(***********************************************************************) (* *) (* OCaml *) (* *) (* Xavier Leroy, projet Cristal, INRIA Rocquencourt *) (* *) (* Copyright 1997 Institut National de Recherche en Informatique et *) (* en Automatique. All rights reserved. This file is distributed *) (* under the terms of the GNU Library General Public License, with *) (* the special exception on linking described in file ../LICENSE. *) (* *) (***********************************************************************) (** Marshaling of data structures. This module provides functions to encode arbitrary data structures as sequences of bytes, which can then be written on a file or sent over a pipe or network connection. The bytes can then be read back later, possibly in another process, and decoded back into a data structure. The format for the byte sequences is compatible across all machines for a given version of OCaml. Warning: marshaling is currently not type-safe. The type of marshaled data is not transmitted along the value of the data, making it impossible to check that the data read back possesses the type expected by the context. In particular, the result type of the [Marshal.from_*] functions is given as ['a], but this is misleading: the returned OCaml value does not possess type ['a] for all ['a]; it has one, unique type which cannot be determined at compile-type. The programmer should explicitly give the expected type of the returned value, using the following syntax: - [(Marshal.from_channel chan : type)]. Anything can happen at run-time if the object in the file does not belong to the given type. OCaml exception values (of type [exn]) returned by the unmarhsaller should not be pattern-matched over through [match ... with] or [try ... with], because unmarshalling does not preserve the information required for matching their exception constructor. Structural equalities with other exception values does not work either. Most other uses such as Printexc.to_string, will still work as expected. The representation of marshaled values is not human-readable, and uses bytes that are not printable characters. Therefore, input and output channels used in conjunction with [Marshal.to_channel] and [Marshal.from_channel] must be opened in binary mode, using e.g. [open_out_bin] or [open_in_bin]; channels opened in text mode will cause unmarshaling errors on platforms where text channels behave differently than binary channels, e.g. Windows. *) type extern_flags = No_sharing (** Don't preserve sharing *) | Closures (** Send function closures *) | Compat_32 (** Ensure 32-bit compatibility *) (** The flags to the [Marshal.to_*] functions below. *) val to_channel : out_channel -> 'a -> extern_flags list -> unit (** [Marshal.to_channel chan v flags] writes the representation of [v] on channel [chan]. The [flags] argument is a possibly empty list of flags that governs the marshaling behavior with respect to sharing, functional values, and compatibility between 32- and 64-bit platforms. If [flags] does not contain [Marshal.No_sharing], circularities and sharing inside the value [v] are detected and preserved in the sequence of bytes produced. In particular, this guarantees that marshaling always terminates. Sharing between values marshaled by successive calls to [Marshal.to_channel] is neither detected nor preserved, though. If [flags] contains [Marshal.No_sharing], sharing is ignored. This results in faster marshaling if [v] contains no shared substructures, but may cause slower marshaling and larger byte representations if [v] actually contains sharing, or even non-termination if [v] contains cycles. If [flags] does not contain [Marshal.Closures], marshaling fails when it encounters a functional value inside [v]: only 'pure' data structures, containing neither functions nor objects, can safely be transmitted between different programs. If [flags] contains [Marshal.Closures], functional values will be marshaled as a the position in the code of the program together with the values corresponding to the free variables captured in the closure. In this case, the output of marshaling can only be read back in processes that run exactly the same program, with exactly the same compiled code. (This is checked at un-marshaling time, using an MD5 digest of the code transmitted along with the code position.) The exact definition of which free variables are captured in a closure is not specified and can very between bytecode and native code (and according to optimization flags). In particular, a function value accessing a global reference may or may not include the reference in its closure. If it does, unmarshaling the corresponding closure will create a new reference, different from the global one. If [flags] contains [Marshal.Compat_32], marshaling fails when it encounters an integer value outside the range [[-2{^30}, 2{^30}-1]] of integers that are representable on a 32-bit platform. This ensures that marshaled data generated on a 64-bit platform can be safely read back on a 32-bit platform. If [flags] does not contain [Marshal.Compat_32], integer values outside the range [[-2{^30}, 2{^30}-1]] are marshaled, and can be read back on a 64-bit platform, but will cause an error at un-marshaling time when read back on a 32-bit platform. The [Mashal.Compat_32] flag only matters when marshaling is performed on a 64-bit platform; it has no effect if marshaling is performed on a 32-bit platform. *) external to_bytes : 'a -> extern_flags list -> bytes = "caml_output_value_to_string" (** [Marshal.to_string v flags] returns a byte sequence containing the representation of [v]. The [flags] argument has the same meaning as for {!Marshal.to_channel}. *) external to_string : 'a -> extern_flags list -> string = "caml_output_value_to_string" (** Same as [to_bytes] but return the result as a string instead of a byte sequence. *) val to_buffer : bytes -> int -> int -> 'a -> extern_flags list -> int (** [Marshal.to_buffer buff ofs len v flags] marshals the value [v], storing its byte representation in the sequence [buff], starting at index [ofs], and writing at most [len] bytes. It returns the number of bytes actually written to the sequence. If the byte representation of [v] does not fit in [len] characters, the exception [Failure] is raised. *) val from_channel : in_channel -> 'a (** [Marshal.from_channel chan] reads from channel [chan] the byte representation of a structured value, as produced by one of the [Marshal.to_*] functions, and reconstructs and returns the corresponding value.*) val from_bytes : bytes -> int -> 'a (** [Marshal.from_bytes buff ofs] unmarshals a structured value like {!Marshal.from_channel} does, except that the byte representation is not read from a channel, but taken from the string [buff], starting at position [ofs]. *) val from_string : string -> int -> 'a (** Same as [from_bytes] but take a string as argument instead of a byte sequence. *) val header_size : int (** The bytes representing a marshaled value are composed of a fixed-size header and a variable-sized data part, whose size can be determined from the header. {!Marshal.header_size} is the size, in bytes, of the header. {!Marshal.data_size}[ buff ofs] is the size, in bytes, of the data part, assuming a valid header is stored in [buff] starting at position [ofs]. Finally, {!Marshal.total_size} [buff ofs] is the total size, in bytes, of the marshaled value. Both {!Marshal.data_size} and {!Marshal.total_size} raise [Failure] if [buff], [ofs] does not contain a valid header. To read the byte representation of a marshaled value into a byte sequence, the program needs to read first {!Marshal.header_size} bytes into the sequence, then determine the length of the remainder of the representation using {!Marshal.data_size}, make sure the sequence is large enough to hold the remaining data, then read it, and finally call {!Marshal.from_bytes} to unmarshal the value. *) val data_size : bytes -> int -> int (** See {!Marshal.header_size}.*) val total_size : bytes -> int -> int (** See {!Marshal.header_size}.*)