/* * (C) Copyright David Gibson , 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 #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 DT_DEL_PROP %token DT_DEL_NODE %token DT_PROPNODENAME %token DT_LITERAL %token DT_CHAR_LITERAL %token DT_BASE %token DT_BYTE %token DT_STRING %token DT_LABEL %token DT_REF %token DT_INCBIN %type propdata %type propdataprefix %type memreserve %type memreserves %type arrayprefix %type bytestring %type propdef %type proplist %type devicetree %type nodedef %type subnode %type subnodes %type integer_prim %type integer_unary %type integer_mul %type integer_add %type integer_shift %type integer_rela %type integer_eq %type integer_bitand %type integer_bitxor %type integer_bitor %type integer_and %type integer_or %type integer_trinary %type 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); $$ = $1; } | devicetree DT_DEL_NODE DT_REF ';' { struct node *target = get_node_by_ref($1, $3); if (!target) print_error("label or path, '%s', not found", $3); else delete_node(target); $$ = $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 ';' { $$ = build_property($1, empty_data); } | DT_DEL_PROP DT_PROPNODENAME ';' { $$ = build_property_delete($2); } | 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_DEL_NODE DT_PROPNODENAME ';' { $$ = name_node(build_node_delete(), $2); } | DT_LABEL subnode { add_label(&$2->labels, $1); $$ = $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; }