prot = PROT_READ | PROT_WRITE;
cell alloc_size = 2 * pagesize + size;
+#if defined(__APPLE__) && defined(FACTOR_ARM64) // FIXME: could be in header file
+ char* array = (char*)mmap(NULL, alloc_size, prot,
+ MAP_ANON | MAP_PRIVATE | MAP_JIT, -1, 0);
+#else
char* array = (char*)mmap(NULL, alloc_size, prot,
MAP_ANON | MAP_PRIVATE, -1, 0);
+#endif
if (array == (char*)-1)
fatal_error("Out of memory in mmap", alloc_size);
set_border_locked(true);
}
-void segment::set_border_locked(bool locked) {
- int pagesize = getpagesize();
- cell lo = start - pagesize;
- if (!set_memory_locked(lo, pagesize, locked)) {
- fatal_error("Cannot (un)protect low guard page", lo);
- }
-
- cell hi = end;
- if (!set_memory_locked(hi, pagesize, locked)) {
- fatal_error("Cannot (un)protect high guard page", hi);
- }
-}
-
segment::~segment() {
int pagesize = getpagesize();
- int retval = munmap((void*)(start - pagesize), pagesize + size + pagesize);
+ int retval = munmap((void*)(start - pagesize), 2 * pagesize + size);
if (retval)
fatal_error("Segment deallocation failed", 0);
}
-void factor_vm::dispatch_signal(void* uap, void(handler)()) {
- dispatch_signal_handler((cell*)&UAP_STACK_POINTER(uap),
- (cell*)&UAP_PROGRAM_COUNTER(uap),
- (cell)FUNCTION_CODE_POINTER(handler));
- UAP_SET_TOC_POINTER(uap, (cell)FUNCTION_TOC_POINTER(handler));
-}
-
void factor_vm::start_sampling_profiler_timer() {
struct itimerval timer;
memset((void*)&timer, 0, sizeof(struct itimerval));
setitimer(ITIMER_REAL, &timer, NULL);
}
-void memory_signal_handler(int signal, siginfo_t* siginfo, void* uap) {
+void factor_vm::dispatch_signal(void* uap, void(handler)()) {
+ dispatch_signal_handler((cell*)&UAP_STACK_POINTER(uap),
+ (cell*)&UAP_PROGRAM_COUNTER(uap),
+ (cell)FUNCTION_CODE_POINTER(handler));
+}
+void memory_signal_handler(int signal, siginfo_t* siginfo, void* uap) {
+ (void) signal;
cell fault_addr = (cell)siginfo->si_addr;
cell fault_pc = (cell)UAP_PROGRAM_COUNTER(uap);
factor_vm* vm = current_vm();
- vm->verify_memory_protection_error(fault_addr);
- vm->signal_fault_addr = fault_addr;
- vm->signal_fault_pc = fault_pc;
+ vm->set_memory_protection_error(fault_addr, fault_pc);
vm->dispatch_signal(uap, factor::memory_signal_handler_impl);
}
void synchronous_signal_handler(int signal, siginfo_t* siginfo, void* uap) {
+ (void) siginfo;
if (factor_vm::fatal_erroring_p)
return;
factor_vm* vm = current_vm_p();
- if (vm) {
- vm->signal_number = signal;
- vm->dispatch_signal(uap, factor::synchronous_signal_handler_impl);
- } else
+ if (!vm)
fatal_error("Foreign thread received signal", signal);
+ vm->signal_number = signal;
+ vm->dispatch_signal(uap, factor::synchronous_signal_handler_impl);
}
void safe_write_nonblock(int fd, void* data, ssize_t size);
}
void enqueue_signal_handler(int signal, siginfo_t* siginfo, void* uap) {
+ (void) siginfo;
+ (void) uap;
if (factor_vm::fatal_erroring_p)
return;
}
void fep_signal_handler(int signal, siginfo_t* siginfo, void* uap) {
+ (void) siginfo;
+ (void) uap;
if (factor_vm::fatal_erroring_p)
return;
factor_vm* vm = current_vm_p();
if (vm) {
- vm->safepoint.enqueue_fep(vm);
+ vm->enqueue_fep();
enqueue_signal(vm, signal);
} else
fatal_error("Foreign thread received signal", signal);
}
void sample_signal_handler(int signal, siginfo_t* siginfo, void* uap) {
+ (void) siginfo;
factor_vm* vm = current_vm_p();
bool foreign_thread = false;
if (vm == NULL) {
vm = thread_vms.begin()->second;
}
if (atomic::load(&vm->sampling_profiler_p))
- vm->safepoint.enqueue_samples(vm, 1, (cell)UAP_PROGRAM_COUNTER(uap),
- foreign_thread);
+ vm->enqueue_samples(1, (cell)UAP_PROGRAM_COUNTER(uap), foreign_thread);
else if (!foreign_thread)
enqueue_signal(vm, signal);
}
-void ignore_signal_handler(int signal, siginfo_t* siginfo, void* uap) {}
+void ignore_signal_handler(int signal, siginfo_t* siginfo, void* uap) {
+ (void) signal;
+ (void) siginfo;
+ (void) uap;
+}
void fpe_signal_handler(int signal, siginfo_t* siginfo, void* uap) {
factor_vm* vm = current_vm();
sigaction_safe(SIGALRM, &sample_sigaction, NULL);
}
- /* We don't use SA_IGN here because then the ignore action is inherited
- by subprocesses, which we don't want. There is a unit test in
- io.launcher.unix for this. */
+ // We don't use SA_IGN here because then the ignore action is inherited
+ // by subprocesses, which we don't want. There is a unit test in
+ // io.launcher.unix for this.
{
struct sigaction ignore_sigaction;
init_sigaction_with_handler(&ignore_sigaction, ignore_signal_handler);
sigaction_safe(SIGPIPE, &ignore_sigaction, NULL);
- /* We send SIGUSR2 to the stdin_loop thread to interrupt it on FEP */
+ // We send SIGUSR2 to the stdin_loop thread to interrupt it on FEP
sigaction_safe(SIGUSR2, &ignore_sigaction, NULL);
}
}
-/* On Unix, shared fds such as stdin cannot be set to non-blocking mode
- (http://homepages.tesco.net/J.deBoynePollard/FGA/dont-set-shared-file-descriptors-to-non-blocking-mode.html)
- so we kludge around this by spawning a thread, which waits on a control pipe
- for a signal, upon receiving this signal it reads one block of data from
- stdin and writes it to a data pipe. Upon completion, it writes a 4-byte
- integer to the size pipe, indicating how much data was written to the data
- pipe.
+// On Unix, shared fds such as stdin cannot be set to non-blocking mode
+// (http://homepages.tesco.net/J.deBoynePollard/FGA/dont-set-shared-file-descriptors-to-non-blocking-mode.html)
+// so we kludge around this by spawning a thread, which waits on a control pipe
+// for a signal, upon receiving this signal it reads one block of data from
+// stdin and writes it to a data pipe. Upon completion, it writes a 4-byte
+// integer to the size pipe, indicating how much data was written to the data
+// pipe.
- The read end of the size pipe can be set to non-blocking. */
+// The read end of the size pipe can be set to non-blocking.
extern "C" {
int stdin_read;
int stdin_write;
}
void* stdin_loop(void* arg) {
+ (void) arg;
unsigned char buf[4096];
bool loop_running = true;
fatal_error("stdin_loop: bad data on control fd", buf[0]);
for (;;) {
- /* If we fep, the parent thread will grab stdin_mutex and send us
- SIGUSR2 to interrupt the read() call. */
+ // If we fep, the parent thread will grab stdin_mutex and send us
+ // SIGUSR2 to interrupt the read() call.
pthread_mutex_lock(&stdin_mutex);
pthread_mutex_unlock(&stdin_mutex);
ssize_t bytes = read(0, buf, sizeof(buf));
pthread_mutex_init(&stdin_mutex, NULL);
}
-/* This method is used to kill the stdin_loop before exiting from factor.
- A Nvidia driver bug on Linux is the reason this has to be done, see:
- http://www.nvnews.net/vbulletin/showthread.php?t=164619 */
+// This method is used to kill the stdin_loop before exiting from factor.
+// An Nvidia driver bug on Linux is the reason this has to be done, see:
+// http://www.nvnews.net/vbulletin/showthread.php?t=164619
void close_console() {
if (stdin_thread_initialized_p) {
pthread_cancel(stdin_thread);
void lock_console() {
FACTOR_ASSERT(stdin_thread_initialized_p);
- /* Lock the stdin_mutex and send the stdin_loop thread a signal to interrupt
- any read() it has in progress. When the stdin loop iterates again, it will
- try to lock the same mutex and wait until unlock_console() is called. */
+ // Lock the stdin_mutex and send the stdin_loop thread a signal to interrupt
+ // any read() it has in progress. When the stdin loop iterates again, it will
+ // try to lock the same mutex and wait until unlock_console() is called.
pthread_mutex_lock(&stdin_mutex);
pthread_kill(stdin_thread, SIGUSR2);
}
sigaction_safe(SIGINT, &fep_sigaction, NULL);
}
+void factor_vm::primitive_disable_ctrl_break() {
+ stop_on_ctrl_break = false;
+}
+
+void factor_vm::primitive_enable_ctrl_break() {
+ stop_on_ctrl_break = true;
+}
+
void abort() {
sig_t ret;
do {