FDOT (2-way, multiple vectors, FP8 to FP16)
Multi-vector 8-bit floating-point dot-product to half-precision
The instruction computes the fused sum-of-products of a group of two 8-bit floating-point values held in the corresponding 16-bit elements of the two or four first and second source vectors. The half-precision sum-of-products are scaled by 2-UInt(FPMR.LSCALE[3:0]), before being destructively added without intermediate rounding to the corresponding half-precision elements of the ZA single-vector groups. The 8-bit floating-point encoding format for the elements of the first source vector and the second source vector is selected by FPMR.F8S1 and FPMR.F8S2 respectively.
The single-vector group within each half of or each quarter of the ZA array is selected by the sum of the vector select register and offset, modulo half or quarter the number of ZA array vectors.
The vector group symbol, VGx2 or VGx4, indicates that the ZA operand consists of two or four ZA single-vector groups respectively. The vector group symbol is preferred for disassembly, but optional in assembler source code.
This instruction is unpredicated.
Green
False
SM_1_only
It has encodings from 2 classes:
Two ZA single-vectors
and
Four ZA single-vectors
1
1
0
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0
FDOT ZA.H[<Wv>, <offs>{, VGx2}], { <Zn1>.B-<Zn2>.B }, { <Zm1>.B-<Zm2>.B }
if !IsFeatureImplemented(FEAT_SME_F8F16) then UNDEFINED;
constant integer v = UInt('010':Rv);
constant integer n = UInt(Zn:'0');
constant integer m = UInt(Zm:'0');
constant integer offset = UInt(off3);
constant integer nreg = 2;
1
1
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FDOT ZA.H[<Wv>, <offs>{, VGx4}], { <Zn1>.B-<Zn4>.B }, { <Zm1>.B-<Zm4>.B }
if !IsFeatureImplemented(FEAT_SME_F8F16) then UNDEFINED;
constant integer v = UInt('010':Rv);
constant integer n = UInt(Zn:'00');
constant integer m = UInt(Zm:'00');
constant integer offset = UInt(off3);
constant integer nreg = 4;
<Wv>
Is the 32-bit name of the vector select register W8-W11, encoded in the "Rv" field.
<offs>
Is the vector select offset, in the range 0 to 7, encoded in the "off3" field.
<Zn1>
For the two ZA single-vectors variant: is the name of the first scalable vector register of the first source multi-vector group, encoded as "Zn" times 2.
<Zn1>
For the four ZA single-vectors variant: is the name of the first scalable vector register of the first source multi-vector group, encoded as "Zn" times 4.
<Zn4>
Is the name of the fourth scalable vector register of the first source multi-vector group, encoded as "Zn" times 4 plus 3.
<Zn2>
Is the name of the second scalable vector register of the first source multi-vector group, encoded as "Zn" times 2 plus 1.
<Zm1>
For the two ZA single-vectors 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 ZA single-vectors variant: is the name of the first scalable vector register of the second source multi-vector group, encoded as "Zm" times 4.
<Zm4>
Is the name of the fourth scalable vector register of the second source multi-vector group, encoded as "Zm" times 4 plus 3.
<Zm2>
Is the name of the second scalable vector register of the second source multi-vector group, encoded as "Zm" times 2 plus 1.
CheckFPMREnabled();
CheckStreamingSVEAndZAEnabled();
constant integer VL = CurrentVL;
constant integer elements = VL DIV 16;
constant integer vectors = VL DIV 8;
constant integer vstride = vectors DIV nreg;
constant bits(32) vbase = X[v, 32];
integer vec = (UInt(vbase) + offset) MOD vstride;
bits(VL) result;
for r = 0 to nreg-1
constant bits(VL) operand1 = Z[n+r, VL];
constant bits(VL) operand2 = Z[m+r, VL];
constant bits(VL) operand3 = ZAvector[vec, VL];
for e = 0 to elements-1
constant bits(16) op1 = Elem[operand1, e, 16];
constant bits(16) op2 = Elem[operand2, e, 16];
bits(16) sum = Elem[operand3, e, 16];
sum = FP8DotAddFP(sum, op1, op2, FPCR, FPMR);
Elem[result, e, 16] = sum;
ZAvector[vec, VL] = result;
vec = vec + vstride;