This document attempts to describe portions of the API related to the new Unicode functionality and the best practices for upgrading existing functions to support Unicode. Your first stop should be README.UNICODE: it covers the general Unicode functionality and concepts without going into technical implementation details. Internal Encoding ================= UTF-16 is the internal encoding used for Unicode strings. UTF-16 consumes two bytes for any Unicode character in the Basic Multilingual Plane, which is where most of the current world's languages are represented. While being less memory efficient for basic ASCII text it simplifies the processing and makes interfacing with ICU easier, since ICU uses UTF-16 for its internal processing as well. Zval Structure Changes ====================== For IS_UNICODE type, we add another structure to the union: union { .... struct { UChar *val; /* Unicode string value */ int len; /* number of UChar's */ } ustr; .... } value; This cleanly separates the two types of strings and helps preserve backwards compatibility. To optimize access to IS_STRING and IS_UNICODE storage at runtime, we need yet another structure: union { .... struct { /* Universal string type */ zstr val; int len; } uni; .... } value; Where zstr ia union of char*, UChar*, and void*. Parameter Parsing API Modifications =================================== There are now five new specifiers: 'u', 't', 'T', 'U', 'S', 'x' and a new '&' modifier. 't' specifier ------------- This specifier indicates that the caller requires the incoming parameter to be string data (IS_STRING, IS_UNICODE). The caller has to provide the storage for string value, length, and type. void *str; int len; zend_uchar type; if (zend_parse_parameters(ZEND_NUM_ARGS() TSRMLS_CC, "t", &str, &len, &type) == FAILURE) { return; } if (type == IS_UNICODE) { /* process Unicode string */ } else { /* process binary string */ } For IS_STRING type, the length represents the number of bytes, and for IS_UNICODE the number of UChar's. When converting other types (numbers, booleans, etc) to strings, the exact behavior depends on the Unicode semantics switch: if on, they are converted to IS_UNICODE, otherwise to IS_STRING. 'u' specifier ------------- This specifier indicates that the caller requires the incoming parameter to be a Unicode encoded string. If a non-Unicode string is passed, the engine creates a copy of the string and automatically convert it to Unicode type before passing it to the internal function. No such conversion is necessary for Unicode strings, obviously. UChar *str; int len; if (zend_parse_parameters(ZEND_NUM_ARGS() TSRMLS_CC, "u", &str, &len) == FAILURE) { return; } /* process Unicode string */ 'T' specifier ------------- This specifier is useful when the function takes two or more strings and operates on them. Using 't' specifier for each one would be somewhat problematic if the passed-in strings are of mixed types, and multiple checks need to be performed in order to do anything. All parameters marked by the 'T' specifier are promoted to the same type. If at least one of the 'T' parameters is of Unicode type, then the rest of them are converted to IS_UNICODE. Otherwise all 'T' parameters are conveted to IS_STRING type. void *str1, *str2; int len1, len2; zend_uchar type1, type2; if (zend_parse_parameters(ZEND_NUM_ARGS() TSRMLS_CC, "TT", &str1, &len1, &type1, &str2, &len2, &type2) == FAILURE) { return; } if (type1 == IS_UNICODE) { /* process as Unicode, str2 is guaranteed to be Unicode as well */ } else { /* process as binary string, str2 is guaranteed to be the same */ } 'x' specifier ------------- This specifier acts as either 'u' or 's', depending on the value of the unicode semantics switch. If UG(unicode) is on, it behaves as 'u', and as 's' otherwise. The existing 's' specifier has been modified as well. If a Unicode string is passed in, it automatically copies and converts the string to the runtime encoding, and issues a warning. If a binary type is passed-in, no conversion is necessary. The '&' modifier can be used after 's' specifier to force a different converter instead. char *str; int len; if (zend_parse_parameters(ZEND_NUM_ARGS() TSRMLS_CC, "s&", &str, &len, UG(utf8_conv)) == FAILURE) { return; } /* here str is in UTF-8, if a Unicode string was passed in */ The 'U' and 'S' specifiers are similar to 'u' and 's' but they are more strict about the type of the passed-in parameter. If 'U' is specified and the binary string is passed in, the engine will issue a warning instead of doing automatic conversion. The converse applies to the 'S' specifier. Working in Unicode World ======================== Strings ------- A lot of internal functionality is controlled by the unicode.semantics switch. Its value is found in the Unicode globals variable, UG(unicode). It is either on or off for the entire request. The big thing is that there is a new string types: IS_UNICODE. This has its own storage in the value union part of zval (value.ustr) while non-unicode (binary) strings reuse the IS_STRING type and the value.str element of the zval. New macros exist (parallel to Z_STRVAL/Z_STRLEN) for accessing unicode strings. Z_USTRVAL(), Z_USTRLEN() - accesses the value (as a UChar*) and length (in code units) of the Unicode type string value.ustr.val value.ustr.len Z_UNIVAL(), Z_UNILEN() - accesses the value (as a zstr) and length (in type-appropriate units) value.uni.val value.uni.len Z_USTRCPLEN() - gives the number of codepoints (not units) in the Unicode type string This macro examines the actual string taking into account Surrogate Pairs and returns the number of UChar32(UTF32) codepoints which may be less than the number of UChar(UTF16) codeunits found in the string buffer. If this value will be used repeatedly, consider storing it in a local variable to avoid having to reexamine the string every time. ZVAL_* macros ------------- The 'dup' parameter to the ZVAL_STRING()/RETVAL_STRING()/RETURN_STRING() type macros has been extended slightly. The following defines are now encouraged instead: #define ZSTR_DUPLICATE (1<<0) #define ZSTR_AUTOFREE (1<<1) ZSTR_DUPLICATE (which has a resulting value of 1) serves the same purpose as a truth value in old-style 'dup' flags. The value of 1 was specifically chosen to match the common practice of passing a 1 for this parameter. Warning: If you find extension code which uses a truth value other than one for the dup flag, its logic should be modified to explicitly pass ZSTR_DUPLICATE instead. ZSTR_AUTOFREE is used with macros such as ZVAL_RT_STRING which may populate Unicode zvals from non-unicode source strings. When UG(unicode) is on, the source string will be implicitly copied (to make a UChar* version). If the original string needed copying anyway this is fine. However if the original string was emalloc()'d and would have ordinarily been given to the engine (i.e. RETURN_STRING(estrdup("foo"), 0)) then it will need to be freed in UG(unicode) mode to avoid leaking. The ZSTR_AUTOFREE flag ensures that the original string is freed in UG(unicode) mode. ZVAL_UNICODE(pzv, str, dup), ZVAL_UNICODEL(pzv, str, str_len, dup) - Sets zval to hold a Unicode string. Takes the same parameters as Z_STRING(), Z_STRINGL(). ZVAL_U_STRING(conv, pzv, str, dup), ZVAL_U_STRINGL(conv, pzv, str, str_len, dup) - When UG(unicode) is off, it's equivalent to Z_STRING(), ZSTRINGL() and the conv parameter is ignored. When UG(unicode) is on, it sets zval to hold a Unicode representation of the passed-in string using the UConverter* specified by conv. Since a new string is always created in this case, passing ZSTR_DUPLICATE for 'dup' does not matter, but ZSTR_AUTOFREE will be used will be used to efree the original value ZVAL_RT_STRING(pzv, str, dup), ZVAL_RT_STRINGL(pzv, str, str_len, dup) - When UG(unicode) is off, it's equivalent to Z_STRING(), Z_STRINGL(). When UG(unicode) is on, it takes the input string, converts it to Unicode using the runtime_encoding converter and sets zval to it. Since a new string is always created in this case, passing ZSTR_DUPLICATE for 'dup' does not matter, but ZSTR_AUTOFREE will be used will be used to efree the original value ZVAL_ASCII_STRING(pzv, str, dup), ZVAL_ASCII_STRINGL(pzv, str, str_len, dup) - When UG(unicode) is off, it's equivalent to Z_STRING(), Z_STRINGL(). When UG(unicode) is on, it takes the input string, converts it to Unicode using an ASCII converter and sets zval to it. Since a new string is always created in this case, passing ZSTR_DUPLICATE for 'dup' does not matter, but ZSTR_AUTOFREE will be used will be used to efree the original value ZVAL_UTF8_STRING(pzv, str, dup), ZVAL_UTF8_STRINGL(pzv, str, str_len, dup) - When UG(unicode) is off, it's equivalent to Z_STRING(), Z_STRINGL(). When UG(unicode) is on, it takes the input string, converts it to Unicode using a UTF8 converter and sets zval to it. Since a new string is always created in this case, passing ZSTR_DUPLICATE for 'dup' does not matter, but ZSTR_AUTOFREE will be used will be used to efree the original value ZVAL_ZSTR(pzv, type, zstr, dup), ZVAL_ZSTRL(pzv, type, zstr, zstr_len, dup) - This macro uses 'type' to switch between calling ZVAL_STRING(pzv, zstr.s, dup) and ZVAL_UNICODE(pzv, zstr.u, dup). No conversion happens so the presense of absense of ZSTR_AUTOFREE is ignored. ZVAL_TEXT(pzv, zstr, dup), ZVAL_TEXTL(pzv, zstr, zstr_len, dup) - This macro sets the zval to hold either a Unicode or a normal string, depending on the value of UG(unicode). No conversion happens, so be certain that the string passed in matches the type expected by UG(unicode). One example of its usage would be to initialize zval to hold the name of a user function. ZVAL_EMPTY_UNICODE(pzv) / ZVAL_EMPTY_TEXT(pzv) - These macros work identically to ZVAL_EMPTY_STRING() with the UNICODE version always generating an IS_UNICODE zval, and the TEXT version generating a UG(unicode) dependent string type. ZVAL_UCHAR32(pzv, char) - Converts the character provided into a UChar string (which may potentially be 1 or 2 characters long in the case of surrogate pairs) and dispatches to ZVAL_UNICODEL(). As usual, for each ZVAL_* macro, there is a matching RETVAL_* and RETURN_* macro. Conversion Macros ----------------- convert_to_string_with_converter(zval *op, UConverter *conv) - converts a zval to native string using the specified converter, if necessary. convert_to_unicode_with_converter(zval *op, UConverter *conv) - converts a zval to Unicode string using the specified converter, if necessary. convert_to_unicode(zval *op) - converts a zval to Unicode string. convert_to_string(zval *op) - Behaves just as it currently does, converting to IS_STRING type convert_to_text(zval *op) - converts a zval to either Unicode or native string, depending on the value of UG(unicode) switch zend_ascii_to_unicode() function can be used to convert an ASCII char* string to Unicode. This is useful especially for inline string literals, in which case you can simply use USTR_MAKE() macro, e.g.: UChar* ustr; ustr = USTR_MAKE("main"); If you need to initialize a few such variables, it may be more efficient to use ICU macros, which avoid the conversion, depending on the platform. See [1] for more information. USTR_FREE(zstr) can be used to free a UChar* string safely, since it checks for NULL argument. USTR_LEN() takes a zstr as its argument, and depending on the UG(unicode) value, and returns its strlen() or u_strlen(). Array Manipulation ------------------ The add_next_index_*(), add_index_*() and add_assoc_*() functions have been significantly expanded both to allow for the unicode type as a value and to permit various types of keys. Values: In the following examples, {1} represents a placeholder for the keytype and its arguments (covered later). add_{1}_unicode(zval *arr, {1}, UChar *ustr, int dup); add_{1}_unicodel(zval *arr, {1}, UChar *ustr, int ustr_len, int dup); - Works like add_{1}_string() and add_{1}_stringl() but takes a UChar* value and adds an IS_UNICODE type. add_{1}_rt_string(zval *arr, {1}, char *str, int dup); add_{1}_rt_stringl(zval *arr, {1}, char *str, int str_len, int dup); - Works like add_{1}_string() and add_{1}_stringl() but converts the char* value to Unicode using runtime encoding when UG(unicode) is on. add_{1}_ascii_string(zval *arr, {1}, char *str, int dup); add_{1}_ascii_stringl(zval *arr, {1}, char *str, int str_len, int dup); - Works like add_{1}_rt_string() and add_{1}_rt_stringl() but uses an ASCII converter rather than runtime encoding. add_{1}_utf8_string(zval *arr, {1}, char *str, int dup); add_{1}_utf8_stringl(zval *arr, {1}, char *str, int str_len, int dup); - Works like add_{1}_rt_string() and add_{1}_rt_stringl() but uses a UTF8 converter rather than runtime encoding. add_{1}_text(zval *arr, {1}, zstr str, int dup); add_{1}_textl(zval *arr, {1}, zstr str, int str_len, int dup); - Wrapper which dispatches to add_{1}_string(l)() or add_{1}_unicode(l)() depending on the setting of UG(unicode). add_{1}_zstr(zval *arr, {1}, zend_uchar type, zstr str, int dup); add_{1}_zstrl(zval *arr, {1}, zend_uchar type, zstr str, int str_len, int dup); - Works like add_{1}_text() and add_{1}_textl(), but dispatches based on 'type'. Keys: In the following example, the zval* type is used for values, however each of the value types (including those listed above) are supported. The existing key types work as they always have: add_next_index_zval(zval *arr, zval *val); add_index_zval(zval *arr, long idx, zval *val); add_assoc_zval(zval *arr, char *key, zval *val); add_assoc_zval_ex(zval *arr, char *key, int key_len, zval *val); . Associative keys are considered binary (IS_STRING) . Remember that key_len includes the terminating NULL The following additional methods provide unicode capable keytypes: add_u_assoc_zval(zval *arr, zend_uchar type, zstr key, zval *val); add_u_assoc_zval_ex(zval *arr, zend_uchar type, zstr key, int key_len, zval *val); . When type==IS_STRING, these behave identically to their add_assoc_zval() and add_assoc_zval_ex() counterparts. When type==IS_STRING, the key is considered to be Unicode (UChar*). add_rt_assoc_zval(zval *arr, char *key, zval *val); add_rt_assoc_zval_ex(zval *arr, char *key, int key_len, zval *val); . When UG(unicode) is off, these behave identically to their add_assoc_zval() and add_assoc_zval_ex() counterparts. When UG(unicode) is on, key is converted to Unicode using runtime encoding. add_ascii_assoc_zval(zval *arr, char *key, zval *val); add_ascii_assoc_zval_ex(zval *arr, char *key, int key_len, zval *val); . When UG(unicode) is off, these behave identically to their add_assoc_zval() and add_assoc_zval_ex() counterparts. When UG(unicode) is on, key is converted to Unicode using an ASCII converter. add_utf8_assoc_zval(zval *arr, char *key, zval *val); add_utf8_assoc_zval_ex(zval *arr, char *key, int key_len, zval *val); . When UG(unicode) is off, these behave identically to their add_assoc_zval() and add_assoc_zval_ex() counterparts. When UG(unicode) is on, key is converted to Unicode using a UTF8 converter. Keytype and Valuetype specification may be mixed in any combination, for example: add_utf8_assoc_ascii_stringl_ex(zval *arr, char *key, int key_len, char *val, int val_len, int dup); Miscellaneous ------------- UBYTES() macro can be used to obtain the number of bytes necessary to store the given number of UChar's. The typical usage is: char *constant_name = colon + (UG(unicode)?UBYTES(2):2); Code Points and Code Units -------------------------- Unicode type strings are in the UTF-16 encoding where 1 Unicode character may be represented by 1 or 2 UChar's. Each UChar is referred to as a "code unit", and a full Unicode character as a "code point". Consequently, number of code units and number of code points for the same Unicode string may be different. This has many implications, the most important of which is that you cannot simply index the UChar* string to get the desired codepoint. The zval's value.ustr.len contains the number of code units (UChar -- UTF16). To obtain the number of code points, one can use u_countChar32() ICU API function or Z_USTRCPLEN() macro. ICU provides a number of macros for working with UTF-16 strings on the codepoint level [2]. They allow you to do things like obtain a codepoint at random code unit offset, move forward and backward over the string, etc. There are two versions of iterator macros, *_SAFE and *_UNSAFE. It is strong recommended to use *_SAFE version, since they handle unpaired surrogates and check for string boundaries. Here is an example of how to move through UChar* string and work on codepoints. UChar *str = ...; int32_t str_len = ...; UChar32 codepoint; int32_t offset = 0; while (offset < str_len) { U16_NEXT(str, offset, str_len, codepoint); /* now we have the Unicode character in codepoint */ } There is not macro to get a codepoint at a certain code point offset, but there is a Zend API function that does it. inline UChar32 zend_get_codepoint_at(UChar *str, int32_t length, int32_t n); To retrieve 3rd codepoint, you would call: zend_get_codepoint_at(str, str_len, 3); If you have a UChar32 codepoint and need to put it into a UChar* string, there is another helper function, zend_codepoint_to_uchar(). It takes a single UChar32 and converts it to a UChar sequence (1 or 2 UChar's). UChar buf[8]; UChar32 codepoint = 0x101a2; int8_t num_uchars; num_uchars = zend_codepoint_to_uchar(codepoint, buf); The return value is the number of resulting UChar's or 0, which indicates invalid codepoint. Memory Allocation ----------------- For ease of use and to reduce possible bugs, there are memory allocation functions specific to Unicode strings. Please use them at all times when allocating UChar's. eumalloc(size) eurealloc(ptr, size) eustrndup(s, length) eustrdup(s) peumalloc(size, persistent) peurealloc(ptr, size, persistent) The size parameter refers to the number of UChar's, not bytes. zend_zstrndup(type, zstr, length) Hashes ------ Hashes API has been upgraded to work with Unicode and binary strings. All hash functions that worked with string keys now have their equivalent zend_u_hash_* API. The zend_u_hash_* functions take the type of the key string as the second argument. When UG(unicode) switch is on, the IS_STRING keys are upconverted to IS_UNICODE and then used in the hash lookup. A new HASH_KEY constant has been added for differentiating key types: . HASH_KEY_IS_UNICODE Note that zend_hash_get_current_key_ex() does not have a zend_u_hash_* version. It returns the key as a char* pointer, you can can cast it appropriately based on the key type. Identifiers and Class Entries ----------------------------- In Unicode mode all the identifiers are Unicode strings. This means that while various structures such as zend_class_entry, zend_function, etc store the identifier name as a char* pointer, it will actually point to UChar* string. Be careful when accessing the names of classes, functions, and such -- always check UG(unicode) before using them. Formatted Output ---------------- Since UTF-16 strings frequently contain NULL bytes, you cannot simpley use %s format to print them out. Towards that end, output functions such as php_printf(), spprintf(), etc now have three different formats for use with Unicode strings: %r This format treats the corresponding argument as a Unicode string. The string is automatically converted to the output encoding. If you wish to apply a different converter to the string, use %*r and pass the converter before the string argument. UChar *class_name = USTR_NAME("ReflectionClass"); zend_printf("%r", class_name); spprintf(&utf8_buffer, 0, "%*r", UG(utf8_conv), class_name); %R This format requires at least two arguments: the first one specifies the type of the string to follow (IS_STRING or IS_UNICODE), and the second one - the string itself. If the string is of Unicode type, it is automatically converted to the output encoding. If you wish to apply a different converter to the string, use %*R and pass the converter before the string argument. zend_throw_exception_ex(U_CLASS_ENTRY(reflection_exception_ptr), 0 TSRMLS_CC, "Interface %R does not exist", Z_TYPE_P(class_name), Z_UNIVAL_P(class_name)); %v This format takes only one parameter, the string, but the expected string type depends on the UG(unicode) value. If the string is of Unicode type, it is automatically converted to the output encoding. If you wish to apply a different converter to the string, use %*R and pass the converter before the string argument. zend_error(E_WARNING, "%v::__toString() did not return anything", Z_OBJCE_P(object)->name); Since [v]spprintf() can only output native strings there are also the new functions [v]uspprintf() and [v]zspprintf() that create unicode strings and return the number of characters printed. That is they return the length rather than the byte size. The second pair of functions also takes an additional type parameter that allows to create a string of arbitrary type. The following example illustrates the use. Assume it fetches a unicode/native string into path, path_len and path_type inorder to create sub_name, sub_len and sub_type. zstr path, sub_name; int path_len, sub_len; zend_uchar path_type, sub_type; /* fetch */ if (path.v) { sub_type = path_type; sub_len = zspprintf(path_type, &sub_name, 0, "%R%c%s", path_type, path, DEFAULT_SLASH, entry.d_name); } Upgrading Functions =================== Let's take a look at a couple of functions that have been upgraded to support new string types. substr() -------- This functions returns part of a string based on offset and length parameters. zstr str; int str_len, cp_len; zend_uchar str_type; if (zend_parse_parameters(ZEND_NUM_ARGS() TSRMLS_CC, "tl|l", &str, &str_len, &str_type, &f, &l) == FAILURE) { return; } The first thing we notice is that the incoming string specifier is 't', which means that we can accept all 3 string types. The 'str' variable is declared as zstr, because it can point to either UChar* or char*. The actual type of the incoming string is stored in 'str_type' variable. if (str_type == IS_UNICODE) { cp_len = u_countChar32(str.u, str_len); } else { cp_len = str_len; } If the string is a Unicode one, we cannot rely on the str_len value to tell us the number of characters in it. Instead, we call u_countChar32() to obtain it. The next several lines normalize start and length parameters to fit within the string. Nothing new here. Then we locate the appropriate segment. if (str_type == IS_UNICODE) { int32_t start = 0, end = 0; U16_FWD_N(str.u, end, str_len, f); start = end; U16_FWD_N(str.u, end, str_len, l); RETURN_UNICODEL(str.u + start, end-start, ZSTR_DUPLICATE); Since codepoint (character) #n is not necessarily at offset #n in Unicode strings, we start at the beginning and iterate forward until we have gone through the required number of codepoints to reach the start of the segment. Then we save the location in 'start' and continue iterating through the number of codepoints specified by the offset. Once that's done, we can return the segment as a Unicode string. } else { RETURN_STRINGL(str.s + f, l, ZSTR_DUPLICATE); } For native strings, we can return the segment directly. strrev() -------- Let's look at strrev() which requires somewhat more complicated upgrade. While one of the guidelines for upgrades is that combining sequences are not really taken into account during processing -- substr() can break them up, for example -- in this case, we actually should be concerned, because reversing combining sequence may result in a completely different string. To illustrate: a (U+0061 LATIN SMALL LETTER A) o (U+006f LATIN SMALL LETTER O) + ' (U+0301 COMBINING ACUTE ACCENT) + _ (U+0320 COMBINING MINUS SIGN BELOW) l (U+006C LATIN SMALL LETTER L) Reversing this would result in: l (U+006C LATIN SMALL LETTER L) + _ (U+0320 COMBINING MINUS SIGN BELOW) + ' (U+0301 COMBINING ACUTE ACCENT) o (U+006f LATIN SMALL LETTER O) a (U+0061 LATIN SMALL LETTER A) All of a sudden the combining marks are being applied to 'l' instead of 'o'. To avoid this, we need to treat combininig sequences as a unit, by checking the combining character class of each character with u_getCombiningClass(). strrev() obtains its single argument, a string, and unless the string is of Unicode type, processes it exactly as before, simply swapping bytes around. For Unicode case, the magic is like this: int32_t i, x1, x2; UChar32 ch; UChar *u_s, *u_n, *u_p; u_n = eumalloc(Z_USTRLEN_PP(str)+1); u_p = u_n; u_s = Z_USTRVAL_PP(str); i = Z_USTRLEN_PP(str); while (i > 0) { U16_PREV(u_s, 0, i, ch); if (u_getCombiningClass(ch) == 0) { u_p += zend_codepoint_to_uchar(ch, u_p); } else { x2 = i; do { U16_PREV(u_s, 0, i, ch); } while (u_getCombiningClass(ch) != 0); x1 = i; while (x1 <= x2) { U16_NEXT(u_s, x1, Z_USTRLEN_PP(str), ch); u_p += zend_codepoint_to_uchar(ch, u_p); } } } *u_p = 0; The basic idea is to walk the string backwards from the end, using U16_PREV() macro. If the combining class of the current character is 0, meaning it's a base character and not a combining mark, we simply append it to the new string. Otherwise, we save the location of the index and do a run over the characters until we get to the next one with combining class 0. At that point we append the sequence as is, without reversing, to the new string. Voila. Note that the code uses zend_codepoint_to_uchar() to convert full Unicode characters (UChar32 type) to 1 or 2 UTF-16 code units (UChar type). realpath() ---------- Filenames use their own converter as it's not uncommon, for example, to need to access files on a filesystem with latin1 entries while outputting UTF8 runtime content. The most common approach to parsing filenames can be found in realpath(): zval **ppfilename; char *filename; int filename_len; if (zend_parse_parameters(ZEND_NUM_ARGS() TSRMLS_CC, "Z", &ppfilename) == FAILURE || php_stream_path_param_encode(ppfilename, &filename, &filename_len, REPORT_ERRORS, FG(default_context)) == FAILURE) { return; } Here, the filename is taken first as a generic zval**, then converted (separating if necessary) and populated into local char* and int storage. The filename will be converted according to unicode.filesystem_encoding unless the wrapper specified overrides this with its own conversion function (The http:// wrapper, for example, enforces utf8 conversion). rmdir() ------- If the function accepts a context parameter, then this context should be used in place of FG(default_context) zval **ppdir, *zcontext = NULL; char *dir; int dir_len; if (zend_parse_parameters(ZEND_NUM_ARGS() TSRMLS_CC, "Z|r", &ppdir, &zcontext) == FAILURE) { return; } context = php_stream_context_from_zval(zcontext, 0); if (php_stream_path_param_encode(ppdir, &dir, &dir_len, REPORT_ERRORS, context) == FAILURE) { return; } sqlite_query() -------------- If the function's underlying library expects a particular encoding (i.e. UTF8), then the alternate form of the string parameter may be used with zend_parse_parameters(). char *sql; int sql_len; if (zend_parse_parameters(ZEND_NUM_ARGS() TSRMLS_CC, "s&", &sql, &sql_len, UG(utf8_conv)) == FAILURE) { return; } Converters ========== Standard Converters ------------------- The following converters (UConverter*) are initialized by Zend and are always available (regardless of UG(unicode) mode): UG(utf8_conv) UG(ascii_conv) UG(fallback_encoding_conv) - UTF8 unless overridden by INI setting unicode.fallback_encoding Additional converters will be optionally initialized depending on INI settings: UG(runtime_encoding_conv) - unicode.runtime_encoding . Unicode output generated by a script will be encoding using this converter UG(script_encoding_conv) - unicode.script_encoding . Scripts read from disk will be decoded using this converter UG(filesystem_encoding_conv) - unicode.filesystem_encoding . Filenames and paths will be encoding using this converter Since these additional converters may not be instatiated (because their INI value is not set), all uses of these converters must be wrapped in ZEND_U_CONVERTER() for safety. If the converter hasn't been instantiated, then UG(fallback_encoding_conv) will be used instead. For example, RETURN_RT_STRING("foo", ZSTR_DUPLICATE); expands out to: RETURN_U_STRING(ZEND_U_CONVERTER(UG(runtime_encoding_conv)), "foo", ZSTR_DUPLICATE); Which uses UG(runtime_encoding_conv) if it's been set, otherwise using UG(fallback_encoding_conv). Note that the INI setting unicode.stream_encoding does not instantiate a UConverter* automatically for use by the process/thread, it stores the value as a string for use during fopen() style calls where a UConverter* is instantiated for that particular stream. References ========== [1] http://icu.sourceforge.net/apiref/icu4c/ustring_8h.html#a1 [2] http://icu.sourceforge.net/apiref/icu4c/utf16_8h.html vim: set et ai tw=76 fo=tron21: