postgres/contrib/sepgsql/selinux.c

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/* -------------------------------------------------------------------------
*
* contrib/sepgsql/selinux.c
*
* Interactions between userspace and selinux in kernelspace,
* using libselinux api.
*
* Copyright (c) 2010-2023, PostgreSQL Global Development Group
*
* -------------------------------------------------------------------------
*/
#include "postgres.h"
#include "lib/stringinfo.h"
#include "sepgsql.h"
/*
* selinux_catalog
*
* This mapping table enables to translate the name of object classes and
* access vectors to/from their own codes.
* When we ask SELinux whether the required privileges are allowed or not,
* we use security_compute_av(3). It needs us to represent object classes
* and access vectors using 'external' codes defined in the security policy.
* It is determined in the runtime, not build time. So, it needs an internal
* service to translate object class/access vectors which we want to check
* into the code which kernel want to be given.
*/
static struct
{
const char *class_name;
uint16 class_code;
struct
{
const char *av_name;
uint32 av_code;
} av[32];
} selinux_catalog[] =
2011-04-10 19:42:00 +04:00
{
{
"process", SEPG_CLASS_PROCESS,
{
{
"transition", SEPG_PROCESS__TRANSITION
},
{
"dyntransition", SEPG_PROCESS__DYNTRANSITION
},
{
"setcurrent", SEPG_PROCESS__SETCURRENT
},
{
NULL, 0UL
}
}
},
{
"file", SEPG_CLASS_FILE,
{
{
"read", SEPG_FILE__READ
},
{
"write", SEPG_FILE__WRITE
},
{
"create", SEPG_FILE__CREATE
},
{
"getattr", SEPG_FILE__GETATTR
},
{
"unlink", SEPG_FILE__UNLINK
},
{
"rename", SEPG_FILE__RENAME
},
{
"append", SEPG_FILE__APPEND
},
{
NULL, 0UL
}
}
},
{
"dir", SEPG_CLASS_DIR,
{
{
"read", SEPG_DIR__READ
},
{
"write", SEPG_DIR__WRITE
},
{
"create", SEPG_DIR__CREATE
},
{
"getattr", SEPG_DIR__GETATTR
},
{
"unlink", SEPG_DIR__UNLINK
},
{
"rename", SEPG_DIR__RENAME
},
{
"search", SEPG_DIR__SEARCH
},
{
"add_name", SEPG_DIR__ADD_NAME
},
{
"remove_name", SEPG_DIR__REMOVE_NAME
},
{
"rmdir", SEPG_DIR__RMDIR
},
{
"reparent", SEPG_DIR__REPARENT
},
{
NULL, 0UL
}
}
},
{
"lnk_file", SEPG_CLASS_LNK_FILE,
{
{
"read", SEPG_LNK_FILE__READ
},
{
"write", SEPG_LNK_FILE__WRITE
},
{
"create", SEPG_LNK_FILE__CREATE
},
{
"getattr", SEPG_LNK_FILE__GETATTR
},
{
"unlink", SEPG_LNK_FILE__UNLINK
},
{
"rename", SEPG_LNK_FILE__RENAME
},
{
NULL, 0UL
}
}
},
{
"chr_file", SEPG_CLASS_CHR_FILE,
{
{
"read", SEPG_CHR_FILE__READ
},
{
"write", SEPG_CHR_FILE__WRITE
},
{
"create", SEPG_CHR_FILE__CREATE
},
{
"getattr", SEPG_CHR_FILE__GETATTR
},
{
"unlink", SEPG_CHR_FILE__UNLINK
},
{
"rename", SEPG_CHR_FILE__RENAME
},
{
NULL, 0UL
}
}
},
{
"blk_file", SEPG_CLASS_BLK_FILE,
{
{
"read", SEPG_BLK_FILE__READ
},
{
"write", SEPG_BLK_FILE__WRITE
},
{
"create", SEPG_BLK_FILE__CREATE
},
{
"getattr", SEPG_BLK_FILE__GETATTR
},
{
"unlink", SEPG_BLK_FILE__UNLINK
},
{
"rename", SEPG_BLK_FILE__RENAME
},
{
NULL, 0UL
}
}
},
{
"sock_file", SEPG_CLASS_SOCK_FILE,
{
{
"read", SEPG_SOCK_FILE__READ
},
{
"write", SEPG_SOCK_FILE__WRITE
},
{
"create", SEPG_SOCK_FILE__CREATE
},
{
"getattr", SEPG_SOCK_FILE__GETATTR
},
{
"unlink", SEPG_SOCK_FILE__UNLINK
},
{
"rename", SEPG_SOCK_FILE__RENAME
},
{
NULL, 0UL
}
}
},
{
"fifo_file", SEPG_CLASS_FIFO_FILE,
{
{
"read", SEPG_FIFO_FILE__READ
},
{
"write", SEPG_FIFO_FILE__WRITE
},
{
"create", SEPG_FIFO_FILE__CREATE
},
{
"getattr", SEPG_FIFO_FILE__GETATTR
},
{
"unlink", SEPG_FIFO_FILE__UNLINK
},
{
"rename", SEPG_FIFO_FILE__RENAME
},
{
NULL, 0UL
}
}
},
{
"db_database", SEPG_CLASS_DB_DATABASE,
{
{
"create", SEPG_DB_DATABASE__CREATE
},
{
"drop", SEPG_DB_DATABASE__DROP
},
{
"getattr", SEPG_DB_DATABASE__GETATTR
},
{
"setattr", SEPG_DB_DATABASE__SETATTR
},
{
"relabelfrom", SEPG_DB_DATABASE__RELABELFROM
},
{
"relabelto", SEPG_DB_DATABASE__RELABELTO
},
{
"access", SEPG_DB_DATABASE__ACCESS
},
{
"load_module", SEPG_DB_DATABASE__LOAD_MODULE
},
{
NULL, 0UL
},
}
},
{
"db_schema", SEPG_CLASS_DB_SCHEMA,
{
{
"create", SEPG_DB_SCHEMA__CREATE
},
{
"drop", SEPG_DB_SCHEMA__DROP
},
{
"getattr", SEPG_DB_SCHEMA__GETATTR
},
{
"setattr", SEPG_DB_SCHEMA__SETATTR
},
{
"relabelfrom", SEPG_DB_SCHEMA__RELABELFROM
},
{
"relabelto", SEPG_DB_SCHEMA__RELABELTO
},
{
"search", SEPG_DB_SCHEMA__SEARCH
},
{
"add_name", SEPG_DB_SCHEMA__ADD_NAME
},
{
"remove_name", SEPG_DB_SCHEMA__REMOVE_NAME
},
{
NULL, 0UL
},
}
},
{
"db_table", SEPG_CLASS_DB_TABLE,
{
{
"create", SEPG_DB_TABLE__CREATE
},
{
"drop", SEPG_DB_TABLE__DROP
},
{
"getattr", SEPG_DB_TABLE__GETATTR
},
{
"setattr", SEPG_DB_TABLE__SETATTR
},
{
"relabelfrom", SEPG_DB_TABLE__RELABELFROM
},
{
"relabelto", SEPG_DB_TABLE__RELABELTO
},
{
"select", SEPG_DB_TABLE__SELECT
},
{
"update", SEPG_DB_TABLE__UPDATE
},
{
"insert", SEPG_DB_TABLE__INSERT
},
{
"delete", SEPG_DB_TABLE__DELETE
},
{
"lock", SEPG_DB_TABLE__LOCK
},
{
"truncate", SEPG_DB_TABLE__TRUNCATE
},
{
NULL, 0UL
},
}
},
{
"db_sequence", SEPG_CLASS_DB_SEQUENCE,
{
{
"create", SEPG_DB_SEQUENCE__CREATE
},
{
"drop", SEPG_DB_SEQUENCE__DROP
},
{
"getattr", SEPG_DB_SEQUENCE__GETATTR
},
{
"setattr", SEPG_DB_SEQUENCE__SETATTR
},
{
"relabelfrom", SEPG_DB_SEQUENCE__RELABELFROM
},
{
"relabelto", SEPG_DB_SEQUENCE__RELABELTO
},
{
"get_value", SEPG_DB_SEQUENCE__GET_VALUE
},
{
"next_value", SEPG_DB_SEQUENCE__NEXT_VALUE
},
{
"set_value", SEPG_DB_SEQUENCE__SET_VALUE
},
{
NULL, 0UL
},
}
},
{
"db_procedure", SEPG_CLASS_DB_PROCEDURE,
{
{
"create", SEPG_DB_PROCEDURE__CREATE
},
{
"drop", SEPG_DB_PROCEDURE__DROP
},
{
"getattr", SEPG_DB_PROCEDURE__GETATTR
},
{
"setattr", SEPG_DB_PROCEDURE__SETATTR
},
{
"relabelfrom", SEPG_DB_PROCEDURE__RELABELFROM
},
{
"relabelto", SEPG_DB_PROCEDURE__RELABELTO
},
{
"execute", SEPG_DB_PROCEDURE__EXECUTE
},
{
"entrypoint", SEPG_DB_PROCEDURE__ENTRYPOINT
},
{
"install", SEPG_DB_PROCEDURE__INSTALL
},
{
NULL, 0UL
},
}
},
{
"db_column", SEPG_CLASS_DB_COLUMN,
{
{
"create", SEPG_DB_COLUMN__CREATE
},
{
"drop", SEPG_DB_COLUMN__DROP
},
{
"getattr", SEPG_DB_COLUMN__GETATTR
},
{
"setattr", SEPG_DB_COLUMN__SETATTR
},
{
"relabelfrom", SEPG_DB_COLUMN__RELABELFROM
},
{
"relabelto", SEPG_DB_COLUMN__RELABELTO
},
{
"select", SEPG_DB_COLUMN__SELECT
},
{
"update", SEPG_DB_COLUMN__UPDATE
},
{
"insert", SEPG_DB_COLUMN__INSERT
},
{
NULL, 0UL
},
}
},
{
"db_tuple", SEPG_CLASS_DB_TUPLE,
{
{
"relabelfrom", SEPG_DB_TUPLE__RELABELFROM
},
{
"relabelto", SEPG_DB_TUPLE__RELABELTO
},
{
"select", SEPG_DB_TUPLE__SELECT
},
{
"update", SEPG_DB_TUPLE__UPDATE
},
{
"insert", SEPG_DB_TUPLE__INSERT
},
{
"delete", SEPG_DB_TUPLE__DELETE
},
{
NULL, 0UL
},
}
},
{
"db_blob", SEPG_CLASS_DB_BLOB,
{
{
"create", SEPG_DB_BLOB__CREATE
},
{
"drop", SEPG_DB_BLOB__DROP
},
{
"getattr", SEPG_DB_BLOB__GETATTR
},
{
"setattr", SEPG_DB_BLOB__SETATTR
},
{
"relabelfrom", SEPG_DB_BLOB__RELABELFROM
},
{
"relabelto", SEPG_DB_BLOB__RELABELTO
},
{
"read", SEPG_DB_BLOB__READ
},
{
"write", SEPG_DB_BLOB__WRITE
},
{
"import", SEPG_DB_BLOB__IMPORT
},
{
"export", SEPG_DB_BLOB__EXPORT
},
{
NULL, 0UL
},
}
},
{
"db_language", SEPG_CLASS_DB_LANGUAGE,
{
{
"create", SEPG_DB_LANGUAGE__CREATE
},
{
"drop", SEPG_DB_LANGUAGE__DROP
},
{
"getattr", SEPG_DB_LANGUAGE__GETATTR
},
{
"setattr", SEPG_DB_LANGUAGE__SETATTR
},
{
"relabelfrom", SEPG_DB_LANGUAGE__RELABELFROM
},
{
"relabelto", SEPG_DB_LANGUAGE__RELABELTO
},
{
"implement", SEPG_DB_LANGUAGE__IMPLEMENT
},
{
"execute", SEPG_DB_LANGUAGE__EXECUTE
},
{
NULL, 0UL
},
}
},
{
"db_view", SEPG_CLASS_DB_VIEW,
{
{
"create", SEPG_DB_VIEW__CREATE
},
{
"drop", SEPG_DB_VIEW__DROP
},
{
"getattr", SEPG_DB_VIEW__GETATTR
},
{
"setattr", SEPG_DB_VIEW__SETATTR
},
{
"relabelfrom", SEPG_DB_VIEW__RELABELFROM
},
{
"relabelto", SEPG_DB_VIEW__RELABELTO
},
{
"expand", SEPG_DB_VIEW__EXPAND
},
{
NULL, 0UL
},
}
},
};
/*
* sepgsql_mode
*
* SEPGSQL_MODE_DISABLED: Disabled on runtime
* SEPGSQL_MODE_DEFAULT: Same as system settings
* SEPGSQL_MODE_PERMISSIVE: Always permissive mode
* SEPGSQL_MODE_INTERNAL: Same as permissive, except for no audit logs
*/
static int sepgsql_mode = SEPGSQL_MODE_INTERNAL;
/*
* sepgsql_is_enabled
*/
bool
sepgsql_is_enabled(void)
{
return (sepgsql_mode != SEPGSQL_MODE_DISABLED);
}
/*
* sepgsql_get_mode
*/
int
sepgsql_get_mode(void)
{
return sepgsql_mode;
}
/*
* sepgsql_set_mode
*/
int
sepgsql_set_mode(int new_mode)
{
int old_mode = sepgsql_mode;
sepgsql_mode = new_mode;
return old_mode;
}
/*
* sepgsql_getenforce
*
* It returns whether the current working mode tries to enforce access
* control decision, or not. It shall be enforced when sepgsql_mode is
* SEPGSQL_MODE_DEFAULT and system is running in enforcing mode.
*/
bool
sepgsql_getenforce(void)
{
if (sepgsql_mode == SEPGSQL_MODE_DEFAULT &&
selinux_status_getenforce() > 0)
return true;
return false;
}
/*
* sepgsql_audit_log
*
* It generates a security audit record. It writes out audit records
* into standard PG's logfile.
*
* SELinux can control what should be audited and should not using
* "auditdeny" and "auditallow" rules in the security policy. In the
* default, all the access violations are audited, and all the access
* allowed are not audited. But we can set up the security policy, so
* we can have exceptions. So, it is necessary to follow the suggestion
* come from the security policy. (av_decision.auditallow and auditdeny)
*
* Security audit is an important feature, because it enables us to check
* what was happen if we have a security incident. In fact, ISO/IEC15408
* defines several security functionalities for audit features.
*/
void
sepgsql_audit_log(bool denied,
bool enforcing,
const char *scontext,
const char *tcontext,
uint16 tclass,
uint32 audited,
const char *audit_name)
{
StringInfoData buf;
const char *class_name;
const char *av_name;
int i;
/* lookup name of the object class */
Assert(tclass < SEPG_CLASS_MAX);
class_name = selinux_catalog[tclass].class_name;
/* lookup name of the permissions */
initStringInfo(&buf);
appendStringInfo(&buf, "%s {",
(denied ? "denied" : "allowed"));
for (i = 0; selinux_catalog[tclass].av[i].av_name; i++)
{
if (audited & (1UL << i))
{
av_name = selinux_catalog[tclass].av[i].av_name;
appendStringInfo(&buf, " %s", av_name);
}
}
appendStringInfoString(&buf, " }");
/*
* Call external audit module, if loaded
*/
appendStringInfo(&buf, " scontext=%s tcontext=%s tclass=%s",
scontext, tcontext, class_name);
if (audit_name)
appendStringInfo(&buf, " name=\"%s\"", audit_name);
if (enforcing)
appendStringInfoString(&buf, " permissive=0");
else
appendStringInfoString(&buf, " permissive=1");
ereport(LOG, (errmsg("SELinux: %s", buf.data)));
}
/*
* sepgsql_compute_avd
*
* It actually asks SELinux what permissions are allowed on a pair of
* the security contexts and object class. It also returns what permissions
* should be audited on access violation or allowed.
* In most cases, subject's security context (scontext) is a client, and
* target security context (tcontext) is a database object.
*
* The access control decision shall be set on the given av_decision.
* The av_decision.allowed has a bitmask of SEPG_<class>__<perms>
* to suggest a set of allowed actions in this object class.
*/
void
sepgsql_compute_avd(const char *scontext,
const char *tcontext,
uint16 tclass,
struct av_decision *avd)
{
const char *tclass_name;
security_class_t tclass_ex;
struct av_decision avd_ex;
int i,
deny_unknown = security_deny_unknown();
/* Get external code of the object class */
Assert(tclass < SEPG_CLASS_MAX);
Assert(tclass == selinux_catalog[tclass].class_code);
tclass_name = selinux_catalog[tclass].class_name;
tclass_ex = string_to_security_class(tclass_name);
if (tclass_ex == 0)
{
/*
* If the current security policy does not support permissions
* corresponding to database objects, we fill up them with dummy data.
* If security_deny_unknown() returns positive value, undefined
* permissions should be denied. Otherwise, allowed
*/
avd->allowed = (security_deny_unknown() > 0 ? 0 : ~0);
avd->auditallow = 0U;
avd->auditdeny = ~0U;
avd->flags = 0;
return;
}
/*
* Ask SELinux what is allowed set of permissions on a pair of the
* security contexts and the given object class.
*/
if (security_compute_av_flags_raw(scontext,
tcontext,
tclass_ex, 0, &avd_ex) < 0)
ereport(ERROR,
(errcode(ERRCODE_INTERNAL_ERROR),
errmsg("SELinux could not compute av_decision: "
"scontext=%s tcontext=%s tclass=%s: %m",
scontext, tcontext, tclass_name)));
/*
* SELinux returns its access control decision as a set of permissions
* represented in external code which depends on run-time environment. So,
* we need to translate it to the internal representation before returning
* results for the caller.
*/
memset(avd, 0, sizeof(struct av_decision));
for (i = 0; selinux_catalog[tclass].av[i].av_name; i++)
{
access_vector_t av_code_ex;
const char *av_name = selinux_catalog[tclass].av[i].av_name;
uint32 av_code = selinux_catalog[tclass].av[i].av_code;
av_code_ex = string_to_av_perm(tclass_ex, av_name);
if (av_code_ex == 0)
{
/* fill up undefined permissions */
if (!deny_unknown)
avd->allowed |= av_code;
avd->auditdeny |= av_code;
continue;
}
if (avd_ex.allowed & av_code_ex)
avd->allowed |= av_code;
if (avd_ex.auditallow & av_code_ex)
avd->auditallow |= av_code;
if (avd_ex.auditdeny & av_code_ex)
avd->auditdeny |= av_code;
}
}
/*
* sepgsql_compute_create
*
* It returns a default security context to be assigned on a new database
* object. SELinux compute it based on a combination of client, upper object
* which owns the new object and object class.
*
* For example, when a client (staff_u:staff_r:staff_t:s0) tries to create
* a new table within a schema (system_u:object_r:sepgsql_schema_t:s0),
* SELinux looks-up its security policy. If it has a special rule on the
* combination of these security contexts and object class (db_table),
* it returns the security context suggested by the special rule.
* Otherwise, it returns the security context of schema, as is.
*
* We expect the caller already applies sanity/validation checks on the
* given security context.
*
* scontext: security context of the subject (mostly, peer process).
2012-05-02 17:27:34 +04:00
* tcontext: security context of the upper database object.
* tclass: class code (SEPG_CLASS_*) of the new object in creation
*/
char *
sepgsql_compute_create(const char *scontext,
const char *tcontext,
uint16 tclass,
const char *objname)
{
char *ncontext;
security_class_t tclass_ex;
const char *tclass_name;
char *result;
/* Get external code of the object class */
Assert(tclass < SEPG_CLASS_MAX);
tclass_name = selinux_catalog[tclass].class_name;
tclass_ex = string_to_security_class(tclass_name);
/*
* Ask SELinux what is the default context for the given object class on a
* pair of security contexts
*/
if (security_compute_create_name_raw(scontext,
tcontext,
tclass_ex,
objname,
&ncontext) < 0)
ereport(ERROR,
(errcode(ERRCODE_INTERNAL_ERROR),
errmsg("SELinux could not compute a new context: "
"scontext=%s tcontext=%s tclass=%s: %m",
scontext, tcontext, tclass_name)));
/*
* libselinux returns malloc()'ed string, so we need to copy it on the
* palloc()'ed region.
*/
PG_TRY();
{
result = pstrdup(ncontext);
}
PG_FINALLY();
{
freecon(ncontext);
}
PG_END_TRY();
return result;
}