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Merge pull request #14 from torvalds/Subsurface-branch

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Merge with upstream libdivecomputer
This commit is contained in:
Dirk Hohndel 2018-03-13 22:33:47 -07:00 committed by GitHub
commit 9cda25a98b
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GPG Key ID: 4AEE18F83AFDEB23
38 changed files with 2017 additions and 957 deletions
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8
configure.ac
View File

@ -166,6 +166,7 @@ AC_CHECK_HEADERS([IOKit/serial/ioss.h])
AC_CHECK_HEADERS([getopt.h])
AC_CHECK_HEADERS([sys/param.h])
AC_CHECK_HEADERS([pthread.h])
AC_CHECK_HEADERS([mach/mach_time.h])
# Checks for global variable declarations.
AC_CHECK_DECLS([optreset])
@ -178,6 +179,7 @@ AC_CHECK_MEMBERS([struct tm.tm_gmtoff],,,[
# Checks for library functions.
AC_FUNC_STRERROR_R
AC_CHECK_FUNCS([localtime_r gmtime_r timegm _mkgmtime])
AC_CHECK_FUNCS([clock_gettime mach_absolute_time])
AC_CHECK_FUNCS([getopt_long])
# Checks for supported compiler options.
@ -187,12 +189,16 @@ AX_APPEND_COMPILE_FLAGS([ \
-Wrestrict \
-Wformat=2 \
-Wwrite-strings \
-Wcast-qual \
-Wpointer-arith \
-Wstrict-prototypes \
-Wmissing-prototypes \
-Wmissing-declarations \
-Wno-unused-parameter \
-Wno-unused-function \
-Wno-unused-variable \
-Wno-unused-but-set-variable \
-Wno-pointer-sign \
-Wno-shadow \
])
# Windows specific compiler options.

1
include/libdivecomputer/custom_io.h
View File

@ -49,7 +49,6 @@ typedef struct dc_custom_io_t
dc_status_t (*serial_configure) (struct dc_custom_io_t *io, unsigned int baudrate, unsigned int databits, dc_parity_t parity, dc_stopbits_t stopbits, dc_flowcontrol_t flowcontrol);
dc_status_t (*serial_set_dtr) (struct dc_custom_io_t *io, int level);
dc_status_t (*serial_set_rts) (struct dc_custom_io_t *io, int level);
dc_status_t (*serial_set_halfduplex) (struct dc_custom_io_t *io, unsigned int value);
dc_status_t (*serial_set_break) (struct dc_custom_io_t *io, unsigned int level);
//dc_serial_set_latency (dc_serial_t *device, unsigned int milliseconds) - Unused
//dc_serial_get_lines (dc_serial_t *device, unsigned int *value) - Unused

3
include/libdivecomputer/descriptor.h
View File

@ -58,9 +58,6 @@ dc_descriptor_get_type (dc_descriptor_t *descriptor);
unsigned int
dc_descriptor_get_model (dc_descriptor_t *descriptor);
unsigned int
dc_descriptor_get_serial (dc_descriptor_t *descriptor);
dc_transport_t
dc_descriptor_get_transport (dc_descriptor_t *descriptor);

11
include/libdivecomputer/iostream.h
View File

@ -129,17 +129,6 @@ dc_iostream_set_timeout (dc_iostream_t *iostream, int timeout);
dc_status_t
dc_iostream_set_latency (dc_iostream_t *iostream, unsigned int value);
/**
* Set the state of the half duplex emulation.
*
* @param[in] iostream A valid I/O stream.
* @param[in] value The half duplex state.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_iostream_set_halfduplex (dc_iostream_t *iostream, unsigned int value);
/**
* Set the state of the break condition.
*

8
msvc/libdivecomputer.vcproj
View File

@ -482,6 +482,10 @@
RelativePath="..\src\suunto_vyper_parser.c"
>
</File>
<File
RelativePath="..\src\timer.c"
>
</File>
<File
RelativePath="..\src\usbhid.c"
>
@ -820,6 +824,10 @@
RelativePath="..\src\suunto_vyper2.h"
>
</File>
<File
RelativePath="..\src\timer.h"
>
</File>
<File
RelativePath="..\include\libdivecomputer\units.h"
>

3
src/Makefile.am
View File

@ -16,7 +16,7 @@ endif
libdivecomputer_la_SOURCES = \
version.c \
descriptor.c \
descriptor-private.h descriptor.c \
iostream-private.h iostream.c \
iterator-private.h iterator.c \
common-private.h common.c \
@ -24,6 +24,7 @@ libdivecomputer_la_SOURCES = \
device-private.h device.c \
parser-private.h parser.c \
datetime.c \
timer.h timer.c \
suunto_common.h suunto_common.c \
suunto_common2.h suunto_common2.c \
suunto_solution.h suunto_solution.c suunto_solution_parser.c \

481
src/bluetooth.c
View File

@ -24,6 +24,7 @@
#endif
#include <stdlib.h> // malloc, free
#include <stdio.h>
#include "socket.h"
@ -50,6 +51,8 @@
#include "common-private.h"
#include "context-private.h"
#include "iostream-private.h"
#include "iterator-private.h"
#include "descriptor-private.h"
#ifdef _WIN32
#define DC_ADDRESS_FORMAT "%012I64X"
@ -64,12 +67,38 @@
#define ISINSTANCE(device) dc_iostream_isinstance((device), &dc_bluetooth_vtable)
struct dc_bluetooth_device_t {
dc_bluetooth_address_t address;
char name[248];
};
#ifdef BLUETOOTH
static dc_status_t dc_bluetooth_iterator_next (dc_iterator_t *iterator, void *item);
static dc_status_t dc_bluetooth_iterator_free (dc_iterator_t *iterator);
typedef struct dc_bluetooth_iterator_t {
dc_iterator_t base;
dc_filter_t filter;
#ifdef _WIN32
HANDLE hLookup;
#else
int fd;
inquiry_info *devices;
size_t count;
size_t current;
#endif
} dc_bluetooth_iterator_t;
static const dc_iterator_vtable_t dc_bluetooth_iterator_vtable = {
sizeof(dc_bluetooth_iterator_t),
dc_bluetooth_iterator_next,
dc_bluetooth_iterator_free,
};
static const dc_iostream_vtable_t dc_bluetooth_vtable = {
sizeof(dc_socket_t),
dc_socket_set_timeout, /* set_timeout */
dc_socket_set_latency, /* set_latency */
dc_socket_set_halfduplex, /* set_halfduplex */
dc_socket_set_break, /* set_break */
dc_socket_set_dtr, /* set_dtr */
dc_socket_set_rts, /* set_rts */
@ -194,8 +223,275 @@ error:
#endif
#endif
char *
dc_bluetooth_addr2str(dc_bluetooth_address_t address, char *str, size_t size)
{
if (str == NULL || size < DC_BLUETOOTH_SIZE)
return NULL;
int n = snprintf(str, size, "%02X:%02X:%02X:%02X:%02X:%02X",
(unsigned char)((address >> 40) & 0xFF),
(unsigned char)((address >> 32) & 0xFF),
(unsigned char)((address >> 24) & 0xFF),
(unsigned char)((address >> 16) & 0xFF),
(unsigned char)((address >> 8) & 0xFF),
(unsigned char)((address >> 0) & 0xFF));
if (n < 0 || (size_t) n >= size)
return NULL;
return str;
}
dc_bluetooth_address_t
dc_bluetooth_str2addr(const char *str)
{
dc_bluetooth_address_t address = 0;
if (str == NULL)
return 0;
unsigned char c = 0;
while ((c = *str++) != '\0') {
if (c == ':') {
continue;
} else if (c >= '0' && c <= '9') {
c -= '0';
} else if (c >= 'A' && c <= 'F') {
c -= 'A' - 10;
} else if (c >= 'a' && c <= 'f') {
c -= 'a' - 10;
} else {
return 0; /* Invalid character! */
}
address <<= 4;
address |= c;
}
return address;
}
dc_bluetooth_address_t
dc_bluetooth_device_get_address (dc_bluetooth_device_t *device)
{
if (device == NULL)
return 0;
return device->address;
}
const char *
dc_bluetooth_device_get_name (dc_bluetooth_device_t *device)
{
if (device == NULL || device->name[0] == '\0')
return NULL;
return device->name;
}
void
dc_bluetooth_device_free (dc_bluetooth_device_t *device)
{
free (device);
}
dc_status_t
dc_bluetooth_open (dc_iostream_t **out, dc_context_t *context)
dc_bluetooth_iterator_new (dc_iterator_t **out, dc_context_t *context, dc_descriptor_t *descriptor)
{
#ifdef BLUETOOTH
dc_status_t status = DC_STATUS_SUCCESS;
dc_bluetooth_iterator_t *iterator = NULL;
if (out == NULL)
return DC_STATUS_INVALIDARGS;
iterator = (dc_bluetooth_iterator_t *) dc_iterator_allocate (context, &dc_bluetooth_iterator_vtable);
if (iterator == NULL) {
SYSERROR (context, S_ENOMEM);
return DC_STATUS_NOMEMORY;
}
#ifdef _WIN32
WSAQUERYSET wsaq;
memset(&wsaq, 0, sizeof (wsaq));
wsaq.dwSize = sizeof (wsaq);
wsaq.dwNameSpace = NS_BTH;
wsaq.lpcsaBuffer = NULL;
HANDLE hLookup = NULL;
if (WSALookupServiceBegin(&wsaq, LUP_CONTAINERS | LUP_FLUSHCACHE, &hLookup) != 0) {
s_errcode_t errcode = S_ERRNO;
if (errcode == WSASERVICE_NOT_FOUND) {
// No remote bluetooth devices found.
hLookup = NULL;
} else {
SYSERROR (context, errcode);
status = dc_socket_syserror(errcode);
goto error_free;
}
}
iterator->hLookup = hLookup;
#else
// Get the resource number for the first available bluetooth adapter.
int dev = hci_get_route (NULL);
if (dev < 0) {
s_errcode_t errcode = S_ERRNO;
SYSERROR (context, errcode);
status = dc_socket_syserror(errcode);
goto error_free;
}
// Open a socket to the bluetooth adapter.
int fd = hci_open_dev (dev);
if (fd < 0) {
s_errcode_t errcode = S_ERRNO;
SYSERROR (context, errcode);
status = dc_socket_syserror(errcode);
goto error_free;
}
// Perform the bluetooth device discovery. The inquiry lasts for at
// most MAX_PERIODS * 1.28 seconds, and at most MAX_DEVICES devices
// will be returned.
inquiry_info *devices = NULL;
int ndevices = hci_inquiry (dev, MAX_PERIODS, MAX_DEVICES, NULL, &devices, IREQ_CACHE_FLUSH);
if (ndevices < 0) {
s_errcode_t errcode = S_ERRNO;
SYSERROR (context, errcode);
status = dc_socket_syserror(errcode);
goto error_close;
}
iterator->fd = fd;
iterator->devices = devices;
iterator->count = ndevices;
iterator->current = 0;
#endif
iterator->filter = dc_descriptor_get_filter (descriptor);
*out = (dc_iterator_t *) iterator;
return DC_STATUS_SUCCESS;
#ifndef _WIN32
error_close:
hci_close_dev(fd);
#endif
error_free:
dc_iterator_deallocate ((dc_iterator_t *) iterator);
return status;
#else
return DC_STATUS_UNSUPPORTED;
#endif
}
#ifdef BLUETOOTH
static dc_status_t
dc_bluetooth_iterator_next (dc_iterator_t *abstract, void *out)
{
dc_bluetooth_iterator_t *iterator = (dc_bluetooth_iterator_t *) abstract;
dc_bluetooth_device_t *device = NULL;
#ifdef _WIN32
if (iterator->hLookup == NULL) {
return DC_STATUS_DONE;
}
unsigned char buf[4096];
LPWSAQUERYSET pwsaResults = (LPWSAQUERYSET) buf;
memset(pwsaResults, 0, sizeof(WSAQUERYSET));
pwsaResults->dwSize = sizeof(WSAQUERYSET);
pwsaResults->dwNameSpace = NS_BTH;
pwsaResults->lpBlob = NULL;
while (1) {
DWORD dwSize = sizeof(buf);
if (WSALookupServiceNext (iterator->hLookup, LUP_RETURN_NAME | LUP_RETURN_ADDR, &dwSize, pwsaResults) != 0) {
s_errcode_t errcode = S_ERRNO;
if (errcode == WSA_E_NO_MORE || errcode == WSAENOMORE) {
break; // No more results.
}
SYSERROR (abstract->context, errcode);
return dc_socket_syserror(errcode);
}
if (pwsaResults->dwNumberOfCsAddrs == 0 ||
pwsaResults->lpcsaBuffer == NULL ||
pwsaResults->lpcsaBuffer->RemoteAddr.lpSockaddr == NULL) {
ERROR (abstract->context, "Invalid results returned");
return DC_STATUS_IO;
}
SOCKADDR_BTH *sa = (SOCKADDR_BTH *) pwsaResults->lpcsaBuffer->RemoteAddr.lpSockaddr;
dc_bluetooth_address_t address = sa->btAddr;
const char *name = (char *) pwsaResults->lpszServiceInstanceName;
#else
while (iterator->current < iterator->count) {
inquiry_info *dev = &iterator->devices[iterator->current++];
dc_bluetooth_address_t address = dc_address_get (&dev->bdaddr);
// Get the user friendly name.
char buf[HCI_MAX_NAME_LENGTH], *name = buf;
int rc = hci_read_remote_name (iterator->fd, &dev->bdaddr, sizeof(buf), buf, 0);
if (rc < 0) {
name = NULL;
}
// Null terminate the string.
buf[sizeof(buf) - 1] = '\0';
#endif
INFO (abstract->context, "Discover: address=" DC_ADDRESS_FORMAT ", name=%s",
address, name ? name : "");
if (iterator->filter && !iterator->filter (DC_TRANSPORT_BLUETOOTH, name)) {
continue;
}
device = (dc_bluetooth_device_t *) malloc (sizeof(dc_bluetooth_device_t));
if (device == NULL) {
SYSERROR (abstract->context, S_ENOMEM);
return DC_STATUS_NOMEMORY;
}
device->address = address;
if (name) {
strncpy(device->name, name, sizeof(device->name) - 1);
device->name[sizeof(device->name) - 1] = '\0';
} else {
memset(device->name, 0, sizeof(device->name));
}
*(dc_bluetooth_device_t **) out = device;
return DC_STATUS_SUCCESS;
}
return DC_STATUS_DONE;
}
static dc_status_t
dc_bluetooth_iterator_free (dc_iterator_t *abstract)
{
dc_bluetooth_iterator_t *iterator = (dc_bluetooth_iterator_t *) abstract;
#ifdef _WIN32
if (iterator->hLookup) {
WSALookupServiceEnd (iterator->hLookup);
}
#else
bt_free(iterator->devices);
hci_close_dev(iterator->fd);
#endif
return DC_STATUS_SUCCESS;
}
#endif
dc_status_t
dc_bluetooth_open (dc_iostream_t **out, dc_context_t *context, dc_bluetooth_address_t address, unsigned int port)
{
#ifdef BLUETOOTH
dc_status_t status = DC_STATUS_SUCCESS;
@ -204,6 +500,8 @@ dc_bluetooth_open (dc_iostream_t **out, dc_context_t *context)
if (out == NULL)
return DC_STATUS_INVALIDARGS;
INFO (context, "Open: address=" DC_ADDRESS_FORMAT ", port=%u", address, port);
// Allocate memory.
device = (dc_socket_t *) dc_iostream_allocate (context, &dc_bluetooth_vtable);
if (device == NULL) {
@ -221,164 +519,6 @@ dc_bluetooth_open (dc_iostream_t **out, dc_context_t *context)
goto error_free;
}
*out = (dc_iostream_t *) device;
return DC_STATUS_SUCCESS;
error_free:
dc_iostream_deallocate ((dc_iostream_t *) device);
return status;
#else
return DC_STATUS_UNSUPPORTED;
#endif
}
dc_status_t
dc_bluetooth_discover (dc_iostream_t *abstract, dc_bluetooth_callback_t callback, void *userdata)
{
#ifdef BLUETOOTH
dc_status_t status = DC_STATUS_SUCCESS;
if (!ISINSTANCE (abstract))
return DC_STATUS_INVALIDARGS;
#ifdef _WIN32
WSAQUERYSET wsaq;
memset(&wsaq, 0, sizeof (wsaq));
wsaq.dwSize = sizeof (wsaq);
wsaq.dwNameSpace = NS_BTH;
wsaq.lpcsaBuffer = NULL;
HANDLE hLookup;
if (WSALookupServiceBegin(&wsaq, LUP_CONTAINERS | LUP_FLUSHCACHE, &hLookup) != 0) {
s_errcode_t errcode = S_ERRNO;
if (errcode == WSASERVICE_NOT_FOUND) {
// No remote bluetooth devices found.
status = DC_STATUS_SUCCESS;
} else {
SYSERROR (abstract->context, errcode);
status = dc_socket_syserror(errcode);
}
goto error_exit;
}
unsigned char buf[4096];
LPWSAQUERYSET pwsaResults = (LPWSAQUERYSET) buf;
memset(pwsaResults, 0, sizeof(WSAQUERYSET));
pwsaResults->dwSize = sizeof(WSAQUERYSET);
pwsaResults->dwNameSpace = NS_BTH;
pwsaResults->lpBlob = NULL;
while (1) {
DWORD dwSize = sizeof(buf);
if (WSALookupServiceNext (hLookup, LUP_RETURN_NAME | LUP_RETURN_ADDR, &dwSize, pwsaResults) != 0) {
s_errcode_t errcode = S_ERRNO;
if (errcode == WSA_E_NO_MORE || errcode == WSAENOMORE) {
break; // No more results.
}
SYSERROR (abstract->context, errcode);
status = dc_socket_syserror(errcode);
goto error_close;
}
if (pwsaResults->dwNumberOfCsAddrs == 0 ||
pwsaResults->lpcsaBuffer == NULL ||
pwsaResults->lpcsaBuffer->RemoteAddr.lpSockaddr == NULL) {
ERROR (abstract->context, "Invalid results returned");
status = DC_STATUS_IO;
goto error_close;
}
SOCKADDR_BTH *sa = (SOCKADDR_BTH *) pwsaResults->lpcsaBuffer->RemoteAddr.lpSockaddr;
dc_bluetooth_address_t address = sa->btAddr;
const char *name = (char *) pwsaResults->lpszServiceInstanceName;
INFO (abstract->context, "Discover: address=" DC_ADDRESS_FORMAT ", name=%s", address, name);
if (callback) callback (address, name, userdata);
}
error_close:
WSALookupServiceEnd (hLookup);
#else
// Get the resource number for the first available bluetooth adapter.
int dev = hci_get_route (NULL);
if (dev < 0) {
s_errcode_t errcode = S_ERRNO;
SYSERROR (abstract->context, errcode);
status = dc_socket_syserror(errcode);
goto error_exit;
}
// Open a socket to the bluetooth adapter.
int fd = hci_open_dev (dev);
if (fd < 0) {
s_errcode_t errcode = S_ERRNO;
SYSERROR (abstract->context, errcode);
status = dc_socket_syserror(errcode);
goto error_exit;
}
// Allocate a buffer to store the results of the discovery.
inquiry_info *devices = (inquiry_info *) malloc (MAX_DEVICES * sizeof(inquiry_info));
if (devices == NULL) {
s_errcode_t errcode = S_ERRNO;
SYSERROR (abstract->context, errcode);
status = dc_socket_syserror(errcode);
goto error_close;
}
// Perform the bluetooth device discovery. The inquiry lasts for at
// most MAX_PERIODS * 1.28 seconds, and at most MAX_DEVICES devices
// will be returned.
int ndevices = hci_inquiry (dev, MAX_PERIODS, MAX_DEVICES, NULL, &devices, IREQ_CACHE_FLUSH);
if (ndevices < 0) {
s_errcode_t errcode = S_ERRNO;
SYSERROR (abstract->context, errcode);
status = dc_socket_syserror(errcode);
goto error_free;
}
for (unsigned int i = 0; i < ndevices; ++i) {
dc_bluetooth_address_t address = dc_address_get (&devices[i].bdaddr);
// Get the user friendly name.
char buf[HCI_MAX_NAME_LENGTH], *name = buf;
int rc = hci_read_remote_name (fd, &devices[i].bdaddr, sizeof(buf), buf, 0);
if (rc < 0) {
name = NULL;
}
INFO (abstract->context, "Discover: address=" DC_ADDRESS_FORMAT ", name=%s", address, name);
if (callback) callback (address, name, userdata);
}
error_free:
free(devices);
error_close:
hci_close_dev(fd);
#endif
error_exit:
return status;
#else
return DC_STATUS_UNSUPPORTED;
#endif
}
dc_status_t
dc_bluetooth_connect (dc_iostream_t *abstract, dc_bluetooth_address_t address, unsigned int port)
{
#ifdef BLUETOOTH
dc_socket_t *device = (dc_socket_t *) abstract;
if (!ISINSTANCE (abstract))
return DC_STATUS_INVALIDARGS;
INFO (abstract->context, "Connect: address=" DC_ADDRESS_FORMAT ", port=%d", address, port);
#ifdef _WIN32
SOCKADDR_BTH sa;
sa.addressFamily = AF_BTH;
@ -394,16 +534,29 @@ dc_bluetooth_connect (dc_iostream_t *abstract, dc_bluetooth_address_t address, u
sa.rc_family = AF_BLUETOOTH;
dc_address_set (&sa.rc_bdaddr, address);
if (port == 0) {
dc_status_t rc = dc_bluetooth_sdp (&sa.rc_channel, abstract->context, &sa.rc_bdaddr);
if (rc != DC_STATUS_SUCCESS) {
return rc;
status = dc_bluetooth_sdp (&sa.rc_channel, context, &sa.rc_bdaddr);
if (status != DC_STATUS_SUCCESS) {
goto error_close;
}
} else {
sa.rc_channel = port;
}
#endif
return dc_socket_connect (&device->base, (struct sockaddr *) &sa, sizeof (sa));
status = dc_socket_connect (&device->base, (struct sockaddr *) &sa, sizeof (sa));
if (status != DC_STATUS_SUCCESS) {
goto error_close;
}
*out = (dc_iostream_t *) device;
return DC_STATUS_SUCCESS;
error_close:
dc_socket_close (&device->base);
error_free:
dc_iostream_deallocate ((dc_iostream_t *) device);
return status;
#else
return DC_STATUS_UNSUPPORTED;
#endif

102
src/bluetooth.h
View File

@ -25,11 +25,19 @@
#include <libdivecomputer/common.h>
#include <libdivecomputer/context.h>
#include <libdivecomputer/iostream.h>
#include <libdivecomputer/iterator.h>
#include <libdivecomputer/descriptor.h>
#ifdef __cplusplus
extern "C" {
#endif /* __cplusplus */
/**
* The minimum number of bytes (including the terminating null byte) for
* formatting a bluetooth address as a string.
*/
#define DC_BLUETOOTH_SIZE 18
/**
* Bluetooth address (48 bits).
*/
@ -40,48 +48,86 @@ typedef unsigned long long dc_bluetooth_address_t;
#endif
/**
* Bluetooth enumeration callback.
* Convert a bluetooth address to a string.
*
* @param[in] address The bluetooth device address.
* @param[in] name The bluetooth device name.
* @param[in] userdata The user data pointer.
* The bluetooth address is formatted as XX:XX:XX:XX:XX:XX, where each
* XX is a hexadecimal number specifying an octet of the 48-bit address.
* The minimum size for the buffer is #DC_BLUETOOTH_SIZE bytes.
*
* @param[in] address A bluetooth address.
* @param[in] str The memory buffer to store the result.
* @param[in] size The size of the memory buffer.
* @returns The null-terminated string on success, or NULL on failure.
*/
typedef void (*dc_bluetooth_callback_t) (dc_bluetooth_address_t address, const char *name, void *userdata);
char *
dc_bluetooth_addr2str(dc_bluetooth_address_t address, char *str, size_t size);
/**
* Convert a string to a bluetooth address.
*
* The string is expected to be in the format XX:XX:XX:XX:XX:XX, where
* each XX is a hexadecimal number specifying an octet of the 48-bit
* address.
*
* @param[in] address A null-terminated string.
* @returns The bluetooth address on success, or zero on failure.
*/
dc_bluetooth_address_t
dc_bluetooth_str2addr(const char *address);
/**
* Opaque object representing a bluetooth device.
*/
typedef struct dc_bluetooth_device_t dc_bluetooth_device_t;
/**
* Get the address of the bluetooth device.
*
* @param[in] device A valid bluetooth device.
*/
dc_bluetooth_address_t
dc_bluetooth_device_get_address (dc_bluetooth_device_t *device);
/**
* Get the name of the bluetooth device.
*
* @param[in] device A valid bluetooth device.
*/
const char *
dc_bluetooth_device_get_name (dc_bluetooth_device_t *device);
/**
* Destroy the bluetooth device and free all resources.
*
* @param[in] device A valid bluetooth device.
*/
void
dc_bluetooth_device_free (dc_bluetooth_device_t *device);
/**
* Create an iterator to enumerate the bluetooth devices.
*
* @param[out] iterator A location to store the iterator.
* @param[in] context A valid context object.
* @param[in] descriptor A valid device descriptor or NULL.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_bluetooth_iterator_new (dc_iterator_t **iterator, dc_context_t *context, dc_descriptor_t *descriptor);
/**
* Open an bluetooth connection.
*
* @param[out] iostream A location to store the bluetooth connection.
* @param[in] context A valid context object.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_bluetooth_open (dc_iostream_t **iostream, dc_context_t *context);
/**
* Enumerate the bluetooth devices.
*
* @param[in] iostream A valid bluetooth connection.
* @param[in] callback The callback function to call.
* @param[in] userdata User data to pass to the callback function.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_bluetooth_discover (dc_iostream_t *iostream, dc_bluetooth_callback_t callback, void *userdata);
/**
* Connect to an bluetooth device.
*
* @param[in] iostream A valid bluetooth connection.
* @param[in] address The bluetooth device address.
* @param[in] port The bluetooth port number.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_bluetooth_connect (dc_iostream_t *iostream, dc_bluetooth_address_t address, unsigned int port);
dc_bluetooth_open (dc_iostream_t **iostream, dc_context_t *context, dc_bluetooth_address_t address, unsigned int port);
#ifdef __cplusplus
}

42
src/context.c
View File

@ -27,11 +27,11 @@
#ifdef _WIN32
#define NOGDI
#include <windows.h>
#else
#include <sys/time.h>
#endif
#include "context-private.h"
#include "timer.h"
#include <libdivecomputer/custom_io.h>
struct dc_context_t {
@ -40,11 +40,7 @@ struct dc_context_t {
void *userdata;
#ifdef ENABLE_LOGGING
char msg[8192 + 32];
#ifdef _WIN32
LARGE_INTEGER timestamp, frequency;
#else
struct timeval timestamp;
#endif
dc_timer_t *timer;
#endif
dc_custom_io_t *custom_io;
dc_user_device_t *user_device;
@ -137,23 +133,11 @@ logfunc (dc_context_t *context, dc_loglevel_t loglevel, const char *file, unsign
{
const char *loglevels[] = {"NONE", "ERROR", "WARNING", "INFO", "DEBUG", "ALL"};
unsigned long seconds = 0, microseconds = 0;
dc_usecs_t now = 0;
dc_timer_now (context->timer, &now);
#ifdef _WIN32
LARGE_INTEGER now, delta;
QueryPerformanceCounter(&now);
delta.QuadPart = now.QuadPart - context->timestamp.QuadPart;
delta.QuadPart *= 1000000;
delta.QuadPart /= context->frequency.QuadPart;
seconds = delta.QuadPart / 1000000;
microseconds = delta.QuadPart % 1000000;
#else
struct timeval now, delta;
gettimeofday (&now, NULL);
timersub (&now, &context->timestamp, &delta);
seconds = delta.tv_sec;
microseconds = delta.tv_usec;
#endif
unsigned long seconds = now / 1000000;
unsigned long microseconds = now % 1000000;
if (loglevel == DC_LOGLEVEL_ERROR || loglevel == DC_LOGLEVEL_WARNING) {
fprintf (stderr, "[%li.%06li] %s: %s [in %s:%d (%s)]\n",
@ -190,12 +174,8 @@ dc_context_new (dc_context_t **out)
#ifdef ENABLE_LOGGING
memset (context->msg, 0, sizeof (context->msg));
#ifdef _WIN32
QueryPerformanceFrequency(&context->frequency);
QueryPerformanceCounter(&context->timestamp);
#else
gettimeofday (&context->timestamp, NULL);
#endif
context->timer = NULL;
dc_timer_new (&context->timer);
#endif
context->custom_io = NULL;
@ -208,6 +188,10 @@ dc_context_new (dc_context_t **out)
dc_status_t
dc_context_free (dc_context_t *context)
{
if (context == NULL)
return DC_STATUS_SUCCESS;
dc_timer_free (context->timer);
free (context);
return DC_STATUS_SUCCESS;

13
src/custom.c
View File

@ -29,7 +29,6 @@
static dc_status_t dc_custom_set_timeout (dc_iostream_t *abstract, int timeout);
static dc_status_t dc_custom_set_latency (dc_iostream_t *abstract, unsigned int value);
static dc_status_t dc_custom_set_halfduplex (dc_iostream_t *abstract, unsigned int value);
static dc_status_t dc_custom_set_break (dc_iostream_t *abstract, unsigned int value);
static dc_status_t dc_custom_set_dtr (dc_iostream_t *abstract, unsigned int value);
static dc_status_t dc_custom_set_rts (dc_iostream_t *abstract, unsigned int value);
@ -55,7 +54,6 @@ static const dc_iostream_vtable_t dc_custom_vtable = {
sizeof(dc_custom_t),
dc_custom_set_timeout, /* set_timeout */
dc_custom_set_latency, /* set_latency */
dc_custom_set_halfduplex, /* set_halfduplex */
dc_custom_set_break, /* set_break */
dc_custom_set_dtr, /* set_dtr */
dc_custom_set_rts, /* set_rts */
@ -117,17 +115,6 @@ dc_custom_set_latency (dc_iostream_t *abstract, unsigned int value)
return custom->callbacks.set_latency (custom->userdata, value);
}
static dc_status_t
dc_custom_set_halfduplex (dc_iostream_t *abstract, unsigned int value)
{
dc_custom_t *custom = (dc_custom_t *) abstract;
if (custom->callbacks.set_halfduplex == NULL)
return DC_STATUS_UNSUPPORTED;
return custom->callbacks.set_halfduplex (custom->userdata, value);
}
static dc_status_t
dc_custom_set_break (dc_iostream_t *abstract, unsigned int value)
{

1
src/custom.h
View File

@ -33,7 +33,6 @@ extern "C" {
typedef struct dc_custom_cbs_t {
dc_status_t (*set_timeout) (void *userdata, int timeout);
dc_status_t (*set_latency) (void *userdata, unsigned int value);
dc_status_t (*set_halfduplex) (void *userdata, unsigned int value);
dc_status_t (*set_break) (void *userdata, unsigned int value);
dc_status_t (*set_dtr) (void *userdata, unsigned int value);
dc_status_t (*set_rts) (void *userdata, unsigned int value);

13
src/custom_io.c
View File

@ -56,18 +56,6 @@ dc_custom_set_latency (dc_iostream_t *abstract, unsigned int value)
return DC_STATUS_SUCCESS;
}
static dc_status_t
dc_custom_set_halfduplex (dc_iostream_t *abstract, unsigned int value)
{
dc_custom_t *custom = (dc_custom_t *) abstract;
dc_custom_io_t *io = _dc_context_custom_io(custom->context);
if (!io->serial_set_halfduplex)
return DC_STATUS_SUCCESS;
return io->serial_set_halfduplex(io, value);
}
static dc_status_t
dc_custom_set_break (dc_iostream_t *abstract, unsigned int value)
{
@ -198,7 +186,6 @@ static const dc_iostream_vtable_t dc_custom_vtable = {
sizeof(dc_custom_t),
dc_custom_set_timeout, /* set_timeout */
dc_custom_set_latency, /* set_latency */
dc_custom_set_halfduplex, /* set_halfduplex */
dc_custom_set_break, /* set_break */
dc_custom_set_dtr, /* set_dtr */
dc_custom_set_rts, /* set_rts */

44
src/descriptor-private.h Normal file
View File

@ -0,0 +1,44 @@
/*
* libdivecomputer
*
* Copyright (C) 2017 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
*/
#ifndef DC_DESCRIPTOR_PRIVATE_H
#define DC_DESCRIPTOR_PRIVATE_H
#include <libdivecomputer/descriptor.h>
#ifdef __cplusplus
extern "C" {
#endif /* __cplusplus */
typedef struct dc_usb_desc_t {
unsigned short vid;
unsigned short pid;
} dc_usb_desc_t;
typedef int (*dc_filter_t) (dc_transport_t transport, const void *userdata);
dc_filter_t
dc_descriptor_get_filter (dc_descriptor_t *descriptor);
#ifdef __cplusplus
}
#endif /* __cplusplus */
#endif /* DC_DESCRIPTOR_PRIVATE_H */

616
src/descriptor.c
View File

@ -41,19 +41,38 @@
#include <stddef.h>
#include <stdlib.h>
#include <string.h>
#include <libdivecomputer/descriptor.h>
#include "descriptor-private.h"
#include "iterator-private.h"
#include "platform.h"
#define C_ARRAY_SIZE(array) (sizeof (array) / sizeof *(array))
static int dc_filter_uwatec (dc_transport_t transport, const void *userdata);
static int dc_filter_suunto (dc_transport_t transport, const void *userdata);
static int dc_filter_shearwater (dc_transport_t transport, const void *userdata);
static int dc_filter_hw (dc_transport_t transport, const void *userdata);
static dc_status_t dc_descriptor_iterator_next (dc_iterator_t *iterator, void *item);
struct dc_descriptor_t {
const char *vendor;
const char *product;
dc_family_t type;
unsigned int model;
unsigned int serial;
dc_filter_t filter;
};
typedef struct dc_descriptor_iterator_t {
dc_iterator_t base;
size_t current;
} dc_descriptor_iterator_t;
static const dc_iterator_vtable_t dc_descriptor_iterator_vtable = {
sizeof(dc_descriptor_iterator_t),
dc_descriptor_iterator_next,
NULL,
};
/*
@ -65,285 +84,369 @@ struct dc_descriptor_t {
static const dc_descriptor_t g_descriptors[] = {
/* Suunto Solution */
{"Suunto", "Solution", DC_FAMILY_SUUNTO_SOLUTION, 0}, // FTDI
{"Suunto", "Solution", DC_FAMILY_SUUNTO_SOLUTION, 0, NULL},
/* Suunto Eon */
{"Suunto", "Eon", DC_FAMILY_SUUNTO_EON, 0}, // FTDI
{"Suunto", "Solution Alpha", DC_FAMILY_SUUNTO_EON, 0}, // FTDI
{"Suunto", "Solution Nitrox", DC_FAMILY_SUUNTO_EON, 0}, // FTDI
{"Suunto", "Eon", DC_FAMILY_SUUNTO_EON, 0, NULL},
{"Suunto", "Solution Alpha", DC_FAMILY_SUUNTO_EON, 0, NULL},
{"Suunto", "Solution Nitrox", DC_FAMILY_SUUNTO_EON, 0, NULL},
/* Suunto Vyper */
{"Suunto", "Spyder", DC_FAMILY_SUUNTO_VYPER, 0x01}, // FTDI
{"Suunto", "Stinger", DC_FAMILY_SUUNTO_VYPER, 0x03}, // FTDI
{"Suunto", "Mosquito", DC_FAMILY_SUUNTO_VYPER, 0x04}, // FTDI
{"Suunto", "D3", DC_FAMILY_SUUNTO_VYPER, 0x05}, // FTDI
{"Suunto", "Vyper", DC_FAMILY_SUUNTO_VYPER, 0x0A}, // FTDI
{"Suunto", "Vytec", DC_FAMILY_SUUNTO_VYPER, 0X0B}, // FTDI
{"Suunto", "Cobra", DC_FAMILY_SUUNTO_VYPER, 0X0C}, // FTDI
{"Suunto", "Gekko", DC_FAMILY_SUUNTO_VYPER, 0X0D}, // FTDI
{"Suunto", "Zoop", DC_FAMILY_SUUNTO_VYPER, 0x16}, // FTDI
{"Suunto", "Spyder", DC_FAMILY_SUUNTO_VYPER, 0x01, NULL},
{"Suunto", "Stinger", DC_FAMILY_SUUNTO_VYPER, 0x03, NULL},
{"Suunto", "Mosquito", DC_FAMILY_SUUNTO_VYPER, 0x04, NULL},
{"Suunto", "D3", DC_FAMILY_SUUNTO_VYPER, 0x05, NULL},
{"Suunto", "Vyper", DC_FAMILY_SUUNTO_VYPER, 0x0A, NULL},
{"Suunto", "Vytec", DC_FAMILY_SUUNTO_VYPER, 0X0B, NULL},
{"Suunto", "Cobra", DC_FAMILY_SUUNTO_VYPER, 0X0C, NULL},
{"Suunto", "Gekko", DC_FAMILY_SUUNTO_VYPER, 0X0D, NULL},
{"Suunto", "Zoop", DC_FAMILY_SUUNTO_VYPER, 0x16, NULL},
/* Suunto Vyper 2 */
{"Suunto", "Vyper 2", DC_FAMILY_SUUNTO_VYPER2, 0x10}, // FTDI
{"Suunto", "Cobra 2", DC_FAMILY_SUUNTO_VYPER2, 0x11}, // FTDI
{"Suunto", "Vyper Air", DC_FAMILY_SUUNTO_VYPER2, 0x13}, // FTDI
{"Suunto", "Cobra 3", DC_FAMILY_SUUNTO_VYPER2, 0x14}, // FTDI
{"Suunto", "HelO2", DC_FAMILY_SUUNTO_VYPER2, 0x15}, // FTDI
{"Suunto", "Vyper 2", DC_FAMILY_SUUNTO_VYPER2, 0x10, NULL},
{"Suunto", "Cobra 2", DC_FAMILY_SUUNTO_VYPER2, 0x11, NULL},
{"Suunto", "Vyper Air", DC_FAMILY_SUUNTO_VYPER2, 0x13, NULL},
{"Suunto", "Cobra 3", DC_FAMILY_SUUNTO_VYPER2, 0x14, NULL},
{"Suunto", "HelO2", DC_FAMILY_SUUNTO_VYPER2, 0x15, NULL},
/* Suunto D9 */
{"Suunto", "D9", DC_FAMILY_SUUNTO_D9, 0x0E}, // FTDI
{"Suunto", "D6", DC_FAMILY_SUUNTO_D9, 0x0F}, // FTDI
{"Suunto", "D4", DC_FAMILY_SUUNTO_D9, 0x12}, // FTDI
{"Suunto", "D4i", DC_FAMILY_SUUNTO_D9, 0x19}, // FTDI
{"Suunto", "D6i", DC_FAMILY_SUUNTO_D9, 0x1A}, // FTDI
{"Suunto", "D9tx", DC_FAMILY_SUUNTO_D9, 0x1B}, // FTDI
{"Suunto", "DX", DC_FAMILY_SUUNTO_D9, 0x1C}, // FTDI
{"Suunto", "Vyper Novo", DC_FAMILY_SUUNTO_D9, 0x1D}, // FTDI
{"Suunto", "Zoop Novo", DC_FAMILY_SUUNTO_D9, 0x1E}, // FTDI
{"Suunto", "D4f", DC_FAMILY_SUUNTO_D9, 0x20}, // FTDI
{"Suunto", "D9", DC_FAMILY_SUUNTO_D9, 0x0E, NULL},
{"Suunto", "D6", DC_FAMILY_SUUNTO_D9, 0x0F, NULL},
{"Suunto", "D4", DC_FAMILY_SUUNTO_D9, 0x12, NULL},
{"Suunto", "D4i", DC_FAMILY_SUUNTO_D9, 0x19, NULL},
{"Suunto", "D6i", DC_FAMILY_SUUNTO_D9, 0x1A, NULL},
{"Suunto", "D9tx", DC_FAMILY_SUUNTO_D9, 0x1B, NULL},
{"Suunto", "DX", DC_FAMILY_SUUNTO_D9, 0x1C, NULL},
{"Suunto", "Vyper Novo", DC_FAMILY_SUUNTO_D9, 0x1D, NULL},
{"Suunto", "Zoop Novo", DC_FAMILY_SUUNTO_D9, 0x1E, NULL},
{"Suunto", "D4f", DC_FAMILY_SUUNTO_D9, 0x20, NULL},
/* Suunto EON Steel */
#if defined(USBHID) || defined(ENABLE_BLE)
{"Suunto", "EON Steel", DC_FAMILY_SUUNTO_EONSTEEL, 0}, // BLE
{"Suunto", "EON Core", DC_FAMILY_SUUNTO_EONSTEEL, 1}, // BLE
{"Suunto", "EON Steel", DC_FAMILY_SUUNTO_EONSTEEL, 0, dc_filter_suunto},
{"Suunto", "EON Core", DC_FAMILY_SUUNTO_EONSTEEL, 1, dc_filter_suunto},
#endif
/* Uwatec Aladin */
{"Uwatec", "Aladin Air Twin", DC_FAMILY_UWATEC_ALADIN, 0x1C}, // FTDI
{"Uwatec", "Aladin Sport Plus", DC_FAMILY_UWATEC_ALADIN, 0x3E}, // FTDI
{"Uwatec", "Aladin Pro", DC_FAMILY_UWATEC_ALADIN, 0x3F}, // FTDI
{"Uwatec", "Aladin Air Z", DC_FAMILY_UWATEC_ALADIN, 0x44}, // FTDI
{"Uwatec", "Aladin Air Z O2", DC_FAMILY_UWATEC_ALADIN, 0xA4}, // FTDI
{"Uwatec", "Aladin Air Z Nitrox", DC_FAMILY_UWATEC_ALADIN, 0xF4}, // FTDI
{"Uwatec", "Aladin Pro Ultra", DC_FAMILY_UWATEC_ALADIN, 0xFF}, // FTDI
{"Uwatec", "Aladin Air Twin", DC_FAMILY_UWATEC_ALADIN, 0x1C, NULL},
{"Uwatec", "Aladin Sport Plus", DC_FAMILY_UWATEC_ALADIN, 0x3E, NULL},
{"Uwatec", "Aladin Pro", DC_FAMILY_UWATEC_ALADIN, 0x3F, NULL},
{"Uwatec", "Aladin Air Z", DC_FAMILY_UWATEC_ALADIN, 0x44, NULL},
{"Uwatec", "Aladin Air Z O2", DC_FAMILY_UWATEC_ALADIN, 0xA4, NULL},
{"Uwatec", "Aladin Air Z Nitrox", DC_FAMILY_UWATEC_ALADIN, 0xF4, NULL},
{"Uwatec", "Aladin Pro Ultra", DC_FAMILY_UWATEC_ALADIN, 0xFF, NULL},
/* Uwatec Memomouse */
{"Uwatec", "Memomouse", DC_FAMILY_UWATEC_MEMOMOUSE, 0}, // FTDI
{"Uwatec", "Memomouse", DC_FAMILY_UWATEC_MEMOMOUSE, 0, NULL},
/* Uwatec Smart */
#ifdef IRDA
{"Uwatec", "Smart Pro", DC_FAMILY_UWATEC_SMART, 0x10},
{"Uwatec", "Galileo Sol", DC_FAMILY_UWATEC_SMART, 0x11},
{"Uwatec", "Galileo Luna", DC_FAMILY_UWATEC_SMART, 0x11},
{"Uwatec", "Galileo Terra", DC_FAMILY_UWATEC_SMART, 0x11},
{"Uwatec", "Aladin Tec", DC_FAMILY_UWATEC_SMART, 0x12},
{"Uwatec", "Aladin Prime", DC_FAMILY_UWATEC_SMART, 0x12},
{"Uwatec", "Aladin Tec 2G", DC_FAMILY_UWATEC_SMART, 0x13},
{"Uwatec", "Aladin 2G", DC_FAMILY_UWATEC_SMART, 0x13},
{"Subgear","XP-10", DC_FAMILY_UWATEC_SMART, 0x13},
{"Uwatec", "Smart Com", DC_FAMILY_UWATEC_SMART, 0x14},
{"Uwatec", "Aladin 2G", DC_FAMILY_UWATEC_SMART, 0x15},
{"Uwatec", "Aladin Tec 3G", DC_FAMILY_UWATEC_SMART, 0x15},
{"Uwatec", "Aladin Sport", DC_FAMILY_UWATEC_SMART, 0x15},
{"Subgear","XP-3G", DC_FAMILY_UWATEC_SMART, 0x15},
{"Uwatec", "Smart Tec", DC_FAMILY_UWATEC_SMART, 0x18},
{"Uwatec", "Galileo Trimix",DC_FAMILY_UWATEC_SMART, 0x19},
{"Uwatec", "Smart Z", DC_FAMILY_UWATEC_SMART, 0x1C},
{"Subgear","XP Air", DC_FAMILY_UWATEC_SMART, 0x1C},
{"Uwatec", "Smart Pro", DC_FAMILY_UWATEC_SMART, 0x10, dc_filter_uwatec},
{"Uwatec", "Galileo Sol", DC_FAMILY_UWATEC_SMART, 0x11, dc_filter_uwatec},
{"Uwatec", "Galileo Luna", DC_FAMILY_UWATEC_SMART, 0x11, dc_filter_uwatec},
{"Uwatec", "Galileo Terra", DC_FAMILY_UWATEC_SMART, 0x11, dc_filter_uwatec},
{"Uwatec", "Aladin Tec", DC_FAMILY_UWATEC_SMART, 0x12, dc_filter_uwatec},
{"Uwatec", "Aladin Prime", DC_FAMILY_UWATEC_SMART, 0x12, dc_filter_uwatec},
{"Uwatec", "Aladin Tec 2G", DC_FAMILY_UWATEC_SMART, 0x13, dc_filter_uwatec},
{"Uwatec", "Aladin 2G", DC_FAMILY_UWATEC_SMART, 0x13, dc_filter_uwatec},
{"Subgear","XP-10", DC_FAMILY_UWATEC_SMART, 0x13, dc_filter_uwatec},
{"Uwatec", "Smart Com", DC_FAMILY_UWATEC_SMART, 0x14, dc_filter_uwatec},
{"Uwatec", "Aladin 2G", DC_FAMILY_UWATEC_SMART, 0x15, dc_filter_uwatec},
{"Uwatec", "Aladin Tec 3G", DC_FAMILY_UWATEC_SMART, 0x15, dc_filter_uwatec},
{"Uwatec", "Aladin Sport", DC_FAMILY_UWATEC_SMART, 0x15, dc_filter_uwatec},
{"Subgear","XP-3G", DC_FAMILY_UWATEC_SMART, 0x15, dc_filter_uwatec},
{"Uwatec", "Smart Tec", DC_FAMILY_UWATEC_SMART, 0x18, dc_filter_uwatec},
{"Uwatec", "Galileo Trimix",DC_FAMILY_UWATEC_SMART, 0x19, dc_filter_uwatec},
{"Uwatec", "Smart Z", DC_FAMILY_UWATEC_SMART, 0x1C, dc_filter_uwatec},
{"Subgear","XP Air", DC_FAMILY_UWATEC_SMART, 0x1C, dc_filter_uwatec},
#endif
/* Scubapro/Uwatec Meridian */
{"Scubapro", "Meridian", DC_FAMILY_UWATEC_MERIDIAN, 0x20},
{"Scubapro", "Mantis", DC_FAMILY_UWATEC_MERIDIAN, 0x20},
{"Scubapro", "Chromis", DC_FAMILY_UWATEC_MERIDIAN, 0x24},
{"Scubapro", "Mantis 2", DC_FAMILY_UWATEC_MERIDIAN, 0x26},
{"Scubapro", "Meridian", DC_FAMILY_UWATEC_MERIDIAN, 0x20, NULL},
{"Scubapro", "Mantis", DC_FAMILY_UWATEC_MERIDIAN, 0x20, NULL},
{"Scubapro", "Chromis", DC_FAMILY_UWATEC_MERIDIAN, 0x24, NULL},
{"Scubapro", "Mantis 2", DC_FAMILY_UWATEC_MERIDIAN, 0x26, NULL},
/* Scubapro G2 */
#if defined(USBHID) || defined(ENABLE_BLE)
{"Scubapro", "Aladin Sport Matrix", DC_FAMILY_UWATEC_G2, 0x17}, // BLE
{"Scubapro", "Aladin Square", DC_FAMILY_UWATEC_G2, 0x22},
{"Scubapro", "G2", DC_FAMILY_UWATEC_G2, 0x32}, // BLE
{"Scubapro", "Aladin Sport Matrix", DC_FAMILY_UWATEC_G2, 0x17, dc_filter_uwatec},
{"Scubapro", "Aladin Square", DC_FAMILY_UWATEC_G2, 0x22, dc_filter_uwatec},
{"Scubapro", "G2", DC_FAMILY_UWATEC_G2, 0x32, dc_filter_uwatec},
#endif
/* Reefnet */
{"Reefnet", "Sensus", DC_FAMILY_REEFNET_SENSUS, 1},
{"Reefnet", "Sensus Pro", DC_FAMILY_REEFNET_SENSUSPRO, 2},
{"Reefnet", "Sensus Ultra", DC_FAMILY_REEFNET_SENSUSULTRA, 3},
{"Reefnet", "Sensus", DC_FAMILY_REEFNET_SENSUS, 1, NULL},
{"Reefnet", "Sensus Pro", DC_FAMILY_REEFNET_SENSUSPRO, 2, NULL},
{"Reefnet", "Sensus Ultra", DC_FAMILY_REEFNET_SENSUSULTRA, 3, NULL},
/* Oceanic VT Pro */
{"Aeris", "500 AI", DC_FAMILY_OCEANIC_VTPRO, 0x4151}, // FTDI
{"Oceanic", "Versa Pro", DC_FAMILY_OCEANIC_VTPRO, 0x4155}, // FTDI
{"Aeris", "Atmos 2", DC_FAMILY_OCEANIC_VTPRO, 0x4158}, // FTDI
{"Oceanic", "Pro Plus 2", DC_FAMILY_OCEANIC_VTPRO, 0x4159}, // FTDI
{"Aeris", "Atmos AI", DC_FAMILY_OCEANIC_VTPRO, 0x4244}, // FTDI
{"Oceanic", "VT Pro", DC_FAMILY_OCEANIC_VTPRO, 0x4245}, // FTDI
{"Sherwood", "Wisdom", DC_FAMILY_OCEANIC_VTPRO, 0x4246}, // FTDI
{"Aeris", "Elite", DC_FAMILY_OCEANIC_VTPRO, 0x424F}, // FTDI
{"Aeris", "500 AI", DC_FAMILY_OCEANIC_VTPRO, 0x4151, NULL},
{"Oceanic", "Versa Pro", DC_FAMILY_OCEANIC_VTPRO, 0x4155, NULL},
{"Aeris", "Atmos 2", DC_FAMILY_OCEANIC_VTPRO, 0x4158, NULL},
{"Oceanic", "Pro Plus 2", DC_FAMILY_OCEANIC_VTPRO, 0x4159, NULL},
{"Aeris", "Atmos AI", DC_FAMILY_OCEANIC_VTPRO, 0x4244, NULL},
{"Oceanic", "VT Pro", DC_FAMILY_OCEANIC_VTPRO, 0x4245, NULL},
{"Sherwood", "Wisdom", DC_FAMILY_OCEANIC_VTPRO, 0x4246, NULL},
{"Aeris", "Elite", DC_FAMILY_OCEANIC_VTPRO, 0x424F, NULL},
/* Oceanic Veo 250 */
{"Genesis", "React Pro", DC_FAMILY_OCEANIC_VEO250, 0x4247}, // FTDI
{"Oceanic", "Veo 200", DC_FAMILY_OCEANIC_VEO250, 0x424B}, // FTDI
{"Oceanic", "Veo 250", DC_FAMILY_OCEANIC_VEO250, 0x424C}, // FTDI
{"Seemann", "XP5", DC_FAMILY_OCEANIC_VEO250, 0x4251}, // FTDI
{"Oceanic", "Veo 180", DC_FAMILY_OCEANIC_VEO250, 0x4252}, // FTDI
{"Aeris", "XR-2", DC_FAMILY_OCEANIC_VEO250, 0x4255}, // FTDI
{"Sherwood", "Insight", DC_FAMILY_OCEANIC_VEO250, 0x425A}, // FTDI
{"Hollis", "DG02", DC_FAMILY_OCEANIC_VEO250, 0x4352}, // FTDI
{"Genesis", "React Pro", DC_FAMILY_OCEANIC_VEO250, 0x4247, NULL},
{"Oceanic", "Veo 200", DC_FAMILY_OCEANIC_VEO250, 0x424B, NULL},
{"Oceanic", "Veo 250", DC_FAMILY_OCEANIC_VEO250, 0x424C, NULL},
{"Seemann", "XP5", DC_FAMILY_OCEANIC_VEO250, 0x4251, NULL},
{"Oceanic", "Veo 180", DC_FAMILY_OCEANIC_VEO250, 0x4252, NULL},
{"Aeris", "XR-2", DC_FAMILY_OCEANIC_VEO250, 0x4255, NULL},
{"Sherwood", "Insight", DC_FAMILY_OCEANIC_VEO250, 0x425A, NULL},
{"Hollis", "DG02", DC_FAMILY_OCEANIC_VEO250, 0x4352, NULL},
/* Oceanic Atom 2.0 */
{"Oceanic", "Atom 1.0", DC_FAMILY_OCEANIC_ATOM2, 0x4250}, // FTDI
{"Aeris", "Epic", DC_FAMILY_OCEANIC_ATOM2, 0x4257}, // FTDI
{"Oceanic", "VT3", DC_FAMILY_OCEANIC_ATOM2, 0x4258}, // FTDI
{"Aeris", "Elite T3", DC_FAMILY_OCEANIC_ATOM2, 0x4259}, // FTDI
{"Oceanic", "Atom 2.0", DC_FAMILY_OCEANIC_ATOM2, 0x4342}, // FTDI
{"Oceanic", "Geo", DC_FAMILY_OCEANIC_ATOM2, 0x4344}, // FTDI
{"Aeris", "Manta", DC_FAMILY_OCEANIC_ATOM2, 0x4345}, // FTDI
{"Aeris", "XR-1 NX", DC_FAMILY_OCEANIC_ATOM2, 0x4346}, // FTDI
{"Oceanic", "Datamask", DC_FAMILY_OCEANIC_ATOM2, 0x4347}, // FTDI
{"Aeris", "Compumask", DC_FAMILY_OCEANIC_ATOM2, 0x4348}, // FTDI
{"Aeris", "F10", DC_FAMILY_OCEANIC_ATOM2, 0x434D}, // FTDI
{"Oceanic", "OC1", DC_FAMILY_OCEANIC_ATOM2, 0x434E}, // FTDI
{"Sherwood", "Wisdom 2", DC_FAMILY_OCEANIC_ATOM2, 0x4350}, // FTDI
{"Sherwood", "Insight 2", DC_FAMILY_OCEANIC_ATOM2, 0x4353}, // FTDI
{"Genesis", "React Pro White", DC_FAMILY_OCEANIC_ATOM2, 0x4354}, // FTDI
{"Tusa", "Element II (IQ-750)", DC_FAMILY_OCEANIC_ATOM2, 0x4357}, // FTDI
{"Oceanic", "Veo 1.0", DC_FAMILY_OCEANIC_ATOM2, 0x4358}, // FTDI
{"Oceanic", "Veo 2.0", DC_FAMILY_OCEANIC_ATOM2, 0x4359}, // FTDI
{"Oceanic", "Veo 3.0", DC_FAMILY_OCEANIC_ATOM2, 0x435A}, // FTDI
{"Tusa", "Zen (IQ-900)", DC_FAMILY_OCEANIC_ATOM2, 0x4441}, // FTDI
{"Tusa", "Zen Air (IQ-950)", DC_FAMILY_OCEANIC_ATOM2, 0x4442}, // FTDI
{"Aeris", "Atmos AI 2", DC_FAMILY_OCEANIC_ATOM2, 0x4443}, // FTDI
{"Oceanic", "Pro Plus 2.1", DC_FAMILY_OCEANIC_ATOM2, 0x4444}, // FTDI
{"Oceanic", "Geo 2.0", DC_FAMILY_OCEANIC_ATOM2, 0x4446}, // FTDI
{"Oceanic", "VT4", DC_FAMILY_OCEANIC_ATOM2, 0x4447}, // FTDI
{"Oceanic", "OC1", DC_FAMILY_OCEANIC_ATOM2, 0x4449}, // FTDI
{"Beuchat", "Voyager 2G", DC_FAMILY_OCEANIC_ATOM2, 0x444B}, // FTDI
{"Oceanic", "Atom 3.0", DC_FAMILY_OCEANIC_ATOM2, 0x444C}, // FTDI
{"Hollis", "DG03", DC_FAMILY_OCEANIC_ATOM2, 0x444D}, // FTDI
{"Oceanic", "OCS", DC_FAMILY_OCEANIC_ATOM2, 0x4450}, // FTDI
{"Oceanic", "OC1", DC_FAMILY_OCEANIC_ATOM2, 0x4451}, // FTDI
{"Oceanic", "VT 4.1", DC_FAMILY_OCEANIC_ATOM2, 0x4452}, // FTDI
{"Aeris", "Epic", DC_FAMILY_OCEANIC_ATOM2, 0x4453}, // FTDI
{"Aeris", "Elite T3", DC_FAMILY_OCEANIC_ATOM2, 0x4455}, // FTDI
{"Oceanic", "Atom 3.1", DC_FAMILY_OCEANIC_ATOM2, 0x4456}, // FTDI
{"Aeris", "A300 AI", DC_FAMILY_OCEANIC_ATOM2, 0x4457}, // FTDI
{"Sherwood", "Wisdom 3", DC_FAMILY_OCEANIC_ATOM2, 0x4458}, // FTDI
{"Aeris", "A300", DC_FAMILY_OCEANIC_ATOM2, 0x445A}, // FTDI
{"Hollis", "TX1", DC_FAMILY_OCEANIC_ATOM2, 0x4542}, // FTDI
{"Beuchat", "Mundial 2", DC_FAMILY_OCEANIC_ATOM2, 0x4543}, // FTDI
{"Sherwood", "Amphos", DC_FAMILY_OCEANIC_ATOM2, 0x4545}, // FTDI
{"Sherwood", "Amphos Air", DC_FAMILY_OCEANIC_ATOM2, 0x4546}, // FTDI
{"Oceanic", "Pro Plus 3", DC_FAMILY_OCEANIC_ATOM2, 0x4548}, // FTDI
{"Aeris", "F11", DC_FAMILY_OCEANIC_ATOM2, 0x4549}, // FTDI
{"Oceanic", "OCi", DC_FAMILY_OCEANIC_ATOM2, 0x454B}, // FTDI
{"Aeris", "A300CS", DC_FAMILY_OCEANIC_ATOM2, 0x454C}, // FTDI
{"Beuchat", "Mundial 3", DC_FAMILY_OCEANIC_ATOM2, 0x4550}, // FTDI
{"Oceanic", "F10", DC_FAMILY_OCEANIC_ATOM2, 0x4553}, // FTDI
{"Oceanic", "F11", DC_FAMILY_OCEANIC_ATOM2, 0x4554}, // FTDI
{"Subgear", "XP-Air", DC_FAMILY_OCEANIC_ATOM2, 0x4555}, // FTDI
{"Sherwood", "Vision", DC_FAMILY_OCEANIC_ATOM2, 0x4556}, // FTDI
{"Oceanic", "VTX", DC_FAMILY_OCEANIC_ATOM2, 0x4557}, // FTDI
{"Aqualung", "i300", DC_FAMILY_OCEANIC_ATOM2, 0x4559}, // FTDI
{"Aqualung", "i750TC", DC_FAMILY_OCEANIC_ATOM2, 0x455A}, // FTDI
{"Aqualung", "i450T", DC_FAMILY_OCEANIC_ATOM2, 0x4641}, // FTDI
{"Aqualung", "i550", DC_FAMILY_OCEANIC_ATOM2, 0x4642}, // FTDI
{"Aqualung", "i200", DC_FAMILY_OCEANIC_ATOM2, 0x4646}, // FTDI
{"Oceanic", "Atom 1.0", DC_FAMILY_OCEANIC_ATOM2, 0x4250, NULL},
{"Aeris", "Epic", DC_FAMILY_OCEANIC_ATOM2, 0x4257, NULL},
{"Oceanic", "VT3", DC_FAMILY_OCEANIC_ATOM2, 0x4258, NULL},
{"Aeris", "Elite T3", DC_FAMILY_OCEANIC_ATOM2, 0x4259, NULL},
{"Oceanic", "Atom 2.0", DC_FAMILY_OCEANIC_ATOM2, 0x4342, NULL},
{"Oceanic", "Geo", DC_FAMILY_OCEANIC_ATOM2, 0x4344, NULL},
{"Aeris", "Manta", DC_FAMILY_OCEANIC_ATOM2, 0x4345, NULL},
{"Aeris", "XR-1 NX", DC_FAMILY_OCEANIC_ATOM2, 0x4346, NULL},
{"Oceanic", "Datamask", DC_FAMILY_OCEANIC_ATOM2, 0x4347, NULL},
{"Aeris", "Compumask", DC_FAMILY_OCEANIC_ATOM2, 0x4348, NULL},
{"Aeris", "F10", DC_FAMILY_OCEANIC_ATOM2, 0x434D, NULL},
{"Oceanic", "OC1", DC_FAMILY_OCEANIC_ATOM2, 0x434E, NULL},
{"Sherwood", "Wisdom 2", DC_FAMILY_OCEANIC_ATOM2, 0x4350, NULL},
{"Sherwood", "Insight 2", DC_FAMILY_OCEANIC_ATOM2, 0x4353, NULL},
{"Genesis", "React Pro White", DC_FAMILY_OCEANIC_ATOM2, 0x4354, NULL},
{"Tusa", "Element II (IQ-750)", DC_FAMILY_OCEANIC_ATOM2, 0x4357, NULL},
{"Oceanic", "Veo 1.0", DC_FAMILY_OCEANIC_ATOM2, 0x4358, NULL},
{"Oceanic", "Veo 2.0", DC_FAMILY_OCEANIC_ATOM2, 0x4359, NULL},
{"Oceanic", "Veo 3.0", DC_FAMILY_OCEANIC_ATOM2, 0x435A, NULL},
{"Tusa", "Zen (IQ-900)", DC_FAMILY_OCEANIC_ATOM2, 0x4441, NULL},
{"Tusa", "Zen Air (IQ-950)", DC_FAMILY_OCEANIC_ATOM2, 0x4442, NULL},
{"Aeris", "Atmos AI 2", DC_FAMILY_OCEANIC_ATOM2, 0x4443, NULL},
{"Oceanic", "Pro Plus 2.1", DC_FAMILY_OCEANIC_ATOM2, 0x4444, NULL},
{"Oceanic", "Geo 2.0", DC_FAMILY_OCEANIC_ATOM2, 0x4446, NULL},
{"Oceanic", "VT4", DC_FAMILY_OCEANIC_ATOM2, 0x4447, NULL},
{"Oceanic", "OC1", DC_FAMILY_OCEANIC_ATOM2, 0x4449, NULL},
{"Beuchat", "Voyager 2G", DC_FAMILY_OCEANIC_ATOM2, 0x444B, NULL},
{"Oceanic", "Atom 3.0", DC_FAMILY_OCEANIC_ATOM2, 0x444C, NULL},
{"Hollis", "DG03", DC_FAMILY_OCEANIC_ATOM2, 0x444D, NULL},
{"Oceanic", "OCS", DC_FAMILY_OCEANIC_ATOM2, 0x4450, NULL},
{"Oceanic", "OC1", DC_FAMILY_OCEANIC_ATOM2, 0x4451, NULL},
{"Oceanic", "VT 4.1", DC_FAMILY_OCEANIC_ATOM2, 0x4452, NULL},
{"Aeris", "Epic", DC_FAMILY_OCEANIC_ATOM2, 0x4453, NULL},
{"Aeris", "Elite T3", DC_FAMILY_OCEANIC_ATOM2, 0x4455, NULL},
{"Oceanic", "Atom 3.1", DC_FAMILY_OCEANIC_ATOM2, 0x4456, NULL},
{"Aeris", "A300 AI", DC_FAMILY_OCEANIC_ATOM2, 0x4457, NULL},
{"Sherwood", "Wisdom 3", DC_FAMILY_OCEANIC_ATOM2, 0x4458, NULL},
{"Aeris", "A300", DC_FAMILY_OCEANIC_ATOM2, 0x445A, NULL},
{"Hollis", "TX1", DC_FAMILY_OCEANIC_ATOM2, 0x4542, NULL},
{"Beuchat", "Mundial 2", DC_FAMILY_OCEANIC_ATOM2, 0x4543, NULL},
{"Sherwood", "Amphos", DC_FAMILY_OCEANIC_ATOM2, 0x4545, NULL},
{"Sherwood", "Amphos Air", DC_FAMILY_OCEANIC_ATOM2, 0x4546, NULL},
{"Oceanic", "Pro Plus 3", DC_FAMILY_OCEANIC_ATOM2, 0x4548, NULL},
{"Aeris", "F11", DC_FAMILY_OCEANIC_ATOM2, 0x4549, NULL},
{"Oceanic", "OCi", DC_FAMILY_OCEANIC_ATOM2, 0x454B, NULL},
{"Aeris", "A300CS", DC_FAMILY_OCEANIC_ATOM2, 0x454C, NULL},
{"Beuchat", "Mundial 3", DC_FAMILY_OCEANIC_ATOM2, 0x4550, NULL},
{"Oceanic", "F10", DC_FAMILY_OCEANIC_ATOM2, 0x4553, NULL},
{"Oceanic", "F11", DC_FAMILY_OCEANIC_ATOM2, 0x4554, NULL},
{"Subgear", "XP-Air", DC_FAMILY_OCEANIC_ATOM2, 0x4555, NULL},
{"Sherwood", "Vision", DC_FAMILY_OCEANIC_ATOM2, 0x4556, NULL},
{"Oceanic", "VTX", DC_FAMILY_OCEANIC_ATOM2, 0x4557, NULL},
{"Aqualung", "i300", DC_FAMILY_OCEANIC_ATOM2, 0x4559, NULL},
{"Aqualung", "i750TC", DC_FAMILY_OCEANIC_ATOM2, 0x455A, NULL},
{"Aqualung", "i450T", DC_FAMILY_OCEANIC_ATOM2, 0x4641, NULL},
{"Aqualung", "i550", DC_FAMILY_OCEANIC_ATOM2, 0x4642, NULL},
{"Aqualung", "i200", DC_FAMILY_OCEANIC_ATOM2, 0x4646, NULL},
/* Mares Nemo */
{"Mares", "Nemo", DC_FAMILY_MARES_NEMO, 0},
{"Mares", "Nemo Steel", DC_FAMILY_MARES_NEMO, 0},
{"Mares", "Nemo Titanium",DC_FAMILY_MARES_NEMO, 0},
{"Mares", "Nemo Excel", DC_FAMILY_MARES_NEMO, 17},
{"Mares", "Nemo Apneist", DC_FAMILY_MARES_NEMO, 18},
{"Mares", "Nemo", DC_FAMILY_MARES_NEMO, 0, NULL},
{"Mares", "Nemo Steel", DC_FAMILY_MARES_NEMO, 0, NULL},
{"Mares", "Nemo Titanium",DC_FAMILY_MARES_NEMO, 0, NULL},
{"Mares", "Nemo Excel", DC_FAMILY_MARES_NEMO, 17, NULL},
{"Mares", "Nemo Apneist", DC_FAMILY_MARES_NEMO, 18, NULL},
/* Mares Puck */
{"Mares", "Puck", DC_FAMILY_MARES_PUCK, 7},
{"Mares", "Puck Air", DC_FAMILY_MARES_PUCK, 19},
{"Mares", "Nemo Air", DC_FAMILY_MARES_PUCK, 4},
{"Mares", "Nemo Wide", DC_FAMILY_MARES_PUCK, 1},
{"Mares", "Puck", DC_FAMILY_MARES_PUCK, 7, NULL},
{"Mares", "Puck Air", DC_FAMILY_MARES_PUCK, 19, NULL},
{"Mares", "Nemo Air", DC_FAMILY_MARES_PUCK, 4, NULL},
{"Mares", "Nemo Wide", DC_FAMILY_MARES_PUCK, 1, NULL},
/* Mares Darwin */
{"Mares", "Darwin", DC_FAMILY_MARES_DARWIN , 0},
{"Mares", "M1", DC_FAMILY_MARES_DARWIN , 0},
{"Mares", "M2", DC_FAMILY_MARES_DARWIN , 0},
{"Mares", "Darwin Air", DC_FAMILY_MARES_DARWIN , 1},
{"Mares", "Airlab", DC_FAMILY_MARES_DARWIN , 1},
{"Mares", "Darwin", DC_FAMILY_MARES_DARWIN , 0, NULL},
{"Mares", "M1", DC_FAMILY_MARES_DARWIN , 0, NULL},
{"Mares", "M2", DC_FAMILY_MARES_DARWIN , 0, NULL},
{"Mares", "Darwin Air", DC_FAMILY_MARES_DARWIN , 1, NULL},
{"Mares", "Airlab", DC_FAMILY_MARES_DARWIN , 1, NULL},
/* Mares Icon HD */
{"Mares", "Matrix", DC_FAMILY_MARES_ICONHD , 0x0F},
{"Mares", "Smart", DC_FAMILY_MARES_ICONHD , 0x000010},
{"Mares", "Smart Apnea", DC_FAMILY_MARES_ICONHD , 0x010010},
{"Mares", "Icon HD", DC_FAMILY_MARES_ICONHD , 0x14},
{"Mares", "Icon HD Net Ready", DC_FAMILY_MARES_ICONHD , 0x15},
{"Mares", "Puck Pro", DC_FAMILY_MARES_ICONHD , 0x18},
{"Mares", "Nemo Wide 2", DC_FAMILY_MARES_ICONHD , 0x19},
{"Mares", "Puck 2", DC_FAMILY_MARES_ICONHD , 0x1F},
{"Mares", "Quad Air", DC_FAMILY_MARES_ICONHD , 0x23},
{"Mares", "Quad", DC_FAMILY_MARES_ICONHD , 0x29},
{"Mares", "Matrix", DC_FAMILY_MARES_ICONHD , 0x0F, NULL},
{"Mares", "Smart", DC_FAMILY_MARES_ICONHD , 0x000010, NULL},
{"Mares", "Smart Apnea", DC_FAMILY_MARES_ICONHD , 0x010010, NULL},
{"Mares", "Icon HD", DC_FAMILY_MARES_ICONHD , 0x14, NULL},
{"Mares", "Icon HD Net Ready", DC_FAMILY_MARES_ICONHD , 0x15, NULL},
{"Mares", "Puck Pro", DC_FAMILY_MARES_ICONHD , 0x18, NULL},
{"Mares", "Nemo Wide 2", DC_FAMILY_MARES_ICONHD , 0x19, NULL},
{"Mares", "Puck 2", DC_FAMILY_MARES_ICONHD , 0x1F, NULL},
{"Mares", "Quad Air", DC_FAMILY_MARES_ICONHD , 0x23, NULL},
{"Mares", "Quad", DC_FAMILY_MARES_ICONHD , 0x29, NULL},
/* Heinrichs Weikamp */
{"Heinrichs Weikamp", "OSTC", DC_FAMILY_HW_OSTC, 0}, // FTDI
{"Heinrichs Weikamp", "OSTC Mk2", DC_FAMILY_HW_OSTC, 1}, // FTDI
{"Heinrichs Weikamp", "OSTC 2N", DC_FAMILY_HW_OSTC, 2}, // FTDI
{"Heinrichs Weikamp", "OSTC 2C", DC_FAMILY_HW_OSTC, 3}, // FTDI
{"Heinrichs Weikamp", "Frog", DC_FAMILY_HW_FROG, 0}, // FTDI
{"Heinrichs Weikamp", "OSTC 2", DC_FAMILY_HW_OSTC3, 0x11}, // FTDI
{"Heinrichs Weikamp", "OSTC 2", DC_FAMILY_HW_OSTC3, 0x13}, // FTDI
{"Heinrichs Weikamp", "OSTC 2", DC_FAMILY_HW_OSTC3, 0x1B}, // FTDI
{"Heinrichs Weikamp", "OSTC 3", DC_FAMILY_HW_OSTC3, 0x0A}, // FTDI
{"Heinrichs Weikamp", "OSTC Plus", DC_FAMILY_HW_OSTC3, 0x13}, // FTDI // BT
{"Heinrichs Weikamp", "OSTC Plus", DC_FAMILY_HW_OSTC3, 0x1A}, // FTDI // BT
{"Heinrichs Weikamp", "OSTC 4", DC_FAMILY_HW_OSTC3, 0x3B}, // BT
{"Heinrichs Weikamp", "OSTC cR", DC_FAMILY_HW_OSTC3, 0x05}, // FTDI
{"Heinrichs Weikamp", "OSTC cR", DC_FAMILY_HW_OSTC3, 0x07}, // FTDI
{"Heinrichs Weikamp", "OSTC Sport", DC_FAMILY_HW_OSTC3, 0x12}, // FTDI // BT
{"Heinrichs Weikamp", "OSTC Sport", DC_FAMILY_HW_OSTC3, 0x13}, // FTDI // BT
{"Heinrichs Weikamp", "OSTC", DC_FAMILY_HW_OSTC, 0, NULL},
{"Heinrichs Weikamp", "OSTC Mk2", DC_FAMILY_HW_OSTC, 1, NULL},
{"Heinrichs Weikamp", "OSTC 2N", DC_FAMILY_HW_OSTC, 2, NULL},
{"Heinrichs Weikamp", "OSTC 2C", DC_FAMILY_HW_OSTC, 3, NULL},
{"Heinrichs Weikamp", "Frog", DC_FAMILY_HW_FROG, 0, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC 2", DC_FAMILY_HW_OSTC3, 0x11, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC 2", DC_FAMILY_HW_OSTC3, 0x13, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC 2", DC_FAMILY_HW_OSTC3, 0x1B, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC 3", DC_FAMILY_HW_OSTC3, 0x0A, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC Plus", DC_FAMILY_HW_OSTC3, 0x13, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC Plus", DC_FAMILY_HW_OSTC3, 0x1A, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC 4", DC_FAMILY_HW_OSTC3, 0x3B, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC cR", DC_FAMILY_HW_OSTC3, 0x05, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC cR", DC_FAMILY_HW_OSTC3, 0x07, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC Sport", DC_FAMILY_HW_OSTC3, 0x12, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC Sport", DC_FAMILY_HW_OSTC3, 0x13, dc_filter_hw},
{"Heinrichs Weikamp", "OSTC 2 TR", DC_FAMILY_HW_OSTC3, 0x33, dc_filter_hw},
/* Cressi Edy */
{"Tusa", "IQ-700", DC_FAMILY_CRESSI_EDY, 0x05},
{"Cressi", "Edy", DC_FAMILY_CRESSI_EDY, 0x08},
{"Tusa", "IQ-700", DC_FAMILY_CRESSI_EDY, 0x05, NULL},
{"Cressi", "Edy", DC_FAMILY_CRESSI_EDY, 0x08, NULL},
/* Cressi Leonardo */
{"Cressi", "Leonardo", DC_FAMILY_CRESSI_LEONARDO, 1},
{"Cressi", "Giotto", DC_FAMILY_CRESSI_LEONARDO, 4},
{"Cressi", "Newton", DC_FAMILY_CRESSI_LEONARDO, 5},
{"Cressi", "Drake", DC_FAMILY_CRESSI_LEONARDO, 6},
{"Cressi", "Leonardo", DC_FAMILY_CRESSI_LEONARDO, 1, NULL},
{"Cressi", "Giotto", DC_FAMILY_CRESSI_LEONARDO, 4, NULL},
{"Cressi", "Newton", DC_FAMILY_CRESSI_LEONARDO, 5, NULL},
{"Cressi", "Drake", DC_FAMILY_CRESSI_LEONARDO, 6, NULL},
/* Zeagle N2iTiON3 */
{"Zeagle", "N2iTiON3", DC_FAMILY_ZEAGLE_N2ITION3, 0},
{"Apeks", "Quantum X", DC_FAMILY_ZEAGLE_N2ITION3, 0},
{"Dive Rite", "NiTek Trio", DC_FAMILY_ZEAGLE_N2ITION3, 0},
{"Scubapro", "XTender 5", DC_FAMILY_ZEAGLE_N2ITION3, 0},
{"Zeagle", "N2iTiON3", DC_FAMILY_ZEAGLE_N2ITION3, 0, NULL},
{"Apeks", "Quantum X", DC_FAMILY_ZEAGLE_N2ITION3, 0, NULL},
{"Dive Rite", "NiTek Trio", DC_FAMILY_ZEAGLE_N2ITION3, 0, NULL},
{"Scubapro", "XTender 5", DC_FAMILY_ZEAGLE_N2ITION3, 0, NULL},
/* Atomic Aquatics Cobalt */
#ifdef HAVE_LIBUSB
{"Atomic Aquatics", "Cobalt", DC_FAMILY_ATOMICS_COBALT, 0},
{"Atomic Aquatics", "Cobalt 2", DC_FAMILY_ATOMICS_COBALT, 2},
{"Atomic Aquatics", "Cobalt", DC_FAMILY_ATOMICS_COBALT, 0, NULL},
{"Atomic Aquatics", "Cobalt 2", DC_FAMILY_ATOMICS_COBALT, 2, NULL},
#endif
/* Shearwater Predator */
{"Shearwater", "Predator", DC_FAMILY_SHEARWATER_PREDATOR, 2}, // BT
/* Shearwater Petrel family */
{"Shearwater", "Petrel", DC_FAMILY_SHEARWATER_PETREL, 3}, // BT // BLE
{"Shearwater", "Petrel 2", DC_FAMILY_SHEARWATER_PETREL, 3}, // BT // BLE
{"Shearwater", "Nerd", DC_FAMILY_SHEARWATER_PETREL, 4}, // BT
{"Shearwater", "Perdix", DC_FAMILY_SHEARWATER_PETREL, 5}, // BT // BLE
{"Shearwater", "Perdix AI", DC_FAMILY_SHEARWATER_PETREL, 6}, // BLE
{"Shearwater", "Nerd 2", DC_FAMILY_SHEARWATER_PETREL, 7}, // BLE
{"Shearwater", "Predator", DC_FAMILY_SHEARWATER_PREDATOR, 2, dc_filter_shearwater},
/* Shearwater Petrel */
{"Shearwater", "Petrel", DC_FAMILY_SHEARWATER_PETREL, 3, dc_filter_shearwater},
{"Shearwater", "Petrel 2", DC_FAMILY_SHEARWATER_PETREL, 3, dc_filter_shearwater},
{"Shearwater", "Nerd", DC_FAMILY_SHEARWATER_PETREL, 4, dc_filter_shearwater},
{"Shearwater", "Perdix", DC_FAMILY_SHEARWATER_PETREL, 5, dc_filter_shearwater},
{"Shearwater", "Perdix AI", DC_FAMILY_SHEARWATER_PETREL, 6, dc_filter_shearwater},
{"Shearwater", "Nerd 2", DC_FAMILY_SHEARWATER_PETREL, 7, dc_filter_shearwater},
/* Dive Rite NiTek Q */
{"Dive Rite", "NiTek Q", DC_FAMILY_DIVERITE_NITEKQ, 0},
{"Dive Rite", "NiTek Q", DC_FAMILY_DIVERITE_NITEKQ, 0, NULL},
/* Citizen Hyper Aqualand */
{"Citizen", "Hyper Aqualand", DC_FAMILY_CITIZEN_AQUALAND, 0},
{"Citizen", "Hyper Aqualand", DC_FAMILY_CITIZEN_AQUALAND, 0, NULL},
/* DiveSystem/Ratio iDive */
{"DiveSystem", "Orca", DC_FAMILY_DIVESYSTEM_IDIVE, 0x02},
{"DiveSystem", "iDive Pro", DC_FAMILY_DIVESYSTEM_IDIVE, 0x03},
{"DiveSystem", "iDive DAN", DC_FAMILY_DIVESYSTEM_IDIVE, 0x04},
{"DiveSystem", "iDive Tech", DC_FAMILY_DIVESYSTEM_IDIVE, 0x05},
{"DiveSystem", "iDive Reb", DC_FAMILY_DIVESYSTEM_IDIVE, 0x06},
{"DiveSystem", "iDive Stealth", DC_FAMILY_DIVESYSTEM_IDIVE, 0x07},
{"DiveSystem", "iDive Free", DC_FAMILY_DIVESYSTEM_IDIVE, 0x08},
{"DiveSystem", "iDive Easy", DC_FAMILY_DIVESYSTEM_IDIVE, 0x09},
{"DiveSystem", "iDive X3M", DC_FAMILY_DIVESYSTEM_IDIVE, 0x0A},
{"DiveSystem", "iDive Deep", DC_FAMILY_DIVESYSTEM_IDIVE, 0x0B},
{"Ratio", "iX3M Easy", DC_FAMILY_DIVESYSTEM_IDIVE, 0x22},
{"Ratio", "iX3M Deep", DC_FAMILY_DIVESYSTEM_IDIVE, 0x23},
{"Ratio", "iX3M Tech+", DC_FAMILY_DIVESYSTEM_IDIVE, 0x24},
{"Ratio", "iX3M Reb", DC_FAMILY_DIVESYSTEM_IDIVE, 0x25},
{"Ratio", "iX3M Pro Easy", DC_FAMILY_DIVESYSTEM_IDIVE, 0x32},
{"Ratio", "iX3M Pro Deep", DC_FAMILY_DIVESYSTEM_IDIVE, 0x34},
{"Ratio", "iX3M Pro Tech+",DC_FAMILY_DIVESYSTEM_IDIVE, 0x35},
{"Ratio", "iDive Free", DC_FAMILY_DIVESYSTEM_IDIVE, 0x40},
{"Ratio", "iDive Easy", DC_FAMILY_DIVESYSTEM_IDIVE, 0x42},
{"Ratio", "iDive Deep", DC_FAMILY_DIVESYSTEM_IDIVE, 0x44},
{"Ratio", "iDive Tech+", DC_FAMILY_DIVESYSTEM_IDIVE, 0x45},
{"Seac", "Jack", DC_FAMILY_DIVESYSTEM_IDIVE, 0x1000},
{"DiveSystem", "Orca", DC_FAMILY_DIVESYSTEM_IDIVE, 0x02, NULL},
{"DiveSystem", "iDive Pro", DC_FAMILY_DIVESYSTEM_IDIVE, 0x03, NULL},
{"DiveSystem", "iDive DAN", DC_FAMILY_DIVESYSTEM_IDIVE, 0x04, NULL},
{"DiveSystem", "iDive Tech", DC_FAMILY_DIVESYSTEM_IDIVE, 0x05, NULL},
{"DiveSystem", "iDive Reb", DC_FAMILY_DIVESYSTEM_IDIVE, 0x06, NULL},
{"DiveSystem", "iDive Stealth", DC_FAMILY_DIVESYSTEM_IDIVE, 0x07, NULL},
{"DiveSystem", "iDive Free", DC_FAMILY_DIVESYSTEM_IDIVE, 0x08, NULL},
{"DiveSystem", "iDive Easy", DC_FAMILY_DIVESYSTEM_IDIVE, 0x09, NULL},
{"DiveSystem", "iDive X3M", DC_FAMILY_DIVESYSTEM_IDIVE, 0x0A, NULL},
{"DiveSystem", "iDive Deep", DC_FAMILY_DIVESYSTEM_IDIVE, 0x0B, NULL},
{"Ratio", "iX3M Easy", DC_FAMILY_DIVESYSTEM_IDIVE, 0x22, NULL},
{"Ratio", "iX3M Deep", DC_FAMILY_DIVESYSTEM_IDIVE, 0x23, NULL},
{"Ratio", "iX3M Tech+", DC_FAMILY_DIVESYSTEM_IDIVE, 0x24, NULL},
{"Ratio", "iX3M Reb", DC_FAMILY_DIVESYSTEM_IDIVE, 0x25, NULL},
{"Ratio", "iX3M Pro Easy", DC_FAMILY_DIVESYSTEM_IDIVE, 0x32, NULL},
{"Ratio", "iX3M Pro Deep", DC_FAMILY_DIVESYSTEM_IDIVE, 0x34, NULL},
{"Ratio", "iX3M Pro Tech+",DC_FAMILY_DIVESYSTEM_IDIVE, 0x35, NULL},
{"Ratio", "iDive Free", DC_FAMILY_DIVESYSTEM_IDIVE, 0x40, NULL},
{"Ratio", "iDive Easy", DC_FAMILY_DIVESYSTEM_IDIVE, 0x42, NULL},
{"Ratio", "iDive Deep", DC_FAMILY_DIVESYSTEM_IDIVE, 0x44, NULL},
{"Ratio", "iDive Tech+", DC_FAMILY_DIVESYSTEM_IDIVE, 0x45, NULL},
{"Seac", "Jack", DC_FAMILY_DIVESYSTEM_IDIVE, 0x1000, NULL},
/* Cochran Commander */
{"Cochran", "Commander TM", DC_FAMILY_COCHRAN_COMMANDER, 0}, // FTDI
{"Cochran", "Commander I", DC_FAMILY_COCHRAN_COMMANDER, 1}, // FTDI
{"Cochran", "Commander II", DC_FAMILY_COCHRAN_COMMANDER, 2}, // FTDI
{"Cochran", "EMC-14", DC_FAMILY_COCHRAN_COMMANDER, 3}, // FTDI
{"Cochran", "EMC-16", DC_FAMILY_COCHRAN_COMMANDER, 4}, // FTDI
{"Cochran", "EMC-20H", DC_FAMILY_COCHRAN_COMMANDER, 5}, // FTDI
{"Cochran", "Commander TM", DC_FAMILY_COCHRAN_COMMANDER, 0, NULL},
{"Cochran", "Commander I", DC_FAMILY_COCHRAN_COMMANDER, 1, NULL},
{"Cochran", "Commander II", DC_FAMILY_COCHRAN_COMMANDER, 2, NULL},
{"Cochran", "EMC-14", DC_FAMILY_COCHRAN_COMMANDER, 3, NULL},
{"Cochran", "EMC-16", DC_FAMILY_COCHRAN_COMMANDER, 4, NULL},
{"Cochran", "EMC-20H", DC_FAMILY_COCHRAN_COMMANDER, 5, NULL},
};
typedef struct dc_descriptor_iterator_t {
dc_iterator_t base;
size_t current;
} dc_descriptor_iterator_t;
static int
dc_filter_internal_name (const char *name, const char *values[], size_t count)
{
if (name == NULL)
return 0;
static dc_status_t dc_descriptor_iterator_next (dc_iterator_t *iterator, void *item);
static dc_status_t dc_descriptor_iterator_free (dc_iterator_t *iterator);
for (size_t i = 0; i < count; ++i) {
if (strcasecmp (name, values[i]) == 0) {
return 1;
}
}
static const dc_iterator_vtable_t dc_descriptor_iterator_vtable = {
dc_descriptor_iterator_free,
dc_descriptor_iterator_next
};
return 0;
}
static int
dc_filter_internal_usb (const dc_usb_desc_t *desc, const dc_usb_desc_t values[], size_t count)
{
if (desc == NULL)
return 0;
for (size_t i = 0; i < count; ++i) {
if (desc->vid == values[i].vid &&
desc->pid == values[i].pid) {
return 1;
}
}
return 0;
}
static int dc_filter_uwatec (dc_transport_t transport, const void *userdata)
{
static const char *irda[] = {
"Aladin Smart Com",
"Aladin Smart Pro",
"Aladin Smart Tec",
"Aladin Smart Z",
"Uwatec Aladin",
"UWATEC Galileo",
"UWATEC Galileo Sol",
};
static const dc_usb_desc_t usbhid[] = {
{0x2e6c, 0x3201}, // G2
{0xc251, 0x2006}, // Aladin Square
};
if (transport == DC_TRANSPORT_IRDA) {
return dc_filter_internal_name ((const char *) userdata, irda, C_ARRAY_SIZE(irda));
} else if (transport == DC_TRANSPORT_USBHID) {
return dc_filter_internal_usb ((const dc_usb_desc_t *) userdata, usbhid, C_ARRAY_SIZE(usbhid));
}
return 1;
}
static int dc_filter_suunto (dc_transport_t transport, const void *userdata)
{
static const dc_usb_desc_t usbhid[] = {
{0x1493, 0x0030}, // Eon Steel
{0x1493, 0x0033}, // Eon Core
};
if (transport == DC_TRANSPORT_USBHID) {
return dc_filter_internal_usb ((const dc_usb_desc_t *) userdata, usbhid, C_ARRAY_SIZE(usbhid));
}
return 1;
}
static int dc_filter_hw (dc_transport_t transport, const void *userdata)
{
if (transport == DC_TRANSPORT_BLUETOOTH) {
return strncasecmp ((const char *) userdata, "OSTC", 4) == 0 ||
strncasecmp ((const char *) userdata, "FROG", 4) == 0;
}
return 1;
}
static int dc_filter_shearwater (dc_transport_t transport, const void *userdata)
{
static const char *bluetooth[] = {
"Predator",
"Petrel",
"Nerd",
"Perdix",
};
if (transport == DC_TRANSPORT_BLUETOOTH) {
return dc_filter_internal_name ((const char *) userdata, bluetooth, C_ARRAY_SIZE(bluetooth));
}
return 1;
}
dc_status_t
dc_descriptor_iterator (dc_iterator_t **out)
@ -353,11 +456,10 @@ dc_descriptor_iterator (dc_iterator_t **out)
if (out == NULL)
return DC_STATUS_INVALIDARGS;
iterator = (dc_descriptor_iterator_t *) malloc (sizeof (dc_descriptor_iterator_t));
iterator = (dc_descriptor_iterator_t *) dc_iterator_allocate (NULL, &dc_descriptor_iterator_vtable);
if (iterator == NULL)
return DC_STATUS_NOMEMORY;
iterator->base.vtable = &dc_descriptor_iterator_vtable;
iterator->current = 0;
*out = (dc_iterator_t *) iterator;
@ -365,14 +467,6 @@ dc_descriptor_iterator (dc_iterator_t **out)
return DC_STATUS_SUCCESS;
}
static dc_status_t
dc_descriptor_iterator_free (dc_iterator_t *iterator)
{
free (iterator);
return DC_STATUS_SUCCESS;
}
static dc_status_t
dc_descriptor_iterator_next (dc_iterator_t *abstract, void *out)
{
@ -436,15 +530,6 @@ dc_descriptor_get_model (dc_descriptor_t *descriptor)
return descriptor->model;
}
unsigned int
dc_descriptor_get_serial (dc_descriptor_t *descriptor)
{
if (descriptor == NULL)
return 0;
return descriptor->serial;
}
dc_transport_t
dc_descriptor_get_transport (dc_descriptor_t *descriptor)
{
@ -462,3 +547,12 @@ dc_descriptor_get_transport (dc_descriptor_t *descriptor)
else
return DC_TRANSPORT_SERIAL;
}
dc_filter_t
dc_descriptor_get_filter (dc_descriptor_t *descriptor)
{
if (descriptor == NULL)
return NULL;
return descriptor->filter;
}

9
src/hw_ostc_parser.c
View File

@ -757,6 +757,7 @@ hw_ostc_parser_samples_foreach (dc_parser_t *abstract, dc_sample_callback_t call
switch (info[i].type) {
case 0: // Temperature
case 1: // Deco / NDL
case 6: // Tank pressure
if (info[i].size != 2) {
ERROR(abstract->context, "Unexpected sample size.");
return DC_STATUS_DATAFORMAT;
@ -790,6 +791,7 @@ hw_ostc_parser_samples_foreach (dc_parser_t *abstract, dc_sample_callback_t call
unsigned int time = 0;
unsigned int nsamples = 0;
unsigned int tank = parser->initial != UNDEFINED ? parser->initial : 0;
unsigned int offset = header;
if (version == 0x23 || version == 0x24)
@ -925,6 +927,7 @@ hw_ostc_parser_samples_foreach (dc_parser_t *abstract, dc_sample_callback_t call
idx--; /* Convert to a zero based index. */
sample.gasmix = idx;
if (callback) callback (DC_SAMPLE_GASMIX, sample, userdata);
tank = idx;
offset++;
length--;
}
@ -1025,6 +1028,12 @@ hw_ostc_parser_samples_foreach (dc_parser_t *abstract, dc_sample_callback_t call
sample.cns = data[offset] / 100.0;
if (callback) callback (DC_SAMPLE_CNS, sample, userdata);
break;
case 6: // Tank pressure
value = array_uint16_le (data + offset);
sample.pressure.tank = tank;
sample.pressure.value = value / 10.0;
if (callback) callback (DC_SAMPLE_PRESSURE, sample, userdata);
break;
default: // Not yet used.
break;
}

2
src/iostream-private.h
View File

@ -44,8 +44,6 @@ struct dc_iostream_vtable_t {
dc_status_t (*set_latency) (dc_iostream_t *iostream, unsigned int value);
dc_status_t (*set_halfduplex) (dc_iostream_t *iostream, unsigned int value);
dc_status_t (*set_break) (dc_iostream_t *iostream, unsigned int value);
dc_status_t (*set_dtr) (dc_iostream_t *iostream, unsigned int value);

11
src/iostream.c
View File

@ -85,17 +85,6 @@ dc_iostream_set_latency (dc_iostream_t *iostream, unsigned int value)
return iostream->vtable->set_latency (iostream, value);
}
dc_status_t
dc_iostream_set_halfduplex (dc_iostream_t *iostream, unsigned int value)
{
if (iostream == NULL || iostream->vtable->set_halfduplex == NULL)
return DC_STATUS_UNSUPPORTED;
INFO (iostream->context, "Halfduplex: value=%i", value);
return iostream->vtable->set_halfduplex (iostream, value);
}
dc_status_t
dc_iostream_set_break (dc_iostream_t *iostream, unsigned int value)
{

253
src/irda.c
View File

@ -47,17 +47,51 @@
#include "common-private.h"
#include "context-private.h"
#include "iostream-private.h"
#include "iterator-private.h"
#include "descriptor-private.h"
#include "array.h"
#include "platform.h"
#define ISINSTANCE(device) dc_iostream_isinstance((device), &dc_irda_vtable)
#define DISCOVER_MAX_DEVICES 16 // Maximum number of devices.
#define DISCOVER_MAX_RETRIES 4 // Maximum number of retries.
#ifdef _WIN32
#define DISCOVER_BUFSIZE sizeof (DEVICELIST) + \
sizeof (IRDA_DEVICE_INFO) * (DISCOVER_MAX_DEVICES - 1)
#else
#define DISCOVER_BUFSIZE sizeof (struct irda_device_list) + \
sizeof (struct irda_device_info) * (DISCOVER_MAX_DEVICES - 1)
#endif
struct dc_irda_device_t {
unsigned int address;
unsigned int charset;
unsigned int hints;
char name[22];
};
#ifdef IRDA
static dc_status_t dc_irda_iterator_next (dc_iterator_t *iterator, void *item);
typedef struct dc_irda_iterator_t {
dc_iterator_t base;
dc_irda_device_t items[DISCOVER_MAX_DEVICES];
size_t count;
size_t current;
} dc_irda_iterator_t;
static const dc_iterator_vtable_t dc_irda_iterator_vtable = {
sizeof(dc_irda_iterator_t),
dc_irda_iterator_next,
NULL,
};
static const dc_iostream_vtable_t dc_irda_vtable = {
sizeof(dc_socket_t),
dc_socket_set_timeout, /* set_timeout */
dc_socket_set_latency, /* set_latency */
dc_socket_set_halfduplex, /* set_halfduplex */
dc_socket_set_break, /* set_break */
dc_socket_set_dtr, /* set_dtr */
dc_socket_set_rts, /* set_rts */
@ -73,73 +107,72 @@ static const dc_iostream_vtable_t dc_irda_vtable = {
};
#endif
unsigned int
dc_irda_device_get_address (dc_irda_device_t *device)
{
if (device == NULL)
return 0;
return device->address;
}
const char *
dc_irda_device_get_name (dc_irda_device_t *device)
{
if (device == NULL || device->name[0] == '\0')
return NULL;
return device->name;
}
void
dc_irda_device_free (dc_irda_device_t *device)
{
free (device);
}
dc_status_t
dc_irda_open (dc_iostream_t **out, dc_context_t *context)
dc_irda_iterator_new (dc_iterator_t **out, dc_context_t *context, dc_descriptor_t *descriptor)
{
#ifdef IRDA
dc_status_t status = DC_STATUS_SUCCESS;
dc_socket_t *device = NULL;
dc_irda_iterator_t *iterator = NULL;
if (out == NULL)
return DC_STATUS_INVALIDARGS;
// Allocate memory.
device = (dc_socket_t *) dc_iostream_allocate (context, &dc_irda_vtable);
if (device == NULL) {
iterator = (dc_irda_iterator_t *) dc_iterator_allocate (context, &dc_irda_iterator_vtable);
if (iterator == NULL) {
SYSERROR (context, S_ENOMEM);
return DC_STATUS_NOMEMORY;
}
// Open the socket.
status = dc_socket_open (&device->base, AF_IRDA, SOCK_STREAM, 0);
// Initialize the socket library.
status = dc_socket_init (context);
if (status != DC_STATUS_SUCCESS) {
goto error_free;
}
*out = (dc_iostream_t *) device;
return DC_STATUS_SUCCESS;
error_free:
dc_iostream_deallocate ((dc_iostream_t *) device);
return status;
#else
return DC_STATUS_UNSUPPORTED;
#endif
}
#define DISCOVER_MAX_DEVICES 16 // Maximum number of devices.
#define DISCOVER_MAX_RETRIES 4 // Maximum number of retries.
#ifdef _WIN32
#define DISCOVER_BUFSIZE sizeof (DEVICELIST) + \
sizeof (IRDA_DEVICE_INFO) * (DISCOVER_MAX_DEVICES - 1)
#else
#define DISCOVER_BUFSIZE sizeof (struct irda_device_list) + \
sizeof (struct irda_device_info) * (DISCOVER_MAX_DEVICES - 1)
#endif
dc_status_t
dc_irda_discover (dc_iostream_t *abstract, dc_irda_callback_t callback, void *userdata)
{
#ifdef IRDA
dc_socket_t *device = (dc_socket_t *) abstract;
if (!ISINSTANCE (abstract))
return DC_STATUS_INVALIDARGS;
// Open the socket.
int fd = socket (AF_IRDA, SOCK_STREAM, 0);
if (fd == S_INVALID) {
s_errcode_t errcode = S_ERRNO;
SYSERROR (context, errcode);
status = dc_socket_syserror(errcode);
goto error_socket_exit;
}
unsigned char data[DISCOVER_BUFSIZE] = {0};
#ifdef _WIN32
DEVICELIST *list = (DEVICELIST *) data;
int size = sizeof (data);
#else
struct irda_device_list *list = (struct irda_device_list *) data;
socklen_t size = sizeof (data);
#endif
s_socklen_t size = sizeof (data);
int rc = 0;
unsigned int nretries = 0;
while ((rc = getsockopt (device->fd, SOL_IRLMP, IRLMP_ENUMDEVICES, (char*) data, &size)) != 0 ||
while ((rc = getsockopt (fd, SOL_IRLMP, IRLMP_ENUMDEVICES, (char *) data, &size)) != 0 ||
#ifdef _WIN32
list->numDevice == 0)
#else
@ -153,14 +186,16 @@ dc_irda_discover (dc_iostream_t *abstract, dc_irda_callback_t callback, void *us
if (rc != 0) {
s_errcode_t errcode = S_ERRNO;
if (errcode != S_EAGAIN) {
SYSERROR (abstract->context, errcode);
return dc_socket_syserror(errcode);
SYSERROR (context, errcode);
status = dc_socket_syserror(errcode);
goto error_socket_close;
}
}
// Abort if the maximum number of retries is reached.
if (nretries++ >= DISCOVER_MAX_RETRIES)
return DC_STATUS_SUCCESS;
if (nretries++ >= DISCOVER_MAX_RETRIES) {
break;
}
// Restore the size parameter in case it was
// modified by the previous getsockopt call.
@ -173,88 +208,109 @@ dc_irda_discover (dc_iostream_t *abstract, dc_irda_callback_t callback, void *us
#endif
}
if (callback) {
S_CLOSE (fd);
dc_socket_exit (context);
dc_filter_t filter = dc_descriptor_get_filter (descriptor);
unsigned int count = 0;
#ifdef _WIN32
for (unsigned int i = 0; i < list->numDevice; ++i) {
for (size_t i = 0; i < list->numDevice; ++i) {
const char *name = list->Device[i].irdaDeviceName;
unsigned int address = array_uint32_le (list->Device[i].irdaDeviceID);
unsigned int charset = list->Device[i].irdaCharSet;
unsigned int hints = (list->Device[i].irdaDeviceHints1 << 8) +
list->Device[i].irdaDeviceHints2;
#else
for (unsigned int i = 0; i < list->len; ++i) {
for (size_t i = 0; i < list->len; ++i) {
const char *name = list->dev[i].info;
unsigned int address = list->dev[i].daddr;
unsigned int charset = list->dev[i].charset;
unsigned int hints = array_uint16_be (list->dev[i].hints);
#endif
INFO (abstract->context,
"Discover: address=%08x, name=%s, charset=%02x, hints=%04x",
INFO (context, "Discover: address=%08x, name=%s, charset=%02x, hints=%04x",
address, name, charset, hints);
callback (address, name, charset, hints, userdata);
if (filter && !filter (DC_TRANSPORT_IRDA, name)) {
continue;
}
strncpy(iterator->items[count].name, name, sizeof(iterator->items[count].name) - 1);
iterator->items[count].name[sizeof(iterator->items[count].name) - 1] = '\0';
iterator->items[count].address = address;
iterator->items[count].charset = charset;
iterator->items[count].hints = hints;
count++;
}
iterator->current = 0;
iterator->count = count;
*out = (dc_iterator_t *) iterator;
return DC_STATUS_SUCCESS;
error_socket_close:
S_CLOSE (fd);
error_socket_exit:
dc_socket_exit (context);
error_free:
dc_iterator_deallocate ((dc_iterator_t *) iterator);
return status;
#else
return DC_STATUS_UNSUPPORTED;
#endif
}
dc_status_t
dc_irda_connect_name (dc_iostream_t *abstract, unsigned int address, const char *name)
{
#ifdef IRDA
dc_socket_t *device = (dc_socket_t *) abstract;
static dc_status_t
dc_irda_iterator_next (dc_iterator_t *abstract, void *out)
{
dc_irda_iterator_t *iterator = (dc_irda_iterator_t *) abstract;
dc_irda_device_t *device = NULL;
if (!ISINSTANCE (abstract))
return DC_STATUS_INVALIDARGS;
if (iterator->current >= iterator->count)
return DC_STATUS_DONE;
INFO (abstract->context, "Connect: address=%08x, name=%s", address, name ? name : "");
#ifdef _WIN32
SOCKADDR_IRDA peer;
peer.irdaAddressFamily = AF_IRDA;
peer.irdaDeviceID[0] = (address ) & 0xFF;
peer.irdaDeviceID[1] = (address >> 8) & 0xFF;
peer.irdaDeviceID[2] = (address >> 16) & 0xFF;
peer.irdaDeviceID[3] = (address >> 24) & 0xFF;
if (name) {
strncpy (peer.irdaServiceName, name, sizeof(peer.irdaServiceName) - 1);
peer.irdaServiceName[sizeof(peer.irdaServiceName) - 1] = '\0';
} else {
memset (peer.irdaServiceName, 0x00, sizeof(peer.irdaServiceName));
device = (dc_irda_device_t *) malloc (sizeof(dc_irda_device_t));
if (device == NULL) {
SYSERROR (abstract->context, S_ENOMEM);
return DC_STATUS_NOMEMORY;
}
#else
struct sockaddr_irda peer;
peer.sir_family = AF_IRDA;
peer.sir_addr = address;
if (name) {
strncpy (peer.sir_name, name, sizeof(peer.sir_name) - 1);
peer.sir_name[sizeof(peer.sir_name) - 1] = '\0';
} else {
memset (peer.sir_name, 0x00, sizeof(peer.sir_name));
}
#endif
return dc_socket_connect (&device->base, (struct sockaddr *) &peer, sizeof (peer));
#else
return DC_STATUS_UNSUPPORTED;
#endif
*device = iterator->items[iterator->current++];
*(dc_irda_device_t **) out = device;
return DC_STATUS_SUCCESS;
}
#endif
dc_status_t
dc_irda_connect_lsap (dc_iostream_t *abstract, unsigned int address, unsigned int lsap)
dc_irda_open (dc_iostream_t **out, dc_context_t *context, unsigned int address, unsigned int lsap)
{
#ifdef IRDA
dc_socket_t *device = (dc_socket_t *) abstract;
dc_status_t status = DC_STATUS_SUCCESS;
dc_socket_t *device = NULL;
if (!ISINSTANCE (abstract))
if (out == NULL)
return DC_STATUS_INVALIDARGS;
INFO (abstract->context, "Connect: address=%08x, lsap=%u", address, lsap);
INFO (context, "Open: address=%08x, lsap=%u", address, lsap);
// Allocate memory.
device = (dc_socket_t *) dc_iostream_allocate (context, &dc_irda_vtable);
if (device == NULL) {
SYSERROR (context, S_ENOMEM);
return DC_STATUS_NOMEMORY;
}
// Open the socket.
status = dc_socket_open (&device->base, AF_IRDA, SOCK_STREAM, 0);
if (status != DC_STATUS_SUCCESS) {
goto error_free;
}
#ifdef _WIN32
SOCKADDR_IRDA peer;
@ -272,7 +328,20 @@ dc_irda_connect_lsap (dc_iostream_t *abstract, unsigned int address, unsigned in
memset (peer.sir_name, 0x00, sizeof(peer.sir_name));
#endif
return dc_socket_connect (&device->base, (struct sockaddr *) &peer, sizeof (peer));
status = dc_socket_connect (&device->base, (struct sockaddr *) &peer, sizeof (peer));
if (status != DC_STATUS_SUCCESS) {
goto error_close;
}
*out = (dc_iostream_t *) device;
return DC_STATUS_SUCCESS;
error_close:
dc_socket_close (&device->base);
error_free:
dc_iostream_deallocate ((dc_iostream_t *) device);
return status;
#else
return DC_STATUS_UNSUPPORTED;
#endif

84
src/irda.h
View File

@ -25,68 +25,66 @@
#include <libdivecomputer/common.h>
#include <libdivecomputer/context.h>
#include <libdivecomputer/iostream.h>
#include <libdivecomputer/iterator.h>
#include <libdivecomputer/descriptor.h>
#ifdef __cplusplus
extern "C" {
#endif /* __cplusplus */
/**
* IrDA enumeration callback.
*
* @param[in] address The IrDA device address.
* @param[in] name The IrDA device name.
* @param[in] charset The IrDA device character set.
* @param[in] hints The IrDA device hints.
* @param[in] userdata The user data pointer.
* Opaque object representing an IrDA device.
*/
typedef void (*dc_irda_callback_t) (unsigned int address, const char *name, unsigned int charset, unsigned int hints, void *userdata);
typedef struct dc_irda_device_t dc_irda_device_t;
/**
* Get the address of the IrDA device.
*
* @param[in] device A valid IrDA device.
*/
unsigned int
dc_irda_device_get_address (dc_irda_device_t *device);
/**
* Get the name of the IrDA device.
*
* @param[in] device A valid IrDA device.
*/
const char *
dc_irda_device_get_name (dc_irda_device_t *device);
/**
* Destroy the IrDA device and free all resources.
*
* @param[in] device A valid IrDA device.
*/
void
dc_irda_device_free (dc_irda_device_t *device);
/**
* Create an iterator to enumerate the IrDA devices.
*
* @param[out] iterator A location to store the iterator.
* @param[in] context A valid context object.
* @param[in] descriptor A valid device descriptor or NULL.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_irda_iterator_new (dc_iterator_t **iterator, dc_context_t *context, dc_descriptor_t *descriptor);
/**
* Open an IrDA connection.
*
* @param[out] iostream A location to store the IrDA connection.
* @param[in] context A valid context object.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_irda_open (dc_iostream_t **iostream, dc_context_t *context);
/**
* Enumerate the IrDA devices.
*
* @param[in] iostream A valid IrDA connection.
* @param[in] callback The callback function to call.
* @param[in] userdata User data to pass to the callback function.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_irda_discover (dc_iostream_t *iostream, dc_irda_callback_t callback, void *userdata);
/**
* Connect to an IrDA device.
*
* @param[in] iostream A valid IrDA connection.
* @param[in] address The IrDA device address.
* @param[in] name The IrDA service name.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_irda_connect_name (dc_iostream_t *iostream, unsigned int address, const char *name);
/**
* Connect to an IrDA device.
*
* @param[in] iostream A valid IrDA connection.
* @param[in] address The IrDA device address.
* @param[in] lsap The IrDA LSAP number.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_irda_connect_lsap (dc_iostream_t *iostream, unsigned int address, unsigned int lsap);
dc_irda_open (dc_iostream_t **iostream, dc_context_t *context, unsigned int address, unsigned int lsap);
#ifdef __cplusplus
}

14
src/iterator-private.h
View File

@ -22,6 +22,7 @@
#ifndef DC_ITERATOR_PRIVATE_H
#define DC_ITERATOR_PRIVATE_H
#include <libdivecomputer/context.h>
#include <libdivecomputer/iterator.h>
#ifdef __cplusplus
@ -32,13 +33,24 @@ typedef struct dc_iterator_vtable_t dc_iterator_vtable_t;
struct dc_iterator_t {
const dc_iterator_vtable_t *vtable;
dc_context_t *context;
};
struct dc_iterator_vtable_t {
dc_status_t (*free) (dc_iterator_t *iterator);
size_t size;
dc_status_t (*next) (dc_iterator_t *iterator, void *item);
dc_status_t (*free) (dc_iterator_t *iterator);
};
dc_iterator_t *
dc_iterator_allocate (dc_context_t *context, const dc_iterator_vtable_t *vtable);
void
dc_iterator_deallocate (dc_iterator_t *iterator);
int
dc_iterator_isinstance (dc_iterator_t *iterator, const dc_iterator_vtable_t *vtable);
#ifdef __cplusplus
}
#endif /* __cplusplus */

54
src/iterator.c
View File

@ -21,16 +21,51 @@
#include <stddef.h>
#include <stdlib.h>
#include <assert.h>
#include "context-private.h"
#include "iterator-private.h"
dc_iterator_t *
dc_iterator_allocate (dc_context_t *context, const dc_iterator_vtable_t *vtable)
{
dc_iterator_t *iterator = NULL;
assert(vtable != NULL);
assert(vtable->size >= sizeof(dc_iterator_t));
// Allocate memory.
iterator = (dc_iterator_t *) malloc (vtable->size);
if (iterator == NULL) {
ERROR (context, "Failed to allocate memory.");
return iterator;
}
iterator->vtable = vtable;
iterator->context = context;
return iterator;
}
void
dc_iterator_deallocate (dc_iterator_t *iterator)
{
free (iterator);
}
int
dc_iterator_isinstance (dc_iterator_t *iterator, const dc_iterator_vtable_t *vtable)
{
if (iterator == NULL)
return 0;
return iterator->vtable == vtable;
}
dc_status_t
dc_iterator_next (dc_iterator_t *iterator, void *item)
{
if (iterator == NULL)
return DC_STATUS_UNSUPPORTED;
if (iterator->vtable->next == NULL)
if (iterator == NULL || iterator->vtable->next == NULL)
return DC_STATUS_UNSUPPORTED;
if (item == NULL)
@ -42,11 +77,16 @@ dc_iterator_next (dc_iterator_t *iterator, void *item)
dc_status_t
dc_iterator_free (dc_iterator_t *iterator)
{
dc_status_t status = DC_STATUS_SUCCESS;
if (iterator == NULL)
return DC_STATUS_SUCCESS;
if (iterator->vtable->free == NULL)
return DC_STATUS_UNSUPPORTED;
if (iterator->vtable->free) {
status = iterator->vtable->free (iterator);
}
return iterator->vtable->free (iterator);
dc_iterator_deallocate (iterator);
return status;
}

1
src/libdivecomputer.symbols
View File

@ -35,7 +35,6 @@ dc_descriptor_get_model
dc_descriptor_get_transport
dc_iostream_set_timeout
dc_iostream_set_halfduplex
dc_iostream_set_latency
dc_iostream_set_break
dc_iostream_set_dtr

36
src/oceanic_common.c
View File

@ -32,7 +32,7 @@
#define VTABLE(abstract) ((const oceanic_common_device_vtable_t *) abstract->vtable)
#define RB_LOGBOOK_DISTANCE(a,b,l) ringbuffer_distance (a, b, 0, l->rb_logbook_begin, l->rb_logbook_end)
#define RB_LOGBOOK_DISTANCE(a,b,l) ringbuffer_distance (a, b, 1, l->rb_logbook_begin, l->rb_logbook_end)
#define RB_LOGBOOK_INCR(a,b,l) ringbuffer_increment (a, b, l->rb_logbook_begin, l->rb_logbook_end)
#define RB_PROFILE_DISTANCE(a,b,l) ringbuffer_distance (a, b, 0, l->rb_profile_begin, l->rb_profile_end)
@ -208,31 +208,37 @@ oceanic_common_device_logbook (dc_device_t *abstract, dc_event_progress_t *progr
// Get the logbook pointers.
unsigned int rb_logbook_first = array_uint16_le (pointers + 4);
unsigned int rb_logbook_last = array_uint16_le (pointers + 6);
if (rb_logbook_first < layout->rb_logbook_begin ||
rb_logbook_first >= layout->rb_logbook_end ||
rb_logbook_last < layout->rb_logbook_begin ||
if (rb_logbook_last < layout->rb_logbook_begin ||
rb_logbook_last >= layout->rb_logbook_end)
{
ERROR (abstract->context, "Invalid logbook pointer detected (0x%04x 0x%04x).",
rb_logbook_first, rb_logbook_last);
ERROR (abstract->context, "Invalid logbook end pointer detected (0x%04x).", rb_logbook_last);
return DC_STATUS_DATAFORMAT;
}
// Calculate the end pointer and the number of bytes.
unsigned int rb_logbook_end, rb_logbook_size;
// Calculate the end pointer.
unsigned int rb_logbook_end = 0;
if (layout->pt_mode_global == 0) {
rb_logbook_end = RB_LOGBOOK_INCR (rb_logbook_last, layout->rb_logbook_entry_size, layout);
rb_logbook_size = RB_LOGBOOK_DISTANCE (rb_logbook_first, rb_logbook_last, layout) + layout->rb_logbook_entry_size;
} else {
rb_logbook_end = rb_logbook_last;
rb_logbook_size = RB_LOGBOOK_DISTANCE (rb_logbook_first, rb_logbook_last, layout);
}
// Calculate the number of bytes.
// In a typical ringbuffer implementation with only two begin/end
// pointers, there is no distinction possible between an empty and
// a full ringbuffer. We always consider the ringbuffer full in
// that case, because an empty ringbuffer can be detected by
// inspecting the logbook entries once they are downloaded.
if (rb_logbook_first == rb_logbook_last)
// pointers, there is no distinction possible between an empty and a
// full ringbuffer. We always consider the ringbuffer full in that
// case, because an empty ringbuffer can be detected by inspecting
// the logbook entries once they are downloaded.
unsigned int rb_logbook_size = 0;
if (rb_logbook_first < layout->rb_logbook_begin ||
rb_logbook_first >= layout->rb_logbook_end)
{
// Fall back to downloading the entire logbook ringbuffer as
// workaround for an invalid logbook begin pointer!
ERROR (abstract->context, "Invalid logbook begin pointer detected (0x%04x).", rb_logbook_first);
rb_logbook_size = layout->rb_logbook_end - layout->rb_logbook_begin;
} else {
rb_logbook_size = RB_LOGBOOK_DISTANCE (rb_logbook_first, rb_logbook_end, layout);
}
// Update and emit a progress event.

2
src/parser.c
View File

@ -195,7 +195,7 @@ dc_parser_new2 (dc_parser_t **out, dc_context_t *context, dc_descriptor_t *descr
return dc_parser_new_internal (out, context,
dc_descriptor_get_type (descriptor),
dc_descriptor_get_model (descriptor),
dc_descriptor_get_serial (descriptor),
0,
devtime, systime);
}

1
src/platform.h
View File

@ -35,6 +35,7 @@ extern "C" {
#ifdef _MSC_VER
#define snprintf _snprintf
#define strcasecmp _stricmp
#define strncasecmp _strnicmp
#if _MSC_VER < 1800
// The rint() function is only available in MSVC 2013 and later
// versions. Our replacement macro isn't entirely correct, because the

34
src/serial.h
View File

@ -25,29 +25,45 @@
#include <libdivecomputer/common.h>
#include <libdivecomputer/context.h>
#include <libdivecomputer/iostream.h>
#include <libdivecomputer/iterator.h>
#include <libdivecomputer/descriptor.h>
#ifdef __cplusplus
extern "C" {
#endif /* __cplusplus */
/**
* Serial enumeration callback.
*
* @param[in] name The name of the device node.
* @param[in] userdata The user data pointer.
* Opaque object representing a serial device.
*/
typedef void (*dc_serial_callback_t) (const char *name, void *userdata);
typedef struct dc_serial_device_t dc_serial_device_t;
/**
* Enumerate the serial ports.
* Get the device node of the serial device.
*
* @param[in] callback The callback function to call.
* @param[in] userdata User data to pass to the callback function.
* @param[in] device A valid serial device.
*/
const char *
dc_serial_device_get_name (dc_serial_device_t *device);
/**
* Destroy the serial device and free all resources.
*
* @param[in] device A valid serial device.
*/
void
dc_serial_device_free (dc_serial_device_t *device);
/**
* Create an iterator to enumerate the serial devices.
*
* @param[out] iterator A location to store the iterator.
* @param[in] context A valid context object.
* @param[in] descriptor A valid device descriptor or NULL.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_serial_enumerate (dc_serial_callback_t callback, void *userdata);
dc_serial_iterator_new (dc_iterator_t **iterator, dc_context_t *context, dc_descriptor_t *descriptor);
/**
* Open a serial connection.

249
src/serial_posix.c
View File

@ -30,7 +30,6 @@
#include <fcntl.h> // fcntl
#include <termios.h> // tcgetattr, tcsetattr, cfsetispeed, cfsetospeed, tcflush, tcsendbreak
#include <sys/ioctl.h> // ioctl
#include <sys/time.h> // gettimeofday
#include <time.h> // nanosleep
#ifdef HAVE_LINUX_SERIAL_H
#include <linux/serial.h>
@ -58,10 +57,17 @@
#include "common-private.h"
#include "context-private.h"
#include "iostream-private.h"
#include "iterator-private.h"
#include "descriptor-private.h"
#include "timer.h"
#define DIRNAME "/dev"
static dc_status_t dc_serial_iterator_next (dc_iterator_t *iterator, void *item);
static dc_status_t dc_serial_iterator_free (dc_iterator_t *iterator);
static dc_status_t dc_serial_set_timeout (dc_iostream_t *iostream, int timeout);
static dc_status_t dc_serial_set_latency (dc_iostream_t *iostream, unsigned int value);
static dc_status_t dc_serial_set_halfduplex (dc_iostream_t *iostream, unsigned int value);
static dc_status_t dc_serial_set_break (dc_iostream_t *iostream, unsigned int value);
static dc_status_t dc_serial_set_dtr (dc_iostream_t *iostream, unsigned int value);
static dc_status_t dc_serial_set_rts (dc_iostream_t *iostream, unsigned int value);
@ -75,6 +81,16 @@ static dc_status_t dc_serial_purge (dc_iostream_t *iostream, dc_direction_t dire
static dc_status_t dc_serial_sleep (dc_iostream_t *iostream, unsigned int milliseconds);
static dc_status_t dc_serial_close (dc_iostream_t *iostream);
struct dc_serial_device_t {
char name[256];
};
typedef struct dc_serial_iterator_t {
dc_iterator_t base;
dc_filter_t filter;
DIR *dp;
} dc_serial_iterator_t;
typedef struct dc_serial_t {
dc_iostream_t base;
/*
@ -82,23 +98,25 @@ typedef struct dc_serial_t {
*/
int fd;
int timeout;
dc_timer_t *timer;
/*
* Serial port settings are saved into this variable immediately
* after the port is opened. These settings are restored when the
* serial port is closed.
*/
struct termios tty;
/* Half-duplex settings */
int halfduplex;
unsigned int baudrate;
unsigned int nbits;
} dc_serial_t;
static const dc_iterator_vtable_t dc_serial_iterator_vtable = {
sizeof(dc_serial_iterator_t),
dc_serial_iterator_next,
dc_serial_iterator_free,
};
static const dc_iostream_vtable_t dc_serial_vtable = {
sizeof(dc_serial_t),
dc_serial_set_timeout, /* set_timeout */
dc_serial_set_latency, /* set_latency */
dc_serial_set_halfduplex, /* set_halfduplex */
dc_serial_set_break, /* set_break */
dc_serial_set_dtr, /* set_dtr */
dc_serial_set_rts, /* set_rts */
@ -131,12 +149,62 @@ syserror(int errcode)
}
}
dc_status_t
dc_serial_enumerate (dc_serial_callback_t callback, void *userdata)
const char *
dc_serial_device_get_name (dc_serial_device_t *device)
{
DIR *dp = NULL;
if (device == NULL || device->name[0] == '\0')
return NULL;
return device->name;
}
void
dc_serial_device_free (dc_serial_device_t *device)
{
free (device);
}
dc_status_t
dc_serial_iterator_new (dc_iterator_t **out, dc_context_t *context, dc_descriptor_t *descriptor)
{
dc_status_t status = DC_STATUS_SUCCESS;
dc_serial_iterator_t *iterator = NULL;
if (out == NULL)
return DC_STATUS_INVALIDARGS;
iterator = (dc_serial_iterator_t *) dc_iterator_allocate (context, &dc_serial_iterator_vtable);
if (iterator == NULL) {
SYSERROR (context, ENOMEM);
return DC_STATUS_NOMEMORY;
}
iterator->dp = opendir (DIRNAME);
if (iterator->dp == NULL) {
int errcode = errno;
SYSERROR (context, errcode);
status = syserror (errcode);
goto error_free;
}
iterator->filter = dc_descriptor_get_filter (descriptor);
*out = (dc_iterator_t *) iterator;
return DC_STATUS_SUCCESS;
error_free:
dc_iterator_deallocate ((dc_iterator_t *) iterator);
return status;
}
static dc_status_t
dc_serial_iterator_next (dc_iterator_t *abstract, void *out)
{
dc_serial_iterator_t *iterator = (dc_serial_iterator_t *) abstract;
dc_serial_device_t *device = NULL;
struct dirent *ep = NULL;
const char *dirname = "/dev";
const char *patterns[] = {
#if defined (__APPLE__)
"tty.*",
@ -149,28 +217,44 @@ dc_serial_enumerate (dc_serial_callback_t callback, void *userdata)
NULL
};
dp = opendir (dirname);
if (dp == NULL) {
return DC_STATUS_IO;
}
while ((ep = readdir (dp)) != NULL) {
while ((ep = readdir (iterator->dp)) != NULL) {
for (size_t i = 0; patterns[i] != NULL; ++i) {
if (fnmatch (patterns[i], ep->d_name, 0) == 0) {
char filename[1024];
int n = snprintf (filename, sizeof (filename), "%s/%s", dirname, ep->d_name);
if (n >= sizeof (filename)) {
closedir (dp);
if (fnmatch (patterns[i], ep->d_name, 0) != 0)
continue;
char filename[sizeof(device->name)];
int n = snprintf (filename, sizeof (filename), "%s/%s", DIRNAME, ep->d_name);
if (n < 0 || (size_t) n >= sizeof (filename)) {
return DC_STATUS_NOMEMORY;
}
callback (filename, userdata);
break;
if (iterator->filter && !iterator->filter (DC_TRANSPORT_SERIAL, filename)) {
continue;
}
device = (dc_serial_device_t *) malloc (sizeof(dc_serial_device_t));
if (device == NULL) {
SYSERROR (abstract->context, ENOMEM);
return DC_STATUS_NOMEMORY;
}
strncpy(device->name, filename, sizeof(device->name));
*(dc_serial_device_t **) out = device;
return DC_STATUS_SUCCESS;
}
}
closedir (dp);
return DC_STATUS_DONE;
}
static dc_status_t
dc_serial_iterator_free (dc_iterator_t *abstract)
{
dc_serial_iterator_t *iterator = (dc_serial_iterator_t *) abstract;
closedir (iterator->dp);
return DC_STATUS_SUCCESS;
}
@ -200,10 +284,12 @@ dc_serial_open (dc_iostream_t **out, dc_context_t *context, const char *name)
// Default to blocking reads.
device->timeout = -1;
// Default to full-duplex.
device->halfduplex = 0;
device->baudrate = 0;
device->nbits = 0;
// Create a high resolution timer.
status = dc_timer_new (&device->timer);
if (status != DC_STATUS_SUCCESS) {
ERROR (context, "Failed to create a high resolution timer.");
goto error_free;
}
// Open the device in non-blocking mode, to return immediately
// without waiting for the modem connection to complete.
@ -212,7 +298,7 @@ dc_serial_open (dc_iostream_t **out, dc_context_t *context, const char *name)
int errcode = errno;
SYSERROR (context, errcode);
status = syserror (errcode);
goto error_free;
goto error_timer_free;
}
#ifndef ENABLE_PTY
@ -242,6 +328,8 @@ dc_serial_open (dc_iostream_t **out, dc_context_t *context, const char *name)
error_close:
close (device->fd);
error_timer_free:
dc_timer_free (device->timer);
error_free:
dc_iostream_deallocate ((dc_iostream_t *) device);
return status;
@ -276,6 +364,8 @@ dc_serial_close (dc_iostream_t *abstract)
dc_status_set_error(&status, syserror (errcode));
}
dc_timer_free (device->timer);
return status;
}
@ -522,9 +612,6 @@ dc_serial_configure (dc_iostream_t *abstract, unsigned int baudrate, unsigned in
#endif
}
device->baudrate = baudrate;
device->nbits = 1 + databits + stopbits + (parity ? 1 : 0);
return DC_STATUS_SUCCESS;
}
@ -538,16 +625,6 @@ dc_serial_set_timeout (dc_iostream_t *abstract, int timeout)
return DC_STATUS_SUCCESS;
}
static dc_status_t
dc_serial_set_halfduplex (dc_iostream_t *abstract, unsigned int value)
{
dc_serial_t *device = (dc_serial_t *) abstract;
device->halfduplex = value;
return DC_STATUS_SUCCESS;
}
static dc_status_t
dc_serial_set_latency (dc_iostream_t *abstract, unsigned int milliseconds)
{
@ -597,11 +674,8 @@ dc_serial_read (dc_iostream_t *abstract, void *data, size_t size, size_t *actual
dc_serial_t *device = (dc_serial_t *) abstract;
size_t nbytes = 0;
// The total timeout.
int timeout = device->timeout;
// The absolute target time.
struct timeval tve;
dc_usecs_t target = 0;
int init = 1;
while (nbytes < size) {
@ -609,35 +683,40 @@ dc_serial_read (dc_iostream_t *abstract, void *data, size_t size, size_t *actual
FD_ZERO (&fds);
FD_SET (device->fd, &fds);
struct timeval tvt;
if (timeout > 0) {
struct timeval now;
if (gettimeofday (&now, NULL) != 0) {
int errcode = errno;
SYSERROR (abstract->context, errcode);
status = syserror (errcode);
struct timeval tv, *ptv = NULL;
if (device->timeout > 0) {
dc_usecs_t timeout = 0;
dc_usecs_t now = 0;
status = dc_timer_now (device->timer, &now);
if (status != DC_STATUS_SUCCESS) {
goto out;
}
if (init) {
// Calculate the initial timeout.
tvt.tv_sec = (timeout / 1000);
tvt.tv_usec = (timeout % 1000) * 1000;
timeout = device->timeout * 1000;
// Calculate the target time.
timeradd (&now, &tvt, &tve);
target = now + timeout;
init = 0;
} else {
// Calculate the remaining timeout.
if (timercmp (&now, &tve, <))
timersub (&tve, &now, &tvt);
else
timerclear (&tvt);
if (now < target) {
timeout = target - now;
} else {
timeout = 0;
}
init = 0;
} else if (timeout == 0) {
timerclear (&tvt);
}
tv.tv_sec = timeout / 1000000;
tv.tv_usec = timeout % 1000000;
ptv = &tv;
} else if (device->timeout == 0) {
tv.tv_sec = 0;
tv.tv_usec = 0;
ptv = &tv;
}
int rc = select (device->fd + 1, &fds, NULL, NULL, timeout >= 0 ? &tvt : NULL);
int rc = select (device->fd + 1, &fds, NULL, NULL, ptv);
if (rc < 0) {
int errcode = errno;
if (errcode == EINTR)
@ -682,17 +761,6 @@ dc_serial_write (dc_iostream_t *abstract, const void *data, size_t size, size_t
dc_serial_t *device = (dc_serial_t *) abstract;
size_t nbytes = 0;
struct timeval tve, tvb;
if (device->halfduplex) {
// Get the current time.
if (gettimeofday (&tvb, NULL) != 0) {
int errcode = errno;
SYSERROR (abstract->context, errcode);
status = syserror (errcode);
goto out;
}
}
while (nbytes < size) {
fd_set fds;
FD_ZERO (&fds);
@ -740,35 +808,6 @@ dc_serial_write (dc_iostream_t *abstract, const void *data, size_t size, size_t
}
}
if (device->halfduplex) {
// Get the current time.
if (gettimeofday (&tve, NULL) != 0) {
int errcode = errno;
SYSERROR (abstract->context, errcode);
status = syserror (errcode);
goto out;
}
// Calculate the elapsed time (microseconds).
struct timeval tvt;
timersub (&tve, &tvb, &tvt);
unsigned long elapsed = tvt.tv_sec * 1000000 + tvt.tv_usec;
// Calculate the expected duration (microseconds). A 2 millisecond fudge
// factor is added because it improves the success rate significantly.
unsigned long expected = 1000000.0 * device->nbits / device->baudrate * size + 0.5 + 2000;
// Wait for the remaining time.
if (elapsed < expected) {
unsigned long remaining = expected - elapsed;
// The remaining time is rounded up to the nearest millisecond to
// match the Windows implementation. The higher resolution is
// pointless anyway, since we already added a fudge factor above.
dc_serial_sleep (abstract, (remaining + 999) / 1000);
}
}
out:
if (actual)
*actual = nbytes;

203
src/serial_win32.c
View File

@ -29,10 +29,14 @@
#include "common-private.h"
#include "context-private.h"
#include "iostream-private.h"
#include "iterator-private.h"
#include "descriptor-private.h"
static dc_status_t dc_serial_iterator_next (dc_iterator_t *iterator, void *item);
static dc_status_t dc_serial_iterator_free (dc_iterator_t *iterator);
static dc_status_t dc_serial_set_timeout (dc_iostream_t *iostream, int timeout);
static dc_status_t dc_serial_set_latency (dc_iostream_t *iostream, unsigned int value);
static dc_status_t dc_serial_set_halfduplex (dc_iostream_t *iostream, unsigned int value);
static dc_status_t dc_serial_set_break (dc_iostream_t *iostream, unsigned int value);
static dc_status_t dc_serial_set_dtr (dc_iostream_t *iostream, unsigned int value);
static dc_status_t dc_serial_set_rts (dc_iostream_t *iostream, unsigned int value);
@ -46,6 +50,18 @@ static dc_status_t dc_serial_purge (dc_iostream_t *iostream, dc_direction_t dire
static dc_status_t dc_serial_sleep (dc_iostream_t *iostream, unsigned int milliseconds);
static dc_status_t dc_serial_close (dc_iostream_t *iostream);
struct dc_serial_device_t {
char name[256];
};
typedef struct dc_serial_iterator_t {
dc_iterator_t base;
dc_filter_t filter;
HKEY hKey;
DWORD count;
DWORD current;
} dc_serial_iterator_t;
typedef struct dc_serial_t {
dc_iostream_t base;
/*
@ -59,17 +75,18 @@ typedef struct dc_serial_t {
*/
DCB dcb;
COMMTIMEOUTS timeouts;
/* Half-duplex settings */
int halfduplex;
unsigned int baudrate;
unsigned int nbits;
} dc_serial_t;
static const dc_iterator_vtable_t dc_serial_iterator_vtable = {
sizeof(dc_serial_iterator_t),
dc_serial_iterator_next,
dc_serial_iterator_free,
};
static const dc_iostream_vtable_t dc_serial_vtable = {
sizeof(dc_serial_t),
dc_serial_set_timeout, /* set_timeout */
dc_serial_set_latency, /* set_latency */
dc_serial_set_halfduplex, /* set_halfduplex */
dc_serial_set_break, /* set_break */
dc_serial_set_dtr, /* set_dtr */
dc_serial_set_rts, /* set_rts */
@ -101,37 +118,93 @@ syserror(DWORD errcode)
}
}
dc_status_t
dc_serial_enumerate (dc_serial_callback_t callback, void *userdata)
const char *
dc_serial_device_get_name (dc_serial_device_t *device)
{
if (device == NULL || device->name[0] == '\0')
return NULL;
return device->name;
}
void
dc_serial_device_free (dc_serial_device_t *device)
{
free (device);
}
dc_status_t
dc_serial_iterator_new (dc_iterator_t **out, dc_context_t *context, dc_descriptor_t *descriptor)
{
dc_status_t status = DC_STATUS_SUCCESS;
dc_serial_iterator_t *iterator = NULL;
HKEY hKey = NULL;
DWORD count = 0;
LONG rc = 0;
if (out == NULL)
return DC_STATUS_INVALIDARGS;
iterator = (dc_serial_iterator_t *) dc_iterator_allocate (context, &dc_serial_iterator_vtable);
if (iterator == NULL) {
SYSERROR (context, ERROR_OUTOFMEMORY);
return DC_STATUS_NOMEMORY;
}
// Open the registry key.
HKEY hKey;
LONG rc = RegOpenKeyExA (HKEY_LOCAL_MACHINE, "HARDWARE\\DEVICEMAP\\SERIALCOMM", 0, KEY_QUERY_VALUE, &hKey);
rc = RegOpenKeyExA (HKEY_LOCAL_MACHINE, "HARDWARE\\DEVICEMAP\\SERIALCOMM", 0, KEY_QUERY_VALUE, &hKey);
if (rc != ERROR_SUCCESS) {
if (rc == ERROR_FILE_NOT_FOUND)
return DC_STATUS_SUCCESS;
else
return DC_STATUS_IO;
if (rc == ERROR_FILE_NOT_FOUND) {
hKey = NULL;
} else {
SYSERROR (context, rc);
status = syserror (rc);
goto error_free;
}
}
// Get the number of values.
DWORD count = 0;
if (hKey) {
rc = RegQueryInfoKey (hKey, NULL, NULL, NULL, NULL, NULL, NULL, &count, NULL, NULL, NULL, NULL);
if (rc != ERROR_SUCCESS) {
RegCloseKey(hKey);
return DC_STATUS_IO;
SYSERROR (context, rc);
status = syserror (rc);
goto error_close;
}
}
for (DWORD i = 0; i < count; ++i) {
iterator->filter = dc_descriptor_get_filter (descriptor);
iterator->hKey = hKey;
iterator->count = count;
iterator->current = 0;
*out = (dc_iterator_t *) iterator;
return DC_STATUS_SUCCESS;
error_close:
RegCloseKey (hKey);
error_free:
dc_iterator_deallocate ((dc_iterator_t *) iterator);
return status;
}
static dc_status_t
dc_serial_iterator_next (dc_iterator_t *abstract, void *out)
{
dc_serial_iterator_t *iterator = (dc_serial_iterator_t *) abstract;
dc_serial_device_t *device = NULL;
while (iterator->current < iterator->count) {
// Get the value name, data and type.
char name[512], data[512];
char name[256], data[sizeof(device->name)];
DWORD name_len = sizeof (name);
DWORD data_len = sizeof (data);
DWORD type = 0;
rc = RegEnumValueA (hKey, i, name, &name_len, NULL, &type, (LPBYTE) data, &data_len);
LONG rc = RegEnumValueA (iterator->hKey, iterator->current++, name, &name_len, NULL, &type, (LPBYTE) data, &data_len);
if (rc != ERROR_SUCCESS) {
RegCloseKey(hKey);
return DC_STATUS_IO;
SYSERROR (abstract->context, rc);
return syserror (rc);
}
// Ignore non-string values.
@ -140,17 +213,40 @@ dc_serial_enumerate (dc_serial_callback_t callback, void *userdata)
// Prevent a possible buffer overflow.
if (data_len >= sizeof (data)) {
RegCloseKey(hKey);
return DC_STATUS_NOMEMORY;
}
// Null terminate the string.
data[data_len] = 0;
callback (data, userdata);
if (iterator->filter && !iterator->filter (DC_TRANSPORT_SERIAL, data)) {
continue;
}
RegCloseKey(hKey);
device = (dc_serial_device_t *) malloc (sizeof(dc_serial_device_t));
if (device == NULL) {
SYSERROR (abstract->context, ERROR_OUTOFMEMORY);
return DC_STATUS_NOMEMORY;
}
strncpy(device->name, data, sizeof(device->name));
*(dc_serial_device_t **) out = device;
return DC_STATUS_SUCCESS;
}
return DC_STATUS_DONE;
}
static dc_status_t
dc_serial_iterator_free (dc_iterator_t *abstract)
{
dc_serial_iterator_t *iterator = (dc_serial_iterator_t *) abstract;
if (iterator->hKey) {
RegCloseKey (iterator->hKey);
}
return DC_STATUS_SUCCESS;
}
@ -190,11 +286,6 @@ dc_serial_open (dc_iostream_t **out, dc_context_t *context, const char *name)
return DC_STATUS_NOMEMORY;
}
// Default to full-duplex.
device->halfduplex = 0;
device->baudrate = 0;
device->nbits = 0;
// Open the device.
device->hFile = CreateFileA (devname,
GENERIC_READ | GENERIC_WRITE, 0,
@ -359,9 +450,6 @@ dc_serial_configure (dc_iostream_t *abstract, unsigned int baudrate, unsigned in
return syserror (errcode);
}
device->baudrate = baudrate;
device->nbits = 1 + databits + stopbits + (parity ? 1 : 0);
return DC_STATUS_SUCCESS;
}
@ -412,16 +500,6 @@ dc_serial_set_timeout (dc_iostream_t *abstract, int timeout)
return DC_STATUS_SUCCESS;
}
static dc_status_t
dc_serial_set_halfduplex (dc_iostream_t *abstract, unsigned int value)
{
dc_serial_t *device = (dc_serial_t *) abstract;
device->halfduplex = value;
return DC_STATUS_SUCCESS;
}
static dc_status_t
dc_serial_set_latency (dc_iostream_t *abstract, unsigned int value)
{
@ -460,18 +538,6 @@ dc_serial_write (dc_iostream_t *abstract, const void *data, size_t size, size_t
dc_serial_t *device = (dc_serial_t *) abstract;
DWORD dwWritten = 0;
LARGE_INTEGER begin, end, freq;
if (device->halfduplex) {
// Get the current time.
if (!QueryPerformanceFrequency(&freq) ||
!QueryPerformanceCounter(&begin)) {
DWORD errcode = GetLastError ();
SYSERROR (abstract->context, errcode);
status = syserror (errcode);
goto out;
}
}
if (!WriteFile (device->hFile, data, size, &dwWritten, NULL)) {
DWORD errcode = GetLastError ();
SYSERROR (abstract->context, errcode);
@ -479,33 +545,6 @@ dc_serial_write (dc_iostream_t *abstract, const void *data, size_t size, size_t
goto out;
}
if (device->halfduplex) {
// Get the current time.
if (!QueryPerformanceCounter(&end)) {
DWORD errcode = GetLastError ();
SYSERROR (abstract->context, errcode);
status = syserror (errcode);
goto out;
}
// Calculate the elapsed time (microseconds).
unsigned long elapsed = 1000000.0 * (end.QuadPart - begin.QuadPart) / freq.QuadPart + 0.5;
// Calculate the expected duration (microseconds). A 2 millisecond fudge
// factor is added because it improves the success rate significantly.
unsigned long expected = 1000000.0 * device->nbits / device->baudrate * size + 0.5 + 2000;
// Wait for the remaining time.
if (elapsed < expected) {
unsigned long remaining = expected - elapsed;
// The remaining time is rounded up to the nearest millisecond
// because the Windows Sleep() function doesn't have a higher
// resolution.
dc_serial_sleep (abstract, (remaining + 999) / 1000);
}
}
if (dwWritten != size) {
status = DC_STATUS_TIMEOUT;
}

2
src/shearwater_predator_parser.c
View File

@ -494,7 +494,7 @@ shearwater_predator_parser_cache (shearwater_predator_parser_t *parser)
nsensors++;
}
}
if (nsensors == ndefaults) {
if (nsensors && nsensors == ndefaults) {
// If all (calibrated) sensors still have their factory default
// calibration values (2100), they are probably not calibrated
// properly. To avoid returning incorrect ppO2 values to the

6
src/socket.c
View File

@ -169,12 +169,6 @@ dc_socket_set_latency (dc_iostream_t *iostream, unsigned int value)
return DC_STATUS_SUCCESS;
}
dc_status_t
dc_socket_set_halfduplex (dc_iostream_t *iostream, unsigned int value)
{
return DC_STATUS_SUCCESS;
}
dc_status_t
dc_socket_set_break (dc_iostream_t *iostream, unsigned int value)
{

3
src/socket.h
View File

@ -107,9 +107,6 @@ dc_socket_set_timeout (dc_iostream_t *iostream, int timeout);
dc_status_t
dc_socket_set_latency (dc_iostream_t *iostream, unsigned int value);
dc_status_t
dc_socket_set_halfduplex (dc_iostream_t *iostream, unsigned int value);
dc_status_t
dc_socket_set_break (dc_iostream_t *iostream, unsigned int value);

2
src/suunto_eonsteel_parser.c
View File

@ -1462,6 +1462,8 @@ static int traverse_sample_fields(suunto_eonsteel_parser_t *eon, const struct ty
set_depth_field(eon, array_uint16_le(data));
data += 2;
continue;
default:
break;
}
break;
}

57
src/suunto_vyper2.c
View File

@ -28,6 +28,7 @@
#include "serial.h"
#include "checksum.h"
#include "array.h"
#include "timer.h"
#define ISINSTANCE(device) dc_device_isinstance((device), (const dc_device_vtable_t *) &suunto_vyper2_device_vtable)
@ -36,6 +37,7 @@
typedef struct suunto_vyper2_device_t {
suunto_common2_device_t base;
dc_iostream_t *iostream;
dc_timer_t *timer;
} suunto_vyper2_device_t;
static dc_status_t suunto_vyper2_device_packet (dc_device_t *abstract, const unsigned char command[], unsigned int csize, unsigned char answer[], unsigned int asize, unsigned int size);
@ -95,11 +97,18 @@ suunto_vyper2_device_open (dc_device_t **out, dc_context_t *context, const char
// Set the default values.
device->iostream = NULL;
// Create a high resolution timer.
status = dc_timer_new (&device->timer);
if (status != DC_STATUS_SUCCESS) {
ERROR (context, "Failed to create a high resolution timer.");
goto error_free;
}
// 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;
goto error_timer_free;
}
// Set the serial communication protocol (9600 8N1).
@ -133,13 +142,6 @@ suunto_vyper2_device_open (dc_device_t **out, dc_context_t *context, const char
goto error_close;
}
// Enable half-duplex emulation.
status = dc_iostream_set_halfduplex (device->iostream, 1);
if (status != DC_STATUS_SUCCESS) {
ERROR (context, "Failed to set half duplex.");
goto error_close;
}
// Read the version info.
status = suunto_common2_device_version ((dc_device_t *) device, device->base.version, sizeof (device->base.version));
if (status != DC_STATUS_SUCCESS) {
@ -160,6 +162,8 @@ suunto_vyper2_device_open (dc_device_t **out, dc_context_t *context, const char
error_close:
dc_iostream_close (device->iostream);
error_timer_free:
dc_timer_free (device->timer);
error_free:
dc_device_deallocate ((dc_device_t *) device);
return status;
@ -173,6 +177,8 @@ suunto_vyper2_device_close (dc_device_t *abstract)
suunto_vyper2_device_t *device = (suunto_vyper2_device_t*) abstract;
dc_status_t rc = DC_STATUS_SUCCESS;
dc_timer_free (device->timer);
// Close the device.
rc = dc_iostream_close (device->iostream);
if (rc != DC_STATUS_SUCCESS) {
@ -201,6 +207,13 @@ suunto_vyper2_device_packet (dc_device_t *abstract, const unsigned char command[
return status;
}
// Get the current timestamp.
dc_usecs_t begin = 0;
status = dc_timer_now (device->timer, &begin);
if (status != DC_STATUS_SUCCESS) {
return status;
}
// Send the command to the dive computer.
status = dc_iostream_write (device->iostream, command, csize, NULL);
if (status != DC_STATUS_SUCCESS) {
@ -208,6 +221,34 @@ suunto_vyper2_device_packet (dc_device_t *abstract, const unsigned char command[
return status;
}
// Get the current timestamp.
dc_usecs_t end = 0;
status = dc_timer_now (device->timer, &end);
if (status != DC_STATUS_SUCCESS) {
return status;
}
// Calculate the elapsed time.
dc_usecs_t elapsed = end - begin;
// Calculate the expected duration. A 2 millisecond fudge factor is added
// because it improves the success rate significantly.
unsigned int baudrate = 9600;
unsigned int nbits = 1 + 8 /* databits */ + 1 /* stopbits */ + 0 /* parity */;
dc_usecs_t expected = (dc_usecs_t) csize * 1000000 * nbits / baudrate + 2000;
// Wait for the remaining time.
if (elapsed < expected) {
dc_usecs_t remaining = expected - elapsed;
// The remaining time is rounded up to the nearest millisecond
// because the sleep function doesn't support a higher
// resolution on all platforms. The higher resolution is
// pointless anyway, since we already added a fudge factor
// above.
dc_iostream_sleep (device->iostream, (remaining + 999) / 1000);
}
// Clear RTS to receive the reply.
status = dc_iostream_set_rts (device->iostream, 0);
if (status != DC_STATUS_SUCCESS) {

161
src/timer.c Normal file
View File

@ -0,0 +1,161 @@
/*
* libdivecomputer
*
* Copyright (C) 2018 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
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <stdlib.h>
#ifdef _WIN32
#define NOGDI
#include <windows.h>
#else
#include <time.h>
#include <sys/time.h>
#ifdef HAVE_MACH_MACH_TIME_H
#include <mach/mach_time.h>
#endif
#endif
#include "timer.h"
struct dc_timer_t {
#if defined (_WIN32)
LARGE_INTEGER timestamp;
LARGE_INTEGER frequency;
#elif defined (HAVE_CLOCK_GETTIME)
struct timespec timestamp;
#elif defined (HAVE_MACH_ABSOLUTE_TIME)
uint64_t timestamp;
mach_timebase_info_data_t info;
#else
struct timeval timestamp;
#endif
};
dc_status_t
dc_timer_new (dc_timer_t **out)
{
dc_timer_t *timer = NULL;
if (out == NULL)
return DC_STATUS_INVALIDARGS;
timer = (dc_timer_t *) malloc (sizeof (dc_timer_t));
if (timer == NULL) {
return DC_STATUS_NOMEMORY;
}
#if defined (_WIN32)
if (!QueryPerformanceFrequency(&timer->frequency) ||
!QueryPerformanceCounter(&timer->timestamp)) {
free(timer);
return DC_STATUS_IO;
}
#elif defined (HAVE_CLOCK_GETTIME)
if (clock_gettime(CLOCK_MONOTONIC, &timer->timestamp) != 0) {
free(timer);
return DC_STATUS_IO;
}
#elif defined (HAVE_MACH_ABSOLUTE_TIME)
if (mach_timebase_info(&timer->info) != KERN_SUCCESS) {
free(timer);
return DC_STATUS_IO;
}
timer->timestamp = mach_absolute_time();
#else
if (gettimeofday (&timer->timestamp, NULL) != 0) {
free(timer);
return DC_STATUS_IO;
}
#endif
*out = timer;
return DC_STATUS_SUCCESS;
}
dc_status_t
dc_timer_now (dc_timer_t *timer, dc_usecs_t *usecs)
{
dc_status_t status = DC_STATUS_SUCCESS;
dc_usecs_t value = 0;
if (timer == NULL) {
status = DC_STATUS_INVALIDARGS;
goto out;
}
#if defined (_WIN32)
LARGE_INTEGER now;
if (!QueryPerformanceCounter(&now)) {
status = DC_STATUS_IO;
goto out;
}
value = (now.QuadPart - timer->timestamp.QuadPart) * 1000000 / timer->frequency.QuadPart;
#elif defined (HAVE_CLOCK_GETTIME)
struct timespec now, delta;
if (clock_gettime(CLOCK_MONOTONIC, &now) != 0) {
status = DC_STATUS_IO;
goto out;
}
if (now.tv_nsec < timer->timestamp.tv_nsec) {
delta.tv_nsec = 1000000000 + now.tv_nsec - timer->timestamp.tv_nsec;
delta.tv_sec = now.tv_sec - timer->timestamp.tv_sec - 1;
} else {
delta.tv_nsec = now.tv_nsec - timer->timestamp.tv_nsec;
delta.tv_sec = now.tv_sec - timer->timestamp.tv_sec;
}
value = (dc_usecs_t) delta.tv_sec * 1000000 + delta.tv_nsec / 1000;
#elif defined (HAVE_MACH_ABSOLUTE_TIME)
uint64_t now = mach_absolute_time();
value = (now - timer->timestamp) * timer->info.numer / timer->info.denom;
#else
struct timeval now, delta;
if (gettimeofday (&now, NULL) != 0) {
status = DC_STATUS_IO;
goto out;
}
timersub (&now, &timer->timestamp, &delta);
value = (dc_usecs_t) delta.tv_sec * 1000000 + delta.tv_usec;
#endif
out:
if (usecs)
*usecs = value;
return status;
}
dc_status_t
dc_timer_free (dc_timer_t *timer)
{
free (timer);
return DC_STATUS_SUCCESS;
}

51
src/timer.h Normal file
View File

@ -0,0 +1,51 @@
/*
* libdivecomputer
*
* Copyright (C) 2018 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
*/
#ifndef DC_TIMER_H
#define DC_TIMER_H
#include <libdivecomputer/common.h>
#ifdef __cplusplus
extern "C" {
#endif /* __cplusplus */
#if defined (_WIN32) && !defined (__GNUC__)
typedef unsigned __int64 dc_usecs_t;
#else
typedef unsigned long long dc_usecs_t;
#endif
typedef struct dc_timer_t dc_timer_t;
dc_status_t
dc_timer_new (dc_timer_t **timer);
dc_status_t
dc_timer_now (dc_timer_t *timer, dc_usecs_t *usecs);
dc_status_t
dc_timer_free (dc_timer_t *timer);
#ifdef __cplusplus
}
#endif /* __cplusplus */
#endif /* DC_TIMER_H */

251
src/usbhid.c
View File

@ -54,6 +54,8 @@
#include "common-private.h"
#include "context-private.h"
#include "iostream-private.h"
#include "descriptor-private.h"
#include "iterator-private.h"
#include "platform.h"
#ifdef _WIN32
@ -66,12 +68,31 @@ typedef pthread_mutex_t dc_mutex_t;
#define ISINSTANCE(device) dc_iostream_isinstance((device), &dc_usbhid_vtable)
struct dc_usbhid_device_t {
unsigned short vid, pid;
};
#ifdef USBHID
static dc_status_t dc_usbhid_iterator_next (dc_iterator_t *iterator, void *item);
static dc_status_t dc_usbhid_iterator_free (dc_iterator_t *iterator);
static dc_status_t dc_usbhid_set_timeout (dc_iostream_t *iostream, int timeout);
static dc_status_t dc_usbhid_read (dc_iostream_t *iostream, void *data, size_t size, size_t *actual);
static dc_status_t dc_usbhid_write (dc_iostream_t *iostream, const void *data, size_t size, size_t *actual);
static dc_status_t dc_usbhid_close (dc_iostream_t *iostream);
typedef struct dc_usbhid_iterator_t {
dc_iterator_t base;
dc_filter_t filter;
#if defined(USE_LIBUSB)
struct libusb_device **devices;
size_t count;
size_t current;
#elif defined(USE_HIDAPI)
struct hid_device_info *devices, *current;
#endif
} dc_usbhid_iterator_t;
typedef struct dc_usbhid_t {
/* Base class. */
dc_iostream_t base;
@ -88,11 +109,16 @@ typedef struct dc_usbhid_t {
#endif
} dc_usbhid_t;
static const dc_iterator_vtable_t dc_usbhid_iterator_vtable = {
sizeof(dc_usbhid_iterator_t),
dc_usbhid_iterator_next,
dc_usbhid_iterator_free,
};
static const dc_iostream_vtable_t dc_usbhid_vtable = {
sizeof(dc_usbhid_t),
dc_usbhid_set_timeout, /* set_timeout */
NULL, /* set_latency */
NULL, /* set_halfduplex */
NULL, /* set_break */
NULL, /* set_dtr */
NULL, /* set_rts */
@ -286,6 +312,229 @@ dc_usbhid_exit (void)
}
#endif
unsigned int
dc_usbhid_device_get_vid (dc_usbhid_device_t *device)
{
if (device == NULL)
return 0;
return device->vid;
}
unsigned int
dc_usbhid_device_get_pid (dc_usbhid_device_t *device)
{
if (device == NULL)
return 0;
return device->pid;
}
void
dc_usbhid_device_free(dc_usbhid_device_t *device)
{
free (device);
}
dc_status_t
dc_usbhid_iterator_new (dc_iterator_t **out, dc_context_t *context, dc_descriptor_t *descriptor)
{
#ifdef USBHID
dc_status_t status = DC_STATUS_SUCCESS;
dc_usbhid_iterator_t *iterator = NULL;
if (out == NULL)
return DC_STATUS_INVALIDARGS;
iterator = (dc_usbhid_iterator_t *) dc_iterator_allocate (context, &dc_usbhid_iterator_vtable);
if (iterator == NULL) {
ERROR (context, "Failed to allocate memory.");
return DC_STATUS_NOMEMORY;
}
// Initialize the usb library.
status = dc_usbhid_init (context);
if (status != DC_STATUS_SUCCESS) {
goto error_free;
}
#if defined(USE_LIBUSB)
// Enumerate the USB devices.
struct libusb_device **devices = NULL;
ssize_t ndevices = libusb_get_device_list (g_usbhid_ctx, &devices);
if (ndevices < 0) {
ERROR (context, "Failed to enumerate the usb devices (%s).",
libusb_error_name (ndevices));
status = syserror (ndevices);
goto error_usb_exit;
}
iterator->devices = devices;
iterator->count = ndevices;
iterator->current = 0;
#elif defined(USE_HIDAPI)
struct hid_device_info *devices = hid_enumerate(0x0, 0x0);
if (devices == NULL) {
status = DC_STATUS_IO;
goto error_usb_exit;
}
iterator->devices = devices;
iterator->current = devices;
#endif
iterator->filter = dc_descriptor_get_filter (descriptor);
*out = (dc_iterator_t *) iterator;
return DC_STATUS_SUCCESS;
error_usb_exit:
dc_usbhid_exit ();
error_free:
dc_iterator_deallocate ((dc_iterator_t *) iterator);
return status;
#else
return DC_STATUS_UNSUPPORTED;
#endif
}
#ifdef USBHID
static dc_status_t
dc_usbhid_iterator_next (dc_iterator_t *abstract, void *out)
{
dc_usbhid_iterator_t *iterator = (dc_usbhid_iterator_t *) abstract;
dc_usbhid_device_t *device = NULL;
#if defined(USE_LIBUSB)
while (iterator->current < iterator->count) {
struct libusb_device *current = iterator->devices[iterator->current++];
// Get the device descriptor.
struct libusb_device_descriptor dev;
int rc = libusb_get_device_descriptor (current, &dev);
if (rc < 0) {
ERROR (abstract->context, "Failed to get the device descriptor (%s).",
libusb_error_name (rc));
return syserror (rc);
}
dc_usb_desc_t usb = {dev.idVendor, dev.idProduct};
if (iterator->filter && !iterator->filter (DC_TRANSPORT_USBHID, &usb)) {
continue;
}
// Get the active configuration descriptor.
struct libusb_config_descriptor *config = NULL;
rc = libusb_get_active_config_descriptor (current, &config);
if (rc != LIBUSB_SUCCESS) {
ERROR (abstract->context, "Failed to get the configuration descriptor (%s).",
libusb_error_name (rc));
return syserror (rc);
}
// Find the first HID interface.
const struct libusb_interface_descriptor *interface = NULL;
for (unsigned int i = 0; i < config->bNumInterfaces; i++) {
const struct libusb_interface *iface = &config->interface[i];
for (int j = 0; j < iface->num_altsetting; j++) {
const struct libusb_interface_descriptor *desc = &iface->altsetting[j];
if (desc->bInterfaceClass == LIBUSB_CLASS_HID && interface == NULL) {
interface = desc;
}
}
}
if (interface == NULL) {
libusb_free_config_descriptor (config);
continue;
}
// Find the first input and output interrupt endpoints.
const struct libusb_endpoint_descriptor *ep_in = NULL, *ep_out = NULL;
for (unsigned int i = 0; i < interface->bNumEndpoints; i++) {
const struct libusb_endpoint_descriptor *desc = &interface->endpoint[i];
unsigned int type = desc->bmAttributes & LIBUSB_TRANSFER_TYPE_MASK;
unsigned int direction = desc->bEndpointAddress & LIBUSB_ENDPOINT_DIR_MASK;
if (type != LIBUSB_TRANSFER_TYPE_INTERRUPT) {
continue;
}
if (direction == LIBUSB_ENDPOINT_IN && ep_in == NULL) {
ep_in = desc;
}
if (direction == LIBUSB_ENDPOINT_OUT && ep_out == NULL) {
ep_out = desc;
}
}
if (ep_in == NULL || ep_out == NULL) {
libusb_free_config_descriptor (config);
continue;
}
device = (dc_usbhid_device_t *) malloc (sizeof(dc_usbhid_device_t));
if (device == NULL) {
ERROR (abstract->context, "Failed to allocate memory.");
libusb_free_config_descriptor (config);
return DC_STATUS_NOMEMORY;
}
device->vid = dev.idVendor;
device->pid = dev.idProduct;
*(dc_usbhid_device_t **) out = device;
libusb_free_config_descriptor (config);
return DC_STATUS_SUCCESS;
}
#elif defined(USE_HIDAPI)
while (iterator->current) {
struct hid_device_info *current = iterator->current;
iterator->current = current->next;
dc_usb_desc_t usb = {current->vendor_id, current->product_id};
if (iterator->filter && !iterator->filter (DC_TRANSPORT_USBHID, &usb)) {
continue;
}
device = (dc_usbhid_device_t *) malloc (sizeof(dc_usbhid_device_t));
if (device == NULL) {
ERROR (abstract->context, "Failed to allocate memory.");
return DC_STATUS_NOMEMORY;
}
device->vid = current->vendor_id;
device->pid = current->product_id;
*(dc_usbhid_device_t **) out = device;
return DC_STATUS_SUCCESS;
}
#endif
return DC_STATUS_DONE;
}
static dc_status_t
dc_usbhid_iterator_free (dc_iterator_t *abstract)
{
dc_usbhid_iterator_t *iterator = (dc_usbhid_iterator_t *) abstract;
#if defined(USE_LIBUSB)
libusb_free_device_list (iterator->devices, 1);
#elif defined(USE_HIDAPI)
hid_free_enumeration (iterator->devices);
#endif
dc_usbhid_exit ();
return DC_STATUS_SUCCESS;
}
#endif
dc_status_t
dc_usbhid_open (dc_iostream_t **out, dc_context_t *context, unsigned int vid, unsigned int pid)
{

43
src/usbhid.h
View File

@ -25,11 +25,54 @@
#include <libdivecomputer/common.h>
#include <libdivecomputer/context.h>
#include <libdivecomputer/iostream.h>
#include <libdivecomputer/iterator.h>
#include <libdivecomputer/descriptor.h>
#ifdef __cplusplus
extern "C" {
#endif /* __cplusplus */
/**
* Opaque object representing a USB HID device.
*/
typedef struct dc_usbhid_device_t dc_usbhid_device_t;
/**
* Get the vendor id (VID) of the USB HID device.
*
* @param[in] device A valid USB HID device.
*/
unsigned int
dc_usbhid_device_get_vid (dc_usbhid_device_t *device);
/**
* Get the product id (PID) of the USB HID device.
*
* @param[in] device A valid USB HID device.
*/
unsigned int
dc_usbhid_device_get_pid (dc_usbhid_device_t *device);
/**
* Destroy the USB HID device and free all resources.
*
* @param[in] device A valid USB HID device.
*/
void
dc_usbhid_device_free(dc_usbhid_device_t *device);
/**
* Create an iterator to enumerate the USB HID devices.
*
* @param[out] iterator A location to store the iterator.
* @param[in] context A valid context object.
* @param[in] descriptor A valid device descriptor or NULL.
* @returns #DC_STATUS_SUCCESS on success, or another #dc_status_t code
* on failure.
*/
dc_status_t
dc_usbhid_iterator_new (dc_iterator_t **iterator, dc_context_t *context, dc_descriptor_t *descriptor);
/**
* Open a USB HID connection.
*

63
src/uwatec_smart.c
View File

@ -36,7 +36,6 @@
typedef struct uwatec_smart_device_t {
dc_device_t base;
dc_iostream_t *iostream;
unsigned int address;
unsigned int timestamp;
unsigned int devtime;
dc_ticks_t systime;
@ -62,8 +61,8 @@ static const dc_device_vtable_t uwatec_smart_device_vtable = {
static dc_status_t
uwatec_smart_extract_dives (dc_device_t *device, const unsigned char data[], unsigned int size, dc_dive_callback_t callback, void *userdata);
static void
uwatec_smart_discovery (unsigned int address, const char *name, unsigned int charset, unsigned int hints, void *userdata)
static int
uwatec_smart_filter (const char *name)
{
static const char *names[] = {
"Aladin Smart Com",
@ -75,16 +74,16 @@ uwatec_smart_discovery (unsigned int address, const char *name, unsigned int cha
"UWATEC Galileo Sol",
};
uwatec_smart_device_t *device = (uwatec_smart_device_t*) userdata;
if (device == NULL || name == NULL)
return;
if (name == NULL)
return 0;
for (size_t i = 0; i < C_ARRAY_SIZE(names); ++i) {
if (strcasecmp(name, names[i]) == 0) {
device->address = address;
return;
return 1;
}
}
return 0;
}
@ -152,6 +151,8 @@ uwatec_smart_device_open (dc_device_t **out, dc_context_t *context)
{
dc_status_t status = DC_STATUS_SUCCESS;
uwatec_smart_device_t *device = NULL;
dc_iterator_t *iterator = NULL;
dc_irda_device_t *dev = NULL;
if (out == NULL)
return DC_STATUS_INVALIDARGS;
@ -165,36 +166,44 @@ uwatec_smart_device_open (dc_device_t **out, dc_context_t *context)
// Set the default values.
device->iostream = NULL;
device->address = 0;
device->timestamp = 0;
device->systime = (dc_ticks_t) -1;
device->devtime = 0;
// Open the irda socket.
status = dc_irda_open (&device->iostream, context);
// Create the irda device iterator.
status = dc_irda_iterator_new (&iterator, context, NULL);
if (status != DC_STATUS_SUCCESS) {
ERROR (context, "Failed to open the irda socket.");
ERROR (context, "Failed to create the irda iterator.");
goto error_free;
}
// Discover the device.
status = dc_irda_discover (device->iostream, uwatec_smart_discovery, device);
// Enumerate the irda devices.
while (1) {
dc_irda_device_t *current = NULL;
status = dc_iterator_next (iterator, &current);
if (status != DC_STATUS_SUCCESS) {
ERROR (context, "Failed to discover the device.");
goto error_close;
}
if (device->address == 0) {
if (status == DC_STATUS_DONE) {
ERROR (context, "No dive computer found.");
status = DC_STATUS_IO;
goto error_close;
status = DC_STATUS_NODEVICE;
} else {
ERROR (context, "Failed to enumerate the irda devices.");
}
goto error_iterator_free;
}
// Connect the device.
status = dc_irda_connect_lsap (device->iostream, device->address, 1);
if (uwatec_smart_filter (dc_irda_device_get_name (current))) {
dev = current;
break;
}
dc_irda_device_free (current);
}
// Open the irda socket.
status = dc_irda_open (&device->iostream, context, dc_irda_device_get_address (dev), 1);
if (status != DC_STATUS_SUCCESS) {
ERROR (context, "Failed to connect the device.");
goto error_close;
ERROR (context, "Failed to open the irda socket.");
goto error_device_free;
}
// Perform the handshaking.
@ -210,6 +219,10 @@ uwatec_smart_device_open (dc_device_t **out, dc_context_t *context)
error_close:
dc_iostream_close (device->iostream);
error_device_free:
dc_irda_device_free (dev);
error_iterator_free:
dc_iterator_free (iterator);
error_free:
dc_device_deallocate ((dc_device_t *) device);
return status;