/* Chrysalide - Outil d'analyse de fichiers binaires * ##FILE## - traduction d'instructions ARMv7 * * Copyright (C) 2017 Cyrille Bagard * * This file is part of Chrysalide. * * Chrysalide is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * Chrysalide is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with Chrysalide. If not, see . */ @title VQNEG @id 328 @desc { Vector Saturating Negate negates each element in a vector, and places the results in the destination vector. If any of the results overflow, they are saturated. The cumulative saturation bit, FPSCR.QC, is set if saturation occurs. For details see Pseudocode details of saturation on page A2-44. Depending on settings in the CPACR, NSACR, and HCPTR registers, and the security state and mode in which the instruction is executed, an attempt to execute the instruction might be UNDEFINED, or trapped to Hyp mode. Summary of access controls for Advanced SIMD functionality on page B1-1232 summarizes these controls. ARM deprecates the conditional execution of any Advanced SIMD instruction encoding that is not also available as a VFP instruction encoding, see Conditional execution on page A8-288. } @encoding (T1) { @word 1 1 1 1 1 1 1 1 1 D(1) 1 1 size(2) 0 0 Vd(4) 0 1 1 1 1 Q(1) M(1) 0 Vm(4) @syntax { @subid 1617 @assert { Q == 1 size == 0 } @conv { qwvec_D = QuadWordVector(D:Vd) qwvec_M = QuadWordVector(M:Vm) } @asm vqneg.s8 qwvec_D qwvec_M } @syntax { @subid 1618 @assert { Q == 1 size == 1 } @conv { qwvec_D = QuadWordVector(D:Vd) qwvec_M = QuadWordVector(M:Vm) } @asm vqneg.s16 qwvec_D qwvec_M } @syntax { @subid 1619 @assert { Q == 1 size == 10 } @conv { qwvec_D = QuadWordVector(D:Vd) qwvec_M = QuadWordVector(M:Vm) } @asm vqneg.s32 qwvec_D qwvec_M } @syntax { @subid 1620 @assert { Q == 0 size == 0 } @conv { dwvec_D = DoubleWordVector(D:Vd) dwvec_M = DoubleWordVector(M:Vm) } @asm vqneg.s8 dwvec_D dwvec_M } @syntax { @subid 1621 @assert { Q == 0 size == 1 } @conv { dwvec_D = DoubleWordVector(D:Vd) dwvec_M = DoubleWordVector(M:Vm) } @asm vqneg.s16 dwvec_D dwvec_M } @syntax { @subid 1622 @assert { Q == 0 size == 10 } @conv { dwvec_D = DoubleWordVector(D:Vd) dwvec_M = DoubleWordVector(M:Vm) } @asm vqneg.s32 dwvec_D dwvec_M } } @encoding (A1) { @word 1 1 1 1 1 1 1 1 1 D(1) 1 1 size(2) 0 0 Vd(4) 0 1 1 1 1 Q(1) M(1) 0 Vm(4) @syntax { @subid 1623 @assert { Q == 1 size == 0 } @conv { qwvec_D = QuadWordVector(D:Vd) qwvec_M = QuadWordVector(M:Vm) } @asm vqneg.s8 qwvec_D qwvec_M } @syntax { @subid 1624 @assert { Q == 1 size == 1 } @conv { qwvec_D = QuadWordVector(D:Vd) qwvec_M = QuadWordVector(M:Vm) } @asm vqneg.s16 qwvec_D qwvec_M } @syntax { @subid 1625 @assert { Q == 1 size == 10 } @conv { qwvec_D = QuadWordVector(D:Vd) qwvec_M = QuadWordVector(M:Vm) } @asm vqneg.s32 qwvec_D qwvec_M } @syntax { @subid 1626 @assert { Q == 0 size == 0 } @conv { dwvec_D = DoubleWordVector(D:Vd) dwvec_M = DoubleWordVector(M:Vm) } @asm vqneg.s8 dwvec_D dwvec_M } @syntax { @subid 1627 @assert { Q == 0 size == 1 } @conv { dwvec_D = DoubleWordVector(D:Vd) dwvec_M = DoubleWordVector(M:Vm) } @asm vqneg.s16 dwvec_D dwvec_M } @syntax { @subid 1628 @assert { Q == 0 size == 10 } @conv { dwvec_D = DoubleWordVector(D:Vd) dwvec_M = DoubleWordVector(M:Vm) } @asm vqneg.s32 dwvec_D dwvec_M } }