Source code for pylibftdi.device

pylibftdi.device - access to individual FTDI devices

Copyright (c) 2010-2014 Ben Bass <>
See LICENSE file for details and (absence of) warranty



import functools
import itertools
import os

from ctypes import byref, create_string_buffer, c_char_p

from pylibftdi._base import FtdiError
from pylibftdi.driver import (
        Driver, USB_VID_LIST, USB_PID_LIST,

[docs]class Device(object): """ Represents a connection to a single FTDI device """
[docs] def __init__(self, device_id=None, mode="b", encoding="latin1", lazy_open=False, chunk_size=0, interface_select=None, device_index=0, **kwargs): """ Device([device_id[, mode, [OPTIONS ...]]) -> Device instance represents a single FTDI device accessible via the libftdi driver. Supports a basic file-like interface (open/close/read/write, context manager support). :param device_id: an optional serial number of the device to open. if omitted, this refers to the first device found, which is convenient if only one device is attached, but otherwise fairly useless. :param mode: either 'b' (binary) or 't' (text). This primarily affects Python 3 calls to read() and write(), which will accept/return unicode strings which will be encoded/decoded according to the given... :param encoding: the codec name to be used for text operations. :param lazy_open: if True, then the device will not be opened immediately - the user must perform an explicit open() call prior to other operations. :param chunk_size: if non-zero, split read and write operations into chunks of this size. With large or slow accesses, interruptions (i.e. KeyboardInterrupt) may not happen in a timely fashion. :param interface_select: select interface to use on multi-interface devices :param device_index: optional index of the device to open, in the event of multiple matches for other parameters (PID, VID, device_id). Defaults to zero (the first device found). """ self._opened = False self.driver = Driver(**kwargs) self.fdll = self.driver.fdll # device_id is an optional serial number of the requested device. self.device_id = device_id # mode can be either 'b' for binary, or 't' for text. # if set to text, the values returned from read() will # be decoded using encoding before being returned as # strings; for binary the raw bytes will be returned. # This will only affect Python3. self.mode = mode # when giving a str to Device.write(), it is encoded. # default is latin1, because it provides # a one-to-one correspondence for code points 0-FF self.encoding = encoding # ftdi_usb_open_dev initialises the device baudrate # to 9600, which certainly seems to be a de-facto # standard for serial devices. self._baudrate = 9600 # defining softspace allows us to 'print' to this device self.softspace = 0 # chunk_size (if not 0) chunks the reads and writes # to allow interruption self.chunk_size = chunk_size # interface can be set for devices which have multiple interface # ports (e.g. FT4232, FT2232) self.interface_select = interface_select # device_index is an optional integer index of device to choose self.device_index = device_index # lazy_open tells us not to open immediately. if not lazy_open:
def __del__(self): "free the ftdi_context resource" if self._opened: self.close()
[docs] def open(self): """ open connection to a FTDI device """ if self._opened: return # create context for this device self.ctx = create_string_buffer(1024) res = self.fdll.ftdi_init(byref(self.ctx)) if res != 0: msg = "%s (%d)" % (self.get_error_string(), res) del self.ctx raise FtdiError(msg) if self.interface_select is not None: res = self.fdll.ftdi_set_interface(byref(self.ctx), self.interface_select) if res != 0: msg = "%s (%d)" % (self.get_error_string(), res) del self.ctx raise FtdiError(msg) # Try to open the device. If this fails, reset things to how # they were, but we can't use self.close as that assumes things # have already been setup. res = self._open_device() if res != 0: msg = "%s (%d)" % (self.get_error_string(), res) # free the context self.fdll.ftdi_deinit(byref(self.ctx)) del self.ctx raise FtdiError(msg) # explicitly reset the device to serial mode with standard settings # - no flow control, 9600 baud - in case it had previously been used # in bitbang mode (some later driver versions might do bits of this # automatically) self.fdll.ftdi_set_bitmode(byref(self.ctx), 0, BITMODE_RESET) self.fdll.ftdi_setflowctrl(byref(self.ctx), 0) self.baudrate = 9600 self._opened = True
def _open_device(self): """ Actually open the target device :return: status of the open command (0 = success) :rtype: int """ # FTDI vendor/product ids required here. res = None for usb_vid, usb_pid in itertools.product(USB_VID_LIST, USB_PID_LIST): open_args = [byref(self.ctx), usb_vid, usb_pid, 0, 0, self.device_index] if self.device_id is None: res = self.fdll.ftdi_usb_open_desc_index(*tuple(open_args)) else: # attempt to match device_id to serial number open_args[-2] = c_char_p(self.device_id.encode('latin1')) res = self.fdll.ftdi_usb_open_desc_index(*tuple(open_args)) if res != 0: # swap (description, serial) parameters and try again # - attempt to match device_id to description open_args[-3], open_args[-2] = open_args[-2], open_args[-3] res = self.fdll.ftdi_usb_open_desc_index(*tuple(open_args)) if res != FTDI_ERROR_DEVICE_NOT_FOUND: # if we succeed (0) or get a specific error, don't continue # otherwise (-3) - look for another device break return res
[docs] def close(self): "close our connection, free resources" if self._opened: self.fdll.ftdi_usb_close(byref(self.ctx)) self.fdll.ftdi_deinit(byref(self.ctx)) del self.ctx self._opened = False
@property def baudrate(self): """ get or set the baudrate of the FTDI device. Re-read after setting to ensure baudrate was accepted by the driver. """ return self._baudrate @baudrate.setter def baudrate(self, value): result = self.fdll.ftdi_set_baudrate(byref(self.ctx), value) if result == 0: self._baudrate = value def _read(self, length): """ actually do the low level reading :return: bytes read from the device :rtype: bytes """ buf = create_string_buffer(length) rlen = self.fdll.ftdi_read_data(byref(self.ctx), byref(buf), length) if rlen < 0: raise FtdiError(self.get_error_string()) byte_data = buf.raw[:rlen] return byte_data
[docs] def read(self, length): """ read(length) -> bytes/string of up to `length` bytes. read upto `length` bytes from the FTDI device :param length: maximum number of bytes to read :return: value read from device :rtype: bytes if self.mode is 'b', else decode with self.encoding """ if not self._opened: raise FtdiError("read() on closed Device") # read the data if self.chunk_size != 0: remaining = length byte_data_list = [] while remaining > 0: rx_bytes = self._read(min(remaining, self.chunk_size)) if not rx_bytes: break byte_data_list.append(rx_bytes) remaining -= len(rx_bytes) byte_data = b''.join(byte_data_list) else: byte_data = self._read(length) if self.mode == 'b': return byte_data else: # TODO: for some codecs, this may choke if we haven't read the # full required data. If this is the case we should probably trim # a byte at a time from the output until the decoding works, and # buffer the remainder for next time. return byte_data.decode(self.encoding)
def _write(self, byte_data): """ actually do the low level writing :param byte_data: data to be written :type byte_data: bytes :return: number of bytes written """ buf = create_string_buffer(byte_data) written = self.fdll.ftdi_write_data(byref(self.ctx), byref(buf), len(byte_data)) if written < 0: raise FtdiError(self.get_error_string()) return written
[docs] def write(self, data): """ write(data) -> count of bytes actually written write given `data` string to the FTDI device :param data: string to be written :type data: string or bytes :return: count of bytes written, which may be less than `len(data)` """ if not self._opened: raise FtdiError("write() on closed Device") try: byte_data = bytes(data) except TypeError: # this will happen if we are Python3 and data is a str. byte_data = data.encode(self.encoding) # actually write it if self.chunk_size != 0: remaining = len(byte_data) written = 0 while remaining > 0: start = written length = min(remaining, self.chunk_size) result = self._write(byte_data[start: start + length]) if result == 0: # don't continue to try writing forever if nothing # is actually being written break else: written += result remaining -= result else: written = self._write(byte_data) return written
[docs] def flush(self, flush_what=FLUSH_BOTH): """ Instruct the FTDI device to flush its FIFO buffers By default both the input and output buffers will be flushed, but the caller can selectively chose to only flush the input or output buffers using `flush_what`: :param flush_what: select what to flush: `FLUSH_BOTH` (default); `FLUSH_INPUT` (just the rx buffer); `FLUSH_OUTPUT` (just the tx buffer) """ if flush_what == FLUSH_BOTH: fn = self.fdll.ftdi_usb_purge_buffers elif flush_what == FLUSH_INPUT: fn = self.fdll.ftdi_usb_purge_rx_buffer elif flush_what == FLUSH_OUTPUT: fn = self.fdll.ftdi_usb_purge_tx_buffer else: raise ValueError("Invalid value passed to %s.flush()" % self.__class__.__name__) res = fn(byref(self.ctx)) if res != 0: msg = "%s (%d)" % (self.get_error_string(), res) raise FtdiError(msg)
[docs] def flush_input(self): """ flush the device input buffer """ self.flush(FLUSH_INPUT)
[docs] def flush_output(self): """ flush the device output buffer """ self.flush(FLUSH_OUTPUT)
[docs] def get_error_string(self): """ :return: error string from libftdi driver """ return self.fdll.ftdi_get_error_string(byref(self.ctx))
@property def ftdi_fn(self): """ this allows the vast majority of libftdi functions which are called with a pointer to a ftdi_context struct as the first parameter to be called here preventing the need to leak self.ctx into the user code (and import byref from ctypes): >>> with Device() as dev: ... # set 8 bit data, 2 stop bits, no parity ... dev.ftdi_fn.ftdi_set_line_property(8, 2, 0) ... """ # note this class is constructed on each call, so this # won't be particularly quick. It does ensure that the # fdll and ctx objects in the closure are up-to-date, though. class FtdiForwarder(object): def __getattr__(innerself, key): return functools.partial(getattr(self.fdll, key), byref(self.ctx)) return FtdiForwarder() def __enter__(self): """ support for context manager. Note the device is opened and closed automatically when used in a with statement, and the device object itself is returned: >>> with Device(mode='t') as dev: ... dev.write('Hello World!') ... """ return self def __exit__(self, exc_type, exc_val, tb): "support for context manager" self.close() # # following are various properties and functions to make # this emulate a file-object more closely. # @property def closed(self): """ The Python file API defines a read-only 'closed' attribute """ return not self._opened
[docs] def readline(self, size=0): """ readline() for file-like compatibility. :param size: maximum amount of data to read looking for a line :return: a line of text, or size bytes if no line-ending found This only works for mode='t' on Python3 """ lsl = len(os.linesep) line_buffer = [] while True: next_char = if next_char == '' or (size > 0 and len(line_buffer) > size): break line_buffer.append(next_char) if (len(line_buffer) >= lsl and line_buffer[-lsl:] == list(os.linesep)): break return ''.join(line_buffer)
[docs] def readlines(self, sizehint=None): """ readlines() for file-like compatibility. """ lines = [] if sizehint is not None: string_blob = lines.extend(string_blob.split(os.linesep)) while True: line = self.readline() if not line: break lines.append(line) return lines
[docs] def writelines(self, lines): """ writelines for file-like compatibility. :param lines: sequence of lines to write """ for line in lines: self.write(line)
def __iter__(self): return self def __next__(self): while True: line = self.readline() if line: return line else: raise StopIteration next = __next__