platform_external_dtc/dtc-parser.y
Stephen Warren 5f0c3b2d62 dtc: Basic integer expressions
Written by David Gibson <david@gibson.dropbear.id.au>. Additions by me:
* Ported to ToT dtc.
* Renamed cell to integer throughout.
* Implemented value range checks.
* Allow U/L/UL/LL/ULL suffix on literals.
* Enabled the commented test.

Signed-off-by: Stephen Warren <swarren@wwwdotorg.org>
2012-04-09 08:42:05 -05:00

511 lines
9.7 KiB
Text

/*
* (C) Copyright David Gibson <dwg@au1.ibm.com>, IBM Corporation. 2005.
*
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation; either version 2 of the
* License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307
* USA
*/
%{
#include <stdio.h>
#include "dtc.h"
#include "srcpos.h"
YYLTYPE yylloc;
extern int yylex(void);
extern void print_error(char const *fmt, ...);
extern void yyerror(char const *s);
extern struct boot_info *the_boot_info;
extern int treesource_error;
static unsigned long long eval_literal(const char *s, int base, int bits);
static unsigned char eval_char_literal(const char *s);
%}
%union {
char *propnodename;
char *literal;
char *labelref;
unsigned int cbase;
uint8_t byte;
struct data data;
struct {
struct data data;
int bits;
} array;
struct property *prop;
struct property *proplist;
struct node *node;
struct node *nodelist;
struct reserve_info *re;
uint64_t integer;
}
%token DT_V1
%token DT_MEMRESERVE
%token DT_LSHIFT DT_RSHIFT DT_LE DT_GE DT_EQ DT_NE DT_AND DT_OR
%token DT_BITS
%token <propnodename> DT_PROPNODENAME
%token <literal> DT_LITERAL
%token <literal> DT_CHAR_LITERAL
%token <cbase> DT_BASE
%token <byte> DT_BYTE
%token <data> DT_STRING
%token <labelref> DT_LABEL
%token <labelref> DT_REF
%token DT_INCBIN
%type <data> propdata
%type <data> propdataprefix
%type <re> memreserve
%type <re> memreserves
%type <array> arrayprefix
%type <data> bytestring
%type <prop> propdef
%type <proplist> proplist
%type <node> devicetree
%type <node> nodedef
%type <node> subnode
%type <nodelist> subnodes
%type <integer> integer_prim
%type <integer> integer_unary
%type <integer> integer_mul
%type <integer> integer_add
%type <integer> integer_shift
%type <integer> integer_rela
%type <integer> integer_eq
%type <integer> integer_bitand
%type <integer> integer_bitxor
%type <integer> integer_bitor
%type <integer> integer_and
%type <integer> integer_or
%type <integer> integer_trinary
%type <integer> integer_expr
%%
sourcefile:
DT_V1 ';' memreserves devicetree
{
the_boot_info = build_boot_info($3, $4,
guess_boot_cpuid($4));
}
;
memreserves:
/* empty */
{
$$ = NULL;
}
| memreserve memreserves
{
$$ = chain_reserve_entry($1, $2);
}
;
memreserve:
DT_MEMRESERVE integer_prim integer_prim ';'
{
$$ = build_reserve_entry($2, $3);
}
| DT_LABEL memreserve
{
add_label(&$2->labels, $1);
$$ = $2;
}
;
devicetree:
'/' nodedef
{
$$ = name_node($2, "");
}
| devicetree '/' nodedef
{
$$ = merge_nodes($1, $3);
}
| devicetree DT_REF nodedef
{
struct node *target = get_node_by_ref($1, $2);
if (target)
merge_nodes(target, $3);
else
print_error("label or path, '%s', not found", $2);
$$ = $1;
}
;
nodedef:
'{' proplist subnodes '}' ';'
{
$$ = build_node($2, $3);
}
;
proplist:
/* empty */
{
$$ = NULL;
}
| proplist propdef
{
$$ = chain_property($2, $1);
}
;
propdef:
DT_PROPNODENAME '=' propdata ';'
{
$$ = build_property($1, $3);
}
| DT_PROPNODENAME ';'
{
$$ = build_property($1, empty_data);
}
| DT_LABEL propdef
{
add_label(&$2->labels, $1);
$$ = $2;
}
;
propdata:
propdataprefix DT_STRING
{
$$ = data_merge($1, $2);
}
| propdataprefix arrayprefix '>'
{
$$ = data_merge($1, $2.data);
}
| propdataprefix '[' bytestring ']'
{
$$ = data_merge($1, $3);
}
| propdataprefix DT_REF
{
$$ = data_add_marker($1, REF_PATH, $2);
}
| propdataprefix DT_INCBIN '(' DT_STRING ',' integer_prim ',' integer_prim ')'
{
FILE *f = srcfile_relative_open($4.val, NULL);
struct data d;
if ($6 != 0)
if (fseek(f, $6, SEEK_SET) != 0)
print_error("Couldn't seek to offset %llu in \"%s\": %s",
(unsigned long long)$6,
$4.val,
strerror(errno));
d = data_copy_file(f, $8);
$$ = data_merge($1, d);
fclose(f);
}
| propdataprefix DT_INCBIN '(' DT_STRING ')'
{
FILE *f = srcfile_relative_open($4.val, NULL);
struct data d = empty_data;
d = data_copy_file(f, -1);
$$ = data_merge($1, d);
fclose(f);
}
| propdata DT_LABEL
{
$$ = data_add_marker($1, LABEL, $2);
}
;
propdataprefix:
/* empty */
{
$$ = empty_data;
}
| propdata ','
{
$$ = $1;
}
| propdataprefix DT_LABEL
{
$$ = data_add_marker($1, LABEL, $2);
}
;
arrayprefix:
DT_BITS DT_LITERAL '<'
{
$$.data = empty_data;
$$.bits = eval_literal($2, 0, 7);
if (($$.bits != 8) &&
($$.bits != 16) &&
($$.bits != 32) &&
($$.bits != 64))
{
print_error("Only 8, 16, 32 and 64-bit elements"
" are currently supported");
$$.bits = 32;
}
}
| '<'
{
$$.data = empty_data;
$$.bits = 32;
}
| arrayprefix integer_prim
{
if ($1.bits < 64) {
uint64_t mask = (1ULL << $1.bits) - 1;
/*
* Bits above mask must either be all zero
* (positive within range of mask) or all one
* (negative and sign-extended). The second
* condition is true if when we set all bits
* within the mask to one (i.e. | in the
* mask), all bits are one.
*/
if (($2 > mask) && (($2 | mask) != -1ULL))
print_error(
"integer value out of range "
"%016lx (%d bits)", $1.bits);
}
$$.data = data_append_integer($1.data, $2, $1.bits);
}
| arrayprefix DT_REF
{
uint64_t val = ~0ULL >> (64 - $1.bits);
if ($1.bits == 32)
$1.data = data_add_marker($1.data,
REF_PHANDLE,
$2);
else
print_error("References are only allowed in "
"arrays with 32-bit elements.");
$$.data = data_append_integer($1.data, val, $1.bits);
}
| arrayprefix DT_LABEL
{
$$.data = data_add_marker($1.data, LABEL, $2);
}
;
integer_prim:
DT_LITERAL
{
$$ = eval_literal($1, 0, 64);
}
| DT_CHAR_LITERAL
{
$$ = eval_char_literal($1);
}
| '(' integer_expr ')'
{
$$ = $2;
}
;
integer_expr:
integer_trinary
;
integer_trinary:
integer_or
| integer_or '?' integer_expr ':' integer_trinary { $$ = $1 ? $3 : $5; }
;
integer_or:
integer_and
| integer_or DT_OR integer_and { $$ = $1 || $3; }
;
integer_and:
integer_bitor
| integer_and DT_AND integer_bitor { $$ = $1 && $3; }
;
integer_bitor:
integer_bitxor
| integer_bitor '|' integer_bitxor { $$ = $1 | $3; }
;
integer_bitxor:
integer_bitand
| integer_bitxor '^' integer_bitand { $$ = $1 ^ $3; }
;
integer_bitand:
integer_eq
| integer_bitand '&' integer_eq { $$ = $1 & $3; }
;
integer_eq:
integer_rela
| integer_eq DT_EQ integer_rela { $$ = $1 == $3; }
| integer_eq DT_NE integer_rela { $$ = $1 != $3; }
;
integer_rela:
integer_shift
| integer_rela '<' integer_shift { $$ = $1 < $3; }
| integer_rela '>' integer_shift { $$ = $1 > $3; }
| integer_rela DT_LE integer_shift { $$ = $1 <= $3; }
| integer_rela DT_GE integer_shift { $$ = $1 >= $3; }
;
integer_shift:
integer_shift DT_LSHIFT integer_add { $$ = $1 << $3; }
| integer_shift DT_RSHIFT integer_add { $$ = $1 >> $3; }
| integer_add
;
integer_add:
integer_add '+' integer_mul { $$ = $1 + $3; }
| integer_add '-' integer_mul { $$ = $1 - $3; }
| integer_mul
;
integer_mul:
integer_mul '*' integer_unary { $$ = $1 * $3; }
| integer_mul '/' integer_unary { $$ = $1 / $3; }
| integer_mul '%' integer_unary { $$ = $1 % $3; }
| integer_unary
;
integer_unary:
integer_prim
| '-' integer_unary { $$ = -$2; }
| '~' integer_unary { $$ = ~$2; }
| '!' integer_unary { $$ = !$2; }
;
bytestring:
/* empty */
{
$$ = empty_data;
}
| bytestring DT_BYTE
{
$$ = data_append_byte($1, $2);
}
| bytestring DT_LABEL
{
$$ = data_add_marker($1, LABEL, $2);
}
;
subnodes:
/* empty */
{
$$ = NULL;
}
| subnode subnodes
{
$$ = chain_node($1, $2);
}
| subnode propdef
{
print_error("syntax error: properties must precede subnodes");
YYERROR;
}
;
subnode:
DT_PROPNODENAME nodedef
{
$$ = name_node($2, $1);
}
| DT_LABEL subnode
{
add_label(&$2->labels, $1);
$$ = $2;
}
;
%%
void print_error(char const *fmt, ...)
{
va_list va;
va_start(va, fmt);
srcpos_verror(&yylloc, fmt, va);
va_end(va);
treesource_error = 1;
}
void yyerror(char const *s) {
print_error("%s", s);
}
static unsigned long long eval_literal(const char *s, int base, int bits)
{
unsigned long long val;
char *e;
errno = 0;
val = strtoull(s, &e, base);
if (*e) {
size_t uls = strspn(e, "UL");
if (e[uls])
print_error("bad characters in literal");
}
if ((errno == ERANGE)
|| ((bits < 64) && (val >= (1ULL << bits))))
print_error("literal out of range");
else if (errno != 0)
print_error("bad literal");
return val;
}
static unsigned char eval_char_literal(const char *s)
{
int i = 1;
char c = s[0];
if (c == '\0')
{
print_error("empty character literal");
return 0;
}
/*
* If the first character in the character literal is a \ then process
* the remaining characters as an escape encoding. If the first
* character is neither an escape or a terminator it should be the only
* character in the literal and will be returned.
*/
if (c == '\\')
c = get_escape_char(s, &i);
if (s[i] != '\0')
print_error("malformed character literal");
return c;
}