u-boot/scripts/kconfig/symbol.c
Tom Rini 587e4a4296 kconfig / kbuild: Re-sync with Linux 4.19
Align Kconfig and Kbuild logic to Linux 4.19 release with minimal impact
on files outside of this scope.

Our previous Kconfig sync was done by commit 5972ff077e ("kconfig /
kbuild: re-sync with Linux 4.18").

In this particular re-sync in order to keep clang support working a
number of related changes needed to be pulled in that had been missed
previously.  Not all of these changes we easily traceable and so have
been omitted from the list below.

The imported Linux commits are:
[From prior to v4.18]
9f3f1fd29976 kbuild: Add __cc-option macro
d7f14c66c273 kbuild: Enable Large File Support for hostprogs
6d79a7b424a5 kbuild: suppress warnings from 'getconf LFS_*'
24403874316a Shared library support
86a9df597cdd kbuild: fix linker feature test macros when cross compiling with Clang
0294e6f4a000 kbuild: simplify ld-option implementation

[From v4.18 to v4.19]
96f14fe738b6 kbuild: Rename HOSTCFLAGS to KBUILD_HOSTCFLAGS
10844aebf448 kbuild: Rename HOSTCXXFLAGS to KBUILD_HOSTCXXFLAGS
b90a368000ab kbuild: Rename HOSTLDFLAGS to KBUILD_HOSTLDFLAGS
8377bd2b9ee1 kbuild: Rename HOST_LOADLIBES to KBUILD_HOSTLDLIBS
f92d19e0ef9b kbuild: Use HOST*FLAGS options from the command line
4ab3b80159d4 kconfig: check for pkg-config on make {menu,n,g,x}config
693359f7ac90 kconfig: rename SYMBOL_AUTO to SYMBOL_NO_WRITE
f60b992e30ff kbuild: replace $(LDFLAGS) $(ldflags-y) with $(ld_flags)
2fb9279f2c3e kbuild: change ld_flags to contain LDFLAGS_$(@F)
c931d34ea085 arm64: build with baremetal linker target instead of Linux when available
5accd7f3360e kconfig: handle format string before calling conf_message_callback()
a2ff4040151a kconfig: rename file_write_dep and move it to confdata.c
0608182ad542 kconfig: split out useful helpers in confdata.c
adc18acf42a1 kconfig: remove unneeded directory generation from local*config
79123b1389cc kconfig: create directories needed for syncconfig by itself
16952b77d8b5 kconfig: make syncconfig update .config regardless of sym_change_count
d6c6ab93e17f kbuild: remove deprecated host-progs variable
56869d45e364 kconfig: fix the rule of mainmenu_stmt symbol
c151272d1687 kconfig: remove unused sym_get_env_prop() function
1880861226c1 kconfig: remove P_ENV property type
e3fd9b5384f3 scripts/dtc: consolidate include path options in Makefile
4bf6a9af0e91 kconfig: add build-only configurator targets
f1575595d156 kconfig: error out when seeing recursive dependency
5e8c5299d315 kconfig: report recursive dependency involving 'imply'
f498926c47aa kconfig: improve the recursive dependency report
98a4afbfafd2 kconfig: fix "Can't open ..." in parallel build
9a9ddcf47831 kconfig: suppress "configuration written to .config" for syncconfig
87a32e624037 kbuild: pass LDFLAGS to recordmcount.pl
d503ac531a52 kbuild: rename LDFLAGS to KBUILD_LDFLAGS
217c3e019675 disable stringop truncation warnings for now
bc8d2e20a3eb kconfig: remove a spurious self-assignment
fd65465b7016 kconfig: do not require pkg-config on make {menu,n}config
5a4630aadb9a ftrace: Build with CPPFLAGS to get -Qunused-arguments

Note that this adds new cleanup work to do in that we should adapt the
shared library support we have to what is now upstream.

Signed-off-by: Tom Rini <trini@konsulko.com>
Reviewed-by: Masahiro Yamada <masahiroy@kernel.org>
2020-04-10 11:18:32 -04:00

1335 lines
29 KiB
C

/*
* Copyright (C) 2002 Roman Zippel <zippel@linux-m68k.org>
* Released under the terms of the GNU GPL v2.0.
*/
#include <ctype.h>
#include <stdlib.h>
#include <string.h>
#include <regex.h>
#include <sys/utsname.h>
#include "lkc.h"
struct symbol symbol_yes = {
.name = "y",
.curr = { "y", yes },
.flags = SYMBOL_CONST|SYMBOL_VALID,
}, symbol_mod = {
.name = "m",
.curr = { "m", mod },
.flags = SYMBOL_CONST|SYMBOL_VALID,
}, symbol_no = {
.name = "n",
.curr = { "n", no },
.flags = SYMBOL_CONST|SYMBOL_VALID,
}, symbol_empty = {
.name = "",
.curr = { "", no },
.flags = SYMBOL_VALID,
};
struct symbol *sym_defconfig_list;
struct symbol *modules_sym;
tristate modules_val;
enum symbol_type sym_get_type(struct symbol *sym)
{
enum symbol_type type = sym->type;
if (type == S_TRISTATE) {
if (sym_is_choice_value(sym) && sym->visible == yes)
type = S_BOOLEAN;
else if (modules_val == no)
type = S_BOOLEAN;
}
return type;
}
const char *sym_type_name(enum symbol_type type)
{
switch (type) {
case S_BOOLEAN:
return "bool";
case S_TRISTATE:
return "tristate";
case S_INT:
return "integer";
case S_HEX:
return "hex";
case S_STRING:
return "string";
case S_UNKNOWN:
return "unknown";
case S_OTHER:
break;
}
return "???";
}
struct property *sym_get_choice_prop(struct symbol *sym)
{
struct property *prop;
for_all_choices(sym, prop)
return prop;
return NULL;
}
static struct property *sym_get_default_prop(struct symbol *sym)
{
struct property *prop;
for_all_defaults(sym, prop) {
prop->visible.tri = expr_calc_value(prop->visible.expr);
if (prop->visible.tri != no)
return prop;
}
return NULL;
}
static struct property *sym_get_range_prop(struct symbol *sym)
{
struct property *prop;
for_all_properties(sym, prop, P_RANGE) {
prop->visible.tri = expr_calc_value(prop->visible.expr);
if (prop->visible.tri != no)
return prop;
}
return NULL;
}
static long long sym_get_range_val(struct symbol *sym, int base)
{
sym_calc_value(sym);
switch (sym->type) {
case S_INT:
base = 10;
break;
case S_HEX:
base = 16;
break;
default:
break;
}
return strtoll(sym->curr.val, NULL, base);
}
static void sym_validate_range(struct symbol *sym)
{
struct property *prop;
int base;
long long val, val2;
char str[64];
switch (sym->type) {
case S_INT:
base = 10;
break;
case S_HEX:
base = 16;
break;
default:
return;
}
prop = sym_get_range_prop(sym);
if (!prop)
return;
val = strtoll(sym->curr.val, NULL, base);
val2 = sym_get_range_val(prop->expr->left.sym, base);
if (val >= val2) {
val2 = sym_get_range_val(prop->expr->right.sym, base);
if (val <= val2)
return;
}
if (sym->type == S_INT)
sprintf(str, "%lld", val2);
else
sprintf(str, "0x%llx", val2);
sym->curr.val = xstrdup(str);
}
static void sym_set_changed(struct symbol *sym)
{
struct property *prop;
sym->flags |= SYMBOL_CHANGED;
for (prop = sym->prop; prop; prop = prop->next) {
if (prop->menu)
prop->menu->flags |= MENU_CHANGED;
}
}
static void sym_set_all_changed(void)
{
struct symbol *sym;
int i;
for_all_symbols(i, sym)
sym_set_changed(sym);
}
static void sym_calc_visibility(struct symbol *sym)
{
struct property *prop;
struct symbol *choice_sym = NULL;
tristate tri;
/* any prompt visible? */
tri = no;
if (sym_is_choice_value(sym))
choice_sym = prop_get_symbol(sym_get_choice_prop(sym));
for_all_prompts(sym, prop) {
prop->visible.tri = expr_calc_value(prop->visible.expr);
/*
* Tristate choice_values with visibility 'mod' are
* not visible if the corresponding choice's value is
* 'yes'.
*/
if (choice_sym && sym->type == S_TRISTATE &&
prop->visible.tri == mod && choice_sym->curr.tri == yes)
prop->visible.tri = no;
tri = EXPR_OR(tri, prop->visible.tri);
}
if (tri == mod && (sym->type != S_TRISTATE || modules_val == no))
tri = yes;
if (sym->visible != tri) {
sym->visible = tri;
sym_set_changed(sym);
}
if (sym_is_choice_value(sym))
return;
/* defaulting to "yes" if no explicit "depends on" are given */
tri = yes;
if (sym->dir_dep.expr)
tri = expr_calc_value(sym->dir_dep.expr);
if (tri == mod && sym_get_type(sym) == S_BOOLEAN)
tri = yes;
if (sym->dir_dep.tri != tri) {
sym->dir_dep.tri = tri;
sym_set_changed(sym);
}
tri = no;
if (sym->rev_dep.expr)
tri = expr_calc_value(sym->rev_dep.expr);
if (tri == mod && sym_get_type(sym) == S_BOOLEAN)
tri = yes;
if (sym->rev_dep.tri != tri) {
sym->rev_dep.tri = tri;
sym_set_changed(sym);
}
tri = no;
if (sym->implied.expr && sym->dir_dep.tri != no)
tri = expr_calc_value(sym->implied.expr);
if (tri == mod && sym_get_type(sym) == S_BOOLEAN)
tri = yes;
if (sym->implied.tri != tri) {
sym->implied.tri = tri;
sym_set_changed(sym);
}
}
/*
* Find the default symbol for a choice.
* First try the default values for the choice symbol
* Next locate the first visible choice value
* Return NULL if none was found
*/
struct symbol *sym_choice_default(struct symbol *sym)
{
struct symbol *def_sym;
struct property *prop;
struct expr *e;
/* any of the defaults visible? */
for_all_defaults(sym, prop) {
prop->visible.tri = expr_calc_value(prop->visible.expr);
if (prop->visible.tri == no)
continue;
def_sym = prop_get_symbol(prop);
if (def_sym->visible != no)
return def_sym;
}
/* just get the first visible value */
prop = sym_get_choice_prop(sym);
expr_list_for_each_sym(prop->expr, e, def_sym)
if (def_sym->visible != no)
return def_sym;
/* failed to locate any defaults */
return NULL;
}
static struct symbol *sym_calc_choice(struct symbol *sym)
{
struct symbol *def_sym;
struct property *prop;
struct expr *e;
int flags;
/* first calculate all choice values' visibilities */
flags = sym->flags;
prop = sym_get_choice_prop(sym);
expr_list_for_each_sym(prop->expr, e, def_sym) {
sym_calc_visibility(def_sym);
if (def_sym->visible != no)
flags &= def_sym->flags;
}
sym->flags &= flags | ~SYMBOL_DEF_USER;
/* is the user choice visible? */
def_sym = sym->def[S_DEF_USER].val;
if (def_sym && def_sym->visible != no)
return def_sym;
def_sym = sym_choice_default(sym);
if (def_sym == NULL)
/* no choice? reset tristate value */
sym->curr.tri = no;
return def_sym;
}
static void sym_warn_unmet_dep(struct symbol *sym)
{
struct gstr gs = str_new();
str_printf(&gs,
"\nWARNING: unmet direct dependencies detected for %s\n",
sym->name);
str_printf(&gs,
" Depends on [%c]: ",
sym->dir_dep.tri == mod ? 'm' : 'n');
expr_gstr_print(sym->dir_dep.expr, &gs);
str_printf(&gs, "\n");
expr_gstr_print_revdep(sym->rev_dep.expr, &gs, yes,
" Selected by [y]:\n");
expr_gstr_print_revdep(sym->rev_dep.expr, &gs, mod,
" Selected by [m]:\n");
fputs(str_get(&gs), stderr);
}
void sym_calc_value(struct symbol *sym)
{
struct symbol_value newval, oldval;
struct property *prop;
struct expr *e;
if (!sym)
return;
if (sym->flags & SYMBOL_VALID)
return;
if (sym_is_choice_value(sym) &&
sym->flags & SYMBOL_NEED_SET_CHOICE_VALUES) {
sym->flags &= ~SYMBOL_NEED_SET_CHOICE_VALUES;
prop = sym_get_choice_prop(sym);
sym_calc_value(prop_get_symbol(prop));
}
sym->flags |= SYMBOL_VALID;
oldval = sym->curr;
switch (sym->type) {
case S_INT:
case S_HEX:
case S_STRING:
newval = symbol_empty.curr;
break;
case S_BOOLEAN:
case S_TRISTATE:
newval = symbol_no.curr;
break;
default:
sym->curr.val = sym->name;
sym->curr.tri = no;
return;
}
sym->flags &= ~SYMBOL_WRITE;
sym_calc_visibility(sym);
if (sym->visible != no)
sym->flags |= SYMBOL_WRITE;
/* set default if recursively called */
sym->curr = newval;
switch (sym_get_type(sym)) {
case S_BOOLEAN:
case S_TRISTATE:
if (sym_is_choice_value(sym) && sym->visible == yes) {
prop = sym_get_choice_prop(sym);
newval.tri = (prop_get_symbol(prop)->curr.val == sym) ? yes : no;
} else {
if (sym->visible != no) {
/* if the symbol is visible use the user value
* if available, otherwise try the default value
*/
if (sym_has_value(sym)) {
newval.tri = EXPR_AND(sym->def[S_DEF_USER].tri,
sym->visible);
goto calc_newval;
}
}
if (sym->rev_dep.tri != no)
sym->flags |= SYMBOL_WRITE;
if (!sym_is_choice(sym)) {
prop = sym_get_default_prop(sym);
if (prop) {
newval.tri = EXPR_AND(expr_calc_value(prop->expr),
prop->visible.tri);
if (newval.tri != no)
sym->flags |= SYMBOL_WRITE;
}
if (sym->implied.tri != no) {
sym->flags |= SYMBOL_WRITE;
newval.tri = EXPR_OR(newval.tri, sym->implied.tri);
}
}
calc_newval:
if (sym->dir_dep.tri < sym->rev_dep.tri)
sym_warn_unmet_dep(sym);
newval.tri = EXPR_OR(newval.tri, sym->rev_dep.tri);
}
if (newval.tri == mod &&
(sym_get_type(sym) == S_BOOLEAN || sym->implied.tri == yes))
newval.tri = yes;
break;
case S_STRING:
case S_HEX:
case S_INT:
if (sym->visible != no && sym_has_value(sym)) {
newval.val = sym->def[S_DEF_USER].val;
break;
}
prop = sym_get_default_prop(sym);
if (prop) {
struct symbol *ds = prop_get_symbol(prop);
if (ds) {
sym->flags |= SYMBOL_WRITE;
sym_calc_value(ds);
newval.val = ds->curr.val;
}
}
break;
default:
;
}
sym->curr = newval;
if (sym_is_choice(sym) && newval.tri == yes)
sym->curr.val = sym_calc_choice(sym);
sym_validate_range(sym);
if (memcmp(&oldval, &sym->curr, sizeof(oldval))) {
sym_set_changed(sym);
if (modules_sym == sym) {
sym_set_all_changed();
modules_val = modules_sym->curr.tri;
}
}
if (sym_is_choice(sym)) {
struct symbol *choice_sym;
prop = sym_get_choice_prop(sym);
expr_list_for_each_sym(prop->expr, e, choice_sym) {
if ((sym->flags & SYMBOL_WRITE) &&
choice_sym->visible != no)
choice_sym->flags |= SYMBOL_WRITE;
if (sym->flags & SYMBOL_CHANGED)
sym_set_changed(choice_sym);
}
}
if (sym->flags & SYMBOL_NO_WRITE)
sym->flags &= ~SYMBOL_WRITE;
if (sym->flags & SYMBOL_NEED_SET_CHOICE_VALUES)
set_all_choice_values(sym);
}
void sym_clear_all_valid(void)
{
struct symbol *sym;
int i;
for_all_symbols(i, sym)
sym->flags &= ~SYMBOL_VALID;
sym_add_change_count(1);
sym_calc_value(modules_sym);
}
bool sym_tristate_within_range(struct symbol *sym, tristate val)
{
int type = sym_get_type(sym);
if (sym->visible == no)
return false;
if (type != S_BOOLEAN && type != S_TRISTATE)
return false;
if (type == S_BOOLEAN && val == mod)
return false;
if (sym->visible <= sym->rev_dep.tri)
return false;
if (sym->implied.tri == yes && val == mod)
return false;
if (sym_is_choice_value(sym) && sym->visible == yes)
return val == yes;
return val >= sym->rev_dep.tri && val <= sym->visible;
}
bool sym_set_tristate_value(struct symbol *sym, tristate val)
{
tristate oldval = sym_get_tristate_value(sym);
if (oldval != val && !sym_tristate_within_range(sym, val))
return false;
if (!(sym->flags & SYMBOL_DEF_USER)) {
sym->flags |= SYMBOL_DEF_USER;
sym_set_changed(sym);
}
/*
* setting a choice value also resets the new flag of the choice
* symbol and all other choice values.
*/
if (sym_is_choice_value(sym) && val == yes) {
struct symbol *cs = prop_get_symbol(sym_get_choice_prop(sym));
struct property *prop;
struct expr *e;
cs->def[S_DEF_USER].val = sym;
cs->flags |= SYMBOL_DEF_USER;
prop = sym_get_choice_prop(cs);
for (e = prop->expr; e; e = e->left.expr) {
if (e->right.sym->visible != no)
e->right.sym->flags |= SYMBOL_DEF_USER;
}
}
sym->def[S_DEF_USER].tri = val;
if (oldval != val)
sym_clear_all_valid();
return true;
}
tristate sym_toggle_tristate_value(struct symbol *sym)
{
tristate oldval, newval;
oldval = newval = sym_get_tristate_value(sym);
do {
switch (newval) {
case no:
newval = mod;
break;
case mod:
newval = yes;
break;
case yes:
newval = no;
break;
}
if (sym_set_tristate_value(sym, newval))
break;
} while (oldval != newval);
return newval;
}
bool sym_string_valid(struct symbol *sym, const char *str)
{
signed char ch;
switch (sym->type) {
case S_STRING:
return true;
case S_INT:
ch = *str++;
if (ch == '-')
ch = *str++;
if (!isdigit(ch))
return false;
if (ch == '0' && *str != 0)
return false;
while ((ch = *str++)) {
if (!isdigit(ch))
return false;
}
return true;
case S_HEX:
if (str[0] == '0' && (str[1] == 'x' || str[1] == 'X'))
str += 2;
ch = *str++;
do {
if (!isxdigit(ch))
return false;
} while ((ch = *str++));
return true;
case S_BOOLEAN:
case S_TRISTATE:
switch (str[0]) {
case 'y': case 'Y':
case 'm': case 'M':
case 'n': case 'N':
return true;
}
return false;
default:
return false;
}
}
bool sym_string_within_range(struct symbol *sym, const char *str)
{
struct property *prop;
long long val;
switch (sym->type) {
case S_STRING:
return sym_string_valid(sym, str);
case S_INT:
if (!sym_string_valid(sym, str))
return false;
prop = sym_get_range_prop(sym);
if (!prop)
return true;
val = strtoll(str, NULL, 10);
return val >= sym_get_range_val(prop->expr->left.sym, 10) &&
val <= sym_get_range_val(prop->expr->right.sym, 10);
case S_HEX:
if (!sym_string_valid(sym, str))
return false;
prop = sym_get_range_prop(sym);
if (!prop)
return true;
val = strtoll(str, NULL, 16);
return val >= sym_get_range_val(prop->expr->left.sym, 16) &&
val <= sym_get_range_val(prop->expr->right.sym, 16);
case S_BOOLEAN:
case S_TRISTATE:
switch (str[0]) {
case 'y': case 'Y':
return sym_tristate_within_range(sym, yes);
case 'm': case 'M':
return sym_tristate_within_range(sym, mod);
case 'n': case 'N':
return sym_tristate_within_range(sym, no);
}
return false;
default:
return false;
}
}
bool sym_set_string_value(struct symbol *sym, const char *newval)
{
const char *oldval;
char *val;
int size;
switch (sym->type) {
case S_BOOLEAN:
case S_TRISTATE:
switch (newval[0]) {
case 'y': case 'Y':
return sym_set_tristate_value(sym, yes);
case 'm': case 'M':
return sym_set_tristate_value(sym, mod);
case 'n': case 'N':
return sym_set_tristate_value(sym, no);
}
return false;
default:
;
}
if (!sym_string_within_range(sym, newval))
return false;
if (!(sym->flags & SYMBOL_DEF_USER)) {
sym->flags |= SYMBOL_DEF_USER;
sym_set_changed(sym);
}
oldval = sym->def[S_DEF_USER].val;
size = strlen(newval) + 1;
if (sym->type == S_HEX && (newval[0] != '0' || (newval[1] != 'x' && newval[1] != 'X'))) {
size += 2;
sym->def[S_DEF_USER].val = val = xmalloc(size);
*val++ = '0';
*val++ = 'x';
} else if (!oldval || strcmp(oldval, newval))
sym->def[S_DEF_USER].val = val = xmalloc(size);
else
return true;
strcpy(val, newval);
free((void *)oldval);
sym_clear_all_valid();
return true;
}
/*
* Find the default value associated to a symbol.
* For tristate symbol handle the modules=n case
* in which case "m" becomes "y".
* If the symbol does not have any default then fallback
* to the fixed default values.
*/
const char *sym_get_string_default(struct symbol *sym)
{
struct property *prop;
struct symbol *ds;
const char *str;
tristate val;
sym_calc_visibility(sym);
sym_calc_value(modules_sym);
val = symbol_no.curr.tri;
str = symbol_empty.curr.val;
/* If symbol has a default value look it up */
prop = sym_get_default_prop(sym);
if (prop != NULL) {
switch (sym->type) {
case S_BOOLEAN:
case S_TRISTATE:
/* The visibility may limit the value from yes => mod */
val = EXPR_AND(expr_calc_value(prop->expr), prop->visible.tri);
break;
default:
/*
* The following fails to handle the situation
* where a default value is further limited by
* the valid range.
*/
ds = prop_get_symbol(prop);
if (ds != NULL) {
sym_calc_value(ds);
str = (const char *)ds->curr.val;
}
}
}
/* Handle select statements */
val = EXPR_OR(val, sym->rev_dep.tri);
/* transpose mod to yes if modules are not enabled */
if (val == mod)
if (!sym_is_choice_value(sym) && modules_sym->curr.tri == no)
val = yes;
/* transpose mod to yes if type is bool */
if (sym->type == S_BOOLEAN && val == mod)
val = yes;
/* adjust the default value if this symbol is implied by another */
if (val < sym->implied.tri)
val = sym->implied.tri;
switch (sym->type) {
case S_BOOLEAN:
case S_TRISTATE:
switch (val) {
case no: return "n";
case mod: return "m";
case yes: return "y";
}
case S_INT:
case S_HEX:
return str;
case S_STRING:
return str;
case S_OTHER:
case S_UNKNOWN:
break;
}
return "";
}
const char *sym_get_string_value(struct symbol *sym)
{
tristate val;
switch (sym->type) {
case S_BOOLEAN:
case S_TRISTATE:
val = sym_get_tristate_value(sym);
switch (val) {
case no:
return "n";
case mod:
sym_calc_value(modules_sym);
return (modules_sym->curr.tri == no) ? "n" : "m";
case yes:
return "y";
}
break;
default:
;
}
return (const char *)sym->curr.val;
}
bool sym_is_changable(struct symbol *sym)
{
return sym->visible > sym->rev_dep.tri;
}
static unsigned strhash(const char *s)
{
/* fnv32 hash */
unsigned hash = 2166136261U;
for (; *s; s++)
hash = (hash ^ *s) * 0x01000193;
return hash;
}
struct symbol *sym_lookup(const char *name, int flags)
{
struct symbol *symbol;
char *new_name;
int hash;
if (name) {
if (name[0] && !name[1]) {
switch (name[0]) {
case 'y': return &symbol_yes;
case 'm': return &symbol_mod;
case 'n': return &symbol_no;
}
}
hash = strhash(name) % SYMBOL_HASHSIZE;
for (symbol = symbol_hash[hash]; symbol; symbol = symbol->next) {
if (symbol->name &&
!strcmp(symbol->name, name) &&
(flags ? symbol->flags & flags
: !(symbol->flags & (SYMBOL_CONST|SYMBOL_CHOICE))))
return symbol;
}
new_name = xstrdup(name);
} else {
new_name = NULL;
hash = 0;
}
symbol = xmalloc(sizeof(*symbol));
memset(symbol, 0, sizeof(*symbol));
symbol->name = new_name;
symbol->type = S_UNKNOWN;
symbol->flags |= flags;
symbol->next = symbol_hash[hash];
symbol_hash[hash] = symbol;
return symbol;
}
struct symbol *sym_find(const char *name)
{
struct symbol *symbol = NULL;
int hash = 0;
if (!name)
return NULL;
if (name[0] && !name[1]) {
switch (name[0]) {
case 'y': return &symbol_yes;
case 'm': return &symbol_mod;
case 'n': return &symbol_no;
}
}
hash = strhash(name) % SYMBOL_HASHSIZE;
for (symbol = symbol_hash[hash]; symbol; symbol = symbol->next) {
if (symbol->name &&
!strcmp(symbol->name, name) &&
!(symbol->flags & SYMBOL_CONST))
break;
}
return symbol;
}
const char *sym_escape_string_value(const char *in)
{
const char *p;
size_t reslen;
char *res;
size_t l;
reslen = strlen(in) + strlen("\"\"") + 1;
p = in;
for (;;) {
l = strcspn(p, "\"\\");
p += l;
if (p[0] == '\0')
break;
reslen++;
p++;
}
res = xmalloc(reslen);
res[0] = '\0';
strcat(res, "\"");
p = in;
for (;;) {
l = strcspn(p, "\"\\");
strncat(res, p, l);
p += l;
if (p[0] == '\0')
break;
strcat(res, "\\");
strncat(res, p++, 1);
}
strcat(res, "\"");
return res;
}
struct sym_match {
struct symbol *sym;
off_t so, eo;
};
/* Compare matched symbols as thus:
* - first, symbols that match exactly
* - then, alphabetical sort
*/
static int sym_rel_comp(const void *sym1, const void *sym2)
{
const struct sym_match *s1 = sym1;
const struct sym_match *s2 = sym2;
int exact1, exact2;
/* Exact match:
* - if matched length on symbol s1 is the length of that symbol,
* then this symbol should come first;
* - if matched length on symbol s2 is the length of that symbol,
* then this symbol should come first.
* Note: since the search can be a regexp, both symbols may match
* exactly; if this is the case, we can't decide which comes first,
* and we fallback to sorting alphabetically.
*/
exact1 = (s1->eo - s1->so) == strlen(s1->sym->name);
exact2 = (s2->eo - s2->so) == strlen(s2->sym->name);
if (exact1 && !exact2)
return -1;
if (!exact1 && exact2)
return 1;
/* As a fallback, sort symbols alphabetically */
return strcmp(s1->sym->name, s2->sym->name);
}
struct symbol **sym_re_search(const char *pattern)
{
struct symbol *sym, **sym_arr = NULL;
struct sym_match *sym_match_arr = NULL;
int i, cnt, size;
regex_t re;
regmatch_t match[1];
cnt = size = 0;
/* Skip if empty */
if (strlen(pattern) == 0)
return NULL;
if (regcomp(&re, pattern, REG_EXTENDED|REG_ICASE))
return NULL;
for_all_symbols(i, sym) {
if (sym->flags & SYMBOL_CONST || !sym->name)
continue;
if (regexec(&re, sym->name, 1, match, 0))
continue;
if (cnt >= size) {
void *tmp;
size += 16;
tmp = realloc(sym_match_arr, size * sizeof(struct sym_match));
if (!tmp)
goto sym_re_search_free;
sym_match_arr = tmp;
}
sym_calc_value(sym);
/* As regexec returned 0, we know we have a match, so
* we can use match[0].rm_[se]o without further checks
*/
sym_match_arr[cnt].so = match[0].rm_so;
sym_match_arr[cnt].eo = match[0].rm_eo;
sym_match_arr[cnt++].sym = sym;
}
if (sym_match_arr) {
qsort(sym_match_arr, cnt, sizeof(struct sym_match), sym_rel_comp);
sym_arr = malloc((cnt+1) * sizeof(struct symbol *));
if (!sym_arr)
goto sym_re_search_free;
for (i = 0; i < cnt; i++)
sym_arr[i] = sym_match_arr[i].sym;
sym_arr[cnt] = NULL;
}
sym_re_search_free:
/* sym_match_arr can be NULL if no match, but free(NULL) is OK */
free(sym_match_arr);
regfree(&re);
return sym_arr;
}
/*
* When we check for recursive dependencies we use a stack to save
* current state so we can print out relevant info to user.
* The entries are located on the call stack so no need to free memory.
* Note insert() remove() must always match to properly clear the stack.
*/
static struct dep_stack {
struct dep_stack *prev, *next;
struct symbol *sym;
struct property *prop;
struct expr **expr;
} *check_top;
static void dep_stack_insert(struct dep_stack *stack, struct symbol *sym)
{
memset(stack, 0, sizeof(*stack));
if (check_top)
check_top->next = stack;
stack->prev = check_top;
stack->sym = sym;
check_top = stack;
}
static void dep_stack_remove(void)
{
check_top = check_top->prev;
if (check_top)
check_top->next = NULL;
}
/*
* Called when we have detected a recursive dependency.
* check_top point to the top of the stact so we use
* the ->prev pointer to locate the bottom of the stack.
*/
static void sym_check_print_recursive(struct symbol *last_sym)
{
struct dep_stack *stack;
struct symbol *sym, *next_sym;
struct menu *menu = NULL;
struct property *prop;
struct dep_stack cv_stack;
if (sym_is_choice_value(last_sym)) {
dep_stack_insert(&cv_stack, last_sym);
last_sym = prop_get_symbol(sym_get_choice_prop(last_sym));
}
for (stack = check_top; stack != NULL; stack = stack->prev)
if (stack->sym == last_sym)
break;
if (!stack) {
fprintf(stderr, "unexpected recursive dependency error\n");
return;
}
for (; stack; stack = stack->next) {
sym = stack->sym;
next_sym = stack->next ? stack->next->sym : last_sym;
prop = stack->prop;
if (prop == NULL)
prop = stack->sym->prop;
/* for choice values find the menu entry (used below) */
if (sym_is_choice(sym) || sym_is_choice_value(sym)) {
for (prop = sym->prop; prop; prop = prop->next) {
menu = prop->menu;
if (prop->menu)
break;
}
}
if (stack->sym == last_sym)
fprintf(stderr, "%s:%d:error: recursive dependency detected!\n",
prop->file->name, prop->lineno);
if (sym_is_choice(sym)) {
fprintf(stderr, "%s:%d:\tchoice %s contains symbol %s\n",
menu->file->name, menu->lineno,
sym->name ? sym->name : "<choice>",
next_sym->name ? next_sym->name : "<choice>");
} else if (sym_is_choice_value(sym)) {
fprintf(stderr, "%s:%d:\tsymbol %s is part of choice %s\n",
menu->file->name, menu->lineno,
sym->name ? sym->name : "<choice>",
next_sym->name ? next_sym->name : "<choice>");
} else if (stack->expr == &sym->dir_dep.expr) {
fprintf(stderr, "%s:%d:\tsymbol %s depends on %s\n",
prop->file->name, prop->lineno,
sym->name ? sym->name : "<choice>",
next_sym->name ? next_sym->name : "<choice>");
} else if (stack->expr == &sym->rev_dep.expr) {
fprintf(stderr, "%s:%d:\tsymbol %s is selected by %s\n",
prop->file->name, prop->lineno,
sym->name ? sym->name : "<choice>",
next_sym->name ? next_sym->name : "<choice>");
} else if (stack->expr == &sym->implied.expr) {
fprintf(stderr, "%s:%d:\tsymbol %s is implied by %s\n",
prop->file->name, prop->lineno,
sym->name ? sym->name : "<choice>",
next_sym->name ? next_sym->name : "<choice>");
} else if (stack->expr) {
fprintf(stderr, "%s:%d:\tsymbol %s %s value contains %s\n",
prop->file->name, prop->lineno,
sym->name ? sym->name : "<choice>",
prop_get_type_name(prop->type),
next_sym->name ? next_sym->name : "<choice>");
} else {
fprintf(stderr, "%s:%d:\tsymbol %s %s is visible depending on %s\n",
prop->file->name, prop->lineno,
sym->name ? sym->name : "<choice>",
prop_get_type_name(prop->type),
next_sym->name ? next_sym->name : "<choice>");
}
}
fprintf(stderr,
"For a resolution refer to Documentation/kbuild/kconfig-language.txt\n"
"subsection \"Kconfig recursive dependency limitations\"\n"
"\n");
if (check_top == &cv_stack)
dep_stack_remove();
}
static struct symbol *sym_check_expr_deps(struct expr *e)
{
struct symbol *sym;
if (!e)
return NULL;
switch (e->type) {
case E_OR:
case E_AND:
sym = sym_check_expr_deps(e->left.expr);
if (sym)
return sym;
return sym_check_expr_deps(e->right.expr);
case E_NOT:
return sym_check_expr_deps(e->left.expr);
case E_EQUAL:
case E_GEQ:
case E_GTH:
case E_LEQ:
case E_LTH:
case E_UNEQUAL:
sym = sym_check_deps(e->left.sym);
if (sym)
return sym;
return sym_check_deps(e->right.sym);
case E_SYMBOL:
return sym_check_deps(e->left.sym);
default:
break;
}
fprintf(stderr, "Oops! How to check %d?\n", e->type);
return NULL;
}
/* return NULL when dependencies are OK */
static struct symbol *sym_check_sym_deps(struct symbol *sym)
{
struct symbol *sym2;
struct property *prop;
struct dep_stack stack;
dep_stack_insert(&stack, sym);
stack.expr = &sym->dir_dep.expr;
sym2 = sym_check_expr_deps(sym->dir_dep.expr);
if (sym2)
goto out;
stack.expr = &sym->rev_dep.expr;
sym2 = sym_check_expr_deps(sym->rev_dep.expr);
if (sym2)
goto out;
stack.expr = &sym->implied.expr;
sym2 = sym_check_expr_deps(sym->implied.expr);
if (sym2)
goto out;
stack.expr = NULL;
for (prop = sym->prop; prop; prop = prop->next) {
if (prop->type == P_CHOICE || prop->type == P_SELECT ||
prop->type == P_IMPLY)
continue;
stack.prop = prop;
sym2 = sym_check_expr_deps(prop->visible.expr);
if (sym2)
break;
if (prop->type != P_DEFAULT || sym_is_choice(sym))
continue;
stack.expr = &prop->expr;
sym2 = sym_check_expr_deps(prop->expr);
if (sym2)
break;
stack.expr = NULL;
}
out:
dep_stack_remove();
return sym2;
}
static struct symbol *sym_check_choice_deps(struct symbol *choice)
{
struct symbol *sym, *sym2;
struct property *prop;
struct expr *e;
struct dep_stack stack;
dep_stack_insert(&stack, choice);
prop = sym_get_choice_prop(choice);
expr_list_for_each_sym(prop->expr, e, sym)
sym->flags |= (SYMBOL_CHECK | SYMBOL_CHECKED);
choice->flags |= (SYMBOL_CHECK | SYMBOL_CHECKED);
sym2 = sym_check_sym_deps(choice);
choice->flags &= ~SYMBOL_CHECK;
if (sym2)
goto out;
expr_list_for_each_sym(prop->expr, e, sym) {
sym2 = sym_check_sym_deps(sym);
if (sym2)
break;
}
out:
expr_list_for_each_sym(prop->expr, e, sym)
sym->flags &= ~SYMBOL_CHECK;
if (sym2 && sym_is_choice_value(sym2) &&
prop_get_symbol(sym_get_choice_prop(sym2)) == choice)
sym2 = choice;
dep_stack_remove();
return sym2;
}
struct symbol *sym_check_deps(struct symbol *sym)
{
struct symbol *sym2;
struct property *prop;
if (sym->flags & SYMBOL_CHECK) {
sym_check_print_recursive(sym);
return sym;
}
if (sym->flags & SYMBOL_CHECKED)
return NULL;
if (sym_is_choice_value(sym)) {
struct dep_stack stack;
/* for choice groups start the check with main choice symbol */
dep_stack_insert(&stack, sym);
prop = sym_get_choice_prop(sym);
sym2 = sym_check_deps(prop_get_symbol(prop));
dep_stack_remove();
} else if (sym_is_choice(sym)) {
sym2 = sym_check_choice_deps(sym);
} else {
sym->flags |= (SYMBOL_CHECK | SYMBOL_CHECKED);
sym2 = sym_check_sym_deps(sym);
sym->flags &= ~SYMBOL_CHECK;
}
return sym2;
}
struct property *prop_alloc(enum prop_type type, struct symbol *sym)
{
struct property *prop;
struct property **propp;
prop = xmalloc(sizeof(*prop));
memset(prop, 0, sizeof(*prop));
prop->type = type;
prop->sym = sym;
prop->file = current_file;
prop->lineno = zconf_lineno();
/* append property to the prop list of symbol */
if (sym) {
for (propp = &sym->prop; *propp; propp = &(*propp)->next)
;
*propp = prop;
}
return prop;
}
struct symbol *prop_get_symbol(struct property *prop)
{
if (prop->expr && (prop->expr->type == E_SYMBOL ||
prop->expr->type == E_LIST))
return prop->expr->left.sym;
return NULL;
}
const char *prop_get_type_name(enum prop_type type)
{
switch (type) {
case P_PROMPT:
return "prompt";
case P_COMMENT:
return "comment";
case P_MENU:
return "menu";
case P_DEFAULT:
return "default";
case P_CHOICE:
return "choice";
case P_SELECT:
return "select";
case P_IMPLY:
return "imply";
case P_RANGE:
return "range";
case P_SYMBOL:
return "symbol";
case P_UNKNOWN:
break;
}
return "unknown";
}