[cacao.git] / src / vm / jit / alpha / codegen.h

/* vm/jit/alpha/codegen.h - code generation macros and definitions for alpha

   Copyright (C) 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003
   Institut f. Computersprachen, TU Wien
   R. Grafl, A. Krall, C. Kruegel, C. Oates, R. Obermaisser,
   M. Probst, S. Ring, E. Steiner, C. Thalinger, D. Thuernbeck,
   P. Tomsich, J. Wenninger

   This file is part of CACAO.

   This program is free software; you can redistribute it and/or
   modify it under the terms of the GNU General Public License as
   published by the Free Software Foundation; either version 2, or (at
   your option) any later version.

   This program is distributed in the hope that it will be useful, but
   WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
   General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program; if not, write to the Free Software
   Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
   02111-1307, USA.

   Contact: cacao@complang.tuwien.ac.at

   Authors: Andreas Krall
            Reinhard Grafl

   $Id: codegen.h 1624 2004-11-30 14:49:45Z twisti $

*/


#ifndef _CODEGEN_H
#define _CODEGEN_H

#include <ucontext.h>


/* additional functions and macros to generate code ***************************/

/* #define BlockPtrOfPC(pc)        block+block_index[pc] */
#define BlockPtrOfPC(pc)  ((basicblock *) iptr->target)


#ifdef STATISTICS
#define COUNT_SPILLS count_spills++
#else
#define COUNT_SPILLS
#endif


/* gen_nullptr_check(objreg) */

#define gen_nullptr_check(objreg) \
    if (checknull) { \
        M_BEQZ((objreg), 0); \
        codegen_addxnullrefs(cd, mcodeptr); \
    }

#define gen_bound_check \
    if (checkbounds) { \
        M_ILD(REG_ITMP3, s1, OFFSET(java_arrayheader, size));\
        M_CMPULT(s2, REG_ITMP3, REG_ITMP3);\
        M_BEQZ(REG_ITMP3, 0);\
        codegen_addxboundrefs(cd, mcodeptr, s2); \
    }


/* MCODECHECK(icnt) */

#define MCODECHECK(icnt) \
        if ((mcodeptr + (icnt)) > cd->mcodeend) \
        mcodeptr = codegen_increase(cd, (u1 *) mcodeptr)

/* M_INTMOVE:
     generates an integer-move from register a to b.
     if a and b are the same int-register, no code will be generated.
*/ 

#define M_INTMOVE(a,b) if (a != b) { M_MOV(a, b); }


/* M_FLTMOVE:
    generates a floating-point-move from register a to b.
    if a and b are the same float-register, no code will be generated
*/ 

#define M_FLTMOVE(a,b) if (a != b) { M_FMOV(a, b); }


/* var_to_reg_xxx:
    this function generates code to fetch data from a pseudo-register
    into a real register. 
    If the pseudo-register has actually been assigned to a real 
    register, no code will be emitted, since following operations
    can use this register directly.
    
    v: pseudoregister to be fetched from
    tempregnum: temporary register to be used if v is actually spilled to ram

    return: the register number, where the operand can be found after 
            fetching (this wil be either tempregnum or the register
            number allready given to v)
*/

#define var_to_reg_int(regnr,v,tempnr) { \
        if ((v)->flags & INMEMORY) { \
                COUNT_SPILLS; \
        M_LLD(tempnr, REG_SP, 8 * (v)->regoff); \
        regnr = tempnr; \
    } else regnr = (v)->regoff; \
}


#define var_to_reg_flt(regnr,v,tempnr) { \
        if ((v)->flags & INMEMORY) { \
                COUNT_SPILLS; \
        M_DLD(tempnr, REG_SP, 8 * (v)->regoff); \
        regnr = tempnr; \
    } else regnr = (v)->regoff; \
}


/* store_reg_to_var_xxx:
    This function generates the code to store the result of an operation
    back into a spilled pseudo-variable.
    If the pseudo-variable has not been spilled in the first place, this 
    function will generate nothing.
    
    v ............ Pseudovariable
    tempregnum ... Number of the temporary registers as returned by
                   reg_of_var.
*/      

#define store_reg_to_var_int(sptr, tempregnum) {       \
        if ((sptr)->flags & INMEMORY) {                    \
                COUNT_SPILLS;                                  \
                M_LST(tempregnum, REG_SP, 8 * (sptr)->regoff); \
                }                                              \
        }

#define store_reg_to_var_flt(sptr, tempregnum) {       \
        if ((sptr)->flags & INMEMORY) {                    \
                COUNT_SPILLS;                                  \
                M_DST(tempregnum, REG_SP, 8 * (sptr)->regoff); \
                }                                              \
        }


#define M_COPY(from,to) \
        d = reg_of_var(rd, to, REG_IFTMP); \
        if ((from->regoff != to->regoff) || \
            ((from->flags ^ to->flags) & INMEMORY)) { \
                if (IS_FLT_DBL_TYPE(from->type)) { \
                        var_to_reg_flt(s1, from, d); \
                        M_FLTMOVE(s1,d); \
                        store_reg_to_var_flt(to, d); \
                        }\
                else { \
                        var_to_reg_int(s1, from, d); \
                        M_INTMOVE(s1,d); \
                        store_reg_to_var_int(to, d); \
                        }\
                }


#define ICONST(r,c) \
    if ((c) >= -32768 && (c) <= 32767) { \
        M_LDA((r), REG_ZERO, c); \
    } else { \
        a = dseg_adds4(cd, (c)); \
        M_ILD((r), REG_PV, a); \
    }

#define LCONST(r,c) \
    if ((c) >= -32768 && (c) <= 32767) { \
        M_LDA((r), REG_ZERO, (c)); \
    } else { \
        a = dseg_adds8(cd, (c)); \
        M_LLD((r), REG_PV, a); \
    }


/* macros to create code ******************************************************/

#define REG   0
#define CONST 1

/* 3-address-operations: M_OP3
      op ..... opcode
      fu ..... function-number
      a  ..... register number source 1
      b  ..... register number or constant integer source 2
      c  ..... register number destination
      const .. switch to use b as constant integer 
                 (REG means: use b as register number)
                 (CONST means: use b as constant 8-bit-integer)
*/      
#define M_OP3(op,fu,a,b,c,const) \
        *(mcodeptr++) = ( (((s4)(op))<<26)|((a)<<21)|((b)<<(16-3*(const)))| \
        ((const)<<12)|((fu)<<5)|((c)) )

/* 3-address-floating-point-operation: M_FOP3 
     op .... opcode
     fu .... function-number
     a,b ... source floating-point registers
     c ..... destination register
*/ 
#define M_FOP3(op,fu,a,b,c) \
        *(mcodeptr++) = ( (((s4)(op))<<26)|((a)<<21)|((b)<<16)|((fu)<<5)|(c) )

/* branch instructions: M_BRA 
      op ..... opcode
      a ...... register to be tested
      disp ... relative address to be jumped to (divided by 4)
*/
#define M_BRA(op,a,disp) \
        *(mcodeptr++) = ( (((s4)(op))<<26)|((a)<<21)|((disp)&0x1fffff) )


/* memory operations: M_MEM
      op ..... opcode
      a ...... source/target register for memory access
      b ...... base register
      disp ... displacement (16 bit signed) to be added to b
*/ 
#define M_MEM(op,a,b,disp) \
        *(mcodeptr++) = ( (((s4)(op))<<26)|((a)<<21)|((b)<<16)|((disp)&0xffff) )


/* macros for all used commands (see an Alpha-manual for description) *********/

#define M_LDA(a,b,disp)         M_MEM (0x08,a,b,disp)           /* low const  */
#define M_LDAH(a,b,disp)        M_MEM (0x09,a,b,disp)           /* high const */
#define M_BLDU(a,b,disp)        M_MEM (0x0a,a,b,disp)           /*  8 load    */
#define M_SLDU(a,b,disp)        M_MEM (0x0c,a,b,disp)           /* 16 load    */
#define M_ILD(a,b,disp)         M_MEM (0x28,a,b,disp)           /* 32 load    */
#define M_LLD(a,b,disp)         M_MEM (0x29,a,b,disp)           /* 64 load    */
#define M_ALD(a,b,disp)         M_MEM (0x29,a,b,disp)           /* addr load  */
#define M_BST(a,b,disp)         M_MEM (0x0e,a,b,disp)           /*  8 store   */
#define M_SST(a,b,disp)         M_MEM (0x0d,a,b,disp)           /* 16 store   */
#define M_IST(a,b,disp)         M_MEM (0x2c,a,b,disp)           /* 32 store   */
#define M_LST(a,b,disp)         M_MEM (0x2d,a,b,disp)           /* 64 store   */
#define M_AST(a,b,disp)         M_MEM (0x2d,a,b,disp)           /* addr store */

#define M_BSEXT(b,c)            M_OP3 (0x1c,0x0,REG_ZERO,b,c,0) /*  8 signext */
#define M_SSEXT(b,c)            M_OP3 (0x1c,0x1,REG_ZERO,b,c,0) /* 16 signext */

#define M_BR(disp)              M_BRA (0x30,REG_ZERO,disp)      /* branch     */
#define M_BSR(ra,disp)          M_BRA (0x34,ra,disp)            /* branch sbr */
#define M_BEQZ(a,disp)          M_BRA (0x39,a,disp)             /* br a == 0  */
#define M_BLTZ(a,disp)          M_BRA (0x3a,a,disp)             /* br a <  0  */
#define M_BLEZ(a,disp)          M_BRA (0x3b,a,disp)             /* br a <= 0  */
#define M_BNEZ(a,disp)          M_BRA (0x3d,a,disp)             /* br a != 0  */
#define M_BGEZ(a,disp)          M_BRA (0x3e,a,disp)             /* br a >= 0  */
#define M_BGTZ(a,disp)          M_BRA (0x3f,a,disp)             /* br a >  0  */

#define M_JMP(a,b)              M_MEM (0x1a,a,b,0x0000)         /* jump       */
#define M_JSR(a,b)              M_MEM (0x1a,a,b,0x4000)         /* call sbr   */
#define M_RET(a,b)              M_MEM (0x1a,a,b,0x8000)         /* return     */

#define M_IADD(a,b,c)           M_OP3 (0x10,0x0,  a,b,c,0)      /* 32 add     */
#define M_LADD(a,b,c)           M_OP3 (0x10,0x20, a,b,c,0)      /* 64 add     */
#define M_ISUB(a,b,c)           M_OP3 (0x10,0x09, a,b,c,0)      /* 32 sub     */
#define M_LSUB(a,b,c)           M_OP3 (0x10,0x29, a,b,c,0)      /* 64 sub     */
#define M_IMUL(a,b,c)           M_OP3 (0x13,0x00, a,b,c,0)      /* 32 mul     */
#define M_LMUL(a,b,c)           M_OP3 (0x13,0x20, a,b,c,0)      /* 64 mul     */

#define M_IADD_IMM(a,b,c)       M_OP3 (0x10,0x0,  a,b,c,1)      /* 32 add     */
#define M_LADD_IMM(a,b,c)       M_OP3 (0x10,0x20, a,b,c,1)      /* 64 add     */
#define M_ISUB_IMM(a,b,c)       M_OP3 (0x10,0x09, a,b,c,1)      /* 32 sub     */
#define M_LSUB_IMM(a,b,c)       M_OP3 (0x10,0x29, a,b,c,1)      /* 64 sub     */
#define M_IMUL_IMM(a,b,c)       M_OP3 (0x13,0x00, a,b,c,1)      /* 32 mul     */
#define M_LMUL_IMM(a,b,c)       M_OP3 (0x13,0x20, a,b,c,1)      /* 64 mul     */

#define M_CMPEQ(a,b,c)          M_OP3 (0x10,0x2d, a,b,c,0)      /* c = a == b */
#define M_CMPLT(a,b,c)          M_OP3 (0x10,0x4d, a,b,c,0)      /* c = a <  b */
#define M_CMPLE(a,b,c)          M_OP3 (0x10,0x6d, a,b,c,0)      /* c = a <= b */

#define M_CMPULE(a,b,c)         M_OP3 (0x10,0x3d, a,b,c,0)      /* c = a <= b */
#define M_CMPULT(a,b,c)         M_OP3 (0x10,0x1d, a,b,c,0)      /* c = a <= b */

#define M_CMPEQ_IMM(a,b,c)      M_OP3 (0x10,0x2d, a,b,c,1)      /* c = a == b */
#define M_CMPLT_IMM(a,b,c)      M_OP3 (0x10,0x4d, a,b,c,1)      /* c = a <  b */
#define M_CMPLE_IMM(a,b,c)      M_OP3 (0x10,0x6d, a,b,c,1)      /* c = a <= b */

#define M_CMPULE_IMM(a,b,c)     M_OP3 (0x10,0x3d, a,b,c,1)      /* c = a <= b */
#define M_CMPULT_IMM(a,b,c)     M_OP3 (0x10,0x1d, a,b,c,1)      /* c = a <= b */

#define M_AND(a,b,c)            M_OP3 (0x11,0x00, a,b,c,0)      /* c = a &  b */
#define M_OR( a,b,c)            M_OP3 (0x11,0x20, a,b,c,0)      /* c = a |  b */
#define M_XOR(a,b,c)            M_OP3 (0x11,0x40, a,b,c,0)      /* c = a ^  b */

#define M_AND_IMM(a,b,c)        M_OP3 (0x11,0x00, a,b,c,1)      /* c = a &  b */
#define M_OR_IMM( a,b,c)        M_OP3 (0x11,0x20, a,b,c,1)      /* c = a |  b */
#define M_XOR_IMM(a,b,c)        M_OP3 (0x11,0x40, a,b,c,1)      /* c = a ^  b */

#define M_MOV(a,c)              M_OR (a,a,c)                    /* c = a      */
#define M_CLR(c)                M_OR (31,31,c)                  /* c = 0      */
#define M_NOP                   M_OR (31,31,31)                 /* ;          */

#define M_SLL(a,b,c)            M_OP3 (0x12,0x39, a,b,c,0)      /* c = a << b */
#define M_SRA(a,b,c)            M_OP3 (0x12,0x3c, a,b,c,0)      /* c = a >> b */
#define M_SRL(a,b,c)            M_OP3 (0x12,0x34, a,b,c,0)      /* c = a >>>b */

#define M_SLL_IMM(a,b,c)        M_OP3 (0x12,0x39, a,b,c,1)      /* c = a << b */
#define M_SRA_IMM(a,b,c)        M_OP3 (0x12,0x3c, a,b,c,1)      /* c = a >> b */
#define M_SRL_IMM(a,b,c)        M_OP3 (0x12,0x34, a,b,c,1)      /* c = a >>>b */

#define M_FLD(a,b,disp)         M_MEM (0x22,a,b,disp)           /* load flt   */
#define M_DLD(a,b,disp)         M_MEM (0x23,a,b,disp)           /* load dbl   */
#define M_FST(a,b,disp)         M_MEM (0x26,a,b,disp)           /* store flt  */
#define M_DST(a,b,disp)         M_MEM (0x27,a,b,disp)           /* store dbl  */

#define M_FADD(a,b,c)           M_FOP3 (0x16, 0x080, a,b,c)     /* flt add    */
#define M_DADD(a,b,c)           M_FOP3 (0x16, 0x0a0, a,b,c)     /* dbl add    */
#define M_FSUB(a,b,c)           M_FOP3 (0x16, 0x081, a,b,c)     /* flt sub    */
#define M_DSUB(a,b,c)           M_FOP3 (0x16, 0x0a1, a,b,c)     /* dbl sub    */
#define M_FMUL(a,b,c)           M_FOP3 (0x16, 0x082, a,b,c)     /* flt mul    */
#define M_DMUL(a,b,c)           M_FOP3 (0x16, 0x0a2, a,b,c)     /* dbl mul    */
#define M_FDIV(a,b,c)           M_FOP3 (0x16, 0x083, a,b,c)     /* flt div    */
#define M_DDIV(a,b,c)           M_FOP3 (0x16, 0x0a3, a,b,c)     /* dbl div    */

#define M_FADDS(a,b,c)          M_FOP3 (0x16, 0x580, a,b,c)     /* flt add    */
#define M_DADDS(a,b,c)          M_FOP3 (0x16, 0x5a0, a,b,c)     /* dbl add    */
#define M_FSUBS(a,b,c)          M_FOP3 (0x16, 0x581, a,b,c)     /* flt sub    */
#define M_DSUBS(a,b,c)          M_FOP3 (0x16, 0x5a1, a,b,c)     /* dbl sub    */
#define M_FMULS(a,b,c)          M_FOP3 (0x16, 0x582, a,b,c)     /* flt mul    */
#define M_DMULS(a,b,c)          M_FOP3 (0x16, 0x5a2, a,b,c)     /* dbl mul    */
#define M_FDIVS(a,b,c)          M_FOP3 (0x16, 0x583, a,b,c)     /* flt div    */
#define M_DDIVS(a,b,c)          M_FOP3 (0x16, 0x5a3, a,b,c)     /* dbl div    */

#define M_CVTDF(b,c)            M_FOP3 (0x16, 0x0ac, 31,b,c)    /* dbl2flt    */
#define M_CVTLF(b,c)            M_FOP3 (0x16, 0x0bc, 31,b,c)    /* long2flt   */
#define M_CVTLD(b,c)            M_FOP3 (0x16, 0x0be, 31,b,c)    /* long2dbl   */
#define M_CVTDL(b,c)            M_FOP3 (0x16, 0x1af, 31,b,c)    /* dbl2long   */
#define M_CVTDL_C(b,c)          M_FOP3 (0x16, 0x12f, 31,b,c)    /* dbl2long   */
#define M_CVTLI(b,c)            M_FOP3 (0x17, 0x130, 31,b,c)    /* long2int   */

#define M_CVTDFS(b,c)           M_FOP3 (0x16, 0x5ac, 31,b,c)    /* dbl2flt    */
#define M_CVTFDS(b,c)           M_FOP3 (0x16, 0x6ac, 31,b,c)    /* flt2dbl    */
#define M_CVTDLS(b,c)           M_FOP3 (0x16, 0x5af, 31,b,c)    /* dbl2long   */
#define M_CVTDL_CS(b,c)         M_FOP3 (0x16, 0x52f, 31,b,c)    /* dbl2long   */
#define M_CVTLIS(b,c)           M_FOP3 (0x17, 0x530, 31,b,c)    /* long2int   */

#define M_FCMPEQ(a,b,c)         M_FOP3 (0x16, 0x0a5, a,b,c)     /* c = a==b   */
#define M_FCMPLT(a,b,c)         M_FOP3 (0x16, 0x0a6, a,b,c)     /* c = a<b    */

#define M_FCMPEQS(a,b,c)        M_FOP3 (0x16, 0x5a5, a,b,c)     /* c = a==b   */
#define M_FCMPLTS(a,b,c)        M_FOP3 (0x16, 0x5a6, a,b,c)     /* c = a<b    */

#define M_FMOV(fa,fb)           M_FOP3 (0x17, 0x020, fa,fa,fb)  /* b = a      */
#define M_FMOVN(fa,fb)          M_FOP3 (0x17, 0x021, fa,fa,fb)  /* b = -a     */

#define M_FNOP                  M_FMOV (31,31)

#define M_FBEQZ(fa,disp)        M_BRA (0x31,fa,disp)            /* br a == 0.0*/

/* macros for special commands (see an Alpha-manual for description) **********/ 

#define M_TRAPB                 M_MEM (0x18,0,0,0x0000)        /* trap barrier*/

#define M_S4ADDL(a,b,c)         M_OP3 (0x10,0x02, a,b,c,0)     /* c = a*4 + b */
#define M_S4ADDQ(a,b,c)         M_OP3 (0x10,0x22, a,b,c,0)     /* c = a*4 + b */
#define M_S4SUBL(a,b,c)         M_OP3 (0x10,0x0b, a,b,c,0)     /* c = a*4 - b */
#define M_S4SUBQ(a,b,c)         M_OP3 (0x10,0x2b, a,b,c,0)     /* c = a*4 - b */
#define M_S8ADDL(a,b,c)         M_OP3 (0x10,0x12, a,b,c,0)     /* c = a*8 + b */
#define M_S8ADDQ(a,b,c)         M_OP3 (0x10,0x32, a,b,c,0)     /* c = a*8 + b */
#define M_S8SUBL(a,b,c)         M_OP3 (0x10,0x1b, a,b,c,0)     /* c = a*8 - b */
#define M_S8SUBQ(a,b,c)         M_OP3 (0x10,0x3b, a,b,c,0)     /* c = a*8 - b */
#define M_SAADDQ(a,b,c)         M_S8ADDQ(a,b,c)                /* c = a*8 + b */

#define M_S4ADDL_IMM(a,b,c)     M_OP3 (0x10,0x02, a,b,c,1)     /* c = a*4 + b */
#define M_S4ADDQ_IMM(a,b,c)     M_OP3 (0x10,0x22, a,b,c,1)     /* c = a*4 + b */
#define M_S4SUBL_IMM(a,b,c)     M_OP3 (0x10,0x0b, a,b,c,1)     /* c = a*4 - b */
#define M_S4SUBQ_IMM(a,b,c)     M_OP3 (0x10,0x2b, a,b,c,1)     /* c = a*4 - b */
#define M_S8ADDL_IMM(a,b,c)     M_OP3 (0x10,0x12, a,b,c,1)     /* c = a*8 + b */
#define M_S8ADDQ_IMM(a,b,c)     M_OP3 (0x10,0x32, a,b,c,1)     /* c = a*8 + b */
#define M_S8SUBL_IMM(a,b,c)     M_OP3 (0x10,0x1b, a,b,c,1)     /* c = a*8 - b */
#define M_S8SUBQ_IMM(a,b,c)     M_OP3 (0x10,0x3b, a,b,c,1)     /* c = a*8 - b */

#define M_LLD_U(a,b,disp)       M_MEM (0x0b,a,b,disp)          /* unalign ld  */
#define M_LST_U(a,b,disp)       M_MEM (0x0f,a,b,disp)          /* unalign st  */

#define M_ZAP(a,b,c)            M_OP3 (0x12,0x30, a,b,c,0)
#define M_ZAPNOT(a,b,c)         M_OP3 (0x12,0x31, a,b,c,0)

#define M_ZAP_IMM(a,b,c)        M_OP3 (0x12,0x30, a,b,c,1)
#define M_ZAPNOT_IMM(a,b,c)     M_OP3 (0x12,0x31, a,b,c,1)

#define M_BZEXT(a,b)            M_ZAPNOT_IMM(a, 0x01, b)       /*  8 zeroext  */
#define M_CZEXT(a,b)            M_ZAPNOT_IMM(a, 0x03, b)       /* 16 zeroext  */
#define M_IZEXT(a,b)            M_ZAPNOT_IMM(a, 0x0f, b)       /* 32 zeroext  */

#define M_EXTBL(a,b,c)          M_OP3 (0x12,0x06, a,b,c,0)
#define M_EXTWL(a,b,c)          M_OP3 (0x12,0x16, a,b,c,0)
#define M_EXTLL(a,b,c)          M_OP3 (0x12,0x26, a,b,c,0)
#define M_EXTQL(a,b,c)          M_OP3 (0x12,0x36, a,b,c,0)
#define M_EXTWH(a,b,c)          M_OP3 (0x12,0x5a, a,b,c,0)
#define M_EXTLH(a,b,c)          M_OP3 (0x12,0x6a, a,b,c,0)
#define M_EXTQH(a,b,c)          M_OP3 (0x12,0x7a, a,b,c,0)
#define M_INSBL(a,b,c)          M_OP3 (0x12,0x0b, a,b,c,0)
#define M_INSWL(a,b,c)          M_OP3 (0x12,0x1b, a,b,c,0)
#define M_INSLL(a,b,c)          M_OP3 (0x12,0x2b, a,b,c,0)
#define M_INSQL(a,b,c)          M_OP3 (0x12,0x3b, a,b,c,0)
#define M_INSWH(a,b,c)          M_OP3 (0x12,0x57, a,b,c,0)
#define M_INSLH(a,b,c)          M_OP3 (0x12,0x67, a,b,c,0)
#define M_INSQH(a,b,c)          M_OP3 (0x12,0x77, a,b,c,0)
#define M_MSKBL(a,b,c)          M_OP3 (0x12,0x02, a,b,c,0)
#define M_MSKWL(a,b,c)          M_OP3 (0x12,0x12, a,b,c,0)
#define M_MSKLL(a,b,c)          M_OP3 (0x12,0x22, a,b,c,0)
#define M_MSKQL(a,b,c)          M_OP3 (0x12,0x32, a,b,c,0)
#define M_MSKWH(a,b,c)          M_OP3 (0x12,0x52, a,b,c,0)
#define M_MSKLH(a,b,c)          M_OP3 (0x12,0x62, a,b,c,0)
#define M_MSKQH(a,b,c)          M_OP3 (0x12,0x72, a,b,c,0)

#define M_EXTBL_IMM(a,b,c)      M_OP3 (0x12,0x06, a,b,c,1)
#define M_EXTWL_IMM(a,b,c)      M_OP3 (0x12,0x16, a,b,c,1)
#define M_EXTLL_IMM(a,b,c)      M_OP3 (0x12,0x26, a,b,c,1)
#define M_EXTQL_IMM(a,b,c)      M_OP3 (0x12,0x36, a,b,c,1)
#define M_EXTWH_IMM(a,b,c)      M_OP3 (0x12,0x5a, a,b,c,1)
#define M_EXTLH_IMM(a,b,c)      M_OP3 (0x12,0x6a, a,b,c,1)
#define M_EXTQH_IMM(a,b,c)      M_OP3 (0x12,0x7a, a,b,c,1)
#define M_INSBL_IMM(a,b,c)      M_OP3 (0x12,0x0b, a,b,c,1)
#define M_INSWL_IMM(a,b,c)      M_OP3 (0x12,0x1b, a,b,c,1)
#define M_INSLL_IMM(a,b,c)      M_OP3 (0x12,0x2b, a,b,c,1)
#define M_INSQL_IMM(a,b,c)      M_OP3 (0x12,0x3b, a,b,c,1)
#define M_INSWH_IMM(a,b,c)      M_OP3 (0x12,0x57, a,b,c,1)
#define M_INSLH_IMM(a,b,c)      M_OP3 (0x12,0x67, a,b,c,1)
#define M_INSQH_IMM(a,b,c)      M_OP3 (0x12,0x77, a,b,c,1)
#define M_MSKBL_IMM(a,b,c)      M_OP3 (0x12,0x02, a,b,c,1)
#define M_MSKWL_IMM(a,b,c)      M_OP3 (0x12,0x12, a,b,c,1)
#define M_MSKLL_IMM(a,b,c)      M_OP3 (0x12,0x22, a,b,c,1)
#define M_MSKQL_IMM(a,b,c)      M_OP3 (0x12,0x32, a,b,c,1)
#define M_MSKWH_IMM(a,b,c)      M_OP3 (0x12,0x52, a,b,c,1)
#define M_MSKLH_IMM(a,b,c)      M_OP3 (0x12,0x62, a,b,c,1)
#define M_MSKQH_IMM(a,b,c)      M_OP3 (0x12,0x72, a,b,c,1)

#define M_UMULH(a,b,c)          M_OP3 (0x13,0x30, a,b,c,0)     /* 64 umulh    */

#define M_UMULH_IMM(a,b,c)      M_OP3 (0x13,0x30, a,b,c,1)     /* 64 umulh    */

#define M_CMOVEQ(a,b,c)         M_OP3 (0x11,0x24, a,b,c,0)     /* a==0 ? c=b  */
#define M_CMOVNE(a,b,c)         M_OP3 (0x11,0x26, a,b,c,0)     /* a!=0 ? c=b  */
#define M_CMOVLT(a,b,c)         M_OP3 (0x11,0x44, a,b,c,0)     /* a< 0 ? c=b  */
#define M_CMOVGE(a,b,c)         M_OP3 (0x11,0x46, a,b,c,0)     /* a>=0 ? c=b  */
#define M_CMOVLE(a,b,c)         M_OP3 (0x11,0x64, a,b,c,0)     /* a<=0 ? c=b  */
#define M_CMOVGT(a,b,c)         M_OP3 (0x11,0x66, a,b,c,0)     /* a> 0 ? c=b  */

#define M_CMOVEQ_IMM(a,b,c)     M_OP3 (0x11,0x24, a,b,c,1)     /* a==0 ? c=b  */
#define M_CMOVNE_IMM(a,b,c)     M_OP3 (0x11,0x26, a,b,c,1)     /* a!=0 ? c=b  */
#define M_CMOVLT_IMM(a,b,c)     M_OP3 (0x11,0x44, a,b,c,1)     /* a< 0 ? c=b  */
#define M_CMOVGE_IMM(a,b,c)     M_OP3 (0x11,0x46, a,b,c,1)     /* a>=0 ? c=b  */
#define M_CMOVLE_IMM(a,b,c)     M_OP3 (0x11,0x64, a,b,c,1)     /* a<=0 ? c=b  */
#define M_CMOVGT_IMM(a,b,c)     M_OP3 (0x11,0x66, a,b,c,1)     /* a> 0 ? c=b  */

/* macros for unused commands (see an Alpha-manual for description) ***********/ 

#define M_ANDNOT(a,b,c,const)   M_OP3 (0x11,0x08, a,b,c,const) /* c = a &~ b  */
#define M_ORNOT(a,b,c,const)    M_OP3 (0x11,0x28, a,b,c,const) /* c = a |~ b  */
#define M_XORNOT(a,b,c,const)   M_OP3 (0x11,0x48, a,b,c,const) /* c = a ^~ b  */

#define M_CMPBGE(a,b,c,const)   M_OP3 (0x10,0x0f, a,b,c,const)

#define M_FCMPUN(a,b,c)         M_FOP3 (0x16, 0x0a4, a,b,c)    /* unordered   */
#define M_FCMPLE(a,b,c)         M_FOP3 (0x16, 0x0a7, a,b,c)    /* c = a<=b    */

#define M_FCMPUNS(a,b,c)        M_FOP3 (0x16, 0x5a4, a,b,c)    /* unordered   */
#define M_FCMPLES(a,b,c)        M_FOP3 (0x16, 0x5a7, a,b,c)    /* c = a<=b    */

#define M_FBNEZ(fa,disp)        M_BRA (0x35,fa,disp)
#define M_FBLEZ(fa,disp)        M_BRA (0x33,fa,disp)

#define M_JMP_CO(a,b)           M_MEM (0x1a,a,b,0xc000)        /* call cosub  */


/* function gen_resolvebranch **************************************************

        backpatches a branch instruction; Alpha branch instructions are very
        regular, so it is only necessary to overwrite some fixed bits in the
        instruction.

        parameters: ip ... pointer to instruction after branch (void*)
                    so ... offset of instruction after branch  (s4)
                    to ... offset of branch target             (s4)

*******************************************************************************/

#define gen_resolvebranch(ip,so,to) \
    ((s4 *) (ip))[-1] |= ((s4) (to) - (so)) >> 2 & 0x1fffff


/* function prototypes */

void thread_restartcriticalsection(ucontext_t*);

#endif /* _CODEGEN_H */


/*
 * These are local overrides for various environment variables in Emacs.
 * Please do not remove this and leave it at the end of the file, where
 * Emacs will automagically detect them.
 * ---------------------------------------------------------------------
 * Local variables:
 * mode: c
 * indent-tabs-mode: t
 * c-basic-offset: 4
 * tab-width: 4
 * End:
 */