VSUB (floating-point) Vector Subtract (floating-point) Vector Subtract (floating-point) subtracts the elements of one vector from the corresponding elements of another vector, and places the results in the destination vector. Depending on settings in the CPACR, NSACR, HCPTR, and FPEXC registers, and the Security state and PE mode in which the instruction is executed, an attempt to execute the instruction might be undefined, or trapped to Hyp mode. For more information see Enabling Advanced SIMD and floating-point support. It has encodings from the following instruction sets: A32 ( A1 and A2 ) and T32 ( T1 and T2 ) . 1 1 1 1 0 0 1 0 0 1 1 1 0 1 0 0 VSUB{<c>}{<q>}.<dt> {<Dd>, }<Dn>, <Dm> 1 VSUB{<c>}{<q>}.<dt> {<Qd>, }<Qn>, <Qm> if Q == '1' && (Vd<0> == '1' || Vn<0> == '1' || Vm<0> == '1') then UNDEFINED; if sz == '1' && !HaveFP16Ext() then UNDEFINED; advsimd = TRUE; integer esize; integer elements; case sz of when '0' esize = 32; elements = 2; when '1' esize = 16; elements = 4; d = UInt(D:Vd); n = UInt(N:Vn); m = UInt(M:Vm); regs = if Q == '0' then 1 else 2; != 1111 1 1 1 0 0 1 1 1 0 1 0 0 1 VSUB{<c>}{<q>}.F16 {<Sd>,} <Sn>, <Sm> 1 0 VSUB{<c>}{<q>}.F32 {<Sd>,} <Sn>, <Sm> 1 1 VSUB{<c>}{<q>}.F64 {<Dd>,} <Dn>, <Dm> if FPSCR.Len != '000' || FPSCR.Stride != '00' then UNDEFINED; if size == '00' || (size == '01' && !HaveFP16Ext()) then UNDEFINED; if size == '01' && cond != '1110' then UNPREDICTABLE; advsimd = FALSE; integer esize; integer d; integer n; integer m; case size of when '01' esize = 16; d = UInt(Vd:D); n = UInt(Vn:N); m = UInt(Vm:M); when '10' esize = 32; d = UInt(Vd:D); n = UInt(Vn:N); m = UInt(Vm:M); when '11' esize = 64; d = UInt(D:Vd); n = UInt(N:Vn); m = UInt(M:Vm); size == '01' && cond != '1110' The instruction executes as if it passes the Condition code check. The instruction executes as NOP. This means it behaves as if it fails the Condition code check. 1 1 1 0 1 1 1 1 0 1 1 1 0 1 0 0 VSUB{<c>}{<q>}.<dt> {<Dd>, }<Dn>, <Dm> 1 VSUB{<c>}{<q>}.<dt> {<Qd>, }<Qn>, <Qm> if Q == '1' && (Vd<0> == '1' || Vn<0> == '1' || Vm<0> == '1') then UNDEFINED; if sz == '1' && !HaveFP16Ext() then UNDEFINED; if sz == '1' && InITBlock() then UNPREDICTABLE; advsimd = TRUE; integer esize; integer elements; case sz of when '0' esize = 32; elements = 2; when '1' esize = 16; elements = 4; d = UInt(D:Vd); n = UInt(N:Vn); m = UInt(M:Vm); regs = if Q == '0' then 1 else 2; sz == '1' && InITBlock() The instruction executes as if it passes the Condition code check. The instruction executes as NOP. This means it behaves as if it fails the Condition code check. 1 1 1 0 1 1 1 0 0 1 1 1 0 1 0 0 1 VSUB{<c>}{<q>}.F16 {<Sd>,} <Sn>, <Sm> 1 0 VSUB{<c>}{<q>}.F32 {<Sd>,} <Sn>, <Sm> 1 1 VSUB{<c>}{<q>}.F64 {<Dd>,} <Dn>, <Dm> if FPSCR.Len != '000' || FPSCR.Stride != '00' then UNDEFINED; if size == '00' || (size == '01' && !HaveFP16Ext()) then UNDEFINED; if size == '01' && InITBlock() then UNPREDICTABLE; advsimd = FALSE; integer esize; integer d; integer n; integer m; case size of when '01' esize = 16; d = UInt(Vd:D); n = UInt(Vn:N); m = UInt(Vm:M); when '10' esize = 32; d = UInt(Vd:D); n = UInt(Vn:N); m = UInt(Vm:M); when '11' esize = 64; d = UInt(D:Vd); n = UInt(N:Vn); m = UInt(M:Vm); size == '01' && InITBlock() The instruction executes as if it passes the Condition code check. The instruction executes as NOP. This means it behaves as if it fails the Condition code check. <c> For encoding A1: see Standard assembler syntax fields. This encoding must be unconditional. <c> For encoding A2, T1 and T2: see Standard assembler syntax fields. <q> See Standard assembler syntax fields. <dt> Is the data type for the elements of the vectors, sz <dt> 0 F32 1 F16 <Qd> Is the 128-bit name of the SIMD&FP destination register, encoded in the "D:Vd" field as <Qd>*2. <Qn> Is the 128-bit name of the first SIMD&FP source register, encoded in the "N:Vn" field as <Qn>*2. <Qm> Is the 128-bit name of the second SIMD&FP source register, encoded in the "M:Vm" field as <Qm>*2. <Dd> Is the 64-bit name of the SIMD&FP destination register, encoded in the "D:Vd" field. <Dn> Is the 64-bit name of the first SIMD&FP source register, encoded in the "N:Vn" field. <Dm> Is the 64-bit name of the second SIMD&FP source register, encoded in the "M:Vm" field. <Sd> Is the 32-bit name of the SIMD&FP destination register, encoded in the "Vd:D" field. <Sn> Is the 32-bit name of the first SIMD&FP source register, encoded in the "Vn:N" field. <Sm> Is the 32-bit name of the second SIMD&FP source register, encoded in the "Vm:M" field. if ConditionPassed() then EncodingSpecificOperations(); CheckAdvSIMDOrVFPEnabled(TRUE, advsimd); if advsimd then // Advanced SIMD instruction for r = 0 to regs-1 for e = 0 to elements-1 Elem[D[d+r],e,esize] = FPSub(Elem[D[n+r],e,esize], Elem[D[m+r],e,esize], StandardFPSCRValue()); else // VFP instruction case esize of when 16 S[d] = Zeros(16) : FPSub(S[n]<15:0>, S[m]<15:0>, FPSCR[]); when 32 S[d] = FPSub(S[n], S[m], FPSCR[]); when 64 D[d] = FPSub(D[n], D[m], FPSCR[]);