Beispiel #1
0
// inet:getaddrs0/2 [4]
term_t bif_getaddrs0_2(term_t Addr, term_t Family, proc_t *proc)
{
	apr_status_t rs;
	apr_pool_t *tmp;
	apr_sockaddr_t *sa;
	const char *host;
	term_t addrs = nil;

	if (!is_binary(Addr) || !is_atom(Family))
		bif_bad_arg0();

	if (Family != A_INET)
		bif_exception(A_NOT_SUPPORTED);

	host = (const char *)peel(Addr)->binary.data;	//null-terminated by caller

	apr_pool_create(&tmp, 0);
	rs = apr_sockaddr_info_get(&sa, host, APR_INET, 0, 0, tmp);
	if (rs == 0)
	{
		term_t first = nil;
		term_t last = nil;

		while (sa)
		{
			struct in_addr ia = *(struct in_addr *)sa->ipaddr_ptr;
			apr_byte_t qs[4];
			term_t ip;

#if APR_IS_BIGENDIAN
			PUT32(qs, ia.s_addr);
#else
			PUT32_LE(qs, ia.s_addr);
#endif

			ip = heap_tuple4(proc->heap,
				tag_int(qs[0]),
				tag_int(qs[1]),
				tag_int(qs[2]),
				tag_int(qs[3]));

			cons_up(first, last, ip, proc->heap);

			sa = sa->next;
		}

		addrs = first;
	}

	apr_pool_destroy(tmp);

	if (rs != 0)
		bif_exception(decipher_status(rs));

	return addrs;
}
Beispiel #2
0
term_t cbif_process_info2(proc_t *proc, term_t *regs)
{
	term_t Pid = regs[0];
	term_t What = regs[1];

	if (!is_short_pid(Pid))
		badarg(Pid);
	if (!is_atom(What))
		badarg(What);

	proc_t *probe = scheduler_lookup(Pid);
	if (probe == 0)
		return A_UNDEFINED;

	term_t val;
	if (What == A_BACKTRACE)
	{
		//TODO: current stack trace is not enough
		val = A_UNDEFINED;
	}
	else if (What == A_BINARY)
	{
		//NB: BinInfo is documented to be a list, yet its contents is unspesfied
		val = int_to_term(probe->hp.total_pb_size, &probe->hp);
	}
	else if (What == A_CATCHLEVEL)
	{
		assert(fits_int(probe->catch_level));
		val = tag_int(probe->catch_level);
	}
	else if (What == A_CURRENT_FUNCTION)
	{
		// NB: probe->cap.ip is valid even if proc == probe
		uint32_t *fi = backstep_to_func_info(probe->cap.ip);
		val = heap_tuple3(&proc->hp, fi[1], fi[2], tag_int(fi[3]));
	}
	else if (What == A_CURRENT_LOCATION)
	{
		// NB: probe->cap.ip is valid even if proc == probe
		uint32_t *fi = backstep_to_func_info(probe->cap.ip);
		term_t loc = nil;
		char fname[256];
		uint32_t line = code_base_source_line(probe->cap.ip, fname, sizeof(fname));
		if (line != 0)
		{
			term_t f = heap_strz(&proc->hp, fname);
			term_t t1 = heap_tuple2(&proc->hp, A_FILE, f);
			term_t t2 = heap_tuple2(&proc->hp, A_LINE, tag_int(line));
			loc = heap_cons(&proc->hp, t2, nil);
			loc = heap_cons(&proc->hp, t1, loc);
		}

		val = heap_tuple4(&proc->hp, fi[1], fi[2], tag_int(fi[3]), loc);
	}
	else if (What == A_CURRENT_STACKTRACE)
	{
		val = probe->stack_trace;
		if (probe != proc)
		{
			int x = heap_copy_terms_N(&proc->hp, &val, 1);
			if (x < 0)
				fail(err_to_term(x));
		}
	}
	else if (What == A_DICTIONARY)
	{
		val = probe->dictionary;
		if (probe != proc)
		{
			int x = heap_copy_terms_N(&proc->hp, &val, 1);
			if (x < 0)
				fail(err_to_term(x));
		}
	}
	else if (What == A_ERROR_HANDLER)
		val = A_ERROR_HANDLER;
	else if (What == A_GARBAGE_COLLECTION)
	{
		//TODO
		val = A_UNDEFINED;
	}
	else if (What == A_GROUP_LEADER)
		val = probe->group_leader;
	else if (What == A_HEAP_SIZE)
		val = int_to_term(probe->hp.total_size, &proc->hp);
	else if (What == A_INITIAL_CALL)
	{
		val = (probe->init_call_mod == noval)
				?A_UNDEFINED
				:heap_tuple3(&proc->hp, probe->init_call_mod,
										probe->init_call_func,
										tag_int(probe->init_call_arity));
	}
	else if (What == A_LINKS)
	{
		term_t ids = nil;
		plink_t *pl = probe->links.active;
		while (pl != 0)
		{
			ids = heap_cons(&proc->hp, pl->id, ids);
			pl = pl->next;
		}

		val = ids;
	}
	else if (What == A_LAST_CALLS)
	{
		//TODO
		val = A_FALSE;
	}
	else if (What == A_MEMORY)
	{
		int pages = 0;

		pages += probe->home_node->index;
		pages += probe->stack_node->index;
		memnode_t *node = probe->hp.nodes;
		while (node != 0)
		{
			pages += node->index;
			node = node->next;
		}
		node = probe->mailbox.nodes;
		while (node != 0)
		{
			pages += node->index;
			node = node->next;
		}
		node = probe->links.nodes;
		while (node != 0)
		{
			pages += node->index;
			node = node->next;
		}

		int bytes = pages * PAGE_SIZE;
		val = int_to_term(bytes, &proc->hp);
	}
	else if (What == A_MESSAGE_BINARY)
	{
		//TODO
		val = A_UNDEFINED;
	}
	else if (What == A_MESSAGE_QUEUE_LEN)
	{
		int len = msg_queue_len(&probe->mailbox);
		assert(fits_int(len));
		val = tag_int(len);
	}
	else if (What == A_MESSAGES)
	{
		int messages = nil;
		message_t *msg = probe->mailbox.head;
		while (msg != 0)
		{
			term_t marsh_body = msg->body;
			if (probe != proc)
			{
				int x = heap_copy_terms_N(&proc->hp, &marsh_body, 1);
				if (x < 0)
					fail(err_to_term(x));
			}
			messages = heap_cons(&proc->hp, marsh_body, messages);
			msg = msg->next;
		}

		val = list_rev(messages, &proc->hp);
	}
	else if (What == A_MIN_HEAP_SIZE)
		val = tag_int(INIT_HEAP_SIZE);
	else if (What == A_MIN_BIN_VHEAP_SIZE)
	{
		//TODO
		val = A_UNDEFINED;
	}
	else if (What == A_MONITORED_BY)
		val = list_monitored_by(probe->pid, &proc->hp);
	else if (What == A_MONITORS)
		val = list_monitors(probe->pid, &proc->hp);
	else if (What == A_PRIORITY)
		val = probe->priority;
	else if (What == A_REDUCTIONS)
		val = int_to_term(probe->total_reds, &proc->hp);
	else if (What == A_REGISTERED_NAME)
	{
		val = probe->name;
		if (val == noval)
			return nil;		// be backward compatible
	}
	else if (What == A_SEQUENTIAL_TRACE_TOKEN)
	{
		//TODO
		val = A_UNDEFINED;
	}
	else if (What == A_STACK_SIZE)
	{
		int ss = proc_stack_bottom(probe) - proc_stack_top(probe);
		assert(fits_int(ss));
		val = tag_int(ss);
	}
	else if (What == A_STATUS)
	{
		if (probe->my_queue == MY_QUEUE_NORMAL ||
			probe->my_queue == MY_QUEUE_HIGH ||
			probe->my_queue == MY_QUEUE_LOW)
				val = A_RUNNABLE;
		else if (probe->my_queue == MY_QUEUE_INF_WAIT ||
				 probe->my_queue == MY_QUEUE_TIMED_WAIT)
			val = A_WAITING;
		else
		{
			assert(probe->my_queue == MY_QUEUE_NONE);
			val = A_RUNNING;
		}
	}
	else if (What == A_SUSPENDING)
	{
		//TODO
		val = nil;
	}
	else if (What == A_TOTAL_HEAP_SIZE)
	{
		int ss = proc_stack_bottom(probe) - proc_stack_top(probe);
		int ths = probe->hp.total_size + ss;
		assert(fits_int(ths));
		val = tag_int(ths);
	}
	else if (What == A_TRACE)
	{
		//TODO
		val = A_UNDEFINED;
	}
	else if (What == A_TRAP_EXIT)
		val = probe->trap_exit;
	else
		badarg(What);

	return heap_tuple2(&proc->hp, What, val);
}