shaba/lvm2
1
0
Fork 0
mirror of git://sourceware.org/git/lvm2.git synced 2024-12-21 13:34:40 +03:00
Code Releases Activity
e08e5a5a07
lvm2/tools/man-generator.c
Zdenek Kabelac bebbb1e66a command: use command_id_to_enum 
Instead of storing command_id as string, direcly
translate string to enum index and use 'command_enum()'
to get string when needed for printing.

This way we can easily detect error in the structure
while parsing it - and we can later avoid separate
'translation' loop.
2024-05-13 02:15:55 +02:00

1804 lines
45 KiB
C
Raw Blame History

/*
* Copyright (C) 2024 Red Hat, Inc. All rights reserved.
*
* This file is part of LVM2.
*
* This copyrighted material is made available to anyone wishing to use,
* modify, copy, or redistribute it subject to the terms and conditions
* of the GNU Lesser General Public License v.2.1.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include <sys/types.h>
#include <stdint.h>
#include <string.h>
#include <stdlib.h>
#include <getopt.h>
#define stack
struct cmd_context {
void *libmem;
};
#define log_error(fmt, args...) \
do { \
printf(fmt "\n", ##args); \
} while (0)
#define dm_snprintf snprintf
static int dm_strncpy(char *dest, const char *src, size_t n)
{
if (memccpy(dest, src, 0, n))
return 1;
if (n > 0)
dest[n - 1] = '\0';
return 0;
}
static inline int _dm_strncpy(char *dest, const char *src, size_t n) {
return dm_strncpy(dest, src, n);
}
static char *dm_pool_strdup(void *p, const char *str)
{
return strdup(str);
}
static void *dm_pool_alloc(void *p, size_t size)
{
return malloc(size);
}
/* needed to include args.h */
#define ARG_COUNTABLE 0x00000001
#define ARG_GROUPABLE 0x00000002
#define ARG_NONINTERACTIVE 0x00000004
struct arg_values;
/* needed to include vals.h */
static inline int yes_no_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int activation_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int cachemetadataformat_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int cachemode_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int discards_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int mirrorlog_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int size_kb_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int ssize_kb_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int size_mb_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int ssize_mb_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int psize_mb_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int nsize_mb_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int int_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int uint32_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int int_arg_with_sign(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int int_arg_with_plus(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int extents_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int sextents_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int pextents_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int nextents_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int string_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int tag_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int permission_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int metadatatype_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int segtype_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int alloc_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int locktype_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int readahead_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int regionsize_mb_arg(struct cmd_context *cmd, struct arg_values *av) { return 0; }
static inline int vgmetadatacopies_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int pvmetadatacopies_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int metadatacopies_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int polloperation_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int writemostly_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int syncaction_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int reportformat_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int configreport_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int configtype_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int repairtype_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int dumptype_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
static inline int headings_arg(struct cmd_context *cmd __attribute__((unused)), struct arg_values *av) { return 0; }
#define MAN_PAGE_GENERATOR
#include "command_enums.h"
#include "command.c"
static const size_t _LONG_LINE = 42; /* length of line that neededs .nh .. .hy */
static const char *_lvt_enum_to_name(int lvt_enum)
{
return lv_types[lvt_enum].name;
}
static int _get_val_enum(const struct command_name *cname, int opt_enum)
{
return _update_relative_opt(cname->name, opt_enum, opt_names[opt_enum].val_enum);
}
/*
* FIXME: this just replicates the val usage strings
* that officially lives in vals.h. Should there
* be some programatic way to add man markup to
* the strings in vals.h without replicating it?
* Otherwise, this function has to be updated in
* sync with any string changes in vals.h
*/
static void _print_val_man(const struct command_name *cname, int opt_enum, int val_enum)
{
const char *str;
char *line;
char *line_argv[MAX_LINE_ARGC];
int line_argc;
int i;
_was_hyphen = 0;
switch (val_enum) {
case sizemb_VAL:
printf("\\fISize\\fP[m|UNIT]");
return;
case ssizemb_VAL:
printf("[\\fB+\\fP|\\fB-\\fP]\\fISize\\fP[m|UNIT]");
return;
case psizemb_VAL:
printf("[\\fB+\\fP]\\fISize\\fP[m|UNIT]");
return;
case nsizemb_VAL:
printf("[\\fB-\\fP]\\fISize\\fP[m|UNIT]");
return;
case extents_VAL:
printf("\\fINumber\\fP[PERCENT]");
return;
case sextents_VAL:
printf("[\\fB+\\fP|\\fB-\\fP]\\fINumber\\fP[PERCENT]");
return;
case pextents_VAL:
printf("[\\fB+\\fP]\\fINumber\\fP[PERCENT]");
return;
case nextents_VAL:
printf("[\\fB-\\fP]\\fINumber\\fP[PERCENT]");
return;
case sizekb_VAL:
printf("\\fISize\\fP[k|UNIT]");
return;
case ssizekb_VAL:
printf("[\\fB+\\fP|\\fB-\\fP]\\fISize\\fP[k|UNIT]");
return;
case regionsizemb_VAL:
printf("\\fISize\\fP[m|UNIT]");
return;
case snumber_VAL:
printf("[\\fB+\\fP|\\fB-\\fP]\\fINumber\\fP");
return;
case pnumber_VAL:
printf("[\\fB+\\fP]\\fINumber\\fP");
return;
}
str = val_names[val_enum].usage;
if (!str)
str = val_names[val_enum].name;
if (!strcmp(str, "PV[:t|n|y]")) {
printf("\\fIPV\\fP[\\fB:t\\fP|\\fBn\\fP|\\fBy\\fP]");
return;
}
if (!strcmp(str, "Number") ||
!strcmp(str, "String") ||
!strncmp(str, "VG", 2) ||
!strncmp(str, "LV", 2) ||
!strncmp(str, "PV", 2) ||
!strcmp(str, "Tag")) {
printf("\\fI%s\\fP", str);
return;
}
if (strchr(str, '|')) {
if (!(line = strdup(str)))
return;
if ((_was_hyphen = (strlen(line) > _LONG_LINE)))
/* TODO: prevent line to end with already printed space */
printf("\\c\n.nh\n\\%%");
_split_line(line, &line_argc, line_argv, '|');
for (i = 0; i < line_argc; i++) {
if (i)
printf("|%s", _was_hyphen ? "\\:" : "");
if (strncmp(line_argv[i], "[Number]", 8) == 0) {
printf("[\\fINumber\\fP]");
line_argv[i] += 8;
}
if (strstr(line_argv[i], "Number"))
printf("\\fI%s\\fP", line_argv[i]);
else
printf("\\fB%s\\fP", line_argv[i]);
}
if (_was_hyphen)
printf("\n.hy");
free(line);
return;
}
printf("\\fB%s\\fP", str);
}
static void _print_def_man(const struct command_name *cname, int opt_enum, struct arg_def *def, int usage, uint64_t *lv_type_bits)
{
int val_enum, tmp_val;
int sep = 0;
if (lv_type_bits)
*lv_type_bits = 0;
for (val_enum = 0; val_enum < VAL_COUNT; val_enum++) {
if (def->val_bits & val_enum_to_bit(val_enum)) {
if (val_enum == conststr_VAL)
printf("\\fB%s\\fP", def->str);
else if (val_enum == constnum_VAL)
printf("\\fB%llu\\fP", (unsigned long long)def->num);
else {
if (sep) printf("|");
if (!usage || !val_names[val_enum].usage) {
if (_was_hyphen) {
printf("\n");
_was_hyphen = 0;
}
/* special case to print LV1 instead of LV */
if ((val_enum == lv_VAL) && def->lvt_bits && lv_type_bits) {
printf("\\fILV1\\fP");
*lv_type_bits = def->lvt_bits;
} else {
printf("\\fI%s\\fP", val_names[val_enum].name);
}
} else {
tmp_val = _update_relative_opt(cname->name, opt_enum, val_enum);
_print_val_man(cname, opt_enum, tmp_val);
}
sep = 1;
}
if (((val_enum == vg_VAL) && (def->flags & ARG_DEF_FLAG_NEW_VG)) ||
((val_enum == lv_VAL) && (def->flags & ARG_DEF_FLAG_NEW_LV)))
printf("\\fI_new\\fP");
}
}
if (def->flags & ARG_DEF_FLAG_MAY_REPEAT)
printf(" ...");
}
#define LONG_OPT_NAME_LEN 64
static const char *_man_long_opt_name(const char *cmdname, int opt_enum)
{
static char _long_opt_name[LONG_OPT_NAME_LEN];
const char *long_opt;
unsigned i;
memset(&_long_opt_name, 0, sizeof(_long_opt_name));
switch (opt_enum) {
case syncaction_ARG:
long_opt = "--[raid]syncaction";
break;
case writemostly_ARG:
long_opt = "--[raid]writemostly";
break;
case minrecoveryrate_ARG:
long_opt = "--[raid]minrecoveryrate";
break;
case maxrecoveryrate_ARG:
long_opt = "--[raid]maxrecoveryrate";
break;
case writebehind_ARG:
long_opt = "--[raid]writebehind";
break;
case vgmetadatacopies_ARG:
if (!strncmp(cmdname, "vg", 2))
long_opt = "--[vg]metadatacopies";
else
long_opt = "--vgmetadatacopies";
break;
case pvmetadatacopies_ARG:
if (!strncmp(cmdname, "pv", 2))
long_opt = "--[pv]metadatacopies";
else
long_opt = "--pvmetadatacopies";
break;
default:
long_opt = opt_names[opt_enum].long_opt;
break;
}
if (strchr(long_opt, '[')) {
for (i = 0; *long_opt && i < sizeof(_long_opt_name) - 1; ++long_opt, ++i) {
if (i < (sizeof(_long_opt_name) - 8))
switch(*long_opt) {
case '[':
memcpy(_long_opt_name + i, "\\fP[\\fB", 7);
i += 6; // 6 + 1
continue;
case ']':
memcpy(_long_opt_name + i, "\\fP]\\fB", 7);
i += 6; // 6 + 1
continue;
}
_long_opt_name[i] = *long_opt;
}
_long_opt_name[i] = 0;
return _long_opt_name;
}
return long_opt;
}
static void _print_man_usage(char *lvmname, struct command *cmd)
{
const struct command_name *cname = &command_names[cmd->lvm_command_enum];
const struct command_name_args *cna = &command_names_args[cmd->lvm_command_enum];
int any_req = (cmd->cmd_flags & CMD_FLAG_ANY_REQUIRED_OPT) ? 1 : 0;
int sep, ro, rp, oo, op, opt_enum;
int need_ro_indent_end = 0;
int include_extents = 0;
int lvt_enum;
uint64_t lv_type_bits = 0;
_was_hyphen = 0;
printf("\\fB%s\\fP", lvmname);
if (!any_req)
goto ro_normal;
/*
* required options that follow command name, all required
*/
if (cmd->ro_count) {
sep = 0;
for (ro = 0; ro < cmd->ro_count; ro++) {
/* avoid long line wrapping */
if ((cmd->ro_count > 2) && (sep == 2)) {
printf("\n.RS 5\n");
need_ro_indent_end = 1;
}
opt_enum = cmd->required_opt_args[ro].opt;
if ((opt_enum == size_ARG) && command_has_alternate_extents(cmd->name))
include_extents = 1;
if (opt_names[opt_enum].short_opt) {
printf(" \\fB-%c\\fP|\\fB%s\\fP",
opt_names[opt_enum].short_opt,
_man_long_opt_name(cmd->name, opt_enum));
} else
printf(" \\fB%s\\fP", opt_names[cmd->required_opt_args[ro].opt].long_opt);
if (cmd->required_opt_args[ro].def.val_bits) {
printf(" ");
_print_def_man(cname, opt_enum, &cmd->required_opt_args[ro].def, 1, NULL);
}
sep++;
}
}
/*
* one required option in a set, print as:
* ( -a|--a,
* -b|--b,
* --c,
* --d )
*
* First loop through ro prints those with short opts,
* and the second loop prints those without short opts.
*/
if (cmd->any_ro_count) {
printf("\n");
printf(".RS 4\n");
printf("(");
sep = 0;
/* print required options with a short opt */
for (ro = cmd->ro_count; ro < cmd->ro_count + cmd->any_ro_count; ro++) {
opt_enum = cmd->required_opt_args[ro].opt;
if (!opt_names[opt_enum].short_opt)
continue;
if (sep) {
printf("\n.br\n");
printf(" ");
}
if (opt_names[opt_enum].short_opt) {
printf(" \\fB-%c\\fP|\\fB%s\\fP",
opt_names[opt_enum].short_opt,
_man_long_opt_name(cmd->name, opt_enum));
} else {
printf(" ");
printf(" \\fB%s\\fP", _man_long_opt_name(cmd->name, opt_enum));
}
if (cmd->required_opt_args[ro].def.val_bits) {
printf(" ");
_print_def_man(cname, opt_enum, &cmd->required_opt_args[ro].def, 1, NULL);
}
sep++;
}
/* print required options without a short opt */
for (ro = cmd->ro_count; ro < cmd->ro_count + cmd->any_ro_count; ro++) {
opt_enum = cmd->required_opt_args[ro].opt;
if (opt_names[opt_enum].short_opt)
continue;
if (sep) {
printf("\n.br\n");
printf(" ");
} else
printf(".ad l\n");
printf(" ");
printf(" \\fB%s\\fP", _man_long_opt_name(cmd->name, opt_enum));
if (cmd->required_opt_args[ro].def.val_bits) {
printf(" ");
_print_def_man(cname, opt_enum, &cmd->required_opt_args[ro].def, 1, NULL);
}
sep++;
}
printf_hyphen(')');
printf(".RE\n");
}
/* print required position args on a new line after the any_req set */
if (cmd->rp_count) {
printf(".RS 4\n");
for (rp = 0; rp < cmd->rp_count; rp++) {
if (cmd->required_pos_args[rp].def.val_bits) {
printf(" ");
_print_def_man(cname, 0, &cmd->required_pos_args[rp].def, 1, NULL);
}
}
printf("\n");
printf(".RE\n");
} else {
/* printf("\n"); */
}
printf(".br\n");
goto oo_count;
ro_normal:
/*
* all are required options, print as:
* -a|--aaa <val> -b|--bbb <val>
*/
if (cmd->ro_count) {
sep = 0;
for (ro = 0; ro < cmd->ro_count; ro++) {
/* avoid long line wrapping */
if ((cmd->ro_count > 2) && (sep == 2)) {
printf("\n.RS 5\n");
need_ro_indent_end = 1;
}
opt_enum = cmd->required_opt_args[ro].opt;
if ((opt_enum == size_ARG) && command_has_alternate_extents(cmd->name))
include_extents = 1;
if (opt_names[opt_enum].short_opt) {
printf(" \\fB-%c\\fP|\\fB%s\\fP",
opt_names[opt_enum].short_opt,
_man_long_opt_name(cmd->name, opt_enum));
} else
printf(" \\fB%s\\fP", opt_names[cmd->required_opt_args[ro].opt].long_opt);
if (cmd->required_opt_args[ro].def.val_bits) {
printf(" ");
_print_def_man(cname, opt_enum, &cmd->required_opt_args[ro].def, 1, NULL);
}
sep++;
}
}
/* print required position args on the same line as the required options */
if (cmd->rp_count) {
for (rp = 0; rp < cmd->rp_count; rp++) {
if (cmd->required_pos_args[rp].def.val_bits) {
printf(" ");
/* Only print lv_type_bits for one LV arg (no cases exist with more) */
_print_def_man(cname, 0, &cmd->required_pos_args[rp].def, 1, lv_type_bits ? NULL : &lv_type_bits);
}
}
printf("\n");
} else {
printf("\n");
}
if (need_ro_indent_end)
printf(".RE\n");
printf(".br\n");
oo_count:
if (!cmd->oo_count)
goto op_count;
sep = 0;
if (cmd->oo_count) {
printf(".RS 4\n");
printf(".ad l\n");
if (cmd->autotype) {
if (!cmd->autotype2)
printf("[ \\fB--type %s\\fP ] (implied)\n", cmd->autotype);
else
printf("[ \\fB--type %s\\fP|\\fB%s\\fP ] (implied)\n", cmd->autotype, cmd->autotype2);
printf(".br\n");
sep = 1;
}
if (include_extents) {
/*
* NB we don't just pass extents_VAL here because the
* actual val type for extents_ARG has been adjusted
* in opt_names[] according to the command name.
*/
printf("[ \\fB-l\\fP|\\fB--extents\\fP ");
_print_val_man(cname, extents_ARG, _get_val_enum(cname, extents_ARG));
printf_hyphen(']');
sep = 1;
}
/* print optional options with short opts */
for (oo = 0; oo < cmd->oo_count; oo++) {
opt_enum = cmd->optional_opt_args[oo].opt;
if (!opt_names[opt_enum].short_opt)
continue;
if (_is_lvm_all_opt(opt_enum))
continue;
if ((cna->variants > 1) && cna->common_options[opt_enum])
continue;
if (sep)
printf(".br\n");
printf("[ \\fB-%c\\fP|\\fB%s\\fP",
opt_names[opt_enum].short_opt,
_man_long_opt_name(cmd->name, opt_enum));
if (cmd->optional_opt_args[oo].def.val_bits) {
printf(" ");
_print_def_man(cname, opt_enum, &cmd->optional_opt_args[oo].def, 1, NULL);
}
printf_hyphen(']');
sep = 1;
}
/* print optional options without short opts */
for (oo = 0; oo < cmd->oo_count; oo++) {
opt_enum = cmd->optional_opt_args[oo].opt;
if (opt_names[opt_enum].short_opt)
continue;
if (_is_lvm_all_opt(opt_enum))
continue;
if ((cna->variants > 1) && cna->common_options[opt_enum])
continue;
if (sep)
printf(".br\n");
/* space alignment without short opt */
printf("[ ");
printf(" \\fB%s\\fP", _man_long_opt_name(cmd->name, opt_enum));
if (cmd->optional_opt_args[oo].def.val_bits) {
printf(" ");
_print_def_man(cname, opt_enum, &cmd->optional_opt_args[oo].def, 1, NULL);
}
printf_hyphen(']');
sep = 1;
}
if (sep) {
printf(".br\n");
/* space alignment without short opt */
/* printf(" "); */
}
printf("[ COMMON_OPTIONS ]\n");
printf(".ad b\n");
printf(".RE\n");
}
op_count:
if (!cmd->op_count)
goto out;
printf(".RS 4\n");
printf("[");
if (cmd->op_count) {
for (op = 0; op < cmd->op_count; op++) {
if (cmd->optional_pos_args[op].def.val_bits) {
printf(" ");
_print_def_man(cname, 0, &cmd->optional_pos_args[op].def, 1, NULL);
}
}
}
printf_hyphen(']');
printf(".RE\n");
out:
printf(".P\n");
if (!lv_type_bits)
return;
printf(".RS 4\n");
if (lv_type_bits) {
printf("LV1 types:");
for (lvt_enum = 1; lvt_enum < LVT_COUNT; lvt_enum++) {
if (lvt_bit_is_set(lv_type_bits, lvt_enum))
printf(" %s", _lvt_enum_to_name(lvt_enum));
}
printf("\n");
}
printf(".RE\n");
printf(".P\n");
}
/*
* common options listed in the usage section.
*
* For commands with only one variant, this is only
* the options which are common to all lvm commands
* (in lvm_all, see _is_lvm_all_opt).
*
* For commands with more than one variant, this
* is the set of options common to all variants
* (in cname->common_options), (which obviously
* includes the options common to all lvm commands.)
*
* List ordering:
* options with short+long names, alphabetically,
* then options with only long names, alphabetically
*/
static void _print_man_usage_common_lvm(struct command *cmd)
{
const struct command_name *cname = &command_names[cmd->lvm_command_enum];
int i, sep, oo, opt_enum;
printf("Common options for lvm:\n");
printf(".\n");
sep = 0;
printf(".RS 4\n");
printf(".ad l\n");
/* print those with short opts */
for (i = 0; i < ARG_COUNT; i++) {
opt_enum = opt_names_alpha[i]->opt_enum;
if (!opt_names[opt_enum].short_opt)
continue;
if (!_is_lvm_all_opt(opt_enum))
continue;
if (sep)
printf(".br\n");
for (oo = 0; oo < cmd->oo_count; oo++) {
if (cmd->optional_opt_args[oo].opt != opt_enum)
continue;
printf("[ \\fB-%c\\fP|\\fB%s\\fP",
opt_names[opt_enum].short_opt,
_man_long_opt_name(cmd->name, opt_enum));
if (cmd->optional_opt_args[oo].def.val_bits) {
printf(" ");
_print_def_man(cname, opt_enum, &cmd->optional_opt_args[oo].def, 1, NULL);
}
printf_hyphen(']');
sep = 1;
break;
}
}
/* print those without short opts */
for (i = 0; i < ARG_COUNT; i++) {
opt_enum = opt_names_alpha[i]->opt_enum;
if (opt_names[opt_enum].short_opt)
continue;
if (!_is_lvm_all_opt(opt_enum))
continue;
if (sep)
printf(".br\n");
for (oo = 0; oo < cmd->oo_count; oo++) {
if (cmd->optional_opt_args[oo].opt != opt_enum)
continue;
/* space alignment without short opt */
printf("[ ");
printf(" \\fB%s\\fP", _man_long_opt_name(cmd->name, opt_enum));
if (cmd->optional_opt_args[oo].def.val_bits) {
printf(" ");
_print_def_man(cname, opt_enum, &cmd->optional_opt_args[oo].def, 1, NULL);
}
printf_hyphen(']');
sep = 1;
break;
}
}
printf(".ad b\n");
printf(".RE\n");
}
static void _print_man_usage_common_cmd(struct command *cmd)
{
const struct command_name *cname = &command_names[cmd->lvm_command_enum];
const struct command_name_args *cna = &command_names_args[cmd->lvm_command_enum];
int i, sep, oo, opt_enum;
int found_common_command = 0;
if (cna->variants < 2)
return;
for (opt_enum = 0; opt_enum < ARG_COUNT; opt_enum++) {
if (!cna->common_options[opt_enum])
continue;
if (_is_lvm_all_opt(opt_enum))
continue;
found_common_command = 1;
break;
}
if (!found_common_command)
return;
printf("Common options for command:\n");
printf(".\n");
sep = 0;
printf(".RS 4\n");
printf(".ad l\n");
/* print those with short opts */
for (i = 0; i < ARG_COUNT; i++) {
opt_enum = opt_names_alpha[i]->opt_enum;
if (!cna->common_options[opt_enum])
continue;
if (!opt_names[opt_enum].short_opt)
continue;
/* common cmd options only used with variants */
if (cna->variants < 2)
continue;
if (_is_lvm_all_opt(opt_enum))
continue;
if (sep)
printf(".br\n");
for (oo = 0; oo < cmd->oo_count; oo++) {
if (cmd->optional_opt_args[oo].opt != opt_enum)
continue;
printf("[ \\fB-%c\\fP|\\fB%s\\fP",
opt_names[opt_enum].short_opt,
_man_long_opt_name(cmd->name, opt_enum));
if (cmd->optional_opt_args[oo].def.val_bits) {
printf(" ");
_print_def_man(cname, opt_enum, &cmd->optional_opt_args[oo].def, 1, NULL);
}
printf_hyphen(']');
sep = 1;
break;
}
}
/* print those without short opts */
for (i = 0; i < ARG_COUNT; i++) {
opt_enum = opt_names_alpha[i]->opt_enum;
if (!cna->common_options[opt_enum])
continue;
if (opt_names[opt_enum].short_opt)
continue;
/* common cmd options only used with variants */
if (cna->variants < 2)
continue;
if (_is_lvm_all_opt(opt_enum))
continue;
if (sep)
printf(".br\n");
for (oo = 0; oo < cmd->oo_count; oo++) {
if (cmd->optional_opt_args[oo].opt != opt_enum)
continue;
/* space alignment without short opt */
printf("[ ");
printf(" \\fB%s\\fP", _man_long_opt_name(cmd->name, opt_enum));
if (cmd->optional_opt_args[oo].def.val_bits) {
printf(" ");
_print_def_man(cname, opt_enum, &cmd->optional_opt_args[oo].def, 1, NULL);
}
printf_hyphen(']');
sep = 1;
break;
}
}
printf(".ad b\n");
printf(".RE\n");
printf(".P\n");
}
/*
* Format of description, when different command names have
* different descriptions:
*
* "#cmdname1"
* "text foo goes here"
* "a second line of text."
* "#cmdname2"
* "text bar goes here"
* "another line of text."
*
* When called for cmdname2, this function should just print:
*
* "text bar goes here"
* "another line of text."
*/
static void _print_man_option_desc(const struct command_name *cname, int opt_enum)
{
const char *desc = opt_names[opt_enum].desc;
char buf[DESC_LINE];
int started_cname = 0;
int line_count = 0;
int bi = 0;
unsigned di;
if (desc[0] != '#') {
printf("%s", desc);
return;
}
for (di = 0; desc[di]; di++) {
buf[bi++] = desc[di];
if (bi == DESC_LINE) {
log_error("Parsing command defs: print_man_option_desc line too long.");
exit(EXIT_FAILURE);
}
if (buf[bi-1] != '\n')
continue;
if (buf[0] != '#') {
if (started_cname) {
printf("%s", buf);
line_count++;
}
memset(buf, 0, sizeof(buf));
bi = 0;
continue;
}
/* Line starting with #cmdname */
/*
* Must be starting a new command name.
* If no lines have been printed, multiple command names
* are using the same text. If lines have been printed,
* then the start of a new command name means the end
* of text for the current command name.
*/
if (line_count && started_cname)
return;
if (!strncmp(buf + 1, cname->name, strlen(cname->name))) {
/* The start of our command name. */
started_cname = 1;
memset(buf, 0, sizeof(buf));
bi = 0;
} else {
/* The start of another command name. */
memset(buf, 0, sizeof(buf));
bi = 0;
}
}
if (bi && started_cname)
printf("%s", buf);
}
/*
* Print a list of all options names for a given command name.
*/
static void _print_man_all_options_list(const struct command_name *cname)
{
const struct command_name_args *cna;
int opt_enum, val_enum;
int sep = 0;
int i;
int adl = 0;
cna = &command_names_args[cname->lvm_command_enum];
for (i = 0; i < ARG_COUNT; i++) {
opt_enum = opt_names_alpha[i]->opt_enum;
if (!cna->all_options[opt_enum])
continue;
if (sep)
printf(".br\n");
if (!adl) {
printf(".ad l\n");
adl = 1;
}
if (opt_names[opt_enum].short_opt) {
printf(" \\fB-%c\\fP|\\fB%s\\fP",
opt_names[opt_enum].short_opt,
_man_long_opt_name(cname->name, opt_enum));
} else {
/* spaces for alignment without short opt */
printf(" \\fB%s\\fP", _man_long_opt_name(cname->name, opt_enum));
}
val_enum = _get_val_enum(cname, opt_enum);
if (!val_names[val_enum].fn) {
/* takes no arg */
} else if (!val_names[val_enum].usage) {
printf(" \\fI%s\\fP", val_names[val_enum].name);
} else {
printf(" ");
_print_val_man(cname, opt_enum, val_enum);
}
printf("\n");
sep = 1;
}
if (adl)
printf(".ad b\n");
}
/*
* All options used for a given command name, along with descriptions.
*/
static void _print_man_all_options_desc(const struct command_name *cname)
{
const struct command_name_args *cna;
int opt_enum, val_enum;
int i;
int adl;
cna = &command_names_args[cname->lvm_command_enum];
for (i = 0; i < ARG_COUNT; i++) {
opt_enum = opt_names_alpha[i]->opt_enum;
if (!cna->all_options[opt_enum])
continue;
val_enum = _get_val_enum(cname, opt_enum);
if (val_names[val_enum].usage &&
(strlen(val_names[val_enum].usage) > _LONG_LINE)) {
printf(".\n.HP\n");
printf(".ad l\n");
adl = 1;
} else {
/* printf(".\n.TP\n");
* ATM HTML rendering can't handle HP and TP mixing properly
* so still keeping .HP usage for this case
* untill some better workaround is found
* .TP does not need .br */
printf(".\n.HP\n");
adl = 0;
}
if (opt_names[opt_enum].short_opt) {
printf("\\fB-%c\\fP|\\fB%s\\fP",
opt_names[opt_enum].short_opt,
_man_long_opt_name(cname->name, opt_enum));
} else {
printf("\\fB%s\\fP", _man_long_opt_name(cname->name, opt_enum));
}
if (!val_names[val_enum].fn) {
/* takes no arg */
} else if (!val_names[val_enum].usage) {
printf(" \\fI%s\\fP", val_names[val_enum].name);
} else {
printf(" ");
_print_val_man(cname, opt_enum, val_enum);
}
if (opt_names[opt_enum].flags & ARG_COUNTABLE)
printf(" ...");
printf("\n");
if (adl) {
printf(".ad b\n");
}
printf(".br\n");
if (opt_names[opt_enum].desc) {
_print_man_option_desc(cname, opt_enum);
}
}
}
static void _print_man_all_positions_desc(const struct command_name *cname)
{
struct command *cmd;
int ci, rp, op;
int has_vg_val = 0;
int has_lv_val = 0;
int has_pv_val = 0;
int has_tag_val = 0;
int has_select_val = 0;
int has_lv_type = 0;
for (ci = 0; ci < COMMAND_COUNT; ci++) {
cmd = &commands[ci];
if (strcmp(cmd->name, cname->name))
continue;
for (rp = 0; rp < cmd->rp_count; rp++) {
if (cmd->required_pos_args[rp].def.val_bits & val_enum_to_bit(vg_VAL))
has_vg_val = 1;
if (cmd->required_pos_args[rp].def.val_bits & val_enum_to_bit(lv_VAL)) {
has_lv_val = 1;
if (cmd->required_pos_args[rp].def.lvt_bits)
has_lv_type = 1;
}
if (cmd->required_pos_args[rp].def.val_bits & val_enum_to_bit(pv_VAL))
has_pv_val = 1;
if (cmd->required_pos_args[rp].def.val_bits & val_enum_to_bit(tag_VAL))
has_tag_val = 1;
if (cmd->required_pos_args[rp].def.val_bits & val_enum_to_bit(select_VAL))
has_select_val = 1;
}
for (op = 0; op < cmd->op_count; op++) {
if (cmd->optional_pos_args[op].def.val_bits & val_enum_to_bit(vg_VAL))
has_vg_val = 1;
if (cmd->optional_pos_args[op].def.val_bits & val_enum_to_bit(lv_VAL)) {
has_lv_val = 1;
if (cmd->optional_pos_args[op].def.lvt_bits)
has_lv_type = 1;
}
if (cmd->optional_pos_args[op].def.val_bits & val_enum_to_bit(pv_VAL))
has_pv_val = 1;
if (cmd->optional_pos_args[op].def.val_bits & val_enum_to_bit(tag_VAL))
has_tag_val = 1;
if (cmd->optional_pos_args[op].def.val_bits & val_enum_to_bit(select_VAL))
has_select_val = 1;
}
}
if (has_vg_val) {
printf(".TP\n");
printf(".I %s\n", val_names[vg_VAL].name);
printf("Volume Group name. See \\fBlvm\\fP(8) for valid names.\n");
if (!strcmp(cname->name, "lvcreate"))
printf("For lvcreate, the required VG positional arg may be\n"
"omitted when the VG name is included in another option,\n"
"e.g. --name VG/LV.\n");
}
if (has_lv_val) {
printf(".TP\n");
printf(".I %s\n", val_names[lv_VAL].name);
printf("Logical Volume name. See \\fBlvm\\fP(8) for valid names.\n"
"An LV positional arg generally includes the VG name and LV name, e.g. VG/LV.\n");
if (has_lv_type)
printf("LV1 indicates the LV must have a specific type, where the\n"
"accepted LV types are listed. (raid represents raid<N> type).\n");
}
if (has_pv_val) {
printf(".TP\n");
printf(".I %s\n", val_names[pv_VAL].name);
printf("Physical Volume name, a device path under /dev.\n"
"For commands managing physical extents, a PV positional arg\n"
"generally accepts a suffix indicating a range (or multiple ranges)\n"
"of physical extents (PEs). When the first PE is omitted, it defaults\n"
"to the start of the device, and when the last PE is omitted it defaults to end.\n"
"Start and end range (inclusive): \\fIPV\\fP[\\fB:\\fP\\fIPE\\fP\\fB-\\fP\\fIPE\\fP]...\n"
"Start and length range (counting from 0): \\fIPV\\fP[\\fB:\\fP\\fIPE\\fP\\fB+\\fP\\fIPE\\fP]...\n");
}
if (has_tag_val) {
printf(".TP\n");
printf(".I %s\n", val_names[tag_VAL].name);
printf("Tag name. See \\fBlvm\\fP(8) for information about tag names and using tags\n"
"in place of a VG, LV or PV.\n");
}
if (has_select_val) {
printf(".TP\n");
printf(".I %s\n", val_names[select_VAL].name);
printf("Select indicates that a required positional parameter can\n"
"be omitted if the \\fB--select\\fP option is used.\n"
"No arg appears in this position.\n");
}
/* Every command uses a string arg somewhere. */
printf(".TP\n");
printf(".I %s\n", val_names[string_VAL].name);
printf("See the option description for information about the string content.\n");
/*
* We could possibly check if the command accepts any option that
* uses Size, and only print this in those cases, but this seems
* so common that we should probably always print it.
*/
printf(".TP\n");
printf(".IR Size [UNIT]\n");
printf("Size is an input number that accepts an optional unit.\n"
"Input units are always treated as base two values, regardless of\n"
"capitalization, e.g. 'k' and 'K' both refer to 1024.\n"
"The default input unit is specified by letter, followed by |UNIT.\n"
"UNIT represents other possible input units:\n"
".BR b | B\nis bytes,\n.BR s | S\nis sectors of 512 bytes,\n.BR k | K\nis KiB,\n"
".BR m | M\nis MiB,\n.BR g | G\nis GiB,\n.BR t | T\nis TiB,\n"
".BR p | P\nis PiB,\n.BR e | E\nis EiB.\n"
"(This should not be confused with the output control --units, where\n"
"capital letters mean multiple of 1000.)\n");
printf(".\n.SH ENVIRONMENT VARIABLES\n.\n");
printf("See \\fBlvm\\fP(8) for information about environment variables used by lvm.\n"
"For example, LVM_VG_NAME can generally be substituted for a required VG parameter.\n");
}
static void _print_desc_man(const char *desc)
{
char buf[DESC_LINE] = {0};
unsigned di;
int bi = 0;
for (di = 0; desc[di]; di++) {
if (desc[di] == '\n')
continue;
if (!strncmp(&desc[di], "DESC:", 5)) {
if (bi) {
printf("%s\n", buf);
printf(".br\n");
memset(buf, 0, sizeof(buf));
bi = 0;
}
di += 5;
continue;
}
if (!bi && desc[di] == ' ')
continue;
buf[bi++] = desc[di];
if (bi == (DESC_LINE - 1))
break;
}
if (bi) {
printf("%s\n", buf);
printf(".br\n");
}
}
static const char *_upper_command_name(char *str)
{
static char str_upper[32];
int i = 0;
while (*str) {
str_upper[i++] = toupper(*str);
str++;
}
str_upper[i] = '\0';
return str_upper;
}
#define MAX_MAN_DESC (1024 * 1024)
static int _include_description_file(char *name, char *des_file)
{
char *buf;
int fd, r = 0;
ssize_t sz;
struct stat statbuf = { 0 };
if ((fd = open(des_file, O_RDONLY)) < 0) {
log_error("Failed to open description file %s.", des_file);
return 0;
}
if (fstat(fd, &statbuf) < 0) {
log_error("Failed to stat description file %s.", des_file);
goto out_close;
}
if (statbuf.st_size > MAX_MAN_DESC) {
log_error("Description file %s is too large.", des_file);
goto out_close;
}
if (!(buf = malloc(statbuf.st_size + 1))) {
log_error("Failed to allocate buffer for description file %s.", des_file);
goto out_close;
}
if ((sz = read(fd, buf, statbuf.st_size)) < 0) {
log_error("Failed to read description file %s.", des_file);
goto out_free;
}
buf[sz] = '\0';
printf(".\n.SH DESCRIPTION\n.\n%s", buf);
r = 1;
out_free:
free(buf);
out_close:
(void) close(fd);
return r;
}
static int _print_man(char *name, char *des_file, int secondary)
{
const struct command_name *cname;
const struct command_name_args *cna;
struct command *cmd, *prev_cmd = NULL;
char *lvmname = name;
int i;
if (!strncmp(name, "lvm-", 4)) {
name[3] = ' ';
name += 4;
}
cname = find_command_name(name);
printf(".TH %s 8 \"LVM TOOLS #VERSION#\" \"Red Hat, Inc.\"\n",
_upper_command_name(lvmname));
for (i = 0; i < COMMAND_COUNT; i++) {
cmd = &commands[i];
if (prev_cmd && strcmp(prev_cmd->name, cmd->name)) {
_print_man_usage_common_cmd(prev_cmd);
_print_man_usage_common_lvm(prev_cmd);
printf(".\n.SH OPTIONS\n.\n");
_print_man_all_options_desc(cname);
printf(".\n.SH VARIABLES\n.\n");
_print_man_all_positions_desc(cname);
prev_cmd = NULL;
}
if (cmd->cmd_flags & CMD_FLAG_PREVIOUS_SYNTAX)
continue;
if ((cmd->cmd_flags & CMD_FLAG_SECONDARY_SYNTAX) && !secondary)
continue;
if (strcmp(name, cmd->name))
continue;
if (!prev_cmd || strcmp(prev_cmd->name, cmd->name)) {
printf(".\n.SH NAME\n.\n");
if (cname && cname->desc)
printf("%s \\(em %s\n", lvmname, cname->desc);
else
printf("%s\n", lvmname);
printf(".\n.SH SYNOPSIS\n.\n");
prev_cmd = cmd;
cname = &command_names[cmd->lvm_command_enum];
cna = &command_names_args[cmd->lvm_command_enum];
if (cna->variant_has_ro && cna->variant_has_rp)
printf("\\fB%s\\fP \\fIoption_args\\fP \\fIposition_args\\fP\n", lvmname);
else if (cna->variant_has_ro && !cna->variant_has_rp)
printf("\\fB%s\\fP \\fIoption_args\\fP\n", lvmname);
else if (!cna->variant_has_ro && cna->variant_has_rp)
printf("\\fB%s\\fP \\fIposition_args\\fP\n", lvmname);
else if (!cna->variant_has_ro && !cna->variant_has_rp)
printf("\\fB%s\\fP\n", lvmname);
printf(".br\n");
if (cna->variant_has_oo) {
printf(" [ \\fIoption_args\\fP ]\n");
printf(".br\n");
}
if (cna->variant_has_op) {
printf(" [ \\fIposition_args\\fP ]\n");
printf(".br\n");
}
/* listing them all when there's only 1 or 2 is just repetative */
if (cna->variants > 2) {
printf(".P\n");
_print_man_all_options_list(cname);
}
if (des_file && !_include_description_file(lvmname, des_file))
return 0;
printf(".\n.SH USAGE\n.\n");
}
if (cmd->desc) {
_print_desc_man(cmd->desc);
printf(".P\n");
}
_print_man_usage(lvmname, cmd);
if (i == (COMMAND_COUNT - 1)) {
_print_man_usage_common_cmd(cmd);
_print_man_usage_common_lvm(cmd);
printf(".\n.SH OPTIONS\n.\n");
_print_man_all_options_desc(cname);
printf(".\n.SH VARIABLES\n.\n");
_print_man_all_positions_desc(cname);
} else {
if (cna->variants > 2) {
printf("\\(em\n");
printf(".P\n");
}
}
}
return 1;
}
static void _print_man_secondary(char *name)
{
struct command *cmd;
char *lvmname = name;
int header = 0;
int i;
if (!strncmp(name, "lvm-", 4))
name += 4;
for (i = 0; i < COMMAND_COUNT; i++) {
cmd = &commands[i];
if (cmd->cmd_flags & CMD_FLAG_PREVIOUS_SYNTAX)
continue;
if (!(cmd->cmd_flags & CMD_FLAG_SECONDARY_SYNTAX))
continue;
if (strcmp(name, cmd->name))
continue;
if (!header) {
printf(".\n.SH ADVANCED USAGE\n.\n");
printf("Alternate command forms, advanced command usage, and listing of all valid syntax for completeness.\n");
printf(".P\n");
header = 1;
}
if (cmd->desc) {
_print_desc_man(cmd->desc);
printf(".P\n");
}
_print_man_usage(lvmname, cmd);
printf("\\(em\n");
printf(".P\n");
}
}
static void _print_opt_list(const char *prefix, int *opt_list, int opt_count)
{
int i;
int opt_enum;
printf("%s ", prefix);
for (i = 0; i < opt_count; i++) {
opt_enum = opt_list[i];
printf(" %s", opt_names[opt_enum].long_opt);
}
printf("\n");
}
/* return 1 if the lists do not match, 0 if they match */
static int _compare_opt_lists(int *list1, int count1, int *list2, int count2, const char *type1_str, const char *type2_str)
{
int i, j;
if (count1 != count2)
return 1;
for (i = 0; i < count1; i++) {
for (j = 0; j < count2; j++) {
/* lists do not match if one has --type foo and the other --type bar */
if ((list1[i] == type_ARG) && (list2[j] == type_ARG) &&
type1_str && type2_str && strcmp(type1_str, type2_str)) {
return 1;
}
if (list1[i] == list2[j])
goto next;
}
return 1;
next:
;
}
return 0;
}
static int _compare_cmds(struct command *cmd1, struct command *cmd2, int *all_req_opts)
{
const char *cmd1_type_str = NULL;
const char *cmd2_type_str = NULL;
int opt_list_1[ARG_COUNT] = { 0 };
int opt_list_2[ARG_COUNT] = { 0 };
int opt_count_1 = 0;
int opt_count_2 = 0;
int i, j;
int r = 1;
/* different number of required pos items means different cmds */
if (cmd1->rp_count != cmd2->rp_count)
return 1;
/* different types of required pos items means different cmds */
for (i = 0; i < cmd1->rp_count; i++) {
if (cmd1->required_pos_args[i].def.val_bits != cmd2->required_pos_args[i].def.val_bits)
return 1;
}
/* create opt list from cmd1 */
for (i = 0; i < cmd1->ro_count; i++) {
if (!all_req_opts[cmd1->required_opt_args[i].opt])
continue;
opt_list_1[opt_count_1++] = cmd1->required_opt_args[i].opt;
if (cmd1->required_opt_args[i].opt == type_ARG)
cmd1_type_str = cmd1->required_opt_args[i].def.str;
}
/* create opt list from cmd2 */
for (i = 0; i < cmd2->ro_count; i++) {
if (!all_req_opts[cmd2->required_opt_args[i].opt])
continue;
opt_list_2[opt_count_2++] = cmd2->required_opt_args[i].opt;
if (cmd2->required_opt_args[i].opt == type_ARG)
cmd2_type_str = cmd2->required_opt_args[i].def.str;
}
/* "--type foo" and "--type bar" are different */
if (cmd1_type_str && cmd2_type_str && strcmp(cmd1_type_str, cmd2_type_str))
return 1;
/* compare opt_list_1 and opt_list_2 */
if (!_compare_opt_lists(opt_list_1, opt_count_1, opt_list_2, opt_count_2, NULL, NULL)) {
log_error("Repeated commands %s %s",
command_enum(cmd1->command_enum),
command_enum(cmd2->command_enum));
log_error("cmd1: %s", cmd1->desc);
log_error("cmd2: %s", cmd2->desc);
_print_opt_list("cmd1 options: ", opt_list_1, opt_count_1);
_print_opt_list("cmd2 options: ", opt_list_2, opt_count_2);
printf("\n");
r = 0;
}
/* check if cmd1 matches cmd2 + one of its oo */
for (i = 0; i < cmd2->oo_count; i++) {
/* for each cmd2 optional_opt_arg, add it to opt_list_2
and compare opt_list_1 and opt_list_2 again */
/* cmd1 "--type foo" and cmd2 OO "--type bar" are different */
if (cmd2->optional_opt_args[i].opt == type_ARG) {
if (cmd2->optional_opt_args[i].def.str && cmd1_type_str &&
strcmp(cmd2->optional_opt_args[i].def.str, cmd1_type_str))
return 1;
}
opt_list_2[opt_count_2] = cmd2->optional_opt_args[i].opt;
if (!_compare_opt_lists(opt_list_1, opt_count_1, opt_list_2, opt_count_2+1, NULL, NULL)) {
log_error("Repeated commands %s %s",
command_enum(cmd1->command_enum),
command_enum(cmd2->command_enum));
log_error("cmd1: %s", cmd1->desc);
log_error("cmd2: %s", cmd2->desc);
log_error("Included cmd2 OO: %s", opt_names[cmd2->optional_opt_args[i].opt].long_opt);
_print_opt_list("cmd1 options: ", opt_list_1, opt_count_1);
_print_opt_list("cmd2 options: ", opt_list_2, opt_count_2+1);
printf("\n");
r = 0;
}
}
/* check if cmd1 + an oo matches cmd2 + an oo */
if (!cmd1_type_str) {
for (i = 0; i < cmd1->oo_count; i++) {
if (cmd1->optional_opt_args[i].opt == type_ARG)
cmd1_type_str = cmd1->optional_opt_args[i].def.str;
}
}
if (!cmd2_type_str) {
for (j = 0; j < cmd2->oo_count; j++) {
if (cmd2->optional_opt_args[j].opt == type_ARG)
cmd2_type_str = cmd2->optional_opt_args[j].def.str;
}
}
for (i = 0; i < cmd1->oo_count; i++) {
for (j = 0; j < cmd2->oo_count; j++) {
if (cmd1->optional_opt_args[i].opt == cmd2->optional_opt_args[j].opt)
continue;
opt_list_1[opt_count_1] = cmd1->optional_opt_args[i].opt;
opt_list_2[opt_count_2] = cmd2->optional_opt_args[j].opt;
if (!_compare_opt_lists(opt_list_1, opt_count_1+1, opt_list_2, opt_count_2+1, cmd1_type_str, cmd2_type_str)) {
log_error("Repeated commands %s %s",
command_enum(cmd1->command_enum),
command_enum(cmd2->command_enum));
log_error("cmd1: %s", cmd1->desc);
log_error("cmd2: %s", cmd2->desc);
log_error("Included cmd1 OO: %s and cmd2 OO: %s",
opt_names[cmd1->optional_opt_args[i].opt].long_opt,
opt_names[cmd2->optional_opt_args[j].opt].long_opt);
_print_opt_list("cmd1 options: ", opt_list_1, opt_count_1+1);
_print_opt_list("cmd2 options: ", opt_list_2, opt_count_2+1);
printf("\n");
r = 0;
}
}
}
return r;
}
static int _check_overlap(void)
{
int all_req_opts[ARG_COUNT] = { 0 };
struct command *cmd1, *cmd2;
int i, j;
int r = 1;
for (i = 0; i < COMMAND_COUNT; i++) {
cmd1 = &commands[i];
for (j = 0; j < cmd1->ro_count; j++)
all_req_opts[cmd1->required_opt_args[j].opt] = 1;
}
for (i = 0; i < COMMAND_COUNT; i++) {
cmd1 = &commands[i];
if (cmd1->any_ro_count)
continue;
for (j = 0; j < COMMAND_COUNT; j++) {
if (i == j)
continue;
cmd2 = &commands[j];
if (cmd2->any_ro_count)
continue;
if (strcmp(cmd1->name, cmd2->name))
continue;
if (!_compare_cmds(cmd1, cmd2, all_req_opts))
r = 0;
}
}
return r;
}
#define STDOUT_BUF_SIZE (MAX_MAN_DESC + 4 * 1024)
int main(int argc, char *argv[])
{
struct cmd_context cmdtool = { 0 };
char *cmdname = NULL;
char *desfile = NULL;
char *stdout_buf;
int primary = 0;
int secondary = 0;
int check = 0;
int r = 0;
size_t sz = STDOUT_BUF_SIZE;
static struct option long_options[] = {
{"primary", no_argument, 0, 'p' },
{"secondary", no_argument, 0, 's' },
{"check", no_argument, 0, 'c' },
{0, 0, 0, 0 }
};
if (!(stdout_buf = malloc(sz)))
log_error("Failed to allocate stdout buffer; carrying on with default buffering.");
else
setbuffer(stdout, stdout_buf, sz);
while (1) {
int c;
int option_index = 0;
c = getopt_long(argc, argv, "psc", long_options, &option_index);
if (c == -1)
break;
switch (c) {
case '0':
break;
case 'p':
primary = 1;
break;
case 's':
secondary = 1;
break;
case 'c':
check = 1;
break;
}
}
if (!primary && !secondary && !check) {
log_error("Usage: %s --primary|--secondary|--check <command> [/path/to/description-file].", argv[0]);
goto out_free;
}
if (optind < argc) {
if (!(cmdname = strdup(argv[optind++]))) {
log_error("Out of memory.");
goto out_free;
}
} else if (!check) {
log_error("Missing command name.");
goto out_free;
}
if (optind < argc)
desfile = argv[optind++];
if (!define_commands(&cmdtool, NULL))
goto out_free;
factor_common_options();
if (primary && cmdname)
r = _print_man(cmdname, desfile, secondary);
else if (secondary && cmdname) {
r = 1;
_print_man_secondary(cmdname);
} else if (check) {
r = _check_overlap();
}
out_free:
if (stdout_buf) {
fflush(stdout);
setlinebuf(stdout);
free(stdout_buf);
}
exit(r ? EXIT_SUCCESS: EXIT_FAILURE);
}
View Git Blame Copy Permalink