/* * Copyright 2018 Advanced Micro Devices, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice 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 COPYRIGHT HOLDER(S) OR AUTHOR(S) 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 "sw_sync.h" #include #include #define NSECS_PER_SEC (1000000000ull) /* * Each test measurement step runs for ~5 seconds. * This gives a decent sample size + enough time for any adaptation to occur if necessary. */ #define TEST_DURATION_NS (5000000000ull) enum { TEST_NONE = 0, TEST_DPMS = 1 << 0, TEST_SUSPEND = 1 << 1, }; typedef struct range { unsigned int min; unsigned int max; } range_t; typedef struct data { igt_display_t display; int drm_fd; igt_fb_t fb0; igt_fb_t fb1; } data_t; typedef void (*test_t)(data_t*, enum pipe, igt_output_t*, uint32_t); /* Converts a timespec structure to nanoseconds. */ static uint64_t timespec_to_ns(struct timespec *ts) { return ts->tv_sec * NSECS_PER_SEC + ts->tv_nsec; } /* * Gets a vblank event from DRM and returns its timestamp in nanoseconds. * This blocks until the event is received. */ static uint64_t get_vblank_event_ns(data_t *data) { struct drm_event_vblank ev; igt_set_timeout(1, "Waiting for vblank event\n"); igt_assert_eq(read(data->drm_fd, &ev, sizeof(ev)), sizeof(ev)); igt_reset_timeout(); return ev.tv_sec * NSECS_PER_SEC + ev.tv_usec * 1000ull; } /* * Returns the current CLOCK_MONOTONIC time in nanoseconds. * The regular IGT helpers can't be used since they default to * CLOCK_MONOTONIC_RAW - which isn't what the kernel uses for its timestamps. */ static uint64_t get_time_ns(void) { struct timespec ts; memset(&ts, 0, sizeof(ts)); errno = 0; if (!clock_gettime(CLOCK_MONOTONIC, &ts)) return timespec_to_ns(&ts); igt_warn("Could not read monotonic time: %s\n", strerror(errno)); igt_fail(-errno); return 0; } /* Returns the rate duration in nanoseconds for the given refresh rate. */ static uint64_t rate_from_refresh(uint64_t refresh) { return NSECS_PER_SEC / refresh; } /* Returns the min and max vrr range from the connector debugfs. */ static range_t get_vrr_range(data_t *data, igt_output_t *output) { char buf[256]; char *start_loc; int fd, res; range_t range; fd = igt_debugfs_connector_dir(data->drm_fd, output->name, O_RDONLY); igt_assert(fd >= 0); res = igt_debugfs_simple_read(fd, "vrr_range", buf, sizeof(buf)); igt_require(res > 0); close(fd); igt_assert(start_loc = strstr(buf, "Min: ")); igt_assert_eq(sscanf(start_loc, "Min: %u", &range.min), 1); igt_assert(start_loc = strstr(buf, "Max: ")); igt_assert_eq(sscanf(start_loc, "Max: %u", &range.max), 1); return range; } /* Returns a suitable vrr test frequency. */ static uint32_t get_test_rate_ns(data_t *data, igt_output_t *output) { drmModeModeInfo *mode = igt_output_get_mode(output); range_t range; uint32_t vtest; /* * The frequency with the fastest convergence speed should be * the midpoint between the current mode vfreq and the min * supported vfreq. */ range = get_vrr_range(data, output); igt_require(mode->vrefresh > range.min); vtest = (mode->vrefresh - range.min) / 2 + range.min; igt_require(vtest < mode->vrefresh); return rate_from_refresh(vtest); } /* Returns true if an output supports VRR. */ static bool has_vrr(igt_output_t *output) { return igt_output_has_prop(output, IGT_CONNECTOR_VRR_CAPABLE) && igt_output_get_prop(output, IGT_CONNECTOR_VRR_CAPABLE); } /* Toggles variable refresh rate on the pipe. */ static void set_vrr_on_pipe(data_t *data, enum pipe pipe, bool enabled) { igt_pipe_set_prop_value(&data->display, pipe, IGT_CRTC_VRR_ENABLED, enabled); igt_display_commit_atomic(&data->display, 0, NULL); } /* Prepare the display for testing on the given pipe. */ static void prepare_test(data_t *data, igt_output_t *output, enum pipe pipe) { drmModeModeInfo mode = *igt_output_get_mode(output); igt_plane_t *primary; cairo_t *cr; /* Reset output */ igt_display_reset(&data->display); igt_output_set_pipe(output, pipe); /* Prepare resources */ igt_create_color_fb(data->drm_fd, mode.hdisplay, mode.vdisplay, DRM_FORMAT_XRGB8888, LOCAL_DRM_FORMAT_MOD_NONE, 0.50, 0.50, 0.50, &data->fb0); igt_create_color_fb(data->drm_fd, mode.hdisplay, mode.vdisplay, DRM_FORMAT_XRGB8888, LOCAL_DRM_FORMAT_MOD_NONE, 0.50, 0.50, 0.50, &data->fb1); cr = igt_get_cairo_ctx(data->drm_fd, &data->fb0); igt_paint_color(cr, 0, 0, mode.hdisplay / 10, mode.vdisplay / 10, 1.00, 0.00, 0.00); igt_put_cairo_ctx(data->drm_fd, &data->fb0, cr); /* Take care of any required modesetting before the test begins. */ primary = igt_output_get_plane_type(output, DRM_PLANE_TYPE_PRIMARY); igt_plane_set_fb(primary, &data->fb0); igt_display_commit_atomic(&data->display, DRM_MODE_ATOMIC_ALLOW_MODESET, NULL); } /* Waits for the vblank interval. Returns the vblank timestamp in ns. */ static uint64_t wait_for_vblank(data_t *data, enum pipe pipe) { drmVBlank vbl = {}; vbl.request.type = kmstest_get_vbl_flag(pipe); vbl.request.type |= DRM_VBLANK_RELATIVE | DRM_VBLANK_EVENT; vbl.request.sequence = 1; drmWaitVBlank(data->drm_fd, &vbl); return get_vblank_event_ns(data); } /* Performs an asynchronous non-blocking page-flip on a pipe. */ static int do_flip(data_t *data, enum pipe pipe_id, igt_fb_t *fb) { igt_pipe_t *pipe = &data->display.pipes[pipe_id]; int ret; igt_set_timeout(1, "Scheduling page flip\n"); /* * Only the legacy flip ioctl supports async flips. * It's also non-blocking, but returns -EBUSY if flipping too fast. * 2x monitor tests will need async flips in the atomic API. */ do { ret = drmModePageFlip(data->drm_fd, pipe->crtc_id, fb->fb_id, DRM_MODE_PAGE_FLIP_EVENT | DRM_MODE_PAGE_FLIP_ASYNC, data); } while (ret == -EBUSY); igt_assert_eq(ret, 0); igt_reset_timeout(); return 0; } /* * Flips at the given rate and measures against the expected value. * Returns the pass rate as a percentage from 0 - 100. * * The VRR API is quite flexible in terms of definition - the driver * can arbitrarily restrict the bounds further than the absolute * min and max range. But VRR is really about extending the flip * to prevent stuttering or to match a source content rate. * * The only way to "present" at a fixed rate like userspace in a vendor * neutral manner is to do it with async flips. This avoids the need * to wait for next vblank and it should eventually converge at the * desired rate. */ static uint32_t flip_and_measure(data_t *data, igt_output_t *output, enum pipe pipe, uint64_t rate_ns, uint64_t duration_ns) { uint64_t start_ns, last_vblank_ns; uint32_t total_flip = 0, total_pass = 0; bool front = false; /* Align with the vblank region to speed up convergence. */ last_vblank_ns = wait_for_vblank(data, pipe); start_ns = get_time_ns(); for (;;) { uint64_t now_ns, vblank_ns, wait_ns, target_ns; int64_t diff_ns; front = !front; do_flip(data, pipe, front ? &data->fb1 : &data->fb0); vblank_ns = get_vblank_event_ns(data); diff_ns = rate_ns - (vblank_ns - last_vblank_ns); last_vblank_ns = vblank_ns; total_flip += 1; /* * Check if the difference between the two flip timestamps * was within the required threshold from the expected rate. * * A ~50us threshold is arbitrary, but it's roughly the * difference between 144Hz and 143Hz which should give this * enough accuracy for most use cases. */ if (llabs(diff_ns) < 50000ll) total_pass += 1; now_ns = get_time_ns(); if (now_ns - start_ns > duration_ns) break; /* * Burn CPU until next timestamp, sleeping isn't accurate enough. * It's worth noting that the target timestamp is based on absolute * timestamp rather than a delta to avoid accumulation errors. */ diff_ns = now_ns - start_ns; wait_ns = ((diff_ns + rate_ns - 1) / rate_ns) * rate_ns; target_ns = start_ns + wait_ns - 10; while (get_time_ns() < target_ns); } igt_info("Completed %u flips, %u were in threshold for %luns.\n", total_flip, total_pass, rate_ns); return total_flip ? ((total_pass * 100) / total_flip) : 0; } /* Basic VRR flip functionality test - enable, measure, disable, measure */ static void test_basic(data_t *data, enum pipe pipe, igt_output_t *output, uint32_t flags) { uint64_t rate; uint32_t result; rate = get_test_rate_ns(data, output); prepare_test(data, output, pipe); set_vrr_on_pipe(data, pipe, 1); /* * Do a short run with VRR, but don't check the result. * This is to make sure we were actually in the middle of * active flipping before doing the DPMS/suspend steps. */ flip_and_measure(data, output, pipe, rate, 250000000ull); if (flags & TEST_DPMS) { kmstest_set_connector_dpms(output->display->drm_fd, output->config.connector, DRM_MODE_DPMS_OFF); kmstest_set_connector_dpms(output->display->drm_fd, output->config.connector, DRM_MODE_DPMS_ON); } if (flags & TEST_SUSPEND) igt_system_suspend_autoresume(SUSPEND_STATE_MEM, SUSPEND_TEST_NONE); result = flip_and_measure(data, output, pipe, rate, TEST_DURATION_NS); set_vrr_on_pipe(data, pipe, 0); /* This check is delayed until after VRR is disabled so it isn't * left enabled if the test fails. */ igt_assert_f(result > 75, "Target VRR on threshold not reached, result was %u%%\n", result); result = flip_and_measure(data, output, pipe, rate, TEST_DURATION_NS); igt_assert_f(result < 10, "Target VRR off threshold exceeded, result was %u%%\n", result); igt_remove_fb(data->drm_fd, &data->fb1); igt_remove_fb(data->drm_fd, &data->fb0); } /* Runs tests on outputs that are VRR capable. */ static void run_vrr_test(data_t *data, test_t test, uint32_t flags) { igt_output_t *output; bool found = false; for_each_connected_output(&data->display, output) { enum pipe pipe; if (!has_vrr(output)) continue; for_each_pipe(&data->display, pipe) if (igt_pipe_connector_valid(pipe, output)) { test(data, pipe, output, flags); found = true; break; } } if (!found) igt_skip("No vrr capable outputs found.\n"); } igt_main { data_t data = { 0 }; igt_skip_on_simulation(); igt_fixture { data.drm_fd = drm_open_driver_master(DRIVER_ANY); kmstest_set_vt_graphics_mode(); igt_display_require(&data.display, data.drm_fd); igt_require(data.display.is_atomic); igt_display_require_output(&data.display); } igt_subtest("flip-basic") run_vrr_test(&data, test_basic, 0); igt_subtest("flip-dpms") run_vrr_test(&data, test_basic, TEST_DPMS); igt_subtest("flip-suspend") run_vrr_test(&data, test_basic, TEST_SUSPEND); igt_fixture { igt_display_fini(&data.display); } }