| /* |
| * Copyright (c) 1997, 2014, Oracle and/or its affiliates. All rights reserved. |
| * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. |
| * |
| * This code is free software; you can redistribute it and/or modify it |
| * under the terms of the GNU General Public License version 2 only, as |
| * published by the Free Software Foundation. |
| * |
| * This code is distributed in the hope that it will be useful, but WITHOUT |
| * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or |
| * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License |
| * version 2 for more details (a copy is included in the LICENSE file that |
| * accompanied this code). |
| * |
| * You should have received a copy of the GNU General Public License version |
| * 2 along with this work; if not, write to the Free Software Foundation, |
| * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. |
| * |
| * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA |
| * or visit www.oracle.com if you need additional information or have any |
| * questions. |
| * |
| */ |
| |
| #ifndef CPU_SPARC_VM_ASSEMBLER_SPARC_HPP |
| #define CPU_SPARC_VM_ASSEMBLER_SPARC_HPP |
| |
| #include "asm/register.hpp" |
| |
| // The SPARC Assembler: Pure assembler doing NO optimizations on the instruction |
| // level; i.e., what you write |
| // is what you get. The Assembler is generating code into a CodeBuffer. |
| |
| class Assembler : public AbstractAssembler { |
| friend class AbstractAssembler; |
| friend class AddressLiteral; |
| |
| // code patchers need various routines like inv_wdisp() |
| friend class NativeInstruction; |
| friend class NativeGeneralJump; |
| friend class Relocation; |
| friend class Label; |
| |
| public: |
| // op carries format info; see page 62 & 267 |
| |
| enum ops { |
| call_op = 1, // fmt 1 |
| branch_op = 0, // also sethi (fmt2) |
| arith_op = 2, // fmt 3, arith & misc |
| ldst_op = 3 // fmt 3, load/store |
| }; |
| |
| enum op2s { |
| bpr_op2 = 3, |
| fb_op2 = 6, |
| fbp_op2 = 5, |
| br_op2 = 2, |
| bp_op2 = 1, |
| sethi_op2 = 4 |
| }; |
| |
| enum op3s { |
| // selected op3s |
| add_op3 = 0x00, |
| and_op3 = 0x01, |
| or_op3 = 0x02, |
| xor_op3 = 0x03, |
| sub_op3 = 0x04, |
| andn_op3 = 0x05, |
| orn_op3 = 0x06, |
| xnor_op3 = 0x07, |
| addc_op3 = 0x08, |
| mulx_op3 = 0x09, |
| umul_op3 = 0x0a, |
| smul_op3 = 0x0b, |
| subc_op3 = 0x0c, |
| udivx_op3 = 0x0d, |
| udiv_op3 = 0x0e, |
| sdiv_op3 = 0x0f, |
| |
| addcc_op3 = 0x10, |
| andcc_op3 = 0x11, |
| orcc_op3 = 0x12, |
| xorcc_op3 = 0x13, |
| subcc_op3 = 0x14, |
| andncc_op3 = 0x15, |
| orncc_op3 = 0x16, |
| xnorcc_op3 = 0x17, |
| addccc_op3 = 0x18, |
| aes4_op3 = 0x19, |
| umulcc_op3 = 0x1a, |
| smulcc_op3 = 0x1b, |
| subccc_op3 = 0x1c, |
| udivcc_op3 = 0x1e, |
| sdivcc_op3 = 0x1f, |
| |
| taddcc_op3 = 0x20, |
| tsubcc_op3 = 0x21, |
| taddcctv_op3 = 0x22, |
| tsubcctv_op3 = 0x23, |
| mulscc_op3 = 0x24, |
| sll_op3 = 0x25, |
| sllx_op3 = 0x25, |
| srl_op3 = 0x26, |
| srlx_op3 = 0x26, |
| sra_op3 = 0x27, |
| srax_op3 = 0x27, |
| rdreg_op3 = 0x28, |
| membar_op3 = 0x28, |
| |
| flushw_op3 = 0x2b, |
| movcc_op3 = 0x2c, |
| sdivx_op3 = 0x2d, |
| popc_op3 = 0x2e, |
| movr_op3 = 0x2f, |
| |
| sir_op3 = 0x30, |
| wrreg_op3 = 0x30, |
| saved_op3 = 0x31, |
| |
| fpop1_op3 = 0x34, |
| fpop2_op3 = 0x35, |
| impdep1_op3 = 0x36, |
| aes3_op3 = 0x36, |
| sha_op3 = 0x36, |
| alignaddr_op3 = 0x36, |
| faligndata_op3 = 0x36, |
| flog3_op3 = 0x36, |
| edge_op3 = 0x36, |
| fsrc_op3 = 0x36, |
| impdep2_op3 = 0x37, |
| stpartialf_op3 = 0x37, |
| jmpl_op3 = 0x38, |
| rett_op3 = 0x39, |
| trap_op3 = 0x3a, |
| flush_op3 = 0x3b, |
| save_op3 = 0x3c, |
| restore_op3 = 0x3d, |
| done_op3 = 0x3e, |
| retry_op3 = 0x3e, |
| |
| lduw_op3 = 0x00, |
| ldub_op3 = 0x01, |
| lduh_op3 = 0x02, |
| ldd_op3 = 0x03, |
| stw_op3 = 0x04, |
| stb_op3 = 0x05, |
| sth_op3 = 0x06, |
| std_op3 = 0x07, |
| ldsw_op3 = 0x08, |
| ldsb_op3 = 0x09, |
| ldsh_op3 = 0x0a, |
| ldx_op3 = 0x0b, |
| |
| stx_op3 = 0x0e, |
| swap_op3 = 0x0f, |
| |
| stwa_op3 = 0x14, |
| stxa_op3 = 0x1e, |
| |
| ldf_op3 = 0x20, |
| ldfsr_op3 = 0x21, |
| ldqf_op3 = 0x22, |
| lddf_op3 = 0x23, |
| stf_op3 = 0x24, |
| stfsr_op3 = 0x25, |
| stqf_op3 = 0x26, |
| stdf_op3 = 0x27, |
| |
| prefetch_op3 = 0x2d, |
| |
| casa_op3 = 0x3c, |
| casxa_op3 = 0x3e, |
| |
| mftoi_op3 = 0x36, |
| |
| alt_bit_op3 = 0x10, |
| cc_bit_op3 = 0x10 |
| }; |
| |
| enum opfs { |
| // selected opfs |
| edge8n_opf = 0x01, |
| |
| fmovs_opf = 0x01, |
| fmovd_opf = 0x02, |
| |
| fnegs_opf = 0x05, |
| fnegd_opf = 0x06, |
| |
| alignaddr_opf = 0x18, |
| |
| fadds_opf = 0x41, |
| faddd_opf = 0x42, |
| fsubs_opf = 0x45, |
| fsubd_opf = 0x46, |
| |
| faligndata_opf = 0x48, |
| |
| fmuls_opf = 0x49, |
| fmuld_opf = 0x4a, |
| fdivs_opf = 0x4d, |
| fdivd_opf = 0x4e, |
| |
| fcmps_opf = 0x51, |
| fcmpd_opf = 0x52, |
| |
| fstox_opf = 0x81, |
| fdtox_opf = 0x82, |
| fxtos_opf = 0x84, |
| fxtod_opf = 0x88, |
| fitos_opf = 0xc4, |
| fdtos_opf = 0xc6, |
| fitod_opf = 0xc8, |
| fstod_opf = 0xc9, |
| fstoi_opf = 0xd1, |
| fdtoi_opf = 0xd2, |
| |
| mdtox_opf = 0x110, |
| mstouw_opf = 0x111, |
| mstosw_opf = 0x113, |
| mxtod_opf = 0x118, |
| mwtos_opf = 0x119, |
| |
| aes_kexpand0_opf = 0x130, |
| aes_kexpand2_opf = 0x131, |
| |
| sha1_opf = 0x141, |
| sha256_opf = 0x142, |
| sha512_opf = 0x143 |
| }; |
| |
| enum op5s { |
| aes_eround01_op5 = 0x00, |
| aes_eround23_op5 = 0x01, |
| aes_dround01_op5 = 0x02, |
| aes_dround23_op5 = 0x03, |
| aes_eround01_l_op5 = 0x04, |
| aes_eround23_l_op5 = 0x05, |
| aes_dround01_l_op5 = 0x06, |
| aes_dround23_l_op5 = 0x07, |
| aes_kexpand1_op5 = 0x08 |
| }; |
| |
| enum RCondition { rc_z = 1, rc_lez = 2, rc_lz = 3, rc_nz = 5, rc_gz = 6, rc_gez = 7, rc_last = rc_gez }; |
| |
| enum Condition { |
| // for FBfcc & FBPfcc instruction |
| f_never = 0, |
| f_notEqual = 1, |
| f_notZero = 1, |
| f_lessOrGreater = 2, |
| f_unorderedOrLess = 3, |
| f_less = 4, |
| f_unorderedOrGreater = 5, |
| f_greater = 6, |
| f_unordered = 7, |
| f_always = 8, |
| f_equal = 9, |
| f_zero = 9, |
| f_unorderedOrEqual = 10, |
| f_greaterOrEqual = 11, |
| f_unorderedOrGreaterOrEqual = 12, |
| f_lessOrEqual = 13, |
| f_unorderedOrLessOrEqual = 14, |
| f_ordered = 15, |
| |
| // V8 coproc, pp 123 v8 manual |
| |
| cp_always = 8, |
| cp_never = 0, |
| cp_3 = 7, |
| cp_2 = 6, |
| cp_2or3 = 5, |
| cp_1 = 4, |
| cp_1or3 = 3, |
| cp_1or2 = 2, |
| cp_1or2or3 = 1, |
| cp_0 = 9, |
| cp_0or3 = 10, |
| cp_0or2 = 11, |
| cp_0or2or3 = 12, |
| cp_0or1 = 13, |
| cp_0or1or3 = 14, |
| cp_0or1or2 = 15, |
| |
| |
| // for integers |
| |
| never = 0, |
| equal = 1, |
| zero = 1, |
| lessEqual = 2, |
| less = 3, |
| lessEqualUnsigned = 4, |
| lessUnsigned = 5, |
| carrySet = 5, |
| negative = 6, |
| overflowSet = 7, |
| always = 8, |
| notEqual = 9, |
| notZero = 9, |
| greater = 10, |
| greaterEqual = 11, |
| greaterUnsigned = 12, |
| greaterEqualUnsigned = 13, |
| carryClear = 13, |
| positive = 14, |
| overflowClear = 15 |
| }; |
| |
| enum CC { |
| icc = 0, xcc = 2, |
| // ptr_cc is the correct condition code for a pointer or intptr_t: |
| ptr_cc = NOT_LP64(icc) LP64_ONLY(xcc), |
| fcc0 = 0, fcc1 = 1, fcc2 = 2, fcc3 = 3 |
| }; |
| |
| enum PrefetchFcn { |
| severalReads = 0, oneRead = 1, severalWritesAndPossiblyReads = 2, oneWrite = 3, page = 4 |
| }; |
| |
| public: |
| // Helper functions for groups of instructions |
| |
| enum Predict { pt = 1, pn = 0 }; // pt = predict taken |
| |
| enum Membar_mask_bits { // page 184, v9 |
| StoreStore = 1 << 3, |
| LoadStore = 1 << 2, |
| StoreLoad = 1 << 1, |
| LoadLoad = 1 << 0, |
| |
| Sync = 1 << 6, |
| MemIssue = 1 << 5, |
| Lookaside = 1 << 4 |
| }; |
| |
| static bool is_in_wdisp_range(address a, address b, int nbits) { |
| intptr_t d = intptr_t(b) - intptr_t(a); |
| return is_simm(d, nbits + 2); |
| } |
| |
| address target_distance(Label& L) { |
| // Assembler::target(L) should be called only when |
| // a branch instruction is emitted since non-bound |
| // labels record current pc() as a branch address. |
| if (L.is_bound()) return target(L); |
| // Return current address for non-bound labels. |
| return pc(); |
| } |
| |
| // test if label is in simm16 range in words (wdisp16). |
| bool is_in_wdisp16_range(Label& L) { |
| return is_in_wdisp_range(target_distance(L), pc(), 16); |
| } |
| // test if the distance between two addresses fits in simm30 range in words |
| static bool is_in_wdisp30_range(address a, address b) { |
| return is_in_wdisp_range(a, b, 30); |
| } |
| |
| enum ASIs { // page 72, v9 |
| ASI_PRIMARY = 0x80, |
| ASI_PRIMARY_NOFAULT = 0x82, |
| ASI_PRIMARY_LITTLE = 0x88, |
| // 8x8-bit partial store |
| ASI_PST8_PRIMARY = 0xC0, |
| // Block initializing store |
| ASI_ST_BLKINIT_PRIMARY = 0xE2, |
| // Most-Recently-Used (MRU) BIS variant |
| ASI_ST_BLKINIT_MRU_PRIMARY = 0xF2 |
| // add more from book as needed |
| }; |
| |
| protected: |
| // helpers |
| |
| // x is supposed to fit in a field "nbits" wide |
| // and be sign-extended. Check the range. |
| |
| static void assert_signed_range(intptr_t x, int nbits) { |
| assert(nbits == 32 || (-(1 << nbits-1) <= x && x < ( 1 << nbits-1)), |
| err_msg("value out of range: x=" INTPTR_FORMAT ", nbits=%d", x, nbits)); |
| } |
| |
| static void assert_signed_word_disp_range(intptr_t x, int nbits) { |
| assert( (x & 3) == 0, "not word aligned"); |
| assert_signed_range(x, nbits + 2); |
| } |
| |
| static void assert_unsigned_const(int x, int nbits) { |
| assert( juint(x) < juint(1 << nbits), "unsigned constant out of range"); |
| } |
| |
| // fields: note bits numbered from LSB = 0, |
| // fields known by inclusive bit range |
| |
| static int fmask(juint hi_bit, juint lo_bit) { |
| assert( hi_bit >= lo_bit && 0 <= lo_bit && hi_bit < 32, "bad bits"); |
| return (1 << ( hi_bit-lo_bit + 1 )) - 1; |
| } |
| |
| // inverse of u_field |
| |
| static int inv_u_field(int x, int hi_bit, int lo_bit) { |
| juint r = juint(x) >> lo_bit; |
| r &= fmask( hi_bit, lo_bit); |
| return int(r); |
| } |
| |
| |
| // signed version: extract from field and sign-extend |
| |
| static int inv_s_field(int x, int hi_bit, int lo_bit) { |
| int sign_shift = 31 - hi_bit; |
| return inv_u_field( ((x << sign_shift) >> sign_shift), hi_bit, lo_bit); |
| } |
| |
| // given a field that ranges from hi_bit to lo_bit (inclusive, |
| // LSB = 0), and an unsigned value for the field, |
| // shift it into the field |
| |
| #ifdef ASSERT |
| static int u_field(int x, int hi_bit, int lo_bit) { |
| assert( ( x & ~fmask(hi_bit, lo_bit)) == 0, |
| "value out of range"); |
| int r = x << lo_bit; |
| assert( inv_u_field(r, hi_bit, lo_bit) == x, "just checking"); |
| return r; |
| } |
| #else |
| // make sure this is inlined as it will reduce code size significantly |
| #define u_field(x, hi_bit, lo_bit) ((x) << (lo_bit)) |
| #endif |
| |
| static int inv_op( int x ) { return inv_u_field(x, 31, 30); } |
| static int inv_op2( int x ) { return inv_u_field(x, 24, 22); } |
| static int inv_op3( int x ) { return inv_u_field(x, 24, 19); } |
| static int inv_cond( int x ){ return inv_u_field(x, 28, 25); } |
| |
| static bool inv_immed( int x ) { return (x & Assembler::immed(true)) != 0; } |
| |
| static Register inv_rd( int x ) { return as_Register(inv_u_field(x, 29, 25)); } |
| static Register inv_rs1( int x ) { return as_Register(inv_u_field(x, 18, 14)); } |
| static Register inv_rs2( int x ) { return as_Register(inv_u_field(x, 4, 0)); } |
| |
| static int op( int x) { return u_field(x, 31, 30); } |
| static int rd( Register r) { return u_field(r->encoding(), 29, 25); } |
| static int fcn( int x) { return u_field(x, 29, 25); } |
| static int op3( int x) { return u_field(x, 24, 19); } |
| static int rs1( Register r) { return u_field(r->encoding(), 18, 14); } |
| static int rs2( Register r) { return u_field(r->encoding(), 4, 0); } |
| static int annul( bool a) { return u_field(a ? 1 : 0, 29, 29); } |
| static int cond( int x) { return u_field(x, 28, 25); } |
| static int cond_mov( int x) { return u_field(x, 17, 14); } |
| static int rcond( RCondition x) { return u_field(x, 12, 10); } |
| static int op2( int x) { return u_field(x, 24, 22); } |
| static int predict( bool p) { return u_field(p ? 1 : 0, 19, 19); } |
| static int branchcc( CC fcca) { return u_field(fcca, 21, 20); } |
| static int cmpcc( CC fcca) { return u_field(fcca, 26, 25); } |
| static int imm_asi( int x) { return u_field(x, 12, 5); } |
| static int immed( bool i) { return u_field(i ? 1 : 0, 13, 13); } |
| static int opf_low6( int w) { return u_field(w, 10, 5); } |
| static int opf_low5( int w) { return u_field(w, 9, 5); } |
| static int op5( int x) { return u_field(x, 8, 5); } |
| static int trapcc( CC cc) { return u_field(cc, 12, 11); } |
| static int sx( int i) { return u_field(i, 12, 12); } // shift x=1 means 64-bit |
| static int opf( int x) { return u_field(x, 13, 5); } |
| |
| static bool is_cbcond( int x ) { |
| return (VM_Version::has_cbcond() && (inv_cond(x) > rc_last) && |
| inv_op(x) == branch_op && inv_op2(x) == bpr_op2); |
| } |
| static bool is_cxb( int x ) { |
| assert(is_cbcond(x), "wrong instruction"); |
| return (x & (1<<21)) != 0; |
| } |
| static int cond_cbcond( int x) { return u_field((((x & 8)<<1) + 8 + (x & 7)), 29, 25); } |
| static int inv_cond_cbcond(int x) { |
| assert(is_cbcond(x), "wrong instruction"); |
| return inv_u_field(x, 27, 25) | (inv_u_field(x, 29, 29)<<3); |
| } |
| |
| static int opf_cc( CC c, bool useFloat ) { return u_field((useFloat ? 0 : 4) + c, 13, 11); } |
| static int mov_cc( CC c, bool useFloat ) { return u_field(useFloat ? 0 : 1, 18, 18) | u_field(c, 12, 11); } |
| |
| static int fd( FloatRegister r, FloatRegisterImpl::Width fwa) { return u_field(r->encoding(fwa), 29, 25); }; |
| static int fs1(FloatRegister r, FloatRegisterImpl::Width fwa) { return u_field(r->encoding(fwa), 18, 14); }; |
| static int fs2(FloatRegister r, FloatRegisterImpl::Width fwa) { return u_field(r->encoding(fwa), 4, 0); }; |
| static int fs3(FloatRegister r, FloatRegisterImpl::Width fwa) { return u_field(r->encoding(fwa), 13, 9); }; |
| |
| // some float instructions use this encoding on the op3 field |
| static int alt_op3(int op, FloatRegisterImpl::Width w) { |
| int r; |
| switch(w) { |
| case FloatRegisterImpl::S: r = op + 0; break; |
| case FloatRegisterImpl::D: r = op + 3; break; |
| case FloatRegisterImpl::Q: r = op + 2; break; |
| default: ShouldNotReachHere(); break; |
| } |
| return op3(r); |
| } |
| |
| |
| // compute inverse of simm |
| static int inv_simm(int x, int nbits) { |
| return (int)(x << (32 - nbits)) >> (32 - nbits); |
| } |
| |
| static int inv_simm13( int x ) { return inv_simm(x, 13); } |
| |
| // signed immediate, in low bits, nbits long |
| static int simm(int x, int nbits) { |
| assert_signed_range(x, nbits); |
| return x & (( 1 << nbits ) - 1); |
| } |
| |
| // compute inverse of wdisp16 |
| static intptr_t inv_wdisp16(int x, intptr_t pos) { |
| int lo = x & (( 1 << 14 ) - 1); |
| int hi = (x >> 20) & 3; |
| if (hi >= 2) hi |= ~1; |
| return (((hi << 14) | lo) << 2) + pos; |
| } |
| |
| // word offset, 14 bits at LSend, 2 bits at B21, B20 |
| static int wdisp16(intptr_t x, intptr_t off) { |
| intptr_t xx = x - off; |
| assert_signed_word_disp_range(xx, 16); |
| int r = (xx >> 2) & ((1 << 14) - 1) |
| | ( ( (xx>>(2+14)) & 3 ) << 20 ); |
| assert( inv_wdisp16(r, off) == x, "inverse is not inverse"); |
| return r; |
| } |
| |
| // compute inverse of wdisp10 |
| static intptr_t inv_wdisp10(int x, intptr_t pos) { |
| assert(is_cbcond(x), "wrong instruction"); |
| int lo = inv_u_field(x, 12, 5); |
| int hi = (x >> 19) & 3; |
| if (hi >= 2) hi |= ~1; |
| return (((hi << 8) | lo) << 2) + pos; |
| } |
| |
| // word offset for cbcond, 8 bits at [B12,B5], 2 bits at [B20,B19] |
| static int wdisp10(intptr_t x, intptr_t off) { |
| assert(VM_Version::has_cbcond(), "This CPU does not have CBCOND instruction"); |
| intptr_t xx = x - off; |
| assert_signed_word_disp_range(xx, 10); |
| int r = ( ( (xx >> 2 ) & ((1 << 8) - 1) ) << 5 ) |
| | ( ( (xx >> (2+8)) & 3 ) << 19 ); |
| // Have to fake cbcond instruction to pass assert in inv_wdisp10() |
| assert(inv_wdisp10((r | op(branch_op) | cond_cbcond(rc_last+1) | op2(bpr_op2)), off) == x, "inverse is not inverse"); |
| return r; |
| } |
| |
| // word displacement in low-order nbits bits |
| |
| static intptr_t inv_wdisp( int x, intptr_t pos, int nbits ) { |
| int pre_sign_extend = x & (( 1 << nbits ) - 1); |
| int r = pre_sign_extend >= ( 1 << (nbits-1) ) |
| ? pre_sign_extend | ~(( 1 << nbits ) - 1) |
| : pre_sign_extend; |
| return (r << 2) + pos; |
| } |
| |
| static int wdisp( intptr_t x, intptr_t off, int nbits ) { |
| intptr_t xx = x - off; |
| assert_signed_word_disp_range(xx, nbits); |
| int r = (xx >> 2) & (( 1 << nbits ) - 1); |
| assert( inv_wdisp( r, off, nbits ) == x, "inverse not inverse"); |
| return r; |
| } |
| |
| |
| // Extract the top 32 bits in a 64 bit word |
| static int32_t hi32( int64_t x ) { |
| int32_t r = int32_t( (uint64_t)x >> 32 ); |
| return r; |
| } |
| |
| // given a sethi instruction, extract the constant, left-justified |
| static int inv_hi22( int x ) { |
| return x << 10; |
| } |
| |
| // create an imm22 field, given a 32-bit left-justified constant |
| static int hi22( int x ) { |
| int r = int( juint(x) >> 10 ); |
| assert( (r & ~((1 << 22) - 1)) == 0, "just checkin'"); |
| return r; |
| } |
| |
| // create a low10 __value__ (not a field) for a given a 32-bit constant |
| static int low10( int x ) { |
| return x & ((1 << 10) - 1); |
| } |
| |
| // AES crypto instructions supported only on certain processors |
| static void aes_only() { assert( VM_Version::has_aes(), "This instruction only works on SPARC with AES instructions support"); } |
| |
| // SHA crypto instructions supported only on certain processors |
| static void sha1_only() { assert( VM_Version::has_sha1(), "This instruction only works on SPARC with SHA1"); } |
| static void sha256_only() { assert( VM_Version::has_sha256(), "This instruction only works on SPARC with SHA256"); } |
| static void sha512_only() { assert( VM_Version::has_sha512(), "This instruction only works on SPARC with SHA512"); } |
| |
| // instruction only in VIS1 |
| static void vis1_only() { assert( VM_Version::has_vis1(), "This instruction only works on SPARC with VIS1"); } |
| |
| // instruction only in VIS2 |
| static void vis2_only() { assert( VM_Version::has_vis2(), "This instruction only works on SPARC with VIS2"); } |
| |
| // instruction only in VIS3 |
| static void vis3_only() { assert( VM_Version::has_vis3(), "This instruction only works on SPARC with VIS3"); } |
| |
| // instruction only in v9 |
| static void v9_only() { } // do nothing |
| |
| // instruction deprecated in v9 |
| static void v9_dep() { } // do nothing for now |
| |
| // v8 has no CC field |
| static void v8_no_cc(CC cc) { if (cc) v9_only(); } |
| |
| protected: |
| // Simple delay-slot scheme: |
| // In order to check the programmer, the assembler keeps track of deley slots. |
| // It forbids CTIs in delay slots (conservative, but should be OK). |
| // Also, when putting an instruction into a delay slot, you must say |
| // asm->delayed()->add(...), in order to check that you don't omit |
| // delay-slot instructions. |
| // To implement this, we use a simple FSA |
| |
| #ifdef ASSERT |
| #define CHECK_DELAY |
| #endif |
| #ifdef CHECK_DELAY |
| enum Delay_state { no_delay, at_delay_slot, filling_delay_slot } delay_state; |
| #endif |
| |
| public: |
| // Tells assembler next instruction must NOT be in delay slot. |
| // Use at start of multinstruction macros. |
| void assert_not_delayed() { |
| // This is a separate overloading to avoid creation of string constants |
| // in non-asserted code--with some compilers this pollutes the object code. |
| #ifdef CHECK_DELAY |
| assert_not_delayed("next instruction should not be a delay slot"); |
| #endif |
| } |
| void assert_not_delayed(const char* msg) { |
| #ifdef CHECK_DELAY |
| assert(delay_state == no_delay, msg); |
| #endif |
| } |
| |
| protected: |
| // Insert a nop if the previous is cbcond |
| void insert_nop_after_cbcond() { |
| if (UseCBCond && cbcond_before()) { |
| nop(); |
| } |
| } |
| // Delay slot helpers |
| // cti is called when emitting control-transfer instruction, |
| // BEFORE doing the emitting. |
| // Only effective when assertion-checking is enabled. |
| void cti() { |
| // A cbcond instruction immediately followed by a CTI |
| // instruction introduces pipeline stalls, we need to avoid that. |
| no_cbcond_before(); |
| #ifdef CHECK_DELAY |
| assert_not_delayed("cti should not be in delay slot"); |
| #endif |
| } |
| |
| // called when emitting cti with a delay slot, AFTER emitting |
| void has_delay_slot() { |
| #ifdef CHECK_DELAY |
| assert_not_delayed("just checking"); |
| delay_state = at_delay_slot; |
| #endif |
| } |
| |
| // cbcond instruction should not be generated one after an other |
| bool cbcond_before() { |
| if (offset() == 0) return false; // it is first instruction |
| int x = *(int*)(intptr_t(pc()) - 4); // previous instruction |
| return is_cbcond(x); |
| } |
| |
| void no_cbcond_before() { |
| assert(offset() == 0 || !cbcond_before(), "cbcond should not follow an other cbcond"); |
| } |
| public: |
| |
| bool use_cbcond(Label& L) { |
| if (!UseCBCond || cbcond_before()) return false; |
| intptr_t x = intptr_t(target_distance(L)) - intptr_t(pc()); |
| assert( (x & 3) == 0, "not word aligned"); |
| return is_simm12(x); |
| } |
| |
| // Tells assembler you know that next instruction is delayed |
| Assembler* delayed() { |
| #ifdef CHECK_DELAY |
| assert ( delay_state == at_delay_slot, "delayed instruction is not in delay slot"); |
| delay_state = filling_delay_slot; |
| #endif |
| return this; |
| } |
| |
| void flush() { |
| #ifdef CHECK_DELAY |
| assert ( delay_state == no_delay, "ending code with a delay slot"); |
| #endif |
| AbstractAssembler::flush(); |
| } |
| |
| inline void emit_int32(int); // shadows AbstractAssembler::emit_int32 |
| inline void emit_data(int x) { emit_int32(x); } |
| inline void emit_data(int, RelocationHolder const&); |
| inline void emit_data(int, relocInfo::relocType rtype); |
| // helper for above fcns |
| inline void check_delay(); |
| |
| |
| public: |
| // instructions, refer to page numbers in the SPARC Architecture Manual, V9 |
| |
| // pp 135 (addc was addx in v8) |
| |
| inline void add(Register s1, Register s2, Register d ); |
| inline void add(Register s1, int simm13a, Register d ); |
| |
| void addcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(add_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void addcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(add_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void addc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(addc_op3 ) | rs1(s1) | rs2(s2) ); } |
| void addc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(addc_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void addccc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(addc_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void addccc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(addc_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| |
| // 4-operand AES instructions |
| |
| void aes_eround01( FloatRegister s1, FloatRegister s2, FloatRegister s3, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes4_op3) | fs1(s1, FloatRegisterImpl::D) | fs3(s3, FloatRegisterImpl::D) | op5(aes_eround01_op5) | fs2(s2, FloatRegisterImpl::D) ); } |
| void aes_eround23( FloatRegister s1, FloatRegister s2, FloatRegister s3, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes4_op3) | fs1(s1, FloatRegisterImpl::D) | fs3(s3, FloatRegisterImpl::D) | op5(aes_eround23_op5) | fs2(s2, FloatRegisterImpl::D) ); } |
| void aes_dround01( FloatRegister s1, FloatRegister s2, FloatRegister s3, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes4_op3) | fs1(s1, FloatRegisterImpl::D) | fs3(s3, FloatRegisterImpl::D) | op5(aes_dround01_op5) | fs2(s2, FloatRegisterImpl::D) ); } |
| void aes_dround23( FloatRegister s1, FloatRegister s2, FloatRegister s3, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes4_op3) | fs1(s1, FloatRegisterImpl::D) | fs3(s3, FloatRegisterImpl::D) | op5(aes_dround23_op5) | fs2(s2, FloatRegisterImpl::D) ); } |
| void aes_eround01_l( FloatRegister s1, FloatRegister s2, FloatRegister s3, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes4_op3) | fs1(s1, FloatRegisterImpl::D) | fs3(s3, FloatRegisterImpl::D) | op5(aes_eround01_l_op5) | fs2(s2, FloatRegisterImpl::D) ); } |
| void aes_eround23_l( FloatRegister s1, FloatRegister s2, FloatRegister s3, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes4_op3) | fs1(s1, FloatRegisterImpl::D) | fs3(s3, FloatRegisterImpl::D) | op5(aes_eround23_l_op5) | fs2(s2, FloatRegisterImpl::D) ); } |
| void aes_dround01_l( FloatRegister s1, FloatRegister s2, FloatRegister s3, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes4_op3) | fs1(s1, FloatRegisterImpl::D) | fs3(s3, FloatRegisterImpl::D) | op5(aes_dround01_l_op5) | fs2(s2, FloatRegisterImpl::D) ); } |
| void aes_dround23_l( FloatRegister s1, FloatRegister s2, FloatRegister s3, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes4_op3) | fs1(s1, FloatRegisterImpl::D) | fs3(s3, FloatRegisterImpl::D) | op5(aes_dround23_l_op5) | fs2(s2, FloatRegisterImpl::D) ); } |
| void aes_kexpand1( FloatRegister s1, FloatRegister s2, int imm5a, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes4_op3) | fs1(s1, FloatRegisterImpl::D) | u_field(imm5a, 13, 9) | op5(aes_kexpand1_op5) | fs2(s2, FloatRegisterImpl::D) ); } |
| |
| |
| // 3-operand AES instructions |
| |
| void aes_kexpand0( FloatRegister s1, FloatRegister s2, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes3_op3) | fs1(s1, FloatRegisterImpl::D) | opf(aes_kexpand0_opf) | fs2(s2, FloatRegisterImpl::D) ); } |
| void aes_kexpand2( FloatRegister s1, FloatRegister s2, FloatRegister d ) { aes_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(aes3_op3) | fs1(s1, FloatRegisterImpl::D) | opf(aes_kexpand2_opf) | fs2(s2, FloatRegisterImpl::D) ); } |
| |
| // pp 136 |
| |
| inline void bpr(RCondition c, bool a, Predict p, Register s1, address d, relocInfo::relocType rt = relocInfo::none); |
| inline void bpr(RCondition c, bool a, Predict p, Register s1, Label& L); |
| |
| // compare and branch |
| inline void cbcond(Condition c, CC cc, Register s1, Register s2, Label& L); |
| inline void cbcond(Condition c, CC cc, Register s1, int simm5, Label& L); |
| |
| protected: // use MacroAssembler::br instead |
| |
| // pp 138 |
| |
| inline void fb( Condition c, bool a, address d, relocInfo::relocType rt = relocInfo::none ); |
| inline void fb( Condition c, bool a, Label& L ); |
| |
| // pp 141 |
| |
| inline void fbp( Condition c, bool a, CC cc, Predict p, address d, relocInfo::relocType rt = relocInfo::none ); |
| inline void fbp( Condition c, bool a, CC cc, Predict p, Label& L ); |
| |
| // pp 144 |
| |
| inline void br( Condition c, bool a, address d, relocInfo::relocType rt = relocInfo::none ); |
| inline void br( Condition c, bool a, Label& L ); |
| |
| // pp 146 |
| |
| inline void bp( Condition c, bool a, CC cc, Predict p, address d, relocInfo::relocType rt = relocInfo::none ); |
| inline void bp( Condition c, bool a, CC cc, Predict p, Label& L ); |
| |
| // pp 149 |
| |
| inline void call( address d, relocInfo::relocType rt = relocInfo::runtime_call_type ); |
| inline void call( Label& L, relocInfo::relocType rt = relocInfo::runtime_call_type ); |
| |
| public: |
| |
| // pp 150 |
| |
| // These instructions compare the contents of s2 with the contents of |
| // memory at address in s1. If the values are equal, the contents of memory |
| // at address s1 is swapped with the data in d. If the values are not equal, |
| // the the contents of memory at s1 is loaded into d, without the swap. |
| |
| void casa( Register s1, Register s2, Register d, int ia = -1 ) { v9_only(); emit_int32( op(ldst_op) | rd(d) | op3(casa_op3 ) | rs1(s1) | (ia == -1 ? immed(true) : imm_asi(ia)) | rs2(s2)); } |
| void casxa( Register s1, Register s2, Register d, int ia = -1 ) { v9_only(); emit_int32( op(ldst_op) | rd(d) | op3(casxa_op3) | rs1(s1) | (ia == -1 ? immed(true) : imm_asi(ia)) | rs2(s2)); } |
| |
| // pp 152 |
| |
| void udiv( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(udiv_op3 ) | rs1(s1) | rs2(s2)); } |
| void udiv( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(udiv_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void sdiv( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sdiv_op3 ) | rs1(s1) | rs2(s2)); } |
| void sdiv( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sdiv_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void udivcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(udiv_op3 | cc_bit_op3) | rs1(s1) | rs2(s2)); } |
| void udivcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(udiv_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void sdivcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sdiv_op3 | cc_bit_op3) | rs1(s1) | rs2(s2)); } |
| void sdivcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sdiv_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 155 |
| |
| void done() { v9_only(); cti(); emit_int32( op(arith_op) | fcn(0) | op3(done_op3) ); } |
| void retry() { v9_only(); cti(); emit_int32( op(arith_op) | fcn(1) | op3(retry_op3) ); } |
| |
| // pp 156 |
| |
| void fadd( FloatRegisterImpl::Width w, FloatRegister s1, FloatRegister s2, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, w) | op3(fpop1_op3) | fs1(s1, w) | opf(0x40 + w) | fs2(s2, w)); } |
| void fsub( FloatRegisterImpl::Width w, FloatRegister s1, FloatRegister s2, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, w) | op3(fpop1_op3) | fs1(s1, w) | opf(0x44 + w) | fs2(s2, w)); } |
| |
| // pp 157 |
| |
| void fcmp( FloatRegisterImpl::Width w, CC cc, FloatRegister s1, FloatRegister s2) { emit_int32( op(arith_op) | cmpcc(cc) | op3(fpop2_op3) | fs1(s1, w) | opf(0x50 + w) | fs2(s2, w)); } |
| void fcmpe( FloatRegisterImpl::Width w, CC cc, FloatRegister s1, FloatRegister s2) { emit_int32( op(arith_op) | cmpcc(cc) | op3(fpop2_op3) | fs1(s1, w) | opf(0x54 + w) | fs2(s2, w)); } |
| |
| // pp 159 |
| |
| void ftox( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { v9_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(fpop1_op3) | opf(0x80 + w) | fs2(s, w)); } |
| void ftoi( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::S) | op3(fpop1_op3) | opf(0xd0 + w) | fs2(s, w)); } |
| |
| // pp 160 |
| |
| void ftof( FloatRegisterImpl::Width sw, FloatRegisterImpl::Width dw, FloatRegister s, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, dw) | op3(fpop1_op3) | opf(0xc0 + sw + dw*4) | fs2(s, sw)); } |
| |
| // pp 161 |
| |
| void fxtof( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { v9_only(); emit_int32( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x80 + w*4) | fs2(s, FloatRegisterImpl::D)); } |
| void fitof( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0xc0 + w*4) | fs2(s, FloatRegisterImpl::S)); } |
| |
| // pp 162 |
| |
| void fmov( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x00 + w) | fs2(s, w)); } |
| |
| void fneg( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x04 + w) | fs2(s, w)); } |
| |
| void fabs( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x08 + w) | fs2(s, w)); } |
| |
| // pp 163 |
| |
| void fmul( FloatRegisterImpl::Width w, FloatRegister s1, FloatRegister s2, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, w) | op3(fpop1_op3) | fs1(s1, w) | opf(0x48 + w) | fs2(s2, w)); } |
| void fmul( FloatRegisterImpl::Width sw, FloatRegisterImpl::Width dw, FloatRegister s1, FloatRegister s2, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, dw) | op3(fpop1_op3) | fs1(s1, sw) | opf(0x60 + sw + dw*4) | fs2(s2, sw)); } |
| void fdiv( FloatRegisterImpl::Width w, FloatRegister s1, FloatRegister s2, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, w) | op3(fpop1_op3) | fs1(s1, w) | opf(0x4c + w) | fs2(s2, w)); } |
| |
| // FXORs/FXORd instructions |
| |
| void fxor( FloatRegisterImpl::Width w, FloatRegister s1, FloatRegister s2, FloatRegister d ) { vis1_only(); emit_int32( op(arith_op) | fd(d, w) | op3(flog3_op3) | fs1(s1, w) | opf(0x6E - w) | fs2(s2, w)); } |
| |
| // pp 164 |
| |
| void fsqrt( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { emit_int32( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x28 + w) | fs2(s, w)); } |
| |
| // pp 165 |
| |
| inline void flush( Register s1, Register s2 ); |
| inline void flush( Register s1, int simm13a); |
| |
| // pp 167 |
| |
| void flushw() { v9_only(); emit_int32( op(arith_op) | op3(flushw_op3) ); } |
| |
| // pp 168 |
| |
| void illtrap( int const22a) { if (const22a != 0) v9_only(); emit_int32( op(branch_op) | u_field(const22a, 21, 0) ); } |
| // v8 unimp == illtrap(0) |
| |
| // pp 169 |
| |
| void impdep1( int id1, int const19a ) { v9_only(); emit_int32( op(arith_op) | fcn(id1) | op3(impdep1_op3) | u_field(const19a, 18, 0)); } |
| void impdep2( int id1, int const19a ) { v9_only(); emit_int32( op(arith_op) | fcn(id1) | op3(impdep2_op3) | u_field(const19a, 18, 0)); } |
| |
| // pp 170 |
| |
| void jmpl( Register s1, Register s2, Register d ); |
| void jmpl( Register s1, int simm13a, Register d, RelocationHolder const& rspec = RelocationHolder() ); |
| |
| // 171 |
| |
| inline void ldf(FloatRegisterImpl::Width w, Register s1, Register s2, FloatRegister d); |
| inline void ldf(FloatRegisterImpl::Width w, Register s1, int simm13a, FloatRegister d, RelocationHolder const& rspec = RelocationHolder()); |
| |
| |
| inline void ldfsr( Register s1, Register s2 ); |
| inline void ldfsr( Register s1, int simm13a); |
| inline void ldxfsr( Register s1, Register s2 ); |
| inline void ldxfsr( Register s1, int simm13a); |
| |
| // 173 |
| |
| void ldfa( FloatRegisterImpl::Width w, Register s1, Register s2, int ia, FloatRegister d ) { v9_only(); emit_int32( op(ldst_op) | fd(d, w) | alt_op3(ldf_op3 | alt_bit_op3, w) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void ldfa( FloatRegisterImpl::Width w, Register s1, int simm13a, FloatRegister d ) { v9_only(); emit_int32( op(ldst_op) | fd(d, w) | alt_op3(ldf_op3 | alt_bit_op3, w) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 175, lduw is ld on v8 |
| |
| inline void ldsb( Register s1, Register s2, Register d ); |
| inline void ldsb( Register s1, int simm13a, Register d); |
| inline void ldsh( Register s1, Register s2, Register d ); |
| inline void ldsh( Register s1, int simm13a, Register d); |
| inline void ldsw( Register s1, Register s2, Register d ); |
| inline void ldsw( Register s1, int simm13a, Register d); |
| inline void ldub( Register s1, Register s2, Register d ); |
| inline void ldub( Register s1, int simm13a, Register d); |
| inline void lduh( Register s1, Register s2, Register d ); |
| inline void lduh( Register s1, int simm13a, Register d); |
| inline void lduw( Register s1, Register s2, Register d ); |
| inline void lduw( Register s1, int simm13a, Register d); |
| inline void ldx( Register s1, Register s2, Register d ); |
| inline void ldx( Register s1, int simm13a, Register d); |
| inline void ldd( Register s1, Register s2, Register d ); |
| inline void ldd( Register s1, int simm13a, Register d); |
| |
| // pp 177 |
| |
| void ldsba( Register s1, Register s2, int ia, Register d ) { emit_int32( op(ldst_op) | rd(d) | op3(ldsb_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void ldsba( Register s1, int simm13a, Register d ) { emit_int32( op(ldst_op) | rd(d) | op3(ldsb_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void ldsha( Register s1, Register s2, int ia, Register d ) { emit_int32( op(ldst_op) | rd(d) | op3(ldsh_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void ldsha( Register s1, int simm13a, Register d ) { emit_int32( op(ldst_op) | rd(d) | op3(ldsh_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void ldswa( Register s1, Register s2, int ia, Register d ) { v9_only(); emit_int32( op(ldst_op) | rd(d) | op3(ldsw_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void ldswa( Register s1, int simm13a, Register d ) { v9_only(); emit_int32( op(ldst_op) | rd(d) | op3(ldsw_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void lduba( Register s1, Register s2, int ia, Register d ) { emit_int32( op(ldst_op) | rd(d) | op3(ldub_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void lduba( Register s1, int simm13a, Register d ) { emit_int32( op(ldst_op) | rd(d) | op3(ldub_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void lduha( Register s1, Register s2, int ia, Register d ) { emit_int32( op(ldst_op) | rd(d) | op3(lduh_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void lduha( Register s1, int simm13a, Register d ) { emit_int32( op(ldst_op) | rd(d) | op3(lduh_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void lduwa( Register s1, Register s2, int ia, Register d ) { emit_int32( op(ldst_op) | rd(d) | op3(lduw_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void lduwa( Register s1, int simm13a, Register d ) { emit_int32( op(ldst_op) | rd(d) | op3(lduw_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void ldxa( Register s1, Register s2, int ia, Register d ) { v9_only(); emit_int32( op(ldst_op) | rd(d) | op3(ldx_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void ldxa( Register s1, int simm13a, Register d ) { v9_only(); emit_int32( op(ldst_op) | rd(d) | op3(ldx_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 181 |
| |
| void and3( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(and_op3 ) | rs1(s1) | rs2(s2) ); } |
| void and3( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(and_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void andcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(and_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void andcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(and_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void andn( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(andn_op3 ) | rs1(s1) | rs2(s2) ); } |
| void andn( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(andn_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void andncc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(andn_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void andncc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(andn_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void or3( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(or_op3 ) | rs1(s1) | rs2(s2) ); } |
| void or3( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(or_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void orcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(or_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void orcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(or_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void orn( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(orn_op3) | rs1(s1) | rs2(s2) ); } |
| void orn( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(orn_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void orncc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(orn_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void orncc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(orn_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void xor3( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(xor_op3 ) | rs1(s1) | rs2(s2) ); } |
| void xor3( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(xor_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void xorcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(xor_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void xorcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(xor_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void xnor( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(xnor_op3 ) | rs1(s1) | rs2(s2) ); } |
| void xnor( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(xnor_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void xnorcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(xnor_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void xnorcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(xnor_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 183 |
| |
| void membar( Membar_mask_bits const7a ) { v9_only(); emit_int32( op(arith_op) | op3(membar_op3) | rs1(O7) | immed(true) | u_field( int(const7a), 6, 0)); } |
| |
| // pp 185 |
| |
| void fmov( FloatRegisterImpl::Width w, Condition c, bool floatCC, CC cca, FloatRegister s2, FloatRegister d ) { v9_only(); emit_int32( op(arith_op) | fd(d, w) | op3(fpop2_op3) | cond_mov(c) | opf_cc(cca, floatCC) | opf_low6(w) | fs2(s2, w)); } |
| |
| // pp 189 |
| |
| void fmov( FloatRegisterImpl::Width w, RCondition c, Register s1, FloatRegister s2, FloatRegister d ) { v9_only(); emit_int32( op(arith_op) | fd(d, w) | op3(fpop2_op3) | rs1(s1) | rcond(c) | opf_low5(4 + w) | fs2(s2, w)); } |
| |
| // pp 191 |
| |
| void movcc( Condition c, bool floatCC, CC cca, Register s2, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(movcc_op3) | mov_cc(cca, floatCC) | cond_mov(c) | rs2(s2) ); } |
| void movcc( Condition c, bool floatCC, CC cca, int simm11a, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(movcc_op3) | mov_cc(cca, floatCC) | cond_mov(c) | immed(true) | simm(simm11a, 11) ); } |
| |
| // pp 195 |
| |
| void movr( RCondition c, Register s1, Register s2, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(movr_op3) | rs1(s1) | rcond(c) | rs2(s2) ); } |
| void movr( RCondition c, Register s1, int simm10a, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(movr_op3) | rs1(s1) | rcond(c) | immed(true) | simm(simm10a, 10) ); } |
| |
| // pp 196 |
| |
| void mulx( Register s1, Register s2, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(mulx_op3 ) | rs1(s1) | rs2(s2) ); } |
| void mulx( Register s1, int simm13a, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(mulx_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void sdivx( Register s1, Register s2, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(sdivx_op3) | rs1(s1) | rs2(s2) ); } |
| void sdivx( Register s1, int simm13a, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(sdivx_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void udivx( Register s1, Register s2, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(udivx_op3) | rs1(s1) | rs2(s2) ); } |
| void udivx( Register s1, int simm13a, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(udivx_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 197 |
| |
| void umul( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(umul_op3 ) | rs1(s1) | rs2(s2) ); } |
| void umul( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(umul_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void smul( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(smul_op3 ) | rs1(s1) | rs2(s2) ); } |
| void smul( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(smul_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void umulcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(umul_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void umulcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(umul_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void smulcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(smul_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void smulcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(smul_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 201 |
| |
| void nop() { emit_int32( op(branch_op) | op2(sethi_op2) ); } |
| |
| |
| // pp 202 |
| |
| void popc( Register s, Register d) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(popc_op3) | rs2(s)); } |
| void popc( int simm13a, Register d) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(popc_op3) | immed(true) | simm(simm13a, 13)); } |
| |
| // pp 203 |
| |
| void prefetch( Register s1, Register s2, PrefetchFcn f) { v9_only(); emit_int32( op(ldst_op) | fcn(f) | op3(prefetch_op3) | rs1(s1) | rs2(s2) ); } |
| void prefetch( Register s1, int simm13a, PrefetchFcn f) { v9_only(); emit_data( op(ldst_op) | fcn(f) | op3(prefetch_op3) | rs1(s1) | immed(true) | simm(simm13a, 13)); } |
| |
| void prefetcha( Register s1, Register s2, int ia, PrefetchFcn f ) { v9_only(); emit_int32( op(ldst_op) | fcn(f) | op3(prefetch_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void prefetcha( Register s1, int simm13a, PrefetchFcn f ) { v9_only(); emit_int32( op(ldst_op) | fcn(f) | op3(prefetch_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 208 |
| |
| // not implementing read privileged register |
| |
| inline void rdy( Register d) { v9_dep(); emit_int32( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(0, 18, 14)); } |
| inline void rdccr( Register d) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(2, 18, 14)); } |
| inline void rdasi( Register d) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(3, 18, 14)); } |
| inline void rdtick( Register d) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(4, 18, 14)); } // Spoon! |
| inline void rdpc( Register d) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(5, 18, 14)); } |
| inline void rdfprs( Register d) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(6, 18, 14)); } |
| |
| // pp 213 |
| |
| inline void rett( Register s1, Register s2); |
| inline void rett( Register s1, int simm13a, relocInfo::relocType rt = relocInfo::none); |
| |
| // pp 214 |
| |
| void save( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(save_op3) | rs1(s1) | rs2(s2) ); } |
| void save( Register s1, int simm13a, Register d ) { |
| // make sure frame is at least large enough for the register save area |
| assert(-simm13a >= 16 * wordSize, "frame too small"); |
| emit_int32( op(arith_op) | rd(d) | op3(save_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); |
| } |
| |
| void restore( Register s1 = G0, Register s2 = G0, Register d = G0 ) { emit_int32( op(arith_op) | rd(d) | op3(restore_op3) | rs1(s1) | rs2(s2) ); } |
| void restore( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(restore_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 216 |
| |
| void saved() { v9_only(); emit_int32( op(arith_op) | fcn(0) | op3(saved_op3)); } |
| void restored() { v9_only(); emit_int32( op(arith_op) | fcn(1) | op3(saved_op3)); } |
| |
| // pp 217 |
| |
| inline void sethi( int imm22a, Register d, RelocationHolder const& rspec = RelocationHolder() ); |
| // pp 218 |
| |
| void sll( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sll_op3) | rs1(s1) | sx(0) | rs2(s2) ); } |
| void sll( Register s1, int imm5a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sll_op3) | rs1(s1) | sx(0) | immed(true) | u_field(imm5a, 4, 0) ); } |
| void srl( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(srl_op3) | rs1(s1) | sx(0) | rs2(s2) ); } |
| void srl( Register s1, int imm5a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(srl_op3) | rs1(s1) | sx(0) | immed(true) | u_field(imm5a, 4, 0) ); } |
| void sra( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sra_op3) | rs1(s1) | sx(0) | rs2(s2) ); } |
| void sra( Register s1, int imm5a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sra_op3) | rs1(s1) | sx(0) | immed(true) | u_field(imm5a, 4, 0) ); } |
| |
| void sllx( Register s1, Register s2, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(sll_op3) | rs1(s1) | sx(1) | rs2(s2) ); } |
| void sllx( Register s1, int imm6a, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(sll_op3) | rs1(s1) | sx(1) | immed(true) | u_field(imm6a, 5, 0) ); } |
| void srlx( Register s1, Register s2, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(srl_op3) | rs1(s1) | sx(1) | rs2(s2) ); } |
| void srlx( Register s1, int imm6a, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(srl_op3) | rs1(s1) | sx(1) | immed(true) | u_field(imm6a, 5, 0) ); } |
| void srax( Register s1, Register s2, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(sra_op3) | rs1(s1) | sx(1) | rs2(s2) ); } |
| void srax( Register s1, int imm6a, Register d ) { v9_only(); emit_int32( op(arith_op) | rd(d) | op3(sra_op3) | rs1(s1) | sx(1) | immed(true) | u_field(imm6a, 5, 0) ); } |
| |
| // pp 220 |
| |
| void sir( int simm13a ) { emit_int32( op(arith_op) | fcn(15) | op3(sir_op3) | immed(true) | simm(simm13a, 13)); } |
| |
| // pp 221 |
| |
| void stbar() { emit_int32( op(arith_op) | op3(membar_op3) | u_field(15, 18, 14)); } |
| |
| // pp 222 |
| |
| inline void stf( FloatRegisterImpl::Width w, FloatRegister d, Register s1, Register s2); |
| inline void stf( FloatRegisterImpl::Width w, FloatRegister d, Register s1, int simm13a); |
| |
| inline void stfsr( Register s1, Register s2 ); |
| inline void stfsr( Register s1, int simm13a); |
| inline void stxfsr( Register s1, Register s2 ); |
| inline void stxfsr( Register s1, int simm13a); |
| |
| // pp 224 |
| |
| void stfa( FloatRegisterImpl::Width w, FloatRegister d, Register s1, Register s2, int ia ) { v9_only(); emit_int32( op(ldst_op) | fd(d, w) | alt_op3(stf_op3 | alt_bit_op3, w) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void stfa( FloatRegisterImpl::Width w, FloatRegister d, Register s1, int simm13a ) { v9_only(); emit_int32( op(ldst_op) | fd(d, w) | alt_op3(stf_op3 | alt_bit_op3, w) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // p 226 |
| |
| inline void stb( Register d, Register s1, Register s2 ); |
| inline void stb( Register d, Register s1, int simm13a); |
| inline void sth( Register d, Register s1, Register s2 ); |
| inline void sth( Register d, Register s1, int simm13a); |
| inline void stw( Register d, Register s1, Register s2 ); |
| inline void stw( Register d, Register s1, int simm13a); |
| inline void stx( Register d, Register s1, Register s2 ); |
| inline void stx( Register d, Register s1, int simm13a); |
| inline void std( Register d, Register s1, Register s2 ); |
| inline void std( Register d, Register s1, int simm13a); |
| |
| // pp 177 |
| |
| void stba( Register d, Register s1, Register s2, int ia ) { emit_int32( op(ldst_op) | rd(d) | op3(stb_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void stba( Register d, Register s1, int simm13a ) { emit_int32( op(ldst_op) | rd(d) | op3(stb_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void stha( Register d, Register s1, Register s2, int ia ) { emit_int32( op(ldst_op) | rd(d) | op3(sth_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void stha( Register d, Register s1, int simm13a ) { emit_int32( op(ldst_op) | rd(d) | op3(sth_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void stwa( Register d, Register s1, Register s2, int ia ) { emit_int32( op(ldst_op) | rd(d) | op3(stw_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void stwa( Register d, Register s1, int simm13a ) { emit_int32( op(ldst_op) | rd(d) | op3(stw_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void stxa( Register d, Register s1, Register s2, int ia ) { v9_only(); emit_int32( op(ldst_op) | rd(d) | op3(stx_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void stxa( Register d, Register s1, int simm13a ) { v9_only(); emit_int32( op(ldst_op) | rd(d) | op3(stx_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void stda( Register d, Register s1, Register s2, int ia ) { emit_int32( op(ldst_op) | rd(d) | op3(std_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void stda( Register d, Register s1, int simm13a ) { emit_int32( op(ldst_op) | rd(d) | op3(std_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 230 |
| |
| void sub( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sub_op3 ) | rs1(s1) | rs2(s2) ); } |
| void sub( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sub_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| void subcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sub_op3 | cc_bit_op3 ) | rs1(s1) | rs2(s2) ); } |
| void subcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(sub_op3 | cc_bit_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void subc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(subc_op3 ) | rs1(s1) | rs2(s2) ); } |
| void subc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(subc_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| void subccc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(subc_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } |
| void subccc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(subc_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 231 |
| |
| inline void swap( Register s1, Register s2, Register d ); |
| inline void swap( Register s1, int simm13a, Register d); |
| |
| // pp 232 |
| |
| void swapa( Register s1, Register s2, int ia, Register d ) { v9_dep(); emit_int32( op(ldst_op) | rd(d) | op3(swap_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } |
| void swapa( Register s1, int simm13a, Register d ) { v9_dep(); emit_int32( op(ldst_op) | rd(d) | op3(swap_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 234, note op in book is wrong, see pp 268 |
| |
| void taddcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(taddcc_op3 ) | rs1(s1) | rs2(s2) ); } |
| void taddcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(taddcc_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 235 |
| |
| void tsubcc( Register s1, Register s2, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(tsubcc_op3 ) | rs1(s1) | rs2(s2) ); } |
| void tsubcc( Register s1, int simm13a, Register d ) { emit_int32( op(arith_op) | rd(d) | op3(tsubcc_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } |
| |
| // pp 237 |
| |
| void trap( Condition c, CC cc, Register s1, Register s2 ) { emit_int32( op(arith_op) | cond(c) | op3(trap_op3) | rs1(s1) | trapcc(cc) | rs2(s2)); } |
| void trap( Condition c, CC cc, Register s1, int trapa ) { emit_int32( op(arith_op) | cond(c) | op3(trap_op3) | rs1(s1) | trapcc(cc) | immed(true) | u_field(trapa, 6, 0)); } |
| // simple uncond. trap |
| void trap( int trapa ) { trap( always, icc, G0, trapa ); } |
| |
| // pp 239 omit write priv register for now |
| |
| inline void wry( Register d) { v9_dep(); emit_int32( op(arith_op) | rs1(d) | op3(wrreg_op3) | u_field(0, 29, 25)); } |
| inline void wrccr(Register s) { v9_only(); emit_int32( op(arith_op) | rs1(s) | op3(wrreg_op3) | u_field(2, 29, 25)); } |
| inline void wrccr(Register s, int simm13a) { v9_only(); emit_int32( op(arith_op) | |
| rs1(s) | |
| op3(wrreg_op3) | |
| u_field(2, 29, 25) | |
| immed(true) | |
| simm(simm13a, 13)); } |
| inline void wrasi(Register d) { v9_only(); emit_int32( op(arith_op) | rs1(d) | op3(wrreg_op3) | u_field(3, 29, 25)); } |
| // wrasi(d, imm) stores (d xor imm) to asi |
| inline void wrasi(Register d, int simm13a) { v9_only(); emit_int32( op(arith_op) | rs1(d) | op3(wrreg_op3) | |
| u_field(3, 29, 25) | immed(true) | simm(simm13a, 13)); } |
| inline void wrfprs( Register d) { v9_only(); emit_int32( op(arith_op) | rs1(d) | op3(wrreg_op3) | u_field(6, 29, 25)); } |
| |
| // VIS1 instructions |
| |
| void alignaddr( Register s1, Register s2, Register d ) { vis1_only(); emit_int32( op(arith_op) | rd(d) | op3(alignaddr_op3) | rs1(s1) | opf(alignaddr_opf) | rs2(s2)); } |
| |
| void faligndata( FloatRegister s1, FloatRegister s2, FloatRegister d ) { vis1_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(faligndata_op3) | fs1(s1, FloatRegisterImpl::D) | opf(faligndata_opf) | fs2(s2, FloatRegisterImpl::D)); } |
| |
| void fsrc2( FloatRegisterImpl::Width w, FloatRegister s2, FloatRegister d ) { vis1_only(); emit_int32( op(arith_op) | fd(d, w) | op3(fsrc_op3) | opf(0x7A - w) | fs2(s2, w)); } |
| |
| void stpartialf( Register s1, Register s2, FloatRegister d, int ia = -1 ) { vis1_only(); emit_int32( op(ldst_op) | fd(d, FloatRegisterImpl::D) | op3(stpartialf_op3) | rs1(s1) | imm_asi(ia) | rs2(s2)); } |
| |
| // VIS2 instructions |
| |
| void edge8n( Register s1, Register s2, Register d ) { vis2_only(); emit_int32( op(arith_op) | rd(d) | op3(edge_op3) | rs1(s1) | opf(edge8n_opf) | rs2(s2)); } |
| |
| // VIS3 instructions |
| |
| void movstosw( FloatRegister s, Register d ) { vis3_only(); emit_int32( op(arith_op) | rd(d) | op3(mftoi_op3) | opf(mstosw_opf) | fs2(s, FloatRegisterImpl::S)); } |
| void movstouw( FloatRegister s, Register d ) { vis3_only(); emit_int32( op(arith_op) | rd(d) | op3(mftoi_op3) | opf(mstouw_opf) | fs2(s, FloatRegisterImpl::S)); } |
| void movdtox( FloatRegister s, Register d ) { vis3_only(); emit_int32( op(arith_op) | rd(d) | op3(mftoi_op3) | opf(mdtox_opf) | fs2(s, FloatRegisterImpl::D)); } |
| |
| void movwtos( Register s, FloatRegister d ) { vis3_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::S) | op3(mftoi_op3) | opf(mwtos_opf) | rs2(s)); } |
| void movxtod( Register s, FloatRegister d ) { vis3_only(); emit_int32( op(arith_op) | fd(d, FloatRegisterImpl::D) | op3(mftoi_op3) | opf(mxtod_opf) | rs2(s)); } |
| |
| // Crypto SHA instructions |
| |
| void sha1() { sha1_only(); emit_int32( op(arith_op) | op3(sha_op3) | opf(sha1_opf)); } |
| void sha256() { sha256_only(); emit_int32( op(arith_op) | op3(sha_op3) | opf(sha256_opf)); } |
| void sha512() { sha512_only(); emit_int32( op(arith_op) | op3(sha_op3) | opf(sha512_opf)); } |
| |
| // Creation |
| Assembler(CodeBuffer* code) : AbstractAssembler(code) { |
| #ifdef CHECK_DELAY |
| delay_state = no_delay; |
| #endif |
| } |
| }; |
| |
| #endif // CPU_SPARC_VM_ASSEMBLER_SPARC_HPP |