/*
* demo-json-rpc-server.c: JSON-RPC 2.0 demo server
*
* Copyright (c) 2015 - 2018, Přemysl Janouch
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
* OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
* CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*
*/
#define print_fatal_data ((void *) LOG_ERR)
#define print_error_data ((void *) LOG_ERR)
#define print_warning_data ((void *) LOG_WARNING)
#define print_status_data ((void *) LOG_INFO)
#define print_debug_data ((void *) LOG_DEBUG)
#define LIBERTY_WANT_SSL
#define LIBERTY_WANT_PROTO_HTTP
#define LIBERTY_WANT_PROTO_WS
#define LIBERTY_WANT_PROTO_SCGI
#define LIBERTY_WANT_PROTO_FASTCGI
#include "config.h"
#include "liberty/liberty.c"
#include
#include
#include
#include
#include
#include
#include
#include "http-parser/http_parser.h"
enum { PIPE_READ, PIPE_WRITE };
// --- libev helpers -----------------------------------------------------------
static bool
flush_queue (struct write_queue *queue, ev_io *watcher)
{
struct iovec vec[queue->len], *vec_iter = vec;
LIST_FOR_EACH (struct write_req, iter, queue->head)
*vec_iter++ = iter->data;
ssize_t written;
again:
written = writev (watcher->fd, vec, N_ELEMENTS (vec));
if (written < 0)
{
if (errno == EAGAIN)
goto skip;
if (errno == EINTR)
goto again;
return false;
}
write_queue_processed (queue, written);
skip:
if (write_queue_is_empty (queue))
ev_io_stop (EV_DEFAULT_ watcher);
else
ev_io_start (EV_DEFAULT_ watcher);
return true;
}
// --- Logging -----------------------------------------------------------------
static void
log_message_syslog (void *user_data, const char *quote, const char *fmt,
va_list ap)
{
int prio = (int) (intptr_t) user_data;
va_list va;
va_copy (va, ap);
int size = vsnprintf (NULL, 0, fmt, va);
va_end (va);
if (size < 0)
return;
char buf[size + 1];
if (vsnprintf (buf, sizeof buf, fmt, ap) >= 0)
syslog (prio, "%s%s", quote, buf);
}
// --- FastCGI -----------------------------------------------------------------
/// @defgroup FastCGI
/// @{
enum fcgi_request_state
{
FCGI_REQUEST_PARAMS, ///< Reading headers
FCGI_REQUEST_STDIN ///< Reading input
};
struct fcgi_request
{
struct fcgi_muxer *muxer; ///< The parent muxer
uint16_t request_id; ///< The ID of this request
uint8_t flags; ///< Request flags
enum fcgi_request_state state; ///< Parsing state
struct str_map headers; ///< Headers
struct fcgi_nv_parser hdr_parser; ///< Header parser
struct str output_buffer; ///< Output buffer
void *handler_data; ///< Handler data
};
struct fcgi_muxer
{
struct fcgi_parser parser; ///< FastCGI message parser
// TODO: bool quitting; that causes us to reject all requests?
void (*write_cb) (void *user_data, const void *data, size_t len);
void (*close_cb) (void *user_data);
void *(*request_start_cb) (void *user_data, struct fcgi_request *request);
void (*request_push_cb) (void *handler_data, const void *data, size_t len);
void (*request_destroy_cb) (void *handler_data);
void *user_data; ///< User data for callbacks
/// Requests assigned to request IDs (may not be FCGI_NULL_REQUEST_ID)
struct fcgi_request *requests[1 << 8];
};
static void
fcgi_muxer_send (struct fcgi_muxer *self,
enum fcgi_type type, uint16_t request_id, const void *data, size_t len)
{
hard_assert (len <= UINT16_MAX);
struct str message = str_make ();
static char zeroes[8];
size_t padding = -len & 7;
str_pack_u8 (&message, FCGI_VERSION_1);
str_pack_u8 (&message, type);
str_pack_u16 (&message, request_id);
str_pack_u16 (&message, len); // content length
str_pack_u8 (&message, padding); // padding length
str_pack_u8 (&message, 0); // reserved
str_append_data (&message, data, len);
str_append_data (&message, zeroes, padding);
// XXX: we should probably have another write_cb that assumes ownership
self->write_cb (self->user_data, message.str, message.len);
str_free (&message);
}
static void
fcgi_muxer_send_end_request (struct fcgi_muxer *self, uint16_t request_id,
uint32_t app_status, enum fcgi_protocol_status protocol_status)
{
uint8_t content[8] = { app_status >> 24, app_status >> 16,
app_status << 8, app_status, protocol_status };
fcgi_muxer_send (self, FCGI_END_REQUEST, request_id,
content, sizeof content);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
fcgi_request_init (struct fcgi_request *self)
{
memset (self, 0, sizeof *self);
self->headers = str_map_make (free);
self->hdr_parser = fcgi_nv_parser_make ();
self->hdr_parser.output = &self->headers;
}
static void
fcgi_request_free (struct fcgi_request *self)
{
str_map_free (&self->headers);
fcgi_nv_parser_free (&self->hdr_parser);
}
static void
fcgi_request_push_params
(struct fcgi_request *self, const void *data, size_t len)
{
if (self->state != FCGI_REQUEST_PARAMS)
{
// TODO: probably reject the request
return;
}
if (len)
fcgi_nv_parser_push (&self->hdr_parser, data, len);
else
{
// TODO: probably check the state of the header parser
// TODO: request_start() can return false, end the request here?
self->handler_data = self->muxer->request_start_cb
(self->muxer->user_data, self);
self->state = FCGI_REQUEST_STDIN;
}
}
static void
fcgi_request_push_stdin
(struct fcgi_request *self, const void *data, size_t len)
{
if (self->state != FCGI_REQUEST_STDIN)
{
// TODO: probably reject the request
return;
}
self->muxer->request_push_cb (self->handler_data, data, len);
}
static void
fcgi_request_flush (struct fcgi_request *self)
{
if (!self->output_buffer.len)
return;
fcgi_muxer_send (self->muxer, FCGI_STDOUT, self->request_id,
self->output_buffer.str, self->output_buffer.len);
str_reset (&self->output_buffer);
}
static void
fcgi_request_write (struct fcgi_request *self, const void *data, size_t len)
{
// We're buffering the output and splitting it into messages
bool need_flush = true;
while (len)
{
size_t to_write = UINT16_MAX - self->output_buffer.len;
if (to_write > len)
{
to_write = len;
need_flush = false;
}
str_append_data (&self->output_buffer, data, to_write);
data = (uint8_t *) data + to_write;
len -= to_write;
if (need_flush)
fcgi_request_flush (self);
}
}
static void
fcgi_request_finish (struct fcgi_request *self)
{
// TODO: flush(), end_request(), delete self, muxer->request_destroy_cb()?
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
typedef void (*fcgi_muxer_handler_fn)
(struct fcgi_muxer *, const struct fcgi_parser *);
static void
fcgi_muxer_on_get_values
(struct fcgi_muxer *self, const struct fcgi_parser *parser)
{
if (parser->request_id != FCGI_NULL_REQUEST_ID)
{
print_debug ("FastCGI: ignoring invalid %s message",
STRINGIFY (FCGI_GET_VALUES));
return;
}
struct str_map values = str_map_make (free);
struct str_map response = str_map_make (free);
struct fcgi_nv_parser nv_parser = fcgi_nv_parser_make ();
nv_parser.output = &values;
fcgi_nv_parser_push (&nv_parser, parser->content.str, parser->content.len);
const char *key = NULL;
// No real-world servers seem to actually use multiplexing
// or even issue this request, but we will implement it anyway
if (str_map_find (&values, (key = FCGI_MPXS_CONNS)))
str_map_set (&response, key, xstrdup ("1"));
// It's not clear whether FCGI_MAX_REQS means concurrently over all
// connections or over just a single connection (multiplexed), though
// supposedly it's actually per /web server/. Supply the strictest limit.
if (str_map_find (&values, (key = FCGI_MAX_REQS)))
str_map_set (&response, key,
xstrdup_printf ("%zu", N_ELEMENTS (self->requests) - 1));
// FCGI_MAX_CONNS would be basically infinity. We don't limit connections.
struct str content = str_make ();
fcgi_nv_convert (&response, &content);
fcgi_muxer_send (self, FCGI_GET_VALUES_RESULT, parser->request_id,
content.str, content.len);
str_free (&content);
str_map_free (&values);
str_map_free (&response);
}
static void
fcgi_muxer_on_begin_request
(struct fcgi_muxer *self, const struct fcgi_parser *parser)
{
struct msg_unpacker unpacker =
msg_unpacker_make (parser->content.str, parser->content.len);
uint16_t role;
uint8_t flags;
bool success = true;
success &= msg_unpacker_u16 (&unpacker, &role);
success &= msg_unpacker_u8 (&unpacker, &flags);
// Ignoring 5 reserved bytes
if (!success)
{
print_debug ("FastCGI: ignoring invalid %s message",
STRINGIFY (FCGI_BEGIN_REQUEST));
return;
}
struct fcgi_request *request = self->requests[parser->request_id];
if (parser->request_id == FCGI_NULL_REQUEST_ID || request)
{
// TODO: fail
return;
}
// We can only act as a responder, reject everything else up front
if (role != FCGI_RESPONDER)
{
fcgi_muxer_send_end_request (self,
parser->request_id, 0, FCGI_UNKNOWN_ROLE);
return;
}
// TODO: also send OVERLOADED when shutting down?
if (parser->request_id >= N_ELEMENTS (self->requests))
{
fcgi_muxer_send_end_request (self,
parser->request_id, 0, FCGI_OVERLOADED);
return;
}
request = xcalloc (1, sizeof *request);
fcgi_request_init (request);
request->muxer = self;
request->request_id = parser->request_id;
request->flags = flags;
self->requests[parser->request_id] = request;
}
static void
fcgi_muxer_on_abort_request
(struct fcgi_muxer *self, const struct fcgi_parser *parser)
{
struct fcgi_request *request = self->requests[parser->request_id];
if (parser->request_id == FCGI_NULL_REQUEST_ID || !request)
{
print_debug ("FastCGI: received %s for an unknown request",
STRINGIFY (FCGI_ABORT_REQUEST));
return;
}
// TODO: abort the request: let it somehow produce FCGI_END_REQUEST,
// make sure to send an stdout EOF record
}
static void
fcgi_muxer_on_params (struct fcgi_muxer *self, const struct fcgi_parser *parser)
{
struct fcgi_request *request = self->requests[parser->request_id];
if (parser->request_id == FCGI_NULL_REQUEST_ID || !request)
{
print_debug ("FastCGI: received %s for an unknown request",
STRINGIFY (FCGI_PARAMS));
return;
}
fcgi_request_push_params (request,
parser->content.str, parser->content.len);
}
static void
fcgi_muxer_on_stdin (struct fcgi_muxer *self, const struct fcgi_parser *parser)
{
struct fcgi_request *request = self->requests[parser->request_id];
if (parser->request_id == FCGI_NULL_REQUEST_ID || !request)
{
print_debug ("FastCGI: received %s for an unknown request",
STRINGIFY (FCGI_STDIN));
return;
}
fcgi_request_push_stdin (request,
parser->content.str, parser->content.len);
}
static void
fcgi_muxer_on_message (const struct fcgi_parser *parser, void *user_data)
{
struct fcgi_muxer *self = user_data;
if (parser->version != FCGI_VERSION_1)
{
print_debug ("FastCGI: unsupported version %d", parser->version);
// TODO: also return false to stop processing on protocol error?
return;
}
static const fcgi_muxer_handler_fn handlers[] =
{
[FCGI_GET_VALUES] = fcgi_muxer_on_get_values,
[FCGI_BEGIN_REQUEST] = fcgi_muxer_on_begin_request,
[FCGI_ABORT_REQUEST] = fcgi_muxer_on_abort_request,
[FCGI_PARAMS] = fcgi_muxer_on_params,
[FCGI_STDIN] = fcgi_muxer_on_stdin,
};
fcgi_muxer_handler_fn handler;
if (parser->type >= N_ELEMENTS (handlers)
|| !(handler = handlers[parser->type]))
{
// Responding in this way even to application records, unspecified
uint8_t content[8] = { parser->type };
fcgi_muxer_send (self, FCGI_UNKNOWN_TYPE, parser->request_id,
content, sizeof content);
return;
}
handler (self, parser);
}
static void
fcgi_muxer_init (struct fcgi_muxer *self)
{
self->parser = fcgi_parser_make ();
self->parser.on_message = fcgi_muxer_on_message;
self->parser.user_data = self;
}
static void
fcgi_muxer_free (struct fcgi_muxer *self)
{
fcgi_parser_free (&self->parser);
}
static void
fcgi_muxer_push (struct fcgi_muxer *self, const void *data, size_t len)
{
fcgi_parser_push (&self->parser, data, len);
}
/// @}
// --- WebSockets --------------------------------------------------------------
/// @defgroup WebSockets
/// @{
// WebSockets aren't CGI-compatible, therefore we must handle the initial HTTP
// handshake ourselves. Luckily it's not too much of a bother with http-parser.
// Typically there will be a normal HTTP server in front of us, proxying the
// requests based on the URI.
enum ws_handler_state
{
WS_HANDLER_CONNECTING, ///< Parsing HTTP
WS_HANDLER_OPEN, ///< Parsing WebSockets frames
WS_HANDLER_CLOSING, ///< Closing the connection
WS_HANDLER_ALMOST_DEAD, ///< Closing connection after failure
WS_HANDLER_CLOSED ///< Dead
};
struct ws_handler
{
enum ws_handler_state state; ///< State
// HTTP handshake:
http_parser hp; ///< HTTP parser
bool have_header_value; ///< Parsing header value or field?
struct str field; ///< Field part buffer
struct str value; ///< Value part buffer
struct str_map headers; ///< HTTP Headers
struct str url; ///< Request URL
ev_timer handshake_timeout_watcher; ///< Handshake timeout watcher
// WebSocket frame protocol:
struct ws_parser parser; ///< Protocol frame parser
bool expecting_continuation; ///< For non-control traffic
enum ws_opcode message_opcode; ///< Opcode for the current message
struct str message_data; ///< Concatenated message data
ev_timer ping_timer; ///< Ping timer
bool received_pong; ///< Received PONG since the last PING
ev_timer close_timeout_watcher; ///< Close timeout watcher
// Configuration:
unsigned handshake_timeout; ///< How long to wait for the handshake
unsigned close_timeout; ///< How long to wait for TCP close
unsigned ping_interval; ///< Ping interval in seconds
uint64_t max_payload_len; ///< Maximum length of any message
// Event callbacks:
// TODO: void (*on_handshake) (protocols) that will allow the user
// to choose any sub-protocol, if the client has provided any.
// This may render "on_connected" unnecessary.
/// Called after successfuly connecting (handshake complete)
bool (*on_connected) (void *user_data);
/// Called upon reception of a single full message
bool (*on_message) (void *user_data,
enum ws_opcode type, const void *data, size_t len);
/// The connection is about to close. @a close_code may, or may not, be one
/// of enum ws_status. The @a reason is never NULL.
// TODO; also note that ideally, the handler should (be able to) first
// receive a notification about the connection being closed because of
// an error (recv()) returns -1, and call on_close() in reaction.
// Actually, calling push() could work pretty fine for this.
void (*on_close) (void *user_data, int close_code, const char *reason);
// Virtual method callbacks:
/// Write a chunk of data to the stream
void (*write_cb) (void *user_data, const void *data, size_t len);
/// Close the connection
void (*close_cb) (void *user_data);
void *user_data; ///< User data for callbacks
};
static void
ws_handler_send_control (struct ws_handler *self,
enum ws_opcode opcode, const void *data, size_t len)
{
if (len > WS_MAX_CONTROL_PAYLOAD_LEN)
{
print_debug ("truncating output control frame payload"
" from %zu to %zu bytes", len, (size_t) WS_MAX_CONTROL_PAYLOAD_LEN);
len = WS_MAX_CONTROL_PAYLOAD_LEN;
}
uint8_t header[2] = { 0x80 | (opcode & 0x0F), len };
self->write_cb (self->user_data, header, sizeof header);
self->write_cb (self->user_data, data, len);
}
static void
ws_handler_close (struct ws_handler *self,
enum ws_status close_code, const char *reason, size_t len)
{
struct str payload = str_make ();
str_pack_u16 (&payload, close_code);
// XXX: maybe accept a null-terminated string on input? Has to be UTF-8 a/w
str_append_data (&payload, reason, len);
ws_handler_send_control (self, WS_OPCODE_CLOSE, payload.str, payload.len);
// Close initiated by us; the reason is null-terminated within `payload'
if (self->on_close)
self->on_close (self->user_data, close_code, payload.str + 2);
self->state = WS_HANDLER_CLOSING;
str_free (&payload);
}
static void
ws_handler_fail (struct ws_handler *self, enum ws_status close_code)
{
ws_handler_close (self, close_code, NULL, 0);
self->state = WS_HANDLER_ALMOST_DEAD;
// TODO: set the close timer, ignore all further incoming input (either set
// some flag for the case that we're in the middle of ws_handler_push(),
// and/or add a mechanism to stop the caller from polling the socket for
// reads).
// TODO: make sure we don't send pings after the close
}
// TODO: add support for fragmented responses
static void
ws_handler_send (struct ws_handler *self,
enum ws_opcode opcode, const void *data, size_t len)
{
if (!soft_assert (self->state == WS_HANDLER_OPEN))
return;
struct str header = str_make ();
str_pack_u8 (&header, 0x80 | (opcode & 0x0F));
if (len > UINT16_MAX)
{
str_pack_u8 (&header, 127);
str_pack_u64 (&header, len);
}
else if (len > 125)
{
str_pack_u8 (&header, 126);
str_pack_u16 (&header, len);
}
else
str_pack_u8 (&header, len);
self->write_cb (self->user_data, header.str, header.len);
self->write_cb (self->user_data, data, len);
str_free (&header);
}
static bool
ws_handler_on_frame_header (void *user_data, const struct ws_parser *parser)
{
struct ws_handler *self = user_data;
// Note that we aren't expected to send any close frame before closing the
// connection when the frame is unmasked
if (parser->reserved_1 || parser->reserved_2 || parser->reserved_3
|| !parser->is_masked // client -> server payload must be masked
|| (ws_is_control_frame (parser->opcode) &&
(!parser->is_fin || parser->payload_len > WS_MAX_CONTROL_PAYLOAD_LEN))
|| (!ws_is_control_frame (parser->opcode) &&
(self->expecting_continuation && parser->opcode != WS_OPCODE_CONT))
|| parser->payload_len >= 0x8000000000000000ULL)
ws_handler_fail (self, WS_STATUS_PROTOCOL_ERROR);
else if (parser->payload_len > self->max_payload_len)
ws_handler_fail (self, WS_STATUS_MESSAGE_TOO_BIG);
else
return true;
return false;
}
static bool
ws_handler_on_protocol_close
(struct ws_handler *self, const struct ws_parser *parser)
{
struct msg_unpacker unpacker =
msg_unpacker_make (parser->input.str, parser->payload_len);
char *reason = NULL;
uint16_t close_code = WS_STATUS_NO_STATUS_RECEIVED;
if (parser->payload_len >= 2)
{
(void) msg_unpacker_u16 (&unpacker, &close_code);
reason = xstrndup (parser->input.str + 2, parser->payload_len - 2);
}
else
reason = xstrdup ("");
if (self->state != WS_HANDLER_CLOSING)
{
// Close initiated by the client
ws_handler_send_control (self, WS_OPCODE_CLOSE,
parser->input.str, parser->payload_len);
if (self->on_close)
self->on_close (self->user_data, close_code, reason);
}
free (reason);
self->state = WS_HANDLER_ALMOST_DEAD;
return true;
}
static bool
ws_handler_on_control_frame
(struct ws_handler *self, const struct ws_parser *parser)
{
switch (parser->opcode)
{
case WS_OPCODE_CLOSE:
return ws_handler_on_protocol_close (self, parser);
case WS_OPCODE_PING:
ws_handler_send_control (self, WS_OPCODE_PONG,
parser->input.str, parser->payload_len);
break;
case WS_OPCODE_PONG:
// XXX: maybe we should check the payload
self->received_pong = true;
break;
default:
// Unknown control frame
ws_handler_fail (self, WS_STATUS_PROTOCOL_ERROR);
// FIXME: we shouldn't close the connection right away;
// also check other places
return false;
}
return true;
}
static bool
ws_handler_on_frame (void *user_data, const struct ws_parser *parser)
{
struct ws_handler *self = user_data;
if (ws_is_control_frame (parser->opcode))
return ws_handler_on_control_frame (self, parser);
// TODO: do this rather in "on_frame_header"
if (self->message_data.len + parser->payload_len > self->max_payload_len)
{
ws_handler_fail (self, WS_STATUS_MESSAGE_TOO_BIG);
return false;
}
if (!self->expecting_continuation)
self->message_opcode = parser->opcode;
str_append_data (&self->message_data,
parser->input.str, parser->payload_len);
self->expecting_continuation = !parser->is_fin;
if (!parser->is_fin)
return true;
if (self->message_opcode == WS_OPCODE_TEXT
&& !utf8_validate (self->message_data.str, self->message_data.len))
{
ws_handler_fail (self, WS_STATUS_INVALID_PAYLOAD_DATA);
return false;
}
bool result = true;
if (self->on_message)
result = self->on_message (self->user_data, self->message_opcode,
self->message_data.str, self->message_data.len);
str_reset (&self->message_data);
return result;
}
static void
ws_handler_on_ping_timer (EV_P_ ev_timer *watcher, int revents)
{
(void) loop;
(void) revents;
struct ws_handler *self = watcher->data;
if (!self->received_pong)
{
// TODO: close/fail the connection?
}
else
{
ws_handler_send_control (self, WS_OPCODE_PING, NULL, 0);
ev_timer_again (EV_A_ watcher);
}
}
static void
ws_handler_on_close_timeout (EV_P_ ev_timer *watcher, int revents)
{
(void) revents;
struct ws_handler *self = watcher->data;
// TODO: anything else to do here? Invalidate our state?
if (self->close_cb)
self->close_cb (self->user_data);
}
static void
ws_handler_on_handshake_timeout (EV_P_ ev_timer *watcher, int revents)
{
(void) revents;
struct ws_handler *self = watcher->data;
// TODO
}
static void
ws_handler_init (struct ws_handler *self)
{
memset (self, 0, sizeof *self);
self->state = WS_HANDLER_CONNECTING;
http_parser_init (&self->hp, HTTP_REQUEST);
self->hp.data = self;
self->field = str_make ();
self->value = str_make ();
self->headers = str_map_make (free);
self->headers.key_xfrm = tolower_ascii_strxfrm;
self->url = str_make ();
ev_timer_init (&self->handshake_timeout_watcher,
ws_handler_on_handshake_timeout, 0., 0.);
self->handshake_timeout_watcher.data = self;
self->parser = ws_parser_make ();
self->parser.on_frame_header = ws_handler_on_frame_header;
self->parser.on_frame = ws_handler_on_frame;
self->parser.user_data = self;
self->message_data = str_make ();
ev_timer_init (&self->ping_timer,
ws_handler_on_ping_timer, 0., 0.);
self->ping_timer.data = self;
ev_timer_init (&self->close_timeout_watcher,
ws_handler_on_close_timeout, 0., 0.);
self->ping_timer.data = self;
// So that the first ping timer doesn't timeout the connection
self->received_pong = true;
self->handshake_timeout = self->close_timeout = self->ping_interval = 60;
// This is still ridiculously high. Note that the most significant bit
// must always be zero, i.e. the protocol maximum is 0x7FFF FFFF FFFF FFFF.
self->max_payload_len = UINT32_MAX;
}
/// Stop all timers, not going to use the handler anymore
static void
ws_handler_stop (struct ws_handler *self)
{
ev_timer_stop (EV_DEFAULT_ &self->handshake_timeout_watcher);
ev_timer_stop (EV_DEFAULT_ &self->ping_timer);
ev_timer_stop (EV_DEFAULT_ &self->close_timeout_watcher);
}
static void
ws_handler_free (struct ws_handler *self)
{
ws_handler_stop (self);
str_free (&self->field);
str_free (&self->value);
str_map_free (&self->headers);
str_free (&self->url);
ws_parser_free (&self->parser);
str_free (&self->message_data);
}
static bool
ws_handler_header_field_is_a_list (const char *name)
{
// This must contain all header fields we use for anything
static const char *concatenable[] =
{ SEC_WS_PROTOCOL, SEC_WS_EXTENSIONS, "Connection", "Upgrade" };
for (size_t i = 0; i < N_ELEMENTS (concatenable); i++)
if (!strcasecmp_ascii (name, concatenable[i]))
return true;
return false;
}
static void
ws_handler_on_header_read (struct ws_handler *self)
{
// The HTTP parser unfolds values and removes preceding whitespace, but
// otherwise doesn't touch the values or the following whitespace.
// RFC 7230 states that trailing whitespace is not part of a field value
char *value = self->field.str;
size_t len = self->field.len;
while (len--)
if (value[len] == '\t' || value[len] == ' ')
value[len] = '\0';
else
break;
self->field.len = len;
const char *field = self->field.str;
const char *current = str_map_find (&self->headers, field);
if (ws_handler_header_field_is_a_list (field) && current)
str_map_set (&self->headers, field,
xstrdup_printf ("%s, %s", current, self->value.str));
else
// If the field cannot be concatenated, just overwrite the last value.
// Maybe we should issue a warning or something.
str_map_set (&self->headers, field, xstrdup (self->value.str));
}
static int
ws_handler_on_header_field (http_parser *parser, const char *at, size_t len)
{
struct ws_handler *self = parser->data;
if (self->have_header_value)
{
ws_handler_on_header_read (self);
str_reset (&self->field);
str_reset (&self->value);
}
str_append_data (&self->field, at, len);
self->have_header_value = false;
return 0;
}
static int
ws_handler_on_header_value (http_parser *parser, const char *at, size_t len)
{
struct ws_handler *self = parser->data;
str_append_data (&self->value, at, len);
self->have_header_value = true;
return 0;
}
static int
ws_handler_on_headers_complete (http_parser *parser)
{
struct ws_handler *self = parser->data;
if (self->have_header_value)
ws_handler_on_header_read (self);
// We strictly require a protocol upgrade
if (!parser->upgrade)
return 2;
return 0;
}
static int
ws_handler_on_url (http_parser *parser, const char *at, size_t len)
{
struct ws_handler *self = parser->data;
str_append_data (&self->value, at, len);
return 0;
}
#define HTTP_101_SWITCHING_PROTOCOLS "101 Switching Protocols"
#define HTTP_400_BAD_REQUEST "400 Bad Request"
#define HTTP_405_METHOD_NOT_ALLOWED "405 Method Not Allowed"
#define HTTP_417_EXPECTATION_FAILED "407 Expectation Failed"
#define HTTP_505_VERSION_NOT_SUPPORTED "505 HTTP Version Not Supported"
static void
ws_handler_http_responsev (struct ws_handler *self,
const char *status, char *const *fields)
{
hard_assert (status != NULL);
struct str response = str_make ();
str_append_printf (&response, "HTTP/1.1 %s\r\n", status);
while (*fields)
str_append_printf (&response, "%s\r\n", *fields++);
time_t now = time (NULL);
struct tm ts;
gmtime_r (&now, &ts);
// See RFC 7231, 7.1.1.2. Date
const char *dow[] = { "Sun", "Mon", "Tue", "Wed", "Thu", "Fri", "Sat" };
const char *moy[] = { "Jan", "Feb", "Mar", "Apr", "May", "Jun",
"Jul", "Aug", "Sep", "Oct", "Nov", "Dec" };
str_append_printf (&response,
"Date: %s, %02d %s %04d %02d:%02d:%02d GMT\r\n",
dow[ts.tm_wday], ts.tm_mday, moy[ts.tm_mon], ts.tm_year + 1900,
ts.tm_hour, ts.tm_min, ts.tm_sec);
str_append (&response, "Server: "
PROGRAM_NAME "/" PROGRAM_VERSION "\r\n\r\n");
self->write_cb (self->user_data, response.str, response.len);
str_free (&response);
}
static void
ws_handler_http_response (struct ws_handler *self, const char *status, ...)
{
struct strv v = strv_make ();
va_list ap;
va_start (ap, status);
const char *s;
while ((s = va_arg (ap, const char *)))
strv_append (&v, s);
va_end (ap);
ws_handler_http_responsev (self, status, v.vector);
strv_free (&v);
}
#define FAIL_HANDSHAKE(status, ...) \
BLOCK_START \
self->state = WS_HANDLER_ALMOST_DEAD; \
ws_handler_http_response (self, (status), __VA_ARGS__); \
return false; \
BLOCK_END
static bool
ws_handler_finish_handshake (struct ws_handler *self)
{
// XXX: we probably shouldn't use 505 to reject the minor version but w/e
if (self->hp.http_major != 1 || self->hp.http_minor < 1)
FAIL_HANDSHAKE (HTTP_505_VERSION_NOT_SUPPORTED, NULL);
if (self->hp.method != HTTP_GET)
FAIL_HANDSHAKE (HTTP_405_METHOD_NOT_ALLOWED, "Allow: GET", NULL);
// Your expectations are way too high
if (str_map_find (&self->headers, "Expect"))
FAIL_HANDSHAKE (HTTP_417_EXPECTATION_FAILED, NULL);
// Reject URLs specifying the schema and host; we're not parsing that
// TODO: actually do parse this and let our user decide if it matches
struct http_parser_url url;
if (http_parser_parse_url (self->url.str, self->url.len, false, &url)
|| (url.field_set & (1 << UF_SCHEMA | 1 << UF_HOST | 1 << UF_PORT))
|| !str_map_find (&self->headers, "Host"))
FAIL_HANDSHAKE (HTTP_400_BAD_REQUEST, NULL);
const char *connection = str_map_find (&self->headers, "Connection");
if (!connection || strcasecmp_ascii (connection, "Upgrade"))
FAIL_HANDSHAKE (HTTP_400_BAD_REQUEST, NULL);
// Check if we can actually upgrade the protocol to WebSockets
const char *upgrade = str_map_find (&self->headers, "Upgrade");
struct http_protocol *offered_upgrades = NULL;
bool can_upgrade = false;
if (upgrade && http_parse_upgrade (upgrade, &offered_upgrades))
// Case-insensitive according to RFC 6455; neither RFC 2616 nor 7230
// say anything at all about case-sensitivity for this field
LIST_FOR_EACH (struct http_protocol, iter, offered_upgrades)
{
if (!iter->version && !strcasecmp_ascii (iter->name, "websocket"))
can_upgrade = true;
http_protocol_destroy (iter);
}
if (!can_upgrade)
FAIL_HANDSHAKE (HTTP_400_BAD_REQUEST, NULL);
// Okay, we're finally past the basic HTTP/1.1 stuff
const char *key = str_map_find (&self->headers, SEC_WS_KEY);
const char *version = str_map_find (&self->headers, SEC_WS_VERSION);
/*
const char *protocol = str_map_find (&self->headers, SEC_WS_PROTOCOL);
const char *extensions = str_map_find (&self->headers, SEC_WS_EXTENSIONS);
*/
if (!key)
FAIL_HANDSHAKE (HTTP_400_BAD_REQUEST, NULL);
struct str tmp = str_make ();
bool key_is_valid = base64_decode (key, false, &tmp) && tmp.len == 16;
str_free (&tmp);
if (!key_is_valid)
FAIL_HANDSHAKE (HTTP_400_BAD_REQUEST, NULL);
if (!version)
FAIL_HANDSHAKE (HTTP_400_BAD_REQUEST, NULL);
if (strcmp (version, "13"))
FAIL_HANDSHAKE (HTTP_400_BAD_REQUEST, SEC_WS_VERSION ": 13", NULL);
struct strv fields = strv_make ();
strv_append_args (&fields,
"Upgrade: websocket",
"Connection: Upgrade",
NULL);
char *response_key = ws_encode_response_key (key);
strv_append_owned (&fields,
xstrdup_printf (SEC_WS_ACCEPT ": %s", response_key));
free (response_key);
// TODO: make it possible to choose Sec-Websocket-{Extensions,Protocol}
ws_handler_http_responsev (self,
HTTP_101_SWITCHING_PROTOCOLS, fields.vector);
strv_free (&fields);
ev_timer_init (&self->ping_timer, ws_handler_on_ping_timer,
self->ping_interval, 0);
ev_timer_start (EV_DEFAULT_ &self->ping_timer);
return true;
}
/// Tells the handler that the TCP connection has been established so it can
/// timeout when the client handshake doesn't arrive soon enough
static void
ws_handler_start (struct ws_handler *self)
{
ev_timer_set (&self->handshake_timeout_watcher,
self->handshake_timeout, 0.);
ev_timer_start (EV_DEFAULT_ &self->handshake_timeout_watcher);
}
/// Push data to the WebSocket handler; "len == 0" means EOF
static bool
ws_handler_push (struct ws_handler *self, const void *data, size_t len)
{
// TODO: make sure all timers are stopped appropriately
if (!len)
{
ev_timer_stop (EV_DEFAULT_ &self->handshake_timeout_watcher);
if (self->state == WS_HANDLER_OPEN)
{
if (self->on_close)
self->on_close (self->user_data,
WS_STATUS_ABNORMAL_CLOSURE, "");
}
else
{
// TODO: anything to do besides just closing the connection?
}
self->state = WS_HANDLER_CLOSED;
return false;
}
if (self->state == WS_HANDLER_ALMOST_DEAD)
// We're waiting for an EOF from the client, must not process data
return true;
if (self->state != WS_HANDLER_CONNECTING)
return ws_parser_push (&self->parser, data, len);
// The handshake hasn't been done yet, process HTTP headers
static const http_parser_settings http_settings =
{
.on_header_field = ws_handler_on_header_field,
.on_header_value = ws_handler_on_header_value,
.on_headers_complete = ws_handler_on_headers_complete,
.on_url = ws_handler_on_url,
};
size_t n_parsed = http_parser_execute (&self->hp,
&http_settings, data, len);
if (self->hp.upgrade)
{
ev_timer_stop (EV_DEFAULT_ &self->handshake_timeout_watcher);
// The handshake hasn't been finished, yet there is more data
// to be processed after the headers already
if (len - n_parsed)
FAIL_HANDSHAKE (HTTP_400_BAD_REQUEST, NULL);
if (!ws_handler_finish_handshake (self))
return false;
self->state = WS_HANDLER_OPEN;
if (self->on_connected)
return self->on_connected (self->user_data);
return true;
}
enum http_errno err = HTTP_PARSER_ERRNO (&self->hp);
if (n_parsed != len || err != HPE_OK)
{
ev_timer_stop (EV_DEFAULT_ &self->handshake_timeout_watcher);
if (err == HPE_CB_headers_complete)
print_debug ("WS handshake failed: %s", "missing `Upgrade' field");
else
print_debug ("WS handshake failed: %s",
http_errno_description (err));
FAIL_HANDSHAKE (HTTP_400_BAD_REQUEST, NULL);
}
return true;
}
/// @}
// --- Server ------------------------------------------------------------------
static struct simple_config_item g_config_table[] =
{
{ "bind_host", NULL, "Address of the server" },
{ "port_fastcgi", "9000", "Port to bind for FastCGI" },
{ "port_scgi", NULL, "Port to bind for SCGI" },
{ "port_ws", NULL, "Port to bind for WebSockets" },
{ "pid_file", NULL, "Full path for the PID file" },
// XXX: here belongs something like a web SPA that interfaces with us
{ "static_root", NULL, "The root for static content" },
{ NULL, NULL, NULL }
};
struct server_context
{
ev_signal sigterm_watcher; ///< Got SIGTERM
ev_signal sigint_watcher; ///< Got SIGINT
ev_timer quit_timeout_watcher; ///< Quit timeout watcher
bool quitting; ///< User requested quitting
struct listener *listeners; ///< Listeners
size_t n_listeners; ///< Number of listening sockets
struct client *clients; ///< Clients
unsigned n_clients; ///< Current number of connections
struct request_handler *handlers; ///< Request handlers
struct str_map config; ///< Server configuration
};
static void initiate_quit (struct server_context *self);
static void try_finish_quit (struct server_context *self);
static void on_quit_timeout (EV_P_ ev_timer *watcher, int revents);
static void close_listeners (struct server_context *self);
static void
server_context_init (struct server_context *self)
{
memset (self, 0, sizeof *self);
self->config = str_map_make (NULL);
simple_config_load_defaults (&self->config, g_config_table);
ev_timer_init (&self->quit_timeout_watcher, on_quit_timeout, 3., 0.);
self->quit_timeout_watcher.data = self;
}
static void
server_context_free (struct server_context *self)
{
// We really shouldn't attempt a quit without closing the clients first
soft_assert (!self->clients);
close_listeners (self);
free (self->listeners);
str_map_free (&self->config);
}
// --- JSON-RPC ----------------------------------------------------------------
/// @defgroup JSON-RPC
/// @{
#define JSON_RPC_ERROR_TABLE(XX) \
XX (-32700, PARSE_ERROR, "Parse error") \
XX (-32600, INVALID_REQUEST, "Invalid Request") \
XX (-32601, METHOD_NOT_FOUND, "Method not found") \
XX (-32602, INVALID_PARAMS, "Invalid params") \
XX (-32603, INTERNAL_ERROR, "Internal error")
enum json_rpc_error
{
#define XX(code, name, message) JSON_RPC_ERROR_ ## name,
JSON_RPC_ERROR_TABLE (XX)
#undef XX
JSON_RPC_ERROR_COUNT
};
static json_t *
json_rpc_error (enum json_rpc_error id, json_t *data)
{
#define XX(code, name, message) { code, message },
static const struct json_rpc_error
{
int code;
const char *message;
}
errors[JSON_RPC_ERROR_COUNT] =
{
JSON_RPC_ERROR_TABLE (XX)
};
#undef XX
json_t *error = json_object ();
json_object_set_new (error, "code", json_integer (errors[id].code));
json_object_set_new (error, "message", json_string (errors[id].message));
if (data)
json_object_set_new (error, "data", data);
return error;
}
static json_t *
json_rpc_response (json_t *id, json_t *result, json_t *error)
{
json_t *x = json_object ();
json_object_set_new (x, "jsonrpc", json_string ("2.0"));
json_object_set_new (x, "id", id ? id : json_null ());
if (result) json_object_set_new (x, "result", result);
if (error) json_object_set_new (x, "error", error);
return x;
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static bool
validate_json_rpc_content_type (const char *content_type)
{
char *type = NULL;
char *subtype = NULL;
struct str_map parameters = str_map_make (free);
parameters.key_xfrm = tolower_ascii_strxfrm;
bool result = http_parse_media_type
(content_type, &type, &subtype, ¶meters);
if (!result)
goto end;
if (strcasecmp_ascii (type, "application")
|| (strcasecmp_ascii (subtype, "json") &&
strcasecmp_ascii (subtype, "json-rpc" /* obsolete */)))
result = false;
const char *charset = str_map_find (¶meters, "charset");
if (charset && strcasecmp_ascii (charset, "UTF-8"))
result = false;
// Currently ignoring all unknown parametrs
end:
free (type);
free (subtype);
str_map_free (¶meters);
return result;
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
typedef json_t *(*json_rpc_handler_fn) (struct server_context *, json_t *);
struct json_rpc_handler_info
{
const char *method_name; ///< JSON-RPC method name
json_rpc_handler_fn handler; ///< Method handler
};
static int
json_rpc_handler_info_cmp (const void *first, const void *second)
{
return strcmp (((struct json_rpc_handler_info *) first)->method_name,
((struct json_rpc_handler_info *) second)->method_name);
}
// TODO: a method that sends a response after a certain number of seconds.
// This has to be owned by the server context as a background job that
// removes itself upon completion.
static json_t *
json_rpc_ping (struct server_context *ctx, json_t *params)
{
(void) ctx;
(void) params;
return json_rpc_response (NULL, json_string ("pong"), NULL);
}
static json_t *
process_json_rpc_request (struct server_context *ctx, json_t *request)
{
// A list of all available methods; this list has to be ordered.
// Eventually it might be better to move this into a map in the context.
static struct json_rpc_handler_info handlers[] =
{
{ "ping", json_rpc_ping },
};
if (!json_is_object (request))
return json_rpc_response (NULL, NULL,
json_rpc_error (JSON_RPC_ERROR_INVALID_REQUEST, NULL));
json_t *v = json_object_get (request, "jsonrpc");
json_t *m = json_object_get (request, "method");
json_t *params = json_object_get (request, "params");
json_t *id = json_object_get (request, "id");
const char *version;
const char *method;
bool ok = true;
ok &= v && (version = json_string_value (v)) && !strcmp (version, "2.0");
ok &= m && (method = json_string_value (m));
ok &= !params || json_is_array (params) || json_is_object (params);
ok &= !id || json_is_null (id) ||
json_is_string (id) || json_is_number (id);
if (!ok)
return json_rpc_response (id, NULL,
json_rpc_error (JSON_RPC_ERROR_INVALID_REQUEST, NULL));
struct json_rpc_handler_info key = { .method_name = method };
struct json_rpc_handler_info *handler = bsearch (&key, handlers,
N_ELEMENTS (handlers), sizeof key, json_rpc_handler_info_cmp);
if (!handler)
return json_rpc_response (id, NULL,
json_rpc_error (JSON_RPC_ERROR_METHOD_NOT_FOUND, NULL));
json_t *response = handler->handler (ctx, params);
if (id)
return response;
// Notifications don't get responses
json_decref (response);
return NULL;
}
static void
flush_json (json_t *json, struct str *output)
{
char *utf8 = json_dumps (json, JSON_ENCODE_ANY);
str_append (output, utf8);
free (utf8);
json_decref (json);
}
static void
process_json_rpc (struct server_context *ctx,
const void *data, size_t len, struct str *output)
{
json_error_t e;
json_t *request;
if (!(request = json_loadb (data, len, JSON_DECODE_ANY, &e)))
{
flush_json (json_rpc_response (NULL, NULL,
json_rpc_error (JSON_RPC_ERROR_PARSE_ERROR, NULL)),
output);
return;
}
if (json_is_array (request))
{
if (!json_array_size (request))
{
flush_json (json_rpc_response (NULL, NULL,
json_rpc_error (JSON_RPC_ERROR_INVALID_REQUEST, NULL)),
output);
return;
}
json_t *response = json_array ();
json_t *iter;
size_t i;
json_array_foreach (request, i, iter)
{
json_t *result = process_json_rpc_request (ctx, iter);
if (result)
json_array_append_new (response, result);
}
if (json_array_size (response))
flush_json (response, output);
else
json_decref (response);
}
else
{
json_t *result = process_json_rpc_request (ctx, request);
if (result)
flush_json (result, output);
}
}
/// @}
// --- Requests ----------------------------------------------------------------
/// @defgroup Requests
/// @{
/// A generic CGI request abstraction, writing data indirectly through callbacks
struct request
{
struct server_context *ctx; ///< Server context
struct request_handler *handler; ///< Assigned request handler
void *handler_data; ///< User data for the handler
/// Callback to write some CGI response data to the output
void (*write_cb) (void *user_data, const void *data, size_t len);
/// Callback to close the connection.
/// CALLING THIS MAY CAUSE THE REQUEST TO BE DESTROYED.
void (*close_cb) (void *user_data);
void *user_data; ///< User data argument for callbacks
};
/// An interface to detect and handle specific kinds of CGI requests.
/// The server walks through a list of them until it finds one that can serve
/// a particular request. If unsuccessful, the remote client gets a 404
/// (the default handling).
struct request_handler
{
LIST_HEADER (struct request_handler)
/// Install ourselves as the handler for the request, if applicable.
/// Sets @a continue_ to false if further processing should be stopped,
/// meaning the request has already been handled.
bool (*try_handle) (struct request *request,
struct str_map *headers, bool *continue_);
/// Handle incoming data.
/// Returns false if there is no more processing to be done.
bool (*push_cb) (struct request *request, const void *data, size_t len);
/// Destroy the handler's data stored in the request object
void (*destroy_cb) (struct request *request);
};
static void
request_init (struct request *self)
{
memset (self, 0, sizeof *self);
}
static void
request_free (struct request *self)
{
if (self->handler)
self->handler->destroy_cb (self);
}
/// This function is only intended to be run from asynchronous event handlers
/// such as timers, not as a direct result of starting the request or receiving
/// request data. CALLING THIS MAY CAUSE THE REQUEST TO BE DESTROYED.
static void
request_finish (struct request *self)
{
self->close_cb (self->user_data);
}
/// Starts processing a request. Returns false if no further action is to be
/// done and the request should be finished.
static bool
request_start (struct request *self, struct str_map *headers)
{
// XXX: it feels like this should rather be two steps:
// bool (*can_handle) (request *, headers)
// ... install the handler ...
// bool (*handle) (request *)
//
// However that might cause some stuff to be done twice.
//
// Another way we could get rid of the continue_ argument is via adding
// some way of marking the request as finished from within the handler.
bool continue_ = true;
LIST_FOR_EACH (struct request_handler, handler, self->ctx->handlers)
if (handler->try_handle (self, headers, &continue_))
{
self->handler = handler;
return continue_;
}
// Unable to serve the request
struct str response = str_make ();
str_append (&response, "Status: 404 Not Found\n");
str_append (&response, "Content-Type: text/plain\n\n");
self->write_cb (self->user_data, response.str, response.len);
str_free (&response);
return false;
}
static bool
request_push (struct request *self, const void *data, size_t len)
{
if (!soft_assert (self->handler))
// No handler, nothing to do with any data
return false;
return self->handler->push_cb (self, data, len);
}
/// @}
// --- Requests handlers -------------------------------------------------------
static bool
request_handler_json_rpc_try_handle
(struct request *request, struct str_map *headers, bool *continue_)
{
const char *content_type = str_map_find (headers, "CONTENT_TYPE");
const char *method = str_map_find (headers, "REQUEST_METHOD");
if (!method || strcmp (method, "POST")
|| !content_type || !validate_json_rpc_content_type (content_type))
return false;
struct str *buf = xcalloc (1, sizeof *buf);
*buf = str_make ();
request->handler_data = buf;
*continue_ = true;
return true;
}
static bool
request_handler_json_rpc_push
(struct request *request, const void *data, size_t len)
{
struct str *buf = request->handler_data;
if (len)
{
str_append_data (buf, data, len);
return true;
}
// TODO: check buf.len against CONTENT_LENGTH; if it's less, then the
// client hasn't been successful in transferring all of its data
struct str response = str_make ();
str_append (&response, "Status: 200 OK\n");
str_append_printf (&response, "Content-Type: %s\n\n", "application/json");
process_json_rpc (request->ctx, buf->str, buf->len, &response);
request->write_cb (request->user_data, response.str, response.len);
str_free (&response);
return false;
}
static void
request_handler_json_rpc_destroy (struct request *request)
{
struct str *buf = request->handler_data;
str_free (buf);
free (buf);
request->handler_data = NULL;
}
struct request_handler g_request_handler_json_rpc =
{
.try_handle = request_handler_json_rpc_try_handle,
.push_cb = request_handler_json_rpc_push,
.destroy_cb = request_handler_json_rpc_destroy,
};
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static char *
canonicalize_url_path (const char *path)
{
// XXX: this strips any slashes at the end
struct strv v = strv_make ();
cstr_split (path, "/", true, &v);
struct strv canonical = strv_make ();
// So that the joined path always begins with a slash
strv_append (&canonical, "");
for (size_t i = 0; i < v.len; i++)
{
const char *dir = v.vector[i];
if (!strcmp (dir, "."))
continue;
if (strcmp (dir, ".."))
strv_append (&canonical, dir);
else if (canonical.len > 1)
// ".." never goes above the root
strv_remove (&canonical, canonical.len - 1);
}
strv_free (&v);
char *joined = strv_join (&canonical, "/");
strv_free (&canonical);
return joined;
}
static char *
detect_magic (const void *data, size_t len)
{
magic_t cookie;
char *mime_type = NULL;
if (!(cookie = magic_open (MAGIC_MIME)))
return NULL;
const char *magic = NULL;
if (!magic_load (cookie, NULL)
&& (magic = magic_buffer (cookie, data, len)))
mime_type = xstrdup (magic);
else
print_debug ("MIME type detection failed: %s", magic_error (cookie));
magic_close (cookie);
return mime_type;
}
static bool
request_handler_static_try_handle
(struct request *request, struct str_map *headers, bool *continue_)
{
// Serving static files is actually quite complicated as it turns out;
// but this is only meant to serve a few tiny text files
struct server_context *ctx = request->ctx;
const char *root = str_map_find (&ctx->config, "static_root");
if (!root)
{
print_debug ("static document root not configured");
return false;
}
const char *method = str_map_find (headers, "REQUEST_METHOD");
if (!method || strcmp (method, "GET"))
return false;
// TODO: look at , REQUEST_URI in the headers
const char *path_info = str_map_find (headers, "PATH_INFO");
if (!path_info)
{
print_debug ("PATH_INFO not defined");
return false;
}
// We need to filter the path to stay in our root
// Being able to read /etc/passwd would be rather embarrasing
char *suffix = canonicalize_url_path (path_info);
char *path = xstrdup_printf ("%s%s", root, suffix);
// TODO: check that this is a regular file
FILE *fp = fopen (path, "rb");
if (!fp)
{
struct str response = str_make ();
str_append (&response, "Status: 404 Not Found\n");
str_append (&response, "Content-Type: text/plain\n\n");
str_append_printf (&response,
"File %s was not found on this server\n", suffix);
request->write_cb (request->user_data, response.str, response.len);
str_free (&response);
free (suffix);
free (path);
return false;
}
free (suffix);
free (path);
uint8_t buf[8192];
size_t len;
// Try to detect the Content-Type from the actual contents
char *mime_type = NULL;
if ((len = fread (buf, 1, sizeof buf, fp)))
mime_type = detect_magic (buf, len);
if (!mime_type)
mime_type = xstrdup ("application/octet_stream");
struct str response = str_make ();
str_append (&response, "Status: 200 OK\n");
str_append_printf (&response, "Content-Type: %s\n\n", mime_type);
request->write_cb (request->user_data, response.str, response.len);
str_free (&response);
free (mime_type);
// Write the chunk we've used to help us with magic detection;
// obviously we have to do it after we've written the headers
if (len)
request->write_cb (request->user_data, buf, len);
while ((len = fread (buf, 1, sizeof buf, fp)))
request->write_cb (request->user_data, buf, len);
fclose (fp);
// TODO: this should rather not be returned all at once but in chunks;
// file read requests never return EAGAIN
// TODO: actual file data should really be returned by a callback when
// the socket is writable with nothing to be sent (pumping the entire
// file all at once won't really work if it's huge).
*continue_ = false;
return true;
}
static bool
request_handler_static_push
(struct request *request, const void *data, size_t len)
{
(void) request;
(void) data;
(void) len;
// Ignoring all content; we shouldn't receive any (GET)
return false;
}
static void
request_handler_static_destroy (struct request *request)
{
(void) request;
// Nothing to dispose of this far
}
struct request_handler g_request_handler_static =
{
.try_handle = request_handler_static_try_handle,
.push_cb = request_handler_static_push,
.destroy_cb = request_handler_static_destroy,
};
// --- Client communication handlers -------------------------------------------
/// A virtual class for client connections coming either from the web server
/// or directly from the end-client, depending on the protocol in use
struct client
{
LIST_HEADER (struct client)
// XXX: do we really need this here?
struct server_context *ctx; ///< Server context
int socket_fd; ///< The TCP socket
struct write_queue write_queue; ///< Write queue
ev_io read_watcher; ///< The socket can be read from
ev_io write_watcher; ///< The socket can be written to
struct client_vtable *vtable; ///< Client behaviour
};
/// The concrete behaviour to serve a particular client's requests
struct client_vtable
{
/// Attempt a graceful shutdown
void (*shutdown) (struct client *client);
/// Do any additional cleanup
// TODO: rename to "finalize" or "cleanup"?
void (*destroy) (struct client *client);
/// Process incoming data; "len == 0" means EOF
bool (*push) (struct client *client, const void *data, size_t len);
};
static void
client_free (struct client *self)
{
write_queue_free (&self->write_queue);
}
static void
client_write (struct client *self, const void *data, size_t len)
{
struct write_req *req = xcalloc (1, sizeof *req);
req->data.iov_base = memcpy (xmalloc (len), data, len);
req->data.iov_len = len;
write_queue_add (&self->write_queue, req);
ev_io_start (EV_DEFAULT_ &self->write_watcher);
}
static void
client_destroy (struct client *self)
{
struct server_context *ctx = self->ctx;
LIST_UNLINK (ctx->clients, self);
ctx->n_clients--;
// First uninitialize the higher-level implementation
self->vtable->destroy (self);
ev_io_stop (EV_DEFAULT_ &self->read_watcher);
ev_io_stop (EV_DEFAULT_ &self->write_watcher);
xclose (self->socket_fd);
client_free (self);
free (self);
try_finish_quit (ctx);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static bool
client_read_loop (EV_P_ struct client *client, ev_io *watcher)
{
char buf[8192];
while (true)
{
ssize_t n_read = recv (watcher->fd, buf, sizeof buf, 0);
if (n_read >= 0)
{
if (!client->vtable->push (client, buf, n_read))
return false;
if (!n_read)
break;
}
else if (errno == EAGAIN)
return true;
else if (errno != EINTR)
return false;
}
// Don't receive the EOF condition repeatedly
ev_io_stop (EV_A_ watcher);
// We can probably still write, so let's just return
// XXX: if there's nothing to be written, shouldn't we close the connection?
return true;
}
static void
on_client_ready (EV_P_ ev_io *watcher, int revents)
{
struct client *client = watcher->data;
// XXX: although read and write are in a sequence, if we create response
// data, we'll still likely need to go back to the event loop.
if (revents & EV_READ)
if (!client_read_loop (EV_A_ client, watcher))
goto close;
if (revents & EV_WRITE)
// TODO: add "closing link" functionality -> automatic shutdown
// (half-close) once we manage to flush the write buffer,
// which is logically followed by waiting for an EOF from the client
// TODO: some sort of "on_buffers_flushed" callback for streaming huge
// chunks of external (or generated) data.
if (!flush_queue (&client->write_queue, watcher))
goto close;
return;
close:
client_destroy (client);
}
static void
client_init (EV_P_ struct client *self, int sock_fd)
{
struct server_context *ctx = ev_userdata (loop);
memset (self, 0, sizeof *self);
self->ctx = ctx;
self->write_queue = write_queue_make ();
set_blocking (sock_fd, false);
self->socket_fd = sock_fd;
ev_io_init (&self->read_watcher, on_client_ready, sock_fd, EV_READ);
ev_io_init (&self->write_watcher, on_client_ready, sock_fd, EV_WRITE);
self->read_watcher.data = self;
self->write_watcher.data = self;
// We're only interested in reading as the write queue is empty now
ev_io_start (EV_A_ &self->read_watcher);
LIST_PREPEND (ctx->clients, self);
ctx->n_clients++;
}
// --- FastCGI client handler --------------------------------------------------
struct client_fcgi
{
struct client client; ///< Parent class
struct fcgi_muxer muxer; ///< FastCGI de/multiplexer
};
struct client_fcgi_request
{
struct fcgi_request *fcgi_request; ///< FastCGI request
struct request request; ///< Request
};
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
client_fcgi_request_write_cb (void *user_data, const void *data, size_t len)
{
struct client_fcgi_request *request = user_data;
fcgi_request_write (request->fcgi_request, data, len);
}
static void
client_fcgi_request_close_cb (void *user_data)
{
struct client_fcgi_request *request = user_data;
// No more data to send, terminate the substream/request
// XXX: this will most probably end up with client_fcgi_request_destroy(),
// we might or might not need to defer this action
fcgi_request_finish (request->fcgi_request);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void *
client_fcgi_request_start (void *user_data, struct fcgi_request *fcgi_request)
{
struct client_fcgi *self = user_data;
// TODO: what if the request is aborted by ;
struct client_fcgi_request *request = xcalloc (1, sizeof *request);
request->fcgi_request = fcgi_request;
request_init (&request->request);
request->request.ctx = self->client.ctx;
request->request.write_cb = client_fcgi_request_write_cb;
request->request.close_cb = client_fcgi_request_close_cb;
request->request.user_data = request;
return request;
}
static void
client_fcgi_request_push (void *handler_data, const void *data, size_t len)
{
struct client_fcgi_request *request = handler_data;
request_push (&request->request, data, len);
}
static void
client_fcgi_request_destroy (void *handler_data)
{
struct client_fcgi_request *request = handler_data;
request_free (&request->request);
free (request);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
client_fcgi_write_cb (void *user_data, const void *data, size_t len)
{
struct client_fcgi *self = user_data;
client_write (&self->client, data, len);
}
static void
client_fcgi_close_cb (void *user_data)
{
struct client_fcgi *self = user_data;
// FIXME: we should probably call something like client_shutdown(),
// which may have an argument whether we should really use close()
client_destroy (&self->client);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
client_fcgi_shutdown (struct client *client)
{
struct client_fcgi *self = (struct client_fcgi *) client;
// TODO: respond with FCGI_END_REQUEST: FCGI_REQUEST_COMPLETE to everything,
// and start sending out FCGI_OVERLOADED to all incoming requests. The
// FastCGI specification isn't very clear about what we should do.
}
static void
client_fcgi_destroy (struct client *client)
{
struct client_fcgi *self = (struct client_fcgi *) client;
fcgi_muxer_free (&self->muxer);
}
static bool
client_fcgi_push (struct client *client, const void *data, size_t len)
{
struct client_fcgi *self = (struct client_fcgi *) client;
fcgi_muxer_push (&self->muxer, data, len);
return true;
}
static struct client_vtable client_fcgi_vtable =
{
.shutdown = client_fcgi_shutdown,
.destroy = client_fcgi_destroy,
.push = client_fcgi_push,
};
static struct client *
client_fcgi_create (EV_P_ int sock_fd)
{
struct client_fcgi *self = xcalloc (1, sizeof *self);
client_init (EV_A_ &self->client, sock_fd);
self->client.vtable = &client_fcgi_vtable;
fcgi_muxer_init (&self->muxer);
self->muxer.write_cb = client_fcgi_write_cb;
self->muxer.close_cb = client_fcgi_close_cb;
self->muxer.request_start_cb = client_fcgi_request_start;
self->muxer.request_push_cb = client_fcgi_request_push;
self->muxer.request_destroy_cb = client_fcgi_request_destroy;
self->muxer.user_data = self;
return &self->client;
}
// --- SCGI client handler -----------------------------------------------------
struct client_scgi
{
struct client client; ///< Parent class
struct scgi_parser parser; ///< SCGI stream parser
struct request request; ///< Request (only one per connection)
};
static void
client_scgi_write_cb (void *user_data, const void *data, size_t len)
{
struct client_scgi *self = user_data;
client_write (&self->client, data, len);
}
static void
client_scgi_close_cb (void *user_data)
{
// NOTE: this rather really means "close me [the request]"
struct client_scgi *self = user_data;
// FIXME: we should probably call something like client_shutdown(),
// which may have an argument whether we should really use close()
client_destroy (&self->client);
}
static bool
client_scgi_on_headers_read (void *user_data)
{
struct client_scgi *self = user_data;
return request_start (&self->request, &self->parser.headers);
}
static bool
client_scgi_on_content (void *user_data, const void *data, size_t len)
{
struct client_scgi *self = user_data;
// XXX: do we have to count CONTENT_LENGTH and supply our own EOF?
// If we do produce our own EOF, we should probably make sure we don't
// send it twice in a row.
return request_push (&self->request, data, len);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
client_scgi_destroy (struct client *client)
{
struct client_scgi *self = (struct client_scgi *) client;
request_free (&self->request);
scgi_parser_free (&self->parser);
}
static bool
client_scgi_push (struct client *client, const void *data, size_t len)
{
struct client_scgi *self = (struct client_scgi *) client;
struct error *e = NULL;
if (scgi_parser_push (&self->parser, data, len, &e))
return true;
if (e != NULL)
{
print_debug ("SCGI parser failed: %s", e->message);
error_free (e);
}
return false;
}
static struct client_vtable client_scgi_vtable =
{
.destroy = client_scgi_destroy,
.push = client_scgi_push,
};
static struct client *
client_scgi_create (EV_P_ int sock_fd)
{
struct client_scgi *self = xcalloc (1, sizeof *self);
client_init (EV_A_ &self->client, sock_fd);
self->client.vtable = &client_scgi_vtable;
request_init (&self->request);
self->request.ctx = self->client.ctx;
self->request.write_cb = client_scgi_write_cb;
self->request.close_cb = client_scgi_close_cb;
self->request.user_data = self;
self->parser = scgi_parser_make ();
self->parser.on_headers_read = client_scgi_on_headers_read;
self->parser.on_content = client_scgi_on_content;
self->parser.user_data = self;
return &self->client;
}
// --- WebSockets client handler -----------------------------------------------
struct client_ws
{
struct client client; ///< Parent class
struct ws_handler handler; ///< WebSockets connection handler
};
static bool
client_ws_on_message (void *user_data,
enum ws_opcode type, const void *data, size_t len)
{
struct client_ws *self = user_data;
if (type != WS_OPCODE_TEXT)
{
ws_handler_fail (&self->handler, WS_STATUS_UNSUPPORTED_DATA);
return false;
}
struct str response = str_make ();
process_json_rpc (self->client.ctx, data, len, &response);
if (response.len)
ws_handler_send (&self->handler,
WS_OPCODE_TEXT, response.str, response.len);
str_free (&response);
return true;
}
static void
client_ws_write_cb (void *user_data, const void *data, size_t len)
{
struct client *client = user_data;
client_write (client, data, len);
}
static void
client_ws_close_cb (void *user_data)
{
struct client_ws *self = user_data;
// FIXME: we should probably call something like client_shutdown(),
// which may have an argument whether we should really use close()
client_destroy (&self->client);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
client_ws_shutdown (struct client *client)
{
struct client_ws *self = (struct client_ws *) client;
ws_handler_close (&self->handler, WS_STATUS_GOING_AWAY, NULL, 0);
}
static void
client_ws_destroy (struct client *client)
{
struct client_ws *self = (struct client_ws *) client;
ws_handler_free (&self->handler);
}
static bool
client_ws_push (struct client *client, const void *data, size_t len)
{
struct client_ws *self = (struct client_ws *) client;
return ws_handler_push (&self->handler, data, len);
}
static struct client_vtable client_ws_vtable =
{
.shutdown = client_ws_shutdown,
.destroy = client_ws_destroy,
.push = client_ws_push,
};
static struct client *
client_ws_create (EV_P_ int sock_fd)
{
struct client_ws *self = xcalloc (1, sizeof *self);
client_init (EV_A_ &self->client, sock_fd);
self->client.vtable = &client_ws_vtable;
ws_handler_init (&self->handler);
self->handler.on_message = client_ws_on_message;
self->handler.write_cb = client_ws_write_cb;
self->handler.close_cb = client_ws_close_cb;
self->handler.user_data = self;
// One mebibyte seems to be a reasonable value
self->handler.max_payload_len = 1 << 10;
return &self->client;
}
// --- Basic server stuff ------------------------------------------------------
typedef struct client *(*client_create_fn) (EV_P_ int sock_fd);
struct listener
{
int fd; ///< Listening socket FD
ev_io watcher; ///< New connection available
client_create_fn create; ///< Client constructor
};
static void
close_listeners (struct server_context *self)
{
for (size_t i = 0; i < self->n_listeners; i++)
{
struct listener *listener = &self->listeners[i];
if (listener->fd == -1)
continue;
ev_io_stop (EV_DEFAULT_ &listener->watcher);
xclose (listener->fd);
listener->fd = -1;
}
}
static void
try_finish_quit (struct server_context *self)
{
if (!self->quitting || self->clients)
return;
ev_timer_stop (EV_DEFAULT_ &self->quit_timeout_watcher);
ev_break (EV_DEFAULT_ EVBREAK_ALL);
}
static void
on_quit_timeout (EV_P_ ev_timer *watcher, int revents)
{
struct server_context *self = watcher->data;
(void) loop;
(void) revents;
LIST_FOR_EACH (struct client, iter, self->clients)
client_destroy (iter);
}
static void
initiate_quit (struct server_context *self)
{
self->quitting = true;
close_listeners (self);
// Wait a little while for all clients to clean up, if necessary
LIST_FOR_EACH (struct client, iter, self->clients)
if (iter->vtable->shutdown)
iter->vtable->shutdown (iter);
ev_timer_start (EV_DEFAULT_ &self->quit_timeout_watcher);
try_finish_quit (self);
}
static void
on_client_available (EV_P_ ev_io *watcher, int revents)
{
struct server_context *ctx = ev_userdata (loop);
struct listener *listener = watcher->data;
(void) revents;
while (true)
{
int sock_fd = accept (watcher->fd, NULL, NULL);
if (sock_fd != -1)
listener->create (EV_A_ sock_fd);
else if (errno == EAGAIN)
return;
else if (errno != EINTR && errno != EMFILE
&& errno != ECONNRESET && errno != ECONNABORTED)
break;
}
// Stop accepting connections to prevent busy looping
ev_io_stop (EV_A_ watcher);
print_fatal ("%s: %s", "accept", strerror (errno));
initiate_quit (ctx);
}
// --- Application setup -------------------------------------------------------
/// This function handles values that require validation before their first use,
/// or some kind of a transformation (such as conversion to an integer) needs
/// to be done before they can be used directly.
static bool
parse_config (struct server_context *ctx, struct error **e)
{
(void) ctx;
(void) e;
return true;
}
static int
listener_bind (struct addrinfo *gai_iter)
{
int fd = socket (gai_iter->ai_family,
gai_iter->ai_socktype, gai_iter->ai_protocol);
if (fd == -1)
return -1;
set_cloexec (fd);
int yes = 1;
soft_assert (setsockopt (fd, SOL_SOCKET, SO_KEEPALIVE,
&yes, sizeof yes) != -1);
soft_assert (setsockopt (fd, SOL_SOCKET, SO_REUSEADDR,
&yes, sizeof yes) != -1);
char host[NI_MAXHOST], port[NI_MAXSERV];
host[0] = port[0] = '\0';
int err = getnameinfo (gai_iter->ai_addr, gai_iter->ai_addrlen,
host, sizeof host, port, sizeof port,
NI_NUMERICHOST | NI_NUMERICSERV);
if (err)
print_debug ("%s: %s", "getnameinfo", gai_strerror (err));
char *address = format_host_port_pair (host, port);
if (bind (fd, gai_iter->ai_addr, gai_iter->ai_addrlen))
print_error ("bind to %s failed: %s", address, strerror (errno));
else if (listen (fd, 16 /* arbitrary number */))
print_error ("listen on %s failed: %s", address, strerror (errno));
else
{
print_status ("listening on %s", address);
free (address);
return fd;
}
free (address);
xclose (fd);
return -1;
}
static void
listener_add (struct server_context *ctx, const char *host, const char *port,
const struct addrinfo *gai_hints, client_create_fn create)
{
struct addrinfo *gai_result, *gai_iter;
int err = getaddrinfo (host, port, gai_hints, &gai_result);
if (err)
{
char *address = format_host_port_pair (host, port);
print_error ("bind to %s failed: %s: %s",
address, "getaddrinfo", gai_strerror (err));
free (address);
return;
}
int fd;
for (gai_iter = gai_result; gai_iter; gai_iter = gai_iter->ai_next)
{
if ((fd = listener_bind (gai_iter)) == -1)
continue;
set_blocking (fd, false);
struct listener *listener = &ctx->listeners[ctx->n_listeners++];
ev_io_init (&listener->watcher, on_client_available, fd, EV_READ);
ev_io_start (EV_DEFAULT_ &listener->watcher);
listener->watcher.data = listener;
listener->create = create;
listener->fd = fd;
break;
}
freeaddrinfo (gai_result);
}
static void
get_ports_from_config (struct server_context *ctx,
const char *key, struct strv *out)
{
const char *ports;
if ((ports = str_map_find (&ctx->config, key)))
cstr_split (ports, ",", true, out);
}
static bool
setup_listen_fds (struct server_context *ctx, struct error **e)
{
static const struct addrinfo gai_hints =
{
.ai_socktype = SOCK_STREAM,
.ai_flags = AI_PASSIVE,
};
struct strv ports_fcgi = strv_make ();
struct strv ports_scgi = strv_make ();
struct strv ports_ws = strv_make ();
get_ports_from_config (ctx, "port_fastcgi", &ports_fcgi);
get_ports_from_config (ctx, "port_scgi", &ports_scgi);
get_ports_from_config (ctx, "port_ws", &ports_ws);
const char *bind_host = str_map_find (&ctx->config, "bind_host");
size_t n_ports = ports_fcgi.len + ports_scgi.len + ports_ws.len;
ctx->listeners = xcalloc (n_ports, sizeof *ctx->listeners);
for (size_t i = 0; i < ports_fcgi.len; i++)
listener_add (ctx, bind_host, ports_fcgi.vector[i],
&gai_hints, client_fcgi_create);
for (size_t i = 0; i < ports_scgi.len; i++)
listener_add (ctx, bind_host, ports_scgi.vector[i],
&gai_hints, client_scgi_create);
for (size_t i = 0; i < ports_ws.len; i++)
listener_add (ctx, bind_host, ports_ws.vector[i],
&gai_hints, client_ws_create);
strv_free (&ports_fcgi);
strv_free (&ports_scgi);
strv_free (&ports_ws);
if (!ctx->n_listeners)
{
error_set (e, "%s: %s",
"network setup failed", "no ports to listen on");
return false;
}
return true;
}
static bool
app_lock_pid_file (struct server_context *ctx, struct error **e)
{
const char *path = str_map_find (&ctx->config, "pid_file");
if (!path)
return true;
char *resolved = resolve_filename (path, resolve_relative_runtime_filename);
bool result = lock_pid_file (resolved, e) != -1;
free (resolved);
return result;
}
// --- Tests -------------------------------------------------------------------
static void
test_misc (void)
{
soft_assert ( validate_json_rpc_content_type
("application/JSON; charset=\"utf-8\""));
soft_assert (!validate_json_rpc_content_type
("text/html; charset=\"utf-8\""));
char *canon = canonicalize_url_path ("///../../../etc/./passwd");
soft_assert (!strcmp (canon, "/etc/passwd"));
free (canon);
}
int
test_main (int argc, char *argv[])
{
struct test test;
test_init (&test, argc, argv);
test_add_simple (&test, "/misc", NULL, test_misc);
// TODO: write more tests
// TODO: test the server handler (happy path)
return test_run (&test);
}
// --- Main program ------------------------------------------------------------
static void
on_termination_signal (EV_P_ ev_signal *handle, int revents)
{
struct server_context *ctx = ev_userdata (loop);
(void) handle;
(void) revents;
// TODO: consider quitting right away if already quitting;
// considering that this may already happen in timeout, it should be OK;
// see on_quit_timeout, just destroy all clients
initiate_quit (ctx);
}
static void
setup_signal_handlers (struct server_context *ctx)
{
ev_signal_init (&ctx->sigterm_watcher, on_termination_signal, SIGTERM);
ev_signal_start (EV_DEFAULT_ &ctx->sigterm_watcher);
ev_signal_init (&ctx->sigint_watcher, on_termination_signal, SIGINT);
ev_signal_start (EV_DEFAULT_ &ctx->sigint_watcher);
(void) signal (SIGPIPE, SIG_IGN);
}
static void
daemonize (struct server_context *ctx)
{
print_status ("daemonizing...");
if (chdir ("/"))
exit_fatal ("%s: %s", "chdir", strerror (errno));
// Because of systemd, we need to exit the parent process _after_ writing
// a PID file, otherwise our grandchild would receive a SIGTERM
int sync_pipe[2];
if (pipe (sync_pipe))
exit_fatal ("%s: %s", "pipe", strerror (errno));
pid_t pid;
if ((pid = fork ()) < 0)
exit_fatal ("%s: %s", "fork", strerror (errno));
else if (pid)
{
// Wait until all write ends of the pipe are closed, which can mean
// either success or failure, we don't need to care
xclose (sync_pipe[PIPE_WRITE]);
char dummy;
if (read (sync_pipe[PIPE_READ], &dummy, 1) < 0)
exit_fatal ("%s: %s", "read", strerror (errno));
exit (EXIT_SUCCESS);
}
setsid ();
signal (SIGHUP, SIG_IGN);
if ((pid = fork ()) < 0)
exit_fatal ("%s: %s", "fork", strerror (errno));
else if (pid)
exit (EXIT_SUCCESS);
openlog (PROGRAM_NAME, LOG_NDELAY | LOG_NOWAIT | LOG_PID, 0);
g_log_message_real = log_message_syslog;
// Write the PID file (if so configured) and get rid of the pipe, so that
// the read() in our grandparent finally returns zero (no write ends)
struct error *e = NULL;
if (!app_lock_pid_file (ctx, &e))
exit_fatal ("%s", e->message);
xclose (sync_pipe[PIPE_READ]);
xclose (sync_pipe[PIPE_WRITE]);
// XXX: we may close our own descriptors this way, crippling ourselves;
// there is no real guarantee that we will start with all three
// descriptors open. In theory we could try to enumerate the descriptors
// at the start of main().
for (int i = 0; i < 3; i++)
xclose (i);
int tty = open ("/dev/null", O_RDWR);
if (tty != 0 || dup (0) != 1 || dup (0) != 2)
exit_fatal ("failed to reopen FD's: %s", strerror (errno));
}
static void
parse_program_arguments (int argc, char **argv)
{
static const struct opt opts[] =
{
{ 't', "test", NULL, 0, "self-test" },
{ 'd', "debug", NULL, 0, "run in debug mode" },
{ 'h', "help", NULL, 0, "display this help and exit" },
{ 'V', "version", NULL, 0, "output version information and exit" },
{ 'w', "write-default-cfg", "FILENAME",
OPT_OPTIONAL_ARG | OPT_LONG_ONLY,
"write a default configuration file and exit" },
{ 0, NULL, NULL, 0, NULL }
};
struct opt_handler oh =
opt_handler_make (argc, argv, opts, NULL, "JSON-RPC 2.0 demo server.");
int c;
while ((c = opt_handler_get (&oh)) != -1)
switch (c)
{
case 't':
test_main (argc, argv);
exit (EXIT_SUCCESS);
case 'd':
g_debug_mode = true;
break;
case 'h':
opt_handler_usage (&oh, stdout);
exit (EXIT_SUCCESS);
case 'V':
printf (PROGRAM_NAME " " PROGRAM_VERSION "\n");
exit (EXIT_SUCCESS);
case 'w':
call_simple_config_write_default (optarg, g_config_table);
exit (EXIT_SUCCESS);
default:
print_error ("wrong options");
opt_handler_usage (&oh, stderr);
exit (EXIT_FAILURE);
}
argc -= optind;
argv += optind;
if (argc)
{
opt_handler_usage (&oh, stderr);
exit (EXIT_FAILURE);
}
opt_handler_free (&oh);
}
int
main (int argc, char *argv[])
{
parse_program_arguments (argc, argv);
print_status (PROGRAM_NAME " " PROGRAM_VERSION " starting");
struct server_context ctx;
server_context_init (&ctx);
struct error *e = NULL;
if (!simple_config_update_from_file (&ctx.config, &e))
{
print_error ("error loading configuration: %s", e->message);
error_free (e);
exit (EXIT_FAILURE);
}
struct ev_loop *loop;
if (!(loop = EV_DEFAULT))
exit_fatal ("libev initialization failed");
ev_set_userdata (loop, &ctx);
setup_signal_handlers (&ctx);
LIST_PREPEND (ctx.handlers, &g_request_handler_static);
LIST_PREPEND (ctx.handlers, &g_request_handler_json_rpc);
if (!parse_config (&ctx, &e)
|| !setup_listen_fds (&ctx, &e))
{
print_error ("%s", e->message);
error_free (e);
exit (EXIT_FAILURE);
}
if (!g_debug_mode)
daemonize (&ctx);
else if (!app_lock_pid_file (&ctx, &e))
exit_fatal ("%s", e->message);
ev_run (loop, 0);
ev_loop_destroy (loop);
server_context_free (&ctx);
return EXIT_SUCCESS;
}