#ifndef REFS_REFS_INTERNAL_H #define REFS_REFS_INTERNAL_H /* * Data structures and functions for the internal use of the refs * module. Code outside of the refs module should use only the public * functions defined in "refs.h", and should *not* include this file. */ /* * Flag passed to lock_ref_sha1_basic() telling it to tolerate broken * refs (i.e., because the reference is about to be deleted anyway). */ #define REF_DELETING 0x02 /* * Used as a flag in ref_update::flags when a loose ref is being * pruned. This flag must only be used when REF_NODEREF is set. */ #define REF_ISPRUNING 0x04 /* * Used as a flag in ref_update::flags when the reference should be * updated to new_sha1. */ #define REF_HAVE_NEW 0x08 /* * Used as a flag in ref_update::flags when old_sha1 should be * checked. */ #define REF_HAVE_OLD 0x10 /* * Used as a flag in ref_update::flags when the lockfile needs to be * committed. */ #define REF_NEEDS_COMMIT 0x20 /* * 0x40 is REF_FORCE_CREATE_REFLOG, so skip it if you're adding a * value to ref_update::flags */ /* * Used as a flag in ref_update::flags when we want to log a ref * update but not actually perform it. This is used when a symbolic * ref update is split up. */ #define REF_LOG_ONLY 0x80 /* * Internal flag, meaning that the containing ref_update was via an * update to HEAD. */ #define REF_UPDATE_VIA_HEAD 0x100 /* * Return true iff refname is minimally safe. "Safe" here means that * deleting a loose reference by this name will not do any damage, for * example by causing a file that is not a reference to be deleted. * This function does not check that the reference name is legal; for * that, use check_refname_format(). * * We consider a refname that starts with "refs/" to be safe as long * as any ".." components that it might contain do not escape "refs/". * Names that do not start with "refs/" are considered safe iff they * consist entirely of upper case characters and '_' (like "HEAD" and * "MERGE_HEAD" but not "config" or "FOO/BAR"). */ int refname_is_safe(const char *refname); enum peel_status { /* object was peeled successfully: */ PEEL_PEELED = 0, /* * object cannot be peeled because the named object (or an * object referred to by a tag in the peel chain), does not * exist. */ PEEL_INVALID = -1, /* object cannot be peeled because it is not a tag: */ PEEL_NON_TAG = -2, /* ref_entry contains no peeled value because it is a symref: */ PEEL_IS_SYMREF = -3, /* * ref_entry cannot be peeled because it is broken (i.e., the * symbolic reference cannot even be resolved to an object * name): */ PEEL_BROKEN = -4 }; /* * Peel the named object; i.e., if the object is a tag, resolve the * tag recursively until a non-tag is found. If successful, store the * result to sha1 and return PEEL_PEELED. If the object is not a tag * or is not valid, return PEEL_NON_TAG or PEEL_INVALID, respectively, * and leave sha1 unchanged. */ enum peel_status peel_object(const unsigned char *name, unsigned char *sha1); /* * Return 0 if a reference named refname could be created without * conflicting with the name of an existing reference. Otherwise, * return a negative value and write an explanation to err. If extras * is non-NULL, it is a list of additional refnames with which refname * is not allowed to conflict. If skip is non-NULL, ignore potential * conflicts with refs in skip (e.g., because they are scheduled for * deletion in the same operation). Behavior is undefined if the same * name is listed in both extras and skip. * * Two reference names conflict if one of them exactly matches the * leading components of the other; e.g., "foo/bar" conflicts with * both "foo" and with "foo/bar/baz" but not with "foo/bar" or * "foo/barbados". * * extras and skip must be sorted. */ int verify_refname_available(const char *newname, const struct string_list *extras, const struct string_list *skip, struct strbuf *err); /* * Copy the reflog message msg to buf, which has been allocated sufficiently * large, while cleaning up the whitespaces. Especially, convert LF to space, * because reflog file is one line per entry. */ int copy_reflog_msg(char *buf, const char *msg); int should_autocreate_reflog(const char *refname); /** * Information needed for a single ref update. Set new_sha1 to the new * value or to null_sha1 to delete the ref. To check the old value * while the ref is locked, set (flags & REF_HAVE_OLD) and set * old_sha1 to the old value, or to null_sha1 to ensure the ref does * not exist before update. */ struct ref_update { /* * If (flags & REF_HAVE_NEW), set the reference to this value: */ unsigned char new_sha1[20]; /* * If (flags & REF_HAVE_OLD), check that the reference * previously had this value: */ unsigned char old_sha1[20]; /* * One or more of REF_HAVE_NEW, REF_HAVE_OLD, REF_NODEREF, * REF_DELETING, REF_ISPRUNING, REF_LOG_ONLY, and * REF_UPDATE_VIA_HEAD: */ unsigned int flags; void *backend_data; unsigned int type; char *msg; /* * If this ref_update was split off of a symref update via * split_symref_update(), then this member points at that * update. This is used for two purposes: * 1. When reporting errors, we report the refname under which * the update was originally requested. * 2. When we read the old value of this reference, we * propagate it back to its parent update for recording in * the latter's reflog. */ struct ref_update *parent_update; const char refname[FLEX_ARRAY]; }; /* * Add a ref_update with the specified properties to transaction, and * return a pointer to the new object. This function does not verify * that refname is well-formed. new_sha1 and old_sha1 are only * dereferenced if the REF_HAVE_NEW and REF_HAVE_OLD bits, * respectively, are set in flags. */ struct ref_update *ref_transaction_add_update( struct ref_transaction *transaction, const char *refname, unsigned int flags, const unsigned char *new_sha1, const unsigned char *old_sha1, const char *msg); /* * Transaction states. * OPEN: The transaction is in a valid state and can accept new updates. * An OPEN transaction can be committed. * CLOSED: A closed transaction is no longer active and no other operations * than free can be used on it in this state. * A transaction can either become closed by successfully committing * an active transaction or if there is a failure while building * the transaction thus rendering it failed/inactive. */ enum ref_transaction_state { REF_TRANSACTION_OPEN = 0, REF_TRANSACTION_CLOSED = 1 }; /* * Data structure for holding a reference transaction, which can * consist of checks and updates to multiple references, carried out * as atomically as possible. This structure is opaque to callers. */ struct ref_transaction { struct ref_update **updates; size_t alloc; size_t nr; enum ref_transaction_state state; }; int files_log_ref_write(const char *refname, const unsigned char *old_sha1, const unsigned char *new_sha1, const char *msg, int flags, struct strbuf *err); /* * Check for entries in extras that are within the specified * directory, where dirname is a reference directory name including * the trailing slash (e.g., "refs/heads/foo/"). Ignore any * conflicting references that are found in skip. If there is a * conflicting reference, return its name. * * extras and skip must be sorted lists of reference names. Either one * can be NULL, signifying the empty list. */ const char *find_descendant_ref(const char *dirname, const struct string_list *extras, const struct string_list *skip); /* * Check whether an attempt to rename old_refname to new_refname would * cause a D/F conflict with any existing reference (other than * possibly old_refname). If there would be a conflict, emit an error * message and return false; otherwise, return true. * * Note that this function is not safe against all races with other * processes (though rename_ref() catches some races that might get by * this check). */ int rename_ref_available(const char *old_refname, const char *new_refname); /* We allow "recursive" symbolic refs. Only within reason, though */ #define SYMREF_MAXDEPTH 5 /* Include broken references in a do_for_each_ref*() iteration: */ #define DO_FOR_EACH_INCLUDE_BROKEN 0x01 /* * Reference iterators * * A reference iterator encapsulates the state of an in-progress * iteration over references. Create an instance of `struct * ref_iterator` via one of the functions in this module. * * A freshly-created ref_iterator doesn't yet point at a reference. To * advance the iterator, call ref_iterator_advance(). If successful, * this sets the iterator's refname, oid, and flags fields to describe * the next reference and returns ITER_OK. The data pointed at by * refname and oid belong to the iterator; if you want to retain them * after calling ref_iterator_advance() again or calling * ref_iterator_abort(), you must make a copy. When the iteration has * been exhausted, ref_iterator_advance() releases any resources * assocated with the iteration, frees the ref_iterator object, and * returns ITER_DONE. If you want to abort the iteration early, call * ref_iterator_abort(), which also frees the ref_iterator object and * any associated resources. If there was an internal error advancing * to the next entry, ref_iterator_advance() aborts the iteration, * frees the ref_iterator, and returns ITER_ERROR. * * The reference currently being looked at can be peeled by calling * ref_iterator_peel(). This function is often faster than peel_ref(), * so it should be preferred when iterating over references. * * Putting it all together, a typical iteration looks like this: * * int ok; * struct ref_iterator *iter = ...; * * while ((ok = ref_iterator_advance(iter)) == ITER_OK) { * if (want_to_stop_iteration()) { * ok = ref_iterator_abort(iter); * break; * } * * // Access information about the current reference: * if (!(iter->flags & REF_ISSYMREF)) * printf("%s is %s\n", iter->refname, oid_to_hex(&iter->oid)); * * // If you need to peel the reference: * ref_iterator_peel(iter, &oid); * } * * if (ok != ITER_DONE) * handle_error(); */ struct ref_iterator { struct ref_iterator_vtable *vtable; const char *refname; const struct object_id *oid; unsigned int flags; }; /* * Advance the iterator to the first or next item and return ITER_OK. * If the iteration is exhausted, free the resources associated with * the ref_iterator and return ITER_DONE. On errors, free the iterator * resources and return ITER_ERROR. It is a bug to use ref_iterator or * call this function again after it has returned ITER_DONE or * ITER_ERROR. */ int ref_iterator_advance(struct ref_iterator *ref_iterator); /* * If possible, peel the reference currently being viewed by the * iterator. Return 0 on success. */ int ref_iterator_peel(struct ref_iterator *ref_iterator, struct object_id *peeled); /* * End the iteration before it has been exhausted, freeing the * reference iterator and any associated resources and returning * ITER_DONE. If the abort itself failed, return ITER_ERROR. */ int ref_iterator_abort(struct ref_iterator *ref_iterator); /* * An iterator over nothing (its first ref_iterator_advance() call * returns ITER_DONE). */ struct ref_iterator *empty_ref_iterator_begin(void); /* * Return true iff ref_iterator is an empty_ref_iterator. */ int is_empty_ref_iterator(struct ref_iterator *ref_iterator); /* * A callback function used to instruct merge_ref_iterator how to * interleave the entries from iter0 and iter1. The function should * return one of the constants defined in enum iterator_selection. It * must not advance either of the iterators itself. * * The function must be prepared to handle the case that iter0 and/or * iter1 is NULL, which indicates that the corresponding sub-iterator * has been exhausted. Its return value must be consistent with the * current states of the iterators; e.g., it must not return * ITER_SKIP_1 if iter1 has already been exhausted. */ typedef enum iterator_selection ref_iterator_select_fn( struct ref_iterator *iter0, struct ref_iterator *iter1, void *cb_data); /* * Iterate over the entries from iter0 and iter1, with the values * interleaved as directed by the select function. The iterator takes * ownership of iter0 and iter1 and frees them when the iteration is * over. */ struct ref_iterator *merge_ref_iterator_begin( struct ref_iterator *iter0, struct ref_iterator *iter1, ref_iterator_select_fn *select, void *cb_data); /* * An iterator consisting of the union of the entries from front and * back. If there are entries common to the two sub-iterators, use the * one from front. Each iterator must iterate over its entries in * strcmp() order by refname for this to work. * * The new iterator takes ownership of its arguments and frees them * when the iteration is over. As a convenience to callers, if front * or back is an empty_ref_iterator, then abort that one immediately * and return the other iterator directly, without wrapping it. */ struct ref_iterator *overlay_ref_iterator_begin( struct ref_iterator *front, struct ref_iterator *back); /* * Wrap iter0, only letting through the references whose names start * with prefix. If trim is set, set iter->refname to the name of the * reference with that many characters trimmed off the front; * otherwise set it to the full refname. The new iterator takes over * ownership of iter0 and frees it when iteration is over. It makes * its own copy of prefix. * * As an convenience to callers, if prefix is the empty string and * trim is zero, this function returns iter0 directly, without * wrapping it. */ struct ref_iterator *prefix_ref_iterator_begin(struct ref_iterator *iter0, const char *prefix, int trim); /* Internal implementation of reference iteration: */ /* * Base class constructor for ref_iterators. Initialize the * ref_iterator part of iter, setting its vtable pointer as specified. * This is meant to be called only by the initializers of derived * classes. */ void base_ref_iterator_init(struct ref_iterator *iter, struct ref_iterator_vtable *vtable); /* * Base class destructor for ref_iterators. Destroy the ref_iterator * part of iter and shallow-free the object. This is meant to be * called only by the destructors of derived classes. */ void base_ref_iterator_free(struct ref_iterator *iter); /* Virtual function declarations for ref_iterators: */ typedef int ref_iterator_advance_fn(struct ref_iterator *ref_iterator); typedef int ref_iterator_peel_fn(struct ref_iterator *ref_iterator, struct object_id *peeled); /* * Implementations of this function should free any resources specific * to the derived class, then call base_ref_iterator_free() to clean * up and free the ref_iterator object. */ typedef int ref_iterator_abort_fn(struct ref_iterator *ref_iterator); struct ref_iterator_vtable { ref_iterator_advance_fn *advance; ref_iterator_peel_fn *peel; ref_iterator_abort_fn *abort; }; /* * current_ref_iter is a performance hack: when iterating over * references using the for_each_ref*() functions, current_ref_iter is * set to the reference iterator before calling the callback function. * If the callback function calls peel_ref(), then peel_ref() first * checks whether the reference to be peeled is the one referred to by * the iterator (it usually is) and if so, asks the iterator for the * peeled version of the reference if it is available. This avoids a * refname lookup in a common case. current_ref_iter is set to NULL * when the iteration is over. */ extern struct ref_iterator *current_ref_iter; /* * The common backend for the for_each_*ref* functions. Call fn for * each reference in iter. If the iterator itself ever returns * ITER_ERROR, return -1. If fn ever returns a non-zero value, stop * the iteration and return that value. Otherwise, return 0. In any * case, free the iterator when done. This function is basically an * adapter between the callback style of reference iteration and the * iterator style. */ int do_for_each_ref_iterator(struct ref_iterator *iter, each_ref_fn fn, void *cb_data); /* * Only include per-worktree refs in a do_for_each_ref*() iteration. * Normally this will be used with a files ref_store, since that's * where all reference backends will presumably store their * per-worktree refs. */ #define DO_FOR_EACH_PER_WORKTREE_ONLY 0x02 struct ref_store; /* refs backends */ /* * Initialize the ref_store for the specified submodule, or for the * main repository if submodule == NULL. These functions should call * base_ref_store_init() to initialize the shared part of the * ref_store and to record the ref_store for later lookup. */ typedef struct ref_store *ref_store_init_fn(const char *submodule); typedef int ref_init_db_fn(struct ref_store *refs, struct strbuf *err); typedef int ref_transaction_commit_fn(struct ref_store *refs, struct ref_transaction *transaction, struct strbuf *err); typedef int pack_refs_fn(struct ref_store *ref_store, unsigned int flags); typedef int peel_ref_fn(struct ref_store *ref_store, const char *refname, unsigned char *sha1); typedef int create_symref_fn(struct ref_store *ref_store, const char *ref_target, const char *refs_heads_master, const char *logmsg); typedef int delete_refs_fn(struct ref_store *ref_store, struct string_list *refnames, unsigned int flags); typedef int rename_ref_fn(struct ref_store *ref_store, const char *oldref, const char *newref, const char *logmsg); /* * Iterate over the references in the specified ref_store that are * within find_containing_dir(prefix). If prefix is NULL or the empty * string, iterate over all references in the submodule. */ typedef struct ref_iterator *ref_iterator_begin_fn( struct ref_store *ref_store, const char *prefix, unsigned int flags); /* reflog functions */ /* * Iterate over the references in the specified ref_store that have a * reflog. The refs are iterated over in arbitrary order. */ typedef struct ref_iterator *reflog_iterator_begin_fn( struct ref_store *ref_store); typedef int for_each_reflog_ent_fn(struct ref_store *ref_store, const char *refname, each_reflog_ent_fn fn, void *cb_data); typedef int for_each_reflog_ent_reverse_fn(struct ref_store *ref_store, const char *refname, each_reflog_ent_fn fn, void *cb_data); typedef int reflog_exists_fn(struct ref_store *ref_store, const char *refname); typedef int create_reflog_fn(struct ref_store *ref_store, const char *refname, int force_create, struct strbuf *err); typedef int delete_reflog_fn(struct ref_store *ref_store, const char *refname); typedef int reflog_expire_fn(struct ref_store *ref_store, const char *refname, const unsigned char *sha1, unsigned int flags, reflog_expiry_prepare_fn prepare_fn, reflog_expiry_should_prune_fn should_prune_fn, reflog_expiry_cleanup_fn cleanup_fn, void *policy_cb_data); /* * Read a reference from the specified reference store, non-recursively. * Set type to describe the reference, and: * * - If refname is the name of a normal reference, fill in sha1 * (leaving referent unchanged). * * - If refname is the name of a symbolic reference, write the full * name of the reference to which it refers (e.g. * "refs/heads/master") to referent and set the REF_ISSYMREF bit in * type (leaving sha1 unchanged). The caller is responsible for * validating that referent is a valid reference name. * * WARNING: refname might be used as part of a filename, so it is * important from a security standpoint that it be safe in the sense * of refname_is_safe(). Moreover, for symrefs this function sets * referent to whatever the repository says, which might not be a * properly-formatted or even safe reference name. NEITHER INPUT NOR * OUTPUT REFERENCE NAMES ARE VALIDATED WITHIN THIS FUNCTION. * * Return 0 on success. If the ref doesn't exist, set errno to ENOENT * and return -1. If the ref exists but is neither a symbolic ref nor * a sha1, it is broken; set REF_ISBROKEN in type, set errno to * EINVAL, and return -1. If there is another error reading the ref, * set errno appropriately and return -1. * * Backend-specific flags might be set in type as well, regardless of * outcome. * * It is OK for refname to point into referent. If so: * * - if the function succeeds with REF_ISSYMREF, referent will be * overwritten and the memory formerly pointed to by it might be * changed or even freed. * * - in all other cases, referent will be untouched, and therefore * refname will still be valid and unchanged. */ typedef int read_raw_ref_fn(struct ref_store *ref_store, const char *refname, unsigned char *sha1, struct strbuf *referent, unsigned int *type); typedef int verify_refname_available_fn(struct ref_store *ref_store, const char *newname, const struct string_list *extras, const struct string_list *skip, struct strbuf *err); struct ref_storage_be { struct ref_storage_be *next; const char *name; ref_store_init_fn *init; ref_init_db_fn *init_db; ref_transaction_commit_fn *transaction_commit; ref_transaction_commit_fn *initial_transaction_commit; pack_refs_fn *pack_refs; peel_ref_fn *peel_ref; create_symref_fn *create_symref; delete_refs_fn *delete_refs; rename_ref_fn *rename_ref; ref_iterator_begin_fn *iterator_begin; read_raw_ref_fn *read_raw_ref; verify_refname_available_fn *verify_refname_available; reflog_iterator_begin_fn *reflog_iterator_begin; for_each_reflog_ent_fn *for_each_reflog_ent; for_each_reflog_ent_reverse_fn *for_each_reflog_ent_reverse; reflog_exists_fn *reflog_exists; create_reflog_fn *create_reflog; delete_reflog_fn *delete_reflog; reflog_expire_fn *reflog_expire; }; extern struct ref_storage_be refs_be_files; /* * A representation of the reference store for the main repository or * a submodule. The ref_store instances for submodules are kept in a * linked list. */ struct ref_store { /* The backend describing this ref_store's storage scheme: */ const struct ref_storage_be *be; }; /* * Fill in the generic part of refs and add it to our collection of * reference stores. */ void base_ref_store_init(struct ref_store *refs, const struct ref_storage_be *be); /* * Return the ref_store instance for the specified submodule. For the * main repository, use submodule==NULL; such a call cannot fail. For * a submodule, the submodule must exist and be a nonbare repository, * otherwise return NULL. If the requested reference store has not yet * been initialized, initialize it first. * * For backwards compatibility, submodule=="" is treated the same as * submodule==NULL. */ struct ref_store *get_ref_store(const char *submodule); #endif /* REFS_REFS_INTERNAL_H */