From: Jacob Lifshay Date: Sat, 20 May 2023 02:51:39 +0000 (-0700) Subject: add more bfp_* functions X-Git-Url: https://git.libre-soc.org/?a=commitdiff_plain;h=d595b73b068079c7392b4601b801f0a73155d372;p=openpower-isa.git add more bfp_* functions --- diff --git a/openpower/isafunctions/bfp.mdwn b/openpower/isafunctions/bfp.mdwn index 09f9aeda..126320d2 100644 --- a/openpower/isafunctions/bfp.mdwn +++ b/openpower/isafunctions/bfp.mdwn @@ -746,6 +746,120 @@ section 7.6.2.2 # floating-point working format. return bfp_CONVERT_FROM_BFP64(0x0010_0000_0000_0000) + def bfp_ROUND_HELPER(p, ro, rmode, x): + # not part of the PowerISA v3.1B specification. + # helper function for the bfp_ROUND_* functions. + # doesn't set inc_flag or xx_flag. + # + # x is a binary floating-point value that is represented in the binary + # floating-point working format and has unbounded exponent range and + # significand precision. x must be rounded as presented, without + # prenormalization. + # + # p is an integer value specifying the precision (i.e., number of bits) + # the significand is rounded to. + # + # ro is a 1-bit unsigned integer and rmode is a 3-bit unsigned integer, + # together specifying one of six rounding modes to be used in + # rounding x. + # + # ro=0 rmode=0b000 Round to Nearest Even + # ro=0 rmode=0b001 Round towards Zero + # ro=0 rmode=0b010 Round towards +Infinity + # ro=0 rmode=0b011 Round towards -Infinity + # ro=0 rmode=0b100 Round to Nearest Away + # ro=1 Round to Odd + + if IsInf(x) | IsNaN(x) | IsZero(x) then + inc_flag <- 0 # TODO: does the spec specify this? + xx_flag <- 0 # TODO: does the spec specify this? + return x + + result <- x + result.significand <- 0 + result.significand[0:p - 1] <- x.significand[0:p - 1] + exact <- x.significand = result.significand + halfway <- 0b0 + more_than_half <- 0b0 + if x.significand[p] then + t <- x + t.significand <- 0 + t.significand[0:p] <- x.significand[0:p] + if t.significand = x.significand then halfway <- 0b1 + else more_than_half <- 0b1 + even <- ¬result.significand[p - 1] + + if (ro=0) & (rmode=0b000) then # Round to Nearest Even + round_up <- (halfway & ¬even) | more_than_half + if (ro=0) & (rmode=0b001) then # Round towards Zero + round_up <- 0b0 + if (ro=0) & (rmode=0b010) then # Round towards +Infinity + round_up <- (x.sign = 0) & ¬exact + if (ro=0) & (rmode=0b011) then # Round towards -Infinity + round_up <- (x.sign = 1) & ¬exact + if (ro=0) & (rmode=0b100) then # Round to Nearest Away + round_up <- halfway | more_than_half + if ro=1 then # Round to Odd + round_up <- ¬exact & even + + if round_up then + result.significand[0:p-1] <- result.significand[0:p-1] + 1 + if result.significand[0:p-1] = 0 then + result.significand[0] <- 1 + result.exponent <- result.exponent + 1 + + if result.significand != 0 then + do while result.significand[0] != 1 + result.significand <- result.significand * 2 + result.exponent <- result.exponent - 1 + result.class.Normal <- 1 + result.class.Denormal <- 0 + result.class.Zero <- 0 + else + result.class.Normal <- 0 + result.class.Denormal <- 0 + result.class.Zero <- 1 + + return result + + def bfp_ROUND_NEAR_EVEN(p, x): + # x is a binary floating-point value that is represented in the binary + # floating-point working format and has unbounded exponent range and + # significand precision. x must be rounded as presented, without + # prenormalization. + # + # p is an integer value specifying the precision (i.e., number of bits) + # the significand is rounded to. + + result <- bfp_ROUND_HELPER(p, 0b0, 0b000, x) + + if bfp_COMPARE_GT(bfp_ABSOLUTE(result), bfp_ABSOLUTE(x)) then + inc_flag <- 1 + else inc_flag <- 0 # TODO: does the spec specify this? + if ¬bfp_COMPARE_EQ(result, x) then xx_flag <- 1 + else xx_flag <- 0 # TODO: does the spec specify this? + + return result + + def bfp_ROUND_TRUNC(p, x): + # x is a binary floating-point value that is represented in the binary + # floating-point working format and has unbounded exponent range and + # significand precision. x must be rounded as presented, without + # prenormalization. + # + # p is an integer value specifying the precision (i.e., number of bits) + # the significand is rounded to. + + result <- bfp_ROUND_HELPER(p, 0b0, 0b001, x) + + if bfp_COMPARE_GT(bfp_ABSOLUTE(result), bfp_ABSOLUTE(x)) then + inc_flag <- 1 + else inc_flag <- 0 # TODO: does the spec specify this? + if ¬bfp_COMPARE_EQ(result, x) then xx_flag <- 1 + else xx_flag <- 0 # TODO: does the spec specify this? + + return result + def bfp_ROUND_CEIL(p, x): # x is a binary floating-point value that is represented in the binary # floating-point working format and has unbounded exponent range and @@ -755,13 +869,87 @@ section 7.6.2.2 # p is an integer value specifying the precision (i.e., number of bits) # the significand is rounded to. - TODO() # TODO: finish - # Return the smallest floating-point number having unbounded exponent - # range and a significand with a width of p bits that is greater or - # equal in value to x. + result <- bfp_ROUND_HELPER(p, 0b0, 0b010, x) if bfp_COMPARE_GT(bfp_ABSOLUTE(result), bfp_ABSOLUTE(x)) then inc_flag <- 1 else inc_flag <- 0 # TODO: does the spec specify this? - if bfp_COMPARE_EQ(result, x) then xx_flag <- 1 + if ¬bfp_COMPARE_EQ(result, x) then xx_flag <- 1 else xx_flag <- 0 # TODO: does the spec specify this? + + return result + + def bfp_ROUND_FLOOR(p, x): + # x is a binary floating-point value that is represented in the binary + # floating-point working format and has unbounded exponent range and + # significand precision. x must be rounded as presented, without + # prenormalization. + # + # p is an integer value specifying the precision (i.e., number of bits) + # the significand is rounded to. + + result <- bfp_ROUND_HELPER(p, 0b0, 0b011, x) + + if bfp_COMPARE_GT(bfp_ABSOLUTE(result), bfp_ABSOLUTE(x)) then + inc_flag <- 1 + else inc_flag <- 0 # TODO: does the spec specify this? + if ¬bfp_COMPARE_EQ(result, x) then xx_flag <- 1 + else xx_flag <- 0 # TODO: does the spec specify this? + + return result + + def bfp_ROUND_NEAR_AWAY(p, x): + # not part of the PowerISA v3.1B specification. + # + # x is a binary floating-point value that is represented in the binary + # floating-point working format and has unbounded exponent range and + # significand precision. x must be rounded as presented, without + # prenormalization. + # + # p is an integer value specifying the precision (i.e., number of bits) + # the significand is rounded to. + + result <- bfp_ROUND_HELPER(p, 0b0, 0b100, x) + + if bfp_COMPARE_GT(bfp_ABSOLUTE(result), bfp_ABSOLUTE(x)) then + inc_flag <- 1 + else inc_flag <- 0 # TODO: does the spec specify this? + if ¬bfp_COMPARE_EQ(result, x) then xx_flag <- 1 + else xx_flag <- 0 # TODO: does the spec specify this? + + return result + + def bfp_ROUND_ODD(p, x): + # x is a binary floating-point value that is represented in the binary + # floating-point working format and has unbounded exponent range and + # significand precision. x must be rounded as presented, without + # prenormalization. + # + # p is an integer value specifying the precision (i.e., number of bits) + # the significand is rounded to. + + result <- bfp_ROUND_HELPER(p, 0b1, 0b000, x) + + if bfp_COMPARE_GT(bfp_ABSOLUTE(result), bfp_ABSOLUTE(x)) then + inc_flag <- 1 + else inc_flag <- 0 # TODO: does the spec specify this? + if ¬bfp_COMPARE_EQ(result, x) then xx_flag <- 1 + else xx_flag <- 0 # TODO: does the spec specify this? + + return result + + def fprf_CLASS_BFP64(x): + # x is a floating-point value represented in double-precision format. + # + # Return the 5-bit code that specifies the sign and class of x. + + v <- bfp_CONVERT_FROM_BFP64(x) + if v.class.QNaN then return 0b10001 + if (v.sign = 1) & v.class.Infinity then return 0b01001 + if (v.sign = 0) & v.class.Infinity then return 0b00101 + if (v.sign = 1) & v.class.Zero then return 0b10010 + if (v.sign = 0) & v.class.Zero then return 0b00010 + if (v.sign = 1) & v.class.Denormal then return 0b11000 + if (v.sign = 0) & v.class.Denormal then return 0b10100 + if (v.sign = 1) & v.class.Normal then return 0b01000 + if (v.sign = 0) & v.class.Normal then return 0b00100