/* Serval DNA - HTTP Server Copyright (C) 2013 Serval Project Inc. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include #include #include #include "serval.h" #include "conf.h" #include "http_server.h" #include "log.h" #include "str.h" #include "strbuf.h" #include "strbuf_helpers.h" #include "net.h" #include "mem.h" #define BOUNDARY_STRING_MAXLEN 70 // legislated limit from RFC-1341 /* The (struct http_request).verb field points to one of these static strings, so that a simple * equality test can be used, eg, (r->verb == HTTP_VERB_GET) instead of a strcmp(). * * @author Andrew Bettison */ const char HTTP_VERB_GET[] = "GET"; const char HTTP_VERB_POST[] = "POST"; const char HTTP_VERB_PUT[] = "PUT"; const char HTTP_VERB_HEAD[] = "HEAD"; const char HTTP_VERB_DELETE[] = "DELETE"; const char HTTP_VERB_TRACE[] = "TRACE"; const char HTTP_VERB_OPTIONS[] = "OPTIONS"; const char HTTP_VERB_CONNECT[] = "CONNECT"; const char HTTP_VERB_PATCH[] = "PATCH"; static struct { const char *word; size_t wordlen; } http_verbs[] = { #define VERB_ENTRY(NAME) { HTTP_VERB_##NAME, sizeof HTTP_VERB_##NAME - 1 } VERB_ENTRY(GET), VERB_ENTRY(POST), VERB_ENTRY(PUT), VERB_ENTRY(HEAD), VERB_ENTRY(DELETE), VERB_ENTRY(TRACE), VERB_ENTRY(OPTIONS), VERB_ENTRY(CONNECT), VERB_ENTRY(PATCH) #undef VERB_ENTRY }; static struct profile_total http_server_stats = { .name = "http_server_poll", }; #define DEBUG_DUMP_PARSED(r) do { \ if (config.debug.httpd) \ DEBUGF("%s %s HTTP/%u.%u", r->verb ? r->verb : "NULL", alloca_str_toprint(r->path), r->version_major, r->version_minor);\ } while (0) #define DEBUG_DUMP_PARSER(r) do { \ if (config.debug.httpd) \ DEBUGF("parsed %d %s cursor %d %s end %d remain %"PRIhttp_size_t, \ (int)(r->parsed - r->received), alloca_toprint(-1, r->parsed, r->cursor - r->parsed), \ (int)(r->cursor - r->received), alloca_toprint(50, r->cursor, r->end - r->cursor), \ (int)(r->end - r->received), \ r->request_content_remaining \ ); \ } while (0) static void http_server_poll(struct sched_ent *); static void http_request_set_idle_timeout(struct http_request *r); static int http_request_parse_verb(struct http_request *r); static int http_request_parse_path(struct http_request *r); static int http_request_parse_http_version(struct http_request *r); static int http_request_start_parsing_headers(struct http_request *r); static int http_request_parse_header(struct http_request *r); static int http_request_start_body(struct http_request *r); static int http_request_parse_body_form_data(struct http_request *r); static void http_request_start_response(struct http_request *r); void http_request_init(struct http_request *r, int sockfd) { assert(sockfd != -1); r->request_header.content_length = CONTENT_LENGTH_UNKNOWN; r->request_content_remaining = CONTENT_LENGTH_UNKNOWN; r->response.header.content_length = CONTENT_LENGTH_UNKNOWN; r->response.header.resource_length = CONTENT_LENGTH_UNKNOWN; r->alarm.stats = &http_server_stats; r->alarm.function = http_server_poll; if (r->idle_timeout == 0) r->idle_timeout = 10000; // 10 seconds r->alarm.poll.fd = sockfd; r->alarm.poll.events = POLLIN; r->phase = RECEIVE; r->reserved = r->buffer; // Put aside a few bytes for reserving strings, so that the path can be reserved ok. r->received = r->end = r->parsed = r->cursor = r->buffer + 32; r->parser = http_request_parse_verb; watch(&r->alarm); http_request_set_idle_timeout(r); } static void http_request_set_idle_timeout(struct http_request *r) { assert(r->phase == RECEIVE || r->phase == TRANSMIT); r->alarm.alarm = gettime_ms() + r->idle_timeout; r->alarm.deadline = r->alarm.alarm + r->idle_timeout; unschedule(&r->alarm); schedule(&r->alarm); } void http_request_free_response_buffer(struct http_request *r) { if (r->response_free_buffer) { if (r->debug_flag && *r->debug_flag) DEBUGF("Free response buffer of %zu bytes", r->response_buffer_size); r->response_free_buffer(r->response_buffer); r->response_free_buffer = NULL; } r->response_buffer = NULL; r->response_buffer_size = 0; } int http_request_set_response_bufsize(struct http_request *r, size_t bufsiz) { // Don't allocate a new buffer if the existing one contains content. assert(r->response_buffer_sent == r->response_buffer_length); const char *const bufe = r->buffer + sizeof r->buffer; assert(r->reserved < bufe); size_t rbufsiz = bufe - r->reserved; if (bufsiz <= rbufsiz) { http_request_free_response_buffer(r); r->response_buffer = (char *) r->reserved; r->response_buffer_size = rbufsiz; if (r->debug_flag && *r->debug_flag) DEBUGF("Static response buffer %zu bytes", r->response_buffer_size); return 0; } if (bufsiz != r->response_buffer_size) { http_request_free_response_buffer(r); if ((r->response_buffer = emalloc(bufsiz)) == NULL) return -1; r->response_free_buffer = free; r->response_buffer_size = bufsiz; if (r->debug_flag && *r->debug_flag) DEBUGF("Allocated response buffer %zu bytes", r->response_buffer_size); } assert(r->response_buffer_size >= bufsiz); assert(r->response_buffer != NULL); return 0; } void http_request_finalise(struct http_request *r) { if (r->phase == DONE) return; assert(r->phase == RECEIVE || r->phase == TRANSMIT || r->phase == PAUSE); unschedule(&r->alarm); if (r->phase != PAUSE) unwatch(&r->alarm); close(r->alarm.poll.fd); r->alarm.poll.fd = -1; if (r->finalise) r->finalise(r); r->finalise = NULL; http_request_free_response_buffer(r); r->phase = DONE; } struct substring { const char *start; const char *end; }; #define alloca_substring_toprint(sub) alloca_toprint(-1, (sub).start, (sub).end - (sub).start) const struct substring substring_NULL = { NULL, NULL }; #if 0 static int _matches(struct substring str, const char *text) { return strlen(text) == str.end - str.start && memcmp(str.start, text, str.end - str.start) == 0; } #endif void write_pointer(unsigned char *mem, void *v) { uintptr_t n = (uintptr_t) v; unsigned i; for (i = 0; i != sizeof v; ++i) mem[i] = n >> (8 * i); } void *read_pointer(const unsigned char *mem) { uintptr_t n = 0; unsigned i; for (i = 0; i != sizeof(void*); ++i) n |= mem[i] << (8 * i); return (void *) n; } /* Allocate space from the start of the request buffer to hold the given substring plus a * terminating NUL. Enough bytes must have already been marked as parsed in order to make room, * otherwise the reservation fails and returns 0. If successful, copies the substring plus a * terminating NUL into the reserved space, places a pointer to the reserved area into '*resp', and * returns 1. * * Keeps a copy to the pointer 'resp', so that when the reserved area is released, all pointers into * it can be set to NULL automatically. This provides some safety: if the pointer is accidentally * dereferenced after the release it will cause a SEGV instead of using a string that has been * overwritten. It does not protect from using copies of '*resp', which of course will not be have * been set to NULL by the release. * * @author Andrew Bettison */ static int _reserve(struct http_request *r, const char **resp, struct substring str) { // Reserved string pointer must lie within this http_request struct. assert((char*)resp >= (char*)r); assert((char*)resp < (char*)(r + 1)); size_t len = str.end - str.start; // Substring must contain no NUL chars. assert(strnchr(str.start, len, '\0') == NULL); char *reslim = r->buffer + sizeof r->buffer - 1024; // always leave this much unreserved space assert(r->reserved <= reslim); size_t siz = sizeof(char**) + len + 1; if (r->reserved + siz > reslim) { r->response.result_code = 414; return 0; } if (r->reserved + siz > r->parsed) { WARNF("Error during HTTP parsing, unparsed content %s would be overwritten by reserving %s", alloca_toprint(30, r->parsed, r->end - r->parsed), alloca_substring_toprint(str) ); r->response.result_code = 500; return 0; } const char ***respp = (const char ***) r->reserved; char *restr = (char *)(respp + 1); write_pointer((unsigned char*)respp, resp); // can't use *respp = resp; could cause SIGBUS if not aligned if (restr != str.start) memmove(restr, str.start, len); restr[len] = '\0'; r->reserved += siz; if (r->reserved > r->received) r->received = r->reserved; assert(r->received <= r->parsed); *resp = restr; return 1; } /* The same as _reserve(), but takes a NUL-terminated string as a source argument instead of a * substring. * * @author Andrew Bettison */ static int _reserve_str(struct http_request *r, const char **resp, const char *str) { struct substring sub = { .start = str, .end = str + strlen(str) }; return _reserve(r, resp, sub); } /* Release all the strings reserved by _reserve(), returning the space to the request buffer, and * resetting to NULL all the pointers to reserved strings that were set by _reserve(). * * @author Andrew Bettison */ static void _release_reserved(struct http_request *r) { char *res = r->buffer; while (res < r->reserved) { assert(res + sizeof(char**) + 1 <= r->reserved); const char ***respp = (const char ***) res; char *restr = (char *)(respp + 1); const char **resp = read_pointer((const unsigned char*)respp); // can't use resp = *respp; could cause SIGBUS if not aligned assert((const char*)resp >= (const char*)r); assert((const char*)resp < (const char*)(r + 1)); assert(*resp == restr); *resp = NULL; for (res = restr; res < r->reserved && *res; ++res) ; assert(res < r->reserved); assert(*res == '\0'); ++res; } assert(res == r->reserved); r->reserved = r->buffer; } static inline int _end_of_content(struct http_request *r) { return r->cursor == r->end && r->request_content_remaining == 0; } static inline int _run_out(struct http_request *r) { assert(r->cursor <= r->end); return r->cursor == r->end; } static inline int _buffer_full(struct http_request *r) { const char *const bufend = r->buffer + sizeof r->buffer; return r->parsed == r->received && (r->end == bufend || r->request_content_remaining == 0); } static inline void _rewind(struct http_request *r) { assert(r->parsed >= r->received); r->cursor = r->parsed; } static inline void _commit(struct http_request *r) { assert(r->cursor <= r->end); r->parsed = r->cursor; } static inline void _skip_all(struct http_request *r) { r->cursor = r->end; } static inline int _skip_crlf(struct http_request *r) { return !_run_out(r) && *r->cursor == '\r' && ++r->cursor && !_run_out(r) && *r->cursor == '\n' && ++r->cursor; } static inline int _skip_to_crlf(struct http_request *r) { for (; !_run_out(r); ++r->cursor) if (r->cursor + 1 < r->end && r->cursor[0] == '\r' && r->cursor[1] == '\n') return 1; return 0; } static inline void _rewind_optional_cr(struct http_request *r) { if (r->cursor > r->parsed && r->cursor[-1] == '\r') --r->cursor; } static inline void _rewind_crlf(struct http_request *r) { assert(r->cursor >= r->parsed + 2); assert(r->cursor[-2] == '\r'); assert(r->cursor[-1] == '\n'); r->cursor -= 2; } /* More permissive than _skip_crlf(), this counts NUL characters preceding and between the CR and LF * as part of the end-of-line sequence and treats the CR as optional. This allows simple manual * testing using telnet(1). */ static inline int _skip_eol(struct http_request *r) { unsigned crcount = 0; for (; !_run_out(r); ++r->cursor) { switch (*r->cursor) { case '\0': // ignore any leading NULs (telnet inserts them) break; case '\r': // ignore up to one leading CR if (++crcount > 1) return 0; break; case '\n': ++r->cursor; return 1; default: return 0; } } return 0; } /* More permissive than _skip_crlf(), this counts NUL characters preceding and between the CR and LF * as part of the end-of-line sequence and treats the CR as optional. This allows simple manual * testing using telnet(1). */ static int _skip_to_eol(struct http_request *r) { const char *const start = r->cursor; while (!_run_out(r) && *r->cursor != '\n') ++r->cursor; if (_run_out(r)) return 0; // consume preceding NULs (telnet inserts them) while (r->cursor > start && r->cursor[-1] == '\0') --r->cursor; // consume a single preceding CR if (r->cursor > start && r->cursor[-1] == '\r') --r->cursor; // consume any more preceding NULs while (r->cursor > start && r->cursor[-1] == '\0') --r->cursor; return 1; } static int _skip_literal(struct http_request *r, const char *literal) { while (!_run_out(r) && *literal && *r->cursor == *literal) ++literal, ++r->cursor; return *literal == '\0'; } static int _skip_literal_nocase(struct http_request *r, const char *literal) { while (!_run_out(r) && *literal && toupper(*r->cursor) == toupper(*literal)) ++literal, ++r->cursor; return *literal == '\0'; } static int is_http_space(char c) { return c == ' ' || c == '\t'; } static int _skip_optional_space(struct http_request *r) { while (!_run_out(r) && is_http_space(*r->cursor)) ++r->cursor; return 1; } static inline int _skip_space(struct http_request *r) { const char *const start = r->cursor; _skip_optional_space(r); return r->cursor > start; } static size_t _skip_word_printable(struct http_request *r, struct substring *str) { if (_run_out(r) || isspace(*r->cursor) || !isprint(*r->cursor)) return 0; const char *start = r->cursor; for (++r->cursor; !_run_out(r) && !isspace(*r->cursor) && isprint(*r->cursor); ++r->cursor) ; if (_run_out(r)) return 0; assert(r->cursor > start); assert(isspace(*r->cursor)); if (str) { str->start = start; str->end = r->cursor; } return r->cursor - start; } static size_t _skip_token(struct http_request *r, struct substring *str) { if (_run_out(r) || !is_http_token(*r->cursor)) return 0; const char *start = r->cursor; for (++r->cursor; !_run_out(r) && is_http_token(*r->cursor); ++r->cursor) ; if (_run_out(r)) return 0; assert(r->cursor > start); assert(!is_http_token(*r->cursor)); if (str) { str->start = start; str->end = r->cursor; } return r->cursor - start; } static size_t _parse_token(struct http_request *r, char *dst, size_t dstsiz) { struct substring str; size_t len = _skip_token(r, &str); if (len && dst) { size_t cpy = len < dstsiz - 1 ? len : dstsiz - 1; strncpy(dst, str.start, cpy)[cpy] = '\0'; } return len; } static size_t _parse_quoted_string(struct http_request *r, char *dst, size_t dstsiz) { assert(r->cursor <= r->end); if (_run_out(r) || *r->cursor != '"') return 0; int slosh = 0; size_t len = 0; for (++r->cursor; !_run_out(r); ++r->cursor) { if (!isprint(*r->cursor)) return 0; if (slosh) { if (dst && len < dstsiz - 1) dst[len] = *r->cursor; ++len; slosh = 0; } else if (*r->cursor == '"') break; else if (*r->cursor == '\\') slosh = 1; else { if (dst && len < dstsiz - 1) dst[len] = *r->cursor; ++len; } } if (dst) dst[len < dstsiz - 1 ? len : dstsiz - 1] = '\0'; if (_run_out(r)) return 0; assert(*r->cursor == '"'); ++r->cursor; return len; } static size_t _parse_token_or_quoted_string(struct http_request *r, char *dst, size_t dstsiz) { assert(dstsiz > 0); if (!_run_out(r) && *r->cursor == '"') return _parse_quoted_string(r, dst, dstsiz); return _parse_token(r, dst, dstsiz); } static inline int _parse_http_size_t(struct http_request *r, http_size_t *szp) { return !_run_out(r) && isdigit(*r->cursor) && str_to_uint64(r->cursor, 10, szp, (const char **)&r->cursor); } static inline int _parse_uint32(struct http_request *r, uint32_t *uint32p) { return !_run_out(r) && isdigit(*r->cursor) && str_to_uint32(r->cursor, 10, uint32p, (const char **)&r->cursor); } static unsigned _parse_ranges(struct http_request *r, struct http_range *range, unsigned nrange) { unsigned i = 0; while (1) { enum http_range_type type; http_size_t first = 0, last = 0; if (_skip_literal(r, "-")) { if (!_parse_http_size_t(r, &last)) return 0; type = SUFFIX; } else if (_parse_http_size_t(r, &first) && _skip_literal(r, "-")) { if (_parse_http_size_t(r, &last)) { if (last < first) return 0; type = CLOSED; } else type = OPEN; } else return 0; if (i < nrange) { range[i].type = type; range[i].first = first; range[i].last = last; } ++i; if (!_skip_literal(r, ",")) break; _skip_optional_space(r); } return i; } static int _parse_content_type(struct http_request *r, struct mime_content_type *ct) { size_t n = _parse_token(r, ct->type, sizeof ct->type); if (n == 0) return 0; if (n >= sizeof ct->type) { WARNF("HTTP Content-Type type truncated: %s", alloca_str_toprint(ct->type)); return 0; } if (!_skip_literal(r, "/")) return 0; n = _parse_token(r, ct->subtype, sizeof ct->subtype); if (n == 0) return 0; if (n >= sizeof ct->subtype) { WARNF("HTTP Content-Type subtype truncated: %s", alloca_str_toprint(ct->subtype)); return 0; } while (_skip_optional_space(r) && _skip_literal(r, ";") && _skip_optional_space(r)) { char *start = r->cursor; if (_skip_literal(r, "charset=")) { size_t n = _parse_token_or_quoted_string(r, ct->charset, sizeof ct->charset); if (n == 0) return 0; if (n >= sizeof ct->charset) { WARNF("HTTP Content-Type charset truncated: %s", alloca_str_toprint(ct->charset)); return 0; } continue; } r->cursor = start; if (_skip_literal(r, "boundary=")) { size_t n = _parse_token_or_quoted_string(r, ct->multipart_boundary, sizeof ct->multipart_boundary); if (n == 0) return 0; if (n >= sizeof ct->multipart_boundary) { WARNF("HTTP Content-Type boundary truncated: %s", alloca_str_toprint(ct->multipart_boundary)); return 0; } continue; } r->cursor = start; struct substring param; if (_skip_token(r, ¶m) && _skip_literal(r, "=") && _parse_token_or_quoted_string(r, NULL, 0)) { if (r->debug_flag && *r->debug_flag) DEBUGF("Skipping HTTP Content-Type parameter: %s", alloca_substring_toprint(param)); continue; } WARNF("Malformed HTTP Content-Type: %s", alloca_toprint(50, r->cursor, r->end - r->cursor)); return 0; } return 1; } static size_t _parse_base64(struct http_request *r, char *bin, size_t binsize) { return base64_decode((unsigned char *)bin, binsize, r->cursor, r->end - r->cursor, (const char **)&r->cursor, B64_CONSUME_ALL, is_http_space); } static int _parse_authorization_credentials_basic(struct http_request *r, struct http_client_credentials_basic *cred, char *buf, size_t bufsz) { size_t n = _parse_base64(r, buf, bufsz - 1); // leave room for NUL terminator on password assert(n < bufsz); // buffer must be big enough char *pw = (char *) strnchr(buf, n, ':'); if (pw == NULL) return 0; // malformed cred->user = buf; *pw++ = '\0'; // NUL terminate user cred->password = pw; buf[n] = '\0'; // NUL terminate password return 1; } static int _parse_authorization(struct http_request *r, struct http_client_authorization *auth, size_t header_bytes) { char *start = r->cursor; if (_skip_literal(r, "Basic") && _skip_space(r)) { size_t bufsz = 5 + header_bytes * 3 / 4; // enough for base64 decoding char buf[bufsz]; if (_parse_authorization_credentials_basic(r, &auth->credentials.basic, buf, bufsz)) { auth->scheme = BASIC; if ( !_reserve_str(r, &auth->credentials.basic.user, auth->credentials.basic.user) || !_reserve_str(r, &auth->credentials.basic.password, auth->credentials.basic.password) ) return 0; // error return 1; } if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP header: Authorization: %s", alloca_toprint(50, start, header_bytes)); return 0; } if (_skip_literal(r, "Digest") && _skip_space(r)) { if (r->debug_flag && *r->debug_flag) DEBUG("Ignoring unsupported HTTP Authorization scheme: Digest"); r->cursor += header_bytes; return 1; } struct substring scheme; if (_skip_token(r, &scheme) && _skip_space(r)) { if (r->debug_flag && *r->debug_flag) DEBUGF("Unrecognised HTTP Authorization scheme: %s", alloca_toprint(-1, scheme.start, scheme.end - scheme.start)); return 0; } if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP Authorization header: %s", alloca_toprint(50, r->parsed, r->end - r->parsed)); return 0; } static int _parse_quoted_rfc822_time(struct http_request *r, time_t *timep) { char datestr[40]; size_t n = _parse_quoted_string(r, datestr, sizeof datestr); if (n == 0 || n >= sizeof datestr) return 0; // TODO: Move the following code into its own function in str.c struct tm tm; bzero(&tm, sizeof tm); // TODO: Ensure this works in non-English locales, ie, "%a" still accepts "Mon", "Tue" etc. and // "%b" still accepts "Jan", "Feb" etc. // TODO: Support symbolic time zones, eg, "UT", "GMT", "UTC", "EST"... const char *c = strptime(datestr, "%a, %d %b %Y %T ", &tm); if ((c[0] == '-' || c[0] == '+') && isdigit(c[1]) && isdigit(c[2]) && isdigit(c[3]) && isdigit(c[4]) && c[5] == '\0') { time_t zone = (c[0] == '-' ? -1 : 1) * ((c[1] - '0') * 600 + (c[2] - '0') * 60 + (c[3] - '0') * 10 + (c[4] - '0')); const char *tz = getenv("TZ"); if (tz) tz = alloca_strdup(tz); setenv("TZ", "", 1); tzset(); *timep = mktime(&tm) - zone; if (tz) setenv("TZ", tz, 1); else unsetenv("TZ"); tzset(); return 1; } return 0; } /* If parsing completes, then sets r->parser to the next parsing function and returns 0. If parsing * cannot complete due to running out of data, returns 100 without changing r->parser, so this * function will be called again once more data has been read. Returns a 4nn or 5nn HTTP result * code if parsing fails. Returns -1 if an unexpected error occurs. * * @author Andrew Bettison */ static int http_request_parse_verb(struct http_request *r) { DEBUG_DUMP_PARSER(r); _rewind(r); assert(r->cursor >= r->received); assert(!_run_out(r)); // Parse verb: GET, PUT, POST, etc. assert(r->verb == NULL); unsigned i; for (i = 0; i < NELS(http_verbs); ++i) { _rewind(r); if (_skip_literal(r, http_verbs[i].word) && _skip_literal(r, " ")) { r->verb = http_verbs[i].word; break; } if (_run_out(r)) return 100; // read more and try again } if (r->verb == NULL) { if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP request, invalid verb: %s", alloca_toprint(20, r->cursor, r->end - r->cursor)); return 400; } _commit(r); r->parser = http_request_parse_path; return 0; } /* If parsing completes, then sets r->parser to the next parsing function and returns 0. If parsing * cannot complete due to running out of data, returns 100 without changing r->parser, so this * function will be called again once more data has been read. Returns a 4nn or 5nn HTTP result * code if parsing fails. Returns -1 if an unexpected error occurs. * * @author Andrew Bettison */ static int http_request_parse_path(struct http_request *r) { DEBUG_DUMP_PARSER(r); // Parse path: word immediately following verb, delimited by spaces. assert(r->path == NULL); struct substring path; if (!(_skip_word_printable(r, &path) && _skip_literal(r, " "))) { if (_run_out(r)) return 100; // read more and try again if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP %s request at path: %s", r->verb, alloca_toprint(20, r->parsed, r->end - r->parsed)); return 400; } _commit(r); if (!_reserve(r, &r->path, path)) return 0; // error r->parser = http_request_parse_http_version; return 0; } /* If parsing completes, then sets r->parser to the next parsing function and returns 0. If parsing * cannot complete due to running out of data, returns 100 without changing r->parser, so this * function will be called again once more data has been read. Returns a 4nn or 5nn HTTP result * code if parsing fails. Returns -1 if an unexpected error occurs. * * @author Andrew Bettison */ static int http_request_parse_http_version(struct http_request *r) { DEBUG_DUMP_PARSER(r); // Parse HTTP version: HTTP/m.n followed by CRLF. assert(r->version_major == 0); assert(r->version_minor == 0); uint32_t major, minor; if (!( _skip_literal(r, "HTTP/") && _parse_uint32(r, &major) && major > 0 && major < UINT8_MAX && _skip_literal(r, ".") && _parse_uint32(r, &minor) && minor < UINT8_MAX && _skip_eol(r) ) ) { if (_run_out(r)) return 100; // read more and try again if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP %s request at version: %s", r->verb, alloca_toprint(20, r->parsed, r->end - r->parsed)); return 400; } _commit(r); r->version_major = major; r->version_minor = minor; r->parser = http_request_start_parsing_headers; if (r->handle_first_line) return r->handle_first_line(r); return 0; // parsing complete } /* Select the header parser. Returns 0 after setting the new parser function. Returns a 4nn or 5nn * HTTP result code if the request cannot be handled (eg, unsupported HTTP version or invalid path). * * @author Andrew Bettison */ static int http_request_start_parsing_headers(struct http_request *r) { DEBUG_DUMP_PARSER(r); assert(r->verb != NULL); assert(r->path != NULL); assert(r->version_major != 0); if (r->version_major != 1) { if (r->debug_flag && *r->debug_flag) DEBUGF("Unsupported HTTP version: %u.%u", r->version_major, r->version_minor); return 400; } r->parser = http_request_parse_header; return 0; } /* Parse one request header line. * * If the end of headers is parsed (blank line), then sets r->parser to the next parsing function * and returns 0. If a single header line is successfully parsed, returns 0 after advancing * r->parsed. If parsing cannot complete due to running out of data, returns 0 without changing * r->parser, so this function will be called again once more data has been read. Returns a 4nn or * 5nn HTTP result code if parsing fails. Returns -1 if an unexpected error occurs. * * @author Andrew Bettison */ static int http_request_parse_header(struct http_request *r) { DEBUG_DUMP_PARSER(r); _skip_to_eol(r); const char *const eol = r->cursor; _skip_eol(r); if (eol == r->parsed) { // if EOL is at start of line (ie, blank line)... _commit(r); if (r->request_header.content_length != CONTENT_LENGTH_UNKNOWN) { size_t unparsed = r->end - r->parsed; if (unparsed > r->request_header.content_length) { WARNF("HTTP parsing: already read %zu bytes past end of content", (size_t)(unparsed - r->request_header.content_length)); r->request_content_remaining = 0; } else r->request_content_remaining = r->request_header.content_length - unparsed; } r->parser = http_request_start_body; if (r->handle_headers) return r->handle_headers(r); return 0; } char *const nextline = r->cursor; _rewind(r); const char *const sol = r->cursor; if (_skip_literal_nocase(r, "Content-Length:")) { if (r->request_header.content_length != CONTENT_LENGTH_UNKNOWN) { if (r->debug_flag && *r->debug_flag) DEBUGF("Skipping duplicate HTTP header Content-Length: %s", alloca_toprint(50, sol, r->end - sol)); r->cursor = nextline; _commit(r); return 0; } _skip_optional_space(r); http_size_t length; if (_parse_http_size_t(r, &length) && _skip_optional_space(r) && r->cursor == eol) { r->cursor = nextline; _commit(r); r->request_header.content_length = length; if (r->debug_flag && *r->debug_flag) DEBUGF("Parsed HTTP request Content-Length: %"PRIhttp_size_t, r->request_header.content_length); return 0; } goto malformed; } _rewind(r); if (_skip_literal_nocase(r, "Content-Type:")) { if (r->request_header.content_type.type[0]) { if (r->debug_flag && *r->debug_flag) DEBUGF("Skipping duplicate HTTP header Content-Type: %s", alloca_toprint(50, sol, r->end - sol)); r->cursor = nextline; _commit(r); return 0; } _skip_optional_space(r); if ( _parse_content_type(r, &r->request_header.content_type) && _skip_optional_space(r) && r->cursor == eol ) { r->cursor = nextline; _commit(r); if (r->debug_flag && *r->debug_flag) DEBUGF("Parsed HTTP request Content-type: %s", alloca_mime_content_type(&r->request_header.content_type)); return 0; } goto malformed; } _rewind(r); if (_skip_literal_nocase(r, "Range:")) { if (r->request_header.content_range_count) { if (r->debug_flag && *r->debug_flag) DEBUGF("Skipping duplicate HTTP header Range: %s", alloca_toprint(50, sol, r->end - sol)); r->cursor = nextline; _commit(r); return 0; } _skip_optional_space(r); unsigned int n; if ( _skip_literal(r, "bytes=") && (n = _parse_ranges(r, r->request_header.content_ranges, NELS(r->request_header.content_ranges))) && _skip_optional_space(r) && r->cursor == eol ) { r->cursor = nextline; _commit(r); if (n > NELS(r->request_header.content_ranges)) { if (r->debug_flag && *r->debug_flag) DEBUGF("HTTP request Range header overflow (%u ranges in set, can only handle %zu): %s", n, NELS(r->request_header.content_ranges), alloca_toprint(-1, sol, eol - sol)); // In this case ignore the Range: header -- respond with the entire resource. r->request_header.content_range_count = 0; } else { r->request_header.content_range_count = n; if (r->debug_flag && *r->debug_flag) DEBUGF("Parsed HTTP request Range: bytes=%s", alloca_http_ranges(r->request_header.content_ranges)); } return 0; } goto malformed; } _rewind(r); if (_skip_literal_nocase(r, "Authorization:")) { if (r->request_header.authorization.scheme != NOAUTH) { if (r->debug_flag && *r->debug_flag) DEBUGF("Skipping duplicate HTTP header Authorization: %s", alloca_toprint(50, sol, r->end - sol)); r->cursor = nextline; _commit(r); return 0; } _skip_optional_space(r); if ( _parse_authorization(r, &r->request_header.authorization, eol - r->cursor) && _skip_optional_space(r) && r->cursor == eol ) { assert(r->request_header.authorization.scheme != NOAUTH); r->cursor = nextline; _commit(r); return 0; } goto malformed; } _rewind(r); if (r->debug_flag && *r->debug_flag) DEBUGF("Skipped HTTP request header: %s", alloca_toprint(-1, sol, eol - sol)); r->cursor = nextline; _commit(r); return 0; malformed: if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP request header: %s", alloca_toprint(-1, sol, eol - sol)); return 400; } /* If parsing completes, then sets r->parser to the next parsing function and returns 0. If parsing * cannot complete due to running out of data, returns 0 without changing r->parser, so this * function will be called again once more data has been read. Returns a 4nn or 5nn HTTP result * code if parsing fails. Returns -1 if an unexpected error occurs. * * @author Andrew Bettison */ static int http_request_start_body(struct http_request *r) { DEBUG_DUMP_PARSER(r); assert(r->verb != NULL); assert(r->path != NULL); assert(r->version_major != 0); assert(r->parsed <= r->end); if (r->verb == HTTP_VERB_GET) { // TODO: Implement HEAD requests (only send response header, not body) if (r->request_header.content_length != 0 && r->request_header.content_length != CONTENT_LENGTH_UNKNOWN) { if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP %s request: non-zero Content-Length not allowed", r->verb); return 400; } if (r->request_header.content_type.type[0]) { if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP %s request: Content-Type not allowed", r->verb); return 400; } r->parser = NULL; } else if (r->verb == HTTP_VERB_POST) { if (r->request_header.content_length == CONTENT_LENGTH_UNKNOWN) { if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP %s request: missing Content-Length header", r->verb); return 411; } if (r->request_header.content_type.type[0] == '\0') { if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP %s request: missing Content-Type header", r->verb); return 400; } if ( strcmp(r->request_header.content_type.type, "multipart") == 0 && strcmp(r->request_header.content_type.subtype, "form-data") == 0 ) { if ( r->request_header.content_type.multipart_boundary == NULL || r->request_header.content_type.multipart_boundary[0] == '\0' ) { if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP %s request: Content-Type %s/%s missing boundary parameter", r->verb, r->request_header.content_type.type, r->request_header.content_type.subtype); return 400; } r->parser = http_request_parse_body_form_data; r->form_data_state = START; } else { if (r->debug_flag && *r->debug_flag) DEBUGF("Unsupported HTTP %s request: Content-Type %s not supported", r->verb, alloca_mime_content_type(&r->request_header.content_type)); return 415; } } else { if (r->debug_flag && *r->debug_flag) DEBUGF("Unsupported HTTP %s request", r->verb); r->parser = NULL; return 501; } if (_run_out(r)) return 100; return 0; } /* Returns 1 if a MIME delimiter is skipped, 2 if a MIME close-delimiter is skipped. */ static int _skip_mime_boundary(struct http_request *r) { if (!_skip_literal(r, "--") || !_skip_literal(r, r->request_header.content_type.multipart_boundary)) return 0; if (_skip_literal(r, "--") && _skip_crlf(r)) return 2; if (_skip_crlf(r)) return 1; return 0; } static int _parse_content_disposition(struct http_request *r, struct mime_content_disposition *cd) { size_t n = _parse_token(r, cd->type, sizeof cd->type); if (n == 0) return 0; if (n >= sizeof cd->type) { WARNF("HTTP Content-Disposition type truncated: %s", alloca_str_toprint(cd->type)); return 0; } while (_skip_optional_space(r) && _skip_literal(r, ";") && _skip_optional_space(r)) { char *start = r->cursor; if (_skip_literal(r, "filename=")) { size_t n = _parse_token_or_quoted_string(r, cd->filename, sizeof cd->filename); if (n == 0) return 0; if (n >= sizeof cd->filename) { WARNF("HTTP Content-Disposition filename truncated: %s", alloca_str_toprint(cd->filename)); return 0; } continue; } r->cursor = start; if (_skip_literal(r, "name=")) { size_t n = _parse_token_or_quoted_string(r, cd->name, sizeof cd->name); if (n == 0) return 0; if (n >= sizeof cd->name) { WARNF("HTTP Content-Disposition name truncated: %s", alloca_str_toprint(cd->name)); return 0; } continue; } r->cursor = start; if (_skip_literal(r, "size=")) { if (!_parse_http_size_t(r, &cd->size)) goto malformed; continue; } r->cursor = start; if (_skip_literal(r, "creation-date=")) { if (!_parse_quoted_rfc822_time(r, &cd->creation_date)) goto malformed; continue; } r->cursor = start; if (_skip_literal(r, "modification-date=")) { if (!_parse_quoted_rfc822_time(r, &cd->modification_date)) goto malformed; continue; } r->cursor = start; if (_skip_literal(r, "read-date=")) { if (!_parse_quoted_rfc822_time(r, &cd->read_date)) goto malformed; continue; } r->cursor = start; struct substring param; if (_skip_token(r, ¶m) && _skip_literal(r, "=") && _parse_token_or_quoted_string(r, NULL, 0)) { if (r->debug_flag && *r->debug_flag) DEBUGF("Skipping HTTP Content-Disposition parameter: %s", alloca_substring_toprint(param)); continue; } malformed: WARNF("Malformed HTTP Content-Disposition: %s", alloca_toprint(50, r->cursor, r->end - r->cursor)); return 0; } return 1; } #define _HANDLER_RESULT(result) do { \ if (r->phase != RECEIVE) \ return 1; \ if (result) { \ assert((result) >= 400); \ assert((result) < 600); \ return (result); \ } \ } while (0) #define _INVOKE_HANDLER_VOID(FUNC) do { \ if (r->form_data.FUNC) { \ if (r->debug_flag && *r->debug_flag) \ DEBUGF(#FUNC "()"); \ int result = r->form_data.FUNC(r); \ _HANDLER_RESULT(result); \ } \ } while (0) #define _INVOKE_HANDLER_BUF_LEN(FUNC, START, END) do { \ if (r->form_data.FUNC && (START) != (END)) { \ if (r->debug_flag && *r->debug_flag) \ DEBUGF(#FUNC "(%s length=%zu)", alloca_toprint(50, (START), (END) - (START)), (END) - (START)); \ int result = r->form_data.FUNC(r, (START), (END) - (START)); \ _HANDLER_RESULT(result); \ } \ } while (0) static int http_request_form_data_start_part(struct http_request *r, int b) { switch (r->form_data_state) { case BODY: if ( r->part_header.content_length != CONTENT_LENGTH_UNKNOWN && r->part_body_length != r->part_header.content_length ) { WARNF("HTTP multipart part body length (%"PRIhttp_size_t") does not match Content-Length header (%"PRIhttp_size_t")", r->part_body_length, r->part_header.content_length ); } // fall through... case HEADER: _INVOKE_HANDLER_VOID(handle_mime_part_end); break; default: break; } if (b == 1) { r->form_data_state = HEADER; bzero(&r->part_header, sizeof r->part_header); r->part_body_length = 0; r->part_header.content_length = CONTENT_LENGTH_UNKNOWN; _INVOKE_HANDLER_VOID(handle_mime_part_start); } else r->form_data_state = EPILOGUE; return 0; } /* If parsing completes (ie, parsed to end of epilogue), then sets r->parser to NULL and returns 0, * so this function will not be called again. If parsing cannot complete due to running out of * data, returns 100, so this function will not be called again until more data has been read. * Returns a 4nn or 5nn HTTP result code if parsing fails. Returns -1 if an unexpected error * occurs. * * NOTE: No support for nested/mixed parts, as that would considerably complicate the parser. If * the need arises in future, we will deal with it then. In the meantime, we will have something * that meets our immediate needs for Rhizome Direct and a variety of use cases. * * @author Andrew Bettison */ static int http_request_parse_body_form_data(struct http_request *r) { DEBUG_DUMP_PARSER(r); int at_start = 0; switch (r->form_data_state) { case START: if (config.debug.httpd) DEBUGF("START"); // The logic here allows for a missing initial CRLF before the first boundary line. at_start = 1; r->form_data_state = PREAMBLE; // fall through case PREAMBLE: { if (config.debug.httpd) DEBUGF("PREAMBLE"); char *start = r->parsed; for (; at_start || _skip_to_crlf(r); at_start = 0) { const char *end_preamble = r->cursor; int b; if ((b = _skip_mime_boundary(r))) { assert(end_preamble >= r->parsed); _INVOKE_HANDLER_BUF_LEN(handle_mime_preamble, r->parsed, end_preamble); _rewind_crlf(r); _commit(r); return http_request_form_data_start_part(r, b); } } if (_end_of_content(r)) { if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP %s form data: missing first boundary", r->verb); return 400; } _rewind_optional_cr(r); _commit(r); assert(r->parsed >= start); _INVOKE_HANDLER_BUF_LEN(handle_mime_preamble, start, r->parsed); } return 100; // need more data case HEADER: { if (config.debug.httpd) DEBUGF("HEADER"); // If not at a CRLF, then we are skipping through an over-long header that didn't // fit into the buffer. Just discard bytes up to the next CRLF. if (!_skip_crlf(r)) { _skip_to_crlf(r); // advance to next CRLF or end of buffer _rewind_optional_cr(r); // don't skip a CR at end of buffer (it might be part of a half-received CRLF) assert(r->cursor > r->parsed); if (r->debug_flag && *r->debug_flag) DEBUGF("skipping %zu header bytes", r->cursor - r->parsed); _commit(r); return 0; } char *const sol = r->cursor; // A blank line finishes the headers. The CRLF does not form part of the body. if (_skip_crlf(r)) { _commit(r); if (r->form_data.handle_mime_part_header) { if (r->debug_flag && *r->debug_flag) DEBUGF("handle_mime_part_header(Content-Length: %"PRIhttp_size_t", Content-Type: %s, Content-Disposition: %s)", r->part_header.content_length, alloca_mime_content_type(&r->part_header.content_type), alloca_mime_content_disposition(&r->part_header.content_disposition) ); int result = r->form_data.handle_mime_part_header(r, &r->part_header); _HANDLER_RESULT(result); \ } r->form_data_state = BODY; return 0; } if (_run_out(r)) return 100; // read more and try again r->cursor = sol; // A mime boundary technically should not occur in the middle of the headers, but if it // does, treat it as a zero-length body. int b; if ((b = _skip_mime_boundary(r))) { _rewind_crlf(r); _commit(r); // A boundary in the middle of headers finishes the current part and starts a new part. // An end boundary terminates the current part and starts the epilogue. return http_request_form_data_start_part(r, b); } if (_run_out(r)) return 100; // read more and try again r->cursor = sol; struct substring label; if (_skip_token(r, &label) && _skip_literal(r, ":") && _skip_optional_space(r)) { size_t labellen = label.end - label.start; char labelstr[labellen + 1]; strncpy(labelstr, label.start, labellen)[labellen] = '\0'; str_tolower_inplace(labelstr); const char *value = r->cursor; if (strcmp(labelstr, "content-length") == 0) { if (r->part_header.content_length != CONTENT_LENGTH_UNKNOWN) { if (r->debug_flag && *r->debug_flag) DEBUGF("Skipping duplicate HTTP multipart header Content-Length: %s", alloca_toprint(50, sol, r->end - sol)); return 400; } http_size_t length; if (_parse_http_size_t(r, &length) && _skip_optional_space(r) && _skip_crlf(r)) { _rewind_crlf(r); _commit(r); r->part_header.content_length = length; if (r->debug_flag && *r->debug_flag) DEBUGF("Parsed HTTP multipart header Content-Length: %"PRIhttp_size_t, r->part_header.content_length); return 0; } } else if (strcmp(labelstr, "content-type") == 0) { if (r->part_header.content_type.type[0]) { if (r->debug_flag && *r->debug_flag) DEBUGF("Skipping duplicate HTTP multipart header Content-Type: %s", alloca_toprint(50, sol, r->end - sol)); return 400; } if (_parse_content_type(r, &r->part_header.content_type) && _skip_optional_space(r) && _skip_crlf(r)) { _rewind_crlf(r); _commit(r); if (r->debug_flag && *r->debug_flag) DEBUGF("Parsed HTTP multipart header Content-Type: %s", alloca_mime_content_type(&r->part_header.content_type)); return 0; } } else if (strcmp(labelstr, "content-disposition") == 0) { if (r->part_header.content_disposition.type[0]) { if (r->debug_flag && *r->debug_flag) DEBUGF("Skipping duplicate HTTP multipart header Content-Disposition: %s", alloca_toprint(50, sol, r->end - sol)); return 400; } if (_parse_content_disposition(r, &r->part_header.content_disposition) && _skip_optional_space(r) && _skip_crlf(r)) { _rewind_crlf(r); _commit(r); if (r->debug_flag && *r->debug_flag) DEBUGF("Parsed HTTP multipart header Content-Disposition: %s", alloca_mime_content_disposition(&r->part_header.content_disposition)); return 0; } } else if (_skip_to_crlf(r)) { _commit(r); if (r->debug_flag && *r->debug_flag) DEBUGF("Skip HTTP multipart header: %s: %s", alloca_str_toprint(labelstr), alloca_toprint(-1, value, value - r->cursor)); return 0; } } r->cursor = sol; if (_buffer_full(r)) { // The line does not start with "Token:" and is too long to fit into the buffer. Start // skipping it. WARNF("Skipping unterminated HTTP MIME header %s", alloca_toprint(50, sol, r->end - sol)); r->cursor = r->end; _rewind_optional_cr(r); if (r->debug_flag && *r->debug_flag) DEBUGF("skipping %zu header bytes", r->cursor - r->parsed); _commit(r); return 0; } if (_run_out(r)) return 100; // read more and try again if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP %s form data part: invalid header %s", r->verb, alloca_toprint(50, sol, r->end - sol)); DEBUG_DUMP_PARSER(r); } return 400; case BODY: if (config.debug.httpd) DEBUGF("BODY"); char *start = r->parsed; while (_skip_to_crlf(r)) { int b; char *end_body = r->cursor; _skip_crlf(r); if ((b = _skip_mime_boundary(r))) { _rewind_crlf(r); _commit(r); assert(end_body >= start); r->part_body_length += end_body - start; // Note: the handler function may modify the data in-place (eg, Rhizome does encryption // that way). _INVOKE_HANDLER_BUF_LEN(handle_mime_body, start, end_body); // excluding CRLF at end return http_request_form_data_start_part(r, b); } } if (_end_of_content(r)) { if (r->debug_flag && *r->debug_flag) DEBUGF("Malformed HTTP %s form data part: missing end boundary", r->verb); return 400; } _rewind_optional_cr(r); _commit(r); assert(r->parsed >= start); r->part_body_length += r->parsed - start; // Note: the handler function may modify the data in-place _INVOKE_HANDLER_BUF_LEN(handle_mime_body, start, r->parsed); return 100; // need more data case EPILOGUE: if (config.debug.httpd) DEBUGF("EPILOGUE"); r->cursor = r->end; assert(r->cursor >= r->parsed); _INVOKE_HANDLER_BUF_LEN(handle_mime_epilogue, r->parsed, r->cursor); _commit(r); assert(_run_out(r)); if (_end_of_content(r)) return 0; // done return 100; // need more data default: FATALF("form_data_state = %d", r->form_data_state); } abort(); // not reached } static ssize_t http_request_read(struct http_request *r, char *buf, size_t len) { sigPipeFlag = 0; ssize_t bytes = read_nonblock(r->alarm.poll.fd, buf, len); if (bytes == -1) { if (r->debug_flag && *r->debug_flag) DEBUG("HTTP socket read error, closing connection"); http_request_finalise(r); return -1; } if (sigPipeFlag) { if (r->debug_flag && *r->debug_flag) DEBUG("Received SIGPIPE on HTTP socket read, closing connection"); http_request_finalise(r); return -1; } return bytes; } static void http_request_receive(struct http_request *r) { assert(r->phase == RECEIVE); const char *const bufend = r->buffer + sizeof r->buffer; assert(r->end <= bufend); assert(r->parsed >= r->received); assert(r->parsed <= r->end); // If the end of content falls within the buffer, then there is no need to make any more room, // just read up to the end of content. Otherwise, If buffer is running short on unused space, // shift existing content in buffer down to make more room if possible. size_t room = bufend - r->end; if (r->request_content_remaining != CONTENT_LENGTH_UNKNOWN && room > r->request_content_remaining) room = r->request_content_remaining; else { size_t spare = r->parsed - r->received; if (spare && (room < 128 || (room < 1024 && spare >= 32))) { size_t unparsed = r->end - r->parsed; memmove((char *)r->received, r->parsed, unparsed); // memcpy() does not handle overlapping src and dst r->parsed = r->received; r->end = r->received + unparsed; room = bufend - r->end; if (r->request_content_remaining != CONTENT_LENGTH_UNKNOWN && room > r->request_content_remaining) room = r->request_content_remaining; } } // If there is no more buffer space, fail the request. if (room == 0) { if (r->debug_flag && *r->debug_flag) DEBUG("Buffer size reached, reporting overflow"); http_request_simple_response(r, 431, NULL); return; } // Read up to the end of available buffer space or the end of content, whichever is first. Read // as many bytes as possible into the unused buffer space. Any read error closes the connection // without any response. assert(room > 0); if (r->request_content_remaining != CONTENT_LENGTH_UNKNOWN) assert(room <= r->request_content_remaining); ssize_t bytes = http_request_read(r, (char *)r->end, room); if (bytes == -1) return; assert((size_t) bytes <= room); // If no data was read, then just return to polling. Don't drop the connection on an empty read, // because that drops connections when they shouldn't, including during testing. The inactivity // timeout will drop inactive connections. if (bytes == 0) return; r->end += (size_t) bytes; if (r->request_content_remaining != CONTENT_LENGTH_UNKNOWN) r->request_content_remaining -= (size_t) bytes; // We got some data, so reset the inactivity timer and invoke the parsing state machine to process // it. The state machine invokes the caller-supplied callback functions. http_request_set_idle_timeout(r); // Parse the unparsed and received data. while (r->phase == RECEIVE) { int result; _rewind(r); DEBUG_DUMP_PARSER(r); if (_end_of_content(r)) { if (r->handle_content_end) result = r->handle_content_end(r); else { if (r->debug_flag && *r->debug_flag) DEBUG("Internal failure parsing HTTP request: no end-of-content function set"); result = 500; } } else { HTTP_REQUEST_PARSER *oldparser = r->parser; const char *oldparsed = r->parsed; if (r->parser == NULL) { if (r->debug_flag && *r->debug_flag) DEBUGF("No HTTP parser function set -- skipping %zu bytes", (size_t)(r->end - r->cursor)); _skip_all(r); _commit(r); result = 0; } else { result = r->parser(r); assert(r->parsed >= oldparsed); } if (r->phase != RECEIVE) break; if (result == 100) return; // needs more data; poll again if (result == 0 && r->parsed == oldparsed && r->parser == oldparser) { if (r->debug_flag && *r->debug_flag) DEBUG("Internal failure parsing HTTP request: parser function did not advance"); DEBUG_DUMP_PARSER(r); result = 500; } } if (result >= 200 && result < 600) { assert(r->response.result_code == 0 || r->response.result_code == result); r->response.result_code = result; } else if (result) { if (r->debug_flag && *r->debug_flag) DEBUGF("Internal failure parsing HTTP request: invalid result=%d", result); r->response.result_code = 500; } if (r->response.result_code) break; if (result == -1) { if (r->debug_flag && *r->debug_flag) DEBUG("Unrecoverable error parsing HTTP request, closing connection"); http_request_finalise(r); return; } } if (r->phase != RECEIVE) { assert(r->response.result_code != 0); return; } if (r->response.result_code == 0) { WHY("No HTTP response set, using 500 Server Error"); r->response.result_code = 500; } http_request_start_response(r); } /* Write the current contents of the response buffer to the HTTP socket. When no more bytes can be * written, return so that socket polling can continue. Once all bytes are sent, if there is a * content generator function, invoke it to put more content in the response buffer, and write that * content. * * @author Andrew Bettison */ static void http_request_send_response(struct http_request *r) { assert(r->phase == TRANSMIT); while (1) { if (r->response_length != CONTENT_LENGTH_UNKNOWN) assert(r->response_sent <= r->response_length); assert(r->response_buffer_sent <= r->response_buffer_length); uint64_t remaining = CONTENT_LENGTH_UNKNOWN; size_t unsent = r->response_buffer_length - r->response_buffer_sent; if (r->debug_flag && *r->debug_flag) DEBUGF("HTTP response buffer contains %zu bytes unsent", unsent); if (r->response_length != CONTENT_LENGTH_UNKNOWN) { remaining = r->response_length - r->response_sent; assert(unsent <= remaining); assert(r->response_buffer_need <= remaining); if (remaining == 0) break; // no more to generate } if (unsent == 0) r->response_buffer_sent = r->response_buffer_length = 0; if (r->phase == PAUSE) { if (unsent == 0) return; // nothing to send } else if (r->response.content_generator) { // If the buffer is smaller than the content generator needs, and it contains no unsent // content, then allocate a larger buffer. if (r->response_buffer_need > r->response_buffer_size && unsent == 0) { if (http_request_set_response_bufsize(r, r->response_buffer_need) == -1) { WHYF("HTTP response truncated at offset=%"PRIhttp_size_t" due to insufficient buffer space", r->response_sent); http_request_finalise(r); return; } } // If there are some sent bytes at the start of the buffer and only a few unsent bytes, then // move the unsent content to the start of the buffer to make more room. if (r->response_buffer_sent > 0 && unsent < 128) { memmove(r->response_buffer, r->response_buffer + r->response_buffer_sent, unsent); r->response_buffer_length -= r->response_buffer_sent; r->response_buffer_sent = 0; } // If there is enough unfilled room at the end of the buffer, then fill the buffer with some // more content. assert(r->response_buffer_length <= r->response_buffer_size); size_t unfilled = r->response_buffer_size - r->response_buffer_length; if (unfilled > 0 && unfilled >= r->response_buffer_need) { // The content generator must fill or partly fill the part of the buffer we indicate and // return the number of bytes appended. If it returns zero, it means it has no more // content (EOF), and must not be called again. If the return value exceeds the buffer size // we supply, it gives the amount of free space the generator needs in order to append; the // generator will not append any bytes until that much free space is available. If returns // -1, it means an unrecoverable error occurred, and the generator must not be called again. struct http_content_generator_result result; bzero(&result, sizeof result); int ret = r->response.content_generator(r, (unsigned char *) r->response_buffer + r->response_buffer_length, unfilled, &result); if (ret == -1) { WHY("Content generation error, closing connection"); http_request_finalise(r); return; } assert(result.generated <= unfilled); r->response_buffer_length += result.generated; r->response_buffer_need = result.need; if (result.generated == 0 && result.need <= unfilled && r->phase != PAUSE) { WHYF("HTTP response generator produced no content at offset %"PRIhttp_size_t" (ret=%d)", r->response_sent, ret); http_request_finalise(r); return; } if (r->debug_flag && *r->debug_flag) DEBUGF("Generated HTTP %zu bytes of content, need %zu bytes of buffer (ret=%d)", result.generated, result.need, ret); if (r->phase != PAUSE && ret == 0) r->response.content_generator = NULL; // ensure we never invoke again continue; } } else if (remaining != CONTENT_LENGTH_UNKNOWN && unsent < remaining) { WHYF("HTTP response generator finished prematurely at offset %"PRIhttp_size_t"/%"PRIhttp_size_t" (%"PRIhttp_size_t" bytes remaining)", r->response_sent, r->response_length, remaining); http_request_finalise(r); return; } else if (unsent == 0) break; assert(unsent > 0); if (remaining != CONTENT_LENGTH_UNKNOWN && unsent > remaining) { WHYF("HTTP response overruns Content-Length (%"PRIhttp_size_t") by %"PRIhttp_size_t" bytes -- truncating", r->response_length, unsent - remaining); unsent = remaining; } sigPipeFlag = 0; ssize_t written = write_nonblock(r->alarm.poll.fd, r->response_buffer + r->response_buffer_sent, unsent); if (written == -1) { if (r->debug_flag && *r->debug_flag) DEBUG("HTTP socket write error, closing connection"); http_request_finalise(r); return; } if (sigPipeFlag) { if (r->debug_flag && *r->debug_flag) DEBUG("Received SIGPIPE on HTTP socket write, closing connection"); http_request_finalise(r); return; } // If we wrote nothing, go back to polling. if (written == 0) return; r->response_sent += (size_t) written; r->response_buffer_sent += (size_t) written; assert(r->response_sent <= r->response_length); assert(r->response_buffer_sent <= r->response_buffer_length); if (r->debug_flag && *r->debug_flag) DEBUGF("Wrote %zu bytes to HTTP socket, total %"PRIhttp_size_t", remaining=%"PRIhttp_size_t, (size_t) written, r->response_sent, r->response_length - r->response_sent); // Reset inactivity timer. if (r->phase != PAUSE) http_request_set_idle_timeout(r); // If we wrote less than we tried, then go back to polling, otherwise keep generating content. if ((size_t) written < (size_t) unsent) return; } if (r->debug_flag && *r->debug_flag) DEBUG("Done, closing connection"); http_request_finalise(r); } static void http_server_poll(struct sched_ent *alarm) { struct http_request *r = (struct http_request *) alarm; if (alarm->poll.revents == 0) { if (r->phase == PAUSE) { r->phase = TRANSMIT; r->alarm.poll.events = POLLOUT; watch(&r->alarm); http_request_set_idle_timeout(r); } else { if (r->debug_flag && *r->debug_flag) DEBUGF("Timeout, closing connection"); http_request_finalise(r); } } else if (alarm->poll.revents & (POLLHUP | POLLERR)) { if (r->debug_flag && *r->debug_flag) DEBUGF("Poll error (%s), closing connection", alloca_poll_events(alarm->poll.revents)); http_request_finalise(r); } else { if (r->phase == RECEIVE && (alarm->poll.revents & POLLIN)) http_request_receive(r); // this could change the phase to TRANSMIT if (r->phase == TRANSMIT && (alarm->poll.revents & POLLOUT)) http_request_send_response(r); } // Any of the above calls could change the phase to DONE. if (r->phase == DONE && r->free) r->free(r); // after this, *r is no longer valid } /* Copy the array of byte ranges, closing it (converting all ranges to CLOSED) using the supplied * resource length. If a range is not satisfiable it is omitted from 'dst'. Returns the number of * closed ranges written to 'dst'. * * @author Andrew Bettison */ unsigned http_range_close(struct http_range *dst, const struct http_range *src, unsigned nranges, http_size_t resource_length) { unsigned i; unsigned ndst = 0; for (i = 0; i != nranges; ++i) { http_size_t first = 0; http_size_t last = resource_length - 1; const struct http_range *range = &src[i]; switch (range->type) { case CLOSED: last = range->last < resource_length ? range->last : resource_length - 1; case OPEN: first = range->first < resource_length ? range->first : resource_length; break; case SUFFIX: first = range->last < resource_length ? resource_length - range->last : 0; break; default: abort(); // not reached } if (first <= last) dst[ndst++] = (struct http_range){ .type = CLOSED, .first=first, .last=last }; } return ndst; } /* Return the total number of bytes represented by the given ranges which must all be CLOSED and * valid. * * @author Andrew Bettison */ http_size_t http_range_bytes(const struct http_range *range, unsigned nranges) { http_size_t bytes = 0; unsigned i; for (i = 0; i != nranges; ++i) { assert(range[i].type == CLOSED); assert(range[i].last >= range[i].first); bytes += range[i].last - range[i].first + 1; } return bytes; } /* Return appropriate message for HTTP response codes, both known and unknown. */ static const char *httpResultString(int response_code) { switch (response_code) { case 200: return "OK"; case 201: return "Created"; case 206: return "Partial Content"; case 400: return "Bad Request"; case 401: return "Unauthorized"; case 403: return "Forbidden"; case 404: return "Not Found"; case 405: return "Method Not Allowed"; case 408: return "Request Timeout"; case 409: return "Conflict"; case 411: return "Length Required"; case 414: return "Request-URI Too Long"; case 415: return "Unsupported Media Type"; case 416: return "Requested Range Not Satisfiable"; case 431: return "Request Header Fields Too Large"; case 500: return "Internal Server Error"; case 501: return "Not Implemented"; default: return (response_code <= 4) ? "Unknown status code" : "A suffusion of yellow"; } } static strbuf strbuf_status_body(strbuf sb, struct http_response *hr, const char *message) { if (hr->header.content_type && strcmp(hr->header.content_type, "text/plain") == 0) { strbuf_sprintf(sb, "%03u %s\r\n", hr->result_code, message); } else if (hr->header.content_type && strcmp(hr->header.content_type, "application/json") == 0) { strbuf_sprintf(sb, "{\n \"http_status_code\": %u,\n \"http_status_message\": ", hr->result_code); strbuf_json_string(sb, message); strbuf_puts(sb, " \n}"); } else { hr->header.content_type = "text/html"; strbuf_sprintf(sb, "

%03u %s

", hr->result_code, message); } return sb; } /* Render the HTTP response into the current response buffer. Return 1 if it fits, 0 if it does * not. The buffer response_pointer may be NULL, in which case no response is rendered, but the * content_length is still computed * * @author Andrew Bettison */ static int _render_response(struct http_request *r) { struct http_response hr = r->response; assert(hr.result_code >= 100); assert(hr.result_code < 600); // Status code 401 must be accompanied by a WWW-Authenticate header. if (hr.result_code == 401) assert(hr.header.www_authenticate.scheme != NOAUTH); const char *result_string = httpResultString(hr.result_code); strbuf sb = strbuf_local(r->response_buffer, r->response_buffer_size); // Cannot specify both static (pre-rendered) content AND generated content. assert(!(hr.content && hr.content_generator)); if (hr.content || hr.content_generator) { // With static (pre-rendered) content, the content length is mandatory (so we know how much data // follows the 'hr.content' pointer. Generated content will generally not send a Content-Length // header, nor send partial content, but they might. if (hr.content) assert(hr.header.content_length != CONTENT_LENGTH_UNKNOWN); // Ensure that all partial content fields are consistent. If content length or resource length // are unknown, there can be no range field. if ( hr.header.content_length != CONTENT_LENGTH_UNKNOWN && hr.header.resource_length != CONTENT_LENGTH_UNKNOWN ) { assert(hr.header.content_length <= hr.header.resource_length); assert(hr.header.content_range_start + hr.header.content_length <= hr.header.resource_length); } else { assert(hr.header.content_range_start == 0); } // Convert a 200 status code into 206 if only partial content is being sent. This saves page // handlers having to decide between 200 (OK) and 206 (Partial Content), they can just set the // content and resource length fields and pass 200 to http_request_response_static(), and this // logic will change it to 206 if appropriate. if ( hr.header.content_length != CONTENT_LENGTH_UNKNOWN && hr.header.resource_length != CONTENT_LENGTH_UNKNOWN && hr.header.content_length > 0 && hr.header.content_length < hr.header.resource_length ) { if (hr.result_code == 200) hr.result_code = 206; // Partial Content } } else { // If no content is supplied at all, then render a standard, short body based solely on result // code, consistent with the response Content-Type if already set (HTML if not set). assert(hr.header.content_length == CONTENT_LENGTH_UNKNOWN); assert(hr.header.resource_length == CONTENT_LENGTH_UNKNOWN); assert(hr.header.content_range_start == 0); assert(hr.result_code != 206); strbuf cb; STRBUF_ALLOCA_FIT(cb, 40 + strlen(result_string), (strbuf_status_body(cb, &hr, result_string))); hr.content = strbuf_str(cb); hr.header.content_length = strbuf_len(cb); hr.header.resource_length = hr.header.content_length; hr.header.content_range_start = 0; } assert(hr.header.content_type != NULL); assert(hr.header.content_type[0]); strbuf_sprintf(sb, "HTTP/1.0 %03u %s\r\n", hr.result_code, result_string); strbuf_sprintf(sb, "Content-Type: %s", hr.header.content_type); if (hr.header.boundary) { strbuf_puts(sb, "; boundary="); if (strchr(hr.header.boundary, '"') || strchr(hr.header.boundary, '\\')) strbuf_append_quoted_string(sb, hr.header.boundary); else strbuf_puts(sb, hr.header.boundary); } strbuf_puts(sb, "\r\n"); if (hr.result_code == 206) { // Must only use result code 206 (Partial Content) if the content is in fact less than the whole // resource length. assert(hr.header.content_length != CONTENT_LENGTH_UNKNOWN); assert(hr.header.resource_length != CONTENT_LENGTH_UNKNOWN); assert(hr.header.content_length > 0); assert(hr.header.content_length < hr.header.resource_length); strbuf_sprintf(sb, "Content-Range: bytes %"PRIhttp_size_t"-%"PRIhttp_size_t"/%"PRIhttp_size_t"\r\n", hr.header.content_range_start, hr.header.content_range_start + hr.header.content_length - 1, hr.header.resource_length ); } if (hr.header.content_length != CONTENT_LENGTH_UNKNOWN) strbuf_sprintf(sb, "Content-Length: %"PRIhttp_size_t"\r\n", hr.header.content_length); const char *scheme = NULL; switch (hr.header.www_authenticate.scheme) { case NOAUTH: break; case BASIC: scheme = "Basic"; break; } if (scheme) { assert(hr.result_code == 401); strbuf_sprintf(sb, "WWW-Authenticate: %s realm=", scheme); strbuf_append_quoted_string(sb, hr.header.www_authenticate.realm); strbuf_puts(sb, "\r\n"); } if (r->render_extra_headers) r->render_extra_headers(r, sb); assert(strcmp(strbuf_substr(sb, -2), "\r\n") == 0); strbuf_puts(sb, "\r\n"); if (hr.header.content_length != CONTENT_LENGTH_UNKNOWN) r->response_length = strbuf_count(sb) + hr.header.content_length; else r->response_length = CONTENT_LENGTH_UNKNOWN; r->response_buffer_need = strbuf_count(sb) + 1; // the header and the strbuf terminating NUL if (hr.content) { assert(r->response_length != CONTENT_LENGTH_UNKNOWN); if (r->response_buffer_need < r->response_length) r->response_buffer_need = r->response_length; } else assert(hr.content_generator); if (r->response_buffer_size < r->response_buffer_need) return 0; // doesn't fit assert(!strbuf_overrun(sb)); if (hr.content) { bcopy(hr.content, strbuf_end(sb), hr.header.content_length); r->response_buffer_length = r->response_length; } else { r->response_buffer_length = strbuf_count(sb); } r->response_buffer_sent = 0; return 1; } /* Returns with the length of the rendered response in r->response_length. If the rendered response * did not fit into any available buffer, then returns with r->response_buffer == NULL, otherwise * r->response_buffer points to the rendered response. * * @author Andrew Bettison */ static void http_request_render_response(struct http_request *r) { // If there is no response buffer allocated yet, use the available part of the in-struct buffer. http_request_set_response_bufsize(r, 1); // Try rendering the response into the existing buffer. This will discover the length of the // rendered headers, so after this step, whether or not the buffer was overrun, we know the total // length of the response. if (!_render_response(r)) { // If the static response did not fit into the existing buffer, then allocate a large buffer // from the heap and try rendering again. if (http_request_set_response_bufsize(r, r->response_buffer_need) == -1) WHY("Cannot render HTTP response, out of memory"); else if (!_render_response(r)) FATAL("Re-render of HTTP response overflowed buffer"); } } static size_t http_request_drain(struct http_request *r) { assert(r->phase == RECEIVE); char buf[8192]; size_t drained = 0; ssize_t bytes; while ((bytes = http_request_read(r, buf, sizeof buf)) != -1 && bytes != 0) drained += (size_t) bytes; return drained; } static void http_request_start_response(struct http_request *r) { assert(r->phase == RECEIVE); _release_reserved(r); if (r->response.content || r->response.content_generator) { assert(r->response.header.content_type != NULL); assert(r->response.header.content_type[0]); } // If HTTP responses are disabled (eg, for testing purposes) then skip all response construction // and close the connection. if (r->disable_tx_flag && *r->disable_tx_flag) { INFO("HTTP transmit disabled, closing connection"); http_request_finalise(r); return; } // Drain the rest of the request that has not been received yet (eg, if sending an error response // provoked while parsing the early part of a partially-received request). If a read error // occurs, the connection is closed so the phase changes to DONE. http_request_drain(r); if (r->phase != RECEIVE) return; // Ensure conformance to HTTP standards. if (r->response.result_code == 401 && r->response.header.www_authenticate.scheme == NOAUTH) { WHY("HTTP 401 response missing WWW-Authenticate header, sending 500 Server Error instead"); r->response.result_code = 500; r->response.content = NULL; r->response.content_generator = NULL; } // If the response cannot be rendered, then render a 500 Server Error instead. If that fails, // then just close the connection. http_request_render_response(r); if (r->response_buffer == NULL) { WARN("Cannot render HTTP response, sending 500 Server Error instead"); r->response.result_code = 500; r->response.content = NULL; r->response.content_generator = NULL; http_request_render_response(r); if (r->response_buffer == NULL) { WHY("Cannot render HTTP 500 Server Error response, closing connection"); http_request_finalise(r); return; } } r->response_buffer_need = 0; r->response_sent = 0; if (r->debug_flag && *r->debug_flag) DEBUGF("Sending HTTP response: %s", alloca_toprint(160, (const char *)r->response_buffer, r->response_buffer_length)); r->phase = TRANSMIT; r->alarm.poll.events = POLLOUT; watch(&r->alarm); } void http_request_pause_response(struct http_request *r, time_ms_t until) { if (r->debug_flag && *r->debug_flag) DEBUGF("Pausing response for %.3f sec", (double)(until - gettime_ms()) / 1000.0); assert(r->phase == TRANSMIT); r->phase = PAUSE; r->alarm.alarm = until; r->alarm.deadline = until + r->idle_timeout; unwatch(&r->alarm); unschedule(&r->alarm); schedule(&r->alarm); } /* Start sending a static (pre-computed) response back to the client. The response's Content-Type * is set by the 'mime_type' parameter (in the standard format "type/subtype"). The response's * content is set from the 'body' and 'bytes' parameters, which need not point to persistent data, * ie, the memory pointed to by 'body' is no longer referenced once this function returns. * * @author Andrew Bettison */ void http_request_response_static(struct http_request *r, int result, const char *mime_type, const char *body, uint64_t bytes) { assert(r->phase == RECEIVE); assert(mime_type != NULL); assert(mime_type[0]); r->response.result_code = result; r->response.header.content_type = mime_type; r->response.header.content_range_start = 0; r->response.header.content_length = r->response.header.resource_length = bytes; r->response.content = body; r->response.content_generator = NULL; http_request_start_response(r); } void http_request_response_generated(struct http_request *r, int result, const char *mime_type, HTTP_CONTENT_GENERATOR generator) { assert(r->phase == RECEIVE); assert(mime_type != NULL); assert(mime_type[0]); r->response.result_code = result; r->response.header.content_type = mime_type; r->response.content = NULL; r->response.content_generator = generator; http_request_start_response(r); } /* Start sending a short response back to the client. The result code must be either a success * (2xx), redirection (3xx) or client error (4xx) or server error (5xx) code. The 'message' * argument may be a bare message which is enclosed in an HTML envelope to form the response * content, so it may contain HTML markup. If the 'message' argument is NULL, then the response * content is generated automatically from the result code. * * @author Andrew Bettison */ void http_request_simple_response(struct http_request *r, uint16_t result, const char *message) { assert(r->phase == RECEIVE); r->response.result_code = result; r->response.header.content_range_start = 0; strbuf h = NULL; if (message) STRBUF_ALLOCA_FIT(h, 40 + strlen(message), (strbuf_status_body(h, &r->response, message))); if (h) { r->response.header.resource_length = r->response.header.content_length = strbuf_len(h); r->response.content = strbuf_str(h); } r->response.content_generator = NULL; http_request_start_response(r); }