/** * coopgammad -- Cooperative gamma server * Copyright (C) 2016 Mattias Andrée (maandree@kth.se) * * This library 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 3 of the License, or * (at your option) any later version. * * This library 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 library. If not, see . */ #include "message.h" #include "util.h" #include #include #include #include #include /** * Initialise a message slot so that it can * be used by to read messages * * @param this Memory slot in which to store the new message * @return Non-zero on error, `errno` will be set accordingly */ int message_initialise(struct message* this) { this->headers = NULL; this->header_count = 0; this->payload = NULL; this->payload_size = 0; this->payload_ptr = 0; this->buffer_size = 128; this->buffer_ptr = 0; this->stage = 0; this->buffer = malloc(this->buffer_size); if (this->buffer == NULL) return -1; return 0; } /** * Release all resources in a message, should * be done even if initialisation fails * * @param this The message */ void message_destroy(struct message* this) { size_t i; if (this->headers != NULL) for (i = 0; i < this->header_count; i++) free(this->headers[i]); free(this->headers); free(this->payload); free(this->buffer); } /** * Marshal a message for state serialisation * * @param this The message * @param buf Output buffer for the marshalled data, * `NULL` just measure how large the buffers * needs to be * @return The number of marshalled byte */ size_t message_marshal(const struct message* this, void* buf) { size_t i, n, off = 0; char* bs = buf; if (bs != NULL) *(size_t*)(bs + off) = this->header_count; off += sizeof(size_t); if (bs != NULL) *(size_t*)(bs + off) = this->payload_size; off += sizeof(size_t); if (bs != NULL) *(size_t*)(bs + off) = this->payload_ptr; off += sizeof(size_t); if (bs != NULL) *(size_t*)(bs + off) = this->buffer_ptr; off += sizeof(size_t); if (bs != NULL) *(int*)(bs + off) = this->stage; off += sizeof(int); for (i = 0; i < this->header_count; i++) { n = strlen(this->headers[i]) + 1; if (bs != NULL) memcpy(bs + off, this->headers[i], n); off += n; } if (bs != NULL) memcpy(bs + off, this->payload, this->payload_ptr); off += this->payload_ptr; if (bs != NULL) memcpy(bs + off, this->buffer, this->buffer_ptr); off += this->buffer_ptr; return off; } /** * Unmarshal a message for state deserialisation * * @param this Memory slot in which to store the new message * @param buf In buffer with the marshalled data * @return The number of unmarshalled bytes, 0 on error */ size_t message_unmarshal(struct message* this, const void* buf) { size_t i, n, off = 0, header_count; const char* bs = buf; this->header_count = 0; header_count = *(const size_t*)(bs + off); off += sizeof(size_t); this->payload_size = *(const size_t*)(bs + off); off += sizeof(size_t); this->payload_ptr = *(const size_t*)(bs + off); off += sizeof(size_t); this->buffer_size = this->buffer_ptr = *(const size_t*)(bs + off); off += sizeof(size_t); this->stage = *(const int*)(bs + off); off += sizeof(int); /* Make sure that the pointers are NULL so that they are not freed without being allocated when the message is destroyed if this function fails. */ this->headers = NULL; this->payload = NULL; this->buffer = NULL; /* To 2-power-multiple of 128 bytes. */ this->buffer_size >>= 7; if (this->buffer_size == 0) this->buffer_size = 1; else { this->buffer_size -= 1; this->buffer_size |= this->buffer_size >> 1; this->buffer_size |= this->buffer_size >> 2; this->buffer_size |= this->buffer_size >> 4; this->buffer_size |= this->buffer_size >> 8; this->buffer_size |= this->buffer_size >> 16; #if SIZE_MAX == UINT64_MAX this->buffer_size |= this->buffer_size >> 32; #endif this->buffer_size += 1; } this->buffer_size <<= 7; /* Allocate header list, payload and read buffer. */ if (header_count > 0) if (!(this->headers = malloc(header_count * sizeof(char*)))) goto fail; if (this->payload_size > 0) if (!(this->payload = malloc(this->payload_size))) goto fail; if (!(this->buffer = malloc(this->buffer_size))) goto fail; /* Fill the header list, payload and read buffer. */ for (i = 0; i < header_count; i++) { n = strlen(bs + off) + 1; this->headers[i] = memdup(bs + off, n); if (this->headers[i] == NULL) goto fail; off += n; this->header_count++; } memcpy(this->payload, bs + off, this->payload_ptr); off += this->payload_ptr; memcpy(this->buffer, bs + off, this->buffer_ptr); off += this->buffer_ptr; return off; fail: return 0; } /** * Extend the header list's allocation * * @param this The message * @param extent The number of additional entries * @return Zero on success, -1 on error */ static int extend_headers(struct message* this, size_t extent) { char** new; if (!(new = realloc(this->headers, (this->header_count + extent) * sizeof(char*)))) return -1; this->headers = new; return 0; } /** * Extend the read buffer by way of doubling * * @param this The message * @return Zero on success, -1 on error */ static int extend_buffer(struct message* this) { char* new; if (!(new = realloc(this->buffer, (this->buffer_size << 1) * sizeof(char)))) return -1; this->buffer = new; this->buffer_size <<= 1; return 0; } /** * Reset the header list and the payload * * @param this The message */ static void reset_message(struct message* this) { size_t i; if (this->headers != NULL) for (i = 0; i < this->header_count; i++) free(this->headers[i]); free(this->headers); this->headers = NULL; this->header_count = 0; free(this->payload); this->payload = NULL; this->payload_size = 0; this->payload_ptr = 0; } /** * Read the headers the message and determine, and store, its payload's length * * @param this The message * @return Zero on success, negative on error (malformated message: unrecoverable state) */ #if defined(__GNUC__) __attribute__((pure)) #endif static int get_payload_length(struct message* this) { char* header; size_t i; for (i = 0; i < this->header_count; i++) if (strstr(this->headers[i], "Length: ") == this->headers[i]) { /* Store the message length. */ header = this->headers[i] + strlen("Length: "); this->payload_size = (size_t)atol(header); /* Do not except a length that is not correctly formated. */ for (; *header; header++) if ((*header < '0') || ('9' < *header)) return -2; /* Malformated value, enters unrecoverable state. */ /* Stop searching for the ‘Length’ header, we have found and parsed it. */ break; } return 0; } /** * Verify that a header is correctly formatted * * @param header The header, must be NUL-terminated * @param length The length of the header * @return Zero if valid, negative if invalid (malformated message: unrecoverable state) */ #if defined(__GNUC__) __attribute__((pure)) #endif static int validate_header(const char* header, size_t length) { char* p = memchr(header, ':', length * sizeof(char)); if (verify_utf8(header, 0) < 0) /* Either the string is not UTF-8, or your are under an UTF-8 attack, lets just call this unrecoverable because the client will not correct. */ return -2; if ((p == NULL) || /* Buck you, rawmemchr should not segfault the program. */ (p[1] != ' ')) /* Also an invalid format. ' ' is mandated after the ':'. */ return -2; return 0; } /** * Remove the beginning of the read buffer * * @param this The message * @param length The number of characters to remove * @param update_ptr Whether to update the buffer pointer */ static void unbuffer_beginning(struct message* this, size_t length, int update_ptr) { memmove(this->buffer, this->buffer + length, (this->buffer_ptr - length) * sizeof(char)); if (update_ptr) this->buffer_ptr -= length; } /** * Remove the header–payload delimiter from the buffer, * get the payload's size and allocate the payload * * @param this The message * @return The return value follows the rules of `message_read` */ static int initialise_payload(struct message* this) { /* Remove the \n (end of empty line) we found from the buffer. */ unbuffer_beginning(this, 1, 1); /* Get the length of the payload. */ if (get_payload_length(this) < 0) return -2; /* Malformated value, enters unrecoverable state. */ /* Allocate the payload buffer. */ if (this->payload_size > 0) if (!(this->payload = malloc(this->payload_size))) return -1; return 0; } /** * Create a header from the buffer and store it * * @param this The message * @param length The length of the header, including LF-termination * @return The return value follows the rules of `message_read` */ static int store_header(struct message* this, size_t length) { char* header; /* Allocate the header. */ if (!(header = malloc(length))) /* Last char is a LF, which is substituted with NUL. */ return -1; /* Copy the header data into the allocated header, */ memcpy(header, this->buffer, length * sizeof(char)); /* and NUL-terminate it. */ header[length - 1] = '\0'; /* Remove the header data from the read buffer. */ unbuffer_beginning(this, length, 1); /* Make sure the the header syntax is correct so that the program does not need to care about it. */ if (validate_header(header, length)) { free(header); return -2; } /* Store the header in the header list. */ this->headers[this->header_count++] = header; return 0; } /** * Continue reading from the socket into the buffer * * @param this The message * @param fd The file descriptor of the socket * @return The return value follows the rules of `message_read` */ static int continue_read(struct message* this, int fd) { size_t n; ssize_t got; int r; /* Figure out how much space we have left in the read buffer. */ n = this->buffer_size - this->buffer_ptr; /* If we do not have too much left, */ if (n < 128) { /* grow the buffer, */ if ((r = extend_buffer(this)) < 0) return r; /* and recalculate how much space we have left. */ n = this->buffer_size - this->buffer_ptr; } /* Then read from the socket. */ errno = 0; got = recv(fd, this->buffer + this->buffer_ptr, n, 0); this->buffer_ptr += (size_t)(got < 0 ? 0 : got); if (errno) return -1; if (got == 0) { errno = ECONNRESET; return -1; } return 0; } /** * Read the next message from a file descriptor * * @param this Memory slot in which to store the new message * @param fd The file descriptor * @return Non-zero on error or interruption, `errno` will be * set accordingly. Destroy the message on error, * be aware that the reading could have been * interrupted by a signal rather than canonical error. * If -2 is returned `errno` will not have been set, * -2 indicates that the message is malformated, * which is a state that cannot be recovered from. */ int message_read(struct message* this, int fd) { size_t header_commit_buffer = 0; int r; /* If we are at stage 2, we are done and it is time to start over. This is important because the function could have been interrupted. */ if (this->stage == 2) { reset_message(this); this->stage = 0; } /* Read from file descriptor until we have a full message. */ for (;;) { char* p; size_t length; /* Stage 0: headers. */ /* Read all headers that we have stored into the read buffer. */ while ((this->stage == 0) && ((p = memchr(this->buffer, '\n', this->buffer_ptr * sizeof(char))) != NULL)) if ((length = (size_t)(p - this->buffer))) { /* We have found a header. */ /* On every eighth header found with this function call, we prepare the header list for eight more headers so that it does not need to be reallocated again and again. */ if (header_commit_buffer == 0) if ((r = extend_headers(this, header_commit_buffer = 8)) < 0) return r; /* Create and store header. */ if ((r = store_header(this, length + 1)) < 0) return r; header_commit_buffer -= 1; } else { /* We have found an empty line, i.e. the end of the headers. */ /* Remove the header–payload delimiter from the buffer, get the payload's size and allocate the payload. */ if ((r = initialise_payload(this)) < 0) return r; /* Mark end of stage, next stage is getting the payload. */ this->stage = 1; } /* Stage 1: payload. */ if ((this->stage == 1) && (this->payload_size > 0)) { /* How much of the payload that has not yet been filled. */ size_t need = this->payload_size - this->payload_ptr; /* How much we have of that what is needed. */ size_t move = this->buffer_ptr < need ? this->buffer_ptr : need; /* Copy what we have, and remove it from the the read buffer. */ memcpy(this->payload + this->payload_ptr, this->buffer, move * sizeof(char)); unbuffer_beginning(this, move, 1); /* Keep track of how much we have read. */ this->payload_ptr += move; } if ((this->stage == 1) && (this->payload_ptr == this->payload_size)) { /* If we have filled the payload (or there was no payload), mark the end of this stage, i.e. that the message is complete, and return with success. */ this->stage = 2; return 0; } /* If stage 1 was not completed. */ /* Continue reading from the socket into the buffer. */ if ((r = continue_read(this, fd)) < 0) return r; } }