2011-01-24 15:00:09 -05:00
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PEP: 393
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Title: Flexible String Representation
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2011-01-24 15:14:21 -05:00
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Version: $Revision$
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Last-Modified: $Date$
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2011-01-24 15:00:09 -05:00
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Author: Martin v. Löwis <martin@v.loewis.de>
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2011-10-15 10:06:07 -04:00
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Status: Final
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2011-01-24 15:00:09 -05:00
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Type: Standards Track
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Content-Type: text/x-rst
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Created: 24-Jan-2010
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Python-Version: 3.3
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Post-History:
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Abstract
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========
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The Unicode string type is changed to support multiple internal
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representations, depending on the character with the largest Unicode
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ordinal (1, 2, or 4 bytes). This will allow a space-efficient
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representation in common cases, but give access to full UCS-4 on all
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systems. For compatibility with existing APIs, several representations
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may exist in parallel; over time, this compatibility should be phased
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out. The distinction between narrow and wide Unicode builds is
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dropped. An implementation of this PEP is available at [1]_.
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Rationale
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=========
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There are two classes of complaints about the current implementation
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of the unicode type: on systems only supporting UTF-16, users complain
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that non-BMP characters are not properly supported. On systems using
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UCS-4 internally (and also sometimes on systems using UCS-2), there is
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a complaint that Unicode strings take up too much memory - especially
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compared to Python 2.x, where the same code would often use ASCII
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strings (i.e. ASCII-encoded byte strings). With the proposed approach,
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ASCII-only Unicode strings will again use only one byte per character;
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while still allowing efficient indexing of strings containing non-BMP
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characters (as strings containing them will use 4 bytes per
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character).
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One problem with the approach is support for existing applications
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(e.g. extension modules). For compatibility, redundant representations
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may be computed. Applications are encouraged to phase out reliance on
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a specific internal representation if possible. As interaction with
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other libraries will often require some sort of internal
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representation, the specification chooses UTF-8 as the recommended way
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of exposing strings to C code.
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For many strings (e.g. ASCII), multiple representations may actually
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share memory (e.g. the shortest form may be shared with the UTF-8 form
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if all characters are ASCII). With such sharing, the overhead of
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compatibility representations is reduced. If representations do share
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data, it is also possible to omit structure fields, reducing the base
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size of string objects.
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Specification
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=============
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Unicode structures are now defined as a hierarchy of structures,
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namely::
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typedef struct {
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PyObject_HEAD
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Py_ssize_t length;
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Py_hash_t hash;
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struct {
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unsigned int interned:2;
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unsigned int kind:2;
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unsigned int compact:1;
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unsigned int ascii:1;
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unsigned int ready:1;
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} state;
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wchar_t *wstr;
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} PyASCIIObject;
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typedef struct {
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PyASCIIObject _base;
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Py_ssize_t utf8_length;
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char *utf8;
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Py_ssize_t wstr_length;
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} PyCompactUnicodeObject;
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typedef struct {
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PyCompactUnicodeObject _base;
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union {
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void *any;
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Py_UCS1 *latin1;
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Py_UCS2 *ucs2;
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Py_UCS4 *ucs4;
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} data;
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} PyUnicodeObject;
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Objects for which both size and maximum character are known at
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creation time are called "compact" unicode objects; character data
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immediately follow the base structure. If the maximum character is
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less than 128, they use the PyASCIIObject structure, and the UTF-8
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data, the UTF-8 length and the wstr length are the same as the length
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of the ASCII data. For non-ASCII strings, the PyCompactObject
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structure is used. Resizing compact objects is not supported.
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Objects for which the maximum character is not given at creation time
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are called "legacy" objects, created through
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PyUnicode_FromStringAndSize(NULL, length). They use the
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PyUnicodeObject structure. Initially, their data is only in the wstr
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pointer; when PyUnicode_READY is called, the data pointer (union) is
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allocated. Resizing is possible as long PyUnicode_READY has not been
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called.
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The fields have the following interpretations:
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- length: number of code points in the string (result of sq_length)
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- interned: interned-state (SSTATE_*) as in 3.2
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- kind: form of string
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+ 00 => str is not initialized (data are in wstr)
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+ 01 => 1 byte (Latin-1)
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+ 10 => 2 byte (UCS-2)
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+ 11 => 4 byte (UCS-4);
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- compact: the object uses one of the compact representations
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(implies ready)
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- ascii: the object uses the PyASCIIObject representation
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(implies compact and ready)
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- ready: the canonical representation is ready to be accessed through
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PyUnicode_DATA and PyUnicode_GET_LENGTH. This is set either if the
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object is compact, or the data pointer and length have been
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initialized.
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- wstr_length, wstr: representation in platform's wchar_t
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(null-terminated). If wchar_t is 16-bit, this form may use surrogate
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pairs (in which cast wstr_length differs form length).
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wstr_length differs from length only if there are surrogate pairs
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in the representation.
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- utf8_length, utf8: UTF-8 representation (null-terminated).
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- data: shortest-form representation of the unicode string.
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The string is null-terminated (in its respective representation).
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All three representations are optional, although the data form is
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considered the canonical representation which can be absent only
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while the string is being created. If the representation is absent,
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the pointer is NULL, and the corresponding length field may contain
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arbitrary data.
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The Py_UNICODE type is still supported but deprecated. It is always
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defined as a typedef for wchar_t, so the wstr representation can double
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as Py_UNICODE representation.
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The data and utf8 pointers point to the same memory if the string uses
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only ASCII characters (using only Latin-1 is not sufficient). The data
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and wstr pointers point to the same memory if the string happens to
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fit exactly to the wchar_t type of the platform (i.e. uses some
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BMP-not-Latin-1 characters if sizeof(wchar_t) is 2, and uses some
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non-BMP characters if sizeof(wchar_t) is 4).
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String Creation
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---------------
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The recommended way to create a Unicode object is to use the function
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PyUnicode_New::
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PyObject* PyUnicode_New(Py_ssize_t size, Py_UCS4 maxchar);
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Both parameters must denote the eventual size/range of the strings.
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In particular, codecs using this API must compute both the number of
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characters and the maximum character in advance. An string is
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allocated according to the specified size and character range and is
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null-terminated; the actual characters in it may be uninitialized.
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PyUnicode_FromString and PyUnicode_FromStringAndSize remain supported
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for processing UTF-8 input; the input is decoded, and the UTF-8
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representation is not yet set for the string.
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PyUnicode_FromUnicode remains supported but is deprecated. If the
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Py_UNICODE pointer is non-null, the data representation is set. If the
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pointer is NULL, a properly-sized wstr representation is allocated,
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which can be modified until PyUnicode_READY() is called (explicitly
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or implicitly). Resizing a Unicode string remains possible until it
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is finalized.
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PyUnicode_READY() converts a string containing only a wstr
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representation into the canonical representation. Unless wstr and data
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can share the memory, the wstr representation is discarded after the
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conversion. The macro returns 0 on success and -1 on failure, which
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happens in particular if the memory allocation fails.
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String Access
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-------------
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The canonical representation can be accessed using two macros
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PyUnicode_Kind and PyUnicode_Data. PyUnicode_Kind gives one of the
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values PyUnicode_WCHAR_KIND (0), PyUnicode_1BYTE_KIND (1),
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PyUnicode_2BYTE_KIND (2), or PyUnicode_4BYTE_KIND (3). PyUnicode_DATA
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gives the void pointer to the data. Access to individual characters
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should use PyUnicode_{READ|WRITE}[_CHAR]:
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- PyUnicode_READ(kind, data, index)
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- PyUnicode_WRITE(kind, data, index, value)
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- PyUnicode_READ_CHAR(unicode, index)
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All these macros assume that the string is in canonical form;
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callers need to ensure this by calling PyUnicode_READY.
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A new function PyUnicode_AsUTF8 is provided to access the UTF-8
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representation. It is thus identical to the existing
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_PyUnicode_AsString, which is removed. The function will compute the
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utf8 representation when first called. Since this representation will
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consume memory until the string object is released, applications
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should use the existing PyUnicode_AsUTF8String where possible
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(which generates a new string object every time). APIs that implicitly
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converts a string to a char* (such as the ParseTuple functions) will
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use PyUnicode_AsUTF8 to compute a conversion.
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New API
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-------
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This section summarizes the API additions.
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Macros to access the internal representation of a Unicode object
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(read-only):
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- PyUnicode_IS_COMPACT_ASCII(o), PyUnicode_IS_COMPACT(o),
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PyUnicode_IS_READY(o)
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- PyUnicode_GET_LENGTH(o)
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- PyUnicode_KIND(o), PyUnicode_CHARACTER_SIZE(o),
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PyUnicode_MAX_CHAR_VALUE(o)
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- PyUnicode_DATA(o), PyUnicode_1BYTE_DATA(o), PyUnicode_2BYTE_DATA(o),
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PyUnicode_4BYTE_DATA(o)
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Character access macros:
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- PyUnicode_READ(kind, data, index), PyUnicode_READ_CHAR(o, index)
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- PyUnicode_WRITE(kind, data, index, value)
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Other macros:
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- PyUnicode_READY(o)
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- PyUnicode_CONVERT_BYTES(from_type, to_type, begin, end, to)
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String creation functions:
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- PyUnicode_New(size, maxchar)
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- PyUnicode_FromKindAndData(kind, data, size)
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- PyUnicode_Substring(o, start, end)
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Character access utility functions:
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- PyUnicode_GetLength(o), PyUnicode_ReadChar(o, index),
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PyUnicode_WriteChar(o, index, character)
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- PyUnicode_CopyCharacters(to, to_start, from, from_start, how_many)
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- PyUnicode_FindChar(str, ch, start, end, direction)
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Representation conversion:
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- PyUnicode_AsUCS4(o, buffer, buflen)
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- PyUnicode_AsUCS4Copy(o)
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- PyUnicode_AsUnicodeAndSize(o, size_out)
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- PyUnicode_AsUTF8(o)
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- PyUnicode_AsUTF8AndSize(o, size_out)
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UCS4 utility functions:
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- Py_UCS4_{strlen, strcpy, strcat, strncpy, strcmp, strncpy, strcmp,
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strncmp, strchr, strrchr}
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Stable ABI
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----------
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The following functions are added to the stable ABI (PEP 384), as they
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are independent of the actual representation of Unicode objects:
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PyUnicode_New, PyUnicode_Substring, PyUnicode_GetLength,
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PyUnicode_ReadChar, PyUnicode_WriteChar, PyUnicode_Find,
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PyUnicode_FindChar.
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2011-01-27 16:16:50 -05:00
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GDB Debugging Hooks
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-------------------
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Tools/gdb/libpython.py contains debugging hooks that embed knowledge
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about the internals of CPython's data types, include PyUnicodeObject
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2011-09-27 17:46:28 -04:00
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instances. It has been updated to track the change.
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2011-01-27 16:16:50 -05:00
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2011-09-25 16:58:13 -04:00
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Deprecations, Removals, and Incompatibilities
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---------------------------------------------
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While the Py_UNICODE representation and APIs are deprecated with this
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PEP, no removal of the respective APIs is scheduled. The APIs should
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remain available at least five years after the PEP is accepted; before
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they are removed, existing extension modules should be studied to find
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out whether a sufficient majority of the open-source code on PyPI has
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been ported to the new API. A reasonable motivation for using the
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deprecated API even in new code is for code that shall work both on
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Python 2 and Python 3.
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2011-09-27 18:08:51 -04:00
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The following macros and functions are deprecated:
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- PyUnicode_FromUnicode
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- PyUnicode_GET_SIZE, PyUnicode_GetSize, PyUnicode_GET_DATA_SIZE,
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- PyUnicode_AS_UNICODE, PyUnicode_AsUnicode, PyUnicode_AsUnicodeAndSize
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- PyUnicode_COPY, PyUnicode_FILL, PyUnicode_MATCH
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- PyUnicode_Encode, PyUnicode_EncodeUTF7, PyUnicode_EncodeUTF8,
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PyUnicode_EncodeUTF16, PyUnicode_EncodeUTF32,
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PyUnicode_EncodeUnicodeEscape, PyUnicode_EncodeRawUnicodeEscape,
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PyUnicode_EncodeLatin1, PyUnicode_EncodeASCII,
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PyUnicode_EncodeCharmap, PyUnicode_TranslateCharmap,
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2011-09-28 21:56:12 -04:00
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PyUnicode_EncodeMBCS, PyUnicode_EncodeDecimal,
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2011-09-27 18:08:51 -04:00
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PyUnicode_TransformDecimalToASCII
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- Py_UNICODE_{strlen, strcat, strcpy, strcmp, strchr, strrchr}
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- PyUnicode_AsUnicodeCopy
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2011-09-28 18:01:23 -04:00
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- PyUnicode_GetMax
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2011-09-27 18:08:51 -04:00
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2011-09-25 16:58:13 -04:00
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_PyUnicode_AsDefaultEncodedString is removed. It previously returned a
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borrowed reference to an UTF-8-encoded bytes object. Since the unicode
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object cannot anymore cache such a reference, implementing it without
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leaking memory is not possible. No deprecation phase is provided,
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since it was an API for internal use only.
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Extension modules using the legacy API may inadvertently call
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PyUnicode_READY, by calling some API that requires that the object is
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ready, and then continue accessing the (now invalid) Py_UNICODE
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pointer. Such code will break with this PEP. The code was already
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flawed in 3.2, as there is was no explicit guarantee that the
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PyUnicode_AS_UNICODE result would stay valid after an API call (due to
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2011-09-28 21:56:12 -04:00
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the possibility of string resizing). Modules that face this issue
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2011-09-25 16:58:13 -04:00
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need to re-fetch the Py_UNICODE pointer after API calls; doing
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so will continue to work correctly in earlier Python versions.
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2011-01-27 16:42:35 -05:00
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Discussion
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==========
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Several concerns have been raised about the approach presented here:
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It makes the implementation more complex. That's true, but considered
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2011-08-26 18:50:22 -04:00
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worth it given the benefits.
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2011-01-27 16:16:50 -05:00
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2011-08-27 01:23:59 -04:00
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The Py_UNICODE representation is not instantaneously available,
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2011-01-27 16:47:00 -05:00
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slowing down applications that request it. While this is also true,
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applications that care about this problem can be rewritten to use the
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2011-08-28 14:51:49 -04:00
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data representation.
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2011-01-27 16:47:00 -05:00
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2011-08-28 14:12:38 -04:00
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Performance
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-----------
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Performance of this patch must be considered for both memory
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consumption and runtime efficiency. For memory consumption, the
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expectation is that applications that have many large strings will see
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a reduction in memory usage. For small strings, the effects depend on
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the pointer size of the system, and the size of the Py_UNICODE/wchar_t
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2011-08-28 14:51:49 -04:00
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type. The following table demonstrates this for various small ASCII
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2011-09-25 16:58:13 -04:00
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and Latin-1 string sizes and platforms.
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+-------+---------------------------------+---------------------------------+
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|string | Python 3.2 | This PEP |
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|size +----------------+----------------+----------------+----------------+
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| | 16-bit wchar_t | 32-bit wchar_t | ASCII | Latin-1 |
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| +---------+------+--------+-------+--------+-------+--------+-------+
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| | 32-bit |64-bit| 32-bit |64-bit | 32-bit |64-bit | 32-bit |64-bit |
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+-------+---------+------+--------+-------+--------+-------+--------+-------+
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|1 | 32 | 64 | 40 | 64 | 32 | 56 | 40 | 80 |
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+-------+---------+------+--------+-------+--------+-------+--------+-------+
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|2 | 40 | 64 | 40 | 72 | 32 | 56 | 40 | 80 |
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+-------+---------+------+--------+-------+--------+-------+--------+-------+
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|3 | 40 | 64 | 48 | 72 | 32 | 56 | 40 | 80 |
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+-------+---------+------+--------+-------+--------+-------+--------+-------+
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|4 | 40 | 72 | 48 | 80 | 32 | 56 | 48 | 80 |
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+-------+---------+------+--------+-------+--------+-------+--------+-------+
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|5 | 40 | 72 | 56 | 80 | 32 | 56 | 48 | 80 |
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+-------+---------+------+--------+-------+--------+-------+--------+-------+
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|6 | 48 | 72 | 56 | 88 | 32 | 56 | 48 | 80 |
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+-------+---------+------+--------+-------+--------+-------+--------+-------+
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|7 | 48 | 72 | 64 | 88 | 32 | 56 | 48 | 80 |
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+-------+---------+------+--------+-------+--------+-------+--------+-------+
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|8 | 48 | 80 | 64 | 96 | 40 | 64 | 48 | 88 |
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+-------+---------+------+--------+-------+--------+-------+--------+-------+
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2011-08-28 14:12:38 -04:00
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2011-08-28 15:44:21 -04:00
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The runtime effect is significantly affected by the API being
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used. After porting the relevant pieces of code to the new API,
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the iobench, stringbench, and json benchmarks see typically
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slowdowns of 1% to 30%; for specific benchmarks, speedups may
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happen as may happen significantly larger slowdowns.
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2011-08-28 14:12:38 -04:00
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2011-09-15 11:29:41 -04:00
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Porting Guidelines
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==================
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Only a small fraction of C code is affected by this PEP, namely code
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that needs to look "inside" unicode strings. That code doesn't
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necessarily need to be ported to this API, as the existing API will
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continue to work correctly. In particular, modules that need to
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support both Python 2 and Python 3 might get too complicated when
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simultaneously supporting this new API and the old Unicode API.
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In order to port modules to the new API, try to eliminate
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the use of these API elements:
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- the Py_UNICODE type,
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- PyUnicode_AS_UNICODE and PyUnicode_AsUnicode,
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2011-09-27 18:08:51 -04:00
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- PyUnicode_GET_SIZE and PyUnicode_GetSize, and
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2011-09-15 11:29:41 -04:00
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- PyUnicode_FromUnicode.
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When iterating over an existing string, or looking at specific
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characters, use indexing operations rather than pointer arithmetic;
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indexing works well for PyUnicode_READ(_CHAR) and PyUnicode_WRITE. Use
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void* as the buffer type for characters to let the compiler detect
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invalid dereferencing operations. If you do want to use pointer
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2011-09-28 21:56:12 -04:00
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arithmetics (e.g. when converting existing code), use (unsigned)
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2011-09-15 11:29:41 -04:00
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char* as the buffer type, and keep the element size (1, 2, or 4) in a
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variable. Notice that (1<<(kind-1)) will produce the element size
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given a buffer kind.
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When creating new strings, it was common in Python to start of with a
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heuristical buffer size, and then grow or shrink if the heuristics
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failed. With this PEP, this is now less practical, as you need not
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only a heuristics for the length of the string, but also for the
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maximum character.
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In order to avoid heuristics, you need to make two passes over the
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input: once to determine the output length, and the maximum character;
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then allocate the target string with PyUnicode_New and iterate over
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the input a second time to produce the final output. While this may
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sound expensive, it could actually be cheaper than having to copy the
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result again as in the following approach.
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If you take the heuristical route, avoid allocating a string meant to
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be resized, as resizing strings won't work for their canonical
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representation. Instead, allocate a separate buffer to collect the
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characters, and then construct a unicode object from that using
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PyUnicode_FromKindAndData. One option is to use Py_UCS4 as the buffer
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element, assuming for the worst case in character ordinals. This will
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allow for pointer arithmetics, but may require a lot of memory.
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Alternatively, start with a 1-byte buffer, and increase the element
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size as you encounter larger characters. In any case,
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PyUnicode_FromKindAndData will scan over the buffer to verify the
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maximum character.
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For common tasks, direct access to the string representation may not
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be necessary: PyUnicode_Find, PyUnicode_FindChar, PyUnicode_Ord, and
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PyUnicode_CopyCharacters help in analyzing and creating string
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2011-09-28 21:56:12 -04:00
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objects, operating on indexes instead of data pointers.
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2011-09-15 11:29:41 -04:00
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2011-09-26 06:25:49 -04:00
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References
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==========
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.. [1] PEP 393 branch
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https://bitbucket.org/t0rsten/pep-393
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2011-01-24 15:00:09 -05:00
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Copyright
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=========
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This document has been placed in the public domain.
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..
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Local Variables:
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mode: indented-text
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indent-tabs-mode: nil
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sentence-end-double-space: t
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fill-column: 70
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coding: utf-8
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End:
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