%{
/*
* Copyright(c) 2019-2023 rev.ng Labs Srl. All Rights Reserved.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, see .
*/
#include "idef-parser.h"
#include "parser-helpers.h"
#include "idef-parser.tab.h"
#include "idef-parser.yy.h"
/* Uncomment this to disable yyasserts */
/* #define NDEBUG */
#define ERR_LINE_CONTEXT 40
%}
%lex-param {void *scanner}
%parse-param {void *scanner}
%parse-param {Context *c}
%define parse.error verbose
%define parse.lac full
%define api.pure full
%locations
%union {
GString *string;
HexValue rvalue;
HexSat sat;
HexCast cast;
HexExtract extract;
HexMpy mpy;
HexSignedness signedness;
int index;
}
/* Tokens */
%start input
%expect 1
%token IN INAME VAR
%token ABS CROUND ROUND CIRCADD COUNTONES INC DEC ANDA ORA XORA PLUSPLUS ASL
%token ASR LSR EQ NEQ LTE GTE MIN MAX ANDL FOR ICIRC IF MUN FSCR FCHK SXT
%token ZXT CONSTEXT LOCNT BREV SIGN LOAD STORE PC LPCFG
%token LOAD_CANCEL STORE_CANCEL CANCEL IDENTITY ROTL INSBITS SETBITS EXTRANGE
%token CAST4_8U FAIL CARRY_FROM_ADD ADDSAT64 LSBNEW
%token TYPE_SIZE_T TYPE_INT TYPE_SIGNED TYPE_UNSIGNED TYPE_LONG
%token REG IMM PRED
%token ELSE
%token MPY
%token SAT
%token CAST DEPOSIT SETHALF
%token EXTRACT
%type INAME
%type rvalue lvalue VAR assign_statement var var_decl var_type
%type FAIL
%type TYPE_SIGNED TYPE_UNSIGNED TYPE_INT TYPE_LONG TYPE_SIZE_T
%type if_stmt IF
%type SIGN
/* Operator Precedences */
%left MIN MAX
%left '('
%left ','
%left '='
%right CIRCADD
%right INC DEC ANDA ORA XORA
%left '?' ':'
%left ANDL
%left '|'
%left '^' ANDOR
%left '&'
%left EQ NEQ
%left '<' '>' LTE GTE
%left ASL ASR LSR
%right ABS
%left '-' '+'
%left '*' '/' '%' MPY
%right '~' '!'
%left '['
%right CAST
%right LOCNT BREV
/* Bison Grammar */
%%
/* Input file containing the description of each hexagon instruction */
input : instructions
{
/* Suppress warning about unused yynerrs */
(void) yynerrs;
YYACCEPT;
}
;
instructions : instruction instructions
| %empty
;
instruction : INAME
{
gen_inst(c, $1);
}
arguments
{
EMIT_SIG(c, ")");
EMIT_HEAD(c, "{\n");
}
code
{
gen_inst_code(c, &@1);
}
| error /* Recover gracefully after instruction compilation error */
{
free_instruction(c);
}
;
arguments : '(' ')'
| '(' argument_list ')';
argument_list : argument_decl ',' argument_list
| argument_decl
;
var : VAR
{
track_string(c, $1.var.name);
$$ = $1;
}
;
/*
* Here the integer types are defined from valid combinations of
* `signed`, `unsigned`, `int`, and `long` tokens. The `signed`
* and `unsigned` tokens are here assumed to always be placed
* first in the type declaration, which is not the case in
* normal C. Similarly, `int` is assumed to always be placed
* last in the type.
*/
type_int : TYPE_INT
| TYPE_SIGNED
| TYPE_SIGNED TYPE_INT;
type_uint : TYPE_UNSIGNED
| TYPE_UNSIGNED TYPE_INT;
type_ulonglong : TYPE_UNSIGNED TYPE_LONG TYPE_LONG
| TYPE_UNSIGNED TYPE_LONG TYPE_LONG TYPE_INT;
/*
* Here the various valid int types defined above specify
* their `signedness` and `bit_width`. The LP64 convention
* is assumed where longs are 64-bit, long longs are then
* assumed to also be 64-bit.
*/
var_type : TYPE_SIZE_T
{
yyassert(c, &@1, $1.bit_width <= 64,
"Variables with size > 64-bit are not supported!");
$$ = $1;
}
| type_int
{
$$.signedness = SIGNED;
$$.bit_width = 32;
}
| type_uint
{
$$.signedness = UNSIGNED;
$$.bit_width = 32;
}
| type_ulonglong
{
$$.signedness = UNSIGNED;
$$.bit_width = 64;
}
;
/* Rule to capture declarations of VARs */
var_decl : var_type IMM
{
/*
* Rule to capture "int i;" declarations since "i" is special
* and assumed to be always be IMM. Moreover, "i" is only
* assumed to be used in for-loops.
*
* Therefore we want to NOP these declarations.
*/
yyassert(c, &@2, $2.imm.type == I,
"Variable declaration with immedaties only allowed"
" for the loop induction variable \"i\"");
$$ = $2;
}
| var_type var
{
/*
* Allocate new variable, this checks that it hasn't already
* been declared.
*/
gen_varid_allocate(c, &@1, &$2, $1.bit_width, $1.signedness);
/* Copy var for variable name */
$$ = $2;
/* Copy type info from var_type */
$$.signedness = $1.signedness;
$$.bit_width = $1.bit_width;
}
;
/* Return the modified registers list */
code : '{' statements '}'
{
c->inst.code_begin = c->input_buffer + @2.first_column - 1;
c->inst.code_end = c->input_buffer + @2.last_column - 1;
}
| '{'
{
/* Nop */
}
'}'
;
argument_decl : REG
{
emit_arg(c, &@1, &$1);
/* Enqueue register into initialization list */
g_array_append_val(c->inst.init_list, $1);
}
| PRED
{
emit_arg(c, &@1, &$1);
/* Enqueue predicate into initialization list */
g_array_append_val(c->inst.init_list, $1);
}
| IN REG
{
emit_arg(c, &@2, &$2);
}
| IN PRED
{
emit_arg(c, &@2, &$2);
}
| IMM
{
EMIT_SIG(c, ", int %ciV", $1.imm.id);
}
;
code_block : '{' statements '}'
| '{' '}'
;
/* A list of one or more statements */
statements : statements statement
| statement
;
/* Statements can be assignment (rvalue ';'), control or memory statements */
statement : control_statement
| var_decl ';'
| rvalue ';'
| code_block
| ';'
;
assign_statement : lvalue '=' rvalue
{
@1.last_column = @3.last_column;
gen_assign(c, &@1, &$1, &$3);
$$ = $1;
}
| var_decl '=' rvalue
{
@1.last_column = @3.last_column;
gen_assign(c, &@1, &$1, &$3);
$$ = $1;
}
| lvalue INC rvalue
{
@1.last_column = @3.last_column;
HexValue tmp = gen_bin_op(c, &@1, ADD_OP, &$1, &$3);
gen_assign(c, &@1, &$1, &tmp);
$$ = $1;
}
| lvalue DEC rvalue
{
@1.last_column = @3.last_column;
HexValue tmp = gen_bin_op(c, &@1, SUB_OP, &$1, &$3);
gen_assign(c, &@1, &$1, &tmp);
$$ = $1;
}
| lvalue ANDA rvalue
{
@1.last_column = @3.last_column;
HexValue tmp = gen_bin_op(c, &@1, ANDB_OP, &$1, &$3);
gen_assign(c, &@1, &$1, &tmp);
$$ = $1;
}
| lvalue ORA rvalue
{
@1.last_column = @3.last_column;
HexValue tmp = gen_bin_op(c, &@1, ORB_OP, &$1, &$3);
gen_assign(c, &@1, &$1, &tmp);
$$ = $1;
}
| lvalue XORA rvalue
{
@1.last_column = @3.last_column;
HexValue tmp = gen_bin_op(c, &@1, XORB_OP, &$1, &$3);
gen_assign(c, &@1, &$1, &tmp);
$$ = $1;
}
| PRED '=' rvalue
{
@1.last_column = @3.last_column;
gen_pred_assign(c, &@1, &$1, &$3);
}
| IMM '=' rvalue
{
@1.last_column = @3.last_column;
yyassert(c, &@1, $3.type == IMMEDIATE,
"Cannot assign non-immediate to immediate!");
yyassert(c, &@1, $1.imm.type == VARIABLE,
"Cannot assign to non-variable!");
/* Assign to the function argument */
OUT(c, &@1, &$1, " = ", &$3, ";\n");
$$ = $1;
}
| LOAD '(' IMM ',' IMM ',' SIGN ',' var ',' lvalue ')'
{
@1.last_column = @12.last_column;
yyassert(c, &@1, !is_inside_ternary(c),
"Assignment side-effect not modeled!");
yyassert(c, &@1, $3.imm.value == 1,
"LOAD of arrays not supported!");
gen_load(c, &@1, &$5, $7, &$9, &$11);
}
| STORE '(' IMM ',' IMM ',' var ',' rvalue ')'
/* Store primitive */
{
@1.last_column = @10.last_column;
yyassert(c, &@1, !is_inside_ternary(c),
"Assignment side-effect not modeled!");
yyassert(c, &@1, $3.imm.value == 1,
"STORE of arrays not supported!");
gen_store(c, &@1, &$5, &$7, &$9);
}
| LPCFG '=' rvalue
{
@1.last_column = @3.last_column;
yyassert(c, &@1, !is_inside_ternary(c),
"Assignment side-effect not modeled!");
$3 = gen_rvalue_truncate(c, &@1, &$3);
$3 = rvalue_materialize(c, &@1, &$3);
OUT(c, &@1, "gen_set_usr_field(ctx, USR_LPCFG, ", &$3, ");\n");
}
| DEPOSIT '(' rvalue ',' rvalue ',' rvalue ')'
{
@1.last_column = @8.last_column;
yyassert(c, &@1, !is_inside_ternary(c),
"Assignment side-effect not modeled!");
gen_deposit_op(c, &@1, &$5, &$7, &$3, &$1);
}
| SETHALF '(' rvalue ',' lvalue ',' rvalue ')'
{
@1.last_column = @8.last_column;
yyassert(c, &@1, !is_inside_ternary(c),
"Assignment side-effect not modeled!");
gen_sethalf(c, &@1, &$1, &$3, &$5, &$7);
}
| SETBITS '(' rvalue ',' rvalue ',' rvalue ',' rvalue ')'
{
@1.last_column = @10.last_column;
yyassert(c, &@1, !is_inside_ternary(c),
"Assignment side-effect not modeled!");
gen_setbits(c, &@1, &$3, &$5, &$7, &$9);
}
| INSBITS '(' lvalue ',' rvalue ',' rvalue ',' rvalue ')'
{
@1.last_column = @10.last_column;
yyassert(c, &@1, !is_inside_ternary(c),
"Assignment side-effect not modeled!");
gen_rdeposit_op(c, &@1, &$3, &$9, &$7, &$5);
}
| IDENTITY '(' rvalue ')'
{
@1.last_column = @4.last_column;
$$ = $3;
}
;
control_statement : frame_check
| cancel_statement
| if_statement
| for_statement
;
frame_check : FCHK '(' rvalue ',' rvalue ')' ';'
;
cancel_statement : LOAD_CANCEL
{
gen_load_cancel(c, &@1);
}
| STORE_CANCEL
{
gen_cancel(c, &@1);
}
| CANCEL
;
if_statement : if_stmt
{
/* Fix else label */
OUT(c, &@1, "gen_set_label(if_label_", &$1, ");\n");
}
| if_stmt ELSE
{
@1.last_column = @2.last_column;
$2 = gen_if_else(c, &@1, $1);
}
statement
{
OUT(c, &@1, "gen_set_label(if_label_", &$2, ");\n");
}
;
for_statement : FOR '(' IMM '=' IMM ';' IMM '<' IMM ';' IMM PLUSPLUS ')'
{
yyassert(c, &@3,
$3.imm.type == I &&
$7.imm.type == I &&
$11.imm.type == I,
"Loop induction variable must be \"i\"");
@1.last_column = @13.last_column;
OUT(c, &@1, "for (int ", &$3, " = ", &$5, "; ",
&$7, " < ", &$9);
OUT(c, &@1, "; ", &$11, "++) {\n");
}
code_block
{
OUT(c, &@1, "}\n");
}
;
if_stmt : IF '(' rvalue ')'
{
@1.last_column = @3.last_column;
$1 = gen_if_cond(c, &@1, &$3);
}
statement
{
$$ = $1;
}
;
rvalue : FAIL
{
yyassert(c, &@1, false, "Encountered a FAIL token as rvalue.\n");
}
| assign_statement
| REG
{
$$ = $1;
}
| IMM
{
$$ = $1;
}
| PRED
{
$$ = gen_rvalue_pred(c, &@1, &$1);
}
| PC
{
/* Read PC from the CR */
HexValue rvalue;
memset(&rvalue, 0, sizeof(HexValue));
rvalue.type = IMMEDIATE;
rvalue.imm.type = IMM_PC;
rvalue.bit_width = 32;
rvalue.signedness = UNSIGNED;
$$ = rvalue;
}
| CONSTEXT
{
HexValue rvalue;
memset(&rvalue, 0, sizeof(HexValue));
rvalue.type = IMMEDIATE;
rvalue.imm.type = IMM_CONSTEXT;
rvalue.signedness = UNSIGNED;
rvalue.is_dotnew = false;
$$ = rvalue;
}
| var
{
$$ = gen_rvalue_var(c, &@1, &$1);
}
| MPY '(' rvalue ',' rvalue ')'
{
@1.last_column = @6.last_column;
$$ = gen_rvalue_mpy(c, &@1, &$1, &$3, &$5);
}
| rvalue '+' rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, ADD_OP, &$1, &$3);
}
| rvalue '-' rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, SUB_OP, &$1, &$3);
}
| rvalue '*' rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, MUL_OP, &$1, &$3);
}
| rvalue ASL rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, ASL_OP, &$1, &$3);
}
| rvalue ASR rvalue
{
@1.last_column = @3.last_column;
assert_signedness(c, &@1, $1.signedness);
if ($1.signedness == UNSIGNED) {
$$ = gen_bin_op(c, &@1, LSR_OP, &$1, &$3);
} else if ($1.signedness == SIGNED) {
$$ = gen_bin_op(c, &@1, ASR_OP, &$1, &$3);
}
}
| rvalue LSR rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, LSR_OP, &$1, &$3);
}
| rvalue '&' rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, ANDB_OP, &$1, &$3);
}
| rvalue '|' rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, ORB_OP, &$1, &$3);
}
| rvalue '^' rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, XORB_OP, &$1, &$3);
}
| rvalue ANDL rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, ANDL_OP, &$1, &$3);
}
| MIN '(' rvalue ',' rvalue ')'
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, MINI_OP, &$3, &$5);
}
| MAX '(' rvalue ',' rvalue ')'
{
@1.last_column = @3.last_column;
$$ = gen_bin_op(c, &@1, MAXI_OP, &$3, &$5);
}
| '~' rvalue
{
@1.last_column = @2.last_column;
$$ = gen_rvalue_not(c, &@1, &$2);
}
| '!' rvalue
{
@1.last_column = @2.last_column;
$$ = gen_rvalue_notl(c, &@1, &$2);
}
| SAT '(' IMM ',' rvalue ')'
{
@1.last_column = @6.last_column;
$$ = gen_rvalue_sat(c, &@1, &$1, &$3, &$5);
}
| CAST rvalue
{
@1.last_column = @2.last_column;
/* Assign target signedness */
$2.signedness = $1.signedness;
$$ = gen_cast_op(c, &@1, &$2, $1.bit_width, $1.signedness);
}
| rvalue EQ rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_cmp(c, &@1, TCG_COND_EQ, &$1, &$3);
}
| rvalue NEQ rvalue
{
@1.last_column = @3.last_column;
$$ = gen_bin_cmp(c, &@1, TCG_COND_NE, &$1, &$3);
}
| rvalue '<' rvalue
{
@1.last_column = @3.last_column;
assert_signedness(c, &@1, $1.signedness);
assert_signedness(c, &@1, $3.signedness);
if ($1.signedness == UNSIGNED || $3.signedness == UNSIGNED) {
$$ = gen_bin_cmp(c, &@1, TCG_COND_LTU, &$1, &$3);
} else {
$$ = gen_bin_cmp(c, &@1, TCG_COND_LT, &$1, &$3);
}
}
| rvalue '>' rvalue
{
@1.last_column = @3.last_column;
assert_signedness(c, &@1, $1.signedness);
assert_signedness(c, &@1, $3.signedness);
if ($1.signedness == UNSIGNED || $3.signedness == UNSIGNED) {
$$ = gen_bin_cmp(c, &@1, TCG_COND_GTU, &$1, &$3);
} else {
$$ = gen_bin_cmp(c, &@1, TCG_COND_GT, &$1, &$3);
}
}
| rvalue LTE rvalue
{
@1.last_column = @3.last_column;
assert_signedness(c, &@1, $1.signedness);
assert_signedness(c, &@1, $3.signedness);
if ($1.signedness == UNSIGNED || $3.signedness == UNSIGNED) {
$$ = gen_bin_cmp(c, &@1, TCG_COND_LEU, &$1, &$3);
} else {
$$ = gen_bin_cmp(c, &@1, TCG_COND_LE, &$1, &$3);
}
}
| rvalue GTE rvalue
{
@1.last_column = @3.last_column;
assert_signedness(c, &@1, $1.signedness);
assert_signedness(c, &@1, $3.signedness);
if ($1.signedness == UNSIGNED || $3.signedness == UNSIGNED) {
$$ = gen_bin_cmp(c, &@1, TCG_COND_GEU, &$1, &$3);
} else {
$$ = gen_bin_cmp(c, &@1, TCG_COND_GE, &$1, &$3);
}
}
| rvalue '?'
{
Ternary t = { 0 };
t.state = IN_LEFT;
t.cond = $1;
g_array_append_val(c->ternary, t);
}
rvalue ':'
{
Ternary *t = &g_array_index(c->ternary, Ternary,
c->ternary->len - 1);
t->state = IN_RIGHT;
}
rvalue
{
@1.last_column = @5.last_column;
$$ = gen_rvalue_ternary(c, &@1, &$1, &$4, &$7);
}
| FSCR '(' rvalue ')'
{
@1.last_column = @4.last_column;
$$ = gen_rvalue_fscr(c, &@1, &$3);
}
| SXT '(' rvalue ',' IMM ',' rvalue ')'
{
@1.last_column = @8.last_column;
yyassert(c, &@1, $5.type == IMMEDIATE &&
$5.imm.type == VALUE,
"SXT expects immediate values\n");
$$ = gen_extend_op(c, &@1, &$3, $5.imm.value, &$7, SIGNED);
}
| ZXT '(' rvalue ',' IMM ',' rvalue ')'
{
@1.last_column = @8.last_column;
yyassert(c, &@1, $5.type == IMMEDIATE &&
$5.imm.type == VALUE,
"ZXT expects immediate values\n");
$$ = gen_extend_op(c, &@1, &$3, $5.imm.value, &$7, UNSIGNED);
}
| '(' rvalue ')'
{
$$ = $2;
}
| ABS rvalue
{
@1.last_column = @2.last_column;
$$ = gen_rvalue_abs(c, &@1, &$2);
}
| CROUND '(' rvalue ',' rvalue ')'
{
@1.last_column = @6.last_column;
$$ = gen_convround_n(c, &@1, &$3, &$5);
}
| CROUND '(' rvalue ')'
{
@1.last_column = @4.last_column;
$$ = gen_convround(c, &@1, &$3);
}
| ROUND '(' rvalue ',' rvalue ')'
{
@1.last_column = @6.last_column;
$$ = gen_round(c, &@1, &$3, &$5);
}
| '-' rvalue
{
@1.last_column = @2.last_column;
$$ = gen_rvalue_neg(c, &@1, &$2);
}
| ICIRC '(' rvalue ')' ASL IMM
{
@1.last_column = @6.last_column;
$$ = gen_tmp(c, &@1, 32, UNSIGNED);
OUT(c, &@1, "gen_read_ireg(", &$$, ", ", &$3, ", ", &$6, ");\n");
}
| CIRCADD '(' rvalue ',' rvalue ',' rvalue ')'
{
@1.last_column = @8.last_column;
gen_circ_op(c, &@1, &$3, &$5, &$7);
}
| LOCNT '(' rvalue ')'
{
@1.last_column = @4.last_column;
/* Leading ones count */
$$ = gen_locnt_op(c, &@1, &$3);
}
| COUNTONES '(' rvalue ')'
{
@1.last_column = @4.last_column;
/* Ones count */
$$ = gen_ctpop_op(c, &@1, &$3);
}
| EXTRACT '(' rvalue ',' rvalue ')'
{
@1.last_column = @6.last_column;
$$ = gen_extract_op(c, &@1, &$5, &$3, &$1);
}
| EXTRANGE '(' rvalue ',' rvalue ',' rvalue ')'
{
@1.last_column = @8.last_column;
yyassert(c, &@1, $5.type == IMMEDIATE &&
$5.imm.type == VALUE &&
$7.type == IMMEDIATE &&
$7.imm.type == VALUE,
"Range extract needs immediate values!\n");
$$ = gen_rextract_op(c,
&@1,
&$3,
$7.imm.value,
$5.imm.value - $7.imm.value + 1);
}
| CAST4_8U '(' rvalue ')'
{
@1.last_column = @4.last_column;
$$ = gen_rvalue_truncate(c, &@1, &$3);
$$.signedness = UNSIGNED;
$$ = rvalue_materialize(c, &@1, &$$);
$$ = gen_rvalue_extend(c, &@1, &$$);
}
| BREV '(' rvalue ')'
{
@1.last_column = @4.last_column;
$$ = gen_rvalue_brev(c, &@1, &$3);
}
| ROTL '(' rvalue ',' rvalue ')'
{
@1.last_column = @6.last_column;
$$ = gen_rotl(c, &@1, &$3, &$5);
}
| ADDSAT64 '(' rvalue ',' rvalue ',' rvalue ')'
{
@1.last_column = @8.last_column;
gen_addsat64(c, &@1, &$3, &$5, &$7);
}
| CARRY_FROM_ADD '(' rvalue ',' rvalue ',' rvalue ')'
{
@1.last_column = @8.last_column;
$$ = gen_carry_from_add(c, &@1, &$3, &$5, &$7);
}
| LSBNEW '(' rvalue ')'
{
@1.last_column = @4.last_column;
HexValue one = gen_imm_value(c, &@1, 1, 32, UNSIGNED);
$$ = gen_bin_op(c, &@1, ANDB_OP, &$3, &one);
}
;
lvalue : FAIL
{
@1.last_column = @1.last_column;
yyassert(c, &@1, false, "Encountered a FAIL token as lvalue.\n");
}
| REG
{
$$ = $1;
}
| var
{
$$ = $1;
}
;
%%
int main(int argc, char **argv)
{
if (argc != 5) {
fprintf(stderr,
"Semantics: Hexagon ISA to tinycode generator compiler\n\n");
fprintf(stderr,
"Usage: ./semantics IDEFS EMITTER_C EMITTER_H "
"ENABLED_INSTRUCTIONS_LIST\n");
return 1;
}
enum {
ARG_INDEX_ARGV0 = 0,
ARG_INDEX_IDEFS,
ARG_INDEX_EMITTER_C,
ARG_INDEX_EMITTER_H,
ARG_INDEX_ENABLED_INSTRUCTIONS_LIST
};
FILE *enabled_file = fopen(argv[ARG_INDEX_ENABLED_INSTRUCTIONS_LIST], "w");
FILE *output_file = fopen(argv[ARG_INDEX_EMITTER_C], "w");
fputs("#include \"qemu/osdep.h\"\n", output_file);
fputs("#include \"qemu/log.h\"\n", output_file);
fputs("#include \"cpu.h\"\n", output_file);
fputs("#include \"internal.h\"\n", output_file);
fputs("#include \"tcg/tcg-op.h\"\n", output_file);
fputs("#include \"insn.h\"\n", output_file);
fputs("#include \"opcodes.h\"\n", output_file);
fputs("#include \"translate.h\"\n", output_file);
fputs("#define QEMU_GENERATE\n", output_file);
fputs("#include \"genptr.h\"\n", output_file);
fputs("#include \"tcg/tcg.h\"\n", output_file);
fputs("#include \"macros.h\"\n", output_file);
fprintf(output_file, "#include \"%s\"\n", argv[ARG_INDEX_EMITTER_H]);
FILE *defines_file = fopen(argv[ARG_INDEX_EMITTER_H], "w");
assert(defines_file != NULL);
fputs("#ifndef HEX_EMITTER_H\n", defines_file);
fputs("#define HEX_EMITTER_H\n", defines_file);
fputs("\n", defines_file);
fputs("#include \"insn.h\"\n\n", defines_file);
/* Parser input file */
Context context = { 0 };
context.defines_file = defines_file;
context.output_file = output_file;
context.enabled_file = enabled_file;
/* Initialize buffers */
context.out_str = g_string_new(NULL);
context.signature_str = g_string_new(NULL);
context.header_str = g_string_new(NULL);
context.ternary = g_array_new(FALSE, TRUE, sizeof(Ternary));
/* Read input file */
FILE *input_file = fopen(argv[ARG_INDEX_IDEFS], "r");
fseek(input_file, 0L, SEEK_END);
long input_size = ftell(input_file);
context.input_buffer = (char *) calloc(input_size + 1, sizeof(char));
fseek(input_file, 0L, SEEK_SET);
size_t read_chars = fread(context.input_buffer,
sizeof(char),
input_size,
input_file);
if (read_chars != (size_t) input_size) {
fprintf(stderr, "Error: an error occurred while reading input file!\n");
return -1;
}
yylex_init(&context.scanner);
YY_BUFFER_STATE buffer;
buffer = yy_scan_string(context.input_buffer, context.scanner);
/* Start the parsing procedure */
yyparse(context.scanner, &context);
if (context.implemented_insn != context.total_insn) {
fprintf(stderr,
"Warning: %d/%d meta instructions have been implemented!\n",
context.implemented_insn,
context.total_insn);
}
fputs("#endif " START_COMMENT " HEX_EMITTER_h " END_COMMENT "\n",
defines_file);
/* Cleanup */
yy_delete_buffer(buffer, context.scanner);
yylex_destroy(context.scanner);
free(context.input_buffer);
g_string_free(context.out_str, TRUE);
g_string_free(context.signature_str, TRUE);
g_string_free(context.header_str, TRUE);
g_array_free(context.ternary, TRUE);
fclose(output_file);
fclose(input_file);
fclose(defines_file);
fclose(enabled_file);
return 0;
}