/* * libdivecomputer * * Copyright (C) 2008 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 // memcpy #include // malloc, free #include #include "oceanic_vtpro.h" #include "oceanic_common.h" #include "context-private.h" #include "device-private.h" #include "serial.h" #include "ringbuffer.h" #include "checksum.h" #include "array.h" #define ISINSTANCE(device) dc_device_isinstance((device), &oceanic_vtpro_device_vtable.base) #define MAXRETRIES 2 #define MULTIPAGE 4 #define ACK 0x5A #define NAK 0xA5 #define END 0x51 #define AERIS500AI 0x4151 typedef enum oceanic_vtpro_protocol_t { MOD, INTR, } oceanic_vtpro_protocol_t; typedef struct oceanic_vtpro_device_t { oceanic_common_device_t base; dc_iostream_t *iostream; unsigned int model; oceanic_vtpro_protocol_t protocol; } oceanic_vtpro_device_t; static dc_status_t oceanic_vtpro_device_logbook (dc_device_t *abstract, dc_event_progress_t *progress, dc_buffer_t *logbook); static dc_status_t oceanic_vtpro_device_read (dc_device_t *abstract, unsigned int address, unsigned char data[], unsigned int size); static dc_status_t oceanic_vtpro_device_close (dc_device_t *abstract); static const oceanic_common_device_vtable_t oceanic_vtpro_device_vtable = { { sizeof(oceanic_vtpro_device_t), DC_FAMILY_OCEANIC_VTPRO, oceanic_common_device_set_fingerprint, /* set_fingerprint */ oceanic_vtpro_device_read, /* read */ NULL, /* write */ oceanic_common_device_dump, /* dump */ oceanic_common_device_foreach, /* foreach */ NULL, /* timesync */ oceanic_vtpro_device_close /* close */ }, oceanic_vtpro_device_logbook, oceanic_common_device_profile, }; static const oceanic_common_version_t oceanic_vtpro_version[] = { {"VERSAPRO \0\0 256K"}, {"ATMOSTWO \0\0 256K"}, {"PROPLUS2 \0\0 256K"}, {"ATMOSAIR \0\0 256K"}, {"VTPRO r\0\0 256K"}, {"ELITE r\0\0 256K"}, }; static const oceanic_common_version_t oceanic_wisdom_version[] = { {"WISDOM r\0\0 256K"}, }; static const oceanic_common_layout_t oceanic_vtpro_layout = { 0x8000, /* memsize */ 0x0000, /* cf_devinfo */ 0x0040, /* cf_pointers */ 0x0240, /* rb_logbook_begin */ 0x0440, /* rb_logbook_end */ 8, /* rb_logbook_entry_size */ 0x0440, /* rb_profile_begin */ 0x8000, /* rb_profile_end */ 0, /* pt_mode_global */ 0, /* pt_mode_logbook */ 0, /* pt_mode_serial */ }; static const oceanic_common_layout_t oceanic_wisdom_layout = { 0x8000, /* memsize */ 0x0000, /* cf_devinfo */ 0x0040, /* cf_pointers */ 0x03D0, /* rb_logbook_begin */ 0x05D0, /* rb_logbook_end */ 8, /* rb_logbook_entry_size */ 0x05D0, /* rb_profile_begin */ 0x8000, /* rb_profile_end */ 0, /* pt_mode_global */ 0, /* pt_mode_logbook */ 0, /* pt_mode_serial */ }; static const oceanic_common_layout_t aeris_500ai_layout = { 0x20000, /* memsize */ 0x0000, /* cf_devinfo */ 0x0110, /* cf_pointers */ 0x0200, /* rb_logbook_begin */ 0x0200, /* rb_logbook_end */ 8, /* rb_logbook_entry_size */ 0x00200, /* rb_profile_begin */ 0x20000, /* rb_profile_end */ 0, /* pt_mode_global */ 1, /* pt_mode_logbook */ 2, /* pt_mode_serial */ }; static dc_status_t oceanic_vtpro_send (oceanic_vtpro_device_t *device, const unsigned char command[], unsigned int csize) { dc_status_t status = DC_STATUS_SUCCESS; dc_device_t *abstract = (dc_device_t *) device; if (device_is_cancelled (abstract)) return DC_STATUS_CANCELLED; // Send the command to the dive computer. status = dc_iostream_write (device->iostream, command, csize, NULL); if (status != DC_STATUS_SUCCESS) { ERROR (abstract->context, "Failed to send the command."); return status; } // Receive the response (ACK/NAK) of the dive computer. unsigned char response = NAK; status = dc_iostream_read (device->iostream, &response, 1, NULL); if (status != DC_STATUS_SUCCESS) { ERROR (abstract->context, "Failed to receive the answer."); return status; } // Verify the response of the dive computer. if (response != ACK) { ERROR (abstract->context, "Unexpected answer start byte(s)."); return DC_STATUS_PROTOCOL; } return DC_STATUS_SUCCESS; } static dc_status_t oceanic_vtpro_transfer (oceanic_vtpro_device_t *device, const unsigned char command[], unsigned int csize, unsigned char answer[], unsigned int asize) { dc_status_t status = DC_STATUS_SUCCESS; dc_device_t *abstract = (dc_device_t *) device; // Send the command to the device. If the device responds with an // ACK byte, the command was received successfully and the answer // (if any) follows after the ACK byte. If the device responds with // a NAK byte, we try to resend the command a number of times before // returning an error. unsigned int nretries = 0; dc_status_t rc = DC_STATUS_SUCCESS; while ((rc = oceanic_vtpro_send (device, command, csize)) != DC_STATUS_SUCCESS) { if (rc != DC_STATUS_TIMEOUT && rc != DC_STATUS_PROTOCOL) return rc; // Abort if the maximum number of retries is reached. if (nretries++ >= MAXRETRIES) return rc; } if (asize) { // Receive the answer of the dive computer. status = dc_iostream_read (device->iostream, answer, asize, NULL); if (status != DC_STATUS_SUCCESS) { ERROR (abstract->context, "Failed to receive the answer."); return status; } } return DC_STATUS_SUCCESS; } static dc_status_t oceanic_vtpro_init (oceanic_vtpro_device_t *device) { dc_status_t status = DC_STATUS_SUCCESS; dc_device_t *abstract = (dc_device_t *) device; // Send the command to the dive computer. unsigned char command[2][2] = { {0xAA, 0x00}, {0x20, 0x00}}; status = dc_iostream_write (device->iostream, command[device->protocol], sizeof (command[device->protocol]), NULL); if (status != DC_STATUS_SUCCESS) { ERROR (abstract->context, "Failed to send the command."); return status; } // Receive the answer of the dive computer. unsigned char answer[13] = {0}; status = dc_iostream_read (device->iostream, answer, sizeof (answer), NULL); if (status != DC_STATUS_SUCCESS) { ERROR (abstract->context, "Failed to receive the answer."); return status; } // Verify the answer. const unsigned char response[2][13] = { {0x4D, 0x4F, 0x44, 0x2D, 0x2D, 0x4F, 0x4B, 0x5F, 0x56, 0x32, 0x2E, 0x30, 0x30}, {0x49, 0x4E, 0x54, 0x52, 0x2D, 0x4F, 0x4B, 0x5F, 0x56, 0x31, 0x2E, 0x31, 0x31}}; if (memcmp (answer, response[device->protocol], sizeof (response[device->protocol])) != 0) { ERROR (abstract->context, "Unexpected answer byte(s)."); return DC_STATUS_PROTOCOL; } return DC_STATUS_SUCCESS; } static dc_status_t oceanic_vtpro_quit (oceanic_vtpro_device_t *device) { dc_device_t *abstract = (dc_device_t *) device; // Send the command to the dive computer. unsigned char answer[1] = {0}; unsigned char command[4] = {0x6A, 0x05, 0xA5, 0x00}; dc_status_t rc = oceanic_vtpro_transfer (device, command, sizeof (command), answer, sizeof (answer)); if (rc != DC_STATUS_SUCCESS) return rc; // Verify the last byte of the answer. if (answer[0] != END) { ERROR (abstract->context, "Unexpected answer byte(s)."); return DC_STATUS_PROTOCOL; } return DC_STATUS_SUCCESS; } static dc_status_t oceanic_vtpro_calibrate (oceanic_vtpro_device_t *device) { dc_device_t *abstract = (dc_device_t *) device; // Send the command to the dive computer. // The timeout is temporary increased, because the // device needs approximately 6 seconds to respond. unsigned char answer[2] = {0}; unsigned char command[2] = {0x18, 0x00}; dc_iostream_set_timeout (device->iostream, 9000); dc_status_t rc = oceanic_vtpro_transfer (device, command, sizeof (command), answer, sizeof (answer)); dc_iostream_set_timeout (device->iostream, 3000); if (rc != DC_STATUS_SUCCESS) return rc; // Verify the last byte of the answer. if (answer[1] != 0x00) { ERROR (abstract->context, "Unexpected answer byte(s)."); return DC_STATUS_PROTOCOL; } return DC_STATUS_SUCCESS; } static dc_status_t oceanic_aeris500ai_device_logbook (dc_device_t *abstract, dc_event_progress_t *progress, dc_buffer_t *logbook) { dc_status_t rc = DC_STATUS_SUCCESS; oceanic_vtpro_device_t *device = (oceanic_vtpro_device_t *) abstract; assert (device != NULL); assert (device->base.layout != NULL); assert (device->base.layout->rb_logbook_entry_size == PAGESIZE / 2); assert (device->base.layout->rb_logbook_begin == device->base.layout->rb_logbook_end); assert (progress != NULL); const oceanic_common_layout_t *layout = device->base.layout; // Erase the buffer. if (!dc_buffer_clear (logbook)) return DC_STATUS_NOMEMORY; // Read the pointer data. unsigned char pointers[PAGESIZE] = {0}; rc = oceanic_vtpro_device_read (abstract, layout->cf_pointers, pointers, sizeof (pointers)); if (rc != DC_STATUS_SUCCESS) { ERROR (abstract->context, "Failed to read the memory page."); return rc; } // Get the logbook pointers. unsigned int last = pointers[0x03]; // Update and emit a progress event. progress->current += PAGESIZE; progress->maximum += PAGESIZE + (last + 1) * PAGESIZE / 2; device_event_emit (abstract, DC_EVENT_PROGRESS, progress); // Allocate memory for the logbook entries. if (!dc_buffer_reserve (logbook, (last + 1) * PAGESIZE / 2)) return DC_STATUS_NOMEMORY; // Send the logbook index command. unsigned char command[] = {0x52, (last >> 8) & 0xFF, // high (last ) & 0xFF, // low 0x00}; rc = oceanic_vtpro_transfer (device, command, sizeof (command), NULL, 0); if (rc != DC_STATUS_SUCCESS) { ERROR (abstract->context, "Failed to send the logbook index command."); return rc; } // Read the logbook index. for (unsigned int i = 0; i < last + 1; ++i) { // Receive the answer of the dive computer. unsigned char answer[PAGESIZE / 2 + 1] = {0}; rc = dc_iostream_read (device->iostream, answer, sizeof(answer), NULL); if (rc != DC_STATUS_SUCCESS) { ERROR (abstract->context, "Failed to receive the answer."); return rc; } // Verify the checksum of the answer. unsigned char crc = answer[PAGESIZE / 2]; unsigned char ccrc = checksum_add_uint4 (answer, PAGESIZE / 2, 0x00); if (crc != ccrc) { ERROR (abstract->context, "Unexpected answer checksum."); return DC_STATUS_PROTOCOL; } // Update and emit a progress event. progress->current += PAGESIZE / 2; device_event_emit (abstract, DC_EVENT_PROGRESS, progress); // Ignore uninitialized entries. if (array_isequal (answer, PAGESIZE / 2, 0xFF)) { WARNING (abstract->context, "Uninitialized logbook entries detected!"); continue; } // Compare the fingerprint to identify previously downloaded entries. if (memcmp (answer, device->base.fingerprint, PAGESIZE / 2) == 0) { dc_buffer_clear (logbook); } else { dc_buffer_append (logbook, answer, PAGESIZE / 2); } } return DC_STATUS_SUCCESS; } static dc_status_t oceanic_vtpro_device_logbook (dc_device_t *abstract, dc_event_progress_t *progress, dc_buffer_t *logbook) { oceanic_vtpro_device_t *device = (oceanic_vtpro_device_t *) abstract; if (device->model == AERIS500AI) { return oceanic_aeris500ai_device_logbook (abstract, progress, logbook); } else { return oceanic_common_device_logbook (abstract, progress, logbook); } } dc_status_t oceanic_vtpro_device_open (dc_device_t **out, dc_context_t *context, const char *name, unsigned int model) { dc_status_t status = DC_STATUS_SUCCESS; oceanic_vtpro_device_t *device = NULL; if (out == NULL) return DC_STATUS_INVALIDARGS; // Allocate memory. device = (oceanic_vtpro_device_t *) dc_device_allocate (context, &oceanic_vtpro_device_vtable.base); if (device == NULL) { ERROR (context, "Failed to allocate memory."); return DC_STATUS_NOMEMORY; } // Initialize the base class. oceanic_common_device_init (&device->base); // Override the base class values. device->base.multipage = MULTIPAGE; // Set the default values. device->iostream = NULL; device->model = model; if (model == AERIS500AI) { device->protocol = INTR; } else { device->protocol = MOD; } // Open the device. status = dc_serial_open (&device->iostream, context, name); if (status != DC_STATUS_SUCCESS) { ERROR (context, "Failed to open the serial port."); goto error_free; } // Set the serial communication protocol (9600 8N1). status = dc_iostream_configure (device->iostream, 9600, 8, DC_PARITY_NONE, DC_STOPBITS_ONE, DC_FLOWCONTROL_NONE); if (status != DC_STATUS_SUCCESS) { ERROR (context, "Failed to set the terminal attributes."); goto error_close; } // Set the timeout for receiving data (3000 ms). status = dc_iostream_set_timeout (device->iostream, 3000); if (status != DC_STATUS_SUCCESS) { ERROR (context, "Failed to set the timeout."); goto error_close; } // Set the DTR line. status = dc_iostream_set_dtr (device->iostream, 1); if (status != DC_STATUS_SUCCESS) { ERROR (context, "Failed to set the DTR line."); goto error_close; } // Set the RTS line. status = dc_iostream_set_rts (device->iostream, 1); if (status != DC_STATUS_SUCCESS) { ERROR (context, "Failed to set the RTS line."); goto error_close; } // Give the interface 100 ms to settle and draw power up. dc_iostream_sleep (device->iostream, device->protocol == MOD ? 100 : 1000); // Make sure everything is in a sane state. dc_iostream_purge (device->iostream, DC_DIRECTION_ALL); // Initialize the data cable (MOD mode). status = oceanic_vtpro_init (device); if (status != DC_STATUS_SUCCESS) { goto error_close; } // Switch the device from surface mode into download mode. Before sending // this command, the device needs to be in PC mode (manually activated by // the user), or already in download mode. status = oceanic_vtpro_device_version ((dc_device_t *) device, device->base.version, sizeof (device->base.version)); if (status != DC_STATUS_SUCCESS) { goto error_close; } // Calibrate the device. Although calibration is optional, it's highly // recommended because it reduces the transfer time considerably, even // when processing the command itself is quite slow. status = oceanic_vtpro_calibrate (device); if (status != DC_STATUS_SUCCESS) { goto error_close; } // Override the base class values. if (model == AERIS500AI) { device->base.layout = &aeris_500ai_layout; } else if (OCEANIC_COMMON_MATCH (device->base.version, oceanic_wisdom_version)) { device->base.layout = &oceanic_wisdom_layout; } else if (OCEANIC_COMMON_MATCH (device->base.version, oceanic_vtpro_version)) { device->base.layout = &oceanic_vtpro_layout; } else { WARNING (context, "Unsupported device detected!"); device->base.layout = &oceanic_vtpro_layout; } *out = (dc_device_t*) device; return DC_STATUS_SUCCESS; error_close: dc_iostream_close (device->iostream); error_free: dc_device_deallocate ((dc_device_t *) device); return status; } static dc_status_t oceanic_vtpro_device_close (dc_device_t *abstract) { dc_status_t status = DC_STATUS_SUCCESS; oceanic_vtpro_device_t *device = (oceanic_vtpro_device_t*) abstract; dc_status_t rc = DC_STATUS_SUCCESS; // Switch the device back to surface mode. rc = oceanic_vtpro_quit (device); if (rc != DC_STATUS_SUCCESS) { dc_status_set_error(&status, rc); } // Close the device. rc = dc_iostream_close (device->iostream); if (rc != DC_STATUS_SUCCESS) { dc_status_set_error(&status, rc); } return status; } dc_status_t oceanic_vtpro_device_keepalive (dc_device_t *abstract) { oceanic_vtpro_device_t *device = (oceanic_vtpro_device_t*) abstract; if (!ISINSTANCE (abstract)) return DC_STATUS_INVALIDARGS; // Send the command to the dive computer. unsigned char answer[1] = {0}; unsigned char command[4] = {0x6A, 0x08, 0x00, 0x00}; dc_status_t rc = oceanic_vtpro_transfer (device, command, sizeof (command), answer, sizeof (answer)); if (rc != DC_STATUS_SUCCESS) return rc; // Verify the last byte of the answer. if (answer[0] != END) { ERROR (abstract->context, "Unexpected answer byte(s)."); return DC_STATUS_PROTOCOL; } return DC_STATUS_SUCCESS; } dc_status_t oceanic_vtpro_device_version (dc_device_t *abstract, unsigned char data[], unsigned int size) { oceanic_vtpro_device_t *device = (oceanic_vtpro_device_t*) abstract; if (!ISINSTANCE (abstract)) return DC_STATUS_INVALIDARGS; if (size < PAGESIZE) return DC_STATUS_INVALIDARGS; // Switch the device into download mode. The response is ignored here, // since it is identical (except for the missing trailing byte) to the // response of the first part of the other command in this function. unsigned char cmd[2] = {0x88, 0x00}; unsigned char ans[PAGESIZE / 2 + 1] = {0}; dc_status_t rc = oceanic_vtpro_transfer (device, cmd, sizeof (cmd), ans, sizeof (ans)); if (rc != DC_STATUS_SUCCESS) return rc; // Verify the checksum of the answer. unsigned char crc = ans[PAGESIZE / 2]; unsigned char ccrc = checksum_add_uint4 (ans, PAGESIZE / 2, 0x00); if (crc != ccrc) { ERROR (abstract->context, "Unexpected answer checksum."); return DC_STATUS_PROTOCOL; } if (device->protocol == MOD) { // Obtain the device identification string. This string is // split over two packets, but we join both parts again. for (unsigned int i = 0; i < 2; ++i) { unsigned char command[4] = {0x72, 0x03, i * 0x10, 0x00}; unsigned char answer[PAGESIZE / 2 + 2] = {0}; rc = oceanic_vtpro_transfer (device, command, sizeof (command), answer, sizeof (answer)); if (rc != DC_STATUS_SUCCESS) return rc; // Verify the checksum of the answer. unsigned char crc = answer[PAGESIZE / 2]; unsigned char ccrc = checksum_add_uint4 (answer, PAGESIZE / 2, 0x00); if (crc != ccrc) { ERROR (abstract->context, "Unexpected answer checksum."); return DC_STATUS_PROTOCOL; } // Verify the last byte of the answer. if (answer[PAGESIZE / 2 + 1] != END) { ERROR (abstract->context, "Unexpected answer byte."); return DC_STATUS_PROTOCOL; } // Append the answer to the output buffer. memcpy (data + i * PAGESIZE / 2, answer, PAGESIZE / 2); } } else { // Return an empty device identification string. memset (data, 0x00, PAGESIZE); } return DC_STATUS_SUCCESS; } static dc_status_t oceanic_vtpro_device_read (dc_device_t *abstract, unsigned int address, unsigned char data[], unsigned int size) { oceanic_vtpro_device_t *device = (oceanic_vtpro_device_t*) abstract; if ((address % PAGESIZE != 0) || (size % PAGESIZE != 0)) return DC_STATUS_INVALIDARGS; unsigned int nbytes = 0; while (nbytes < size) { // Calculate the number of packages. unsigned int npackets = (size - nbytes) / PAGESIZE; if (npackets > MULTIPAGE) npackets = MULTIPAGE; // Read the package. unsigned int first = address / PAGESIZE; unsigned int last = first + npackets - 1; unsigned char answer[(PAGESIZE + 1) * MULTIPAGE] = {0}; unsigned char command[6] = {0x34, (first >> 8) & 0xFF, // high (first ) & 0xFF, // low (last >> 8) & 0xFF, // high (last ) & 0xFF, // low 0x00}; dc_status_t rc = oceanic_vtpro_transfer (device, command, sizeof (command), answer, (PAGESIZE + 1) * npackets); if (rc != DC_STATUS_SUCCESS) return rc; unsigned int offset = 0; for (unsigned int i = 0; i < npackets; ++i) { // Verify the checksum of the answer. unsigned char crc = answer[offset + PAGESIZE]; unsigned char ccrc = checksum_add_uint8 (answer + offset, PAGESIZE, 0x00); if (crc != ccrc) { ERROR (abstract->context, "Unexpected answer checksum."); return DC_STATUS_PROTOCOL; } memcpy (data, answer + offset, PAGESIZE); offset += PAGESIZE + 1; nbytes += PAGESIZE; address += PAGESIZE; data += PAGESIZE; } } return DC_STATUS_SUCCESS; }