FAMIN

Multi-vector floating-point absolute minimum

This instruction determines the minimum absolute value from floating-point elements of the two or four second source vectors and the corresponding floating-point elements of the two or four first source vectors and destructively places the results in the corresponding elements of the two or four first source vectors.

Regardless of the value of FPCR.AH, the behavior is as follows:

  • When FPCR.DN is 0, if either element is a NaN, the result is a quiet NaN.
  • When FPCR.DN is 1, if either element is a NaN, the result is the Default NaN, with the sign bit set to 0.
  • Denormalized inputs and results are never flushed to zero, as if FPCR.{FZ, FZ16, FIZ} are all 0.
  • Denormalized inputs never generate an Input Denormal floating-point exception.

    • This instruction follows SME2 floating-point numerical behaviors corresponding to instructions that place their results in one or more SVE Z vectors.

    This instruction is unpredicated.

    Encoding: Two registers

    Variants: FEAT_SME2 && FEAT_FAMINMAX (FEAT_SME2 && FEAT_FAMINMAX)

    313029282726252423222120191817161514131211109876543210
    1100000110101100010101
    sizeZmopcZdno2

    FAMIN { <Zdn1>.<T>-<Zdn2>.<T> }, { <Zdn1>.<T>-<Zdn2>.<T> }, { <Zm1>.<T>-<Zm2>.<T> }

    Decoding algorithm

    if !IsFeatureImplemented(FEAT_SME2) || !IsFeatureImplemented(FEAT_FAMINMAX) then
    EndOfDecode(Decode_UNDEF);
if size == '00' then EndOfDecode(Decode_UNDEF);
constant integer esize = 8 << UInt(size);
constant integer dn = UInt(Zdn:'0');
constant integer m = UInt(Zm:'0');
constant integer nreg = 2;

    Encoding: Four registers

    Variants: FEAT_SME2 && FEAT_FAMINMAX (FEAT_SME2 && FEAT_FAMINMAX)

    313029282726252423222120191817161514131211109876543210
    110000011001011100101001
    sizeZmopcZdno2

    FAMIN { <Zdn1>.<T>-<Zdn4>.<T> }, { <Zdn1>.<T>-<Zdn4>.<T> }, { <Zm1>.<T>-<Zm4>.<T> }

    Decoding algorithm

    if !IsFeatureImplemented(FEAT_SME2) || !IsFeatureImplemented(FEAT_FAMINMAX) then
    EndOfDecode(Decode_UNDEF);
if size == '00' then EndOfDecode(Decode_UNDEF);
constant integer esize = 8 << UInt(size);
constant integer dn = UInt(Zdn:'00');
constant integer m = UInt(Zm:'00');
constant integer nreg = 4;

    Operation

    CheckStreamingSVEEnabled();
constant integer VL = CurrentVL;
constant integer elements = VL DIV esize;
array [0..3] of bits(VL) results;

for r = 0 to nreg-1
    constant bits(VL) operand1 = Z[dn+r, VL];
    constant bits(VL) operand2 = Z[m+r, VL];
    for e = 0 to elements-1
        constant bits(esize) element1 = Elem[operand1, e, esize];
        constant bits(esize) element2 = Elem[operand2, e, esize];
        Elem[results[r], e, esize] = FPAbsMin(element1, element2, FPCR);

for r = 0 to nreg-1
    Z[dn+r, VL] = results[r];

    Explanations

    <Zdn1>: For the "Two registers" variant: is the name of the first scalable vector register of the destination and first source multi-vector group, encoded as "Zdn" times 2.
    <Zdn1>: For the "Four registers" variant: is the name of the first scalable vector register of the destination and first source multi-vector group, encoded as "Zdn" times 4.
    <T>: <Zdn2>: Is the name of the second scalable vector register of the destination and first source multi-vector group, encoded as "Zdn" times 2 plus 1.
    <Zm1>: For the "Two registers" variant: is the name of the first scalable vector register of the second source multi-vector group, encoded as "Zm" times 2.
    <Zm1>: For the "Four registers" variant: is the name of the first scalable vector register of the second source multi-vector group, encoded as "Zm" times 4.
    <Zm2>: Is the name of the second scalable vector register of the second source multi-vector group, encoded as "Zm" times 2 plus 1.
    <Zdn4>: Is the name of the fourth scalable vector register of the destination and first source multi-vector group, encoded as "Zdn" times 4 plus 3.
    <Zm4>: Is the name of the fourth scalable vector register of the second source multi-vector group, encoded as "Zm" times 4 plus 3.