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start designing new data structures for m-valued logic

devel
Stefan Holst 4 years ago
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  1. 146
      src/kyupy/logic.py
  2. 105
      tests/test_logic.py

146
src/kyupy/logic.py
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"""Data structures for 2-valued, 4-valued, and 8-valued logic computation.
Integer constants: ZERO, ONE, UNASSIGNED, UNKNOWN, RISING, FALLING, PPULSE, NPULSE.
* The bits in the constants have the following meaning:
* bit 0: Final/settled binary value of a signal
* bit 1: Initial binary value of a signal
* bit 2: 1, if activity or transitions are present on a signal
Special meaning is given to values where bits 0 and 1 differ, but activity is 0.
These values are interpreted as 'unknown' or 'unassigned' in 4-valued and 8-valued logic.
* 4-valued logic: 2 bits for storage, the third bit is implicitly 0
* 0 (0b00) : '0', 0, False, logic-0 (kyupy.logic.ZERO)
* 1 (0b01) : '-', None, unassigned (kyupy.logic.UNASSIGNED)
* 2 (0b10) : 'X', unknown (kyupy.logic.UNKNOWN)
* 3 (0b11) : '1', 1, True, logic-1 (kyupy.logic.ONE)
* 8-valued logic: 3 bits for storage, adds the following 4 interpretations
* 4 (0b100) : 'P', positive pulse 0 -> 1 -> 0 (kyupy.logic.PPULSE)
* 5 (0b101) : 'R', rising transition (kyupy.logic.RISING)
* 6 (0b110) : 'F', falling transition (kyupy.logic.FALLING)
* 7 (0b111) : 'N', negative pulse 1 -> 0 -> 1 (kyupy.logic.NPULSE)
"""
import math
from collections.abc import Iterable
import numpy as np
ZERO = 0b000
UNASSIGNED = 0b001
UNKNOWN = 0b010
ONE = 0b011
PPULSE = 0b100
RISING = 0b101
FALLING = 0b110
NPULSE = 0b111
def interpret(value):
if isinstance(value, Iterable) and not (isinstance(value, str) and len(value) == 1):
return list(map(interpret, value))
if value in [0, '0', False, 'L', 'l']:
return ZERO
if value in [1, '1', True, 'H', 'h']:
return ONE
if value in [None, '-', 'Z', 'z']:
return UNASSIGNED
if value in ['R', 'r', '/']:
return RISING
if value in ['F', 'f', '\\']:
return FALLING
if value in ['P', 'p', '^']:
return PPULSE
if value in ['N', 'n', 'v']:
return NPULSE
return UNKNOWN
class MVArray:
"""An n-dimensional array of m-valued logic values.
This class wraps a numpy.ndarray of type uint8 and adds support for encoding and
interpreting 2-valued, 4-valued, and 8-valued logic values.
Each logic value is stored as an uint8, value manipulations are cheaper than in BPArray.
Axis convention (1 axis, a single vector/pattern):
* Axis is PI/PO/FF position, the length of this axis is called "width".
Axis convention for 2 and more axes is consistent with BPArray:
* Second-last axis is PI/PO/FF position, the length of this axis is called "width".
* Last axis is vector/pattern, the length of this axis is called "length".
"""
def __init__(self, a, m=None):
self.m = m or 4
assert self.m in range(2, 256)
# Try our best to interpret given a.
if isinstance(a, MVArray):
self.data = a.data.copy()
self.m = m or a.m
elif isinstance(a, int) or isinstance(a, tuple):
self.data = np.full(a, UNASSIGNED, dtype=np.uint8)
else:
self.data = np.asarray(interpret(a), dtype=np.uint8)
if self.data.ndim > 1:
self.data = np.moveaxis(self.data, -2, -1)
# Cast data to m-valued logic.
if self.m == 2:
self.data[...] = ((self.data & 0b001) & ((self.data >> 1) & 0b001) | (self.data == RISING)) * ONE
elif self.m == 4:
self.data[...] = (self.data & 0b011) & ((self.data != FALLING) * ONE) | ((self.data == RISING) * ONE)
elif self.m == 8:
self.data[...] = self.data & 0b111
self.length = 1 if self.data.ndim == 1 else self.data.shape[-1]
self.width = len(self.data) if self.data.ndim == 1 else self.data.shape[-2]
def __repr__(self):
return f'<MVArray length={self.length} width={self.width} m={self.m} bytes={self.data.nbytes}>'
class BPArray:
"""An n-dimensional array of m-valued logic values that uses bit-parallel storage.
The primary use of this format is in aiding efficient bit-parallel logic simulation.
The secondary benefit over MVArray is its memory efficiency.
Direct value manipulations are more expensive than with MVArray.
It is advised to first construct a MVArray, pack it into a BPArray for simulation and unpack the results
back into a MVArray for value access.
The values along the last axis (vectors/patterns) are packed into uint8 words.
The second-last axis has length ceil(log2(m)) for storing all bits.
All other axes stay the same as in MVArray.
"""
def __init__(self, a, m=None):
if not isinstance(a, MVArray) and not isinstance(a, BPArray):
a = MVArray(a, m)
if isinstance(a, MVArray):
if m is not None and m != a.m:
a = MVArray(a, m) # cast data
self.m = a.m
assert self.m in [2, 4, 8]
nwords = math.ceil(math.log2(self.m))
nbytes = (a.data.shape[-1] - 1) // 8 + 1
self.data = np.zeros(a.data.shape[:-1] + (nwords, nbytes), dtype=np.uint8)
for i in range(self.data.shape[-2]):
self.data[..., i, :] = np.packbits((a.data >> i) & 1, axis=-1)
else: # we have a BPArray
self.data = a.data.copy() # TODO: support conversion to different m
self.length = a.length
self.width = a.width
def __repr__(self):
return f'<BPArray length={self.length} width={self.width} m={self.m} bytes={self.data.nbytes}>'

105
tests/test_logic.py
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import kyupy.logic as lg
def test_mvarray():
# instantiation with shape
ary = lg.MVArray(4)
assert ary.length == 1
assert ary.width == 4
ary = lg.MVArray((3, 2))
assert ary.length == 2
assert ary.width == 3
# instantiation with single vector
ary = lg.MVArray([1, 0, 1])
assert ary.length == 1
assert ary.width == 3
ary = lg.MVArray("10X-")
assert ary.length == 1
assert ary.width == 4
# instantiation with multiple vectors
ary = lg.MVArray([[0, 0], [0, 1], [1, 0], [1, 1]])
assert ary.length == 4
assert ary.width == 2
ary = lg.MVArray(["000", "001", "110", "---"])
assert ary.length == 4
assert ary.width == 3
# casting to 2-valued logic
ary = lg.MVArray([0, 1, 2, None], m=2)
assert ary.data[0] == lg.ZERO
assert ary.data[1] == lg.ONE
assert ary.data[2] == lg.ZERO
assert ary.data[3] == lg.ZERO
ary = lg.MVArray("0-X1PRFN", m=2)
assert ary.data[0] == lg.ZERO
assert ary.data[1] == lg.ZERO
assert ary.data[2] == lg.ZERO
assert ary.data[3] == lg.ONE
assert ary.data[4] == lg.ZERO
assert ary.data[5] == lg.ONE
assert ary.data[6] == lg.ZERO
assert ary.data[7] == lg.ONE
# casting to 4-valued logic
ary = lg.MVArray([0, 1, 2, None, 'F'])
assert ary.data[0] == lg.ZERO
assert ary.data[1] == lg.ONE
assert ary.data[2] == lg.UNKNOWN
assert ary.data[3] == lg.UNASSIGNED
assert ary.data[4] == lg.ZERO
ary = lg.MVArray("0-X1PRFN")
assert ary.data[0] == lg.ZERO
assert ary.data[1] == lg.UNASSIGNED
assert ary.data[2] == lg.UNKNOWN
assert ary.data[3] == lg.ONE
assert ary.data[4] == lg.ZERO
assert ary.data[5] == lg.ONE
assert ary.data[6] == lg.ZERO
assert ary.data[7] == lg.ONE
# casting to 8-valued logic
ary = lg.MVArray([0, 1, 2, None, 'F'], m=8)
assert ary.data[0] == lg.ZERO
assert ary.data[1] == lg.ONE
assert ary.data[2] == lg.UNKNOWN
assert ary.data[3] == lg.UNASSIGNED
assert ary.data[4] == lg.FALLING
ary = lg.MVArray("0-X1PRFN", m=8)
assert ary.data[0] == lg.ZERO
assert ary.data[1] == lg.UNASSIGNED
assert ary.data[2] == lg.UNKNOWN
assert ary.data[3] == lg.ONE
assert ary.data[4] == lg.PPULSE
assert ary.data[5] == lg.RISING
assert ary.data[6] == lg.FALLING
assert ary.data[7] == lg.NPULSE
# copy constructor and casting
ary8 = lg.MVArray(ary, m=8)
assert ary8.length == 1
assert ary8.width == 8
assert ary8.data[7] == lg.NPULSE
ary4 = lg.MVArray(ary, m=4)
assert ary4.data[1] == lg.UNASSIGNED
assert ary4.data[7] == lg.ONE
ary2 = lg.MVArray(ary, m=2)
assert ary2.data[1] == lg.ZERO
assert ary2.data[7] == lg.ONE
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