binutils-gdb/gas/config/bfin-parse.y
Mike Frysinger 3823a07437 gas: blackfin: gas: blackfin: reject invalid BYTEOP16M insns
The destination registers must be different with BYTEOP16M insns,
otherwise the hardware throws up an exception.  So reject them.

Signed-off-by: Mike Frysinger <vapier@gentoo.org>
2011-03-29 05:51:22 +00:00

4669 lines
104 KiB
Plaintext
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/* bfin-parse.y ADI Blackfin parser
Copyright 2005, 2006, 2007, 2008, 2009, 2010, 2011
Free Software Foundation, Inc.
This file is part of GAS, the GNU Assembler.
GAS 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 3, or (at your option)
any later version.
GAS 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 GAS; see the file COPYING. If not, write to the Free
Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA
02110-1301, USA. */
%{
#include "as.h"
#include <obstack.h>
#include "bfin-aux.h" /* Opcode generating auxiliaries. */
#include "libbfd.h"
#include "elf/common.h"
#include "elf/bfin.h"
#define DSP32ALU(aopcde, HL, dst1, dst0, src0, src1, s, x, aop) \
bfin_gen_dsp32alu (HL, aopcde, aop, s, x, dst0, dst1, src0, src1)
#define DSP32MAC(op1, MM, mmod, w1, P, h01, h11, h00, h10, dst, op0, src0, src1, w0) \
bfin_gen_dsp32mac (op1, MM, mmod, w1, P, h01, h11, h00, h10, op0, \
dst, src0, src1, w0)
#define DSP32MULT(op1, MM, mmod, w1, P, h01, h11, h00, h10, dst, op0, src0, src1, w0) \
bfin_gen_dsp32mult (op1, MM, mmod, w1, P, h01, h11, h00, h10, op0, \
dst, src0, src1, w0)
#define DSP32SHIFT(sopcde, dst0, src0, src1, sop, hls) \
bfin_gen_dsp32shift (sopcde, dst0, src0, src1, sop, hls)
#define DSP32SHIFTIMM(sopcde, dst0, immag, src1, sop, hls) \
bfin_gen_dsp32shiftimm (sopcde, dst0, immag, src1, sop, hls)
#define LDIMMHALF_R(reg, h, s, z, hword) \
bfin_gen_ldimmhalf (reg, h, s, z, hword, 1)
#define LDIMMHALF_R5(reg, h, s, z, hword) \
bfin_gen_ldimmhalf (reg, h, s, z, hword, 2)
#define LDSTIDXI(ptr, reg, w, sz, z, offset) \
bfin_gen_ldstidxi (ptr, reg, w, sz, z, offset)
#define LDST(ptr, reg, aop, sz, z, w) \
bfin_gen_ldst (ptr, reg, aop, sz, z, w)
#define LDSTII(ptr, reg, offset, w, op) \
bfin_gen_ldstii (ptr, reg, offset, w, op)
#define DSPLDST(i, m, reg, aop, w) \
bfin_gen_dspldst (i, reg, aop, w, m)
#define LDSTPMOD(ptr, reg, idx, aop, w) \
bfin_gen_ldstpmod (ptr, reg, aop, w, idx)
#define LDSTIIFP(offset, reg, w) \
bfin_gen_ldstiifp (reg, offset, w)
#define LOGI2OP(dst, src, opc) \
bfin_gen_logi2op (opc, src, dst.regno & CODE_MASK)
#define ALU2OP(dst, src, opc) \
bfin_gen_alu2op (dst, src, opc)
#define BRCC(t, b, offset) \
bfin_gen_brcc (t, b, offset)
#define UJUMP(offset) \
bfin_gen_ujump (offset)
#define PROGCTRL(prgfunc, poprnd) \
bfin_gen_progctrl (prgfunc, poprnd)
#define PUSHPOPMULTIPLE(dr, pr, d, p, w) \
bfin_gen_pushpopmultiple (dr, pr, d, p, w)
#define PUSHPOPREG(reg, w) \
bfin_gen_pushpopreg (reg, w)
#define CALLA(addr, s) \
bfin_gen_calla (addr, s)
#define LINKAGE(r, framesize) \
bfin_gen_linkage (r, framesize)
#define COMPI2OPD(dst, src, op) \
bfin_gen_compi2opd (dst, src, op)
#define COMPI2OPP(dst, src, op) \
bfin_gen_compi2opp (dst, src, op)
#define DAGMODIK(i, op) \
bfin_gen_dagmodik (i, op)
#define DAGMODIM(i, m, op, br) \
bfin_gen_dagmodim (i, m, op, br)
#define COMP3OP(dst, src0, src1, opc) \
bfin_gen_comp3op (src0, src1, dst, opc)
#define PTR2OP(dst, src, opc) \
bfin_gen_ptr2op (dst, src, opc)
#define CCFLAG(x, y, opc, i, g) \
bfin_gen_ccflag (x, y, opc, i, g)
#define CCMV(src, dst, t) \
bfin_gen_ccmv (src, dst, t)
#define CACTRL(reg, a, op) \
bfin_gen_cactrl (reg, a, op)
#define LOOPSETUP(soffset, c, rop, eoffset, reg) \
bfin_gen_loopsetup (soffset, c, rop, eoffset, reg)
#define HL2(r1, r0) (IS_H (r1) << 1 | IS_H (r0))
#define IS_RANGE(bits, expr, sign, mul) \
value_match(expr, bits, sign, mul, 1)
#define IS_URANGE(bits, expr, sign, mul) \
value_match(expr, bits, sign, mul, 0)
#define IS_CONST(expr) (expr->type == Expr_Node_Constant)
#define IS_RELOC(expr) (expr->type != Expr_Node_Constant)
#define IS_IMM(expr, bits) value_match (expr, bits, 0, 1, 1)
#define IS_UIMM(expr, bits) value_match (expr, bits, 0, 1, 0)
#define IS_PCREL4(expr) \
(value_match (expr, 4, 0, 2, 0))
#define IS_LPPCREL10(expr) \
(value_match (expr, 10, 0, 2, 0))
#define IS_PCREL10(expr) \
(value_match (expr, 10, 0, 2, 1))
#define IS_PCREL12(expr) \
(value_match (expr, 12, 0, 2, 1))
#define IS_PCREL24(expr) \
(value_match (expr, 24, 0, 2, 1))
static int value_match (Expr_Node *, int, int, int, int);
extern FILE *errorf;
extern INSTR_T insn;
static Expr_Node *binary (Expr_Op_Type, Expr_Node *, Expr_Node *);
static Expr_Node *unary (Expr_Op_Type, Expr_Node *);
static void notethat (char *, ...);
char *current_inputline;
extern char *yytext;
int yyerror (char *);
void error (char *format, ...)
{
va_list ap;
static char buffer[2000];
va_start (ap, format);
vsprintf (buffer, format, ap);
va_end (ap);
as_bad ("%s", buffer);
}
int
yyerror (char *msg)
{
if (msg[0] == '\0')
error ("%s", msg);
else if (yytext[0] != ';')
error ("%s. Input text was %s.", msg, yytext);
else
error ("%s.", msg);
return -1;
}
static int
in_range_p (Expr_Node *exp, int from, int to, unsigned int mask)
{
int val = EXPR_VALUE (exp);
if (exp->type != Expr_Node_Constant)
return 0;
if (val < from || val > to)
return 0;
return (val & mask) == 0;
}
extern int yylex (void);
#define imm3(x) EXPR_VALUE (x)
#define imm4(x) EXPR_VALUE (x)
#define uimm4(x) EXPR_VALUE (x)
#define imm5(x) EXPR_VALUE (x)
#define uimm5(x) EXPR_VALUE (x)
#define imm6(x) EXPR_VALUE (x)
#define imm7(x) EXPR_VALUE (x)
#define uimm8(x) EXPR_VALUE (x)
#define imm16(x) EXPR_VALUE (x)
#define uimm16s4(x) ((EXPR_VALUE (x)) >> 2)
#define uimm16(x) EXPR_VALUE (x)
/* Return true if a value is inside a range. */
#define IN_RANGE(x, low, high) \
(((EXPR_VALUE(x)) >= (low)) && (EXPR_VALUE(x)) <= ((high)))
/* Auxiliary functions. */
static int
valid_dreg_pair (Register *reg1, Expr_Node *reg2)
{
if (!IS_DREG (*reg1))
{
yyerror ("Dregs expected");
return 0;
}
if (reg1->regno != 1 && reg1->regno != 3)
{
yyerror ("Bad register pair");
return 0;
}
if (imm7 (reg2) != reg1->regno - 1)
{
yyerror ("Bad register pair");
return 0;
}
reg1->regno--;
return 1;
}
static int
check_multiply_halfregs (Macfunc *aa, Macfunc *ab)
{
if ((!REG_EQUAL (aa->s0, ab->s0) && !REG_EQUAL (aa->s0, ab->s1))
|| (!REG_EQUAL (aa->s1, ab->s1) && !REG_EQUAL (aa->s1, ab->s0)))
return yyerror ("Source multiplication register mismatch");
return 0;
}
/* Check mac option. */
static int
check_macfunc_option (Macfunc *a, Opt_mode *opt)
{
/* Default option is always valid. */
if (opt->mod == 0)
return 0;
if ((a->w == 1 && a->P == 1
&& opt->mod != M_FU && opt->mod != M_IS && opt->mod != M_IU
&& opt->mod != M_S2RND && opt->mod != M_ISS2)
|| (a->w == 1 && a->P == 0
&& opt->mod != M_FU && opt->mod != M_IS && opt->mod != M_IU
&& opt->mod != M_T && opt->mod != M_TFU && opt->mod != M_S2RND
&& opt->mod != M_ISS2 && opt->mod != M_IH)
|| (a->w == 0 && a->P == 0
&& opt->mod != M_FU && opt->mod != M_IS && opt->mod != M_W32))
return -1;
return 0;
}
/* Check (vector) mac funcs and ops. */
static int
check_macfuncs (Macfunc *aa, Opt_mode *opa,
Macfunc *ab, Opt_mode *opb)
{
/* Variables for swapping. */
Macfunc mtmp;
Opt_mode otmp;
/* The option mode should be put at the end of the second instruction
of the vector except M, which should follow MAC1 instruction. */
if (opa->mod != 0)
return yyerror ("Bad opt mode");
/* If a0macfunc comes before a1macfunc, swap them. */
if (aa->n == 0)
{
/* (M) is not allowed here. */
if (opa->MM != 0)
return yyerror ("(M) not allowed with A0MAC");
if (ab->n != 1)
return yyerror ("Vector AxMACs can't be same");
mtmp = *aa; *aa = *ab; *ab = mtmp;
otmp = *opa; *opa = *opb; *opb = otmp;
}
else
{
if (opb->MM != 0)
return yyerror ("(M) not allowed with A0MAC");
if (ab->n != 0)
return yyerror ("Vector AxMACs can't be same");
}
/* If both ops are one of 0, 1, or 2, we have multiply_halfregs in both
assignment_or_macfuncs. */
if ((aa->op == 0 || aa->op == 1 || aa->op == 2)
&& (ab->op == 0 || ab->op == 1 || ab->op == 2))
{
if (check_multiply_halfregs (aa, ab) < 0)
return -1;
}
else
{
/* Only one of the assign_macfuncs has a half reg multiply
Evil trick: Just 'OR' their source register codes:
We can do that, because we know they were initialized to 0
in the rules that don't use multiply_halfregs. */
aa->s0.regno |= (ab->s0.regno & CODE_MASK);
aa->s1.regno |= (ab->s1.regno & CODE_MASK);
}
if (aa->w == ab->w && aa->P != ab->P)
return yyerror ("Destination Dreg sizes (full or half) must match");
if (aa->w && ab->w)
{
if (aa->P && (aa->dst.regno - ab->dst.regno) != 1)
return yyerror ("Destination Dregs (full) must differ by one");
if (!aa->P && aa->dst.regno != ab->dst.regno)
return yyerror ("Destination Dregs (half) must match");
}
/* Make sure mod flags get ORed, too. */
opb->mod |= opa->mod;
/* Check option. */
if (check_macfunc_option (aa, opb) < 0
&& check_macfunc_option (ab, opb) < 0)
return yyerror ("bad option");
/* Make sure first macfunc has got both P flags ORed. */
aa->P |= ab->P;
return 0;
}
static int
is_group1 (INSTR_T x)
{
/* Group1 is dpsLDST, LDSTpmod, LDST, LDSTiiFP, LDSTii. */
if ((x->value & 0xc000) == 0x8000 || (x->value == 0x0000))
return 1;
return 0;
}
static int
is_group2 (INSTR_T x)
{
if ((((x->value & 0xfc00) == 0x9c00) /* dspLDST. */
&& !((x->value & 0xfde0) == 0x9c60) /* dagMODim. */
&& !((x->value & 0xfde0) == 0x9ce0) /* dagMODim with bit rev. */
&& !((x->value & 0xfde0) == 0x9d60)) /* pick dagMODik. */
|| (x->value == 0x0000))
return 1;
return 0;
}
static int
is_store (INSTR_T x)
{
if (!x)
return 0;
if ((x->value & 0xf000) == 0x8000)
{
int aop = ((x->value >> 9) & 0x3);
int w = ((x->value >> 11) & 0x1);
if (!w || aop == 3)
return 0;
return 1;
}
if (((x->value & 0xFF60) == 0x9E60) || /* dagMODim_0 */
((x->value & 0xFFF0) == 0x9F60)) /* dagMODik_0 */
return 0;
/* decode_dspLDST_0 */
if ((x->value & 0xFC00) == 0x9C00)
{
int w = ((x->value >> 9) & 0x1);
if (w)
return 1;
}
return 0;
}
static INSTR_T
gen_multi_instr_1 (INSTR_T dsp32, INSTR_T dsp16_grp1, INSTR_T dsp16_grp2)
{
int mask1 = dsp32 ? insn_regmask (dsp32->value, dsp32->next->value) : 0;
int mask2 = dsp16_grp1 ? insn_regmask (dsp16_grp1->value, 0) : 0;
int mask3 = dsp16_grp2 ? insn_regmask (dsp16_grp2->value, 0) : 0;
if ((mask1 & mask2) || (mask1 & mask3) || (mask2 & mask3))
yyerror ("resource conflict in multi-issue instruction");
/* Anomaly 05000074 */
if (ENABLE_AC_05000074
&& dsp32 != NULL && dsp16_grp1 != NULL
&& (dsp32->value & 0xf780) == 0xc680
&& ((dsp16_grp1->value & 0xfe40) == 0x9240
|| (dsp16_grp1->value & 0xfe08) == 0xba08
|| (dsp16_grp1->value & 0xfc00) == 0xbc00))
yyerror ("anomaly 05000074 - Multi-Issue Instruction with \
dsp32shiftimm in slot1 and P-reg Store in slot2 Not Supported");
if (is_store (dsp16_grp1) && is_store (dsp16_grp2))
yyerror ("Only one instruction in multi-issue instruction can be a store");
return bfin_gen_multi_instr (dsp32, dsp16_grp1, dsp16_grp2);
}
%}
%union {
INSTR_T instr;
Expr_Node *expr;
SYMBOL_T symbol;
long value;
Register reg;
Macfunc macfunc;
struct { int r0; int s0; int x0; int aop; } modcodes;
struct { int r0; } r0;
Opt_mode mod;
}
/* Tokens. */
/* Vector Specific. */
%token BYTEOP16P BYTEOP16M
%token BYTEOP1P BYTEOP2P BYTEOP3P
%token BYTEUNPACK BYTEPACK
%token PACK
%token SAA
%token ALIGN8 ALIGN16 ALIGN24
%token VIT_MAX
%token EXTRACT DEPOSIT EXPADJ SEARCH
%token ONES SIGN SIGNBITS
/* Stack. */
%token LINK UNLINK
/* Registers. */
%token REG
%token PC
%token CCREG BYTE_DREG
%token REG_A_DOUBLE_ZERO REG_A_DOUBLE_ONE
%token A_ZERO_DOT_L A_ZERO_DOT_H A_ONE_DOT_L A_ONE_DOT_H
%token HALF_REG
/* Progctrl. */
%token NOP
%token RTI RTS RTX RTN RTE
%token HLT IDLE
%token STI CLI
%token CSYNC SSYNC
%token EMUEXCPT
%token RAISE EXCPT
%token LSETUP
%token LOOP
%token LOOP_BEGIN
%token LOOP_END
%token DISALGNEXCPT
%token JUMP JUMP_DOT_S JUMP_DOT_L
%token CALL
/* Emulator only. */
%token ABORT
/* Operators. */
%token NOT TILDA BANG
%token AMPERSAND BAR
%token PERCENT
%token CARET
%token BXOR
%token MINUS PLUS STAR SLASH
%token NEG
%token MIN MAX ABS
%token DOUBLE_BAR
%token _PLUS_BAR_PLUS _PLUS_BAR_MINUS _MINUS_BAR_PLUS _MINUS_BAR_MINUS
%token _MINUS_MINUS _PLUS_PLUS
/* Shift/rotate ops. */
%token SHIFT LSHIFT ASHIFT BXORSHIFT
%token _GREATER_GREATER_GREATER_THAN_ASSIGN
%token ROT
%token LESS_LESS GREATER_GREATER
%token _GREATER_GREATER_GREATER
%token _LESS_LESS_ASSIGN _GREATER_GREATER_ASSIGN
%token DIVS DIVQ
/* In place operators. */
%token ASSIGN _STAR_ASSIGN
%token _BAR_ASSIGN _CARET_ASSIGN _AMPERSAND_ASSIGN
%token _MINUS_ASSIGN _PLUS_ASSIGN
/* Assignments, comparisons. */
%token _ASSIGN_BANG _LESS_THAN_ASSIGN _ASSIGN_ASSIGN
%token GE LT LE GT
%token LESS_THAN
/* Cache. */
%token FLUSHINV FLUSH
%token IFLUSH PREFETCH
/* Misc. */
%token PRNT
%token OUTC
%token WHATREG
%token TESTSET
/* Modifiers. */
%token ASL ASR
%token B W
%token NS S CO SCO
%token TH TL
%token BP
%token BREV
%token X Z
%token M MMOD
%token R RND RNDL RNDH RND12 RND20
%token V
%token LO HI
/* Bit ops. */
%token BITTGL BITCLR BITSET BITTST BITMUX
/* Debug. */
%token DBGAL DBGAH DBGHALT DBG DBGA DBGCMPLX
/* Semantic auxiliaries. */
%token IF COMMA BY
%token COLON SEMICOLON
%token RPAREN LPAREN LBRACK RBRACK
%token STATUS_REG
%token MNOP
%token SYMBOL NUMBER
%token GOT GOT17M4 FUNCDESC_GOT17M4
%token AT PLTPC
/* Types. */
%type <instr> asm
%type <value> MMOD
%type <mod> opt_mode
%type <value> NUMBER
%type <r0> aligndir
%type <modcodes> byteop_mod
%type <reg> a_assign
%type <reg> a_plusassign
%type <reg> a_minusassign
%type <macfunc> multiply_halfregs
%type <macfunc> assign_macfunc
%type <macfunc> a_macfunc
%type <expr> expr_1
%type <instr> asm_1
%type <r0> vmod
%type <modcodes> vsmod
%type <modcodes> ccstat
%type <r0> cc_op
%type <reg> CCREG
%type <reg> reg_with_postinc
%type <reg> reg_with_predec
%type <r0> searchmod
%type <expr> symbol
%type <symbol> SYMBOL
%type <expr> eterm
%type <reg> REG
%type <reg> BYTE_DREG
%type <reg> REG_A_DOUBLE_ZERO
%type <reg> REG_A_DOUBLE_ONE
%type <reg> REG_A
%type <reg> STATUS_REG
%type <expr> expr
%type <r0> xpmod
%type <r0> xpmod1
%type <modcodes> smod
%type <modcodes> b3_op
%type <modcodes> rnd_op
%type <modcodes> post_op
%type <reg> HALF_REG
%type <r0> iu_or_nothing
%type <r0> plus_minus
%type <r0> asr_asl
%type <r0> asr_asl_0
%type <modcodes> sco
%type <modcodes> amod0
%type <modcodes> amod1
%type <modcodes> amod2
%type <r0> op_bar_op
%type <r0> w32_or_nothing
%type <r0> c_align
%type <r0> min_max
%type <expr> got
%type <expr> got_or_expr
%type <expr> pltpc
%type <value> any_gotrel GOT GOT17M4 FUNCDESC_GOT17M4
/* Precedence rules. */
%left BAR
%left CARET
%left AMPERSAND
%left LESS_LESS GREATER_GREATER
%left PLUS MINUS
%left STAR SLASH PERCENT
%right ASSIGN
%right TILDA BANG
%start statement
%%
statement:
| asm
{
insn = $1;
if (insn == (INSTR_T) 0)
return NO_INSN_GENERATED;
else if (insn == (INSTR_T) - 1)
return SEMANTIC_ERROR;
else
return INSN_GENERATED;
}
;
asm: asm_1 SEMICOLON
/* Parallel instructions. */
| asm_1 DOUBLE_BAR asm_1 DOUBLE_BAR asm_1 SEMICOLON
{
if (($1->value & 0xf800) == 0xc000)
{
if (is_group1 ($3) && is_group2 ($5))
$$ = gen_multi_instr_1 ($1, $3, $5);
else if (is_group2 ($3) && is_group1 ($5))
$$ = gen_multi_instr_1 ($1, $5, $3);
else
return yyerror ("Wrong 16 bit instructions groups, slot 2 and slot 3 must be 16-bit instrution group");
}
else if (($3->value & 0xf800) == 0xc000)
{
if (is_group1 ($1) && is_group2 ($5))
$$ = gen_multi_instr_1 ($3, $1, $5);
else if (is_group2 ($1) && is_group1 ($5))
$$ = gen_multi_instr_1 ($3, $5, $1);
else
return yyerror ("Wrong 16 bit instructions groups, slot 1 and slot 3 must be 16-bit instrution group");
}
else if (($5->value & 0xf800) == 0xc000)
{
if (is_group1 ($1) && is_group2 ($3))
$$ = gen_multi_instr_1 ($5, $1, $3);
else if (is_group2 ($1) && is_group1 ($3))
$$ = gen_multi_instr_1 ($5, $3, $1);
else
return yyerror ("Wrong 16 bit instructions groups, slot 1 and slot 2 must be 16-bit instrution group");
}
else
error ("\nIllegal Multi Issue Construct, at least any one of the slot must be DSP32 instruction group\n");
}
| asm_1 DOUBLE_BAR asm_1 SEMICOLON
{
if (($1->value & 0xf800) == 0xc000)
{
if (is_group1 ($3))
$$ = gen_multi_instr_1 ($1, $3, 0);
else if (is_group2 ($3))
$$ = gen_multi_instr_1 ($1, 0, $3);
else
return yyerror ("Wrong 16 bit instructions groups, slot 2 must be the 16-bit instruction group");
}
else if (($3->value & 0xf800) == 0xc000)
{
if (is_group1 ($1))
$$ = gen_multi_instr_1 ($3, $1, 0);
else if (is_group2 ($1))
$$ = gen_multi_instr_1 ($3, 0, $1);
else
return yyerror ("Wrong 16 bit instructions groups, slot 1 must be the 16-bit instruction group");
}
else if (is_group1 ($1) && is_group2 ($3))
$$ = gen_multi_instr_1 (0, $1, $3);
else if (is_group2 ($1) && is_group1 ($3))
$$ = gen_multi_instr_1 (0, $3, $1);
else
return yyerror ("Wrong 16 bit instructions groups, slot 1 and slot 2 must be the 16-bit instruction group");
}
| error
{
$$ = 0;
yyerror ("");
yyerrok;
}
;
/* DSPMAC. */
asm_1:
MNOP
{
$$ = DSP32MAC (3, 0, 0, 0, 0, 0, 0, 0, 0, 0, 3, 0, 0, 0);
}
| assign_macfunc opt_mode
{
int op0, op1;
int w0 = 0, w1 = 0;
int h00, h10, h01, h11;
if (check_macfunc_option (&$1, &$2) < 0)
return yyerror ("bad option");
if ($1.n == 0)
{
if ($2.MM)
return yyerror ("(m) not allowed with a0 unit");
op1 = 3;
op0 = $1.op;
w1 = 0;
w0 = $1.w;
h00 = IS_H ($1.s0);
h10 = IS_H ($1.s1);
h01 = h11 = 0;
}
else
{
op1 = $1.op;
op0 = 3;
w1 = $1.w;
w0 = 0;
h00 = h10 = 0;
h01 = IS_H ($1.s0);
h11 = IS_H ($1.s1);
}
$$ = DSP32MAC (op1, $2.MM, $2.mod, w1, $1.P, h01, h11, h00, h10,
&$1.dst, op0, &$1.s0, &$1.s1, w0);
}
/* VECTOR MACs. */
| assign_macfunc opt_mode COMMA assign_macfunc opt_mode
{
Register *dst;
if (check_macfuncs (&$1, &$2, &$4, &$5) < 0)
return -1;
notethat ("assign_macfunc (.), assign_macfunc (.)\n");
if ($1.w)
dst = &$1.dst;
else
dst = &$4.dst;
$$ = DSP32MAC ($1.op, $2.MM, $5.mod, $1.w, $1.P,
IS_H ($1.s0), IS_H ($1.s1), IS_H ($4.s0), IS_H ($4.s1),
dst, $4.op, &$1.s0, &$1.s1, $4.w);
}
/* DSPALU. */
| DISALGNEXCPT
{
notethat ("dsp32alu: DISALGNEXCPT\n");
$$ = DSP32ALU (18, 0, 0, 0, 0, 0, 0, 0, 3);
}
| REG ASSIGN LPAREN a_plusassign REG_A RPAREN
{
if (IS_DREG ($1) && !IS_A1 ($4) && IS_A1 ($5))
{
notethat ("dsp32alu: dregs = ( A0 += A1 )\n");
$$ = DSP32ALU (11, 0, 0, &$1, 0, 0, 0, 0, 0);
}
else
return yyerror ("Register mismatch");
}
| HALF_REG ASSIGN LPAREN a_plusassign REG_A RPAREN
{
if (!IS_A1 ($4) && IS_A1 ($5))
{
notethat ("dsp32alu: dregs_half = ( A0 += A1 )\n");
$$ = DSP32ALU (11, IS_H ($1), 0, &$1, 0, 0, 0, 0, 1);
}
else
return yyerror ("Register mismatch");
}
| A_ZERO_DOT_H ASSIGN HALF_REG
{
notethat ("dsp32alu: A_ZERO_DOT_H = dregs_hi\n");
$$ = DSP32ALU (9, IS_H ($3), 0, 0, &$3, 0, 0, 0, 0);
}
| A_ONE_DOT_H ASSIGN HALF_REG
{
notethat ("dsp32alu: A_ZERO_DOT_H = dregs_hi\n");
$$ = DSP32ALU (9, IS_H ($3), 0, 0, &$3, 0, 0, 0, 2);
}
| LPAREN REG COMMA REG RPAREN ASSIGN BYTEOP16P LPAREN REG
COLON expr COMMA REG COLON expr RPAREN aligndir
{
if (!IS_DREG ($2) || !IS_DREG ($4))
return yyerror ("Dregs expected");
else if (REG_SAME ($2, $4))
return yyerror ("Illegal dest register combination");
else if (!valid_dreg_pair (&$9, $11))
return yyerror ("Bad dreg pair");
else if (!valid_dreg_pair (&$13, $15))
return yyerror ("Bad dreg pair");
else
{
notethat ("dsp32alu: (dregs , dregs ) = BYTEOP16P (dregs_pair , dregs_pair ) (aligndir)\n");
$$ = DSP32ALU (21, 0, &$2, &$4, &$9, &$13, $17.r0, 0, 0);
}
}
| LPAREN REG COMMA REG RPAREN ASSIGN BYTEOP16M LPAREN REG COLON expr COMMA
REG COLON expr RPAREN aligndir
{
if (!IS_DREG ($2) || !IS_DREG ($4))
return yyerror ("Dregs expected");
else if (REG_SAME ($2, $4))
return yyerror ("Illegal dest register combination");
else if (!valid_dreg_pair (&$9, $11))
return yyerror ("Bad dreg pair");
else if (!valid_dreg_pair (&$13, $15))
return yyerror ("Bad dreg pair");
else
{
notethat ("dsp32alu: (dregs , dregs ) = BYTEOP16M (dregs_pair , dregs_pair ) (aligndir)\n");
$$ = DSP32ALU (21, 0, &$2, &$4, &$9, &$13, $17.r0, 0, 1);
}
}
| LPAREN REG COMMA REG RPAREN ASSIGN BYTEUNPACK REG COLON expr aligndir
{
if (!IS_DREG ($2) || !IS_DREG ($4))
return yyerror ("Dregs expected");
else if (!valid_dreg_pair (&$8, $10))
return yyerror ("Bad dreg pair");
else
{
notethat ("dsp32alu: (dregs , dregs ) = BYTEUNPACK dregs_pair (aligndir)\n");
$$ = DSP32ALU (24, 0, &$2, &$4, &$8, 0, $11.r0, 0, 1);
}
}
| LPAREN REG COMMA REG RPAREN ASSIGN SEARCH REG LPAREN searchmod RPAREN
{
if (REG_SAME ($2, $4))
return yyerror ("Illegal dest register combination");
if (IS_DREG ($2) && IS_DREG ($4) && IS_DREG ($8))
{
notethat ("dsp32alu: (dregs , dregs ) = SEARCH dregs (searchmod)\n");
$$ = DSP32ALU (13, 0, &$2, &$4, &$8, 0, 0, 0, $10.r0);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN A_ONE_DOT_L PLUS A_ONE_DOT_H COMMA
REG ASSIGN A_ZERO_DOT_L PLUS A_ZERO_DOT_H
{
if (REG_SAME ($1, $7))
return yyerror ("Illegal dest register combination");
if (IS_DREG ($1) && IS_DREG ($7))
{
notethat ("dsp32alu: dregs = A1.l + A1.h, dregs = A0.l + A0.h \n");
$$ = DSP32ALU (12, 0, &$1, &$7, 0, 0, 0, 0, 1);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN REG_A PLUS REG_A COMMA REG ASSIGN REG_A MINUS REG_A amod1
{
if (REG_SAME ($1, $7))
return yyerror ("Resource conflict in dest reg");
if (IS_DREG ($1) && IS_DREG ($7) && !REG_SAME ($3, $5)
&& IS_A1 ($9) && !IS_A1 ($11))
{
notethat ("dsp32alu: dregs = A1 + A0 , dregs = A1 - A0 (amod1)\n");
$$ = DSP32ALU (17, 0, &$1, &$7, 0, 0, $12.s0, $12.x0, 0);
}
else if (IS_DREG ($1) && IS_DREG ($7) && !REG_SAME ($3, $5)
&& !IS_A1 ($9) && IS_A1 ($11))
{
notethat ("dsp32alu: dregs = A0 + A1 , dregs = A0 - A1 (amod1)\n");
$$ = DSP32ALU (17, 0, &$1, &$7, 0, 0, $12.s0, $12.x0, 1);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN REG plus_minus REG COMMA REG ASSIGN REG plus_minus REG amod1
{
if ($4.r0 == $10.r0)
return yyerror ("Operators must differ");
if (IS_DREG ($1) && IS_DREG ($3) && IS_DREG ($5)
&& REG_SAME ($3, $9) && REG_SAME ($5, $11))
{
notethat ("dsp32alu: dregs = dregs + dregs,"
"dregs = dregs - dregs (amod1)\n");
$$ = DSP32ALU (4, 0, &$1, &$7, &$3, &$5, $12.s0, $12.x0, 2);
}
else
return yyerror ("Register mismatch");
}
/* Bar Operations. */
| REG ASSIGN REG op_bar_op REG COMMA REG ASSIGN REG op_bar_op REG amod2
{
if (!REG_SAME ($3, $9) || !REG_SAME ($5, $11))
return yyerror ("Differing source registers");
if (!IS_DREG ($1) || !IS_DREG ($3) || !IS_DREG ($5) || !IS_DREG ($7))
return yyerror ("Dregs expected");
if (REG_SAME ($1, $7))
return yyerror ("Resource conflict in dest reg");
if ($4.r0 == 1 && $10.r0 == 2)
{
notethat ("dsp32alu: dregs = dregs .|. dregs , dregs = dregs .|. dregs (amod2)\n");
$$ = DSP32ALU (1, 1, &$1, &$7, &$3, &$5, $12.s0, $12.x0, $12.r0);
}
else if ($4.r0 == 0 && $10.r0 == 3)
{
notethat ("dsp32alu: dregs = dregs .|. dregs , dregs = dregs .|. dregs (amod2)\n");
$$ = DSP32ALU (1, 0, &$1, &$7, &$3, &$5, $12.s0, $12.x0, $12.r0);
}
else
return yyerror ("Bar operand mismatch");
}
| REG ASSIGN ABS REG vmod
{
int op;
if (IS_DREG ($1) && IS_DREG ($4))
{
if ($5.r0)
{
notethat ("dsp32alu: dregs = ABS dregs (v)\n");
op = 6;
}
else
{
/* Vector version of ABS. */
notethat ("dsp32alu: dregs = ABS dregs\n");
op = 7;
}
$$ = DSP32ALU (op, 0, 0, &$1, &$4, 0, 0, 0, 2);
}
else
return yyerror ("Dregs expected");
}
| a_assign ABS REG_A
{
notethat ("dsp32alu: Ax = ABS Ax\n");
$$ = DSP32ALU (16, IS_A1 ($1), 0, 0, 0, 0, 0, 0, IS_A1 ($3));
}
| A_ZERO_DOT_L ASSIGN HALF_REG
{
if (IS_DREG_L ($3))
{
notethat ("dsp32alu: A0.l = reg_half\n");
$$ = DSP32ALU (9, IS_H ($3), 0, 0, &$3, 0, 0, 0, 0);
}
else
return yyerror ("A0.l = Rx.l expected");
}
| A_ONE_DOT_L ASSIGN HALF_REG
{
if (IS_DREG_L ($3))
{
notethat ("dsp32alu: A1.l = reg_half\n");
$$ = DSP32ALU (9, IS_H ($3), 0, 0, &$3, 0, 0, 0, 2);
}
else
return yyerror ("A1.l = Rx.l expected");
}
| REG ASSIGN c_align LPAREN REG COMMA REG RPAREN
{
if (IS_DREG ($1) && IS_DREG ($5) && IS_DREG ($7))
{
notethat ("dsp32shift: dregs = ALIGN8 (dregs , dregs )\n");
$$ = DSP32SHIFT (13, &$1, &$7, &$5, $3.r0, 0);
}
else
return yyerror ("Dregs expected");
}
| REG ASSIGN BYTEOP1P LPAREN REG COLON expr COMMA REG COLON expr RPAREN byteop_mod
{
if (!IS_DREG ($1))
return yyerror ("Dregs expected");
else if (!valid_dreg_pair (&$5, $7))
return yyerror ("Bad dreg pair");
else if (!valid_dreg_pair (&$9, $11))
return yyerror ("Bad dreg pair");
else
{
notethat ("dsp32alu: dregs = BYTEOP1P (dregs_pair , dregs_pair ) (T)\n");
$$ = DSP32ALU (20, 0, 0, &$1, &$5, &$9, $13.s0, 0, $13.r0);
}
}
| REG ASSIGN BYTEOP1P LPAREN REG COLON expr COMMA REG COLON expr RPAREN
{
if (!IS_DREG ($1))
return yyerror ("Dregs expected");
else if (!valid_dreg_pair (&$5, $7))
return yyerror ("Bad dreg pair");
else if (!valid_dreg_pair (&$9, $11))
return yyerror ("Bad dreg pair");
else
{
notethat ("dsp32alu: dregs = BYTEOP1P (dregs_pair , dregs_pair ) (T)\n");
$$ = DSP32ALU (20, 0, 0, &$1, &$5, &$9, 0, 0, 0);
}
}
| REG ASSIGN BYTEOP2P LPAREN REG COLON expr COMMA REG COLON expr RPAREN
rnd_op
{
if (!IS_DREG ($1))
return yyerror ("Dregs expected");
else if (!valid_dreg_pair (&$5, $7))
return yyerror ("Bad dreg pair");
else if (!valid_dreg_pair (&$9, $11))
return yyerror ("Bad dreg pair");
else
{
notethat ("dsp32alu: dregs = BYTEOP2P (dregs_pair , dregs_pair ) (rnd_op)\n");
$$ = DSP32ALU (22, $13.r0, 0, &$1, &$5, &$9, $13.s0, $13.x0, $13.aop);
}
}
| REG ASSIGN BYTEOP3P LPAREN REG COLON expr COMMA REG COLON expr RPAREN
b3_op
{
if (!IS_DREG ($1))
return yyerror ("Dregs expected");
else if (!valid_dreg_pair (&$5, $7))
return yyerror ("Bad dreg pair");
else if (!valid_dreg_pair (&$9, $11))
return yyerror ("Bad dreg pair");
else
{
notethat ("dsp32alu: dregs = BYTEOP3P (dregs_pair , dregs_pair ) (b3_op)\n");
$$ = DSP32ALU (23, $13.x0, 0, &$1, &$5, &$9, $13.s0, 0, 0);
}
}
| REG ASSIGN BYTEPACK LPAREN REG COMMA REG RPAREN
{
if (IS_DREG ($1) && IS_DREG ($5) && IS_DREG ($7))
{
notethat ("dsp32alu: dregs = BYTEPACK (dregs , dregs )\n");
$$ = DSP32ALU (24, 0, 0, &$1, &$5, &$7, 0, 0, 0);
}
else
return yyerror ("Dregs expected");
}
| HALF_REG ASSIGN HALF_REG ASSIGN SIGN LPAREN HALF_REG RPAREN STAR
HALF_REG PLUS SIGN LPAREN HALF_REG RPAREN STAR HALF_REG
{
if (IS_HCOMPL ($1, $3) && IS_HCOMPL ($7, $14) && IS_HCOMPL ($10, $17))
{
notethat ("dsp32alu: dregs_hi = dregs_lo ="
"SIGN (dregs_hi) * dregs_hi + "
"SIGN (dregs_lo) * dregs_lo \n");
$$ = DSP32ALU (12, 0, 0, &$1, &$7, &$10, 0, 0, 0);
}
else
return yyerror ("Dregs expected");
}
| REG ASSIGN REG plus_minus REG amod1
{
if (IS_DREG ($1) && IS_DREG ($3) && IS_DREG ($5))
{
if ($6.aop == 0)
{
/* No saturation flag specified, generate the 16 bit variant. */
notethat ("COMP3op: dregs = dregs +- dregs\n");
$$ = COMP3OP (&$1, &$3, &$5, $4.r0);
}
else
{
/* Saturation flag specified, generate the 32 bit variant. */
notethat ("dsp32alu: dregs = dregs +- dregs (amod1)\n");
$$ = DSP32ALU (4, 0, 0, &$1, &$3, &$5, $6.s0, $6.x0, $4.r0);
}
}
else
if (IS_PREG ($1) && IS_PREG ($3) && IS_PREG ($5) && $4.r0 == 0)
{
notethat ("COMP3op: pregs = pregs + pregs\n");
$$ = COMP3OP (&$1, &$3, &$5, 5);
}
else
return yyerror ("Dregs expected");
}
| REG ASSIGN min_max LPAREN REG COMMA REG RPAREN vmod
{
int op;
if (IS_DREG ($1) && IS_DREG ($5) && IS_DREG ($7))
{
if ($9.r0)
op = 6;
else
op = 7;
notethat ("dsp32alu: dregs = {MIN|MAX} (dregs, dregs)\n");
$$ = DSP32ALU (op, 0, 0, &$1, &$5, &$7, 0, 0, $3.r0);
}
else
return yyerror ("Dregs expected");
}
| a_assign MINUS REG_A
{
notethat ("dsp32alu: Ax = - Ax\n");
$$ = DSP32ALU (14, IS_A1 ($1), 0, 0, 0, 0, 0, 0, IS_A1 ($3));
}
| HALF_REG ASSIGN HALF_REG plus_minus HALF_REG amod1
{
notethat ("dsp32alu: dregs_lo = dregs_lo +- dregs_lo (amod1)\n");
$$ = DSP32ALU (2 | $4.r0, IS_H ($1), 0, &$1, &$3, &$5,
$6.s0, $6.x0, HL2 ($3, $5));
}
| a_assign a_assign expr
{
if (EXPR_VALUE ($3) == 0 && !REG_SAME ($1, $2))
{
notethat ("dsp32alu: A1 = A0 = 0\n");
$$ = DSP32ALU (8, 0, 0, 0, 0, 0, 0, 0, 2);
}
else
return yyerror ("Bad value, 0 expected");
}
/* Saturating. */
| a_assign REG_A LPAREN S RPAREN
{
if (REG_SAME ($1, $2))
{
notethat ("dsp32alu: Ax = Ax (S)\n");
$$ = DSP32ALU (8, 0, 0, 0, 0, 0, 1, 0, IS_A1 ($1));
}
else
return yyerror ("Registers must be equal");
}
| HALF_REG ASSIGN REG LPAREN RND RPAREN
{
if (IS_DREG ($3))
{
notethat ("dsp32alu: dregs_half = dregs (RND)\n");
$$ = DSP32ALU (12, IS_H ($1), 0, &$1, &$3, 0, 0, 0, 3);
}
else
return yyerror ("Dregs expected");
}
| HALF_REG ASSIGN REG plus_minus REG LPAREN RND12 RPAREN
{
if (IS_DREG ($3) && IS_DREG ($5))
{
notethat ("dsp32alu: dregs_half = dregs (+-) dregs (RND12)\n");
$$ = DSP32ALU (5, IS_H ($1), 0, &$1, &$3, &$5, 0, 0, $4.r0);
}
else
return yyerror ("Dregs expected");
}
| HALF_REG ASSIGN REG plus_minus REG LPAREN RND20 RPAREN
{
if (IS_DREG ($3) && IS_DREG ($5))
{
notethat ("dsp32alu: dregs_half = dregs -+ dregs (RND20)\n");
$$ = DSP32ALU (5, IS_H ($1), 0, &$1, &$3, &$5, 0, 1, $4.r0 | 2);
}
else
return yyerror ("Dregs expected");
}
| a_assign REG_A
{
if (!REG_SAME ($1, $2))
{
notethat ("dsp32alu: An = Am\n");
$$ = DSP32ALU (8, 0, 0, 0, 0, 0, IS_A1 ($1), 0, 3);
}
else
return yyerror ("Accu reg arguments must differ");
}
| a_assign REG
{
if (IS_DREG ($2))
{
notethat ("dsp32alu: An = dregs\n");
$$ = DSP32ALU (9, 0, 0, 0, &$2, 0, 1, 0, IS_A1 ($1) << 1);
}
else
return yyerror ("Dregs expected");
}
| REG ASSIGN HALF_REG xpmod
{
if (!IS_H ($3))
{
if ($1.regno == REG_A0x && IS_DREG ($3))
{
notethat ("dsp32alu: A0.x = dregs_lo\n");
$$ = DSP32ALU (9, 0, 0, 0, &$3, 0, 0, 0, 1);
}
else if ($1.regno == REG_A1x && IS_DREG ($3))
{
notethat ("dsp32alu: A1.x = dregs_lo\n");
$$ = DSP32ALU (9, 0, 0, 0, &$3, 0, 0, 0, 3);
}
else if (IS_DREG ($1) && IS_DREG ($3))
{
notethat ("ALU2op: dregs = dregs_lo\n");
$$ = ALU2OP (&$1, &$3, 10 | ($4.r0 ? 0: 1));
}
else
return yyerror ("Register mismatch");
}
else
return yyerror ("Low reg expected");
}
| HALF_REG ASSIGN expr
{
notethat ("LDIMMhalf: pregs_half = imm16\n");
if (!IS_DREG ($1) && !IS_PREG ($1) && !IS_IREG ($1)
&& !IS_MREG ($1) && !IS_BREG ($1) && !IS_LREG ($1))
return yyerror ("Wrong register for load immediate");
if (!IS_IMM ($3, 16) && !IS_UIMM ($3, 16))
return yyerror ("Constant out of range");
$$ = LDIMMHALF_R (&$1, IS_H ($1), 0, 0, $3);
}
| a_assign expr
{
notethat ("dsp32alu: An = 0\n");
if (imm7 ($2) != 0)
return yyerror ("0 expected");
$$ = DSP32ALU (8, 0, 0, 0, 0, 0, 0, 0, IS_A1 ($1));
}
| REG ASSIGN expr xpmod1
{
if (!IS_DREG ($1) && !IS_PREG ($1) && !IS_IREG ($1)
&& !IS_MREG ($1) && !IS_BREG ($1) && !IS_LREG ($1))
return yyerror ("Wrong register for load immediate");
if ($4.r0 == 0)
{
/* 7 bit immediate value if possible.
We will check for that constant value for efficiency
If it goes to reloc, it will be 16 bit. */
if (IS_CONST ($3) && IS_IMM ($3, 7) && IS_DREG ($1))
{
notethat ("COMPI2opD: dregs = imm7 (x) \n");
$$ = COMPI2OPD (&$1, imm7 ($3), 0);
}
else if (IS_CONST ($3) && IS_IMM ($3, 7) && IS_PREG ($1))
{
notethat ("COMPI2opP: pregs = imm7 (x)\n");
$$ = COMPI2OPP (&$1, imm7 ($3), 0);
}
else
{
if (IS_CONST ($3) && !IS_IMM ($3, 16))
return yyerror ("Immediate value out of range");
notethat ("LDIMMhalf: regs = luimm16 (x)\n");
/* reg, H, S, Z. */
$$ = LDIMMHALF_R5 (&$1, 0, 1, 0, $3);
}
}
else
{
/* (z) There is no 7 bit zero extended instruction.
If the expr is a relocation, generate it. */
if (IS_CONST ($3) && !IS_UIMM ($3, 16))
return yyerror ("Immediate value out of range");
notethat ("LDIMMhalf: regs = luimm16 (x)\n");
/* reg, H, S, Z. */
$$ = LDIMMHALF_R5 (&$1, 0, 0, 1, $3);
}
}
| HALF_REG ASSIGN REG
{
if (IS_H ($1))
return yyerror ("Low reg expected");
if (IS_DREG ($1) && $3.regno == REG_A0x)
{
notethat ("dsp32alu: dregs_lo = A0.x\n");
$$ = DSP32ALU (10, 0, 0, &$1, 0, 0, 0, 0, 0);
}
else if (IS_DREG ($1) && $3.regno == REG_A1x)
{
notethat ("dsp32alu: dregs_lo = A1.x\n");
$$ = DSP32ALU (10, 0, 0, &$1, 0, 0, 0, 0, 1);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN REG op_bar_op REG amod0
{
if (IS_DREG ($1) && IS_DREG ($3) && IS_DREG ($5))
{
notethat ("dsp32alu: dregs = dregs .|. dregs (amod0)\n");
$$ = DSP32ALU (0, 0, 0, &$1, &$3, &$5, $6.s0, $6.x0, $4.r0);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN BYTE_DREG xpmod
{
if (IS_DREG ($1) && IS_DREG ($3))
{
notethat ("ALU2op: dregs = dregs_byte\n");
$$ = ALU2OP (&$1, &$3, 12 | ($4.r0 ? 0: 1));
}
else
return yyerror ("Register mismatch");
}
| a_assign ABS REG_A COMMA a_assign ABS REG_A
{
if (REG_SAME ($1, $3) && REG_SAME ($5, $7) && !REG_SAME ($1, $5))
{
notethat ("dsp32alu: A1 = ABS A1 , A0 = ABS A0\n");
$$ = DSP32ALU (16, 0, 0, 0, 0, 0, 0, 0, 3);
}
else
return yyerror ("Register mismatch");
}
| a_assign MINUS REG_A COMMA a_assign MINUS REG_A
{
if (REG_SAME ($1, $3) && REG_SAME ($5, $7) && !REG_SAME ($1, $5))
{
notethat ("dsp32alu: A1 = - A1 , A0 = - A0\n");
$$ = DSP32ALU (14, 0, 0, 0, 0, 0, 0, 0, 3);
}
else
return yyerror ("Register mismatch");
}
| a_minusassign REG_A w32_or_nothing
{
if (!IS_A1 ($1) && IS_A1 ($2))
{
notethat ("dsp32alu: A0 -= A1\n");
$$ = DSP32ALU (11, 0, 0, 0, 0, 0, $3.r0, 0, 3);
}
else
return yyerror ("Register mismatch");
}
| REG _MINUS_ASSIGN expr
{
if (IS_IREG ($1) && EXPR_VALUE ($3) == 4)
{
notethat ("dagMODik: iregs -= 4\n");
$$ = DAGMODIK (&$1, 3);
}
else if (IS_IREG ($1) && EXPR_VALUE ($3) == 2)
{
notethat ("dagMODik: iregs -= 2\n");
$$ = DAGMODIK (&$1, 1);
}
else
return yyerror ("Register or value mismatch");
}
| REG _PLUS_ASSIGN REG LPAREN BREV RPAREN
{
if (IS_IREG ($1) && IS_MREG ($3))
{
notethat ("dagMODim: iregs += mregs (opt_brev)\n");
/* i, m, op, br. */
$$ = DAGMODIM (&$1, &$3, 0, 1);
}
else if (IS_PREG ($1) && IS_PREG ($3))
{
notethat ("PTR2op: pregs += pregs (BREV )\n");
$$ = PTR2OP (&$1, &$3, 5);
}
else
return yyerror ("Register mismatch");
}
| REG _MINUS_ASSIGN REG
{
if (IS_IREG ($1) && IS_MREG ($3))
{
notethat ("dagMODim: iregs -= mregs\n");
$$ = DAGMODIM (&$1, &$3, 1, 0);
}
else if (IS_PREG ($1) && IS_PREG ($3))
{
notethat ("PTR2op: pregs -= pregs\n");
$$ = PTR2OP (&$1, &$3, 0);
}
else
return yyerror ("Register mismatch");
}
| REG_A _PLUS_ASSIGN REG_A w32_or_nothing
{
if (!IS_A1 ($1) && IS_A1 ($3))
{
notethat ("dsp32alu: A0 += A1 (W32)\n");
$$ = DSP32ALU (11, 0, 0, 0, 0, 0, $4.r0, 0, 2);
}
else
return yyerror ("Register mismatch");
}
| REG _PLUS_ASSIGN REG
{
if (IS_IREG ($1) && IS_MREG ($3))
{
notethat ("dagMODim: iregs += mregs\n");
$$ = DAGMODIM (&$1, &$3, 0, 0);
}
else
return yyerror ("iregs += mregs expected");
}
| REG _PLUS_ASSIGN expr
{
if (IS_IREG ($1))
{
if (EXPR_VALUE ($3) == 4)
{
notethat ("dagMODik: iregs += 4\n");
$$ = DAGMODIK (&$1, 2);
}
else if (EXPR_VALUE ($3) == 2)
{
notethat ("dagMODik: iregs += 2\n");
$$ = DAGMODIK (&$1, 0);
}
else
return yyerror ("iregs += [ 2 | 4 ");
}
else if (IS_PREG ($1) && IS_IMM ($3, 7))
{
notethat ("COMPI2opP: pregs += imm7\n");
$$ = COMPI2OPP (&$1, imm7 ($3), 1);
}
else if (IS_DREG ($1) && IS_IMM ($3, 7))
{
notethat ("COMPI2opD: dregs += imm7\n");
$$ = COMPI2OPD (&$1, imm7 ($3), 1);
}
else if ((IS_DREG ($1) || IS_PREG ($1)) && IS_CONST ($3))
return yyerror ("Immediate value out of range");
else
return yyerror ("Register mismatch");
}
| REG _STAR_ASSIGN REG
{
if (IS_DREG ($1) && IS_DREG ($3))
{
notethat ("ALU2op: dregs *= dregs\n");
$$ = ALU2OP (&$1, &$3, 3);
}
else
return yyerror ("Register mismatch");
}
| SAA LPAREN REG COLON expr COMMA REG COLON expr RPAREN aligndir
{
if (!valid_dreg_pair (&$3, $5))
return yyerror ("Bad dreg pair");
else if (!valid_dreg_pair (&$7, $9))
return yyerror ("Bad dreg pair");
else
{
notethat ("dsp32alu: SAA (dregs_pair , dregs_pair ) (aligndir)\n");
$$ = DSP32ALU (18, 0, 0, 0, &$3, &$7, $11.r0, 0, 0);
}
}
| a_assign REG_A LPAREN S RPAREN COMMA a_assign REG_A LPAREN S RPAREN
{
if (REG_SAME ($1, $2) && REG_SAME ($7, $8) && !REG_SAME ($1, $7))
{
notethat ("dsp32alu: A1 = A1 (S) , A0 = A0 (S)\n");
$$ = DSP32ALU (8, 0, 0, 0, 0, 0, 1, 0, 2);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN LPAREN REG PLUS REG RPAREN LESS_LESS expr
{
if (IS_DREG ($1) && IS_DREG ($4) && IS_DREG ($6)
&& REG_SAME ($1, $4))
{
if (EXPR_VALUE ($9) == 1)
{
notethat ("ALU2op: dregs = (dregs + dregs) << 1\n");
$$ = ALU2OP (&$1, &$6, 4);
}
else if (EXPR_VALUE ($9) == 2)
{
notethat ("ALU2op: dregs = (dregs + dregs) << 2\n");
$$ = ALU2OP (&$1, &$6, 5);
}
else
return yyerror ("Bad shift value");
}
else if (IS_PREG ($1) && IS_PREG ($4) && IS_PREG ($6)
&& REG_SAME ($1, $4))
{
if (EXPR_VALUE ($9) == 1)
{
notethat ("PTR2op: pregs = (pregs + pregs) << 1\n");
$$ = PTR2OP (&$1, &$6, 6);
}
else if (EXPR_VALUE ($9) == 2)
{
notethat ("PTR2op: pregs = (pregs + pregs) << 2\n");
$$ = PTR2OP (&$1, &$6, 7);
}
else
return yyerror ("Bad shift value");
}
else
return yyerror ("Register mismatch");
}
/* COMP3 CCFLAG. */
| REG ASSIGN REG BAR REG
{
if (IS_DREG ($1) && IS_DREG ($3) && IS_DREG ($5))
{
notethat ("COMP3op: dregs = dregs | dregs\n");
$$ = COMP3OP (&$1, &$3, &$5, 3);
}
else
return yyerror ("Dregs expected");
}
| REG ASSIGN REG CARET REG
{
if (IS_DREG ($1) && IS_DREG ($3) && IS_DREG ($5))
{
notethat ("COMP3op: dregs = dregs ^ dregs\n");
$$ = COMP3OP (&$1, &$3, &$5, 4);
}
else
return yyerror ("Dregs expected");
}
| REG ASSIGN REG PLUS LPAREN REG LESS_LESS expr RPAREN
{
if (IS_PREG ($1) && IS_PREG ($3) && IS_PREG ($6))
{
if (EXPR_VALUE ($8) == 1)
{
notethat ("COMP3op: pregs = pregs + (pregs << 1)\n");
$$ = COMP3OP (&$1, &$3, &$6, 6);
}
else if (EXPR_VALUE ($8) == 2)
{
notethat ("COMP3op: pregs = pregs + (pregs << 2)\n");
$$ = COMP3OP (&$1, &$3, &$6, 7);
}
else
return yyerror ("Bad shift value");
}
else
return yyerror ("Dregs expected");
}
| CCREG ASSIGN REG_A _ASSIGN_ASSIGN REG_A
{
if ($3.regno == REG_A0 && $5.regno == REG_A1)
{
notethat ("CCflag: CC = A0 == A1\n");
$$ = CCFLAG (0, 0, 5, 0, 0);
}
else
return yyerror ("AREGs are in bad order or same");
}
| CCREG ASSIGN REG_A LESS_THAN REG_A
{
if ($3.regno == REG_A0 && $5.regno == REG_A1)
{
notethat ("CCflag: CC = A0 < A1\n");
$$ = CCFLAG (0, 0, 6, 0, 0);
}
else
return yyerror ("AREGs are in bad order or same");
}
| CCREG ASSIGN REG LESS_THAN REG iu_or_nothing
{
if ((IS_DREG ($3) && IS_DREG ($5))
|| (IS_PREG ($3) && IS_PREG ($5)))
{
notethat ("CCflag: CC = dpregs < dpregs\n");
$$ = CCFLAG (&$3, $5.regno & CODE_MASK, $6.r0, 0, IS_PREG ($3) ? 1 : 0);
}
else
return yyerror ("Bad register in comparison");
}
| CCREG ASSIGN REG LESS_THAN expr iu_or_nothing
{
if (!IS_DREG ($3) && !IS_PREG ($3))
return yyerror ("Bad register in comparison");
if (($6.r0 == 1 && IS_IMM ($5, 3))
|| ($6.r0 == 3 && IS_UIMM ($5, 3)))
{
notethat ("CCflag: CC = dpregs < (u)imm3\n");
$$ = CCFLAG (&$3, imm3 ($5), $6.r0, 1, IS_PREG ($3) ? 1 : 0);
}
else
return yyerror ("Bad constant value");
}
| CCREG ASSIGN REG _ASSIGN_ASSIGN REG
{
if ((IS_DREG ($3) && IS_DREG ($5))
|| (IS_PREG ($3) && IS_PREG ($5)))
{
notethat ("CCflag: CC = dpregs == dpregs\n");
$$ = CCFLAG (&$3, $5.regno & CODE_MASK, 0, 0, IS_PREG ($3) ? 1 : 0);
}
else
return yyerror ("Bad register in comparison");
}
| CCREG ASSIGN REG _ASSIGN_ASSIGN expr
{
if (!IS_DREG ($3) && !IS_PREG ($3))
return yyerror ("Bad register in comparison");
if (IS_IMM ($5, 3))
{
notethat ("CCflag: CC = dpregs == imm3\n");
$$ = CCFLAG (&$3, imm3 ($5), 0, 1, IS_PREG ($3) ? 1 : 0);
}
else
return yyerror ("Bad constant range");
}
| CCREG ASSIGN REG_A _LESS_THAN_ASSIGN REG_A
{
if ($3.regno == REG_A0 && $5.regno == REG_A1)
{
notethat ("CCflag: CC = A0 <= A1\n");
$$ = CCFLAG (0, 0, 7, 0, 0);
}
else
return yyerror ("AREGs are in bad order or same");
}
| CCREG ASSIGN REG _LESS_THAN_ASSIGN REG iu_or_nothing
{
if ((IS_DREG ($3) && IS_DREG ($5))
|| (IS_PREG ($3) && IS_PREG ($5)))
{
notethat ("CCflag: CC = dpregs <= dpregs (..)\n");
$$ = CCFLAG (&$3, $5.regno & CODE_MASK,
1 + $6.r0, 0, IS_PREG ($3) ? 1 : 0);
}
else
return yyerror ("Bad register in comparison");
}
| CCREG ASSIGN REG _LESS_THAN_ASSIGN expr iu_or_nothing
{
if (!IS_DREG ($3) && !IS_PREG ($3))
return yyerror ("Bad register in comparison");
if (($6.r0 == 1 && IS_IMM ($5, 3))
|| ($6.r0 == 3 && IS_UIMM ($5, 3)))
{
notethat ("CCflag: CC = dpregs <= (u)imm3\n");
$$ = CCFLAG (&$3, imm3 ($5), 1 + $6.r0, 1, IS_PREG ($3) ? 1 : 0);
}
else
return yyerror ("Bad constant value");
}
| REG ASSIGN REG AMPERSAND REG
{
if (IS_DREG ($1) && IS_DREG ($3) && IS_DREG ($5))
{
notethat ("COMP3op: dregs = dregs & dregs\n");
$$ = COMP3OP (&$1, &$3, &$5, 2);
}
else
return yyerror ("Dregs expected");
}
| ccstat
{
notethat ("CC2stat operation\n");
$$ = bfin_gen_cc2stat ($1.r0, $1.x0, $1.s0);
}
| REG ASSIGN REG
{
if ((IS_GENREG ($1) && IS_GENREG ($3))
|| (IS_GENREG ($1) && IS_DAGREG ($3))
|| (IS_DAGREG ($1) && IS_GENREG ($3))
|| (IS_DAGREG ($1) && IS_DAGREG ($3))
|| (IS_GENREG ($1) && $3.regno == REG_USP)
|| ($1.regno == REG_USP && IS_GENREG ($3))
|| ($1.regno == REG_USP && $3.regno == REG_USP)
|| (IS_DREG ($1) && IS_SYSREG ($3))
|| (IS_PREG ($1) && IS_SYSREG ($3))
|| (IS_SYSREG ($1) && IS_GENREG ($3))
|| (IS_ALLREG ($1) && IS_EMUDAT ($3))
|| (IS_EMUDAT ($1) && IS_ALLREG ($3))
|| (IS_SYSREG ($1) && $3.regno == REG_USP))
{
$$ = bfin_gen_regmv (&$3, &$1);
}
else
return yyerror ("Unsupported register move");
}
| CCREG ASSIGN REG
{
if (IS_DREG ($3))
{
notethat ("CC2dreg: CC = dregs\n");
$$ = bfin_gen_cc2dreg (1, &$3);
}
else
return yyerror ("Only 'CC = Dreg' supported");
}
| REG ASSIGN CCREG
{
if (IS_DREG ($1))
{
notethat ("CC2dreg: dregs = CC\n");
$$ = bfin_gen_cc2dreg (0, &$1);
}
else
return yyerror ("Only 'Dreg = CC' supported");
}
| CCREG _ASSIGN_BANG CCREG
{
notethat ("CC2dreg: CC =! CC\n");
$$ = bfin_gen_cc2dreg (3, 0);
}
/* DSPMULT. */
| HALF_REG ASSIGN multiply_halfregs opt_mode
{
notethat ("dsp32mult: dregs_half = multiply_halfregs (opt_mode)\n");
if (!IS_H ($1) && $4.MM)
return yyerror ("(M) not allowed with MAC0");
if ($4.mod != 0 && $4.mod != M_FU && $4.mod != M_IS
&& $4.mod != M_IU && $4.mod != M_T && $4.mod != M_TFU
&& $4.mod != M_S2RND && $4.mod != M_ISS2 && $4.mod != M_IH)
return yyerror ("bad option.");
if (IS_H ($1))
{
$$ = DSP32MULT (0, $4.MM, $4.mod, 1, 0,
IS_H ($3.s0), IS_H ($3.s1), 0, 0,
&$1, 0, &$3.s0, &$3.s1, 0);
}
else
{
$$ = DSP32MULT (0, 0, $4.mod, 0, 0,
0, 0, IS_H ($3.s0), IS_H ($3.s1),
&$1, 0, &$3.s0, &$3.s1, 1);
}
}
| REG ASSIGN multiply_halfregs opt_mode
{
/* Odd registers can use (M). */
if (!IS_DREG ($1))
return yyerror ("Dreg expected");
if (IS_EVEN ($1) && $4.MM)
return yyerror ("(M) not allowed with MAC0");
if ($4.mod != 0 && $4.mod != M_FU && $4.mod != M_IS
&& $4.mod != M_S2RND && $4.mod != M_ISS2)
return yyerror ("bad option");
if (!IS_EVEN ($1))
{
notethat ("dsp32mult: dregs = multiply_halfregs (opt_mode)\n");
$$ = DSP32MULT (0, $4.MM, $4.mod, 1, 1,
IS_H ($3.s0), IS_H ($3.s1), 0, 0,
&$1, 0, &$3.s0, &$3.s1, 0);
}
else
{
notethat ("dsp32mult: dregs = multiply_halfregs opt_mode\n");
$$ = DSP32MULT (0, 0, $4.mod, 0, 1,
0, 0, IS_H ($3.s0), IS_H ($3.s1),
&$1, 0, &$3.s0, &$3.s1, 1);
}
}
| HALF_REG ASSIGN multiply_halfregs opt_mode COMMA
HALF_REG ASSIGN multiply_halfregs opt_mode
{
if (!IS_DREG ($1) || !IS_DREG ($6))
return yyerror ("Dregs expected");
if (!IS_HCOMPL($1, $6))
return yyerror ("Dest registers mismatch");
if (check_multiply_halfregs (&$3, &$8) < 0)
return -1;
if ((!IS_H ($1) && $4.MM)
|| (!IS_H ($6) && $9.MM))
return yyerror ("(M) not allowed with MAC0");
notethat ("dsp32mult: dregs_hi = multiply_halfregs mxd_mod, "
"dregs_lo = multiply_halfregs opt_mode\n");
if (IS_H ($1))
$$ = DSP32MULT (0, $4.MM, $9.mod, 1, 0,
IS_H ($3.s0), IS_H ($3.s1), IS_H ($8.s0), IS_H ($8.s1),
&$1, 0, &$3.s0, &$3.s1, 1);
else
$$ = DSP32MULT (0, $9.MM, $9.mod, 1, 0,
IS_H ($8.s0), IS_H ($8.s1), IS_H ($3.s0), IS_H ($3.s1),
&$1, 0, &$3.s0, &$3.s1, 1);
}
| REG ASSIGN multiply_halfregs opt_mode COMMA REG ASSIGN multiply_halfregs opt_mode
{
if (!IS_DREG ($1) || !IS_DREG ($6))
return yyerror ("Dregs expected");
if ((IS_EVEN ($1) && $6.regno - $1.regno != 1)
|| (IS_EVEN ($6) && $1.regno - $6.regno != 1))
return yyerror ("Dest registers mismatch");
if (check_multiply_halfregs (&$3, &$8) < 0)
return -1;
if ((IS_EVEN ($1) && $4.MM)
|| (IS_EVEN ($6) && $9.MM))
return yyerror ("(M) not allowed with MAC0");
notethat ("dsp32mult: dregs = multiply_halfregs mxd_mod, "
"dregs = multiply_halfregs opt_mode\n");
if (IS_EVEN ($1))
$$ = DSP32MULT (0, $9.MM, $9.mod, 1, 1,
IS_H ($8.s0), IS_H ($8.s1), IS_H ($3.s0), IS_H ($3.s1),
&$1, 0, &$3.s0, &$3.s1, 1);
else
$$ = DSP32MULT (0, $4.MM, $9.mod, 1, 1,
IS_H ($3.s0), IS_H ($3.s1), IS_H ($8.s0), IS_H ($8.s1),
&$1, 0, &$3.s0, &$3.s1, 1);
}
/* SHIFTs. */
| a_assign ASHIFT REG_A BY HALF_REG
{
if (!REG_SAME ($1, $3))
return yyerror ("Aregs must be same");
if (IS_DREG ($5) && !IS_H ($5))
{
notethat ("dsp32shift: A0 = ASHIFT A0 BY dregs_lo\n");
$$ = DSP32SHIFT (3, 0, &$5, 0, 0, IS_A1 ($1));
}
else
return yyerror ("Dregs expected");
}
| HALF_REG ASSIGN ASHIFT HALF_REG BY HALF_REG smod
{
if (IS_DREG ($6) && !IS_H ($6))
{
notethat ("dsp32shift: dregs_half = ASHIFT dregs_half BY dregs_lo\n");
$$ = DSP32SHIFT (0, &$1, &$6, &$4, $7.s0, HL2 ($1, $4));
}
else
return yyerror ("Dregs expected");
}
| a_assign REG_A LESS_LESS expr
{
if (!REG_SAME ($1, $2))
return yyerror ("Aregs must be same");
if (IS_UIMM ($4, 5))
{
notethat ("dsp32shiftimm: A0 = A0 << uimm5\n");
$$ = DSP32SHIFTIMM (3, 0, imm5 ($4), 0, 0, IS_A1 ($1));
}
else
return yyerror ("Bad shift value");
}
| REG ASSIGN REG LESS_LESS expr vsmod
{
if (IS_DREG ($1) && IS_DREG ($3) && IS_UIMM ($5, 5))
{
if ($6.r0)
{
/* Vector? */
notethat ("dsp32shiftimm: dregs = dregs << expr (V, .)\n");
$$ = DSP32SHIFTIMM (1, &$1, imm4 ($5), &$3, $6.s0 ? 1 : 2, 0);
}
else
{
notethat ("dsp32shiftimm: dregs = dregs << uimm5 (.)\n");
$$ = DSP32SHIFTIMM (2, &$1, imm6 ($5), &$3, $6.s0 ? 1 : 2, 0);
}
}
else if ($6.s0 == 0 && IS_PREG ($1) && IS_PREG ($3))
{
if (EXPR_VALUE ($5) == 2)
{
notethat ("PTR2op: pregs = pregs << 2\n");
$$ = PTR2OP (&$1, &$3, 1);
}
else if (EXPR_VALUE ($5) == 1)
{
notethat ("COMP3op: pregs = pregs << 1\n");
$$ = COMP3OP (&$1, &$3, &$3, 5);
}
else
return yyerror ("Bad shift value");
}
else
return yyerror ("Bad shift value or register");
}
| HALF_REG ASSIGN HALF_REG LESS_LESS expr smod
{
if (IS_UIMM ($5, 4))
{
if ($6.s0)
{
notethat ("dsp32shiftimm: dregs_half = dregs_half << uimm4 (S)\n");
$$ = DSP32SHIFTIMM (0x0, &$1, imm5 ($5), &$3, $6.s0, HL2 ($1, $3));
}
else
{
notethat ("dsp32shiftimm: dregs_half = dregs_half << uimm4\n");
$$ = DSP32SHIFTIMM (0x0, &$1, imm5 ($5), &$3, 2, HL2 ($1, $3));
}
}
else
return yyerror ("Bad shift value");
}
| REG ASSIGN ASHIFT REG BY HALF_REG vsmod
{
int op;
if (IS_DREG ($1) && IS_DREG ($4) && IS_DREG ($6) && !IS_H ($6))
{
if ($7.r0)
{
op = 1;
notethat ("dsp32shift: dregs = ASHIFT dregs BY "
"dregs_lo (V, .)\n");
}
else
{
op = 2;
notethat ("dsp32shift: dregs = ASHIFT dregs BY dregs_lo (.)\n");
}
$$ = DSP32SHIFT (op, &$1, &$6, &$4, $7.s0, 0);
}
else
return yyerror ("Dregs expected");
}
/* EXPADJ. */
| HALF_REG ASSIGN EXPADJ LPAREN REG COMMA HALF_REG RPAREN vmod
{
if (IS_DREG_L ($1) && IS_DREG_L ($5) && IS_DREG_L ($7))
{
notethat ("dsp32shift: dregs_lo = EXPADJ (dregs , dregs_lo )\n");
$$ = DSP32SHIFT (7, &$1, &$7, &$5, $9.r0, 0);
}
else
return yyerror ("Bad shift value or register");
}
| HALF_REG ASSIGN EXPADJ LPAREN HALF_REG COMMA HALF_REG RPAREN
{
if (IS_DREG_L ($1) && IS_DREG_L ($5) && IS_DREG_L ($7))
{
notethat ("dsp32shift: dregs_lo = EXPADJ (dregs_lo, dregs_lo)\n");
$$ = DSP32SHIFT (7, &$1, &$7, &$5, 2, 0);
}
else if (IS_DREG_L ($1) && IS_DREG_H ($5) && IS_DREG_L ($7))
{
notethat ("dsp32shift: dregs_lo = EXPADJ (dregs_hi, dregs_lo)\n");
$$ = DSP32SHIFT (7, &$1, &$7, &$5, 3, 0);
}
else
return yyerror ("Bad shift value or register");
}
/* DEPOSIT. */
| REG ASSIGN DEPOSIT LPAREN REG COMMA REG RPAREN
{
if (IS_DREG ($1) && IS_DREG ($5) && IS_DREG ($7))
{
notethat ("dsp32shift: dregs = DEPOSIT (dregs , dregs )\n");
$$ = DSP32SHIFT (10, &$1, &$7, &$5, 2, 0);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN DEPOSIT LPAREN REG COMMA REG RPAREN LPAREN X RPAREN
{
if (IS_DREG ($1) && IS_DREG ($5) && IS_DREG ($7))
{
notethat ("dsp32shift: dregs = DEPOSIT (dregs , dregs ) (X)\n");
$$ = DSP32SHIFT (10, &$1, &$7, &$5, 3, 0);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN EXTRACT LPAREN REG COMMA HALF_REG RPAREN xpmod
{
if (IS_DREG ($1) && IS_DREG ($5) && IS_DREG_L ($7))
{
notethat ("dsp32shift: dregs = EXTRACT (dregs, dregs_lo ) (.)\n");
$$ = DSP32SHIFT (10, &$1, &$7, &$5, $9.r0, 0);
}
else
return yyerror ("Register mismatch");
}
| a_assign REG_A _GREATER_GREATER_GREATER expr
{
if (!REG_SAME ($1, $2))
return yyerror ("Aregs must be same");
if (IS_UIMM ($4, 5))
{
notethat ("dsp32shiftimm: Ax = Ax >>> uimm5\n");
$$ = DSP32SHIFTIMM (3, 0, -imm6 ($4), 0, 0, IS_A1 ($1));
}
else
return yyerror ("Shift value range error");
}
| a_assign LSHIFT REG_A BY HALF_REG
{
if (REG_SAME ($1, $3) && IS_DREG_L ($5))
{
notethat ("dsp32shift: Ax = LSHIFT Ax BY dregs_lo\n");
$$ = DSP32SHIFT (3, 0, &$5, 0, 1, IS_A1 ($1));
}
else
return yyerror ("Register mismatch");
}
| HALF_REG ASSIGN LSHIFT HALF_REG BY HALF_REG
{
if (IS_DREG ($1) && IS_DREG ($4) && IS_DREG_L ($6))
{
notethat ("dsp32shift: dregs_lo = LSHIFT dregs_hi BY dregs_lo\n");
$$ = DSP32SHIFT (0, &$1, &$6, &$4, 2, HL2 ($1, $4));
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN LSHIFT REG BY HALF_REG vmod
{
if (IS_DREG ($1) && IS_DREG ($4) && IS_DREG_L ($6))
{
notethat ("dsp32shift: dregs = LSHIFT dregs BY dregs_lo (V )\n");
$$ = DSP32SHIFT ($7.r0 ? 1: 2, &$1, &$6, &$4, 2, 0);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN SHIFT REG BY HALF_REG
{
if (IS_DREG ($1) && IS_DREG ($4) && IS_DREG_L ($6))
{
notethat ("dsp32shift: dregs = SHIFT dregs BY dregs_lo\n");
$$ = DSP32SHIFT (2, &$1, &$6, &$4, 2, 0);
}
else
return yyerror ("Register mismatch");
}
| a_assign REG_A GREATER_GREATER expr
{
if (REG_SAME ($1, $2) && IS_IMM ($4, 6) >= 0)
{
notethat ("dsp32shiftimm: Ax = Ax >> imm6\n");
$$ = DSP32SHIFTIMM (3, 0, -imm6 ($4), 0, 1, IS_A1 ($1));
}
else
return yyerror ("Accu register expected");
}
| REG ASSIGN REG GREATER_GREATER expr vmod
{
if ($6.r0 == 1)
{
if (IS_DREG ($1) && IS_DREG ($3) && IS_UIMM ($5, 5))
{
notethat ("dsp32shiftimm: dregs = dregs >> uimm5 (V)\n");
$$ = DSP32SHIFTIMM (1, &$1, -uimm5 ($5), &$3, 2, 0);
}
else
return yyerror ("Register mismatch");
}
else
{
if (IS_DREG ($1) && IS_DREG ($3) && IS_UIMM ($5, 5))
{
notethat ("dsp32shiftimm: dregs = dregs >> uimm5\n");
$$ = DSP32SHIFTIMM (2, &$1, -imm6 ($5), &$3, 2, 0);
}
else if (IS_PREG ($1) && IS_PREG ($3) && EXPR_VALUE ($5) == 2)
{
notethat ("PTR2op: pregs = pregs >> 2\n");
$$ = PTR2OP (&$1, &$3, 3);
}
else if (IS_PREG ($1) && IS_PREG ($3) && EXPR_VALUE ($5) == 1)
{
notethat ("PTR2op: pregs = pregs >> 1\n");
$$ = PTR2OP (&$1, &$3, 4);
}
else
return yyerror ("Register mismatch");
}
}
| HALF_REG ASSIGN HALF_REG GREATER_GREATER expr
{
if (IS_UIMM ($5, 5))
{
notethat ("dsp32shiftimm: dregs_half = dregs_half >> uimm5\n");
$$ = DSP32SHIFTIMM (0, &$1, -uimm5 ($5), &$3, 2, HL2 ($1, $3));
}
else
return yyerror ("Register mismatch");
}
| HALF_REG ASSIGN HALF_REG _GREATER_GREATER_GREATER expr smod
{
if (IS_UIMM ($5, 5))
{
notethat ("dsp32shiftimm: dregs_half = dregs_half >>> uimm5\n");
$$ = DSP32SHIFTIMM (0, &$1, -uimm5 ($5), &$3,
$6.s0, HL2 ($1, $3));
}
else
return yyerror ("Register or modifier mismatch");
}
| REG ASSIGN REG _GREATER_GREATER_GREATER expr vsmod
{
if (IS_DREG ($1) && IS_DREG ($3) && IS_UIMM ($5, 5))
{
if ($6.r0)
{
/* Vector? */
notethat ("dsp32shiftimm: dregs = dregs >>> uimm5 (V, .)\n");
$$ = DSP32SHIFTIMM (1, &$1, -uimm5 ($5), &$3, $6.s0, 0);
}
else
{
notethat ("dsp32shiftimm: dregs = dregs >>> uimm5 (.)\n");
$$ = DSP32SHIFTIMM (2, &$1, -uimm5 ($5), &$3, $6.s0, 0);
}
}
else
return yyerror ("Register mismatch");
}
| HALF_REG ASSIGN ONES REG
{
if (IS_DREG_L ($1) && IS_DREG ($4))
{
notethat ("dsp32shift: dregs_lo = ONES dregs\n");
$$ = DSP32SHIFT (6, &$1, 0, &$4, 3, 0);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN PACK LPAREN HALF_REG COMMA HALF_REG RPAREN
{
if (IS_DREG ($1) && IS_DREG ($5) && IS_DREG ($7))
{
notethat ("dsp32shift: dregs = PACK (dregs_hi , dregs_hi )\n");
$$ = DSP32SHIFT (4, &$1, &$7, &$5, HL2 ($5, $7), 0);
}
else
return yyerror ("Register mismatch");
}
| HALF_REG ASSIGN CCREG ASSIGN BXORSHIFT LPAREN REG_A COMMA REG RPAREN
{
if (IS_DREG ($1)
&& $7.regno == REG_A0
&& IS_DREG ($9) && !IS_H ($1) && !IS_A1 ($7))
{
notethat ("dsp32shift: dregs_lo = CC = BXORSHIFT (A0 , dregs )\n");
$$ = DSP32SHIFT (11, &$1, &$9, 0, 0, 0);
}
else
return yyerror ("Register mismatch");
}
| HALF_REG ASSIGN CCREG ASSIGN BXOR LPAREN REG_A COMMA REG RPAREN
{
if (IS_DREG ($1)
&& $7.regno == REG_A0
&& IS_DREG ($9) && !IS_H ($1) && !IS_A1 ($7))
{
notethat ("dsp32shift: dregs_lo = CC = BXOR (A0 , dregs)\n");
$$ = DSP32SHIFT (11, &$1, &$9, 0, 1, 0);
}
else
return yyerror ("Register mismatch");
}
| HALF_REG ASSIGN CCREG ASSIGN BXOR LPAREN REG_A COMMA REG_A COMMA CCREG RPAREN
{
if (IS_DREG ($1) && !IS_H ($1) && !REG_SAME ($7, $9))
{
notethat ("dsp32shift: dregs_lo = CC = BXOR (A0 , A1 , CC)\n");
$$ = DSP32SHIFT (12, &$1, 0, 0, 1, 0);
}
else
return yyerror ("Register mismatch");
}
| a_assign ROT REG_A BY HALF_REG
{
if (REG_SAME ($1, $3) && IS_DREG_L ($5))
{
notethat ("dsp32shift: Ax = ROT Ax BY dregs_lo\n");
$$ = DSP32SHIFT (3, 0, &$5, 0, 2, IS_A1 ($1));
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN ROT REG BY HALF_REG
{
if (IS_DREG ($1) && IS_DREG ($4) && IS_DREG_L ($6))
{
notethat ("dsp32shift: dregs = ROT dregs BY dregs_lo\n");
$$ = DSP32SHIFT (2, &$1, &$6, &$4, 3, 0);
}
else
return yyerror ("Register mismatch");
}
| a_assign ROT REG_A BY expr
{
if (IS_IMM ($5, 6))
{
notethat ("dsp32shiftimm: An = ROT An BY imm6\n");
$$ = DSP32SHIFTIMM (3, 0, imm6 ($5), 0, 2, IS_A1 ($1));
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN ROT REG BY expr
{
if (IS_DREG ($1) && IS_DREG ($4) && IS_IMM ($6, 6))
{
$$ = DSP32SHIFTIMM (2, &$1, imm6 ($6), &$4, 3, IS_A1 ($1));
}
else
return yyerror ("Register mismatch");
}
| HALF_REG ASSIGN SIGNBITS REG_A
{
if (IS_DREG_L ($1))
{
notethat ("dsp32shift: dregs_lo = SIGNBITS An\n");
$$ = DSP32SHIFT (6, &$1, 0, 0, IS_A1 ($4), 0);
}
else
return yyerror ("Register mismatch");
}
| HALF_REG ASSIGN SIGNBITS REG
{
if (IS_DREG_L ($1) && IS_DREG ($4))
{
notethat ("dsp32shift: dregs_lo = SIGNBITS dregs\n");
$$ = DSP32SHIFT (5, &$1, 0, &$4, 0, 0);
}
else
return yyerror ("Register mismatch");
}
| HALF_REG ASSIGN SIGNBITS HALF_REG
{
if (IS_DREG_L ($1))
{
notethat ("dsp32shift: dregs_lo = SIGNBITS dregs_lo\n");
$$ = DSP32SHIFT (5, &$1, 0, &$4, 1 + IS_H ($4), 0);
}
else
return yyerror ("Register mismatch");
}
/* The ASR bit is just inverted here. */
| HALF_REG ASSIGN VIT_MAX LPAREN REG RPAREN asr_asl
{
if (IS_DREG_L ($1) && IS_DREG ($5))
{
notethat ("dsp32shift: dregs_lo = VIT_MAX (dregs) (..)\n");
$$ = DSP32SHIFT (9, &$1, 0, &$5, ($7.r0 ? 0 : 1), 0);
}
else
return yyerror ("Register mismatch");
}
| REG ASSIGN VIT_MAX LPAREN REG COMMA REG RPAREN asr_asl
{
if (IS_DREG ($1) && IS_DREG ($5) && IS_DREG ($7))
{
notethat ("dsp32shift: dregs = VIT_MAX (dregs, dregs) (ASR)\n");
$$ = DSP32SHIFT (9, &$1, &$7, &$5, 2 | ($9.r0 ? 0 : 1), 0);
}
else
return yyerror ("Register mismatch");
}
| BITMUX LPAREN REG COMMA REG COMMA REG_A RPAREN asr_asl
{
if (REG_SAME ($3, $5))
return yyerror ("Illegal source register combination");
if (IS_DREG ($3) && IS_DREG ($5) && !IS_A1 ($7))
{
notethat ("dsp32shift: BITMUX (dregs , dregs , A0) (ASR)\n");
$$ = DSP32SHIFT (8, 0, &$3, &$5, $9.r0, 0);
}
else
return yyerror ("Register mismatch");
}
| a_assign BXORSHIFT LPAREN REG_A COMMA REG_A COMMA CCREG RPAREN
{
if (!IS_A1 ($1) && !IS_A1 ($4) && IS_A1 ($6))
{
notethat ("dsp32shift: A0 = BXORSHIFT (A0 , A1 , CC )\n");
$$ = DSP32SHIFT (12, 0, 0, 0, 0, 0);
}
else
return yyerror ("Dregs expected");
}
/* LOGI2op: BITCLR (dregs, uimm5). */
| BITCLR LPAREN REG COMMA expr RPAREN
{
if (IS_DREG ($3) && IS_UIMM ($5, 5))
{
notethat ("LOGI2op: BITCLR (dregs , uimm5 )\n");
$$ = LOGI2OP ($3, uimm5 ($5), 4);
}
else
return yyerror ("Register mismatch");
}
/* LOGI2op: BITSET (dregs, uimm5). */
| BITSET LPAREN REG COMMA expr RPAREN
{
if (IS_DREG ($3) && IS_UIMM ($5, 5))
{
notethat ("LOGI2op: BITCLR (dregs , uimm5 )\n");
$$ = LOGI2OP ($3, uimm5 ($5), 2);
}
else
return yyerror ("Register mismatch");
}
/* LOGI2op: BITTGL (dregs, uimm5). */
| BITTGL LPAREN REG COMMA expr RPAREN
{
if (IS_DREG ($3) && IS_UIMM ($5, 5))
{
notethat ("LOGI2op: BITCLR (dregs , uimm5 )\n");
$$ = LOGI2OP ($3, uimm5 ($5), 3);
}
else
return yyerror ("Register mismatch");
}
| CCREG _ASSIGN_BANG BITTST LPAREN REG COMMA expr RPAREN
{
if (IS_DREG ($5) && IS_UIMM ($7, 5))
{
notethat ("LOGI2op: CC =! BITTST (dregs , uimm5 )\n");
$$ = LOGI2OP ($5, uimm5 ($7), 0);
}
else
return yyerror ("Register mismatch or value error");
}
| CCREG ASSIGN BITTST LPAREN REG COMMA expr RPAREN
{
if (IS_DREG ($5) && IS_UIMM ($7, 5))
{
notethat ("LOGI2op: CC = BITTST (dregs , uimm5 )\n");
$$ = LOGI2OP ($5, uimm5 ($7), 1);
}
else
return yyerror ("Register mismatch or value error");
}
| IF BANG CCREG REG ASSIGN REG
{
if ((IS_DREG ($4) || IS_PREG ($4))
&& (IS_DREG ($6) || IS_PREG ($6)))
{
notethat ("ccMV: IF ! CC gregs = gregs\n");
$$ = CCMV (&$6, &$4, 0);
}
else
return yyerror ("Register mismatch");
}
| IF CCREG REG ASSIGN REG
{
if ((IS_DREG ($5) || IS_PREG ($5))
&& (IS_DREG ($3) || IS_PREG ($3)))
{
notethat ("ccMV: IF CC gregs = gregs\n");
$$ = CCMV (&$5, &$3, 1);
}
else
return yyerror ("Register mismatch");
}
| IF BANG CCREG JUMP expr
{
if (IS_PCREL10 ($5))
{
notethat ("BRCC: IF !CC JUMP pcrel11m2\n");
$$ = BRCC (0, 0, $5);
}
else
return yyerror ("Bad jump offset");
}
| IF BANG CCREG JUMP expr LPAREN BP RPAREN
{
if (IS_PCREL10 ($5))
{
notethat ("BRCC: IF !CC JUMP pcrel11m2\n");
$$ = BRCC (0, 1, $5);
}
else
return yyerror ("Bad jump offset");
}
| IF CCREG JUMP expr
{
if (IS_PCREL10 ($4))
{
notethat ("BRCC: IF CC JUMP pcrel11m2\n");
$$ = BRCC (1, 0, $4);
}
else
return yyerror ("Bad jump offset");
}
| IF CCREG JUMP expr LPAREN BP RPAREN
{
if (IS_PCREL10 ($4))
{
notethat ("BRCC: IF !CC JUMP pcrel11m2\n");
$$ = BRCC (1, 1, $4);
}
else
return yyerror ("Bad jump offset");
}
| NOP
{
notethat ("ProgCtrl: NOP\n");
$$ = PROGCTRL (0, 0);
}
| RTS
{
notethat ("ProgCtrl: RTS\n");
$$ = PROGCTRL (1, 0);
}
| RTI
{
notethat ("ProgCtrl: RTI\n");
$$ = PROGCTRL (1, 1);
}
| RTX
{
notethat ("ProgCtrl: RTX\n");
$$ = PROGCTRL (1, 2);
}
| RTN
{
notethat ("ProgCtrl: RTN\n");
$$ = PROGCTRL (1, 3);
}
| RTE
{
notethat ("ProgCtrl: RTE\n");
$$ = PROGCTRL (1, 4);
}
| IDLE
{
notethat ("ProgCtrl: IDLE\n");
$$ = PROGCTRL (2, 0);
}
| CSYNC
{
notethat ("ProgCtrl: CSYNC\n");
$$ = PROGCTRL (2, 3);
}
| SSYNC
{
notethat ("ProgCtrl: SSYNC\n");
$$ = PROGCTRL (2, 4);
}
| EMUEXCPT
{
notethat ("ProgCtrl: EMUEXCPT\n");
$$ = PROGCTRL (2, 5);
}
| CLI REG
{
if (IS_DREG ($2))
{
notethat ("ProgCtrl: CLI dregs\n");
$$ = PROGCTRL (3, $2.regno & CODE_MASK);
}
else
return yyerror ("Dreg expected for CLI");
}
| STI REG
{
if (IS_DREG ($2))
{
notethat ("ProgCtrl: STI dregs\n");
$$ = PROGCTRL (4, $2.regno & CODE_MASK);
}
else
return yyerror ("Dreg expected for STI");
}
| JUMP LPAREN REG RPAREN
{
if (IS_PREG ($3))
{
notethat ("ProgCtrl: JUMP (pregs )\n");
$$ = PROGCTRL (5, $3.regno & CODE_MASK);
}
else
return yyerror ("Bad register for indirect jump");
}
| CALL LPAREN REG RPAREN
{
if (IS_PREG ($3))
{
notethat ("ProgCtrl: CALL (pregs )\n");
$$ = PROGCTRL (6, $3.regno & CODE_MASK);
}
else
return yyerror ("Bad register for indirect call");
}
| CALL LPAREN PC PLUS REG RPAREN
{
if (IS_PREG ($5))
{
notethat ("ProgCtrl: CALL (PC + pregs )\n");
$$ = PROGCTRL (7, $5.regno & CODE_MASK);
}
else
return yyerror ("Bad register for indirect call");
}
| JUMP LPAREN PC PLUS REG RPAREN
{
if (IS_PREG ($5))
{
notethat ("ProgCtrl: JUMP (PC + pregs )\n");
$$ = PROGCTRL (8, $5.regno & CODE_MASK);
}
else
return yyerror ("Bad register for indirect jump");
}
| RAISE expr
{
if (IS_UIMM ($2, 4))
{
notethat ("ProgCtrl: RAISE uimm4\n");
$$ = PROGCTRL (9, uimm4 ($2));
}
else
return yyerror ("Bad value for RAISE");
}
| EXCPT expr
{
notethat ("ProgCtrl: EMUEXCPT\n");
$$ = PROGCTRL (10, uimm4 ($2));
}
| TESTSET LPAREN REG RPAREN
{
if (IS_PREG ($3))
{
if ($3.regno == REG_SP || $3.regno == REG_FP)
return yyerror ("Bad register for TESTSET");
notethat ("ProgCtrl: TESTSET (pregs )\n");
$$ = PROGCTRL (11, $3.regno & CODE_MASK);
}
else
return yyerror ("Preg expected");
}
| JUMP expr
{
if (IS_PCREL12 ($2))
{
notethat ("UJUMP: JUMP pcrel12\n");
$$ = UJUMP ($2);
}
else
return yyerror ("Bad value for relative jump");
}
| JUMP_DOT_S expr
{
if (IS_PCREL12 ($2))
{
notethat ("UJUMP: JUMP_DOT_S pcrel12\n");
$$ = UJUMP($2);
}
else
return yyerror ("Bad value for relative jump");
}
| JUMP_DOT_L expr
{
if (IS_PCREL24 ($2))
{
notethat ("CALLa: jump.l pcrel24\n");
$$ = CALLA ($2, 0);
}
else
return yyerror ("Bad value for long jump");
}
| JUMP_DOT_L pltpc
{
if (IS_PCREL24 ($2))
{
notethat ("CALLa: jump.l pcrel24\n");
$$ = CALLA ($2, 2);
}
else
return yyerror ("Bad value for long jump");
}
| CALL expr
{
if (IS_PCREL24 ($2))
{
notethat ("CALLa: CALL pcrel25m2\n");
$$ = CALLA ($2, 1);
}
else
return yyerror ("Bad call address");
}
| CALL pltpc
{
if (IS_PCREL24 ($2))
{
notethat ("CALLa: CALL pcrel25m2\n");
$$ = CALLA ($2, 2);
}
else
return yyerror ("Bad call address");
}
/* ALU2ops. */
/* ALU2op: DIVQ (dregs, dregs). */
| DIVQ LPAREN REG COMMA REG RPAREN
{
if (IS_DREG ($3) && IS_DREG ($5))
$$ = ALU2OP (&$3, &$5, 8);
else
return yyerror ("Bad registers for DIVQ");
}
| DIVS LPAREN REG COMMA REG RPAREN
{
if (IS_DREG ($3) && IS_DREG ($5))
$$ = ALU2OP (&$3, &$5, 9);
else
return yyerror ("Bad registers for DIVS");
}
| REG ASSIGN MINUS REG vsmod
{
if (IS_DREG ($1) && IS_DREG ($4))
{
if ($5.r0 == 0 && $5.s0 == 0 && $5.aop == 0)
{
notethat ("ALU2op: dregs = - dregs\n");
$$ = ALU2OP (&$1, &$4, 14);
}
else if ($5.r0 == 1 && $5.s0 == 0 && $5.aop == 3)
{
notethat ("dsp32alu: dregs = - dregs (.)\n");
$$ = DSP32ALU (15, 0, 0, &$1, &$4, 0, $5.s0, 0, 3);
}
else
{
notethat ("dsp32alu: dregs = - dregs (.)\n");
$$ = DSP32ALU (7, 0, 0, &$1, &$4, 0, $5.s0, 0, 3);
}
}
else
return yyerror ("Dregs expected");
}
| REG ASSIGN TILDA REG
{
if (IS_DREG ($1) && IS_DREG ($4))
{
notethat ("ALU2op: dregs = ~dregs\n");
$$ = ALU2OP (&$1, &$4, 15);
}
else
return yyerror ("Dregs expected");
}
| REG _GREATER_GREATER_ASSIGN REG
{
if (IS_DREG ($1) && IS_DREG ($3))
{
notethat ("ALU2op: dregs >>= dregs\n");
$$ = ALU2OP (&$1, &$3, 1);
}
else
return yyerror ("Dregs expected");
}
| REG _GREATER_GREATER_ASSIGN expr
{
if (IS_DREG ($1) && IS_UIMM ($3, 5))
{
notethat ("LOGI2op: dregs >>= uimm5\n");
$$ = LOGI2OP ($1, uimm5 ($3), 6);
}
else
return yyerror ("Dregs expected or value error");
}
| REG _GREATER_GREATER_GREATER_THAN_ASSIGN REG
{
if (IS_DREG ($1) && IS_DREG ($3))
{
notethat ("ALU2op: dregs >>>= dregs\n");
$$ = ALU2OP (&$1, &$3, 0);
}
else
return yyerror ("Dregs expected");
}
| REG _LESS_LESS_ASSIGN REG
{
if (IS_DREG ($1) && IS_DREG ($3))
{
notethat ("ALU2op: dregs <<= dregs\n");
$$ = ALU2OP (&$1, &$3, 2);
}
else
return yyerror ("Dregs expected");
}
| REG _LESS_LESS_ASSIGN expr
{
if (IS_DREG ($1) && IS_UIMM ($3, 5))
{
notethat ("LOGI2op: dregs <<= uimm5\n");
$$ = LOGI2OP ($1, uimm5 ($3), 7);
}
else
return yyerror ("Dregs expected or const value error");
}
| REG _GREATER_GREATER_GREATER_THAN_ASSIGN expr
{
if (IS_DREG ($1) && IS_UIMM ($3, 5))
{
notethat ("LOGI2op: dregs >>>= uimm5\n");
$$ = LOGI2OP ($1, uimm5 ($3), 5);
}
else
return yyerror ("Dregs expected");
}
/* Cache Control. */
| FLUSH LBRACK REG RBRACK
{
notethat ("CaCTRL: FLUSH [ pregs ]\n");
if (IS_PREG ($3))
$$ = CACTRL (&$3, 0, 2);
else
return yyerror ("Bad register(s) for FLUSH");
}
| FLUSH reg_with_postinc
{
if (IS_PREG ($2))
{
notethat ("CaCTRL: FLUSH [ pregs ++ ]\n");
$$ = CACTRL (&$2, 1, 2);
}
else
return yyerror ("Bad register(s) for FLUSH");
}
| FLUSHINV LBRACK REG RBRACK
{
if (IS_PREG ($3))
{
notethat ("CaCTRL: FLUSHINV [ pregs ]\n");
$$ = CACTRL (&$3, 0, 1);
}
else
return yyerror ("Bad register(s) for FLUSH");
}
| FLUSHINV reg_with_postinc
{
if (IS_PREG ($2))
{
notethat ("CaCTRL: FLUSHINV [ pregs ++ ]\n");
$$ = CACTRL (&$2, 1, 1);
}
else
return yyerror ("Bad register(s) for FLUSH");
}
/* CaCTRL: IFLUSH [pregs]. */
| IFLUSH LBRACK REG RBRACK
{
if (IS_PREG ($3))
{
notethat ("CaCTRL: IFLUSH [ pregs ]\n");
$$ = CACTRL (&$3, 0, 3);
}
else
return yyerror ("Bad register(s) for FLUSH");
}
| IFLUSH reg_with_postinc
{
if (IS_PREG ($2))
{
notethat ("CaCTRL: IFLUSH [ pregs ++ ]\n");
$$ = CACTRL (&$2, 1, 3);
}
else
return yyerror ("Bad register(s) for FLUSH");
}
| PREFETCH LBRACK REG RBRACK
{
if (IS_PREG ($3))
{
notethat ("CaCTRL: PREFETCH [ pregs ]\n");
$$ = CACTRL (&$3, 0, 0);
}
else
return yyerror ("Bad register(s) for PREFETCH");
}
| PREFETCH reg_with_postinc
{
if (IS_PREG ($2))
{
notethat ("CaCTRL: PREFETCH [ pregs ++ ]\n");
$$ = CACTRL (&$2, 1, 0);
}
else
return yyerror ("Bad register(s) for PREFETCH");
}
/* LOAD/STORE. */
/* LDST: B [ pregs <post_op> ] = dregs. */
| B LBRACK REG post_op RBRACK ASSIGN REG
{
if (!IS_DREG ($7))
return yyerror ("Dreg expected for source operand");
if (!IS_PREG ($3))
return yyerror ("Preg expected in address");
notethat ("LDST: B [ pregs <post_op> ] = dregs\n");
$$ = LDST (&$3, &$7, $4.x0, 2, 0, 1);
}
/* LDSTidxI: B [ pregs + imm16 ] = dregs. */
| B LBRACK REG plus_minus expr RBRACK ASSIGN REG
{
Expr_Node *tmp = $5;
if (!IS_DREG ($8))
return yyerror ("Dreg expected for source operand");
if (!IS_PREG ($3))
return yyerror ("Preg expected in address");
if (IS_RELOC ($5))
return yyerror ("Plain symbol used as offset");
if ($4.r0)
tmp = unary (Expr_Op_Type_NEG, tmp);
if (in_range_p (tmp, -32768, 32767, 0))
{
notethat ("LDST: B [ pregs + imm16 ] = dregs\n");
$$ = LDSTIDXI (&$3, &$8, 1, 2, 0, $5);
}
else
return yyerror ("Displacement out of range");
}
/* LDSTii: W [ pregs + uimm4s2 ] = dregs. */
| W LBRACK REG plus_minus expr RBRACK ASSIGN REG
{
Expr_Node *tmp = $5;
if (!IS_DREG ($8))
return yyerror ("Dreg expected for source operand");
if (!IS_PREG ($3))
return yyerror ("Preg expected in address");
if ($4.r0)
tmp = unary (Expr_Op_Type_NEG, tmp);
if (IS_RELOC ($5))
return yyerror ("Plain symbol used as offset");
if (in_range_p (tmp, 0, 30, 1))
{
notethat ("LDSTii: W [ pregs +- uimm5m2 ] = dregs\n");
$$ = LDSTII (&$3, &$8, tmp, 1, 1);
}
else if (in_range_p (tmp, -65536, 65535, 1))
{
notethat ("LDSTidxI: W [ pregs + imm17m2 ] = dregs\n");
$$ = LDSTIDXI (&$3, &$8, 1, 1, 0, tmp);
}
else
return yyerror ("Displacement out of range");
}
/* LDST: W [ pregs <post_op> ] = dregs. */
| W LBRACK REG post_op RBRACK ASSIGN REG
{
if (!IS_DREG ($7))
return yyerror ("Dreg expected for source operand");
if (!IS_PREG ($3))
return yyerror ("Preg expected in address");
notethat ("LDST: W [ pregs <post_op> ] = dregs\n");
$$ = LDST (&$3, &$7, $4.x0, 1, 0, 1);
}
| W LBRACK REG post_op RBRACK ASSIGN HALF_REG
{
if (!IS_DREG ($7))
return yyerror ("Dreg expected for source operand");
if ($4.x0 == 2)
{
if (!IS_IREG ($3) && !IS_PREG ($3))
return yyerror ("Ireg or Preg expected in address");
}
else if (!IS_IREG ($3))
return yyerror ("Ireg expected in address");
if (IS_IREG ($3))
{
notethat ("dspLDST: W [ iregs <post_op> ] = dregs_half\n");
$$ = DSPLDST (&$3, 1 + IS_H ($7), &$7, $4.x0, 1);
}
else
{
notethat ("LDSTpmod: W [ pregs ] = dregs_half\n");
$$ = LDSTPMOD (&$3, &$7, &$3, 1 + IS_H ($7), 1);
}
}
/* LDSTiiFP: [ FP - const ] = dpregs. */
| LBRACK REG plus_minus expr RBRACK ASSIGN REG
{
Expr_Node *tmp = $4;
int ispreg = IS_PREG ($7);
if (!IS_PREG ($2))
return yyerror ("Preg expected in address");
if (!IS_DREG ($7) && !ispreg)
return yyerror ("Preg expected for source operand");
if ($3.r0)
tmp = unary (Expr_Op_Type_NEG, tmp);
if (IS_RELOC ($4))
return yyerror ("Plain symbol used as offset");
if (in_range_p (tmp, 0, 63, 3))
{
notethat ("LDSTii: dpregs = [ pregs + uimm6m4 ]\n");
$$ = LDSTII (&$2, &$7, tmp, 1, ispreg ? 3 : 0);
}
else if ($2.regno == REG_FP && in_range_p (tmp, -128, 0, 3))
{
notethat ("LDSTiiFP: dpregs = [ FP - uimm7m4 ]\n");
tmp = unary (Expr_Op_Type_NEG, tmp);
$$ = LDSTIIFP (tmp, &$7, 1);
}
else if (in_range_p (tmp, -131072, 131071, 3))
{
notethat ("LDSTidxI: [ pregs + imm18m4 ] = dpregs\n");
$$ = LDSTIDXI (&$2, &$7, 1, 0, ispreg ? 1 : 0, tmp);
}
else
return yyerror ("Displacement out of range");
}
| REG ASSIGN W LBRACK REG plus_minus expr RBRACK xpmod
{
Expr_Node *tmp = $7;
if (!IS_DREG ($1))
return yyerror ("Dreg expected for destination operand");
if (!IS_PREG ($5))
return yyerror ("Preg expected in address");
if ($6.r0)
tmp = unary (Expr_Op_Type_NEG, tmp);
if (IS_RELOC ($7))
return yyerror ("Plain symbol used as offset");
if (in_range_p (tmp, 0, 30, 1))
{
notethat ("LDSTii: dregs = W [ pregs + uimm5m2 ] (.)\n");
$$ = LDSTII (&$5, &$1, tmp, 0, 1 << $9.r0);
}
else if (in_range_p (tmp, -65536, 65535, 1))
{
notethat ("LDSTidxI: dregs = W [ pregs + imm17m2 ] (.)\n");
$$ = LDSTIDXI (&$5, &$1, 0, 1, $9.r0, tmp);
}
else
return yyerror ("Displacement out of range");
}
| HALF_REG ASSIGN W LBRACK REG post_op RBRACK
{
if (!IS_DREG ($1))
return yyerror ("Dreg expected for source operand");
if ($6.x0 == 2)
{
if (!IS_IREG ($5) && !IS_PREG ($5))
return yyerror ("Ireg or Preg expected in address");
}
else if (!IS_IREG ($5))
return yyerror ("Ireg expected in address");
if (IS_IREG ($5))
{
notethat ("dspLDST: dregs_half = W [ iregs <post_op> ]\n");
$$ = DSPLDST(&$5, 1 + IS_H ($1), &$1, $6.x0, 0);
}
else
{
notethat ("LDSTpmod: dregs_half = W [ pregs <post_op> ]\n");
$$ = LDSTPMOD (&$5, &$1, &$5, 1 + IS_H ($1), 0);
}
}
| REG ASSIGN W LBRACK REG post_op RBRACK xpmod
{
if (!IS_DREG ($1))
return yyerror ("Dreg expected for destination operand");
if (!IS_PREG ($5))
return yyerror ("Preg expected in address");
notethat ("LDST: dregs = W [ pregs <post_op> ] (.)\n");
$$ = LDST (&$5, &$1, $6.x0, 1, $8.r0, 0);
}
| REG ASSIGN W LBRACK REG _PLUS_PLUS REG RBRACK xpmod
{
if (!IS_DREG ($1))
return yyerror ("Dreg expected for destination operand");
if (!IS_PREG ($5) || !IS_PREG ($7))
return yyerror ("Preg expected in address");
notethat ("LDSTpmod: dregs = W [ pregs ++ pregs ] (.)\n");
$$ = LDSTPMOD (&$5, &$1, &$7, 3, $9.r0);
}
| HALF_REG ASSIGN W LBRACK REG _PLUS_PLUS REG RBRACK
{
if (!IS_DREG ($1))
return yyerror ("Dreg expected for destination operand");
if (!IS_PREG ($5) || !IS_PREG ($7))
return yyerror ("Preg expected in address");
notethat ("LDSTpmod: dregs_half = W [ pregs ++ pregs ]\n");
$$ = LDSTPMOD (&$5, &$1, &$7, 1 + IS_H ($1), 0);
}
| LBRACK REG post_op RBRACK ASSIGN REG
{
if (!IS_IREG ($2) && !IS_PREG ($2))
return yyerror ("Ireg or Preg expected in address");
else if (IS_IREG ($2) && !IS_DREG ($6))
return yyerror ("Dreg expected for source operand");
else if (IS_PREG ($2) && !IS_DREG ($6) && !IS_PREG ($6))
return yyerror ("Dreg or Preg expected for source operand");
if (IS_IREG ($2))
{
notethat ("dspLDST: [ iregs <post_op> ] = dregs\n");
$$ = DSPLDST(&$2, 0, &$6, $3.x0, 1);
}
else if (IS_DREG ($6))
{
notethat ("LDST: [ pregs <post_op> ] = dregs\n");
$$ = LDST (&$2, &$6, $3.x0, 0, 0, 1);
}
else
{
notethat ("LDST: [ pregs <post_op> ] = pregs\n");
$$ = LDST (&$2, &$6, $3.x0, 0, 1, 1);
}
}
| LBRACK REG _PLUS_PLUS REG RBRACK ASSIGN REG
{
if (!IS_DREG ($7))
return yyerror ("Dreg expected for source operand");
if (IS_IREG ($2) && IS_MREG ($4))
{
notethat ("dspLDST: [ iregs ++ mregs ] = dregs\n");
$$ = DSPLDST(&$2, $4.regno & CODE_MASK, &$7, 3, 1);
}
else if (IS_PREG ($2) && IS_PREG ($4))
{
notethat ("LDSTpmod: [ pregs ++ pregs ] = dregs\n");
$$ = LDSTPMOD (&$2, &$7, &$4, 0, 1);
}
else
return yyerror ("Preg ++ Preg or Ireg ++ Mreg expected in address");
}
| W LBRACK REG _PLUS_PLUS REG RBRACK ASSIGN HALF_REG
{
if (!IS_DREG ($8))
return yyerror ("Dreg expected for source operand");
if (IS_PREG ($3) && IS_PREG ($5))
{
notethat ("LDSTpmod: W [ pregs ++ pregs ] = dregs_half\n");
$$ = LDSTPMOD (&$3, &$8, &$5, 1 + IS_H ($8), 1);
}
else
return yyerror ("Preg ++ Preg expected in address");
}
| REG ASSIGN B LBRACK REG plus_minus expr RBRACK xpmod
{
Expr_Node *tmp = $7;
if (!IS_DREG ($1))
return yyerror ("Dreg expected for destination operand");
if (!IS_PREG ($5))
return yyerror ("Preg expected in address");
if ($6.r0)
tmp = unary (Expr_Op_Type_NEG, tmp);
if (IS_RELOC ($7))
return yyerror ("Plain symbol used as offset");
if (in_range_p (tmp, -32768, 32767, 0))
{
notethat ("LDSTidxI: dregs = B [ pregs + imm16 ] (%c)\n",
$9.r0 ? 'X' : 'Z');
$$ = LDSTIDXI (&$5, &$1, 0, 2, $9.r0, tmp);
}
else
return yyerror ("Displacement out of range");
}
| REG ASSIGN B LBRACK REG post_op RBRACK xpmod
{
if (!IS_DREG ($1))
return yyerror ("Dreg expected for destination operand");
if (!IS_PREG ($5))
return yyerror ("Preg expected in address");
notethat ("LDST: dregs = B [ pregs <post_op> ] (%c)\n",
$8.r0 ? 'X' : 'Z');
$$ = LDST (&$5, &$1, $6.x0, 2, $8.r0, 0);
}
| REG ASSIGN LBRACK REG _PLUS_PLUS REG RBRACK
{
if (!IS_DREG ($1))
return yyerror ("Dreg expected for destination operand");
if (IS_IREG ($4) && IS_MREG ($6))
{
notethat ("dspLDST: dregs = [ iregs ++ mregs ]\n");
$$ = DSPLDST(&$4, $6.regno & CODE_MASK, &$1, 3, 0);
}
else if (IS_PREG ($4) && IS_PREG ($6))
{
notethat ("LDSTpmod: dregs = [ pregs ++ pregs ]\n");
$$ = LDSTPMOD (&$4, &$1, &$6, 0, 0);
}
else
return yyerror ("Preg ++ Preg or Ireg ++ Mreg expected in address");
}
| REG ASSIGN LBRACK REG plus_minus got_or_expr RBRACK
{
Expr_Node *tmp = $6;
int ispreg = IS_PREG ($1);
int isgot = IS_RELOC($6);
if (!IS_PREG ($4))
return yyerror ("Preg expected in address");
if (!IS_DREG ($1) && !ispreg)
return yyerror ("Dreg or Preg expected for destination operand");
if (tmp->type == Expr_Node_Reloc
&& strcmp (tmp->value.s_value,
"_current_shared_library_p5_offset_") != 0)
return yyerror ("Plain symbol used as offset");
if ($5.r0)
tmp = unary (Expr_Op_Type_NEG, tmp);
if (isgot)
{
notethat ("LDSTidxI: dpregs = [ pregs + sym@got ]\n");
$$ = LDSTIDXI (&$4, &$1, 0, 0, ispreg ? 1 : 0, tmp);
}
else if (in_range_p (tmp, 0, 63, 3))
{
notethat ("LDSTii: dpregs = [ pregs + uimm7m4 ]\n");
$$ = LDSTII (&$4, &$1, tmp, 0, ispreg ? 3 : 0);
}
else if ($4.regno == REG_FP && in_range_p (tmp, -128, 0, 3))
{
notethat ("LDSTiiFP: dpregs = [ FP - uimm7m4 ]\n");
tmp = unary (Expr_Op_Type_NEG, tmp);
$$ = LDSTIIFP (tmp, &$1, 0);
}
else if (in_range_p (tmp, -131072, 131071, 3))
{
notethat ("LDSTidxI: dpregs = [ pregs + imm18m4 ]\n");
$$ = LDSTIDXI (&$4, &$1, 0, 0, ispreg ? 1 : 0, tmp);
}
else
return yyerror ("Displacement out of range");
}
| REG ASSIGN LBRACK REG post_op RBRACK
{
if (!IS_IREG ($4) && !IS_PREG ($4))
return yyerror ("Ireg or Preg expected in address");
else if (IS_IREG ($4) && !IS_DREG ($1))
return yyerror ("Dreg expected in destination operand");
else if (IS_PREG ($4) && !IS_DREG ($1) && !IS_PREG ($1)
&& ($4.regno != REG_SP || !IS_ALLREG ($1) || $5.x0 != 0))
return yyerror ("Dreg or Preg expected in destination operand");
if (IS_IREG ($4))
{
notethat ("dspLDST: dregs = [ iregs <post_op> ]\n");
$$ = DSPLDST (&$4, 0, &$1, $5.x0, 0);
}
else if (IS_DREG ($1))
{
notethat ("LDST: dregs = [ pregs <post_op> ]\n");
$$ = LDST (&$4, &$1, $5.x0, 0, 0, 0);
}
else if (IS_PREG ($1))
{
if (REG_SAME ($1, $4) && $5.x0 != 2)
return yyerror ("Pregs can't be same");
notethat ("LDST: pregs = [ pregs <post_op> ]\n");
$$ = LDST (&$4, &$1, $5.x0, 0, 1, 0);
}
else
{
notethat ("PushPopReg: allregs = [ SP ++ ]\n");
$$ = PUSHPOPREG (&$1, 0);
}
}
/* PushPopMultiple. */
| reg_with_predec ASSIGN LPAREN REG COLON expr COMMA REG COLON expr RPAREN
{
if ($1.regno != REG_SP)
yyerror ("Stack Pointer expected");
if ($4.regno == REG_R7
&& IN_RANGE ($6, 0, 7)
&& $8.regno == REG_P5
&& IN_RANGE ($10, 0, 5))
{
notethat ("PushPopMultiple: [ -- SP ] = (R7 : reglim , P5 : reglim )\n");
$$ = PUSHPOPMULTIPLE (imm5 ($6), imm5 ($10), 1, 1, 1);
}
else
return yyerror ("Bad register for PushPopMultiple");
}
| reg_with_predec ASSIGN LPAREN REG COLON expr RPAREN
{
if ($1.regno != REG_SP)
yyerror ("Stack Pointer expected");
if ($4.regno == REG_R7 && IN_RANGE ($6, 0, 7))
{
notethat ("PushPopMultiple: [ -- SP ] = (R7 : reglim )\n");
$$ = PUSHPOPMULTIPLE (imm5 ($6), 0, 1, 0, 1);
}
else if ($4.regno == REG_P5 && IN_RANGE ($6, 0, 6))
{
notethat ("PushPopMultiple: [ -- SP ] = (P5 : reglim )\n");
$$ = PUSHPOPMULTIPLE (0, imm5 ($6), 0, 1, 1);
}
else
return yyerror ("Bad register for PushPopMultiple");
}
| LPAREN REG COLON expr COMMA REG COLON expr RPAREN ASSIGN reg_with_postinc
{
if ($11.regno != REG_SP)
yyerror ("Stack Pointer expected");
if ($2.regno == REG_R7 && (IN_RANGE ($4, 0, 7))
&& $6.regno == REG_P5 && (IN_RANGE ($8, 0, 6)))
{
notethat ("PushPopMultiple: (R7 : reglim , P5 : reglim ) = [ SP ++ ]\n");
$$ = PUSHPOPMULTIPLE (imm5 ($4), imm5 ($8), 1, 1, 0);
}
else
return yyerror ("Bad register range for PushPopMultiple");
}
| LPAREN REG COLON expr RPAREN ASSIGN reg_with_postinc
{
if ($7.regno != REG_SP)
yyerror ("Stack Pointer expected");
if ($2.regno == REG_R7 && IN_RANGE ($4, 0, 7))
{
notethat ("PushPopMultiple: (R7 : reglim ) = [ SP ++ ]\n");
$$ = PUSHPOPMULTIPLE (imm5 ($4), 0, 1, 0, 0);
}
else if ($2.regno == REG_P5 && IN_RANGE ($4, 0, 6))
{
notethat ("PushPopMultiple: (P5 : reglim ) = [ SP ++ ]\n");
$$ = PUSHPOPMULTIPLE (0, imm5 ($4), 0, 1, 0);
}
else
return yyerror ("Bad register range for PushPopMultiple");
}
| reg_with_predec ASSIGN REG
{
if ($1.regno != REG_SP)
yyerror ("Stack Pointer expected");
if (IS_ALLREG ($3))
{
notethat ("PushPopReg: [ -- SP ] = allregs\n");
$$ = PUSHPOPREG (&$3, 1);
}
else
return yyerror ("Bad register for PushPopReg");
}
/* Linkage. */
| LINK expr
{
if (IS_URANGE (16, $2, 0, 4))
$$ = LINKAGE (0, uimm16s4 ($2));
else
return yyerror ("Bad constant for LINK");
}
| UNLINK
{
notethat ("linkage: UNLINK\n");
$$ = LINKAGE (1, 0);
}
/* LSETUP. */
| LSETUP LPAREN expr COMMA expr RPAREN REG
{
if (IS_PCREL4 ($3) && IS_LPPCREL10 ($5) && IS_CREG ($7))
{
notethat ("LoopSetup: LSETUP (pcrel4 , lppcrel10 ) counters\n");
$$ = LOOPSETUP ($3, &$7, 0, $5, 0);
}
else
return yyerror ("Bad register or values for LSETUP");
}
| LSETUP LPAREN expr COMMA expr RPAREN REG ASSIGN REG
{
if (IS_PCREL4 ($3) && IS_LPPCREL10 ($5)
&& IS_PREG ($9) && IS_CREG ($7))
{
notethat ("LoopSetup: LSETUP (pcrel4 , lppcrel10 ) counters = pregs\n");
$$ = LOOPSETUP ($3, &$7, 1, $5, &$9);
}
else
return yyerror ("Bad register or values for LSETUP");
}
| LSETUP LPAREN expr COMMA expr RPAREN REG ASSIGN REG GREATER_GREATER expr
{
if (IS_PCREL4 ($3) && IS_LPPCREL10 ($5)
&& IS_PREG ($9) && IS_CREG ($7)
&& EXPR_VALUE ($11) == 1)
{
notethat ("LoopSetup: LSETUP (pcrel4 , lppcrel10 ) counters = pregs >> 1\n");
$$ = LOOPSETUP ($3, &$7, 3, $5, &$9);
}
else
return yyerror ("Bad register or values for LSETUP");
}
/* LOOP. */
| LOOP expr REG
{
if (!IS_RELOC ($2))
return yyerror ("Invalid expression in loop statement");
if (!IS_CREG ($3))
return yyerror ("Invalid loop counter register");
$$ = bfin_gen_loop ($2, &$3, 0, 0);
}
| LOOP expr REG ASSIGN REG
{
if (IS_RELOC ($2) && IS_PREG ($5) && IS_CREG ($3))
{
notethat ("Loop: LOOP expr counters = pregs\n");
$$ = bfin_gen_loop ($2, &$3, 1, &$5);
}
else
return yyerror ("Bad register or values for LOOP");
}
| LOOP expr REG ASSIGN REG GREATER_GREATER expr
{
if (IS_RELOC ($2) && IS_PREG ($5) && IS_CREG ($3) && EXPR_VALUE ($7) == 1)
{
notethat ("Loop: LOOP expr counters = pregs >> 1\n");
$$ = bfin_gen_loop ($2, &$3, 3, &$5);
}
else
return yyerror ("Bad register or values for LOOP");
}
/* LOOP_BEGIN. */
| LOOP_BEGIN NUMBER
{
Expr_Node_Value val;
val.i_value = $2;
Expr_Node *tmp = Expr_Node_Create (Expr_Node_Constant, val, NULL, NULL);
bfin_loop_attempt_create_label (tmp, 1);
if (!IS_RELOC (tmp))
return yyerror ("Invalid expression in LOOP_BEGIN statement");
bfin_loop_beginend (tmp, 1);
$$ = 0;
}
| LOOP_BEGIN expr
{
if (!IS_RELOC ($2))
return yyerror ("Invalid expression in LOOP_BEGIN statement");
bfin_loop_beginend ($2, 1);
$$ = 0;
}
/* LOOP_END. */
| LOOP_END NUMBER
{
Expr_Node_Value val;
val.i_value = $2;
Expr_Node *tmp = Expr_Node_Create (Expr_Node_Constant, val, NULL, NULL);
bfin_loop_attempt_create_label (tmp, 1);
if (!IS_RELOC (tmp))
return yyerror ("Invalid expression in LOOP_END statement");
bfin_loop_beginend (tmp, 0);
$$ = 0;
}
| LOOP_END expr
{
if (!IS_RELOC ($2))
return yyerror ("Invalid expression in LOOP_END statement");
bfin_loop_beginend ($2, 0);
$$ = 0;
}
/* pseudoDEBUG. */
| ABORT
{
notethat ("psedoDEBUG: ABORT\n");
$$ = bfin_gen_pseudodbg (3, 3, 0);
}
| DBG
{
notethat ("pseudoDEBUG: DBG\n");
$$ = bfin_gen_pseudodbg (3, 7, 0);
}
| DBG REG_A
{
notethat ("pseudoDEBUG: DBG REG_A\n");
$$ = bfin_gen_pseudodbg (3, IS_A1 ($2), 0);
}
| DBG REG
{
notethat ("pseudoDEBUG: DBG allregs\n");
$$ = bfin_gen_pseudodbg (0, $2.regno & CODE_MASK, ($2.regno & CLASS_MASK) >> 4);
}
| DBGCMPLX LPAREN REG RPAREN
{
if (!IS_DREG ($3))
return yyerror ("Dregs expected");
notethat ("pseudoDEBUG: DBGCMPLX (dregs )\n");
$$ = bfin_gen_pseudodbg (3, 6, ($3.regno & CODE_MASK) >> 4);
}
| DBGHALT
{
notethat ("psedoDEBUG: DBGHALT\n");
$$ = bfin_gen_pseudodbg (3, 5, 0);
}
| HLT
{
notethat ("psedoDEBUG: HLT\n");
$$ = bfin_gen_pseudodbg (3, 4, 0);
}
| DBGA LPAREN HALF_REG COMMA expr RPAREN
{
notethat ("pseudodbg_assert: DBGA (regs_lo/hi , uimm16 )\n");
$$ = bfin_gen_pseudodbg_assert (IS_H ($3), &$3, uimm16 ($5));
}
| DBGAH LPAREN REG COMMA expr RPAREN
{
notethat ("pseudodbg_assert: DBGAH (regs , uimm16 )\n");
$$ = bfin_gen_pseudodbg_assert (3, &$3, uimm16 ($5));
}
| DBGAL LPAREN REG COMMA expr RPAREN
{
notethat ("psedodbg_assert: DBGAL (regs , uimm16 )\n");
$$ = bfin_gen_pseudodbg_assert (2, &$3, uimm16 ($5));
}
| OUTC expr
{
if (!IS_UIMM ($2, 8))
return yyerror ("Constant out of range");
notethat ("psedodbg_assert: OUTC uimm8\n");
$$ = bfin_gen_pseudochr (uimm8 ($2));
}
| OUTC REG
{
if (!IS_DREG ($2))
return yyerror ("Dregs expected");
notethat ("psedodbg_assert: OUTC dreg\n");
$$ = bfin_gen_pseudodbg (2, $2.regno & CODE_MASK, 0);
}
;
/* AUX RULES. */
/* Register rules. */
REG_A: REG_A_DOUBLE_ZERO
{
$$ = $1;
}
| REG_A_DOUBLE_ONE
{
$$ = $1;
}
;
/* Modifiers. */
opt_mode:
{
$$.MM = 0;
$$.mod = 0;
}
| LPAREN M COMMA MMOD RPAREN
{
$$.MM = 1;
$$.mod = $4;
}
| LPAREN MMOD COMMA M RPAREN
{
$$.MM = 1;
$$.mod = $2;
}
| LPAREN MMOD RPAREN
{
$$.MM = 0;
$$.mod = $2;
}
| LPAREN M RPAREN
{
$$.MM = 1;
$$.mod = 0;
}
;
asr_asl: LPAREN ASL RPAREN
{
$$.r0 = 1;
}
| LPAREN ASR RPAREN
{
$$.r0 = 0;
}
;
sco:
{
$$.s0 = 0;
$$.x0 = 0;
}
| S
{
$$.s0 = 1;
$$.x0 = 0;
}
| CO
{
$$.s0 = 0;
$$.x0 = 1;
}
| SCO
{
$$.s0 = 1;
$$.x0 = 1;
}
;
asr_asl_0:
ASL
{
$$.r0 = 1;
}
| ASR
{
$$.r0 = 0;
}
;
amod0:
{
$$.s0 = 0;
$$.x0 = 0;
}
| LPAREN sco RPAREN
{
$$.s0 = $2.s0;
$$.x0 = $2.x0;
}
;
amod1:
{
$$.s0 = 0;
$$.x0 = 0;
$$.aop = 0;
}
| LPAREN NS RPAREN
{
$$.s0 = 0;
$$.x0 = 0;
$$.aop = 1;
}
| LPAREN S RPAREN
{
$$.s0 = 1;
$$.x0 = 0;
$$.aop = 1;
}
;
amod2:
{
$$.r0 = 0;
$$.s0 = 0;
$$.x0 = 0;
}
| LPAREN asr_asl_0 RPAREN
{
$$.r0 = 2 + $2.r0;
$$.s0 = 0;
$$.x0 = 0;
}
| LPAREN sco RPAREN
{
$$.r0 = 0;
$$.s0 = $2.s0;
$$.x0 = $2.x0;
}
| LPAREN asr_asl_0 COMMA sco RPAREN
{
$$.r0 = 2 + $2.r0;
$$.s0 = $4.s0;
$$.x0 = $4.x0;
}
| LPAREN sco COMMA asr_asl_0 RPAREN
{
$$.r0 = 2 + $4.r0;
$$.s0 = $2.s0;
$$.x0 = $2.x0;
}
;
xpmod:
{
$$.r0 = 0;
}
| LPAREN Z RPAREN
{
$$.r0 = 0;
}
| LPAREN X RPAREN
{
$$.r0 = 1;
}
;
xpmod1:
{
$$.r0 = 0;
}
| LPAREN X RPAREN
{
$$.r0 = 0;
}
| LPAREN Z RPAREN
{
$$.r0 = 1;
}
;
vsmod:
{
$$.r0 = 0;
$$.s0 = 0;
$$.aop = 0;
}
| LPAREN NS RPAREN
{
$$.r0 = 0;
$$.s0 = 0;
$$.aop = 3;
}
| LPAREN S RPAREN
{
$$.r0 = 0;
$$.s0 = 1;
$$.aop = 3;
}
| LPAREN V RPAREN
{
$$.r0 = 1;
$$.s0 = 0;
$$.aop = 3;
}
| LPAREN V COMMA S RPAREN
{
$$.r0 = 1;
$$.s0 = 1;
}
| LPAREN S COMMA V RPAREN
{
$$.r0 = 1;
$$.s0 = 1;
}
;
vmod:
{
$$.r0 = 0;
}
| LPAREN V RPAREN
{
$$.r0 = 1;
}
;
smod:
{
$$.s0 = 0;
}
| LPAREN S RPAREN
{
$$.s0 = 1;
}
;
searchmod:
GE
{
$$.r0 = 1;
}
| GT
{
$$.r0 = 0;
}
| LE
{
$$.r0 = 3;
}
| LT
{
$$.r0 = 2;
}
;
aligndir:
{
$$.r0 = 0;
}
| LPAREN R RPAREN
{
$$.r0 = 1;
}
;
byteop_mod:
LPAREN R RPAREN
{
$$.r0 = 0;
$$.s0 = 1;
}
| LPAREN MMOD RPAREN
{
if ($2 != M_T)
return yyerror ("Bad modifier");
$$.r0 = 1;
$$.s0 = 0;
}
| LPAREN MMOD COMMA R RPAREN
{
if ($2 != M_T)
return yyerror ("Bad modifier");
$$.r0 = 1;
$$.s0 = 1;
}
| LPAREN R COMMA MMOD RPAREN
{
if ($4 != M_T)
return yyerror ("Bad modifier");
$$.r0 = 1;
$$.s0 = 1;
}
;
c_align:
ALIGN8
{
$$.r0 = 0;
}
| ALIGN16
{
$$.r0 = 1;
}
| ALIGN24
{
$$.r0 = 2;
}
;
w32_or_nothing:
{
$$.r0 = 0;
}
| LPAREN MMOD RPAREN
{
if ($2 == M_W32)
$$.r0 = 1;
else
return yyerror ("Only (W32) allowed");
}
;
iu_or_nothing:
{
$$.r0 = 1;
}
| LPAREN MMOD RPAREN
{
if ($2 == M_IU)
$$.r0 = 3;
else
return yyerror ("(IU) expected");
}
;
reg_with_predec: LBRACK _MINUS_MINUS REG RBRACK
{
$$ = $3;
}
;
reg_with_postinc: LBRACK REG _PLUS_PLUS RBRACK
{
$$ = $2;
}
;
/* Operators. */
min_max:
MIN
{
$$.r0 = 1;
}
| MAX
{
$$.r0 = 0;
}
;
op_bar_op:
_PLUS_BAR_PLUS
{
$$.r0 = 0;
}
| _PLUS_BAR_MINUS
{
$$.r0 = 1;
}
| _MINUS_BAR_PLUS
{
$$.r0 = 2;
}
| _MINUS_BAR_MINUS
{
$$.r0 = 3;
}
;
plus_minus:
PLUS
{
$$.r0 = 0;
}
| MINUS
{
$$.r0 = 1;
}
;
rnd_op:
LPAREN RNDH RPAREN
{
$$.r0 = 1; /* HL. */
$$.s0 = 0; /* s. */
$$.x0 = 0; /* x. */
$$.aop = 0; /* aop. */
}
| LPAREN TH RPAREN
{
$$.r0 = 1; /* HL. */
$$.s0 = 0; /* s. */
$$.x0 = 0; /* x. */
$$.aop = 1; /* aop. */
}
| LPAREN RNDL RPAREN
{
$$.r0 = 0; /* HL. */
$$.s0 = 0; /* s. */
$$.x0 = 0; /* x. */
$$.aop = 0; /* aop. */
}
| LPAREN TL RPAREN
{
$$.r0 = 0; /* HL. */
$$.s0 = 0; /* s. */
$$.x0 = 0; /* x. */
$$.aop = 1;
}
| LPAREN RNDH COMMA R RPAREN
{
$$.r0 = 1; /* HL. */
$$.s0 = 1; /* s. */
$$.x0 = 0; /* x. */
$$.aop = 0; /* aop. */
}
| LPAREN TH COMMA R RPAREN
{
$$.r0 = 1; /* HL. */
$$.s0 = 1; /* s. */
$$.x0 = 0; /* x. */
$$.aop = 1; /* aop. */
}
| LPAREN RNDL COMMA R RPAREN
{
$$.r0 = 0; /* HL. */
$$.s0 = 1; /* s. */
$$.x0 = 0; /* x. */
$$.aop = 0; /* aop. */
}
| LPAREN TL COMMA R RPAREN
{
$$.r0 = 0; /* HL. */
$$.s0 = 1; /* s. */
$$.x0 = 0; /* x. */
$$.aop = 1; /* aop. */
}
;
b3_op:
LPAREN LO RPAREN
{
$$.s0 = 0; /* s. */
$$.x0 = 0; /* HL. */
}
| LPAREN HI RPAREN
{
$$.s0 = 0; /* s. */
$$.x0 = 1; /* HL. */
}
| LPAREN LO COMMA R RPAREN
{
$$.s0 = 1; /* s. */
$$.x0 = 0; /* HL. */
}
| LPAREN HI COMMA R RPAREN
{
$$.s0 = 1; /* s. */
$$.x0 = 1; /* HL. */
}
;
post_op:
{
$$.x0 = 2;
}
| _PLUS_PLUS
{
$$.x0 = 0;
}
| _MINUS_MINUS
{
$$.x0 = 1;
}
;
/* Assignments, Macfuncs. */
a_assign:
REG_A ASSIGN
{
$$ = $1;
}
;
a_minusassign:
REG_A _MINUS_ASSIGN
{
$$ = $1;
}
;
a_plusassign:
REG_A _PLUS_ASSIGN
{
$$ = $1;
}
;
assign_macfunc:
REG ASSIGN REG_A
{
if (IS_A1 ($3) && IS_EVEN ($1))
return yyerror ("Cannot move A1 to even register");
else if (!IS_A1 ($3) && !IS_EVEN ($1))
return yyerror ("Cannot move A0 to odd register");
$$.w = 1;
$$.P = 1;
$$.n = IS_A1 ($3);
$$.op = 3;
$$.dst = $1;
$$.s0.regno = 0;
$$.s1.regno = 0;
}
| a_macfunc
{
$$ = $1;
$$.w = 0; $$.P = 0;
$$.dst.regno = 0;
}
| REG ASSIGN LPAREN a_macfunc RPAREN
{
if ($4.n && IS_EVEN ($1))
return yyerror ("Cannot move A1 to even register");
else if (!$4.n && !IS_EVEN ($1))
return yyerror ("Cannot move A0 to odd register");
$$ = $4;
$$.w = 1;
$$.P = 1;
$$.dst = $1;
}
| HALF_REG ASSIGN LPAREN a_macfunc RPAREN
{
if ($4.n && !IS_H ($1))
return yyerror ("Cannot move A1 to low half of register");
else if (!$4.n && IS_H ($1))
return yyerror ("Cannot move A0 to high half of register");
$$ = $4;
$$.w = 1;
$$.P = 0;
$$.dst = $1;
}
| HALF_REG ASSIGN REG_A
{
if (IS_A1 ($3) && !IS_H ($1))
return yyerror ("Cannot move A1 to low half of register");
else if (!IS_A1 ($3) && IS_H ($1))
return yyerror ("Cannot move A0 to high half of register");
$$.w = 1;
$$.P = 0;
$$.n = IS_A1 ($3);
$$.op = 3;
$$.dst = $1;
$$.s0.regno = 0;
$$.s1.regno = 0;
}
;
a_macfunc:
a_assign multiply_halfregs
{
$$.n = IS_A1 ($1);
$$.op = 0;
$$.s0 = $2.s0;
$$.s1 = $2.s1;
}
| a_plusassign multiply_halfregs
{
$$.n = IS_A1 ($1);
$$.op = 1;
$$.s0 = $2.s0;
$$.s1 = $2.s1;
}
| a_minusassign multiply_halfregs
{
$$.n = IS_A1 ($1);
$$.op = 2;
$$.s0 = $2.s0;
$$.s1 = $2.s1;
}
;
multiply_halfregs:
HALF_REG STAR HALF_REG
{
if (IS_DREG ($1) && IS_DREG ($3))
{
$$.s0 = $1;
$$.s1 = $3;
}
else
return yyerror ("Dregs expected");
}
;
cc_op:
ASSIGN
{
$$.r0 = 0;
}
| _BAR_ASSIGN
{
$$.r0 = 1;
}
| _AMPERSAND_ASSIGN
{
$$.r0 = 2;
}
| _CARET_ASSIGN
{
$$.r0 = 3;
}
;
ccstat:
CCREG cc_op STATUS_REG
{
$$.r0 = $3.regno;
$$.x0 = $2.r0;
$$.s0 = 0;
}
| CCREG cc_op V
{
$$.r0 = 0x18;
$$.x0 = $2.r0;
$$.s0 = 0;
}
| STATUS_REG cc_op CCREG
{
$$.r0 = $1.regno;
$$.x0 = $2.r0;
$$.s0 = 1;
}
| V cc_op CCREG
{
$$.r0 = 0x18;
$$.x0 = $2.r0;
$$.s0 = 1;
}
;
/* Expressions and Symbols. */
symbol: SYMBOL
{
Expr_Node_Value val;
val.s_value = S_GET_NAME($1);
$$ = Expr_Node_Create (Expr_Node_Reloc, val, NULL, NULL);
}
;
any_gotrel:
GOT
{ $$ = BFD_RELOC_BFIN_GOT; }
| GOT17M4
{ $$ = BFD_RELOC_BFIN_GOT17M4; }
| FUNCDESC_GOT17M4
{ $$ = BFD_RELOC_BFIN_FUNCDESC_GOT17M4; }
;
got: symbol AT any_gotrel
{
Expr_Node_Value val;
val.i_value = $3;
$$ = Expr_Node_Create (Expr_Node_GOT_Reloc, val, $1, NULL);
}
;
got_or_expr: got
{
$$ = $1;
}
| expr
{
$$ = $1;
}
;
pltpc :
symbol AT PLTPC
{
$$ = $1;
}
;
eterm: NUMBER
{
Expr_Node_Value val;
val.i_value = $1;
$$ = Expr_Node_Create (Expr_Node_Constant, val, NULL, NULL);
}
| symbol
{
$$ = $1;
}
| LPAREN expr_1 RPAREN
{
$$ = $2;
}
| TILDA expr_1
{
$$ = unary (Expr_Op_Type_COMP, $2);
}
| MINUS expr_1 %prec TILDA
{
$$ = unary (Expr_Op_Type_NEG, $2);
}
;
expr: expr_1
{
$$ = $1;
}
;
expr_1: expr_1 STAR expr_1
{
$$ = binary (Expr_Op_Type_Mult, $1, $3);
}
| expr_1 SLASH expr_1
{
$$ = binary (Expr_Op_Type_Div, $1, $3);
}
| expr_1 PERCENT expr_1
{
$$ = binary (Expr_Op_Type_Mod, $1, $3);
}
| expr_1 PLUS expr_1
{
$$ = binary (Expr_Op_Type_Add, $1, $3);
}
| expr_1 MINUS expr_1
{
$$ = binary (Expr_Op_Type_Sub, $1, $3);
}
| expr_1 LESS_LESS expr_1
{
$$ = binary (Expr_Op_Type_Lshift, $1, $3);
}
| expr_1 GREATER_GREATER expr_1
{
$$ = binary (Expr_Op_Type_Rshift, $1, $3);
}
| expr_1 AMPERSAND expr_1
{
$$ = binary (Expr_Op_Type_BAND, $1, $3);
}
| expr_1 CARET expr_1
{
$$ = binary (Expr_Op_Type_LOR, $1, $3);
}
| expr_1 BAR expr_1
{
$$ = binary (Expr_Op_Type_BOR, $1, $3);
}
| eterm
{
$$ = $1;
}
;
%%
EXPR_T
mkexpr (int x, SYMBOL_T s)
{
EXPR_T e = (EXPR_T) ALLOCATE (sizeof (struct expression_cell));
e->value = x;
EXPR_SYMBOL(e) = s;
return e;
}
static int
value_match (Expr_Node *exp, int sz, int sign, int mul, int issigned)
{
int umax = (1 << sz) - 1;
int min = -1 << (sz - 1);
int max = (1 << (sz - 1)) - 1;
int v = (EXPR_VALUE (exp)) & 0xffffffff;
if ((v % mul) != 0)
{
error ("%s:%d: Value Error -- Must align to %d\n", __FILE__, __LINE__, mul);
return 0;
}
v /= mul;
if (sign)
v = -v;
if (issigned)
{
if (v >= min && v <= max) return 1;
#ifdef DEBUG
fprintf(stderr, "signed value %lx out of range\n", v * mul);
#endif
return 0;
}
if (v <= umax && v >= 0)
return 1;
#ifdef DEBUG
fprintf(stderr, "unsigned value %lx out of range\n", v * mul);
#endif
return 0;
}
/* Return the expression structure that allows symbol operations.
If the left and right children are constants, do the operation. */
static Expr_Node *
binary (Expr_Op_Type op, Expr_Node *x, Expr_Node *y)
{
Expr_Node_Value val;
if (x->type == Expr_Node_Constant && y->type == Expr_Node_Constant)
{
switch (op)
{
case Expr_Op_Type_Add:
x->value.i_value += y->value.i_value;
break;
case Expr_Op_Type_Sub:
x->value.i_value -= y->value.i_value;
break;
case Expr_Op_Type_Mult:
x->value.i_value *= y->value.i_value;
break;
case Expr_Op_Type_Div:
if (y->value.i_value == 0)
error ("Illegal Expression: Division by zero.");
else
x->value.i_value /= y->value.i_value;
break;
case Expr_Op_Type_Mod:
x->value.i_value %= y->value.i_value;
break;
case Expr_Op_Type_Lshift:
x->value.i_value <<= y->value.i_value;
break;
case Expr_Op_Type_Rshift:
x->value.i_value >>= y->value.i_value;
break;
case Expr_Op_Type_BAND:
x->value.i_value &= y->value.i_value;
break;
case Expr_Op_Type_BOR:
x->value.i_value |= y->value.i_value;
break;
case Expr_Op_Type_BXOR:
x->value.i_value ^= y->value.i_value;
break;
case Expr_Op_Type_LAND:
x->value.i_value = x->value.i_value && y->value.i_value;
break;
case Expr_Op_Type_LOR:
x->value.i_value = x->value.i_value || y->value.i_value;
break;
default:
error ("%s:%d: Internal assembler error\n", __FILE__, __LINE__);
}
return x;
}
/* Canonicalize order to EXPR OP CONSTANT. */
if (x->type == Expr_Node_Constant)
{
Expr_Node *t = x;
x = y;
y = t;
}
/* Canonicalize subtraction of const to addition of negated const. */
if (op == Expr_Op_Type_Sub && y->type == Expr_Node_Constant)
{
op = Expr_Op_Type_Add;
y->value.i_value = -y->value.i_value;
}
if (y->type == Expr_Node_Constant && x->type == Expr_Node_Binop
&& x->Right_Child->type == Expr_Node_Constant)
{
if (op == x->value.op_value && x->value.op_value == Expr_Op_Type_Add)
{
x->Right_Child->value.i_value += y->value.i_value;
return x;
}
}
/* Create a new expression structure. */
val.op_value = op;
return Expr_Node_Create (Expr_Node_Binop, val, x, y);
}
static Expr_Node *
unary (Expr_Op_Type op, Expr_Node *x)
{
if (x->type == Expr_Node_Constant)
{
switch (op)
{
case Expr_Op_Type_NEG:
x->value.i_value = -x->value.i_value;
break;
case Expr_Op_Type_COMP:
x->value.i_value = ~x->value.i_value;
break;
default:
error ("%s:%d: Internal assembler error\n", __FILE__, __LINE__);
}
return x;
}
else
{
/* Create a new expression structure. */
Expr_Node_Value val;
val.op_value = op;
return Expr_Node_Create (Expr_Node_Unop, val, x, NULL);
}
}
int debug_codeselection = 0;
static void
notethat (char *format, ...)
{
va_list ap;
va_start (ap, format);
if (debug_codeselection)
{
vfprintf (errorf, format, ap);
}
va_end (ap);
}
#ifdef TEST
main (int argc, char **argv)
{
yyparse();
}
#endif