != 0) { xf86DrvMsg(output->scrn->scrnIndex, X_ERROR, "RRChangeOutputProperty error, %d\n", err); return FALSE; } return TRUE; } return FALSE; } static const xf86OutputFuncsRec sna_output_funcs = { .create_resources = sna_output_create_resources, #ifdef RANDR_12_INTERFACE .set_property = sna_output_set_property, .get_property = sna_output_get_property, #endif .dpms = sna_output_dpms, .detect = sna_output_detect, .mode_valid = sna_output_mode_valid, .get_modes = sna_output_get_modes, .destroy = sna_output_destroy }; static const int subpixel_conv_table[7] = { 0, SubPixelUnknown, SubPixelHorizontalRGB, SubPixelHorizontalBGR, SubPixelVerticalRGB, SubPixelVerticalBGR, SubPixelNone }; static const char *output_names[] = { "None", "VGA", "DVI", "DVI", "DVI", "Composite", "TV", "LVDS", "CTV", "DIN", "DP", "HDMI", "HDMI", "TV", "eDP", }; static bool sna_zaphod_match(const char *s, const char *output) { char t[20]; unsigned int i = 0; do { /* match any outputs in a comma list, stopping at whitespace */ switch (*s) { case '\0': t[i] = '\0'; return strcmp(t, output) == 0; case ',': t[i] ='\0'; if (strcmp(t, output) == 0) return TRUE; i = 0; break; case ' ': case '\t': case '\n': case '\r': break; default: t[i++] = *s; break; } s++; } while (i < sizeof(t)); return false; } static void sna_output_init(ScrnInfoPtr scrn, struct sna_mode *mode, int num) { struct sna *sna = to_sna(scrn); xf86OutputPtr output; drmModeConnectorPtr koutput; struct drm_mode_get_encoder enc; struct sna_output *sna_output; const char *output_name; const char *s; char name[32]; koutput = drmModeGetConnector(sna->kgem.fd, mode->kmode->connectors[num]); if (!koutput) return; VG_CLEAR(enc); enc.encoder_id = koutput->encoders[0]; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_GETENCODER, &enc)) goto cleanup_connector; if (koutput->connector_type < ARRAY_SIZE(output_names)) output_name = output_names[koutput->connector_type]; else output_name = "UNKNOWN"; snprintf(name, 32, "%s%d", output_name, koutput->connector_type_id); if (xf86IsEntityShared(scrn->entityList[0])) { s = xf86GetOptValString(sna->Options, OPTION_ZAPHOD); if (s && !sna_zaphod_match(s, name)) goto cleanup_connector; } output = xf86OutputCreate(scrn, &sna_output_funcs, name); if (!output) goto cleanup_connector; sna_output = calloc(sizeof(struct sna_output), 1); if (!sna_output) goto cleanup_output; sna_output->id = mode->kmode->connectors[num]; sna_output->mode_output = koutput; output->mm_width = koutput->mmWidth; output->mm_height = koutput->mmHeight; output->subpixel_order = subpixel_conv_table[koutput->subpixel]; output->driver_private = sna_output; if (is_panel(koutput->connector_type)) sna_output_backlight_init(output); output->possible_crtcs = enc.possible_crtcs; output->possible_clones = enc.possible_clones; output->interlaceAllowed = TRUE; list_add(&sna_output->link, &mode->outputs); return; cleanup_output: xf86OutputDestroy(output); cleanup_connector: drmModeFreeConnector(koutput); } struct sna_visit_set_pixmap_window { PixmapPtr old, new; }; static int sna_visit_set_window_pixmap(WindowPtr window, pointer data) { struct sna_visit_set_pixmap_window *visit = data; ScreenPtr screen = window->drawable.pScreen; if (screen->GetWindowPixmap(window) == visit->old) { screen->SetWindowPixmap(window, visit->new); return WT_WALKCHILDREN; } return WT_DONTWALKCHILDREN; } static void sna_redirect_screen_pixmap(ScrnInfoPtr scrn, PixmapPtr old, PixmapPtr new) { ScreenPtr screen = scrn->pScreen; struct sna_visit_set_pixmap_window visit; visit.old = old; visit.new = new; TraverseTree(screen->root, sna_visit_set_window_pixmap, &visit); screen->SetScreenPixmap(new); } static void copy_front(struct sna *sna, PixmapPtr old, PixmapPtr new) { struct sna_pixmap *old_priv, *new_priv; int16_t sx, sy, dx, dy; BoxRec box; DBG(("%s\n", __FUNCTION__)); if (wedged(sna)) return; old_priv = sna_pixmap_force_to_gpu(old, MOVE_READ); if (!old_priv) return; new_priv = sna_pixmap_force_to_gpu(new, MOVE_WRITE); if (!new_priv) return; box.x1 = box.y1 = 0; box.x2 = min(old->drawable.width, new->drawable.width); box.y2 = min(old->drawable.height, new->drawable.height); sx = dx = 0; if (box.x2 < old->drawable.width) sx = (old->drawable.width - box.x2) / 2; if (box.x2 < new->drawable.width) dx = (new->drawable.width - box.x2) / 2; sy = dy = 0; if (box.y2 < old->drawable.height) sy = (old->drawable.height - box.y2) / 2; if (box.y2 < new->drawable.height) dy = (new->drawable.height - box.y2) / 2; DBG(("%s: copying box (%dx%d) from (%d, %d) to (%d, %d)\n", __FUNCTION__, box.x2, box.y2, sx, sy, dx, dy)); if (old_priv->clear) { (void)sna->render.fill_one(sna, new, new_priv->gpu_bo, old_priv->clear_color, 0, 0, new->drawable.width, new->drawable.height, GXcopy); new_priv->clear = true; new_priv->clear_color = old_priv->clear_color; } else { if (box.x2 != new->drawable.width || box.y2 != new->drawable.height) { (void)sna->render.fill_one(sna, new, new_priv->gpu_bo, 0, 0, 0, new->drawable.width, new->drawable.height, GXclear); } (void)sna->render.copy_boxes(sna, GXcopy, old, old_priv->gpu_bo, sx, sy, new, new_priv->gpu_bo, dx, dy, &box, 1, 0); } if (!DAMAGE_IS_ALL(new_priv->gpu_damage)) sna_damage_all(&new_priv->gpu_damage, new->drawable.width, new->drawable.height); } static Bool sna_crtc_resize(ScrnInfoPtr scrn, int width, int height) { xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(scrn); struct sna *sna = to_sna(scrn); PixmapPtr old_front, new_front; int i; DBG(("%s (%d, %d) -> (%d, %d)\n", __FUNCTION__, scrn->virtualX, scrn->virtualY, width, height)); if (scrn->virtualX == width && scrn->virtualY == height) return TRUE; assert(scrn->pScreen->GetScreenPixmap(scrn->pScreen) == sna->front); assert(scrn->pScreen->GetWindowPixmap(scrn->pScreen->root) == sna->front); DBG(("%s: creating new framebuffer %dx%d\n", __FUNCTION__, width, height)); old_front = sna->front; new_front = scrn->pScreen->CreatePixmap(scrn->pScreen, width, height, scrn->depth, SNA_CREATE_FB); if (!new_front) return FALSE; for (i = 0; i < xf86_config->num_crtc; i++) sna_crtc_disable_shadow(sna, to_sna_crtc(xf86_config->crtc[i])); assert(sna->mode.shadow_active == 0); assert(sna->mode.shadow_damage == NULL); assert(sna->mode.shadow == NULL); copy_front(sna, sna->front, new_front); sna->front = new_front; scrn->virtualX = width; scrn->virtualY = height; scrn->displayWidth = width; for (i = 0; i < xf86_config->num_crtc; i++) { xf86CrtcPtr crtc = xf86_config->crtc[i]; if (!crtc->enabled) continue; if (!sna_crtc_set_mode_major(crtc, &crtc->mode, crtc->rotation, crtc->x, crtc->y)) sna_crtc_disable(crtc); } sna_redirect_screen_pixmap(scrn, old_front, sna->front); assert(scrn->pScreen->GetScreenPixmap(scrn->pScreen) == sna->front); assert(scrn->pScreen->GetWindowPixmap(scrn->pScreen->root) == sna->front); scrn->pScreen->DestroyPixmap(old_front); return TRUE; } static int do_page_flip(struct sna *sna, struct kgem_bo *bo, void *data, int ref_crtc_hw_id) { xf86CrtcConfigPtr config = XF86_CRTC_CONFIG_PTR(sna->scrn); int width = sna->scrn->virtualX; int height = sna->scrn->virtualY; int count = 0; int i; /* * Queue flips on all enabled CRTCs * Note that if/when we get per-CRTC buffers, we'll have to update this. * Right now it assumes a single shared fb across all CRTCs, with the * kernel fixing up the offset of each CRTC as necessary. * * Also, flips queued on disabled or incorrectly configured displays * may never complete; this is a configuration error. */ for (i = 0; i < config->num_crtc; i++) { struct sna_crtc *crtc = config->crtc[i]->driver_private; struct drm_mode_crtc_page_flip arg; DBG(("%s: crtc %d active? %d\n", __FUNCTION__, i, crtc->bo != NULL)); if (crtc->bo == NULL) continue; arg.crtc_id = crtc->id; arg.fb_id = get_fb(sna, bo, width, height); if (arg.fb_id == 0) goto disable; /* Only the reference crtc will finally deliver its page flip * completion event. All other crtc's events will be discarded. */ arg.user_data = (uintptr_t)data; arg.user_data |= crtc->pipe == ref_crtc_hw_id; arg.flags = DRM_MODE_PAGE_FLIP_EVENT; arg.reserved = 0; DBG(("%s: crtc %d [ref? %d] --> fb %d\n", __FUNCTION__, crtc->id, crtc->pipe == ref_crtc_hw_id, arg.fb_id)); if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_PAGE_FLIP, &arg)) { DBG(("%s: flip [fb=%d] on crtc %d [%d] failed - %d\n", __FUNCTION__, arg.fb_id, i, crtc->id, errno)); disable: sna_crtc_disable(config->crtc[i]); continue; } kgem_bo_destroy(&sna->kgem, crtc->bo); crtc->bo = kgem_bo_reference(bo); count++; } return count; } int sna_page_flip(struct sna *sna, struct kgem_bo *bo, void *data, int ref_crtc_hw_id) { int count; DBG(("%s: handle %d attached\n", __FUNCTION__, bo->handle)); kgem_submit(&sna->kgem); /* * Queue flips on all enabled CRTCs * Note that if/when we get per-CRTC buffers, we'll have to update this. * Right now it assumes a single shared fb across all CRTCs, with the * kernel fixing up the offset of each CRTC as necessary. * * Also, flips queued on disabled or incorrectly configured displays * may never complete; this is a configuration error. */ count = do_page_flip(sna, bo, data, ref_crtc_hw_id); DBG(("%s: page flipped %d crtcs\n", __FUNCTION__, count)); return count; } static const xf86CrtcConfigFuncsRec sna_crtc_config_funcs = { sna_crtc_resize }; static void set_size_range(struct sna *sna) { /* We lie slightly as we expect no single monitor to exceed the * crtc limits, so if the mode exceeds the scanout restrictions, * we will quietly convert that to per-crtc pixmaps. */ xf86CrtcSetSizeRange(sna->scrn, 320, 200, INT16_MAX, INT16_MAX); } bool sna_mode_pre_init(ScrnInfoPtr scrn, struct sna *sna) { struct sna_mode *mode = &sna->mode; int i; list_init(&mode->crtcs); list_init(&mode->outputs); xf86CrtcConfigInit(scrn, &sna_crtc_config_funcs); mode->kmode = drmModeGetResources(sna->kgem.fd); if (!mode->kmode) { xf86DrvMsg(scrn->scrnIndex, X_ERROR, "failed to get resources: %s\n", strerror(errno)); return false; } set_size_range(sna); for (i = 0; i < mode->kmode->count_crtcs; i++) sna_crtc_init(scrn, mode, i); for (i = 0; i < mode->kmode->count_connectors; i++) sna_output_init(scrn, mode, i); xf86InitialConfiguration(scrn, TRUE); return true; } void sna_mode_fini(struct sna *sna) { #if 0 while (!list_is_empty(&mode->crtcs)) { xf86CrtcDestroy(list_first_entry(&mode->crtcs, struct sna_crtc, link)->crtc); } while (!list_is_empty(&mode->outputs)) { xf86OutputDestroy(list_first_entry(&mode->outputs, struct sna_output, link)->output); } #endif } static bool sna_box_intersect(BoxPtr r, const BoxRec *a, const BoxRec *b) { r->x1 = a->x1 > b->x1 ? a->x1 : b->x1; r->x2 = a->x2 < b->x2 ? a->x2 : b->x2; r->y1 = a->y1 > b->y1 ? a->y1 : b->y1; r->y2 = a->y2 < b->y2 ? a->y2 : b->y2; DBG(("%s: (%d, %d), (%d, %d) intersect (%d, %d), (%d, %d) = (%d, %d), (%d, %d)\n", __FUNCTION__, a->x1, a->y1, a->x2, a->y2, b->x1, b->y1, b->x2, b->y2, r->x1, r->y1, r->x2, r->y2)); return r->x2 > r->x1 && r->y2 > r->y1; } static int sna_box_area(const BoxRec *box) { return (int)(box->x2 - box->x1) * (int)(box->y2 - box->y1); } /* * Return the crtc covering 'box'. If two crtcs cover a portion of * 'box', then prefer 'desired'. If 'desired' is NULL, then prefer the crtc * with greater coverage */ xf86CrtcPtr sna_covering_crtc(ScrnInfoPtr scrn, const BoxRec *box, xf86CrtcPtr desired) { xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(scrn); xf86CrtcPtr best_crtc; int best_coverage, c; /* If we do not own the VT, we do not own the CRTC either */ if (!scrn->vtSema) return NULL; DBG(("%s for box=(%d, %d), (%d, %d)\n", __FUNCTION__, box->x1, box->y1, box->x2, box->y2)); best_crtc = NULL; best_coverage = 0; for (c = 0; c < xf86_config->num_crtc; c++) { xf86CrtcPtr crtc = xf86_config->crtc[c]; BoxRec cover_box; int coverage; /* If the CRTC is off, treat it as not covering */ if (to_sna_crtc(crtc)->bo == NULL) { DBG(("%s: crtc %d off, skipping\n", __FUNCTION__, c)); continue; } DBG(("%s: crtc %d: (%d, %d), (%d, %d)\n", __FUNCTION__, c, crtc->bounds.x1, crtc->bounds.y1, crtc->bounds.x2, crtc->bounds.y2)); if (!sna_box_intersect(&cover_box, &crtc->bounds, box)) continue; DBG(("%s: box instersects (%d, %d), (%d, %d) of crtc %d\n", __FUNCTION__, cover_box.x1, cover_box.y1, cover_box.x2, cover_box.y2, c)); if (crtc == desired) { DBG(("%s: box is on desired crtc [%p]\n", __FUNCTION__, crtc)); return crtc; } coverage = sna_box_area(&cover_box); DBG(("%s: box covers %d of crtc %d\n", __FUNCTION__, coverage, c)); if (coverage > best_coverage) { best_crtc = crtc; best_coverage = coverage; } } DBG(("%s: best crtc = %p, coverage = %d\n", __FUNCTION__, best_crtc, best_coverage)); return best_crtc; } /* Gen6 wait for scan line support */ #define MI_LOAD_REGISTER_IMM (0x22<<23) /* gen6: Scan lines register */ #define GEN6_PIPEA_SLC (0x70004) #define GEN6_PIPEB_SLC (0x71004) static void sna_emit_wait_for_scanline_gen6(struct sna *sna, int pipe, int y1, int y2, bool full_height) { uint32_t event; uint32_t *b; assert (y2 > 0); /* We just wait until the trace passes the roi */ if (pipe == 0) { pipe = GEN6_PIPEA_SLC; event = MI_WAIT_FOR_PIPEA_SCAN_LINE_WINDOW; } else { pipe = GEN6_PIPEB_SLC; event = MI_WAIT_FOR_PIPEB_SCAN_LINE_WINDOW; } kgem_set_mode(&sna->kgem, KGEM_RENDER); b = kgem_get_batch(&sna->kgem, 4); b[0] = MI_LOAD_REGISTER_IMM | 1; b[1] = pipe; b[2] = y2 - 1; b[3] = MI_WAIT_FOR_EVENT | event; kgem_advance_batch(&sna->kgem, 4); } static void sna_emit_wait_for_scanline_gen4(struct sna *sna, int pipe, int y1, int y2, bool full_height) { uint32_t event; uint32_t *b; if (pipe == 0) { if (full_height) event = MI_WAIT_FOR_PIPEA_SVBLANK; else event = MI_WAIT_FOR_PIPEA_SCAN_LINE_WINDOW; } else { if (full_height) event = MI_WAIT_FOR_PIPEB_SVBLANK; else event = MI_WAIT_FOR_PIPEB_SCAN_LINE_WINDOW; } kgem_set_mode(&sna->kgem, KGEM_BLT); b = kgem_get_batch(&sna->kgem, 5); /* The documentation says that the LOAD_SCAN_LINES command * always comes in pairs. Don't ask me why. */ b[2] = b[0] = MI_LOAD_SCAN_LINES_INCL | pipe << 20; b[3] = b[1] = (y1 << 16) | (y2-1); b[4] = MI_WAIT_FOR_EVENT | event; kgem_advance_batch(&sna->kgem, 5); } static void sna_emit_wait_for_scanline_gen2(struct sna *sna, int pipe, int y1, int y2, bool full_height) { uint32_t *b; /* * Pre-965 doesn't have SVBLANK, so we need a bit * of extra time for the blitter to start up and * do its job for a full height blit */ if (full_height) y2 -= 2; kgem_set_mode(&sna->kgem, KGEM_BLT); b = kgem_get_batch(&sna->kgem, 5); /* The documentation says that the LOAD_SCAN_LINES command * always comes in pairs. Don't ask me why. */ b[2] = b[0] = MI_LOAD_SCAN_LINES_INCL | pipe << 20; b[3] = b[1] = (y1 << 16) | (y2-1); if (pipe == 0) b[4] = MI_WAIT_FOR_EVENT | MI_WAIT_FOR_PIPEA_SCAN_LINE_WINDOW; else b[4] = MI_WAIT_FOR_EVENT | MI_WAIT_FOR_PIPEB_SCAN_LINE_WINDOW; kgem_advance_batch(&sna->kgem, 5); } bool sna_wait_for_scanline(struct sna *sna, PixmapPtr pixmap, xf86CrtcPtr crtc, const BoxRec *clip) { bool full_height; int y1, y2, pipe; assert(crtc); assert(to_sna_crtc(crtc)->bo != NULL); assert(pixmap == sna->front); /* XXX WAIT_EVENT is still causing hangs on SNB */ if (sna->kgem.gen >= 60) return false; /* * Make sure we don't wait for a scanline that will * never occur */ y1 = clip->y1 - crtc->bounds.y1; if (y1 < 0) y1 = 0; y2 = clip->y2 - crtc->bounds.y1; if (y2 > crtc->bounds.y2 - crtc->bounds.y1) y2 = crtc->bounds.y2 - crtc->bounds.y1; DBG(("%s: clipped range = %d, %d\n", __FUNCTION__, y1, y2)); if (y2 <= y1) return false; full_height = y1 == 0 && y2 == crtc->bounds.y2 - crtc->bounds.y1; if (crtc->mode.Flags & V_INTERLACE) { /* DSL count field lines */ y1 /= 2; y2 /= 2; } pipe = sna_crtc_to_pipe(crtc); DBG(("%s: pipe=%d, y1=%d, y2=%d, full_height?=%d\n", __FUNCTION__, pipe, y1, y2, full_height)); if (sna->kgem.gen >= 60) sna_emit_wait_for_scanline_gen6(sna, pipe, y1, y2, full_height); else if (sna->kgem.gen >= 40) sna_emit_wait_for_scanline_gen4(sna, pipe, y1, y2, full_height); else sna_emit_wait_for_scanline_gen2(sna, pipe, y1, y2, full_height); return true; } void sna_mode_update(struct sna *sna) { xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(sna->scrn); int i; /* Validate CRTC attachments */ for (i = 0; i < xf86_config->num_crtc; i++) { xf86CrtcPtr crtc = xf86_config->crtc[i]; if (!crtc->active || !sna_crtc_is_bound(sna, crtc)) sna_crtc_disable(crtc); } } static void sna_crtc_redisplay__fallback(xf86CrtcPtr crtc, RegionPtr region) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); ScreenPtr screen = sna->scrn->pScreen; PictFormatPtr format; PicturePtr src, dst; PixmapPtr pixmap; BoxPtr b; int n, error; void *ptr; DBG(("%s: compositing transformed damage boxes\n", __FUNCTION__)); ptr = kgem_bo_map__gtt(&sna->kgem, sna_crtc->bo); if (ptr == NULL) return; pixmap = sna_pixmap_create_unattached(screen, 0, 0, sna->front->drawable.depth); if (pixmap == NullPixmap) return; if (!screen->ModifyPixmapHeader(pixmap, crtc->mode.HDisplay, crtc->mode.VDisplay, sna->front->drawable.depth, sna->front->drawable.bitsPerPixel, sna_crtc->bo->pitch, ptr)) goto free_pixmap; error = sna_render_format_for_depth(sna->front->drawable.depth); format = PictureMatchFormat(screen, PIXMAN_FORMAT_DEPTH(error), error); if (format == NULL) { DBG(("%s: can't find format for depth=%d [%08x]\n", __FUNCTION__, sna->front->drawable.depth, (int)sna_render_format_for_depth(sna->front->drawable.depth))); goto free_pixmap; } src = CreatePicture(None, &sna->front->drawable, format, 0, NULL, serverClient, &error); if (!src) goto free_pixmap; error = SetPictureTransform(src, &crtc->crtc_to_framebuffer); if (error) goto free_src; if (crtc->filter) SetPicturePictFilter(src, crtc->filter, crtc->params, crtc->nparams); dst = CreatePicture(None, &pixmap->drawable, format, 0, NULL, serverClient, &error); if (!dst) goto free_src; kgem_bo_sync__gtt(&sna->kgem, sna_crtc->bo); n = REGION_NUM_RECTS(region); b = REGION_RECTS(region); do { BoxRec box; box = *b++; box.x1 -= crtc->filter_width >> 1; box.x2 += crtc->filter_width >> 1; box.y1 -= crtc->filter_height >> 1; box.y2 += crtc->filter_height >> 1; pixman_f_transform_bounds(&crtc->f_framebuffer_to_crtc, & box); DBG(("%s: (%d, %d)x(%d, %d) -> (%d, %d), (%d, %d)\n", __FUNCTION__, b[-1].x1, b[-1].y1, b[-1].x2-b[-1].x1, b[-1].y2-b[-1].y1, box.x1, box.y1, box.x2, box.y2)); fbComposite(PictOpSrc, src, NULL, dst, box.x1, box.y1, 0, 0, box.x1, box.y1, box.x2 - box.x1, box.y2 - box.y1); } while (--n); FreePicture(dst, None); free_src: FreePicture(src, None); free_pixmap: screen->DestroyPixmap(pixmap); } static void sna_crtc_redisplay__composite(xf86CrtcPtr crtc, RegionPtr region) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); ScreenPtr screen = sna->scrn->pScreen; struct sna_composite_op tmp; PictFormatPtr format; PicturePtr src, dst; PixmapPtr pixmap; BoxPtr b; int n, error; DBG(("%s: compositing transformed damage boxes\n", __FUNCTION__)); pixmap = sna_pixmap_create_unattached(screen, crtc->mode.HDisplay, crtc->mode.VDisplay, sna->front->drawable.depth); if (pixmap == NullPixmap) return; if (!sna_pixmap_attach_to_bo(pixmap, sna_crtc->bo)) goto free_pixmap; error = sna_render_format_for_depth(sna->front->drawable.depth); format = PictureMatchFormat(screen, PIXMAN_FORMAT_DEPTH(error), error); if (format == NULL) { DBG(("%s: can't find format for depth=%d [%08x]\n", __FUNCTION__, sna->front->drawable.depth, (int)sna_render_format_for_depth(sna->front->drawable.depth))); goto free_pixmap; } src = CreatePicture(None, &sna->front->drawable, format, 0, NULL, serverClient, &error); if (!src) goto free_pixmap; error = SetPictureTransform(src, &crtc->crtc_to_framebuffer); if (error) goto free_src; if (crtc->filter) SetPicturePictFilter(src, crtc->filter, crtc->params, crtc->nparams); dst = CreatePicture(None, &pixmap->drawable, format, 0, NULL, serverClient, &error); if (!dst) goto free_src; if (!sna->render.composite(sna, PictOpSrc, src, NULL, dst, 0, 0, 0, 0, 0, 0, 0, 0, memset(&tmp, 0, sizeof(tmp)))) { DBG(("%s: unsupported operation!\n", __FUNCTION__)); sna_crtc_redisplay__fallback(crtc, region); goto free_dst; } n = REGION_NUM_RECTS(region); b = REGION_RECTS(region); do { BoxRec box; box = *b++; box.x1 -= crtc->filter_width >> 1; box.x2 += crtc->filter_width >> 1; box.y1 -= crtc->filter_height >> 1; box.y2 += crtc->filter_height >> 1; pixman_f_transform_bounds(&crtc->f_framebuffer_to_crtc, & box); DBG(("%s: (%d, %d)x(%d, %d) -> (%d, %d), (%d, %d)\n", __FUNCTION__, b[-1].x1, b[-1].y1, b[-1].x2-b[-1].x1, b[-1].y2-b[-1].y1, box.x1, box.y1, box.x2, box.y2)); tmp.box(sna, &tmp, &box); } while (--n); tmp.done(sna, &tmp); free_dst: FreePicture(dst, None); free_src: FreePicture(src, None); free_pixmap: screen->DestroyPixmap(pixmap); } static void sna_crtc_redisplay(xf86CrtcPtr crtc, RegionPtr region) { struct sna *sna = to_sna(crtc->scrn); struct sna_crtc *sna_crtc = to_sna_crtc(crtc); int16_t tx, ty; DBG(("%s: crtc %d [pipe=%d], damage (%d, %d), (%d, %d) x %d\n", __FUNCTION__, sna_crtc->id, sna_crtc->pipe, region->extents.x1, region->extents.y1, region->extents.x2, region->extents.y2, REGION_NUM_RECTS(region))); assert(!wedged(sna)); if (crtc->filter == NULL && sna_transform_is_integer_translation(&crtc->crtc_to_framebuffer, &tx, &ty)) { PixmapRec tmp; DBG(("%s: copy damage boxes\n", __FUNCTION__)); tmp.drawable.width = crtc->mode.HDisplay; tmp.drawable.height = crtc->mode.VDisplay; tmp.drawable.depth = sna->front->drawable.depth; tmp.drawable.bitsPerPixel = sna->front->drawable.bitsPerPixel; /* XXX for tear-free we may want to try copying to a back * and flipping. */ if (sna->render.copy_boxes(sna, GXcopy, sna->front, sna_pixmap_get_bo(sna->front), 0, 0, &tmp, sna_crtc->bo, -tx, -ty, REGION_RECTS(region), REGION_NUM_RECTS(region), 0)) return; } sna_crtc_redisplay__composite(crtc, region); } void sna_mode_redisplay(struct sna *sna) { xf86CrtcConfigPtr config = XF86_CRTC_CONFIG_PTR(sna->scrn); RegionPtr region; int i; if (!sna->mode.shadow_damage) return; DBG(("%s: posting shadow damage\n", __FUNCTION__)); assert(sna->mode.shadow_active); region = DamageRegion(sna->mode.shadow_damage); if (!RegionNotEmpty(region)) return; if (!sna_pixmap_move_to_gpu(sna->front, MOVE_READ)) { if (!sna_pixmap_move_to_cpu(sna->front, MOVE_READ)) return; for (i = 0; i < config->num_crtc; i++) { xf86CrtcPtr crtc = config->crtc[i]; struct sna_crtc *sna_crtc = to_sna_crtc(crtc); RegionRec damage; if (!sna_crtc->shadow) continue; assert(crtc->enabled); assert(crtc->transform_in_use); damage.extents = crtc->bounds; damage.data = NULL; RegionIntersect(&damage, &damage, region); if (RegionNotEmpty(&damage)) sna_crtc_redisplay__fallback(crtc, &damage); RegionUninit(&damage); } RegionEmpty(region); return; } for (i = 0; i < config->num_crtc; i++) { xf86CrtcPtr crtc = config->crtc[i]; struct sna_crtc *sna_crtc = to_sna_crtc(crtc); RegionRec damage; if (!sna_crtc->shadow || sna_crtc->bo == sna->mode.shadow) continue; assert(crtc->enabled); assert(crtc->transform_in_use); damage.extents = crtc->bounds; damage.data = NULL; RegionIntersect(&damage, &damage, region); if (RegionNotEmpty(&damage)) { sna_crtc_redisplay(crtc, &damage); __kgem_flush(&sna->kgem, sna_crtc->bo); } RegionUninit(&damage); } if (!sna->mode.shadow) { kgem_submit(&sna->kgem); RegionEmpty(region); return; } if (sna->mode.shadow_flip == 0) { struct kgem_bo *new = sna_pixmap_get_bo(sna->front); struct kgem_bo *old = sna->mode.shadow; DBG(("%s: flipping tear-free outputs\n", __FUNCTION__)); kgem_bo_submit(&sna->kgem, new); for (i = 0; i < config->num_crtc; i++) { struct sna_crtc *crtc = config->crtc[i]->driver_private; struct drm_mode_crtc_page_flip arg; DBG(("%s: crtc %d active? %d\n", __FUNCTION__, i, crtc->bo != NULL)); if (crtc->bo != old) continue; arg.crtc_id = crtc->id; arg.fb_id = get_fb(sna, new, sna->scrn->virtualX, sna->scrn->virtualY); if (arg.fb_id == 0) goto disable; /* Only the reference crtc will finally deliver its page flip * completion event. All other crtc's events will be discarded. */ arg.user_data = 0; arg.flags = DRM_MODE_PAGE_FLIP_EVENT; arg.reserved = 0; if (drmIoctl(sna->kgem.fd, DRM_IOCTL_MODE_PAGE_FLIP, &arg)) { DBG(("%s: flip [fb=%d] on crtc %d [%d] failed - %d\n", __FUNCTION__, arg.fb_id, i, crtc->id, errno)); disable: sna_crtc_disable(config->crtc[i]); continue; } kgem_bo_destroy(&sna->kgem, old); crtc->bo = kgem_bo_reference(new); sna->mode.shadow_flip++; } /* XXX only works if the kernel stalls fwrites to the current * scanout whilst the flip is pending */ while (sna->mode.shadow_flip) sna_mode_wakeup(sna); (void)sna->render.copy_boxes(sna, GXcopy, sna->front, new, 0, 0, sna->front, old, 0, 0, REGION_RECTS(region), REGION_NUM_RECTS(region), COPY_LAST); kgem_submit(&sna->kgem); sna_pixmap(sna->front)->gpu_bo = old; sna->mode.shadow = new; new->flush = old->flush; RegionEmpty(region); } } void sna_mode_wakeup(struct sna *sna) { char buffer[1024]; int len, i; /* The DRM read semantics guarantees that we always get only * complete events. */ len = read(sna->kgem.fd, buffer, sizeof (buffer)); if (len < (int)sizeof(struct drm_event)) return; DBG(("%s: len=%d\n", __FUNCTION__, len)); i = 0; while (i < len) { struct drm_event *e = (struct drm_event *)&buffer[i]; switch (e->type) { case DRM_EVENT_VBLANK: sna_dri_vblank_handler(sna, (struct drm_event_vblank *)e); break; case DRM_EVENT_FLIP_COMPLETE: if (((struct drm_event_vblank *)e)->user_data) sna_dri_page_flip_handler(sna, (struct drm_event_vblank *)e); else sna->mode.shadow_flip--; break; default: break; } i += e->length; } }