/* * Copyright © 2013 Intel Corporation * * 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: * Daniel Vetter * Damien Lespiau */ #include "config.h" #include #include #include #include #include #include #include #include #ifdef HAVE_LINUX_KD_H #include #elif HAVE_SYS_KD_H #include #endif #include #include #include #include #include #include "drmtest.h" #include "igt_kms.h" #include "igt_aux.h" #include "igt_edid.h" #include "intel_chipset.h" #include "igt_debugfs.h" #include "igt_device.h" #include "igt_sysfs.h" #include "sw_sync.h" /** * SECTION:igt_kms * @short_description: Kernel modesetting support library * @title: KMS * @include: igt.h * * This library provides support to enumerate and set modeset configurations. * * There are two parts in this library: First the low level helper function * which directly build on top of raw ioctls or the interfaces provided by * libdrm. Those functions all have a kmstest_ prefix. * * The second part is a high-level library to manage modeset configurations * which abstracts away some of the low-level details like the difference * between legacy and universal plane support for setting cursors or in the * future the difference between legacy and atomic commit. These high-level * functions have all igt_ prefixes. This part is still very much work in * progress and so also lacks a bit documentation for the individual functions. * * Note that this library's header pulls in the [i-g-t framebuffer](igt-gpu-tools-i-g-t-framebuffer.html) * library as a dependency. */ /* list of connectors that need resetting on exit */ #define MAX_CONNECTORS 32 static char *forced_connectors[MAX_CONNECTORS + 1]; static int forced_connectors_device[MAX_CONNECTORS + 1]; static void update_edid_csum(unsigned char *edid, int cea_pos) { int i, sum = 0; struct tm *tm; time_t t; /* year of manufacture */ t = time(NULL); tm = localtime(&t); edid[17] = tm->tm_year - 90; /* calculate checksum */ for (i = 0; i < 127; i++) { sum = sum + edid[cea_pos + i]; } edid[cea_pos + 127] = 256 - sum; } /** * igt_kms_get_base_edid: * * Get the base edid block, which includes the following modes: * * - 1920x1080 60Hz * - 1280x720 60Hz * - 1024x768 60Hz * - 800x600 60Hz * - 640x480 60Hz * * This can be extended with further features using functions such as * #kmstest_edid_add_3d. * * Returns: a basic edid block */ const unsigned char *igt_kms_get_base_edid(void) { static struct edid edid; drmModeModeInfo mode = {}; mode.clock = 148500; mode.hdisplay = 1920; mode.hsync_start = 2008; mode.hsync_end = 2052; mode.htotal = 2200; mode.vdisplay = 1080; mode.vsync_start = 1084; mode.vsync_end = 1089; mode.vtotal = 1125; mode.vrefresh = 60; edid_init_with_mode(&edid, &mode); edid_update_checksum(&edid); return (unsigned char *) &edid; } /** * igt_kms_get_alt_edid: * * Get an alternate edid block, which includes the following modes: * * - 1400x1050 60Hz * - 1920x1080 60Hz * - 1280x720 60Hz * - 1024x768 60Hz * - 800x600 60Hz * - 640x480 60Hz * * This can be extended with further features using functions such as * #kmstest_edid_add_3d. * * Returns: an alternate edid block */ const unsigned char *igt_kms_get_alt_edid(void) { static struct edid edid; drmModeModeInfo mode = {}; mode.clock = 101000; mode.hdisplay = 1400; mode.hsync_start = 1448; mode.hsync_end = 1480; mode.htotal = 1560; mode.vdisplay = 1050; mode.vsync_start = 1053; mode.vsync_end = 1057; mode.vtotal = 1080; mode.vrefresh = 60; edid_init_with_mode(&edid, &mode); edid_update_checksum(&edid); return (unsigned char *) &edid; } const char * const igt_plane_prop_names[IGT_NUM_PLANE_PROPS] = { [IGT_PLANE_SRC_X] = "SRC_X", [IGT_PLANE_SRC_Y] = "SRC_Y", [IGT_PLANE_SRC_W] = "SRC_W", [IGT_PLANE_SRC_H] = "SRC_H", [IGT_PLANE_CRTC_X] = "CRTC_X", [IGT_PLANE_CRTC_Y] = "CRTC_Y", [IGT_PLANE_CRTC_W] = "CRTC_W", [IGT_PLANE_CRTC_H] = "CRTC_H", [IGT_PLANE_FB_ID] = "FB_ID", [IGT_PLANE_CRTC_ID] = "CRTC_ID", [IGT_PLANE_IN_FENCE_FD] = "IN_FENCE_FD", [IGT_PLANE_TYPE] = "type", [IGT_PLANE_ROTATION] = "rotation", [IGT_PLANE_IN_FORMATS] = "IN_FORMATS", [IGT_PLANE_COLOR_ENCODING] = "COLOR_ENCODING", [IGT_PLANE_COLOR_RANGE] = "COLOR_RANGE", [IGT_PLANE_PIXEL_BLEND_MODE] = "pixel blend mode", [IGT_PLANE_ALPHA] = "alpha", [IGT_PLANE_ZPOS] = "zpos", }; const char * const igt_crtc_prop_names[IGT_NUM_CRTC_PROPS] = { [IGT_CRTC_BACKGROUND] = "background_color", [IGT_CRTC_CTM] = "CTM", [IGT_CRTC_GAMMA_LUT] = "GAMMA_LUT", [IGT_CRTC_GAMMA_LUT_SIZE] = "GAMMA_LUT_SIZE", [IGT_CRTC_DEGAMMA_LUT] = "DEGAMMA_LUT", [IGT_CRTC_DEGAMMA_LUT_SIZE] = "DEGAMMA_LUT_SIZE", [IGT_CRTC_MODE_ID] = "MODE_ID", [IGT_CRTC_ACTIVE] = "ACTIVE", [IGT_CRTC_OUT_FENCE_PTR] = "OUT_FENCE_PTR", [IGT_CRTC_VRR_ENABLED] = "VRR_ENABLED", }; const char * const igt_connector_prop_names[IGT_NUM_CONNECTOR_PROPS] = { [IGT_CONNECTOR_SCALING_MODE] = "scaling mode", [IGT_CONNECTOR_CRTC_ID] = "CRTC_ID", [IGT_CONNECTOR_DPMS] = "DPMS", [IGT_CONNECTOR_BROADCAST_RGB] = "Broadcast RGB", [IGT_CONNECTOR_CONTENT_PROTECTION] = "Content Protection", [IGT_CONNECTOR_VRR_CAPABLE] = "vrr_capable", }; /* * Retrieve all the properies specified in props_name and store them into * plane->props. */ static void igt_fill_plane_props(igt_display_t *display, igt_plane_t *plane, int num_props, const char * const prop_names[]) { drmModeObjectPropertiesPtr props; int i, j, fd; fd = display->drm_fd; props = drmModeObjectGetProperties(fd, plane->drm_plane->plane_id, DRM_MODE_OBJECT_PLANE); igt_assert(props); for (i = 0; i < props->count_props; i++) { drmModePropertyPtr prop = drmModeGetProperty(fd, props->props[i]); for (j = 0; j < num_props; j++) { if (strcmp(prop->name, prop_names[j]) != 0) continue; plane->props[j] = props->props[i]; break; } drmModeFreeProperty(prop); } drmModeFreeObjectProperties(props); } /* * Retrieve all the properies specified in props_name and store them into * config->atomic_props_crtc and config->atomic_props_connector. */ static void igt_atomic_fill_connector_props(igt_display_t *display, igt_output_t *output, int num_connector_props, const char * const conn_prop_names[]) { drmModeObjectPropertiesPtr props; int i, j, fd; fd = display->drm_fd; props = drmModeObjectGetProperties(fd, output->config.connector->connector_id, DRM_MODE_OBJECT_CONNECTOR); igt_assert(props); for (i = 0; i < props->count_props; i++) { drmModePropertyPtr prop = drmModeGetProperty(fd, props->props[i]); for (j = 0; j < num_connector_props; j++) { if (strcmp(prop->name, conn_prop_names[j]) != 0) continue; output->props[j] = props->props[i]; break; } drmModeFreeProperty(prop); } drmModeFreeObjectProperties(props); } static void igt_fill_pipe_props(igt_display_t *display, igt_pipe_t *pipe, int num_crtc_props, const char * const crtc_prop_names[]) { drmModeObjectPropertiesPtr props; int i, j, fd; fd = display->drm_fd; props = drmModeObjectGetProperties(fd, pipe->crtc_id, DRM_MODE_OBJECT_CRTC); igt_assert(props); for (i = 0; i < props->count_props; i++) { drmModePropertyPtr prop = drmModeGetProperty(fd, props->props[i]); for (j = 0; j < num_crtc_props; j++) { if (strcmp(prop->name, crtc_prop_names[j]) != 0) continue; pipe->props[j] = props->props[i]; break; } drmModeFreeProperty(prop); } drmModeFreeObjectProperties(props); } /** * kmstest_pipe_name: * @pipe: display pipe * * Returns: String representing @pipe, e.g. "A". */ const char *kmstest_pipe_name(enum pipe pipe) { static const char str[] = "A\0B\0C\0D\0E\0F"; _Static_assert(sizeof(str) == IGT_MAX_PIPES * 2, "Missing pipe name"); if (pipe == PIPE_NONE) return "None"; if (pipe >= IGT_MAX_PIPES) return "invalid"; return str + (pipe * 2); } /** * kmstest_pipe_to_index: *@pipe: display pipe in string format * * Returns: index to corresponding pipe */ int kmstest_pipe_to_index(char pipe) { int r = pipe - 'A'; if (r < 0 || r >= IGT_MAX_PIPES) return -EINVAL; return r; } /** * kmstest_plane_type_name: * @plane_type: display plane type * * Returns: String representing @plane_type, e.g. "overlay". */ const char *kmstest_plane_type_name(int plane_type) { static const char * const names[] = { [DRM_PLANE_TYPE_OVERLAY] = "overlay", [DRM_PLANE_TYPE_PRIMARY] = "primary", [DRM_PLANE_TYPE_CURSOR] = "cursor", }; igt_assert(plane_type < ARRAY_SIZE(names) && names[plane_type]); return names[plane_type]; } struct type_name { int type; const char *name; }; static const char *find_type_name(const struct type_name *names, int type) { for (; names->name; names++) { if (names->type == type) return names->name; } return "(invalid)"; } static const struct type_name encoder_type_names[] = { { DRM_MODE_ENCODER_NONE, "none" }, { DRM_MODE_ENCODER_DAC, "DAC" }, { DRM_MODE_ENCODER_TMDS, "TMDS" }, { DRM_MODE_ENCODER_LVDS, "LVDS" }, { DRM_MODE_ENCODER_TVDAC, "TVDAC" }, { DRM_MODE_ENCODER_VIRTUAL, "Virtual" }, { DRM_MODE_ENCODER_DSI, "DSI" }, { DRM_MODE_ENCODER_DPMST, "DP MST" }, {} }; /** * kmstest_encoder_type_str: * @type: DRM_MODE_ENCODER_* enumeration value * * Returns: A string representing the drm encoder @type. */ const char *kmstest_encoder_type_str(int type) { return find_type_name(encoder_type_names, type); } static const struct type_name connector_status_names[] = { { DRM_MODE_CONNECTED, "connected" }, { DRM_MODE_DISCONNECTED, "disconnected" }, { DRM_MODE_UNKNOWNCONNECTION, "unknown" }, {} }; /** * kmstest_connector_status_str: * @status: DRM_MODE_* connector status value * * Returns: A string representing the drm connector status @status. */ const char *kmstest_connector_status_str(int status) { return find_type_name(connector_status_names, status); } static const struct type_name connector_type_names[] = { { DRM_MODE_CONNECTOR_Unknown, "Unknown" }, { DRM_MODE_CONNECTOR_VGA, "VGA" }, { DRM_MODE_CONNECTOR_DVII, "DVI-I" }, { DRM_MODE_CONNECTOR_DVID, "DVI-D" }, { DRM_MODE_CONNECTOR_DVIA, "DVI-A" }, { DRM_MODE_CONNECTOR_Composite, "Composite" }, { DRM_MODE_CONNECTOR_SVIDEO, "SVIDEO" }, { DRM_MODE_CONNECTOR_LVDS, "LVDS" }, { DRM_MODE_CONNECTOR_Component, "Component" }, { DRM_MODE_CONNECTOR_9PinDIN, "DIN" }, { DRM_MODE_CONNECTOR_DisplayPort, "DP" }, { DRM_MODE_CONNECTOR_HDMIA, "HDMI-A" }, { DRM_MODE_CONNECTOR_HDMIB, "HDMI-B" }, { DRM_MODE_CONNECTOR_TV, "TV" }, { DRM_MODE_CONNECTOR_eDP, "eDP" }, { DRM_MODE_CONNECTOR_VIRTUAL, "Virtual" }, { DRM_MODE_CONNECTOR_DSI, "DSI" }, { DRM_MODE_CONNECTOR_DPI, "DPI" }, {} }; /** * kmstest_connector_type_str: * @type: DRM_MODE_CONNECTOR_* enumeration value * * Returns: A string representing the drm connector @type. */ const char *kmstest_connector_type_str(int type) { return find_type_name(connector_type_names, type); } static const char *mode_stereo_name(const drmModeModeInfo *mode) { switch (mode->flags & DRM_MODE_FLAG_3D_MASK) { case DRM_MODE_FLAG_3D_FRAME_PACKING: return "FP"; case DRM_MODE_FLAG_3D_FIELD_ALTERNATIVE: return "FA"; case DRM_MODE_FLAG_3D_LINE_ALTERNATIVE: return "LA"; case DRM_MODE_FLAG_3D_SIDE_BY_SIDE_FULL: return "SBSF"; case DRM_MODE_FLAG_3D_L_DEPTH: return "LD"; case DRM_MODE_FLAG_3D_L_DEPTH_GFX_GFX_DEPTH: return "LDGFX"; case DRM_MODE_FLAG_3D_TOP_AND_BOTTOM: return "TB"; case DRM_MODE_FLAG_3D_SIDE_BY_SIDE_HALF: return "SBSH"; default: return NULL; } } /** * kmstest_dump_mode: * @mode: libdrm mode structure * * Prints @mode to stdout in a human-readable form. */ void kmstest_dump_mode(drmModeModeInfo *mode) { const char *stereo = mode_stereo_name(mode); igt_info(" %s %d %d %d %d %d %d %d %d %d 0x%x 0x%x %d%s%s%s\n", mode->name, mode->vrefresh, mode->hdisplay, mode->hsync_start, mode->hsync_end, mode->htotal, mode->vdisplay, mode->vsync_start, mode->vsync_end, mode->vtotal, mode->flags, mode->type, mode->clock, stereo ? " (3D:" : "", stereo ? stereo : "", stereo ? ")" : ""); } /** * kmstest_get_pipe_from_crtc_id: * @fd: DRM fd * @crtc_id: DRM CRTC id * * Returns: The crtc index for the given DRM CRTC ID @crtc_id. The crtc index * is the equivalent of the pipe id. This value maps directly to an enum pipe * value used in other helper functions. Returns 0 if the index could not be * determined. */ int kmstest_get_pipe_from_crtc_id(int fd, int crtc_id) { drmModeRes *res; drmModeCrtc *crtc; int i, cur_id; res = drmModeGetResources(fd); igt_assert(res); for (i = 0; i < res->count_crtcs; i++) { crtc = drmModeGetCrtc(fd, res->crtcs[i]); igt_assert(crtc); cur_id = crtc->crtc_id; drmModeFreeCrtc(crtc); if (cur_id == crtc_id) break; } igt_assert(i < res->count_crtcs); drmModeFreeResources(res); return i; } /** * kmstest_find_crtc_for_connector: * @fd: DRM fd * @res: libdrm resources pointer * @connector: libdrm connector pointer * @crtc_blacklist_idx_mask: a mask of CRTC indexes that we can't return * * Returns: the CRTC ID for a CRTC that fits the connector, otherwise it asserts * false and never returns. The blacklist mask can be used in case you have * CRTCs that are already in use by other connectors. */ uint32_t kmstest_find_crtc_for_connector(int fd, drmModeRes *res, drmModeConnector *connector, uint32_t crtc_blacklist_idx_mask) { drmModeEncoder *e; uint32_t possible_crtcs; int i, j; for (i = 0; i < connector->count_encoders; i++) { e = drmModeGetEncoder(fd, connector->encoders[i]); possible_crtcs = e->possible_crtcs & ~crtc_blacklist_idx_mask; drmModeFreeEncoder(e); for (j = 0; possible_crtcs >> j; j++) if (possible_crtcs & (1 << j)) return res->crtcs[j]; } igt_assert(false); } /** * kmstest_dumb_create: * @fd: open drm file descriptor * @width: width of the buffer in pixels * @height: height of the buffer in pixels * @bpp: bytes per pixel of the buffer * @stride: Pointer which receives the dumb bo's stride, can be NULL. * @size: Pointer which receives the dumb bo's size, can be NULL. * * This wraps the CREATE_DUMB ioctl, which allocates a new dumb buffer object * for the specified dimensions. * * Returns: The file-private handle of the created buffer object */ uint32_t kmstest_dumb_create(int fd, int width, int height, int bpp, unsigned *stride, uint64_t *size) { struct drm_mode_create_dumb create; memset(&create, 0, sizeof(create)); create.width = width; create.height = height; create.bpp = bpp; create.handle = 0; do_ioctl(fd, DRM_IOCTL_MODE_CREATE_DUMB, &create); igt_assert(create.handle); igt_assert(create.size >= (uint64_t) width * height * bpp / 8); if (stride) *stride = create.pitch; if (size) *size = create.size; return create.handle; } /** * kmstest_dumb_map_buffer: * @fd: Opened drm file descriptor * @handle: Offset in the file referred to by fd * @size: Length of the mapping, must be greater than 0 * @prot: Describes the memory protection of the mapping * Returns: A pointer representing the start of the virtual mapping */ void *kmstest_dumb_map_buffer(int fd, uint32_t handle, uint64_t size, unsigned prot) { struct drm_mode_map_dumb arg = {}; void *ptr; arg.handle = handle; do_ioctl(fd, DRM_IOCTL_MODE_MAP_DUMB, &arg); ptr = mmap(NULL, size, prot, MAP_SHARED, fd, arg.offset); igt_assert(ptr != MAP_FAILED); return ptr; } static int __kmstest_dumb_destroy(int fd, uint32_t handle) { struct drm_mode_destroy_dumb arg = { handle }; int err = 0; if (drmIoctl(fd, DRM_IOCTL_MODE_DESTROY_DUMB, &arg)) err = -errno; errno = 0; return err; } /** * kmstest_dumb_destroy: * @fd: Opened drm file descriptor * @handle: Offset in the file referred to by fd */ void kmstest_dumb_destroy(int fd, uint32_t handle) { igt_assert_eq(__kmstest_dumb_destroy(fd, handle), 0); } /* * Returns: the previous mode, or KD_GRAPHICS if no /dev/tty0 was * found and nothing was done. */ static signed long set_vt_mode(unsigned long mode) { int fd; unsigned long prev_mode; static const char TTY0[] = "/dev/tty0"; if (access(TTY0, F_OK)) { /* errno message should be "No such file". Do not hardcode but ask strerror() in the very unlikely case something else happened. */ igt_debug("VT: %s: %s, cannot change its mode\n", TTY0, strerror(errno)); return KD_GRAPHICS; } fd = open(TTY0, O_RDONLY); if (fd < 0) return -errno; prev_mode = 0; if (drmIoctl(fd, KDGETMODE, &prev_mode)) goto err; if (drmIoctl(fd, KDSETMODE, (void *)mode)) goto err; close(fd); return prev_mode; err: close(fd); return -errno; } static unsigned long orig_vt_mode = -1UL; /** * kmstest_restore_vt_mode: * * Restore the VT mode in use before #kmstest_set_vt_graphics_mode was called. */ void kmstest_restore_vt_mode(void) { long ret; if (orig_vt_mode != -1UL) { ret = set_vt_mode(orig_vt_mode); igt_assert(ret >= 0); igt_debug("VT: original mode 0x%lx restored\n", orig_vt_mode); orig_vt_mode = -1UL; } } /** * kmstest_set_vt_graphics_mode: * * Sets the controlling VT (if available) into graphics/raw mode and installs * an igt exit handler to set the VT back to text mode on exit. Use * #kmstest_restore_vt_mode to restore the previous VT mode manually. * * All kms tests must call this function to make sure that the fbcon doesn't * interfere by e.g. blanking the screen. */ void kmstest_set_vt_graphics_mode(void) { long ret; igt_install_exit_handler((igt_exit_handler_t) kmstest_restore_vt_mode); ret = set_vt_mode(KD_GRAPHICS); igt_assert(ret >= 0); orig_vt_mode = ret; igt_debug("VT: graphics mode set (mode was 0x%lx)\n", ret); } static void reset_connectors_at_exit(int sig) { igt_reset_connectors(); } /** * kmstest_force_connector: * @fd: drm file descriptor * @connector: connector * @state: state to force on @connector * * Force the specified state on the specified connector. * * Returns: true on success */ bool kmstest_force_connector(int drm_fd, drmModeConnector *connector, enum kmstest_force_connector_state state) { char *path, **tmp; const char *value; drmModeConnector *temp; uint32_t devid; int len, dir, idx; if (is_i915_device(drm_fd)) { devid = intel_get_drm_devid(drm_fd); /* * forcing hdmi or dp connectors on HSW and BDW doesn't * currently work, so fail early to allow the test to skip if * required */ if ((connector->connector_type == DRM_MODE_CONNECTOR_HDMIA || connector->connector_type == DRM_MODE_CONNECTOR_HDMIB || connector->connector_type == DRM_MODE_CONNECTOR_DisplayPort) && (IS_HASWELL(devid) || IS_BROADWELL(devid))) return false; } switch (state) { case FORCE_CONNECTOR_ON: value = "on"; break; case FORCE_CONNECTOR_DIGITAL: value = "on-digital"; break; case FORCE_CONNECTOR_OFF: value = "off"; break; default: case FORCE_CONNECTOR_UNSPECIFIED: value = "detect"; break; } dir = igt_sysfs_open(drm_fd); if (dir < 0) return false; idx = igt_device_get_card_index(drm_fd); if (idx < 0 || idx > 63) return false; if (asprintf(&path, "card%d-%s-%d/status", idx, kmstest_connector_type_str(connector->connector_type), connector->connector_type_id) < 0) { close(dir); return false; } if (!igt_sysfs_set(dir, path, value)) { close(dir); return false; } for (len = 0, tmp = forced_connectors; *tmp; tmp++) { /* check the connector is not already present */ if (strcmp(*tmp, path) == 0) { len = -1; break; } len++; } if (len != -1 && len < MAX_CONNECTORS) { forced_connectors[len] = path; forced_connectors_device[len] = dir; } if (len >= MAX_CONNECTORS) igt_warn("Connector limit reached, %s will not be reset\n", path); igt_debug("Connector %s is now forced %s\n", path, value); igt_debug("Current forced connectors:\n"); tmp = forced_connectors; while (*tmp) { igt_debug("\t%s\n", *tmp); tmp++; } igt_install_exit_handler(reset_connectors_at_exit); /* To allow callers to always use GetConnectorCurrent we need to force a * redetection here. */ temp = drmModeGetConnector(drm_fd, connector->connector_id); drmModeFreeConnector(temp); return true; } /** * kmstest_force_edid: * @drm_fd: drm file descriptor * @connector: connector to set @edid on * @edid: An EDID data block * @length: length of the EDID data. #EDID_LENGTH defines the standard EDID * length * * Set the EDID data on @connector to @edid. See also #igt_kms_get_base_edid. * * If @length is zero, the forced EDID will be removed. */ void kmstest_force_edid(int drm_fd, drmModeConnector *connector, const unsigned char *edid, size_t length) { char *path; int debugfs_fd, ret; drmModeConnector *temp; igt_assert_neq(asprintf(&path, "%s-%d/edid_override", kmstest_connector_type_str(connector->connector_type), connector->connector_type_id), -1); debugfs_fd = igt_debugfs_open(drm_fd, path, O_WRONLY | O_TRUNC); free(path); igt_require(debugfs_fd != -1); if (length == 0) ret = write(debugfs_fd, "reset", 5); else ret = write(debugfs_fd, edid, length); close(debugfs_fd); /* To allow callers to always use GetConnectorCurrent we need to force a * redetection here. */ temp = drmModeGetConnector(drm_fd, connector->connector_id); drmModeFreeConnector(temp); igt_assert(ret != -1); } /** * kmstest_get_connector_default_mode: * @drm_fd: DRM fd * @connector: libdrm connector * @mode: libdrm mode * * Retrieves the default mode for @connector and stores it in @mode. * * Returns: true on success, false on failure */ bool kmstest_get_connector_default_mode(int drm_fd, drmModeConnector *connector, drmModeModeInfo *mode) { int i; if (!connector->count_modes) { igt_warn("no modes for connector %d\n", connector->connector_id); return false; } for (i = 0; i < connector->count_modes; i++) { if (i == 0 || connector->modes[i].type & DRM_MODE_TYPE_PREFERRED) { *mode = connector->modes[i]; if (mode->type & DRM_MODE_TYPE_PREFERRED) break; } } return true; } static void _kmstest_connector_config_crtc_mask(int drm_fd, drmModeConnector *connector, struct kmstest_connector_config *config) { int i; config->valid_crtc_idx_mask = 0; /* Now get a compatible encoder */ for (i = 0; i < connector->count_encoders; i++) { drmModeEncoder *encoder = drmModeGetEncoder(drm_fd, connector->encoders[i]); if (!encoder) { igt_warn("could not get encoder %d: %s\n", connector->encoders[i], strerror(errno)); continue; } config->valid_crtc_idx_mask |= encoder->possible_crtcs; drmModeFreeEncoder(encoder); } } static drmModeEncoder * _kmstest_connector_config_find_encoder(int drm_fd, drmModeConnector *connector, enum pipe pipe) { int i; for (i = 0; i < connector->count_encoders; i++) { drmModeEncoder *encoder = drmModeGetEncoder(drm_fd, connector->encoders[i]); if (!encoder) { igt_warn("could not get encoder %d: %s\n", connector->encoders[i], strerror(errno)); continue; } if (encoder->possible_crtcs & (1 << pipe)) return encoder; drmModeFreeEncoder(encoder); } igt_assert(false); return NULL; } /** * _kmstest_connector_config: * @drm_fd: DRM fd * @connector_id: DRM connector id * @crtc_idx_mask: mask of allowed DRM CRTC indices * @config: structure filled with the possible configuration * @probe: whether to fully re-probe mode list or not * * This tries to find a suitable configuration for the given connector and CRTC * constraint and fills it into @config. */ static bool _kmstest_connector_config(int drm_fd, uint32_t connector_id, unsigned long crtc_idx_mask, struct kmstest_connector_config *config, bool probe) { drmModeRes *resources; drmModeConnector *connector; config->pipe = PIPE_NONE; resources = drmModeGetResources(drm_fd); if (!resources) { igt_warn("drmModeGetResources failed"); goto err1; } /* First, find the connector & mode */ if (probe) connector = drmModeGetConnector(drm_fd, connector_id); else connector = drmModeGetConnectorCurrent(drm_fd, connector_id); if (!connector) goto err2; if (connector->connector_id != connector_id) { igt_warn("connector id doesn't match (%d != %d)\n", connector->connector_id, connector_id); goto err3; } /* * Find given CRTC if crtc_id != 0 or else the first CRTC not in use. * In both cases find the first compatible encoder and skip the CRTC * if there is non such. */ _kmstest_connector_config_crtc_mask(drm_fd, connector, config); if (!connector->count_modes) memset(&config->default_mode, 0, sizeof(config->default_mode)); else if (!kmstest_get_connector_default_mode(drm_fd, connector, &config->default_mode)) goto err3; config->connector = connector; crtc_idx_mask &= config->valid_crtc_idx_mask; if (!crtc_idx_mask) /* Keep config->connector */ goto err2; config->pipe = ffs(crtc_idx_mask) - 1; config->encoder = _kmstest_connector_config_find_encoder(drm_fd, connector, config->pipe); config->crtc = drmModeGetCrtc(drm_fd, resources->crtcs[config->pipe]); if (connector->connection != DRM_MODE_CONNECTED) goto err2; if (!connector->count_modes) { if (probe) igt_warn("connector %d/%s-%d has no modes\n", connector_id, kmstest_connector_type_str(connector->connector_type), connector->connector_type_id); goto err2; } drmModeFreeResources(resources); return true; err3: drmModeFreeConnector(connector); err2: drmModeFreeResources(resources); err1: return false; } /** * kmstest_get_connector_config: * @drm_fd: DRM fd * @connector_id: DRM connector id * @crtc_idx_mask: mask of allowed DRM CRTC indices * @config: structure filled with the possible configuration * * This tries to find a suitable configuration for the given connector and CRTC * constraint and fills it into @config. */ bool kmstest_get_connector_config(int drm_fd, uint32_t connector_id, unsigned long crtc_idx_mask, struct kmstest_connector_config *config) { return _kmstest_connector_config(drm_fd, connector_id, crtc_idx_mask, config, 0); } /** * kmstest_probe_connector_config: * @drm_fd: DRM fd * @connector_id: DRM connector id * @crtc_idx_mask: mask of allowed DRM CRTC indices * @config: structure filled with the possible configuration * * This tries to find a suitable configuration for the given connector and CRTC * constraint and fills it into @config, fully probing the connector in the * process. */ bool kmstest_probe_connector_config(int drm_fd, uint32_t connector_id, unsigned long crtc_idx_mask, struct kmstest_connector_config *config) { return _kmstest_connector_config(drm_fd, connector_id, crtc_idx_mask, config, 1); } /** * kmstest_free_connector_config: * @config: connector configuration structure * * Free any resources in @config allocated in kmstest_get_connector_config(). */ void kmstest_free_connector_config(struct kmstest_connector_config *config) { drmModeFreeCrtc(config->crtc); config->crtc = NULL; drmModeFreeEncoder(config->encoder); config->encoder = NULL; drmModeFreeConnector(config->connector); config->connector = NULL; } /** * kmstest_set_connector_dpms: * @fd: DRM fd * @connector: libdrm connector * @mode: DRM DPMS value * * This function sets the DPMS setting of @connector to @mode. */ void kmstest_set_connector_dpms(int fd, drmModeConnector *connector, int mode) { int i, dpms = 0; bool found_it = false; for (i = 0; i < connector->count_props; i++) { struct drm_mode_get_property prop = { .prop_id = connector->props[i], }; if (drmIoctl(fd, DRM_IOCTL_MODE_GETPROPERTY, &prop)) continue; if (strcmp(prop.name, "DPMS")) continue; dpms = prop.prop_id; found_it = true; break; } igt_assert_f(found_it, "DPMS property not found on %d\n", connector->connector_id); igt_assert(drmModeConnectorSetProperty(fd, connector->connector_id, dpms, mode) == 0); } /** * kmstest_get_property: * @drm_fd: drm file descriptor * @object_id: object whose properties we're going to get * @object_type: type of obj_id (DRM_MODE_OBJECT_*) * @name: name of the property we're going to get * @prop_id: if not NULL, returns the property id * @value: if not NULL, returns the property value * @prop: if not NULL, returns the property, and the caller will have to free * it manually. * * Finds a property with the given name on the given object. * * Returns: true in case we found something. */ bool kmstest_get_property(int drm_fd, uint32_t object_id, uint32_t object_type, const char *name, uint32_t *prop_id /* out */, uint64_t *value /* out */, drmModePropertyPtr *prop /* out */) { drmModeObjectPropertiesPtr proplist; drmModePropertyPtr _prop; bool found = false; int i; proplist = drmModeObjectGetProperties(drm_fd, object_id, object_type); for (i = 0; i < proplist->count_props; i++) { _prop = drmModeGetProperty(drm_fd, proplist->props[i]); if (!_prop) continue; if (strcmp(_prop->name, name) == 0) { found = true; if (prop_id) *prop_id = proplist->props[i]; if (value) *value = proplist->prop_values[i]; if (prop) *prop = _prop; else drmModeFreeProperty(_prop); break; } drmModeFreeProperty(_prop); } drmModeFreeObjectProperties(proplist); return found; } struct edid_block { int pos; unsigned char *data; }; #define DTD_SUPPORTS_AUDIO 1<<6 static struct edid_block init_cea_block(const unsigned char *edid, size_t length, unsigned char *new_edid_ptr[], size_t *new_length, char extra_extensions_length, uint32_t dtd_support) { struct edid_block new_edid; int n_extensions; int pos; static const char cea_header_len = 4, video_block_len = 6; igt_assert(new_edid_ptr != NULL && new_length != NULL); *new_length = length + 128; new_edid.data = calloc(*new_length, sizeof(*new_edid.data)); igt_assert_f(new_edid.data, "Failed to allocate %zu bytes for edid\n", sizeof(new_length)); memcpy(new_edid.data, edid, length); *new_edid_ptr = new_edid.data; n_extensions = new_edid.data[126]; n_extensions++; new_edid.data[126] = n_extensions; update_edid_csum(new_edid.data, 0); /* add a cea-861 extension block */ pos = length; new_edid.data[pos++] = 0x2; new_edid.data[pos++] = 0x3; new_edid.data[pos++] = cea_header_len + video_block_len + extra_extensions_length; new_edid.data[pos++] = dtd_support; /* video block (id | length) */ new_edid.data[pos++] = 2 << 5 | (video_block_len - 1); new_edid.data[pos++] = 32 | 0x80; /* 1080p @ 24Hz | (native)*/ new_edid.data[pos++] = 5; /* 1080i @ 60Hz */ new_edid.data[pos++] = 20; /* 1080i @ 50Hz */ new_edid.data[pos++] = 4; /* 720p @ 60Hz*/ new_edid.data[pos++] = 19; /* 720p @ 50Hz*/ new_edid.pos = pos; return new_edid; } /** * kmstest_edid_add_3d: * @edid: an existing valid edid block * @length: length of @edid * @new_edid_ptr: pointer to where the new edid will be placed * @new_length: pointer to the size of the new edid * * Makes a copy of an existing edid block and adds an extension indicating * stereo 3D capabilities. */ void kmstest_edid_add_3d(const unsigned char *edid, size_t length, unsigned char *new_edid_ptr[], size_t *new_length) { char vsdb_block_len = 11; struct edid_block new_edid = init_cea_block(edid, length, new_edid_ptr, new_length, vsdb_block_len, 0); int pos = new_edid.pos; /* vsdb block ( id | length ) */ new_edid.data[pos++] = 3 << 5 | (vsdb_block_len - 1); /* registration id */ new_edid.data[pos++] = 0x3; new_edid.data[pos++] = 0xc; new_edid.data[pos++] = 0x0; /* source physical address */ new_edid.data[pos++] = 0x10; new_edid.data[pos++] = 0x00; /* Supports_AI ... etc */ new_edid.data[pos++] = 0x00; /* Max TMDS Clock */ new_edid.data[pos++] = 0x00; /* Latency present, HDMI Video Present */ new_edid.data[pos++] = 0x20; /* HDMI Video */ new_edid.data[pos++] = 0x80; new_edid.data[pos++] = 0x00; update_edid_csum(new_edid.data, length); } /** * kmstest_edid_add_4k: * @edid: an existing valid edid block * @length: length of @edid * @new_edid_ptr: pointer to where the new edid will be placed * @new_length: pointer to the size of the new edid * * Makes a copy of an existing edid block and adds an extension indicating * a HDMI 4K mode in vsdb. */ void kmstest_edid_add_4k(const unsigned char *edid, size_t length, unsigned char *new_edid_ptr[], size_t *new_length) { char vsdb_block_len = 12; struct edid_block new_edid = init_cea_block(edid, length, new_edid_ptr, new_length, vsdb_block_len, 0); int pos = new_edid.pos; /* vsdb block ( id | length ) */ new_edid.data[pos++] = 3 << 5 | (vsdb_block_len - 1); /* registration id */ new_edid.data[pos++] = 0x3; new_edid.data[pos++] = 0xc; new_edid.data[pos++] = 0x0; /* source physical address */ new_edid.data[pos++] = 0x10; new_edid.data[pos++] = 0x00; /* Supports_AI ... etc */ new_edid.data[pos++] = 0x00; /* Max TMDS Clock */ new_edid.data[pos++] = 0x00; /* Latency present, HDMI Video Present */ new_edid.data[pos++] = 0x20; /* HDMI Video */ new_edid.data[pos++] = 0x00; /* 3D present */ /* HDMI MODE LEN -- how many entries */ new_edid.data[pos++] = 0x20; /* 2160p, specified as short descriptor */ new_edid.data[pos++] = 0x01; update_edid_csum(new_edid.data, length); } /** * kmstest_edid_add_audio: * @edid: an existing valid edid block * @length: length of @edid * @new_edid_ptr: pointer to where the new edid will be placed * @new_length: pointer to the size of the new edid * * Makes a copy of an existing edid block and adds an extension indicating * basic audio support and speaker data block. * */ void kmstest_edid_add_audio(const unsigned char *edid, size_t length, unsigned char *new_edid_ptr[], size_t *new_length) { char vsdb_block_len = 10, audio_block_len = 4, spkr_block_len = 4; struct edid_block new_edid = init_cea_block(edid, length, new_edid_ptr, new_length, vsdb_block_len + audio_block_len + spkr_block_len, DTD_SUPPORTS_AUDIO); int pos = new_edid.pos; /* audio block, short audio block descriptors */ new_edid.data[pos++] = (1 << 5) | (audio_block_len - 1); new_edid.data[pos++] = 0x09; /* Audio Format, PCM */ new_edid.data[pos++] = 0x07; /* Frequency, 32, 44.1, 48kHz */ new_edid.data[pos++] = 0x07; /* Bit Rate 16, 20, 24 bit */ /* vsdb block ( id | length ) -- need vsdb as well * otherwise the kernel will fallback to lower clock modes */ new_edid.data[pos++] = 3 << 5 | (vsdb_block_len - 1); /* registration id */ new_edid.data[pos++] = 0x3; new_edid.data[pos++] = 0xc; new_edid.data[pos++] = 0x0; /* source physical address */ new_edid.data[pos++] = 0x10; new_edid.data[pos++] = 0x00; /* Supports_AI ... etc */ new_edid.data[pos++] = 0x00; /* Max TMDS Clock */ new_edid.data[pos++] = 0x00; /* Latency present, HDMI Video Present */ new_edid.data[pos++] = 0x20; /* HDMI Video */ new_edid.data[pos++] = 0x00; /* 3D present */ /* speaker data block */ new_edid.data[pos++] = (4 << 5) | (spkr_block_len - 1); new_edid.data[pos++] = (1 << 5); new_edid.data[pos++] = 0x00; new_edid.data[pos++] = 0x00; update_edid_csum(new_edid.data, length); } /** * kmstest_unset_all_crtcs: * @drm_fd: the DRM fd * @resources: libdrm resources pointer * * Disables all the screens. */ void kmstest_unset_all_crtcs(int drm_fd, drmModeResPtr resources) { int i, rc; for (i = 0; i < resources->count_crtcs; i++) { rc = drmModeSetCrtc(drm_fd, resources->crtcs[i], 0, 0, 0, NULL, 0, NULL); igt_assert(rc == 0); } } /** * kmstest_get_crtc_idx: * @res: the libdrm resources * @crtc_id: the CRTC id * * Get the CRTC index based on its ID. This is useful since a few places of * libdrm deal with CRTC masks. */ int kmstest_get_crtc_idx(drmModeRes *res, uint32_t crtc_id) { int i; for (i = 0; i < res->count_crtcs; i++) if (res->crtcs[i] == crtc_id) return i; igt_assert(false); } static inline uint32_t pipe_select(int pipe) { if (pipe > 1) return pipe << DRM_VBLANK_HIGH_CRTC_SHIFT; else if (pipe > 0) return DRM_VBLANK_SECONDARY; else return 0; } /** * kmstest_get_vblank: * @fd: Opened drm file descriptor * @pipe: Display pipe * @flags: Flags passed to drm_ioctl_wait_vblank * * Blocks or request a signal when a specified vblank event occurs * * Returns 0 on success or non-zero unsigned integer otherwise */ unsigned int kmstest_get_vblank(int fd, int pipe, unsigned int flags) { union drm_wait_vblank vbl; memset(&vbl, 0, sizeof(vbl)); vbl.request.type = DRM_VBLANK_RELATIVE | pipe_select(pipe) | flags; if (drmIoctl(fd, DRM_IOCTL_WAIT_VBLANK, &vbl)) return 0; return vbl.reply.sequence; } /** * kmstest_wait_for_pageflip: * @fd: Opened drm file descriptor * * Blocks until pageflip is completed * */ void kmstest_wait_for_pageflip(int fd) { drmEventContext evctx = { .version = 2 }; struct timeval timeout = { .tv_sec = 0, .tv_usec = 50000 }; fd_set fds; int ret; /* Wait for pageflip completion, then consume event on fd */ FD_ZERO(&fds); FD_SET(fd, &fds); do { errno = 0; ret = select(fd + 1, &fds, NULL, NULL, &timeout); } while (ret < 0 && errno == EINTR); igt_fail_on_f(ret == 0, "Exceeded timeout (50ms) while waiting for a pageflip\n"); igt_assert_f(ret == 1, "Waiting for pageflip failed with %d from select(drmfd)\n", ret); igt_assert(drmHandleEvent(fd, &evctx) == 0); } static void get_plane(char *str, int type, struct kmstest_plane *plane) { int ret; char buf[256]; plane->type = type; ret = sscanf(str + 12, "%d%*c %*s %[^n]s", &plane->id, buf); igt_assert_eq(ret, 2); ret = sscanf(buf + 9, "%4d%*c%4d%*c", &plane->pos_x, &plane->pos_y); igt_assert_eq(ret, 2); ret = sscanf(buf + 30, "%4d%*c%4d%*c", &plane->width, &plane->height); igt_assert_eq(ret, 2); } static int parse_planes(FILE *fid, struct kmstest_plane *planes) { char tmp[256]; int n_planes; n_planes = 0; while (fgets(tmp, 256, fid) != NULL) { if (strstr(tmp, "type=PRI") != NULL) { if (planes) { get_plane(tmp, DRM_PLANE_TYPE_PRIMARY, &planes[n_planes]); planes[n_planes].index = n_planes; } n_planes++; } else if (strstr(tmp, "type=OVL") != NULL) { if (planes) { get_plane(tmp, DRM_PLANE_TYPE_OVERLAY, &planes[n_planes]); planes[n_planes].index = n_planes; } n_planes++; } else if (strstr(tmp, "type=CUR") != NULL) { if (planes) { get_plane(tmp, DRM_PLANE_TYPE_CURSOR, &planes[n_planes]); planes[n_planes].index = n_planes; } n_planes++; break; } } return n_planes; } static void parse_crtc(char *info, struct kmstest_crtc *crtc) { char buf[256]; int ret; char pipe; ret = sscanf(info + 4, "%d%*c %*s %c%*c %*s %s%*c", &crtc->id, &pipe, buf); igt_assert_eq(ret, 3); crtc->pipe = kmstest_pipe_to_index(pipe); igt_assert(crtc->pipe >= 0); ret = sscanf(buf + 6, "%d%*c%d%*c", &crtc->width, &crtc->height); igt_assert_eq(ret, 2); } static void kmstest_get_crtc(int device, enum pipe pipe, struct kmstest_crtc *crtc) { char tmp[256]; FILE *file; int ncrtc; int line; long int n; int fd; fd = igt_debugfs_open(device, "i915_display_info", O_RDONLY); file = fdopen(fd, "r"); igt_skip_on(file == NULL); ncrtc = 0; line = 0; while (fgets(tmp, 256, file) != NULL) { if ((strstr(tmp, "CRTC") != NULL) && (line > 0)) { if (strstr(tmp, "active=yes") != NULL) { crtc->active = true; parse_crtc(tmp, crtc); n = ftell(file); crtc->n_planes = parse_planes(file, NULL); igt_assert_lt(0, crtc->n_planes); crtc->planes = calloc(crtc->n_planes, sizeof(*crtc->planes)); igt_assert_f(crtc->planes, "Failed to allocate memory for %d planes\n", crtc->n_planes); fseek(file, n, SEEK_SET); parse_planes(file, crtc->planes); if (crtc->pipe != pipe) { free(crtc->planes); } else { ncrtc++; break; } } } line++; } fclose(file); close(fd); igt_assert(ncrtc == 1); } /** * igt_assert_plane_visible: * @fd: Opened file descriptor * @pipe: Display pipe * @visibility: Boolean parameter to test against the plane's current visibility state * * Asserts only if the plane's visibility state matches the status being passed by @visibility */ void igt_assert_plane_visible(int fd, enum pipe pipe, int plane_index, bool visibility) { struct kmstest_crtc crtc; bool visible = true; kmstest_get_crtc(fd, pipe, &crtc); igt_assert(plane_index < crtc.n_planes); if (crtc.planes[plane_index].pos_x > crtc.width || crtc.planes[plane_index].pos_y > crtc.height) visible = false; free(crtc.planes); igt_assert_eq(visible, visibility); } /* * A small modeset API */ #define LOG_SPACES " " #define LOG_N_SPACES (sizeof(LOG_SPACES) - 1) #define LOG_INDENT(d, section) \ do { \ igt_display_log(d, "%s {\n", section); \ igt_display_log_shift(d, 1); \ } while (0) #define LOG_UNINDENT(d) \ do { \ igt_display_log_shift(d, -1); \ igt_display_log(d, "}\n"); \ } while (0) #define LOG(d, fmt, ...) igt_display_log(d, fmt, ## __VA_ARGS__) static void __attribute__((format(printf, 2, 3))) igt_display_log(igt_display_t *display, const char *fmt, ...) { va_list args; int i; va_start(args, fmt); igt_debug("display: "); for (i = 0; i < display->log_shift; i++) igt_debug("%s", LOG_SPACES); igt_vlog(IGT_LOG_DOMAIN, IGT_LOG_DEBUG, fmt, args); va_end(args); } static void igt_display_log_shift(igt_display_t *display, int shift) { display->log_shift += shift; igt_assert(display->log_shift >= 0); } static void igt_output_refresh(igt_output_t *output) { igt_display_t *display = output->display; unsigned long crtc_idx_mask = 0; if (output->pending_pipe != PIPE_NONE) crtc_idx_mask = 1 << output->pending_pipe; kmstest_free_connector_config(&output->config); _kmstest_connector_config(display->drm_fd, output->id, crtc_idx_mask, &output->config, output->force_reprobe); output->force_reprobe = false; if (!output->name && output->config.connector) { drmModeConnector *c = output->config.connector; igt_assert_neq(asprintf(&output->name, "%s-%d", kmstest_connector_type_str(c->connector_type), c->connector_type_id), -1); } if (output->config.connector) igt_atomic_fill_connector_props(display, output, IGT_NUM_CONNECTOR_PROPS, igt_connector_prop_names); LOG(display, "%s: Selecting pipe %s\n", output->name, kmstest_pipe_name(output->pending_pipe)); } static int igt_plane_set_property(igt_plane_t *plane, uint32_t prop_id, uint64_t value) { igt_pipe_t *pipe = plane->pipe; igt_display_t *display = pipe->display; return drmModeObjectSetProperty(display->drm_fd, plane->drm_plane->plane_id, DRM_MODE_OBJECT_PLANE, prop_id, value); } /* * Walk a plane's property list to determine its type. If we don't * find a type property, then the kernel doesn't support universal * planes and we know the plane is an overlay/sprite. */ static int get_drm_plane_type(int drm_fd, uint32_t plane_id) { uint64_t value; bool has_prop; has_prop = kmstest_get_property(drm_fd, plane_id, DRM_MODE_OBJECT_PLANE, "type", NULL, &value, NULL); if (has_prop) return (int)value; return DRM_PLANE_TYPE_OVERLAY; } static void igt_plane_reset(igt_plane_t *plane) { /* Reset src coordinates. */ igt_plane_set_prop_value(plane, IGT_PLANE_SRC_X, 0); igt_plane_set_prop_value(plane, IGT_PLANE_SRC_Y, 0); igt_plane_set_prop_value(plane, IGT_PLANE_SRC_W, 0); igt_plane_set_prop_value(plane, IGT_PLANE_SRC_H, 0); /* Reset crtc coordinates. */ igt_plane_set_prop_value(plane, IGT_PLANE_CRTC_X, 0); igt_plane_set_prop_value(plane, IGT_PLANE_CRTC_Y, 0); igt_plane_set_prop_value(plane, IGT_PLANE_CRTC_W, 0); igt_plane_set_prop_value(plane, IGT_PLANE_CRTC_H, 0); /* Reset binding to fb and crtc. */ igt_plane_set_prop_value(plane, IGT_PLANE_FB_ID, 0); igt_plane_set_prop_value(plane, IGT_PLANE_CRTC_ID, 0); if (igt_plane_has_prop(plane, IGT_PLANE_COLOR_ENCODING)) igt_plane_set_prop_enum(plane, IGT_PLANE_COLOR_ENCODING, igt_color_encoding_to_str(IGT_COLOR_YCBCR_BT601)); if (igt_plane_has_prop(plane, IGT_PLANE_COLOR_RANGE)) igt_plane_set_prop_enum(plane, IGT_PLANE_COLOR_RANGE, igt_color_range_to_str(IGT_COLOR_YCBCR_LIMITED_RANGE)); /* Use default rotation */ if (igt_plane_has_prop(plane, IGT_PLANE_ROTATION)) igt_plane_set_prop_value(plane, IGT_PLANE_ROTATION, IGT_ROTATION_0); if (igt_plane_has_prop(plane, IGT_PLANE_PIXEL_BLEND_MODE)) igt_plane_set_prop_enum(plane, IGT_PLANE_PIXEL_BLEND_MODE, "Pre-multiplied"); if (igt_plane_has_prop(plane, IGT_PLANE_ALPHA)) igt_plane_set_prop_value(plane, IGT_PLANE_ALPHA, 0xffff); igt_plane_clear_prop_changed(plane, IGT_PLANE_IN_FENCE_FD); plane->values[IGT_PLANE_IN_FENCE_FD] = ~0ULL; plane->gem_handle = 0; } static void igt_pipe_reset(igt_pipe_t *pipe) { igt_pipe_obj_set_prop_value(pipe, IGT_CRTC_MODE_ID, 0); igt_pipe_obj_set_prop_value(pipe, IGT_CRTC_ACTIVE, 0); igt_pipe_obj_clear_prop_changed(pipe, IGT_CRTC_OUT_FENCE_PTR); if (igt_pipe_obj_has_prop(pipe, IGT_CRTC_CTM)) igt_pipe_obj_set_prop_value(pipe, IGT_CRTC_CTM, 0); if (igt_pipe_obj_has_prop(pipe, IGT_CRTC_GAMMA_LUT)) igt_pipe_obj_set_prop_value(pipe, IGT_CRTC_GAMMA_LUT, 0); if (igt_pipe_obj_has_prop(pipe, IGT_CRTC_DEGAMMA_LUT)) igt_pipe_obj_set_prop_value(pipe, IGT_CRTC_DEGAMMA_LUT, 0); pipe->out_fence_fd = -1; } static void igt_output_reset(igt_output_t *output) { output->pending_pipe = PIPE_NONE; output->use_override_mode = false; memset(&output->override_mode, 0, sizeof(output->override_mode)); igt_output_set_prop_value(output, IGT_CONNECTOR_CRTC_ID, 0); if (igt_output_has_prop(output, IGT_CONNECTOR_BROADCAST_RGB)) igt_output_set_prop_value(output, IGT_CONNECTOR_BROADCAST_RGB, BROADCAST_RGB_FULL); } /** * igt_display_reset: * @display: a pointer to an #igt_display_t structure * * Reset basic pipes, connectors and planes on @display back to default values. * In particular, the following properties will be reset: * * For outputs: * - %IGT_CONNECTOR_CRTC_ID * - %IGT_CONNECTOR_BROADCAST_RGB (if applicable) * - igt_output_override_mode() to default. * * For pipes: * - %IGT_CRTC_MODE_ID (leaked) * - %IGT_CRTC_ACTIVE * - %IGT_CRTC_OUT_FENCE_PTR * * For planes: * - %IGT_PLANE_SRC_* * - %IGT_PLANE_CRTC_* * - %IGT_PLANE_FB_ID * - %IGT_PLANE_CRTC_ID * - %IGT_PLANE_ROTATION * - %IGT_PLANE_IN_FENCE_FD */ void igt_display_reset(igt_display_t *display) { enum pipe pipe; int i; /* * Allow resetting rotation on all planes, which is normally * prohibited on the primary and cursor plane for legacy commits. */ display->first_commit = true; for_each_pipe(display, pipe) { igt_pipe_t *pipe_obj = &display->pipes[pipe]; igt_plane_t *plane; for_each_plane_on_pipe(display, pipe, plane) igt_plane_reset(plane); igt_pipe_reset(pipe_obj); } for (i = 0; i < display->n_outputs; i++) { igt_output_t *output = &display->outputs[i]; igt_output_reset(output); } } static void igt_fill_plane_format_mod(igt_display_t *display, igt_plane_t *plane); static void igt_fill_display_format_mod(igt_display_t *display); /** * igt_display_require: * @display: a pointer to an #igt_display_t structure * @drm_fd: a drm file descriptor * * Initialize @display and allocate the various resources required. Use * #igt_display_fini to release the resources when they are no longer required. * * This function automatically skips if the kernel driver doesn't support any * CRTC or outputs. */ void igt_display_require(igt_display_t *display, int drm_fd) { drmModeRes *resources; drmModePlaneRes *plane_resources; int i; memset(display, 0, sizeof(igt_display_t)); LOG_INDENT(display, "init"); display->drm_fd = drm_fd; resources = drmModeGetResources(display->drm_fd); if (!resources) goto out; /* * We cache the number of pipes, that number is a physical limit of the * hardware and cannot change of time (for now, at least). */ display->n_pipes = resources->count_crtcs; display->pipes = calloc(sizeof(igt_pipe_t), display->n_pipes); igt_assert_f(display->pipes, "Failed to allocate memory for %d pipes\n", display->n_pipes); drmSetClientCap(drm_fd, DRM_CLIENT_CAP_UNIVERSAL_PLANES, 1); if (drmSetClientCap(drm_fd, DRM_CLIENT_CAP_ATOMIC, 1) == 0) display->is_atomic = 1; plane_resources = drmModeGetPlaneResources(display->drm_fd); igt_assert(plane_resources); display->n_planes = plane_resources->count_planes; display->planes = calloc(sizeof(igt_plane_t), display->n_planes); igt_assert_f(display->planes, "Failed to allocate memory for %d planes\n", display->n_planes); for (i = 0; i < plane_resources->count_planes; ++i) { igt_plane_t *plane = &display->planes[i]; uint32_t id = plane_resources->planes[i]; plane->drm_plane = drmModeGetPlane(display->drm_fd, id); igt_assert(plane->drm_plane); plane->type = get_drm_plane_type(display->drm_fd, id); /* * TODO: Fill in the rest of the plane properties here and * move away from the plane per pipe model to align closer * to the DRM KMS model. */ } for_each_pipe(display, i) { igt_pipe_t *pipe = &display->pipes[i]; igt_plane_t *plane; int p = 1; int j, type; uint8_t last_plane = 0, n_planes = 0; pipe->crtc_id = resources->crtcs[i]; pipe->display = display; pipe->pipe = i; pipe->plane_cursor = -1; pipe->plane_primary = -1; pipe->planes = NULL; igt_fill_pipe_props(display, pipe, IGT_NUM_CRTC_PROPS, igt_crtc_prop_names); /* count number of valid planes */ for (j = 0; j < display->n_planes; j++) { drmModePlane *drm_plane = display->planes[j].drm_plane; igt_assert(drm_plane); if (drm_plane->possible_crtcs & (1 << i)) n_planes++; } igt_assert_lt(0, n_planes); pipe->planes = calloc(sizeof(igt_plane_t), n_planes); igt_assert_f(pipe->planes, "Failed to allocate memory for %d planes\n", n_planes); last_plane = n_planes - 1; /* add the planes that can be used with that pipe */ for (j = 0; j < display->n_planes; j++) { igt_plane_t *global_plane = &display->planes[j]; drmModePlane *drm_plane = global_plane->drm_plane; if (!(drm_plane->possible_crtcs & (1 << i))) continue; type = global_plane->type; if (type == DRM_PLANE_TYPE_PRIMARY && pipe->plane_primary == -1) { plane = &pipe->planes[0]; plane->index = 0; pipe->plane_primary = 0; } else if (type == DRM_PLANE_TYPE_CURSOR && pipe->plane_cursor == -1) { plane = &pipe->planes[last_plane]; plane->index = last_plane; pipe->plane_cursor = last_plane; display->has_cursor_plane = true; } else { plane = &pipe->planes[p]; plane->index = p++; } igt_assert_f(plane->index < n_planes, "n_planes < plane->index failed\n"); plane->type = type; plane->pipe = pipe; plane->drm_plane = drm_plane; plane->values[IGT_PLANE_IN_FENCE_FD] = ~0ULL; plane->ref = global_plane; /* * HACK: point the global plane to the first pipe that * it can go on. */ if (!global_plane->ref) igt_plane_set_pipe(plane, pipe); igt_fill_plane_props(display, plane, IGT_NUM_PLANE_PROPS, igt_plane_prop_names); igt_fill_plane_format_mod(display, plane); } /* * At the bare minimum, we should expect to have a primary * plane, and it must be in slot 0. */ igt_assert_eq(pipe->plane_primary, 0); /* Check that we filled every slot exactly once */ if (display->has_cursor_plane) igt_assert_eq(p, last_plane); else igt_assert_eq(p, n_planes); pipe->n_planes = n_planes; } igt_fill_display_format_mod(display); /* * The number of connectors is set, so we just initialize the outputs * array in _init(). This may change when we need dynamic connectors * (say DisplayPort MST). */ display->n_outputs = resources->count_connectors; display->outputs = calloc(display->n_outputs, sizeof(igt_output_t)); igt_assert_f(display->outputs, "Failed to allocate memory for %d outputs\n", display->n_outputs); for (i = 0; i < display->n_outputs; i++) { igt_output_t *output = &display->outputs[i]; drmModeConnector *connector; /* * We don't assign each output a pipe unless * a pipe is set with igt_output_set_pipe(). */ output->pending_pipe = PIPE_NONE; output->id = resources->connectors[i]; output->display = display; igt_output_refresh(output); connector = output->config.connector; if (connector && (!connector->count_modes || connector->connection == DRM_MODE_UNKNOWNCONNECTION)) { output->force_reprobe = true; igt_output_refresh(output); } } drmModeFreePlaneResources(plane_resources); drmModeFreeResources(resources); /* Set reasonable default values for every object in the display. */ igt_display_reset(display); out: LOG_UNINDENT(display); if (display->n_pipes && display->n_outputs) igt_enable_connectors(drm_fd); else igt_skip("No KMS driver or no outputs, pipes: %d, outputs: %d\n", display->n_pipes, display->n_outputs); } /** * igt_display_get_n_pipes: * @display: A pointer to an #igt_display_t structure * * Returns total number of pipes for the given @display */ int igt_display_get_n_pipes(igt_display_t *display) { return display->n_pipes; } /** * igt_display_require_output: * @display: A pointer to an #igt_display_t structure * * Checks whether there's a valid @pipe/@output combination for the given @display * Skips test if a valid combination of @pipe and @output is not found */ void igt_display_require_output(igt_display_t *display) { enum pipe pipe; igt_output_t *output; for_each_pipe_with_valid_output(display, pipe, output) return; igt_skip("No valid crtc/connector combinations found.\n"); } /** * igt_display_require_output_on_pipe: * @display: A pointer to an #igt_display_t structure * @pipe: Display pipe * * Checks whether there's a valid @pipe/@output combination for the given @display and @pipe * Skips test if a valid @pipe is not found */ void igt_display_require_output_on_pipe(igt_display_t *display, enum pipe pipe) { igt_output_t *output; igt_skip_on_f(pipe >= igt_display_get_n_pipes(display), "Pipe %s does not exist.\n", kmstest_pipe_name(pipe)); for_each_valid_output_on_pipe(display, pipe, output) return; igt_skip("No valid connector found on pipe %s\n", kmstest_pipe_name(pipe)); } /** * igt_output_from_connector: * @display: a pointer to an #igt_display_t structure * @connector: a pointer to a drmModeConnector * * Finds the output corresponding to the given connector * * Returns: A #igt_output_t structure configured to use the connector, or NULL * if none was found */ igt_output_t *igt_output_from_connector(igt_display_t *display, drmModeConnector *connector) { igt_output_t *output, *found = NULL; int i; for (i = 0; i < display->n_outputs; i++) { output = &display->outputs[i]; if (output->config.connector && output->config.connector->connector_id == connector->connector_id) { found = output; break; } } return found; } const drmModeModeInfo *igt_std_1024_mode_get(void) { static const drmModeModeInfo std_1024_mode = { .clock = 65000, .hdisplay = 1024, .hsync_start = 1048, .hsync_end = 1184, .htotal = 1344, .hskew = 0, .vdisplay = 768, .vsync_start = 771, .vsync_end = 777, .vtotal = 806, .vscan = 0, .vrefresh = 60, .flags = 0xA, .type = 0x40, .name = "Custom 1024x768", }; return &std_1024_mode; } static void igt_pipe_fini(igt_pipe_t *pipe) { free(pipe->planes); pipe->planes = NULL; if (pipe->out_fence_fd != -1) close(pipe->out_fence_fd); } static void igt_output_fini(igt_output_t *output) { kmstest_free_connector_config(&output->config); free(output->name); output->name = NULL; } /** * igt_display_fini: * @display: a pointer to an #igt_display_t structure * * Release any resources associated with @display. This does not free @display * itself. */ void igt_display_fini(igt_display_t *display) { int i; for (i = 0; i < display->n_planes; ++i) { igt_plane_t *plane = &display->planes[i]; if (plane->drm_plane) { drmModeFreePlane(plane->drm_plane); plane->drm_plane = NULL; } } for (i = 0; i < display->n_pipes; i++) igt_pipe_fini(&display->pipes[i]); for (i = 0; i < display->n_outputs; i++) igt_output_fini(&display->outputs[i]); free(display->outputs); display->outputs = NULL; free(display->pipes); display->pipes = NULL; free(display->planes); display->planes = NULL; } static void igt_display_refresh(igt_display_t *display) { igt_output_t *output; int i; unsigned long pipes_in_use = 0; /* Check that two outputs aren't trying to use the same pipe */ for (i = 0; i < display->n_outputs; i++) { output = &display->outputs[i]; if (output->pending_pipe != PIPE_NONE) { if (pipes_in_use & (1 << output->pending_pipe)) goto report_dup; pipes_in_use |= 1 << output->pending_pipe; } if (output->force_reprobe) igt_output_refresh(output); } return; report_dup: for (; i > 0; i--) { igt_output_t *b = &display->outputs[i - 1]; igt_assert_f(output->pending_pipe != b->pending_pipe, "%s and %s are both trying to use pipe %s\n", igt_output_name(output), igt_output_name(b), kmstest_pipe_name(output->pending_pipe)); } } static igt_pipe_t *igt_output_get_driving_pipe(igt_output_t *output) { igt_display_t *display = output->display; enum pipe pipe; if (output->pending_pipe == PIPE_NONE) { /* * The user hasn't specified a pipe to use, return none. */ return NULL; } else { /* * Otherwise, return the pending pipe (ie the pipe that should * drive this output after the commit() */ pipe = output->pending_pipe; } igt_assert(pipe >= 0 && pipe < display->n_pipes); return &display->pipes[pipe]; } static igt_plane_t *igt_pipe_get_plane(igt_pipe_t *pipe, int plane_idx) { igt_require_f(plane_idx >= 0 && plane_idx < pipe->n_planes, "Valid pipe->planes plane_idx not found, plane_idx=%d n_planes=%d", plane_idx, pipe->n_planes); return &pipe->planes[plane_idx]; } /** * igt_pipe_get_plane_type: * @pipe: Target pipe * @plane_type: Cursor, primary or an overlay plane * * Finds a valid plane type for the given @pipe otherwise * it skips the test if the right combination of @pipe/@plane_type is not found * * Returns: A #igt_plane_t structure that matches the requested plane type */ igt_plane_t *igt_pipe_get_plane_type(igt_pipe_t *pipe, int plane_type) { int i, plane_idx = -1; switch(plane_type) { case DRM_PLANE_TYPE_CURSOR: plane_idx = pipe->plane_cursor; break; case DRM_PLANE_TYPE_PRIMARY: plane_idx = pipe->plane_primary; break; case DRM_PLANE_TYPE_OVERLAY: for(i = 0; i < pipe->n_planes; i++) if (pipe->planes[i].type == DRM_PLANE_TYPE_OVERLAY) plane_idx = i; break; default: break; } igt_require_f(plane_idx >= 0 && plane_idx < pipe->n_planes, "Valid pipe->planes idx not found. plane_idx=%d plane_type=%d n_planes=%d\n", plane_idx, plane_type, pipe->n_planes); return &pipe->planes[plane_idx]; } /** * igt_pipe_count_plane_type: * @pipe: Target pipe * @plane_type: Cursor, primary or an overlay plane * * Counts the number of planes of type @plane_type for the provided @pipe. * * Returns: The number of planes that match the requested plane type */ int igt_pipe_count_plane_type(igt_pipe_t *pipe, int plane_type) { int i, count = 0; for(i = 0; i < pipe->n_planes; i++) if (pipe->planes[i].type == plane_type) count++; return count; } /** * igt_pipe_get_plane_type_index: * @pipe: Target pipe * @plane_type: Cursor, primary or an overlay plane * @index: the index of the plane among planes of the same type * * Get the @index th plane of type @plane_type for the provided @pipe. * * Returns: The @index th plane that matches the requested plane type */ igt_plane_t *igt_pipe_get_plane_type_index(igt_pipe_t *pipe, int plane_type, int index) { int i, type_index = 0; for(i = 0; i < pipe->n_planes; i++) { if (pipe->planes[i].type != plane_type) continue; if (type_index == index) return &pipe->planes[i]; type_index++; } return NULL; } static bool output_is_internal_panel(igt_output_t *output) { switch (output->config.connector->connector_type) { case DRM_MODE_CONNECTOR_LVDS: case DRM_MODE_CONNECTOR_eDP: case DRM_MODE_CONNECTOR_DSI: case DRM_MODE_CONNECTOR_DPI: return true; default: return false; } } igt_output_t **__igt_pipe_populate_outputs(igt_display_t *display, igt_output_t **chosen_outputs) { unsigned full_pipe_mask = (1 << (display->n_pipes)) - 1, assigned_pipes = 0; igt_output_t *output; int i, j; memset(chosen_outputs, 0, sizeof(*chosen_outputs) * display->n_pipes); /* * Try to assign all outputs to the first available CRTC for * it, start with the outputs restricted to 1 pipe, then increase * number of pipes until we assign connectors to all pipes. */ for (i = 0; i <= display->n_pipes; i++) { for_each_connected_output(display, output) { uint32_t pipe_mask = output->config.valid_crtc_idx_mask & full_pipe_mask; bool found = false; if (output_is_internal_panel(output)) { /* * Internal panel should be assigned to pipe A * if possible, so make sure they're enumerated * first. */ if (i) continue; } else if (__builtin_popcount(pipe_mask) != i) continue; for (j = 0; j < display->n_pipes; j++) { bool pipe_assigned = assigned_pipes & (1 << j); if (pipe_assigned || !(pipe_mask & (1 << j))) continue; if (!found) { /* We found an unassigned pipe, use it! */ found = true; assigned_pipes |= 1 << j; chosen_outputs[j] = output; } else if (!chosen_outputs[j] || /* * Overwrite internal panel if not assigned, * external outputs are faster to do modesets */ output_is_internal_panel(chosen_outputs[j])) chosen_outputs[j] = output; } if (!found) igt_warn("Output %s could not be assigned to a pipe\n", igt_output_name(output)); } } return chosen_outputs; } /** * igt_get_single_output_for_pipe: * @display: a pointer to an #igt_display_t structure * @pipe: The pipe for which an #igt_output_t must be returned. * * Get a compatible output for a pipe. * * Returns: A compatible output for a given pipe, or NULL. */ igt_output_t *igt_get_single_output_for_pipe(igt_display_t *display, enum pipe pipe) { igt_output_t *chosen_outputs[display->n_pipes]; igt_assert(pipe != PIPE_NONE); igt_require(pipe < display->n_pipes); __igt_pipe_populate_outputs(display, chosen_outputs); return chosen_outputs[pipe]; } static igt_output_t *igt_pipe_get_output(igt_pipe_t *pipe) { igt_display_t *display = pipe->display; int i; for (i = 0; i < display->n_outputs; i++) { igt_output_t *output = &display->outputs[i]; if (output->pending_pipe == pipe->pipe) return output; } return NULL; } static uint32_t igt_plane_get_fb_id(igt_plane_t *plane) { return plane->values[IGT_PLANE_FB_ID]; } #define CHECK_RETURN(r, fail) { \ if (r && !fail) \ return r; \ igt_assert_eq(r, 0); \ } /* * Add position and fb changes of a plane to the atomic property set */ static void igt_atomic_prepare_plane_commit(igt_plane_t *plane, igt_pipe_t *pipe, drmModeAtomicReq *req) { igt_display_t *display = pipe->display; int i; igt_assert(plane->drm_plane); LOG(display, "populating plane data: %s.%d, fb %u\n", kmstest_pipe_name(pipe->pipe), plane->index, igt_plane_get_fb_id(plane)); for (i = 0; i < IGT_NUM_PLANE_PROPS; i++) { if (!igt_plane_is_prop_changed(plane, i)) continue; /* it's an error to try an unsupported feature */ igt_assert(plane->props[i]); igt_debug("plane %s.%d: Setting property \"%s\" to 0x%"PRIx64"/%"PRIi64"\n", kmstest_pipe_name(pipe->pipe), plane->index, igt_plane_prop_names[i], plane->values[i], plane->values[i]); igt_assert_lt(0, drmModeAtomicAddProperty(req, plane->drm_plane->plane_id, plane->props[i], plane->values[i])); } } /* * Properties that can be changed through legacy SetProperty: * - Obviously not the XYWH SRC/CRTC coordinates. * - Not CRTC_ID or FENCE_ID, done through SetPlane. * - Can't set IN_FENCE_FD, that would be silly. * * Theoretically the above can all be set through the legacy path * with the atomic cap set, but that's not how our legacy plane * commit behaves, so blacklist it by default. */ #define LEGACY_PLANE_COMMIT_MASK \ (((1ULL << IGT_NUM_PLANE_PROPS) - 1) & \ ~(IGT_PLANE_COORD_CHANGED_MASK | \ (1ULL << IGT_PLANE_FB_ID) | \ (1ULL << IGT_PLANE_CRTC_ID) | \ (1ULL << IGT_PLANE_IN_FENCE_FD))) /* * Commit position and fb changes to a DRM plane via the SetPlane ioctl; if the * DRM call to program the plane fails, we'll either fail immediately (for * tests that expect the commit to succeed) or return the failure code (for * tests that expect a specific error code). */ static int igt_drm_plane_commit(igt_plane_t *plane, igt_pipe_t *pipe, bool fail_on_error) { igt_display_t *display = pipe->display; uint32_t fb_id, crtc_id; int ret, i; uint32_t src_x; uint32_t src_y; uint32_t src_w; uint32_t src_h; int32_t crtc_x; int32_t crtc_y; uint32_t crtc_w; uint32_t crtc_h; uint64_t changed_mask; bool setplane = igt_plane_is_prop_changed(plane, IGT_PLANE_FB_ID) || plane->changed & IGT_PLANE_COORD_CHANGED_MASK; igt_assert(plane->drm_plane); fb_id = igt_plane_get_fb_id(plane); crtc_id = pipe->crtc_id; if (setplane && fb_id == 0) { LOG(display, "SetPlane pipe %s, plane %d, disabling\n", kmstest_pipe_name(pipe->pipe), plane->index); ret = drmModeSetPlane(display->drm_fd, plane->drm_plane->plane_id, crtc_id, fb_id, 0, /* flags */ 0, 0, /* crtc_x, crtc_y */ 0, 0, /* crtc_w, crtc_h */ IGT_FIXED(0,0), /* src_x */ IGT_FIXED(0,0), /* src_y */ IGT_FIXED(0,0), /* src_w */ IGT_FIXED(0,0) /* src_h */); CHECK_RETURN(ret, fail_on_error); } else if (setplane) { src_x = plane->values[IGT_PLANE_SRC_X]; src_y = plane->values[IGT_PLANE_SRC_Y]; src_w = plane->values[IGT_PLANE_SRC_W]; src_h = plane->values[IGT_PLANE_SRC_H]; crtc_x = plane->values[IGT_PLANE_CRTC_X]; crtc_y = plane->values[IGT_PLANE_CRTC_Y]; crtc_w = plane->values[IGT_PLANE_CRTC_W]; crtc_h = plane->values[IGT_PLANE_CRTC_H]; LOG(display, "SetPlane %s.%d, fb %u, src = (%d, %d) " "%ux%u dst = (%u, %u) %ux%u\n", kmstest_pipe_name(pipe->pipe), plane->index, fb_id, src_x >> 16, src_y >> 16, src_w >> 16, src_h >> 16, crtc_x, crtc_y, crtc_w, crtc_h); ret = drmModeSetPlane(display->drm_fd, plane->drm_plane->plane_id, crtc_id, fb_id, 0, /* flags */ crtc_x, crtc_y, crtc_w, crtc_h, src_x, src_y, src_w, src_h); CHECK_RETURN(ret, fail_on_error); } changed_mask = plane->changed & LEGACY_PLANE_COMMIT_MASK; for (i = 0; i < IGT_NUM_PLANE_PROPS; i++) { if (!(changed_mask & (1 << i))) continue; LOG(display, "SetProp plane %s.%d \"%s\" to 0x%"PRIx64"/%"PRIi64"\n", kmstest_pipe_name(pipe->pipe), plane->index, igt_plane_prop_names[i], plane->values[i], plane->values[i]); igt_assert(plane->props[i]); ret = igt_plane_set_property(plane, plane->props[i], plane->values[i]); CHECK_RETURN(ret, fail_on_error); } return 0; } /* * Commit position and fb changes to a cursor via legacy ioctl's. If commit * fails, we'll either fail immediately (for tests that expect the commit to * succeed) or return the failure code (for tests that expect a specific error * code). */ static int igt_cursor_commit_legacy(igt_plane_t *cursor, igt_pipe_t *pipe, bool fail_on_error) { igt_display_t *display = pipe->display; uint32_t crtc_id = pipe->crtc_id; int ret; if (igt_plane_is_prop_changed(cursor, IGT_PLANE_FB_ID)) { if (cursor->gem_handle) LOG(display, "SetCursor pipe %s, fb %u %dx%d\n", kmstest_pipe_name(pipe->pipe), cursor->gem_handle, (unsigned)cursor->values[IGT_PLANE_CRTC_W], (unsigned)cursor->values[IGT_PLANE_CRTC_H]); else LOG(display, "SetCursor pipe %s, disabling\n", kmstest_pipe_name(pipe->pipe)); ret = drmModeSetCursor(display->drm_fd, crtc_id, cursor->gem_handle, cursor->values[IGT_PLANE_CRTC_W], cursor->values[IGT_PLANE_CRTC_H]); CHECK_RETURN(ret, fail_on_error); } if (igt_plane_is_prop_changed(cursor, IGT_PLANE_CRTC_X) || igt_plane_is_prop_changed(cursor, IGT_PLANE_CRTC_Y)) { int x = cursor->values[IGT_PLANE_CRTC_X]; int y = cursor->values[IGT_PLANE_CRTC_Y]; LOG(display, "MoveCursor pipe %s, (%d, %d)\n", kmstest_pipe_name(pipe->pipe), x, y); ret = drmModeMoveCursor(display->drm_fd, crtc_id, x, y); CHECK_RETURN(ret, fail_on_error); } return 0; } /* * Commit position and fb changes to a primary plane via the legacy interface * (setmode). */ static int igt_primary_plane_commit_legacy(igt_plane_t *primary, igt_pipe_t *pipe, bool fail_on_error) { struct igt_display *display = primary->pipe->display; igt_output_t *output = igt_pipe_get_output(pipe); drmModeModeInfo *mode; uint32_t fb_id, crtc_id; int ret; /* Primary planes can't be windowed when using a legacy commit */ igt_assert((primary->values[IGT_PLANE_CRTC_X] == 0 && primary->values[IGT_PLANE_CRTC_Y] == 0)); /* nor rotated */ if (!pipe->display->first_commit) igt_assert(!igt_plane_is_prop_changed(primary, IGT_PLANE_ROTATION)); if (!igt_plane_is_prop_changed(primary, IGT_PLANE_FB_ID) && !(primary->changed & IGT_PLANE_COORD_CHANGED_MASK) && !igt_pipe_obj_is_prop_changed(primary->pipe, IGT_CRTC_MODE_ID)) return 0; crtc_id = pipe->crtc_id; fb_id = output ? igt_plane_get_fb_id(primary) : 0; if (fb_id) mode = igt_output_get_mode(output); else mode = NULL; if (fb_id) { uint32_t src_x = primary->values[IGT_PLANE_SRC_X] >> 16; uint32_t src_y = primary->values[IGT_PLANE_SRC_Y] >> 16; LOG(display, "%s: SetCrtc pipe %s, fb %u, src (%d, %d), " "mode %dx%d\n", igt_output_name(output), kmstest_pipe_name(pipe->pipe), fb_id, src_x, src_y, mode->hdisplay, mode->vdisplay); ret = drmModeSetCrtc(display->drm_fd, crtc_id, fb_id, src_x, src_y, &output->id, 1, mode); } else { LOG(display, "SetCrtc pipe %s, disabling\n", kmstest_pipe_name(pipe->pipe)); ret = drmModeSetCrtc(display->drm_fd, crtc_id, fb_id, 0, 0, /* x, y */ NULL, /* connectors */ 0, /* n_connectors */ NULL /* mode */); } CHECK_RETURN(ret, fail_on_error); return 0; } static int igt_plane_fixup_rotation(igt_plane_t *plane, igt_pipe_t *pipe) { int ret; if (!igt_plane_has_prop(plane, IGT_PLANE_ROTATION)) return 0; LOG(pipe->display, "Fixing up initial rotation pipe %s, plane %d\n", kmstest_pipe_name(pipe->pipe), plane->index); /* First try the easy case, can we change rotation without problems? */ ret = igt_plane_set_property(plane, plane->props[IGT_PLANE_ROTATION], plane->values[IGT_PLANE_ROTATION]); if (!ret) return 0; /* Disable the plane, while we tinker with rotation */ ret = drmModeSetPlane(pipe->display->drm_fd, plane->drm_plane->plane_id, pipe->crtc_id, 0, /* fb_id */ 0, /* flags */ 0, 0, 0, 0, /* crtc_x, crtc_y, crtc_w, crtc_h */ IGT_FIXED(0,0), IGT_FIXED(0,0), /* src_x, src_y */ IGT_FIXED(0,0), IGT_FIXED(0,0)); /* src_w, src_h */ if (ret && plane->type != DRM_PLANE_TYPE_PRIMARY) return ret; /* For primary plane, fall back to disabling the crtc. */ if (ret) { ret = drmModeSetCrtc(pipe->display->drm_fd, pipe->crtc_id, 0, 0, 0, NULL, 0, NULL); if (ret) return ret; } /* and finally, set rotation property. */ return igt_plane_set_property(plane, plane->props[IGT_PLANE_ROTATION], plane->values[IGT_PLANE_ROTATION]); } /* * Commit position and fb changes to a plane. The value of @s will determine * which API is used to do the programming. */ static int igt_plane_commit(igt_plane_t *plane, igt_pipe_t *pipe, enum igt_commit_style s, bool fail_on_error) { if (pipe->display->first_commit || (s == COMMIT_UNIVERSAL && igt_plane_is_prop_changed(plane, IGT_PLANE_ROTATION))) { int ret; ret = igt_plane_fixup_rotation(plane, pipe); CHECK_RETURN(ret, fail_on_error); } if (plane->type == DRM_PLANE_TYPE_CURSOR && s == COMMIT_LEGACY) { return igt_cursor_commit_legacy(plane, pipe, fail_on_error); } else if (plane->type == DRM_PLANE_TYPE_PRIMARY && s == COMMIT_LEGACY) { return igt_primary_plane_commit_legacy(plane, pipe, fail_on_error); } else { return igt_drm_plane_commit(plane, pipe, fail_on_error); } } static bool is_atomic_prop(enum igt_atomic_crtc_properties prop) { if (prop == IGT_CRTC_MODE_ID || prop == IGT_CRTC_ACTIVE || prop == IGT_CRTC_OUT_FENCE_PTR) return true; return false; } /* * Commit all plane changes to an output. Note that if @s is COMMIT_LEGACY, * enabling/disabling the primary plane will also enable/disable the CRTC. * * If @fail_on_error is true, any failure to commit plane state will lead * to subtest failure in the specific function where the failure occurs. * Otherwise, the first error code encountered will be returned and no * further programming will take place, which may result in some changes * taking effect and others not taking effect. */ static int igt_pipe_commit(igt_pipe_t *pipe, enum igt_commit_style s, bool fail_on_error) { int i; int ret; for (i = 0; i < IGT_NUM_CRTC_PROPS; i++) if (igt_pipe_obj_is_prop_changed(pipe, i) && !is_atomic_prop(i)) { igt_assert(pipe->props[i]); ret = drmModeObjectSetProperty(pipe->display->drm_fd, pipe->crtc_id, DRM_MODE_OBJECT_CRTC, pipe->props[i], pipe->values[i]); CHECK_RETURN(ret, fail_on_error); } for (i = 0; i < pipe->n_planes; i++) { igt_plane_t *plane = &pipe->planes[i]; /* skip planes that are handled by another pipe */ if (plane->ref->pipe != pipe) continue; ret = igt_plane_commit(plane, pipe, s, fail_on_error); CHECK_RETURN(ret, fail_on_error); } return 0; } static int igt_output_commit(igt_output_t *output, enum igt_commit_style s, bool fail_on_error) { int i, ret; for (i = 0; i < IGT_NUM_CONNECTOR_PROPS; i++) { if (!igt_output_is_prop_changed(output, i)) continue; /* CRTC_ID is set by calling drmModeSetCrtc in the legacy path. */ if (i == IGT_CONNECTOR_CRTC_ID) continue; igt_assert(output->props[i]); if (s == COMMIT_LEGACY) ret = drmModeConnectorSetProperty(output->display->drm_fd, output->id, output->props[i], output->values[i]); else ret = drmModeObjectSetProperty(output->display->drm_fd, output->id, DRM_MODE_OBJECT_CONNECTOR, output->props[i], output->values[i]); CHECK_RETURN(ret, fail_on_error); } return 0; } static uint64_t igt_mode_object_get_prop(igt_display_t *display, uint32_t object_type, uint32_t object_id, uint32_t prop) { drmModeObjectPropertiesPtr proplist; bool found = false; int i; uint64_t ret; proplist = drmModeObjectGetProperties(display->drm_fd, object_id, object_type); for (i = 0; i < proplist->count_props; i++) { if (proplist->props[i] != prop) continue; found = true; break; } igt_assert(found); ret = proplist->prop_values[i]; drmModeFreeObjectProperties(proplist); return ret; } /** * igt_plane_get_prop: * @plane: Target plane. * @prop: Property to check. * * Return current value on a plane for a given property. * * Returns: The value the property is set to, if this * is a blob, the blob id is returned. This can be passed * to drmModeGetPropertyBlob() to get the contents of the blob. */ uint64_t igt_plane_get_prop(igt_plane_t *plane, enum igt_atomic_plane_properties prop) { igt_assert(igt_plane_has_prop(plane, prop)); return igt_mode_object_get_prop(plane->pipe->display, DRM_MODE_OBJECT_PLANE, plane->drm_plane->plane_id, plane->props[prop]); } static bool igt_mode_object_get_prop_enum_value(int drm_fd, uint32_t id, const char *str, uint64_t *val) { drmModePropertyPtr prop = drmModeGetProperty(drm_fd, id); int i; igt_assert(id); igt_assert(prop); for (i = 0; i < prop->count_enums; i++) if (!strcmp(str, prop->enums[i].name)) { *val = prop->enums[i].value; drmModeFreeProperty(prop); return true; } return false; } bool igt_plane_try_prop_enum(igt_plane_t *plane, enum igt_atomic_plane_properties prop, const char *val) { igt_display_t *display = plane->pipe->display; uint64_t uval; igt_assert(plane->props[prop]); if (!igt_mode_object_get_prop_enum_value(display->drm_fd, plane->props[prop], val, &uval)) return false; igt_plane_set_prop_value(plane, prop, uval); return true; } void igt_plane_set_prop_enum(igt_plane_t *plane, enum igt_atomic_plane_properties prop, const char *val) { igt_assert(igt_plane_try_prop_enum(plane, prop, val)); } /** * igt_plane_replace_prop_blob: * @plane: plane to set property on. * @prop: property for which the blob will be replaced. * @ptr: Pointer to contents for the property. * @length: Length of contents. * * This function will destroy the old property blob for the given property, * and will create a new property blob with the values passed to this function. * * The new property blob will be committed when you call igt_display_commit(), * igt_display_commit2() or igt_display_commit_atomic(). */ void igt_plane_replace_prop_blob(igt_plane_t *plane, enum igt_atomic_plane_properties prop, const void *ptr, size_t length) { igt_display_t *display = plane->pipe->display; uint64_t *blob = &plane->values[prop]; uint32_t blob_id = 0; if (*blob != 0) igt_assert(drmModeDestroyPropertyBlob(display->drm_fd, *blob) == 0); if (length > 0) igt_assert(drmModeCreatePropertyBlob(display->drm_fd, ptr, length, &blob_id) == 0); *blob = blob_id; igt_plane_set_prop_changed(plane, prop); } /** * igt_output_get_prop: * @output: Target output. * @prop: Property to return. * * Return current value on an output for a given property. * * Returns: The value the property is set to, if this * is a blob, the blob id is returned. This can be passed * to drmModeGetPropertyBlob() to get the contents of the blob. */ uint64_t igt_output_get_prop(igt_output_t *output, enum igt_atomic_connector_properties prop) { igt_assert(igt_output_has_prop(output, prop)); return igt_mode_object_get_prop(output->display, DRM_MODE_OBJECT_CONNECTOR, output->id, output->props[prop]); } bool igt_output_try_prop_enum(igt_output_t *output, enum igt_atomic_connector_properties prop, const char *val) { igt_display_t *display = output->display; uint64_t uval; igt_assert(output->props[prop]); if (!igt_mode_object_get_prop_enum_value(display->drm_fd, output->props[prop], val, &uval)) return false; igt_output_set_prop_value(output, prop, uval); return true; } void igt_output_set_prop_enum(igt_output_t *output, enum igt_atomic_connector_properties prop, const char *val) { igt_assert(igt_output_try_prop_enum(output, prop, val)); } /** * igt_output_replace_prop_blob: * @output: output to set property on. * @prop: property for which the blob will be replaced. * @ptr: Pointer to contents for the property. * @length: Length of contents. * * This function will destroy the old property blob for the given property, * and will create a new property blob with the values passed to this function. * * The new property blob will be committed when you call igt_display_commit(), * igt_display_commit2() or igt_display_commit_atomic(). */ void igt_output_replace_prop_blob(igt_output_t *output, enum igt_atomic_connector_properties prop, const void *ptr, size_t length) { igt_display_t *display = output->display; uint64_t *blob = &output->values[prop]; uint32_t blob_id = 0; if (*blob != 0) igt_assert(drmModeDestroyPropertyBlob(display->drm_fd, *blob) == 0); if (length > 0) igt_assert(drmModeCreatePropertyBlob(display->drm_fd, ptr, length, &blob_id) == 0); *blob = blob_id; igt_output_set_prop_changed(output, prop); } /** * igt_pipe_obj_get_prop: * @pipe: Target pipe. * @prop: Property to return. * * Return current value on a pipe for a given property. * * Returns: The value the property is set to, if this * is a blob, the blob id is returned. This can be passed * to drmModeGetPropertyBlob() to get the contents of the blob. */ uint64_t igt_pipe_obj_get_prop(igt_pipe_t *pipe, enum igt_atomic_crtc_properties prop) { igt_assert(igt_pipe_obj_has_prop(pipe, prop)); return igt_mode_object_get_prop(pipe->display, DRM_MODE_OBJECT_CRTC, pipe->crtc_id, pipe->props[prop]); } bool igt_pipe_obj_try_prop_enum(igt_pipe_t *pipe_obj, enum igt_atomic_crtc_properties prop, const char *val) { igt_display_t *display = pipe_obj->display; uint64_t uval; igt_assert(pipe_obj->props[prop]); if (!igt_mode_object_get_prop_enum_value(display->drm_fd, pipe_obj->props[prop], val, &uval)) return false; igt_pipe_obj_set_prop_value(pipe_obj, prop, uval); return true; } void igt_pipe_obj_set_prop_enum(igt_pipe_t *pipe_obj, enum igt_atomic_crtc_properties prop, const char *val) { igt_assert(igt_pipe_obj_try_prop_enum(pipe_obj, prop, val)); } /** * igt_pipe_obj_replace_prop_blob: * @pipe: pipe to set property on. * @prop: property for which the blob will be replaced. * @ptr: Pointer to contents for the property. * @length: Length of contents. * * This function will destroy the old property blob for the given property, * and will create a new property blob with the values passed to this function. * * The new property blob will be committed when you call igt_display_commit(), * igt_display_commit2() or igt_display_commit_atomic(). * * Please use igt_output_override_mode() if you want to set #IGT_CRTC_MODE_ID, * it works better with legacy commit. */ void igt_pipe_obj_replace_prop_blob(igt_pipe_t *pipe, enum igt_atomic_crtc_properties prop, const void *ptr, size_t length) { igt_display_t *display = pipe->display; uint64_t *blob = &pipe->values[prop]; uint32_t blob_id = 0; if (*blob != 0) igt_assert(drmModeDestroyPropertyBlob(display->drm_fd, *blob) == 0); if (length > 0) igt_assert(drmModeCreatePropertyBlob(display->drm_fd, ptr, length, &blob_id) == 0); *blob = blob_id; igt_pipe_obj_set_prop_changed(pipe, prop); } /* * Add crtc property changes to the atomic property set */ static void igt_atomic_prepare_crtc_commit(igt_pipe_t *pipe_obj, drmModeAtomicReq *req) { int i; for (i = 0; i < IGT_NUM_CRTC_PROPS; i++) { if (!igt_pipe_obj_is_prop_changed(pipe_obj, i)) continue; igt_debug("Pipe %s: Setting property \"%s\" to 0x%"PRIx64"/%"PRIi64"\n", kmstest_pipe_name(pipe_obj->pipe), igt_crtc_prop_names[i], pipe_obj->values[i], pipe_obj->values[i]); igt_assert_lt(0, drmModeAtomicAddProperty(req, pipe_obj->crtc_id, pipe_obj->props[i], pipe_obj->values[i])); } if (pipe_obj->out_fence_fd != -1) { close(pipe_obj->out_fence_fd); pipe_obj->out_fence_fd = -1; } } /* * Add connector property changes to the atomic property set */ static void igt_atomic_prepare_connector_commit(igt_output_t *output, drmModeAtomicReq *req) { int i; for (i = 0; i < IGT_NUM_CONNECTOR_PROPS; i++) { if (!igt_output_is_prop_changed(output, i)) continue; /* it's an error to try an unsupported feature */ igt_assert(output->props[i]); igt_debug("%s: Setting property \"%s\" to 0x%"PRIx64"/%"PRIi64"\n", igt_output_name(output), igt_connector_prop_names[i], output->values[i], output->values[i]); igt_assert_lt(0, drmModeAtomicAddProperty(req, output->config.connector->connector_id, output->props[i], output->values[i])); } } /* * Commit all the changes of all the planes,crtcs, connectors * atomically using drmModeAtomicCommit() */ static int igt_atomic_commit(igt_display_t *display, uint32_t flags, void *user_data) { int ret = 0, i; enum pipe pipe; drmModeAtomicReq *req; igt_output_t *output; if (display->is_atomic != 1) return -1; req = drmModeAtomicAlloc(); drmModeAtomicSetCursor(req, 0); for_each_pipe(display, pipe) { igt_pipe_t *pipe_obj = &display->pipes[pipe]; igt_plane_t *plane; /* * Add CRTC Properties to the property set */ if (pipe_obj->changed) igt_atomic_prepare_crtc_commit(pipe_obj, req); for_each_plane_on_pipe(display, pipe, plane) { /* skip planes that are handled by another pipe */ if (plane->ref->pipe != pipe_obj) continue; if (plane->changed) igt_atomic_prepare_plane_commit(plane, pipe_obj, req); } } for (i = 0; i < display->n_outputs; i++) { output = &display->outputs[i]; if (!output->config.connector || !output->changed) continue; LOG(display, "%s: preparing atomic, pipe: %s\n", igt_output_name(output), kmstest_pipe_name(output->config.pipe)); igt_atomic_prepare_connector_commit(output, req); } ret = drmModeAtomicCommit(display->drm_fd, req, flags, user_data); drmModeAtomicFree(req); return ret; } static void display_commit_changed(igt_display_t *display, enum igt_commit_style s) { int i; enum pipe pipe; for_each_pipe(display, pipe) { igt_pipe_t *pipe_obj = &display->pipes[pipe]; igt_plane_t *plane; if (s == COMMIT_ATOMIC) { if (igt_pipe_obj_is_prop_changed(pipe_obj, IGT_CRTC_OUT_FENCE_PTR)) igt_assert(pipe_obj->out_fence_fd >= 0); pipe_obj->values[IGT_CRTC_OUT_FENCE_PTR] = 0; pipe_obj->changed = 0; } else { for (i = 0; i < IGT_NUM_CRTC_PROPS; i++) if (!is_atomic_prop(i)) igt_pipe_obj_clear_prop_changed(pipe_obj, i); if (s != COMMIT_UNIVERSAL) { igt_pipe_obj_clear_prop_changed(pipe_obj, IGT_CRTC_MODE_ID); igt_pipe_obj_clear_prop_changed(pipe_obj, IGT_CRTC_ACTIVE); } } for_each_plane_on_pipe(display, pipe, plane) { if (s == COMMIT_ATOMIC) { int fd; plane->changed = 0; fd = plane->values[IGT_PLANE_IN_FENCE_FD]; if (fd != -1) close(fd); /* reset fence_fd to prevent it from being set for the next commit */ plane->values[IGT_PLANE_IN_FENCE_FD] = -1; } else { plane->changed &= ~IGT_PLANE_COORD_CHANGED_MASK; igt_plane_clear_prop_changed(plane, IGT_PLANE_CRTC_ID); igt_plane_clear_prop_changed(plane, IGT_PLANE_FB_ID); if (s != COMMIT_LEGACY || !(plane->type == DRM_PLANE_TYPE_PRIMARY || plane->type == DRM_PLANE_TYPE_CURSOR)) plane->changed &= ~LEGACY_PLANE_COMMIT_MASK; if (display->first_commit) igt_plane_clear_prop_changed(plane, IGT_PLANE_ROTATION); } } } for (i = 0; i < display->n_outputs; i++) { igt_output_t *output = &display->outputs[i]; if (s != COMMIT_UNIVERSAL) output->changed = 0; else /* no modeset in universal commit, no change to crtc. */ output->changed &= 1 << IGT_CONNECTOR_CRTC_ID; } if (display->first_commit) { igt_reset_fifo_underrun_reporting(display->drm_fd); igt_display_drop_events(display); display->first_commit = false; } } /* * Commit all plane changes across all outputs of the display. * * If @fail_on_error is true, any failure to commit plane state will lead * to subtest failure in the specific function where the failure occurs. * Otherwise, the first error code encountered will be returned and no * further programming will take place, which may result in some changes * taking effect and others not taking effect. */ static int do_display_commit(igt_display_t *display, enum igt_commit_style s, bool fail_on_error) { int i, ret = 0; enum pipe pipe; LOG_INDENT(display, "commit"); /* someone managed to bypass igt_display_require, catch them */ assert(display->n_pipes && display->n_outputs); igt_display_refresh(display); if (s == COMMIT_ATOMIC) { ret = igt_atomic_commit(display, DRM_MODE_ATOMIC_ALLOW_MODESET, NULL); } else { for_each_pipe(display, pipe) { igt_pipe_t *pipe_obj = &display->pipes[pipe]; ret = igt_pipe_commit(pipe_obj, s, fail_on_error); if (ret) break; } for (i = 0; !ret && i < display->n_outputs; i++) ret = igt_output_commit(&display->outputs[i], s, fail_on_error); } LOG_UNINDENT(display); CHECK_RETURN(ret, fail_on_error); display_commit_changed(display, s); igt_debug_wait_for_keypress("modeset"); return 0; } /** * igt_display_try_commit_atomic: * @display: #igt_display_t to commit. * @flags: Flags passed to drmModeAtomicCommit. * @user_data: User defined pointer passed to drmModeAtomicCommit. * * This function is similar to #igt_display_try_commit2, but is * used when you want to pass different flags to the actual commit. * * Useful flags can be DRM_MODE_ATOMIC_ALLOW_MODESET, * DRM_MODE_ATOMIC_NONBLOCK, DRM_MODE_PAGE_FLIP_EVENT, * or DRM_MODE_ATOMIC_TEST_ONLY. * * @user_data is returned in the event if you pass * DRM_MODE_PAGE_FLIP_EVENT to @flags. * * This function will return an error if commit fails, instead of * aborting the test. */ int igt_display_try_commit_atomic(igt_display_t *display, uint32_t flags, void *user_data) { int ret; /* someone managed to bypass igt_display_require, catch them */ assert(display->n_pipes && display->n_outputs); LOG_INDENT(display, "commit"); igt_display_refresh(display); ret = igt_atomic_commit(display, flags, user_data); LOG_UNINDENT(display); if (ret || (flags & DRM_MODE_ATOMIC_TEST_ONLY)) return ret; if (display->first_commit) igt_fail_on_f(flags & (DRM_MODE_PAGE_FLIP_EVENT | DRM_MODE_ATOMIC_NONBLOCK), "First commit has to drop all stale events\n"); display_commit_changed(display, COMMIT_ATOMIC); igt_debug_wait_for_keypress("modeset"); return 0; } /** * igt_display_commit_atomic: * @display: #igt_display_t to commit. * @flags: Flags passed to drmModeAtomicCommit. * @user_data: User defined pointer passed to drmModeAtomicCommit. * * This function is similar to #igt_display_commit2, but is * used when you want to pass different flags to the actual commit. * * Useful flags can be DRM_MODE_ATOMIC_ALLOW_MODESET, * DRM_MODE_ATOMIC_NONBLOCK, DRM_MODE_PAGE_FLIP_EVENT, * or DRM_MODE_ATOMIC_TEST_ONLY. * * @user_data is returned in the event if you pass * DRM_MODE_PAGE_FLIP_EVENT to @flags. * * This function will abort the test if commit fails. */ void igt_display_commit_atomic(igt_display_t *display, uint32_t flags, void *user_data) { int ret = igt_display_try_commit_atomic(display, flags, user_data); igt_assert_eq(ret, 0); } /** * igt_display_commit2: * @display: DRM device handle * @s: Commit style * * Commits framebuffer and positioning changes to all planes of each display * pipe, using a specific API to perform the programming. This function should * be used to exercise a specific driver programming API; igt_display_commit * should be used instead if the API used is unimportant to the test being run. * * This function should only be used to commit changes that are expected to * succeed, since any failure during the commit process will cause the IGT * subtest to fail. To commit changes that are expected to fail, use * @igt_try_display_commit2 instead. * * Returns: 0 upon success. This function will never return upon failure * since igt_fail() at lower levels will longjmp out of it. */ int igt_display_commit2(igt_display_t *display, enum igt_commit_style s) { do_display_commit(display, s, true); return 0; } /** * igt_display_try_commit2: * @display: DRM device handle * @s: Commit style * * Attempts to commit framebuffer and positioning changes to all planes of each * display pipe. This function should be used to commit changes that are * expected to fail, so that the error code can be checked for correctness. * For changes that are expected to succeed, use @igt_display_commit instead. * * Note that in non-atomic commit styles, no display programming will be * performed after the first failure is encountered, so only some of the * operations requested by a test may have been completed. Tests that catch * errors returned by this function should take care to restore the display to * a sane state after a failure is detected. * * Returns: 0 upon success, otherwise the error code of the first error * encountered. */ int igt_display_try_commit2(igt_display_t *display, enum igt_commit_style s) { return do_display_commit(display, s, false); } /** * igt_display_commit: * @display: DRM device handle * * Commits framebuffer and positioning changes to all planes of each display * pipe. * * Returns: 0 upon success. This function will never return upon failure * since igt_fail() at lower levels will longjmp out of it. */ int igt_display_commit(igt_display_t *display) { return igt_display_commit2(display, COMMIT_LEGACY); } /** * igt_display_drop_events: * @display: DRM device handle * * Nonblockingly reads all current events and drops them, for highest * reliablility, call igt_display_commit2() first to flush all outstanding * events. * * This will be called on the first commit after igt_display_reset() too, * to make sure any stale events are flushed. * * Returns: Number of dropped events. */ int igt_display_drop_events(igt_display_t *display) { int ret = 0; /* Clear all events from drm fd. */ struct pollfd pfd = { .fd = display->drm_fd, .events = POLLIN }; while (poll(&pfd, 1, 0) > 0) { struct drm_event *ev; char buf[4096]; ssize_t retval; retval = read(display->drm_fd, &buf, sizeof(buf)); igt_assert_lt(0, retval); for (int i = 0; i < retval; i += ev->length) { ev = (struct drm_event *)&buf[i]; igt_info("Dropping event type %u length %u\n", ev->type, ev->length); igt_assert(ev->length + i <= sizeof(buf)); ret++; } } return ret; } /** * igt_output_name: * @output: Target output * * Returns: String representing a connector's name, e.g. "DP-1". */ const char *igt_output_name(igt_output_t *output) { return output->name; } /** * igt_output_get_mode: * @output: Target output * * Get the current mode of the given connector * * Returns: A #drmModeModeInfo struct representing the current mode */ drmModeModeInfo *igt_output_get_mode(igt_output_t *output) { if (output->use_override_mode) return &output->override_mode; else return &output->config.default_mode; } /** * igt_output_override_mode: * @output: Output of which the mode will be overridden * @mode: New mode, or NULL to disable override. * * Overrides the output's mode with @mode, so that it is used instead of the * mode obtained with get connectors. Note that the mode is used without * checking if the output supports it, so this might lead to unexpected results. */ void igt_output_override_mode(igt_output_t *output, const drmModeModeInfo *mode) { igt_pipe_t *pipe = igt_output_get_driving_pipe(output); if (mode) output->override_mode = *mode; output->use_override_mode = !!mode; if (pipe) { if (output->display->is_atomic) igt_pipe_obj_replace_prop_blob(pipe, IGT_CRTC_MODE_ID, igt_output_get_mode(output), sizeof(*mode)); else igt_pipe_obj_set_prop_changed(pipe, IGT_CRTC_MODE_ID); } } /* * igt_output_set_pipe: * @output: Target output for which the pipe is being set to * @pipe: Display pipe to set to * * This function sets a @pipe to a specific @output connector by * setting the CRTC_ID property of the @pipe. The pipe * is only activated for all pipes except PIPE_NONE. */ void igt_output_set_pipe(igt_output_t *output, enum pipe pipe) { igt_display_t *display = output->display; igt_pipe_t *old_pipe = NULL, *pipe_obj = NULL;; igt_assert(output->name); if (output->pending_pipe != PIPE_NONE) old_pipe = igt_output_get_driving_pipe(output); if (pipe != PIPE_NONE) pipe_obj = &display->pipes[pipe]; LOG(display, "%s: set_pipe(%s)\n", igt_output_name(output), kmstest_pipe_name(pipe)); output->pending_pipe = pipe; if (old_pipe) { igt_output_t *old_output; old_output = igt_pipe_get_output(old_pipe); if (!old_output) { if (display->is_atomic) igt_pipe_obj_replace_prop_blob(old_pipe, IGT_CRTC_MODE_ID, NULL, 0); else igt_pipe_obj_set_prop_changed(old_pipe, IGT_CRTC_MODE_ID); igt_pipe_obj_set_prop_value(old_pipe, IGT_CRTC_ACTIVE, 0); } } igt_output_set_prop_value(output, IGT_CONNECTOR_CRTC_ID, pipe == PIPE_NONE ? 0 : display->pipes[pipe].crtc_id); igt_output_refresh(output); if (pipe_obj) { if (display->is_atomic) igt_pipe_obj_replace_prop_blob(pipe_obj, IGT_CRTC_MODE_ID, igt_output_get_mode(output), sizeof(drmModeModeInfo)); else igt_pipe_obj_set_prop_changed(pipe_obj, IGT_CRTC_MODE_ID); igt_pipe_obj_set_prop_value(pipe_obj, IGT_CRTC_ACTIVE, 1); } } /* * igt_pipe_refresh: * @display: a pointer to an #igt_display_t structure * @pipe: Pipe to refresh * @force: Should be set to true if mode_blob is no longer considered * to be valid, for example after doing an atomic commit during fork or closing display fd. * * Requests the pipe to be part of the state on next update. * This is useful when state may have been out of sync after * a fork, or we just want to be sure the pipe is included * in the next commit. */ void igt_pipe_refresh(igt_display_t *display, enum pipe pipe, bool force) { igt_pipe_t *pipe_obj = &display->pipes[pipe]; if (force && display->is_atomic) { igt_output_t *output = igt_pipe_get_output(pipe_obj); pipe_obj->values[IGT_CRTC_MODE_ID] = 0; if (output) igt_pipe_obj_replace_prop_blob(pipe_obj, IGT_CRTC_MODE_ID, igt_output_get_mode(output), sizeof(drmModeModeInfo)); } else igt_pipe_obj_set_prop_changed(pipe_obj, IGT_CRTC_MODE_ID); } igt_plane_t *igt_output_get_plane(igt_output_t *output, int plane_idx) { igt_pipe_t *pipe; pipe = igt_output_get_driving_pipe(output); igt_assert(pipe); return igt_pipe_get_plane(pipe, plane_idx); } /** * igt_output_get_plane_type: * @output: Target output * @plane_type: Cursor, primary or an overlay plane * * Finds a valid plane type for the given @output otherwise * the test is skipped if the right combination of @output/@plane_type is not found * * Returns: A #igt_plane_t structure that matches the requested plane type */ igt_plane_t *igt_output_get_plane_type(igt_output_t *output, int plane_type) { igt_pipe_t *pipe; pipe = igt_output_get_driving_pipe(output); igt_assert(pipe); return igt_pipe_get_plane_type(pipe, plane_type); } /** * igt_output_count_plane_type: * @output: Target output * @plane_type: Cursor, primary or an overlay plane * * Counts the number of planes of type @plane_type for the provided @output. * * Returns: The number of planes that match the requested plane type */ int igt_output_count_plane_type(igt_output_t *output, int plane_type) { igt_pipe_t *pipe = igt_output_get_driving_pipe(output); igt_assert(pipe); return igt_pipe_count_plane_type(pipe, plane_type); } /** * igt_output_get_plane_type_index: * @output: Target output * @plane_type: Cursor, primary or an overlay plane * @index: the index of the plane among planes of the same type * * Get the @index th plane of type @plane_type for the provided @output. * * Returns: The @index th plane that matches the requested plane type */ igt_plane_t *igt_output_get_plane_type_index(igt_output_t *output, int plane_type, int index) { igt_pipe_t *pipe = igt_output_get_driving_pipe(output); igt_assert(pipe); return igt_pipe_get_plane_type_index(pipe, plane_type, index); } /** * igt_plane_set_fb: * @plane: Plane * @fb: Framebuffer pointer * * Pairs a given @framebuffer to a @plane * * This function also sets a default size and position for the framebuffer * to avoid crashes on applications that ignore to set these. */ void igt_plane_set_fb(igt_plane_t *plane, struct igt_fb *fb) { igt_pipe_t *pipe = plane->pipe; igt_display_t *display = pipe->display; LOG(display, "%s.%d: plane_set_fb(%d)\n", kmstest_pipe_name(pipe->pipe), plane->index, fb ? fb->fb_id : 0); igt_plane_set_prop_value(plane, IGT_PLANE_CRTC_ID, fb ? pipe->crtc_id : 0); igt_plane_set_prop_value(plane, IGT_PLANE_FB_ID, fb ? fb->fb_id : 0); if (plane->type == DRM_PLANE_TYPE_CURSOR && fb) plane->gem_handle = fb->gem_handle; else plane->gem_handle = 0; /* hack to keep tests working that don't call igt_plane_set_size() */ if (fb) { /* set default plane size as fb size */ igt_plane_set_size(plane, fb->width, fb->height); /* set default src pos/size as fb size */ igt_fb_set_position(fb, plane, 0, 0); igt_fb_set_size(fb, plane, fb->width, fb->height); if (igt_plane_has_prop(plane, IGT_PLANE_COLOR_ENCODING)) igt_plane_set_prop_enum(plane, IGT_PLANE_COLOR_ENCODING, igt_color_encoding_to_str(fb->color_encoding)); if (igt_plane_has_prop(plane, IGT_PLANE_COLOR_RANGE)) igt_plane_set_prop_enum(plane, IGT_PLANE_COLOR_RANGE, igt_color_range_to_str(fb->color_range)); /* Hack to prioritize the plane on the pipe that last set fb */ igt_plane_set_pipe(plane, pipe); } else { igt_plane_set_size(plane, 0, 0); /* set default src pos/size as fb size */ igt_fb_set_position(fb, plane, 0, 0); igt_fb_set_size(fb, plane, 0, 0); } } /** * igt_plane_set_fence_fd: * @plane: plane * @fence_fd: fence fd, disable fence_fd by setting it to -1 * * This function sets a fence fd to enable a commit to wait for some event to * occur before completing. */ void igt_plane_set_fence_fd(igt_plane_t *plane, int fence_fd) { int64_t fd; fd = plane->values[IGT_PLANE_IN_FENCE_FD]; if (fd != -1) close(fd); if (fence_fd != -1) { fd = dup(fence_fd); igt_fail_on(fd == -1); } else fd = -1; igt_plane_set_prop_value(plane, IGT_PLANE_IN_FENCE_FD, fd); } /** * igt_plane_set_pipe: * @plane: Target plane pointer * @pipe: The pipe to assign the plane to * */ void igt_plane_set_pipe(igt_plane_t *plane, igt_pipe_t *pipe) { /* * HACK: Point the global plane back to the local plane. * This is used to help apply the correct atomic state while * we're moving away from the single pipe per plane model. */ plane->ref->ref = plane; plane->ref->pipe = pipe; } /** * igt_plane_set_position: * @plane: Plane pointer for which position is to be set * @x: X coordinate * @y: Y coordinate * * This function sets a new (x,y) position for the given plane. * New position will be committed at plane commit time via drmModeSetPlane(). */ void igt_plane_set_position(igt_plane_t *plane, int x, int y) { igt_pipe_t *pipe = plane->pipe; igt_display_t *display = pipe->display; LOG(display, "%s.%d: plane_set_position(%d,%d)\n", kmstest_pipe_name(pipe->pipe), plane->index, x, y); igt_plane_set_prop_value(plane, IGT_PLANE_CRTC_X, x); igt_plane_set_prop_value(plane, IGT_PLANE_CRTC_Y, y); } /** * igt_plane_set_size: * @plane: plane pointer for which size to be set * @w: width * @h: height * * This function sets width and height for requested plane. * New size will be committed at plane commit time via * drmModeSetPlane(). */ void igt_plane_set_size(igt_plane_t *plane, int w, int h) { igt_pipe_t *pipe = plane->pipe; igt_display_t *display = pipe->display; LOG(display, "%s.%d: plane_set_size (%dx%d)\n", kmstest_pipe_name(pipe->pipe), plane->index, w, h); igt_plane_set_prop_value(plane, IGT_PLANE_CRTC_W, w); igt_plane_set_prop_value(plane, IGT_PLANE_CRTC_H, h); } /** * igt_fb_set_position: * @fb: framebuffer pointer * @plane: plane * @x: X position * @y: Y position * * This function sets position for requested framebuffer as src to plane. * New position will be committed at plane commit time via drmModeSetPlane(). */ void igt_fb_set_position(struct igt_fb *fb, igt_plane_t *plane, uint32_t x, uint32_t y) { igt_pipe_t *pipe = plane->pipe; igt_display_t *display = pipe->display; LOG(display, "%s.%d: fb_set_position(%d,%d)\n", kmstest_pipe_name(pipe->pipe), plane->index, x, y); igt_plane_set_prop_value(plane, IGT_PLANE_SRC_X, IGT_FIXED(x, 0)); igt_plane_set_prop_value(plane, IGT_PLANE_SRC_Y, IGT_FIXED(y, 0)); } /** * igt_fb_set_size: * @fb: framebuffer pointer * @plane: plane * @w: width * @h: height * * This function sets fetch rect size from requested framebuffer as src * to plane. New size will be committed at plane commit time via * drmModeSetPlane(). */ void igt_fb_set_size(struct igt_fb *fb, igt_plane_t *plane, uint32_t w, uint32_t h) { igt_pipe_t *pipe = plane->pipe; igt_display_t *display = pipe->display; LOG(display, "%s.%d: fb_set_size(%dx%d)\n", kmstest_pipe_name(pipe->pipe), plane->index, w, h); igt_plane_set_prop_value(plane, IGT_PLANE_SRC_W, IGT_FIXED(w, 0)); igt_plane_set_prop_value(plane, IGT_PLANE_SRC_H, IGT_FIXED(h, 0)); } static const char *rotation_name(igt_rotation_t rotation) { switch (rotation & IGT_ROTATION_MASK) { case IGT_ROTATION_0: return "0°"; case IGT_ROTATION_90: return "90°"; case IGT_ROTATION_180: return "180°"; case IGT_ROTATION_270: return "270°"; default: igt_assert(0); } } /** * igt_plane_set_rotation: * @plane: Plane pointer for which rotation is to be set * @rotation: Plane rotation value (0, 90, 180, 270) * * This function sets a new rotation for the requested @plane. * New @rotation will be committed at plane commit time via * drmModeSetPlane(). */ void igt_plane_set_rotation(igt_plane_t *plane, igt_rotation_t rotation) { igt_pipe_t *pipe = plane->pipe; igt_display_t *display = pipe->display; LOG(display, "%s.%d: plane_set_rotation(%s)\n", kmstest_pipe_name(pipe->pipe), plane->index, rotation_name(rotation)); igt_plane_set_prop_value(plane, IGT_PLANE_ROTATION, rotation); } /** * igt_pipe_request_out_fence: * @pipe: pipe which out fence will be requested for * * Marks this pipe for requesting an out fence at the next atomic commit * will contain the fd number of the out fence created by KMS. */ void igt_pipe_request_out_fence(igt_pipe_t *pipe) { igt_pipe_obj_set_prop_value(pipe, IGT_CRTC_OUT_FENCE_PTR, (ptrdiff_t)&pipe->out_fence_fd); } /** * igt_wait_for_vblank_count: * @drm_fd: A drm file descriptor * @pipe: Pipe to wait_for_vblank on * @count: Number of vblanks to wait on * * Waits for a given number of vertical blank intervals */ void igt_wait_for_vblank_count(int drm_fd, enum pipe pipe, int count) { drmVBlank wait_vbl; uint32_t pipe_id_flag; memset(&wait_vbl, 0, sizeof(wait_vbl)); pipe_id_flag = kmstest_get_vbl_flag(pipe); wait_vbl.request.type = DRM_VBLANK_RELATIVE; wait_vbl.request.type |= pipe_id_flag; wait_vbl.request.sequence = count; igt_assert(drmWaitVBlank(drm_fd, &wait_vbl) == 0); } /** * igt_wait_for_vblank: * @drm_fd: A drm file descriptor * @pipe: Pipe to wait_for_vblank on * * Waits for 1 vertical blank intervals */ void igt_wait_for_vblank(int drm_fd, enum pipe pipe) { igt_wait_for_vblank_count(drm_fd, pipe, 1); } /** * igt_enable_connectors: * @drm_fd: A drm file descriptor * * Force connectors to be enabled where this is known to work well. Use * #igt_reset_connectors to revert the changes. * * An exit handler is installed to ensure connectors are reset when the test * exits. */ void igt_enable_connectors(int drm_fd) { drmModeRes *res; res = drmModeGetResources(drm_fd); if (!res) return; for (int i = 0; i < res->count_connectors; i++) { drmModeConnector *c; /* Do a probe. This may be the first action after booting */ c = drmModeGetConnector(drm_fd, res->connectors[i]); if (!c) { igt_warn("Could not read connector %u: %m\n", res->connectors[i]); continue; } /* don't attempt to force connectors that are already connected */ if (c->connection == DRM_MODE_CONNECTED) continue; /* just enable VGA for now */ if (c->connector_type == DRM_MODE_CONNECTOR_VGA) { if (!kmstest_force_connector(drm_fd, c, FORCE_CONNECTOR_ON)) igt_info("Unable to force state on %s-%d\n", kmstest_connector_type_str(c->connector_type), c->connector_type_id); } drmModeFreeConnector(c); } } /** * igt_reset_connectors: * * Remove any forced state from the connectors. */ void igt_reset_connectors(void) { /* reset the connectors stored in forced_connectors, avoiding any * functions that are not safe to call in signal handlers */ for (int i = 0; forced_connectors[i]; i++) igt_sysfs_set(forced_connectors_device[i], forced_connectors[i], "detect"); } /** * igt_watch_hotplug: * * Begin monitoring udev for sysfs hotplug events. * * Returns: a udev monitor for detecting hotplugs on */ struct udev_monitor *igt_watch_hotplug(void) { struct udev *udev; struct udev_monitor *mon; int ret, flags, fd; udev = udev_new(); igt_assert(udev != NULL); mon = udev_monitor_new_from_netlink(udev, "udev"); igt_assert(mon != NULL); ret = udev_monitor_filter_add_match_subsystem_devtype(mon, "drm", "drm_minor"); igt_assert_eq(ret, 0); ret = udev_monitor_filter_update(mon); igt_assert_eq(ret, 0); ret = udev_monitor_enable_receiving(mon); igt_assert_eq(ret, 0); /* Set the fd for udev as non blocking */ fd = udev_monitor_get_fd(mon); flags = fcntl(fd, F_GETFL, 0); igt_assert(flags); flags |= O_NONBLOCK; igt_assert_neq(fcntl(fd, F_SETFL, flags), -1); return mon; } static bool event_detected(struct udev_monitor *mon, int timeout_secs, const char *property) { struct udev_device *dev; const char *hotplug_val; struct pollfd fd = { .fd = udev_monitor_get_fd(mon), .events = POLLIN }; bool hotplug_received = false; /* Go through all of the events pending on the udev monitor. Once we * receive a hotplug, we continue going through the rest of the events * so that redundant hotplug events don't change the results of future * checks */ while (!hotplug_received && poll(&fd, 1, timeout_secs * 1000)) { dev = udev_monitor_receive_device(mon); hotplug_val = udev_device_get_property_value(dev, property); if (hotplug_val && atoi(hotplug_val) == 1) hotplug_received = true; udev_device_unref(dev); } return hotplug_received; } /** * igt_hotplug_detected: * @mon: A udev monitor initialized with #igt_watch_hotplug * @timeout_secs: How long to wait for a hotplug event to occur. * * Assert that a hotplug event was received since we last checked the monitor. * * Returns: true if a sysfs hotplug event was received, false if we timed out */ bool igt_hotplug_detected(struct udev_monitor *mon, int timeout_secs) { return event_detected(mon, timeout_secs, "HOTPLUG"); } /** * igt_lease_change_detected: * @mon: A udev monitor initialized with #igt_watch_hotplug * @timeout_secs: How long to wait for a lease change event to occur. * * Assert that a lease change event was received since we last checked the monitor. * * Returns: true if a sysfs lease change event was received, false if we timed out */ bool igt_lease_change_detected(struct udev_monitor *mon, int timeout_secs) { return event_detected(mon, timeout_secs, "LEASE"); } /** * igt_flush_hotplugs: * @mon: A udev monitor initialized with #igt_watch_hotplug * * Get rid of any pending hotplug events */ void igt_flush_hotplugs(struct udev_monitor *mon) { struct udev_device *dev; while ((dev = udev_monitor_receive_device(mon))) udev_device_unref(dev); } /** * igt_cleanup_hotplug: * @mon: A udev monitor initialized with #igt_watch_hotplug * * Cleanup the resources allocated by #igt_watch_hotplug */ void igt_cleanup_hotplug(struct udev_monitor *mon) { struct udev *udev = udev_monitor_get_udev(mon); udev_monitor_unref(mon); mon = NULL; udev_unref(udev); } /** * kmstest_get_vbl_flag: * @pipe_id: Pipe to convert to flag representation. * * Convert a pipe id into the flag representation * expected in DRM while processing DRM_IOCTL_WAIT_VBLANK. */ uint32_t kmstest_get_vbl_flag(uint32_t pipe_id) { if (pipe_id == 0) return 0; else if (pipe_id == 1) return _DRM_VBLANK_SECONDARY; else { uint32_t pipe_flag = pipe_id << 1; igt_assert(!(pipe_flag & ~DRM_VBLANK_HIGH_CRTC_MASK)); return pipe_flag; } } static inline const uint32_t * formats_ptr(const struct drm_format_modifier_blob *blob) { return (const uint32_t *)((const char *)blob + blob->formats_offset); } static inline const struct drm_format_modifier * modifiers_ptr(const struct drm_format_modifier_blob *blob) { return (const struct drm_format_modifier *)((const char *)blob + blob->modifiers_offset); } static int igt_count_plane_format_mod(const struct drm_format_modifier_blob *blob_data) { const struct drm_format_modifier *modifiers; int count = 0; modifiers = modifiers_ptr(blob_data); for (int i = 0; i < blob_data->count_modifiers; i++) count += igt_hweight(modifiers[i].formats); return count; } static void igt_fill_plane_format_mod(igt_display_t *display, igt_plane_t *plane) { const struct drm_format_modifier_blob *blob_data; drmModePropertyBlobPtr blob; uint64_t blob_id; int idx = 0; int count; if (!igt_plane_has_prop(plane, IGT_PLANE_IN_FORMATS)) { drmModePlanePtr p = plane->drm_plane; count = p->count_formats; plane->format_mod_count = count; plane->formats = calloc(count, sizeof(plane->formats[0])); igt_assert(plane->formats); plane->modifiers = calloc(count, sizeof(plane->modifiers[0])); igt_assert(plane->modifiers); /* * We don't know which modifiers are * supported, so we'll assume linear only. */ for (int i = 0; i < count; i++) { plane->formats[i] = p->formats[i]; plane->modifiers[i] = DRM_FORMAT_MOD_LINEAR; } return; } blob_id = igt_plane_get_prop(plane, IGT_PLANE_IN_FORMATS); blob = drmModeGetPropertyBlob(display->drm_fd, blob_id); if (!blob) return; blob_data = (const struct drm_format_modifier_blob *) blob->data; count = igt_count_plane_format_mod(blob_data); if (!count) return; plane->format_mod_count = count; plane->formats = calloc(count, sizeof(plane->formats[0])); igt_assert(plane->formats); plane->modifiers = calloc(count, sizeof(plane->modifiers[0])); igt_assert(plane->modifiers); for (int i = 0; i < blob_data->count_modifiers; i++) { for (int j = 0; j < 64; j++) { const struct drm_format_modifier *modifiers = modifiers_ptr(blob_data); const uint32_t *formats = formats_ptr(blob_data); if (!(modifiers[i].formats & (1ULL << j))) continue; plane->formats[idx] = formats[modifiers[i].offset + j]; plane->modifiers[idx] = modifiers[i].modifier; idx++; igt_assert_lte(idx, plane->format_mod_count); } } igt_assert_eq(idx, plane->format_mod_count); } bool igt_plane_has_format_mod(igt_plane_t *plane, uint32_t format, uint64_t modifier) { int i; for (i = 0; i < plane->format_mod_count; i++) { if (plane->formats[i] == format && plane->modifiers[i] == modifier) return true; } return false; } static int igt_count_display_format_mod(igt_display_t *display) { enum pipe pipe; int count = 0; for_each_pipe(display, pipe) { igt_plane_t *plane; for_each_plane_on_pipe(display, pipe, plane) { count += plane->format_mod_count; } } return count; } static void igt_add_display_format_mod(igt_display_t *display, uint32_t format, uint64_t modifier) { int i; for (i = 0; i < display->format_mod_count; i++) { if (display->formats[i] == format && display->modifiers[i] == modifier) return; } display->formats[i] = format; display->modifiers[i] = modifier; display->format_mod_count++; } static void igt_fill_display_format_mod(igt_display_t *display) { int count = igt_count_display_format_mod(display); enum pipe pipe; if (!count) return; display->formats = calloc(count, sizeof(display->formats[0])); igt_assert(display->formats); display->modifiers = calloc(count, sizeof(display->modifiers[0])); igt_assert(display->modifiers); for_each_pipe(display, pipe) { igt_plane_t *plane; for_each_plane_on_pipe(display, pipe, plane) { for (int i = 0; i < plane->format_mod_count; i++) { igt_add_display_format_mod(display, plane->formats[i], plane->modifiers[i]); igt_assert_lte(display->format_mod_count, count); } } } } bool igt_display_has_format_mod(igt_display_t *display, uint32_t format, uint64_t modifier) { int i; for (i = 0; i < display->format_mod_count; i++) { if (display->formats[i] == format && display->modifiers[i] == modifier) return true; } return false; }