I need a compact representation of an array of booleans, does Python have a builtin bitfield type or will I need to find an alternate solution?
Bitarray was the best answer I found, when I recently had a similar need. It's a C extension (so much faster than BitVector, which is pure python) and stores its data in an actual bitfield (so it's eight times more memory efficient than a numpy boolean array, which appears to use a byte per element.)
If you mainly want to be able to name your bit fields and easily manipulate them, e.g. to work with flags represented as single bits in a communications protocol, then you can use the standard Structure and Union features of ctypes, as described at How Do I Properly Declare a ctype Structure + Union in Python? - Stack Overflow
For example, to work with the 4 least-significant bits of a byte individually, just name them from least to most significant in a LittleEndianStructure. You use a union to provide access to the same data as a byte or int so you can move the data in or out of the communication protocol. In this case that is done via the
import ctypes c_uint8 = ctypes.c_uint8 class Flags_bits(ctypes.LittleEndianStructure): _fields_ = [ ("logout", c_uint8, 1), ("userswitch", c_uint8, 1), ("suspend", c_uint8, 1), ("idle", c_uint8, 1), ] class Flags(ctypes.Union): _fields_ = [("b", Flags_bits), ("asbyte", c_uint8)] flags = Flags() flags.asbyte = 0xc print(flags.b.idle) print(flags.b.suspend) print(flags.b.userswitch) print(flags.b.logout)
The four bits (which I've printed here starting with the most significant, which seems more natural when printing) are 1, 1, 0, 0, i.e. 0xc in binary.
You should take a look at the bitstring module, which has recently reached version 2.0. The binary data is compactly stored as a byte array and can be easily created, modified and analysed.
You can create
BitString objects from binary, octal, hex, integers (big or little endian), strings, bytes, floats, files and more.
a = BitString('0xed44') b = BitString('0b11010010') c = BitString(int=100, length=14) d = BitString('uintle:16=55, 0b110, 0o34') e = BitString(bytes='hello') f = pack('<2H, bin:3', 5, 17, '001')
You can then analyse and modify them with simple functions or slice notation - no need to worry about bit masks etc.
a.prepend('0b110') if '0b11' in b: c.reverse() g = a.join([b, d, e]) g.replace('0b101', '0x3400ee1') if g: del g[14:17] else: g[55:58] = 'uint:11=33, int:9=-1'
There is also a concept of a bit position, so that you can treat it like a file or stream if that's useful to you. Properties are used to give different interpretations of the bit data.
w = g.read(10).uint x, y, z = g.readlist('int:4, int:4, hex:32') if g.peek(8) == '0x00': g.pos += 10
Plus there's support for the standard bit-wise binary operators, packing, unpacking, endianness and more. The latest version is for Python 2.7 and 3.x, and although it's pure Python it is reasonably well optimised in terms of memory and speed.
I use the binary bit-wise operators !, &, |, ^, >>, and <<. They work really well and are implemented directly in the underlying C, which is usually directly on the underlying hardware.
Represent each of your values as a power of two:
testA = 2**0 testB = 2**1 testC = 2**3
Then to set a value true:
table = table | testB
To set a value false:
table = table & (~testC)
To test for a value:
bitfield_length = 0xff if ((table & testB & bitfield_length) != 0): print "Field B set"
Dig a little deeper into hexadecimal representation if this doesn't make sense to you. This is basically how you keep track of your boolean flags in an embedded C application as well (if you have limitted memory).
The BitVector package may be what you need. It's not built in to my python installation, but easy to track down on the python site.
https://pypi.python.org/pypi/BitVector for the current version.
NumPy has a array interface module that you can use to make a bitfield.
If you want to use ints (or long ints) to represent as arrays of bools (or as sets of integers), take a look at http://sourceforge.net/projects/pybitop/files/
It provides insert/extract of bitfields into long ints; finding the most-significant, or least-significant '1' bit; counting all the 1's; bit-reversal; stuff like that which is all possible in pure python but much faster in C.
For mostly-consecutive bits there's the https://pypi.org/project/range_set/ module which is API compatible to Python's built-in
set. As the name implies, it stores the bits as begin/end pairs.
I had to deal with some control words / flags in a communication protocol and my focus was that the editor gives me suggestions of the flag names and jumps to the definition of the flags with "F3". The code below suffices theses requirements (The solution with ctypes by @nealmcb unfortunately is not supported by the PyCharm indexer today. ). Suggestions welcome:
""" The following bit-manipulation methods are written to take a tuple as input, which is provided by the Bitfield class. The construct looks weired, however the call to a setBit() looks ok and the editor (PyCharm) suggests all possible bit names. I did not find a more elegant solution that calls the setBit()-function and needs only one argument. Example call: setBit( STW1.bm01NoOff2() ) """ def setBit(TupleBitField_BitMask): # word = word | bit_mask TupleBitField_BitMask.word = TupleBitField_BitMask.word | TupleBitField_BitMask def isBit(TupleBitField_BitMask): # (word & bit_mask) != 0 return (TupleBitField_BitMask.word & TupleBitField_BitMask) !=0 def clrBit(TupleBitField_BitMask): #word = word & (~ BitMask) TupleBitField_BitMask.word = TupleBitField_BitMask.word & (~ TupleBitField_BitMask) def toggleBit(TupleBitField_BitMask): #word = word ^ BitMask TupleBitField_BitMask.word = TupleBitField_BitMask.word ^ TupleBitField_BitMask """ Create a Bitfield type for each control word of the application. (e.g. 16bit length). Assign a name for each bit in order that the editor (e.g. PyCharm) suggests the names from outside. The bits are defined as methods that return the corresponding bit mask in order that the bit masks are read-only and will not be corrupted by chance. The return of each "bit"-function is a tuple (handle to bitfield, bit_mask) in order that they can be sent as arguments to the single bit manipulation functions (see above): isBit(), setBit(), clrBit(), toggleBit() The complete word of the Bitfield is accessed from outside by xxx.word. Examples: STW1 = STW1Type(0x1234) # instanciates and inits the bitfield STW1, STW1.word = 0x1234 setBit(STW1.bm00() ) # set the bit with the name bm00(), e.g. bm00 = bitmask 0x0001 print("STW1.word =", hex(STW1.word)) """ class STW1Type(): # assign names to the bit masks for each bit (these names will be suggested by PyCharm) # tip: copy the application's manual description here def __init__(self, word): # word = initial value, e.g. 0x0000 self.word = word # define all bits here and copy the description of each bit from the application manual. Then you can jump # to this explanation with "F3" # return the handle to the bitfield and the BitMask of the bit. def bm00NoOff1_MeansON(self): # 0001 0/1= ON (edge)(pulses can be enabled) # 0 = OFF1 (braking with ramp-function generator, then pulse suppression & ready for switching on) return self, 0x0001 def bm01NoOff2(self): # 0002 1 = No OFF2 (enable is possible) # 0 = OFF2 (immediate pulse suppression and switching on inhibited) return self, 0x0002 def bm02NoOff3(self): # 0004 1 = No OFF3 (enable possible) # 0 = OFF3 (braking with the OFF3 ramp p1135, then pulse suppression and switching on inhibited) return self, 0x0004 def bm03EnableOperation(self): # 0008 1 = Enable operation (pulses can be enabled) # 0 = Inhibit operation (suppress pulses) return self, 0x0008 def bm04RampGenEnable(self): # 0010 1 = Hochlaufgeber freigeben (the ramp-function generator can be enabled) # 0 = Inhibit ramp-function generator (set the ramp-function generator output to zero) return self, 0x0010 def b05RampGenContinue(self): # 0020 1 = Continue ramp-function generator # 0 = Freeze ramp-function generator (freeze the ramp-function generator output) return self, 0x0020 def b06RampGenEnable(self): # 0040 1 = Enable speed setpoint; Drehzahlsollwert freigeben # 0 = Inhibit setpoint; Drehzahlsollwert sperren (set the ramp-function generator input to zero) return self, 0x0040 def b07AcknowledgeFaults(self): # 0080 0/1= 1. Acknowledge faults; 1. Quittieren Störung return self, 0x0080 def b08Reserved(self): # 0100 Reserved return self, 0x0100 def b09Reserved(self): # 0200 Reserved return self, 0x0200 def b10ControlByPLC(self): # 0400 1 = Control by PLC; Führung durch PLC return self, 0x0400 def b11SetpointInversion(self): # 0800 1 = Setpoint inversion; Sollwert Invertierung return self, 0x0800 def b12Reserved(self): # 1000 Reserved return self, 0x1000 def b13MotorPotiSPRaise(self): # 2000 1 = Motorized potentiometer setpoint raise; (Motorpotenziometer Sollwert höher) return self, 0x2000 def b14MotorPotiSPLower(self): # 4000 1 = Motorized potentiometer setpoint lower; (Motorpotenziometer Sollwert tiefer) return self, 0x4000 def b15Reserved(self): # 8000 Reserved return self, 0x8000 """ test the constrution and methods """ STW1 = STW1Type(0xffff) print("STW1.word =", hex(STW1.word)) clrBit(STW1.bm00NoOff1_MeansON()) print("STW1.word =", hex(STW1.word)) STW1.word = 0x1234 print("STW1.word =", hex(STW1.word)) setBit( STW1.bm00NoOff1_MeansON() ) print("STW1.word =", hex(STW1.word)) clrBit( STW1.bm00NoOff1_MeansON() ) print("STW1.word =", hex(STW1.word)) toggleBit(STW1.bm03EnableOperation()) print("STW1.word =", hex(STW1.word)) toggleBit(STW1.bm03EnableOperation()) print("STW1.word =", hex(STW1.word)) print("STW1.bm00ON =", isBit(STW1.bm00NoOff1_MeansON() ) ) print("STW1.bm04 =", isBit(STW1.bm04RampGenEnable() ) )
It prints out:
STW1.word = 0xffff STW1.word = 0xfffe STW1.word = 0x1234 STW1.word = 0x1235 STW1.word = 0x1234 STW1.word = 0x123c STW1.word = 0x1234 STW1.bm00ON = False STW1.bm04 = True