// Based on cmd/internal/obj/ppc64/asm9.go. // // Copyright © 1994-1999 Lucent Technologies Inc. All rights reserved. // Portions Copyright © 1995-1997 C H Forsyth (forsyth@terzarima.net) // Portions Copyright © 1997-1999 Vita Nuova Limited // Portions Copyright © 2000-2008 Vita Nuova Holdings Limited (www.vitanuova.com) // Portions Copyright © 2004,2006 Bruce Ellis // Portions Copyright © 2005-2007 C H Forsyth (forsyth@terzarima.net) // Revisions Copyright © 2000-2008 Lucent Technologies Inc. and others // Portions Copyright © 2009 The Go Authors. All rights reserved. // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN // THE SOFTWARE. package s390x import ( "cmd/internal/obj" "cmd/internal/objabi" "fmt" "log" "math" "slices" ) // ctxtz holds state while assembling a single function. // Each function gets a fresh ctxtz. // This allows for multiple functions to be safely concurrently assembled. type ctxtz struct { ctxt *obj.Link newprog obj.ProgAlloc cursym *obj.LSym autosize int32 instoffset int64 pc int64 } // instruction layout. const ( funcAlign = 16 ) type Optab struct { as obj.As // opcode i uint8 // handler index a1 uint8 // From a2 uint8 // Reg a3 uint8 // RestArgs[0] a4 uint8 // RestArgs[1] a5 uint8 // RestArgs[2] a6 uint8 // To } var optab = []Optab{ // zero-length instructions {i: 0, as: obj.ATEXT, a1: C_ADDR, a6: C_TEXTSIZE}, {i: 0, as: obj.ATEXT, a1: C_ADDR, a3: C_LCON, a6: C_TEXTSIZE}, {i: 0, as: obj.APCDATA, a1: C_LCON, a6: C_LCON}, {i: 0, as: obj.AFUNCDATA, a1: C_SCON, a6: C_ADDR}, {i: 0, as: obj.ANOP}, {i: 0, as: obj.ANOP, a1: C_SAUTO}, // move register {i: 1, as: AMOVD, a1: C_REG, a6: C_REG}, {i: 1, as: AMOVB, a1: C_REG, a6: C_REG}, {i: 1, as: AMOVBZ, a1: C_REG, a6: C_REG}, {i: 1, as: AMOVW, a1: C_REG, a6: C_REG}, {i: 1, as: AMOVWZ, a1: C_REG, a6: C_REG}, {i: 1, as: AFMOVD, a1: C_FREG, a6: C_FREG}, {i: 1, as: AMOVDBR, a1: C_REG, a6: C_REG}, // load constant {i: 26, as: AMOVD, a1: C_LACON, a6: C_REG}, {i: 26, as: AMOVW, a1: C_LACON, a6: C_REG}, {i: 26, as: AMOVWZ, a1: C_LACON, a6: C_REG}, {i: 3, as: AMOVD, a1: C_DCON, a6: C_REG}, {i: 3, as: AMOVW, a1: C_DCON, a6: C_REG}, {i: 3, as: AMOVWZ, a1: C_DCON, a6: C_REG}, {i: 3, as: AMOVB, a1: C_DCON, a6: C_REG}, {i: 3, as: AMOVBZ, a1: C_DCON, a6: C_REG}, // store constant {i: 72, as: AMOVD, a1: C_SCON, a6: C_LAUTO}, {i: 72, as: AMOVD, a1: C_ADDCON, a6: C_LAUTO}, {i: 72, as: AMOVW, a1: C_SCON, a6: C_LAUTO}, {i: 72, as: AMOVW, a1: C_ADDCON, a6: C_LAUTO}, {i: 72, as: AMOVWZ, a1: C_SCON, a6: C_LAUTO}, {i: 72, as: AMOVWZ, a1: C_ADDCON, a6: C_LAUTO}, {i: 72, as: AMOVB, a1: C_SCON, a6: C_LAUTO}, {i: 72, as: AMOVB, a1: C_ADDCON, a6: C_LAUTO}, {i: 72, as: AMOVBZ, a1: C_SCON, a6: C_LAUTO}, {i: 72, as: AMOVBZ, a1: C_ADDCON, a6: C_LAUTO}, {i: 72, as: AMOVD, a1: C_SCON, a6: C_LOREG}, {i: 72, as: AMOVD, a1: C_ADDCON, a6: C_LOREG}, {i: 72, as: AMOVW, a1: C_SCON, a6: C_LOREG}, {i: 72, as: AMOVW, a1: C_ADDCON, a6: C_LOREG}, {i: 72, as: AMOVWZ, a1: C_SCON, a6: C_LOREG}, {i: 72, as: AMOVWZ, a1: C_ADDCON, a6: C_LOREG}, {i: 72, as: AMOVB, a1: C_SCON, a6: C_LOREG}, {i: 72, as: AMOVB, a1: C_ADDCON, a6: C_LOREG}, {i: 72, as: AMOVBZ, a1: C_SCON, a6: C_LOREG}, {i: 72, as: AMOVBZ, a1: C_ADDCON, a6: C_LOREG}, // store {i: 35, as: AMOVD, a1: C_REG, a6: C_LAUTO}, {i: 35, as: AMOVW, a1: C_REG, a6: C_LAUTO}, {i: 35, as: AMOVWZ, a1: C_REG, a6: C_LAUTO}, {i: 35, as: AMOVBZ, a1: C_REG, a6: C_LAUTO}, {i: 35, as: AMOVB, a1: C_REG, a6: C_LAUTO}, {i: 35, as: AMOVDBR, a1: C_REG, a6: C_LAUTO}, {i: 35, as: AMOVHBR, a1: C_REG, a6: C_LAUTO}, {i: 35, as: AMOVD, a1: C_REG, a6: C_LOREG}, {i: 35, as: AMOVW, a1: C_REG, a6: C_LOREG}, {i: 35, as: AMOVWZ, a1: C_REG, a6: C_LOREG}, {i: 35, as: AMOVBZ, a1: C_REG, a6: C_LOREG}, {i: 35, as: AMOVB, a1: C_REG, a6: C_LOREG}, {i: 35, as: AMOVDBR, a1: C_REG, a6: C_LOREG}, {i: 35, as: AMOVHBR, a1: C_REG, a6: C_LOREG}, {i: 74, as: AMOVD, a1: C_REG, a6: C_ADDR}, {i: 74, as: AMOVW, a1: C_REG, a6: C_ADDR}, {i: 74, as: AMOVWZ, a1: C_REG, a6: C_ADDR}, {i: 74, as: AMOVBZ, a1: C_REG, a6: C_ADDR}, {i: 74, as: AMOVB, a1: C_REG, a6: C_ADDR}, // load {i: 36, as: AMOVD, a1: C_LAUTO, a6: C_REG}, {i: 36, as: AMOVW, a1: C_LAUTO, a6: C_REG}, {i: 36, as: AMOVWZ, a1: C_LAUTO, a6: C_REG}, {i: 36, as: AMOVBZ, a1: C_LAUTO, a6: C_REG}, {i: 36, as: AMOVB, a1: C_LAUTO, a6: C_REG}, {i: 36, as: AMOVDBR, a1: C_LAUTO, a6: C_REG}, {i: 36, as: AMOVHBR, a1: C_LAUTO, a6: C_REG}, {i: 36, as: AMOVD, a1: C_LOREG, a6: C_REG}, {i: 36, as: AMOVW, a1: C_LOREG, a6: C_REG}, {i: 36, as: AMOVWZ, a1: C_LOREG, a6: C_REG}, {i: 36, as: AMOVBZ, a1: C_LOREG, a6: C_REG}, {i: 36, as: AMOVB, a1: C_LOREG, a6: C_REG}, {i: 36, as: AMOVDBR, a1: C_LOREG, a6: C_REG}, {i: 36, as: AMOVHBR, a1: C_LOREG, a6: C_REG}, {i: 75, as: AMOVD, a1: C_ADDR, a6: C_REG}, {i: 75, as: AMOVW, a1: C_ADDR, a6: C_REG}, {i: 75, as: AMOVWZ, a1: C_ADDR, a6: C_REG}, {i: 75, as: AMOVBZ, a1: C_ADDR, a6: C_REG}, {i: 75, as: AMOVB, a1: C_ADDR, a6: C_REG}, // interlocked load and op {i: 99, as: ALAAG, a1: C_REG, a2: C_REG, a6: C_LOREG}, // integer arithmetic {i: 2, as: AADD, a1: C_REG, a2: C_REG, a6: C_REG}, {i: 2, as: AADD, a1: C_REG, a6: C_REG}, {i: 22, as: AADD, a1: C_LCON, a2: C_REG, a6: C_REG}, {i: 22, as: AADD, a1: C_LCON, a6: C_REG}, {i: 12, as: AADD, a1: C_LOREG, a6: C_REG}, {i: 12, as: AADD, a1: C_LAUTO, a6: C_REG}, {i: 21, as: ASUB, a1: C_LCON, a2: C_REG, a6: C_REG}, {i: 21, as: ASUB, a1: C_LCON, a6: C_REG}, {i: 12, as: ASUB, a1: C_LOREG, a6: C_REG}, {i: 12, as: ASUB, a1: C_LAUTO, a6: C_REG}, {i: 4, as: AMULHD, a1: C_REG, a6: C_REG}, {i: 4, as: AMULHD, a1: C_REG, a2: C_REG, a6: C_REG}, {i: 62, as: AMLGR, a1: C_REG, a6: C_REG}, {i: 2, as: ADIVW, a1: C_REG, a2: C_REG, a6: C_REG}, {i: 2, as: ADIVW, a1: C_REG, a6: C_REG}, {i: 10, as: ASUB, a1: C_REG, a2: C_REG, a6: C_REG}, {i: 10, as: ASUB, a1: C_REG, a6: C_REG}, {i: 47, as: ANEG, a1: C_REG, a6: C_REG}, {i: 47, as: ANEG, a6: C_REG}, // integer logical {i: 6, as: AAND, a1: C_REG, a2: C_REG, a6: C_REG}, {i: 6, as: AAND, a1: C_REG, a6: C_REG}, {i: 23, as: AAND, a1: C_LCON, a6: C_REG}, {i: 12, as: AAND, a1: C_LOREG, a6: C_REG}, {i: 12, as: AAND, a1: C_LAUTO, a6: C_REG}, {i: 6, as: AANDW, a1: C_REG, a2: C_REG, a6: C_REG}, {i: 6, as: AANDW, a1: C_REG, a6: C_REG}, {i: 24, as: AANDW, a1: C_LCON, a6: C_REG}, {i: 12, as: AANDW, a1: C_LOREG, a6: C_REG}, {i: 12, as: AANDW, a1: C_LAUTO, a6: C_REG}, {i: 7, as: ASLD, a1: C_REG, a6: C_REG}, {i: 7, as: ASLD, a1: C_REG, a2: C_REG, a6: C_REG}, {i: 7, as: ASLD, a1: C_SCON, a2: C_REG, a6: C_REG}, {i: 7, as: ASLD, a1: C_SCON, a6: C_REG}, {i: 13, as: ARNSBG, a1: C_SCON, a3: C_SCON, a4: C_SCON, a5: C_REG, a6: C_REG}, // compare and swap {i: 79, as: ACSG, a1: C_REG, a2: C_REG, a6: C_SOREG}, // floating point {i: 32, as: AFADD, a1: C_FREG, a6: C_FREG}, {i: 33, as: AFABS, a1: C_FREG, a6: C_FREG}, {i: 33, as: AFABS, a6: C_FREG}, {i: 34, as: AFMADD, a1: C_FREG, a2: C_FREG, a6: C_FREG}, {i: 32, as: AFMUL, a1: C_FREG, a6: C_FREG}, {i: 36, as: AFMOVD, a1: C_LAUTO, a6: C_FREG}, {i: 36, as: AFMOVD, a1: C_LOREG, a6: C_FREG}, {i: 75, as: AFMOVD, a1: C_ADDR, a6: C_FREG}, {i: 35, as: AFMOVD, a1: C_FREG, a6: C_LAUTO}, {i: 35, as: AFMOVD, a1: C_FREG, a6: C_LOREG}, {i: 74, as: AFMOVD, a1: C_FREG, a6: C_ADDR}, {i: 67, as: AFMOVD, a1: C_ZCON, a6: C_FREG}, {i: 81, as: ALDGR, a1: C_REG, a6: C_FREG}, {i: 81, as: ALGDR, a1: C_FREG, a6: C_REG}, {i: 82, as: ACEFBRA, a1: C_REG, a6: C_FREG}, {i: 83, as: ACFEBRA, a1: C_FREG, a6: C_REG}, {i: 48, as: AFIEBR, a1: C_SCON, a2: C_FREG, a6: C_FREG}, {i: 49, as: ACPSDR, a1: C_FREG, a2: C_FREG, a6: C_FREG}, {i: 50, as: ALTDBR, a1: C_FREG, a6: C_FREG}, {i: 51, as: ATCDB, a1: C_FREG, a6: C_SCON}, // load symbol address (plus offset) {i: 19, as: AMOVD, a1: C_SYMADDR, a6: C_REG}, {i: 93, as: AMOVD, a1: C_GOTADDR, a6: C_REG}, {i: 94, as: AMOVD, a1: C_TLS_LE, a6: C_REG}, {i: 95, as: AMOVD, a1: C_TLS_IE, a6: C_REG}, // system call {i: 5, as: ASYSCALL}, {i: 77, as: ASYSCALL, a1: C_SCON}, // branch {i: 16, as: ABEQ, a6: C_SBRA}, {i: 16, as: ABRC, a1: C_SCON, a6: C_SBRA}, {i: 11, as: ABR, a6: C_LBRA}, {i: 16, as: ABC, a1: C_SCON, a2: C_REG, a6: C_LBRA}, {i: 18, as: ABR, a6: C_REG}, {i: 18, as: ABR, a1: C_REG, a6: C_REG}, {i: 15, as: ABR, a6: C_ZOREG}, {i: 15, as: ABC, a6: C_ZOREG}, // compare and branch {i: 89, as: ACGRJ, a1: C_SCON, a2: C_REG, a3: C_REG, a6: C_SBRA}, {i: 89, as: ACMPBEQ, a1: C_REG, a2: C_REG, a6: C_SBRA}, {i: 89, as: ACLGRJ, a1: C_SCON, a2: C_REG, a3: C_REG, a6: C_SBRA}, {i: 89, as: ACMPUBEQ, a1: C_REG, a2: C_REG, a6: C_SBRA}, {i: 90, as: ACGIJ, a1: C_SCON, a2: C_REG, a3: C_ADDCON, a6: C_SBRA}, {i: 90, as: ACGIJ, a1: C_SCON, a2: C_REG, a3: C_SCON, a6: C_SBRA}, {i: 90, as: ACMPBEQ, a1: C_REG, a3: C_ADDCON, a6: C_SBRA}, {i: 90, as: ACMPBEQ, a1: C_REG, a3: C_SCON, a6: C_SBRA}, {i: 90, as: ACLGIJ, a1: C_SCON, a2: C_REG, a3: C_ADDCON, a6: C_SBRA}, {i: 90, as: ACMPUBEQ, a1: C_REG, a3: C_ANDCON, a6: C_SBRA}, // branch on count {i: 41, as: ABRCT, a1: C_REG, a6: C_SBRA}, {i: 41, as: ABRCTG, a1: C_REG, a6: C_SBRA}, // move on condition {i: 17, as: AMOVDEQ, a1: C_REG, a6: C_REG}, // load on condition {i: 25, as: ALOCGR, a1: C_SCON, a2: C_REG, a6: C_REG}, // find leftmost one {i: 8, as: AFLOGR, a1: C_REG, a6: C_REG}, // population count {i: 9, as: APOPCNT, a1: C_REG, a6: C_REG}, // compare {i: 70, as: ACMP, a1: C_REG, a6: C_REG}, {i: 71, as: ACMP, a1: C_REG, a6: C_LCON}, {i: 70, as: ACMPU, a1: C_REG, a6: C_REG}, {i: 71, as: ACMPU, a1: C_REG, a6: C_LCON}, {i: 70, as: AFCMPO, a1: C_FREG, a6: C_FREG}, {i: 70, as: AFCMPO, a1: C_FREG, a2: C_REG, a6: C_FREG}, // test under mask {i: 91, as: ATMHH, a1: C_REG, a6: C_ANDCON}, // insert program mask {i: 92, as: AIPM, a1: C_REG}, // set program mask {i: 76, as: ASPM, a1: C_REG}, // 32-bit access registers {i: 68, as: AMOVW, a1: C_AREG, a6: C_REG}, {i: 68, as: AMOVWZ, a1: C_AREG, a6: C_REG}, {i: 69, as: AMOVW, a1: C_REG, a6: C_AREG}, {i: 69, as: AMOVWZ, a1: C_REG, a6: C_AREG}, // macros {i: 96, as: ACLEAR, a1: C_LCON, a6: C_LOREG}, {i: 96, as: ACLEAR, a1: C_LCON, a6: C_LAUTO}, // load/store multiple {i: 97, as: ASTMG, a1: C_REG, a2: C_REG, a6: C_LOREG}, {i: 97, as: ASTMG, a1: C_REG, a2: C_REG, a6: C_LAUTO}, {i: 98, as: ALMG, a1: C_LOREG, a2: C_REG, a6: C_REG}, {i: 98, as: ALMG, a1: C_LAUTO, a2: C_REG, a6: C_REG}, // bytes {i: 40, as: ABYTE, a1: C_SCON}, {i: 40, as: AWORD, a1: C_LCON}, {i: 31, as: ADWORD, a1: C_LCON}, {i: 31, as: ADWORD, a1: C_DCON}, // fast synchronization {i: 80, as: ASYNC}, // store clock {i: 88, as: ASTCK, a6: C_SAUTO}, {i: 88, as: ASTCK, a6: C_SOREG}, // storage and storage {i: 84, as: AMVC, a1: C_SCON, a3: C_LOREG, a6: C_LOREG}, {i: 84, as: AMVC, a1: C_SCON, a3: C_LOREG, a6: C_LAUTO}, {i: 84, as: AMVC, a1: C_SCON, a3: C_LAUTO, a6: C_LAUTO}, // address {i: 85, as: ALARL, a1: C_LCON, a6: C_REG}, {i: 85, as: ALARL, a1: C_SYMADDR, a6: C_REG}, {i: 86, as: ALA, a1: C_SOREG, a6: C_REG}, {i: 86, as: ALA, a1: C_SAUTO, a6: C_REG}, {i: 87, as: AEXRL, a1: C_SYMADDR, a6: C_REG}, // undefined (deliberate illegal instruction) {i: 78, as: obj.AUNDEF}, // Break point instruction(0x0001 opcode) {i: 73, as: ABRRK}, // 2 byte no-operation {i: 66, as: ANOPH}, // crypto instructions // KM {i: 124, as: AKM, a1: C_REG, a6: C_REG}, // KDSA {i: 125, as: AKDSA, a1: C_REG, a6: C_REG}, // KMA {i: 126, as: AKMA, a1: C_REG, a2: C_REG, a6: C_REG}, // vector instructions // VRX store {i: 100, as: AVST, a1: C_VREG, a6: C_SOREG}, {i: 100, as: AVST, a1: C_VREG, a6: C_SAUTO}, {i: 100, as: AVSTEG, a1: C_SCON, a2: C_VREG, a6: C_SOREG}, {i: 100, as: AVSTEG, a1: C_SCON, a2: C_VREG, a6: C_SAUTO}, // VRX load {i: 101, as: AVL, a1: C_SOREG, a6: C_VREG}, {i: 101, as: AVL, a1: C_SAUTO, a6: C_VREG}, {i: 101, as: AVLEG, a1: C_SCON, a3: C_SOREG, a6: C_VREG}, {i: 101, as: AVLEG, a1: C_SCON, a3: C_SAUTO, a6: C_VREG}, // VRV scatter {i: 102, as: AVSCEG, a1: C_SCON, a2: C_VREG, a6: C_SOREG}, {i: 102, as: AVSCEG, a1: C_SCON, a2: C_VREG, a6: C_SAUTO}, // VRV gather {i: 103, as: AVGEG, a1: C_SCON, a3: C_SOREG, a6: C_VREG}, {i: 103, as: AVGEG, a1: C_SCON, a3: C_SAUTO, a6: C_VREG}, // VRS element shift/rotate and load gr to/from vr element {i: 104, as: AVESLG, a1: C_SCON, a2: C_VREG, a6: C_VREG}, {i: 104, as: AVESLG, a1: C_REG, a2: C_VREG, a6: C_VREG}, {i: 104, as: AVESLG, a1: C_SCON, a6: C_VREG}, {i: 104, as: AVESLG, a1: C_REG, a6: C_VREG}, {i: 104, as: AVLGVG, a1: C_SCON, a2: C_VREG, a6: C_REG}, {i: 104, as: AVLGVG, a1: C_REG, a2: C_VREG, a6: C_REG}, {i: 104, as: AVLVGG, a1: C_SCON, a2: C_REG, a6: C_VREG}, {i: 104, as: AVLVGG, a1: C_REG, a2: C_REG, a6: C_VREG}, // VRS store multiple {i: 105, as: AVSTM, a1: C_VREG, a2: C_VREG, a6: C_SOREG}, {i: 105, as: AVSTM, a1: C_VREG, a2: C_VREG, a6: C_SAUTO}, // VRS load multiple {i: 106, as: AVLM, a1: C_SOREG, a2: C_VREG, a6: C_VREG}, {i: 106, as: AVLM, a1: C_SAUTO, a2: C_VREG, a6: C_VREG}, // VRS store with length {i: 107, as: AVSTL, a1: C_REG, a2: C_VREG, a6: C_SOREG}, {i: 107, as: AVSTL, a1: C_REG, a2: C_VREG, a6: C_SAUTO}, // VRS load with length {i: 108, as: AVLL, a1: C_REG, a3: C_SOREG, a6: C_VREG}, {i: 108, as: AVLL, a1: C_REG, a3: C_SAUTO, a6: C_VREG}, // VRI-a {i: 109, as: AVGBM, a1: C_ANDCON, a6: C_VREG}, {i: 109, as: AVZERO, a6: C_VREG}, {i: 109, as: AVREPIG, a1: C_ADDCON, a6: C_VREG}, {i: 109, as: AVREPIG, a1: C_SCON, a6: C_VREG}, {i: 109, as: AVLEIG, a1: C_SCON, a3: C_ADDCON, a6: C_VREG}, {i: 109, as: AVLEIG, a1: C_SCON, a3: C_SCON, a6: C_VREG}, // VRI-b generate mask {i: 110, as: AVGMG, a1: C_SCON, a3: C_SCON, a6: C_VREG}, // VRI-c replicate {i: 111, as: AVREPG, a1: C_UCON, a2: C_VREG, a6: C_VREG}, // VRI-d element rotate and insert under mask and // shift left double by byte {i: 112, as: AVERIMG, a1: C_SCON, a2: C_VREG, a3: C_VREG, a6: C_VREG}, {i: 112, as: AVSLDB, a1: C_SCON, a2: C_VREG, a3: C_VREG, a6: C_VREG}, // VRI-d fp test data class immediate {i: 113, as: AVFTCIDB, a1: C_SCON, a2: C_VREG, a6: C_VREG}, // VRR-a load reg {i: 114, as: AVLR, a1: C_VREG, a6: C_VREG}, // VRR-a compare {i: 115, as: AVECG, a1: C_VREG, a6: C_VREG}, // VRR-b {i: 117, as: AVCEQG, a1: C_VREG, a2: C_VREG, a6: C_VREG}, {i: 117, as: AVFAEF, a1: C_VREG, a2: C_VREG, a6: C_VREG}, {i: 117, as: AVPKSG, a1: C_VREG, a2: C_VREG, a6: C_VREG}, // VRR-c {i: 118, as: AVAQ, a1: C_VREG, a2: C_VREG, a6: C_VREG}, {i: 118, as: AVAQ, a1: C_VREG, a6: C_VREG}, {i: 118, as: AVNOT, a1: C_VREG, a6: C_VREG}, {i: 123, as: AVPDI, a1: C_SCON, a2: C_VREG, a3: C_VREG, a6: C_VREG}, // VRR-c shifts {i: 119, as: AVERLLVG, a1: C_VREG, a2: C_VREG, a6: C_VREG}, {i: 119, as: AVERLLVG, a1: C_VREG, a6: C_VREG}, // VRR-d {i: 120, as: AVACQ, a1: C_VREG, a2: C_VREG, a3: C_VREG, a6: C_VREG}, // VRR-e {i: 121, as: AVSEL, a1: C_VREG, a2: C_VREG, a3: C_VREG, a6: C_VREG}, // VRR-f {i: 122, as: AVLVGP, a1: C_REG, a2: C_REG, a6: C_VREG}, } var oprange [ALAST & obj.AMask][]Optab var xcmp [C_NCLASS][C_NCLASS]bool func spanz(ctxt *obj.Link, cursym *obj.LSym, newprog obj.ProgAlloc) { if ctxt.Retpoline { ctxt.Diag("-spectre=ret not supported on s390x") ctxt.Retpoline = false // don't keep printing } p := cursym.Func().Text if p == nil || p.Link == nil { // handle external functions and ELF section symbols return } if oprange[AORW&obj.AMask] == nil { ctxt.Diag("s390x ops not initialized, call s390x.buildop first") } c := ctxtz{ctxt: ctxt, newprog: newprog, cursym: cursym, autosize: int32(p.To.Offset)} buffer := make([]byte, 0) changed := true loop := 0 nrelocs0 := len(c.cursym.R) for changed { if loop > 100 { c.ctxt.Diag("stuck in spanz loop") break } changed = false buffer = buffer[:0] for i := range c.cursym.R[nrelocs0:] { c.cursym.R[nrelocs0+i] = obj.Reloc{} } c.cursym.R = c.cursym.R[:nrelocs0] // preserve marker relocations generated by the compiler for p := c.cursym.Func().Text; p != nil; p = p.Link { pc := int64(len(buffer)) if pc != p.Pc { changed = true } p.Pc = pc c.pc = p.Pc c.asmout(p, &buffer) if pc == int64(len(buffer)) { switch p.As { case obj.ANOP, obj.AFUNCDATA, obj.APCDATA, obj.ATEXT: // ok default: c.ctxt.Diag("zero-width instruction\n%v", p) } } } loop++ } c.cursym.Size = int64(len(buffer)) if c.cursym.Size%funcAlign != 0 { c.cursym.Size += funcAlign - (c.cursym.Size % funcAlign) } c.cursym.Grow(c.cursym.Size) copy(c.cursym.P, buffer) // Mark nonpreemptible instruction sequences. // We use REGTMP as a scratch register during call injection, // so instruction sequences that use REGTMP are unsafe to // preempt asynchronously. obj.MarkUnsafePoints(c.ctxt, c.cursym.Func().Text, c.newprog, c.isUnsafePoint, nil) } // Return whether p is an unsafe point. func (c *ctxtz) isUnsafePoint(p *obj.Prog) bool { if p.From.Reg == REGTMP || p.To.Reg == REGTMP || p.Reg == REGTMP { return true } for _, a := range p.RestArgs { if a.Reg == REGTMP { return true } } return p.Mark&USETMP != 0 } func isint32(v int64) bool { return int64(int32(v)) == v } func isuint32(v uint64) bool { return uint64(uint32(v)) == v } func (c *ctxtz) aclass(a *obj.Addr) int { switch a.Type { case obj.TYPE_NONE: return C_NONE case obj.TYPE_REG: if REG_R0 <= a.Reg && a.Reg <= REG_R15 { return C_REG } if REG_F0 <= a.Reg && a.Reg <= REG_F15 { return C_FREG } if REG_AR0 <= a.Reg && a.Reg <= REG_AR15 { return C_AREG } if REG_V0 <= a.Reg && a.Reg <= REG_V31 { return C_VREG } return C_GOK case obj.TYPE_MEM: switch a.Name { case obj.NAME_EXTERN, obj.NAME_STATIC: if a.Sym == nil { // must have a symbol break } c.instoffset = a.Offset if a.Sym.Type == objabi.STLSBSS { if c.ctxt.Flag_shared { return C_TLS_IE // initial exec model } return C_TLS_LE // local exec model } return C_ADDR case obj.NAME_GOTREF: return C_GOTADDR case obj.NAME_AUTO: if a.Reg == REGSP { // unset base register for better printing, since // a.Offset is still relative to pseudo-SP. a.Reg = obj.REG_NONE } c.instoffset = int64(c.autosize) + a.Offset if c.instoffset >= -BIG && c.instoffset < BIG { return C_SAUTO } return C_LAUTO case obj.NAME_PARAM: if a.Reg == REGSP { // unset base register for better printing, since // a.Offset is still relative to pseudo-FP. a.Reg = obj.REG_NONE } c.instoffset = int64(c.autosize) + a.Offset + c.ctxt.Arch.FixedFrameSize if c.instoffset >= -BIG && c.instoffset < BIG { return C_SAUTO } return C_LAUTO case obj.NAME_NONE: c.instoffset = a.Offset if c.instoffset == 0 { return C_ZOREG } if c.instoffset >= -BIG && c.instoffset < BIG { return C_SOREG } return C_LOREG } return C_GOK case obj.TYPE_TEXTSIZE: return C_TEXTSIZE case obj.TYPE_FCONST: if f64, ok := a.Val.(float64); ok && math.Float64bits(f64) == 0 { return C_ZCON } c.ctxt.Diag("cannot handle the floating point constant %v", a.Val) case obj.TYPE_CONST, obj.TYPE_ADDR: switch a.Name { case obj.NAME_NONE: c.instoffset = a.Offset if a.Reg != 0 { if -BIG <= c.instoffset && c.instoffset <= BIG { return C_SACON } if isint32(c.instoffset) { return C_LACON } return C_DACON } case obj.NAME_EXTERN, obj.NAME_STATIC: s := a.Sym if s == nil { return C_GOK } c.instoffset = a.Offset return C_SYMADDR case obj.NAME_AUTO: if a.Reg == REGSP { // unset base register for better printing, since // a.Offset is still relative to pseudo-SP. a.Reg = obj.REG_NONE } c.instoffset = int64(c.autosize) + a.Offset if c.instoffset >= -BIG && c.instoffset < BIG { return C_SACON } return C_LACON case obj.NAME_PARAM: if a.Reg == REGSP { // unset base register for better printing, since // a.Offset is still relative to pseudo-FP. a.Reg = obj.REG_NONE } c.instoffset = int64(c.autosize) + a.Offset + c.ctxt.Arch.FixedFrameSize if c.instoffset >= -BIG && c.instoffset < BIG { return C_SACON } return C_LACON default: return C_GOK } if c.instoffset == 0 { return C_ZCON } if c.instoffset >= 0 { if c.instoffset <= 0x7fff { return C_SCON } if c.instoffset <= 0xffff { return C_ANDCON } if c.instoffset&0xffff == 0 && isuint32(uint64(c.instoffset)) { /* && ((instoffset & (1<<31)) == 0) */ return C_UCON } if isint32(c.instoffset) || isuint32(uint64(c.instoffset)) { return C_LCON } return C_DCON } if c.instoffset >= -0x8000 { return C_ADDCON } if c.instoffset&0xffff == 0 && isint32(c.instoffset) { return C_UCON } if isint32(c.instoffset) { return C_LCON } return C_DCON case obj.TYPE_BRANCH: return C_SBRA } return C_GOK } func (c *ctxtz) oplook(p *obj.Prog) *Optab { // Return cached optab entry if available. if p.Optab != 0 { return &optab[p.Optab-1] } if len(p.RestArgs) > 3 { c.ctxt.Diag("too many RestArgs: got %v, maximum is 3\n", len(p.RestArgs)) return nil } // Initialize classes for all arguments. p.From.Class = int8(c.aclass(&p.From) + 1) p.To.Class = int8(c.aclass(&p.To) + 1) for i := range p.RestArgs { p.RestArgs[i].Addr.Class = int8(c.aclass(&p.RestArgs[i].Addr) + 1) } // Mirrors the argument list in Optab. args := [...]int8{ p.From.Class - 1, C_NONE, // p.Reg C_NONE, // p.RestArgs[0] C_NONE, // p.RestArgs[1] C_NONE, // p.RestArgs[2] p.To.Class - 1, } // Fill in argument class for p.Reg. switch { case REG_R0 <= p.Reg && p.Reg <= REG_R15: args[1] = C_REG case REG_V0 <= p.Reg && p.Reg <= REG_V31: args[1] = C_VREG case REG_F0 <= p.Reg && p.Reg <= REG_F15: args[1] = C_FREG case REG_AR0 <= p.Reg && p.Reg <= REG_AR15: args[1] = C_AREG } // Fill in argument classes for p.RestArgs. for i, a := range p.RestArgs { args[2+i] = a.Class - 1 } // Lookup op in optab. ops := oprange[p.As&obj.AMask] cmp := [len(args)]*[C_NCLASS]bool{} for i := range cmp { cmp[i] = &xcmp[args[i]] } for i := range ops { op := &ops[i] if cmp[0][op.a1] && cmp[1][op.a2] && cmp[2][op.a3] && cmp[3][op.a4] && cmp[4][op.a5] && cmp[5][op.a6] { p.Optab = uint16(cap(optab) - cap(ops) + i + 1) return op } } // Cannot find a case; abort. s := "" for _, a := range args { s += fmt.Sprintf(" %v", DRconv(int(a))) } c.ctxt.Diag("illegal combination %v%v\n", p.As, s) c.ctxt.Diag("prog: %v\n", p) return nil } func cmp(a int, b int) bool { if a == b { return true } switch a { case C_DCON: if b == C_LCON { return true } fallthrough case C_LCON: if b == C_ZCON || b == C_SCON || b == C_UCON || b == C_ADDCON || b == C_ANDCON { return true } case C_ADDCON: if b == C_ZCON || b == C_SCON { return true } case C_ANDCON: if b == C_ZCON || b == C_SCON { return true } case C_UCON: if b == C_ZCON || b == C_SCON { return true } case C_SCON: if b == C_ZCON { return true } case C_LACON: if b == C_SACON { return true } case C_LBRA: if b == C_SBRA { return true } case C_LAUTO: if b == C_SAUTO { return true } case C_LOREG: if b == C_ZOREG || b == C_SOREG { return true } case C_SOREG: if b == C_ZOREG { return true } case C_ANY: return true } return false } func ocmp(p1, p2 Optab) int { if p1.as != p2.as { return int(p1.as) - int(p2.as) } if p1.a1 != p2.a1 { return int(p1.a1) - int(p2.a1) } if p1.a2 != p2.a2 { return int(p1.a2) - int(p2.a2) } if p1.a3 != p2.a3 { return int(p1.a3) - int(p2.a3) } if p1.a4 != p2.a4 { return int(p1.a4) - int(p2.a4) } return 0 } func opset(a, b obj.As) { oprange[a&obj.AMask] = oprange[b&obj.AMask] } func buildop(ctxt *obj.Link) { if oprange[AORW&obj.AMask] != nil { // Already initialized; stop now. // This happens in the cmd/asm tests, // each of which re-initializes the arch. return } for i := 0; i < C_NCLASS; i++ { for n := 0; n < C_NCLASS; n++ { if cmp(n, i) { xcmp[i][n] = true } } } slices.SortFunc(optab, ocmp) for i := 0; i < len(optab); i++ { r := optab[i].as start := i for ; i+1 < len(optab); i++ { if optab[i+1].as != r { break } } oprange[r&obj.AMask] = optab[start : i+1] // opset() aliases optab ranges for similar instructions, to reduce the number of optabs in the array. // oprange[] is used by oplook() to find the Optab entry that applies to a given Prog. switch r { case AADD: opset(AADDC, r) opset(AADDW, r) opset(AADDE, r) opset(AMULLD, r) opset(AMULLW, r) case ADIVW: opset(ADIVD, r) opset(ADIVDU, r) opset(ADIVWU, r) opset(AMODD, r) opset(AMODDU, r) opset(AMODW, r) opset(AMODWU, r) case AMULHD: opset(AMULHDU, r) case AMOVBZ: opset(AMOVH, r) opset(AMOVHZ, r) case ALA: opset(ALAY, r) case AMVC: opset(AMVCIN, r) opset(ACLC, r) opset(AXC, r) opset(AOC, r) opset(ANC, r) case ASTCK: opset(ASTCKC, r) opset(ASTCKE, r) opset(ASTCKF, r) case ALAAG: opset(ALAA, r) opset(ALAAL, r) opset(ALAALG, r) opset(ALAN, r) opset(ALANG, r) opset(ALAX, r) opset(ALAXG, r) opset(ALAO, r) opset(ALAOG, r) case ASTMG: opset(ASTMY, r) case ALMG: opset(ALMY, r) case ABEQ: opset(ABGE, r) opset(ABGT, r) opset(ABLE, r) opset(ABLT, r) opset(ABNE, r) opset(ABVC, r) opset(ABVS, r) opset(ABLEU, r) opset(ABLTU, r) case ABR: opset(ABL, r) case ABC: opset(ABCL, r) case AFABS: opset(AFNABS, r) opset(ALPDFR, r) opset(ALNDFR, r) opset(AFNEG, r) opset(AFNEGS, r) opset(ALEDBR, r) opset(ALDEBR, r) opset(AFSQRT, r) opset(AFSQRTS, r) case AFADD: opset(AFADDS, r) opset(AFDIV, r) opset(AFDIVS, r) opset(AFSUB, r) opset(AFSUBS, r) case AFMADD: opset(AFMADDS, r) opset(AFMSUB, r) opset(AFMSUBS, r) case AFMUL: opset(AFMULS, r) case AFCMPO: opset(AFCMPU, r) opset(ACEBR, r) case AAND: opset(AOR, r) opset(AXOR, r) case AANDW: opset(AORW, r) opset(AXORW, r) case ASLD: opset(ASRD, r) opset(ASLW, r) opset(ASRW, r) opset(ASRAD, r) opset(ASRAW, r) opset(ARLL, r) opset(ARLLG, r) case ARNSBG: opset(ARXSBG, r) opset(AROSBG, r) opset(ARNSBGT, r) opset(ARXSBGT, r) opset(AROSBGT, r) opset(ARISBG, r) opset(ARISBGN, r) opset(ARISBGZ, r) opset(ARISBGNZ, r) opset(ARISBHG, r) opset(ARISBLG, r) opset(ARISBHGZ, r) opset(ARISBLGZ, r) case ACSG: opset(ACS, r) case ASUB: opset(ASUBC, r) opset(ASUBE, r) opset(ASUBW, r) case ANEG: opset(ANEGW, r) case AFMOVD: opset(AFMOVS, r) case AMOVDBR: opset(AMOVWBR, r) case ACMP: opset(ACMPW, r) case ACMPU: opset(ACMPWU, r) case ATMHH: opset(ATMHL, r) opset(ATMLH, r) opset(ATMLL, r) case ACEFBRA: opset(ACDFBRA, r) opset(ACEGBRA, r) opset(ACDGBRA, r) opset(ACELFBR, r) opset(ACDLFBR, r) opset(ACELGBR, r) opset(ACDLGBR, r) case ACFEBRA: opset(ACFDBRA, r) opset(ACGEBRA, r) opset(ACGDBRA, r) opset(ACLFEBR, r) opset(ACLFDBR, r) opset(ACLGEBR, r) opset(ACLGDBR, r) case AFIEBR: opset(AFIDBR, r) case ACMPBEQ: opset(ACMPBGE, r) opset(ACMPBGT, r) opset(ACMPBLE, r) opset(ACMPBLT, r) opset(ACMPBNE, r) case ACMPUBEQ: opset(ACMPUBGE, r) opset(ACMPUBGT, r) opset(ACMPUBLE, r) opset(ACMPUBLT, r) opset(ACMPUBNE, r) case ACGRJ: opset(ACRJ, r) case ACLGRJ: opset(ACLRJ, r) case ACGIJ: opset(ACIJ, r) case ACLGIJ: opset(ACLIJ, r) case AMOVDEQ: opset(AMOVDGE, r) opset(AMOVDGT, r) opset(AMOVDLE, r) opset(AMOVDLT, r) opset(AMOVDNE, r) case ALOCGR: opset(ALOCR, r) case ALTDBR: opset(ALTEBR, r) case ATCDB: opset(ATCEB, r) case AVL: opset(AVLLEZB, r) opset(AVLLEZH, r) opset(AVLLEZF, r) opset(AVLLEZG, r) opset(AVLREPB, r) opset(AVLREPH, r) opset(AVLREPF, r) opset(AVLREPG, r) case AVLEG: opset(AVLBB, r) opset(AVLEB, r) opset(AVLEH, r) opset(AVLEF, r) opset(AVLEG, r) opset(AVLREP, r) case AVSTEG: opset(AVSTEB, r) opset(AVSTEH, r) opset(AVSTEF, r) case AVSCEG: opset(AVSCEF, r) case AVGEG: opset(AVGEF, r) case AVESLG: opset(AVESLB, r) opset(AVESLH, r) opset(AVESLF, r) opset(AVERLLB, r) opset(AVERLLH, r) opset(AVERLLF, r) opset(AVERLLG, r) opset(AVESRAB, r) opset(AVESRAH, r) opset(AVESRAF, r) opset(AVESRAG, r) opset(AVESRLB, r) opset(AVESRLH, r) opset(AVESRLF, r) opset(AVESRLG, r) case AVLGVG: opset(AVLGVB, r) opset(AVLGVH, r) opset(AVLGVF, r) case AVLVGG: opset(AVLVGB, r) opset(AVLVGH, r) opset(AVLVGF, r) case AVZERO: opset(AVONE, r) case AVREPIG: opset(AVREPIB, r) opset(AVREPIH, r) opset(AVREPIF, r) case AVLEIG: opset(AVLEIB, r) opset(AVLEIH, r) opset(AVLEIF, r) case AVGMG: opset(AVGMB, r) opset(AVGMH, r) opset(AVGMF, r) case AVREPG: opset(AVREPB, r) opset(AVREPH, r) opset(AVREPF, r) case AVERIMG: opset(AVERIMB, r) opset(AVERIMH, r) opset(AVERIMF, r) case AVFTCIDB: opset(AWFTCIDB, r) case AVLR: opset(AVUPHB, r) opset(AVUPHH, r) opset(AVUPHF, r) opset(AVUPLHB, r) opset(AVUPLHH, r) opset(AVUPLHF, r) opset(AVUPLB, r) opset(AVUPLHW, r) opset(AVUPLF, r) opset(AVUPLLB, r) opset(AVUPLLH, r) opset(AVUPLLF, r) opset(AVCLZB, r) opset(AVCLZH, r) opset(AVCLZF, r) opset(AVCLZG, r) opset(AVCTZB, r) opset(AVCTZH, r) opset(AVCTZF, r) opset(AVCTZG, r) opset(AVLDEB, r) opset(AWLDEB, r) opset(AVFLCDB, r) opset(AWFLCDB, r) opset(AVFLNDB, r) opset(AWFLNDB, r) opset(AVFLPDB, r) opset(AWFLPDB, r) opset(AVFSQDB, r) opset(AWFSQDB, r) opset(AVISTRB, r) opset(AVISTRH, r) opset(AVISTRF, r) opset(AVISTRBS, r) opset(AVISTRHS, r) opset(AVISTRFS, r) opset(AVLCB, r) opset(AVLCH, r) opset(AVLCF, r) opset(AVLCG, r) opset(AVLPB, r) opset(AVLPH, r) opset(AVLPF, r) opset(AVLPG, r) opset(AVPOPCT, r) opset(AVSEGB, r) opset(AVSEGH, r) opset(AVSEGF, r) case AVECG: opset(AVECB, r) opset(AVECH, r) opset(AVECF, r) opset(AVECLB, r) opset(AVECLH, r) opset(AVECLF, r) opset(AVECLG, r) opset(AWFCDB, r) opset(AWFKDB, r) case AVCEQG: opset(AVCEQB, r) opset(AVCEQH, r) opset(AVCEQF, r) opset(AVCEQBS, r) opset(AVCEQHS, r) opset(AVCEQFS, r) opset(AVCEQGS, r) opset(AVCHB, r) opset(AVCHH, r) opset(AVCHF, r) opset(AVCHG, r) opset(AVCHBS, r) opset(AVCHHS, r) opset(AVCHFS, r) opset(AVCHGS, r) opset(AVCHLB, r) opset(AVCHLH, r) opset(AVCHLF, r) opset(AVCHLG, r) opset(AVCHLBS, r) opset(AVCHLHS, r) opset(AVCHLFS, r) opset(AVCHLGS, r) case AVFAEF: opset(AVFAEB, r) opset(AVFAEH, r) opset(AVFAEBS, r) opset(AVFAEHS, r) opset(AVFAEFS, r) opset(AVFAEZB, r) opset(AVFAEZH, r) opset(AVFAEZF, r) opset(AVFAEZBS, r) opset(AVFAEZHS, r) opset(AVFAEZFS, r) opset(AVFEEB, r) opset(AVFEEH, r) opset(AVFEEF, r) opset(AVFEEBS, r) opset(AVFEEHS, r) opset(AVFEEFS, r) opset(AVFEEZB, r) opset(AVFEEZH, r) opset(AVFEEZF, r) opset(AVFEEZBS, r) opset(AVFEEZHS, r) opset(AVFEEZFS, r) opset(AVFENEB, r) opset(AVFENEH, r) opset(AVFENEF, r) opset(AVFENEBS, r) opset(AVFENEHS, r) opset(AVFENEFS, r) opset(AVFENEZB, r) opset(AVFENEZH, r) opset(AVFENEZF, r) opset(AVFENEZBS, r) opset(AVFENEZHS, r) opset(AVFENEZFS, r) case AVPKSG: opset(AVPKSH, r) opset(AVPKSF, r) opset(AVPKSHS, r) opset(AVPKSFS, r) opset(AVPKSGS, r) opset(AVPKLSH, r) opset(AVPKLSF, r) opset(AVPKLSG, r) opset(AVPKLSHS, r) opset(AVPKLSFS, r) opset(AVPKLSGS, r) case AVAQ: opset(AVAB, r) opset(AVAH, r) opset(AVAF, r) opset(AVAG, r) opset(AVACCB, r) opset(AVACCH, r) opset(AVACCF, r) opset(AVACCG, r) opset(AVACCQ, r) opset(AVN, r) opset(AVNC, r) opset(AVAVGB, r) opset(AVAVGH, r) opset(AVAVGF, r) opset(AVAVGG, r) opset(AVAVGLB, r) opset(AVAVGLH, r) opset(AVAVGLF, r) opset(AVAVGLG, r) opset(AVCKSM, r) opset(AVX, r) opset(AVFADB, r) opset(AWFADB, r) opset(AVFCEDB, r) opset(AVFCEDBS, r) opset(AWFCEDB, r) opset(AWFCEDBS, r) opset(AVFCHDB, r) opset(AVFCHDBS, r) opset(AWFCHDB, r) opset(AWFCHDBS, r) opset(AVFCHEDB, r) opset(AVFCHEDBS, r) opset(AWFCHEDB, r) opset(AWFCHEDBS, r) opset(AVFMDB, r) opset(AWFMDB, r) opset(AVGFMB, r) opset(AVGFMH, r) opset(AVGFMF, r) opset(AVGFMG, r) opset(AVMXB, r) opset(AVMXH, r) opset(AVMXF, r) opset(AVMXG, r) opset(AVMXLB, r) opset(AVMXLH, r) opset(AVMXLF, r) opset(AVMXLG, r) opset(AVMNB, r) opset(AVMNH, r) opset(AVMNF, r) opset(AVMNG, r) opset(AVMNLB, r) opset(AVMNLH, r) opset(AVMNLF, r) opset(AVMNLG, r) opset(AVMRHB, r) opset(AVMRHH, r) opset(AVMRHF, r) opset(AVMRHG, r) opset(AVMRLB, r) opset(AVMRLH, r) opset(AVMRLF, r) opset(AVMRLG, r) opset(AVMEB, r) opset(AVMEH, r) opset(AVMEF, r) opset(AVMLEB, r) opset(AVMLEH, r) opset(AVMLEF, r) opset(AVMOB, r) opset(AVMOH, r) opset(AVMOF, r) opset(AVMLOB, r) opset(AVMLOH, r) opset(AVMLOF, r) opset(AVMHB, r) opset(AVMHH, r) opset(AVMHF, r) opset(AVMLHB, r) opset(AVMLHH, r) opset(AVMLHF, r) opset(AVMLH, r) opset(AVMLHW, r) opset(AVMLF, r) opset(AVNO, r) opset(AVO, r) opset(AVPKH, r) opset(AVPKF, r) opset(AVPKG, r) opset(AVSUMGH, r) opset(AVSUMGF, r) opset(AVSUMQF, r) opset(AVSUMQG, r) opset(AVSUMB, r) opset(AVSUMH, r) case AVERLLVG: opset(AVERLLVB, r) opset(AVERLLVH, r) opset(AVERLLVF, r) opset(AVESLVB, r) opset(AVESLVH, r) opset(AVESLVF, r) opset(AVESLVG, r) opset(AVESRAVB, r) opset(AVESRAVH, r) opset(AVESRAVF, r) opset(AVESRAVG, r) opset(AVESRLVB, r) opset(AVESRLVH, r) opset(AVESRLVF, r) opset(AVESRLVG, r) opset(AVFDDB, r) opset(AWFDDB, r) opset(AVFSDB, r) opset(AWFSDB, r) opset(AVSL, r) opset(AVSLB, r) opset(AVSRA, r) opset(AVSRAB, r) opset(AVSRL, r) opset(AVSRLB, r) opset(AVSB, r) opset(AVSH, r) opset(AVSF, r) opset(AVSG, r) opset(AVSQ, r) opset(AVSCBIB, r) opset(AVSCBIH, r) opset(AVSCBIF, r) opset(AVSCBIG, r) opset(AVSCBIQ, r) case AVACQ: opset(AVACCCQ, r) opset(AVGFMAB, r) opset(AVGFMAH, r) opset(AVGFMAF, r) opset(AVGFMAG, r) opset(AVMALB, r) opset(AVMALHW, r) opset(AVMALF, r) opset(AVMAHB, r) opset(AVMAHH, r) opset(AVMAHF, r) opset(AVMALHB, r) opset(AVMALHH, r) opset(AVMALHF, r) opset(AVMAEB, r) opset(AVMAEH, r) opset(AVMAEF, r) opset(AVMALEB, r) opset(AVMALEH, r) opset(AVMALEF, r) opset(AVMAOB, r) opset(AVMAOH, r) opset(AVMAOF, r) opset(AVMALOB, r) opset(AVMALOH, r) opset(AVMALOF, r) opset(AVSTRC, r) opset(AVSTRCB, r) opset(AVSTRCH, r) opset(AVSTRCF, r) opset(AVSTRCBS, r) opset(AVSTRCHS, r) opset(AVSTRCFS, r) opset(AVSTRCZB, r) opset(AVSTRCZH, r) opset(AVSTRCZF, r) opset(AVSTRCZBS, r) opset(AVSTRCZHS, r) opset(AVSTRCZFS, r) opset(AVSBCBIQ, r) opset(AVSBIQ, r) opset(AVMSLG, r) opset(AVMSLEG, r) opset(AVMSLOG, r) opset(AVMSLEOG, r) case AVSEL: opset(AVFMADB, r) opset(AWFMADB, r) opset(AVFMSDB, r) opset(AWFMSDB, r) opset(AVPERM, r) case AKM: opset(AKMC, r) opset(AKLMD, r) opset(AKIMD, r) case AKMA: opset(AKMCTR, r) } } } const ( op_A uint32 = 0x5A00 // FORMAT_RX1 ADD (32) op_AD uint32 = 0x6A00 // FORMAT_RX1 ADD NORMALIZED (long HFP) op_ADB uint32 = 0xED1A // FORMAT_RXE ADD (long BFP) op_ADBR uint32 = 0xB31A // FORMAT_RRE ADD (long BFP) op_ADR uint32 = 0x2A00 // FORMAT_RR ADD NORMALIZED (long HFP) op_ADTR uint32 = 0xB3D2 // FORMAT_RRF1 ADD (long DFP) op_ADTRA uint32 = 0xB3D2 // FORMAT_RRF1 ADD (long DFP) op_AE uint32 = 0x7A00 // FORMAT_RX1 ADD NORMALIZED (short HFP) op_AEB uint32 = 0xED0A // FORMAT_RXE ADD (short BFP) op_AEBR uint32 = 0xB30A // FORMAT_RRE ADD (short BFP) op_AER uint32 = 0x3A00 // FORMAT_RR ADD NORMALIZED (short HFP) op_AFI uint32 = 0xC209 // FORMAT_RIL1 ADD IMMEDIATE (32) op_AG uint32 = 0xE308 // FORMAT_RXY1 ADD (64) op_AGF uint32 = 0xE318 // FORMAT_RXY1 ADD (64<-32) op_AGFI uint32 = 0xC208 // FORMAT_RIL1 ADD IMMEDIATE (64<-32) op_AGFR uint32 = 0xB918 // FORMAT_RRE ADD (64<-32) op_AGHI uint32 = 0xA70B // FORMAT_RI1 ADD HALFWORD IMMEDIATE (64) op_AGHIK uint32 = 0xECD9 // FORMAT_RIE4 ADD IMMEDIATE (64<-16) op_AGR uint32 = 0xB908 // FORMAT_RRE ADD (64) op_AGRK uint32 = 0xB9E8 // FORMAT_RRF1 ADD (64) op_AGSI uint32 = 0xEB7A // FORMAT_SIY ADD IMMEDIATE (64<-8) op_AH uint32 = 0x4A00 // FORMAT_RX1 ADD HALFWORD op_AHHHR uint32 = 0xB9C8 // FORMAT_RRF1 ADD HIGH (32) op_AHHLR uint32 = 0xB9D8 // FORMAT_RRF1 ADD HIGH (32) op_AHI uint32 = 0xA70A // FORMAT_RI1 ADD HALFWORD IMMEDIATE (32) op_AHIK uint32 = 0xECD8 // FORMAT_RIE4 ADD IMMEDIATE (32<-16) op_AHY uint32 = 0xE37A // FORMAT_RXY1 ADD HALFWORD op_AIH uint32 = 0xCC08 // FORMAT_RIL1 ADD IMMEDIATE HIGH (32) op_AL uint32 = 0x5E00 // FORMAT_RX1 ADD LOGICAL (32) op_ALC uint32 = 0xE398 // FORMAT_RXY1 ADD LOGICAL WITH CARRY (32) op_ALCG uint32 = 0xE388 // FORMAT_RXY1 ADD LOGICAL WITH CARRY (64) op_ALCGR uint32 = 0xB988 // FORMAT_RRE ADD LOGICAL WITH CARRY (64) op_ALCR uint32 = 0xB998 // FORMAT_RRE ADD LOGICAL WITH CARRY (32) op_ALFI uint32 = 0xC20B // FORMAT_RIL1 ADD LOGICAL IMMEDIATE (32) op_ALG uint32 = 0xE30A // FORMAT_RXY1 ADD LOGICAL (64) op_ALGF uint32 = 0xE31A // FORMAT_RXY1 ADD LOGICAL (64<-32) op_ALGFI uint32 = 0xC20A // FORMAT_RIL1 ADD LOGICAL IMMEDIATE (64<-32) op_ALGFR uint32 = 0xB91A // FORMAT_RRE ADD LOGICAL (64<-32) op_ALGHSIK uint32 = 0xECDB // FORMAT_RIE4 ADD LOGICAL WITH SIGNED IMMEDIATE (64<-16) op_ALGR uint32 = 0xB90A // FORMAT_RRE ADD LOGICAL (64) op_ALGRK uint32 = 0xB9EA // FORMAT_RRF1 ADD LOGICAL (64) op_ALGSI uint32 = 0xEB7E // FORMAT_SIY ADD LOGICAL WITH SIGNED IMMEDIATE (64<-8) op_ALHHHR uint32 = 0xB9CA // FORMAT_RRF1 ADD LOGICAL HIGH (32) op_ALHHLR uint32 = 0xB9DA // FORMAT_RRF1 ADD LOGICAL HIGH (32) op_ALHSIK uint32 = 0xECDA // FORMAT_RIE4 ADD LOGICAL WITH SIGNED IMMEDIATE (32<-16) op_ALR uint32 = 0x1E00 // FORMAT_RR ADD LOGICAL (32) op_ALRK uint32 = 0xB9FA // FORMAT_RRF1 ADD LOGICAL (32) op_ALSI uint32 = 0xEB6E // FORMAT_SIY ADD LOGICAL WITH SIGNED IMMEDIATE (32<-8) op_ALSIH uint32 = 0xCC0A // FORMAT_RIL1 ADD LOGICAL WITH SIGNED IMMEDIATE HIGH (32) op_ALSIHN uint32 = 0xCC0B // FORMAT_RIL1 ADD LOGICAL WITH SIGNED IMMEDIATE HIGH (32) op_ALY uint32 = 0xE35E // FORMAT_RXY1 ADD LOGICAL (32) op_AP uint32 = 0xFA00 // FORMAT_SS2 ADD DECIMAL op_AR uint32 = 0x1A00 // FORMAT_RR ADD (32) op_ARK uint32 = 0xB9F8 // FORMAT_RRF1 ADD (32) op_ASI uint32 = 0xEB6A // FORMAT_SIY ADD IMMEDIATE (32<-8) op_AU uint32 = 0x7E00 // FORMAT_RX1 ADD UNNORMALIZED (short HFP) op_AUR uint32 = 0x3E00 // FORMAT_RR ADD UNNORMALIZED (short HFP) op_AW uint32 = 0x6E00 // FORMAT_RX1 ADD UNNORMALIZED (long HFP) op_AWR uint32 = 0x2E00 // FORMAT_RR ADD UNNORMALIZED (long HFP) op_AXBR uint32 = 0xB34A // FORMAT_RRE ADD (extended BFP) op_AXR uint32 = 0x3600 // FORMAT_RR ADD NORMALIZED (extended HFP) op_AXTR uint32 = 0xB3DA // FORMAT_RRF1 ADD (extended DFP) op_AXTRA uint32 = 0xB3DA // FORMAT_RRF1 ADD (extended DFP) op_AY uint32 = 0xE35A // FORMAT_RXY1 ADD (32) op_BAKR uint32 = 0xB240 // FORMAT_RRE BRANCH AND STACK op_BAL uint32 = 0x4500 // FORMAT_RX1 BRANCH AND LINK op_BALR uint32 = 0x0500 // FORMAT_RR BRANCH AND LINK op_BAS uint32 = 0x4D00 // FORMAT_RX1 BRANCH AND SAVE op_BASR uint32 = 0x0D00 // FORMAT_RR BRANCH AND SAVE op_BASSM uint32 = 0x0C00 // FORMAT_RR BRANCH AND SAVE AND SET MODE op_BC uint32 = 0x4700 // FORMAT_RX2 BRANCH ON CONDITION op_BCR uint32 = 0x0700 // FORMAT_RR BRANCH ON CONDITION op_BCT uint32 = 0x4600 // FORMAT_RX1 BRANCH ON COUNT (32) op_BCTG uint32 = 0xE346 // FORMAT_RXY1 BRANCH ON COUNT (64) op_BCTGR uint32 = 0xB946 // FORMAT_RRE BRANCH ON COUNT (64) op_BCTR uint32 = 0x0600 // FORMAT_RR BRANCH ON COUNT (32) op_BPP uint32 = 0xC700 // FORMAT_SMI BRANCH PREDICTION PRELOAD op_BPRP uint32 = 0xC500 // FORMAT_MII BRANCH PREDICTION RELATIVE PRELOAD op_BRAS uint32 = 0xA705 // FORMAT_RI2 BRANCH RELATIVE AND SAVE op_BRASL uint32 = 0xC005 // FORMAT_RIL2 BRANCH RELATIVE AND SAVE LONG op_BRC uint32 = 0xA704 // FORMAT_RI3 BRANCH RELATIVE ON CONDITION op_BRCL uint32 = 0xC004 // FORMAT_RIL3 BRANCH RELATIVE ON CONDITION LONG op_BRCT uint32 = 0xA706 // FORMAT_RI2 BRANCH RELATIVE ON COUNT (32) op_BRCTG uint32 = 0xA707 // FORMAT_RI2 BRANCH RELATIVE ON COUNT (64) op_BRCTH uint32 = 0xCC06 // FORMAT_RIL2 BRANCH RELATIVE ON COUNT HIGH (32) op_BRXH uint32 = 0x8400 // FORMAT_RSI BRANCH RELATIVE ON INDEX HIGH (32) op_BRXHG uint32 = 0xEC44 // FORMAT_RIE5 BRANCH RELATIVE ON INDEX HIGH (64) op_BRXLE uint32 = 0x8500 // FORMAT_RSI BRANCH RELATIVE ON INDEX LOW OR EQ. (32) op_BRXLG uint32 = 0xEC45 // FORMAT_RIE5 BRANCH RELATIVE ON INDEX LOW OR EQ. (64) op_BSA uint32 = 0xB25A // FORMAT_RRE BRANCH AND SET AUTHORITY op_BSG uint32 = 0xB258 // FORMAT_RRE BRANCH IN SUBSPACE GROUP op_BSM uint32 = 0x0B00 // FORMAT_RR BRANCH AND SET MODE op_BXH uint32 = 0x8600 // FORMAT_RS1 BRANCH ON INDEX HIGH (32) op_BXHG uint32 = 0xEB44 // FORMAT_RSY1 BRANCH ON INDEX HIGH (64) op_BXLE uint32 = 0x8700 // FORMAT_RS1 BRANCH ON INDEX LOW OR EQUAL (32) op_BXLEG uint32 = 0xEB45 // FORMAT_RSY1 BRANCH ON INDEX LOW OR EQUAL (64) op_C uint32 = 0x5900 // FORMAT_RX1 COMPARE (32) op_CD uint32 = 0x6900 // FORMAT_RX1 COMPARE (long HFP) op_CDB uint32 = 0xED19 // FORMAT_RXE COMPARE (long BFP) op_CDBR uint32 = 0xB319 // FORMAT_RRE COMPARE (long BFP) op_CDFBR uint32 = 0xB395 // FORMAT_RRE CONVERT FROM FIXED (32 to long BFP) op_CDFBRA uint32 = 0xB395 // FORMAT_RRF5 CONVERT FROM FIXED (32 to long BFP) op_CDFR uint32 = 0xB3B5 // FORMAT_RRE CONVERT FROM FIXED (32 to long HFP) op_CDFTR uint32 = 0xB951 // FORMAT_RRE CONVERT FROM FIXED (32 to long DFP) op_CDGBR uint32 = 0xB3A5 // FORMAT_RRE CONVERT FROM FIXED (64 to long BFP) op_CDGBRA uint32 = 0xB3A5 // FORMAT_RRF5 CONVERT FROM FIXED (64 to long BFP) op_CDGR uint32 = 0xB3C5 // FORMAT_RRE CONVERT FROM FIXED (64 to long HFP) op_CDGTR uint32 = 0xB3F1 // FORMAT_RRE CONVERT FROM FIXED (64 to long DFP) op_CDGTRA uint32 = 0xB3F1 // FORMAT_RRF5 CONVERT FROM FIXED (64 to long DFP) op_CDLFBR uint32 = 0xB391 // FORMAT_RRF5 CONVERT FROM LOGICAL (32 to long BFP) op_CDLFTR uint32 = 0xB953 // FORMAT_RRF5 CONVERT FROM LOGICAL (32 to long DFP) op_CDLGBR uint32 = 0xB3A1 // FORMAT_RRF5 CONVERT FROM LOGICAL (64 to long BFP) op_CDLGTR uint32 = 0xB952 // FORMAT_RRF5 CONVERT FROM LOGICAL (64 to long DFP) op_CDR uint32 = 0x2900 // FORMAT_RR COMPARE (long HFP) op_CDS uint32 = 0xBB00 // FORMAT_RS1 COMPARE DOUBLE AND SWAP (32) op_CDSG uint32 = 0xEB3E // FORMAT_RSY1 COMPARE DOUBLE AND SWAP (64) op_CDSTR uint32 = 0xB3F3 // FORMAT_RRE CONVERT FROM SIGNED PACKED (64 to long DFP) op_CDSY uint32 = 0xEB31 // FORMAT_RSY1 COMPARE DOUBLE AND SWAP (32) op_CDTR uint32 = 0xB3E4 // FORMAT_RRE COMPARE (long DFP) op_CDUTR uint32 = 0xB3F2 // FORMAT_RRE CONVERT FROM UNSIGNED PACKED (64 to long DFP) op_CDZT uint32 = 0xEDAA // FORMAT_RSL CONVERT FROM ZONED (to long DFP) op_CE uint32 = 0x7900 // FORMAT_RX1 COMPARE (short HFP) op_CEB uint32 = 0xED09 // FORMAT_RXE COMPARE (short BFP) op_CEBR uint32 = 0xB309 // FORMAT_RRE COMPARE (short BFP) op_CEDTR uint32 = 0xB3F4 // FORMAT_RRE COMPARE BIASED EXPONENT (long DFP) op_CEFBR uint32 = 0xB394 // FORMAT_RRE CONVERT FROM FIXED (32 to short BFP) op_CEFBRA uint32 = 0xB394 // FORMAT_RRF5 CONVERT FROM FIXED (32 to short BFP) op_CEFR uint32 = 0xB3B4 // FORMAT_RRE CONVERT FROM FIXED (32 to short HFP) op_CEGBR uint32 = 0xB3A4 // FORMAT_RRE CONVERT FROM FIXED (64 to short BFP) op_CEGBRA uint32 = 0xB3A4 // FORMAT_RRF5 CONVERT FROM FIXED (64 to short BFP) op_CEGR uint32 = 0xB3C4 // FORMAT_RRE CONVERT FROM FIXED (64 to short HFP) op_CELFBR uint32 = 0xB390 // FORMAT_RRF5 CONVERT FROM LOGICAL (32 to short BFP) op_CELGBR uint32 = 0xB3A0 // FORMAT_RRF5 CONVERT FROM LOGICAL (64 to short BFP) op_CER uint32 = 0x3900 // FORMAT_RR COMPARE (short HFP) op_CEXTR uint32 = 0xB3FC // FORMAT_RRE COMPARE BIASED EXPONENT (extended DFP) op_CFC uint32 = 0xB21A // FORMAT_S COMPARE AND FORM CODEWORD op_CFDBR uint32 = 0xB399 // FORMAT_RRF5 CONVERT TO FIXED (long BFP to 32) op_CFDBRA uint32 = 0xB399 // FORMAT_RRF5 CONVERT TO FIXED (long BFP to 32) op_CFDR uint32 = 0xB3B9 // FORMAT_RRF5 CONVERT TO FIXED (long HFP to 32) op_CFDTR uint32 = 0xB941 // FORMAT_RRF5 CONVERT TO FIXED (long DFP to 32) op_CFEBR uint32 = 0xB398 // FORMAT_RRF5 CONVERT TO FIXED (short BFP to 32) op_CFEBRA uint32 = 0xB398 // FORMAT_RRF5 CONVERT TO FIXED (short BFP to 32) op_CFER uint32 = 0xB3B8 // FORMAT_RRF5 CONVERT TO FIXED (short HFP to 32) op_CFI uint32 = 0xC20D // FORMAT_RIL1 COMPARE IMMEDIATE (32) op_CFXBR uint32 = 0xB39A // FORMAT_RRF5 CONVERT TO FIXED (extended BFP to 32) op_CFXBRA uint32 = 0xB39A // FORMAT_RRF5 CONVERT TO FIXED (extended BFP to 32) op_CFXR uint32 = 0xB3BA // FORMAT_RRF5 CONVERT TO FIXED (extended HFP to 32) op_CFXTR uint32 = 0xB949 // FORMAT_RRF5 CONVERT TO FIXED (extended DFP to 32) op_CG uint32 = 0xE320 // FORMAT_RXY1 COMPARE (64) op_CGDBR uint32 = 0xB3A9 // FORMAT_RRF5 CONVERT TO FIXED (long BFP to 64) op_CGDBRA uint32 = 0xB3A9 // FORMAT_RRF5 CONVERT TO FIXED (long BFP to 64) op_CGDR uint32 = 0xB3C9 // FORMAT_RRF5 CONVERT TO FIXED (long HFP to 64) op_CGDTR uint32 = 0xB3E1 // FORMAT_RRF5 CONVERT TO FIXED (long DFP to 64) op_CGDTRA uint32 = 0xB3E1 // FORMAT_RRF5 CONVERT TO FIXED (long DFP to 64) op_CGEBR uint32 = 0xB3A8 // FORMAT_RRF5 CONVERT TO FIXED (short BFP to 64) op_CGEBRA uint32 = 0xB3A8 // FORMAT_RRF5 CONVERT TO FIXED (short BFP to 64) op_CGER uint32 = 0xB3C8 // FORMAT_RRF5 CONVERT TO FIXED (short HFP to 64) op_CGF uint32 = 0xE330 // FORMAT_RXY1 COMPARE (64<-32) op_CGFI uint32 = 0xC20C // FORMAT_RIL1 COMPARE IMMEDIATE (64<-32) op_CGFR uint32 = 0xB930 // FORMAT_RRE COMPARE (64<-32) op_CGFRL uint32 = 0xC60C // FORMAT_RIL2 COMPARE RELATIVE LONG (64<-32) op_CGH uint32 = 0xE334 // FORMAT_RXY1 COMPARE HALFWORD (64<-16) op_CGHI uint32 = 0xA70F // FORMAT_RI1 COMPARE HALFWORD IMMEDIATE (64<-16) op_CGHRL uint32 = 0xC604 // FORMAT_RIL2 COMPARE HALFWORD RELATIVE LONG (64<-16) op_CGHSI uint32 = 0xE558 // FORMAT_SIL COMPARE HALFWORD IMMEDIATE (64<-16) op_CGIB uint32 = 0xECFC // FORMAT_RIS COMPARE IMMEDIATE AND BRANCH (64<-8) op_CGIJ uint32 = 0xEC7C // FORMAT_RIE3 COMPARE IMMEDIATE AND BRANCH RELATIVE (64<-8) op_CGIT uint32 = 0xEC70 // FORMAT_RIE1 COMPARE IMMEDIATE AND TRAP (64<-16) op_CGR uint32 = 0xB920 // FORMAT_RRE COMPARE (64) op_CGRB uint32 = 0xECE4 // FORMAT_RRS COMPARE AND BRANCH (64) op_CGRJ uint32 = 0xEC64 // FORMAT_RIE2 COMPARE AND BRANCH RELATIVE (64) op_CGRL uint32 = 0xC608 // FORMAT_RIL2 COMPARE RELATIVE LONG (64) op_CGRT uint32 = 0xB960 // FORMAT_RRF3 COMPARE AND TRAP (64) op_CGXBR uint32 = 0xB3AA // FORMAT_RRF5 CONVERT TO FIXED (extended BFP to 64) op_CGXBRA uint32 = 0xB3AA // FORMAT_RRF5 CONVERT TO FIXED (extended BFP to 64) op_CGXR uint32 = 0xB3CA // FORMAT_RRF5 CONVERT TO FIXED (extended HFP to 64) op_CGXTR uint32 = 0xB3E9 // FORMAT_RRF5 CONVERT TO FIXED (extended DFP to 64) op_CGXTRA uint32 = 0xB3E9 // FORMAT_RRF5 CONVERT TO FIXED (extended DFP to 64) op_CH uint32 = 0x4900 // FORMAT_RX1 COMPARE HALFWORD (32<-16) op_CHF uint32 = 0xE3CD // FORMAT_RXY1 COMPARE HIGH (32) op_CHHR uint32 = 0xB9CD // FORMAT_RRE COMPARE HIGH (32) op_CHHSI uint32 = 0xE554 // FORMAT_SIL COMPARE HALFWORD IMMEDIATE (16) op_CHI uint32 = 0xA70E // FORMAT_RI1 COMPARE HALFWORD IMMEDIATE (32<-16) op_CHLR uint32 = 0xB9DD // FORMAT_RRE COMPARE HIGH (32) op_CHRL uint32 = 0xC605 // FORMAT_RIL2 COMPARE HALFWORD RELATIVE LONG (32<-16) op_CHSI uint32 = 0xE55C // FORMAT_SIL COMPARE HALFWORD IMMEDIATE (32<-16) op_CHY uint32 = 0xE379 // FORMAT_RXY1 COMPARE HALFWORD (32<-16) op_CIB uint32 = 0xECFE // FORMAT_RIS COMPARE IMMEDIATE AND BRANCH (32<-8) op_CIH uint32 = 0xCC0D // FORMAT_RIL1 COMPARE IMMEDIATE HIGH (32) op_CIJ uint32 = 0xEC7E // FORMAT_RIE3 COMPARE IMMEDIATE AND BRANCH RELATIVE (32<-8) op_CIT uint32 = 0xEC72 // FORMAT_RIE1 COMPARE IMMEDIATE AND TRAP (32<-16) op_CKSM uint32 = 0xB241 // FORMAT_RRE CHECKSUM op_CL uint32 = 0x5500 // FORMAT_RX1 COMPARE LOGICAL (32) op_CLC uint32 = 0xD500 // FORMAT_SS1 COMPARE LOGICAL (character) op_CLCL uint32 = 0x0F00 // FORMAT_RR COMPARE LOGICAL LONG op_CLCLE uint32 = 0xA900 // FORMAT_RS1 COMPARE LOGICAL LONG EXTENDED op_CLCLU uint32 = 0xEB8F // FORMAT_RSY1 COMPARE LOGICAL LONG UNICODE op_CLFDBR uint32 = 0xB39D // FORMAT_RRF5 CONVERT TO LOGICAL (long BFP to 32) op_CLFDTR uint32 = 0xB943 // FORMAT_RRF5 CONVERT TO LOGICAL (long DFP to 32) op_CLFEBR uint32 = 0xB39C // FORMAT_RRF5 CONVERT TO LOGICAL (short BFP to 32) op_CLFHSI uint32 = 0xE55D // FORMAT_SIL COMPARE LOGICAL IMMEDIATE (32<-16) op_CLFI uint32 = 0xC20F // FORMAT_RIL1 COMPARE LOGICAL IMMEDIATE (32) op_CLFIT uint32 = 0xEC73 // FORMAT_RIE1 COMPARE LOGICAL IMMEDIATE AND TRAP (32<-16) op_CLFXBR uint32 = 0xB39E // FORMAT_RRF5 CONVERT TO LOGICAL (extended BFP to 32) op_CLFXTR uint32 = 0xB94B // FORMAT_RRF5 CONVERT TO LOGICAL (extended DFP to 32) op_CLG uint32 = 0xE321 // FORMAT_RXY1 COMPARE LOGICAL (64) op_CLGDBR uint32 = 0xB3AD // FORMAT_RRF5 CONVERT TO LOGICAL (long BFP to 64) op_CLGDTR uint32 = 0xB942 // FORMAT_RRF5 CONVERT TO LOGICAL (long DFP to 64) op_CLGEBR uint32 = 0xB3AC // FORMAT_RRF5 CONVERT TO LOGICAL (short BFP to 64) op_CLGF uint32 = 0xE331 // FORMAT_RXY1 COMPARE LOGICAL (64<-32) op_CLGFI uint32 = 0xC20E // FORMAT_RIL1 COMPARE LOGICAL IMMEDIATE (64<-32) op_CLGFR uint32 = 0xB931 // FORMAT_RRE COMPARE LOGICAL (64<-32) op_CLGFRL uint32 = 0xC60E // FORMAT_RIL2 COMPARE LOGICAL RELATIVE LONG (64<-32) op_CLGHRL uint32 = 0xC606 // FORMAT_RIL2 COMPARE LOGICAL RELATIVE LONG (64<-16) op_CLGHSI uint32 = 0xE559 // FORMAT_SIL COMPARE LOGICAL IMMEDIATE (64<-16) op_CLGIB uint32 = 0xECFD // FORMAT_RIS COMPARE LOGICAL IMMEDIATE AND BRANCH (64<-8) op_CLGIJ uint32 = 0xEC7D // FORMAT_RIE3 COMPARE LOGICAL IMMEDIATE AND BRANCH RELATIVE (64<-8) op_CLGIT uint32 = 0xEC71 // FORMAT_RIE1 COMPARE LOGICAL IMMEDIATE AND TRAP (64<-16) op_CLGR uint32 = 0xB921 // FORMAT_RRE COMPARE LOGICAL (64) op_CLGRB uint32 = 0xECE5 // FORMAT_RRS COMPARE LOGICAL AND BRANCH (64) op_CLGRJ uint32 = 0xEC65 // FORMAT_RIE2 COMPARE LOGICAL AND BRANCH RELATIVE (64) op_CLGRL uint32 = 0xC60A // FORMAT_RIL2 COMPARE LOGICAL RELATIVE LONG (64) op_CLGRT uint32 = 0xB961 // FORMAT_RRF3 COMPARE LOGICAL AND TRAP (64) op_CLGT uint32 = 0xEB2B // FORMAT_RSY2 COMPARE LOGICAL AND TRAP (64) op_CLGXBR uint32 = 0xB3AE // FORMAT_RRF5 CONVERT TO LOGICAL (extended BFP to 64) op_CLGXTR uint32 = 0xB94A // FORMAT_RRF5 CONVERT TO LOGICAL (extended DFP to 64) op_CLHF uint32 = 0xE3CF // FORMAT_RXY1 COMPARE LOGICAL HIGH (32) op_CLHHR uint32 = 0xB9CF // FORMAT_RRE COMPARE LOGICAL HIGH (32) op_CLHHSI uint32 = 0xE555 // FORMAT_SIL COMPARE LOGICAL IMMEDIATE (16) op_CLHLR uint32 = 0xB9DF // FORMAT_RRE COMPARE LOGICAL HIGH (32) op_CLHRL uint32 = 0xC607 // FORMAT_RIL2 COMPARE LOGICAL RELATIVE LONG (32<-16) op_CLI uint32 = 0x9500 // FORMAT_SI COMPARE LOGICAL (immediate) op_CLIB uint32 = 0xECFF // FORMAT_RIS COMPARE LOGICAL IMMEDIATE AND BRANCH (32<-8) op_CLIH uint32 = 0xCC0F // FORMAT_RIL1 COMPARE LOGICAL IMMEDIATE HIGH (32) op_CLIJ uint32 = 0xEC7F // FORMAT_RIE3 COMPARE LOGICAL IMMEDIATE AND BRANCH RELATIVE (32<-8) op_CLIY uint32 = 0xEB55 // FORMAT_SIY COMPARE LOGICAL (immediate) op_CLM uint32 = 0xBD00 // FORMAT_RS2 COMPARE LOGICAL CHAR. UNDER MASK (low) op_CLMH uint32 = 0xEB20 // FORMAT_RSY2 COMPARE LOGICAL CHAR. UNDER MASK (high) op_CLMY uint32 = 0xEB21 // FORMAT_RSY2 COMPARE LOGICAL CHAR. UNDER MASK (low) op_CLR uint32 = 0x1500 // FORMAT_RR COMPARE LOGICAL (32) op_CLRB uint32 = 0xECF7 // FORMAT_RRS COMPARE LOGICAL AND BRANCH (32) op_CLRJ uint32 = 0xEC77 // FORMAT_RIE2 COMPARE LOGICAL AND BRANCH RELATIVE (32) op_CLRL uint32 = 0xC60F // FORMAT_RIL2 COMPARE LOGICAL RELATIVE LONG (32) op_CLRT uint32 = 0xB973 // FORMAT_RRF3 COMPARE LOGICAL AND TRAP (32) op_CLST uint32 = 0xB25D // FORMAT_RRE COMPARE LOGICAL STRING op_CLT uint32 = 0xEB23 // FORMAT_RSY2 COMPARE LOGICAL AND TRAP (32) op_CLY uint32 = 0xE355 // FORMAT_RXY1 COMPARE LOGICAL (32) op_CMPSC uint32 = 0xB263 // FORMAT_RRE COMPRESSION CALL op_CP uint32 = 0xF900 // FORMAT_SS2 COMPARE DECIMAL op_CPSDR uint32 = 0xB372 // FORMAT_RRF2 COPY SIGN (long) op_CPYA uint32 = 0xB24D // FORMAT_RRE COPY ACCESS op_CR uint32 = 0x1900 // FORMAT_RR COMPARE (32) op_CRB uint32 = 0xECF6 // FORMAT_RRS COMPARE AND BRANCH (32) op_CRDTE uint32 = 0xB98F // FORMAT_RRF2 COMPARE AND REPLACE DAT TABLE ENTRY op_CRJ uint32 = 0xEC76 // FORMAT_RIE2 COMPARE AND BRANCH RELATIVE (32) op_CRL uint32 = 0xC60D // FORMAT_RIL2 COMPARE RELATIVE LONG (32) op_CRT uint32 = 0xB972 // FORMAT_RRF3 COMPARE AND TRAP (32) op_CS uint32 = 0xBA00 // FORMAT_RS1 COMPARE AND SWAP (32) op_CSCH uint32 = 0xB230 // FORMAT_S CLEAR SUBCHANNEL op_CSDTR uint32 = 0xB3E3 // FORMAT_RRF4 CONVERT TO SIGNED PACKED (long DFP to 64) op_CSG uint32 = 0xEB30 // FORMAT_RSY1 COMPARE AND SWAP (64) op_CSP uint32 = 0xB250 // FORMAT_RRE COMPARE AND SWAP AND PURGE op_CSPG uint32 = 0xB98A // FORMAT_RRE COMPARE AND SWAP AND PURGE op_CSST uint32 = 0xC802 // FORMAT_SSF COMPARE AND SWAP AND STORE op_CSXTR uint32 = 0xB3EB // FORMAT_RRF4 CONVERT TO SIGNED PACKED (extended DFP to 128) op_CSY uint32 = 0xEB14 // FORMAT_RSY1 COMPARE AND SWAP (32) op_CU12 uint32 = 0xB2A7 // FORMAT_RRF3 CONVERT UTF-8 TO UTF-16 op_CU14 uint32 = 0xB9B0 // FORMAT_RRF3 CONVERT UTF-8 TO UTF-32 op_CU21 uint32 = 0xB2A6 // FORMAT_RRF3 CONVERT UTF-16 TO UTF-8 op_CU24 uint32 = 0xB9B1 // FORMAT_RRF3 CONVERT UTF-16 TO UTF-32 op_CU41 uint32 = 0xB9B2 // FORMAT_RRE CONVERT UTF-32 TO UTF-8 op_CU42 uint32 = 0xB9B3 // FORMAT_RRE CONVERT UTF-32 TO UTF-16 op_CUDTR uint32 = 0xB3E2 // FORMAT_RRE CONVERT TO UNSIGNED PACKED (long DFP to 64) op_CUSE uint32 = 0xB257 // FORMAT_RRE COMPARE UNTIL SUBSTRING EQUAL op_CUTFU uint32 = 0xB2A7 // FORMAT_RRF3 CONVERT UTF-8 TO UNICODE op_CUUTF uint32 = 0xB2A6 // FORMAT_RRF3 CONVERT UNICODE TO UTF-8 op_CUXTR uint32 = 0xB3EA // FORMAT_RRE CONVERT TO UNSIGNED PACKED (extended DFP to 128) op_CVB uint32 = 0x4F00 // FORMAT_RX1 CONVERT TO BINARY (32) op_CVBG uint32 = 0xE30E // FORMAT_RXY1 CONVERT TO BINARY (64) op_CVBY uint32 = 0xE306 // FORMAT_RXY1 CONVERT TO BINARY (32) op_CVD uint32 = 0x4E00 // FORMAT_RX1 CONVERT TO DECIMAL (32) op_CVDG uint32 = 0xE32E // FORMAT_RXY1 CONVERT TO DECIMAL (64) op_CVDY uint32 = 0xE326 // FORMAT_RXY1 CONVERT TO DECIMAL (32) op_CXBR uint32 = 0xB349 // FORMAT_RRE COMPARE (extended BFP) op_CXFBR uint32 = 0xB396 // FORMAT_RRE CONVERT FROM FIXED (32 to extended BFP) op_CXFBRA uint32 = 0xB396 // FORMAT_RRF5 CONVERT FROM FIXED (32 to extended BFP) op_CXFR uint32 = 0xB3B6 // FORMAT_RRE CONVERT FROM FIXED (32 to extended HFP) op_CXFTR uint32 = 0xB959 // FORMAT_RRE CONVERT FROM FIXED (32 to extended DFP) op_CXGBR uint32 = 0xB3A6 // FORMAT_RRE CONVERT FROM FIXED (64 to extended BFP) op_CXGBRA uint32 = 0xB3A6 // FORMAT_RRF5 CONVERT FROM FIXED (64 to extended BFP) op_CXGR uint32 = 0xB3C6 // FORMAT_RRE CONVERT FROM FIXED (64 to extended HFP) op_CXGTR uint32 = 0xB3F9 // FORMAT_RRE CONVERT FROM FIXED (64 to extended DFP) op_CXGTRA uint32 = 0xB3F9 // FORMAT_RRF5 CONVERT FROM FIXED (64 to extended DFP) op_CXLFBR uint32 = 0xB392 // FORMAT_RRF5 CONVERT FROM LOGICAL (32 to extended BFP) op_CXLFTR uint32 = 0xB95B // FORMAT_RRF5 CONVERT FROM LOGICAL (32 to extended DFP) op_CXLGBR uint32 = 0xB3A2 // FORMAT_RRF5 CONVERT FROM LOGICAL (64 to extended BFP) op_CXLGTR uint32 = 0xB95A // FORMAT_RRF5 CONVERT FROM LOGICAL (64 to extended DFP) op_CXR uint32 = 0xB369 // FORMAT_RRE COMPARE (extended HFP) op_CXSTR uint32 = 0xB3FB // FORMAT_RRE CONVERT FROM SIGNED PACKED (128 to extended DFP) op_CXTR uint32 = 0xB3EC // FORMAT_RRE COMPARE (extended DFP) op_CXUTR uint32 = 0xB3FA // FORMAT_RRE CONVERT FROM UNSIGNED PACKED (128 to ext. DFP) op_CXZT uint32 = 0xEDAB // FORMAT_RSL CONVERT FROM ZONED (to extended DFP) op_CY uint32 = 0xE359 // FORMAT_RXY1 COMPARE (32) op_CZDT uint32 = 0xEDA8 // FORMAT_RSL CONVERT TO ZONED (from long DFP) op_CZXT uint32 = 0xEDA9 // FORMAT_RSL CONVERT TO ZONED (from extended DFP) op_D uint32 = 0x5D00 // FORMAT_RX1 DIVIDE (32<-64) op_DD uint32 = 0x6D00 // FORMAT_RX1 DIVIDE (long HFP) op_DDB uint32 = 0xED1D // FORMAT_RXE DIVIDE (long BFP) op_DDBR uint32 = 0xB31D // FORMAT_RRE DIVIDE (long BFP) op_DDR uint32 = 0x2D00 // FORMAT_RR DIVIDE (long HFP) op_DDTR uint32 = 0xB3D1 // FORMAT_RRF1 DIVIDE (long DFP) op_DDTRA uint32 = 0xB3D1 // FORMAT_RRF1 DIVIDE (long DFP) op_DE uint32 = 0x7D00 // FORMAT_RX1 DIVIDE (short HFP) op_DEB uint32 = 0xED0D // FORMAT_RXE DIVIDE (short BFP) op_DEBR uint32 = 0xB30D // FORMAT_RRE DIVIDE (short BFP) op_DER uint32 = 0x3D00 // FORMAT_RR DIVIDE (short HFP) op_DIDBR uint32 = 0xB35B // FORMAT_RRF2 DIVIDE TO INTEGER (long BFP) op_DIEBR uint32 = 0xB353 // FORMAT_RRF2 DIVIDE TO INTEGER (short BFP) op_DL uint32 = 0xE397 // FORMAT_RXY1 DIVIDE LOGICAL (32<-64) op_DLG uint32 = 0xE387 // FORMAT_RXY1 DIVIDE LOGICAL (64<-128) op_DLGR uint32 = 0xB987 // FORMAT_RRE DIVIDE LOGICAL (64<-128) op_DLR uint32 = 0xB997 // FORMAT_RRE DIVIDE LOGICAL (32<-64) op_DP uint32 = 0xFD00 // FORMAT_SS2 DIVIDE DECIMAL op_DR uint32 = 0x1D00 // FORMAT_RR DIVIDE (32<-64) op_DSG uint32 = 0xE30D // FORMAT_RXY1 DIVIDE SINGLE (64) op_DSGF uint32 = 0xE31D // FORMAT_RXY1 DIVIDE SINGLE (64<-32) op_DSGFR uint32 = 0xB91D // FORMAT_RRE DIVIDE SINGLE (64<-32) op_DSGR uint32 = 0xB90D // FORMAT_RRE DIVIDE SINGLE (64) op_DXBR uint32 = 0xB34D // FORMAT_RRE DIVIDE (extended BFP) op_DXR uint32 = 0xB22D // FORMAT_RRE DIVIDE (extended HFP) op_DXTR uint32 = 0xB3D9 // FORMAT_RRF1 DIVIDE (extended DFP) op_DXTRA uint32 = 0xB3D9 // FORMAT_RRF1 DIVIDE (extended DFP) op_EAR uint32 = 0xB24F // FORMAT_RRE EXTRACT ACCESS op_ECAG uint32 = 0xEB4C // FORMAT_RSY1 EXTRACT CACHE ATTRIBUTE op_ECTG uint32 = 0xC801 // FORMAT_SSF EXTRACT CPU TIME op_ED uint32 = 0xDE00 // FORMAT_SS1 EDIT op_EDMK uint32 = 0xDF00 // FORMAT_SS1 EDIT AND MARK op_EEDTR uint32 = 0xB3E5 // FORMAT_RRE EXTRACT BIASED EXPONENT (long DFP to 64) op_EEXTR uint32 = 0xB3ED // FORMAT_RRE EXTRACT BIASED EXPONENT (extended DFP to 64) op_EFPC uint32 = 0xB38C // FORMAT_RRE EXTRACT FPC op_EPAIR uint32 = 0xB99A // FORMAT_RRE EXTRACT PRIMARY ASN AND INSTANCE op_EPAR uint32 = 0xB226 // FORMAT_RRE EXTRACT PRIMARY ASN op_EPSW uint32 = 0xB98D // FORMAT_RRE EXTRACT PSW op_EREG uint32 = 0xB249 // FORMAT_RRE EXTRACT STACKED REGISTERS (32) op_EREGG uint32 = 0xB90E // FORMAT_RRE EXTRACT STACKED REGISTERS (64) op_ESAIR uint32 = 0xB99B // FORMAT_RRE EXTRACT SECONDARY ASN AND INSTANCE op_ESAR uint32 = 0xB227 // FORMAT_RRE EXTRACT SECONDARY ASN op_ESDTR uint32 = 0xB3E7 // FORMAT_RRE EXTRACT SIGNIFICANCE (long DFP) op_ESEA uint32 = 0xB99D // FORMAT_RRE EXTRACT AND SET EXTENDED AUTHORITY op_ESTA uint32 = 0xB24A // FORMAT_RRE EXTRACT STACKED STATE op_ESXTR uint32 = 0xB3EF // FORMAT_RRE EXTRACT SIGNIFICANCE (extended DFP) op_ETND uint32 = 0xB2EC // FORMAT_RRE EXTRACT TRANSACTION NESTING DEPTH op_EX uint32 = 0x4400 // FORMAT_RX1 EXECUTE op_EXRL uint32 = 0xC600 // FORMAT_RIL2 EXECUTE RELATIVE LONG op_FIDBR uint32 = 0xB35F // FORMAT_RRF5 LOAD FP INTEGER (long BFP) op_FIDBRA uint32 = 0xB35F // FORMAT_RRF5 LOAD FP INTEGER (long BFP) op_FIDR uint32 = 0xB37F // FORMAT_RRE LOAD FP INTEGER (long HFP) op_FIDTR uint32 = 0xB3D7 // FORMAT_RRF5 LOAD FP INTEGER (long DFP) op_FIEBR uint32 = 0xB357 // FORMAT_RRF5 LOAD FP INTEGER (short BFP) op_FIEBRA uint32 = 0xB357 // FORMAT_RRF5 LOAD FP INTEGER (short BFP) op_FIER uint32 = 0xB377 // FORMAT_RRE LOAD FP INTEGER (short HFP) op_FIXBR uint32 = 0xB347 // FORMAT_RRF5 LOAD FP INTEGER (extended BFP) op_FIXBRA uint32 = 0xB347 // FORMAT_RRF5 LOAD FP INTEGER (extended BFP) op_FIXR uint32 = 0xB367 // FORMAT_RRE LOAD FP INTEGER (extended HFP) op_FIXTR uint32 = 0xB3DF // FORMAT_RRF5 LOAD FP INTEGER (extended DFP) op_FLOGR uint32 = 0xB983 // FORMAT_RRE FIND LEFTMOST ONE op_HDR uint32 = 0x2400 // FORMAT_RR HALVE (long HFP) op_HER uint32 = 0x3400 // FORMAT_RR HALVE (short HFP) op_HSCH uint32 = 0xB231 // FORMAT_S HALT SUBCHANNEL op_IAC uint32 = 0xB224 // FORMAT_RRE INSERT ADDRESS SPACE CONTROL op_IC uint32 = 0x4300 // FORMAT_RX1 INSERT CHARACTER op_ICM uint32 = 0xBF00 // FORMAT_RS2 INSERT CHARACTERS UNDER MASK (low) op_ICMH uint32 = 0xEB80 // FORMAT_RSY2 INSERT CHARACTERS UNDER MASK (high) op_ICMY uint32 = 0xEB81 // FORMAT_RSY2 INSERT CHARACTERS UNDER MASK (low) op_ICY uint32 = 0xE373 // FORMAT_RXY1 INSERT CHARACTER op_IDTE uint32 = 0xB98E // FORMAT_RRF2 INVALIDATE DAT TABLE ENTRY op_IEDTR uint32 = 0xB3F6 // FORMAT_RRF2 INSERT BIASED EXPONENT (64 to long DFP) op_IEXTR uint32 = 0xB3FE // FORMAT_RRF2 INSERT BIASED EXPONENT (64 to extended DFP) op_IIHF uint32 = 0xC008 // FORMAT_RIL1 INSERT IMMEDIATE (high) op_IIHH uint32 = 0xA500 // FORMAT_RI1 INSERT IMMEDIATE (high high) op_IIHL uint32 = 0xA501 // FORMAT_RI1 INSERT IMMEDIATE (high low) op_IILF uint32 = 0xC009 // FORMAT_RIL1 INSERT IMMEDIATE (low) op_IILH uint32 = 0xA502 // FORMAT_RI1 INSERT IMMEDIATE (low high) op_IILL uint32 = 0xA503 // FORMAT_RI1 INSERT IMMEDIATE (low low) op_IPK uint32 = 0xB20B // FORMAT_S INSERT PSW KEY op_IPM uint32 = 0xB222 // FORMAT_RRE INSERT PROGRAM MASK op_IPTE uint32 = 0xB221 // FORMAT_RRF1 INVALIDATE PAGE TABLE ENTRY op_ISKE uint32 = 0xB229 // FORMAT_RRE INSERT STORAGE KEY EXTENDED op_IVSK uint32 = 0xB223 // FORMAT_RRE INSERT VIRTUAL STORAGE KEY op_KDB uint32 = 0xED18 // FORMAT_RXE COMPARE AND SIGNAL (long BFP) op_KDBR uint32 = 0xB318 // FORMAT_RRE COMPARE AND SIGNAL (long BFP) op_KDTR uint32 = 0xB3E0 // FORMAT_RRE COMPARE AND SIGNAL (long DFP) op_KEB uint32 = 0xED08 // FORMAT_RXE COMPARE AND SIGNAL (short BFP) op_KEBR uint32 = 0xB308 // FORMAT_RRE COMPARE AND SIGNAL (short BFP) op_KIMD uint32 = 0xB93E // FORMAT_RRE COMPUTE INTERMEDIATE MESSAGE DIGEST op_KLMD uint32 = 0xB93F // FORMAT_RRE COMPUTE LAST MESSAGE DIGEST op_KM uint32 = 0xB92E // FORMAT_RRE CIPHER MESSAGE op_KMAC uint32 = 0xB91E // FORMAT_RRE COMPUTE MESSAGE AUTHENTICATION CODE op_KMC uint32 = 0xB92F // FORMAT_RRE CIPHER MESSAGE WITH CHAINING op_KMA uint32 = 0xB929 // FORMAT_RRF2 CIPHER MESSAGE WITH AUTHENTICATION op_KMCTR uint32 = 0xB92D // FORMAT_RRF2 CIPHER MESSAGE WITH COUNTER op_KMF uint32 = 0xB92A // FORMAT_RRE CIPHER MESSAGE WITH CFB op_KMO uint32 = 0xB92B // FORMAT_RRE CIPHER MESSAGE WITH OFB op_KXBR uint32 = 0xB348 // FORMAT_RRE COMPARE AND SIGNAL (extended BFP) op_KXTR uint32 = 0xB3E8 // FORMAT_RRE COMPARE AND SIGNAL (extended DFP) op_L uint32 = 0x5800 // FORMAT_RX1 LOAD (32) op_LA uint32 = 0x4100 // FORMAT_RX1 LOAD ADDRESS op_LAA uint32 = 0xEBF8 // FORMAT_RSY1 LOAD AND ADD (32) op_LAAG uint32 = 0xEBE8 // FORMAT_RSY1 LOAD AND ADD (64) op_LAAL uint32 = 0xEBFA // FORMAT_RSY1 LOAD AND ADD LOGICAL (32) op_LAALG uint32 = 0xEBEA // FORMAT_RSY1 LOAD AND ADD LOGICAL (64) op_LAE uint32 = 0x5100 // FORMAT_RX1 LOAD ADDRESS EXTENDED op_LAEY uint32 = 0xE375 // FORMAT_RXY1 LOAD ADDRESS EXTENDED op_LAM uint32 = 0x9A00 // FORMAT_RS1 LOAD ACCESS MULTIPLE op_LAMY uint32 = 0xEB9A // FORMAT_RSY1 LOAD ACCESS MULTIPLE op_LAN uint32 = 0xEBF4 // FORMAT_RSY1 LOAD AND AND (32) op_LANG uint32 = 0xEBE4 // FORMAT_RSY1 LOAD AND AND (64) op_LAO uint32 = 0xEBF6 // FORMAT_RSY1 LOAD AND OR (32) op_LAOG uint32 = 0xEBE6 // FORMAT_RSY1 LOAD AND OR (64) op_LARL uint32 = 0xC000 // FORMAT_RIL2 LOAD ADDRESS RELATIVE LONG op_LASP uint32 = 0xE500 // FORMAT_SSE LOAD ADDRESS SPACE PARAMETERS op_LAT uint32 = 0xE39F // FORMAT_RXY1 LOAD AND TRAP (32L<-32) op_LAX uint32 = 0xEBF7 // FORMAT_RSY1 LOAD AND EXCLUSIVE OR (32) op_LAXG uint32 = 0xEBE7 // FORMAT_RSY1 LOAD AND EXCLUSIVE OR (64) op_LAY uint32 = 0xE371 // FORMAT_RXY1 LOAD ADDRESS op_LB uint32 = 0xE376 // FORMAT_RXY1 LOAD BYTE (32) op_LBH uint32 = 0xE3C0 // FORMAT_RXY1 LOAD BYTE HIGH (32<-8) op_LBR uint32 = 0xB926 // FORMAT_RRE LOAD BYTE (32) op_LCDBR uint32 = 0xB313 // FORMAT_RRE LOAD COMPLEMENT (long BFP) op_LCDFR uint32 = 0xB373 // FORMAT_RRE LOAD COMPLEMENT (long) op_LCDR uint32 = 0x2300 // FORMAT_RR LOAD COMPLEMENT (long HFP) op_LCEBR uint32 = 0xB303 // FORMAT_RRE LOAD COMPLEMENT (short BFP) op_LCER uint32 = 0x3300 // FORMAT_RR LOAD COMPLEMENT (short HFP) op_LCGFR uint32 = 0xB913 // FORMAT_RRE LOAD COMPLEMENT (64<-32) op_LCGR uint32 = 0xB903 // FORMAT_RRE LOAD COMPLEMENT (64) op_LCR uint32 = 0x1300 // FORMAT_RR LOAD COMPLEMENT (32) op_LCTL uint32 = 0xB700 // FORMAT_RS1 LOAD CONTROL (32) op_LCTLG uint32 = 0xEB2F // FORMAT_RSY1 LOAD CONTROL (64) op_LCXBR uint32 = 0xB343 // FORMAT_RRE LOAD COMPLEMENT (extended BFP) op_LCXR uint32 = 0xB363 // FORMAT_RRE LOAD COMPLEMENT (extended HFP) op_LD uint32 = 0x6800 // FORMAT_RX1 LOAD (long) op_LDE uint32 = 0xED24 // FORMAT_RXE LOAD LENGTHENED (short to long HFP) op_LDEB uint32 = 0xED04 // FORMAT_RXE LOAD LENGTHENED (short to long BFP) op_LDEBR uint32 = 0xB304 // FORMAT_RRE LOAD LENGTHENED (short to long BFP) op_LDER uint32 = 0xB324 // FORMAT_RRE LOAD LENGTHENED (short to long HFP) op_LDETR uint32 = 0xB3D4 // FORMAT_RRF4 LOAD LENGTHENED (short to long DFP) op_LDGR uint32 = 0xB3C1 // FORMAT_RRE LOAD FPR FROM GR (64 to long) op_LDR uint32 = 0x2800 // FORMAT_RR LOAD (long) op_LDXBR uint32 = 0xB345 // FORMAT_RRE LOAD ROUNDED (extended to long BFP) op_LDXBRA uint32 = 0xB345 // FORMAT_RRF5 LOAD ROUNDED (extended to long BFP) op_LDXR uint32 = 0x2500 // FORMAT_RR LOAD ROUNDED (extended to long HFP) op_LDXTR uint32 = 0xB3DD // FORMAT_RRF5 LOAD ROUNDED (extended to long DFP) op_LDY uint32 = 0xED65 // FORMAT_RXY1 LOAD (long) op_LE uint32 = 0x7800 // FORMAT_RX1 LOAD (short) op_LEDBR uint32 = 0xB344 // FORMAT_RRE LOAD ROUNDED (long to short BFP) op_LEDBRA uint32 = 0xB344 // FORMAT_RRF5 LOAD ROUNDED (long to short BFP) op_LEDR uint32 = 0x3500 // FORMAT_RR LOAD ROUNDED (long to short HFP) op_LEDTR uint32 = 0xB3D5 // FORMAT_RRF5 LOAD ROUNDED (long to short DFP) op_LER uint32 = 0x3800 // FORMAT_RR LOAD (short) op_LEXBR uint32 = 0xB346 // FORMAT_RRE LOAD ROUNDED (extended to short BFP) op_LEXBRA uint32 = 0xB346 // FORMAT_RRF5 LOAD ROUNDED (extended to short BFP) op_LEXR uint32 = 0xB366 // FORMAT_RRE LOAD ROUNDED (extended to short HFP) op_LEY uint32 = 0xED64 // FORMAT_RXY1 LOAD (short) op_LFAS uint32 = 0xB2BD // FORMAT_S LOAD FPC AND SIGNAL op_LFH uint32 = 0xE3CA // FORMAT_RXY1 LOAD HIGH (32) op_LFHAT uint32 = 0xE3C8 // FORMAT_RXY1 LOAD HIGH AND TRAP (32H<-32) op_LFPC uint32 = 0xB29D // FORMAT_S LOAD FPC op_LG uint32 = 0xE304 // FORMAT_RXY1 LOAD (64) op_LGAT uint32 = 0xE385 // FORMAT_RXY1 LOAD AND TRAP (64) op_LGB uint32 = 0xE377 // FORMAT_RXY1 LOAD BYTE (64) op_LGBR uint32 = 0xB906 // FORMAT_RRE LOAD BYTE (64) op_LGDR uint32 = 0xB3CD // FORMAT_RRE LOAD GR FROM FPR (long to 64) op_LGF uint32 = 0xE314 // FORMAT_RXY1 LOAD (64<-32) op_LGFI uint32 = 0xC001 // FORMAT_RIL1 LOAD IMMEDIATE (64<-32) op_LGFR uint32 = 0xB914 // FORMAT_RRE LOAD (64<-32) op_LGFRL uint32 = 0xC40C // FORMAT_RIL2 LOAD RELATIVE LONG (64<-32) op_LGH uint32 = 0xE315 // FORMAT_RXY1 LOAD HALFWORD (64) op_LGHI uint32 = 0xA709 // FORMAT_RI1 LOAD HALFWORD IMMEDIATE (64) op_LGHR uint32 = 0xB907 // FORMAT_RRE LOAD HALFWORD (64) op_LGHRL uint32 = 0xC404 // FORMAT_RIL2 LOAD HALFWORD RELATIVE LONG (64<-16) op_LGR uint32 = 0xB904 // FORMAT_RRE LOAD (64) op_LGRL uint32 = 0xC408 // FORMAT_RIL2 LOAD RELATIVE LONG (64) op_LH uint32 = 0x4800 // FORMAT_RX1 LOAD HALFWORD (32) op_LHH uint32 = 0xE3C4 // FORMAT_RXY1 LOAD HALFWORD HIGH (32<-16) op_LHI uint32 = 0xA708 // FORMAT_RI1 LOAD HALFWORD IMMEDIATE (32) op_LHR uint32 = 0xB927 // FORMAT_RRE LOAD HALFWORD (32) op_LHRL uint32 = 0xC405 // FORMAT_RIL2 LOAD HALFWORD RELATIVE LONG (32<-16) op_LHY uint32 = 0xE378 // FORMAT_RXY1 LOAD HALFWORD (32) op_LLC uint32 = 0xE394 // FORMAT_RXY1 LOAD LOGICAL CHARACTER (32) op_LLCH uint32 = 0xE3C2 // FORMAT_RXY1 LOAD LOGICAL CHARACTER HIGH (32<-8) op_LLCR uint32 = 0xB994 // FORMAT_RRE LOAD LOGICAL CHARACTER (32) op_LLGC uint32 = 0xE390 // FORMAT_RXY1 LOAD LOGICAL CHARACTER (64) op_LLGCR uint32 = 0xB984 // FORMAT_RRE LOAD LOGICAL CHARACTER (64) op_LLGF uint32 = 0xE316 // FORMAT_RXY1 LOAD LOGICAL (64<-32) op_LLGFAT uint32 = 0xE39D // FORMAT_RXY1 LOAD LOGICAL AND TRAP (64<-32) op_LLGFR uint32 = 0xB916 // FORMAT_RRE LOAD LOGICAL (64<-32) op_LLGFRL uint32 = 0xC40E // FORMAT_RIL2 LOAD LOGICAL RELATIVE LONG (64<-32) op_LLGH uint32 = 0xE391 // FORMAT_RXY1 LOAD LOGICAL HALFWORD (64) op_LLGHR uint32 = 0xB985 // FORMAT_RRE LOAD LOGICAL HALFWORD (64) op_LLGHRL uint32 = 0xC406 // FORMAT_RIL2 LOAD LOGICAL HALFWORD RELATIVE LONG (64<-16) op_LLGT uint32 = 0xE317 // FORMAT_RXY1 LOAD LOGICAL THIRTY ONE BITS op_LLGTAT uint32 = 0xE39C // FORMAT_RXY1 LOAD LOGICAL THIRTY ONE BITS AND TRAP (64<-31) op_LLGTR uint32 = 0xB917 // FORMAT_RRE LOAD LOGICAL THIRTY ONE BITS op_LLH uint32 = 0xE395 // FORMAT_RXY1 LOAD LOGICAL HALFWORD (32) op_LLHH uint32 = 0xE3C6 // FORMAT_RXY1 LOAD LOGICAL HALFWORD HIGH (32<-16) op_LLHR uint32 = 0xB995 // FORMAT_RRE LOAD LOGICAL HALFWORD (32) op_LLHRL uint32 = 0xC402 // FORMAT_RIL2 LOAD LOGICAL HALFWORD RELATIVE LONG (32<-16) op_LLIHF uint32 = 0xC00E // FORMAT_RIL1 LOAD LOGICAL IMMEDIATE (high) op_LLIHH uint32 = 0xA50C // FORMAT_RI1 LOAD LOGICAL IMMEDIATE (high high) op_LLIHL uint32 = 0xA50D // FORMAT_RI1 LOAD LOGICAL IMMEDIATE (high low) op_LLILF uint32 = 0xC00F // FORMAT_RIL1 LOAD LOGICAL IMMEDIATE (low) op_LLILH uint32 = 0xA50E // FORMAT_RI1 LOAD LOGICAL IMMEDIATE (low high) op_LLILL uint32 = 0xA50F // FORMAT_RI1 LOAD LOGICAL IMMEDIATE (low low) op_LM uint32 = 0x9800 // FORMAT_RS1 LOAD MULTIPLE (32) op_LMD uint32 = 0xEF00 // FORMAT_SS5 LOAD MULTIPLE DISJOINT op_LMG uint32 = 0xEB04 // FORMAT_RSY1 LOAD MULTIPLE (64) op_LMH uint32 = 0xEB96 // FORMAT_RSY1 LOAD MULTIPLE HIGH op_LMY uint32 = 0xEB98 // FORMAT_RSY1 LOAD MULTIPLE (32) op_LNDBR uint32 = 0xB311 // FORMAT_RRE LOAD NEGATIVE (long BFP) op_LNDFR uint32 = 0xB371 // FORMAT_RRE LOAD NEGATIVE (long) op_LNDR uint32 = 0x2100 // FORMAT_RR LOAD NEGATIVE (long HFP) op_LNEBR uint32 = 0xB301 // FORMAT_RRE LOAD NEGATIVE (short BFP) op_LNER uint32 = 0x3100 // FORMAT_RR LOAD NEGATIVE (short HFP) op_LNGFR uint32 = 0xB911 // FORMAT_RRE LOAD NEGATIVE (64<-32) op_LNGR uint32 = 0xB901 // FORMAT_RRE LOAD NEGATIVE (64) op_LNR uint32 = 0x1100 // FORMAT_RR LOAD NEGATIVE (32) op_LNXBR uint32 = 0xB341 // FORMAT_RRE LOAD NEGATIVE (extended BFP) op_LNXR uint32 = 0xB361 // FORMAT_RRE LOAD NEGATIVE (extended HFP) op_LOC uint32 = 0xEBF2 // FORMAT_RSY2 LOAD ON CONDITION (32) op_LOCG uint32 = 0xEBE2 // FORMAT_RSY2 LOAD ON CONDITION (64) op_LOCGR uint32 = 0xB9E2 // FORMAT_RRF3 LOAD ON CONDITION (64) op_LOCR uint32 = 0xB9F2 // FORMAT_RRF3 LOAD ON CONDITION (32) op_LPD uint32 = 0xC804 // FORMAT_SSF LOAD PAIR DISJOINT (32) op_LPDBR uint32 = 0xB310 // FORMAT_RRE LOAD POSITIVE (long BFP) op_LPDFR uint32 = 0xB370 // FORMAT_RRE LOAD POSITIVE (long) op_LPDG uint32 = 0xC805 // FORMAT_SSF LOAD PAIR DISJOINT (64) op_LPDR uint32 = 0x2000 // FORMAT_RR LOAD POSITIVE (long HFP) op_LPEBR uint32 = 0xB300 // FORMAT_RRE LOAD POSITIVE (short BFP) op_LPER uint32 = 0x3000 // FORMAT_RR LOAD POSITIVE (short HFP) op_LPGFR uint32 = 0xB910 // FORMAT_RRE LOAD POSITIVE (64<-32) op_LPGR uint32 = 0xB900 // FORMAT_RRE LOAD POSITIVE (64) op_LPQ uint32 = 0xE38F // FORMAT_RXY1 LOAD PAIR FROM QUADWORD op_LPR uint32 = 0x1000 // FORMAT_RR LOAD POSITIVE (32) op_LPSW uint32 = 0x8200 // FORMAT_S LOAD PSW op_LPSWE uint32 = 0xB2B2 // FORMAT_S LOAD PSW EXTENDED op_LPTEA uint32 = 0xB9AA // FORMAT_RRF2 LOAD PAGE TABLE ENTRY ADDRESS op_LPXBR uint32 = 0xB340 // FORMAT_RRE LOAD POSITIVE (extended BFP) op_LPXR uint32 = 0xB360 // FORMAT_RRE LOAD POSITIVE (extended HFP) op_LR uint32 = 0x1800 // FORMAT_RR LOAD (32) op_LRA uint32 = 0xB100 // FORMAT_RX1 LOAD REAL ADDRESS (32) op_LRAG uint32 = 0xE303 // FORMAT_RXY1 LOAD REAL ADDRESS (64) op_LRAY uint32 = 0xE313 // FORMAT_RXY1 LOAD REAL ADDRESS (32) op_LRDR uint32 = 0x2500 // FORMAT_RR LOAD ROUNDED (extended to long HFP) op_LRER uint32 = 0x3500 // FORMAT_RR LOAD ROUNDED (long to short HFP) op_LRL uint32 = 0xC40D // FORMAT_RIL2 LOAD RELATIVE LONG (32) op_LRV uint32 = 0xE31E // FORMAT_RXY1 LOAD REVERSED (32) op_LRVG uint32 = 0xE30F // FORMAT_RXY1 LOAD REVERSED (64) op_LRVGR uint32 = 0xB90F // FORMAT_RRE LOAD REVERSED (64) op_LRVH uint32 = 0xE31F // FORMAT_RXY1 LOAD REVERSED (16) op_LRVR uint32 = 0xB91F // FORMAT_RRE LOAD REVERSED (32) op_LT uint32 = 0xE312 // FORMAT_RXY1 LOAD AND TEST (32) op_LTDBR uint32 = 0xB312 // FORMAT_RRE LOAD AND TEST (long BFP) op_LTDR uint32 = 0x2200 // FORMAT_RR LOAD AND TEST (long HFP) op_LTDTR uint32 = 0xB3D6 // FORMAT_RRE LOAD AND TEST (long DFP) op_LTEBR uint32 = 0xB302 // FORMAT_RRE LOAD AND TEST (short BFP) op_LTER uint32 = 0x3200 // FORMAT_RR LOAD AND TEST (short HFP) op_LTG uint32 = 0xE302 // FORMAT_RXY1 LOAD AND TEST (64) op_LTGF uint32 = 0xE332 // FORMAT_RXY1 LOAD AND TEST (64<-32) op_LTGFR uint32 = 0xB912 // FORMAT_RRE LOAD AND TEST (64<-32) op_LTGR uint32 = 0xB902 // FORMAT_RRE LOAD AND TEST (64) op_LTR uint32 = 0x1200 // FORMAT_RR LOAD AND TEST (32) op_LTXBR uint32 = 0xB342 // FORMAT_RRE LOAD AND TEST (extended BFP) op_LTXR uint32 = 0xB362 // FORMAT_RRE LOAD AND TEST (extended HFP) op_LTXTR uint32 = 0xB3DE // FORMAT_RRE LOAD AND TEST (extended DFP) op_LURA uint32 = 0xB24B // FORMAT_RRE LOAD USING REAL ADDRESS (32) op_LURAG uint32 = 0xB905 // FORMAT_RRE LOAD USING REAL ADDRESS (64) op_LXD uint32 = 0xED25 // FORMAT_RXE LOAD LENGTHENED (long to extended HFP) op_LXDB uint32 = 0xED05 // FORMAT_RXE LOAD LENGTHENED (long to extended BFP) op_LXDBR uint32 = 0xB305 // FORMAT_RRE LOAD LENGTHENED (long to extended BFP) op_LXDR uint32 = 0xB325 // FORMAT_RRE LOAD LENGTHENED (long to extended HFP) op_LXDTR uint32 = 0xB3DC // FORMAT_RRF4 LOAD LENGTHENED (long to extended DFP) op_LXE uint32 = 0xED26 // FORMAT_RXE LOAD LENGTHENED (short to extended HFP) op_LXEB uint32 = 0xED06 // FORMAT_RXE LOAD LENGTHENED (short to extended BFP) op_LXEBR uint32 = 0xB306 // FORMAT_RRE LOAD LENGTHENED (short to extended BFP) op_LXER uint32 = 0xB326 // FORMAT_RRE LOAD LENGTHENED (short to extended HFP) op_LXR uint32 = 0xB365 // FORMAT_RRE LOAD (extended) op_LY uint32 = 0xE358 // FORMAT_RXY1 LOAD (32) op_LZDR uint32 = 0xB375 // FORMAT_RRE LOAD ZERO (long) op_LZER uint32 = 0xB374 // FORMAT_RRE LOAD ZERO (short) op_LZXR uint32 = 0xB376 // FORMAT_RRE LOAD ZERO (extended) op_M uint32 = 0x5C00 // FORMAT_RX1 MULTIPLY (64<-32) op_MAD uint32 = 0xED3E // FORMAT_RXF MULTIPLY AND ADD (long HFP) op_MADB uint32 = 0xED1E // FORMAT_RXF MULTIPLY AND ADD (long BFP) op_MADBR uint32 = 0xB31E // FORMAT_RRD MULTIPLY AND ADD (long BFP) op_MADR uint32 = 0xB33E // FORMAT_RRD MULTIPLY AND ADD (long HFP) op_MAE uint32 = 0xED2E // FORMAT_RXF MULTIPLY AND ADD (short HFP) op_MAEB uint32 = 0xED0E // FORMAT_RXF MULTIPLY AND ADD (short BFP) op_MAEBR uint32 = 0xB30E // FORMAT_RRD MULTIPLY AND ADD (short BFP) op_MAER uint32 = 0xB32E // FORMAT_RRD MULTIPLY AND ADD (short HFP) op_MAY uint32 = 0xED3A // FORMAT_RXF MULTIPLY & ADD UNNORMALIZED (long to ext. HFP) op_MAYH uint32 = 0xED3C // FORMAT_RXF MULTIPLY AND ADD UNNRM. (long to ext. high HFP) op_MAYHR uint32 = 0xB33C // FORMAT_RRD MULTIPLY AND ADD UNNRM. (long to ext. high HFP) op_MAYL uint32 = 0xED38 // FORMAT_RXF MULTIPLY AND ADD UNNRM. (long to ext. low HFP) op_MAYLR uint32 = 0xB338 // FORMAT_RRD MULTIPLY AND ADD UNNRM. (long to ext. low HFP) op_MAYR uint32 = 0xB33A // FORMAT_RRD MULTIPLY & ADD UNNORMALIZED (long to ext. HFP) op_MC uint32 = 0xAF00 // FORMAT_SI MONITOR CALL op_MD uint32 = 0x6C00 // FORMAT_RX1 MULTIPLY (long HFP) op_MDB uint32 = 0xED1C // FORMAT_RXE MULTIPLY (long BFP) op_MDBR uint32 = 0xB31C // FORMAT_RRE MULTIPLY (long BFP) op_MDE uint32 = 0x7C00 // FORMAT_RX1 MULTIPLY (short to long HFP) op_MDEB uint32 = 0xED0C // FORMAT_RXE MULTIPLY (short to long BFP) op_MDEBR uint32 = 0xB30C // FORMAT_RRE MULTIPLY (short to long BFP) op_MDER uint32 = 0x3C00 // FORMAT_RR MULTIPLY (short to long HFP) op_MDR uint32 = 0x2C00 // FORMAT_RR MULTIPLY (long HFP) op_MDTR uint32 = 0xB3D0 // FORMAT_RRF1 MULTIPLY (long DFP) op_MDTRA uint32 = 0xB3D0 // FORMAT_RRF1 MULTIPLY (long DFP) op_ME uint32 = 0x7C00 // FORMAT_RX1 MULTIPLY (short to long HFP) op_MEE uint32 = 0xED37 // FORMAT_RXE MULTIPLY (short HFP) op_MEEB uint32 = 0xED17 // FORMAT_RXE MULTIPLY (short BFP) op_MEEBR uint32 = 0xB317 // FORMAT_RRE MULTIPLY (short BFP) op_MEER uint32 = 0xB337 // FORMAT_RRE MULTIPLY (short HFP) op_MER uint32 = 0x3C00 // FORMAT_RR MULTIPLY (short to long HFP) op_MFY uint32 = 0xE35C // FORMAT_RXY1 MULTIPLY (64<-32) op_MGHI uint32 = 0xA70D // FORMAT_RI1 MULTIPLY HALFWORD IMMEDIATE (64) op_MH uint32 = 0x4C00 // FORMAT_RX1 MULTIPLY HALFWORD (32) op_MHI uint32 = 0xA70C // FORMAT_RI1 MULTIPLY HALFWORD IMMEDIATE (32) op_MHY uint32 = 0xE37C // FORMAT_RXY1 MULTIPLY HALFWORD (32) op_ML uint32 = 0xE396 // FORMAT_RXY1 MULTIPLY LOGICAL (64<-32) op_MLG uint32 = 0xE386 // FORMAT_RXY1 MULTIPLY LOGICAL (128<-64) op_MLGR uint32 = 0xB986 // FORMAT_RRE MULTIPLY LOGICAL (128<-64) op_MLR uint32 = 0xB996 // FORMAT_RRE MULTIPLY LOGICAL (64<-32) op_MP uint32 = 0xFC00 // FORMAT_SS2 MULTIPLY DECIMAL op_MR uint32 = 0x1C00 // FORMAT_RR MULTIPLY (64<-32) op_MS uint32 = 0x7100 // FORMAT_RX1 MULTIPLY SINGLE (32) op_MSCH uint32 = 0xB232 // FORMAT_S MODIFY SUBCHANNEL op_MSD uint32 = 0xED3F // FORMAT_RXF MULTIPLY AND SUBTRACT (long HFP) op_MSDB uint32 = 0xED1F // FORMAT_RXF MULTIPLY AND SUBTRACT (long BFP) op_MSDBR uint32 = 0xB31F // FORMAT_RRD MULTIPLY AND SUBTRACT (long BFP) op_MSDR uint32 = 0xB33F // FORMAT_RRD MULTIPLY AND SUBTRACT (long HFP) op_MSE uint32 = 0xED2F // FORMAT_RXF MULTIPLY AND SUBTRACT (short HFP) op_MSEB uint32 = 0xED0F // FORMAT_RXF MULTIPLY AND SUBTRACT (short BFP) op_MSEBR uint32 = 0xB30F // FORMAT_RRD MULTIPLY AND SUBTRACT (short BFP) op_MSER uint32 = 0xB32F // FORMAT_RRD MULTIPLY AND SUBTRACT (short HFP) op_MSFI uint32 = 0xC201 // FORMAT_RIL1 MULTIPLY SINGLE IMMEDIATE (32) op_MSG uint32 = 0xE30C // FORMAT_RXY1 MULTIPLY SINGLE (64) op_MSGF uint32 = 0xE31C // FORMAT_RXY1 MULTIPLY SINGLE (64<-32) op_MSGFI uint32 = 0xC200 // FORMAT_RIL1 MULTIPLY SINGLE IMMEDIATE (64<-32) op_MSGFR uint32 = 0xB91C // FORMAT_RRE MULTIPLY SINGLE (64<-32) op_MSGR uint32 = 0xB90C // FORMAT_RRE MULTIPLY SINGLE (64) op_MSR uint32 = 0xB252 // FORMAT_RRE MULTIPLY SINGLE (32) op_MSTA uint32 = 0xB247 // FORMAT_RRE MODIFY STACKED STATE op_MSY uint32 = 0xE351 // FORMAT_RXY1 MULTIPLY SINGLE (32) op_MVC uint32 = 0xD200 // FORMAT_SS1 MOVE (character) op_MVCDK uint32 = 0xE50F // FORMAT_SSE MOVE WITH DESTINATION KEY op_MVCIN uint32 = 0xE800 // FORMAT_SS1 MOVE INVERSE op_MVCK uint32 = 0xD900 // FORMAT_SS4 MOVE WITH KEY op_MVCL uint32 = 0x0E00 // FORMAT_RR MOVE LONG op_MVCLE uint32 = 0xA800 // FORMAT_RS1 MOVE LONG EXTENDED op_MVCLU uint32 = 0xEB8E // FORMAT_RSY1 MOVE LONG UNICODE op_MVCOS uint32 = 0xC800 // FORMAT_SSF MOVE WITH OPTIONAL SPECIFICATIONS op_MVCP uint32 = 0xDA00 // FORMAT_SS4 MOVE TO PRIMARY op_MVCS uint32 = 0xDB00 // FORMAT_SS4 MOVE TO SECONDARY op_MVCSK uint32 = 0xE50E // FORMAT_SSE MOVE WITH SOURCE KEY op_MVGHI uint32 = 0xE548 // FORMAT_SIL MOVE (64<-16) op_MVHHI uint32 = 0xE544 // FORMAT_SIL MOVE (16<-16) op_MVHI uint32 = 0xE54C // FORMAT_SIL MOVE (32<-16) op_MVI uint32 = 0x9200 // FORMAT_SI MOVE (immediate) op_MVIY uint32 = 0xEB52 // FORMAT_SIY MOVE (immediate) op_MVN uint32 = 0xD100 // FORMAT_SS1 MOVE NUMERICS op_MVO uint32 = 0xF100 // FORMAT_SS2 MOVE WITH OFFSET op_MVPG uint32 = 0xB254 // FORMAT_RRE MOVE PAGE op_MVST uint32 = 0xB255 // FORMAT_RRE MOVE STRING op_MVZ uint32 = 0xD300 // FORMAT_SS1 MOVE ZONES op_MXBR uint32 = 0xB34C // FORMAT_RRE MULTIPLY (extended BFP) op_MXD uint32 = 0x6700 // FORMAT_RX1 MULTIPLY (long to extended HFP) op_MXDB uint32 = 0xED07 // FORMAT_RXE MULTIPLY (long to extended BFP) op_MXDBR uint32 = 0xB307 // FORMAT_RRE MULTIPLY (long to extended BFP) op_MXDR uint32 = 0x2700 // FORMAT_RR MULTIPLY (long to extended HFP) op_MXR uint32 = 0x2600 // FORMAT_RR MULTIPLY (extended HFP) op_MXTR uint32 = 0xB3D8 // FORMAT_RRF1 MULTIPLY (extended DFP) op_MXTRA uint32 = 0xB3D8 // FORMAT_RRF1 MULTIPLY (extended DFP) op_MY uint32 = 0xED3B // FORMAT_RXF MULTIPLY UNNORMALIZED (long to ext. HFP) op_MYH uint32 = 0xED3D // FORMAT_RXF MULTIPLY UNNORM. (long to ext. high HFP) op_MYHR uint32 = 0xB33D // FORMAT_RRD MULTIPLY UNNORM. (long to ext. high HFP) op_MYL uint32 = 0xED39 // FORMAT_RXF MULTIPLY UNNORM. (long to ext. low HFP) op_MYLR uint32 = 0xB339 // FORMAT_RRD MULTIPLY UNNORM. (long to ext. low HFP) op_MYR uint32 = 0xB33B // FORMAT_RRD MULTIPLY UNNORMALIZED (long to ext. HFP) op_N uint32 = 0x5400 // FORMAT_RX1 AND (32) op_NC uint32 = 0xD400 // FORMAT_SS1 AND (character) op_NG uint32 = 0xE380 // FORMAT_RXY1 AND (64) op_NGR uint32 = 0xB980 // FORMAT_RRE AND (64) op_NGRK uint32 = 0xB9E4 // FORMAT_RRF1 AND (64) op_NI uint32 = 0x9400 // FORMAT_SI AND (immediate) op_NIAI uint32 = 0xB2FA // FORMAT_IE NEXT INSTRUCTION ACCESS INTENT op_NIHF uint32 = 0xC00A // FORMAT_RIL1 AND IMMEDIATE (high) op_NIHH uint32 = 0xA504 // FORMAT_RI1 AND IMMEDIATE (high high) op_NIHL uint32 = 0xA505 // FORMAT_RI1 AND IMMEDIATE (high low) op_NILF uint32 = 0xC00B // FORMAT_RIL1 AND IMMEDIATE (low) op_NILH uint32 = 0xA506 // FORMAT_RI1 AND IMMEDIATE (low high) op_NILL uint32 = 0xA507 // FORMAT_RI1 AND IMMEDIATE (low low) op_NIY uint32 = 0xEB54 // FORMAT_SIY AND (immediate) op_NR uint32 = 0x1400 // FORMAT_RR AND (32) op_NRK uint32 = 0xB9F4 // FORMAT_RRF1 AND (32) op_NTSTG uint32 = 0xE325 // FORMAT_RXY1 NONTRANSACTIONAL STORE op_NY uint32 = 0xE354 // FORMAT_RXY1 AND (32) op_O uint32 = 0x5600 // FORMAT_RX1 OR (32) op_OC uint32 = 0xD600 // FORMAT_SS1 OR (character) op_OG uint32 = 0xE381 // FORMAT_RXY1 OR (64) op_OGR uint32 = 0xB981 // FORMAT_RRE OR (64) op_OGRK uint32 = 0xB9E6 // FORMAT_RRF1 OR (64) op_OI uint32 = 0x9600 // FORMAT_SI OR (immediate) op_OIHF uint32 = 0xC00C // FORMAT_RIL1 OR IMMEDIATE (high) op_OIHH uint32 = 0xA508 // FORMAT_RI1 OR IMMEDIATE (high high) op_OIHL uint32 = 0xA509 // FORMAT_RI1 OR IMMEDIATE (high low) op_OILF uint32 = 0xC00D // FORMAT_RIL1 OR IMMEDIATE (low) op_OILH uint32 = 0xA50A // FORMAT_RI1 OR IMMEDIATE (low high) op_OILL uint32 = 0xA50B // FORMAT_RI1 OR IMMEDIATE (low low) op_OIY uint32 = 0xEB56 // FORMAT_SIY OR (immediate) op_OR uint32 = 0x1600 // FORMAT_RR OR (32) op_ORK uint32 = 0xB9F6 // FORMAT_RRF1 OR (32) op_OY uint32 = 0xE356 // FORMAT_RXY1 OR (32) op_PACK uint32 = 0xF200 // FORMAT_SS2 PACK op_PALB uint32 = 0xB248 // FORMAT_RRE PURGE ALB op_PC uint32 = 0xB218 // FORMAT_S PROGRAM CALL op_PCC uint32 = 0xB92C // FORMAT_RRE PERFORM CRYPTOGRAPHIC COMPUTATION op_PCKMO uint32 = 0xB928 // FORMAT_RRE PERFORM CRYPTOGRAPHIC KEY MGMT. OPERATIONS op_PFD uint32 = 0xE336 // FORMAT_RXY2 PREFETCH DATA op_PFDRL uint32 = 0xC602 // FORMAT_RIL3 PREFETCH DATA RELATIVE LONG op_PFMF uint32 = 0xB9AF // FORMAT_RRE PERFORM FRAME MANAGEMENT FUNCTION op_PFPO uint32 = 0x010A // FORMAT_E PERFORM FLOATING-POINT OPERATION op_PGIN uint32 = 0xB22E // FORMAT_RRE PAGE IN op_PGOUT uint32 = 0xB22F // FORMAT_RRE PAGE OUT op_PKA uint32 = 0xE900 // FORMAT_SS6 PACK ASCII op_PKU uint32 = 0xE100 // FORMAT_SS6 PACK UNICODE op_PLO uint32 = 0xEE00 // FORMAT_SS5 PERFORM LOCKED OPERATION op_POPCNT uint32 = 0xB9E1 // FORMAT_RRE POPULATION COUNT op_PPA uint32 = 0xB2E8 // FORMAT_RRF3 PERFORM PROCESSOR ASSIST op_PR uint32 = 0x0101 // FORMAT_E PROGRAM RETURN op_PT uint32 = 0xB228 // FORMAT_RRE PROGRAM TRANSFER op_PTF uint32 = 0xB9A2 // FORMAT_RRE PERFORM TOPOLOGY FUNCTION op_PTFF uint32 = 0x0104 // FORMAT_E PERFORM TIMING FACILITY FUNCTION op_PTI uint32 = 0xB99E // FORMAT_RRE PROGRAM TRANSFER WITH INSTANCE op_PTLB uint32 = 0xB20D // FORMAT_S PURGE TLB op_QADTR uint32 = 0xB3F5 // FORMAT_RRF2 QUANTIZE (long DFP) op_QAXTR uint32 = 0xB3FD // FORMAT_RRF2 QUANTIZE (extended DFP) op_RCHP uint32 = 0xB23B // FORMAT_S RESET CHANNEL PATH op_RISBG uint32 = 0xEC55 // FORMAT_RIE6 ROTATE THEN INSERT SELECTED BITS op_RISBGN uint32 = 0xEC59 // FORMAT_RIE6 ROTATE THEN INSERT SELECTED BITS op_RISBHG uint32 = 0xEC5D // FORMAT_RIE6 ROTATE THEN INSERT SELECTED BITS HIGH op_RISBLG uint32 = 0xEC51 // FORMAT_RIE6 ROTATE THEN INSERT SELECTED BITS LOW op_RLL uint32 = 0xEB1D // FORMAT_RSY1 ROTATE LEFT SINGLE LOGICAL (32) op_RLLG uint32 = 0xEB1C // FORMAT_RSY1 ROTATE LEFT SINGLE LOGICAL (64) op_RNSBG uint32 = 0xEC54 // FORMAT_RIE6 ROTATE THEN AND SELECTED BITS op_ROSBG uint32 = 0xEC56 // FORMAT_RIE6 ROTATE THEN OR SELECTED BITS op_RP uint32 = 0xB277 // FORMAT_S RESUME PROGRAM op_RRBE uint32 = 0xB22A // FORMAT_RRE RESET REFERENCE BIT EXTENDED op_RRBM uint32 = 0xB9AE // FORMAT_RRE RESET REFERENCE BITS MULTIPLE op_RRDTR uint32 = 0xB3F7 // FORMAT_RRF2 REROUND (long DFP) op_RRXTR uint32 = 0xB3FF // FORMAT_RRF2 REROUND (extended DFP) op_RSCH uint32 = 0xB238 // FORMAT_S RESUME SUBCHANNEL op_RXSBG uint32 = 0xEC57 // FORMAT_RIE6 ROTATE THEN EXCLUSIVE OR SELECTED BITS op_S uint32 = 0x5B00 // FORMAT_RX1 SUBTRACT (32) op_SAC uint32 = 0xB219 // FORMAT_S SET ADDRESS SPACE CONTROL op_SACF uint32 = 0xB279 // FORMAT_S SET ADDRESS SPACE CONTROL FAST op_SAL uint32 = 0xB237 // FORMAT_S SET ADDRESS LIMIT op_SAM24 uint32 = 0x010C // FORMAT_E SET ADDRESSING MODE (24) op_SAM31 uint32 = 0x010D // FORMAT_E SET ADDRESSING MODE (31) op_SAM64 uint32 = 0x010E // FORMAT_E SET ADDRESSING MODE (64) op_SAR uint32 = 0xB24E // FORMAT_RRE SET ACCESS op_SCHM uint32 = 0xB23C // FORMAT_S SET CHANNEL MONITOR op_SCK uint32 = 0xB204 // FORMAT_S SET CLOCK op_SCKC uint32 = 0xB206 // FORMAT_S SET CLOCK COMPARATOR op_SCKPF uint32 = 0x0107 // FORMAT_E SET CLOCK PROGRAMMABLE FIELD op_SD uint32 = 0x6B00 // FORMAT_RX1 SUBTRACT NORMALIZED (long HFP) op_SDB uint32 = 0xED1B // FORMAT_RXE SUBTRACT (long BFP) op_SDBR uint32 = 0xB31B // FORMAT_RRE SUBTRACT (long BFP) op_SDR uint32 = 0x2B00 // FORMAT_RR SUBTRACT NORMALIZED (long HFP) op_SDTR uint32 = 0xB3D3 // FORMAT_RRF1 SUBTRACT (long DFP) op_SDTRA uint32 = 0xB3D3 // FORMAT_RRF1 SUBTRACT (long DFP) op_SE uint32 = 0x7B00 // FORMAT_RX1 SUBTRACT NORMALIZED (short HFP) op_SEB uint32 = 0xED0B // FORMAT_RXE SUBTRACT (short BFP) op_SEBR uint32 = 0xB30B // FORMAT_RRE SUBTRACT (short BFP) op_SER uint32 = 0x3B00 // FORMAT_RR SUBTRACT NORMALIZED (short HFP) op_SFASR uint32 = 0xB385 // FORMAT_RRE SET FPC AND SIGNAL op_SFPC uint32 = 0xB384 // FORMAT_RRE SET FPC op_SG uint32 = 0xE309 // FORMAT_RXY1 SUBTRACT (64) op_SGF uint32 = 0xE319 // FORMAT_RXY1 SUBTRACT (64<-32) op_SGFR uint32 = 0xB919 // FORMAT_RRE SUBTRACT (64<-32) op_SGR uint32 = 0xB909 // FORMAT_RRE SUBTRACT (64) op_SGRK uint32 = 0xB9E9 // FORMAT_RRF1 SUBTRACT (64) op_SH uint32 = 0x4B00 // FORMAT_RX1 SUBTRACT HALFWORD op_SHHHR uint32 = 0xB9C9 // FORMAT_RRF1 SUBTRACT HIGH (32) op_SHHLR uint32 = 0xB9D9 // FORMAT_RRF1 SUBTRACT HIGH (32) op_SHY uint32 = 0xE37B // FORMAT_RXY1 SUBTRACT HALFWORD op_SIGP uint32 = 0xAE00 // FORMAT_RS1 SIGNAL PROCESSOR op_SL uint32 = 0x5F00 // FORMAT_RX1 SUBTRACT LOGICAL (32) op_SLA uint32 = 0x8B00 // FORMAT_RS1 SHIFT LEFT SINGLE (32) op_SLAG uint32 = 0xEB0B // FORMAT_RSY1 SHIFT LEFT SINGLE (64) op_SLAK uint32 = 0xEBDD // FORMAT_RSY1 SHIFT LEFT SINGLE (32) op_SLB uint32 = 0xE399 // FORMAT_RXY1 SUBTRACT LOGICAL WITH BORROW (32) op_SLBG uint32 = 0xE389 // FORMAT_RXY1 SUBTRACT LOGICAL WITH BORROW (64) op_SLBGR uint32 = 0xB989 // FORMAT_RRE SUBTRACT LOGICAL WITH BORROW (64) op_SLBR uint32 = 0xB999 // FORMAT_RRE SUBTRACT LOGICAL WITH BORROW (32) op_SLDA uint32 = 0x8F00 // FORMAT_RS1 SHIFT LEFT DOUBLE op_SLDL uint32 = 0x8D00 // FORMAT_RS1 SHIFT LEFT DOUBLE LOGICAL op_SLDT uint32 = 0xED40 // FORMAT_RXF SHIFT SIGNIFICAND LEFT (long DFP) op_SLFI uint32 = 0xC205 // FORMAT_RIL1 SUBTRACT LOGICAL IMMEDIATE (32) op_SLG uint32 = 0xE30B // FORMAT_RXY1 SUBTRACT LOGICAL (64) op_SLGF uint32 = 0xE31B // FORMAT_RXY1 SUBTRACT LOGICAL (64<-32) op_SLGFI uint32 = 0xC204 // FORMAT_RIL1 SUBTRACT LOGICAL IMMEDIATE (64<-32) op_SLGFR uint32 = 0xB91B // FORMAT_RRE SUBTRACT LOGICAL (64<-32) op_SLGR uint32 = 0xB90B // FORMAT_RRE SUBTRACT LOGICAL (64) op_SLGRK uint32 = 0xB9EB // FORMAT_RRF1 SUBTRACT LOGICAL (64) op_SLHHHR uint32 = 0xB9CB // FORMAT_RRF1 SUBTRACT LOGICAL HIGH (32) op_SLHHLR uint32 = 0xB9DB // FORMAT_RRF1 SUBTRACT LOGICAL HIGH (32) op_SLL uint32 = 0x8900 // FORMAT_RS1 SHIFT LEFT SINGLE LOGICAL (32) op_SLLG uint32 = 0xEB0D // FORMAT_RSY1 SHIFT LEFT SINGLE LOGICAL (64) op_SLLK uint32 = 0xEBDF // FORMAT_RSY1 SHIFT LEFT SINGLE LOGICAL (32) op_SLR uint32 = 0x1F00 // FORMAT_RR SUBTRACT LOGICAL (32) op_SLRK uint32 = 0xB9FB // FORMAT_RRF1 SUBTRACT LOGICAL (32) op_SLXT uint32 = 0xED48 // FORMAT_RXF SHIFT SIGNIFICAND LEFT (extended DFP) op_SLY uint32 = 0xE35F // FORMAT_RXY1 SUBTRACT LOGICAL (32) op_SP uint32 = 0xFB00 // FORMAT_SS2 SUBTRACT DECIMAL op_SPKA uint32 = 0xB20A // FORMAT_S SET PSW KEY FROM ADDRESS op_SPM uint32 = 0x0400 // FORMAT_RR SET PROGRAM MASK op_SPT uint32 = 0xB208 // FORMAT_S SET CPU TIMER op_SPX uint32 = 0xB210 // FORMAT_S SET PREFIX op_SQD uint32 = 0xED35 // FORMAT_RXE SQUARE ROOT (long HFP) op_SQDB uint32 = 0xED15 // FORMAT_RXE SQUARE ROOT (long BFP) op_SQDBR uint32 = 0xB315 // FORMAT_RRE SQUARE ROOT (long BFP) op_SQDR uint32 = 0xB244 // FORMAT_RRE SQUARE ROOT (long HFP) op_SQE uint32 = 0xED34 // FORMAT_RXE SQUARE ROOT (short HFP) op_SQEB uint32 = 0xED14 // FORMAT_RXE SQUARE ROOT (short BFP) op_SQEBR uint32 = 0xB314 // FORMAT_RRE SQUARE ROOT (short BFP) op_SQER uint32 = 0xB245 // FORMAT_RRE SQUARE ROOT (short HFP) op_SQXBR uint32 = 0xB316 // FORMAT_RRE SQUARE ROOT (extended BFP) op_SQXR uint32 = 0xB336 // FORMAT_RRE SQUARE ROOT (extended HFP) op_SR uint32 = 0x1B00 // FORMAT_RR SUBTRACT (32) op_SRA uint32 = 0x8A00 // FORMAT_RS1 SHIFT RIGHT SINGLE (32) op_SRAG uint32 = 0xEB0A // FORMAT_RSY1 SHIFT RIGHT SINGLE (64) op_SRAK uint32 = 0xEBDC // FORMAT_RSY1 SHIFT RIGHT SINGLE (32) op_SRDA uint32 = 0x8E00 // FORMAT_RS1 SHIFT RIGHT DOUBLE op_SRDL uint32 = 0x8C00 // FORMAT_RS1 SHIFT RIGHT DOUBLE LOGICAL op_SRDT uint32 = 0xED41 // FORMAT_RXF SHIFT SIGNIFICAND RIGHT (long DFP) op_SRK uint32 = 0xB9F9 // FORMAT_RRF1 SUBTRACT (32) op_SRL uint32 = 0x8800 // FORMAT_RS1 SHIFT RIGHT SINGLE LOGICAL (32) op_SRLG uint32 = 0xEB0C // FORMAT_RSY1 SHIFT RIGHT SINGLE LOGICAL (64) op_SRLK uint32 = 0xEBDE // FORMAT_RSY1 SHIFT RIGHT SINGLE LOGICAL (32) op_SRNM uint32 = 0xB299 // FORMAT_S SET BFP ROUNDING MODE (2 bit) op_SRNMB uint32 = 0xB2B8 // FORMAT_S SET BFP ROUNDING MODE (3 bit) op_SRNMT uint32 = 0xB2B9 // FORMAT_S SET DFP ROUNDING MODE op_SRP uint32 = 0xF000 // FORMAT_SS3 SHIFT AND ROUND DECIMAL op_SRST uint32 = 0xB25E // FORMAT_RRE SEARCH STRING op_SRSTU uint32 = 0xB9BE // FORMAT_RRE SEARCH STRING UNICODE op_SRXT uint32 = 0xED49 // FORMAT_RXF SHIFT SIGNIFICAND RIGHT (extended DFP) op_SSAIR uint32 = 0xB99F // FORMAT_RRE SET SECONDARY ASN WITH INSTANCE op_SSAR uint32 = 0xB225 // FORMAT_RRE SET SECONDARY ASN op_SSCH uint32 = 0xB233 // FORMAT_S START SUBCHANNEL op_SSKE uint32 = 0xB22B // FORMAT_RRF3 SET STORAGE KEY EXTENDED op_SSM uint32 = 0x8000 // FORMAT_S SET SYSTEM MASK op_ST uint32 = 0x5000 // FORMAT_RX1 STORE (32) op_STAM uint32 = 0x9B00 // FORMAT_RS1 STORE ACCESS MULTIPLE op_STAMY uint32 = 0xEB9B // FORMAT_RSY1 STORE ACCESS MULTIPLE op_STAP uint32 = 0xB212 // FORMAT_S STORE CPU ADDRESS op_STC uint32 = 0x4200 // FORMAT_RX1 STORE CHARACTER op_STCH uint32 = 0xE3C3 // FORMAT_RXY1 STORE CHARACTER HIGH (8) op_STCK uint32 = 0xB205 // FORMAT_S STORE CLOCK op_STCKC uint32 = 0xB207 // FORMAT_S STORE CLOCK COMPARATOR op_STCKE uint32 = 0xB278 // FORMAT_S STORE CLOCK EXTENDED op_STCKF uint32 = 0xB27C // FORMAT_S STORE CLOCK FAST op_STCM uint32 = 0xBE00 // FORMAT_RS2 STORE CHARACTERS UNDER MASK (low) op_STCMH uint32 = 0xEB2C // FORMAT_RSY2 STORE CHARACTERS UNDER MASK (high) op_STCMY uint32 = 0xEB2D // FORMAT_RSY2 STORE CHARACTERS UNDER MASK (low) op_STCPS uint32 = 0xB23A // FORMAT_S STORE CHANNEL PATH STATUS op_STCRW uint32 = 0xB239 // FORMAT_S STORE CHANNEL REPORT WORD op_STCTG uint32 = 0xEB25 // FORMAT_RSY1 STORE CONTROL (64) op_STCTL uint32 = 0xB600 // FORMAT_RS1 STORE CONTROL (32) op_STCY uint32 = 0xE372 // FORMAT_RXY1 STORE CHARACTER op_STD uint32 = 0x6000 // FORMAT_RX1 STORE (long) op_STDY uint32 = 0xED67 // FORMAT_RXY1 STORE (long) op_STE uint32 = 0x7000 // FORMAT_RX1 STORE (short) op_STEY uint32 = 0xED66 // FORMAT_RXY1 STORE (short) op_STFH uint32 = 0xE3CB // FORMAT_RXY1 STORE HIGH (32) op_STFL uint32 = 0xB2B1 // FORMAT_S STORE FACILITY LIST op_STFLE uint32 = 0xB2B0 // FORMAT_S STORE FACILITY LIST EXTENDED op_STFPC uint32 = 0xB29C // FORMAT_S STORE FPC op_STG uint32 = 0xE324 // FORMAT_RXY1 STORE (64) op_STGRL uint32 = 0xC40B // FORMAT_RIL2 STORE RELATIVE LONG (64) op_STH uint32 = 0x4000 // FORMAT_RX1 STORE HALFWORD op_STHH uint32 = 0xE3C7 // FORMAT_RXY1 STORE HALFWORD HIGH (16) op_STHRL uint32 = 0xC407 // FORMAT_RIL2 STORE HALFWORD RELATIVE LONG op_STHY uint32 = 0xE370 // FORMAT_RXY1 STORE HALFWORD op_STIDP uint32 = 0xB202 // FORMAT_S STORE CPU ID op_STM uint32 = 0x9000 // FORMAT_RS1 STORE MULTIPLE (32) op_STMG uint32 = 0xEB24 // FORMAT_RSY1 STORE MULTIPLE (64) op_STMH uint32 = 0xEB26 // FORMAT_RSY1 STORE MULTIPLE HIGH op_STMY uint32 = 0xEB90 // FORMAT_RSY1 STORE MULTIPLE (32) op_STNSM uint32 = 0xAC00 // FORMAT_SI STORE THEN AND SYSTEM MASK op_STOC uint32 = 0xEBF3 // FORMAT_RSY2 STORE ON CONDITION (32) op_STOCG uint32 = 0xEBE3 // FORMAT_RSY2 STORE ON CONDITION (64) op_STOSM uint32 = 0xAD00 // FORMAT_SI STORE THEN OR SYSTEM MASK op_STPQ uint32 = 0xE38E // FORMAT_RXY1 STORE PAIR TO QUADWORD op_STPT uint32 = 0xB209 // FORMAT_S STORE CPU TIMER op_STPX uint32 = 0xB211 // FORMAT_S STORE PREFIX op_STRAG uint32 = 0xE502 // FORMAT_SSE STORE REAL ADDRESS op_STRL uint32 = 0xC40F // FORMAT_RIL2 STORE RELATIVE LONG (32) op_STRV uint32 = 0xE33E // FORMAT_RXY1 STORE REVERSED (32) op_STRVG uint32 = 0xE32F // FORMAT_RXY1 STORE REVERSED (64) op_STRVH uint32 = 0xE33F // FORMAT_RXY1 STORE REVERSED (16) op_STSCH uint32 = 0xB234 // FORMAT_S STORE SUBCHANNEL op_STSI uint32 = 0xB27D // FORMAT_S STORE SYSTEM INFORMATION op_STURA uint32 = 0xB246 // FORMAT_RRE STORE USING REAL ADDRESS (32) op_STURG uint32 = 0xB925 // FORMAT_RRE STORE USING REAL ADDRESS (64) op_STY uint32 = 0xE350 // FORMAT_RXY1 STORE (32) op_SU uint32 = 0x7F00 // FORMAT_RX1 SUBTRACT UNNORMALIZED (short HFP) op_SUR uint32 = 0x3F00 // FORMAT_RR SUBTRACT UNNORMALIZED (short HFP) op_SVC uint32 = 0x0A00 // FORMAT_I SUPERVISOR CALL op_SW uint32 = 0x6F00 // FORMAT_RX1 SUBTRACT UNNORMALIZED (long HFP) op_SWR uint32 = 0x2F00 // FORMAT_RR SUBTRACT UNNORMALIZED (long HFP) op_SXBR uint32 = 0xB34B // FORMAT_RRE SUBTRACT (extended BFP) op_SXR uint32 = 0x3700 // FORMAT_RR SUBTRACT NORMALIZED (extended HFP) op_SXTR uint32 = 0xB3DB // FORMAT_RRF1 SUBTRACT (extended DFP) op_SXTRA uint32 = 0xB3DB // FORMAT_RRF1 SUBTRACT (extended DFP) op_SY uint32 = 0xE35B // FORMAT_RXY1 SUBTRACT (32) op_TABORT uint32 = 0xB2FC // FORMAT_S TRANSACTION ABORT op_TAM uint32 = 0x010B // FORMAT_E TEST ADDRESSING MODE op_TAR uint32 = 0xB24C // FORMAT_RRE TEST ACCESS op_TB uint32 = 0xB22C // FORMAT_RRE TEST BLOCK op_TBDR uint32 = 0xB351 // FORMAT_RRF5 CONVERT HFP TO BFP (long) op_TBEDR uint32 = 0xB350 // FORMAT_RRF5 CONVERT HFP TO BFP (long to short) op_TBEGIN uint32 = 0xE560 // FORMAT_SIL TRANSACTION BEGIN op_TBEGINC uint32 = 0xE561 // FORMAT_SIL TRANSACTION BEGIN op_TCDB uint32 = 0xED11 // FORMAT_RXE TEST DATA CLASS (long BFP) op_TCEB uint32 = 0xED10 // FORMAT_RXE TEST DATA CLASS (short BFP) op_TCXB uint32 = 0xED12 // FORMAT_RXE TEST DATA CLASS (extended BFP) op_TDCDT uint32 = 0xED54 // FORMAT_RXE TEST DATA CLASS (long DFP) op_TDCET uint32 = 0xED50 // FORMAT_RXE TEST DATA CLASS (short DFP) op_TDCXT uint32 = 0xED58 // FORMAT_RXE TEST DATA CLASS (extended DFP) op_TDGDT uint32 = 0xED55 // FORMAT_RXE TEST DATA GROUP (long DFP) op_TDGET uint32 = 0xED51 // FORMAT_RXE TEST DATA GROUP (short DFP) op_TDGXT uint32 = 0xED59 // FORMAT_RXE TEST DATA GROUP (extended DFP) op_TEND uint32 = 0xB2F8 // FORMAT_S TRANSACTION END op_THDER uint32 = 0xB358 // FORMAT_RRE CONVERT BFP TO HFP (short to long) op_THDR uint32 = 0xB359 // FORMAT_RRE CONVERT BFP TO HFP (long) op_TM uint32 = 0x9100 // FORMAT_SI TEST UNDER MASK op_TMH uint32 = 0xA700 // FORMAT_RI1 TEST UNDER MASK HIGH op_TMHH uint32 = 0xA702 // FORMAT_RI1 TEST UNDER MASK (high high) op_TMHL uint32 = 0xA703 // FORMAT_RI1 TEST UNDER MASK (high low) op_TML uint32 = 0xA701 // FORMAT_RI1 TEST UNDER MASK LOW op_TMLH uint32 = 0xA700 // FORMAT_RI1 TEST UNDER MASK (low high) op_TMLL uint32 = 0xA701 // FORMAT_RI1 TEST UNDER MASK (low low) op_TMY uint32 = 0xEB51 // FORMAT_SIY TEST UNDER MASK op_TP uint32 = 0xEBC0 // FORMAT_RSL TEST DECIMAL op_TPI uint32 = 0xB236 // FORMAT_S TEST PENDING INTERRUPTION op_TPROT uint32 = 0xE501 // FORMAT_SSE TEST PROTECTION op_TR uint32 = 0xDC00 // FORMAT_SS1 TRANSLATE op_TRACE uint32 = 0x9900 // FORMAT_RS1 TRACE (32) op_TRACG uint32 = 0xEB0F // FORMAT_RSY1 TRACE (64) op_TRAP2 uint32 = 0x01FF // FORMAT_E TRAP op_TRAP4 uint32 = 0xB2FF // FORMAT_S TRAP op_TRE uint32 = 0xB2A5 // FORMAT_RRE TRANSLATE EXTENDED op_TROO uint32 = 0xB993 // FORMAT_RRF3 TRANSLATE ONE TO ONE op_TROT uint32 = 0xB992 // FORMAT_RRF3 TRANSLATE ONE TO TWO op_TRT uint32 = 0xDD00 // FORMAT_SS1 TRANSLATE AND TEST op_TRTE uint32 = 0xB9BF // FORMAT_RRF3 TRANSLATE AND TEST EXTENDED op_TRTO uint32 = 0xB991 // FORMAT_RRF3 TRANSLATE TWO TO ONE op_TRTR uint32 = 0xD000 // FORMAT_SS1 TRANSLATE AND TEST REVERSE op_TRTRE uint32 = 0xB9BD // FORMAT_RRF3 TRANSLATE AND TEST REVERSE EXTENDED op_TRTT uint32 = 0xB990 // FORMAT_RRF3 TRANSLATE TWO TO TWO op_TS uint32 = 0x9300 // FORMAT_S TEST AND SET op_TSCH uint32 = 0xB235 // FORMAT_S TEST SUBCHANNEL op_UNPK uint32 = 0xF300 // FORMAT_SS2 UNPACK op_UNPKA uint32 = 0xEA00 // FORMAT_SS1 UNPACK ASCII op_UNPKU uint32 = 0xE200 // FORMAT_SS1 UNPACK UNICODE op_UPT uint32 = 0x0102 // FORMAT_E UPDATE TREE op_X uint32 = 0x5700 // FORMAT_RX1 EXCLUSIVE OR (32) op_XC uint32 = 0xD700 // FORMAT_SS1 EXCLUSIVE OR (character) op_XG uint32 = 0xE382 // FORMAT_RXY1 EXCLUSIVE OR (64) op_XGR uint32 = 0xB982 // FORMAT_RRE EXCLUSIVE OR (64) op_XGRK uint32 = 0xB9E7 // FORMAT_RRF1 EXCLUSIVE OR (64) op_XI uint32 = 0x9700 // FORMAT_SI EXCLUSIVE OR (immediate) op_XIHF uint32 = 0xC006 // FORMAT_RIL1 EXCLUSIVE OR IMMEDIATE (high) op_XILF uint32 = 0xC007 // FORMAT_RIL1 EXCLUSIVE OR IMMEDIATE (low) op_XIY uint32 = 0xEB57 // FORMAT_SIY EXCLUSIVE OR (immediate) op_XR uint32 = 0x1700 // FORMAT_RR EXCLUSIVE OR (32) op_XRK uint32 = 0xB9F7 // FORMAT_RRF1 EXCLUSIVE OR (32) op_XSCH uint32 = 0xB276 // FORMAT_S CANCEL SUBCHANNEL op_XY uint32 = 0xE357 // FORMAT_RXY1 EXCLUSIVE OR (32) op_ZAP uint32 = 0xF800 // FORMAT_SS2 ZERO AND ADD op_BRRK uint32 = 0x0001 // FORMAT_E BREAKPOINT // added in z13 op_CXPT uint32 = 0xEDAF // RSL-b CONVERT FROM PACKED (to extended DFP) op_CDPT uint32 = 0xEDAE // RSL-b CONVERT FROM PACKED (to long DFP) op_CPXT uint32 = 0xEDAD // RSL-b CONVERT TO PACKED (from extended DFP) op_CPDT uint32 = 0xEDAC // RSL-b CONVERT TO PACKED (from long DFP) op_LZRF uint32 = 0xE33B // RXY-a LOAD AND ZERO RIGHTMOST BYTE (32) op_LZRG uint32 = 0xE32A // RXY-a LOAD AND ZERO RIGHTMOST BYTE (64) op_LCCB uint32 = 0xE727 // RXE LOAD COUNT TO BLOCK BOUNDARY op_LOCHHI uint32 = 0xEC4E // RIE-g LOAD HALFWORD HIGH IMMEDIATE ON CONDITION (32←16) op_LOCHI uint32 = 0xEC42 // RIE-g LOAD HALFWORD IMMEDIATE ON CONDITION (32←16) op_LOCGHI uint32 = 0xEC46 // RIE-g LOAD HALFWORD IMMEDIATE ON CONDITION (64←16) op_LOCFH uint32 = 0xEBE0 // RSY-b LOAD HIGH ON CONDITION (32) op_LOCFHR uint32 = 0xB9E0 // RRF-c LOAD HIGH ON CONDITION (32) op_LLZRGF uint32 = 0xE33A // RXY-a LOAD LOGICAL AND ZERO RIGHTMOST BYTE (64←32) op_STOCFH uint32 = 0xEBE1 // RSY-b STORE HIGH ON CONDITION op_VA uint32 = 0xE7F3 // VRR-c VECTOR ADD op_VACC uint32 = 0xE7F1 // VRR-c VECTOR ADD COMPUTE CARRY op_VAC uint32 = 0xE7BB // VRR-d VECTOR ADD WITH CARRY op_VACCC uint32 = 0xE7B9 // VRR-d VECTOR ADD WITH CARRY COMPUTE CARRY op_VN uint32 = 0xE768 // VRR-c VECTOR AND op_VNC uint32 = 0xE769 // VRR-c VECTOR AND WITH COMPLEMENT op_VAVG uint32 = 0xE7F2 // VRR-c VECTOR AVERAGE op_VAVGL uint32 = 0xE7F0 // VRR-c VECTOR AVERAGE LOGICAL op_VCKSM uint32 = 0xE766 // VRR-c VECTOR CHECKSUM op_VCEQ uint32 = 0xE7F8 // VRR-b VECTOR COMPARE EQUAL op_VCH uint32 = 0xE7FB // VRR-b VECTOR COMPARE HIGH op_VCHL uint32 = 0xE7F9 // VRR-b VECTOR COMPARE HIGH LOGICAL op_VCLZ uint32 = 0xE753 // VRR-a VECTOR COUNT LEADING ZEROS op_VCTZ uint32 = 0xE752 // VRR-a VECTOR COUNT TRAILING ZEROS op_VEC uint32 = 0xE7DB // VRR-a VECTOR ELEMENT COMPARE op_VECL uint32 = 0xE7D9 // VRR-a VECTOR ELEMENT COMPARE LOGICAL op_VERIM uint32 = 0xE772 // VRI-d VECTOR ELEMENT ROTATE AND INSERT UNDER MASK op_VERLL uint32 = 0xE733 // VRS-a VECTOR ELEMENT ROTATE LEFT LOGICAL op_VERLLV uint32 = 0xE773 // VRR-c VECTOR ELEMENT ROTATE LEFT LOGICAL op_VESLV uint32 = 0xE770 // VRR-c VECTOR ELEMENT SHIFT LEFT op_VESL uint32 = 0xE730 // VRS-a VECTOR ELEMENT SHIFT LEFT op_VESRA uint32 = 0xE73A // VRS-a VECTOR ELEMENT SHIFT RIGHT ARITHMETIC op_VESRAV uint32 = 0xE77A // VRR-c VECTOR ELEMENT SHIFT RIGHT ARITHMETIC op_VESRL uint32 = 0xE738 // VRS-a VECTOR ELEMENT SHIFT RIGHT LOGICAL op_VESRLV uint32 = 0xE778 // VRR-c VECTOR ELEMENT SHIFT RIGHT LOGICAL op_VX uint32 = 0xE76D // VRR-c VECTOR EXCLUSIVE OR op_VFAE uint32 = 0xE782 // VRR-b VECTOR FIND ANY ELEMENT EQUAL op_VFEE uint32 = 0xE780 // VRR-b VECTOR FIND ELEMENT EQUAL op_VFENE uint32 = 0xE781 // VRR-b VECTOR FIND ELEMENT NOT EQUAL op_VFA uint32 = 0xE7E3 // VRR-c VECTOR FP ADD op_WFK uint32 = 0xE7CA // VRR-a VECTOR FP COMPARE AND SIGNAL SCALAR op_VFCE uint32 = 0xE7E8 // VRR-c VECTOR FP COMPARE EQUAL op_VFCH uint32 = 0xE7EB // VRR-c VECTOR FP COMPARE HIGH op_VFCHE uint32 = 0xE7EA // VRR-c VECTOR FP COMPARE HIGH OR EQUAL op_WFC uint32 = 0xE7CB // VRR-a VECTOR FP COMPARE SCALAR op_VCDG uint32 = 0xE7C3 // VRR-a VECTOR FP CONVERT FROM FIXED 64-BIT op_VCDLG uint32 = 0xE7C1 // VRR-a VECTOR FP CONVERT FROM LOGICAL 64-BIT op_VCGD uint32 = 0xE7C2 // VRR-a VECTOR FP CONVERT TO FIXED 64-BIT op_VCLGD uint32 = 0xE7C0 // VRR-a VECTOR FP CONVERT TO LOGICAL 64-BIT op_VFD uint32 = 0xE7E5 // VRR-c VECTOR FP DIVIDE op_VLDE uint32 = 0xE7C4 // VRR-a VECTOR FP LOAD LENGTHENED op_VLED uint32 = 0xE7C5 // VRR-a VECTOR FP LOAD ROUNDED op_VFM uint32 = 0xE7E7 // VRR-c VECTOR FP MULTIPLY op_VFMA uint32 = 0xE78F // VRR-e VECTOR FP MULTIPLY AND ADD op_VFMS uint32 = 0xE78E // VRR-e VECTOR FP MULTIPLY AND SUBTRACT op_VFPSO uint32 = 0xE7CC // VRR-a VECTOR FP PERFORM SIGN OPERATION op_VFSQ uint32 = 0xE7CE // VRR-a VECTOR FP SQUARE ROOT op_VFS uint32 = 0xE7E2 // VRR-c VECTOR FP SUBTRACT op_VFTCI uint32 = 0xE74A // VRI-e VECTOR FP TEST DATA CLASS IMMEDIATE op_VGFM uint32 = 0xE7B4 // VRR-c VECTOR GALOIS FIELD MULTIPLY SUM op_VGFMA uint32 = 0xE7BC // VRR-d VECTOR GALOIS FIELD MULTIPLY SUM AND ACCUMULATE op_VGEF uint32 = 0xE713 // VRV VECTOR GATHER ELEMENT (32) op_VGEG uint32 = 0xE712 // VRV VECTOR GATHER ELEMENT (64) op_VGBM uint32 = 0xE744 // VRI-a VECTOR GENERATE BYTE MASK op_VGM uint32 = 0xE746 // VRI-b VECTOR GENERATE MASK op_VISTR uint32 = 0xE75C // VRR-a VECTOR ISOLATE STRING op_VL uint32 = 0xE706 // VRX VECTOR LOAD op_VLR uint32 = 0xE756 // VRR-a VECTOR LOAD op_VLREP uint32 = 0xE705 // VRX VECTOR LOAD AND REPLICATE op_VLC uint32 = 0xE7DE // VRR-a VECTOR LOAD COMPLEMENT op_VLEH uint32 = 0xE701 // VRX VECTOR LOAD ELEMENT (16) op_VLEF uint32 = 0xE703 // VRX VECTOR LOAD ELEMENT (32) op_VLEG uint32 = 0xE702 // VRX VECTOR LOAD ELEMENT (64) op_VLEB uint32 = 0xE700 // VRX VECTOR LOAD ELEMENT (8) op_VLEIH uint32 = 0xE741 // VRI-a VECTOR LOAD ELEMENT IMMEDIATE (16) op_VLEIF uint32 = 0xE743 // VRI-a VECTOR LOAD ELEMENT IMMEDIATE (32) op_VLEIG uint32 = 0xE742 // VRI-a VECTOR LOAD ELEMENT IMMEDIATE (64) op_VLEIB uint32 = 0xE740 // VRI-a VECTOR LOAD ELEMENT IMMEDIATE (8) op_VFI uint32 = 0xE7C7 // VRR-a VECTOR LOAD FP INTEGER op_VLGV uint32 = 0xE721 // VRS-c VECTOR LOAD GR FROM VR ELEMENT op_VLLEZ uint32 = 0xE704 // VRX VECTOR LOAD LOGICAL ELEMENT AND ZERO op_VLM uint32 = 0xE736 // VRS-a VECTOR LOAD MULTIPLE op_VLP uint32 = 0xE7DF // VRR-a VECTOR LOAD POSITIVE op_VLBB uint32 = 0xE707 // VRX VECTOR LOAD TO BLOCK BOUNDARY op_VLVG uint32 = 0xE722 // VRS-b VECTOR LOAD VR ELEMENT FROM GR op_VLVGP uint32 = 0xE762 // VRR-f VECTOR LOAD VR FROM GRS DISJOINT op_VLL uint32 = 0xE737 // VRS-b VECTOR LOAD WITH LENGTH op_VMX uint32 = 0xE7FF // VRR-c VECTOR MAXIMUM op_VMXL uint32 = 0xE7FD // VRR-c VECTOR MAXIMUM LOGICAL op_VMRH uint32 = 0xE761 // VRR-c VECTOR MERGE HIGH op_VMRL uint32 = 0xE760 // VRR-c VECTOR MERGE LOW op_VMN uint32 = 0xE7FE // VRR-c VECTOR MINIMUM op_VMNL uint32 = 0xE7FC // VRR-c VECTOR MINIMUM LOGICAL op_VMAE uint32 = 0xE7AE // VRR-d VECTOR MULTIPLY AND ADD EVEN op_VMAH uint32 = 0xE7AB // VRR-d VECTOR MULTIPLY AND ADD HIGH op_VMALE uint32 = 0xE7AC // VRR-d VECTOR MULTIPLY AND ADD LOGICAL EVEN op_VMALH uint32 = 0xE7A9 // VRR-d VECTOR MULTIPLY AND ADD LOGICAL HIGH op_VMALO uint32 = 0xE7AD // VRR-d VECTOR MULTIPLY AND ADD LOGICAL ODD op_VMAL uint32 = 0xE7AA // VRR-d VECTOR MULTIPLY AND ADD LOW op_VMAO uint32 = 0xE7AF // VRR-d VECTOR MULTIPLY AND ADD ODD op_VME uint32 = 0xE7A6 // VRR-c VECTOR MULTIPLY EVEN op_VMH uint32 = 0xE7A3 // VRR-c VECTOR MULTIPLY HIGH op_VMLE uint32 = 0xE7A4 // VRR-c VECTOR MULTIPLY EVEN LOGICAL op_VMLH uint32 = 0xE7A1 // VRR-c VECTOR MULTIPLY HIGH LOGICAL op_VMLO uint32 = 0xE7A5 // VRR-c VECTOR MULTIPLY ODD LOGICAL op_VML uint32 = 0xE7A2 // VRR-c VECTOR MULTIPLY LOW op_VMO uint32 = 0xE7A7 // VRR-c VECTOR MULTIPLY ODD op_VNO uint32 = 0xE76B // VRR-c VECTOR NOR op_VO uint32 = 0xE76A // VRR-c VECTOR OR op_VPK uint32 = 0xE794 // VRR-c VECTOR PACK op_VPKLS uint32 = 0xE795 // VRR-b VECTOR PACK LOGICAL SATURATE op_VPKS uint32 = 0xE797 // VRR-b VECTOR PACK SATURATE op_VPERM uint32 = 0xE78C // VRR-e VECTOR PERMUTE op_VPDI uint32 = 0xE784 // VRR-c VECTOR PERMUTE DOUBLEWORD IMMEDIATE op_VPOPCT uint32 = 0xE750 // VRR-a VECTOR POPULATION COUNT op_VREP uint32 = 0xE74D // VRI-c VECTOR REPLICATE op_VREPI uint32 = 0xE745 // VRI-a VECTOR REPLICATE IMMEDIATE op_VSCEF uint32 = 0xE71B // VRV VECTOR SCATTER ELEMENT (32) op_VSCEG uint32 = 0xE71A // VRV VECTOR SCATTER ELEMENT (64) op_VSEL uint32 = 0xE78D // VRR-e VECTOR SELECT op_VSL uint32 = 0xE774 // VRR-c VECTOR SHIFT LEFT op_VSLB uint32 = 0xE775 // VRR-c VECTOR SHIFT LEFT BY BYTE op_VSLDB uint32 = 0xE777 // VRI-d VECTOR SHIFT LEFT DOUBLE BY BYTE op_VSRA uint32 = 0xE77E // VRR-c VECTOR SHIFT RIGHT ARITHMETIC op_VSRAB uint32 = 0xE77F // VRR-c VECTOR SHIFT RIGHT ARITHMETIC BY BYTE op_VSRL uint32 = 0xE77C // VRR-c VECTOR SHIFT RIGHT LOGICAL op_VSRLB uint32 = 0xE77D // VRR-c VECTOR SHIFT RIGHT LOGICAL BY BYTE op_VSEG uint32 = 0xE75F // VRR-a VECTOR SIGN EXTEND TO DOUBLEWORD op_VST uint32 = 0xE70E // VRX VECTOR STORE op_VSTEH uint32 = 0xE709 // VRX VECTOR STORE ELEMENT (16) op_VSTEF uint32 = 0xE70B // VRX VECTOR STORE ELEMENT (32) op_VSTEG uint32 = 0xE70A // VRX VECTOR STORE ELEMENT (64) op_VSTEB uint32 = 0xE708 // VRX VECTOR STORE ELEMENT (8) op_VSTM uint32 = 0xE73E // VRS-a VECTOR STORE MULTIPLE op_VSTL uint32 = 0xE73F // VRS-b VECTOR STORE WITH LENGTH op_VSTRC uint32 = 0xE78A // VRR-d VECTOR STRING RANGE COMPARE op_VS uint32 = 0xE7F7 // VRR-c VECTOR SUBTRACT op_VSCBI uint32 = 0xE7F5 // VRR-c VECTOR SUBTRACT COMPUTE BORROW INDICATION op_VSBCBI uint32 = 0xE7BD // VRR-d VECTOR SUBTRACT WITH BORROW COMPUTE BORROW INDICATION op_VSBI uint32 = 0xE7BF // VRR-d VECTOR SUBTRACT WITH BORROW INDICATION op_VSUMG uint32 = 0xE765 // VRR-c VECTOR SUM ACROSS DOUBLEWORD op_VSUMQ uint32 = 0xE767 // VRR-c VECTOR SUM ACROSS QUADWORD op_VSUM uint32 = 0xE764 // VRR-c VECTOR SUM ACROSS WORD op_VTM uint32 = 0xE7D8 // VRR-a VECTOR TEST UNDER MASK op_VUPH uint32 = 0xE7D7 // VRR-a VECTOR UNPACK HIGH op_VUPLH uint32 = 0xE7D5 // VRR-a VECTOR UNPACK LOGICAL HIGH op_VUPLL uint32 = 0xE7D4 // VRR-a VECTOR UNPACK LOGICAL LOW op_VUPL uint32 = 0xE7D6 // VRR-a VECTOR UNPACK LOW op_VMSL uint32 = 0xE7B8 // VRR-d VECTOR MULTIPLY SUM LOGICAL // added in z15 op_KDSA uint32 = 0xB93A // FORMAT_RRE COMPUTE DIGITAL SIGNATURE AUTHENTICATION (KDSA) ) func oclass(a *obj.Addr) int { return int(a.Class) - 1 } // Add a relocation for the immediate in a RIL style instruction. // The addend will be adjusted as required. func (c *ctxtz) addrilreloc(sym *obj.LSym, add int64) { if sym == nil { c.ctxt.Diag("require symbol to apply relocation") } offset := int64(2) // relocation offset from start of instruction c.cursym.AddRel(c.ctxt, obj.Reloc{ Type: objabi.R_PCRELDBL, Off: int32(c.pc + offset), Siz: 4, Sym: sym, Add: add + offset + 4, }) } func (c *ctxtz) addrilrelocoffset(sym *obj.LSym, add, offset int64) { if sym == nil { c.ctxt.Diag("require symbol to apply relocation") } offset += int64(2) // relocation offset from start of instruction c.cursym.AddRel(c.ctxt, obj.Reloc{ Type: objabi.R_PCRELDBL, Off: int32(c.pc + offset), Siz: 4, Sym: sym, Add: add + offset + 4, }) } // Add a CALL relocation for the immediate in a RIL style instruction. // The addend will be adjusted as required. func (c *ctxtz) addcallreloc(sym *obj.LSym, add int64) { if sym == nil { c.ctxt.Diag("require symbol to apply relocation") } offset := int64(2) // relocation offset from start of instruction c.cursym.AddRel(c.ctxt, obj.Reloc{ Type: objabi.R_CALL, Off: int32(c.pc + offset), Siz: 4, Sym: sym, Add: add + offset + int64(4), }) } func (c *ctxtz) branchMask(p *obj.Prog) CCMask { switch p.As { case ABRC, ALOCR, ALOCGR, ACRJ, ACGRJ, ACIJ, ACGIJ, ACLRJ, ACLGRJ, ACLIJ, ACLGIJ: return CCMask(p.From.Offset) case ABEQ, ACMPBEQ, ACMPUBEQ, AMOVDEQ: return Equal case ABGE, ACMPBGE, ACMPUBGE, AMOVDGE: return GreaterOrEqual case ABGT, ACMPBGT, ACMPUBGT, AMOVDGT: return Greater case ABLE, ACMPBLE, ACMPUBLE, AMOVDLE: return LessOrEqual case ABLT, ACMPBLT, ACMPUBLT, AMOVDLT: return Less case ABNE, ACMPBNE, ACMPUBNE, AMOVDNE: return NotEqual case ABLEU: // LE or unordered return NotGreater case ABLTU: // LT or unordered return LessOrUnordered case ABVC: return Never // needs extra instruction case ABVS: return Unordered } c.ctxt.Diag("unknown conditional branch %v", p.As) return Always } func regtmp(p *obj.Prog) uint32 { p.Mark |= USETMP return REGTMP } func (c *ctxtz) asmout(p *obj.Prog, asm *[]byte) { o := c.oplook(p) if o == nil { return } // If REGTMP is used in generated code, we need to set USETMP on p.Mark. // So we use regtmp(p) for REGTMP. switch o.i { default: c.ctxt.Diag("unknown index %d", o.i) case 0: // PSEUDO OPS break case 1: // mov reg reg switch p.As { default: c.ctxt.Diag("unhandled operation: %v", p.As) case AMOVD: zRRE(op_LGR, uint32(p.To.Reg), uint32(p.From.Reg), asm) // sign extend case AMOVW: zRRE(op_LGFR, uint32(p.To.Reg), uint32(p.From.Reg), asm) case AMOVH: zRRE(op_LGHR, uint32(p.To.Reg), uint32(p.From.Reg), asm) case AMOVB: zRRE(op_LGBR, uint32(p.To.Reg), uint32(p.From.Reg), asm) // zero extend case AMOVWZ: zRRE(op_LLGFR, uint32(p.To.Reg), uint32(p.From.Reg), asm) case AMOVHZ: zRRE(op_LLGHR, uint32(p.To.Reg), uint32(p.From.Reg), asm) case AMOVBZ: zRRE(op_LLGCR, uint32(p.To.Reg), uint32(p.From.Reg), asm) // reverse bytes case AMOVDBR: zRRE(op_LRVGR, uint32(p.To.Reg), uint32(p.From.Reg), asm) case AMOVWBR: zRRE(op_LRVR, uint32(p.To.Reg), uint32(p.From.Reg), asm) // floating point case AFMOVD, AFMOVS: zRR(op_LDR, uint32(p.To.Reg), uint32(p.From.Reg), asm) } case 2: // arithmetic op reg [reg] reg r := p.Reg if r == 0 { r = p.To.Reg } var opcode uint32 switch p.As { default: c.ctxt.Diag("invalid opcode") case AADD: opcode = op_AGRK case AADDC: opcode = op_ALGRK case AADDE: opcode = op_ALCGR case AADDW: opcode = op_ARK case AMULLW: opcode = op_MSGFR case AMULLD: opcode = op_MSGR case ADIVW, AMODW: opcode = op_DSGFR case ADIVWU, AMODWU: opcode = op_DLR case ADIVD, AMODD: opcode = op_DSGR case ADIVDU, AMODDU: opcode = op_DLGR } switch p.As { default: case AADD, AADDC, AADDW: if p.As == AADDW && r == p.To.Reg { zRR(op_AR, uint32(p.To.Reg), uint32(p.From.Reg), asm) } else { zRRF(opcode, uint32(p.From.Reg), 0, uint32(p.To.Reg), uint32(r), asm) } case AADDE, AMULLW, AMULLD: if r == p.To.Reg { zRRE(opcode, uint32(p.To.Reg), uint32(p.From.Reg), asm) } else if p.From.Reg == p.To.Reg { zRRE(opcode, uint32(p.To.Reg), uint32(r), asm) } else { zRRE(op_LGR, uint32(p.To.Reg), uint32(r), asm) zRRE(opcode, uint32(p.To.Reg), uint32(p.From.Reg), asm) } case ADIVW, ADIVWU, ADIVD, ADIVDU: if p.As == ADIVWU || p.As == ADIVDU { zRI(op_LGHI, regtmp(p), 0, asm) } zRRE(op_LGR, REGTMP2, uint32(r), asm) zRRE(opcode, regtmp(p), uint32(p.From.Reg), asm) zRRE(op_LGR, uint32(p.To.Reg), REGTMP2, asm) case AMODW, AMODWU, AMODD, AMODDU: if p.As == AMODWU || p.As == AMODDU { zRI(op_LGHI, regtmp(p), 0, asm) } zRRE(op_LGR, REGTMP2, uint32(r), asm) zRRE(opcode, regtmp(p), uint32(p.From.Reg), asm) zRRE(op_LGR, uint32(p.To.Reg), regtmp(p), asm) } case 3: // mov $constant reg v := c.vregoff(&p.From) switch p.As { case AMOVBZ: v = int64(uint8(v)) case AMOVHZ: v = int64(uint16(v)) case AMOVWZ: v = int64(uint32(v)) case AMOVB: v = int64(int8(v)) case AMOVH: v = int64(int16(v)) case AMOVW: v = int64(int32(v)) } if int64(int16(v)) == v { zRI(op_LGHI, uint32(p.To.Reg), uint32(v), asm) } else if v&0xffff0000 == v { zRI(op_LLILH, uint32(p.To.Reg), uint32(v>>16), asm) } else if v&0xffff00000000 == v { zRI(op_LLIHL, uint32(p.To.Reg), uint32(v>>32), asm) } else if uint64(v)&0xffff000000000000 == uint64(v) { zRI(op_LLIHH, uint32(p.To.Reg), uint32(v>>48), asm) } else if int64(int32(v)) == v { zRIL(_a, op_LGFI, uint32(p.To.Reg), uint32(v), asm) } else if int64(uint32(v)) == v { zRIL(_a, op_LLILF, uint32(p.To.Reg), uint32(v), asm) } else if uint64(v)&0xffffffff00000000 == uint64(v) { zRIL(_a, op_LLIHF, uint32(p.To.Reg), uint32(v>>32), asm) } else { zRIL(_a, op_LLILF, uint32(p.To.Reg), uint32(v), asm) zRIL(_a, op_IIHF, uint32(p.To.Reg), uint32(v>>32), asm) } case 4: // multiply high (a*b)>>64 r := p.Reg if r == 0 { r = p.To.Reg } zRRE(op_LGR, REGTMP2, uint32(r), asm) zRRE(op_MLGR, regtmp(p), uint32(p.From.Reg), asm) switch p.As { case AMULHDU: // Unsigned: move result into correct register. zRRE(op_LGR, uint32(p.To.Reg), regtmp(p), asm) case AMULHD: // Signed: need to convert result. // See Hacker's Delight 8-3. zRSY(op_SRAG, REGTMP2, uint32(p.From.Reg), 0, 63, asm) zRRE(op_NGR, REGTMP2, uint32(r), asm) zRRE(op_SGR, regtmp(p), REGTMP2, asm) zRSY(op_SRAG, REGTMP2, uint32(r), 0, 63, asm) zRRE(op_NGR, REGTMP2, uint32(p.From.Reg), asm) zRRF(op_SGRK, REGTMP2, 0, uint32(p.To.Reg), regtmp(p), asm) } case 5: // syscall zI(op_SVC, 0, asm) case 6: // logical op reg [reg] reg var oprr, oprre, oprrf uint32 switch p.As { case AAND: oprre = op_NGR oprrf = op_NGRK case AANDW: oprr = op_NR oprrf = op_NRK case AOR: oprre = op_OGR oprrf = op_OGRK case AORW: oprr = op_OR oprrf = op_ORK case AXOR: oprre = op_XGR oprrf = op_XGRK case AXORW: oprr = op_XR oprrf = op_XRK } if p.Reg == 0 { if oprr != 0 { zRR(oprr, uint32(p.To.Reg), uint32(p.From.Reg), asm) } else { zRRE(oprre, uint32(p.To.Reg), uint32(p.From.Reg), asm) } } else { zRRF(oprrf, uint32(p.Reg), 0, uint32(p.To.Reg), uint32(p.From.Reg), asm) } case 7: // shift/rotate reg [reg] reg d2 := c.vregoff(&p.From) b2 := p.From.Reg r3 := p.Reg if r3 == 0 { r3 = p.To.Reg } r1 := p.To.Reg var opcode uint32 switch p.As { default: case ASLD: opcode = op_SLLG case ASRD: opcode = op_SRLG case ASLW: opcode = op_SLLK case ASRW: opcode = op_SRLK case ARLL: opcode = op_RLL case ARLLG: opcode = op_RLLG case ASRAW: opcode = op_SRAK case ASRAD: opcode = op_SRAG } zRSY(opcode, uint32(r1), uint32(r3), uint32(b2), uint32(d2), asm) case 8: // find leftmost one if p.To.Reg&1 != 0 { c.ctxt.Diag("target must be an even-numbered register") } // FLOGR also writes a mask to p.To.Reg+1. zRRE(op_FLOGR, uint32(p.To.Reg), uint32(p.From.Reg), asm) case 9: // population count zRRE(op_POPCNT, uint32(p.To.Reg), uint32(p.From.Reg), asm) case 10: // subtract reg [reg] reg r := int(p.Reg) switch p.As { default: case ASUB: if r == 0 { zRRE(op_SGR, uint32(p.To.Reg), uint32(p.From.Reg), asm) } else { zRRF(op_SGRK, uint32(p.From.Reg), 0, uint32(p.To.Reg), uint32(r), asm) } case ASUBC: if r == 0 { zRRE(op_SLGR, uint32(p.To.Reg), uint32(p.From.Reg), asm) } else { zRRF(op_SLGRK, uint32(p.From.Reg), 0, uint32(p.To.Reg), uint32(r), asm) } case ASUBE: if r == 0 { r = int(p.To.Reg) } if r == int(p.To.Reg) { zRRE(op_SLBGR, uint32(p.To.Reg), uint32(p.From.Reg), asm) } else if p.From.Reg == p.To.Reg { zRRE(op_LGR, regtmp(p), uint32(p.From.Reg), asm) zRRE(op_LGR, uint32(p.To.Reg), uint32(r), asm) zRRE(op_SLBGR, uint32(p.To.Reg), regtmp(p), asm) } else { zRRE(op_LGR, uint32(p.To.Reg), uint32(r), asm) zRRE(op_SLBGR, uint32(p.To.Reg), uint32(p.From.Reg), asm) } case ASUBW: if r == 0 { zRR(op_SR, uint32(p.To.Reg), uint32(p.From.Reg), asm) } else { zRRF(op_SRK, uint32(p.From.Reg), 0, uint32(p.To.Reg), uint32(r), asm) } } case 11: // br/bl v := int32(0) if p.To.Target() != nil { v = int32((p.To.Target().Pc - p.Pc) >> 1) } if p.As == ABR && p.To.Sym == nil && int32(int16(v)) == v { zRI(op_BRC, 0xF, uint32(v), asm) } else { if p.As == ABL { zRIL(_b, op_BRASL, uint32(REG_LR), uint32(v), asm) } else { zRIL(_c, op_BRCL, 0xF, uint32(v), asm) } if p.To.Sym != nil { c.addcallreloc(p.To.Sym, p.To.Offset) } } case 12: r1 := p.To.Reg d2 := c.vregoff(&p.From) b2 := p.From.Reg if b2 == 0 { b2 = REGSP } x2 := p.From.Index if -DISP20/2 > d2 || d2 >= DISP20/2 { zRIL(_a, op_LGFI, regtmp(p), uint32(d2), asm) if x2 != 0 { zRX(op_LA, regtmp(p), regtmp(p), uint32(x2), 0, asm) } x2 = int16(regtmp(p)) d2 = 0 } var opx, opxy uint32 switch p.As { case AADD: opxy = op_AG case AADDC: opxy = op_ALG case AADDE: opxy = op_ALCG case AADDW: opx = op_A opxy = op_AY case AMULLW: opx = op_MS opxy = op_MSY case AMULLD: opxy = op_MSG case ASUB: opxy = op_SG case ASUBC: opxy = op_SLG case ASUBE: opxy = op_SLBG case ASUBW: opx = op_S opxy = op_SY case AAND: opxy = op_NG case AANDW: opx = op_N opxy = op_NY case AOR: opxy = op_OG case AORW: opx = op_O opxy = op_OY case AXOR: opxy = op_XG case AXORW: opx = op_X opxy = op_XY } if opx != 0 && 0 <= d2 && d2 < DISP12 { zRX(opx, uint32(r1), uint32(x2), uint32(b2), uint32(d2), asm) } else { zRXY(opxy, uint32(r1), uint32(x2), uint32(b2), uint32(d2), asm) } case 13: // rotate, followed by operation r1 := p.To.Reg r2 := p.RestArgs[2].Reg i3 := uint8(p.From.Offset) // start i4 := uint8(p.RestArgs[0].Offset) // end i5 := uint8(p.RestArgs[1].Offset) // rotate amount switch p.As { case ARNSBGT, ARXSBGT, AROSBGT: i3 |= 0x80 // test-results case ARISBGZ, ARISBGNZ, ARISBHGZ, ARISBLGZ: i4 |= 0x80 // zero-remaining-bits } var opcode uint32 switch p.As { case ARNSBG, ARNSBGT: opcode = op_RNSBG case ARXSBG, ARXSBGT: opcode = op_RXSBG case AROSBG, AROSBGT: opcode = op_ROSBG case ARISBG, ARISBGZ: opcode = op_RISBG case ARISBGN, ARISBGNZ: opcode = op_RISBGN case ARISBHG, ARISBHGZ: opcode = op_RISBHG case ARISBLG, ARISBLGZ: opcode = op_RISBLG } zRIE(_f, uint32(opcode), uint32(r1), uint32(r2), 0, uint32(i3), uint32(i4), 0, uint32(i5), asm) case 15: // br/bl (reg) r := p.To.Reg if p.As == ABCL || p.As == ABL { zRR(op_BASR, uint32(REG_LR), uint32(r), asm) } else { zRR(op_BCR, uint32(Always), uint32(r), asm) } case 16: // conditional branch v := int32(0) if p.To.Target() != nil { v = int32((p.To.Target().Pc - p.Pc) >> 1) } mask := uint32(c.branchMask(p)) if p.To.Sym == nil && int32(int16(v)) == v { zRI(op_BRC, mask, uint32(v), asm) } else { zRIL(_c, op_BRCL, mask, uint32(v), asm) } if p.To.Sym != nil { c.addrilreloc(p.To.Sym, p.To.Offset) } case 17: // move on condition m3 := uint32(c.branchMask(p)) zRRF(op_LOCGR, m3, 0, uint32(p.To.Reg), uint32(p.From.Reg), asm) case 18: // br/bl reg if p.As == ABL { zRR(op_BASR, uint32(REG_LR), uint32(p.To.Reg), asm) } else { zRR(op_BCR, uint32(Always), uint32(p.To.Reg), asm) } case 19: // mov $sym+n(SB) reg d := c.vregoff(&p.From) zRIL(_b, op_LARL, uint32(p.To.Reg), 0, asm) if d&1 != 0 { zRX(op_LA, uint32(p.To.Reg), uint32(p.To.Reg), 0, 1, asm) d -= 1 } c.addrilreloc(p.From.Sym, d) case 21: // subtract $constant [reg] reg v := c.vregoff(&p.From) r := p.Reg if r == 0 { r = p.To.Reg } switch p.As { case ASUB: zRIL(_a, op_LGFI, uint32(regtmp(p)), uint32(v), asm) zRRF(op_SLGRK, uint32(regtmp(p)), 0, uint32(p.To.Reg), uint32(r), asm) case ASUBC: if r != p.To.Reg { zRRE(op_LGR, uint32(p.To.Reg), uint32(r), asm) } zRIL(_a, op_SLGFI, uint32(p.To.Reg), uint32(v), asm) case ASUBW: if r != p.To.Reg { zRR(op_LR, uint32(p.To.Reg), uint32(r), asm) } zRIL(_a, op_SLFI, uint32(p.To.Reg), uint32(v), asm) } case 22: // add/multiply $constant [reg] reg v := c.vregoff(&p.From) r := p.Reg if r == 0 { r = p.To.Reg } var opri, opril, oprie uint32 switch p.As { case AADD: opri = op_AGHI opril = op_AGFI oprie = op_AGHIK case AADDC: opril = op_ALGFI oprie = op_ALGHSIK case AADDW: opri = op_AHI opril = op_AFI oprie = op_AHIK case AMULLW: opri = op_MHI opril = op_MSFI case AMULLD: opri = op_MGHI opril = op_MSGFI } if r != p.To.Reg && (oprie == 0 || int64(int16(v)) != v) { switch p.As { case AADD, AADDC, AMULLD: zRRE(op_LGR, uint32(p.To.Reg), uint32(r), asm) case AADDW, AMULLW: zRR(op_LR, uint32(p.To.Reg), uint32(r), asm) } r = p.To.Reg } if opri != 0 && r == p.To.Reg && int64(int16(v)) == v { zRI(opri, uint32(p.To.Reg), uint32(v), asm) } else if oprie != 0 && int64(int16(v)) == v { zRIE(_d, oprie, uint32(p.To.Reg), uint32(r), uint32(v), 0, 0, 0, 0, asm) } else { zRIL(_a, opril, uint32(p.To.Reg), uint32(v), asm) } case 23: // 64-bit logical op $constant reg // TODO(mundaym): merge with case 24. v := c.vregoff(&p.From) switch p.As { default: c.ctxt.Diag("%v is not supported", p) case AAND: if v >= 0 { // needs zero extend zRIL(_a, op_LGFI, regtmp(p), uint32(v), asm) zRRE(op_NGR, uint32(p.To.Reg), regtmp(p), asm) } else if int64(int16(v)) == v { zRI(op_NILL, uint32(p.To.Reg), uint32(v), asm) } else { // r.To.Reg & 0xffffffff00000000 & uint32(v) zRIL(_a, op_NILF, uint32(p.To.Reg), uint32(v), asm) } case AOR: if int64(uint32(v)) != v { // needs sign extend zRIL(_a, op_LGFI, regtmp(p), uint32(v), asm) zRRE(op_OGR, uint32(p.To.Reg), regtmp(p), asm) } else if int64(uint16(v)) == v { zRI(op_OILL, uint32(p.To.Reg), uint32(v), asm) } else { zRIL(_a, op_OILF, uint32(p.To.Reg), uint32(v), asm) } case AXOR: if int64(uint32(v)) != v { // needs sign extend zRIL(_a, op_LGFI, regtmp(p), uint32(v), asm) zRRE(op_XGR, uint32(p.To.Reg), regtmp(p), asm) } else { zRIL(_a, op_XILF, uint32(p.To.Reg), uint32(v), asm) } } case 24: // 32-bit logical op $constant reg v := c.vregoff(&p.From) switch p.As { case AANDW: if uint32(v&0xffff0000) == 0xffff0000 { zRI(op_NILL, uint32(p.To.Reg), uint32(v), asm) } else if uint32(v&0x0000ffff) == 0x0000ffff { zRI(op_NILH, uint32(p.To.Reg), uint32(v)>>16, asm) } else { zRIL(_a, op_NILF, uint32(p.To.Reg), uint32(v), asm) } case AORW: if uint32(v&0xffff0000) == 0 { zRI(op_OILL, uint32(p.To.Reg), uint32(v), asm) } else if uint32(v&0x0000ffff) == 0 { zRI(op_OILH, uint32(p.To.Reg), uint32(v)>>16, asm) } else { zRIL(_a, op_OILF, uint32(p.To.Reg), uint32(v), asm) } case AXORW: zRIL(_a, op_XILF, uint32(p.To.Reg), uint32(v), asm) } case 25: // load on condition (register) m3 := uint32(c.branchMask(p)) var opcode uint32 switch p.As { case ALOCR: opcode = op_LOCR case ALOCGR: opcode = op_LOCGR } zRRF(opcode, m3, 0, uint32(p.To.Reg), uint32(p.Reg), asm) case 26: // MOVD $offset(base)(index), reg v := c.regoff(&p.From) r := p.From.Reg if r == 0 { r = REGSP } i := p.From.Index if v >= 0 && v < DISP12 { zRX(op_LA, uint32(p.To.Reg), uint32(r), uint32(i), uint32(v), asm) } else if v >= -DISP20/2 && v < DISP20/2 { zRXY(op_LAY, uint32(p.To.Reg), uint32(r), uint32(i), uint32(v), asm) } else { zRIL(_a, op_LGFI, regtmp(p), uint32(v), asm) zRX(op_LA, uint32(p.To.Reg), uint32(r), regtmp(p), uint32(i), asm) } case 31: // dword wd := uint64(c.vregoff(&p.From)) *asm = append(*asm, uint8(wd>>56), uint8(wd>>48), uint8(wd>>40), uint8(wd>>32), uint8(wd>>24), uint8(wd>>16), uint8(wd>>8), uint8(wd)) case 32: // float op freg freg var opcode uint32 switch p.As { default: c.ctxt.Diag("invalid opcode") case AFADD: opcode = op_ADBR case AFADDS: opcode = op_AEBR case AFDIV: opcode = op_DDBR case AFDIVS: opcode = op_DEBR case AFMUL: opcode = op_MDBR case AFMULS: opcode = op_MEEBR case AFSUB: opcode = op_SDBR case AFSUBS: opcode = op_SEBR } zRRE(opcode, uint32(p.To.Reg), uint32(p.From.Reg), asm) case 33: // float op [freg] freg r := p.From.Reg if oclass(&p.From) == C_NONE { r = p.To.Reg } var opcode uint32 switch p.As { default: case AFABS: opcode = op_LPDBR case AFNABS: opcode = op_LNDBR case ALPDFR: opcode = op_LPDFR case ALNDFR: opcode = op_LNDFR case AFNEG: opcode = op_LCDFR case AFNEGS: opcode = op_LCEBR case ALEDBR: opcode = op_LEDBR case ALDEBR: opcode = op_LDEBR case AFSQRT: opcode = op_SQDBR case AFSQRTS: opcode = op_SQEBR } zRRE(opcode, uint32(p.To.Reg), uint32(r), asm) case 34: // float multiply-add freg freg freg var opcode uint32 switch p.As { default: c.ctxt.Diag("invalid opcode") case AFMADD: opcode = op_MADBR case AFMADDS: opcode = op_MAEBR case AFMSUB: opcode = op_MSDBR case AFMSUBS: opcode = op_MSEBR } zRRD(opcode, uint32(p.To.Reg), uint32(p.From.Reg), uint32(p.Reg), asm) case 35: // mov reg mem (no relocation) d2 := c.regoff(&p.To) b2 := p.To.Reg if b2 == 0 { b2 = REGSP } x2 := p.To.Index if d2 < -DISP20/2 || d2 >= DISP20/2 { zRIL(_a, op_LGFI, regtmp(p), uint32(d2), asm) if x2 != 0 { zRX(op_LA, regtmp(p), regtmp(p), uint32(x2), 0, asm) } x2 = int16(regtmp(p)) d2 = 0 } // Emits an RX instruction if an appropriate one exists and the displacement fits in 12 bits. Otherwise use an RXY instruction. if op, ok := c.zopstore12(p.As); ok && isU12(d2) { zRX(op, uint32(p.From.Reg), uint32(x2), uint32(b2), uint32(d2), asm) } else { zRXY(c.zopstore(p.As), uint32(p.From.Reg), uint32(x2), uint32(b2), uint32(d2), asm) } case 36: // mov mem reg (no relocation) d2 := c.regoff(&p.From) b2 := p.From.Reg if b2 == 0 { b2 = REGSP } x2 := p.From.Index if d2 < -DISP20/2 || d2 >= DISP20/2 { zRIL(_a, op_LGFI, regtmp(p), uint32(d2), asm) if x2 != 0 { zRX(op_LA, regtmp(p), regtmp(p), uint32(x2), 0, asm) } x2 = int16(regtmp(p)) d2 = 0 } // Emits an RX instruction if an appropriate one exists and the displacement fits in 12 bits. Otherwise use an RXY instruction. if op, ok := c.zopload12(p.As); ok && isU12(d2) { zRX(op, uint32(p.To.Reg), uint32(x2), uint32(b2), uint32(d2), asm) } else { zRXY(c.zopload(p.As), uint32(p.To.Reg), uint32(x2), uint32(b2), uint32(d2), asm) } case 40: // word/byte wd := uint32(c.regoff(&p.From)) if p.As == AWORD { //WORD *asm = append(*asm, uint8(wd>>24), uint8(wd>>16), uint8(wd>>8), uint8(wd)) } else { //BYTE *asm = append(*asm, uint8(wd)) } case 41: // branch on count r1 := p.From.Reg ri2 := (p.To.Target().Pc - p.Pc) >> 1 if int64(int16(ri2)) != ri2 { c.ctxt.Diag("branch target too far away") } var opcode uint32 switch p.As { case ABRCT: opcode = op_BRCT case ABRCTG: opcode = op_BRCTG } zRI(opcode, uint32(r1), uint32(ri2), asm) case 47: // negate [reg] reg r := p.From.Reg if r == 0 { r = p.To.Reg } switch p.As { case ANEG: zRRE(op_LCGR, uint32(p.To.Reg), uint32(r), asm) case ANEGW: zRRE(op_LCGFR, uint32(p.To.Reg), uint32(r), asm) } case 48: // floating-point round to integer m3 := c.vregoff(&p.From) if 0 > m3 || m3 > 7 { c.ctxt.Diag("mask (%v) must be in the range [0, 7]", m3) } var opcode uint32 switch p.As { case AFIEBR: opcode = op_FIEBR case AFIDBR: opcode = op_FIDBR } zRRF(opcode, uint32(m3), 0, uint32(p.To.Reg), uint32(p.Reg), asm) case 49: // copysign zRRF(op_CPSDR, uint32(p.From.Reg), 0, uint32(p.To.Reg), uint32(p.Reg), asm) case 50: // load and test var opcode uint32 switch p.As { case ALTEBR: opcode = op_LTEBR case ALTDBR: opcode = op_LTDBR } zRRE(opcode, uint32(p.To.Reg), uint32(p.From.Reg), asm) case 51: // test data class (immediate only) var opcode uint32 switch p.As { case ATCEB: opcode = op_TCEB case ATCDB: opcode = op_TCDB } d2 := c.regoff(&p.To) zRXE(opcode, uint32(p.From.Reg), 0, 0, uint32(d2), 0, asm) case 62: // equivalent of Mul64 in math/bits zRRE(op_MLGR, uint32(p.To.Reg), uint32(p.From.Reg), asm) case 66: zRR(op_BCR, uint32(Never), 0, asm) case 67: // fmov $0 freg var opcode uint32 switch p.As { case AFMOVS: opcode = op_LZER case AFMOVD: opcode = op_LZDR } zRRE(opcode, uint32(p.To.Reg), 0, asm) case 68: // movw areg reg zRRE(op_EAR, uint32(p.To.Reg), uint32(p.From.Reg-REG_AR0), asm) case 69: // movw reg areg zRRE(op_SAR, uint32(p.To.Reg-REG_AR0), uint32(p.From.Reg), asm) case 70: // cmp reg reg if p.As == ACMPW || p.As == ACMPWU { zRR(c.zoprr(p.As), uint32(p.From.Reg), uint32(p.To.Reg), asm) } else { zRRE(c.zoprre(p.As), uint32(p.From.Reg), uint32(p.To.Reg), asm) } case 71: // cmp reg $constant v := c.vregoff(&p.To) switch p.As { case ACMP, ACMPW: if int64(int32(v)) != v { c.ctxt.Diag("%v overflows an int32", v) } case ACMPU, ACMPWU: if int64(uint32(v)) != v { c.ctxt.Diag("%v overflows a uint32", v) } } if p.As == ACMP && int64(int16(v)) == v { zRI(op_CGHI, uint32(p.From.Reg), uint32(v), asm) } else if p.As == ACMPW && int64(int16(v)) == v { zRI(op_CHI, uint32(p.From.Reg), uint32(v), asm) } else { zRIL(_a, c.zopril(p.As), uint32(p.From.Reg), uint32(v), asm) } case 72: // mov $constant mem v := c.regoff(&p.From) d := c.regoff(&p.To) r := p.To.Reg if p.To.Index != 0 { c.ctxt.Diag("cannot use index register") } if r == 0 { r = REGSP } var opcode uint32 switch p.As { case AMOVD: opcode = op_MVGHI case AMOVW, AMOVWZ: opcode = op_MVHI case AMOVH, AMOVHZ: opcode = op_MVHHI case AMOVB, AMOVBZ: opcode = op_MVI } if d < 0 || d >= DISP12 { if r == int16(regtmp(p)) { c.ctxt.Diag("displacement must be in range [0, 4096) to use %v", r) } if d >= -DISP20/2 && d < DISP20/2 { if opcode == op_MVI { opcode = op_MVIY } else { zRXY(op_LAY, uint32(regtmp(p)), 0, uint32(r), uint32(d), asm) r = int16(regtmp(p)) d = 0 } } else { zRIL(_a, op_LGFI, regtmp(p), uint32(d), asm) zRX(op_LA, regtmp(p), regtmp(p), uint32(r), 0, asm) r = int16(regtmp(p)) d = 0 } } switch opcode { case op_MVI: zSI(opcode, uint32(v), uint32(r), uint32(d), asm) case op_MVIY: zSIY(opcode, uint32(v), uint32(r), uint32(d), asm) default: zSIL(opcode, uint32(r), uint32(d), uint32(v), asm) } case 73: //Illegal opcode with SIGTRAP Exception zE(op_BRRK, asm) case 74: // mov reg addr (including relocation) i2 := c.regoff(&p.To) switch p.As { case AMOVD: zRIL(_b, op_STGRL, uint32(p.From.Reg), 0, asm) case AMOVW, AMOVWZ: // The zero extension doesn't affect store instructions zRIL(_b, op_STRL, uint32(p.From.Reg), 0, asm) case AMOVH, AMOVHZ: // The zero extension doesn't affect store instructions zRIL(_b, op_STHRL, uint32(p.From.Reg), 0, asm) case AMOVB, AMOVBZ: // The zero extension doesn't affect store instructions zRIL(_b, op_LARL, regtmp(p), 0, asm) adj := uint32(0) // adjustment needed for odd addresses if i2&1 != 0 { i2 -= 1 adj = 1 } zRX(op_STC, uint32(p.From.Reg), 0, regtmp(p), adj, asm) case AFMOVD: zRIL(_b, op_LARL, regtmp(p), 0, asm) zRX(op_STD, uint32(p.From.Reg), 0, regtmp(p), 0, asm) case AFMOVS: zRIL(_b, op_LARL, regtmp(p), 0, asm) zRX(op_STE, uint32(p.From.Reg), 0, regtmp(p), 0, asm) } c.addrilreloc(p.To.Sym, int64(i2)) case 75: // mov addr reg (including relocation) i2 := c.regoff(&p.From) switch p.As { case AMOVD: if i2&1 != 0 { zRIL(_b, op_LARL, regtmp(p), 0, asm) zRXY(op_LG, uint32(p.To.Reg), regtmp(p), 0, 1, asm) i2 -= 1 } else { zRIL(_b, op_LGRL, uint32(p.To.Reg), 0, asm) } case AMOVW: zRIL(_b, op_LGFRL, uint32(p.To.Reg), 0, asm) case AMOVWZ: zRIL(_b, op_LLGFRL, uint32(p.To.Reg), 0, asm) case AMOVH: zRIL(_b, op_LGHRL, uint32(p.To.Reg), 0, asm) case AMOVHZ: zRIL(_b, op_LLGHRL, uint32(p.To.Reg), 0, asm) case AMOVB, AMOVBZ: zRIL(_b, op_LARL, regtmp(p), 0, asm) adj := uint32(0) // adjustment needed for odd addresses if i2&1 != 0 { i2 -= 1 adj = 1 } switch p.As { case AMOVB: zRXY(op_LGB, uint32(p.To.Reg), 0, regtmp(p), adj, asm) case AMOVBZ: zRXY(op_LLGC, uint32(p.To.Reg), 0, regtmp(p), adj, asm) } case AFMOVD: zRIL(_a, op_LARL, regtmp(p), 0, asm) zRX(op_LD, uint32(p.To.Reg), 0, regtmp(p), 0, asm) case AFMOVS: zRIL(_a, op_LARL, regtmp(p), 0, asm) zRX(op_LE, uint32(p.To.Reg), 0, regtmp(p), 0, asm) } c.addrilreloc(p.From.Sym, int64(i2)) case 76: // set program mask zRR(op_SPM, uint32(p.From.Reg), 0, asm) case 77: // syscall $constant if p.From.Offset > 255 || p.From.Offset < 1 { c.ctxt.Diag("illegal system call; system call number out of range: %v", p) zE(op_TRAP2, asm) // trap always } else { zI(op_SVC, uint32(p.From.Offset), asm) } case 78: // undef // "An instruction consisting entirely of binary 0s is guaranteed // always to be an illegal instruction." *asm = append(*asm, 0, 0, 0, 0) case 79: // compare and swap reg reg reg v := c.regoff(&p.To) if v < 0 { v = 0 } if p.As == ACS { zRS(op_CS, uint32(p.From.Reg), uint32(p.Reg), uint32(p.To.Reg), uint32(v), asm) } else if p.As == ACSG { zRSY(op_CSG, uint32(p.From.Reg), uint32(p.Reg), uint32(p.To.Reg), uint32(v), asm) } case 80: // sync zRR(op_BCR, 14, 0, asm) // fast-BCR-serialization case 81: // float to fixed and fixed to float moves (no conversion) switch p.As { case ALDGR: zRRE(op_LDGR, uint32(p.To.Reg), uint32(p.From.Reg), asm) case ALGDR: zRRE(op_LGDR, uint32(p.To.Reg), uint32(p.From.Reg), asm) } case 82: // fixed to float conversion var opcode uint32 switch p.As { default: log.Fatalf("unexpected opcode %v", p.As) case ACEFBRA: opcode = op_CEFBRA case ACDFBRA: opcode = op_CDFBRA case ACEGBRA: opcode = op_CEGBRA case ACDGBRA: opcode = op_CDGBRA case ACELFBR: opcode = op_CELFBR case ACDLFBR: opcode = op_CDLFBR case ACELGBR: opcode = op_CELGBR case ACDLGBR: opcode = op_CDLGBR } // set immediate operand M3 to 0 to use the default BFP rounding mode // (usually round to nearest, ties to even) // TODO(mundaym): should this be fixed at round to nearest, ties to even? // M4 is reserved and must be 0 zRRF(opcode, 0, 0, uint32(p.To.Reg), uint32(p.From.Reg), asm) case 83: // float to fixed conversion var opcode uint32 switch p.As { default: log.Fatalf("unexpected opcode %v", p.As) case ACFEBRA: opcode = op_CFEBRA case ACFDBRA: opcode = op_CFDBRA case ACGEBRA: opcode = op_CGEBRA case ACGDBRA: opcode = op_CGDBRA case ACLFEBR: opcode = op_CLFEBR case ACLFDBR: opcode = op_CLFDBR case ACLGEBR: opcode = op_CLGEBR case ACLGDBR: opcode = op_CLGDBR } // set immediate operand M3 to 5 for rounding toward zero (required by Go spec) // M4 is reserved and must be 0 zRRF(opcode, 5, 0, uint32(p.To.Reg), uint32(p.From.Reg), asm) case 84: // storage-and-storage operations $length mem mem l := c.regoff(&p.From) if l < 1 || l > 256 { c.ctxt.Diag("number of bytes (%v) not in range [1,256]", l) } if p.GetFrom3().Index != 0 || p.To.Index != 0 { c.ctxt.Diag("cannot use index reg") } b1 := p.To.Reg b2 := p.GetFrom3().Reg if b1 == 0 { b1 = REGSP } if b2 == 0 { b2 = REGSP } d1 := c.regoff(&p.To) d2 := c.regoff(p.GetFrom3()) if d1 < 0 || d1 >= DISP12 { if b2 == int16(regtmp(p)) { c.ctxt.Diag("regtmp(p) conflict") } if b1 != int16(regtmp(p)) { zRRE(op_LGR, regtmp(p), uint32(b1), asm) } zRIL(_a, op_AGFI, regtmp(p), uint32(d1), asm) if d1 == d2 && b1 == b2 { d2 = 0 b2 = int16(regtmp(p)) } d1 = 0 b1 = int16(regtmp(p)) } if d2 < 0 || d2 >= DISP12 { if b1 == REGTMP2 { c.ctxt.Diag("REGTMP2 conflict") } if b2 != REGTMP2 { zRRE(op_LGR, REGTMP2, uint32(b2), asm) } zRIL(_a, op_AGFI, REGTMP2, uint32(d2), asm) d2 = 0 b2 = REGTMP2 } var opcode uint32 switch p.As { default: c.ctxt.Diag("unexpected opcode %v", p.As) case AMVC: opcode = op_MVC case AMVCIN: opcode = op_MVCIN case ACLC: opcode = op_CLC // swap operand order for CLC so that it matches CMP b1, b2 = b2, b1 d1, d2 = d2, d1 case AXC: opcode = op_XC case AOC: opcode = op_OC case ANC: opcode = op_NC } zSS(_a, opcode, uint32(l-1), 0, uint32(b1), uint32(d1), uint32(b2), uint32(d2), asm) case 85: // load address relative long v := c.regoff(&p.From) if p.From.Sym == nil { if (v & 1) != 0 { c.ctxt.Diag("cannot use LARL with odd offset: %v", v) } } else { c.addrilreloc(p.From.Sym, int64(v)) v = 0 } zRIL(_b, op_LARL, uint32(p.To.Reg), uint32(v>>1), asm) case 86: // load address d := c.vregoff(&p.From) x := p.From.Index b := p.From.Reg if b == 0 { b = REGSP } switch p.As { case ALA: zRX(op_LA, uint32(p.To.Reg), uint32(x), uint32(b), uint32(d), asm) case ALAY: zRXY(op_LAY, uint32(p.To.Reg), uint32(x), uint32(b), uint32(d), asm) } case 87: // execute relative long v := c.vregoff(&p.From) if p.From.Sym == nil { if v&1 != 0 { c.ctxt.Diag("cannot use EXRL with odd offset: %v", v) } } else { c.addrilreloc(p.From.Sym, v) v = 0 } zRIL(_b, op_EXRL, uint32(p.To.Reg), uint32(v>>1), asm) case 88: // store clock var opcode uint32 switch p.As { case ASTCK: opcode = op_STCK case ASTCKC: opcode = op_STCKC case ASTCKE: opcode = op_STCKE case ASTCKF: opcode = op_STCKF } v := c.vregoff(&p.To) r := p.To.Reg if r == 0 { r = REGSP } zS(opcode, uint32(r), uint32(v), asm) case 89: // compare and branch reg reg var v int32 if p.To.Target() != nil { v = int32((p.To.Target().Pc - p.Pc) >> 1) } // Some instructions take a mask as the first argument. r1, r2 := p.From.Reg, p.Reg if p.From.Type == obj.TYPE_CONST { r1, r2 = p.Reg, p.RestArgs[0].Reg } m3 := uint32(c.branchMask(p)) var opcode uint32 switch p.As { case ACRJ: // COMPARE AND BRANCH RELATIVE (32) opcode = op_CRJ case ACGRJ, ACMPBEQ, ACMPBGE, ACMPBGT, ACMPBLE, ACMPBLT, ACMPBNE: // COMPARE AND BRANCH RELATIVE (64) opcode = op_CGRJ case ACLRJ: // COMPARE LOGICAL AND BRANCH RELATIVE (32) opcode = op_CLRJ case ACLGRJ, ACMPUBEQ, ACMPUBGE, ACMPUBGT, ACMPUBLE, ACMPUBLT, ACMPUBNE: // COMPARE LOGICAL AND BRANCH RELATIVE (64) opcode = op_CLGRJ } if int32(int16(v)) != v { // The branch is too far for one instruction so crack // `CMPBEQ x, y, target` into: // // CMPBNE x, y, 2(PC) // BR target // // Note that the instruction sequence MUST NOT clobber // the condition code. m3 ^= 0xe // invert 3-bit mask zRIE(_b, opcode, uint32(r1), uint32(r2), uint32(sizeRIE+sizeRIL)/2, 0, 0, m3, 0, asm) zRIL(_c, op_BRCL, uint32(Always), uint32(v-sizeRIE/2), asm) } else { zRIE(_b, opcode, uint32(r1), uint32(r2), uint32(v), 0, 0, m3, 0, asm) } case 90: // compare and branch reg $constant var v int32 if p.To.Target() != nil { v = int32((p.To.Target().Pc - p.Pc) >> 1) } // Some instructions take a mask as the first argument. r1, i2 := p.From.Reg, p.RestArgs[0].Offset if p.From.Type == obj.TYPE_CONST { r1 = p.Reg } m3 := uint32(c.branchMask(p)) var opcode uint32 switch p.As { case ACIJ: opcode = op_CIJ case ACGIJ, ACMPBEQ, ACMPBGE, ACMPBGT, ACMPBLE, ACMPBLT, ACMPBNE: opcode = op_CGIJ case ACLIJ: opcode = op_CLIJ case ACLGIJ, ACMPUBEQ, ACMPUBGE, ACMPUBGT, ACMPUBLE, ACMPUBLT, ACMPUBNE: opcode = op_CLGIJ } if int32(int16(v)) != v { // The branch is too far for one instruction so crack // `CMPBEQ x, $0, target` into: // // CMPBNE x, $0, 2(PC) // BR target // // Note that the instruction sequence MUST NOT clobber // the condition code. m3 ^= 0xe // invert 3-bit mask zRIE(_c, opcode, uint32(r1), m3, uint32(sizeRIE+sizeRIL)/2, 0, 0, 0, uint32(i2), asm) zRIL(_c, op_BRCL, uint32(Always), uint32(v-sizeRIE/2), asm) } else { zRIE(_c, opcode, uint32(r1), m3, uint32(v), 0, 0, 0, uint32(i2), asm) } case 91: // test under mask (immediate) var opcode uint32 switch p.As { case ATMHH: opcode = op_TMHH case ATMHL: opcode = op_TMHL case ATMLH: opcode = op_TMLH case ATMLL: opcode = op_TMLL } zRI(opcode, uint32(p.From.Reg), uint32(c.vregoff(&p.To)), asm) case 92: // insert program mask zRRE(op_IPM, uint32(p.From.Reg), 0, asm) case 93: // GOT lookup v := c.vregoff(&p.To) if v != 0 { c.ctxt.Diag("invalid offset against GOT slot %v", p) } zRIL(_b, op_LGRL, uint32(p.To.Reg), 0, asm) c.cursym.AddRel(c.ctxt, obj.Reloc{ Type: objabi.R_GOTPCREL, Off: int32(c.pc + 2), Siz: 4, Sym: p.From.Sym, Add: 2 + 4, }) case 94: // TLS local exec model zRIL(_b, op_LARL, regtmp(p), (sizeRIL+sizeRXY+sizeRI)>>1, asm) zRXY(op_LG, uint32(p.To.Reg), regtmp(p), 0, 0, asm) zRI(op_BRC, 0xF, (sizeRI+8)>>1, asm) *asm = append(*asm, 0, 0, 0, 0, 0, 0, 0, 0) c.cursym.AddRel(c.ctxt, obj.Reloc{ Type: objabi.R_TLS_LE, Off: int32(c.pc + sizeRIL + sizeRXY + sizeRI), Siz: 8, Sym: p.From.Sym, }) case 95: // TLS initial exec model // Assembly | Relocation symbol | Done Here? // -------------------------------------------------------------- // ear %r11, %a0 | | // sllg %r11, %r11, 32 | | // ear %r11, %a1 | | // larl %r10, @indntpoff | R_390_TLS_IEENT | Y // lg %r10, 0(%r10) | R_390_TLS_LOAD (tag) | Y // la %r10, 0(%r10, %r11) | | // -------------------------------------------------------------- // R_390_TLS_IEENT zRIL(_b, op_LARL, regtmp(p), 0, asm) c.cursym.AddRel(c.ctxt, obj.Reloc{ Type: objabi.R_TLS_IE, Off: int32(c.pc + 2), Siz: 4, Sym: p.From.Sym, Add: 2 + 4, }) // R_390_TLS_LOAD zRXY(op_LGF, uint32(p.To.Reg), regtmp(p), 0, 0, asm) // TODO(mundaym): add R_390_TLS_LOAD relocation here // not strictly required but might allow the linker to optimize case 96: // clear macro length := c.vregoff(&p.From) offset := c.vregoff(&p.To) reg := p.To.Reg if reg == 0 { reg = REGSP } if length <= 0 { c.ctxt.Diag("cannot CLEAR %d bytes, must be greater than 0", length) } for length > 0 { if offset < 0 || offset >= DISP12 { if offset >= -DISP20/2 && offset < DISP20/2 { zRXY(op_LAY, regtmp(p), uint32(reg), 0, uint32(offset), asm) } else { if reg != int16(regtmp(p)) { zRRE(op_LGR, regtmp(p), uint32(reg), asm) } zRIL(_a, op_AGFI, regtmp(p), uint32(offset), asm) } reg = int16(regtmp(p)) offset = 0 } size := length if size > 256 { size = 256 } switch size { case 1: zSI(op_MVI, 0, uint32(reg), uint32(offset), asm) case 2: zSIL(op_MVHHI, uint32(reg), uint32(offset), 0, asm) case 4: zSIL(op_MVHI, uint32(reg), uint32(offset), 0, asm) case 8: zSIL(op_MVGHI, uint32(reg), uint32(offset), 0, asm) default: zSS(_a, op_XC, uint32(size-1), 0, uint32(reg), uint32(offset), uint32(reg), uint32(offset), asm) } length -= size offset += size } case 97: // store multiple rstart := p.From.Reg rend := p.Reg offset := c.regoff(&p.To) reg := p.To.Reg if reg == 0 { reg = REGSP } if offset < -DISP20/2 || offset >= DISP20/2 { if reg != int16(regtmp(p)) { zRRE(op_LGR, regtmp(p), uint32(reg), asm) } zRIL(_a, op_AGFI, regtmp(p), uint32(offset), asm) reg = int16(regtmp(p)) offset = 0 } switch p.As { case ASTMY: if offset >= 0 && offset < DISP12 { zRS(op_STM, uint32(rstart), uint32(rend), uint32(reg), uint32(offset), asm) } else { zRSY(op_STMY, uint32(rstart), uint32(rend), uint32(reg), uint32(offset), asm) } case ASTMG: zRSY(op_STMG, uint32(rstart), uint32(rend), uint32(reg), uint32(offset), asm) } case 98: // load multiple rstart := p.Reg rend := p.To.Reg offset := c.regoff(&p.From) reg := p.From.Reg if reg == 0 { reg = REGSP } if offset < -DISP20/2 || offset >= DISP20/2 { if reg != int16(regtmp(p)) { zRRE(op_LGR, regtmp(p), uint32(reg), asm) } zRIL(_a, op_AGFI, regtmp(p), uint32(offset), asm) reg = int16(regtmp(p)) offset = 0 } switch p.As { case ALMY: if offset >= 0 && offset < DISP12 { zRS(op_LM, uint32(rstart), uint32(rend), uint32(reg), uint32(offset), asm) } else { zRSY(op_LMY, uint32(rstart), uint32(rend), uint32(reg), uint32(offset), asm) } case ALMG: zRSY(op_LMG, uint32(rstart), uint32(rend), uint32(reg), uint32(offset), asm) } case 99: // interlocked load and op if p.To.Index != 0 { c.ctxt.Diag("cannot use indexed address") } offset := c.regoff(&p.To) if offset < -DISP20/2 || offset >= DISP20/2 { c.ctxt.Diag("%v does not fit into 20-bit signed integer", offset) } var opcode uint32 switch p.As { case ALAA: opcode = op_LAA case ALAAG: opcode = op_LAAG case ALAAL: opcode = op_LAAL case ALAALG: opcode = op_LAALG case ALAN: opcode = op_LAN case ALANG: opcode = op_LANG case ALAX: opcode = op_LAX case ALAXG: opcode = op_LAXG case ALAO: opcode = op_LAO case ALAOG: opcode = op_LAOG } zRSY(opcode, uint32(p.Reg), uint32(p.From.Reg), uint32(p.To.Reg), uint32(offset), asm) case 100: // VRX STORE op, m3, _ := vop(p.As) v1 := p.From.Reg if p.Reg != 0 { m3 = uint32(c.vregoff(&p.From)) v1 = p.Reg } b2 := p.To.Reg if b2 == 0 { b2 = REGSP } d2 := uint32(c.vregoff(&p.To)) zVRX(op, uint32(v1), uint32(p.To.Index), uint32(b2), d2, m3, asm) case 101: // VRX LOAD op, m3, _ := vop(p.As) src := &p.From if p.GetFrom3() != nil { m3 = uint32(c.vregoff(&p.From)) src = p.GetFrom3() } b2 := src.Reg if b2 == 0 { b2 = REGSP } d2 := uint32(c.vregoff(src)) zVRX(op, uint32(p.To.Reg), uint32(src.Index), uint32(b2), d2, m3, asm) case 102: // VRV SCATTER op, _, _ := vop(p.As) m3 := uint32(c.vregoff(&p.From)) b2 := p.To.Reg if b2 == 0 { b2 = REGSP } d2 := uint32(c.vregoff(&p.To)) zVRV(op, uint32(p.Reg), uint32(p.To.Index), uint32(b2), d2, m3, asm) case 103: // VRV GATHER op, _, _ := vop(p.As) m3 := uint32(c.vregoff(&p.From)) b2 := p.GetFrom3().Reg if b2 == 0 { b2 = REGSP } d2 := uint32(c.vregoff(p.GetFrom3())) zVRV(op, uint32(p.To.Reg), uint32(p.GetFrom3().Index), uint32(b2), d2, m3, asm) case 104: // VRS SHIFT/ROTATE and LOAD GR FROM VR ELEMENT op, m4, _ := vop(p.As) fr := p.Reg if fr == 0 { fr = p.To.Reg } bits := uint32(c.vregoff(&p.From)) zVRS(op, uint32(p.To.Reg), uint32(fr), uint32(p.From.Reg), bits, m4, asm) case 105: // VRS STORE MULTIPLE op, _, _ := vop(p.As) offset := uint32(c.vregoff(&p.To)) reg := p.To.Reg if reg == 0 { reg = REGSP } zVRS(op, uint32(p.From.Reg), uint32(p.Reg), uint32(reg), offset, 0, asm) case 106: // VRS LOAD MULTIPLE op, _, _ := vop(p.As) offset := uint32(c.vregoff(&p.From)) reg := p.From.Reg if reg == 0 { reg = REGSP } zVRS(op, uint32(p.Reg), uint32(p.To.Reg), uint32(reg), offset, 0, asm) case 107: // VRS STORE WITH LENGTH op, _, _ := vop(p.As) offset := uint32(c.vregoff(&p.To)) reg := p.To.Reg if reg == 0 { reg = REGSP } zVRS(op, uint32(p.Reg), uint32(p.From.Reg), uint32(reg), offset, 0, asm) case 108: // VRS LOAD WITH LENGTH op, _, _ := vop(p.As) offset := uint32(c.vregoff(p.GetFrom3())) reg := p.GetFrom3().Reg if reg == 0 { reg = REGSP } zVRS(op, uint32(p.To.Reg), uint32(p.From.Reg), uint32(reg), offset, 0, asm) case 109: // VRI-a op, m3, _ := vop(p.As) i2 := uint32(c.vregoff(&p.From)) if p.GetFrom3() != nil { m3 = uint32(c.vregoff(&p.From)) i2 = uint32(c.vregoff(p.GetFrom3())) } switch p.As { case AVZERO: i2 = 0 case AVONE: i2 = 0xffff } zVRIa(op, uint32(p.To.Reg), i2, m3, asm) case 110: op, m4, _ := vop(p.As) i2 := uint32(c.vregoff(&p.From)) i3 := uint32(c.vregoff(p.GetFrom3())) zVRIb(op, uint32(p.To.Reg), i2, i3, m4, asm) case 111: op, m4, _ := vop(p.As) i2 := uint32(c.vregoff(&p.From)) zVRIc(op, uint32(p.To.Reg), uint32(p.Reg), i2, m4, asm) case 112: op, m5, _ := vop(p.As) i4 := uint32(c.vregoff(&p.From)) zVRId(op, uint32(p.To.Reg), uint32(p.Reg), uint32(p.GetFrom3().Reg), i4, m5, asm) case 113: op, m4, _ := vop(p.As) m5 := singleElementMask(p.As) i3 := uint32(c.vregoff(&p.From)) zVRIe(op, uint32(p.To.Reg), uint32(p.Reg), i3, m5, m4, asm) case 114: // VRR-a op, m3, m5 := vop(p.As) m4 := singleElementMask(p.As) zVRRa(op, uint32(p.To.Reg), uint32(p.From.Reg), m5, m4, m3, asm) case 115: // VRR-a COMPARE op, m3, m5 := vop(p.As) m4 := singleElementMask(p.As) zVRRa(op, uint32(p.From.Reg), uint32(p.To.Reg), m5, m4, m3, asm) case 117: // VRR-b op, m4, m5 := vop(p.As) zVRRb(op, uint32(p.To.Reg), uint32(p.From.Reg), uint32(p.Reg), m5, m4, asm) case 118: // VRR-c op, m4, m6 := vop(p.As) m5 := singleElementMask(p.As) v3 := p.Reg if v3 == 0 { v3 = p.To.Reg } zVRRc(op, uint32(p.To.Reg), uint32(p.From.Reg), uint32(v3), m6, m5, m4, asm) case 119: // VRR-c SHIFT/ROTATE/DIVIDE/SUB (rhs value on the left, like SLD, DIV etc.) op, m4, m6 := vop(p.As) m5 := singleElementMask(p.As) v2 := p.Reg if v2 == 0 { v2 = p.To.Reg } zVRRc(op, uint32(p.To.Reg), uint32(v2), uint32(p.From.Reg), m6, m5, m4, asm) case 120: // VRR-d op, m6, m5 := vop(p.As) v1 := uint32(p.To.Reg) v2 := uint32(p.From.Reg) v3 := uint32(p.Reg) v4 := uint32(p.GetFrom3().Reg) zVRRd(op, v1, v2, v3, m6, m5, v4, asm) case 121: // VRR-e op, m6, _ := vop(p.As) m5 := singleElementMask(p.As) v1 := uint32(p.To.Reg) v2 := uint32(p.From.Reg) v3 := uint32(p.Reg) v4 := uint32(p.GetFrom3().Reg) zVRRe(op, v1, v2, v3, m6, m5, v4, asm) case 122: // VRR-f LOAD VRS FROM GRS DISJOINT op, _, _ := vop(p.As) zVRRf(op, uint32(p.To.Reg), uint32(p.From.Reg), uint32(p.Reg), asm) case 123: // VPDI $m4, V2, V3, V1 op, _, _ := vop(p.As) m4 := c.regoff(&p.From) zVRRc(op, uint32(p.To.Reg), uint32(p.Reg), uint32(p.GetFrom3().Reg), 0, 0, uint32(m4), asm) case 124: var opcode uint32 switch p.As { default: c.ctxt.Diag("unexpected opcode %v", p.As) case AKM, AKMC, AKLMD: if p.From.Reg == REG_R0 { c.ctxt.Diag("input must not be R0 in %v", p) } if p.From.Reg&1 != 0 { c.ctxt.Diag("input must be even register in %v", p) } if p.To.Reg == REG_R0 { c.ctxt.Diag("second argument must not be R0 in %v", p) } if p.To.Reg&1 != 0 { c.ctxt.Diag("second argument must be even register in %v", p) } if p.As == AKM { opcode = op_KM } else if p.As == AKMC { opcode = op_KMC } else { opcode = op_KLMD } case AKIMD: if p.To.Reg == REG_R0 { c.ctxt.Diag("second argument must not be R0 in %v", p) } if p.To.Reg&1 != 0 { c.ctxt.Diag("second argument must be even register in %v", p) } opcode = op_KIMD } zRRE(opcode, uint32(p.From.Reg), uint32(p.To.Reg), asm) case 125: // KDSA sign and verify if p.To.Reg == REG_R0 { c.ctxt.Diag("second argument must not be R0 in %v", p) } if p.To.Reg&1 != 0 { c.ctxt.Diag("second argument must be an even register in %v", p) } zRRE(op_KDSA, uint32(p.From.Reg), uint32(p.To.Reg), asm) case 126: // KMA and KMCTR - CIPHER MESSAGE WITH AUTHENTICATION; CIPHER MESSAGE WITH COUNTER var opcode uint32 switch p.As { default: c.ctxt.Diag("unexpected opcode %v", p.As) case AKMA, AKMCTR: if p.From.Reg == REG_R0 { c.ctxt.Diag("input argument must not be R0 in %v", p) } if p.From.Reg&1 != 0 { c.ctxt.Diag("input argument must be even register in %v", p) } if p.To.Reg == REG_R0 { c.ctxt.Diag("output argument must not be R0 in %v", p) } if p.To.Reg&1 != 0 { c.ctxt.Diag("output argument must be an even register in %v", p) } if p.Reg == REG_R0 { c.ctxt.Diag("third argument must not be R0 in %v", p) } if p.Reg&1 != 0 { c.ctxt.Diag("third argument must be even register in %v", p) } if p.As == AKMA { opcode = op_KMA } else if p.As == AKMCTR { opcode = op_KMCTR } } zRRF(opcode, uint32(p.Reg), 0, uint32(p.From.Reg), uint32(p.To.Reg), asm) } } func (c *ctxtz) vregoff(a *obj.Addr) int64 { c.instoffset = 0 if a != nil { c.aclass(a) } return c.instoffset } func (c *ctxtz) regoff(a *obj.Addr) int32 { return int32(c.vregoff(a)) } // find if the displacement is within 12 bit. func isU12(displacement int32) bool { return displacement >= 0 && displacement < DISP12 } // zopload12 returns the RX op with 12 bit displacement for the given load. func (c *ctxtz) zopload12(a obj.As) (uint32, bool) { switch a { case AFMOVD: return op_LD, true case AFMOVS: return op_LE, true } return 0, false } // zopload returns the RXY op for the given load. func (c *ctxtz) zopload(a obj.As) uint32 { switch a { // fixed point load case AMOVD: return op_LG case AMOVW: return op_LGF case AMOVWZ: return op_LLGF case AMOVH: return op_LGH case AMOVHZ: return op_LLGH case AMOVB: return op_LGB case AMOVBZ: return op_LLGC // floating point load case AFMOVD: return op_LDY case AFMOVS: return op_LEY // byte reversed load case AMOVDBR: return op_LRVG case AMOVWBR: return op_LRV case AMOVHBR: return op_LRVH } c.ctxt.Diag("unknown store opcode %v", a) return 0 } // zopstore12 returns the RX op with 12 bit displacement for the given store. func (c *ctxtz) zopstore12(a obj.As) (uint32, bool) { switch a { case AFMOVD: return op_STD, true case AFMOVS: return op_STE, true case AMOVW, AMOVWZ: return op_ST, true case AMOVH, AMOVHZ: return op_STH, true case AMOVB, AMOVBZ: return op_STC, true } return 0, false } // zopstore returns the RXY op for the given store. func (c *ctxtz) zopstore(a obj.As) uint32 { switch a { // fixed point store case AMOVD: return op_STG case AMOVW, AMOVWZ: return op_STY case AMOVH, AMOVHZ: return op_STHY case AMOVB, AMOVBZ: return op_STCY // floating point store case AFMOVD: return op_STDY case AFMOVS: return op_STEY // byte reversed store case AMOVDBR: return op_STRVG case AMOVWBR: return op_STRV case AMOVHBR: return op_STRVH } c.ctxt.Diag("unknown store opcode %v", a) return 0 } // zoprre returns the RRE op for the given a. func (c *ctxtz) zoprre(a obj.As) uint32 { switch a { case ACMP: return op_CGR case ACMPU: return op_CLGR case AFCMPO: //ordered return op_KDBR case AFCMPU: //unordered return op_CDBR case ACEBR: return op_CEBR } c.ctxt.Diag("unknown rre opcode %v", a) return 0 } // zoprr returns the RR op for the given a. func (c *ctxtz) zoprr(a obj.As) uint32 { switch a { case ACMPW: return op_CR case ACMPWU: return op_CLR } c.ctxt.Diag("unknown rr opcode %v", a) return 0 } // zopril returns the RIL op for the given a. func (c *ctxtz) zopril(a obj.As) uint32 { switch a { case ACMP: return op_CGFI case ACMPU: return op_CLGFI case ACMPW: return op_CFI case ACMPWU: return op_CLFI } c.ctxt.Diag("unknown ril opcode %v", a) return 0 } // z instructions sizes const ( sizeE = 2 sizeI = 2 sizeIE = 4 sizeMII = 6 sizeRI = 4 sizeRI1 = 4 sizeRI2 = 4 sizeRI3 = 4 sizeRIE = 6 sizeRIE1 = 6 sizeRIE2 = 6 sizeRIE3 = 6 sizeRIE4 = 6 sizeRIE5 = 6 sizeRIE6 = 6 sizeRIL = 6 sizeRIL1 = 6 sizeRIL2 = 6 sizeRIL3 = 6 sizeRIS = 6 sizeRR = 2 sizeRRD = 4 sizeRRE = 4 sizeRRF = 4 sizeRRF1 = 4 sizeRRF2 = 4 sizeRRF3 = 4 sizeRRF4 = 4 sizeRRF5 = 4 sizeRRR = 2 sizeRRS = 6 sizeRS = 4 sizeRS1 = 4 sizeRS2 = 4 sizeRSI = 4 sizeRSL = 6 sizeRSY = 6 sizeRSY1 = 6 sizeRSY2 = 6 sizeRX = 4 sizeRX1 = 4 sizeRX2 = 4 sizeRXE = 6 sizeRXF = 6 sizeRXY = 6 sizeRXY1 = 6 sizeRXY2 = 6 sizeS = 4 sizeSI = 4 sizeSIL = 6 sizeSIY = 6 sizeSMI = 6 sizeSS = 6 sizeSS1 = 6 sizeSS2 = 6 sizeSS3 = 6 sizeSS4 = 6 sizeSS5 = 6 sizeSS6 = 6 sizeSSE = 6 sizeSSF = 6 ) // instruction format variations type form int const ( _a form = iota _b _c _d _e _f ) func zE(op uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(op)) } func zI(op, i1 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(i1)) } func zMII(op, m1, ri2, ri3 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(m1)<<4)|uint8((ri2>>8)&0x0F), uint8(ri2), uint8(ri3>>16), uint8(ri3>>8), uint8(ri3)) } func zRI(op, r1_m1, i2_ri2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(r1_m1)<<4)|(uint8(op)&0x0F), uint8(i2_ri2>>8), uint8(i2_ri2)) } // Expected argument values for the instruction formats. // // Format a1 a2 a3 a4 a5 a6 a7 // ------------------------------------ // a r1, 0, i2, 0, 0, m3, 0 // b r1, r2, ri4, 0, 0, m3, 0 // c r1, m3, ri4, 0, 0, 0, i2 // d r1, r3, i2, 0, 0, 0, 0 // e r1, r3, ri2, 0, 0, 0, 0 // f r1, r2, 0, i3, i4, 0, i5 // g r1, m3, i2, 0, 0, 0, 0 func zRIE(f form, op, r1, r2_m3_r3, i2_ri4_ri2, i3, i4, m3, i2_i5 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(r1)<<4|uint8(r2_m3_r3&0x0F)) switch f { default: *asm = append(*asm, uint8(i2_ri4_ri2>>8), uint8(i2_ri4_ri2)) case _f: *asm = append(*asm, uint8(i3), uint8(i4)) } switch f { case _a, _b: *asm = append(*asm, uint8(m3)<<4) default: *asm = append(*asm, uint8(i2_i5)) } *asm = append(*asm, uint8(op)) } func zRIL(f form, op, r1_m1, i2_ri2 uint32, asm *[]byte) { if f == _a || f == _b { r1_m1 = r1_m1 - obj.RBaseS390X // this is a register base } *asm = append(*asm, uint8(op>>8), (uint8(r1_m1)<<4)|(uint8(op)&0x0F), uint8(i2_ri2>>24), uint8(i2_ri2>>16), uint8(i2_ri2>>8), uint8(i2_ri2)) } func zRIS(op, r1, m3, b4, d4, i2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(r1)<<4)|uint8(m3&0x0F), (uint8(b4)<<4)|(uint8(d4>>8)&0x0F), uint8(d4), uint8(i2), uint8(op)) } func zRR(op, r1, r2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(r1)<<4)|uint8(r2&0x0F)) } func zRRD(op, r1, r3, r2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(op), uint8(r1)<<4, (uint8(r3)<<4)|uint8(r2&0x0F)) } func zRRE(op, r1, r2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(op), 0, (uint8(r1)<<4)|uint8(r2&0x0F)) } func zRRF(op, r3_m3, m4, r1, r2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(op), (uint8(r3_m3)<<4)|uint8(m4&0x0F), (uint8(r1)<<4)|uint8(r2&0x0F)) } func zRRS(op, r1, r2, b4, d4, m3 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(r1)<<4)|uint8(r2&0x0F), (uint8(b4)<<4)|uint8((d4>>8)&0x0F), uint8(d4), uint8(m3)<<4, uint8(op)) } func zRS(op, r1, r3_m3, b2, d2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(r1)<<4)|uint8(r3_m3&0x0F), (uint8(b2)<<4)|uint8((d2>>8)&0x0F), uint8(d2)) } func zRSI(op, r1, r3, ri2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(r1)<<4)|uint8(r3&0x0F), uint8(ri2>>8), uint8(ri2)) } func zRSL(op, l1, b2, d2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(l1), (uint8(b2)<<4)|uint8((d2>>8)&0x0F), uint8(d2), uint8(op)) } func zRSY(op, r1, r3_m3, b2, d2 uint32, asm *[]byte) { dl2 := uint16(d2) & 0x0FFF *asm = append(*asm, uint8(op>>8), (uint8(r1)<<4)|uint8(r3_m3&0x0F), (uint8(b2)<<4)|(uint8(dl2>>8)&0x0F), uint8(dl2), uint8(d2>>12), uint8(op)) } func zRX(op, r1_m1, x2, b2, d2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(r1_m1)<<4)|uint8(x2&0x0F), (uint8(b2)<<4)|uint8((d2>>8)&0x0F), uint8(d2)) } func zRXE(op, r1, x2, b2, d2, m3 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(r1)<<4)|uint8(x2&0x0F), (uint8(b2)<<4)|uint8((d2>>8)&0x0F), uint8(d2), uint8(m3)<<4, uint8(op)) } func zRXF(op, r3, x2, b2, d2, m1 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(r3)<<4)|uint8(x2&0x0F), (uint8(b2)<<4)|uint8((d2>>8)&0x0F), uint8(d2), uint8(m1)<<4, uint8(op)) } func zRXY(op, r1_m1, x2, b2, d2 uint32, asm *[]byte) { dl2 := uint16(d2) & 0x0FFF *asm = append(*asm, uint8(op>>8), (uint8(r1_m1)<<4)|uint8(x2&0x0F), (uint8(b2)<<4)|(uint8(dl2>>8)&0x0F), uint8(dl2), uint8(d2>>12), uint8(op)) } func zS(op, b2, d2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(op), (uint8(b2)<<4)|uint8((d2>>8)&0x0F), uint8(d2)) } func zSI(op, i2, b1, d1 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(i2), (uint8(b1)<<4)|uint8((d1>>8)&0x0F), uint8(d1)) } func zSIL(op, b1, d1, i2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(op), (uint8(b1)<<4)|uint8((d1>>8)&0x0F), uint8(d1), uint8(i2>>8), uint8(i2)) } func zSIY(op, i2, b1, d1 uint32, asm *[]byte) { dl1 := uint16(d1) & 0x0FFF *asm = append(*asm, uint8(op>>8), uint8(i2), (uint8(b1)<<4)|(uint8(dl1>>8)&0x0F), uint8(dl1), uint8(d1>>12), uint8(op)) } func zSMI(op, m1, b3, d3, ri2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(m1)<<4, (uint8(b3)<<4)|uint8((d3>>8)&0x0F), uint8(d3), uint8(ri2>>8), uint8(ri2)) } // Expected argument values for the instruction formats. // // Format a1 a2 a3 a4 a5 a6 // ------------------------------- // a l1, 0, b1, d1, b2, d2 // b l1, l2, b1, d1, b2, d2 // c l1, i3, b1, d1, b2, d2 // d r1, r3, b1, d1, b2, d2 // e r1, r3, b2, d2, b4, d4 // f 0, l2, b1, d1, b2, d2 func zSS(f form, op, l1_r1, l2_i3_r3, b1_b2, d1_d2, b2_b4, d2_d4 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8)) switch f { case _a: *asm = append(*asm, uint8(l1_r1)) case _b, _c, _d, _e: *asm = append(*asm, (uint8(l1_r1)<<4)|uint8(l2_i3_r3&0x0F)) case _f: *asm = append(*asm, uint8(l2_i3_r3)) } *asm = append(*asm, (uint8(b1_b2)<<4)|uint8((d1_d2>>8)&0x0F), uint8(d1_d2), (uint8(b2_b4)<<4)|uint8((d2_d4>>8)&0x0F), uint8(d2_d4)) } func zSSE(op, b1, d1, b2, d2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(op), (uint8(b1)<<4)|uint8((d1>>8)&0x0F), uint8(d1), (uint8(b2)<<4)|uint8((d2>>8)&0x0F), uint8(d2)) } func zSSF(op, r3, b1, d1, b2, d2 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(r3)<<4)|(uint8(op)&0x0F), (uint8(b1)<<4)|uint8((d1>>8)&0x0F), uint8(d1), (uint8(b2)<<4)|uint8((d2>>8)&0x0F), uint8(d2)) } func rxb(va, vb, vc, vd uint32) uint8 { mask := uint8(0) if va >= REG_V16 && va <= REG_V31 { mask |= 0x8 } if vb >= REG_V16 && vb <= REG_V31 { mask |= 0x4 } if vc >= REG_V16 && vc <= REG_V31 { mask |= 0x2 } if vd >= REG_V16 && vd <= REG_V31 { mask |= 0x1 } return mask } func zVRX(op, v1, x2, b2, d2, m3 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(x2)&0xf), (uint8(b2)<<4)|(uint8(d2>>8)&0xf), uint8(d2), (uint8(m3)<<4)|rxb(v1, 0, 0, 0), uint8(op)) } func zVRV(op, v1, v2, b2, d2, m3 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(v2)&0xf), (uint8(b2)<<4)|(uint8(d2>>8)&0xf), uint8(d2), (uint8(m3)<<4)|rxb(v1, v2, 0, 0), uint8(op)) } func zVRS(op, v1, v3_r3, b2, d2, m4 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(v3_r3)&0xf), (uint8(b2)<<4)|(uint8(d2>>8)&0xf), uint8(d2), (uint8(m4)<<4)|rxb(v1, v3_r3, 0, 0), uint8(op)) } func zVRRa(op, v1, v2, m5, m4, m3 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(v2)&0xf), 0, (uint8(m5)<<4)|(uint8(m4)&0xf), (uint8(m3)<<4)|rxb(v1, v2, 0, 0), uint8(op)) } func zVRRb(op, v1, v2, v3, m5, m4 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(v2)&0xf), uint8(v3)<<4, uint8(m5)<<4, (uint8(m4)<<4)|rxb(v1, v2, v3, 0), uint8(op)) } func zVRRc(op, v1, v2, v3, m6, m5, m4 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(v2)&0xf), uint8(v3)<<4, (uint8(m6)<<4)|(uint8(m5)&0xf), (uint8(m4)<<4)|rxb(v1, v2, v3, 0), uint8(op)) } func zVRRd(op, v1, v2, v3, m5, m6, v4 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(v2)&0xf), (uint8(v3)<<4)|(uint8(m5)&0xf), uint8(m6)<<4, (uint8(v4)<<4)|rxb(v1, v2, v3, v4), uint8(op)) } func zVRRe(op, v1, v2, v3, m6, m5, v4 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(v2)&0xf), (uint8(v3)<<4)|(uint8(m6)&0xf), uint8(m5), (uint8(v4)<<4)|rxb(v1, v2, v3, v4), uint8(op)) } func zVRRf(op, v1, r2, r3 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(r2)&0xf), uint8(r3)<<4, 0, rxb(v1, 0, 0, 0), uint8(op)) } func zVRIa(op, v1, i2, m3 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(v1)<<4, uint8(i2>>8), uint8(i2), (uint8(m3)<<4)|rxb(v1, 0, 0, 0), uint8(op)) } func zVRIb(op, v1, i2, i3, m4 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), uint8(v1)<<4, uint8(i2), uint8(i3), (uint8(m4)<<4)|rxb(v1, 0, 0, 0), uint8(op)) } func zVRIc(op, v1, v3, i2, m4 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(v3)&0xf), uint8(i2>>8), uint8(i2), (uint8(m4)<<4)|rxb(v1, v3, 0, 0), uint8(op)) } func zVRId(op, v1, v2, v3, i4, m5 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(v2)&0xf), uint8(v3)<<4, uint8(i4), (uint8(m5)<<4)|rxb(v1, v2, v3, 0), uint8(op)) } func zVRIe(op, v1, v2, i3, m5, m4 uint32, asm *[]byte) { *asm = append(*asm, uint8(op>>8), (uint8(v1)<<4)|(uint8(v2)&0xf), uint8(i3>>4), (uint8(i3)<<4)|(uint8(m5)&0xf), (uint8(m4)<<4)|rxb(v1, v2, 0, 0), uint8(op)) }