1 /* 2 * Copyright (c) 2016, 2017, Oracle and/or its affiliates. All rights reserved. 3 * Copyright (c) 2016, 2017 SAP SE. All rights reserved. 4 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. 5 * 6 * This code is free software; you can redistribute it and/or modify it 7 * under the terms of the GNU General Public License version 2 only, as 8 * published by the Free Software Foundation. 9 * 10 * This code is distributed in the hope that it will be useful, but WITHOUT 11 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or 12 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License 13 * version 2 for more details (a copy is included in the LICENSE file that 14 * accompanied this code). 15 * 16 * You should have received a copy of the GNU General Public License version 17 * 2 along with this work; if not, write to the Free Software Foundation, 18 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. 19 * 20 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA 21 * or visit www.oracle.com if you need additional information or have any 22 * questions. 23 * 24 */ 25 26 #ifndef CPU_S390_VM_ASSEMBLER_S390_INLINE_HPP 27 #define CPU_S390_VM_ASSEMBLER_S390_INLINE_HPP 28 29 #include "asm/assembler.inline.hpp" 30 #include "asm/codeBuffer.hpp" 31 #include "code/codeCache.hpp" 32 33 // Convention: Use Z_R0 and Z_R1 instead of Z_scratch_* in all 34 // assembler_s390.* files. 35 36 // Local implementation of byte emitters to help inlining. 37 inline void Assembler::emit_16(int x) { 38 CodeSection* cs = code_section(); 39 address code_pos = pc(); 40 *(unsigned short*)code_pos = (unsigned short)x; 41 cs->set_end( code_pos + sizeof(unsigned short)); 42 } 43 44 inline void Assembler::emit_32(int x) { 45 CodeSection* cs = code_section(); 46 address code_pos = pc(); 47 *(jint*)code_pos = (jint)x; 48 cs->set_end( code_pos + sizeof( jint)); 49 } 50 51 inline void Assembler::emit_48(long x) { 52 CodeSection* cs = code_section(); 53 address code_pos = pc(); 54 *(unsigned short*)code_pos = (unsigned short)(x>>32); 55 *(jint*)(code_pos+sizeof(unsigned short)) = (jint)x; 56 cs->set_end( code_pos + sizeof( jint) + sizeof( unsigned short)); 57 } 58 59 // Support lightweight sync (from z196). Experimental as of now. For explanation see *.hpp file. 60 inline void Assembler::z_sync() { 61 if (VM_Version::has_FastSync()) { 62 z_bcr(bcondLightSync, Z_R0); 63 } else { 64 z_bcr(bcondFullSync, Z_R0); 65 } 66 } 67 inline void Assembler::z_release() { } 68 inline void Assembler::z_acquire() { } 69 inline void Assembler::z_fence() { z_sync(); } 70 71 inline void Assembler::z_illtrap() { 72 emit_16(0); 73 } 74 inline void Assembler::z_illtrap(int id) { 75 emit_16(id & 0x00ff); 76 } 77 inline void Assembler::z_illtrap_eyecatcher(unsigned short xpattern, unsigned short pattern) { 78 z_llill(Z_R0, xpattern); 79 z_iilh(Z_R0, pattern); 80 z_illtrap((unsigned int)xpattern); 81 } 82 83 inline void Assembler::z_lhrl(Register r1, int64_t i2) { emit_48( LHRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 84 inline void Assembler::z_lrl(Register r1, int64_t i2) { emit_48( LRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 85 inline void Assembler::z_lghrl(Register r1, int64_t i2) { emit_48( LGHRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 86 inline void Assembler::z_lgfrl(Register r1, int64_t i2) { emit_48( LGFRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 87 inline void Assembler::z_lgrl(Register r1, int64_t i2) { emit_48( LGRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 88 inline void Assembler::z_llhrl(Register r1, int64_t i2) { emit_48( LLHRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 89 inline void Assembler::z_llghrl(Register r1, int64_t i2){ emit_48( LLGHRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 90 inline void Assembler::z_llgfrl(Register r1, int64_t i2){ emit_48( LLGFRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 91 92 inline void Assembler::z_sthrl(Register r1, int64_t i2) { emit_48( STHRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 93 inline void Assembler::z_strl(Register r1, int64_t i2) { emit_48( STRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 94 inline void Assembler::z_stgrl(Register r1, int64_t i2) { emit_48( STGRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 95 96 inline void Assembler::z_cksm(Register r1, Register r2) { emit_32( CKSM_ZOPC | regt(r1, 24, 32) | regt(r2, 28, 32)); } 97 inline void Assembler::z_km( Register r1, Register r2) { emit_32( KM_ZOPC | regt(r1, 24, 32) | regt(r2, 28, 32)); } 98 inline void Assembler::z_kmc( Register r1, Register r2) { emit_32( KMC_ZOPC | regt(r1, 24, 32) | regt(r2, 28, 32)); } 99 inline void Assembler::z_kimd(Register r1, Register r2) { emit_32( KIMD_ZOPC | regt(r1, 24, 32) | regt(r2, 28, 32)); } 100 inline void Assembler::z_klmd(Register r1, Register r2) { emit_32( KLMD_ZOPC | regt(r1, 24, 32) | regt(r2, 28, 32)); } 101 inline void Assembler::z_kmac(Register r1, Register r2) { emit_32( KMAC_ZOPC | regt(r1, 24, 32) | regt(r2, 28, 32)); } 102 103 inline void Assembler::z_exrl(Register r1, int64_t i2) { emit_48( EXRL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } // z10 104 inline void Assembler::z_exrl(Register r1, address a2) { emit_48( EXRL_ZOPC | regt(r1, 8, 48) | simm32(RelAddr::pcrel_off32(a2, pc()), 16, 48)); } // z10 105 106 inline void Assembler::z_ectg(int64_t d1, Register b1, int64_t d2, Register b2, Register r3) { emit_48( ECTG_ZOPC | reg(r3, 8, 48) | uimm12(d1, 20, 48) | reg(b1, 16, 48) | uimm12(d2, 36, 48) | reg(b2, 32, 48)); } 107 inline void Assembler::z_ecag(Register r1, Register r3, int64_t d2, Register b2) { emit_48( ECAG_ZOPC | reg(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | reg(b2, 16, 48)); } 108 109 110 //------------------------------ 111 // Interlocked-Update 112 //------------------------------ 113 inline void Assembler::z_laa( Register r1, Register r3, int64_t d2, Register b2) { emit_48( LAA_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 114 inline void Assembler::z_laag( Register r1, Register r3, int64_t d2, Register b2) { emit_48( LAAG_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 115 inline void Assembler::z_laal( Register r1, Register r3, int64_t d2, Register b2) { emit_48( LAAL_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 116 inline void Assembler::z_laalg(Register r1, Register r3, int64_t d2, Register b2) { emit_48( LAALG_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 117 inline void Assembler::z_lan( Register r1, Register r3, int64_t d2, Register b2) { emit_48( LAN_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 118 inline void Assembler::z_lang( Register r1, Register r3, int64_t d2, Register b2) { emit_48( LANG_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 119 inline void Assembler::z_lax( Register r1, Register r3, int64_t d2, Register b2) { emit_48( LAX_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 120 inline void Assembler::z_laxg( Register r1, Register r3, int64_t d2, Register b2) { emit_48( LAXG_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 121 inline void Assembler::z_lao( Register r1, Register r3, int64_t d2, Register b2) { emit_48( LAO_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 122 inline void Assembler::z_laog( Register r1, Register r3, int64_t d2, Register b2) { emit_48( LAOG_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 123 124 inline void Assembler::z_laa( Register r1, Register r3, const Address& a) { assert(!a.has_index(), " no index reg allowed"); z_laa( r1, r3, a.disp12(), a.base()); } 125 inline void Assembler::z_laag( Register r1, Register r3, const Address& a) { assert(!a.has_index(), " no index reg allowed"); z_laag( r1, r3, a.disp12(), a.base()); } 126 inline void Assembler::z_laal( Register r1, Register r3, const Address& a) { assert(!a.has_index(), " no index reg allowed"); z_laal( r1, r3, a.disp12(), a.base()); } 127 inline void Assembler::z_laalg(Register r1, Register r3, const Address& a) { assert(!a.has_index(), " no index reg allowed"); z_laalg(r1, r3, a.disp12(), a.base()); } 128 inline void Assembler::z_lan( Register r1, Register r3, const Address& a) { assert(!a.has_index(), " no index reg allowed"); z_lan( r1, r3, a.disp12(), a.base()); } 129 inline void Assembler::z_lang( Register r1, Register r3, const Address& a) { assert(!a.has_index(), " no index reg allowed"); z_lang( r1, r3, a.disp12(), a.base()); } 130 inline void Assembler::z_lax( Register r1, Register r3, const Address& a) { assert(!a.has_index(), " no index reg allowed"); z_lax( r1, r3, a.disp12(), a.base()); } 131 inline void Assembler::z_laxg( Register r1, Register r3, const Address& a) { assert(!a.has_index(), " no index reg allowed"); z_laxg( r1, r3, a.disp12(), a.base()); } 132 inline void Assembler::z_lao( Register r1, Register r3, const Address& a) { assert(!a.has_index(), " no index reg allowed"); z_lao( r1, r3, a.disp12(), a.base()); } 133 inline void Assembler::z_laog( Register r1, Register r3, const Address& a) { assert(!a.has_index(), " no index reg allowed"); z_laog( r1, r3, a.disp12(), a.base()); } 134 135 //-------------------------------- 136 // Execution Prediction 137 //-------------------------------- 138 inline void Assembler::z_pfd( int64_t m1, int64_t d2, Register x2, Register b2) { emit_48( PFD_ZOPC | uimm4(m1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 139 inline void Assembler::z_pfd( int64_t m1, Address a) { z_pfd(m1, a.disp(), a.indexOrR0(), a.base()); } 140 inline void Assembler::z_pfdrl(int64_t m1, int64_t i2) { emit_48( PFDRL_ZOPC | uimm4(m1, 8, 48) | simm32(i2, 16, 48)); } 141 inline void Assembler::z_bpp( int64_t m1, int64_t i2, int64_t d3, Register b3) { emit_48( BPP_ZOPC | uimm4(m1, 8, 48) | uimm12(d3, 20, 48) | reg(b3, 16, 48) | simm16(i2, 32, 48)); } 142 inline void Assembler::z_bprp( int64_t m1, int64_t i2, int64_t i3) { emit_48( BPRP_ZOPC | uimm4(m1, 8, 48) | simm12(i2, 12, 48) | simm24(i3, 24, 48)); } 143 144 //------------------------------- 145 // Transaction Control 146 //------------------------------- 147 inline void Assembler::z_tbegin( int64_t d1, Register b1, int64_t i2) { emit_48( TBEGIN_ZOPC | uimm12(d1, 20, 48) | reg(b1, 16, 48) | uimm16(i2, 32, 48)); } 148 inline void Assembler::z_tbeginc(int64_t d1, Register b1, int64_t i2) { emit_48( TBEGINC_ZOPC | uimm12(d1, 20, 48) | reg(b1, 16, 48) | uimm16(i2, 32, 48)); } 149 inline void Assembler::z_tend() { emit_32( TEND_ZOPC); } 150 inline void Assembler::z_tabort( int64_t d2, Register b2) { emit_32( TABORT_ZOPC | uimm12(d2, 20, 32) | reg(b2, 16, 32)); } 151 inline void Assembler::z_etnd(Register r1) { emit_32( ETND_ZOPC | regt(r1, 24, 32)); } 152 inline void Assembler::z_ppa(Register r1, Register r2, int64_t m3) { emit_32( PPA_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32) | uimm4(m3, 16, 32)); } 153 154 //--------------------------------- 155 // Conditional Execution 156 //--------------------------------- 157 inline void Assembler::z_locr( Register r1, Register r2, branch_condition cc) { emit_32( LOCR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | uimm4(cc, 16, 32)); } // z196 158 inline void Assembler::z_locgr( Register r1, Register r2, branch_condition cc) { emit_32( LOCGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | uimm4(cc, 16, 32)); } // z196 159 inline void Assembler::z_loc( Register r1, int64_t d2, Register b2, branch_condition cc) { emit_48( LOC_ZOPC | regt(r1, 8, 48) | simm20(d2) | regz(b2, 16, 48) | uimm4(cc, 12, 48)); } // z196 160 inline void Assembler::z_locg( Register r1, int64_t d2, Register b2, branch_condition cc) { emit_48( LOCG_ZOPC | regt(r1, 8, 48) | simm20(d2) | regz(b2, 16, 48) | uimm4(cc, 12, 48)); } // z196 161 inline void Assembler::z_loc( Register r1, const Address &a, branch_condition cc) { z_loc(r1, a.disp(), a.base(), cc); } 162 inline void Assembler::z_locg( Register r1, const Address &a, branch_condition cc) { z_locg(r1, a.disp(), a.base(), cc); } 163 inline void Assembler::z_stoc( Register r1, int64_t d2, Register b2, branch_condition cc) { emit_48( STOC_ZOPC | regt(r1, 8, 48) | simm20(d2) | regz(b2, 16, 48) | uimm4(cc, 12, 48)); } // z196 164 inline void Assembler::z_stocg( Register r1, int64_t d2, Register b2, branch_condition cc) { emit_48( STOCG_ZOPC | regt(r1, 8, 48) | simm20(d2) | regz(b2, 16, 48) | uimm4(cc, 12, 48)); } // z196 165 166 inline void Assembler::z_srst( Register r1, Register r2) { emit_32( SRST_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 167 inline void Assembler::z_srstu(Register r1, Register r2) { emit_32( SRSTU_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 168 169 //--------------------------------- 170 // Address calculation 171 //--------------------------------- 172 inline void Assembler::z_layz(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LAY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | reg(b2, 16, 48)); } 173 inline void Assembler::z_lay( Register r1, const Address &a) { z_layz(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 174 inline void Assembler::z_lay( Register r1, int64_t d2, Register x2, Register b2) { emit_48( LAY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 175 inline void Assembler::z_laz( Register r1, int64_t d2, Register x2, Register b2) { emit_32( LA_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | reg(b2, 16, 32)); } 176 inline void Assembler::z_la( Register r1, const Address &a) { z_laz(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 177 inline void Assembler::z_la( Register r1, int64_t d2, Register x2, Register b2) { emit_32( LA_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32));} 178 inline void Assembler::z_larl(Register r1, int64_t i2) { emit_48( LARL_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 179 inline void Assembler::z_larl(Register r1, address a) { emit_48( LARL_ZOPC | regt(r1, 8, 48) | simm32(RelAddr::pcrel_off32(a, pc()), 16, 48)); } 180 181 inline void Assembler::z_lr(Register r1, Register r2) { emit_16( LR_ZOPC | regt(r1,8,16) | reg(r2,12,16)); } 182 inline void Assembler::z_lgr(Register r1, Register r2) { emit_32( LGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 183 inline void Assembler::z_lh(Register r1, int64_t d2, Register x2, Register b2) { emit_32( LH_ZOPC | 0 << 16 | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 184 inline void Assembler::z_lh(Register r1, const Address &a) { z_lh(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 185 inline void Assembler::z_l(Register r1, int64_t d2, Register x2, Register b2) { emit_32( L_ZOPC | 0 << 16 | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 186 inline void Assembler::z_l(Register r1, const Address &a) { z_l(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 187 inline void Assembler::z_lg(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 188 inline void Assembler::z_lg(Register r1, const Address &a) { z_lg(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 189 190 inline void Assembler::z_lbr( Register r1, Register r2) { emit_32( LBR_ZOPC | regt(r1, 24, 32) | reg( r2, 28, 32)); } 191 inline void Assembler::z_lhr( Register r1, Register r2) { emit_32( LHR_ZOPC | regt(r1, 24, 32) | reg( r2, 28, 32)); } 192 inline void Assembler::z_lgbr( Register r1, Register r2) { emit_32( LGBR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 193 inline void Assembler::z_lghr( Register r1, Register r2) { emit_32( LGHR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 194 inline void Assembler::z_lgfr( Register r1, Register r2) { emit_32( LGFR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 195 inline void Assembler::z_llhr( Register r1, Register r2) { emit_32( LLHR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 196 inline void Assembler::z_llgcr(Register r1, Register r2) { emit_32( LLGCR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 197 inline void Assembler::z_llghr(Register r1, Register r2) { emit_32( LLGHR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 198 inline void Assembler::z_llgfr(Register r1, Register r2) { emit_32( LLGFR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 199 200 inline void Assembler::z_sth(Register r1, const Address &a) { z_sth(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 201 inline void Assembler::z_sth(Register r1, int64_t d2, Register x2, Register b2) { emit_32( STH_ZOPC | reg(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 202 inline void Assembler::z_st( Register r1, const Address& d) { z_st(r1, d.disp(), d.indexOrR0(), d.base()); } 203 inline void Assembler::z_st( Register r1, int64_t d2, Register x2, Register b2) { emit_32( ST_ZOPC | reg(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 204 inline void Assembler::z_stg(Register r1, const Address& d) { z_stg(r1, d.disp(), d.indexOrR0(), d.base()); } 205 inline void Assembler::z_stg(Register r1, int64_t d2, Register x2, Register b2) { emit_48( STG_ZOPC | reg(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 206 207 inline void Assembler::z_stcm (Register r1, int64_t m3, int64_t d2, Register b2) { emit_32( STCM_ZOPC | regt(r1, 8, 32) | uimm4(m3, 12, 32) | uimm12(d2, 20, 32) | regz(b2, 16, 32)); } 208 inline void Assembler::z_stcmy(Register r1, int64_t m3, int64_t d2, Register b2) { emit_48( STCMY_ZOPC | regt(r1, 8, 48) | uimm4(m3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 209 inline void Assembler::z_stcmh(Register r1, int64_t m3, int64_t d2, Register b2) { emit_48( STCMH_ZOPC | regt(r1, 8, 48) | uimm4(m3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 210 211 // memory-immediate instructions (8-bit immediate) 212 inline void Assembler::z_cli( int64_t d1, Register b1, int64_t i2) { emit_32( CLI_ZOPC | uimm12(d1, 20, 32) | regz(b1, 16, 32) | uimm8(i2, 8, 32)); } 213 inline void Assembler::z_mvi( int64_t d1, Register b1, int64_t i2) { emit_32( MVI_ZOPC | uimm12(d1, 20, 32) | regz(b1, 16, 32) | imm8(i2, 8, 32)); } 214 inline void Assembler::z_tm( int64_t d1, Register b1, int64_t i2) { emit_32( TM_ZOPC | uimm12(d1, 20, 32) | regz(b1, 16, 32) | imm8(i2, 8, 32)); } 215 inline void Assembler::z_ni( int64_t d1, Register b1, int64_t i2) { emit_32( NI_ZOPC | uimm12(d1, 20, 32) | regz(b1, 16, 32) | imm8(i2, 8, 32)); } 216 inline void Assembler::z_oi( int64_t d1, Register b1, int64_t i2) { emit_32( OI_ZOPC | uimm12(d1, 20, 32) | regz(b1, 16, 32) | imm8(i2, 8, 32)); } 217 inline void Assembler::z_xi( int64_t d1, Register b1, int64_t i2) { emit_32( XI_ZOPC | uimm12(d1, 20, 32) | regz(b1, 16, 32) | imm8(i2, 8, 32)); } 218 inline void Assembler::z_cliy(int64_t d1, Register b1, int64_t i2) { emit_48( CLIY_ZOPC | simm20(d1) | regz(b1, 16, 48) | uimm8(i2, 8, 48)); } 219 inline void Assembler::z_mviy(int64_t d1, Register b1, int64_t i2) { emit_48( MVIY_ZOPC | simm20(d1) | regz(b1, 16, 48) | imm8(i2, 8, 48)); } 220 inline void Assembler::z_tmy( int64_t d1, Register b1, int64_t i2) { emit_48( TMY_ZOPC | simm20(d1) | regz(b1, 16, 48) | imm8(i2, 8, 48)); } 221 inline void Assembler::z_niy( int64_t d1, Register b1, int64_t i2) { emit_48( NIY_ZOPC | simm20(d1) | regz(b1, 16, 48) | imm8(i2, 8, 48)); } 222 inline void Assembler::z_oiy( int64_t d1, Register b1, int64_t i2) { emit_48( OIY_ZOPC | simm20(d1) | regz(b1, 16, 48) | imm8(i2, 8, 48)); } 223 inline void Assembler::z_xiy( int64_t d1, Register b1, int64_t i2) { emit_48( XIY_ZOPC | simm20(d1) | regz(b1, 16, 48) | imm8(i2, 8, 48)); } 224 225 inline void Assembler::z_cli( const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in CLI"); z_cli( a.disp12(), a.base(), imm); } 226 inline void Assembler::z_mvi( const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in CLI"); z_mvi( a.disp12(), a.base(), imm); } 227 inline void Assembler::z_tm( const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in CLI"); z_tm( a.disp12(), a.base(), imm); } 228 inline void Assembler::z_ni( const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in CLI"); z_ni( a.disp12(), a.base(), imm); } 229 inline void Assembler::z_oi( const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in CLI"); z_oi( a.disp12(), a.base(), imm); } 230 inline void Assembler::z_xi( const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in CLI"); z_xi( a.disp12(), a.base(), imm); } 231 inline void Assembler::z_cliy(const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in CLIY"); z_cliy(a.disp20(), a.base(), imm); } 232 inline void Assembler::z_mviy(const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in MVIY"); z_mviy(a.disp20(), a.base(), imm); } 233 inline void Assembler::z_tmy( const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in TMY"); z_tmy( a.disp20(), a.base(), imm); } 234 inline void Assembler::z_niy( const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in NIY"); z_niy( a.disp20(), a.base(), imm); } 235 inline void Assembler::z_oiy( const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in OIY"); z_oiy( a.disp20(), a.base(), imm); } 236 inline void Assembler::z_xiy( const Address& a, int64_t imm) { assert(!a.has_index(), " no index reg allowed in XIY"); z_xiy( a.disp20(), a.base(), imm); } 237 238 239 inline void Assembler::z_mvc(const Address& d, const Address& s, int64_t l) { 240 assert(!d.has_index() && !s.has_index(), "Address operand can not be encoded."); 241 z_mvc(d.disp(), l-1, d.base(), s.disp(), s.base()); 242 } 243 inline void Assembler::z_mvc(int64_t d1, int64_t l, Register b1, int64_t d2, Register b2) { emit_48( MVC_ZOPC | uimm12(d1, 20, 48) | uimm8(l, 8, 48) | regz(b1, 16, 48) | uimm12(d2, 36, 48) | regz(b2, 32, 48)); } 244 inline void Assembler::z_mvcle(Register r1, Register r3, int64_t d2, Register b2) { emit_32( MVCLE_ZOPC | reg(r1, 8, 32) | reg(r3, 12, 32) | uimm12(d2, 20, 32) | reg(b2, 16, 32)); } 245 246 inline void Assembler::z_mvhhi( int64_t d1, Register b1, int64_t i2) { emit_48( MVHHI_ZOPC | uimm12( d1, 20, 48) | regz(b1, 16, 48) | simm16(i2, 32, 48)); } 247 inline void Assembler::z_mvhi ( int64_t d1, Register b1, int64_t i2) { emit_48( MVHI_ZOPC | uimm12( d1, 20, 48) | regz(b1, 16, 48) | simm16(i2, 32, 48)); } 248 inline void Assembler::z_mvghi( int64_t d1, Register b1, int64_t i2) { emit_48( MVGHI_ZOPC | uimm12( d1, 20, 48) | regz(b1, 16, 48) | simm16(i2, 32, 48)); } 249 inline void Assembler::z_mvhhi( const Address &d, int64_t i2) { assert(!d.has_index(), " no index reg allowed in MVHHI"); z_mvhhi( d.disp(), d.baseOrR0(), i2); } 250 inline void Assembler::z_mvhi ( const Address &d, int64_t i2) { assert(!d.has_index(), " no index reg allowed in MVHI"); z_mvhi( d.disp(), d.baseOrR0(), i2); } 251 inline void Assembler::z_mvghi( const Address &d, int64_t i2) { assert(!d.has_index(), " no index reg allowed in MVGHI"); z_mvghi( d.disp(), d.baseOrR0(), i2); } 252 253 inline void Assembler::z_ex(Register r1, int64_t d2, Register x2, Register b2) { emit_32( EX_ZOPC | regz(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 254 255 inline void Assembler::z_ic (Register r1, int64_t d2, Register x2, Register b2) { emit_32( IC_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 256 inline void Assembler::z_icy (Register r1, int64_t d2, Register x2, Register b2) { emit_48( ICY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 257 inline void Assembler::z_icm (Register r1, int64_t m3, int64_t d2, Register b2) { emit_32( ICM_ZOPC | regt(r1, 8, 32) | uimm4(m3, 12, 32) | uimm12(d2, 20, 32) | regz(b2, 16, 32)); } 258 inline void Assembler::z_icmy(Register r1, int64_t m3, int64_t d2, Register b2) { emit_48( ICMY_ZOPC | regt(r1, 8, 48) | uimm4(m3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 259 inline void Assembler::z_icmh(Register r1, int64_t m3, int64_t d2, Register b2) { emit_48( ICMH_ZOPC | regt(r1, 8, 48) | uimm4(m3, 12, 48) | simm20(d2) | regz(b2, 16, 48)); } 260 inline void Assembler::z_iihh(Register r1, int64_t i2) { emit_32( IIHH_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 261 inline void Assembler::z_iihl(Register r1, int64_t i2) { emit_32( IIHL_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 262 inline void Assembler::z_iilh(Register r1, int64_t i2) { emit_32( IILH_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 263 inline void Assembler::z_iill(Register r1, int64_t i2) { emit_32( IILL_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 264 inline void Assembler::z_iihf(Register r1, int64_t i2) { emit_48( IIHF_ZOPC | regt(r1, 8, 48) | imm32(i2, 16, 48)); } 265 inline void Assembler::z_iilf(Register r1, int64_t i2) { emit_48( IILF_ZOPC | regt(r1, 8, 48) | imm32(i2, 16, 48)); } 266 inline void Assembler::z_lgf(Register r1, const Address& a) { z_lgf(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 267 inline void Assembler::z_lgf(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LGF_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 268 inline void Assembler::z_lhy(Register r1, const Address &a) { z_lhy(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 269 inline void Assembler::z_lhy(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LHY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 270 inline void Assembler::z_lgh(Register r1, const Address &a) { z_lgh(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 271 inline void Assembler::z_lgh(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LGH_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 272 inline void Assembler::z_lt(Register r1, const Address &a) { z_lt(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 273 inline void Assembler::z_lt (Register r1, int64_t d2, Register x2, Register b2) { emit_48( LT_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 274 inline void Assembler::z_ltg(Register r1, const Address &a) { z_ltg(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 275 inline void Assembler::z_ltg(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LTG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 276 inline void Assembler::z_ltgf(Register r1, const Address &a) { z_ltgf(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 277 inline void Assembler::z_ltgf(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LTGF_ZOPC| regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 278 inline void Assembler::z_lb(Register r1, const Address &a) { z_lb(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 279 inline void Assembler::z_lb (Register r1, int64_t d2, Register x2, Register b2) { emit_48( LB_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 280 inline void Assembler::z_lgb(Register r1, const Address &a) { z_lgb(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 281 inline void Assembler::z_lgb(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LGB_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 282 inline void Assembler::z_ly(Register r1, const Address &a) { z_ly(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 283 inline void Assembler::z_ly(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 284 inline void Assembler::z_llc(Register r1, const Address& a) { z_llc(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 285 inline void Assembler::z_llc(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LLC_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 286 inline void Assembler::z_llh(Register r1, const Address &a) { z_llh(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 287 inline void Assembler::z_llh(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LLH_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 288 inline void Assembler::z_llgf(Register r1, const Address &a) { z_llgf(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 289 inline void Assembler::z_llgf(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LLGF_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 290 inline void Assembler::z_llgh(Register r1, const Address &a) { z_llgh(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 291 inline void Assembler::z_llgh(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LLGH_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 292 inline void Assembler::z_llgc(Register r1, const Address &a) { z_llgc(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 293 inline void Assembler::z_llgc(Register r1, int64_t d2, Register x2, Register b2) { emit_48( LLGC_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 294 inline void Assembler::z_llgc(Register r1, int64_t d2, Register b2) { z_llgc( r1, d2, Z_R0, b2); } 295 inline void Assembler::z_lhi(Register r1, int64_t i2) { emit_32( LHI_ZOPC | regt(r1, 8, 32) | simm16(i2, 16, 32)); } 296 inline void Assembler::z_lghi(Register r1, int64_t i2) { emit_32( LGHI_ZOPC | regt(r1, 8, 32) | simm16(i2, 16, 32)); } 297 inline void Assembler::z_lgfi(Register r1, int64_t i2) { emit_48( LGFI_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 298 inline void Assembler::z_llihf(Register r1, int64_t i2) { emit_48( LLIHF_ZOPC | regt(r1, 8, 48) | imm32(i2, 16, 48)); } 299 inline void Assembler::z_llilf(Register r1, int64_t i2) { emit_48( LLILF_ZOPC | regt(r1, 8, 48) | imm32(i2, 16, 48)); } 300 inline void Assembler::z_llihh(Register r1, int64_t i2) { emit_32( LLIHH_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 301 inline void Assembler::z_llihl(Register r1, int64_t i2) { emit_32( LLIHL_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 302 inline void Assembler::z_llilh(Register r1, int64_t i2) { emit_32( LLILH_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 303 inline void Assembler::z_llill(Register r1, int64_t i2) { emit_32( LLILL_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 304 305 // allow "monadic" use 306 inline void Assembler::z_lcr( Register r1, Register r2) { emit_16( LCR_ZOPC | regt( r1, 8, 16) | reg((r2 == noreg) ? r1:r2, 12, 16)); } 307 inline void Assembler::z_lcgr( Register r1, Register r2) { emit_32( LCGR_ZOPC | regt( r1, 24, 32) | reg((r2 == noreg) ? r1:r2, 28, 32)); } 308 inline void Assembler::z_lcgfr(Register r1, Register r2) { emit_32( LCGFR_ZOPC | regt( r1, 24, 32) | reg((r2 == noreg) ? r1:r2, 28, 32)); } 309 inline void Assembler::z_lnr( Register r1, Register r2) { emit_16( LNR_ZOPC | regt( r1, 8, 16) | reg((r2 == noreg) ? r1:r2, 12, 16)); } 310 inline void Assembler::z_lngr( Register r1, Register r2) { emit_32( LNGR_ZOPC | regt( r1, 24, 32) | reg((r2 == noreg) ? r1:r2, 28, 32)); } 311 inline void Assembler::z_lngfr(Register r1, Register r2) { emit_32( LNGFR_ZOPC | regt( r1, 24, 32) | reg((r2 == noreg) ? r1:r2, 28, 32)); } 312 313 inline void Assembler::z_lrvr( Register r1, Register r2) { emit_32( LRVR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 314 inline void Assembler::z_lrvgr(Register r1, Register r2) { emit_32( LRVGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 315 316 inline void Assembler::z_ltr( Register r1, Register r2) { emit_16( LTR_ZOPC | regt(r1, 8, 16) | reg(r2, 12, 16)); } 317 inline void Assembler::z_ltgr( Register r1, Register r2) { emit_32( LTGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 318 inline void Assembler::z_ltgfr(Register r1, Register r2) { emit_32( LTGFR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 319 inline void Assembler::z_stc( Register r1, const Address &a) { z_stc(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 320 inline void Assembler::z_stc( Register r1, int64_t d2, Register x2, Register b2) { emit_32( STC_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 321 inline void Assembler::z_stcy( Register r1, const Address &a) { z_stcy(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 322 inline void Assembler::z_stcy( Register r1, int64_t d2, Register x2, Register b2) { emit_48( STCY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 323 inline void Assembler::z_sthy( Register r1, const Address &a) { z_sthy(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 324 inline void Assembler::z_sthy( Register r1, int64_t d2, Register x2, Register b2) { emit_48( STHY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 325 inline void Assembler::z_sty( Register r1, const Address &a) { z_sty(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 326 inline void Assembler::z_sty( Register r1, int64_t d2, Register x2, Register b2) { emit_48( STY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 327 inline void Assembler::z_stfle(int64_t d2, Register b2) { emit_32(STFLE_ZOPC | uimm12(d2,20,32) | regz(b2,16,32)); } 328 329 330 //----------------------------------- 331 // SHIFT/RORATE OPERATIONS 332 //----------------------------------- 333 inline void Assembler::z_sla( Register r1, int64_t d2, Register b2) { emit_32( SLA_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(b2, 16, 32)); } 334 inline void Assembler::z_slag(Register r1, Register r3, int64_t d2, Register b2) { emit_48( SLAG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(b2, 16, 48) | reg(r3, 12, 48)); } 335 inline void Assembler::z_sra( Register r1, int64_t d2, Register b2) { emit_32( SRA_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(b2, 16, 32)); } 336 inline void Assembler::z_srag(Register r1, Register r3, int64_t d2, Register b2) { emit_48( SRAG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(b2, 16, 48) | reg(r3, 12, 48)); } 337 inline void Assembler::z_sll( Register r1, int64_t d2, Register b2) { emit_32( SLL_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(b2, 16, 32)); } 338 inline void Assembler::z_sllg(Register r1, Register r3, int64_t d2, Register b2) { emit_48( SLLG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(b2, 16, 48) | reg(r3, 12, 48)); } 339 inline void Assembler::z_srl( Register r1, int64_t d2, Register b2) { emit_32( SRL_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(b2, 16, 32)); } 340 inline void Assembler::z_srlg(Register r1, Register r3, int64_t d2, Register b2) { emit_48( SRLG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(b2, 16, 48) | reg(r3, 12, 48)); } 341 342 // rotate left 343 inline void Assembler::z_rll( Register r1, Register r3, int64_t d2, Register b2) { emit_48( RLL_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | reg(b2, 16, 48)); } 344 inline void Assembler::z_rllg(Register r1, Register r3, int64_t d2, Register b2) { emit_48( RLLG_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm20(d2) | reg(b2, 16, 48)); } 345 346 // Rotate the AND/XOR/OR/insert 347 inline void Assembler::z_rnsbg( Register r1, Register r2, int64_t spos3, int64_t epos4, int64_t nrot5, bool test_only) { // Rotate then AND selected bits. -- z196 348 const int64_t len = 48; 349 assert(Immediate::is_uimm(spos3, 6), "range start out of range"); // Could just trim to 6bits wide w/o assertion. 350 assert(Immediate::is_uimm(epos4, 6), "range end out of range"); // Could just trim to 6bits wide w/o assertion. 351 assert(Immediate::is_uimm(nrot5, 6), "rotate amount out of range"); // Could just leave it as is. leftmost 2 bits are ignored by instruction. 352 emit_48( RNSBG_ZOPC | regt(r1, 8, len) | regt(r2, 12, len) | uimm6(spos3, 16+2, len) | uimm6(epos4, 24+2, len) | uimm6(nrot5, 32+2, len) | u_field(test_only ? 1 : 0, len-16-1, len-16-1)); 353 } 354 inline void Assembler::z_rxsbg( Register r1, Register r2, int64_t spos3, int64_t epos4, int64_t nrot5, bool test_only) { // Rotate then XOR selected bits. -- z196 355 const int64_t len = 48; 356 assert(Immediate::is_uimm(spos3, 6), "range start out of range"); // Could just trim to 6bits wide w/o assertion. 357 assert(Immediate::is_uimm(epos4, 6), "range end out of range"); // Could just trim to 6bits wide w/o assertion. 358 assert(Immediate::is_uimm(nrot5, 6), "rotate amount out of range"); // Could just leave it as is. leftmost 2 bits are ignored by instruction. 359 emit_48( RXSBG_ZOPC | regt(r1, 8, len) | regt(r2, 12, len) | uimm6(spos3, 16+2, len) | uimm6(epos4, 24+2, len) | uimm6(nrot5, 32+2, len) | u_field(test_only ? 1 : 0, len-16-1, len-16-1)); 360 } 361 inline void Assembler::z_rosbg( Register r1, Register r2, int64_t spos3, int64_t epos4, int64_t nrot5, bool test_only) { // Rotate then OR selected bits. -- z196 362 const int64_t len = 48; 363 assert(Immediate::is_uimm(spos3, 6), "range start out of range"); // Could just trim to 6bits wide w/o assertion. 364 assert(Immediate::is_uimm(epos4, 6), "range end out of range"); // Could just trim to 6bits wide w/o assertion. 365 assert(Immediate::is_uimm(nrot5, 6), "rotate amount out of range"); // Could just leave it as is. leftmost 2 bits are ignored by instruction. 366 emit_48( ROSBG_ZOPC | regt(r1, 8, len) | regt(r2, 12, len) | uimm6(spos3, 16+2, len) | uimm6(epos4, 24+2, len) | uimm6(nrot5, 32+2, len) | u_field(test_only ? 1 : 0, len-16-1, len-16-1)); 367 } 368 inline void Assembler::z_risbg( Register r1, Register r2, int64_t spos3, int64_t epos4, int64_t nrot5, bool zero_rest) { // Rotate then INS selected bits. -- z196 369 const int64_t len = 48; 370 assert(Immediate::is_uimm(spos3, 6), "range start out of range"); // Could just trim to 6bits wide w/o assertion. 371 assert(Immediate::is_uimm(epos4, 6), "range end out of range"); // Could just trim to 6bits wide w/o assertion. 372 assert(Immediate::is_uimm(nrot5, 6), "rotate amount out of range"); // Could just leave it as is. leftmost 2 bits are ignored by instruction. 373 emit_48( RISBG_ZOPC | regt(r1, 8, len) | regt(r2, 12, len) | uimm6(spos3, 16+2, len) | uimm6(epos4, 24+2, len) | uimm6(nrot5, 32+2, len) | u_field(zero_rest ? 1 : 0, len-24-1, len-24-1)); 374 } 375 376 377 //------------------------------ 378 // LOGICAL OPERATIONS 379 //------------------------------ 380 inline void Assembler::z_n( Register r1, int64_t d2, Register x2, Register b2) { emit_32( N_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 381 inline void Assembler::z_ny( Register r1, int64_t d2, Register x2, Register b2) { emit_48( NY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 382 inline void Assembler::z_ng( Register r1, int64_t d2, Register x2, Register b2) { emit_48( NG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 383 inline void Assembler::z_n( Register r1, const Address& a) { z_n( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 384 inline void Assembler::z_ny( Register r1, const Address& a) { z_ny(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 385 inline void Assembler::z_ng( Register r1, const Address& a) { z_ng(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 386 387 inline void Assembler::z_nr( Register r1, Register r2) { emit_16( NR_ZOPC | regt(r1, 8, 16) | reg(r2, 12, 16)); } 388 inline void Assembler::z_ngr( Register r1, Register r2) { emit_32( NGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 389 inline void Assembler::z_nrk( Register r1, Register r2, Register r3) { emit_32( NRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 390 inline void Assembler::z_ngrk(Register r1, Register r2, Register r3) { emit_32( NGRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 391 392 inline void Assembler::z_nihh(Register r1, int64_t i2) { emit_32( NIHH_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 393 inline void Assembler::z_nihl(Register r1, int64_t i2) { emit_32( NIHL_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 394 inline void Assembler::z_nilh(Register r1, int64_t i2) { emit_32( NILH_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 395 inline void Assembler::z_nill(Register r1, int64_t i2) { emit_32( NILL_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 396 inline void Assembler::z_nihf(Register r1, int64_t i2) { emit_48( NIHF_ZOPC | regt(r1, 8, 48) | imm32(i2, 16, 48)); } 397 inline void Assembler::z_nilf(Register r1, int64_t i2) { emit_48( NILF_ZOPC | regt(r1, 8, 48) | imm32(i2, 16, 48)); } 398 399 inline void Assembler::z_o( Register r1, int64_t d2, Register x2, Register b2) { emit_32( O_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 400 inline void Assembler::z_oy( Register r1, int64_t d2, Register x2, Register b2) { emit_48( OY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 401 inline void Assembler::z_og( Register r1, int64_t d2, Register x2, Register b2) { emit_48( OG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 402 inline void Assembler::z_o( Register r1, const Address& a) { z_o( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 403 inline void Assembler::z_oy( Register r1, const Address& a) { z_oy(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 404 inline void Assembler::z_og( Register r1, const Address& a) { z_og(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 405 406 inline void Assembler::z_or( Register r1, Register r2) { emit_16( OR_ZOPC | regt(r1, 8, 16) | reg(r2, 12, 16)); } 407 inline void Assembler::z_ogr( Register r1, Register r2) { emit_32( OGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 408 inline void Assembler::z_ork( Register r1, Register r2, Register r3) { emit_32( ORK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 409 inline void Assembler::z_ogrk(Register r1, Register r2, Register r3) { emit_32( OGRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 410 411 inline void Assembler::z_oihh(Register r1, int64_t i2) { emit_32( OIHH_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 412 inline void Assembler::z_oihl(Register r1, int64_t i2) { emit_32( OIHL_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 413 inline void Assembler::z_oilh(Register r1, int64_t i2) { emit_32( OILH_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 414 inline void Assembler::z_oill(Register r1, int64_t i2) { emit_32( OILL_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 415 inline void Assembler::z_oihf(Register r1, int64_t i2) { emit_48( OIHF_ZOPC | regt(r1, 8, 48) | imm32(i2, 16, 48)); } 416 inline void Assembler::z_oilf(Register r1, int64_t i2) { emit_48( OILF_ZOPC | regt(r1, 8, 48) | imm32(i2, 16, 48)); } 417 418 inline void Assembler::z_x( Register r1, int64_t d2, Register x2, Register b2) { emit_32( X_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 419 inline void Assembler::z_xy( Register r1, int64_t d2, Register x2, Register b2) { emit_48( XY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 420 inline void Assembler::z_xg( Register r1, int64_t d2, Register x2, Register b2) { emit_48( XG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 421 inline void Assembler::z_x( Register r1, const Address& a) { z_x( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 422 inline void Assembler::z_xy( Register r1, const Address& a) { z_xy(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 423 inline void Assembler::z_xg( Register r1, const Address& a) { z_xg(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 424 425 inline void Assembler::z_xr( Register r1, Register r2) { emit_16( XR_ZOPC | regt(r1, 8, 16) | reg(r2, 12, 16)); } 426 inline void Assembler::z_xgr( Register r1, Register r2) { emit_32( XGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 427 inline void Assembler::z_xrk( Register r1, Register r2, Register r3) { emit_32( XRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 428 inline void Assembler::z_xgrk(Register r1, Register r2, Register r3) { emit_32( XGRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 429 430 inline void Assembler::z_xihf(Register r1, int64_t i2) { emit_48( XIHF_ZOPC | regt(r1, 8, 48) | imm32(i2, 16, 48)); } 431 inline void Assembler::z_xilf(Register r1, int64_t i2) { emit_48( XILF_ZOPC | regt(r1, 8, 48) | imm32(i2, 16, 48)); } 432 433 inline void Assembler::z_nc(int64_t d1, int64_t l, Register b1, int64_t d2, Register b2) { emit_48( NC_ZOPC | uimm12(d1, 20, 48) | uimm8(l, 8, 48) | regz(b1, 16, 48) | uimm12(d2, 36, 48) | regz(b2, 32, 48)); } 434 inline void Assembler::z_oc(int64_t d1, int64_t l, Register b1, int64_t d2, Register b2) { emit_48( OC_ZOPC | uimm12(d1, 20, 48) | uimm8(l, 8, 48) | regz(b1, 16, 48) | uimm12(d2, 36, 48) | regz(b2, 32, 48)); } 435 inline void Assembler::z_xc(int64_t d1, int64_t l, Register b1, int64_t d2, Register b2) { emit_48( XC_ZOPC | uimm12(d1, 20, 48) | uimm8(l, 8, 48) | regz(b1, 16, 48) | uimm12(d2, 36, 48) | regz(b2, 32, 48)); } 436 inline void Assembler::z_nc(Address dst, int64_t len, Address src2) { assert(!dst.has_index() && !src2.has_index(), "Cannot encode index"); z_nc(dst.disp12(), len-1, dst.base(), src2.disp12(), src2.base()); } 437 inline void Assembler::z_oc(Address dst, int64_t len, Address src2) { assert(!dst.has_index() && !src2.has_index(), "Cannot encode index"); z_oc(dst.disp12(), len-1, dst.base(), src2.disp12(), src2.base()); } 438 inline void Assembler::z_xc(Address dst, int64_t len, Address src2) { assert(!dst.has_index() && !src2.has_index(), "Cannot encode index"); z_xc(dst.disp12(), len-1, dst.base(), src2.disp12(), src2.base()); } 439 440 441 //--------------- 442 // ADD 443 //--------------- 444 inline void Assembler::z_a( Register r1, int64_t d2, Register x2, Register b2) { emit_32( A_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 445 inline void Assembler::z_ay( Register r1, int64_t d2, Register x2, Register b2) { emit_48( AY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 446 inline void Assembler::z_al( Register r1, int64_t d2, Register x2, Register b2) { emit_32( AL_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 447 inline void Assembler::z_aly( Register r1, int64_t d2, Register x2, Register b2) { emit_48( ALY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 448 inline void Assembler::z_ag( Register r1, int64_t d2, Register x2, Register b2) { emit_48( AG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 449 inline void Assembler::z_agf( Register r1, int64_t d2, Register x2, Register b2) { emit_48( AGF_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 450 inline void Assembler::z_alg( Register r1, int64_t d2, Register x2, Register b2) { emit_48( ALG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 451 inline void Assembler::z_algf(Register r1, int64_t d2, Register x2, Register b2) { emit_48( ALGF_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 452 inline void Assembler::z_a( Register r1, const Address& a) { z_a( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 453 inline void Assembler::z_ay( Register r1, const Address& a) { z_ay( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 454 inline void Assembler::z_al( Register r1, const Address& a) { z_al( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 455 inline void Assembler::z_aly( Register r1, const Address& a) { z_aly( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 456 inline void Assembler::z_ag( Register r1, const Address& a) { z_ag( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 457 inline void Assembler::z_agf( Register r1, const Address& a) { z_agf( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 458 inline void Assembler::z_alg( Register r1, const Address& a) { z_alg( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 459 inline void Assembler::z_algf(Register r1, const Address& a) { z_algf(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 460 461 inline void Assembler::z_ar( Register r1, Register r2) { emit_16( AR_ZOPC | regt(r1, 8, 16) | reg(r2, 12, 16)); } 462 inline void Assembler::z_agr( Register r1, Register r2) { emit_32( AGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 463 inline void Assembler::z_agfr(Register r1, Register r2) { emit_32( AGFR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 464 inline void Assembler::z_ark( Register r1, Register r2, Register r3) { emit_32( ARK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 465 inline void Assembler::z_agrk(Register r1, Register r2, Register r3) { emit_32( AGRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 466 467 inline void Assembler::z_ahi( Register r1, int64_t i2) { emit_32( AHI_ZOPC | regt(r1, 8, 32) | simm16(i2, 16, 32)); } 468 inline void Assembler::z_afi( Register r1, int64_t i2) { emit_48( AFI_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 469 inline void Assembler::z_aghi( Register r1, int64_t i2) { emit_32( AGHI_ZOPC | regt(r1, 8, 32) | simm16(i2, 16, 32)); } 470 inline void Assembler::z_agfi( Register r1, int64_t i2) { emit_48( AGFI_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 471 inline void Assembler::z_aih( Register r1, int64_t i2) { emit_48( AIH_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 472 inline void Assembler::z_ahik( Register r1, Register r3, int64_t i2) { emit_48( AHIK_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm16(i2, 16, 48)); } 473 inline void Assembler::z_aghik(Register r1, Register r3, int64_t i2) { emit_48( AGHIK_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm16(i2, 16, 48)); } 474 475 476 //----------------------- 477 // ADD LOGICAL 478 //----------------------- 479 inline void Assembler::z_alr( Register r1, Register r2) { emit_16( ALR_ZOPC | regt(r1, 8, 16) | reg(r2, 12, 16)); } 480 inline void Assembler::z_algr( Register r1, Register r2) { emit_32( ALGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 481 inline void Assembler::z_algfr(Register r1, Register r2) { emit_32( ALGFR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 482 inline void Assembler::z_alrk( Register r1, Register r2, Register r3) { emit_32( ALRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 483 inline void Assembler::z_algrk(Register r1, Register r2, Register r3) { emit_32( ALGRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 484 inline void Assembler::z_alcgr(Register r1, Register r2) { emit_32( ALCGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 485 486 inline void Assembler::z_alfi( Register r1, int64_t i2) { emit_48( ALFI_ZOPC | regt(r1, 8, 48) | uimm32(i2, 16, 48)); } 487 inline void Assembler::z_algfi(Register r1, int64_t i2) { emit_48( ALGFI_ZOPC | regt(r1, 8, 48) | uimm32(i2, 16, 48)); } 488 489 inline void Assembler::z_alhsik( Register r1, Register r3, int64_t i2) { emit_48( ALHSIK_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm16(i2, 16, 48)); } 490 inline void Assembler::z_alghsik(Register r1, Register r3, int64_t i2) { emit_48( ALGHSIK_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | simm16(i2, 16, 48)); } 491 492 // In-memory arithmetic (add signed, add logical with signed immediate) 493 inline void Assembler::z_asi( int64_t d1, Register b1, int64_t i2) { emit_48( ASI_ZOPC | simm8(i2, 8, 48) | simm20(d1) | regz(b1, 16, 48)); } 494 inline void Assembler::z_agsi( int64_t d1, Register b1, int64_t i2) { emit_48( AGSI_ZOPC | simm8(i2, 8, 48) | simm20(d1) | regz(b1, 16, 48)); } 495 inline void Assembler::z_alsi( int64_t d1, Register b1, int64_t i2) { emit_48( ALSI_ZOPC | simm8(i2, 8, 48) | simm20(d1) | regz(b1, 16, 48)); } 496 inline void Assembler::z_algsi(int64_t d1, Register b1, int64_t i2) { emit_48( ALGSI_ZOPC | simm8(i2, 8, 48) | simm20(d1) | regz(b1, 16, 48)); } 497 inline void Assembler::z_asi( const Address& d, int64_t i2) { assert(!d.has_index(), "No index in ASI"); z_asi( d.disp(), d.base(), i2); } 498 inline void Assembler::z_agsi( const Address& d, int64_t i2) { assert(!d.has_index(), "No index in AGSI"); z_agsi( d.disp(), d.base(), i2); } 499 inline void Assembler::z_alsi( const Address& d, int64_t i2) { assert(!d.has_index(), "No index in ALSI"); z_alsi( d.disp(), d.base(), i2); } 500 inline void Assembler::z_algsi(const Address& d, int64_t i2) { assert(!d.has_index(), "No index in ALGSI"); z_algsi(d.disp(), d.base(), i2); } 501 502 503 //-------------------- 504 // SUBTRACT 505 //-------------------- 506 inline void Assembler::z_s( Register r1, int64_t d2, Register x2, Register b2) { emit_32( S_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 507 inline void Assembler::z_sy( Register r1, int64_t d2, Register x2, Register b2) { emit_48( SY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 508 inline void Assembler::z_sg( Register r1, int64_t d2, Register x2, Register b2) { emit_48( SG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 509 inline void Assembler::z_sgf( Register r1, int64_t d2, Register x2, Register b2) { emit_48( SGF_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 510 inline void Assembler::z_slg( Register r1, int64_t d2, Register x2, Register b2) { emit_48( SLG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 511 inline void Assembler::z_slgf(Register r1, int64_t d2, Register x2, Register b2) { emit_48( SLGF_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 512 inline void Assembler::z_s( Register r1, const Address& a) { z_s( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 513 inline void Assembler::z_sy( Register r1, const Address& a) { z_sy( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 514 inline void Assembler::z_sg( Register r1, const Address& a) { z_sg( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 515 inline void Assembler::z_sgf( Register r1, const Address& a) { z_sgf( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 516 inline void Assembler::z_slg( Register r1, const Address& a) { z_slg( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 517 inline void Assembler::z_slgf(Register r1, const Address& a) { z_slgf(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 518 519 inline void Assembler::z_sr( Register r1, Register r2) { emit_16( SR_ZOPC | regt(r1, 8, 16) | reg(r2, 12, 16)); } 520 inline void Assembler::z_sgr( Register r1, Register r2) { emit_32( SGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 521 inline void Assembler::z_sgfr(Register r1, Register r2) { emit_32( SGFR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 522 inline void Assembler::z_srk( Register r1, Register r2, Register r3) { emit_32( SRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 523 inline void Assembler::z_sgrk(Register r1, Register r2, Register r3) { emit_32( SGRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 524 525 inline void Assembler::z_sh( Register r1, int64_t d2, Register x2, Register b2) { emit_32( SH_ZOPC | regt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 526 inline void Assembler::z_shy( Register r1, int64_t d2, Register x2, Register b2) { emit_48( SHY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 527 inline void Assembler::z_sh( Register r1, const Address &a) { z_sh( r1, a.disp(), a.indexOrR0(), a.base()); } 528 inline void Assembler::z_shy( Register r1, const Address &a) { z_shy(r1, a.disp(), a.indexOrR0(), a.base()); } 529 530 531 //---------------------------- 532 // SUBTRACT LOGICAL 533 //---------------------------- 534 inline void Assembler::z_slr( Register r1, Register r2) { emit_16( SLR_ZOPC | regt(r1, 8, 16) | reg(r2, 12, 16)); } 535 inline void Assembler::z_slgr( Register r1, Register r2) { emit_32( SLGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 536 inline void Assembler::z_slgfr(Register r1, Register r2) { emit_32( SLGFR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 537 inline void Assembler::z_slrk( Register r1, Register r2, Register r3) { emit_32(SLRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 538 inline void Assembler::z_slgrk(Register r1, Register r2, Register r3) { emit_32(SLGRK_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32) | reg(r3, 16, 32)); } 539 inline void Assembler::z_slfi( Register r1, int64_t i2) { emit_48( SLFI_ZOPC | regt(r1, 8, 48) | uimm32(i2, 16, 48)); } 540 inline void Assembler::z_slgfi(Register r1, int64_t i2) { emit_48( SLGFI_ZOPC | regt(r1, 8, 48) | uimm32(i2, 16, 48)); } 541 542 543 //-------------------- 544 // MULTIPLY 545 //-------------------- 546 inline void Assembler::z_msr( Register r1, Register r2) { emit_32( MSR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 547 inline void Assembler::z_msgr( Register r1, Register r2) { emit_32( MSGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 548 inline void Assembler::z_msgfr(Register r1, Register r2) { emit_32( MSGFR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 549 inline void Assembler::z_mlr( Register r1, Register r2) { emit_32( MLR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 550 inline void Assembler::z_mlgr( Register r1, Register r2) { emit_32( MLGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 551 552 inline void Assembler::z_mhy( Register r1, int64_t d2, Register x2, Register b2) { emit_48( MHY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 553 inline void Assembler::z_msy( Register r1, int64_t d2, Register x2, Register b2) { emit_48( MSY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 554 inline void Assembler::z_msg( Register r1, int64_t d2, Register x2, Register b2) { emit_48( MSG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 555 inline void Assembler::z_msgf(Register r1, int64_t d2, Register x2, Register b2) { emit_48( MSGF_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 556 inline void Assembler::z_ml( Register r1, int64_t d2, Register x2, Register b2) { emit_48( ML_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 557 inline void Assembler::z_mlg( Register r1, int64_t d2, Register x2, Register b2) { emit_48( MLG_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 558 559 inline void Assembler::z_mhy( Register r1, const Address& a) { z_mhy( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 560 inline void Assembler::z_msy( Register r1, const Address& a) { z_msy( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 561 inline void Assembler::z_msg( Register r1, const Address& a) { z_msg( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 562 inline void Assembler::z_msgf(Register r1, const Address& a) { z_msgf(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 563 inline void Assembler::z_ml( Register r1, const Address& a) { z_ml( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 564 inline void Assembler::z_mlg( Register r1, const Address& a) { z_mlg( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 565 566 inline void Assembler::z_msfi( Register r1, int64_t i2) { emit_48( MSFI_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 567 inline void Assembler::z_msgfi(Register r1, int64_t i2) { emit_48( MSGFI_ZOPC | regt(r1, 8, 48) | simm32(i2, 16, 48)); } 568 inline void Assembler::z_mhi( Register r1, int64_t i2) { emit_32( MHI_ZOPC | regt(r1, 8, 32) | simm16(i2, 16, 32)); } 569 inline void Assembler::z_mghi( Register r1, int64_t i2) { emit_32( MGHI_ZOPC | regt(r1, 8, 32) | simm16(i2, 16, 32)); } 570 571 572 //------------------ 573 // DIVIDE 574 //------------------ 575 inline void Assembler::z_dsgr( Register r1, Register r2) { emit_32( DSGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 576 inline void Assembler::z_dsgfr(Register r1, Register r2) { emit_32( DSGFR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 577 578 579 //------------------- 580 // COMPARE 581 //------------------- 582 inline void Assembler::z_cr( Register r1, Register r2) { emit_16( CR_ZOPC | reg(r1, 8, 16) | reg(r2,12,16)); } 583 inline void Assembler::z_cgr( Register r1, Register r2) { emit_32( CGR_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32)); } 584 inline void Assembler::z_cgfr(Register r1, Register r2) { emit_32( CGFR_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32)); } 585 inline void Assembler::z_chi( Register r1, int64_t i2) { emit_32( CHI_ZOPC | reg(r1, 8, 32) | simm16(i2, 16, 32)); } 586 inline void Assembler::z_cghi(Register r1, int64_t i2) { emit_32( CGHI_ZOPC | reg(r1, 8, 32) | simm16(i2, 16, 32)); } 587 inline void Assembler::z_cfi( Register r1, int64_t i2) { emit_48( CFI_ZOPC | regt(r1, 8, 48) | uimm32(i2, 16, 48)); } 588 inline void Assembler::z_cgfi(Register r1, int64_t i2) { emit_48( CGFI_ZOPC | regt(r1, 8, 48) | uimm32(i2, 16, 48)); } 589 inline void Assembler::z_ch(Register r1, const Address &a) { z_ch(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 590 inline void Assembler::z_ch(Register r1, int64_t d2, Register x2, Register b2) { emit_32( CH_ZOPC | reg(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 591 inline void Assembler::z_c(Register r1, const Address &a) { z_c(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 592 inline void Assembler::z_c(Register r1, int64_t d2, Register x2, Register b2) { emit_32( C_ZOPC | reg(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 593 inline void Assembler::z_cy(Register r1, const Address &a) { z_cy(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 594 inline void Assembler::z_cy(Register r1, int64_t d2, Register x2, Register b2) { emit_48( CY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 595 inline void Assembler::z_cy(Register r1, int64_t d2, Register b2) { z_cy(r1, d2, Z_R0, b2); } 596 inline void Assembler::z_cg(Register r1, const Address &a) { z_cg(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 597 inline void Assembler::z_cg(Register r1, int64_t d2, Register x2, Register b2) { emit_48( CG_ZOPC | reg(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 598 inline void Assembler::z_clr(Register r1, Register r2) { emit_16( CLR_ZOPC | reg(r1,8,16) | reg(r2,12,16)); } 599 inline void Assembler::z_clgr(Register r1, Register r2) { emit_32( CLGR_ZOPC | regt(r1, 24, 32) | reg(r2, 28, 32)); } 600 601 602 inline void Assembler::z_clfi(Register r1, int64_t i2) { emit_48( CLFI_ZOPC | regt(r1, 8, 48) | uimm32(i2, 16, 48)); } 603 inline void Assembler::z_clgfi(Register r1, int64_t i2) { emit_48( CLGFI_ZOPC | regt(r1, 8, 48) | uimm32(i2, 16, 48)); } 604 inline void Assembler::z_cl(Register r1, const Address &a) { z_cl(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 605 inline void Assembler::z_cl(Register r1, int64_t d2, Register x2, Register b2) { emit_32( CL_ZOPC | regt(r1, 8, 32) | uimm12(d2,20,32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 606 inline void Assembler::z_cly(Register r1, const Address &a) { z_cly(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 607 inline void Assembler::z_cly(Register r1, int64_t d2, Register x2, Register b2) { emit_48( CLY_ZOPC | regt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 608 inline void Assembler::z_cly(Register r1, int64_t d2, Register b2) { z_cly(r1, d2, Z_R0, b2); } 609 inline void Assembler::z_clg(Register r1, const Address &a) { z_clg(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 610 inline void Assembler::z_clg(Register r1, int64_t d2, Register x2, Register b2) { emit_48( CLG_ZOPC | reg(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 611 inline void Assembler::z_clc(int64_t d1, int64_t l, Register b1, int64_t d2, Register b2) { emit_48( CLC_ZOPC | uimm12(d1, 20, 48) | uimm8(l, 8, 48) | regz(b1, 16, 48) | uimm12(d2, 36, 48) | regz(b2, 32, 48)); } 612 inline void Assembler::z_clcle(Register r1, Register r3, int64_t d2, Register b2) { emit_32( CLCLE_ZOPC | reg(r1, 8, 32) | reg(r3, 12, 32) | uimm12(d2, 20, 32) | reg(b2, 16, 32)); } 613 inline void Assembler::z_clclu(Register r1, Register r3, int64_t d2, Register b2) { emit_48( CLCLU_ZOPC | reg(r1, 8, 48) | reg(r3, 12, 48) | uimm12(d2, 20, 48) | reg(b2, 16, 48)); } 614 615 inline void Assembler::z_tmll(Register r1, int64_t i2) { emit_32( TMLL_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 616 inline void Assembler::z_tmlh(Register r1, int64_t i2) { emit_32( TMLH_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 617 inline void Assembler::z_tmhl(Register r1, int64_t i2) { emit_32( TMHL_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 618 inline void Assembler::z_tmhh(Register r1, int64_t i2) { emit_32( TMHH_ZOPC | regt(r1, 8, 32) | imm16(i2, 16, 32)); } 619 620 // translate characters 621 inline void Assembler::z_troo(Register r1, Register r2, int64_t m3) { emit_32( TROO_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32) | uimm4(m3, 16, 32)); } 622 inline void Assembler::z_trot(Register r1, Register r2, int64_t m3) { emit_32( TROT_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32) | uimm4(m3, 16, 32)); } 623 inline void Assembler::z_trto(Register r1, Register r2, int64_t m3) { emit_32( TRTO_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32) | uimm4(m3, 16, 32)); } 624 inline void Assembler::z_trtt(Register r1, Register r2, int64_t m3) { emit_32( TRTT_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32) | uimm4(m3, 16, 32)); } 625 626 // signed comparison 627 inline void Assembler::z_crb(Register r1, Register r2, branch_condition m3, int64_t d4, Register b4) { emit_48( CRB_ZOPC | reg(r1, 8, 48) | reg(r2, 12, 48) | uimm12(d4, 20, 48) | reg(b4, 16, 48) | uimm4(m3, 32, 48)); } 628 inline void Assembler::z_cgrb(Register r1, Register r2, branch_condition m3, int64_t d4, Register b4) { emit_48( CGRB_ZOPC | reg(r1, 8, 48) | reg(r2, 12, 48) | uimm12(d4, 20, 48) | reg(b4, 16, 48) | uimm4(m3, 32, 48)); } 629 inline void Assembler::z_crj(Register r1, Register r2, branch_condition m3, address a4) { emit_48( CRJ_ZOPC | reg(r1, 8, 48) | reg(r2, 12, 48) | simm16(RelAddr::pcrel_off16(a4, pc()), 16, 48) | uimm4(m3, 32, 48)); } 630 inline void Assembler::z_cgrj(Register r1, Register r2, branch_condition m3, address a4) { emit_48( CGRJ_ZOPC | reg(r1, 8, 48) | reg(r2, 12, 48) | simm16(RelAddr::pcrel_off16(a4, pc()), 16, 48) | uimm4(m3, 32, 48)); } 631 inline void Assembler::z_cib(Register r1, int64_t i2, branch_condition m3, int64_t d4, Register b4) { emit_48( CIB_ZOPC | reg(r1, 8, 48) | uimm4(m3, 12, 48) | uimm12(d4, 20, 48) | reg(b4, 16, 48) | simm8(i2, 32, 48)); } 632 inline void Assembler::z_cgib(Register r1, int64_t i2, branch_condition m3, int64_t d4, Register b4) { emit_48( CGIB_ZOPC | reg(r1, 8, 48) | uimm4(m3, 12, 48) | uimm12(d4, 20, 48) | reg(b4, 16, 48) | simm8(i2, 32, 48)); } 633 inline void Assembler::z_cij(Register r1, int64_t i2, branch_condition m3, address a4) { emit_48( CIJ_ZOPC | reg(r1, 8, 48) | uimm4(m3, 12, 48) | simm16(RelAddr::pcrel_off16(a4, pc()), 16, 48) | simm8(i2, 32, 48)); } 634 inline void Assembler::z_cgij(Register r1, int64_t i2, branch_condition m3, address a4) { emit_48( CGIJ_ZOPC | reg(r1, 8, 48) | uimm4(m3, 12, 48) | simm16(RelAddr::pcrel_off16(a4, pc()), 16, 48) | simm8(i2, 32, 48)); } 635 // unsigned comparison 636 inline void Assembler::z_clrb(Register r1, Register r2, branch_condition m3, int64_t d4, Register b4) { emit_48( CLRB_ZOPC | reg(r1, 8, 48) | reg(r2, 12, 48) | uimm12(d4, 20, 48) | reg(b4, 16, 48) | uimm4(m3, 32, 48)); } 637 inline void Assembler::z_clgrb(Register r1, Register r2, branch_condition m3, int64_t d4, Register b4) { emit_48( CLGRB_ZOPC | reg(r1, 8, 48) | reg(r2, 12, 48) | uimm12(d4, 20, 48) | reg(b4, 16, 48) | uimm4(m3, 32, 48)); } 638 inline void Assembler::z_clrj(Register r1, Register r2, branch_condition m3, address a4) { emit_48( CLRJ_ZOPC | reg(r1, 8, 48) | reg(r2, 12, 48) | simm16(RelAddr::pcrel_off16(a4, pc()), 16, 48) | uimm4(m3, 32, 48)); } 639 inline void Assembler::z_clgrj(Register r1, Register r2, branch_condition m3, address a4) { emit_48( CLGRJ_ZOPC | reg(r1, 8, 48) | reg(r2, 12, 48) | simm16(RelAddr::pcrel_off16(a4, pc()), 16, 48) | uimm4(m3, 32, 48)); } 640 inline void Assembler::z_clib(Register r1, int64_t i2, branch_condition m3, int64_t d4, Register b4) { emit_48( CLIB_ZOPC | reg(r1, 8, 48) | uimm4(m3, 12, 48) | uimm12(d4, 20, 48) | reg(b4, 16, 48) | uimm8(i2, 32, 48)); } 641 inline void Assembler::z_clgib(Register r1, int64_t i2, branch_condition m3, int64_t d4, Register b4) { emit_48( CLGIB_ZOPC | reg(r1, 8, 48) | uimm4(m3, 12, 48) | uimm12(d4, 20, 48) | reg(b4, 16, 48) | uimm8(i2, 32, 48)); } 642 inline void Assembler::z_clij(Register r1, int64_t i2, branch_condition m3, address a4) { emit_48( CLIJ_ZOPC | reg(r1, 8, 48) | uimm4(m3, 12, 48) | simm16(RelAddr::pcrel_off16(a4, pc()), 16, 48) | uimm8(i2, 32, 48)); } 643 inline void Assembler::z_clgij(Register r1, int64_t i2, branch_condition m3, address a4) { emit_48( CLGIJ_ZOPC | reg(r1, 8, 48) | uimm4(m3, 12, 48) | simm16(RelAddr::pcrel_off16(a4, pc()), 16, 48) | uimm8(i2, 32, 48)); } 644 645 // Compare and trap instructions (signed). 646 inline void Assembler::z_crt(Register r1, Register r2, int64_t m3) { emit_32( CRT_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32) | uimm4(m3, 16, 32)); } 647 inline void Assembler::z_cgrt(Register r1, Register r2, int64_t m3) { emit_32( CGRT_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32) | uimm4(m3, 16, 32)); } 648 inline void Assembler::z_cit(Register r1, int64_t i2, int64_t m3) { emit_48( CIT_ZOPC | reg(r1, 8, 48) | simm16(i2, 16, 48) | uimm4(m3, 32, 48)); } 649 inline void Assembler::z_cgit(Register r1, int64_t i2, int64_t m3) { emit_48( CGIT_ZOPC | reg(r1, 8, 48) | simm16(i2, 16, 48) | uimm4(m3, 32, 48)); } 650 651 // Compare and trap instructions (unsigned). 652 inline void Assembler::z_clrt(Register r1, Register r2, int64_t m3) { emit_32( CLRT_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32) | uimm4(m3, 16, 32)); } 653 inline void Assembler::z_clgrt(Register r1, Register r2, int64_t m3) { emit_32( CLGRT_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32) | uimm4(m3, 16, 32)); } 654 inline void Assembler::z_clfit(Register r1, int64_t i2, int64_t m3) { emit_48( CLFIT_ZOPC | reg(r1, 8, 48) | uimm16(i2, 16, 48) | uimm4(m3, 32, 48)); } 655 inline void Assembler::z_clgit(Register r1, int64_t i2, int64_t m3) { emit_48( CLGIT_ZOPC | reg(r1, 8, 48) | uimm16(i2, 16, 48) | uimm4(m3, 32, 48)); } 656 657 inline void Assembler::z_bc( branch_condition m1, int64_t d2, Register x2, Register b2) { emit_32( BC_ZOPC | 0 << 16 | uimm4(m1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 658 inline void Assembler::z_bcr( branch_condition m1, Register r2) { emit_16( BCR_ZOPC | uimm4(m1,8,16) | reg(r2,12,16)); } 659 inline void Assembler::z_brc( branch_condition i1, int64_t i2) { emit_32( BRC_ZOPC | uimm4(i1, 8, 32) | simm16(i2, 16, 32)); } 660 inline void Assembler::z_brc( branch_condition i1, address a) { emit_32( BRC_ZOPC | uimm4(i1, 8, 32) | simm16(RelAddr::pcrel_off16(a, pc()), 16, 32)); } 661 inline void Assembler::z_brcl(branch_condition i1, address a) { emit_48( BRCL_ZOPC | uimm4(i1, 8, 48)| simm32(RelAddr::pcrel_off32(a, pc()), 16, 48)); } 662 inline void Assembler::z_bctgr(Register r1, Register r2) { emit_32( BCTGR_ZOPC | reg( r1, 24, 32) | reg( r2, 28, 32)); }; 663 664 inline void Assembler::z_basr(Register r1, Register r2) { emit_16( BASR_ZOPC | regt(r1,8,16) | reg(r2,12,16)); } 665 666 inline void Assembler::z_brasl(Register r1, address a) { emit_48( BRASL_ZOPC | regt(r1, 8, 48) | simm32(RelAddr::pcrel_off32(a, pc()), 16, 48)); } 667 668 inline void Assembler::z_brct(Register r1, address a) { emit_32( BRCT_ZOPC | regt(r1, 8, 32) | simm16(RelAddr::pcrel_off16(a, pc()), 16, 32)); } 669 inline void Assembler::z_brct(Register r1, Label& L) {z_brct(r1, target(L)); } 670 671 inline void Assembler::z_brxh(Register r1, Register r3, address a) {emit_32( BRXH_ZOPC | reg(r1, 8, 32) | reg(r3, 12, 32) | simm16(RelAddr::pcrel_off16(a, pc()), 16, 32));} 672 inline void Assembler::z_brxh(Register r1, Register r3, Label& L) {z_brxh(r1, r3, target(L)); } 673 674 inline void Assembler::z_brxle(Register r1, Register r3, address a) {emit_32( BRXLE_ZOPC | reg(r1, 8, 32) | reg(r3, 12, 32) | simm16(RelAddr::pcrel_off16(a, pc()), 16, 32));} 675 inline void Assembler::z_brxle(Register r1, Register r3, Label& L) {z_brxle(r1, r3, target(L)); } 676 677 inline void Assembler::z_brxhg(Register r1, Register r3, address a) {emit_48( BRXHG_ZOPC | reg(r1, 8, 48) | reg(r3, 12, 48) | simm16(RelAddr::pcrel_off16(a, pc()), 16, 48));} 678 inline void Assembler::z_brxhg(Register r1, Register r3, Label& L) {z_brxhg(r1, r3, target(L)); } 679 680 inline void Assembler::z_brxlg(Register r1, Register r3, address a) {emit_48( BRXLG_ZOPC | reg(r1, 8, 48) | reg(r3, 12, 48) | simm16(RelAddr::pcrel_off16(a, pc()), 16, 48));} 681 inline void Assembler::z_brxlg(Register r1, Register r3, Label& L) {z_brxlg(r1, r3, target(L)); } 682 683 inline void Assembler::z_flogr(Register r1, Register r2) { emit_32( FLOGR_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32)); } 684 inline void Assembler::z_popcnt(Register r1, Register r2) { emit_32( POPCNT_ZOPC | reg(r1, 24, 32) | reg(r2, 28, 32)); } 685 inline void Assembler::z_ahhhr(Register r1, Register r2, Register r3) { emit_32( AHHHR_ZOPC | reg(r3, 16, 32) | reg(r1, 24, 32) | reg(r2, 28, 32)); } 686 inline void Assembler::z_ahhlr(Register r1, Register r2, Register r3) { emit_32( AHHLR_ZOPC | reg(r3, 16, 32) | reg(r1, 24, 32) | reg(r2, 28, 32)); } 687 688 inline void Assembler::z_tam() { emit_16( TAM_ZOPC); } 689 inline void Assembler::z_stck(int64_t d2, Register b2) { emit_32( STCK_ZOPC | uimm12(d2, 20, 32) | regz(b2, 16, 32)); } 690 inline void Assembler::z_stckf(int64_t d2, Register b2) { emit_32( STCKF_ZOPC | uimm12(d2, 20, 32) | regz(b2, 16, 32)); } 691 inline void Assembler::z_stmg(Register r1, Register r3, int64_t d2, Register b2) { emit_48( STMG_ZOPC | simm20(d2) | reg(r1, 8, 48) | reg(r3,12,48)| reg(b2,16,48) ); } 692 inline void Assembler::z_lmg(Register r1, Register r3, int64_t d2, Register b2) { emit_48( LMG_ZOPC | simm20(d2) | reg(r1, 8, 48) | reg(r3,12,48)| reg(b2,16,48) ); } 693 694 inline void Assembler::z_cs(Register r1, Register r3, int64_t d2, Register b2) { emit_32( CS_ZOPC | regt(r1, 8, 32) | reg(r3, 12, 32) | reg(b2, 16, 32) | uimm12(d2, 20, 32)); } 695 inline void Assembler::z_csy(Register r1, Register r3, int64_t d2, Register b2) { emit_48( CSY_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | reg(b2, 16, 48) | simm20(d2)); } 696 inline void Assembler::z_csg(Register r1, Register r3, int64_t d2, Register b2) { emit_48( CSG_ZOPC | regt(r1, 8, 48) | reg(r3, 12, 48) | reg(b2, 16, 48) | simm20(d2)); } 697 inline void Assembler::z_cs( Register r1, Register r3, const Address& a) { assert(!a.has_index(), "Cannot encode index"); z_cs( r1, r3, a.disp(), a.baseOrR0()); } 698 inline void Assembler::z_csy(Register r1, Register r3, const Address& a) { assert(!a.has_index(), "Cannot encode index"); z_csy(r1, r3, a.disp(), a.baseOrR0()); } 699 inline void Assembler::z_csg(Register r1, Register r3, const Address& a) { assert(!a.has_index(), "Cannot encode index"); z_csg(r1, r3, a.disp(), a.baseOrR0()); } 700 701 inline void Assembler::z_cvd(Register r1, int64_t d2, Register x2, Register b2) { emit_32( CVD_ZOPC | regt(r1, 8, 32) | reg(x2, 12, 32) | reg(b2, 16, 32) | uimm12(d2, 20, 32)); } 702 inline void Assembler::z_cvdg(Register r1, int64_t d2, Register x2, Register b2) { emit_48( CVDG_ZOPC | regt(r1, 8, 48) | reg(x2, 12, 48) | reg(b2, 16, 48) | simm20(d2)); } 703 704 705 //--------------------------- 706 //-- Vector Instructions -- 707 //--------------------------- 708 709 //---< Vector Support Instructions >--- 710 711 // Load (transfer from memory) 712 inline void Assembler::z_vlm( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {emit_48(VLM_ZOPC | vreg(v1, 8) | vreg(v3, 12) | rsmask_48(d2, b2)); } 713 inline void Assembler::z_vl( VectorRegister v1, int64_t d2, Register x2, Register b2) {emit_48(VL_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2)); } 714 inline void Assembler::z_vleb( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VLEB_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | veix_mask(m3, VRET_BYTE, 32)); } 715 inline void Assembler::z_vleh( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VLEH_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | veix_mask(m3, VRET_HW, 32)); } 716 inline void Assembler::z_vlef( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VLEF_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | veix_mask(m3, VRET_FW, 32)); } 717 inline void Assembler::z_vleg( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VLEG_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | veix_mask(m3, VRET_DW, 32)); } 718 719 // Gather/Scatter 720 inline void Assembler::z_vgef( VectorRegister v1, int64_t d2, VectorRegister vx2, Register b2, int64_t m3) {emit_48(VGEF_ZOPC | vreg(v1, 8) | rvmask_48(d2, vx2, b2) | veix_mask(m3, VRET_FW, 32)); } 721 inline void Assembler::z_vgeg( VectorRegister v1, int64_t d2, VectorRegister vx2, Register b2, int64_t m3) {emit_48(VGEG_ZOPC | vreg(v1, 8) | rvmask_48(d2, vx2, b2) | veix_mask(m3, VRET_DW, 32)); } 722 723 inline void Assembler::z_vscef( VectorRegister v1, int64_t d2, VectorRegister vx2, Register b2, int64_t m3) {emit_48(VSCEF_ZOPC | vreg(v1, 8) | rvmask_48(d2, vx2, b2) | veix_mask(m3, VRET_FW, 32)); } 724 inline void Assembler::z_vsceg( VectorRegister v1, int64_t d2, VectorRegister vx2, Register b2, int64_t m3) {emit_48(VSCEG_ZOPC | vreg(v1, 8) | rvmask_48(d2, vx2, b2) | veix_mask(m3, VRET_DW, 32)); } 725 726 // load and replicate 727 inline void Assembler::z_vlrep( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VLREP_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | vesc_mask(m3, VRET_BYTE, VRET_DW, 32)); } 728 inline void Assembler::z_vlrepb( VectorRegister v1, int64_t d2, Register x2, Register b2) {z_vlrep(v1, d2, x2, b2, VRET_BYTE); }// load byte and replicate to all vector elements of type 'B' 729 inline void Assembler::z_vlreph( VectorRegister v1, int64_t d2, Register x2, Register b2) {z_vlrep(v1, d2, x2, b2, VRET_HW); } // load HW and replicate to all vector elements of type 'H' 730 inline void Assembler::z_vlrepf( VectorRegister v1, int64_t d2, Register x2, Register b2) {z_vlrep(v1, d2, x2, b2, VRET_FW); } // load FW and replicate to all vector elements of type 'F' 731 inline void Assembler::z_vlrepg( VectorRegister v1, int64_t d2, Register x2, Register b2) {z_vlrep(v1, d2, x2, b2, VRET_DW); } // load DW and replicate to all vector elements of type 'G' 732 733 inline void Assembler::z_vllez( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VLLEZ_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | vesc_mask(m3, VRET_BYTE, VRET_DW, 32)); } 734 inline void Assembler::z_vllezb( VectorRegister v1, int64_t d2, Register x2, Register b2) {z_vllez(v1, d2, x2, b2, VRET_BYTE); }// load logical byte into left DW of VR, zero all other bit positions. 735 inline void Assembler::z_vllezh( VectorRegister v1, int64_t d2, Register x2, Register b2) {z_vllez(v1, d2, x2, b2, VRET_HW); } // load logical HW into left DW of VR, zero all other bit positions. 736 inline void Assembler::z_vllezf( VectorRegister v1, int64_t d2, Register x2, Register b2) {z_vllez(v1, d2, x2, b2, VRET_FW); } // load logical FW into left DW of VR, zero all other bit positions. 737 inline void Assembler::z_vllezg( VectorRegister v1, int64_t d2, Register x2, Register b2) {z_vllez(v1, d2, x2, b2, VRET_DW); } // load logical DW into left DW of VR, zero all other bit positions. 738 739 inline void Assembler::z_vlbb( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VLBB_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | uimm4(m3, 32, 48)); } 740 inline void Assembler::z_vll( VectorRegister v1, Register r3, int64_t d2, Register b2) {emit_48(VLL_ZOPC | vreg(v1, 8) | reg(r3, 12, 48) | rsmask_48(d2, b2)); } 741 742 // Load (register to register) 743 inline void Assembler::z_vlr ( VectorRegister v1, VectorRegister v2) {emit_48(VLR_ZOPC | vreg(v1, 8) | vreg(v2, 12)); } 744 745 inline void Assembler::z_vlgv( Register r1, VectorRegister v3, int64_t d2, Register b2, int64_t m4) {emit_48(VLGV_ZOPC | reg(r1, 8, 48) | vreg(v3, 12) | rsmask_48(d2, b2) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 746 inline void Assembler::z_vlgvb( Register r1, VectorRegister v3, int64_t d2, Register b2) {z_vlgv(r1, v3, d2, b2, VRET_BYTE); } // load byte from VR element (index d2(b2)) into GR (logical) 747 inline void Assembler::z_vlgvh( Register r1, VectorRegister v3, int64_t d2, Register b2) {z_vlgv(r1, v3, d2, b2, VRET_HW); } // load HW from VR element (index d2(b2)) into GR (logical) 748 inline void Assembler::z_vlgvf( Register r1, VectorRegister v3, int64_t d2, Register b2) {z_vlgv(r1, v3, d2, b2, VRET_FW); } // load FW from VR element (index d2(b2)) into GR (logical) 749 inline void Assembler::z_vlgvg( Register r1, VectorRegister v3, int64_t d2, Register b2) {z_vlgv(r1, v3, d2, b2, VRET_DW); } // load DW from VR element (index d2(b2)) into GR. 750 751 inline void Assembler::z_vlvg( VectorRegister v1, Register r3, int64_t d2, Register b2, int64_t m4) {emit_48(VLVG_ZOPC | vreg(v1, 8) | reg(r3, 12, 48) | rsmask_48(d2, b2) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 752 inline void Assembler::z_vlvgb( VectorRegister v1, Register r3, int64_t d2, Register b2) {z_vlvg(v1, r3, d2, b2, VRET_BYTE); } 753 inline void Assembler::z_vlvgh( VectorRegister v1, Register r3, int64_t d2, Register b2) {z_vlvg(v1, r3, d2, b2, VRET_HW); } 754 inline void Assembler::z_vlvgf( VectorRegister v1, Register r3, int64_t d2, Register b2) {z_vlvg(v1, r3, d2, b2, VRET_FW); } 755 inline void Assembler::z_vlvgg( VectorRegister v1, Register r3, int64_t d2, Register b2) {z_vlvg(v1, r3, d2, b2, VRET_DW); } 756 757 inline void Assembler::z_vlvgp( VectorRegister v1, Register r2, Register r3) {emit_48(VLVGP_ZOPC | vreg(v1, 8) | reg(r2, 12, 48) | reg(r3, 16, 48)); } 758 759 // vector register pack 760 inline void Assembler::z_vpk( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VPK_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_HW, VRET_DW, 32)); } 761 inline void Assembler::z_vpkh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpk(v1, v2, v3, VRET_HW); } // vector element type 'H' 762 inline void Assembler::z_vpkf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpk(v1, v2, v3, VRET_FW); } // vector element type 'F' 763 inline void Assembler::z_vpkg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpk(v1, v2, v3, VRET_DW); } // vector element type 'G' 764 765 inline void Assembler::z_vpks( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4, int64_t cc5) {emit_48(VPKS_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_HW, VRET_DW, 32) | vccc_mask(cc5, 24)); } 766 inline void Assembler::z_vpksh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpks(v1, v2, v3, VRET_HW, VOP_CCIGN); } // vector element type 'H', don't set CC 767 inline void Assembler::z_vpksf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpks(v1, v2, v3, VRET_FW, VOP_CCIGN); } // vector element type 'F', don't set CC 768 inline void Assembler::z_vpksg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpks(v1, v2, v3, VRET_DW, VOP_CCIGN); } // vector element type 'G', don't set CC 769 inline void Assembler::z_vpkshs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpks(v1, v2, v3, VRET_HW, VOP_CCSET); } // vector element type 'H', set CC 770 inline void Assembler::z_vpksfs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpks(v1, v2, v3, VRET_FW, VOP_CCSET); } // vector element type 'F', set CC 771 inline void Assembler::z_vpksgs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpks(v1, v2, v3, VRET_DW, VOP_CCSET); } // vector element type 'G', set CC 772 773 inline void Assembler::z_vpkls( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4, int64_t cc5) {emit_48(VPKLS_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_HW, VRET_DW, 32) | vccc_mask(cc5, 24)); } 774 inline void Assembler::z_vpklsh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpkls(v1, v2, v3, VRET_HW, VOP_CCIGN); } // vector element type 'H', don't set CC 775 inline void Assembler::z_vpklsf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpkls(v1, v2, v3, VRET_FW, VOP_CCIGN); } // vector element type 'F', don't set CC 776 inline void Assembler::z_vpklsg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpkls(v1, v2, v3, VRET_DW, VOP_CCIGN); } // vector element type 'G', don't set CC 777 inline void Assembler::z_vpklshs(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpkls(v1, v2, v3, VRET_HW, VOP_CCSET); } // vector element type 'H', set CC 778 inline void Assembler::z_vpklsfs(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpkls(v1, v2, v3, VRET_FW, VOP_CCSET); } // vector element type 'F', set CC 779 inline void Assembler::z_vpklsgs(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vpkls(v1, v2, v3, VRET_DW, VOP_CCSET); } // vector element type 'G', set CC 780 781 // vector register unpack (sign-extended) 782 inline void Assembler::z_vuph( VectorRegister v1, VectorRegister v2, int64_t m3) {emit_48(VUPH_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vesc_mask(m3, VRET_BYTE, VRET_FW, 32)); } 783 inline void Assembler::z_vuphb( VectorRegister v1, VectorRegister v2) {z_vuph(v1, v2, VRET_BYTE); } // vector element type 'B' 784 inline void Assembler::z_vuphh( VectorRegister v1, VectorRegister v2) {z_vuph(v1, v2, VRET_HW); } // vector element type 'H' 785 inline void Assembler::z_vuphf( VectorRegister v1, VectorRegister v2) {z_vuph(v1, v2, VRET_FW); } // vector element type 'F' 786 inline void Assembler::z_vupl( VectorRegister v1, VectorRegister v2, int64_t m3) {emit_48(VUPL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vesc_mask(m3, VRET_BYTE, VRET_FW, 32)); } 787 inline void Assembler::z_vuplb( VectorRegister v1, VectorRegister v2) {z_vupl(v1, v2, VRET_BYTE); } // vector element type 'B' 788 inline void Assembler::z_vuplh( VectorRegister v1, VectorRegister v2) {z_vupl(v1, v2, VRET_HW); } // vector element type 'H' 789 inline void Assembler::z_vuplf( VectorRegister v1, VectorRegister v2) {z_vupl(v1, v2, VRET_FW); } // vector element type 'F' 790 791 // vector register unpack (zero-extended) 792 inline void Assembler::z_vuplh( VectorRegister v1, VectorRegister v2, int64_t m3) {emit_48(VUPLH_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vesc_mask(m3, VRET_BYTE, VRET_FW, 32)); } 793 inline void Assembler::z_vuplhb( VectorRegister v1, VectorRegister v2) {z_vuplh(v1, v2, VRET_BYTE); } // vector element type 'B' 794 inline void Assembler::z_vuplhh( VectorRegister v1, VectorRegister v2) {z_vuplh(v1, v2, VRET_HW); } // vector element type 'H' 795 inline void Assembler::z_vuplhf( VectorRegister v1, VectorRegister v2) {z_vuplh(v1, v2, VRET_FW); } // vector element type 'F' 796 inline void Assembler::z_vupll( VectorRegister v1, VectorRegister v2, int64_t m3) {emit_48(VUPLL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vesc_mask(m3, VRET_BYTE, VRET_FW, 32)); } 797 inline void Assembler::z_vupllb( VectorRegister v1, VectorRegister v2) {z_vupll(v1, v2, VRET_BYTE); } // vector element type 'B' 798 inline void Assembler::z_vupllh( VectorRegister v1, VectorRegister v2) {z_vupll(v1, v2, VRET_HW); } // vector element type 'H' 799 inline void Assembler::z_vupllf( VectorRegister v1, VectorRegister v2) {z_vupll(v1, v2, VRET_FW); } // vector element type 'F' 800 801 // vector register merge high/low 802 inline void Assembler::z_vmrh( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMRH_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 803 inline void Assembler::z_vmrhb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmrh(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 804 inline void Assembler::z_vmrhh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmrh(v1, v2, v3, VRET_HW); } // vector element type 'H' 805 inline void Assembler::z_vmrhf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmrh(v1, v2, v3, VRET_FW); } // vector element type 'F' 806 inline void Assembler::z_vmrhg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmrh(v1, v2, v3, VRET_DW); } // vector element type 'G' 807 808 inline void Assembler::z_vmrl( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMRL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 809 inline void Assembler::z_vmrlb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmrh(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 810 inline void Assembler::z_vmrlh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmrh(v1, v2, v3, VRET_HW); } // vector element type 'H' 811 inline void Assembler::z_vmrlf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmrh(v1, v2, v3, VRET_FW); } // vector element type 'F' 812 inline void Assembler::z_vmrlg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmrh(v1, v2, v3, VRET_DW); } // vector element type 'G' 813 814 // vector register permute 815 inline void Assembler::z_vperm( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4) {emit_48(VPERM_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vreg(v4, 32)); } 816 inline void Assembler::z_vpdi( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VPDI_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | uimm4(m4, 32, 48)); } 817 818 // vector register replicate 819 inline void Assembler::z_vrep( VectorRegister v1, VectorRegister v3, int64_t imm2, int64_t m4) {emit_48(VREP_ZOPC | vreg(v1, 8) | vreg(v3, 12) | simm16(imm2, 16, 48) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 820 inline void Assembler::z_vrepb( VectorRegister v1, VectorRegister v3, int64_t imm2) {z_vrep(v1, v3, imm2, VRET_BYTE); } // vector element type 'B' 821 inline void Assembler::z_vreph( VectorRegister v1, VectorRegister v3, int64_t imm2) {z_vrep(v1, v3, imm2, VRET_HW); } // vector element type 'H' 822 inline void Assembler::z_vrepf( VectorRegister v1, VectorRegister v3, int64_t imm2) {z_vrep(v1, v3, imm2, VRET_FW); } // vector element type 'F' 823 inline void Assembler::z_vrepg( VectorRegister v1, VectorRegister v3, int64_t imm2) {z_vrep(v1, v3, imm2, VRET_DW); } // vector element type 'G' 824 inline void Assembler::z_vrepi( VectorRegister v1, int64_t imm2, int64_t m3) {emit_48(VREPI_ZOPC | vreg(v1, 8) | simm16(imm2, 16, 48) | vesc_mask(m3, VRET_BYTE, VRET_DW, 32)); } 825 inline void Assembler::z_vrepib( VectorRegister v1, int64_t imm2) {z_vrepi(v1, imm2, VRET_BYTE); } // vector element type 'B' 826 inline void Assembler::z_vrepih( VectorRegister v1, int64_t imm2) {z_vrepi(v1, imm2, VRET_HW); } // vector element type 'B' 827 inline void Assembler::z_vrepif( VectorRegister v1, int64_t imm2) {z_vrepi(v1, imm2, VRET_FW); } // vector element type 'B' 828 inline void Assembler::z_vrepig( VectorRegister v1, int64_t imm2) {z_vrepi(v1, imm2, VRET_DW); } // vector element type 'B' 829 830 inline void Assembler::z_vsel( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4) {emit_48(VSEL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vreg(v4, 32)); } 831 inline void Assembler::z_vseg( VectorRegister v1, VectorRegister v2, int64_t m3) {emit_48(VSEG_ZOPC | vreg(v1, 8) | vreg(v2, 12) | uimm4(m3, 32, 48)); } 832 833 // Load (immediate) 834 inline void Assembler::z_vleib( VectorRegister v1, int64_t imm2, int64_t m3) {emit_48(VLEIB_ZOPC | vreg(v1, 8) | simm16(imm2, 32, 48) | veix_mask(m3, VRET_BYTE, 32)); } 835 inline void Assembler::z_vleih( VectorRegister v1, int64_t imm2, int64_t m3) {emit_48(VLEIH_ZOPC | vreg(v1, 8) | simm16(imm2, 32, 48) | veix_mask(m3, VRET_HW, 32)); } 836 inline void Assembler::z_vleif( VectorRegister v1, int64_t imm2, int64_t m3) {emit_48(VLEIF_ZOPC | vreg(v1, 8) | simm16(imm2, 32, 48) | veix_mask(m3, VRET_FW, 32)); } 837 inline void Assembler::z_vleig( VectorRegister v1, int64_t imm2, int64_t m3) {emit_48(VLEIG_ZOPC | vreg(v1, 8) | simm16(imm2, 32, 48) | veix_mask(m3, VRET_DW, 32)); } 838 839 // Store 840 inline void Assembler::z_vstm( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {emit_48(VSTM_ZOPC | vreg(v1, 8) | vreg(v3, 12) | rsmask_48(d2, b2)); } 841 inline void Assembler::z_vst( VectorRegister v1, int64_t d2, Register x2, Register b2) {emit_48(VST_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2)); } 842 inline void Assembler::z_vsteb( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VSTEB_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | veix_mask(m3, VRET_BYTE, 32)); } 843 inline void Assembler::z_vsteh( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VSTEH_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | veix_mask(m3, VRET_HW, 32)); } 844 inline void Assembler::z_vstef( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VSTEF_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | veix_mask(m3, VRET_FW, 32)); } 845 inline void Assembler::z_vsteg( VectorRegister v1, int64_t d2, Register x2, Register b2, int64_t m3) {emit_48(VSTEG_ZOPC | vreg(v1, 8) | rxmask_48(d2, x2, b2) | veix_mask(m3, VRET_DW, 32)); } 846 inline void Assembler::z_vstl( VectorRegister v1, Register r3, int64_t d2, Register b2) {emit_48(VSTL_ZOPC | vreg(v1, 8) | reg(r3, 12, 48) | rsmask_48(d2, b2)); } 847 848 // Misc 849 inline void Assembler::z_vgm( VectorRegister v1, int64_t imm2, int64_t imm3, int64_t m4) {emit_48(VGM_ZOPC | vreg(v1, 8) | uimm8( imm2, 16, 48) | uimm8(imm3, 24, 48) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 850 inline void Assembler::z_vgmb( VectorRegister v1, int64_t imm2, int64_t imm3) {z_vgm(v1, imm2, imm3, VRET_BYTE); } // vector element type 'B' 851 inline void Assembler::z_vgmh( VectorRegister v1, int64_t imm2, int64_t imm3) {z_vgm(v1, imm2, imm3, VRET_HW); } // vector element type 'H' 852 inline void Assembler::z_vgmf( VectorRegister v1, int64_t imm2, int64_t imm3) {z_vgm(v1, imm2, imm3, VRET_FW); } // vector element type 'F' 853 inline void Assembler::z_vgmg( VectorRegister v1, int64_t imm2, int64_t imm3) {z_vgm(v1, imm2, imm3, VRET_DW); } // vector element type 'G' 854 855 inline void Assembler::z_vgbm( VectorRegister v1, int64_t imm2) {emit_48(VGBM_ZOPC | vreg(v1, 8) | uimm16(imm2, 16, 48)); } 856 inline void Assembler::z_vzero( VectorRegister v1) {z_vgbm(v1, 0); } // preferred method to set vreg to all zeroes 857 inline void Assembler::z_vone( VectorRegister v1) {z_vgbm(v1, 0xffff); } // preferred method to set vreg to all ones 858 859 //---< Vector Arithmetic Instructions >--- 860 861 // Load 862 inline void Assembler::z_vlc( VectorRegister v1, VectorRegister v2, int64_t m3) {emit_48(VLC_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vesc_mask(m3, VRET_BYTE, VRET_DW, 32)); } 863 inline void Assembler::z_vlcb( VectorRegister v1, VectorRegister v2) {z_vlc(v1, v2, VRET_BYTE); } // vector element type 'B' 864 inline void Assembler::z_vlch( VectorRegister v1, VectorRegister v2) {z_vlc(v1, v2, VRET_HW); } // vector element type 'H' 865 inline void Assembler::z_vlcf( VectorRegister v1, VectorRegister v2) {z_vlc(v1, v2, VRET_FW); } // vector element type 'F' 866 inline void Assembler::z_vlcg( VectorRegister v1, VectorRegister v2) {z_vlc(v1, v2, VRET_DW); } // vector element type 'G' 867 inline void Assembler::z_vlp( VectorRegister v1, VectorRegister v2, int64_t m3) {emit_48(VLP_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vesc_mask(m3, VRET_BYTE, VRET_DW, 32)); } 868 inline void Assembler::z_vlpb( VectorRegister v1, VectorRegister v2) {z_vlp(v1, v2, VRET_BYTE); } // vector element type 'B' 869 inline void Assembler::z_vlph( VectorRegister v1, VectorRegister v2) {z_vlp(v1, v2, VRET_HW); } // vector element type 'H' 870 inline void Assembler::z_vlpf( VectorRegister v1, VectorRegister v2) {z_vlp(v1, v2, VRET_FW); } // vector element type 'F' 871 inline void Assembler::z_vlpg( VectorRegister v1, VectorRegister v2) {z_vlp(v1, v2, VRET_DW); } // vector element type 'G' 872 873 // ADD 874 inline void Assembler::z_va( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VA_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_QW, 32)); } 875 inline void Assembler::z_vab( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_va(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 876 inline void Assembler::z_vah( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_va(v1, v2, v3, VRET_HW); } // vector element type 'H' 877 inline void Assembler::z_vaf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_va(v1, v2, v3, VRET_FW); } // vector element type 'F' 878 inline void Assembler::z_vag( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_va(v1, v2, v3, VRET_DW); } // vector element type 'G' 879 inline void Assembler::z_vaq( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_va(v1, v2, v3, VRET_QW); } // vector element type 'Q' 880 inline void Assembler::z_vacc( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VACC_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_QW, 32)); } 881 inline void Assembler::z_vaccb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vacc(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 882 inline void Assembler::z_vacch( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vacc(v1, v2, v3, VRET_HW); } // vector element type 'H' 883 inline void Assembler::z_vaccf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vacc(v1, v2, v3, VRET_FW); } // vector element type 'F' 884 inline void Assembler::z_vaccg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vacc(v1, v2, v3, VRET_DW); } // vector element type 'G' 885 inline void Assembler::z_vaccq( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vacc(v1, v2, v3, VRET_QW); } // vector element type 'Q' 886 887 // SUB 888 inline void Assembler::z_vs( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VS_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_QW, 32)); } 889 inline void Assembler::z_vsb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vs(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 890 inline void Assembler::z_vsh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vs(v1, v2, v3, VRET_HW); } // vector element type 'H' 891 inline void Assembler::z_vsf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vs(v1, v2, v3, VRET_FW); } // vector element type 'F' 892 inline void Assembler::z_vsg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vs(v1, v2, v3, VRET_DW); } // vector element type 'G' 893 inline void Assembler::z_vsq( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vs(v1, v2, v3, VRET_QW); } // vector element type 'Q' 894 inline void Assembler::z_vscbi( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VSCBI_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_QW, 32)); } 895 inline void Assembler::z_vscbib( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vscbi(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 896 inline void Assembler::z_vscbih( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vscbi(v1, v2, v3, VRET_HW); } // vector element type 'H' 897 inline void Assembler::z_vscbif( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vscbi(v1, v2, v3, VRET_FW); } // vector element type 'F' 898 inline void Assembler::z_vscbig( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vscbi(v1, v2, v3, VRET_DW); } // vector element type 'G' 899 inline void Assembler::z_vscbiq( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vscbi(v1, v2, v3, VRET_QW); } // vector element type 'Q' 900 901 // MULTIPLY 902 inline void Assembler::z_vml( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VML_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_FW, 32)); } 903 inline void Assembler::z_vmh( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMH_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_FW, 32)); } 904 inline void Assembler::z_vmlh( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMLH_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_FW, 32)); } 905 inline void Assembler::z_vme( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VME_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_FW, 32)); } 906 inline void Assembler::z_vmle( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMLE_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_FW, 32)); } 907 inline void Assembler::z_vmo( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMO_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_FW, 32)); } 908 inline void Assembler::z_vmlo( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMLO_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_FW, 32)); } 909 910 // MULTIPLY & ADD 911 inline void Assembler::z_vmal( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4, int64_t m5) {emit_48(VMAL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vreg(v4, 32) | vesc_mask(m5, VRET_BYTE, VRET_FW, 20)); } 912 inline void Assembler::z_vmah( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4, int64_t m5) {emit_48(VMAH_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vreg(v4, 32) | vesc_mask(m5, VRET_BYTE, VRET_FW, 20)); } 913 inline void Assembler::z_vmalh( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4, int64_t m5) {emit_48(VMALH_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vreg(v4, 32) | vesc_mask(m5, VRET_BYTE, VRET_FW, 20)); } 914 inline void Assembler::z_vmae( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4, int64_t m5) {emit_48(VMAE_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vreg(v4, 32) | vesc_mask(m5, VRET_BYTE, VRET_FW, 20)); } 915 inline void Assembler::z_vmale( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4, int64_t m5) {emit_48(VMALE_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vreg(v4, 32) | vesc_mask(m5, VRET_BYTE, VRET_FW, 20)); } 916 inline void Assembler::z_vmao( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4, int64_t m5) {emit_48(VMAO_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vreg(v4, 32) | vesc_mask(m5, VRET_BYTE, VRET_FW, 20)); } 917 inline void Assembler::z_vmalo( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4, int64_t m5) {emit_48(VMALO_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vreg(v4, 32) | vesc_mask(m5, VRET_BYTE, VRET_FW, 20)); } 918 919 // VECTOR SUM 920 inline void Assembler::z_vsum( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VSUM_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_HW, 32)); } 921 inline void Assembler::z_vsumb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vsum(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 922 inline void Assembler::z_vsumh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vsum(v1, v2, v3, VRET_HW); } // vector element type 'H' 923 inline void Assembler::z_vsumg( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VSUMG_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_HW, VRET_FW, 32)); } 924 inline void Assembler::z_vsumgh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vsumg(v1, v2, v3, VRET_HW); } // vector element type 'B' 925 inline void Assembler::z_vsumgf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vsumg(v1, v2, v3, VRET_FW); } // vector element type 'H' 926 inline void Assembler::z_vsumq( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VSUMQ_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_FW, VRET_DW, 32)); } 927 inline void Assembler::z_vsumqf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vsumq(v1, v2, v3, VRET_FW); } // vector element type 'B' 928 inline void Assembler::z_vsumqg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vsumq(v1, v2, v3, VRET_DW); } // vector element type 'H' 929 930 // Average 931 inline void Assembler::z_vavg( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VAVG_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 932 inline void Assembler::z_vavgb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vavg(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 933 inline void Assembler::z_vavgh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vavg(v1, v2, v3, VRET_HW); } // vector element type 'H' 934 inline void Assembler::z_vavgf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vavg(v1, v2, v3, VRET_FW); } // vector element type 'F' 935 inline void Assembler::z_vavgg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vavg(v1, v2, v3, VRET_DW); } // vector element type 'G' 936 inline void Assembler::z_vavgl( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VAVGL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 937 inline void Assembler::z_vavglb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vavgl(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 938 inline void Assembler::z_vavglh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vavgl(v1, v2, v3, VRET_HW); } // vector element type 'H' 939 inline void Assembler::z_vavglf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vavgl(v1, v2, v3, VRET_FW); } // vector element type 'F' 940 inline void Assembler::z_vavglg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vavgl(v1, v2, v3, VRET_DW); } // vector element type 'G' 941 942 // VECTOR Galois Field Multiply Sum 943 inline void Assembler::z_vgfm( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VGFM_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 944 inline void Assembler::z_vgfmb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vgfm(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 945 inline void Assembler::z_vgfmh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vgfm(v1, v2, v3, VRET_HW); } // vector element type 'H' 946 inline void Assembler::z_vgfmf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vgfm(v1, v2, v3, VRET_FW); } // vector element type 'F' 947 inline void Assembler::z_vgfmg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vgfm(v1, v2, v3, VRET_DW); } // vector element type 'G' 948 inline void Assembler::z_vgfma( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4, int64_t m5) {emit_48(VGFMA_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vreg(v3, 16) | vesc_mask(m5, VRET_BYTE, VRET_DW, 20)); } 949 inline void Assembler::z_vgfmab( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4) {z_vgfma(v1, v2, v3, v4, VRET_BYTE); } // vector element type 'B' 950 inline void Assembler::z_vgfmah( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4) {z_vgfma(v1, v2, v3, v4, VRET_HW); } // vector element type 'H' 951 inline void Assembler::z_vgfmaf( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4) {z_vgfma(v1, v2, v3, v4, VRET_FW); } // vector element type 'F' 952 inline void Assembler::z_vgfmag( VectorRegister v1, VectorRegister v2, VectorRegister v3, VectorRegister v4) {z_vgfma(v1, v2, v3, v4, VRET_DW); } // vector element type 'G' 953 954 //---< Vector Logical Instructions >--- 955 956 // AND 957 inline void Assembler::z_vn( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VN_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 958 inline void Assembler::z_vnc( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VNC_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 959 960 // XOR 961 inline void Assembler::z_vx( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VX_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 962 963 // NOR 964 inline void Assembler::z_vno( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VNO_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 965 966 // OR 967 inline void Assembler::z_vo( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VO_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 968 969 // Comparison (element-wise) 970 inline void Assembler::z_vceq( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4, int64_t cc5) {emit_48(VCEQ_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32) | vccc_mask(cc5, 24)); } 971 inline void Assembler::z_vceqb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vceq(v1, v2, v3, VRET_BYTE, VOP_CCIGN); } // vector element type 'B', don't set CC 972 inline void Assembler::z_vceqh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vceq(v1, v2, v3, VRET_HW, VOP_CCIGN); } // vector element type 'H', don't set CC 973 inline void Assembler::z_vceqf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vceq(v1, v2, v3, VRET_FW, VOP_CCIGN); } // vector element type 'F', don't set CC 974 inline void Assembler::z_vceqg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vceq(v1, v2, v3, VRET_DW, VOP_CCIGN); } // vector element type 'G', don't set CC 975 inline void Assembler::z_vceqbs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vceq(v1, v2, v3, VRET_BYTE, VOP_CCSET); } // vector element type 'B', don't set CC 976 inline void Assembler::z_vceqhs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vceq(v1, v2, v3, VRET_HW, VOP_CCSET); } // vector element type 'H', don't set CC 977 inline void Assembler::z_vceqfs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vceq(v1, v2, v3, VRET_FW, VOP_CCSET); } // vector element type 'F', don't set CC 978 inline void Assembler::z_vceqgs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vceq(v1, v2, v3, VRET_DW, VOP_CCSET); } // vector element type 'G', don't set CC 979 inline void Assembler::z_vch( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4, int64_t cc5) {emit_48(VCH_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32) | vccc_mask(cc5, 24)); } 980 inline void Assembler::z_vchb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vch(v1, v2, v3, VRET_BYTE, VOP_CCIGN); } // vector element type 'B', don't set CC 981 inline void Assembler::z_vchh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vch(v1, v2, v3, VRET_HW, VOP_CCIGN); } // vector element type 'H', don't set CC 982 inline void Assembler::z_vchf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vch(v1, v2, v3, VRET_FW, VOP_CCIGN); } // vector element type 'F', don't set CC 983 inline void Assembler::z_vchg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vch(v1, v2, v3, VRET_DW, VOP_CCIGN); } // vector element type 'G', don't set CC 984 inline void Assembler::z_vchbs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vch(v1, v2, v3, VRET_BYTE, VOP_CCSET); } // vector element type 'B', don't set CC 985 inline void Assembler::z_vchhs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vch(v1, v2, v3, VRET_HW, VOP_CCSET); } // vector element type 'H', don't set CC 986 inline void Assembler::z_vchfs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vch(v1, v2, v3, VRET_FW, VOP_CCSET); } // vector element type 'F', don't set CC 987 inline void Assembler::z_vchgs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vch(v1, v2, v3, VRET_DW, VOP_CCSET); } // vector element type 'G', don't set CC 988 inline void Assembler::z_vchl( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4, int64_t cc5) {emit_48(VCHL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32) | vccc_mask(cc5, 24)); } 989 inline void Assembler::z_vchlb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vchl(v1, v2, v3, VRET_BYTE, VOP_CCIGN); } // vector element type 'B', don't set CC 990 inline void Assembler::z_vchlh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vchl(v1, v2, v3, VRET_HW, VOP_CCIGN); } // vector element type 'H', don't set CC 991 inline void Assembler::z_vchlf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vchl(v1, v2, v3, VRET_FW, VOP_CCIGN); } // vector element type 'F', don't set CC 992 inline void Assembler::z_vchlg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vchl(v1, v2, v3, VRET_DW, VOP_CCIGN); } // vector element type 'G', don't set CC 993 inline void Assembler::z_vchlbs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vchl(v1, v2, v3, VRET_BYTE, VOP_CCSET); } // vector element type 'B', don't set CC 994 inline void Assembler::z_vchlhs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vchl(v1, v2, v3, VRET_HW, VOP_CCSET); } // vector element type 'H', don't set CC 995 inline void Assembler::z_vchlfs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vchl(v1, v2, v3, VRET_FW, VOP_CCSET); } // vector element type 'F', don't set CC 996 inline void Assembler::z_vchlgs( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vchl(v1, v2, v3, VRET_DW, VOP_CCSET); } // vector element type 'G', don't set CC 997 998 // Max/Min (element-wise) 999 inline void Assembler::z_vmx( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMX_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1000 inline void Assembler::z_vmxb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmx(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 1001 inline void Assembler::z_vmxh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmx(v1, v2, v3, VRET_HW); } // vector element type 'H' 1002 inline void Assembler::z_vmxf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmx(v1, v2, v3, VRET_FW); } // vector element type 'F' 1003 inline void Assembler::z_vmxg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmx(v1, v2, v3, VRET_DW); } // vector element type 'G' 1004 inline void Assembler::z_vmxl( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMXL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1005 inline void Assembler::z_vmxlb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmxl(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 1006 inline void Assembler::z_vmxlh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmxl(v1, v2, v3, VRET_HW); } // vector element type 'H' 1007 inline void Assembler::z_vmxlf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmxl(v1, v2, v3, VRET_FW); } // vector element type 'F' 1008 inline void Assembler::z_vmxlg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmxl(v1, v2, v3, VRET_DW); } // vector element type 'G' 1009 inline void Assembler::z_vmn( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMN_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1010 inline void Assembler::z_vmnb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmn(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 1011 inline void Assembler::z_vmnh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmn(v1, v2, v3, VRET_HW); } // vector element type 'H' 1012 inline void Assembler::z_vmnf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmn(v1, v2, v3, VRET_FW); } // vector element type 'F' 1013 inline void Assembler::z_vmng( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmn(v1, v2, v3, VRET_DW); } // vector element type 'G' 1014 inline void Assembler::z_vmnl( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VMNL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1015 inline void Assembler::z_vmnlb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmnl(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 1016 inline void Assembler::z_vmnlh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmnl(v1, v2, v3, VRET_HW); } // vector element type 'H' 1017 inline void Assembler::z_vmnlf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmnl(v1, v2, v3, VRET_FW); } // vector element type 'F' 1018 inline void Assembler::z_vmnlg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vmnl(v1, v2, v3, VRET_DW); } // vector element type 'G' 1019 1020 // Leading/Trailing Zeros, population count 1021 inline void Assembler::z_vclz( VectorRegister v1, VectorRegister v2, int64_t m3) {emit_48(VCLZ_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vesc_mask(m3, VRET_BYTE, VRET_DW, 32)); } 1022 inline void Assembler::z_vclzb( VectorRegister v1, VectorRegister v2) {z_vclz(v1, v2, VRET_BYTE); } // vector element type 'B' 1023 inline void Assembler::z_vclzh( VectorRegister v1, VectorRegister v2) {z_vclz(v1, v2, VRET_HW); } // vector element type 'H' 1024 inline void Assembler::z_vclzf( VectorRegister v1, VectorRegister v2) {z_vclz(v1, v2, VRET_FW); } // vector element type 'F' 1025 inline void Assembler::z_vclzg( VectorRegister v1, VectorRegister v2) {z_vclz(v1, v2, VRET_DW); } // vector element type 'G' 1026 inline void Assembler::z_vctz( VectorRegister v1, VectorRegister v2, int64_t m3) {emit_48(VCTZ_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vesc_mask(m3, VRET_BYTE, VRET_DW, 32)); } 1027 inline void Assembler::z_vctzb( VectorRegister v1, VectorRegister v2) {z_vctz(v1, v2, VRET_BYTE); } // vector element type 'B' 1028 inline void Assembler::z_vctzh( VectorRegister v1, VectorRegister v2) {z_vctz(v1, v2, VRET_HW); } // vector element type 'H' 1029 inline void Assembler::z_vctzf( VectorRegister v1, VectorRegister v2) {z_vctz(v1, v2, VRET_FW); } // vector element type 'F' 1030 inline void Assembler::z_vctzg( VectorRegister v1, VectorRegister v2) {z_vctz(v1, v2, VRET_DW); } // vector element type 'G' 1031 inline void Assembler::z_vpopct( VectorRegister v1, VectorRegister v2, int64_t m3) {emit_48(VPOPCT_ZOPC| vreg(v1, 8) | vreg(v2, 12) | vesc_mask(m3, VRET_BYTE, VRET_DW, 32)); } 1032 1033 // Rotate/Shift 1034 inline void Assembler::z_verllv( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VERLLV_ZOPC| vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1035 inline void Assembler::z_verllvb(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_verllv(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 1036 inline void Assembler::z_verllvh(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_verllv(v1, v2, v3, VRET_HW); } // vector element type 'H' 1037 inline void Assembler::z_verllvf(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_verllv(v1, v2, v3, VRET_FW); } // vector element type 'F' 1038 inline void Assembler::z_verllvg(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_verllv(v1, v2, v3, VRET_DW); } // vector element type 'G' 1039 inline void Assembler::z_verll( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2, int64_t m4) {emit_48(VERLL_ZOPC | vreg(v1, 8) | vreg(v3, 12) | rsmask_48(d2, b2) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1040 inline void Assembler::z_verllb( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_verll(v1, v3, d2, b2, VRET_BYTE);}// vector element type 'B' 1041 inline void Assembler::z_verllh( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_verll(v1, v3, d2, b2, VRET_HW);} // vector element type 'H' 1042 inline void Assembler::z_verllf( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_verll(v1, v3, d2, b2, VRET_FW);} // vector element type 'F' 1043 inline void Assembler::z_verllg( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_verll(v1, v3, d2, b2, VRET_DW);} // vector element type 'G' 1044 inline void Assembler::z_verim( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t imm4, int64_t m5) {emit_48(VERLL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | uimm8(imm4, 24, 48) | vesc_mask(m5, VRET_BYTE, VRET_DW, 32)); } 1045 inline void Assembler::z_verimb( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t imm4) {z_verim(v1, v2, v3, imm4, VRET_BYTE); } // vector element type 'B' 1046 inline void Assembler::z_verimh( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t imm4) {z_verim(v1, v2, v3, imm4, VRET_HW); } // vector element type 'H' 1047 inline void Assembler::z_verimf( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t imm4) {z_verim(v1, v2, v3, imm4, VRET_FW); } // vector element type 'F' 1048 inline void Assembler::z_verimg( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t imm4) {z_verim(v1, v2, v3, imm4, VRET_DW); } // vector element type 'G' 1049 1050 inline void Assembler::z_veslv( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VESLV_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1051 inline void Assembler::z_veslvb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_veslv(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 1052 inline void Assembler::z_veslvh( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_veslv(v1, v2, v3, VRET_HW); } // vector element type 'H' 1053 inline void Assembler::z_veslvf( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_veslv(v1, v2, v3, VRET_FW); } // vector element type 'F' 1054 inline void Assembler::z_veslvg( VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_veslv(v1, v2, v3, VRET_DW); } // vector element type 'G' 1055 inline void Assembler::z_vesl( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2, int64_t m4) {emit_48(VESL_ZOPC | vreg(v1, 8) | vreg(v3, 12) | rsmask_48(d2, b2) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1056 inline void Assembler::z_veslb( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesl(v1, v3, d2, b2, VRET_BYTE);} // vector element type 'B' 1057 inline void Assembler::z_veslh( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesl(v1, v3, d2, b2, VRET_HW);} // vector element type 'H' 1058 inline void Assembler::z_veslf( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesl(v1, v3, d2, b2, VRET_FW);} // vector element type 'F' 1059 inline void Assembler::z_veslg( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesl(v1, v3, d2, b2, VRET_DW);} // vector element type 'G' 1060 1061 inline void Assembler::z_vesrav( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VESRAV_ZOPC| vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1062 inline void Assembler::z_vesravb(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vesrav(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 1063 inline void Assembler::z_vesravh(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vesrav(v1, v2, v3, VRET_HW); } // vector element type 'H' 1064 inline void Assembler::z_vesravf(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vesrav(v1, v2, v3, VRET_FW); } // vector element type 'F' 1065 inline void Assembler::z_vesravg(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vesrav(v1, v2, v3, VRET_DW); } // vector element type 'G' 1066 inline void Assembler::z_vesra( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2, int64_t m4) {emit_48(VESRA_ZOPC | vreg(v1, 8) | vreg(v3, 12) | rsmask_48(d2, b2) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1067 inline void Assembler::z_vesrab( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesra(v1, v3, d2, b2, VRET_BYTE);}// vector element type 'B' 1068 inline void Assembler::z_vesrah( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesra(v1, v3, d2, b2, VRET_HW);} // vector element type 'H' 1069 inline void Assembler::z_vesraf( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesra(v1, v3, d2, b2, VRET_FW);} // vector element type 'F' 1070 inline void Assembler::z_vesrag( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesra(v1, v3, d2, b2, VRET_DW);} // vector element type 'G' 1071 inline void Assembler::z_vesrlv( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t m4) {emit_48(VESRLV_ZOPC| vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1072 inline void Assembler::z_vesrlvb(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vesrlv(v1, v2, v3, VRET_BYTE); } // vector element type 'B' 1073 inline void Assembler::z_vesrlvh(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vesrlv(v1, v2, v3, VRET_HW); } // vector element type 'H' 1074 inline void Assembler::z_vesrlvf(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vesrlv(v1, v2, v3, VRET_FW); } // vector element type 'F' 1075 inline void Assembler::z_vesrlvg(VectorRegister v1, VectorRegister v2, VectorRegister v3) {z_vesrlv(v1, v2, v3, VRET_DW); } // vector element type 'G' 1076 inline void Assembler::z_vesrl( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2, int64_t m4) {emit_48(VESRL_ZOPC | vreg(v1, 8) | vreg(v3, 12) | rsmask_48(d2, b2) | vesc_mask(m4, VRET_BYTE, VRET_DW, 32)); } 1077 inline void Assembler::z_vesrlb( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesrl(v1, v3, d2, b2, VRET_BYTE);}// vector element type 'B' 1078 inline void Assembler::z_vesrlh( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesrl(v1, v3, d2, b2, VRET_HW);} // vector element type 'H' 1079 inline void Assembler::z_vesrlf( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesrl(v1, v3, d2, b2, VRET_FW);} // vector element type 'F' 1080 inline void Assembler::z_vesrlg( VectorRegister v1, VectorRegister v3, int64_t d2, Register b2) {z_vesrl(v1, v3, d2, b2, VRET_DW);} // vector element type 'G' 1081 1082 inline void Assembler::z_vsl( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VSL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 1083 inline void Assembler::z_vslb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VSLB_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 1084 inline void Assembler::z_vsldb( VectorRegister v1, VectorRegister v2, VectorRegister v3, int64_t imm4) {emit_48(VSLDB_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16) | uimm8(imm4, 24, 48)); } 1085 1086 inline void Assembler::z_vsra( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VSRA_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 1087 inline void Assembler::z_vsrab( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VSRAB_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 1088 inline void Assembler::z_vsrl( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VSRL_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 1089 inline void Assembler::z_vsrlb( VectorRegister v1, VectorRegister v2, VectorRegister v3) {emit_48(VSRLB_ZOPC | vreg(v1, 8) | vreg(v2, 12) | vreg(v3, 16)); } 1090 1091 // Test under Mask 1092 inline void Assembler::z_vtm( VectorRegister v1, VectorRegister v2) {emit_48(VTM_ZOPC | vreg(v1, 8) | vreg(v2, 12)); } 1093 1094 1095 //------------------------------- 1096 // FLOAT INSTRUCTIONS 1097 //------------------------------- 1098 1099 //---------------- 1100 // LOAD 1101 //---------------- 1102 inline void Assembler::z_ler( FloatRegister r1, FloatRegister r2) { emit_16( LER_ZOPC | fregt(r1,8,16) | freg(r2,12,16)); } 1103 inline void Assembler::z_ldr( FloatRegister r1, FloatRegister r2) { emit_16( LDR_ZOPC | fregt(r1,8,16) | freg(r2,12,16)); } 1104 inline void Assembler::z_ldebr(FloatRegister r1, FloatRegister r2) { emit_32( LDEBR_ZOPC | fregt(r1, 24, 32) | freg(r2, 28, 32)); } 1105 inline void Assembler::z_ledbr(FloatRegister r1, FloatRegister r2) { emit_32( LEDBR_ZOPC | fregt(r1, 24, 32) | freg(r2, 28, 32)); } 1106 inline void Assembler::z_le( FloatRegister r1, int64_t d2, Register x2, Register b2) { emit_32( LE_ZOPC | fregt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 1107 inline void Assembler::z_ley(FloatRegister r1, int64_t d2, Register x2, Register b2) { emit_48( LEY_ZOPC | fregt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 1108 inline void Assembler::z_ld( FloatRegister r1, int64_t d2, Register x2, Register b2) { emit_32( LD_ZOPC | fregt(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 1109 inline void Assembler::z_ldy(FloatRegister r1, int64_t d2, Register x2, Register b2) { emit_48( LDY_ZOPC | fregt(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 1110 inline void Assembler::z_le( FloatRegister r1, const Address &a) { z_le( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1111 inline void Assembler::z_ley(FloatRegister r1, const Address &a) { z_ley(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1112 inline void Assembler::z_ld( FloatRegister r1, const Address &a) { z_ld( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1113 inline void Assembler::z_ldy(FloatRegister r1, const Address &a) { z_ldy(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1114 1115 inline void Assembler::z_lzdr(FloatRegister r1) { emit_32( LZDR_ZOPC | fregt(r1, 24, 32)); } 1116 inline void Assembler::z_lzer(FloatRegister f1) { emit_32( LZER_ZOPC | fregt(f1, 24, 32)); } 1117 1118 1119 //----------------- 1120 // STORE 1121 //----------------- 1122 inline void Assembler::z_ste( FloatRegister r1, int64_t d2, Register x2, Register b2) { emit_32( STE_ZOPC | freg(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 1123 inline void Assembler::z_stey(FloatRegister r1, int64_t d2, Register x2, Register b2) { emit_48( STEY_ZOPC | freg(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 1124 inline void Assembler::z_std( FloatRegister r1, int64_t d2, Register x2, Register b2) { emit_32( STD_ZOPC | freg(r1, 8, 32) | uimm12(d2, 20, 32) | reg(x2, 12, 32) | regz(b2, 16, 32)); } 1125 inline void Assembler::z_stdy(FloatRegister r1, int64_t d2, Register x2, Register b2) { emit_48( STDY_ZOPC | freg(r1, 8, 48) | simm20(d2) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 1126 inline void Assembler::z_ste( FloatRegister r1, const Address &a) { z_ste( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1127 inline void Assembler::z_stey(FloatRegister r1, const Address &a) { z_stey(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1128 inline void Assembler::z_std( FloatRegister r1, const Address &a) { z_std( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1129 inline void Assembler::z_stdy(FloatRegister r1, const Address &a) { z_stdy(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1130 1131 1132 //--------------- 1133 // ADD 1134 //--------------- 1135 inline void Assembler::z_aebr( FloatRegister f1, FloatRegister f2) { emit_32( AEBR_ZOPC | fregt( f1, 24, 32) | freg( f2, 28, 32));} 1136 inline void Assembler::z_adbr( FloatRegister f1, FloatRegister f2) { emit_32( ADBR_ZOPC | fregt( f1, 24, 32) | freg( f2, 28, 32));} 1137 inline void Assembler::z_aeb( FloatRegister f1, int64_t d2, Register x2, Register b2 ) { emit_48( AEB_ZOPC | fregt( f1, 8, 48) | uimm12( d2, 20, 48) | reg( x2, 12, 48) | regz( b2, 16, 48));} 1138 inline void Assembler::z_adb( FloatRegister f1, int64_t d2, Register x2, Register b2 ) { emit_48( ADB_ZOPC | fregt( f1, 8, 48) | uimm12( d2, 20, 48) | reg( x2, 12, 48) | regz( b2, 16, 48));} 1139 inline void Assembler::z_aeb( FloatRegister r1, const Address& a) { z_aeb(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1140 inline void Assembler::z_adb( FloatRegister r1, const Address& a) { z_adb(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1141 1142 1143 //--------------- 1144 // SUB 1145 //--------------- 1146 inline void Assembler::z_sebr( FloatRegister f1, FloatRegister f2) { emit_32( SEBR_ZOPC | fregt( f1, 24, 32) | freg( f2, 28, 32));} 1147 inline void Assembler::z_sdbr( FloatRegister f1, FloatRegister f2) { emit_32( SDBR_ZOPC | fregt( f1, 24, 32) | freg( f2, 28, 32));} 1148 inline void Assembler::z_seb( FloatRegister f1, int64_t d2, Register x2, Register b2 ) { emit_48( SEB_ZOPC | fregt( f1, 8, 48) | uimm12( d2, 20, 48) | reg( x2, 12, 48) | regz( b2, 16, 48));} 1149 inline void Assembler::z_sdb( FloatRegister f1, int64_t d2, Register x2, Register b2 ) { emit_48( SDB_ZOPC | fregt( f1, 8, 48) | uimm12( d2, 20, 48) | reg( x2, 12, 48) | regz( b2, 16, 48));} 1150 inline void Assembler::z_seb( FloatRegister r1, const Address& a) { z_seb(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1151 inline void Assembler::z_sdb( FloatRegister r1, const Address& a) { z_sdb(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1152 1153 inline void Assembler::z_lcebr(FloatRegister r1, FloatRegister r2) { emit_32( LCEBR_ZOPC | fregt(r1, 24, 32) | freg(r2, 28, 32)); } 1154 inline void Assembler::z_lcdbr(FloatRegister r1, FloatRegister r2) { emit_32( LCDBR_ZOPC | fregt(r1, 24, 32) | freg(r2, 28, 32)); } 1155 1156 inline void Assembler::z_lpdbr( FloatRegister fr1, FloatRegister fr2) { emit_32( LPDBR_ZOPC | fregt( fr1, 24,32) | freg((fr2 == fnoreg) ? fr1:fr2, 28, 32)); } 1157 1158 1159 //--------------- 1160 // MUL 1161 //--------------- 1162 inline void Assembler::z_meebr(FloatRegister f1, FloatRegister f2) { emit_32( MEEBR_ZOPC | fregt( f1, 24, 32) | freg( f2, 28, 32));} 1163 inline void Assembler::z_mdbr( FloatRegister f1, FloatRegister f2) { emit_32( MDBR_ZOPC | fregt( f1, 24, 32) | freg( f2, 28, 32));} 1164 inline void Assembler::z_meeb( FloatRegister f1, int64_t d2, Register x2, Register b2 ) { emit_48( MEEB_ZOPC | fregt( f1, 8, 48) | uimm12( d2, 20, 48) | reg( x2, 12, 48) | regz( b2, 16, 48));} 1165 inline void Assembler::z_mdb( FloatRegister f1, int64_t d2, Register x2, Register b2 ) { emit_48( MDB_ZOPC | fregt( f1, 8, 48) | uimm12( d2, 20, 48) | reg( x2, 12, 48) | regz( b2, 16, 48));} 1166 inline void Assembler::z_meeb( FloatRegister r1, const Address& a) { z_meeb( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1167 inline void Assembler::z_mdb( FloatRegister r1, const Address& a) { z_mdb( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1168 1169 1170 //--------------- 1171 // MUL-ADD 1172 //--------------- 1173 inline void Assembler::z_maebr(FloatRegister f1, FloatRegister f3, FloatRegister f2) { emit_32( MAEBR_ZOPC | fregt(f1, 16, 32) | freg(f3, 24, 32) | freg(f2, 28, 32) );} 1174 inline void Assembler::z_madbr(FloatRegister f1, FloatRegister f3, FloatRegister f2) { emit_32( MADBR_ZOPC | fregt(f1, 16, 32) | freg(f3, 24, 32) | freg(f2, 28, 32) );} 1175 inline void Assembler::z_msebr(FloatRegister f1, FloatRegister f3, FloatRegister f2) { emit_32( MSEBR_ZOPC | fregt(f1, 16, 32) | freg(f3, 24, 32) | freg(f2, 28, 32) );} 1176 inline void Assembler::z_msdbr(FloatRegister f1, FloatRegister f3, FloatRegister f2) { emit_32( MSDBR_ZOPC | fregt(f1, 16, 32) | freg(f3, 24, 32) | freg(f2, 28, 32) );} 1177 inline void Assembler::z_maeb(FloatRegister f1, FloatRegister f3, int64_t d2, Register x2, Register b2) { emit_48( MAEB_ZOPC | fregt(f1, 32, 48) | freg(f3, 8, 48) | uimm12(d2, 20, 48) | reg(x2, 12, 48) | regz(b2, 16, 48) );} 1178 inline void Assembler::z_madb(FloatRegister f1, FloatRegister f3, int64_t d2, Register x2, Register b2) { emit_48( MADB_ZOPC | fregt(f1, 32, 48) | freg(f3, 8, 48) | uimm12(d2, 20, 48) | reg(x2, 12, 48) | regz(b2, 16, 48) );} 1179 inline void Assembler::z_mseb(FloatRegister f1, FloatRegister f3, int64_t d2, Register x2, Register b2) { emit_48( MSEB_ZOPC | fregt(f1, 32, 48) | freg(f3, 8, 48) | uimm12(d2, 20, 48) | reg(x2, 12, 48) | regz(b2, 16, 48) );} 1180 inline void Assembler::z_msdb(FloatRegister f1, FloatRegister f3, int64_t d2, Register x2, Register b2) { emit_48( MSDB_ZOPC | fregt(f1, 32, 48) | freg(f3, 8, 48) | uimm12(d2, 20, 48) | reg(x2, 12, 48) | regz(b2, 16, 48) );} 1181 inline void Assembler::z_maeb(FloatRegister f1, FloatRegister f3, const Address& a) { z_maeb(f1, f3, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1182 inline void Assembler::z_madb(FloatRegister f1, FloatRegister f3, const Address& a) { z_madb(f1, f3, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1183 inline void Assembler::z_mseb(FloatRegister f1, FloatRegister f3, const Address& a) { z_mseb(f1, f3, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1184 inline void Assembler::z_msdb(FloatRegister f1, FloatRegister f3, const Address& a) { z_msdb(f1, f3, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1185 1186 1187 //--------------- 1188 // DIV 1189 //--------------- 1190 inline void Assembler::z_debr( FloatRegister f1, FloatRegister f2) { emit_32( DEBR_ZOPC | fregt( f1, 24, 32) | freg( f2, 28, 32));} 1191 inline void Assembler::z_ddbr( FloatRegister f1, FloatRegister f2) { emit_32( DDBR_ZOPC | fregt( f1, 24, 32) | freg( f2, 28, 32));} 1192 inline void Assembler::z_deb( FloatRegister f1, int64_t d2, Register x2, Register b2 ) { emit_48( DEB_ZOPC | fregt( f1, 8, 48) | uimm12( d2, 20, 48) | reg( x2, 12, 48) | regz( b2, 16, 48));} 1193 inline void Assembler::z_ddb( FloatRegister f1, int64_t d2, Register x2, Register b2 ) { emit_48( DDB_ZOPC | fregt( f1, 8, 48) | uimm12( d2, 20, 48) | reg( x2, 12, 48) | regz( b2, 16, 48));} 1194 inline void Assembler::z_deb( FloatRegister r1, const Address& a) { z_deb( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1195 inline void Assembler::z_ddb( FloatRegister r1, const Address& a) { z_ddb( r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1196 1197 1198 //--------------- 1199 // square root 1200 //--------------- 1201 inline void Assembler::z_sqdbr(FloatRegister f1, FloatRegister f2) { emit_32(SQDBR_ZOPC | fregt(f1, 24, 32) | freg(f2, 28, 32)); } 1202 inline void Assembler::z_sqdb( FloatRegister fr1, int64_t d2, Register x2, Register b2 ) { emit_48( SQDB_ZOPC | fregt( fr1, 8, 48) | uimm12( d2, 20, 48) | reg( x2, 12, 48) | regz( b2, 16, 48));} 1203 inline void Assembler::z_sqdb( FloatRegister fr1, int64_t d2, Register b2) { z_sqdb( fr1, d2, Z_R0, b2);} 1204 1205 1206 //--------------- 1207 // CMP 1208 //--------------- 1209 inline void Assembler::z_cebr(FloatRegister r1, FloatRegister r2) { emit_32( CEBR_ZOPC | fregt(r1, 24, 32) | freg(r2, 28, 32)); } 1210 inline void Assembler::z_ceb(FloatRegister r1, int64_t d2, Register x2, Register b2) { emit_48( CEB_ZOPC | fregt(r1, 8, 48) | uimm12(d2, 20, 48) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 1211 inline void Assembler::z_ceb(FloatRegister r1, const Address &a) { z_ceb(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1212 inline void Assembler::z_cdbr(FloatRegister r1, FloatRegister r2) { emit_32( CDBR_ZOPC | fregt(r1, 24, 32) | freg(r2, 28, 32)); } 1213 inline void Assembler::z_cdb(FloatRegister r1, int64_t d2, Register x2, Register b2) { emit_48( CDB_ZOPC | fregt(r1, 8, 48) | uimm12(d2, 20, 48) | reg(x2, 12, 48) | regz(b2, 16, 48)); } 1214 inline void Assembler::z_cdb(FloatRegister r1, const Address &a) { z_cdb(r1, a.disp(), a.indexOrR0(), a.baseOrR0()); } 1215 1216 1217 //------------------------------------ 1218 // FLOAT <-> INT conversion 1219 //------------------------------------ 1220 inline void Assembler::z_ldgr(FloatRegister r1, Register r2) { emit_32( LDGR_ZOPC | fregt(r1, 24, 32) | reg(r2, 28, 32)); } 1221 inline void Assembler::z_lgdr(Register r1, FloatRegister r2) { emit_32( LGDR_ZOPC | regt( r1, 24, 32) | freg(r2, 28, 32)); } 1222 1223 inline void Assembler::z_cefbr( FloatRegister r1, Register r2) { emit_32( CEFBR_ZOPC | fregt( r1, 24, 32) | reg( r2, 28, 32)); } 1224 inline void Assembler::z_cdfbr( FloatRegister r1, Register r2) { emit_32( CDFBR_ZOPC | fregt( r1, 24, 32) | reg( r2, 28, 32)); } 1225 inline void Assembler::z_cegbr( FloatRegister r1, Register r2) { emit_32( CEGBR_ZOPC | fregt( r1, 24, 32) | reg( r2, 28, 32)); } 1226 inline void Assembler::z_cdgbr( FloatRegister r1, Register r2) { emit_32( CDGBR_ZOPC | fregt( r1, 24, 32) | reg( r2, 28, 32)); } 1227 1228 inline void Assembler::z_cfebr(Register r1, FloatRegister r2, RoundingMode m) { emit_32( CFEBR_ZOPC | regt(r1, 24, 32) | rounding_mode(m, 16, 32) | freg(r2, 28, 32)); } 1229 inline void Assembler::z_cfdbr(Register r1, FloatRegister r2, RoundingMode m) { emit_32( CFDBR_ZOPC | regt(r1, 24, 32) | rounding_mode(m, 16, 32) | freg(r2, 28, 32)); } 1230 inline void Assembler::z_cgebr(Register r1, FloatRegister r2, RoundingMode m) { emit_32( CGEBR_ZOPC | regt(r1, 24, 32) | rounding_mode(m, 16, 32) | freg(r2, 28, 32)); } 1231 inline void Assembler::z_cgdbr(Register r1, FloatRegister r2, RoundingMode m) { emit_32( CGDBR_ZOPC | regt(r1, 24, 32) | rounding_mode(m, 16, 32) | freg(r2, 28, 32)); } 1232 1233 1234 inline void Assembler::z_layz(Register r1, int64_t d2, Register b2) { z_layz(r1, d2, Z_R0, b2); } 1235 inline void Assembler::z_lay(Register r1, int64_t d2, Register b2) { z_lay( r1, d2, Z_R0, b2); } 1236 inline void Assembler::z_laz(Register r1, int64_t d2, Register b2) { z_laz( r1, d2, Z_R0, b2); } 1237 inline void Assembler::z_la(Register r1, int64_t d2, Register b2) { z_la( r1, d2, Z_R0, b2); } 1238 inline void Assembler::z_l(Register r1, int64_t d2, Register b2) { z_l( r1, d2, Z_R0, b2); } 1239 inline void Assembler::z_ly(Register r1, int64_t d2, Register b2) { z_ly( r1, d2, Z_R0, b2); } 1240 inline void Assembler::z_lg(Register r1, int64_t d2, Register b2) { z_lg( r1, d2, Z_R0, b2); } 1241 inline void Assembler::z_st(Register r1, int64_t d2, Register b2) { z_st( r1, d2, Z_R0, b2); } 1242 inline void Assembler::z_sty(Register r1, int64_t d2, Register b2) { z_sty( r1, d2, Z_R0, b2); } 1243 inline void Assembler::z_stg(Register r1, int64_t d2, Register b2) { z_stg( r1, d2, Z_R0, b2); } 1244 inline void Assembler::z_lgf(Register r1, int64_t d2, Register b2) { z_lgf( r1, d2, Z_R0, b2); } 1245 inline void Assembler::z_lgh(Register r1, int64_t d2, Register b2) { z_lgh( r1, d2, Z_R0, b2); } 1246 inline void Assembler::z_llgh(Register r1, int64_t d2, Register b2) { z_llgh(r1, d2, Z_R0, b2); } 1247 inline void Assembler::z_llgf(Register r1, int64_t d2, Register b2) { z_llgf(r1, d2, Z_R0, b2); } 1248 inline void Assembler::z_lgb(Register r1, int64_t d2, Register b2) { z_lgb( r1, d2, Z_R0, b2); } 1249 inline void Assembler::z_cl( Register r1, int64_t d2, Register b2) { z_cl( r1, d2, Z_R0, b2); } 1250 inline void Assembler::z_c(Register r1, int64_t d2, Register b2) { z_c( r1, d2, Z_R0, b2); } 1251 inline void Assembler::z_cg(Register r1, int64_t d2, Register b2) { z_cg( r1, d2, Z_R0, b2); } 1252 inline void Assembler::z_sh(Register r1, int64_t d2, Register b2) { z_sh( r1, d2, Z_R0, b2); } 1253 inline void Assembler::z_shy(Register r1, int64_t d2, Register b2) { z_shy( r1, d2, Z_R0, b2); } 1254 inline void Assembler::z_ste(FloatRegister r1, int64_t d2, Register b2) { z_ste( r1, d2, Z_R0, b2); } 1255 inline void Assembler::z_std(FloatRegister r1, int64_t d2, Register b2) { z_std( r1, d2, Z_R0, b2); } 1256 inline void Assembler::z_stdy(FloatRegister r1, int64_t d2, Register b2) { z_stdy(r1, d2, Z_R0, b2); } 1257 inline void Assembler::z_stey(FloatRegister r1, int64_t d2, Register b2) { z_stey(r1, d2, Z_R0, b2); } 1258 inline void Assembler::z_ld(FloatRegister r1, int64_t d2, Register b2) { z_ld( r1, d2, Z_R0, b2); } 1259 inline void Assembler::z_ldy(FloatRegister r1, int64_t d2, Register b2) { z_ldy( r1, d2, Z_R0, b2); } 1260 inline void Assembler::z_le(FloatRegister r1, int64_t d2, Register b2) { z_le( r1, d2, Z_R0, b2); } 1261 inline void Assembler::z_ley(FloatRegister r1, int64_t d2, Register b2) { z_ley( r1, d2, Z_R0, b2); } 1262 inline void Assembler::z_agf(Register r1, int64_t d2, Register b2) { z_agf( r1, d2, Z_R0, b2); } 1263 inline void Assembler::z_cvd(Register r1, int64_t d2, Register b2) { z_cvd( r1, d2, Z_R0, b2); } 1264 inline void Assembler::z_cvdg(Register r1, int64_t d2, Register b2) { z_cvdg(r1, d2, Z_R0, b2); } 1265 1266 // signed comparison 1267 inline void Assembler::z_crj(Register r1, Register r2, branch_condition m3, Label& L) { z_crj( r1, r2, m3, target(L)); } 1268 inline void Assembler::z_cgrj(Register r1, Register r2, branch_condition m3, Label& L) { z_cgrj( r1, r2, m3, target(L)); } 1269 inline void Assembler::z_cij(Register r1, int64_t i2, branch_condition m3, Label& L) { z_cij( r1, i2, m3, target(L)); } 1270 inline void Assembler::z_cgij(Register r1, int64_t i2, branch_condition m3, Label& L) { z_cgij( r1, i2, m3, target(L)); } 1271 // unsigned comparison 1272 inline void Assembler::z_clrj(Register r1, Register r2, branch_condition m3, Label& L) { z_clrj( r1, r2, m3, target(L)); } 1273 inline void Assembler::z_clgrj(Register r1, Register r2, branch_condition m3, Label& L) { z_clgrj(r1, r2, m3, target(L)); } 1274 inline void Assembler::z_clij(Register r1, int64_t i2, branch_condition m3, Label& L) { z_clij( r1, i2, m3, target(L)); } 1275 inline void Assembler::z_clgij(Register r1, int64_t i2, branch_condition m3, Label& L) { z_clgij(r1, i2, m3, target(L)); } 1276 1277 // branch never (nop), branch always 1278 inline void Assembler::z_nop() { z_bcr(bcondNop, Z_R0); } 1279 inline void Assembler::z_br(Register r2) { assert(r2 != Z_R0, "nop if target is Z_R0, use z_nop() instead"); z_bcr(bcondAlways, r2 ); } 1280 1281 inline void Assembler::z_exrl(Register r1, Label& L) { z_exrl(r1, target(L)); } // z10 1282 inline void Assembler::z_larl(Register r1, Label& L) { z_larl(r1, target(L)); } 1283 inline void Assembler::z_bru( Label& L) { z_brc(bcondAlways,target(L)); } 1284 inline void Assembler::z_brul( Label& L) { z_brcl(bcondAlways,target(L)); } 1285 inline void Assembler::z_brul( address a) { z_brcl(bcondAlways,a); } 1286 inline void Assembler::z_brh( Label& L) { z_brc(bcondHigh,target(L)); } 1287 inline void Assembler::z_brl( Label& L) { z_brc(bcondLow,target(L)); } 1288 inline void Assembler::z_bre( Label& L) { z_brc(bcondEqual,target(L)); } 1289 inline void Assembler::z_brnh( Label& L) { z_brc(bcondNotHigh,target(L)); } 1290 inline void Assembler::z_brnl( Label& L) { z_brc(bcondNotLow,target(L)); } 1291 inline void Assembler::z_brne( Label& L) { z_brc(bcondNotEqual,target(L)); } 1292 inline void Assembler::z_brz( Label& L) { z_brc(bcondZero,target(L)); } 1293 inline void Assembler::z_brnz( Label& L) { z_brc(bcondNotZero,target(L)); } 1294 inline void Assembler::z_braz( Label& L) { z_brc(bcondAllZero,target(L)); } 1295 inline void Assembler::z_brnaz( Label& L) { z_brc(bcondNotAllZero,target(L)); } 1296 inline void Assembler::z_brnp( Label& L) { z_brc( bcondNotPositive, target( L)); } 1297 inline void Assembler::z_btrue( Label& L) { z_brc(bcondAllOne,target(L)); } 1298 inline void Assembler::z_bfalse(Label& L) { z_brc(bcondAllZero,target(L)); } 1299 inline void Assembler::z_brno( Label& L) { z_brc(bcondNotOrdered,target(L)); } 1300 inline void Assembler::z_brc( branch_condition m, Label& L) { z_brc(m, target(L)); } 1301 inline void Assembler::z_brcl(branch_condition m, Label& L) { z_brcl(m, target(L)); } 1302 1303 1304 // Instruction must start at passed address. 1305 // Extra check for illtraps with ID. 1306 inline int Assembler::instr_len(unsigned char *instr) { 1307 switch ((*instr) >> 6) { 1308 case 0: return 2; 1309 case 1: // fallthru 1310 case 2: return 4; 1311 case 3: return 6; 1312 default: 1313 // Control can't reach here. 1314 // The switch expression examines just the leftmost two bytes 1315 // of the main opcode. So the range of values is just [0..3]. 1316 // Having a default clause makes the compiler happy. 1317 ShouldNotReachHere(); 1318 return 0; 1319 } 1320 } 1321 1322 // Move instr at pc right-justified into passed long int. 1323 // Return instr len in bytes as function result. 1324 // Note: 2-byte instr don't really need to be accessed unsigned 1325 // because leftmost two bits are always zero. We use 1326 // unsigned here for reasons of uniformity. 1327 inline unsigned int Assembler::get_instruction(unsigned char *pc, unsigned long *instr) { 1328 unsigned int len = instr_len(pc); 1329 switch (len) { 1330 case 2: 1331 *instr = *(unsigned short*) pc; break; 1332 case 4: 1333 *instr = *(unsigned int*) pc; break; 1334 case 6: 1335 // Must compose this case. Can't read 8 bytes and then cut off 1336 // the rightmost two bytes. Could potentially access 1337 // unallocated storage. 1338 *instr = ((unsigned long)(*(unsigned int*) pc)) << 16 | 1339 ((unsigned long)*(unsigned short*) (pc + 4)); break; 1340 default: 1341 // Control can't reach here. 1342 // The length as returned from instr_len() can only be 2, 4, or 6 bytes. 1343 // Having a default clause makes the compiler happy. 1344 ShouldNotReachHere(); 1345 break; 1346 } 1347 return len; 1348 } 1349 1350 // Check if instruction is the expected one. 1351 // Instruction is passed right-justified in inst. 1352 inline bool Assembler::is_equal(unsigned long inst, unsigned long idef) { 1353 unsigned long imask; 1354 1355 if ((idef >> 32) != 0) { // 6byte instructions 1356 switch (idef >> 40) { // select mask by main opcode 1357 case 0xc0: 1358 case 0xc2: 1359 case 0xc4: 1360 case 0xc6: imask = RIL_MASK; break; 1361 case 0xec: 1362 if ((idef & 0x00ffL) < 0x0080L) { 1363 imask = RIE_MASK; 1364 break; 1365 } 1366 // Fallthru for other sub opcodes. 1367 default: 1368 #ifdef ASSERT 1369 tty->print_cr("inst = %16.16lx, idef = %16.16lx, imask unspecified\n", inst, idef); 1370 tty->flush(); 1371 #endif 1372 ShouldNotReachHere(); 1373 return 0; 1374 } 1375 } else { // 4-byte instructions 1376 switch (idef >> 24) { // Select mask by main opcode. 1377 case 0x84: 1378 case 0x85: imask = RSI_MASK; break; 1379 case 0xa5: 1380 case 0xa7: imask = RI_MASK; break; 1381 case 0xb9: imask = RRE_MASK; break; // RRE_MASK or RRF_MASK. Opcode fields are at same bit positions. 1382 default: { 1383 #ifdef ASSERT 1384 tty->print_cr("inst = %16.16lx, idef = %16.16lx, imask unspecified\n", inst, idef); 1385 tty->flush(); 1386 #endif 1387 ShouldNotReachHere(); 1388 return 0; 1389 } 1390 } 1391 } 1392 return (inst & imask) == idef; 1393 } 1394 1395 inline bool Assembler::is_equal(unsigned long inst, unsigned long idef, unsigned long imask) { 1396 assert(imask != 0, "valid instruction mask required"); 1397 return (inst & imask) == idef; 1398 } 1399 1400 // Check if instruction is the expected one. 1401 // Instruction is passed left-justified at inst. 1402 inline bool Assembler::is_equal(address iloc, unsigned long idef) { 1403 unsigned long inst; 1404 get_instruction(iloc, &inst); 1405 return is_equal(inst, idef); 1406 } 1407 1408 inline bool Assembler::is_equal(address iloc, unsigned long idef, unsigned long imask) { 1409 unsigned long inst; 1410 get_instruction(iloc, &inst); 1411 return is_equal(inst, idef, imask); 1412 } 1413 1414 inline bool Assembler::is_sigtrap_range_check(address pc) { 1415 return (is_equal(pc, CLFIT_ZOPC, RIE_MASK) || is_equal(pc, CLRT_ZOPC, RRE_MASK)); 1416 } 1417 1418 inline bool Assembler::is_sigtrap_zero_check(address pc) { 1419 return (is_equal(pc, CGIT_ZOPC, RIE_MASK) || is_equal(pc, CIT_ZOPC, RIE_MASK)); 1420 } 1421 1422 #endif // CPU_S390_VM_ASSEMBLER_S390_INLINE_HPP