vasilito
f31522130f
Build system (5 gaps hardened): - COOKBOOK_OFFLINE defaults to true (fork-mode) - normalize_patch handles diff -ruN format - New 'repo validate-patches' command (25/25 relibc patches) - 14 patched Qt/Wayland/display recipes added to protected list - relibc archive regenerated with current patch chain Boot fixes (fixable): - Full ISO EFI partition: 16 MiB → 1 MiB (matches mini, BIOS hardcoded 2 MiB offset) - D-Bus system bus: absolute /usr/bin/dbus-daemon path (was skipped) - redbear-sessiond: absolute /usr/bin/redbear-sessiond path (was skipped) - daemon framework: silenced spurious INIT_NOTIFY warnings for oneshot_async services (P0-daemon-silence-init-notify.patch) - udev-shim: demoted INIT_NOTIFY warning to INFO (expected for oneshot_async) - relibc: comprehensive named semaphores (sem_open/close/unlink) replacing upstream todo!() stubs - greeterd: Wayland socket timeout 15s → 30s (compositor DRM wait) - greeter-ui: built and linked (header guard unification, sem_compat stubs removed) - mc: un-ignored in both configs, fixed glib/libiconv/pcre2 transitive deps - greeter config: removed stale keymapd dependency from display/greeter services - prefix toolchain: relibc headers synced, _RELIBC_STDLIB_H guard unified Unfixable (diagnosed, upstream): - i2c-hidd: abort on no-I2C-hardware (QEMU) — process::exit → relibc abort - kded6/greeter-ui: page fault 0x8 — Qt library null deref - Thread panics fd != -1 — Rust std library on Redox - DHCP timeout / eth0 MAC — QEMU user-mode networking - hwrngd/thermald — no hardware RNG/thermal in VM - live preload allocation — BIOS memory fragmentation, continues on demand
192 lines
4.9 KiB
C
192 lines
4.9 KiB
C
#include <signal.h>
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <sys/types.h>
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#include <unistd.h>
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#include "poller.h"
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#include "test.h"
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static void test_poller_init(void) {
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struct poller poller;
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test_assert(poller_init(&poller) == 0);
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poller_finish(&poller);
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}
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struct test_fd {
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int fd;
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uint32_t events;
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};
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static int test_fd_event(int fd, uint32_t mask, void *data) {
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struct test_fd *d = data;
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d->fd = fd;
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d->events = mask;
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return 0;
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}
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static void test_poller_single_fd(void) {
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struct poller poller;
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test_assert(poller_init(&poller) == 0);
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int fds[2];
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test_assert(pipe(fds) == 0);
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struct test_fd evd;
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struct event_source_fd *ev =
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poller_add_fd(&poller, fds[0], EVENT_READABLE, test_fd_event, &evd);
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test_assert(ev != NULL);
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evd.fd = 0;
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evd.events = 0;
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test_assert(write(fds[1], "\0", 1) == 1);
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test_assert(poller_poll(&poller) == 0);
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test_assert(evd.fd == fds[0]);
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test_assert(evd.events == EVENT_READABLE);
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evd.fd = 0;
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evd.events = 0;
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test_assert(write(fds[1], "\0", 1) == 1);
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test_assert(poller_poll(&poller) == 0);
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test_assert(evd.fd == fds[0]);
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test_assert(evd.events == EVENT_READABLE);
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close(fds[0]);
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close(fds[1]);
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poller_finish(&poller);
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}
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static void test_poller_multi_fd(void) {
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struct poller poller;
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test_assert(poller_init(&poller) == 0);
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char dummy[8];
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int fdsa[2], fdsb[2];
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test_assert(pipe(fdsa) == 0);
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test_assert(pipe(fdsb) == 0);
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struct test_fd evd1, evd2;
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struct event_source_fd *ev1 =
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poller_add_fd(&poller, fdsa[0], EVENT_READABLE, test_fd_event, &evd1);
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struct event_source_fd *ev2 =
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poller_add_fd(&poller, fdsb[0], EVENT_READABLE, test_fd_event, &evd2);
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test_assert(ev1 != NULL);
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test_assert(ev2 != NULL);
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evd1.fd = evd2.fd = 0;
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evd1.events = evd2.events = 0;
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test_assert(write(fdsa[1], "\0", 1) == 1);
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test_assert(poller_poll(&poller) == 0);
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test_assert(read(fdsa[0], &dummy, sizeof dummy) == 1);
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test_assert(evd1.fd == fdsa[0]);
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test_assert(evd1.events == EVENT_READABLE);
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test_assert(evd2.fd == 0);
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test_assert(evd2.events == 0);
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evd1.fd = evd2.fd = 0;
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evd1.events = evd2.events = 0;
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test_assert(write(fdsb[1], "\0", 1) == 1);
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test_assert(poller_poll(&poller) == 0);
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test_assert(read(fdsb[0], &dummy, sizeof dummy) == 1);
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test_assert(evd1.fd == 0);
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test_assert(evd1.events == 0);
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test_assert(evd2.fd == fdsb[0]);
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test_assert(evd2.events == EVENT_READABLE);
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evd1.fd = evd2.fd = 0;
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evd1.events = evd2.events = 0;
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test_assert(write(fdsa[1], "\0", 1) == 1);
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test_assert(write(fdsb[1], "\0", 1) == 1);
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test_assert(poller_poll(&poller) == 0);
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test_assert(read(fdsa[0], &dummy, sizeof dummy) == 1);
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test_assert(read(fdsb[0], &dummy, sizeof dummy) == 1);
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test_assert(evd1.fd == fdsa[0]);
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test_assert(evd1.events == EVENT_READABLE);
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test_assert(evd2.fd == fdsb[0]);
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test_assert(evd2.events == EVENT_READABLE);
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close(fdsa[0]);
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close(fdsa[1]);
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close(fdsb[0]);
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close(fdsb[1]);
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poller_finish(&poller);
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}
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struct test_signal {
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int signal;
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};
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static int test_signal_event(int signal, void *data) {
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struct test_signal *d = data;
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d->signal = signal;
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return 0;
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}
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static void test_poller_single_signal(void) {
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struct poller poller;
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test_assert(poller_init(&poller) == 0);
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struct test_signal evd;
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struct event_source_signal *ev =
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poller_add_signal(&poller, SIGRTMIN, test_signal_event, &evd);
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test_assert(ev != NULL);
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evd.signal = 0;
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test_assert(kill(getpid(), SIGRTMIN) == 0);
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test_assert(poller_poll(&poller) == 0);
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test_assert(evd.signal == SIGRTMIN);
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evd.signal = 0;
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test_assert(kill(getpid(), SIGRTMIN) == 0);
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test_assert(poller_poll(&poller) == 0);
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test_assert(evd.signal == SIGRTMIN);
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poller_finish(&poller);
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}
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static void test_poller_multi_signal(void) {
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struct poller poller;
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test_assert(poller_init(&poller) == 0);
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struct test_signal evd1, evd2;
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struct event_source_signal *ev1 =
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poller_add_signal(&poller, SIGRTMIN, test_signal_event, &evd1);
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struct event_source_signal *ev2 =
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poller_add_signal(&poller, SIGRTMIN + 1, test_signal_event, &evd2);
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test_assert(ev1 != NULL);
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test_assert(ev2 != NULL);
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evd1.signal = evd2.signal = 0;
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test_assert(kill(getpid(), SIGRTMIN) == 0);
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test_assert(poller_poll(&poller) == 0);
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test_assert(evd1.signal == SIGRTMIN);
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test_assert(evd2.signal == 0);
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evd1.signal = evd2.signal = 0;
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test_assert(kill(getpid(), SIGRTMIN + 1) == 0);
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test_assert(poller_poll(&poller) == 0);
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test_assert(evd1.signal == 0);
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test_assert(evd2.signal == SIGRTMIN + 1);
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evd1.signal = evd2.signal = 0;
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test_assert(kill(getpid(), SIGRTMIN) == 0);
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test_assert(kill(getpid(), SIGRTMIN + 1) == 0);
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test_assert(poller_poll(&poller) == 0);
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test_assert(evd1.signal == SIGRTMIN);
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test_assert(evd2.signal == SIGRTMIN + 1);
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poller_finish(&poller);
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}
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int main(int argc, char *argv[]) {
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(void)argc;
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(void)argv;
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test_run(test_poller_init);
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test_run(test_poller_single_fd);
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test_run(test_poller_multi_fd);
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test_run(test_poller_single_signal);
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test_run(test_poller_multi_signal);
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}
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