/* * Copyright © 2013,2014 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. * */ #include "igt.h" #include #define MAX_FENCES 32 #define MAXMULTIPLANESAMOUNT 2 struct p_struct { igt_plane_t *plane; struct igt_fb fb; }; enum p_pointorigo { p_top = 1 << 0, p_bottom = 1 << 1, p_left = 1 << 2, p_right = 1 << 3 }; struct p_point{ enum p_pointorigo origo; float_t x; float_t y; }; typedef struct { int gfx_fd; igt_display_t display; struct igt_fb fb; struct igt_fb fb_reference; struct igt_fb fb_unrotated; struct igt_fb fb_flip; igt_crc_t ref_crc; igt_crc_t flip_crc; igt_pipe_crc_t *pipe_crc; igt_rotation_t rotation; int pos_x; int pos_y; uint32_t override_fmt; uint64_t override_tiling; int devid; struct p_struct *multiplaneoldview; struct p_point planepos[MAXMULTIPLANESAMOUNT]; } data_t; typedef struct { float r; float g; float b; } rgb_color_t; static void set_color(rgb_color_t *color, float r, float g, float b) { color->r = r; color->g = g; color->b = b; } static void rotate_colors(rgb_color_t *tl, rgb_color_t *tr, rgb_color_t *br, rgb_color_t *bl, igt_rotation_t rotation) { rgb_color_t bl_tmp, br_tmp, tl_tmp, tr_tmp; if (rotation & IGT_REFLECT_X) { igt_swap(*tl, *tr); igt_swap(*bl, *br); } if (rotation & IGT_ROTATION_90) { bl_tmp = *bl; br_tmp = *br; tl_tmp = *tl; tr_tmp = *tr; *tl = tr_tmp; *bl = tl_tmp; *tr = br_tmp; *br = bl_tmp; } else if (rotation & IGT_ROTATION_180) { igt_swap(*tl, *br); igt_swap(*tr, *bl); } else if (rotation & IGT_ROTATION_270) { bl_tmp = *bl; br_tmp = *br; tl_tmp = *tl; tr_tmp = *tr; *tl = bl_tmp; *bl = br_tmp; *tr = tl_tmp; *br = tr_tmp; } } #define RGB_COLOR(color) \ color.r, color.g, color.b static void paint_squares(data_t *data, igt_rotation_t rotation, struct igt_fb *fb, float o) { cairo_t *cr; unsigned int w = fb->width; unsigned int h = fb->height; rgb_color_t tl, tr, bl, br; igt_assert_f(!(w&1), "rotation image must be even width, now attempted %d\n", w); igt_assert_f(!(h&1), "rotation image must be even height, now attempted %d\n", h); cr = igt_get_cairo_ctx(data->gfx_fd, fb); set_color(&tl, o, 0.0f, 0.0f); set_color(&tr, 0.0f, o, 0.0f); set_color(&br, o, o, o); set_color(&bl, 0.0f, 0.0f, o); rotate_colors(&tl, &tr, &br, &bl, rotation); igt_paint_color(cr, 0, 0, w / 2, h / 2, RGB_COLOR(tl)); igt_paint_color(cr, w / 2, 0, w / 2, h / 2, RGB_COLOR(tr)); igt_paint_color(cr, 0, h / 2, w / 2, h / 2, RGB_COLOR(bl)); igt_paint_color(cr, w / 2, h / 2, w / 2, h / 2, RGB_COLOR(br)); igt_put_cairo_ctx(data->gfx_fd, fb, cr); } static void remove_fbs(data_t *data) { igt_remove_fb(data->gfx_fd, &data->fb); igt_remove_fb(data->gfx_fd, &data->fb_reference); igt_remove_fb(data->gfx_fd, &data->fb_unrotated); igt_remove_fb(data->gfx_fd, &data->fb_flip); } static void cleanup_crtc(data_t *data) { igt_display_t *display = &data->display; igt_pipe_crc_free(data->pipe_crc); data->pipe_crc = NULL; remove_fbs(data); igt_display_reset(display); } static void prepare_crtc(data_t *data, igt_output_t *output, enum pipe pipe, igt_plane_t *plane, bool start_crc) { igt_display_t *display = &data->display; cleanup_crtc(data); igt_output_set_pipe(output, pipe); igt_plane_set_rotation(plane, IGT_ROTATION_0); /* create the pipe_crc object for this pipe */ igt_pipe_crc_free(data->pipe_crc); igt_display_commit2(display, COMMIT_ATOMIC); data->pipe_crc = igt_pipe_crc_new(data->gfx_fd, pipe, INTEL_PIPE_CRC_SOURCE_AUTO); if (start_crc) igt_pipe_crc_start(data->pipe_crc); } enum rectangle_type { rectangle, square, portrait, landscape, num_rectangle_types /* must be last */ }; static void prepare_fbs(data_t *data, igt_output_t *output, igt_plane_t *plane, enum rectangle_type rect, uint32_t format) { drmModeModeInfo *mode; igt_display_t *display = &data->display; unsigned int w, h, ref_w, ref_h, min_w, min_h; uint64_t tiling = data->override_tiling ?: LOCAL_DRM_FORMAT_MOD_NONE; uint32_t pixel_format = data->override_fmt ?: DRM_FORMAT_XRGB8888; const float flip_opacity = 0.75; remove_fbs(data); igt_plane_set_rotation(plane, IGT_ROTATION_0); mode = igt_output_get_mode(output); if (plane->type != DRM_PLANE_TYPE_CURSOR) { w = mode->hdisplay; h = mode->vdisplay; min_w = 256; min_h = 256; } else { pixel_format = data->override_fmt ?: DRM_FORMAT_ARGB8888; w = h = 256; min_w = min_h = 64; } switch (rect) { case rectangle: break; case square: w = h = min(h, w); break; case portrait: w = min_w; break; case landscape: h = min_h; break; case num_rectangle_types: igt_assert(0); } ref_w = w; ref_h = h; /* * For 90/270, we will use create smaller fb so that the rotated * frame can fit in */ if (data->rotation & (IGT_ROTATION_90 | IGT_ROTATION_270)) { tiling = data->override_tiling ?: LOCAL_I915_FORMAT_MOD_Y_TILED; igt_swap(w, h); } /* * Create a reference software rotated flip framebuffer. */ igt_create_fb(data->gfx_fd, ref_w, ref_h, pixel_format, tiling, &data->fb_flip); paint_squares(data, data->rotation, &data->fb_flip, flip_opacity); igt_plane_set_fb(plane, &data->fb_flip); if (plane->type != DRM_PLANE_TYPE_CURSOR) igt_plane_set_position(plane, data->pos_x, data->pos_y); igt_display_commit2(display, COMMIT_ATOMIC); igt_pipe_crc_get_current(display->drm_fd, data->pipe_crc, &data->flip_crc); /* * Prepare the non-rotated flip fb. */ igt_remove_fb(data->gfx_fd, &data->fb_flip); igt_create_fb(data->gfx_fd, w, h, pixel_format, tiling, &data->fb_flip); paint_squares(data, IGT_ROTATION_0, &data->fb_flip, flip_opacity); /* * Create a reference CRC for a software-rotated fb. */ igt_create_fb(data->gfx_fd, ref_w, ref_h, pixel_format, data->override_tiling ?: LOCAL_DRM_FORMAT_MOD_NONE, &data->fb_reference); paint_squares(data, data->rotation, &data->fb_reference, 1.0); igt_plane_set_fb(plane, &data->fb_reference); if (plane->type != DRM_PLANE_TYPE_CURSOR) igt_plane_set_position(plane, data->pos_x, data->pos_y); igt_display_commit2(display, COMMIT_ATOMIC); igt_pipe_crc_get_current(display->drm_fd, data->pipe_crc, &data->ref_crc); /* * Prepare the non-rotated reference fb. */ igt_create_fb(data->gfx_fd, ref_w, ref_h, pixel_format, tiling, &data->fb_unrotated); paint_squares(data, IGT_ROTATION_0, &data->fb_unrotated, 1.0); igt_plane_set_fb(plane, &data->fb_unrotated); igt_plane_set_rotation(plane, IGT_ROTATION_0); if (plane->type != DRM_PLANE_TYPE_CURSOR) igt_plane_set_position(plane, data->pos_x, data->pos_y); igt_display_commit2(display, COMMIT_ATOMIC); /* * Prepare the plane with an non-rotated fb let the hw rotate it. */ igt_create_fb(data->gfx_fd, w, h, pixel_format, tiling, &data->fb); paint_squares(data, IGT_ROTATION_0, &data->fb, 1.0); igt_plane_set_fb(plane, &data->fb); if (plane->type != DRM_PLANE_TYPE_CURSOR) igt_plane_set_position(plane, data->pos_x, data->pos_y); } static void test_single_case(data_t *data, enum pipe pipe, igt_output_t *output, igt_plane_t *plane, enum rectangle_type rect, uint32_t format, bool test_bad_format) { igt_display_t *display = &data->display; igt_crc_t crc_output; int ret; igt_debug("Testing case %i on pipe %s, format %s\n", rect, kmstest_pipe_name(pipe), igt_format_str(format)); prepare_fbs(data, output, plane, rect, format); igt_plane_set_rotation(plane, data->rotation); if (data->rotation & (IGT_ROTATION_90 | IGT_ROTATION_270)) igt_plane_set_size(plane, data->fb.height, data->fb.width); ret = igt_display_try_commit2(display, COMMIT_ATOMIC); if (test_bad_format) { igt_assert_eq(ret, -EINVAL); return; } /* Verify commit was ok. */ igt_assert_eq(ret, 0); /* Check CRC */ igt_pipe_crc_get_current(display->drm_fd, data->pipe_crc, &crc_output); igt_assert_crc_equal(&data->ref_crc, &crc_output); /* * If flips are requested flip to a different fb and * check CRC against that one as well. */ if (data->fb_flip.fb_id) { igt_plane_set_fb(plane, &data->fb_flip); if (data->rotation == IGT_ROTATION_90 || data->rotation == IGT_ROTATION_270) igt_plane_set_size(plane, data->fb.height, data->fb.width); if (plane->type != DRM_PLANE_TYPE_PRIMARY) { igt_display_commit_atomic(display, DRM_MODE_PAGE_FLIP_EVENT | DRM_MODE_ATOMIC_NONBLOCK, NULL); } else { ret = drmModePageFlip(data->gfx_fd, output->config.crtc->crtc_id, data->fb_flip.fb_id, DRM_MODE_PAGE_FLIP_EVENT, NULL); igt_assert_eq(ret, 0); } kmstest_wait_for_pageflip(data->gfx_fd); igt_pipe_crc_get_current(display->drm_fd, data->pipe_crc, &crc_output); igt_assert_crc_equal(&data->flip_crc, &crc_output); } } static void test_plane_rotation(data_t *data, int plane_type, bool test_bad_format) { igt_display_t *display = &data->display; igt_output_t *output; enum pipe pipe; if (plane_type == DRM_PLANE_TYPE_CURSOR) igt_require(display->has_cursor_plane); igt_display_require_output(display); for_each_pipe_with_valid_output(display, pipe, output) { igt_plane_t *plane; int i, j; if (IS_CHERRYVIEW(data->devid) && pipe != PIPE_B) continue; igt_output_set_pipe(output, pipe); plane = igt_output_get_plane_type(output, plane_type); igt_require(igt_plane_has_prop(plane, IGT_PLANE_ROTATION)); prepare_crtc(data, output, pipe, plane, true); for (i = 0; i < num_rectangle_types; i++) { /* Unsupported on i915 */ if (plane_type == DRM_PLANE_TYPE_CURSOR && i != square) continue; /* Only support partial covering primary plane on gen9+ */ if (plane_type == DRM_PLANE_TYPE_PRIMARY && i != rectangle && intel_gen(intel_get_drm_devid(data->gfx_fd)) < 9) continue; if (!data->override_fmt) { for (j = 0; j < plane->drm_plane->count_formats; j++) { uint32_t format = plane->drm_plane->formats[j]; if (!igt_fb_supported_format(format)) continue; test_single_case(data, pipe, output, plane, i, format, test_bad_format); } } else { test_single_case(data, pipe, output, plane, i, data->override_fmt, test_bad_format); } } igt_pipe_crc_stop(data->pipe_crc); } } typedef struct { int32_t x1, y1; uint64_t width, height, tiling, planetype, format; igt_rotation_t rotation_sw, rotation_hw; } planeinfos; static bool get_multiplane_crc(data_t *data, igt_output_t *output, igt_crc_t *crc_output, planeinfos *planeinfo, int numplanes) { uint32_t w, h; igt_display_t *display = &data->display; struct p_struct *planes, *oldplanes; int c, ret; oldplanes = data->multiplaneoldview; planes = calloc(sizeof(*planes), numplanes); for (c = 0; c < numplanes; c++) { planes[c].plane = igt_output_get_plane_type(output, planeinfo[c].planetype); /* * make plane and fb width and height always divisible by 4 * due to NV12 support and Intel hw workarounds. */ w = planeinfo[c].width & ~3; h = planeinfo[c].height & ~3; if (planeinfo[c].rotation_sw & (IGT_ROTATION_90 | IGT_ROTATION_270)) igt_swap(w, h); if (!igt_plane_has_format_mod(planes[c].plane, planeinfo[c].format, planeinfo[c].tiling)) return false; igt_create_fb(data->gfx_fd, w, h, planeinfo[c].format, planeinfo[c].tiling, &planes[c].fb); paint_squares(data, planeinfo[c].rotation_sw, &planes[c].fb, 1.0f); igt_plane_set_fb(planes[c].plane, &planes[c].fb); if (planeinfo[c].rotation_hw & (IGT_ROTATION_90 | IGT_ROTATION_270)) igt_plane_set_size(planes[c].plane, h, w); igt_plane_set_position(planes[c].plane, planeinfo[c].x1, planeinfo[c].y1); igt_plane_set_rotation(planes[c].plane, planeinfo[c].rotation_hw); } ret = igt_display_try_commit2(display, COMMIT_ATOMIC); igt_assert_eq(ret, 0); igt_pipe_crc_get_current(data->gfx_fd, data->pipe_crc, crc_output); for (c = 0; c < numplanes && oldplanes; c++) igt_remove_fb(data->gfx_fd, &oldplanes[c].fb); free(oldplanes); data->multiplaneoldview = (void*)planes; return true; } static void pointlocation(data_t *data, planeinfos *p, drmModeModeInfo *mode, int c) { if (data->planepos[c].origo & p_right) { p[c].x1 = (int32_t)(data->planepos[c].x * mode->hdisplay + mode->hdisplay); p[c].x1 &= ~3; /* * At this point is handled surface on right side. If display * mode is not divisible by 4 but with 2 point location is * fixed to match requirements. Because of YUV planes here is * intentionally ignored bit 1. */ p[c].x1 -= mode->hdisplay & 2; } else { p[c].x1 = (int32_t)(data->planepos[c].x * mode->hdisplay); p[c].x1 &= ~3; } if (data->planepos[c].origo & p_bottom) { p[c].y1 = (int32_t)(data->planepos[c].y * mode->vdisplay + mode->vdisplay); p[c].y1 &= ~3; p[c].y1 -= mode->vdisplay & 2; } else { p[c].y1 = (int32_t)(data->planepos[c].y * mode->vdisplay); p[c].y1 &= ~3; } } /* * Here is pipe parameter which is now used only for first pipe. * It is left here if this test ever was wanted to be run on * different pipes. */ static void test_multi_plane_rotation(data_t *data, enum pipe pipe) { igt_display_t *display = &data->display; igt_output_t *output; igt_crc_t retcrc_sw, retcrc_hw; planeinfos p[2]; int c; struct p_struct *oldplanes; drmModeModeInfo *mode; static const struct { igt_rotation_t rotation; float_t width; float_t height; uint64_t tiling; } planeconfigs[] = { {IGT_ROTATION_0, .2f, .4f, LOCAL_DRM_FORMAT_MOD_NONE }, {IGT_ROTATION_0, .2f, .4f, LOCAL_I915_FORMAT_MOD_X_TILED }, {IGT_ROTATION_0, .2f, .4f, LOCAL_I915_FORMAT_MOD_Y_TILED }, {IGT_ROTATION_0, .2f, .4f, LOCAL_I915_FORMAT_MOD_Yf_TILED }, {IGT_ROTATION_90, .2f, .4f, LOCAL_I915_FORMAT_MOD_Y_TILED }, {IGT_ROTATION_90, .2f, .4f, LOCAL_I915_FORMAT_MOD_Yf_TILED }, {IGT_ROTATION_180, .2f, .4f, LOCAL_DRM_FORMAT_MOD_NONE }, {IGT_ROTATION_180, .2f, .4f, LOCAL_I915_FORMAT_MOD_X_TILED }, {IGT_ROTATION_180, .2f, .4f, LOCAL_I915_FORMAT_MOD_Y_TILED }, {IGT_ROTATION_180, .2f, .4f, LOCAL_I915_FORMAT_MOD_Yf_TILED }, {IGT_ROTATION_270, .2f, .4f, LOCAL_I915_FORMAT_MOD_Y_TILED }, {IGT_ROTATION_270, .2f, .4f, LOCAL_I915_FORMAT_MOD_Yf_TILED }, }; /* * These are those modes which are tested. For testing feel interesting * case with tiling are 2 bpp, 4 bpp and NV12. */ static const uint32_t formatlist[] = {DRM_FORMAT_RGB565, DRM_FORMAT_XRGB8888, DRM_FORMAT_NV12}; for_each_valid_output_on_pipe(display, pipe, output) { int i, j, k, l; igt_output_set_pipe(output, pipe); mode = igt_output_get_mode(output); igt_display_require_output(display); igt_display_commit2(display, COMMIT_ATOMIC); data->pipe_crc = igt_pipe_crc_new(data->gfx_fd, pipe, INTEL_PIPE_CRC_SOURCE_AUTO); igt_pipe_crc_start(data->pipe_crc); for (i = 0; i < ARRAY_SIZE(planeconfigs); i++) { p[0].planetype = DRM_PLANE_TYPE_PRIMARY; p[0].width = (uint64_t)(planeconfigs[i].width * mode->hdisplay); p[0].height = (uint64_t)(planeconfigs[i].height * mode->vdisplay); p[0].tiling = planeconfigs[i].tiling; pointlocation(data, (planeinfos *)&p, mode, 0); for (k = 0; k < ARRAY_SIZE(formatlist); k++) { p[0].format = formatlist[k]; for (j = 0; j < ARRAY_SIZE(planeconfigs); j++) { p[1].planetype = DRM_PLANE_TYPE_OVERLAY; p[1].width = (uint64_t)(planeconfigs[j].width * mode->hdisplay); p[1].height = (uint64_t)(planeconfigs[j].height * mode->vdisplay); p[1].tiling = planeconfigs[j].tiling; pointlocation(data, (planeinfos *)&p, mode, 1); for (l = 0; l < ARRAY_SIZE(formatlist); l++) { p[1].format = formatlist[l]; /* * RGB565 90/270 degrees rotation is supported * from gen11 onwards. */ if (p[0].format == DRM_FORMAT_RGB565 && (planeconfigs[i].rotation & (IGT_ROTATION_90 | IGT_ROTATION_270)) && intel_gen(data->devid) < 11) continue; if (p[1].format == DRM_FORMAT_RGB565 && (planeconfigs[j].rotation & (IGT_ROTATION_90 | IGT_ROTATION_270)) && intel_gen(data->devid) < 11) continue; p[0].rotation_sw = planeconfigs[i].rotation; p[0].rotation_hw = IGT_ROTATION_0; p[1].rotation_sw = planeconfigs[j].rotation; p[1].rotation_hw = IGT_ROTATION_0; if (!get_multiplane_crc(data, output, &retcrc_sw, (planeinfos *)&p, MAXMULTIPLANESAMOUNT)) continue; igt_swap(p[0].rotation_sw, p[0].rotation_hw); igt_swap(p[1].rotation_sw, p[1].rotation_hw); if (!get_multiplane_crc(data, output, &retcrc_hw, (planeinfos *)&p, MAXMULTIPLANESAMOUNT)) continue; igt_assert_crc_equal(&retcrc_sw, &retcrc_hw); } } } } igt_pipe_crc_stop(data->pipe_crc); igt_pipe_crc_free(data->pipe_crc); igt_output_set_pipe(output, PIPE_ANY); } /* * Old fbs are deleted only after new ones are set on planes. * This is done to speed up the test */ oldplanes = data->multiplaneoldview; for (c = 0; c < MAXMULTIPLANESAMOUNT && oldplanes; c++) igt_remove_fb(data->gfx_fd, &oldplanes[c].fb); free(oldplanes); data->multiplaneoldview = NULL; data->pipe_crc = NULL; } static void test_plane_rotation_exhaust_fences(data_t *data, enum pipe pipe, igt_output_t *output, igt_plane_t *plane) { igt_display_t *display = &data->display; uint64_t tiling = LOCAL_I915_FORMAT_MOD_Y_TILED; uint32_t format = DRM_FORMAT_XRGB8888; int fd = data->gfx_fd; drmModeModeInfo *mode; struct igt_fb fb[MAX_FENCES+1] = {}; uint64_t size; unsigned int stride, w, h; uint64_t total_aperture_size, total_fbs_size; int i; igt_require(igt_plane_has_prop(plane, IGT_PLANE_ROTATION)); prepare_crtc(data, output, pipe, plane, false); mode = igt_output_get_mode(output); w = mode->hdisplay; h = mode->vdisplay; igt_calc_fb_size(fd, w, h, format, tiling, &size, &stride); /* * Make sure there is atleast 90% of the available GTT space left * for creating (MAX_FENCES+1) framebuffers. */ total_fbs_size = size * (MAX_FENCES + 1); total_aperture_size = gem_available_aperture_size(fd); igt_require(total_fbs_size < total_aperture_size * 0.9); for (i = 0; i < MAX_FENCES + 1; i++) { igt_create_fb(fd, w, h, format, tiling, &fb[i]); igt_plane_set_fb(plane, &fb[i]); igt_plane_set_rotation(plane, IGT_ROTATION_0); igt_display_commit2(display, COMMIT_ATOMIC); igt_plane_set_rotation(plane, IGT_ROTATION_90); igt_plane_set_size(plane, h, w); igt_display_commit2(display, COMMIT_ATOMIC); } for (i = 0; i < MAX_FENCES + 1; i++) igt_remove_fb(fd, &fb[i]); } static const char *plane_test_str(unsigned plane) { switch (plane) { case DRM_PLANE_TYPE_PRIMARY: return "primary"; case DRM_PLANE_TYPE_OVERLAY: return "sprite"; case DRM_PLANE_TYPE_CURSOR: return "cursor"; default: igt_assert(0); } } static const char *rot_test_str(igt_rotation_t rot) { switch (rot) { 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); } } static const char *tiling_test_str(uint64_t tiling) { switch (tiling) { case LOCAL_I915_FORMAT_MOD_X_TILED: return "x-tiled"; case LOCAL_I915_FORMAT_MOD_Y_TILED: return "y-tiled"; case LOCAL_I915_FORMAT_MOD_Yf_TILED: return "yf-tiled"; default: igt_assert(0); } } igt_main { struct rot_subtest { unsigned plane; igt_rotation_t rot; } *subtest, subtests[] = { { DRM_PLANE_TYPE_PRIMARY, IGT_ROTATION_90 }, { DRM_PLANE_TYPE_PRIMARY, IGT_ROTATION_180 }, { DRM_PLANE_TYPE_PRIMARY, IGT_ROTATION_270 }, { DRM_PLANE_TYPE_OVERLAY, IGT_ROTATION_90 }, { DRM_PLANE_TYPE_OVERLAY, IGT_ROTATION_180 }, { DRM_PLANE_TYPE_OVERLAY, IGT_ROTATION_270 }, { DRM_PLANE_TYPE_CURSOR, IGT_ROTATION_180 }, { 0, 0} }; struct reflect_x { uint64_t tiling; igt_rotation_t rot; } *reflect_x, reflect_x_subtests[] = { { LOCAL_I915_FORMAT_MOD_X_TILED, IGT_ROTATION_0 }, { LOCAL_I915_FORMAT_MOD_X_TILED, IGT_ROTATION_180 }, { LOCAL_I915_FORMAT_MOD_Y_TILED, IGT_ROTATION_0 }, { LOCAL_I915_FORMAT_MOD_Y_TILED, IGT_ROTATION_90 }, { LOCAL_I915_FORMAT_MOD_Y_TILED, IGT_ROTATION_180 }, { LOCAL_I915_FORMAT_MOD_Y_TILED, IGT_ROTATION_270 }, { LOCAL_I915_FORMAT_MOD_Yf_TILED, IGT_ROTATION_0 }, { LOCAL_I915_FORMAT_MOD_Yf_TILED, IGT_ROTATION_90 }, { LOCAL_I915_FORMAT_MOD_Yf_TILED, IGT_ROTATION_180 }, { LOCAL_I915_FORMAT_MOD_Yf_TILED, IGT_ROTATION_270 }, { 0, 0 } }; data_t data = {}; int gen = 0; igt_skip_on_simulation(); igt_fixture { data.gfx_fd = drm_open_driver_master(DRIVER_INTEL); data.devid = intel_get_drm_devid(data.gfx_fd); gen = intel_gen(data.devid); kmstest_set_vt_graphics_mode(); igt_require_pipe_crc(data.gfx_fd); igt_display_require(&data.display, data.gfx_fd); } for (subtest = subtests; subtest->rot; subtest++) { igt_subtest_f("%s-rotation-%s", plane_test_str(subtest->plane), rot_test_str(subtest->rot)) { igt_require(!(subtest->rot & (IGT_ROTATION_90 | IGT_ROTATION_270)) || gen >= 9); data.rotation = subtest->rot; test_plane_rotation(&data, subtest->plane, false); } } igt_subtest_f("sprite-rotation-90-pos-100-0") { igt_require(gen >= 9); data.rotation = IGT_ROTATION_90; data.pos_x = 100, data.pos_y = 0; test_plane_rotation(&data, DRM_PLANE_TYPE_OVERLAY, false); } data.pos_x = 0, data.pos_y = 0; igt_subtest_f("bad-pixel-format") { /* gen11 enables RGB565 rotation for 90/270 degrees. * so apart from this, any other gen11+ pixel format * can be used which doesn't support 90/270 degree * rotation */ igt_require(gen >= 9); data.rotation = IGT_ROTATION_90; data.override_fmt = gen < 11 ? DRM_FORMAT_RGB565 : DRM_FORMAT_Y212; test_plane_rotation(&data, DRM_PLANE_TYPE_PRIMARY, true); } data.override_fmt = 0; igt_subtest_f("bad-tiling") { igt_require(gen >= 9); data.rotation = IGT_ROTATION_90; data.override_tiling = LOCAL_I915_FORMAT_MOD_X_TILED; test_plane_rotation(&data, DRM_PLANE_TYPE_PRIMARY, true); } data.override_tiling = 0; for (reflect_x = reflect_x_subtests; reflect_x->tiling; reflect_x++) { igt_subtest_f("primary-%s-reflect-x-%s", tiling_test_str(reflect_x->tiling), rot_test_str(reflect_x->rot)) { igt_require(gen >= 10 || (IS_CHERRYVIEW(data.devid) && reflect_x->rot == IGT_ROTATION_0 && reflect_x->tiling == LOCAL_I915_FORMAT_MOD_X_TILED)); data.rotation = (IGT_REFLECT_X | reflect_x->rot); data.override_tiling = reflect_x->tiling; test_plane_rotation(&data, DRM_PLANE_TYPE_PRIMARY, false); } } igt_subtest_f("multiplane-rotation") { igt_require(gen >= 9); cleanup_crtc(&data); data.planepos[0].origo = p_top | p_left; data.planepos[0].x = .2f; data.planepos[0].y = .1f; data.planepos[1].origo = p_top | p_right; data.planepos[1].x = -.4f; data.planepos[1].y = .1f; test_multi_plane_rotation(&data, 0); } igt_subtest_f("multiplane-rotation-cropping-top") { igt_require(gen >= 9); cleanup_crtc(&data); data.planepos[0].origo = p_top | p_left; data.planepos[0].x = -.05f; data.planepos[0].y = -.15f; data.planepos[1].origo = p_top | p_right; data.planepos[1].x = -.15f; data.planepos[1].y = -.15f; test_multi_plane_rotation(&data, 0); } igt_subtest_f("multiplane-rotation-cropping-bottom") { igt_require(gen >= 9); cleanup_crtc(&data); data.planepos[0].origo = p_bottom | p_left; data.planepos[0].x = -.05f; data.planepos[0].y = -.20f; data.planepos[1].origo = p_bottom | p_right; data.planepos[1].x = -.15f; data.planepos[1].y = -.20f; test_multi_plane_rotation(&data, 0); } /* * exhaust-fences should be last test, if it fails we may OOM in * the following subtests otherwise. */ igt_subtest_f("exhaust-fences") { enum pipe pipe; igt_output_t *output; igt_require(gen >= 9); igt_display_require_output(&data.display); for_each_pipe_with_valid_output(&data.display, pipe, output) { igt_plane_t *primary = &data.display.pipes[pipe].planes[0]; test_plane_rotation_exhaust_fences(&data, pipe, output, primary); break; } } igt_fixture { igt_display_fini(&data.display); } }