/* * Copyright © 2015 Intel Corporation * Copyright © 2014-2015 Collabora, Ltd. * * 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: * Micah Fedke * Daniel Stone * Pekka Paalanen */ /* * Testcase: testing atomic modesetting API */ #include #include #include #include #include #include #include #include #include "drm.h" #include "ioctl_wrappers.h" #include "drmtest.h" #include "igt.h" #include "igt_aux.h" #ifndef DRM_CLIENT_CAP_ATOMIC #define DRM_CLIENT_CAP_ATOMIC 3 #endif #ifndef DRM_CAP_CURSOR_WIDTH #define DRM_CAP_CURSOR_WIDTH 0x8 #endif #ifndef DRM_CAP_CURSOR_HEIGHT #define DRM_CAP_CURSOR_HEIGHT 0x9 #endif #ifndef DRM_MODE_ATOMIC_TEST_ONLY #define DRM_MODE_ATOMIC_TEST_ONLY 0x0100 #define DRM_MODE_ATOMIC_NONBLOCK 0x0200 #define DRM_MODE_ATOMIC_ALLOW_MODESET 0x0400 struct drm_mode_atomic { __u32 flags; __u32 count_objs; __u64 objs_ptr; __u64 count_props_ptr; __u64 props_ptr; __u64 prop_values_ptr; __u64 reserved; __u64 user_data; }; #endif IGT_TEST_DESCRIPTION("Test atomic modesetting API"); enum kms_atomic_check_relax { ATOMIC_RELAX_NONE = 0, CRTC_RELAX_MODE = (1 << 0), PLANE_RELAX_FB = (1 << 1) }; /** * KMS plane type enum * * KMS plane types are represented by enums, which do not have stable numeric * values, but must be looked up by their string value each time. * * To make the code more simple, we define a plane_type enum which maps to * each KMS enum value. These values must be looked up through the map, and * cannot be passed directly to KMS functions. */ enum plane_type { PLANE_TYPE_PRIMARY = 0, PLANE_TYPE_OVERLAY, PLANE_TYPE_CURSOR, NUM_PLANE_TYPE_PROPS }; static const char *plane_type_prop_names[NUM_PLANE_TYPE_PROPS] = { "Primary", "Overlay", "Cursor" }; enum plane_properties { PLANE_SRC_X = 0, PLANE_SRC_Y, PLANE_SRC_W, PLANE_SRC_H, PLANE_CRTC_X, PLANE_CRTC_Y, PLANE_CRTC_W, PLANE_CRTC_H, PLANE_FB_ID, PLANE_CRTC_ID, PLANE_TYPE, NUM_PLANE_PROPS }; static const char *plane_prop_names[NUM_PLANE_PROPS] = { "SRC_X", "SRC_Y", "SRC_W", "SRC_H", "CRTC_X", "CRTC_Y", "CRTC_W", "CRTC_H", "FB_ID", "CRTC_ID", "type" }; enum crtc_properties { CRTC_MODE_ID = 0, CRTC_ACTIVE, NUM_CRTC_PROPS }; static const char *crtc_prop_names[NUM_CRTC_PROPS] = { "MODE_ID", "ACTIVE" }; enum connector_properties { CONNECTOR_CRTC_ID = 0, NUM_CONNECTOR_PROPS }; static const char *connector_prop_names[NUM_CONNECTOR_PROPS] = { "CRTC_ID" }; struct kms_atomic_blob { uint32_t id; /* 0 if not already allocated */ size_t len; void *data; }; struct kms_atomic_connector_state { struct kms_atomic_state *state; uint32_t obj; uint32_t crtc_id; }; struct kms_atomic_plane_state { struct kms_atomic_state *state; uint32_t obj; enum plane_type type; uint32_t crtc_mask; uint32_t crtc_id; /* 0 to disable */ uint32_t fb_id; /* 0 to disable */ uint32_t src_x, src_y, src_w, src_h; /* 16.16 fixed-point */ uint32_t crtc_x, crtc_y, crtc_w, crtc_h; /* normal integers */ }; struct kms_atomic_crtc_state { struct kms_atomic_state *state; uint32_t obj; int idx; bool active; struct kms_atomic_blob mode; }; struct kms_atomic_state { struct kms_atomic_connector_state *connectors; int num_connectors; struct kms_atomic_crtc_state *crtcs; int num_crtcs; struct kms_atomic_plane_state *planes; int num_planes; struct kms_atomic_desc *desc; }; struct kms_atomic_desc { int fd; uint32_t props_connector[NUM_CONNECTOR_PROPS]; uint32_t props_crtc[NUM_CRTC_PROPS]; uint32_t props_plane[NUM_PLANE_PROPS]; uint64_t props_plane_type[NUM_PLANE_TYPE_PROPS]; }; static uint32_t blob_duplicate(int fd, uint32_t id_orig) { drmModePropertyBlobPtr orig = drmModeGetPropertyBlob(fd, id_orig); uint32_t id_new; igt_assert(orig); do_or_die(drmModeCreatePropertyBlob(fd, orig->data, orig->length, &id_new)); drmModeFreePropertyBlob(orig); return id_new; } #define crtc_set_prop(req, crtc, prop, value) \ igt_assert_lt(0, drmModeAtomicAddProperty(req, crtc->obj, \ crtc->state->desc->props_crtc[prop], \ value)); #define plane_set_prop(req, plane, prop, value) \ igt_assert_lt(0, drmModeAtomicAddProperty(req, plane->obj, \ plane->state->desc->props_plane[prop], \ value)); #define do_atomic_commit(fd, req, flags) \ do_or_die(drmModeAtomicCommit(fd, req, flags, NULL)); #define do_atomic_commit_err(fd, req, flags, err) { \ igt_assert_neq(drmModeAtomicCommit(fd, req, flags, NULL), 0); \ igt_assert_eq(errno, err); \ } #define crtc_commit_atomic(crtc, plane, req, relax) { \ drmModeAtomicSetCursor(req, 0); \ crtc_populate_req(crtc, req); \ plane_populate_req(plane, req); \ do_atomic_commit((crtc)->state->desc->fd, req, 0); \ crtc_check_current_state(crtc, plane, relax); \ plane_check_current_state(plane, relax); \ } #define crtc_commit_atomic_err(crtc, plane, crtc_old, plane_old, req, relax, e) { \ drmModeAtomicSetCursor(req, 0); \ crtc_populate_req(crtc, req); \ plane_populate_req(plane, req); \ do_atomic_commit_err((crtc)->state->desc->fd, req, 0, e); \ crtc_check_current_state(crtc_old, plane_old, relax); \ plane_check_current_state(plane_old, relax); \ } #define plane_commit_atomic(plane, req, relax) { \ drmModeAtomicSetCursor(req, 0); \ plane_populate_req(plane, req); \ do_atomic_commit((plane)->state->desc->fd, req, 0); \ plane_check_current_state(plane, relax); \ } #define plane_commit_atomic_err(plane, plane_old, req, relax, e) { \ drmModeAtomicSetCursor(req, 0); \ plane_populate_req(plane, req); \ do_atomic_commit_err((plane)->state->desc->fd, req, 0, e); \ plane_check_current_state(plane_old, relax); \ } static void connector_get_current_state(struct kms_atomic_connector_state *connector) { drmModeObjectPropertiesPtr props; int i; props = drmModeObjectGetProperties(connector->state->desc->fd, connector->obj, DRM_MODE_OBJECT_CONNECTOR); igt_assert(props); for (i = 0; i < props->count_props; i++) { uint32_t *prop_ids = connector->state->desc->props_connector; if (props->props[i] == prop_ids[CONNECTOR_CRTC_ID]) connector->crtc_id = props->prop_values[i]; } drmModeFreeObjectProperties(props); } #if 0 /* XXX: Checking this repeatedly actually hangs the GPU. I have literally no * idea why. */ static void connector_check_current_state(struct kms_atomic_connector_state *connector) { struct kms_atomic_connector_state connector_kernel; drmModeConnectorPtr legacy; uint32_t crtc_id; legacy = drmModeGetConnectorCurrent(connector->state->desc->fd, connector->obj); igt_assert(legacy); if (legacy->encoder_id) { drmModeEncoderPtr legacy_enc; legacy_enc = drmModeGetEncoder(connector->state->desc->fd, legacy->encoder_id); igt_assert(legacy_enc); crtc_id = legacy_enc->crtc_id; drmModeFreeEncoder(legacy_enc); } else { crtc_id = 0; } igt_assert_eq_u32(crtc_id, connector->crtc_id); memcpy(&connector_kernel, connector, sizeof(connector_kernel)); connector_get_current_state(&connector_kernel); do_or_die(memcmp(&connector_kernel, connector, sizeof(connector_kernel))); drmModeFreeConnector(legacy); } #endif static struct kms_atomic_connector_state * find_connector(struct kms_atomic_state *state, struct kms_atomic_crtc_state *crtc) { int i; for (i = 0; i < state->num_connectors; i++) { struct kms_atomic_connector_state *connector = &state->connectors[i]; if (!connector->obj) continue; if (crtc && connector->crtc_id != crtc->obj) continue; return connector; } return NULL; } static void plane_populate_req(struct kms_atomic_plane_state *plane, drmModeAtomicReq *req) { plane_set_prop(req, plane, PLANE_CRTC_ID, plane->crtc_id); plane_set_prop(req, plane, PLANE_FB_ID, plane->fb_id); plane_set_prop(req, plane, PLANE_SRC_X, plane->src_x); plane_set_prop(req, plane, PLANE_SRC_Y, plane->src_y); plane_set_prop(req, plane, PLANE_SRC_W, plane->src_w); plane_set_prop(req, plane, PLANE_SRC_H, plane->src_h); plane_set_prop(req, plane, PLANE_CRTC_X, plane->crtc_x); plane_set_prop(req, plane, PLANE_CRTC_Y, plane->crtc_y); plane_set_prop(req, plane, PLANE_CRTC_W, plane->crtc_w); plane_set_prop(req, plane, PLANE_CRTC_H, plane->crtc_h); } static void plane_get_current_state(struct kms_atomic_plane_state *plane) { struct kms_atomic_desc *desc = plane->state->desc; drmModeObjectPropertiesPtr props; int i; props = drmModeObjectGetProperties(desc->fd, plane->obj, DRM_MODE_OBJECT_PLANE); igt_assert(props); for (i = 0; i < props->count_props; i++) { uint32_t *prop_ids = desc->props_plane; if (props->props[i] == prop_ids[PLANE_CRTC_ID]) plane->crtc_id = props->prop_values[i]; else if (props->props[i] == prop_ids[PLANE_FB_ID]) plane->fb_id = props->prop_values[i]; else if (props->props[i] == prop_ids[PLANE_CRTC_X]) plane->crtc_x = props->prop_values[i]; else if (props->props[i] == prop_ids[PLANE_CRTC_Y]) plane->crtc_y = props->prop_values[i]; else if (props->props[i] == prop_ids[PLANE_CRTC_W]) plane->crtc_w = props->prop_values[i]; else if (props->props[i] == prop_ids[PLANE_CRTC_H]) plane->crtc_h = props->prop_values[i]; else if (props->props[i] == prop_ids[PLANE_SRC_X]) plane->src_x = props->prop_values[i]; else if (props->props[i] == prop_ids[PLANE_SRC_Y]) plane->src_y = props->prop_values[i]; else if (props->props[i] == prop_ids[PLANE_SRC_W]) plane->src_w = props->prop_values[i]; else if (props->props[i] == prop_ids[PLANE_SRC_H]) plane->src_h = props->prop_values[i]; else if (props->props[i] == prop_ids[PLANE_TYPE]) { int j; for (j = 0; j < ARRAY_SIZE(desc->props_plane_type); j++) { if (props->prop_values[i] == desc->props_plane_type[j]) { plane->type = j; break; } } } } drmModeFreeObjectProperties(props); } static void plane_check_current_state(struct kms_atomic_plane_state *plane, enum kms_atomic_check_relax relax) { drmModePlanePtr legacy; struct kms_atomic_plane_state plane_kernel; legacy = drmModeGetPlane(plane->state->desc->fd, plane->obj); igt_assert(legacy); igt_assert_eq_u32(legacy->crtc_id, plane->crtc_id); if (!(relax & PLANE_RELAX_FB)) igt_assert_eq_u32(legacy->fb_id, plane->fb_id); memcpy(&plane_kernel, plane, sizeof(plane_kernel)); plane_get_current_state(&plane_kernel); /* Legacy cursor ioctls create their own, unknowable, internal * framebuffer which we can't reason about. */ if (relax & PLANE_RELAX_FB) plane_kernel.fb_id = plane->fb_id; do_or_die(memcmp(&plane_kernel, plane, sizeof(plane_kernel))); drmModeFreePlane(legacy); } static void plane_commit_legacy(struct kms_atomic_plane_state *plane, enum kms_atomic_check_relax relax) { do_or_die(drmModeSetPlane(plane->state->desc->fd, plane->obj, plane->crtc_id, plane->fb_id, 0, plane->crtc_x, plane->crtc_y, plane->crtc_w, plane->crtc_h, plane->src_x, plane->src_y, plane->src_w, plane->src_h)); plane_check_current_state(plane, relax); } static struct kms_atomic_plane_state * find_plane(struct kms_atomic_state *state, enum plane_type type, struct kms_atomic_crtc_state *crtc) { int i; for (i = 0; i < state->num_planes; i++) { struct kms_atomic_plane_state *plane = &state->planes[i]; if (!plane->obj) continue; if (type != NUM_PLANE_TYPE_PROPS && plane->type != type) continue; if (crtc && !(plane->crtc_mask & (1 << crtc->idx))) continue; plane_get_current_state(plane); return plane; } return NULL; } static void crtc_populate_req(struct kms_atomic_crtc_state *crtc, drmModeAtomicReq *req) { crtc_set_prop(req, crtc, CRTC_MODE_ID, crtc->mode.id); crtc_set_prop(req, crtc, CRTC_ACTIVE, crtc->active); } static void crtc_get_current_state(struct kms_atomic_crtc_state *crtc) { drmModeObjectPropertiesPtr props; int i; props = drmModeObjectGetProperties(crtc->state->desc->fd, crtc->obj, DRM_MODE_OBJECT_CRTC); igt_assert(props); for (i = 0; i < props->count_props; i++) { uint32_t *prop_ids = crtc->state->desc->props_crtc; if (props->props[i] == prop_ids[CRTC_MODE_ID]) { drmModePropertyBlobPtr blob; crtc->mode.id = props->prop_values[i]; if (!crtc->mode.id) { crtc->mode.len = 0; continue; } blob = drmModeGetPropertyBlob(crtc->state->desc->fd, crtc->mode.id); igt_assert(blob); igt_assert_eq_u32(blob->length, sizeof(struct drm_mode_modeinfo)); if (!crtc->mode.data || memcmp(crtc->mode.data, blob->data, blob->length) != 0) crtc->mode.data = blob->data; crtc->mode.len = blob->length; } else if (props->props[i] == prop_ids[CRTC_ACTIVE]) { crtc->active = props->prop_values[i]; } } drmModeFreeObjectProperties(props); } static void crtc_check_current_state(struct kms_atomic_crtc_state *crtc, struct kms_atomic_plane_state *primary, enum kms_atomic_check_relax relax) { struct kms_atomic_crtc_state crtc_kernel; drmModeCrtcPtr legacy; legacy = drmModeGetCrtc(crtc->state->desc->fd, crtc->obj); igt_assert(legacy); igt_assert_eq_u32(legacy->crtc_id, crtc->obj); igt_assert_eq_u32(legacy->x, primary->src_x >> 16); igt_assert_eq_u32(legacy->y, primary->src_y >> 16); if (crtc->active) igt_assert_eq_u32(legacy->buffer_id, primary->fb_id); else igt_assert_eq_u32(legacy->buffer_id, 0); if (legacy->mode_valid) { igt_assert_neq(legacy->mode_valid, 0); igt_assert_eq(crtc->mode.len, sizeof(struct drm_mode_modeinfo)); do_or_die(memcmp(&legacy->mode, crtc->mode.data, crtc->mode.len)); igt_assert_eq(legacy->width, legacy->mode.hdisplay); igt_assert_eq(legacy->height, legacy->mode.vdisplay); } else { igt_assert_eq(legacy->mode_valid, 0); } memcpy(&crtc_kernel, crtc, sizeof(crtc_kernel)); crtc_get_current_state(&crtc_kernel); if (crtc_kernel.mode.id != 0) igt_assert_eq(crtc_kernel.mode.len, sizeof(struct drm_mode_modeinfo)); /* Optionally relax the check for MODE_ID: using the legacy SetCrtc * API can potentially change MODE_ID even if the mode itself remains * unchanged. */ if (((relax & CRTC_RELAX_MODE) && (crtc_kernel.mode.id != crtc->mode.id && crtc_kernel.mode.id != 0 && crtc->mode.id != 0)) && memcmp(crtc_kernel.mode.data, crtc->mode.data, sizeof(struct drm_mode_modeinfo)) == 0) { crtc_kernel.mode.id = crtc->mode.id; crtc_kernel.mode.data = crtc->mode.data; } do_or_die(memcmp(&crtc_kernel, crtc, sizeof(crtc_kernel))); drmModeFreeCrtc(legacy); } static void crtc_commit_legacy(struct kms_atomic_crtc_state *crtc, struct kms_atomic_plane_state *plane, enum kms_atomic_check_relax relax) { drmModeObjectPropertiesPtr props; uint32_t *connectors; int num_connectors = 0; int i; if (!crtc->active) { do_or_die(drmModeSetCrtc(crtc->state->desc->fd, crtc->obj, 0, 0, 0, NULL, 0, NULL)); return; } connectors = calloc(crtc->state->num_connectors, sizeof(*connectors)); igt_assert(connectors); igt_assert_neq_u32(crtc->mode.id, 0); for (i = 0; i < crtc->state->num_connectors; i++) { struct kms_atomic_connector_state *connector = &crtc->state->connectors[i]; if (connector->crtc_id != crtc->obj) continue; connectors[num_connectors++] = connector->obj; } do_or_die(drmModeSetCrtc(crtc->state->desc->fd, crtc->obj, plane->fb_id, plane->src_x >> 16, plane->src_y >> 16, (num_connectors) ? connectors : NULL, num_connectors, crtc->mode.data)); /* When doing a legacy commit, the core may update MODE_ID to be a new * blob implicitly created by the legacy request. Hence we backfill * the value in the state object to ensure they match. */ props = drmModeObjectGetProperties(crtc->state->desc->fd, crtc->obj, DRM_MODE_OBJECT_CRTC); igt_assert(props); for (i = 0; i < props->count_props; i++) { if (props->props[i] != crtc->state->desc->props_crtc[CRTC_MODE_ID]) continue; crtc->mode.id = props->prop_values[i]; break; } drmModeFreeObjectProperties(props); crtc_check_current_state(crtc, plane, relax); plane_check_current_state(plane, relax); } static struct kms_atomic_crtc_state *find_crtc(struct kms_atomic_state *state, bool must_be_enabled) { int i; for (i = 0; i < state->num_crtcs; i++) { struct kms_atomic_crtc_state *crtc = &state->crtcs[i]; if (!crtc->obj) continue; if (must_be_enabled && !crtc->active) continue; crtc_get_current_state(crtc); return crtc; } return NULL; } static void fill_obj_props(int fd, uint32_t id, int type, int num_props, const char **prop_names, uint32_t *prop_ids) { drmModeObjectPropertiesPtr props; int i, j; props = drmModeObjectGetProperties(fd, id, type); 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; prop_ids[j] = props->props[i]; break; } drmModeFreeProperty(prop); } drmModeFreeObjectProperties(props); } static void fill_obj_prop_map(int fd, uint32_t id, int type, const char *name, int num_enums, const char **enum_names, uint64_t *enum_ids) { drmModeObjectPropertiesPtr props; int i, j, k; props = drmModeObjectGetProperties(fd, id, type); igt_assert(props); for (i = 0; i < props->count_props; i++) { drmModePropertyPtr prop = drmModeGetProperty(fd, props->props[i]); igt_assert(prop); if (strcmp(prop->name, name) != 0) { drmModeFreeProperty(prop); continue; } for (j = 0; j < prop->count_enums; j++) { struct drm_mode_property_enum *e = &prop->enums[j]; for (k = 0; k < num_enums; k++) { if (strcmp(e->name, enum_names[k]) != 0) continue; enum_ids[k] = e->value; break; } } drmModeFreeProperty(prop); } } static void atomic_setup(struct kms_atomic_state *state) { struct kms_atomic_desc *desc = state->desc; drmModeResPtr res; drmModePlaneResPtr res_plane; int i; desc->fd = drm_open_driver_master(DRIVER_ANY); igt_assert_fd(desc->fd); igt_skip_on(drmSetClientCap(desc->fd, DRM_CLIENT_CAP_ATOMIC, 1)); res = drmModeGetResources(desc->fd); res_plane = drmModeGetPlaneResources(desc->fd); igt_assert(res); igt_assert(res_plane); igt_assert_lt(0, res->count_crtcs); state->num_crtcs = res->count_crtcs; state->crtcs = calloc(state->num_crtcs, sizeof(*state->crtcs)); igt_assert(state->crtcs); igt_assert_lt(0, res_plane->count_planes); state->num_planes = res_plane->count_planes; state->planes = calloc(state->num_planes, sizeof(*state->planes)); igt_assert(state->planes); igt_assert_lt(0, res->count_connectors); state->num_connectors = res->count_connectors; state->connectors = calloc(state->num_connectors, sizeof(*state->connectors)); igt_assert(state->connectors); fill_obj_props(desc->fd, res->crtcs[0], DRM_MODE_OBJECT_CRTC, NUM_CRTC_PROPS, crtc_prop_names, desc->props_crtc); fill_obj_props(desc->fd, res_plane->planes[0], DRM_MODE_OBJECT_PLANE, NUM_PLANE_PROPS, plane_prop_names, desc->props_plane); fill_obj_prop_map(desc->fd, res_plane->planes[0], DRM_MODE_OBJECT_PLANE, "type", NUM_PLANE_TYPE_PROPS, plane_type_prop_names, desc->props_plane_type); fill_obj_props(desc->fd, res->connectors[0], DRM_MODE_OBJECT_CONNECTOR, NUM_CONNECTOR_PROPS, connector_prop_names, desc->props_connector); for (i = 0; i < state->num_crtcs; i++) { struct kms_atomic_crtc_state *crtc = &state->crtcs[i]; crtc->state = state; crtc->obj = res->crtcs[i]; crtc->idx = i; crtc_get_current_state(crtc); /* The blob pointed to by MODE_ID could well be transient, * and lose its last reference as we switch away from it. * Duplicate the blob here so we have a reference we know we * own. */ if (crtc->mode.id != 0) crtc->mode.id = blob_duplicate(desc->fd, crtc->mode.id); } for (i = 0; i < state->num_planes; i++) { drmModePlanePtr plane = drmModeGetPlane(desc->fd, res_plane->planes[i]); igt_assert(plane); state->planes[i].state = state; state->planes[i].obj = res_plane->planes[i]; state->planes[i].crtc_mask = plane->possible_crtcs; plane_get_current_state(&state->planes[i]); } for (i = 0; i < state->num_connectors; i++) { state->connectors[i].state = state; state->connectors[i].obj = res->connectors[i]; connector_get_current_state(&state->connectors[i]); } drmModeFreePlaneResources(res_plane); drmModeFreeResources(res); } static struct kms_atomic_state * atomic_state_dup(const struct kms_atomic_state *state) { struct kms_atomic_state *ret = calloc(1, sizeof(*ret)); igt_assert(ret); *ret = *state; ret->crtcs = calloc(ret->num_crtcs, sizeof(*ret->crtcs)); igt_assert(ret->crtcs); memcpy(ret->crtcs, state->crtcs, ret->num_crtcs * sizeof(*ret->crtcs)); ret->planes = calloc(ret->num_planes, sizeof(*ret->planes)); igt_assert(ret->planes); memcpy(ret->planes, state->planes, ret->num_planes * sizeof(*ret->planes)); ret->connectors = calloc(ret->num_connectors, sizeof(*ret->connectors)); igt_assert(ret->connectors); memcpy(ret->connectors, state->connectors, ret->num_connectors * sizeof(*ret->connectors)); return ret; } static void atomic_state_free(struct kms_atomic_state *state) { free(state->crtcs); free(state->planes); free(state->connectors); free(state); } static uint32_t plane_get_igt_format(struct kms_atomic_plane_state *plane) { drmModePlanePtr plane_kms; const uint32_t *igt_formats; uint32_t ret = 0; int num_igt_formats; int i; plane_kms = drmModeGetPlane(plane->state->desc->fd, plane->obj); igt_assert(plane_kms); igt_get_all_cairo_formats(&igt_formats, &num_igt_formats); for (i = 0; i < num_igt_formats; i++) { int j; for (j = 0; j < plane_kms->count_formats; j++) { if (plane_kms->formats[j] == igt_formats[i]) { ret = plane_kms->formats[j]; break; } } } drmModeFreePlane(plane_kms); return ret; } static void plane_overlay(struct kms_atomic_crtc_state *crtc, struct kms_atomic_plane_state *plane_old) { struct drm_mode_modeinfo *mode = crtc->mode.data; struct kms_atomic_plane_state plane = *plane_old; uint32_t format = plane_get_igt_format(&plane); drmModeAtomicReq *req = drmModeAtomicAlloc(); struct igt_fb fb; igt_require(req); igt_require(format != 0); plane.src_x = 0; plane.src_y = 0; plane.src_w = (mode->hdisplay / 2) << 16; plane.src_h = (mode->vdisplay / 2) << 16; plane.crtc_x = mode->hdisplay / 4; plane.crtc_y = mode->vdisplay / 4; plane.crtc_w = mode->hdisplay / 2; plane.crtc_h = mode->vdisplay / 2; plane.crtc_id = crtc->obj; plane.fb_id = igt_create_pattern_fb(plane.state->desc->fd, plane.crtc_w, plane.crtc_h, format, I915_TILING_NONE, &fb); /* Enable the overlay plane using the atomic API, and double-check * state is what we think it should be. */ plane_commit_atomic(&plane, req, ATOMIC_RELAX_NONE); /* Disable the plane and check the state matches the old. */ plane_commit_atomic(plane_old, req, ATOMIC_RELAX_NONE); /* Re-enable the plane through the legacy plane API, and verify through * atomic. */ plane_commit_legacy(&plane, ATOMIC_RELAX_NONE); /* Restore the plane to its original settings through the legacy plane * API, and verify through atomic. */ plane_commit_legacy(plane_old, ATOMIC_RELAX_NONE); drmModeAtomicFree(req); } static void plane_primary(struct kms_atomic_crtc_state *crtc, struct kms_atomic_plane_state *plane_old) { struct drm_mode_modeinfo *mode = crtc->mode.data; struct kms_atomic_plane_state plane = *plane_old; uint32_t format = plane_get_igt_format(&plane); drmModeAtomicReq *req = drmModeAtomicAlloc(); struct igt_fb fb; igt_require(format != 0); plane.src_x = 0; plane.src_y = 0; plane.src_w = mode->hdisplay << 16; plane.src_h = mode->vdisplay << 16; plane.crtc_x = 0; plane.crtc_y = 0; plane.crtc_w = mode->hdisplay; plane.crtc_h = mode->vdisplay; plane.crtc_id = crtc->obj; plane.fb_id = igt_create_pattern_fb(plane.state->desc->fd, plane.crtc_w, plane.crtc_h, format, I915_TILING_NONE, &fb); /* Flip the primary plane using the atomic API, and double-check * state is what we think it should be. */ crtc_commit_atomic(crtc, &plane, req, ATOMIC_RELAX_NONE); /* Restore the primary plane and check the state matches the old. */ crtc_commit_atomic(crtc, plane_old, req, ATOMIC_RELAX_NONE); /* Re-enable the plane through the legacy CRTC/primary-plane API, and * verify through atomic. */ crtc_commit_legacy(crtc, &plane, CRTC_RELAX_MODE); /* Restore the plane to its original settings through the legacy CRTC * API, and verify through atomic. */ crtc_commit_legacy(crtc, plane_old, CRTC_RELAX_MODE); /* Finally, restore to the original state. */ crtc_commit_atomic(crtc, plane_old, req, ATOMIC_RELAX_NONE); drmModeAtomicFree(req); } static void plane_cursor(struct kms_atomic_crtc_state *crtc, struct kms_atomic_plane_state *plane_old) { struct drm_mode_modeinfo *mode = crtc->mode.data; struct kms_atomic_plane_state plane = *plane_old; drmModeAtomicReq *req = drmModeAtomicAlloc(); struct igt_fb fb; uint64_t width, height; igt_assert(req); /* Any kernel new enough for atomic, also has the cursor size caps. */ do_or_die(drmGetCap(plane.state->desc->fd, DRM_CAP_CURSOR_WIDTH, &width)); do_or_die(drmGetCap(plane.state->desc->fd, DRM_CAP_CURSOR_HEIGHT, &height)); plane.src_x = 0; plane.src_y = 0; plane.src_w = width << 16; plane.src_h = height << 16; plane.crtc_x = mode->hdisplay / 2; plane.crtc_y = mode->vdisplay / 2; plane.crtc_w = width; plane.crtc_h = height; plane.crtc_id = crtc->obj; plane.fb_id = igt_create_color_fb(plane.state->desc->fd, width, height, DRM_FORMAT_ARGB8888, LOCAL_DRM_FORMAT_MOD_NONE, 0.0, 0.0, 0.0, &fb); igt_assert_neq_u32(plane.fb_id, 0); /* Flip the cursor plane using the atomic API, and double-check * state is what we think it should be. */ plane_commit_atomic(&plane, req, ATOMIC_RELAX_NONE); /* Restore the cursor plane and check the state matches the old. */ plane_commit_atomic(plane_old, req, ATOMIC_RELAX_NONE); /* Re-enable the plane through the legacy cursor API, and verify * through atomic. */ do_or_die(drmModeMoveCursor(plane.state->desc->fd, plane.crtc_id, plane.crtc_x, plane.crtc_y)); do_or_die(drmModeSetCursor(plane.state->desc->fd, plane.crtc_id, fb.gem_handle, width, height)); plane_check_current_state(&plane, PLANE_RELAX_FB); /* Wiggle. */ plane.crtc_x -= 16; plane.crtc_y -= 16; do_or_die(drmModeMoveCursor(plane.state->desc->fd, plane.crtc_id, plane.crtc_x, plane.crtc_y)); plane_check_current_state(&plane, PLANE_RELAX_FB); /* Restore the plane to its original settings through the legacy cursor * API, and verify through atomic. */ do_or_die(drmModeSetCursor2(plane.state->desc->fd, plane.crtc_id, 0, 0, 0, 0, 0)); plane_check_current_state(plane_old, ATOMIC_RELAX_NONE); /* Finally, restore to the original state. */ plane_commit_atomic(plane_old, req, ATOMIC_RELAX_NONE); drmModeAtomicFree(req); } static void plane_invalid_params(struct kms_atomic_crtc_state *crtc, struct kms_atomic_plane_state *plane_old, struct kms_atomic_connector_state *conn) { struct drm_mode_modeinfo *mode = crtc->mode.data; struct kms_atomic_plane_state plane = *plane_old; uint32_t format = plane_get_igt_format(&plane); drmModeAtomicReq *req = drmModeAtomicAlloc(); struct igt_fb fb; /* Pass a series of invalid object IDs for the FB ID. */ plane.fb_id = plane.obj; plane_commit_atomic_err(&plane, plane_old, req, ATOMIC_RELAX_NONE, EINVAL); plane.fb_id = crtc->obj; plane_commit_atomic_err(&plane, plane_old, req, ATOMIC_RELAX_NONE, EINVAL); plane.fb_id = conn->obj; plane_commit_atomic_err(&plane, plane_old, req, ATOMIC_RELAX_NONE, EINVAL); plane.fb_id = crtc->mode.id; plane_commit_atomic_err(&plane, plane_old, req, ATOMIC_RELAX_NONE, EINVAL); plane.fb_id = plane_old->fb_id; plane_commit_atomic(&plane, req, ATOMIC_RELAX_NONE); /* Pass a series of invalid object IDs for the CRTC ID. */ plane.crtc_id = plane.obj; plane_commit_atomic_err(&plane, plane_old, req, ATOMIC_RELAX_NONE, EINVAL); plane.crtc_id = plane.fb_id; plane_commit_atomic_err(&plane, plane_old, req, ATOMIC_RELAX_NONE, EINVAL); plane.crtc_id = conn->obj; plane_commit_atomic_err(&plane, plane_old, req, ATOMIC_RELAX_NONE, EINVAL); plane.crtc_id = crtc->mode.id; plane_commit_atomic_err(&plane, plane_old, req, ATOMIC_RELAX_NONE, EINVAL); plane.crtc_id = plane_old->crtc_id; plane_commit_atomic(&plane, req, ATOMIC_RELAX_NONE); /* Create a framebuffer too small for the plane configuration. */ igt_require(format != 0); plane.src_x = 0; plane.src_y = 0; plane.src_w = mode->hdisplay << 16; plane.src_h = mode->vdisplay << 16; plane.crtc_x = 0; plane.crtc_y = 0; plane.crtc_w = mode->hdisplay; plane.crtc_h = mode->vdisplay; plane.crtc_id = crtc->obj; plane.fb_id = igt_create_pattern_fb(plane.state->desc->fd, plane.crtc_w - 1, plane.crtc_h - 1, format, I915_TILING_NONE, &fb); plane_commit_atomic_err(&plane, plane_old, req, ATOMIC_RELAX_NONE, ENOSPC); /* Restore the primary plane and check the state matches the old. */ plane_commit_atomic(plane_old, req, ATOMIC_RELAX_NONE); drmModeAtomicFree(req); } static void crtc_invalid_params(struct kms_atomic_crtc_state *crtc_old, struct kms_atomic_plane_state *plane, struct kms_atomic_connector_state *conn) { struct kms_atomic_crtc_state crtc = *crtc_old; drmModeAtomicReq *req = drmModeAtomicAlloc(); igt_assert(req); /* Pass a series of invalid object IDs for the mode ID. */ crtc.mode.id = plane->obj; crtc_commit_atomic_err(&crtc, plane, crtc_old, plane, req, ATOMIC_RELAX_NONE, EINVAL); crtc.mode.id = crtc.obj; crtc_commit_atomic_err(&crtc, plane, crtc_old, plane, req, ATOMIC_RELAX_NONE, EINVAL); crtc.mode.id = conn->obj; crtc_commit_atomic_err(&crtc, plane, crtc_old, plane, req, ATOMIC_RELAX_NONE, EINVAL); crtc.mode.id = plane->fb_id; crtc_commit_atomic_err(&crtc, plane, crtc_old, plane, req, ATOMIC_RELAX_NONE, EINVAL); crtc.mode.id = crtc_old->mode.id; crtc_commit_atomic(&crtc, plane, req, ATOMIC_RELAX_NONE); /* Create a blob which is the wrong size to be a valid mode. */ do_or_die(drmModeCreatePropertyBlob(crtc.state->desc->fd, crtc.mode.data, sizeof(struct drm_mode_modeinfo) - 1, &crtc.mode.id)); crtc_commit_atomic_err(&crtc, plane, crtc_old, plane, req, ATOMIC_RELAX_NONE, EINVAL); do_or_die(drmModeCreatePropertyBlob(crtc.state->desc->fd, crtc.mode.data, sizeof(struct drm_mode_modeinfo) + 1, &crtc.mode.id)); crtc_commit_atomic_err(&crtc, plane, crtc_old, plane, req, ATOMIC_RELAX_NONE, EINVAL); /* Restore the CRTC and check the state matches the old. */ crtc_commit_atomic(crtc_old, plane, req, ATOMIC_RELAX_NONE); drmModeAtomicFree(req); } /* Abuse the atomic ioctl directly in order to test various invalid conditions, * which the libdrm wrapper won't allow us to create. */ static void atomic_invalid_params(struct kms_atomic_crtc_state *crtc, struct kms_atomic_plane_state *plane, struct kms_atomic_connector_state *connector) { struct kms_atomic_desc *desc = crtc->state->desc; struct drm_mode_atomic ioc; uint32_t obj_raw[16]; /* array of objects (sized by count_objs) */ uint32_t num_props_raw[16]; /* array of num props per obj (ditto) */ uint32_t props_raw[256]; /* array of props (sum of count_props) */ uint64_t values_raw[256]; /* array of values for properties (ditto) */ int i; memset(&ioc, 0, sizeof(ioc)); /* An empty request should do nothing. */ do_ioctl(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc); for (i = 0; i < ARRAY_SIZE(obj_raw); i++) obj_raw[i] = 0; for (i = 0; i < ARRAY_SIZE(num_props_raw); i++) num_props_raw[i] = 0; for (i = 0; i < ARRAY_SIZE(props_raw); i++) props_raw[i] = 0; for (i = 0; i < ARRAY_SIZE(values_raw); i++) values_raw[i] = 0; ioc.objs_ptr = (uintptr_t) obj_raw; ioc.count_props_ptr = (uintptr_t) num_props_raw; ioc.props_ptr = (uintptr_t) props_raw; ioc.prop_values_ptr = (uintptr_t) values_raw; /* Valid pointers, but still should copy nothing. */ do_ioctl(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc); /* Nonsense flags. */ ioc.flags = 0xdeadbeef; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EINVAL); /* Specifically forbidden combination. */ ioc.flags = DRM_MODE_ATOMIC_TEST_ONLY | DRM_MODE_PAGE_FLIP_EVENT; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EINVAL); ioc.flags = 0; /* Safety check that flags is reset properly. */ do_ioctl(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc); /* Reserved/MBZ. */ ioc.reserved = 1; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EINVAL); ioc.reserved = 0; do_ioctl(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc); /* Zero is not a valid object ID. */ ioc.count_objs = ARRAY_SIZE(obj_raw); do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, ENOENT); /* Invalid object type (not a thing we can set properties on). */ ioc.count_objs = 1; obj_raw[0] = crtc->mode.id; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, ENOENT); obj_raw[0] = plane->fb_id; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, ENOENT); /* Filled object but with no properties; no-op. */ for (i = 0; i < ARRAY_SIZE(obj_raw); i++) obj_raw[i] = crtc->obj; do_ioctl(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc); /* Pass in all sorts of things other than the property ID. */ num_props_raw[0] = 1; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, ENOENT); props_raw[0] = crtc->obj; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, ENOENT); props_raw[0] = plane->obj; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, ENOENT); props_raw[0] = connector->obj; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, ENOENT); props_raw[0] = crtc->mode.id; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, ENOENT); /* Valid property, valid value. */ for (i = 0; i < ARRAY_SIZE(props_raw); i++) { props_raw[i] = desc->props_crtc[CRTC_MODE_ID]; values_raw[i] = crtc->mode.id; } do_ioctl(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc); /* Setting the same thing multiple times is OK. */ for (i = 0; i < ARRAY_SIZE(obj_raw); i++) num_props_raw[i] = ARRAY_SIZE(props_raw) / ARRAY_SIZE(obj_raw); do_ioctl(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc); ioc.count_objs = ARRAY_SIZE(obj_raw); do_ioctl(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc); /* Pass a series of outlandish addresses. */ ioc.objs_ptr = 0; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EFAULT); ioc.objs_ptr = (uintptr_t) obj_raw; ioc.count_props_ptr = 0; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EFAULT); ioc.count_props_ptr = (uintptr_t) num_props_raw; ioc.props_ptr = 0; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EFAULT); ioc.props_ptr = (uintptr_t) props_raw; ioc.prop_values_ptr = 0; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EFAULT); ioc.prop_values_ptr = (uintptr_t) values_raw; do_ioctl(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc); /* Attempt to overflow and/or trip various boundary conditions. */ ioc.count_objs = UINT32_MAX / sizeof(uint32_t); do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, ENOENT); ioc.count_objs = ARRAY_SIZE(obj_raw); ioc.objs_ptr = UINT64_MAX - sizeof(uint32_t); do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EFAULT); ioc.count_objs = 1; ioc.objs_ptr = UINT64_MAX - sizeof(uint32_t); do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EFAULT); num_props_raw[0] = UINT32_MAX / sizeof(uint32_t); do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EFAULT); num_props_raw[0] = UINT32_MAX - 1; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EFAULT); for (i = 0; i < ARRAY_SIZE(obj_raw); i++) num_props_raw[i] = (UINT32_MAX / ARRAY_SIZE(obj_raw)) + 1; do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EFAULT); for (i = 0; i < ARRAY_SIZE(obj_raw); i++) num_props_raw[i] = ARRAY_SIZE(props_raw) / ARRAY_SIZE(obj_raw); do_ioctl_err(desc->fd, DRM_IOCTL_MODE_ATOMIC, &ioc, EFAULT); } igt_main { struct kms_atomic_desc desc; struct kms_atomic_state *current; memset(&desc, 0, sizeof(desc)); current = calloc(1, sizeof(*current)); igt_assert(current); current->desc = &desc; igt_fixture atomic_setup(current); igt_subtest("plane_overlay_legacy") { struct kms_atomic_state *scratch = atomic_state_dup(current); struct kms_atomic_crtc_state *crtc = find_crtc(scratch, true); struct kms_atomic_plane_state *plane = find_plane(scratch, PLANE_TYPE_OVERLAY, crtc); igt_require(crtc); igt_require(plane); plane_overlay(crtc, plane); atomic_state_free(scratch); } igt_subtest("plane_primary_legacy") { struct kms_atomic_state *scratch = atomic_state_dup(current); struct kms_atomic_crtc_state *crtc = find_crtc(scratch, true); struct kms_atomic_plane_state *plane = find_plane(scratch, PLANE_TYPE_PRIMARY, crtc); igt_require(crtc); igt_require(plane); plane_primary(crtc, plane); atomic_state_free(scratch); } igt_subtest("plane_cursor_legacy") { struct kms_atomic_state *scratch = atomic_state_dup(current); struct kms_atomic_crtc_state *crtc = find_crtc(scratch, true); struct kms_atomic_plane_state *plane = find_plane(scratch, PLANE_TYPE_CURSOR, crtc); igt_require(crtc); igt_require(plane); plane_cursor(crtc, plane); atomic_state_free(scratch); } igt_subtest("plane_invalid_params") { struct kms_atomic_state *scratch = atomic_state_dup(current); struct kms_atomic_crtc_state *crtc = find_crtc(scratch, true); struct kms_atomic_plane_state *plane = find_plane(current, PLANE_TYPE_PRIMARY, crtc); struct kms_atomic_connector_state *conn = find_connector(scratch, crtc); igt_require(crtc); igt_require(plane); plane_invalid_params(crtc, plane, conn); atomic_state_free(scratch); } igt_subtest("crtc_invalid_params") { struct kms_atomic_state *scratch = atomic_state_dup(current); struct kms_atomic_crtc_state *crtc = find_crtc(scratch, true); struct kms_atomic_plane_state *plane = find_plane(scratch, NUM_PLANE_TYPE_PROPS, crtc); struct kms_atomic_connector_state *conn = find_connector(scratch, crtc); igt_require(crtc); igt_require(plane); igt_require(conn); crtc_invalid_params(crtc, plane, conn); atomic_state_free(scratch); } igt_subtest("atomic_invalid_params") { struct kms_atomic_state *scratch = atomic_state_dup(current); struct kms_atomic_crtc_state *crtc = &scratch->crtcs[0]; struct kms_atomic_plane_state *plane = find_plane(scratch, NUM_PLANE_TYPE_PROPS, crtc); struct kms_atomic_connector_state *conn = find_connector(scratch, crtc); igt_require(plane); igt_require(conn); atomic_invalid_params(crtc, plane, conn); atomic_state_free(scratch); } atomic_state_free(current); igt_fixture close(desc.fd); }