/* * Copyright (c) 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. * */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include #include #include #include #include #include #if HAVE_X11_EXTENSIONS_SHMPROTO_H #include #elif HAVE_X11_EXTENSIONS_SHMSTR_H #include #else #error Failed to find the right header for X11 MIT-SHM protocol definitions #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "dri3.h" #define ALIGN(x, y) (((x) + (y) - 1) & -(y)) #define PAGE_ALIGN(x) ALIGN(x, 4096) #define GTT I915_GEM_DOMAIN_GTT #define CPU I915_GEM_DOMAIN_CPU static int _x_error_occurred; static uint32_t stamp; static int _check_error_handler(Display *display, XErrorEvent *event) { printf("X11 error from display %s, serial=%ld, error=%d, req=%d.%d\n", DisplayString(display), event->serial, event->error_code, event->request_code, event->minor_code); _x_error_occurred++; return False; /* ignored */ } static int is_i915_device(int fd) { drm_version_t version; char name[5] = ""; memset(&version, 0, sizeof(version)); version.name_len = 4; version.name = name; if (drmIoctl(fd, DRM_IOCTL_VERSION, &version)) return 0; return strcmp("i915", name) == 0; } static int is_intel(int fd) { struct drm_i915_getparam gp; int ret; /* Confirm that this is a i915.ko device with GEM/KMS enabled */ ret = is_i915_device(fd); if (ret) { gp.param = I915_PARAM_HAS_GEM; gp.value = &ret; if (drmIoctl(fd, DRM_IOCTL_I915_GETPARAM, &gp)) ret = 0; } return ret; } static void *setup_msc(Display *dpy, Window win) { xcb_connection_t *c = XGetXCBConnection(dpy); xcb_void_cookie_t cookie; uint32_t id = xcb_generate_id(c); xcb_generic_error_t *error; void *q; cookie = xcb_present_select_input_checked(c, id, win, XCB_PRESENT_EVENT_MASK_COMPLETE_NOTIFY); q = xcb_register_for_special_xge(c, &xcb_present_id, id, &stamp); error = xcb_request_check(c, cookie); assert(error == NULL); return q; } static uint64_t check_msc(Display *dpy, Window win, void *q, uint64_t last_msc, uint64_t *ust) { xcb_connection_t *c = XGetXCBConnection(dpy); static uint32_t serial = 1; uint64_t msc = 0; int complete = 0; xcb_present_notify_msc(c, win, serial ^ 0xcc00ffee, 0, 0, 0); xcb_flush(c); do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; if (ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC && ce->serial == (serial ^ 0xcc00ffee)) { msc = ce->msc; if (ust) *ust = ce->ust; complete = 1; } free(ev); } while (!complete); if ((int64_t)(msc - last_msc) < 0) { printf("Invalid MSC: was %llu, now %llu\n", (long long)last_msc, (long long)msc); } if (++serial == 0) serial = 1; return msc; } static uint64_t wait_vblank(Display *dpy, Window win, void *q) { xcb_connection_t *c = XGetXCBConnection(dpy); static uint32_t serial = 1; uint64_t msc = 0; int complete = 0; xcb_present_notify_msc(c, win, serial ^ 0xdeadbeef, 0, 1, 0); xcb_flush(c); do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; if (ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC && ce->serial == (serial ^ 0xdeadbeef)) { msc = ce->msc; complete = 1; } free(ev); } while (!complete); if (++serial == 0) serial = 1; return msc; } static uint64_t msc_interval(Display *dpy, Window win, void *q) { xcb_connection_t *c = XGetXCBConnection(dpy); uint64_t msc, ust; int complete = 0; msc = check_msc(dpy, win, q, 0, NULL); xcb_present_notify_msc(c, win, 0xc0ffee00, msc, 0, 0); xcb_present_notify_msc(c, win, 0xc0ffee01, msc + 10, 0, 0); xcb_flush(c); ust = msc = 0; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; if (ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC && ce->serial == 0xc0ffee00) { msc -= ce->msc; ust -= ce->ust; complete++; } if (ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC && ce->serial == 0xc0ffee01) { msc += ce->msc; ust += ce->ust; complete++; } free(ev); } while (complete != 2); printf("10 frame interval: msc=%lld, ust=%lld\n", (long long)msc, (long long)ust); XSync(dpy, True); if (msc == 0) return 0; return (ust + msc/2) / msc; } static void teardown_msc(Display *dpy, void *q) { xcb_unregister_for_special_event(XGetXCBConnection(dpy), q); } static int test_whole(Display *dpy, Window win, const char *phase) { xcb_connection_t *c = XGetXCBConnection(dpy); Pixmap pixmap; struct dri3_fence fence; Window root; unsigned int width, height; unsigned border, depth; int x, y, ret = 1; XGetGeometry(dpy, win, &root, &x, &y, &width, &height, &border, &depth); if (dri3_create_fence(dpy, win, &fence)) return 0; printf("%s: Testing simple flip: %dx%d\n", phase, width, height); _x_error_occurred = 0; xshmfence_reset(fence.addr); pixmap = XCreatePixmap(dpy, win, width, height, depth); xcb_present_pixmap(c, win, pixmap, 0, 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ fence.xid, XCB_PRESENT_OPTION_NONE, 0, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); XFreePixmap(dpy, pixmap); pixmap = XCreatePixmap(dpy, win, width, height, depth); xcb_present_pixmap(c, win, pixmap, 0, 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, /* sync fence */ XCB_PRESENT_OPTION_NONE, 0, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); XFreePixmap(dpy, pixmap); XFlush(dpy); ret = !!xshmfence_await(fence.addr); dri3_fence_free(dpy, &fence); XSync(dpy, True); ret += !!_x_error_occurred; return ret; } static uint64_t flush_flips(Display *dpy, Window win, Pixmap pixmap, void *Q, uint64_t *ust) { xcb_connection_t *c = XGetXCBConnection(dpy); uint64_t msc; int complete; msc = check_msc(dpy, win, Q, 0, NULL); xcb_present_pixmap(c, win, pixmap, 0xdeadbeef, /* serial */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, msc + 60, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); xcb_flush(c); complete = 0; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; complete = (ce->kind == XCB_PRESENT_COMPLETE_KIND_PIXMAP && ce->serial == 0xdeadbeef); free(ev); } while (!complete); XSync(dpy, True); return check_msc(dpy, win, Q, msc, ust); } static int test_double(Display *dpy, Window win, const char *phase, void *Q) { #define COUNT (15*60) xcb_connection_t *c = XGetXCBConnection(dpy); Pixmap pixmap; Window root; unsigned int width, height; unsigned border, depth; int x, y, n, ret; struct { uint64_t msc, ust; } frame[COUNT+1]; int offset = 0; XGetGeometry(dpy, win, &root, &x, &y, &width, &height, &border, &depth); printf("%s: Testing flip double buffering: %dx%d\n", phase, width, height); _x_error_occurred = 0; pixmap = XCreatePixmap(dpy, win, width, height, depth); flush_flips(dpy, win, pixmap, Q, NULL); for (n = 0; n <= COUNT; n++) { int complete; xcb_present_pixmap(c, win, pixmap, n, 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, 0, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); xcb_flush(c); complete = 0; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; if (ce->kind == XCB_PRESENT_COMPLETE_KIND_PIXMAP && ce->serial == n) { frame[n].msc = ce->msc; frame[n].ust = ce->ust; complete = 1; } free(ev); } while (!complete); } XFreePixmap(dpy, pixmap); XSync(dpy, True); ret = !!_x_error_occurred; if (frame[COUNT].msc - frame[0].msc != COUNT) { printf("Expected %d frames interval, %d elapsed instead\n", COUNT, (int)(frame[COUNT].msc - frame[0].msc)); for (n = 0; n <= COUNT; n++) { if (frame[n].msc - frame[0].msc != n + offset) { printf("frame[%d]: msc=%03lld, ust=%lld\n", n, (long long)(frame[n].msc - frame[0].msc), (long long)(frame[n].ust - frame[0].ust)); offset = frame[n].msc - frame[0].msc - n; ret++; } } } return ret; } static int test_future(Display *dpy, Window win, const char *phase, void *Q) { xcb_connection_t *c = XGetXCBConnection(dpy); Pixmap pixmap; struct dri3_fence fence; Window root; unsigned int width, height; unsigned border, depth; int x, y, ret = 0, n; uint64_t msc, ust; int complete, count; int early = 0, late = 0; int earliest = 0, latest = 0; uint64_t interval; XGetGeometry(dpy, win, &root, &x, &y, &width, &height, &border, &depth); if (dri3_create_fence(dpy, win, &fence)) return 0; printf("%s: Testing flips into the future: %dx%d\n", phase, width, height); _x_error_occurred = 0; interval = msc_interval(dpy, win, Q); if (interval == 0) { printf("Zero delay between frames\n"); return 1; } pixmap = XCreatePixmap(dpy, win, width, height, depth); msc = flush_flips(dpy, win, pixmap, Q, &ust); for (n = 1; n <= 10; n++) xcb_present_pixmap(c, win, pixmap, n, /* serial */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, msc + 60 + n*15*60, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); xcb_present_pixmap(c, win, pixmap, 0xdeadbeef, /* serial */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, msc + 60 + n*15*60, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); xcb_flush(c); complete = 0; count = 0; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_PIXMAP); if (ce->serial == 0xdeadbeef) { int64_t time; time = ce->ust - (ust + (60 + 15*60*n) * interval); if (time < -(int64_t)interval) { fprintf(stderr, "\tflips completed too early by %lldms\n", (long long)(-time / 1000)); } else if (time > (int64_t)interval) { fprintf(stderr, "\tflips completed too late by %lldms\n", (long long)(time / 1000)); } complete = 1; } else { int diff = (int64_t)(ce->msc - (15*60*ce->serial + msc + 60)); if (diff < 0) { if (-diff > earliest) { fprintf(stderr, "\tframe %d displayed early by %d frames\n", ce->serial, -diff); earliest = -diff; } early++; ret++; } else if (diff > 0) { if (diff > latest) { fprintf(stderr, "\tframe %d displayed late by %d frames\n", ce->serial, diff); latest = diff; } late++; ret++; } count++; } free(ev); } while (!complete); if (early) printf("\t%d frames shown too early (worst %d)!\n", early, earliest); if (late) printf("\t%d frames shown too late (worst %d)!\n", late, latest); if (count != 10) { fprintf(stderr, "Sentinel frame received too early! %d frames outstanding\n", 10 - count); ret++; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_PIXMAP); free(ev); } while (++count != 10); } ret += !!_x_error_occurred; return ret; } static int test_exhaustion(Display *dpy, Window win, const char *phase, void *Q) { #define N_VBLANKS 256 /* kernel event queue length: 128 vblanks */ xcb_connection_t *c = XGetXCBConnection(dpy); Pixmap pixmap; struct dri3_fence fence[2]; Window root; xcb_xfixes_region_t region; unsigned int width, height; unsigned border, depth; int x, y, ret = 0, n; uint64_t target, final; XGetGeometry(dpy, win, &root, &x, &y, &width, &height, &border, &depth); if (dri3_create_fence(dpy, win, &fence[0]) || dri3_create_fence(dpy, win, &fence[1])) return 0; printf("%s: Testing flips with long vblank queues: %dx%d\n", phase, width, height); _x_error_occurred = 0; region = xcb_generate_id(c); xcb_xfixes_create_region(c, region, 0, NULL); pixmap = XCreatePixmap(dpy, win, width, height, depth); xshmfence_reset(fence[0].addr); xshmfence_reset(fence[1].addr); target = check_msc(dpy, win, Q, 0, NULL); for (n = N_VBLANKS; n--; ) xcb_present_pixmap(c, win, pixmap, 0, 0, /* valid */ region, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, target + N_VBLANKS, /* target msc */ 1, /* divisor */ 0, /* remainder */ 0, NULL); xcb_present_pixmap(c, win, pixmap, 0, region, /* valid */ region, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ fence[0].xid, XCB_PRESENT_OPTION_NONE, target, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); for (n = 1; n < N_VBLANKS; n++) xcb_present_pixmap(c, win, pixmap, 0, region, /* valid */ region, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, target + n, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); xcb_present_pixmap(c, win, pixmap, 0, region, /* valid */ region, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ fence[1].xid, XCB_PRESENT_OPTION_NONE, target + N_VBLANKS, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); xcb_flush(c); ret += !!xshmfence_await(fence[0].addr); final = check_msc(dpy, win, Q, 0, NULL); if (final < target) { printf("\tFirst flip too early, MSC was %llu, expected %llu\n", (long long)final, (long long)target); ret++; } else if (final > target + 1) { printf("\tFirst flip too late, MSC was %llu, expected %llu\n", (long long)final, (long long)target); ret++; } ret += !!xshmfence_await(fence[1].addr); final = check_msc(dpy, win, Q, 0, NULL); if (final < target + N_VBLANKS) { printf("\tLast flip too early, MSC was %llu, expected %llu\n", (long long)final, (long long)(target + N_VBLANKS)); ret++; } else if (final > target + N_VBLANKS + 1) { printf("\tLast flip too late, MSC was %llu, expected %llu\n", (long long)final, (long long)(target + N_VBLANKS)); ret++; } flush_flips(dpy, win, pixmap, Q, NULL); XFreePixmap(dpy, pixmap); xcb_xfixes_destroy_region(c, region); dri3_fence_free(dpy, &fence[1]); dri3_fence_free(dpy, &fence[0]); XSync(dpy, True); ret += !!_x_error_occurred; return ret; #undef N_VBLANKS } static int test_accuracy(Display *dpy, Window win, const char *phase, void *Q) { #define N_VBLANKS (60 * 120) /* ~2 minutes */ xcb_connection_t *c = XGetXCBConnection(dpy); Pixmap pixmap; Window root; unsigned int width, height; unsigned border, depth; int x, y, ret = 0, n; uint64_t target; int early = 0, late = 0; int earliest = 0, latest = 0; int complete, count; XGetGeometry(dpy, win, &root, &x, &y, &width, &height, &border, &depth); printf("%s: Testing flip accuracy: %dx%d\n", phase, width, height); _x_error_occurred = 0; pixmap = XCreatePixmap(dpy, win, width, height, depth); target = flush_flips(dpy, win, pixmap, Q, NULL); for (n = 0; n <= N_VBLANKS; n++) xcb_present_pixmap(c, win, pixmap, n, /* serial */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, target + 60 + n, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); xcb_present_pixmap(c, win, pixmap, 0xdeadbeef, /* serial */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, target + 60 + n, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); xcb_flush(c); complete = 0; count = 0; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_PIXMAP); if (ce->serial != 0xdeadbeef) { int diff = (int64_t)(ce->msc - (target + ce->serial + 60)); if (diff < 0) { if (-diff > earliest) { fprintf(stderr, "\tframe %d displayed early by %d frames\n", ce->serial, -diff); earliest = -diff; } early++; ret++; } else if (diff > 0) { if (diff > latest) { fprintf(stderr, "\tframe %d displayed late by %d frames\n", ce->serial, diff); latest = diff; } late++; ret++; } count++; } else complete = 1; free(ev); } while (!complete); if (early) printf("\t%d frames shown too early (worst %d)!\n", early, earliest); if (late) printf("\t%d frames shown too late (worst %d)!\n", late, latest); if (count != N_VBLANKS+1) { fprintf(stderr, "Sentinel frame received too early! %d frames outstanding\n", N_VBLANKS+1 - count); ret++; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_PIXMAP); free(ev); } while (++count != N_VBLANKS+1); } XFreePixmap(dpy, pixmap); XSync(dpy, True); ret += !!_x_error_occurred; return ret; #undef N_VBLANKS } static int test_modulus(Display *dpy, Window win, const char *phase, void *Q) { xcb_connection_t *c = XGetXCBConnection(dpy); Pixmap pixmap; Window root; unsigned int width, height; unsigned border, depth; xcb_xfixes_region_t region; int x, y, ret = 0; uint64_t target; int early = 0, late = 0; int earliest = 0, latest = 0; int complete, expect, count; XGetGeometry(dpy, win, &root, &x, &y, &width, &height, &border, &depth); printf("%s: Testing flip modulus: %dx%d\n", phase, width, height); _x_error_occurred = 0; region = xcb_generate_id(c); xcb_xfixes_create_region(c, region, 0, NULL); pixmap = XCreatePixmap(dpy, win, width, height, depth); target = flush_flips(dpy, win, pixmap, Q, NULL); expect = 0; for (x = 1; x <= 7; x++) { for (y = 0; y < x; y++) { xcb_present_pixmap(c, win, pixmap, y << 16 | x, /* serial */ region, /* valid */ region, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, 0, /* target msc */ x, /* divisor */ y, /* remainder */ 0, NULL); expect++; } } xcb_present_pixmap(c, win, pixmap, 0xdeadbeef, /* serial */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, target + 2*x, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); xcb_flush(c); complete = 0; count = 0; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; if (ce->kind != XCB_PRESENT_COMPLETE_KIND_PIXMAP) break; assert(ce->serial); if (ce->serial != 0xdeadbeef) { uint64_t msc; int diff; x = ce->serial & 0xffff; y = ce->serial >> 16; msc = target; msc -= target % x; msc += y; if (msc <= target) msc += x; diff = (int64_t)(ce->msc - msc); if (diff < 0) { if (-diff > earliest) { fprintf(stderr, "\tframe (%d, %d) displayed early by %d frames\n", y, x, -diff); earliest = -diff; } early++; ret++; } else if (diff > 0) { if (diff > latest) { fprintf(stderr, "\tframe (%d, %d) displayed late by %d frames\n", y, x, diff); latest = diff; } late++; ret++; } count++; } else complete = 1; free(ev); } while (!complete); if (early) printf("\t%d frames shown too early (worst %d)!\n", early, earliest); if (late) printf("\t%d frames shown too late (worst %d)!\n", late, latest); if (count != expect) { fprintf(stderr, "Sentinel frame received too early! %d frames outstanding\n", expect - count); ret++; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC); free(ev); } while (++count != expect); } XFreePixmap(dpy, pixmap); xcb_xfixes_destroy_region(c, region); XSync(dpy, True); ret += !!_x_error_occurred; return ret; } static int test_future_msc(Display *dpy, void *Q) { xcb_connection_t *c = XGetXCBConnection(dpy); Window root = DefaultRootWindow(dpy); int ret = 0, n; uint64_t msc, ust; int complete, count; int early = 0, late = 0; int earliest = 0, latest = 0; uint64_t interval; printf("Testing notifies into the future\n"); _x_error_occurred = 0; interval = msc_interval(dpy, root, Q); if (interval == 0) { printf("Zero delay between frames\n"); return 1; } msc = check_msc(dpy, root, Q, 0, &ust); printf("Initial msc=%llx, interval between frames %lldus\n", (long long)msc, (long long)interval); for (n = 1; n <= 10; n++) xcb_present_notify_msc(c, root, n, msc + 60 + n*15*60, 0, 0); xcb_present_notify_msc(c, root, 0xdeadbeef, msc + 60 + n*15*60, 0, 0); xcb_flush(c); complete = 0; count = 0; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC); if (ce->serial == 0xdeadbeef) { int64_t time, tolerance; tolerance = 60 + 15*60*n/10; if (tolerance < interval) tolerance = interval; time = ce->ust - (ust + (60 + 15*60*n) * interval); if (time < -(int64_t)tolerance) { fprintf(stderr, "\tnotifies completed too early by %lldms, tolerance %lldus\n", (long long)(-time / 1000), (long long)tolerance); } else if (time > (int64_t)tolerance) { fprintf(stderr, "\tnotifies completed too late by %lldms, tolerance %lldus\n", (long long)(time / 1000), (long long)tolerance); } complete = 1; } else { int diff = (int64_t)(ce->msc - (15*60*ce->serial + msc + 60)); if (ce->serial != count + 1) { fprintf(stderr, "vblank received out of order! expected %d, received %d\n", count + 1, (int)ce->serial); ret++; } count++; if (diff < 0) { if (-diff > earliest) { fprintf(stderr, "\tnotify %d early by %d msc\n", ce->serial, -diff); earliest = -diff; } early++; ret++; } else if (diff > 0) { if (diff > latest) { fprintf(stderr, "\tnotify %d late by %d msc\n", ce->serial, diff); latest = diff; } late++; ret++; } } free(ev); } while (!complete); if (early) printf("\t%d notifies too early (worst %d)!\n", early, earliest); if (late) printf("\t%d notifies too late (worst %d)!\n", late, latest); if (count != 10) { fprintf(stderr, "Sentinel vblank received too early! %d waits outstanding\n", 10 - count); ret++; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC); free(ev); } while (++count != 10); } XSync(dpy, True); ret += !!_x_error_occurred; return ret; } static int test_wrap_msc(Display *dpy) { xcb_connection_t *c = XGetXCBConnection(dpy); Window root, win; int x, y; unsigned int width, height; unsigned border, depth; XSetWindowAttributes attr; int ret = 0, n; uint64_t msc, ust; int complete; uint64_t interval; void *Q; XGetGeometry(dpy, DefaultRootWindow(dpy), &root, &x, &y, &width, &height, &border, &depth); attr.override_redirect = 1; win = XCreateWindow(dpy, root, 0, 0, width, height, 0, depth, InputOutput, DefaultVisual(dpy, DefaultScreen(dpy)), CWOverrideRedirect, &attr); XMapWindow(dpy, win); XSync(dpy, True); if (_x_error_occurred) return 1; printf("Testing wraparound notifies\n"); _x_error_occurred = 0; Q = setup_msc(dpy, win); interval = msc_interval(dpy, win, Q); if (interval == 0) { printf("Zero delay between frames\n"); return 1; } msc = check_msc(dpy, win, Q, 0, &ust); printf("Initial msc=%llx, interval between frames %lldus\n", (long long)msc, (long long)interval); for (n = 1; n <= 10; n++) xcb_present_notify_msc(c, win, n, msc + ((long long)n<<32) + n, 0, 0); for (n = 1; n <= 10; n++) xcb_present_notify_msc(c, win, -n, 0, (long long)n << 32, 0); xcb_present_notify_msc(c, win, 0xdeadbeef, msc + 60*10, 0, 0); xcb_flush(c); complete = 0; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC); if (ce->serial == 0xdeadbeef) { complete = 1; } else { fprintf(stderr, "\tnotify %d recieved at +%llu\n", ce->serial, ce->msc - msc); ret++; } free(ev); } while (!complete); teardown_msc(dpy, Q); XDestroyWindow(dpy, win); XSync(dpy, True); return ret; } static int test_exhaustion_msc(Display *dpy, void *Q) { #define N_VBLANKS 256 /* kernel event queue length: 128 vblanks */ xcb_connection_t *c = XGetXCBConnection(dpy); Window root = DefaultRootWindow(dpy); int ret = 0, n, complete; int earliest = 0, early = 0; int latest = 0, late = 0; uint64_t msc; printf("Testing notifies with long queues\n"); _x_error_occurred = 0; msc = check_msc(dpy, root, Q, 0, NULL); for (n = N_VBLANKS; n--; ) xcb_present_notify_msc(c, root, N_VBLANKS, msc + N_VBLANKS, 0, 0); for (n = 1; n <= N_VBLANKS ; n++) xcb_present_notify_msc(c, root, n, msc + n, 0, 0); xcb_flush(c); complete = 2*N_VBLANKS; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; int diff; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC); diff = (int64_t)(ce->msc - msc - ce->serial); if (diff < 0) { if (-diff > earliest) { fprintf(stderr, "\tnotify %d early by %d msc\n",(int)ce->serial, -diff); earliest = -diff; } early++; ret++; } else if (diff > 0) { if (diff > latest) { fprintf(stderr, "\tnotify %d late by %d msc\n", (int)ce->serial, diff); latest = diff; } late++; ret++; } free(ev); } while (--complete); if (early) printf("\t%d notifies too early (worst %d)!\n", early, earliest); if (late) printf("\t%d notifies too late (worst %d)!\n", late, latest); XSync(dpy, True); ret += !!_x_error_occurred; return ret; #undef N_VBLANKS } static int test_accuracy_msc(Display *dpy, void *Q) { #define N_VBLANKS (60 * 120) /* ~2 minutes */ xcb_connection_t *c = XGetXCBConnection(dpy); Window root = DefaultRootWindow(dpy); int ret = 0, n; uint64_t msc; int early = 0, late = 0; int earliest = 0, latest = 0; int complete, count; printf("Testing notify accuracy\n"); _x_error_occurred = 0; msc = check_msc(dpy, root, Q, 0, NULL); for (n = 0; n <= N_VBLANKS; n++) xcb_present_notify_msc(c, root, n, msc + 60 + n, 0, 0); xcb_present_notify_msc(c, root, 0xdeadbeef, msc + 60 + n, 0, 0); xcb_flush(c); complete = 0; count = 0; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC); if (ce->serial != 0xdeadbeef) { int diff = (int64_t)(ce->msc - (msc + ce->serial + 60)); if (diff < 0) { if (-diff > earliest) { fprintf(stderr, "\tnotify %d early by %d msc\n", ce->serial, -diff); earliest = -diff; } early++; ret++; } else if (diff > 0) { if (diff > latest) { fprintf(stderr, "\tnotify %d late by %d msc\n", ce->serial, diff); latest = diff; } late++; ret++; } count++; } else complete = 1; free(ev); } while (!complete); if (early) printf("\t%d notifies too early (worst %d)!\n", early, earliest); if (late) printf("\t%d notifies too late (worst %d)!\n", late, latest); if (count != N_VBLANKS+1) { fprintf(stderr, "Sentinel vblank received too early! %d waits outstanding\n", N_VBLANKS+1 - count); ret++; do { xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC); free(ev); } while (++count != N_VBLANKS+1); } XSync(dpy, True); ret += !!_x_error_occurred; return ret; #undef N_VBLANKS } static int test_modulus_msc(Display *dpy, void *Q) { xcb_connection_t *c = XGetXCBConnection(dpy); Window root = DefaultRootWindow(dpy); xcb_present_complete_notify_event_t *ce; xcb_generic_event_t *ev; int x, y, ret = 0; uint64_t target; int early = 0, late = 0; int earliest = 0, latest = 0; int complete, count, expect; printf("Testing notify modulus\n"); _x_error_occurred = 0; target = wait_vblank(dpy, root, Q); expect = 0; xcb_present_notify_msc(c, root, 0, 0, 0, 0); for (x = 1; x <= 19; x++) { for (y = 0; y < x; y++) { xcb_present_notify_msc(c, root, y << 16 | x, 0, x, y); expect++; } } xcb_present_notify_msc(c, root, 0xdeadbeef, target + 2*x, 0, 0); xcb_flush(c); ev = xcb_wait_for_special_event(c, Q); if (ev) { ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC); assert(ce->serial == 0); assert(target == ce->msc); target = ce->msc; } complete = 0; count = 0; do { ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC); assert(ce->serial); if (ce->serial != 0xdeadbeef) { uint64_t msc; int diff; x = ce->serial & 0xffff; y = ce->serial >> 16; msc = target; msc -= target % x; msc += y; if (msc <= target) msc += x; diff = (int64_t)(ce->msc - msc); if (diff < 0) { if (-diff > earliest) { fprintf(stderr, "\tnotify (%d, %d) early by %d msc (target %lld, reported %lld)\n", y, x, -diff, (long long)msc, (long long)ce->msc); earliest = -diff; } early++; ret++; } else if (diff > 0) { if (diff > latest) { fprintf(stderr, "\tnotify (%d, %d) late by %d msc (target %lld, reported %lld)\n", y, x, diff, (long long)msc, (long long)ce->msc); latest = diff; } late++; ret++; } count++; } else complete = 1; free(ev); } while (!complete); if (early) printf("\t%d notifies too early (worst %d)!\n", early, earliest); if (late) printf("\t%d notifies too late (worst %d)!\n", late, latest); if (count != expect) { fprintf(stderr, "Sentinel vblank received too early! %d waits outstanding\n", expect - count); ret++; do { ev = xcb_wait_for_special_event(c, Q); if (ev == NULL) break; ce = (xcb_present_complete_notify_event_t *)ev; assert(ce->kind == XCB_PRESENT_COMPLETE_KIND_NOTIFY_MSC); free(ev); } while (++count != expect); } XSync(dpy, True); ret += !!_x_error_occurred; return ret; } static inline XRRScreenResources *_XRRGetScreenResourcesCurrent(Display *dpy, Window window) { XRRScreenResources *res; res = XRRGetScreenResourcesCurrent(dpy, window); if (res == NULL) res = XRRGetScreenResources(dpy, window); return res; } static XRRModeInfo *lookup_mode(XRRScreenResources *res, int id) { int i; for (i = 0; i < res->nmode; i++) { if (res->modes[i].id == id) return &res->modes[i]; } return NULL; } static int for_each_crtc(Display *dpy, int (*func)(Display *dpy, RRCrtc crtc, int width, int height, void *closure), void *closure) { XRRScreenResources *res; XRRCrtcInfo **original_crtc; int i, j, err = 0; if (!XRRQueryVersion(dpy, &i, &j)) return -1; res = _XRRGetScreenResourcesCurrent(dpy, DefaultRootWindow(dpy)); if (res == NULL) return -1; original_crtc = malloc(sizeof(XRRCrtcInfo *)*res->ncrtc); for (i = 0; i < res->ncrtc; i++) original_crtc[i] = XRRGetCrtcInfo(dpy, res, res->crtcs[i]); for (i = 0; i < res->noutput; i++) { XRROutputInfo *output; XRRModeInfo *mode; output = XRRGetOutputInfo(dpy, res, res->outputs[i]); if (output == NULL) continue; mode = NULL; if (res->nmode) mode = lookup_mode(res, output->modes[0]); for (j = 0; mode && j < output->ncrtc; j++) { printf("[%d, %d] -- OUTPUT:%ld, CRTC:%ld\n", i, j, (long)res->outputs[i], (long)output->crtcs[j]); XRRSetCrtcConfig(dpy, res, output->crtcs[j], CurrentTime, 0, 0, output->modes[0], RR_Rotate_0, &res->outputs[i], 1); XSync(dpy, True); err += func(dpy, output->crtcs[j], mode->width, mode->height, closure); XRRSetCrtcConfig(dpy, res, output->crtcs[j], CurrentTime, 0, 0, None, RR_Rotate_0, NULL, 0); XSync(dpy, True); } XRRFreeOutputInfo(output); } for (i = 0; i < res->ncrtc; i++) XRRSetCrtcConfig(dpy, res, res->crtcs[i], CurrentTime, original_crtc[i]->x, original_crtc[i]->y, original_crtc[i]->mode, original_crtc[i]->rotation, original_crtc[i]->outputs, original_crtc[i]->noutput); free(original_crtc); XRRFreeScreenResources(res); return err; } struct test_crtc { Window win; int depth; unsigned flags; struct dri3_fence fence; void *queue; uint64_t msc; }; #define SYNC 0x1 #define FUTURE 0x2 static int __test_crtc(Display *dpy, RRCrtc crtc, int width, int height, void *closure) { struct test_crtc *test = closure; Pixmap pixmap; int err = 0; test->msc = check_msc(dpy, test->win, test->queue, test->msc, NULL); if (test->flags & SYNC) xshmfence_reset(test->fence.addr); pixmap = XCreatePixmap(dpy, test->win, width, height, test->depth); xcb_present_pixmap(XGetXCBConnection(dpy), test->win, pixmap, 0, /* sbc */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ crtc, None, /* wait fence */ test->flags & SYNC ? test->fence.xid : None, XCB_PRESENT_OPTION_NONE, test->msc, /* target msc */ 1, /* divisor */ 0, /* remainder */ 0, NULL); if (test->flags & SYNC) { Pixmap tmp = XCreatePixmap(dpy, test->win, width, height, test->depth); xcb_present_pixmap(XGetXCBConnection(dpy), test->win, tmp, 1, /* sbc */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ crtc, None, /* wait fence */ None, /* sync fence */ XCB_PRESENT_OPTION_NONE, test->msc + (test->flags & FUTURE ? 5 * 16 : 1), /* target msc */ 1, /* divisor */ 0, /* remainder */ 0, NULL); XFreePixmap(dpy, tmp); XFlush(dpy); err += !!xshmfence_await(test->fence.addr); } XFreePixmap(dpy, pixmap); test->msc = check_msc(dpy, test->win, test->queue, test->msc, NULL); return err; } static int test_crtc(Display *dpy, void *queue, uint64_t last_msc) { struct test_crtc test; int err = 0; XSync(dpy, True); _x_error_occurred = 0; test.win = DefaultRootWindow(dpy); test.depth = DefaultDepth(dpy, DefaultScreen(dpy)); if (dri3_create_fence(dpy, test.win, &test.fence)) return -1; test.queue = queue; test.msc = last_msc; printf("Testing each crtc, without waiting for each flip\n"); test.flags = 0; test.msc = check_msc(dpy, test.win, test.queue, test.msc, NULL); err += for_each_crtc(dpy, __test_crtc, &test); test.msc = check_msc(dpy, test.win, test.queue, test.msc, NULL); printf("Testing each crtc, waiting for flips to complete\n"); test.flags = SYNC; test.msc = check_msc(dpy, test.win, test.queue, test.msc, NULL); err += for_each_crtc(dpy, __test_crtc, &test); test.msc = check_msc(dpy, test.win, test.queue, test.msc, NULL); printf("Testing each crtc, with future flips\n"); test.flags = FUTURE | SYNC; test.msc = check_msc(dpy, test.win, test.queue, test.msc, NULL); err += for_each_crtc(dpy, __test_crtc, &test); test.msc = check_msc(dpy, test.win, test.queue, test.msc, NULL); dri3_fence_free(dpy, &test.fence); XSync(dpy, True); err += !!_x_error_occurred; if (err) printf("%s: failures=%d\n", __func__, err); return err; } static int can_use_shm(Display *dpy) { int major, minor, has_pixmap; if (!XShmQueryExtension(dpy)) return 0; XShmQueryVersion(dpy, &major, &minor, &has_pixmap); return has_pixmap; } static int test_shm(Display *dpy) { Window win = DefaultRootWindow(dpy); XShmSegmentInfo shm; Pixmap pixmap; Window root; unsigned int width, height; unsigned border, depth; int x, y, ret = 1; if (!can_use_shm(dpy)) return 0; _x_error_occurred = 0; XGetGeometry(dpy, win, &root, &x, &y, &width, &height, &border, &depth); printf("Using %dx%d SHM\n", width, height); shm.shmid = shmget(IPC_PRIVATE, height * 4*width, IPC_CREAT | 0666); if (shm.shmid == -1) return 0; shm.shmaddr = shmat(shm.shmid, 0, 0); if (shm.shmaddr == (char *) -1) goto rmid; shm.readOnly = False; XShmAttach(dpy, &shm); pixmap = XShmCreatePixmap(dpy, DefaultRootWindow(dpy), shm.shmaddr, &shm, width, height, 24); if (_x_error_occurred) goto detach; xcb_present_pixmap(XGetXCBConnection(dpy), win, pixmap, 0, /* sbc */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, 0, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); XFreePixmap(dpy, pixmap); XSync(dpy, True); if (_x_error_occurred) goto detach; ret = 0; detach: XShmDetach(dpy, &shm); shmdt(shm.shmaddr); XSync(dpy, False); rmid: shmctl(shm.shmid, IPC_RMID, NULL); return ret; } static uint32_t gem_create(int fd, int size) { struct drm_i915_gem_create create; create.handle = 0; create.size = size; (void)drmIoctl(fd, DRM_IOCTL_I915_GEM_CREATE, &create); return create.handle; } struct local_i915_gem_caching { uint32_t handle; uint32_t caching; }; #define LOCAL_I915_GEM_SET_CACHING 0x2f #define LOCAL_IOCTL_I915_GEM_SET_CACHING DRM_IOW(DRM_COMMAND_BASE + LOCAL_I915_GEM_SET_CACHING, struct local_i915_gem_caching) static int gem_set_caching(int fd, uint32_t handle, int caching) { struct local_i915_gem_caching arg; arg.handle = handle; arg.caching = caching; return drmIoctl(fd, LOCAL_IOCTL_I915_GEM_SET_CACHING, &arg) == 0; } static int gem_set_tiling(int fd, uint32_t handle, int tiling, int stride) { struct drm_i915_gem_set_tiling set_tiling; int err; restart: set_tiling.handle = handle; set_tiling.tiling_mode = tiling; set_tiling.stride = stride; if (drmIoctl(fd, DRM_IOCTL_I915_GEM_SET_TILING, &set_tiling) == 0) return 1; err = errno; if (err == EINTR) goto restart; if (err == EAGAIN) { sched_yield(); goto restart; } return 0; } static int gem_export(int fd, uint32_t handle) { struct drm_prime_handle args; args.handle = handle; args.flags = O_CLOEXEC; if (drmIoctl(fd, DRM_IOCTL_PRIME_HANDLE_TO_FD, &args)) return -1; return args.fd; } static void gem_close(int fd, uint32_t handle) { struct drm_gem_close close; close.handle = handle; (void)drmIoctl(fd, DRM_IOCTL_GEM_CLOSE, &close); } static int test_dri3_tiling(Display *dpy) { Window win = DefaultRootWindow(dpy); const int tiling[] = { I915_TILING_NONE, I915_TILING_X, I915_TILING_Y }; Window root; unsigned int width, height; unsigned border, depth, bpp; unsigned stride, size; void *Q; int x, y; int device; int line = -1; int t; device = dri3_open(dpy); if (device < 0) return 0; if (!is_intel(device)) return 0; printf("Opened Intel DRI3 device\n"); XGetGeometry(dpy, win, &root, &x, &y, &width, &height, &border, &depth); switch (depth) { case 8: bpp = 8; break; case 15: case 16: bpp = 16; break; case 24: case 32: bpp = 32; break; default: return 0; } stride = ALIGN(width * bpp/8, 512); size = PAGE_ALIGN(stride * ALIGN(height, 32)); printf("Creating DRI3 %dx%d (source stride=%d, size=%d) for GTT\n", width, height, stride, size); _x_error_occurred = 0; Q = setup_msc(dpy, root); for (t = 0; t < sizeof(tiling)/sizeof(tiling[0]); t++) { uint64_t msc; uint32_t src; int src_fd; Pixmap src_pix; src = gem_create(device, size); if (!src) { line = __LINE__; goto fail; } gem_set_tiling(device, src, tiling[t], stride); src_fd = gem_export(device, src); if (src_fd < 0) { line = __LINE__; goto fail; } src_pix = dri3_create_pixmap(dpy, root, width, height, depth, src_fd, bpp, stride, size); msc = wait_vblank(dpy, root, Q); xcb_present_pixmap(XGetXCBConnection(dpy), win, src_pix, 0, /* sbc */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, msc + 2, /* target msc */ 1, /* divisor */ 0, /* remainder */ 0, NULL); xcb_present_pixmap(XGetXCBConnection(dpy), win, src_pix, 0, /* sbc */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, msc + 3, /* target msc */ 1, /* divisor */ 0, /* remainder */ 0, NULL); XSync(dpy, True); if (_x_error_occurred) { line = __LINE__; goto fail; } XFreePixmap(dpy, src_pix); _x_error_occurred = 0; close(src_fd); gem_close(device, src); } teardown_msc(dpy, Q); return 0; fail: printf("%s failed with tiling %d, line %d\n", __func__, tiling[t], line); teardown_msc(dpy, Q); return 1; } static int test_dri3(Display *dpy) { Window win = DefaultRootWindow(dpy); Pixmap pixmap; Window root; unsigned int width, height; unsigned border, depth; unsigned stride, size; int x, y, ret = 1; int device, handle; int bpp; device = dri3_open(dpy); if (device < 0) return 0; if (!is_intel(device)) return 0; printf("Opened Intel DRI3 device\n"); XGetGeometry(dpy, win, &root, &x, &y, &width, &height, &border, &depth); switch (depth) { case 8: bpp = 8; break; case 15: case 16: bpp = 16; break; case 24: case 32: bpp = 32; break; default: return 0; } stride = width * bpp/8; size = PAGE_ALIGN(stride * height); printf("Creating DRI3 %dx%d (source stride=%d, size=%d) for GTT\n", width, height, stride, size); pixmap = 0; handle = gem_create(device, size); if (handle) { pixmap = dri3_create_pixmap(dpy, root, width, height, depth, gem_export(device, handle), bpp, stride, size); gem_close(device, handle); } if (pixmap == 0) goto fail; xcb_present_pixmap(XGetXCBConnection(dpy), win, pixmap, 0, /* sbc */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, 0, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); XFreePixmap(dpy, pixmap); XSync(dpy, True); if (_x_error_occurred) goto fail; printf("Creating DRI3 %dx%d (source stride=%d, size=%d) for CPU\n", width, height, stride, size); pixmap = 0; handle = gem_create(device, size); if (handle) { gem_set_caching(device, handle, CPU); handle = dri3_create_pixmap(dpy, root, width, height, depth, gem_export(device, handle), bpp, stride, size); gem_close(device, handle); } if (pixmap == 0) goto fail; xcb_present_pixmap(XGetXCBConnection(dpy), win, pixmap, 0, /* sbc */ 0, /* valid */ 0, /* update */ 0, /* x_off */ 0, /* y_off */ None, None, /* wait fence */ None, XCB_PRESENT_OPTION_NONE, 0, /* target msc */ 0, /* divisor */ 0, /* remainder */ 0, NULL); XFreePixmap(dpy, pixmap); XSync(dpy, True); if (_x_error_occurred) goto fail; ret = 0; fail: close(device); return ret; } static int has_present(Display *dpy) { xcb_connection_t *c = XGetXCBConnection(dpy); xcb_generic_error_t *error = NULL; void *reply; reply = xcb_xfixes_query_version_reply(c, xcb_xfixes_query_version(c, XCB_XFIXES_MAJOR_VERSION, XCB_XFIXES_MINOR_VERSION), &error); free(reply); free(error); if (reply == NULL) { fprintf(stderr, "XFixes not supported on %s\n", DisplayString(dpy)); return 0; } reply = xcb_dri3_query_version_reply(c, xcb_dri3_query_version(c, XCB_DRI3_MAJOR_VERSION, XCB_DRI3_MINOR_VERSION), &error); free(reply); free(error); if (reply == NULL) { fprintf(stderr, "DRI3 not supported on %s\n", DisplayString(dpy)); return 0; } reply = xcb_present_query_version_reply(c, xcb_present_query_version(c, XCB_PRESENT_MAJOR_VERSION, XCB_PRESENT_MINOR_VERSION), &error); free(reply); free(error); if (reply == NULL) { fprintf(stderr, "Present not supported on %s\n", DisplayString(dpy)); return 0; } return 1; } static int has_composite(Display *dpy) { int event, error; int major, minor; if (!XCompositeQueryExtension(dpy, &event, &error)) return 0; XCompositeQueryVersion(dpy, &major, &minor); return major > 0 || minor >= 4; } int main(void) { Display *dpy; Window root; int dummy; int error = 0; uint64_t last_msc; void *queue; dpy = XOpenDisplay(NULL); if (dpy == NULL) return 77; if (!has_present(dpy)) return 77; if (DPMSQueryExtension(dpy, &dummy, &dummy)) DPMSDisable(dpy); root = DefaultRootWindow(dpy); signal(SIGALRM, SIG_IGN); XSetErrorHandler(_check_error_handler); queue = setup_msc(dpy, root); last_msc = check_msc(dpy, root, queue, 0, NULL); error += test_future_msc(dpy, queue); last_msc = check_msc(dpy, root, queue, last_msc, NULL); error += test_wrap_msc(dpy); last_msc = check_msc(dpy, root, queue, last_msc, NULL); error += test_accuracy_msc(dpy, queue); last_msc = check_msc(dpy, root, queue, last_msc, NULL); error += test_modulus_msc(dpy, queue); last_msc = check_msc(dpy, root, queue, last_msc, NULL); error += test_exhaustion_msc(dpy, queue); last_msc = check_msc(dpy, root, queue, last_msc, NULL); for (dummy = 0; dummy <= 3; dummy++) { Window win; uint64_t msc = 0; XSetWindowAttributes attr; Visual *visual = DefaultVisual(dpy, DefaultScreen(dpy)); unsigned int width, height; unsigned border, depth; const char *phase; int x, y; void *Q; attr.override_redirect = 1; XGetGeometry(dpy, root, &win, &x, &y, &width, &height, &border, &depth); _x_error_occurred = 0; switch (dummy) { case 0: win = root; phase = "root"; break; case 1: win = XCreateWindow(dpy, root, 0, 0, width, height, 0, depth, InputOutput, visual, CWOverrideRedirect, &attr); phase = "fullscreen"; break; case 2: win = XCreateWindow(dpy, root, 0, 0, width/2, height/2, 0, depth, InputOutput, visual, CWOverrideRedirect, &attr); phase = "window"; break; case 3: if (!has_composite(dpy)) continue; win = XCreateWindow(dpy, root, 0, 0, width, height, 0, DefaultDepth(dpy, DefaultScreen(dpy)), InputOutput, DefaultVisual(dpy, DefaultScreen(dpy)), CWOverrideRedirect, &attr); XCompositeRedirectWindow(dpy, win, CompositeRedirectManual); phase = "composite"; break; default: phase = "broken"; win = root; abort(); break; } XMapWindow(dpy, win); XSync(dpy, True); if (_x_error_occurred) continue; Q = setup_msc(dpy, win); msc = check_msc(dpy, win, Q, msc, NULL); error += test_whole(dpy, win, phase); msc = check_msc(dpy, win, Q, msc, NULL); error += test_double(dpy, win, phase, Q); msc = check_msc(dpy, win, Q, msc, NULL); error += test_future(dpy, win, phase, Q); msc = check_msc(dpy, win, Q, msc, NULL); error += test_accuracy(dpy, win, phase, Q); msc = check_msc(dpy, win, Q, msc, NULL); error += test_modulus(dpy, win, phase, Q); msc = check_msc(dpy, win, Q, msc, NULL); error += test_exhaustion(dpy, win, phase, Q); msc = check_msc(dpy, win, Q, msc, NULL); teardown_msc(dpy, Q); if (win != root) XDestroyWindow(dpy, win); } error += test_crtc(dpy, queue, last_msc); last_msc = check_msc(dpy, root, queue, last_msc, NULL); error += test_shm(dpy); last_msc = check_msc(dpy, root, queue, last_msc, NULL); error += test_dri3(dpy); last_msc = check_msc(dpy, root, queue, last_msc, NULL); error += test_dri3_tiling(dpy); last_msc = check_msc(dpy, root, queue, last_msc, NULL); teardown_msc(dpy, queue); if (DPMSQueryExtension(dpy, &dummy, &dummy)) DPMSEnable(dpy); return !!error; }