ftdi.c - description
-------------------
begin : Fri Apr 4 2003
- copyright : (C) 2003-2008 by Intra2net AG
+ copyright : (C) 2003-2010 by Intra2net AG
email : opensource@intra2net.com
***************************************************************************/
return code; \
} while(0);
+#define ftdi_error_return_free_device_list(code, str, devs) do { \
+ libusb_free_device_list(devs,1); \
+ ftdi->error_str = str; \
+ return code; \
+ } while(0);
+
/**
Internal function to close usb device pointer.
*/
static void ftdi_usb_close_internal (struct ftdi_context *ftdi)
{
- if (ftdi->usb_dev)
+ if (ftdi && ftdi->usb_dev)
{
libusb_close (ftdi->usb_dev);
ftdi->usb_dev = NULL;
*/
int ftdi_init(struct ftdi_context *ftdi)
{
+ ftdi->usb_ctx = NULL;
ftdi->usb_dev = NULL;
ftdi->usb_read_timeout = 5000;
ftdi->usb_write_timeout = 5000;
ftdi->error_str = NULL;
- ftdi->eeprom_size = FTDI_DEFAULT_EEPROM_SIZE;
+ ftdi->eeprom = NULL;
/* All fine. Now allocate the readbuffer */
return ftdi_read_data_set_chunksize(ftdi, 4096);
\retval 0: all fine
\retval -1: unknown interface
+ \retval -2: USB device unavailable
*/
int ftdi_set_interface(struct ftdi_context *ftdi, enum ftdi_interface interface)
{
+ if (ftdi == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
switch (interface)
{
case INTERFACE_ANY:
*/
void ftdi_deinit(struct ftdi_context *ftdi)
{
+ if (ftdi == NULL)
+ return;
+
ftdi_usb_close_internal (ftdi);
if (ftdi->readbuffer != NULL)
free(ftdi->readbuffer);
ftdi->readbuffer = NULL;
}
+ libusb_exit(ftdi->usb_ctx);
}
/**
*/
void ftdi_set_usbdev (struct ftdi_context *ftdi, libusb_device_handle *usb)
{
+ if (ftdi == NULL)
+ return;
+
ftdi->usb_dev = usb;
}
int count = 0;
int i = 0;
- if (libusb_init(NULL) < 0)
+ if (libusb_init(&ftdi->usb_ctx) < 0)
ftdi_error_return(-4, "libusb_init() failed");
- if (libusb_get_device_list(NULL, &devs) < 0)
+ if (libusb_get_device_list(ftdi->usb_ctx, &devs) < 0)
ftdi_error_return(-5, "libusb_get_device_list() failed");
curdev = devlist;
struct libusb_config_descriptor *config0;
unsigned int packet_size;
+ // Sanity check
+ if (ftdi == NULL || dev == NULL)
+ return 64;
+
// Determine maximum packet size. Init with default value.
// New hi-speed devices from FTDI use a packet size of 512 bytes
// but could be connected to a normal speed USB hub -> 64 bytes packet size.
\retval -5: unable to claim device
\retval -6: reset failed
\retval -7: set baudrate failed
+ \retval -8: ftdi context invalid
\retval -9: libusb_get_device_descriptor() failed
\retval -10: libusb_get_config_descriptor() failed
\retval -11: libusb_etach_kernel_driver() failed
{
struct libusb_device_descriptor desc;
struct libusb_config_descriptor *config0;
- int cfg, cfg0;
+ int cfg, cfg0, detach_errno = 0;
+
+ if (ftdi == NULL)
+ ftdi_error_return(-8, "ftdi context invalid");
if (libusb_open(dev, &ftdi->usb_dev) < 0)
ftdi_error_return(-4, "libusb_open() failed");
cfg0 = config0->bConfigurationValue;
libusb_free_config_descriptor (config0);
-#ifdef LIBUSB_HAS_GET_DRIVER_NP
// Try to detach ftdi_sio kernel module.
- // Returns ENODATA if driver is not loaded.
//
// The return code is kept in a separate variable and only parsed
// if usb_set_configuration() or usb_claim_interface() fails as the
// detach operation might be denied and everything still works fine.
// Likely scenario is a static ftdi_sio kernel module.
- ret = libusb_detach_kernel_driver(ftdi->usb_dev, ftdi->interface);
- if (ret < 0 && ret != LIBUSB_ERROR_NOT_FOUND)
- ftdi_error_return(-11, "libusb_detach_kernel_driver () failed");
-#endif
+ if (libusb_detach_kernel_driver(ftdi->usb_dev, ftdi->interface) !=0)
+ detach_errno = errno;
if (libusb_get_configuration (ftdi->usb_dev, &cfg) < 0)
ftdi_error_return(-12, "libusb_get_configuration () failed");
-
// set configuration (needed especially for windows)
// tolerate EBUSY: one device with one configuration, but two interfaces
// and libftdi sessions to both interfaces (e.g. FT2232)
if (libusb_set_configuration(ftdi->usb_dev, cfg0) < 0)
{
ftdi_usb_close_internal (ftdi);
- ftdi_error_return(-3, "unable to set usb configuration. Make sure ftdi_sio is unloaded!");
+ if(detach_errno == EPERM)
+ {
+ ftdi_error_return(-8, "inappropriate permissions on device!");
+ }
+ else
+ {
+ ftdi_error_return(-3, "unable to set usb configuration. Make sure the default FTDI driver is not in use");
+ }
}
}
if (libusb_claim_interface(ftdi->usb_dev, ftdi->interface) < 0)
{
ftdi_usb_close_internal (ftdi);
- ftdi_error_return(-5, "unable to claim usb device. Make sure ftdi_sio is unloaded!");
+ if(detach_errno == EPERM)
+ {
+ ftdi_error_return(-8, "inappropriate permissions on device!");
+ }
+ else
+ {
+ ftdi_error_return(-5, "unable to claim usb device. Make sure the default FTDI driver is not in use");
+ }
}
if (ftdi_usb_reset (ftdi) != 0)
\retval -8: get product description failed
\retval -9: get serial number failed
\retval -10: unable to close device
+ \retval -11: ftdi context invalid
*/
int ftdi_usb_open_desc_index(struct ftdi_context *ftdi, int vendor, int product,
const char* description, const char* serial, unsigned int index)
char string[256];
int i = 0;
- if (libusb_init(NULL) < 0)
+ if (libusb_init(&ftdi->usb_ctx) < 0)
ftdi_error_return(-11, "libusb_init() failed");
- if (libusb_get_device_list(NULL, &devs) < 0)
+ if (ftdi == NULL)
+ ftdi_error_return(-11, "ftdi context invalid");
+
+ if (libusb_get_device_list(ftdi->usb_ctx, &devs) < 0)
ftdi_error_return(-12, "libusb_get_device_list() failed");
while ((dev = devs[i++]) != NULL)
{
struct libusb_device_descriptor desc;
+ int res;
if (libusb_get_device_descriptor(dev, &desc) < 0)
- ftdi_error_return(-13, "libusb_get_device_descriptor() failed");
+ ftdi_error_return_free_device_list(-13, "libusb_get_device_descriptor() failed", devs);
if (desc.idVendor == vendor && desc.idProduct == product)
{
if (libusb_open(dev, &ftdi->usb_dev) < 0)
- ftdi_error_return(-4, "usb_open() failed");
+ ftdi_error_return_free_device_list(-4, "usb_open() failed", devs);
if (description != NULL)
{
if (libusb_get_string_descriptor_ascii(ftdi->usb_dev, desc.iProduct, (unsigned char *)string, sizeof(string)) < 0)
{
libusb_close (ftdi->usb_dev);
- ftdi_error_return(-8, "unable to fetch product description");
+ ftdi_error_return_free_device_list(-8, "unable to fetch product description", devs);
}
if (strncmp(string, description, sizeof(string)) != 0)
{
if (libusb_get_string_descriptor_ascii(ftdi->usb_dev, desc.iSerialNumber, (unsigned char *)string, sizeof(string)) < 0)
{
ftdi_usb_close_internal (ftdi);
- ftdi_error_return(-9, "unable to fetch serial number");
+ ftdi_error_return_free_device_list(-9, "unable to fetch serial number", devs);
}
if (strncmp(string, serial, sizeof(string)) != 0)
{
continue;
}
- return ftdi_usb_open_dev(ftdi, dev);
+ res = ftdi_usb_open_dev(ftdi, dev);
+ libusb_free_device_list(devs,1);
+ return res;
}
}
// device not found
- ftdi_error_return(-3, "device not found");
+ ftdi_error_return_free_device_list(-3, "device not found", devs);
}
/**
\retval -9: get serial number failed
\retval -10: unable to close device
\retval -11: illegal description format
+ \retval -12: ftdi context invalid
*/
int ftdi_usb_open_string(struct ftdi_context *ftdi, const char* description)
{
+ if (ftdi == NULL)
+ ftdi_error_return(-12, "ftdi context invalid");
+
if (description[0] == 0 || description[1] != ':')
ftdi_error_return(-11, "illegal description format");
unsigned int bus_number, device_address;
int i = 0;
- if (libusb_init (NULL) < 0)
+ if (libusb_init (&ftdi->usb_ctx) < 0)
ftdi_error_return(-1, "libusb_init() failed");
- if (libusb_get_device_list(NULL, &devs) < 0)
+ if (libusb_get_device_list(ftdi->usb_ctx, &devs) < 0)
ftdi_error_return(-2, "libusb_get_device_list() failed");
/* XXX: This doesn't handle symlinks/odd paths/etc... */
if (sscanf (description + 2, "%u/%u", &bus_number, &device_address) != 2)
- ftdi_error_return(-11, "illegal description format");
+ ftdi_error_return_free_device_list(-11, "illegal description format", devs);
while ((dev = devs[i++]) != NULL)
{
+ int ret;
if (bus_number == libusb_get_bus_number (dev)
&& device_address == libusb_get_device_address (dev))
- return ftdi_usb_open_dev(ftdi, dev);
+ {
+ ret = ftdi_usb_open_dev(ftdi, dev);
+ libusb_free_device_list(devs,1);
+ return ret;
+ }
}
// device not found
- ftdi_error_return(-3, "device not found");
+ ftdi_error_return_free_device_list(-3, "device not found", devs);
}
else if (description[0] == 'i' || description[0] == 's')
{
\retval 0: all fine
\retval -1: FTDI reset failed
+ \retval -2: USB device unavailable
*/
int ftdi_usb_reset(struct ftdi_context *ftdi)
{
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_OUT_REQTYPE,
SIO_RESET_REQUEST, SIO_RESET_SIO,
ftdi->index, NULL, 0, ftdi->usb_write_timeout) < 0)
\retval 0: all fine
\retval -1: read buffer purge failed
+ \retval -2: USB device unavailable
*/
int ftdi_usb_purge_rx_buffer(struct ftdi_context *ftdi)
{
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_OUT_REQTYPE,
SIO_RESET_REQUEST, SIO_RESET_PURGE_RX,
ftdi->index, NULL, 0, ftdi->usb_write_timeout) < 0)
\retval 0: all fine
\retval -1: write buffer purge failed
+ \retval -2: USB device unavailable
*/
int ftdi_usb_purge_tx_buffer(struct ftdi_context *ftdi)
{
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_OUT_REQTYPE,
SIO_RESET_REQUEST, SIO_RESET_PURGE_TX,
ftdi->index, NULL, 0, ftdi->usb_write_timeout) < 0)
\retval 0: all fine
\retval -1: read buffer purge failed
\retval -2: write buffer purge failed
+ \retval -3: USB device unavailable
*/
int ftdi_usb_purge_buffers(struct ftdi_context *ftdi)
{
int result;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-3, "USB device unavailable");
+
result = ftdi_usb_purge_rx_buffer(ftdi);
if (result < 0)
return -1;
\retval 0: all fine
\retval -1: usb_release failed
+ \retval -3: ftdi context invalid
*/
int ftdi_usb_close(struct ftdi_context *ftdi)
{
int rtn = 0;
+ if (ftdi == NULL)
+ ftdi_error_return(-3, "ftdi context invalid");
+
if (ftdi->usb_dev != NULL)
if (libusb_release_interface(ftdi->usb_dev, ftdi->interface) < 0)
rtn = -1;
\retval 0: all fine
\retval -1: invalid baudrate
\retval -2: setting baudrate failed
+ \retval -3: USB device unavailable
*/
int ftdi_set_baudrate(struct ftdi_context *ftdi, int baudrate)
{
unsigned short value, index;
int actual_baudrate;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-3, "USB device unavailable");
+
if (ftdi->bitbang_enabled)
{
baudrate = baudrate*4;
\retval 0: all fine
\retval -1: Setting line property failed
+ \retval -2: USB device unavailable
*/
int ftdi_set_line_property2(struct ftdi_context *ftdi, enum ftdi_bits_type bits,
enum ftdi_stopbits_type sbit, enum ftdi_parity_type parity,
{
unsigned short value = bits;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
switch (parity)
{
case NONE:
\param buf Buffer with the data
\param size Size of the buffer
+ \retval -666: USB device unavailable
\retval <0: error code from usb_bulk_write()
\retval >0: number of bytes written
*/
int offset = 0;
int actual_length;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-666, "USB device unavailable");
+
while (offset < size)
{
int write_size = ftdi->writebuffer_chunksize;
return offset;
}
-#ifdef LIBFTDI_LINUX_ASYNC_MODE
-#ifdef USB_CLASS_PTP
-#error LIBFTDI_LINUX_ASYNC_MODE is not compatible with libusb-compat-0.1!
-#endif
static void ftdi_read_data_cb(struct libusb_transfer *transfer)
{
struct ftdi_transfer_control *tc = (struct ftdi_transfer_control *) transfer->user_data;
struct ftdi_context *ftdi = tc->ftdi;
int packet_size, actual_length, num_of_chunks, chunk_remains, i, ret;
- // New hi-speed devices from FTDI use a packet size of 512 bytes
- if (ftdi->type == TYPE_2232H || ftdi->type == TYPE_4232H)
- packet_size = 512;
- else
- packet_size = 64;
+ packet_size = ftdi->max_packet_size;
actual_length = transfer->actual_length;
{
struct ftdi_transfer_control *tc = (struct ftdi_transfer_control *) transfer->user_data;
struct ftdi_context *ftdi = tc->ftdi;
-
- tc->offset = transfer->actual_length;
-
+
+ tc->offset += transfer->actual_length;
+
if (tc->offset == tc->size)
{
tc->completed = 1;
Writes data to the chip. Does not wait for completion of the transfer
nor does it make sure that the transfer was successful.
- Use libusb 1.0 Asynchronous API.
- Only available if compiled with --with-async-mode.
+ Use libusb 1.0 asynchronous API.
\param ftdi pointer to ftdi_context
\param buf Buffer with the data
struct libusb_transfer *transfer = libusb_alloc_transfer(0);
int write_size, ret;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ {
+ libusb_free_transfer(transfer);
+ return NULL;
+ }
+
tc = (struct ftdi_transfer_control *) malloc (sizeof (*tc));
if (!tc || !transfer)
else
write_size = ftdi->writebuffer_chunksize;
- libusb_fill_bulk_transfer(transfer, ftdi->usb_dev, ftdi->in_ep, buf, write_size, ftdi_write_data_cb, tc, ftdi->usb_write_timeout);
+ libusb_fill_bulk_transfer(transfer, ftdi->usb_dev, ftdi->in_ep, buf,
+ write_size, ftdi_write_data_cb, tc,
+ ftdi->usb_write_timeout);
transfer->type = LIBUSB_TRANSFER_TYPE_BULK;
ret = libusb_submit_transfer(transfer);
Reads data from the chip. Does not wait for completion of the transfer
nor does it make sure that the transfer was successful.
- Use libusb 1.0 Asynchronous API.
- Only available if compiled with --with-async-mode.
+ Use libusb 1.0 asynchronous API.
\param ftdi pointer to ftdi_context
\param buf Buffer with the data
struct libusb_transfer *transfer;
int ret;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ return NULL;
+
tc = (struct ftdi_transfer_control *) malloc (sizeof (*tc));
if (!tc)
return NULL;
/**
Wait for completion of the transfer.
- Use libusb 1.0 Asynchronous API.
- Only available if compiled with --with-async-mode.
+ Use libusb 1.0 asynchronous API.
\param tc pointer to ftdi_transfer_control
while (!tc->completed)
{
- ret = libusb_handle_events(NULL);
+ ret = libusb_handle_events(tc->ftdi->usb_ctx);
if (ret < 0)
{
if (ret == LIBUSB_ERROR_INTERRUPTED)
continue;
libusb_cancel_transfer(tc->transfer);
while (!tc->completed)
- if (libusb_handle_events(NULL) < 0)
+ if (libusb_handle_events(tc->ftdi->usb_ctx) < 0)
break;
libusb_free_transfer(tc->transfer);
free (tc);
- tc = NULL;
return ret;
}
}
- if (tc->transfer->status == LIBUSB_TRANSFER_COMPLETED)
- ret = tc->offset;
- else
- ret = -1;
-
- libusb_free_transfer(tc->transfer);
+ ret = tc->offset;
+ /**
+ * tc->transfer could be NULL if "(size <= ftdi->readbuffer_remaining)"
+ * at ftdi_read_data_submit(). Therefore, we need to check it here.
+ **/
+ if (tc->transfer)
+ {
+ if (tc->transfer->status != LIBUSB_TRANSFER_COMPLETED)
+ ret = -1;
+ libusb_free_transfer(tc->transfer);
+ }
free(tc);
return ret;
}
-#endif // LIBFTDI_LINUX_ASYNC_MODE
-
/**
Configure write buffer chunk size.
Default is 4096.
\param chunksize Chunk size
\retval 0: all fine
+ \retval -1: ftdi context invalid
*/
int ftdi_write_data_set_chunksize(struct ftdi_context *ftdi, unsigned int chunksize)
{
+ if (ftdi == NULL)
+ ftdi_error_return(-1, "ftdi context invalid");
+
ftdi->writebuffer_chunksize = chunksize;
return 0;
}
\param chunksize Pointer to store chunk size in
\retval 0: all fine
+ \retval -1: ftdi context invalid
*/
int ftdi_write_data_get_chunksize(struct ftdi_context *ftdi, unsigned int *chunksize)
{
+ if (ftdi == NULL)
+ ftdi_error_return(-1, "ftdi context invalid");
+
*chunksize = ftdi->writebuffer_chunksize;
return 0;
}
\param buf Buffer to store data in
\param size Size of the buffer
+ \retval -666: USB device unavailable
\retval <0: error code from libusb_bulk_transfer()
\retval 0: no data was available
\retval >0: number of bytes read
int packet_size = ftdi->max_packet_size;
int actual_length = 1;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-666, "USB device unavailable");
+
// Packet size sanity check (avoid division by zero)
if (packet_size == 0)
ftdi_error_return(-1, "max_packet_size is bogus (zero)");
\param chunksize Chunk size
\retval 0: all fine
+ \retval -1: ftdi context invalid
*/
int ftdi_read_data_set_chunksize(struct ftdi_context *ftdi, unsigned int chunksize)
{
unsigned char *new_buf;
+ if (ftdi == NULL)
+ ftdi_error_return(-1, "ftdi context invalid");
+
// Invalidate all remaining data
ftdi->readbuffer_offset = 0;
ftdi->readbuffer_remaining = 0;
#ifdef __linux__
/* We can't set readbuffer_chunksize larger than MAX_BULK_BUFFER_LENGTH,
which is defined in libusb-1.0. Otherwise, each USB read request will
- be devided into multiple URBs. This will cause issues on Linux kernel
+ be divided into multiple URBs. This will cause issues on Linux kernel
older than 2.6.32. */
if (chunksize > 16384)
chunksize = 16384;
\param chunksize Pointer to store chunk size in
\retval 0: all fine
+ \retval -1: FTDI context invalid
*/
int ftdi_read_data_get_chunksize(struct ftdi_context *ftdi, unsigned int *chunksize)
{
+ if (ftdi == NULL)
+ ftdi_error_return(-1, "FTDI context invalid");
+
*chunksize = ftdi->readbuffer_chunksize;
return 0;
}
\retval 0: all fine
\retval -1: can't enable bitbang mode
+ \retval -2: USB device unavailable
*/
int ftdi_enable_bitbang(struct ftdi_context *ftdi, unsigned char bitmask)
{
unsigned short usb_val;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
usb_val = bitmask; // low byte: bitmask
/* FT2232C: Set bitbang_mode to 2 to enable SPI */
usb_val |= (ftdi->bitbang_mode << 8);
\retval 0: all fine
\retval -1: can't disable bitbang mode
+ \retval -2: USB device unavailable
*/
int ftdi_disable_bitbang(struct ftdi_context *ftdi)
{
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_OUT_REQTYPE, SIO_SET_BITMODE_REQUEST, 0, ftdi->index, NULL, 0, ftdi->usb_write_timeout) < 0)
ftdi_error_return(-1, "unable to leave bitbang mode. Perhaps not a BM type chip?");
\retval 0: all fine
\retval -1: can't enable bitbang mode
+ \retval -2: USB device unavailable
*/
int ftdi_set_bitmode(struct ftdi_context *ftdi, unsigned char bitmask, unsigned char mode)
{
unsigned short usb_val;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
usb_val = bitmask; // low byte: bitmask
usb_val |= (mode << 8);
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_OUT_REQTYPE, SIO_SET_BITMODE_REQUEST, usb_val, ftdi->index, NULL, 0, ftdi->usb_write_timeout) < 0)
\retval 0: all fine
\retval -1: read pins failed
+ \retval -2: USB device unavailable
*/
int ftdi_read_pins(struct ftdi_context *ftdi, unsigned char *pins)
{
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_IN_REQTYPE, SIO_READ_PINS_REQUEST, 0, ftdi->index, (unsigned char *)pins, 1, ftdi->usb_read_timeout) != 1)
ftdi_error_return(-1, "read pins failed");
\retval 0: all fine
\retval -1: latency out of range
\retval -2: unable to set latency timer
+ \retval -3: USB device unavailable
*/
int ftdi_set_latency_timer(struct ftdi_context *ftdi, unsigned char latency)
{
if (latency < 1)
ftdi_error_return(-1, "latency out of range. Only valid for 1-255");
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-3, "USB device unavailable");
+
usb_val = latency;
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_OUT_REQTYPE, SIO_SET_LATENCY_TIMER_REQUEST, usb_val, ftdi->index, NULL, 0, ftdi->usb_write_timeout) < 0)
ftdi_error_return(-2, "unable to set latency timer");
\retval 0: all fine
\retval -1: unable to get latency timer
+ \retval -2: USB device unavailable
*/
int ftdi_get_latency_timer(struct ftdi_context *ftdi, unsigned char *latency)
{
unsigned short usb_val;
+
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_IN_REQTYPE, SIO_GET_LATENCY_TIMER_REQUEST, 0, ftdi->index, (unsigned char *)&usb_val, 1, ftdi->usb_read_timeout) != 1)
ftdi_error_return(-1, "reading latency timer failed");
\retval 0: all fine
\retval -1: unable to retrieve status information
+ \retval -2: USB device unavailable
*/
int ftdi_poll_modem_status(struct ftdi_context *ftdi, unsigned short *status)
{
char usb_val[2];
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_IN_REQTYPE, SIO_POLL_MODEM_STATUS_REQUEST, 0, ftdi->index, (unsigned char *)usb_val, 2, ftdi->usb_read_timeout) != 2)
ftdi_error_return(-1, "getting modem status failed");
\retval 0: all fine
\retval -1: set flow control failed
+ \retval -2: USB device unavailable
*/
int ftdi_setflowctrl(struct ftdi_context *ftdi, int flowctrl)
{
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_OUT_REQTYPE,
SIO_SET_FLOW_CTRL_REQUEST, 0, (flowctrl | ftdi->index),
NULL, 0, ftdi->usb_write_timeout) < 0)
\retval 0: all fine
\retval -1: set dtr failed
+ \retval -2: USB device unavailable
*/
int ftdi_setdtr(struct ftdi_context *ftdi, int state)
{
unsigned short usb_val;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (state)
usb_val = SIO_SET_DTR_HIGH;
else
\param state state to set line to (1 or 0)
\retval 0: all fine
- \retval -1 set rts failed
+ \retval -1: set rts failed
+ \retval -2: USB device unavailable
*/
int ftdi_setrts(struct ftdi_context *ftdi, int state)
{
unsigned short usb_val;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (state)
usb_val = SIO_SET_RTS_HIGH;
else
}
/**
- Set dtr and rts line in one pass
+ Set dtr and rts line in one pass
- \param ftdi pointer to ftdi_context
- \param dtr DTR state to set line to (1 or 0)
- \param rts RTS state to set line to (1 or 0)
+ \param ftdi pointer to ftdi_context
+ \param dtr DTR state to set line to (1 or 0)
+ \param rts RTS state to set line to (1 or 0)
- \retval 0: all fine
- \retval -1 set dtr/rts failed
+ \retval 0: all fine
+ \retval -1: set dtr/rts failed
+ \retval -2: USB device unavailable
*/
int ftdi_setdtr_rts(struct ftdi_context *ftdi, int dtr, int rts)
{
unsigned short usb_val;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (dtr)
usb_val = SIO_SET_DTR_HIGH;
else
\retval 0: all fine
\retval -1: unable to set event character
+ \retval -2: USB device unavailable
*/
int ftdi_set_event_char(struct ftdi_context *ftdi,
unsigned char eventch, unsigned char enable)
{
unsigned short usb_val;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
usb_val = eventch;
if (enable)
usb_val |= 1 << 8;
\retval 0: all fine
\retval -1: unable to set error character
+ \retval -2: USB device unavailable
*/
int ftdi_set_error_char(struct ftdi_context *ftdi,
unsigned char errorch, unsigned char enable)
{
unsigned short usb_val;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
usb_val = errorch;
if (enable)
usb_val |= 1 << 8;
*/
void ftdi_eeprom_setsize(struct ftdi_context *ftdi, struct ftdi_eeprom *eeprom, int size)
{
- ftdi->eeprom_size=size;
- eeprom->size=size;
+ if (ftdi == NULL)
+ return;
+
+ ftdi->eeprom = eeprom;
+ ftdi->eeprom->size=size;
}
/**
\param eeprom Pointer to ftdi_eeprom
*/
-void ftdi_eeprom_initdefaults(struct ftdi_eeprom *eeprom)
+void ftdi_eeprom_initdefaults(struct ftdi_context *ftdi)
{
+ int i;
+ struct ftdi_eeprom *eeprom;
+
+ if (ftdi == NULL)
+ return;
+
+ if (ftdi->eeprom == NULL)
+ return;
+
+ eeprom = ftdi->eeprom;
+
eeprom->vendor_id = 0x0403;
eeprom->product_id = 0x6001;
eeprom->self_powered = 1;
eeprom->remote_wakeup = 1;
- eeprom->BM_type_chip = 1;
+ eeprom->release = 0;
eeprom->in_is_isochronous = 0;
eeprom->out_is_isochronous = 0;
eeprom->manufacturer = NULL;
eeprom->product = NULL;
eeprom->serial = NULL;
+ for (i=0; i < 5; i++)
+ {
+ eeprom->cbus_function[i] = 0;
+ }
+ eeprom->high_current = 0;
+ eeprom->invert = 0;
- eeprom->size = FTDI_DEFAULT_EEPROM_SIZE;
+ eeprom->size = FTDI_MAX_EEPROM_SIZE;
}
/**
- Build binary output from ftdi_eeprom structure.
- Output is suitable for ftdi_write_eeprom().
+ Frees allocated memory in eeprom.
- \param eeprom Pointer to ftdi_eeprom
- \param output Buffer of 128 bytes to store eeprom image to
+ \param eeprom Pointer to ftdi_eeprom
+*/
+void ftdi_eeprom_free(struct ftdi_context *ftdi)
+{
+ if (!ftdi)
+ return;
+ if (ftdi->eeprom)
+ {
+ struct ftdi_eeprom *eeprom = ftdi->eeprom;
- \retval >0: used eeprom size
- \retval -1: eeprom size (128 bytes) exceeded by custom strings
+ if (eeprom->manufacturer != 0) {
+ free(eeprom->manufacturer);
+ eeprom->manufacturer = 0;
+ }
+ if (eeprom->product != 0) {
+ free(eeprom->product);
+ eeprom->product = 0;
+ }
+ if (eeprom->serial != 0) {
+ free(eeprom->serial);
+ eeprom->serial = 0;
+ }
+ }
+}
+
+/**
+ Build binary output from ftdi_eeprom structure.
+ Output is suitable for ftdi_write_eeprom().
+
+ \note This function doesn't handle FT2232x devices. Only FT232x.
+ \param eeprom Pointer to ftdi_eeprom
+ \param output Buffer of 128 bytes to store eeprom image to
+
+ \retval >0: free eeprom size
+ \retval -1: eeprom size (128 bytes) exceeded by custom strings
+ \retval -2: Invalid eeprom pointer
+ \retval -3: Invalid cbus function setting
+ \retval -4: Chip doesn't support invert
+ \retval -5: Chip doesn't support high current drive
*/
-int ftdi_eeprom_build(struct ftdi_eeprom *eeprom, unsigned char *output)
+int ftdi_eeprom_build(struct ftdi_context *ftdi, unsigned char *output)
{
unsigned char i, j;
unsigned short checksum, value;
unsigned char manufacturer_size = 0, product_size = 0, serial_size = 0;
int size_check;
+ const int cbus_max[5] = {13, 13, 13, 13, 9};
+ struct ftdi_eeprom *eeprom;
+
+ if (ftdi == NULL)
+ ftdi_error_return(-2,"No context");
+ if (ftdi->eeprom == NULL)
+ ftdi_error_return(-2,"No eeprom structure");
+
+ eeprom= ftdi->eeprom;
if (eeprom->manufacturer != NULL)
manufacturer_size = strlen(eeprom->manufacturer);
if (eeprom->serial != NULL)
serial_size = strlen(eeprom->serial);
+ // highest allowed cbus value
+ for (i = 0; i < 5; i++)
+ {
+ if ((eeprom->cbus_function[i] > cbus_max[i]) ||
+ (eeprom->cbus_function[i] && ftdi->type != TYPE_R)) return -3;
+ }
+ if (ftdi->type != TYPE_R)
+ {
+ if (eeprom->invert) return -4;
+ if (eeprom->high_current) return -5;
+ }
+
size_check = eeprom->size;
size_check -= 28; // 28 are always in use (fixed)
// it seems that the FTDI chip will not read these strings from the lower half
// Each string starts with two bytes; offset and type (0x03 for string)
// the checksum needs two bytes, so without the string data that 8 bytes from the top half
- if (eeprom->size>=256)size_check = 120;
+ if (eeprom->size>=256) size_check = 120;
size_check -= manufacturer_size*2;
size_check -= product_size*2;
size_check -= serial_size*2;
// empty eeprom
memset (output, 0, eeprom->size);
- // Addr 00: Stay 00 00
+ // Addr 00: High current IO
+ output[0x00] = eeprom->high_current ? HIGH_CURRENT_DRIVE : 0;
+ // Addr 01: IN endpoint size (for R type devices, different for FT2232)
+ if (ftdi->type == TYPE_R) {
+ output[0x01] = 0x40;
+ }
// Addr 02: Vendor ID
output[0x02] = eeprom->vendor_id;
output[0x03] = eeprom->vendor_id >> 8;
// Addr 06: Device release number (0400h for BM features)
output[0x06] = 0x00;
-
- if (eeprom->BM_type_chip == 1)
- output[0x07] = 0x04;
- else
- output[0x07] = 0x02;
+ switch (eeprom->release) {
+ case TYPE_AM:
+ output[0x07] = 0x02;
+ break;
+ case TYPE_BM:
+ output[0x07] = 0x04;
+ break;
+ case TYPE_2232C:
+ output[0x07] = 0x05;
+ break;
+ case TYPE_R:
+ output[0x07] = 0x06;
+ break;
+ default:
+ output[0x07] = 0x00;
+ }
// Addr 08: Config descriptor
// Bit 7: always 1
j = j | 16;
output[0x0A] = j;
- // Addr 0B: reserved
- output[0x0B] = 0x00;
+ // Addr 0B: Invert data lines
+ output[0x0B] = eeprom->invert & 0xff;
// Addr 0C: USB version low byte when 0x0A bit 4 is set
// Addr 0D: USB version high byte when 0x0A bit 4 is set
// Addr 13: Length of serial string
output[0x13] = serial_size*2 + 2;
+ // Addr 14: CBUS function: CBUS0, CBUS1
+ // Addr 15: CBUS function: CBUS2, CBUS3
+ // Addr 16: CBUS function: CBUS5
+ output[0x14] = eeprom->cbus_function[0] | (eeprom->cbus_function[1] << 4);
+ output[0x15] = eeprom->cbus_function[2] | (eeprom->cbus_function[3] << 4);
+ output[0x16] = eeprom->cbus_function[4];
+ // Addr 17: Unknown
+
// Dynamic content
- i=0x14;
- if (eeprom->size>=256) i = 0x80;
+ // In images produced by FTDI's FT_Prog for FT232R strings start at 0x18
+ // Space till 0x18 should be considered as reserved.
+ if (ftdi->type >= TYPE_R) {
+ i = 0x18;
+ } else {
+ i = 0x14;
+ }
+ if (eeprom->size >= 256) i = 0x80;
// Output manufacturer
FIXME: How to pass size? How to handle size field in ftdi_eeprom?
FIXME: Strings are malloc'ed here and should be freed somewhere
*/
-int ftdi_eeprom_decode(struct ftdi_eeprom *eeprom, unsigned char *buf, int size)
+int ftdi_eeprom_decode(struct ftdi_context *ftdi, unsigned char *buf, int size, int verbose)
{
unsigned char i, j;
unsigned short checksum, eeprom_checksum, value;
unsigned char manufacturer_size = 0, product_size = 0, serial_size = 0;
- int eeprom_size = 128;
-#if 0
- size_check = eeprom->size;
- size_check -= 28; // 28 are always in use (fixed)
-
- // Top half of a 256byte eeprom is used just for strings and checksum
- // it seems that the FTDI chip will not read these strings from the lower half
- // Each string starts with two bytes; offset and type (0x03 for string)
- // the checksum needs two bytes, so without the string data that 8 bytes from the top half
- if (eeprom->size>=256)size_check = 120;
- size_check -= manufacturer_size*2;
- size_check -= product_size*2;
- size_check -= serial_size*2;
-
- // eeprom size exceeded?
- if (size_check < 0)
- return (-1);
-#endif
-
- // empty eeprom struct
- memset(eeprom, 0, sizeof(struct ftdi_eeprom));
+ int eeprom_size;
+ struct ftdi_eeprom *eeprom;
- // Addr 00: Stay 00 00
+ if (ftdi == NULL)
+ ftdi_error_return(-1,"No context");
+ if (ftdi->eeprom == NULL)
+ ftdi_error_return(-1,"No eeprom");
+
+ eeprom_size = ftdi->eeprom->size;
+ if(ftdi->type == TYPE_R)
+ eeprom_size = 0x80;
+ eeprom = ftdi->eeprom;
// Addr 02: Vendor ID
eeprom->vendor_id = buf[0x02] + (buf[0x03] << 8);
// Addr 04: Product ID
eeprom->product_id = buf[0x04] + (buf[0x05] << 8);
- value = buf[0x06] + (buf[0x07]<<8);
- switch (value)
- {
- case 0x0400:
- eeprom->BM_type_chip = 1;
- break;
- case 0x0200:
- eeprom->BM_type_chip = 0;
- break;
- default: // Unknown device
- eeprom->BM_type_chip = 0;
- break;
- }
+ eeprom->release = buf[0x06] + (buf[0x07]<<8);
// Addr 08: Config descriptor
// Bit 7: always 1
// Bit 6: 1 if this device is self powered, 0 if bus powered
// Bit 5: 1 if this device uses remote wakeup
// Bit 4: 1 if this device is battery powered
- j = buf[0x08];
- if (j&0x40) eeprom->self_powered = 1;
- if (j&0x20) eeprom->remote_wakeup = 1;
+ eeprom->self_powered = buf[0x08] & 0x40;
+ eeprom->remote_wakeup = buf[0x08] & 0x20;;
// Addr 09: Max power consumption: max power = value * 2 mA
eeprom->max_power = buf[0x09];
// Bit 1: 1 - Out EndPoint is Isochronous
// Bit 0: 1 - In EndPoint is Isochronous
//
- j = buf[0x0A];
- if (j&0x01) eeprom->in_is_isochronous = 1;
- if (j&0x02) eeprom->out_is_isochronous = 1;
- if (j&0x04) eeprom->suspend_pull_downs = 1;
- if (j&0x08) eeprom->use_serial = 1;
- if (j&0x10) eeprom->change_usb_version = 1;
+ eeprom->in_is_isochronous = buf[0x0A]&0x01;
+ eeprom->out_is_isochronous = buf[0x0A]&0x02;
+ eeprom->suspend_pull_downs = buf[0x0A]&0x04;
+ eeprom->use_serial = buf[0x0A]&0x08;
+ eeprom->change_usb_version = buf[0x0A]&0x10;
- // Addr 0B: reserved
+ // Addr 0B: Invert data lines
+ eeprom->invert = buf[0x0B];
// Addr 0C: USB version low byte when 0x0A bit 4 is set
// Addr 0D: USB version high byte when 0x0A bit 4 is set
// Addr 0E: Offset of the manufacturer string + 0x80, calculated later
// Addr 0F: Length of manufacturer string
manufacturer_size = buf[0x0F]/2;
- if (manufacturer_size > 0) eeprom->manufacturer = malloc(manufacturer_size);
+ if (manufacturer_size > 0)
+ {
+ eeprom->manufacturer = malloc(manufacturer_size);
+ if (eeprom->manufacturer)
+ {
+ // Decode manufacturer
+ i = buf[0x0E] & (eeprom_size -1); // offset
+ for (j=0;j<manufacturer_size-1;j++)
+ {
+ eeprom->manufacturer[j] = buf[2*j+i+2];
+ }
+ eeprom->manufacturer[j] = '\0';
+ }
+ }
else eeprom->manufacturer = NULL;
// Addr 10: Offset of the product string + 0x80, calculated later
// Addr 11: Length of product string
product_size = buf[0x11]/2;
- if (product_size > 0) eeprom->product = malloc(product_size);
+ if (product_size > 0)
+ {
+ eeprom->product = malloc(product_size);
+ if(eeprom->product)
+ {
+ // Decode product name
+ i = buf[0x10] & (eeprom_size -1); // offset
+ for (j=0;j<product_size-1;j++)
+ {
+ eeprom->product[j] = buf[2*j+i+2];
+ }
+ eeprom->product[j] = '\0';
+ }
+ }
else eeprom->product = NULL;
// Addr 12: Offset of the serial string + 0x80, calculated later
// Addr 13: Length of serial string
serial_size = buf[0x13]/2;
- if (serial_size > 0) eeprom->serial = malloc(serial_size);
- else eeprom->serial = NULL;
-
- // Decode manufacturer
- i = buf[0x0E] & 0x7f; // offset
- for (j=0;j<manufacturer_size-1;j++)
- {
- eeprom->manufacturer[j] = buf[2*j+i+2];
- }
- eeprom->manufacturer[j] = '\0';
-
- // Decode product name
- i = buf[0x10] & 0x7f; // offset
- for (j=0;j<product_size-1;j++)
- {
- eeprom->product[j] = buf[2*j+i+2];
- }
- eeprom->product[j] = '\0';
-
- // Decode serial
- i = buf[0x12] & 0x7f; // offset
- for (j=0;j<serial_size-1;j++)
+ if (serial_size > 0)
{
- eeprom->serial[j] = buf[2*j+i+2];
+ eeprom->serial = malloc(serial_size);
+ if(eeprom->serial)
+ {
+ // Decode serial
+ i = buf[0x12] & (eeprom_size -1); // offset
+ for (j=0;j<serial_size-1;j++)
+ {
+ eeprom->serial[j] = buf[2*j+i+2];
+ }
+ eeprom->serial[j] = '\0';
+ }
}
- eeprom->serial[j] = '\0';
+ else eeprom->serial = NULL;
// verify checksum
checksum = 0xAAAA;
if (eeprom_checksum != checksum)
{
fprintf(stderr, "Checksum Error: %04x %04x\n", checksum, eeprom_checksum);
- return -1;
+ ftdi_error_return(-1,"EEPROM checksum error");
+ }
+
+ else if ((ftdi->type == TYPE_AM) || (ftdi->type == TYPE_BM))
+ {
+ eeprom->chip = buf[14];
+ }
+ else if(ftdi->type == TYPE_2232C)
+ {
+ eeprom->chip = buf[14];
+ }
+ else if(ftdi->type == TYPE_R)
+ {
+ // Addr 14: CBUS function: CBUS0, CBUS1
+ // Addr 15: CBUS function: CBUS2, CBUS3
+ // Addr 16: CBUS function: CBUS5
+ if (ftdi->type == TYPE_R) {
+ eeprom->cbus_function[0] = buf[0x14] & 0x0f;
+ eeprom->cbus_function[1] = (buf[0x14] >> 4) & 0x0f;
+ eeprom->cbus_function[2] = buf[0x15] & 0x0f;
+ eeprom->cbus_function[3] = (buf[0x15] >> 4) & 0x0f;
+ eeprom->cbus_function[4] = buf[0x16] & 0x0f;
+ } else {
+ for (j=0; j<5; j++) eeprom->cbus_function[j] = 0;
+ }
+ }
+ else if (ftdi->type == TYPE_2232H)
+ {
+ }
+ else if (ftdi->type == TYPE_4232H)
+ {
+ }
+
+ if(verbose)
+ {
+ fprintf(stdout, "VID: 0x%04x\n",eeprom->vendor_id);
+ fprintf(stdout, "PID: 0x%04x\n",eeprom->product_id);
+ fprintf(stdout, "Release: 0x%04x\n",eeprom->release);
+
+ if(eeprom->self_powered)
+ fprintf(stdout, "Self-Powered%s", (eeprom->remote_wakeup)?", USB Remote Wake Up\n":"\n");
+ else
+ fprintf(stdout, "Bus Powered: %3d mA%s", eeprom->max_power*2,
+ (eeprom->remote_wakeup)?" USB Remote Wake Up\n":"\n");
+ if(eeprom->manufacturer)
+ fprintf(stdout, "Manufacturer: %s\n",eeprom->manufacturer);
+ if(eeprom->product)
+ fprintf(stdout, "Product: %s\n",eeprom->product);
+ if(eeprom->serial)
+ fprintf(stdout, "Serial: %s\n",eeprom->serial);
+ fprintf(stderr, "Checksum : %04x %04x\n", checksum);
+
}
return 0;
\retval 0: all fine
\retval -1: read failed
+ \retval -2: USB device unavailable
*/
int ftdi_read_eeprom_location (struct ftdi_context *ftdi, int eeprom_addr, unsigned short *eeprom_val)
{
- if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_IN_REQTYPE, SIO_READ_EEPROM_REQUEST, 0, eeprom_addr, (char *)eeprom_val, 2, ftdi->usb_read_timeout) != 2)
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
+ if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_IN_REQTYPE, SIO_READ_EEPROM_REQUEST, 0, eeprom_addr, (unsigned char *)eeprom_val, 2, ftdi->usb_read_timeout) != 2)
ftdi_error_return(-1, "reading eeprom failed");
return 0;
\retval 0: all fine
\retval -1: read failed
+ \retval -2: USB device unavailable
*/
int ftdi_read_eeprom(struct ftdi_context *ftdi, unsigned char *eeprom)
{
int i;
- for (i = 0; i < ftdi->eeprom_size/2; i++)
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
+ for (i = 0; i < FTDI_MAX_EEPROM_SIZE/2; i++)
{
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_IN_REQTYPE, SIO_READ_EEPROM_REQUEST, 0, i, eeprom+(i*2), 2, ftdi->usb_read_timeout) != 2)
ftdi_error_return(-1, "reading eeprom failed");
}
+ if (ftdi->type == TYPE_R)
+ ftdi->eeprom->size = 0xa0;
+ /* Guesses size of eeprom by comparing halves
+ - will not work with blank eeprom */
+ else if (strrchr((const char *)eeprom, 0xff) == ((const char *)eeprom +FTDI_MAX_EEPROM_SIZE -1))
+ ftdi->eeprom->size = -1;
+ else if(memcmp(eeprom,&eeprom[0x80],0x80) == 0)
+ ftdi->eeprom->size = 0x80;
+ else if(memcmp(eeprom,&eeprom[0x40],0x40) == 0)
+ ftdi->eeprom->size = 0x40;
+ else
+ ftdi->eeprom->size = 0x100;
return 0;
}
\retval 0: all fine
\retval -1: read failed
+ \retval -2: USB device unavailable
*/
int ftdi_read_chipid(struct ftdi_context *ftdi, unsigned int *chipid)
{
unsigned int a = 0, b = 0;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_IN_REQTYPE, SIO_READ_EEPROM_REQUEST, 0, 0x43, (unsigned char *)&a, 2, ftdi->usb_read_timeout) == 2)
{
a = a << 8 | a >> 8;
}
/**
- Guesses size of eeprom by reading eeprom and comparing halves - will not work with blank eeprom
- Call this function then do a write then call again to see if size changes, if so write again.
-
- \param ftdi pointer to ftdi_context
- \param eeprom Pointer to store eeprom into
- \param maxsize the size of the buffer to read into
-
- \retval size of eeprom
-*/
-int ftdi_read_eeprom_getsize(struct ftdi_context *ftdi, unsigned char *eeprom, int maxsize)
-{
- int i=0,j,minsize=32;
- int size=minsize;
-
- do
- {
- for (j = 0; i < maxsize/2 && j<size; j++)
- {
- if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_IN_REQTYPE,
- SIO_READ_EEPROM_REQUEST, 0, i,
- eeprom+(i*2), 2, ftdi->usb_read_timeout) != 2)
- ftdi_error_return(-1, "reading eeprom failed");
- i++;
- }
- size*=2;
- }
- while (size<=maxsize && memcmp(eeprom,&eeprom[size/2],size/2)!=0);
-
- return size/2;
-}
-
-/**
Write eeprom location
\param ftdi pointer to ftdi_context
\retval 0: all fine
\retval -1: read failed
+ \retval -2: USB device unavailable
*/
int ftdi_write_eeprom_location(struct ftdi_context *ftdi, int eeprom_addr, unsigned short eeprom_val)
{
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_OUT_REQTYPE,
SIO_WRITE_EEPROM_REQUEST, eeprom_val, eeprom_addr,
NULL, 0, ftdi->usb_write_timeout) != 0)
\retval 0: all fine
\retval -1: read failed
+ \retval -2: USB device unavailable
*/
int ftdi_write_eeprom(struct ftdi_context *ftdi, unsigned char *eeprom)
{
unsigned short usb_val, status;
int i, ret;
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
/* These commands were traced while running MProg */
if ((ret = ftdi_usb_reset(ftdi)) != 0)
return ret;
if ((ret = ftdi_set_latency_timer(ftdi, 0x77)) != 0)
return ret;
- for (i = 0; i < ftdi->eeprom_size/2; i++)
+ for (i = 0; i < ftdi->eeprom->size/2; i++)
{
usb_val = eeprom[i*2];
usb_val += eeprom[(i*2)+1] << 8;
\retval 0: all fine
\retval -1: erase failed
+ \retval -2: USB device unavailable
*/
int ftdi_erase_eeprom(struct ftdi_context *ftdi)
{
+ if (ftdi == NULL || ftdi->usb_dev == NULL)
+ ftdi_error_return(-2, "USB device unavailable");
+
if (libusb_control_transfer(ftdi->usb_dev, FTDI_DEVICE_OUT_REQTYPE, SIO_ERASE_EEPROM_REQUEST, 0, 0, NULL, 0, ftdi->usb_write_timeout) < 0)
ftdi_error_return(-1, "unable to erase eeprom");
*/
char *ftdi_get_error_string (struct ftdi_context *ftdi)
{
+ if (ftdi == NULL)
+ return "";
+
return ftdi->error_str;
}