Memory Copy, reads unprivileged, writes non-temporal. These instructions perform a memory copy. The prologue, main, and epilogue instructions are expected to be run in succession and to appear consecutively in memory: CPYPRTWN, then CPYMRTWN, and then CPYERTWN.
CPYPRTWN performs some preconditioning of the arguments suitable for using the CPYMRTWN instruction, and performs an implementation defined amount of the memory copy. CPYMRTWN performs an implementation defined amount of the memory copy. CPYERTWN performs the last part of the memory copy.
The inclusion of implementation defined amounts of memory copy allows some optimization of the size that can be performed.
For CPYPRTWN, the following saturation logic is applied:
If Xn<63:55> != 000000000, the copy size Xn is saturated to 0x007FFFFFFFFFFFFF.
After that saturation logic is applied, the direction of the memory copy is based on the following algorithm:
If (Xs > Xd) && (Xd + saturated Xn) > Xs, then direction = forward
Elsif (Xs < Xd) && (Xs + saturated Xn) > Xd, then direction = backward
Else direction = implementation defined choice between forward and backward.
The architecture supports two algorithms for the memory copy: option A and option B. Which algorithm is used is implementation defined.
Portable software should not assume that the choice of algorithm is constant.
After execution of CPYPRTWN, option A (which results in encoding PSTATE.C = 0):
After execution of CPYPRTWN, option B (which results in encoding PSTATE.C = 1):
For CPYMRTWN, option A (encoded by PSTATE.C = 0), the format of the arguments is:
For CPYMRTWN, option B (encoded by PSTATE.C = 1), the format of the arguments is:
For CPYERTWN, option A (encoded by PSTATE.C = 0), the format of the arguments is:
For CPYERTWN, option B (encoded by PSTATE.C = 1), the format of the arguments is:
31 | 30 | 29 | 28 | 27 | 26 | 25 | 24 | 23 | 22 | 21 | 20 | 19 | 18 | 17 | 16 | 15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
sz | 0 | 1 | 1 | 1 | 0 | 1 | op1 | 0 | Rs | 0 | 1 | 1 | 0 | 0 | 1 | Rn | Rd | ||||||||||||||
op2 |
if !HaveFeatMOPS() then UNDEFINED; if sz != '00' then UNDEFINED; integer d = UInt(Rd); integer s = UInt(Rs); integer n = UInt(Rn); bits(4) options = op2; MOPSStage stage; case op1 of when '00' stage = MOPSStage_Prologue; when '01' stage = MOPSStage_Main; when '10' stage = MOPSStage_Epilogue; otherwise SEE "Memory Copy and Memory Set"; if d == s || s == n || d == n then UNDEFINED; if d == 31 || s == 31 || n == 31 then UNDEFINED;
CheckMOPSEnabled(); integer N = MaxBlockSizeCopiedBytes(); bits(64) toaddress = X[d]; bits(64) fromaddress = X[s]; bits(64) cpysize = X[n]; bits(64) stagecpysize; bits(8*N) readdata; integer B; if HaveMTE2Ext() then SetTagCheckedInstruction(TRUE); boolean supports_option_a = MemCpyOptionA(); (racctype, wacctype) = MemCpyAccessTypes(options); if stage == MOPSStage_Prologue then if cpysize<63:55> != '000000000' then cpysize = 0x007FFFFFFFFFFFFF<63:0>; if ((UInt(fromaddress<55:0>) > UInt(toaddress<55:0>)) && (UInt(fromaddress<55:0>) < UInt(toaddress<55:0>+cpysize<55:0>))) then forward = TRUE; elsif ((UInt(fromaddress<55:0>) < UInt(toaddress<55:0>)) && (UInt(fromaddress<55:0>+cpysize<55:0>) > UInt(toaddress<55:0>))) then forward = FALSE; else forward = MemCpyDirectionChoice(fromaddress, toaddress, cpysize); if supports_option_a then PSTATE.C = '0'; PSTATE.N = '0'; if forward then // Copy in the forward direction offsets the arguments. toaddress = toaddress + cpysize; fromaddress = fromaddress + cpysize; cpysize = Zeros(64) - cpysize; else PSTATE.C = '1'; if !forward then // Copy in the reverse direction offsets the arguments. toaddress = toaddress + cpysize; fromaddress = fromaddress + cpysize; PSTATE.N = '1'; else PSTATE.N = '0'; PSTATE.V = '0'; PSTATE.Z = '0'; // IMP DEF selection of the amount covered by pre-processing. stagecpysize = CPYPreSizeChoice(toaddress, fromaddress, cpysize); assert stagecpysize<63> == cpysize<63> || stagecpysize == Zeros(); if SInt(cpysize) > 0 then assert SInt(stagecpysize) <= SInt(cpysize); else assert SInt(stagecpysize) >= SInt(cpysize); else boolean zero_size_exceptions = MemCpyZeroSizeCheck(); // Check if this version is consistent with the state of the call. if zero_size_exceptions || SInt(cpysize) != 0 then if supports_option_a then if PSTATE.C == '1' then boolean wrong_option = TRUE; boolean from_epilogue = stage == MOPSStage_Epilogue; MismatchedMemCpyException(supports_option_a, d, s, n, wrong_option, from_epilogue, options); else if PSTATE.C == '0' then boolean wrong_option = TRUE; boolean from_epilogue = stage == MOPSStage_Epilogue; MismatchedMemCpyException(supports_option_a, d, s, n, wrong_option, from_epilogue, options); bits(64) postsize = CPYPostSizeChoice(toaddress, fromaddress, cpysize); assert postsize<63> == cpysize<63> || SInt(postsize) == 0; if stage == MOPSStage_Main then stagecpysize = cpysize - postsize; // Check if the parameters to this instruction are valid. if MemCpyParametersIllformedM(toaddress, fromaddress, cpysize) then boolean wrong_option = FALSE; boolean from_epilogue = FALSE; MismatchedMemCpyException(supports_option_a, d, s, n, wrong_option, from_epilogue, options); else stagecpysize = postsize; // Check if the parameters to the epilogue are valid. if (cpysize != postsize || MemCpyParametersIllformedE(toaddress, fromaddress, cpysize)) then boolean wrong_option = FALSE; boolean from_epilogue = TRUE; MismatchedMemCpyException(supports_option_a, d, s, n, wrong_option, from_epilogue, options); if supports_option_a then while SInt(stagecpysize) != 0 do // IMP DEF selection of the block size that is worked on. While many // implementations might make this constant, that is not assumed. B = CPYSizeChoice(toaddress, fromaddress, cpysize); if SInt(cpysize) < 0 then assert B <= -1*SInt(stagecpysize); readdata<B*8-1:0> = Mem[fromaddress + cpysize, B, racctype]; Mem[toaddress + cpysize, B, wacctype] = readdata<B*8-1:0>; cpysize = cpysize + B; stagecpysize = stagecpysize + B; else assert B <= SInt(stagecpysize); cpysize = cpysize - B; stagecpysize = stagecpysize - B; readdata<B*8-1:0> = Mem[fromaddress + cpysize, B, racctype]; Mem[toaddress + cpysize, B, wacctype] = readdata<B*8-1:0>; if stage != MOPSStage_Prologue then X[n] = cpysize; else while UInt(stagecpysize) > 0 do // IMP DEF selection of the block size that is worked on. While many // implementations might make this constant, that is not assumed. B = CPYSizeChoice(toaddress, fromaddress, cpysize); assert B <= UInt(stagecpysize); if PSTATE.N == '0' then readdata<B*8-1:0> = Mem[fromaddress, B, racctype]; Mem[toaddress, B, wacctype] = readdata<B*8-1:0>; fromaddress = fromaddress + B; toaddress = toaddress + B; else readdata<B*8-1:0> = Mem[fromaddress - B, B, racctype]; Mem[toaddress - B, B, wacctype] = readdata<B*8-1:0>; fromaddress = fromaddress - B; toaddress = toaddress - B; cpysize = cpysize - B; stagecpysize = stagecpysize - B; if stage != MOPSStage_Prologue then X[n] = cpysize; X[d] = toaddress; X[s] = fromaddress; if stage == MOPSStage_Prologue then X[n] = cpysize; X[d] = toaddress; X[s] = fromaddress;
Internal version only: isa v33.11seprel, AdvSIMD v29.05, pseudocode v2021-09_rel, sve v2021-09_rc3d ; Build timestamp: 2021-10-06T11:41
Copyright © 2010-2021 Arm Limited or its affiliates. All rights reserved. This document is Non-Confidential.