KV_maker.Make
The Git backend specializes a few types:
Metadata.t
.module C : Irmin.Contents.S
module Git = G
Access to the underlying Git store.
module Schema :
Irmin.Schema.S
with type Metadata.t = Metadata.t
and type Hash.t = Git.hash
with type Contents.t = C.t
with type Metadata.t = Metadata.t
with type Info.t = Irmin.Info.default
with type Path.step = string
with type Path.t = string list
with type Hash.t = G.hash
with type Branch.t = branch
include Irmin.S
with type hash = Schema.Hash.t
and module Schema := Schema
with type Backend.Remote.endpoint = endpoint
type hash = Schema.Hash.t
Irmin stores are tree-like read-write stores with extended capabilities. They allow an application (or a collection of applications) to work with multiple local states, which can be forked and merged programmatically, without having to rely on a global state. In a way very similar to version control systems, Irmin local states are called branches.
There are two kinds of store in Irmin: the ones based on persistent named branches and the ones based temporary detached heads. These exist relative to a local, larger (and shared) store, and have some (shared) contents. This is exactly the same as usual version control systems, that the informed user can see as an implicit purely functional data-structure.
type step = Schema.Path.step
The type for key
steps.
val step_t : step Irmin.Type.t
type path = Schema.Path.t
The type for store keys. A key is a sequence of step
s.
val path_t : path Irmin.Type.t
type metadata = Schema.Metadata.t
The type for store metadata.
val metadata_t : metadata Irmin.Type.t
type contents = Schema.Contents.t
The type for store contents.
val contents_t : contents Irmin.Type.t
val node_t : node Irmin.Type.t
val tree_t : tree Irmin.Type.t
val hash_t : hash Irmin.Type.t
val commit_t : repo -> commit Irmin.Type.t
commit_t r
is the value type for commit
.
type branch = Schema.Branch.t
Type for persistent branch names. Branches usually share a common global namespace and it's the user's responsibility to avoid name clashes.
val branch_t : branch Irmin.Type.t
val slice_t : slice Irmin.Type.t
type info = Schema.Info.t
The type for commit info.
val info_t : info Irmin.Type.t
The type for errors associated with functions computing least common ancestors
val lca_error_t : lca_error Irmin.Type.t
The type for errors for Head.fast_forward
.
val ff_error_t : ff_error Irmin.Type.t
module Info : sig ... end
type contents_key = hash
val contents_key_t : contents_key Irmin.Type.t
type node_key = hash
val node_key_t : node_key Irmin.Type.t
type commit_key = hash
val commit_key_t : commit_key Irmin.Type.t
module Repo : sig ... end
Repositories.
empty repo
is a temporary, empty store. Becomes a normal temporary store after the first update.
main r
is a persistent store based on r
's main branch. This operation is cheap, can be repeated multiple times.
of_branch r name
is a persistent store based on the branch name
. Similar to main
, but use name
instead of Irmin.Branch.S.main
.
of_commit c
is a temporary store, based on the commit c
.
Temporary stores do not have stable names: instead they can be addressed using the hash of the current commit. Temporary stores are similar to Git's detached heads. In a temporary store, all the operations are performed relative to the current head and update operations can modify the current head: the current stores's head will automatically become the new head obtained after performing the update.
tree t
is t
's current tree. Contents is not allowed at the root of the tree.
module Status : sig ... end
module Head : sig ... end
Managing the store's heads.
module Hash : Irmin.Hash.S with type t = hash
Object hashes.
module Commit : sig ... end
Commit
defines immutable objects to describe store updates.
module Contents : sig ... end
Contents
provides base functions for the store's contents.
module Tree : sig ... end
Managing store's trees.
kind
is Tree.kind
applied to t
's root tree.
mem_tree t
is Tree.mem_tree
applied to t
's root tree.
find_all t
is Tree.find_all
applied to t
's root tree.
get_all t
is Tree.get_all
applied on t
's root tree.
find_tree t
is Tree.find_tree
applied to t
's root tree.
get_tree t k
is Tree.get_tree
applied to t
's root tree.
val key : t -> path -> kinded_key option Lwt.t
id t k
The type for write errors.
v
instead of the one we were waiting for.val write_error_t : write_error Irmin.Type.t
val set :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
t ->
path ->
contents ->
(unit, write_error) Stdlib.result Lwt.t
set t k ~info v
sets k
to the value v
in t
. Discard any previous results but ensure that no operation is lost in the history.
This function always uses Metadata.default
as metadata. Use set_tree
with `Contents (c, m)
for different ones.
When clear
is set (the default), the tree cache is emptied upon the function's completion, mirroring the effect of invoking Tree.clear
.
The result is Error `Too_many_retries
if the concurrent operations do not allow the operation to commit to the underlying storage layer (livelock).
val set_exn :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
t ->
path ->
contents ->
unit Lwt.t
set_exn
is like set
but raise Failure _
instead of using a result type.
val set_tree :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
t ->
path ->
tree ->
(unit, write_error) Stdlib.result Lwt.t
set_tree
is like set
but for trees.
val set_tree_exn :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
t ->
path ->
tree ->
unit Lwt.t
set_tree
is like set_exn
but for trees.
val remove :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
t ->
path ->
(unit, write_error) Stdlib.result Lwt.t
remove t ~info k
remove any bindings to k
in t
.
The result is Error `Too_many_retries
if the concurrent operations do not allow the operation to commit to the underlying storage layer (livelock).
val remove_exn :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
t ->
path ->
unit Lwt.t
remove_exn
is like remove
but raise Failure _
instead of a using result type.
val test_and_set :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
t ->
path ->
test:contents option ->
set:contents option ->
(unit, write_error) Stdlib.result Lwt.t
test_and_set ~test ~set
is like set
but it atomically checks that the tree is test
before modifying it to set
.
This function always uses Metadata.default
as metadata. Use test_and_set_tree
with `Contents (c, m)
for different ones.
The result is Error (`Test t)
if the current tree is t
instead of test
.
The result is Error `Too_many_retries
if the concurrent operations do not allow the operation to commit to the underlying storage layer (livelock).
val test_and_set_exn :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
t ->
path ->
test:contents option ->
set:contents option ->
unit Lwt.t
test_and_set_exn
is like test_and_set
but raise Failure _
instead of using a result type.
val test_and_set_tree :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
t ->
path ->
test:tree option ->
set:tree option ->
(unit, write_error) Stdlib.result Lwt.t
test_and_set_tree
is like test_and_set
but for trees.
val test_and_set_tree_exn :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
t ->
path ->
test:tree option ->
set:tree option ->
unit Lwt.t
test_and_set_tree_exn
is like test_and_set_exn
but for trees.
val test_set_and_get :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:(unit -> info) ->
t ->
path ->
test:contents option ->
set:contents option ->
(commit option, write_error) Stdlib.result Lwt.t
test_set_and_get
is like test_and_set
except it also returns the commit associated with updating the store with the new value if the test_and_set
is successful. No commit is returned if there was no update to the store.
val test_set_and_get_exn :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:(unit -> info) ->
t ->
path ->
test:contents option ->
set:contents option ->
commit option Lwt.t
test_set_and_get_exn
is like test_set_and_get
but raises Failure _
instead.
val test_set_and_get_tree :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:(unit -> info) ->
t ->
path ->
test:tree option ->
set:tree option ->
(commit option, write_error) Stdlib.result Lwt.t
test_set_and_get_tree
is like test_set_and_get
but for a tree
val test_set_and_get_tree_exn :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:(unit -> info) ->
t ->
path ->
test:tree option ->
set:tree option ->
commit option Lwt.t
test_set_and_get_tree_exn
is like test_set_and_get_tree
but raises Failure _
instead.
val merge :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
old:contents option ->
t ->
path ->
contents option ->
(unit, write_error) Stdlib.result Lwt.t
merge ~old
is like set
but merge the current tree and the new tree using old
as ancestor in case of conflicts.
This function always uses Metadata.default
as metadata. Use merge_tree
with `Contents (c, m)
for different ones.
The result is Error (`Conflict c)
if the merge failed with the conflict c
.
The result is Error `Too_many_retries
if the concurrent operations do not allow the operation to commit to the underlying storage layer (livelock).
val merge_exn :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
old:contents option ->
t ->
path ->
contents option ->
unit Lwt.t
merge_exn
is like merge
but raise Failure _
instead of using a result type.
val merge_tree :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
old:tree option ->
t ->
path ->
tree option ->
(unit, write_error) Stdlib.result Lwt.t
merge_tree
is like merge_tree
but for trees.
val merge_tree_exn :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
info:Info.f ->
old:tree option ->
t ->
path ->
tree option ->
unit Lwt.t
merge_tree
is like merge_tree
but for trees.
val with_tree :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
?strategy:[ `Set | `Test_and_set | `Merge ] ->
info:Info.f ->
t ->
path ->
(tree option -> tree option Lwt.t) ->
(unit, write_error) Stdlib.result Lwt.t
with_tree t k ~info f
replaces atomically the subtree v
under k
in the store t
by the contents of the tree f v
, using the commit info info ()
.
If v = f v
and allow_empty
is unset (default) then, the operation is a no-op.
If v != f v
and no other changes happen concurrently, f v
becomes the new subtree under k
. If other changes happen concurrently to that operations, the semantics depend on the value of strategy
:
strategy = `Set
, use set
and discard any concurrent updates to k
.strategy = `Test_and_set
(default), use test_and_set
and ensure that no concurrent operations are updating k
.strategy = `Merge
, use merge
and ensure that concurrent updates and merged with the values present at the beginning of the transaction.Note: Irmin transactions provides snapshot isolation guarantees: reads and writes are isolated in every transaction, but only write conflicts are visible on commit.
val with_tree_exn :
?clear:bool ->
?retries:int ->
?allow_empty:bool ->
?parents:commit list ->
?strategy:[ `Set | `Test_and_set | `Merge ] ->
info:Info.f ->
t ->
path ->
(tree option -> tree option Lwt.t) ->
unit Lwt.t
with_tree_exn
is like with_tree
but raise Failure _
instead of using a return type.
clone ~src ~dst
makes dst
points to Head.get src
. dst
is created if needed. Remove the current contents en dst
if src
is empty
.
val watch :
t ->
?init:commit ->
(commit Irmin.Diff.t -> unit Lwt.t) ->
watch Lwt.t
watch t f
calls f
every time the contents of t
's head is updated.
Note: even if f
might skip some head updates, it will never be called concurrently: all consecutive calls to f
are done in sequence, so we ensure that the previous one ended before calling the next one.
val watch_key :
t ->
path ->
?init:commit ->
((commit * tree) Irmin.Diff.t -> unit Lwt.t) ->
watch Lwt.t
watch_key t key f
calls f
every time the key
's value is added, removed or updated. If the current branch is deleted, no signal is sent to the watcher.
val unwatch : watch -> unit Lwt.t
unwatch w
disable w
. Return once the w
is fully disabled.
type 'a merge =
info:Info.f ->
?max_depth:int ->
?n:int ->
'a ->
(unit, Irmin.Merge.conflict) Stdlib.result Lwt.t
The type for merge functions.
merge_into ~into:x ~info:i t
merges t
's current branch into x
's current branch using the info i
. After that operation, the two stores are still independent. Similar to git merge <branch>
.
lca ?max_depth ?n msg t1 t2
returns the collection of least common ancestors between the heads of t1
and t2
branches.
max_depth
is the maximum depth of the exploration (default is max_int
). Return Error `Max_depth_reached
if this depth is exceeded.n
is the maximum expected number of lcas. Stop the exploration as soon as n
lcas are found. Return Error `Too_many_lcas
if more lcas
are found.val lcas_with_branch :
t ->
?max_depth:int ->
?n:int ->
branch ->
(commit list, lca_error) Stdlib.result Lwt.t
Same as lcas
but takes a branch ID as argument.
val lcas_with_commit :
t ->
?max_depth:int ->
?n:int ->
commit ->
(commit list, lca_error) Stdlib.result Lwt.t
Same as lcas
but takes a commmit as argument.
history ?depth ?min ?max t
is a view of the history of the store t
, of depth at most depth
, starting from the t
's head (or from max
if the head is not set) and stopping at min
if specified.
last_modified ?number c k
is the list of the last number
commits that modified path
, in ascending order of date. depth
is the maximum depth to be explored in the commit graph, if any. Default value for number
is 1.
module Branch : sig ... end
Manipulate branches.
Path
provides base functions for the stores's paths.
module Metadata : Irmin.Metadata.S with type t = metadata
Metadata
provides base functions for node metadata.
module Backend :
Irmin.Backend.S
with module Schema = Schema
with type Slice.t = slice
and type Repo.t = repo
and module Hash = Hash
and module Node.Path = Path
and type Contents.key = contents_key
and type Node.key = node_key
and type Commit.key = commit_key
with type Remote.endpoint = endpoint
Backend functions, which might be used by the backends.
val of_backend_node : repo -> Backend.Node.value -> node
val to_backend_node : node -> Backend.Node.value Lwt.t
val to_backend_portable_node : node -> Backend.Node_portable.t Lwt.t
val to_backend_commit : commit -> Backend.Commit.value
to_backend_commit c
is the backend commit object associated with the commit c
.
val of_backend_commit :
repo ->
Backend.Commit.Key.t ->
Backend.Commit.value ->
commit
of_backend_commit r k c
is the commit associated with the backend commit object c
that hash key k
in r
.
val save_contents :
[> Irmin.Perms.write ] Backend.Contents.t ->
contents ->
contents_key Lwt.t
Save a content into the database
val save_tree :
?clear:bool ->
repo ->
[> Irmin.Perms.write ] Backend.Contents.t ->
[> Irmin.Perms.read_write ] Backend.Node.t ->
tree ->
kinded_key Lwt.t
Save a tree into the database. Does not do any reads.
When clear
is set (the default), the tree cache is emptied upon the function's completion, mirroring the effect of invoking Tree.clear
.
Deprecated
val git_commit : Repo.t -> commit -> Git.Value.Commit.t option Lwt.t
git_commit repo h
is the commit corresponding to h
in the repository repo
.
val repo_of_git :
?head:Git.Reference.t ->
?bare:bool ->
?lock:Lwt_mutex.t ->
Git.t ->
Repo.t Lwt.t
to_repo t
is the Irmin repository associated to t
.