/* * libdivecomputer * * Copyright (C) 2009 Jef Driesen * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, * MA 02110-1301 USA */ #include // malloc #include // memcpy, memcmp #include // assert #include "context-private.h" #include "mares_common.h" #include "checksum.h" #include "array.h" #define EXITCODE(rc) \ ( \ rc == -1 ? DC_STATUS_IO : DC_STATUS_TIMEOUT \ ) #define MAXRETRIES 4 #define FP_OFFSET 8 #define FP_SIZE 5 void mares_common_device_init (mares_common_device_t *device, dc_context_t *context, const dc_device_vtable_t *vtable) { assert (device != NULL); // Initialize the base class. device_init (&device->base, context, vtable); // Set the default values. device->port = NULL; device->echo = 0; device->delay = 0; } static void mares_common_make_ascii (const unsigned char raw[], unsigned int rsize, unsigned char ascii[], unsigned int asize) { assert (asize == 2 * (rsize + 2)); // Header ascii[0] = '<'; // Data array_convert_bin2hex (raw, rsize, ascii + 1, 2 * rsize); // Checksum unsigned char checksum = checksum_add_uint8 (ascii + 1, 2 * rsize, 0x00); array_convert_bin2hex (&checksum, 1, ascii + 1 + 2 * rsize, 2); // Trailer ascii[asize - 1] = '>'; } static dc_status_t mares_common_packet (mares_common_device_t *device, const unsigned char command[], unsigned int csize, unsigned char answer[], unsigned int asize) { dc_device_t *abstract = (dc_device_t *) device; if (device_is_cancelled (abstract)) return DC_STATUS_CANCELLED; if (device->delay) { serial_sleep (device->port, device->delay); } // Send the command to the device. int n = serial_write (device->port, command, csize); if (n != csize) { ERROR (abstract->context, "Failed to send the command."); return EXITCODE (n); } if (device->echo) { // Receive the echo of the command. unsigned char echo[PACKETSIZE] = {0}; n = serial_read (device->port, echo, csize); if (n != csize) { ERROR (abstract->context, "Failed to receive the echo."); return EXITCODE (n); } // Verify the echo. if (memcmp (echo, command, csize) != 0) { WARNING (abstract->context, "Unexpected echo."); } } // Receive the answer of the device. n = serial_read (device->port, answer, asize); if (n != asize) { ERROR (abstract->context, "Failed to receive the answer."); return EXITCODE (n); } // Verify the header and trailer of the packet. if (answer[0] != '<' || answer[asize - 1] != '>') { ERROR (abstract->context, "Unexpected answer header/trailer byte."); return DC_STATUS_PROTOCOL; } // Verify the checksum of the packet. unsigned char crc = 0; unsigned char ccrc = checksum_add_uint8 (answer + 1, asize - 4, 0x00); array_convert_hex2bin (answer + asize - 3, 2, &crc, 1); if (crc != ccrc) { ERROR (abstract->context, "Unexpected answer checksum."); return DC_STATUS_PROTOCOL; } return DC_STATUS_SUCCESS; } static dc_status_t mares_common_transfer (mares_common_device_t *device, const unsigned char command[], unsigned int csize, unsigned char answer[], unsigned int asize) { unsigned int nretries = 0; dc_status_t rc = DC_STATUS_SUCCESS; while ((rc = mares_common_packet (device, command, csize, answer, asize)) != DC_STATUS_SUCCESS) { // Automatically discard a corrupted packet, // and request a new one. if (rc != DC_STATUS_PROTOCOL && rc != DC_STATUS_TIMEOUT) return rc; // Abort if the maximum number of retries is reached. if (nretries++ >= MAXRETRIES) return rc; // Discard any garbage bytes. serial_sleep (device->port, 100); serial_flush (device->port, SERIAL_QUEUE_INPUT); } return rc; } dc_status_t mares_common_device_read (dc_device_t *abstract, unsigned int address, unsigned char data[], unsigned int size) { mares_common_device_t *device = (mares_common_device_t*) abstract; unsigned int nbytes = 0; while (nbytes < size) { // Calculate the packet size. unsigned int len = size - nbytes; if (len > PACKETSIZE) len = PACKETSIZE; // Build the raw command. unsigned char raw[] = {0x51, (address ) & 0xFF, // Low (address >> 8) & 0xFF, // High len}; // Count // Build the ascii command. unsigned char command[2 * (sizeof (raw) + 2)] = {0}; mares_common_make_ascii (raw, sizeof (raw), command, sizeof (command)); // Send the command and receive the answer. unsigned char answer[2 * (PACKETSIZE + 2)] = {0}; dc_status_t rc = mares_common_transfer (device, command, sizeof (command), answer, 2 * (len + 2)); if (rc != DC_STATUS_SUCCESS) return rc; // Extract the raw data from the packet. array_convert_hex2bin (answer + 1, 2 * len, data, len); nbytes += len; address += len; data += len; } return DC_STATUS_SUCCESS; } dc_status_t mares_common_extract_dives (dc_context_t *context, const mares_common_layout_t *layout, const unsigned char fingerprint[], const unsigned char data[], dc_dive_callback_t callback, void *userdata) { assert (layout != NULL); // Get the freedive mode for this model. unsigned int model = data[1]; unsigned int freedive = 2; if (model == 1 || model == 7 || model == 19) freedive = 3; // Get the end of the profile ring buffer. unsigned int eop = array_uint16_le (data + 0x6B); if (eop < layout->rb_profile_begin || eop >= layout->rb_profile_end) { ERROR (context, "Ringbuffer pointer out of range."); return DC_STATUS_DATAFORMAT; } // Make the ringbuffer linear, to avoid having to deal // with the wrap point. The buffer has extra space to // store the profile data for the freedives. unsigned char *buffer = (unsigned char *) malloc ( layout->rb_profile_end - layout->rb_profile_begin + layout->rb_freedives_end - layout->rb_freedives_begin); if (buffer == NULL) { ERROR (context, "Failed to allocate memory."); return DC_STATUS_NOMEMORY; } memcpy (buffer + 0, data + eop, layout->rb_profile_end - eop); memcpy (buffer + layout->rb_profile_end - eop, data + layout->rb_profile_begin, eop - layout->rb_profile_begin); // For a freedive session, the Mares Nemo stores all the freedives of // that session in a single logbook entry, and each sample is actually // a summary for each individual freedive in the session. The profile // data is stored in a separate memory area. Since only the most recent // recent freediving session can have profile data, we keep track of the // number of freedives. unsigned int nfreedives = 0; unsigned int offset = layout->rb_profile_end - layout->rb_profile_begin; while (offset >= 3) { // Check for the presence of extra header bytes, which can be detected // by means of a three byte marker sequence. unsigned int extra = 0; const unsigned char marker[3] = {0xAA, 0xBB, 0xCC}; if (memcmp (buffer + offset - 3, marker, sizeof (marker)) == 0) { if (model == 19) extra = 7; else extra = 12; } // Check for overflows due to incomplete dives. if (offset < extra + 3) break; // Check the dive mode of the logbook entry. Valid modes are // 0 (air), 1 (EANx), 2 (freedive) or 3 (bottom timer). // If the ringbuffer has never reached the wrap point before, // there will be "empty" memory (filled with 0xFF) and // processing should stop at this point. unsigned int mode = buffer[offset - extra - 1]; if (mode == 0xFF) break; // The header and sample size are dependant on the dive mode. Only // in freedive mode, the sizes are different from the other modes. unsigned int header_size = 53; unsigned int sample_size = 2; if (extra) { if (model == 19) sample_size = 3; else sample_size = 5; } if (mode == freedive) { header_size = 28; sample_size = 6; nfreedives++; } // Get the number of samples in the profile data. unsigned int nsamples = array_uint16_le (buffer + offset - extra - 3); // Calculate the total number of bytes for this dive. // If the buffer does not contain that much bytes, we reached the // end of the ringbuffer. The current dive is incomplete (partially // overwritten with newer data), and processing should stop. unsigned int nbytes = 2 + nsamples * sample_size + header_size + extra; if (offset < nbytes) break; // Move to the start of the dive. offset -= nbytes; // Verify that the length that is stored in the profile data // equals the calculated length. If both values are different, // something is wrong and an error is returned. unsigned int length = array_uint16_le (buffer + offset); if (length != nbytes) { ERROR (context, "Calculated and stored size are not equal."); free (buffer); return DC_STATUS_DATAFORMAT; } // Process the profile data for the most recent freedive entry. // Since we are processing the entries backwards (newest to oldest), // this entry will always be the first one. if (mode == freedive && nfreedives == 1) { // Count the number of freedives in the profile data. unsigned int count = 0; unsigned int idx = layout->rb_freedives_begin; while (idx + 2 <= layout->rb_freedives_end && count != nsamples) { // Each freedive in the session ends with a zero sample. unsigned int sample = array_uint16_le (data + idx); if (sample == 0) count++; // Move to the next sample. idx += 2; } // Verify that the number of freedive entries in the session // equals the number of freedives in the profile data. If // both values are different, the profile data is incomplete. if (count != nsamples) { ERROR (context, "Unexpected number of freedive sessions."); free (buffer); return DC_STATUS_DATAFORMAT; } // Append the profile data to the main logbook entry. The // buffer is guaranteed to have enough space, and the dives // that will be overwritten have already been processed. memcpy (buffer + offset + nbytes, data + layout->rb_freedives_begin, idx - layout->rb_freedives_begin); nbytes += idx - layout->rb_freedives_begin; } unsigned int fp_offset = offset + length - extra - FP_OFFSET; if (fingerprint && memcmp (buffer + fp_offset, fingerprint, FP_SIZE) == 0) { free (buffer); return DC_STATUS_SUCCESS; } if (callback && !callback (buffer + offset, nbytes, buffer + fp_offset, FP_SIZE, userdata)) { free (buffer); return DC_STATUS_SUCCESS; } } free (buffer); return DC_STATUS_SUCCESS; }