pirep 0.0.1

Python Integer Representations & Arithmetic Library

Python Integer Representations & Arithmetic Library

This tool may be useful to system software developers (for example, compiler or binutils developers). Here are functions for representing integers in a convenient form and functions for arithmetic over integers of arbitrary format.

Install

$ git clone https://github.com/smurphik/pirep
$ cd pirep
$ sudo python3 setup.py install clean

Alternative way:

$ sudo pip3 install pirep

Formats

The integer arguments of almost all functions can be of any of 4 formats:

• decimal — usual python integer (0, 7, -2, ...);
• hexadecimal — string with or without prefix '0x' ('0xf', 'a7', and even '-0xcf');
• binary — string with prefix '0b' ('0b010110', '0b0', ...);
• float — usual python float (Why not? 0.0, 17., -3., ...).

You can globally specify the default output format for arithmetic functions by call psetmode or locally for each interface (by their parameter fmt).

Representations

c2repr gives two's complement representation in any output format in accordance with the current signedness and int width (signed 64-bit by default).

>>> from pirep import *

>>> c2repr(5, 'b')
'0b101'

>>> c2repr(-10)
'0xfffffffffffffff6'

>>> c2repr('8000000000000000', 'd')
-9223372036854775808

>>> c2repr('4000000000000000', 'd')
4611686018427387904

Meaning of prepr by example. The operation sethi %hi(0x103c00), %o3 (see Sparc Instruction Set) is encoded to 1700040f. We can clearly expand the code instructions on its fields. For this we need to know the numbers of the last bits of all fields:

>>> prepr('1700040f', (31, 29, 24, 21))
['00', '01011', '100', '0000000000010000001111']

>>> prepr('1700040f', (31, 29, 24, 21), 'h')
['0x0', '0xb', '0x4', '0x40f']

Why '0x40f' and not 0x103c00? It's ok. sethi sets just 22 high bits:

# Left shift
>>> pls('0x40f', 10)
'0x103c00'

We could just decompose any integer by bytes:

>>> prepr(3932166)
['00111100', '00000000', '00000110']

More verbose way to decode — use vrepr() with object of class Enc:

>>> e = Enc('sethi', (('opc', 31), ('rd', 29), ('opc', 24), ('imm22', 21)))

>>> vrepr('1700040f', e, borders=True)
 opc     rd    opc           imm22
  00   01011   100   0000000000010000001111
31-30  29-25  24-22  21-------------------0

>>> e.field(('opc', 31)).add_only_true(0)
>>> e.field(('rd', 29)).add_verbose(11, 'eleven')

>>> vrepr('1700040f', e, 'h')
opc   rd  opc  imm22
0x0  0xb  0x4  0x40f

rd[29:25]:   eleven

It is convenient to have a separate module that contains all the encodings you often use.

Arithmetic

You can globally specify the signedness and the integer width by psetmode:

>>> from pirep import *

# Default mode: signed, 64-bit, hexadecimal default output
>>> pgetmode()
[True, 64, 'h']
>>> psub('0x100', 15)
'0xf1'

# Signed 8-bit int with decimal output by default
>>> psetmode(True, 8, 'd')
>>> psub('0x100', 15.)
-15
>>> psub('0x100', '0b1111', 'b')
'0b11110001'

pirep contains several other elementary arithmetic functions:

>>> psetmode(True, 8, 'd')
>>> pmul(3, padd(pdiv('f', '0b100'), prem(11, '0x3')))
15
>>> psetbits(15, (3, 5), '0b110')
55
>>> padd(pintmin(), pintmax())
-1