import unittest
import struct
+import sys
from openpower.decoder.selectable_int import (SelectableInt, onebit,
selectconcat)
from nmutil.divmod import trunc_divs, trunc_rems
from openpower.decoder.selectable_int import check_extsign
from openpower.util import log
+import math
trunc_div = floordiv
trunc_rem = mod
"""
Links:
* https://bugs.libre-soc.org/show_bug.cgi?id=324 - add trunc_div and trunc_rem
+* https://bugs.libre-soc.org/show_bug.cgi?id=671#c38 - RANGE (and bugfixes)
"""
+def RANGE(start, end):
+ if start > end:
+ # reverse direction
+ # auto-subtract-one (sigh) due to python range
+ return range(start, end-1, -1)
+ # auto-add-one (sigh) due to python range
+ return range(start, end+1)
+
+
def exts(value, bits):
sign = 1 << (bits - 1)
return (value & (sign - 1)) - (value & sign)
def EXTS(value):
""" extends sign bit out from current MSB to all 256 bits
"""
- log ("EXTS", value, type(value))
+ log("EXTS", value, type(value))
assert isinstance(value, SelectableInt)
return SelectableInt(exts(value.value, value.bits) & ((1 << 256)-1), 256)
value = SelectableInt(value.value, 64)
return rotl(value | (value << 32), bits, 64)
+
def MASK32(x, y):
if isinstance(x, SelectableInt):
x = x.value
y = y.value
return MASK(x+32, y+32)
+
def MASK(x, y):
if isinstance(x, SelectableInt):
x = x.value
"""
return v
-def DOUBLE(WORD):
- """convert incoming WORD to double. v3.0B p140 section 4.6.2
- """
- # result, FRT, start off all zeros
- log ("WORD", WORD)
- FRT = SelectableInt(0, 64)
- z1 = SelectableInt(0, 1)
- z29 = SelectableInt(0, 29)
- e = WORD[1:9]
- m = WORD[9:32]
- s = WORD[0]
- log ("word s e m", s, e, m)
-
- # Normalized Operand
- if e.value > 0 and e.value < 255:
- log ("normalised")
- FRT[0:2] = WORD[0:2]
- FRT[2] = ~WORD[1]
- FRT[3] = ~WORD[1]
- FRT[4] = ~WORD[1]
- FRT[5:64] = selectconcat(WORD[2:32], z29)
-
- # Denormalized Operand
- if e.value == 0 and m.value != 0:
- log ("denormalised")
- sign = WORD[0]
- exp = -126
- frac = selectconcat(z1, WORD[9:32], z29)
- # normalize the operand
- while frac[0].value == 0:
- frac[0:53] = selectconcat(frac[1:53], z1)
- exp = exp - 1
- FRT[0] = sign
- FRT[1:12] = exp + 1023
- FRT[12:64] = frac[1:53]
-
- # Zero / Infinity / NaN
- if e.value == 255 or WORD[1:32].value == 0:
- log ("z/inf/nan")
- FRT[0:2] = WORD[0:2]
- FRT[2] = WORD[1]
- FRT[3] = WORD[1]
- FRT[4] = WORD[1]
- FRT[5:64] = selectconcat(WORD[2:32], z29)
-
- log ("Double s e m", FRT[0].value, FRT[1:12].value-1023,
- FRT[12:64].value)
-
- return FRT
-
def SINGLE(FRS):
"""convert incoming FRS into 32-bit word. v3.0B p144 section 4.6.3
m = FRS[12:64]
s = FRS[0]
- log ("SINGLE", FRS)
- log ("s e m", s.value, e.value, m.value)
-
- #No Denormalization Required (includes Zero / Infinity / NaN)
- if e.value > 896 or FRS[1:64].value == 0:
- log("nodenorm", FRS[0:2].value, hex(FRS[5:35].value))
- WORD[0:2] = FRS[0:2]
- WORD[2:32] = FRS[5:35]
-
- #Denormalization Required
- if e.value >= 874 and e.value <= 896:
- sign = FRS[0]
- exp = e.value - 1023
- frac = selectconcat(SelectableInt(1, 1), FRS[12:64])
- log("exp, fract", exp, hex(frac.value))
- # denormalize operand
- while exp < -126:
- frac[0:53] = selectconcat(SelectableInt(0, 1), frac[0:52])
- exp = exp + 1
- WORD[0] = sign
- WORD[1:9] = SelectableInt(0, 8)
- WORD[9:32] = frac[1:24]
- #else WORD = undefined # return zeros
-
- log ("WORD", WORD)
+ log("SINGLE", FRS)
+ log("s e m", s.value, e.value, m.value)
+
+ # No Denormalization Required (includes Zero / Infinity / NaN)
+ if e.value > 896 or FRS[1:64].value == 0:
+ log("nodenorm", FRS[0:2].value, hex(FRS[5:35].value))
+ WORD[0:2] = FRS[0:2]
+ WORD[2:32] = FRS[5:35]
+
+ # Denormalization Required
+ if e.value >= 874 and e.value <= 896:
+ sign = FRS[0]
+ exp = e.value - 1023
+ frac = selectconcat(SelectableInt(1, 1), FRS[12:64])
+ log("exp, fract", exp, hex(frac.value))
+ # denormalize operand
+ while exp < -126:
+ frac[0:53] = selectconcat(SelectableInt(0, 1), frac[0:52])
+ exp = exp + 1
+ WORD[0] = sign
+ WORD[1:9] = SelectableInt(0, 8)
+ WORD[9:32] = frac[1:24]
+ # else WORD = undefined # return zeros
+
+ log("WORD", WORD)
return WORD
# XXX NOTE: these are very quick hacked functions for utterly basic
# FP support
-def fp64toselectable(frt):
- """convert FP number to 64 bit SelectableInt
- """
- b = struct.pack(">d", frt)
- val = int.from_bytes(b, byteorder='big', signed=False)
- return SelectableInt(val, 64)
-
-
-def FPADD32(FRA, FRB):
- from openpower.decoder.isafunctions.double2single import DOUBLE2SINGLE
- #return FPADD64(FRA, FRB)
- #FRA = DOUBLE(SINGLE(FRA))
- #FRB = DOUBLE(SINGLE(FRB))
- result = float(FRA) + float(FRB)
- cvt = fp64toselectable(result)
- cvt = DOUBLE2SINGLE(cvt)
- log ("FPADD32", FRA, FRB, float(FRA), "+", float(FRB), "=", result, cvt)
- return cvt
-
-
-def FPSUB32(FRA, FRB):
- from openpower.decoder.isafunctions.double2single import DOUBLE2SINGLE
- #return FPSUB64(FRA, FRB)
- #FRA = DOUBLE(SINGLE(FRA))
- #FRB = DOUBLE(SINGLE(FRB))
- result = float(FRA) - float(FRB)
- cvt = fp64toselectable(result)
- cvt = DOUBLE2SINGLE(cvt)
- log ("FPSUB32", FRA, FRB, float(FRA), "-", float(FRB), "=", result, cvt)
- return cvt
-
def signinv(res, sign):
if sign == 1:
return -res
-def FPMUL32(FRA, FRB, sign=1):
- from openpower.decoder.isafunctions.double2single import DOUBLE2SINGLE
- #return FPMUL64(FRA, FRB)
- FRA = DOUBLE(SINGLE(FRA))
- FRB = DOUBLE(SINGLE(FRB))
- result = signinv(float(FRA) * float(FRB), sign)
- log ("FPMUL32", FRA, FRB, float(FRA), float(FRB), result, sign)
- cvt = fp64toselectable(result)
- cvt = DOUBLE2SINGLE(cvt)
- log (" cvt", cvt)
- return cvt
-
-
-def FPMULADD32(FRA, FRC, FRB, mulsign, addsign):
- from openpower.decoder.isafunctions.double2single import DOUBLE2SINGLE
- #return FPMUL64(FRA, FRB)
- #FRA = DOUBLE(SINGLE(FRA))
- #FRB = DOUBLE(SINGLE(FRB))
- if addsign == 1:
- if mulsign == 1:
- result = float(FRA) * float(FRC) + float(FRB) # fmadds
- elif mulsign == -1:
- result = -(float(FRA) * float(FRC) - float(FRB)) # fnmsubs
- elif addsign == -1:
- if mulsign == 1:
- result = float(FRA) * float(FRC) - float(FRB) # fmsubs
- elif mulsign == -1:
- result = -(float(FRA) * float(FRC) + float(FRB)) # fnmadds
- elif addsign == 0:
- result = 0.0
- log ("FPMULADD32 FRA FRC FRB", FRA, FRC, FRB)
- log (" FRA", float(FRA))
- log (" FRC", float(FRC))
- log (" FRB", float(FRB))
- log (" (FRA*FRC)+FRB=", mulsign, addsign, result)
- cvt = fp64toselectable(result)
- cvt = DOUBLE2SINGLE(cvt)
- log (" cvt", cvt)
- return cvt
+def fp64toselectable(frt):
+ """convert FP number to 64 bit SelectableInt
+ """
+ b = struct.pack(">d", frt)
+ val = int.from_bytes(b, byteorder='big', signed=False)
+ return SelectableInt(val, 64)
-def FPDIV32(FRA, FRB, sign=1):
- from openpower.decoder.isafunctions.double2single import DOUBLE2SINGLE
- #return FPDIV64(FRA, FRB)
- #FRA = DOUBLE(SINGLE(FRA))
- #FRB = DOUBLE(SINGLE(FRB))
- result = signinv(float(FRA) / float(FRB), sign)
- cvt = fp64toselectable(result)
- cvt = DOUBLE2SINGLE(cvt)
- log ("FPDIV32", FRA, FRB, result, cvt)
- return cvt
+class ISAFPHelpers:
+
+ def FPSIN32(self, FRB):
+ #FRB = DOUBLE(SINGLE(FRB))
+ result = math.sin(float(FRB))
+ cvt = fp64toselectable(result)
+ cvt = self.DOUBLE2SINGLE(cvt)
+ log("FPSIN32", FRB, float(FRB), "=", result, cvt)
+ return cvt
+
+ def FPCOS32(self, FRB):
+ #FRB = DOUBLE(SINGLE(FRB))
+ result = math.cos(float(FRB))
+ cvt = fp64toselectable(result)
+ cvt = self.DOUBLE2SINGLE(cvt)
+ log("FPCOS32", FRB, float(FRB), "=", result, cvt)
+ return cvt
+
+ def FPADD32(self, FRA, FRB):
+ # return FPADD64(FRA, FRB)
+ #FRA = DOUBLE(SINGLE(FRA))
+ #FRB = DOUBLE(SINGLE(FRB))
+ result = float(FRA) + float(FRB)
+ cvt = fp64toselectable(result)
+ cvt = self.DOUBLE2SINGLE(cvt)
+ log("FPADD32", FRA, FRB, float(FRA), "+", float(FRB), "=", result, cvt)
+ return cvt
+
+ def FPSUB32(self, FRA, FRB):
+ # return FPSUB64(FRA, FRB)
+ #FRA = DOUBLE(SINGLE(FRA))
+ #FRB = DOUBLE(SINGLE(FRB))
+ result = float(FRA) - float(FRB)
+ cvt = fp64toselectable(result)
+ cvt = self.DOUBLE2SINGLE(cvt)
+ log("FPSUB32", FRA, FRB, float(FRA), "-", float(FRB), "=", result, cvt)
+ return cvt
+
+ def FPMUL32(self, FRA, FRB, sign=1):
+ # return FPMUL64(FRA, FRB)
+ FRA = self.DOUBLE(SINGLE(FRA))
+ FRB = self.DOUBLE(SINGLE(FRB))
+ result = signinv(float(FRA) * float(FRB), sign)
+ log("FPMUL32", FRA, FRB, float(FRA), float(FRB), result, sign)
+ cvt = fp64toselectable(result)
+ cvt = self.DOUBLE2SINGLE(cvt)
+ log(" cvt", cvt)
+ return cvt
+
+ def FPMULADD32(self, FRA, FRC, FRB, mulsign, addsign):
+ # return FPMUL64(FRA, FRB)
+ #FRA = DOUBLE(SINGLE(FRA))
+ #FRB = DOUBLE(SINGLE(FRB))
+ if addsign == 1:
+ if mulsign == 1:
+ result = float(FRA) * float(FRC) + float(FRB) # fmadds
+ elif mulsign == -1:
+ result = -(float(FRA) * float(FRC) - float(FRB)) # fnmsubs
+ elif addsign == -1:
+ if mulsign == 1:
+ result = float(FRA) * float(FRC) - float(FRB) # fmsubs
+ elif mulsign == -1:
+ result = -(float(FRA) * float(FRC) + float(FRB)) # fnmadds
+ elif addsign == 0:
+ result = 0.0
+ log("FPMULADD32 FRA FRC FRB", FRA, FRC, FRB)
+ log(" FRA", float(FRA))
+ log(" FRC", float(FRC))
+ log(" FRB", float(FRB))
+ log(" (FRA*FRC)+FRB=", mulsign, addsign, result)
+ cvt = fp64toselectable(result)
+ cvt = self.DOUBLE2SINGLE(cvt)
+ log(" cvt", cvt)
+ return cvt
+
+ def FPDIV32(self, FRA, FRB, sign=1):
+ # return FPDIV64(FRA, FRB)
+ #FRA = DOUBLE(SINGLE(FRA))
+ #FRB = DOUBLE(SINGLE(FRB))
+ result = signinv(float(FRA) / float(FRB), sign)
+ cvt = fp64toselectable(result)
+ cvt = self.DOUBLE2SINGLE(cvt)
+ log("FPDIV32", FRA, FRB, result, cvt)
+ return cvt
def FPADD64(FRA, FRB):
result = float(FRA) + float(FRB)
cvt = fp64toselectable(result)
- log ("FPADD64", FRA, FRB, result, cvt)
+ log("FPADD64", FRA, FRB, result, cvt)
return cvt
def FPSUB64(FRA, FRB):
result = float(FRA) - float(FRB)
cvt = fp64toselectable(result)
- log ("FPSUB64", FRA, FRB, result, cvt)
+ log("FPSUB64", FRA, FRB, result, cvt)
return cvt
def FPMUL64(FRA, FRB, sign=1):
result = signinv(float(FRA) * float(FRB), sign)
cvt = fp64toselectable(result)
- log ("FPMUL64", FRA, FRB, result, cvt, sign)
+ log("FPMUL64", FRA, FRB, result, cvt, sign)
return cvt
def FPDIV64(FRA, FRB, sign=1):
result = signinv(float(FRA) / float(FRB), sign)
cvt = fp64toselectable(result)
- log ("FPDIV64", FRA, FRB, result, cvt, sign)
+ log("FPDIV64", FRA, FRB, result, cvt, sign)
return cvt
-
def bitrev(val, VL):
"""Returns the integer whose value is the reverse of the lowest
'width' bits of the integer 'val'
return result
+def log2(val):
+ """return the base-2 logarithm of `val`. Only works for powers of 2."""
+ if isinstance(val, SelectableInt):
+ val = val.value
+ retval = val.bit_length() - 1
+ assert val == 2 ** retval, "value is not a power of 2"
+ return retval
+
+
# For these tests I tried to find power instructions that would let me
# isolate each of these helper operations. So for instance, when I was
# testing the MASK() function, I chose rlwinm and rldicl because if I
return self.assertEqual(a, b, msg)
+class ISACallerHelper:
+ def __init__(self, XLEN):
+ self.__XLEN = XLEN
+
+ @property
+ def XLEN(self):
+ return self.__XLEN
+
+ def XLCASTS(self, value):
+ return SelectableInt(exts(value.value, self.XLEN), self.XLEN)
+
+ def XLCASTU(self, value):
+ # SelectableInt already takes care of masking out the bits
+ return SelectableInt(value.value, self.XLEN)
+
+ def EXTSXL(self, value, bits):
+ return SelectableInt(exts(value.value, bits), self.XLEN)
+
+ def DOUBLE2SINGLE(self, FRS):
+ """ DOUBLE2SINGLE has been renamed to FRSP since it is the
+ implementation of the frsp instruction.
+ use SINGLE() or FRSP() instead, or just use struct.pack/unpack
+ """
+ FPSCR = {
+ 'UE': SelectableInt(0, 1),
+ 'OE': SelectableInt(0, 1),
+ 'RN': SelectableInt(0, 2), # round to nearest, ties to even
+ 'XX': SelectableInt(0, 1),
+ }
+ FRT, FPSCR = self.FRSP(FRS, FPSCR)
+ return FRT
+
+ def __getattr__(self, attr):
+ try:
+ return globals()[attr]
+ except KeyError:
+ raise AttributeError(attr)
+
+
if __name__ == '__main__':
log(SelectableInt.__bases__)
unittest.main()