/* -*- c -*- |
|| This file is part of Pike. For copyright information see COPYRIGHT. |
|| Pike is distributed under GPL, LGPL and MPL. See the file COPYING |
|| for more information. |
*/ |
|
#include "global.h" |
#include "interpret.h" |
#include "svalue.h" |
#include "pike_macros.h" |
#include "object.h" |
#include "program.h" |
#include "array.h" |
#include "pike_error.h" |
#include "constants.h" |
#include "mapping.h" |
#include "stralloc.h" |
#include "multiset.h" |
#include "pike_types.h" |
#include "pike_memory.h" |
#include "threads.h" |
#include "module_support.h" |
#include "cyclic.h" |
#include "bignum.h" |
#include "main.h" |
#include "operators.h" |
#include "builtin_functions.h" |
#include "fsort.h" |
#include "port.h" |
#include "gc.h" |
#include "block_allocator.h" |
#include "pikecode.h" |
#include "opcodes.h" |
|
#include <ctype.h> |
#include <errno.h> |
#include <math.h> |
|
DECLARATIONS |
|
|
/*! @module System |
*/ |
|
#if defined(HAVE_MKTIME) && defined(HAVE_GMTIME) && defined(HAVE_LOCALTIME) |
PIKECLASS TM |
/*! @class TM |
*! A wrapper for the system struct tm time keeping structure. |
*! This can be used as a (very) lightweight alternative to Calendar. |
*/ |
{ |
CVAR struct tm t; |
CVAR time_t unix_time; |
CVAR int modified; |
CVAR struct pike_string *set_zone; |
|
#ifdef STRUCT_TM_HAS___TM_GMTOFF |
#define tm_zone __tm_zone |
#define tm_gmtoff __tm_gmtoff |
#define GET_GMTOFF(TM) ((TM)->tm_gmtoff) |
#define GET_ZONE(TM) ((TM)->tm_zone) |
#define SET_GMTOFF(TM, VAL) (((TM)->tm_gmtoff) = (VAL)) |
#define SET_ZONE(TM, VAL) (((TM)->tm_zone) = (VAL)) |
#elif defined(STRUCT_TM_HAS_GMTOFF) |
#define GET_GMTOFF(TM) ((TM)->tm_gmtoff) |
#define GET_ZONE(TM) ((TM)->tm_zone) |
#define SET_GMTOFF(TM, VAL) (((TM)->tm_gmtoff) = (VAL)) |
#define SET_ZONE(TM, VAL) (((TM)->tm_zone) = (VAL)) |
#else |
#define GET_GMTOFF(TM) 0 |
#define GET_ZONE(TM) ((char*)NULL) |
#define SET_GMTOFF(TM, VAL) (VAL) |
#define SET_ZONE(TM, VAL) (VAL) |
#endif |
|
#if 0 |
/* This is supposed to make any timezone work. |
* However: It does not really work. And makes things even slower than |
* the calendar module. |
*/ |
#ifndef HAVE_EXTERNAL_TIMEZONE |
#define timezone 0 |
#endif |
#define WITH_ZONE(RETURNTYPE, FUNCTION, ARGUMENTS, CALL ) \ |
static RETURNTYPE FUNCTION##_zone ARGUMENTS \ |
{ \ |
RETURNTYPE res; \ |
int reset = 0; \ |
char *old_zone = NULL; \ |
if( GET_ZONE(x) ) \ |
{ \ |
reset = 1; \ |
old_zone = getenv("TZ"); \ |
setenv("TZ", GET_ZONE(x), 1 ); \ |
tzset(); \ |
SET_GMTOFF(x, timezone); \ |
} \ |
\ |
res = FUNCTION CALL; \ |
\ |
if( reset ) \ |
{ \ |
if( old_zone ) \ |
setenv("TZ", old_zone, 1 ); \ |
else \ |
unsetenv( "TZ" ); \ |
tzset(); \ |
} \ |
return res; \ |
} |
|
WITH_ZONE(time_t,mktime,( struct tm *x ),(x)); |
WITH_ZONE(struct tm*,localtime,( time_t *t, struct tm *x ),(t)); |
WITH_ZONE(char *,asctime,( struct tm *x ),(x)); |
WITH_ZONE(int,strftime,( char *buffer, size_t max_len, char *format, struct tm *x ),(buffer,max_len,format,x)); |
#ifdef HAVE_STRPTIME |
WITH_ZONE(char *,strptime,( const char *str, const char *format, struct tm *x ),(str,format,x)); |
#endif |
#else |
#define strftime_zone strftime |
#define mktime_zone mktime |
#define strptime_zone strptime |
#define asctime_zone asctime |
#define localtime_zone(X,Y) localtime(X) |
#endif |
#ifndef HAVE_EXTERNAL_TIMEZONE |
#undef timezone |
#endif |
|
#define MODIFY(X) do{ THIS->modified = 1;THIS->t.X; }while(0) |
#define FIX_THIS() do { \ |
if(THIS->modified){ \ |
THIS->unix_time = mktime_zone( &THIS->t ); \ |
THIS->modified = 0; \ |
} \ |
} while(0) |
|
#ifdef HAVE_STRPTIME |
/* |
*! @decl int(0..1) strptime( string(1..255) format, string(1..255) data ) |
*! |
*! Parse the given @[data] using the format in @[format] as a date. |
*! |
*! %% The % character. |
*! |
*! %a or %A |
*! The weekday name according to the C locale, in abbreviated |
*! form or the full name. |
*! |
*! %b or %B or %h |
*! The month name according to the C locale, in abbreviated form |
*! or the full name. |
*! |
*! %c The date and time representation for the C locale. |
*! |
*! %C The century number (0-99). |
*! |
*! %d or %e |
*! The day of month (1-31). |
*! |
*! %D Equivalent to %m/%d/%y. |
*! |
*! %H The hour (0-23). |
*! |
*! %I The hour on a 12-hour clock (1-12). |
*! |
*! %j The day number in the year (1-366). |
*! |
*! %m The month number (1-12). |
*! |
*! %M The minute (0-59). |
*! |
*! %n Arbitrary whitespace. |
*! |
*! %p The C locale's equivalent of AM or PM. |
*! |
*! %R Equivalent to %H:%M. |
*! |
*! %S The second (0-60; 60 may occur for leap seconds; earlier also 61 was allowed). |
*! |
*! %t Arbitrary whitespace. |
*! |
*! %T Equivalent to %H:%M:%S. |
*! |
*! %U The week number with Sunday the first day of the week (0-53). |
*! |
*! %w The weekday number (0-6) with Sunday = 0. |
*! |
*! %W The week number with Monday the first day of the week (0-53). |
*! |
*! %x The date, using the C locale's date format. |
*! |
*! %X The time, using the C locale's time format. |
*! |
*! %y |
*! The year within century (0-99). When a century is not |
*! otherwise specified, values in the range 69-99 refer to years |
*! in the twentieth century (1969-1999); values in the range |
*! 00-68 refer to years in the twenty-first century (2000-2068). |
*! |
*! %Y The year, including century (for example, 1991). |
*! |
*/ |
PIKEFUN int(0..1) strptime( string(1..255) format, string(1..255) data ) |
{ |
if( format->size_shift || data->size_shift ) |
Pike_error("Only 8bit strings are supported\n"); |
THIS->modified = 1; |
if( strptime_zone( data->str, format->str, &THIS->t ) == NULL ) |
RETURN 0; |
RETURN 1; |
} |
#endif |
/*! @decl string(1..255) strftime( string(1..255) format ) |
*! See also @[Gettext.setlocale] |
*! |
*! Convert the structure to a string. |
*! |
*! %a The abbreviated weekday name according to the current locale |
*! |
*! %A The full weekday name according to the current locale. |
*! |
*! %b The abbreviated month name according to the current locale. |
*! |
*! %B The full month name according to the current locale. |
*! |
*! %c The preferred date and time representation for the current locale. |
*! |
*! %C The century number (year/100) as a 2-digit integer. |
*! |
*! %d The day of the month as a decimal number (range 01 to 31). |
*! |
*! %D Equivalent to %m/%d/%y. (for Americans only. Americans should note that in other countries %d/%m/%y is rather common. This means that in international context this format is ambiguous and should not be used.) |
*! |
*! %e Like %d, the day of the month as a decimal number, but a leading zero is replaced by a space. |
*! |
*! %E Modifier: use alternative format, see below. |
*! |
*! %F Equivalent to %Y-%m-%d (the ISO 8601 date format). (C99) |
*! |
*! %G The ISO 8601 week-based year (see NOTES) with century as a decimal number. The 4-digit year corresponding to the ISO week number (see %V). This has the same format and value as %Y, except that if the ISO week number belongs to the previous or next year, that year is used instead. |
*! |
*! %g Like %G, but without century, that is, with a 2-digit year (00-99). (TZ) |
*! |
*! %h Equivalent to %b. |
*! |
*! %H The hour as a decimal number using a 24-hour clock (range 00 to 23). |
*! |
*! %I The hour as a decimal number using a 12-hour clock (range 01 to 12). |
*! |
*! %j The day of the year as a decimal number (range 001 to 366). |
*! |
*! %k The hour (24-hour clock) as a decimal number (range 0 to 23); single digits are preceded by a blank. (See also %H.) |
*! |
*! %l The hour (12-hour clock) as a decimal number (range 1 to 12); single digits are preceded by a blank. (See also %I.) |
*! |
*! %m The month as a decimal number (range 01 to 12). |
*! |
*! %M The minute as a decimal number (range 00 to 59). |
*! |
*! %n A newline character. (SU) |
*! |
*! %O Modifier: use alternative format, see below. (SU) |
*! |
*! %p Either "AM" or "PM" according to the given time value, or the corresponding strings for the current locale. Noon is treated as "PM" and midnight as "AM". |
*! |
*! %P Like %p but in lowercase: "am" or "pm" or a corresponding string for the current locale. |
*! |
*! %r The time in a.m. or p.m. notation. In the POSIX locale this is equivalent to %I:%M:%S %p. |
*! |
*! %R The time in 24-hour notation (%H:%M). (SU) For a version including the seconds, see %T below. |
*! |
*! %s The number of seconds since the Epoch, 1970-01-01 00:00:00 +0000 (UTC). (TZ) |
*! |
*! %S The second as a decimal number (range 00 to 60). (The range is up to 60 to allow for occasional leap seconds.) |
*! |
*! %t A tab character. (SU) |
*! |
*! %T The time in 24-hour notation (%H:%M:%S). (SU) |
*! |
*! %u The day of the week as a decimal, range 1 to 7, Monday being 1. See also %w. (SU) |
*! |
*! %U The week number of the current year as a decimal number, range 00 to 53, starting with the first Sunday as the first day of week 01. See also %V and %W. |
*! |
*! %V The ISO 8601 week number of the current year as a decimal number, range 01 to 53, where week 1 is the first week that has at least 4 days in the new year. See also %U and %W. |
*! |
*! %w The day of the week as a decimal, range 0 to 6, Sunday being 0. See also %u. |
*/ |
PIKEFUN string strftime(string(1..255) format) |
{ |
char *buffer = xalloc( 8192 ); |
buffer[0] = 0; |
strftime_zone( buffer, 8192, format->str, &THIS->t ); |
push_text( buffer ); |
} |
|
/* |
*! @decl int(0..60) sec; |
*! @decl int(0..59) min; |
*! @decl int(0..59) hour; |
*! @decl int(1..31) mday; |
*! @decl int(0..11) mon; |
*! @decl int year; |
*! |
*! The various fields in the structure. Note that setting these |
*! might cause other fields to be recalculated, as an example, |
*! adding 1000 to the hour field would advance the 'mday', 'mon' |
*! and possibly 'year' fields. |
*! |
*! When read the fields are always normalized. |
*! |
*! Unlike the system struct tm the 'year' field is not year-1900, |
*! instead it is the actual year. |
*/ |
PIKEFUN int(0..60) `sec() { FIX_THIS();RETURN THIS->t.tm_sec; } |
PIKEFUN int(0..59) `min() { FIX_THIS();RETURN THIS->t.tm_min; } |
PIKEFUN int(0..23) `hour() { FIX_THIS();RETURN THIS->t.tm_hour; } |
PIKEFUN int(1..31) `mday() { FIX_THIS();RETURN THIS->t.tm_mday; } |
PIKEFUN int(0..11) `mon() { FIX_THIS();RETURN THIS->t.tm_mon; } |
PIKEFUN int `year() { FIX_THIS();RETURN THIS->t.tm_year+1900; } |
|
PIKEFUN int `sec=(int a) { MODIFY(tm_sec=a); } |
PIKEFUN int `min=(int a) { MODIFY(tm_min=a); } |
PIKEFUN int `hour=(int a){ MODIFY(tm_hour=a); } |
PIKEFUN int `mday=(int a){ MODIFY(tm_mday=a); } |
PIKEFUN int `year=(int a){ MODIFY(tm_year=a-1900); } |
PIKEFUN int `mon=(int a){ MODIFY(tm_mon=a); } |
|
/*! @decl int isdst |
*! |
*! True if daylight savings are in effect. If this field is -1 |
*! (the default) it (and the timezone info) will be updated |
*! automatically using the timezone rules. |
*/ |
PIKEFUN int(-1..1) `isdst() { |
FIX_THIS(); |
RETURN THIS->t.tm_isdst; |
} |
|
/*! @decl int wday |
*! The day of the week, sunday is 0, saturday is 6. |
*! This is calculated from the other fields and can not be changed directly. |
*/ |
PIKEFUN int(0..6) `wday() { FIX_THIS(); RETURN THIS->t.tm_wday; } |
|
/*! @decl int yday |
*! The day of the year, from 0 (the first day) to 365 |
*! This is calculated from the other fields and can not be changed directly. |
*/ |
PIKEFUN int(0..365) `yday() { FIX_THIS(); RETURN THIS->t.tm_yday; } |
|
/*! @decl int unix_time() |
*! Return the unix time corresponding to this time_t. If no time |
*! can be parsed from the structure -1 is returned. |
*/ |
PIKEFUN int unix_time() |
{ |
FIX_THIS(); |
RETURN THIS->unix_time; |
} |
|
/*! @decl string asctime() |
*! Return a string representing the time. Mostly useful for debug |
*! purposes, the exact format is very locale (see |
*! @[Gettext.setlocale]) and OS dependent. |
*/ |
PIKEFUN string asctime() |
{ |
FIX_THIS(); |
{ |
char *tval = asctime_zone( &THIS->t ); |
if( tval ) |
push_text( tval ); |
else |
push_text( 0 ); |
} |
} |
|
PIKEFUN void _sprintf( int flag, mapping options ) |
{ |
int post_sum = 1; |
switch( flag ) |
{ |
case 'O': |
push_text("System.TM("); |
post_sum = 1; |
/* fallthrough */ |
case 's': |
f_TM_asctime(0); |
push_text("\n"); |
if( GET_ZONE(&(THIS->t)) ) |
{ |
push_text(" "); |
push_text( GET_ZONE(&(THIS->t)) ); |
f_add( 2 ); |
} |
else |
push_text(""); |
f_replace( 3 ); |
break; |
case 'd': |
f_TM_unix_time(0); |
break; |
default: |
Pike_error("Can not format as %c", flag ); |
} |
if( post_sum ) |
{ |
push_text(")"); |
f_add(3); |
} |
|
} |
|
PIKEFUN mixed cast( string to ) |
{ |
struct pike_string *s_string, *s_int; |
MAKE_CONST_STRING(s_int, "int"); |
MAKE_CONST_STRING(s_string, "string"); |
if( to == s_int ) |
{ |
f_TM_unix_time(0); |
return; |
} |
if( to == s_string ) |
{ |
f_TM_asctime(0); |
return; |
} |
Pike_error("Does not know how to cast to %s\n", to->str ); |
} |
|
/*! @decl string zone |
*! |
*! The timezone of this structure |
*/ |
PIKEFUN string `zone() { |
FIX_THIS(); |
if( GET_ZONE(&(THIS->t)) ) |
push_text( GET_ZONE(&(THIS->t)) ); |
else |
push_undefined(); |
} |
|
/*! @decl int gmtoff |
*! The offset from GMT for the time in this tm-struct |
*/ |
PIKEFUN int `gmtoff() { |
FIX_THIS(); |
push_int( GET_GMTOFF(&(THIS->t)) ); |
} |
|
/* Setting the zone does not work, so.. */ |
|
/* PIKEFUN string `zone=(string x) { */ |
/* if( THIS->set_zone ) */ |
/* free_string( THIS->set_zone ); */ |
/* THIS->set_zone = x; */ |
/* MODIFY( tm_zone = x->str ); */ |
/* x->refs++; */ |
/* } */ |
|
/*! @decl int(0..1) localtime( int time ) |
*! Initialize the struct tm to the local time for the specified |
*! unix time_t. |
*/ |
PIKEFUN int(0..1) localtime( int _t ) |
{ |
time_t t = _t; |
struct tm *res = localtime_zone( &t, &THIS->t ); |
|
/* These are supposedly correctly by localtime_zone. */ |
SET_GMTOFF(res, GET_GMTOFF(&(THIS->t))); |
SET_ZONE(res, GET_ZONE(&(THIS->t))); |
|
if( !res ) |
RETURN 0; |
THIS->t = *res; |
THIS->modified = 1; |
RETURN 1; |
} |
|
|
/*! @decl int(0..1) gmtime( int time ) |
*! Initialize the struct tm to the UTC time for the specified |
*! unix time_t. |
*/ |
PIKEFUN int(0..1) gmtime( int _t ) |
{ |
time_t t = _t; |
struct tm *res = gmtime( &t ); |
|
if( !res ) |
RETURN 0; |
|
THIS->t = *res; |
THIS->modified = 1; |
RETURN 1; |
} |
|
/*! @decl void create(int t) |
*! Create a new @[TM] initialized from a unix time_t. |
*! The timezone will always be UTC when using this function. |
*/ |
PIKEFUN void create( int _t ) |
{ |
f_TM_gmtime( 1 ); |
if( Pike_sp[-1].u.integer == 0 ) |
Pike_error("time out of range\n"); |
} |
|
/*! @decl void create() |
*! Construct a new TM, all fields will be set to 0. |
*/ |
PIKEFUN void create( ) |
{ |
memset( &THIS->t, 0, sizeof( struct tm ) ); |
THIS->t.tm_isdst = -1; |
THIS->unix_time = 0; |
THIS->modified = 1; |
} |
|
/*! @decl void create( int year, int(0..11) mon, int(1..31) mday, @ |
*! int(0..24) hour, int(0..59) min, int(0..59) sec, @ |
*! string|void timezone ) |
*! Construct a new time using the given values. |
*! Slightly faster than setting them individually. |
*/ |
PIKEFUN void create( int year, int(0..11) mon, int(1..31) mday, |
int(0..24) hour, int(0..59) min, int(0..59) sec, |
string|void timezone ) |
{ |
struct tm *t = &THIS->t; |
t->tm_isdst = -1; |
t->tm_year = year - 1900; |
t->tm_mon = mon; |
t->tm_mday = mday; |
t->tm_hour = hour; |
t->tm_min = min; |
t->tm_sec = sec; |
if (THIS->set_zone) { |
free_string(THIS->set_zone); |
THIS->set_zone = NULL; |
} |
if( !timezone ) /* gmtime. */ |
SET_ZONE(t, "UTC"); |
else |
{ |
add_ref(timezone); |
THIS->set_zone = timezone; |
SET_ZONE(t, timezone->str); |
} |
THIS->unix_time = mktime_zone( t ); |
} |
|
INIT { |
THIS->set_zone = 0; |
THIS->modified = 0; |
} |
|
EXIT { |
if( THIS->set_zone ) |
free_string( THIS->set_zone ); |
} |
} |
#undef FIX_THIS |
#ifdef STRUCT_TM_HAS___TM_GMTOFF |
#undef tm_zone |
#undef tm_gmtoff |
#endif |
#endif |
/*! @endmodule |
*/ |
|
/*! @decl array(array(int|string|type)) describe_program(program p) |
*! @belongs Debug |
*! |
*! Debug function for showing the symbol table of a program. |
*! |
*! @returns |
*! Returns an array of arrays with the following information |
*! for each symbol in @[p]: |
*! @array |
*! @elem int modifiers |
*! Bitfield with the modifiers for the symbol. |
*! @elem string symbol_name |
*! Name of the symbol. |
*! @elem type value_type |
*! Value type for the symbol. |
*! @elem int symbol_type |
*! Type of symbol. |
*! @elem int symbol_offset |
*! Offset into the code or data area for the symbol. |
*! @elem int inherit_offset |
*! Offset in the inherit table to the inherit containing |
*! the symbol. |
*! @elem int inherit_level |
*! Depth in the inherit tree for the inherit containing |
*! the symbol. |
*! @endarray |
*! |
*! @note |
*! The API for this function is not fixed, and has changed |
*! since Pike 7.6. In particular it would make sense to return |
*! an array of objects instead, and more information about the |
*! symbols might be added. |
*/ |
PMOD_EXPORT |
PIKEFUN array(array(int|string)) _describe_program(mixed x) |
efun; |
{ |
struct program *p; |
struct array *res; |
int i; |
|
if (!(p = program_from_svalue(Pike_sp - args))) |
SIMPLE_BAD_ARG_ERROR("_describe_program", 1, "program"); |
|
for (i=0; i < (int)p->num_identifier_references;i++) { |
struct reference *ref = p->identifier_references + i; |
struct identifier *id = ID_FROM_PTR(p, ref); |
struct inherit *inh = INHERIT_FROM_PTR(p, ref); |
push_int(ref->id_flags); |
ref_push_string(id->name); |
ref_push_type_value(id->type); |
push_int(id->identifier_flags); |
if (IDENTIFIER_IS_C_FUNCTION(id->identifier_flags)) { |
push_int(-2); |
} else { |
push_int(id->func.offset); |
} |
push_int(ref->inherit_offset); |
push_int(inh->inherit_level); |
f_aggregate(7); |
} |
f_aggregate(p->num_identifier_references); |
dmalloc_touch_svalue(Pike_sp-1); |
res = Pike_sp[-1].u.array; |
Pike_sp--; |
pop_n_elems(args); |
push_array(res); |
} |
|
/*! @decl string basetype(mixed x) |
*! |
*! Same as sprintf("%t",x); |
*! |
*! @seealso |
*! @[sprintf()] |
*/ |
PMOD_EXPORT |
PIKEFUN string basetype(mixed x) |
efun; |
optflags OPT_TRY_OPTIMIZE; |
{ |
int t = TYPEOF(*x); |
struct program *p; |
if(t == T_OBJECT && (p = x->u.object->prog)) |
{ |
ptrdiff_t fun = FIND_LFUN(p->inherits[SUBTYPEOF(*x)].prog, LFUN__SPRINTF); |
if(fun != -1) |
{ |
push_int('t'); |
f_aggregate_mapping(0); |
apply_low(x->u.object, |
fun + p->inherits[SUBTYPEOF(*x)].identifier_level, 2); |
if(TYPEOF(Pike_sp[-1]) == T_STRING) |
{ |
stack_swap(); |
pop_stack(); |
return; |
} else if (UNSAFE_IS_ZERO(Pike_sp-1)) { |
pop_n_elems(2); |
push_constant_text("object"); |
return; |
} else { |
Pike_error("Non-string returned from _sprintf()\n"); |
} |
} |
} |
pop_stack(); |
switch(t) |
{ |
case T_ARRAY: push_constant_text("array"); break; |
case T_FLOAT: push_constant_text("float"); break; |
case T_FUNCTION: push_constant_text("function"); break; |
case T_INT: push_constant_text("int"); break; |
case T_MAPPING: push_constant_text("mapping"); break; |
case T_MULTISET: push_constant_text("multiset"); break; |
case T_OBJECT: push_constant_text("object"); break; |
case T_PROGRAM: push_constant_text("program"); break; |
case T_STRING: push_constant_text("string"); break; |
case T_TYPE: push_constant_text("type"); break; |
case T_ZERO: push_constant_text("zero"); break; |
case T_VOID: push_constant_text("void"); break; |
/* The following are internal and shouldn't be applicable in normal use. */ |
case T_SVALUE_PTR: push_constant_text("svalue_ptr"); break; |
case T_OBJ_INDEX: push_constant_text("obj_index"); break; |
case T_MAPPING_DATA: push_constant_text("mapping_data"); break; |
case T_PIKE_FRAME: push_constant_text("pike_frame"); break; |
case T_MULTISET_DATA: push_constant_text("multiset_data"); break; |
default: push_constant_text("unknown"); break; |
} |
} |
|
|
/*! @decl string int2char(int x) |
*! @appears String.int2char |
*! |
*! Same as sprintf("%c",x); |
*! |
*! @seealso |
*! @[sprintf()] |
*/ |
PMOD_EXPORT |
PIKEFUN string int2char(int|object x) |
efun; |
optflags OPT_TRY_OPTIMIZE; |
{ |
int c; |
struct program *p; |
if(TYPEOF(*x) == T_OBJECT && (p = x->u.object->prog)) |
{ |
ptrdiff_t fun = FIND_LFUN(p->inherits[SUBTYPEOF(*x)].prog, LFUN__SPRINTF); |
if(fun != -1) |
{ |
push_int('c'); |
f_aggregate_mapping(0); |
apply_low(x->u.object, |
fun + p->inherits[SUBTYPEOF(*x)].identifier_level, 2); |
if(TYPEOF(Pike_sp[-1]) == T_STRING) |
{ |
stack_swap(); |
pop_stack(); |
return; |
} |
Pike_error("Non-string returned from _sprintf()\n"); |
} |
} |
if(TYPEOF(*x) != T_INT) |
SIMPLE_BAD_ARG_ERROR("int2char", 1, "int"); |
|
c=x->u.integer; |
|
if(c>=0 && c<256) |
{ |
struct pike_string *s; |
s=begin_shared_string(1); |
s->str[0]=c; |
RETURN end_shared_string(s); |
}else{ |
struct string_builder tmp; |
init_string_builder(&tmp,0); |
string_builder_putchar(&tmp, c); |
RETURN finish_string_builder(&tmp); |
} |
} |
|
/*! @decl string int2hex(int x) |
*! @appears String.int2hex |
*! |
*! Same as @expr{sprintf("%x",x);@}, i.e. returns the integer @[x] in |
*! hexadecimal base using lower cased symbols. |
*! |
*! @seealso |
*! @[sprintf()] |
*/ |
PMOD_EXPORT |
PIKEFUN string int2hex(int|object x) |
efun; |
optflags OPT_TRY_OPTIMIZE; |
{ |
INT_TYPE c; |
unsigned INT_TYPE n; |
int len; |
struct pike_string *s; |
struct program *p; |
|
if(TYPEOF(*x) == T_OBJECT && (p = x->u.object->prog)) |
{ |
ptrdiff_t fun = FIND_LFUN(p->inherits[SUBTYPEOF(*x)].prog, LFUN__SPRINTF); |
if(fun != -1) |
{ |
push_int('x'); |
f_aggregate_mapping(0); |
apply_low(x->u.object, |
fun + p->inherits[SUBTYPEOF(*x)].identifier_level, 2); |
if(TYPEOF(Pike_sp[-1]) == T_STRING) |
{ |
stack_swap(); |
pop_stack(); |
return; |
} |
Pike_error("Non-string returned from _sprintf()\n"); |
} |
} |
if(TYPEOF(*x) != T_INT) |
SIMPLE_BAD_ARG_ERROR("int2hex", 1, "int"); |
|
c=x->u.integer; |
|
len=1; |
if(c<0) { |
len++; |
n=(-c)&((unsigned INT_TYPE)(-1)); |
}else{ |
n=c; |
} |
while(n>65535) { n>>=16; len+=4; } |
while(n>15) { n>>=4; len++; } |
|
s=begin_shared_string(len); |
if(!c) |
{ |
s->str[0]='0'; |
}else{ |
if(c<0) |
{ |
s->str[0]='-'; |
n=(-c)&((unsigned INT_TYPE)(-1)); |
}else{ |
n=c; |
} |
while(len && n) |
{ |
s->str[--len]="0123456789abcdef"[n&0xf]; |
n>>=4; |
} |
} |
RETURN end_shared_string(s); |
} |
|
|
/*! @decl string string2hex(string data) |
*! @appears String.string2hex |
*! |
*! Convert a string of binary data to a hexadecimal string. |
*! |
*! @seealso |
*! @[hex2string()] |
*/ |
|
static const char hexchar[] = { |
'0','1','2','3','4','5','6','7','8','9', |
'a','b','c','d','e','f' |
}; |
|
static const unsigned char hexdecode[256] = |
{ |
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, |
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, |
|
/* '0' - '9' */ |
0, 1, 2, 3, 4, 5, 6, 7, 8, 9, |
|
0,0,0,0,0,0,0, |
|
/* 'A' - 'F' */ |
10, 11, 12, 13, 14, 15, |
|
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, |
/* 'a' - 'f' */ |
10, 11, 12, 13, 14, 15, |
}; |
|
PMOD_EXPORT |
PIKEFUN string string2hex(string s) |
errname String.string2hex; |
optflags OPT_TRY_OPTIMIZE; |
{ |
struct pike_string *hex; |
unsigned char *p,*st = (unsigned char *)s->str; |
int i, l; |
|
if (s->size_shift) |
Pike_error("Bad argument 1 to string2hex(), expected 8-bit string.\n"); |
|
hex = begin_shared_string(2 * s->len); |
p = (unsigned char *)hex->str; |
l = s->len; |
|
for (i=0; i<l; i++) { |
*p++ = hexchar[*st>>4]; |
*p++ = hexchar[*st&15]; |
st++; |
} |
|
RETURN end_shared_string(hex); |
} |
|
/*! @decl string hex2string(string hex) |
*! @appears String.hex2string |
*! |
*! Convert a string of hexadecimal digits to binary data. |
*! |
*! @seealso |
*! @[string2hex()] |
*/ |
PMOD_EXPORT |
PIKEFUN string hex2string(string hex) |
errname String.hex2string; |
optflags OPT_TRY_OPTIMIZE; |
{ |
struct pike_string *s; |
int tmp, i; |
unsigned char *p, *q = (unsigned char *)hex->str; |
int l = hex->len>>1; |
if(hex->size_shift) Pike_error("Only hex digits allowed.\n"); |
if(hex->len&1) Pike_error("Can't have odd number of digits.\n"); |
|
s = begin_shared_string(l); |
p = (unsigned char *)s->str; |
for (i=0; i<l; i++) |
{ |
tmp = hexdecode[*q++]; |
*p++ = (tmp<<4) | hexdecode[*q++]; |
} |
RETURN end_shared_string(s); |
} |
|
/*! @decl array column(array data, mixed index) |
*! |
*! Extract a column from a two-dimensional array. |
*! |
*! This function is exactly equivalent to: |
*! @code |
*! map(@[data], lambda(mixed x,mixed y) { return x[y]; }, @[index]) |
*! @endcode |
*! |
*! Except of course it is a lot shorter and faster. |
*! That is, it indices every index in the array data on the value of |
*! the argument index and returns an array with the results. |
*! |
*! @seealso |
*! @[rows()] |
*/ |
PMOD_EXPORT |
PIKEFUN array column(array data, mixed index) |
efun; |
optflags OPT_TRY_OPTIMIZE; |
{ |
RETURN array_column (data, index, 1); |
} |
|
/*! @decl multiset mkmultiset(array a) |
*! |
*! This function creates a multiset from an array. |
*! |
*! @seealso |
*! @[aggregate_multiset()] |
*! |
*/ |
PMOD_EXPORT |
PIKEFUN multiset(1) mkmultiset(array(1=mixed) a) |
efun; |
optflags OPT_TRY_OPTIMIZE|OPT_EXTERNAL_DEPEND; |
{ |
RETURN mkmultiset(a); |
} |
|
/*! @decl int trace(int level, void|string facility, void|int all_threads) |
*! |
*! This function changes the trace level for the subsystem identified |
*! by @[facility] to @[level]. If @[facility] is zero or left out, it |
*! changes the global trace level which affects all subsystems. |
*! |
*! Enabling tracing causes messages to be printed to stderr. A higher |
*! trace level includes the output from all lower levels. The lowest |
*! level is zero which disables all trace messages. |
*! |
*! See the @tt{-t@} command-line option for more information. |
*! |
*! @param level |
*! If @[facility] is specified then there is typically only one |
*! trace level for it, i.e. it's an on-or-off toggle. The global |
*! trace levels, when @[facility] isn't specified, are: |
*! |
*! @int |
*! @value 1 |
*! Trace calls to Pike functions and garbage collector runs. |
*! @value 2 |
*! Trace calls to builtin functions. |
*! @value 3 |
*! Trace every interpreted opcode. |
*! @value 4 |
*! Also trace the opcode arguments. |
*! @endint |
*! |
*! @param facility |
*! Valid facilities are: |
*! |
*! @string |
*! @value "gc" |
*! Trace the doings of the garbage collector. The setting is |
*! never thread local. @[level] has two different meanings: |
*! @dl |
*! @item 1..2 |
*! Trace the start and end of each gc run. |
*! @item 3.. |
*! Additionally show info about the collected garbage, to aid |
*! hunting down garbage problems. This currently shows gc'd |
*! trampolines. Note that the output can be very bulky and is |
*! somewhat low-level technical. Also note that pike currently |
*! has to be configured with @expr{--with-rtldebug@} to enable |
*! this. |
*! @enddl |
*! @endstring |
*! |
*! @param all_threads |
*! Trace levels are normally thread local, so changes affect only |
*! the current thread. To change the level in all threads, pass a |
*! nonzero value in this argument. |
*! |
*! @returns |
*! The old trace level in the current thread is returned. |
*/ |
PMOD_EXPORT |
PIKEFUN int trace(int level, void|string facility, void|zero|int all_threads) |
efun; |
optflags OPT_SIDE_EFFECT; |
{ |
INT32 old_level; |
if (facility) { |
struct pike_string *gc_str; |
MAKE_CONST_STRING(gc_str, "gc"); |
if (facility == gc_str) { |
old_level = gc_trace; |
gc_trace = level; |
} |
else { |
bad_arg_error("trace", Pike_sp-args, args, 2, |
"trace facility identifier", Pike_sp-args+1, |
"Bad argument 2 to trace(). Unknown trace facility."); |
} |
} |
else { |
old_level = Pike_interpreter.trace_level; |
#ifdef PIKE_THREADS |
if (!all_threads) |
Pike_interpreter.trace_level = level; |
else { |
struct thread_state *s; |
FOR_EACH_THREAD(s, s->state.trace_level = level); |
} |
#else |
Pike_interpreter.trace_level = level; |
#endif |
} |
RETURN old_level; |
} |
|
/*! @decl mapping(string:float) gc_parameters (void|mapping(string:mixed) params) |
*! @belongs Pike |
*! |
*! Set and get various parameters that control the operation of the |
*! garbage collector. The passed mapping contains the parameters to |
*! set. If a parameter is missing from the mapping, the current value |
*! will be filled in instead. The same mapping is returned. Thus an |
*! empty mapping, or no argument at all, causes a mapping with all |
*! current settings to be returned. |
*! |
*! The following parameters are recognized: |
*! |
*! @mapping |
*! @member int "enabled" |
*! If this is 1 then the gc is enabled as usual. If it's 0 then all |
*! automatically scheduled gc runs are disabled and the parameters |
*! below have no effect, but explicit runs through the @[gc] |
*! function still works as usual. If it's -1 then the gc is |
*! completely disabled so that even explicit @[gc] calls won't do |
*! anything. |
*! @member float "garbage_ratio_low" |
*! As long as the gc time is less than time_ratio below, aim to run |
*! the gc approximately every time the ratio between the garbage |
*! and the total amount of allocated things is this. |
*! @member float "time_ratio" |
*! When more than this fraction of the time is spent in the gc, aim |
*! for garbage_ratio_high instead of garbage_ratio_low. |
*! @member float "garbage_ratio_high" |
*! Upper limit for the garbage ratio - run the gc as often as it |
*! takes to keep it below this. |
*! @member float "min_gc_time_ratio" |
*! This puts an upper limit on the gc interval, in addition to the |
*! factors above. It is specified as the minimum amount of time |
*! spent doing gc, as a factor of the total time. The reason for |
*! this limit is that the current amount of garbage can only be |
*! measured in a gc run, and if the gc starts to run very seldom |
*! due to very little garbage, it might get too slow to react to an |
*! increase in garbage generation. Set to 0.0 to turn this limit |
*! off. |
*! @member float "average_slowness" |
*! When predicting the next gc interval, use a decaying average |
*! with this slowness factor. It should be a value between 0.0 and |
*! 1.0 that specifies the weight to give to the old average value. |
*! The remaining weight up to 1.0 is given to the last reading. |
*! @member function(:void) "pre_cb" |
*! This function is called when the gc starts. |
*! @member function(:void) "post_cb" |
*! This function is called when the mark and sweep pass of the gc |
*! is done. |
*! @member function(object:void) "destruct_cb" |
*! This function is called once for each object that is part of |
*! a cycle just before the gc will destruct it. |
*! @member function(int:void) "done_cb" |
*! This function is called when the gc is done and about to exit. |
*! The argument is the same value as will be returned by gc(). |
*! @endmapping |
*! |
*! @seealso |
*! @[gc], @[Debug.gc_status] |
*/ |
PMOD_EXPORT |
PIKEFUN mapping(string:mixed) gc_parameters (void|mapping(string:mixed) params) |
errname Pike.gc_parameters; |
optflags OPT_SIDE_EFFECT; |
{ |
struct pike_string *str; |
struct svalue *set; |
struct svalue get; |
|
if (!params) { |
push_mapping (allocate_mapping (6)); |
params = Pike_sp[-1].u.mapping; |
} |
|
#define HANDLE_PARAM(NAME, CHECK_AND_SET, GET) do { \ |
MAKE_CONST_STRING (str, NAME); \ |
if ((set = low_mapping_string_lookup (params, str))) { \ |
CHECK_AND_SET; \ |
} \ |
else { \ |
GET; \ |
mapping_string_insert (params, str, &get); \ |
} \ |
} while (0) |
|
#define HANDLE_FLOAT_FACTOR(NAME, VAR) \ |
HANDLE_PARAM (NAME, { \ |
if (TYPEOF(*set) != T_FLOAT || \ |
set->u.float_number < 0.0 || set->u.float_number > 1.0) \ |
SIMPLE_BAD_ARG_ERROR ("Pike.gc_parameters", 1, \ |
"float between 0.0 and 1.0 for " NAME); \ |
VAR = DO_NOT_WARN ((double) set->u.float_number); \ |
}, { \ |
SET_SVAL(get, T_FLOAT, 0, float_number, \ |
DO_NOT_WARN ((FLOAT_TYPE) VAR)); \ |
}); |
|
HANDLE_PARAM ("enabled", { |
if (TYPEOF(*set) != T_INT || set->u.integer < -1 || set->u.integer > 1) |
SIMPLE_BAD_ARG_ERROR ("Pike.gc_parameters", 1, |
"integer in the range -1..1 for 'enabled'"); |
if (gc_enabled != set->u.integer) { |
if (gc_enabled > 0) { |
/* Disabling automatic gc - save the old alloc_threshold and set it to |
* the maximum value to avoid getting gc_evaluator_callback added. */ |
saved_alloc_threshold = alloc_threshold; |
alloc_threshold = GC_MAX_ALLOC_THRESHOLD; |
} |
else if (set->u.integer > 0) { |
/* Enabling automatic gc - restore the old alloc_threshold. If the |
* gc interval has gotten longer than it should be then the |
* multiplier calculation in do_gc should compensate. */ |
alloc_threshold = saved_alloc_threshold; |
} |
gc_enabled = set->u.integer; |
} |
}, { |
SET_SVAL(get, T_INT, NUMBER_NUMBER, integer, gc_enabled); |
}); |
HANDLE_FLOAT_FACTOR ("garbage_ratio_low", gc_garbage_ratio_low); |
HANDLE_FLOAT_FACTOR ("time_ratio", gc_time_ratio); |
HANDLE_FLOAT_FACTOR ("garbage_ratio_high", gc_garbage_ratio_high); |
HANDLE_FLOAT_FACTOR ("min_gc_time_ratio", gc_min_time_ratio); |
HANDLE_FLOAT_FACTOR ("average_slowness", gc_average_slowness); |
|
HANDLE_PARAM("pre_cb", { |
assign_svalue(&gc_pre_cb, set); |
}, { |
assign_svalue(&get, &gc_pre_cb); |
}); |
HANDLE_PARAM("post_cb", { |
assign_svalue(&gc_post_cb, set); |
}, { |
assign_svalue(&get, &gc_post_cb); |
}); |
HANDLE_PARAM("destruct_cb", { |
assign_svalue(&gc_destruct_cb, set); |
}, { |
assign_svalue(&get, &gc_destruct_cb); |
}); |
HANDLE_PARAM("done_cb", { |
assign_svalue(&gc_done_cb, set); |
}, { |
assign_svalue(&get, &gc_done_cb); |
}); |
|
#undef HANDLE_PARAM |
#undef HANDLE_FLOAT_FACTOR |
|
REF_RETURN params; |
} |
|
/*! @decl string ctime(int timestamp) |
*! |
*! Convert the output from a previous call to @[time()] into a readable |
*! string containing the current year, month, day and time. |
*! |
*! Like @[localtime], this function might throw an error if the |
*! ctime(2) call failed on the system. It's platform dependent what |
*! time ranges that function can handle, e.g. Windows doesn't handle |
*! a negative @[timestamp]. |
*! |
*! @seealso |
*! @[time()], @[localtime()], @[mktime()], @[gmtime()] |
*/ |
PMOD_EXPORT |
PIKEFUN string ctime(longest timestamp) |
efun; |
optflags OPT_TRY_OPTIMIZE; |
{ |
time_t i; |
char *s; |
|
#if SIZEOF_TIME_T < SIZEOF_LONGEST |
if (timestamp > MAX_TIME_T || timestamp < MIN_TIME_T) |
SIMPLE_ARG_ERROR ("ctime", 1, "Timestamp outside valid range."); |
#endif |
|
i = (time_t) timestamp; |
s = ctime (&i); |
if (!s) Pike_error ("ctime() on this system cannot handle " |
"the timestamp %ld.\n", (long) i); |
RETURN make_shared_string(s); |
} |
|
/*! @decl mapping mkmapping(array ind, array val) |
*! |
*! Make a mapping from two arrays. |
*! |
*! Makes a mapping @[ind[x]]:@[val[x]], @tt{0 <= x < sizeof(ind)@}. |
*! |
*! @[ind] and @[val] must have the same size. |
*! |
*! This is the inverse operation of @[indices()] and @[values()]. |
*! |
*! @seealso |
*! @[indices()], @[values()] |
*/ |
PMOD_EXPORT |
PIKEFUN mapping(1:2) mkmapping(array(1=mixed) ind, array(2=mixed) val) |
efun; |
optflags OPT_TRY_OPTIMIZE|OPT_EXTERNAL_DEPEND; |
{ |
if(ind->size != val->size) |
bad_arg_error("mkmapping", Pike_sp-args, args, 2, "array", Pike_sp+1-args, |
"mkmapping called on arrays of different sizes (%d != %d)\n", |
ind->size, val->size); |
|
RETURN mkmapping(ind, val); |
} |
|
/*! @decl void secure(string str) |
*! @belongs String |
*! |
*! Marks the string as secure, which will clear the memory area |
*! before freeing the string. |
*/ |
PIKEFUN string string_secure(string str) |
optflags OPT_SIDE_EFFECT; |
rawtype tFunc(tSetvar(0, tStr), tVar(0)); |
{ |
str->flags |= STRING_CLEAR_ON_EXIT; |
REF_RETURN str; |
} |
|
/*! @decl int count(string haystack, string needle) |
*! @belongs String |
*! |
*! Count the number of non-overlapping times the string @[needle] |
*! occurs in the string @[haystack]. The special cases for the needle |
*! @expr{""@} is that it occurs one time in the empty string, zero |
*! times in a one character string and between every character |
*! (length-1) in any other string. |
*! |
*! @seealso |
*! @[search()], @[`/()] |
*/ |
PMOD_EXPORT |
PIKEFUN int string_count(string haystack, string needle) |
errname String.count; |
optflags OPT_TRY_OPTIMIZE; |
{ |
ptrdiff_t c = 0; |
ptrdiff_t i, j; |
|
switch (needle->len) |
{ |
case 0: |
switch (haystack->len) |
{ |
case 0: c=1; break; /* "" appears one time in "" */ |
case 1: c=0; break; /* "" doesn't appear in "x" */ |
default: c=haystack->len-1; /* one time between each character */ |
} |
break; |
case 1: |
/* maybe optimize? */ |
/* It is already fairly optimized in pike_search_engine. */ |
default: |
for (i=0; i<haystack->len; i++) |
{ |
j=string_search(haystack,needle,i); |
if (j==-1) break; |
i=j+needle->len-1; |
c++; |
} |
break; |
} |
RETURN DO_NOT_WARN((INT_TYPE)c); |
} |
|
/*! @decl string trim_whites (string s) |
*! @belongs String |
*! |
*! Trim leading and trailing spaces and tabs from the string @[s]. |
*/ |
PMOD_EXPORT |
PIKEFUN string string_trim_whites (string s) |
errname String.trim_whites; |
optflags OPT_TRY_OPTIMIZE; |
{ |
ptrdiff_t start = 0, end = s->len; |
int chr; |
switch (s->size_shift) { |
#define DO_IT(TYPE) \ |
{ \ |
for (; start < s->len; start++) { \ |
chr = ((TYPE *) s->str)[start]; \ |
if (chr != ' ' && chr != '\t') break; \ |
} \ |
while (--end > start) { \ |
chr = ((TYPE *) s->str)[end]; \ |
if (chr != ' ' && chr != '\t') break; \ |
} \ |
} |
case 0: DO_IT (p_wchar0); break; |
case 1: DO_IT (p_wchar1); break; |
case 2: DO_IT (p_wchar2); break; |
#undef DO_IT |
} |
RETURN string_slice (s, start, end + 1 - start); |
} |
|
/*! @decl string normalize_space (string s, string|void whitespace) |
*! @belongs String |
*! |
*! @param s |
*! Is returned after white space in it has been normalised. |
*! White space is normalised by stripping leading and trailing white space |
*! and replacing sequences of white space characters with a single space. |
*! |
*! @param whitespace |
*! Defines what is considered to be white space eligible for normalisation. |
*! It has a default value that starts with @expr{" \t\r\n\v\f"@} and in |
*! addition to that contains all whitespace characters part of Unicode. |
*! The first character denotes the character for replacing whitespace |
*! sequences. |
*! |
*! @note |
*! Trailing and leading whitespace around \r and \n characters |
*! is stripped as well (only useful if they're not in the @[whitespace] set). |
*! |
*! @note |
*! This function is a lot faster with just one argument (i.e. the builtin |
*! whitespace set has an optimised code path). |
*/ |
PMOD_EXPORT |
PIKEFUN string string_normalize_space (string s, string|void whitespace) |
errname String.normalize_space; |
optflags OPT_TRY_OPTIMIZE; |
{ |
size_t len = s->len, wlen; |
const void *src = s->str; |
unsigned shift = s->size_shift, replspace; |
const void *ws; |
void *wstemp = 0; |
struct string_builder sb; |
unsigned foundspace = 0; |
|
wlen = replspace = 0; /* useless, but suppresses silly compiler warning */ |
|
{ |
unsigned bshift = shift, wshift; |
if(whitespace) |
if(!(wlen = whitespace->len)) |
REF_RETURN s; |
else { |
ws = whitespace->str; wshift = whitespace->size_shift; |
replspace = index_shared_string(whitespace, 0); |
if(replspace > 0xffff) |
bshift = 2; |
else if(replspace > 0xff && !bshift) |
bshift = 1; |
if(wshift!=shift) { /* convert whitespace to shift of input */ |
PCHARP pcnws; |
wstemp = xalloc(wlen<<shift); |
pcnws = MKPCHARP(wstemp, shift); |
if(wshift>shift) { |
PCHARP pcows = MKPCHARP_STR(whitespace); |
size_t clen = wlen, i; |
i = wlen = 0; |
do { |
unsigned chr = INDEX_PCHARP(pcows, i++); |
if (chr<=0xff || (chr<=0xffff && shift)) /* shift is 0 or 1 */ |
SET_INDEX_PCHARP(pcnws, wlen++, chr); |
} while(--clen); |
} else |
pike_string_cpy(pcnws, whitespace); |
ws = wstemp; |
} |
} |
else |
ws = 0; |
|
init_string_builder_alloc (&sb, len, bshift); |
if(bshift == shift) |
sb.known_shift = bshift; |
} |
#define SPACECASE8 \ |
case ' ':case '\t':case '\r':case '\n':case '\v':case '\f': \ |
case 0x85:case 0xa0: |
#include "whitespace.h" |
|
switch (shift) { |
#define NORMALISE_TIGHT_LOOP(TYPE,CASE) \ |
{ \ |
const TYPE *start = src, *end = start+len; \ |
if (!ws) { \ |
TYPE *dst = (void*)sb.s->str; \ |
for (; start < end; start++) { \ |
switch(*start) { \ |
CASE \ |
continue; \ |
} \ |
break; \ |
} \ |
for (; start < end; start++) { \ |
if(*start<=' ' || *start>=0x85) /* optimise common case */ \ |
switch(*start) { \ |
CASE \ |
if (!foundspace) \ |
*dst++ = ' ', foundspace=1; \ |
continue; \ |
default:goto found##TYPE; \ |
} \ |
else \ |
found##TYPE: \ |
foundspace=0; \ |
*dst++ = *start; \ |
} \ |
sb.s->len = dst - (TYPE*)sb.s->str; \ |
} else { \ |
const TYPE*ps = (const TYPE*)ws+wlen; \ |
for (; start < end; start++) { \ |
size_t clen = wlen; \ |
do { \ |
if (ps[0-clen] == *start) \ |
goto lead##TYPE; \ |
} while(--clen); \ |
break; \ |
lead##TYPE:; \ |
} \ |
for (; start < end; start++) { \ |
TYPE chr = *start; \ |
size_t clen = wlen; \ |
do \ |
if (ps[0-clen] == chr) { \ |
if (!foundspace) \ |
string_builder_putchar(&sb, replspace), foundspace=1; \ |
goto skip##TYPE; \ |
} \ |
while(--clen); \ |
if (foundspace && (chr=='\n' || chr=='\r')) { \ |
sb.s->len--; string_builder_putchar(&sb, chr); \ |
foundspace=0; \ |
goto lead##TYPE; \ |
} \ |
string_builder_putchar(&sb, chr); foundspace=0; \ |
skip##TYPE:; \ |
} \ |
} \ |
} |
case 0: NORMALISE_TIGHT_LOOP (p_wchar0,SPACECASE8); break; |
case 1: NORMALISE_TIGHT_LOOP (p_wchar1,SPACECASE16); break; |
case 2: NORMALISE_TIGHT_LOOP (p_wchar2,SPACECASE16); break; |
#undef NORMALISE_TIGHT_LOOP |
#undef SPACECASE8 |
#undef SPACECASE16 |
} |
if (wstemp) |
free(wstemp); |
if (foundspace) |
sb.s->len--; |
RETURN finish_string_builder (&sb); |
} |
|
/*! @decl string trim_all_whites (string s) |
*! @belongs String |
*! |
*! Trim leading and trailing white spaces characters (space, tab, |
*! newline, carriage return, form feed, vertical tab and all the |
*! white spaces defined in Unicode) from the string @[s]. |
*/ |
PMOD_EXPORT |
PIKEFUN string string_trim_all_whites (string s) |
errname String.trim_all_whites; |
optflags OPT_TRY_OPTIMIZE; |
{ |
ptrdiff_t start = 0, end = s->len; |
int chr; |
switch (s->size_shift) { |
#define SPACECASE8 \ |
case ' ':case '\t':case '\r':case '\n':case '\v':case '\f': \ |
case 0x85:case 0xa0: |
#include "whitespace.h" |
|
#define DO_IT(TYPE,CASE) \ |
{ \ |
for (; start < end; start++) { \ |
chr = ((TYPE *) s->str)[start]; \ |
switch(chr) { \ |
CASE \ |
continue; \ |
} \ |
break; \ |
} \ |
while (--end > start) { \ |
chr = ((TYPE *) s->str)[end]; \ |
switch(chr) { \ |
CASE \ |
continue; \ |
} \ |
break; \ |
} \ |
} |
case 0: DO_IT (p_wchar0,SPACECASE8); break; |
case 1: DO_IT (p_wchar1,SPACECASE16); break; |
case 2: DO_IT (p_wchar2,SPACECASE16); break; |
#undef DO_IT |
#undef SPACECASE8 |
#undef SPACECASE16 |
} |
RETURN string_slice (s, start, end + 1 - start); |
} |
|
/*! @decl string status(int verbose) |
*! @belongs String |
*! |
*! Get string table statistics. |
*! |
*! @returns |
*! Returns a string with an ASCII table containing |
*! the current string table statistics. |
*! |
*! @note |
*! Currently returns the empty string (@expr{""@}) |
*! if @[verbose] is zero. |
*! |
*! @note |
*! The formatting and contents of the result |
*! may vary between different versions of Pike. |
*/ |
PIKEFUN string string_status(int verbose) |
errname String.status; |
{ |
RETURN add_string_status(verbose); |
} |
|
/*! @decl int implements(program prog, program api) |
*! @belongs Program |
*! |
*! Returns 1 if @[prog] implements @[api]. |
*/ |
PMOD_EXPORT |
PIKEFUN int program_implements(program prog, program api) |
errname Program.implements; |
optflags OPT_TRY_OPTIMIZE; |
{ |
RETURN implements(prog, api); |
} |
|
/*! @decl int inherits(program|object child, program parent) |
*! @belongs Program |
*! |
*! Returns 1 if @[child] has inherited @[parent]. |
*/ |
PMOD_EXPORT |
PIKEFUN int program_inherits(program|object child, program parent) |
errname Program.inherits; |
optflags OPT_TRY_OPTIMIZE; |
{ |
struct program *p = program_from_svalue(child); |
|
if (!p) |
SIMPLE_ARG_TYPE_ERROR("Program.inherits", 1, "program|object"); |
RETURN low_get_storage(p, parent) != -1; |
} |
|
/*! @decl string defined(program p) |
*! @belongs Program |
*! |
*! Returns a string with filename and linenumber describing where |
*! the program @[p] was defined. |
*! |
*! The returned string is of the format @expr{"filename:linenumber"@}. |
*! |
*! If it cannot be determined where the program was defined, @expr{0@} |
*! (zero) will be returned. |
*/ |
PMOD_EXPORT |
PIKEFUN string program_defined(program p) |
errname Program.defined; |
optflags OPT_TRY_OPTIMIZE; |
{ |
INT_TYPE line; |
struct pike_string *tmp = low_get_program_line(p, &line); |
|
pop_n_elems(args); |
|
if (tmp) { |
push_string(tmp); |
if(line >= 1) |
{ |
push_constant_text(":"); |
push_int(line); |
f_add(3); |
} |
} |
else |
push_int(0); |
} |
|
/*! @decl int(8..8)|int(16..16)|int(32..32) width(string s) |
*! @belongs String |
*! |
*! Returns the width of a string. |
*! |
*! @returns |
*! Three return values are currently possible: |
*! @int |
*! @value 8 |
*! The string @[s] only contains characters <= 255. |
*! @value 16 |
*! The string @[s] only contains characters <= 65535. |
*! @value 32 |
*! The string @[s] contains characters >= 65536. |
*! @endint |
*! |
*! @note |
*! It is possible that a future version of Pike may return |
*! further values. In particular the width @expr{7@} seems |
*! like it could be useful. |
*/ |
PMOD_EXPORT |
PIKEFUN int(8 .. 8)|int(16 .. 16)|int(32 .. 32) string_width(string s) |
errname String.width; |
optflags OPT_TRY_OPTIMIZE; |
{ |
RETURN 8 * (1 << s->size_shift); |
} |
|
/*! @decl mixed m_delete(object|mapping map, mixed index) |
*! |
*! If @[map] is an object that implements @[lfun::_m_delete()], |
*! that function will be called with @[index] as its single argument. |
*! |
*! Otherwise if @[map] is a mapping the entry with index @[index] |
*! will be removed from @[map] destructively. |
*! |
*! If the mapping does not have an entry with index @[index], nothing is done. |
*! |
*! @returns |
*! The value that was removed will be returned. |
*! |
*! @note |
*! Note that @[m_delete()] changes @[map] destructively. |
*! |
*! @seealso |
*! @[mappingp()] |
*/ |
PMOD_EXPORT |
PIKEFUN mixed m_delete(object|mapping map, mixed index) |
efun; |
optflags OPT_SIDE_EFFECT; |
rawtype tOr(tFunc(tMap(tSetvar(0,tMix),tSetvar(1,tMix)) tVar(0),tVar(1)),tFunc(tObj tMix,tMix)) |
{ |
struct program *p; |
if( TYPEOF(*map) == T_MAPPING ) |
{ |
struct svalue s; |
map_delete_no_free(map->u.mapping, index, &s); |
pop_n_elems(args); |
*Pike_sp=s; |
Pike_sp++; |
dmalloc_touch_svalue(Pike_sp-1); |
} |
else if (TYPEOF(*map) == T_OBJECT && (p = map->u.object->prog)) |
{ |
int id = FIND_LFUN(p->inherits[SUBTYPEOF(*map)].prog, LFUN__M_DELETE); |
|
if( id == -1 ) |
SIMPLE_BAD_ARG_ERROR("m_delete", 1, "object containing the _m_delete method"); |
|
apply_low(map->u.object, |
id + p->inherits[SUBTYPEOF(*map)].identifier_level, 1); |
stack_swap(); |
pop_stack(); |
} else { |
SIMPLE_BAD_ARG_ERROR("m_delete", 1, "object|mapping"); |
} |
} |
|
/*! @decl int get_weak_flag(array|mapping|multiset m) |
*! |
*! Returns the weak flag settings for @[m]. It's a combination of |
*! @[Pike.WEAK_INDICES] and @[Pike.WEAK_VALUES]. |
*/ |
PMOD_EXPORT |
PIKEFUN int get_weak_flag(array m) |
efun; |
optflags OPT_EXTERNAL_DEPEND; |
{ |
RETURN (m->flags & ARRAY_WEAK_FLAG) ? PIKE_WEAK_VALUES : 0; |
} |
|
PMOD_EXPORT |
PIKEFUN int get_weak_flag(mapping m) |
{ |
RETURN mapping_get_flags(m) & MAPPING_WEAK; |
} |
|
PMOD_EXPORT |
PIKEFUN int get_weak_flag(multiset m) |
{ |
RETURN multiset_get_flags(m) & MULTISET_WEAK; |
} |
|
/*! @decl program __empty_program(int|void line, string|void file) |
*/ |
PIKEFUN program __empty_program(int|zero|void line, string|void file) |
efun; |
optflags OPT_EXTERNAL_DEPEND; |
{ |
struct program *prog = low_allocate_program(); |
if (file) ext_store_program_line (prog, line, file); |
#if 0 |
push_program (prog); |
safe_pike_fprintf (stderr, "Creating empty program %O (%x)\n", |
Pike_sp - 1, Pike_sp[-1].u.program); |
Pike_sp--; |
#endif |
RETURN prog; |
} |
|
/* Cut the string at the first NUL. */ |
static struct pike_string *delambda(struct pike_string *str) |
{ |
PCHARP pcharp = MKPCHARP_STR(str); |
ptrdiff_t len = pcharp_strlen(pcharp); |
if (len == str->len) { |
/* Common case. */ |
add_ref(str); |
return str; |
} |
return make_shared_binary_pcharp(pcharp, len); |
} |
|
/*! @decl string function_name(function f) |
*! |
*! Return the name of the function @[f]. |
*! |
*! If @[f] is a global function defined in the runtime @expr{0@} |
*! (zero) will be returned. |
*! |
*! @seealso |
*! @[function_object()] |
*/ |
PMOD_EXPORT |
PIKEFUN string function_name(program|function func) |
efun; |
optflags OPT_TRY_OPTIMIZE; |
{ |
int f = -1; |
struct program *p = NULL; |
|
switch(TYPEOF(*func)) |
{ |
default: |
SIMPLE_BAD_ARG_ERROR("function_name", 1, "function|program"); |
return; /* NOTREACHED */ |
|
case PIKE_T_PROGRAM: |
{ |
p = func->u.program; |
|
if(p->parent) |
{ |
int e; |
p=p->parent; |
/* search constants in parent for this |
* program... |
*/ |
|
for(e = p->num_identifier_references; e--; ) |
{ |
struct identifier *id; |
if (p->identifier_references[e].id_flags & ID_HIDDEN) |
continue; |
|
id = ID_FROM_INT(p, e); |
if (IDENTIFIER_IS_CONSTANT(id->identifier_flags) && |
(id->func.const_info.offset >= 0) && |
is_eq( & PROG_FROM_INT(p, e)->constants[id->func.const_info.offset].sval, |
func)) |
REF_RETURN id->name; |
} |
#ifdef PIKE_DEBUG |
if (d_flag>5) { |
fprintf(stderr, |
"Failed to find symbol for program %p\n" |
"Parent program info:\n", |
func->u.program); |
dump_program_tables(func->u.program->parent, 0); |
} |
#endif |
} |
break; |
} |
|
case PIKE_T_FUNCTION: |
if((f = SUBTYPEOF(*func)) == FUNCTION_BUILTIN) break; |
if(!(p = func->u.object->prog)) |
bad_arg_error("function_name", Pike_sp-args, args, 1, |
"function", Pike_sp-args, |
"Destructed object.\n"); |
if(p == pike_trampoline_program) |
{ |
struct pike_trampoline *t; |
t=((struct pike_trampoline *)func->u.object->storage); |
|
if(t->frame->current_object->prog) { |
p = t->frame->current_object->prog; |
f = t->func; |
} |
} |
|
#ifdef PIKE_DEBUG |
if(f >= p->num_identifier_references) |
Pike_fatal("Function without reference.\n"); |
#endif |
RETURN delambda(ID_FROM_INT(p, f)->name); |
} |
pop_n_elems(args); |
push_int(0); |
} |
|
/*! @decl object function_object(function f) |
*! |
*! Return the object the function @[f] is in. |
*! |
*! If @[f] is a global function defined in the runtime @expr{0@} |
*! (zero) will be returned. |
*! |
*! Zero will also be returned if @[f] is a constant in the |
*! parent class. In that case @[function_program()] can be |
*! used to get the parent program. |
*! |
*! @seealso |
*! @[function_name()], @[function_program()] |
*/ |
PMOD_EXPORT |
PIKEFUN object function_object(function|program func) |
efun; |
optflags OPT_TRY_OPTIMIZE; |
type function(function:object); |
{ |
switch(TYPEOF(*func)) |
{ |
case PIKE_T_PROGRAM: |
break; |
|
case PIKE_T_FUNCTION: |
if(SUBTYPEOF(*func) == FUNCTION_BUILTIN) break; |
if(func->u.object->prog == pike_trampoline_program) |
{ |
struct object *o; |
o=((struct pike_trampoline *)func->u.object->storage)->frame->current_object; |
add_ref(o); |
pop_n_elems(args); |
push_object(o); |
return; |
} |
SET_SVAL(*func, T_OBJECT, 0, object, func->u.object); |
return; |
|
|
default: |
SIMPLE_BAD_ARG_ERROR("function_object",1,"function"); |
} |
pop_n_elems(args); |
push_int(0); |
} |
|
/*! @decl program function_program(function|program f) |
*! |
*! Return the program the function @[f] is in. |
*! |
*! If @[f] is a global function defined in the runtime @expr{0@} |
*! (zero) will be returned. |
*! |
*! @seealso |
*! @[function_name()], @[function_object()] |
*/ |
PMOD_EXPORT |
PIKEFUN program function_program(program|function func) |
efun; |
optflags OPT_TRY_OPTIMIZE; |
{ |
switch(TYPEOF(*func)) |
{ |
case PIKE_T_PROGRAM: |
{ |
struct program *p; |
if(!(p=func->u.program->parent)) break; |
add_ref(p); |
free_program(func->u.program); |
func->u.program=p; |
return; |
} |
|
case PIKE_T_FUNCTION: |
{ |
struct program *p; |
if(SUBTYPEOF(*func) == FUNCTION_BUILTIN) |
p = func->u.efun->prog; |
else |
p = func->u.object->prog; |
if(p == pike_trampoline_program) |
{ |
p = ((struct pike_trampoline *)func->u.object->storage)-> |
frame->current_object->prog; |
} |
if (p) { |
ref_push_program(p); |
stack_pop_n_elems_keep_top(args); |
return; |
} |
} |
break; |
|
default: |
SIMPLE_BAD_ARG_ERROR("function_program", 1, "function"); |
} |
pop_n_elems(args); |
push_int(0); |
} |
|
|
/*! @decl mixed random(object o) |
*! If random is called with an object, @[lfun::random] will be |
*! called in the object. |
*! @seealso |
*! @[lfun::_random] |
*/ |
|
/*! @decl mixed lfun::_random() |
*! Called by @[random]. Typical uses is when the object implements |
*! a ADT, then a call to this lfun should return a random member of |
*! the ADT or range implied by the ADT. |
*! @seealso |
*! @[predef::random()] |
*/ |
|
PMOD_EXPORT |
PIKEFUN mixed random(object o) |
efun; |
optflags OPT_TRY_OPTIMIZE|OPT_EXTERNAL_DEPEND; |
{ |
apply(o,"_random",0); |
stack_swap(); |
pop_stack(); |
} |
|
/*! @decl int random(int max) |
*! @decl float random(float max) |
*! |
*! This function returns a random number in the range 0 - @[max]-1. |
*! |
*! @seealso |
*! @[random_seed()] |
*/ |
|
PMOD_EXPORT |
PIKEFUN int random(int i) |
{ |
if(i <= 0) RETURN 0; |
#if SIZEOF_INT_TYPE > 4 |
if(i >> 31) { |
unsigned INT_TYPE a = my_rand(); |
unsigned INT_TYPE b = my_rand(); |
RETURN (INT_TYPE)(((a<<32)|b) % i); |
} |
#endif |
RETURN my_rand() % i; |
} |
|
PMOD_EXPORT |
PIKEFUN float random(float f) |
{ |
if(f<=0.0) RETURN 0.0; |
#define N 1048576 |
RETURN f * (my_rand()%N/((float)N)) + |
f * (my_rand()%N/( ((float)N) * ((float)N) )); |
|
} |
|
/*! @decl mixed random(array|multiset x) |
*! Returns a random element from @[x]. |
*/ |
|
PMOD_EXPORT |
PIKEFUN mixed random(array a) |
rawtype tFunc(tArr(tSetvar(0,tMix)),tVar(0)); |
{ |
if(!a->size) |
SIMPLE_BAD_ARG_ERROR("random", 1, "array with elements in it"); |
push_svalue(a->item + (my_rand() % a->size)); |
stack_swap(); |
pop_stack(); |
} |
|
PMOD_EXPORT |
PIKEFUN mixed random(multiset m) |
rawtype tFunc(tSet(tSetvar(1,tMix)),tVar(1)); |
{ |
if(multiset_is_empty (m)) |
SIMPLE_BAD_ARG_ERROR("random", 1, "multiset with elements in it"); |
if (multiset_indval (m)) { |
ptrdiff_t nodepos = multiset_get_nth (m, my_rand() % multiset_sizeof (m)); |
push_multiset_index (m, nodepos); |
push_multiset_value (m, nodepos); |
sub_msnode_ref (m); |
f_aggregate (2); |
} |
else { |
push_multiset_index (m, multiset_get_nth (m, my_rand() % |
multiset_sizeof (m))); |
sub_msnode_ref (m); |
} |
stack_swap(); |
pop_stack(); |
} |
|
/*! @decl array random(mapping m) |
*! Returns a random index-value pair from the mapping. |
*/ |
|
PMOD_EXPORT |
PIKEFUN array random(mapping m) |
{ |
struct mapping_data *md=m->data; |
size_t bucket, count; |
struct keypair *k; |
|
if(!m_sizeof(m)) |
SIMPLE_BAD_ARG_ERROR("random", 1, "mapping with elements in it"); |
|
/* Find a random, nonempty bucket */ |
bucket=my_rand() % md->hashsize; |
while(! md->hash[bucket] ) |
if(++bucket > (size_t)md->hashsize) |
bucket=0; |
|
/* Count entries in bucket */ |
count=0; |
for(k=md->hash[bucket];k;k=k->next) count++; |
|
/* Select a random entry in this bucket */ |
count = my_rand() % count; |
k=md->hash[bucket]; |
while(count-- > 0) k=k->next; |
|
/* Push result and return */ |
push_svalue(&k->ind); |
push_svalue(&k->val); |
f_aggregate(2); |
stack_swap(); |
pop_stack(); |
} |
|
#if defined(HAVE_SETENV) && defined(HAVE_UNSETENV) |
#define USE_SETENV |
#else |
/* Used to hold refs to the strings that we feed to putenv. Indexed on |
* variable names, values are the "name=value" strings. |
* |
* This is not needed when using {,un}setenv(), since they maintain |
* their own corresponding table. */ |
static struct mapping *env_allocs = NULL; |
#endif |
|
/* Works exactly like the getenv efun defined in the master, but only |
* accesses the real environment. Everyone should use the caching |
* version in the master instead. */ |
PIKEFUN string|mapping _getenv (void|string var) |
rawtype tOr(tFunc(tStr, tString), tFunc(tVoid, tMap (tStr, tStr))); |
{ |
/* FIXME: Perhaps add the amigaos4 stuff from pike_push_env here too. */ |
|
if (var) { |
if (var->size_shift) |
SIMPLE_ARG_TYPE_ERROR ("getenv", 1, "void|string(0..255)"); |
|
if (string_has_null (var)) { |
/* Won't find a variable name like this. */ |
pop_stack(); |
push_int (0); |
} |
|
else { |
char *entry = getenv (var->str); |
pop_stack(); |
if (!entry) |
push_int (0); |
else { |
char *eq = STRCHR (entry, '='); |
/* There should always be a '=' in the entry, but you never know.. */ |
push_string (make_shared_string (eq ? eq + 1 : entry)); |
} |
} |
} |
|
else { |
#ifdef DECLARE_ENVIRON |
extern char **environ; |
#endif |
struct mapping *m, *new_env_allocs; |
int n; |
|
/* Iterate the environment backwards below so that earlier |
* variables will override later ones in case the same variable |
* occur multiple times (which it shouldn't). That makes the |
* result similar to what getenv(3) commonly returns (at least the |
* one in gnu libc). */ |
for (n = 0; environ[n]; n++) {} |
|
m = allocate_mapping (n); |
#ifndef USE_SETENV |
if (env_allocs) |
new_env_allocs = allocate_mapping (m_sizeof (env_allocs)); |
#endif /* !USE_SETENV */ |
|
while (--n >= 0) { |
char *entry = environ[n], *eq = STRCHR (entry, '='); |
if (eq) { /* gnu libc getenv ignores variables without '='. */ |
struct pike_string *var = make_shared_binary_string (entry, eq - entry); |
struct pike_string *val = make_shared_string (eq + 1); |
mapping_string_insert_string (m, var, val); |
|
#ifndef USE_SETENV |
/* Populate new_env_allocs with the env_allocs entries that |
* are still in use. */ |
if (env_allocs) { |
struct svalue *ea_val = low_mapping_string_lookup (env_allocs, var); |
if (ea_val && ea_val->u.string->str == entry) |
mapping_string_insert (new_env_allocs, var, ea_val); |
} |
#endif /* !USE_SETENV */ |
|
free_string (var); |
free_string (val); |
} |
} |
|
#ifndef USE_SETENV |
if (env_allocs) { |
free_mapping (env_allocs); |
env_allocs = new_env_allocs; |
} |
#endif /* !USE_SETENV */ |
|
push_mapping (m); |
} |
} |
|
/* Works exactly like the putenv efun defined in the master, but only |
* updates the real environment. Everyone should use the version in |
* the master instead so that the cache doesn't get stale. */ |
PIKEFUN void _putenv (string var, void|string val) |
{ |
#ifndef USE_SETENV |
struct pike_string *putenv_str, *env_alloc_var; |
#endif |
|
if (var->size_shift) |
SIMPLE_ARG_TYPE_ERROR ("putenv", 1, "string(0..255)"); |
if (string_has_null (var) || STRCHR (var->str, '=')) |
SIMPLE_ARG_ERROR ("putenv", 1, "Variable name cannot contain '=' or NUL."); |
|
if (val) { |
#ifndef USE_SETENV |
struct string_builder sb; |
#endif |
|
if (val->size_shift) |
SIMPLE_ARG_TYPE_ERROR ("putenv", 2, "void|string(0..255)"); |
if (string_has_null (val)) |
SIMPLE_ARG_ERROR ("putenv", 2, "Variable value cannot contain NUL."); |
|
#ifdef USE_SETENV |
if (setenv(var->str, val->str, 1)) { |
if (errno == ENOMEM) |
SIMPLE_OUT_OF_MEMORY_ERROR ("putenv", 0); |
else |
Pike_error ("Error from setenv(3): %s\n", strerror (errno)); |
} |
#else /* !USE_SETENV */ |
init_string_builder (&sb, 0); |
string_builder_shared_strcat (&sb, var); |
string_builder_putchar (&sb, '='); |
string_builder_shared_strcat (&sb, val); |
putenv_str = finish_string_builder (&sb); |
push_string (putenv_str); /* Let mega_apply pop. */ |
#endif /* USE_SETENV */ |
} |
else { |
#ifdef USE_SETENV |
/* Note: Some versions of glibc have a unsetenv(3) that returns void, |
* thus no checking of the return value here. |
*/ |
unsetenv(var->str); |
#else /* !USE_SETENV */ |
#ifdef PUTENV_ALWAYS_REQUIRES_EQUAL |
/* Windows can never get things quite right.. :P */ |
struct string_builder sb; |
init_string_builder (&sb, 0); |
string_builder_shared_strcat (&sb, var); |
string_builder_putchar (&sb, '='); |
putenv_str = finish_string_builder (&sb); |
push_string (putenv_str); /* Let mega_apply pop. */ |
#else |
putenv_str = var; |
#endif |
#endif /* USE_SETENV */ |
} |
|
#ifndef USE_SETENV |
if (putenv (putenv_str->str)) { |
if (errno == ENOMEM) |
SIMPLE_OUT_OF_MEMORY_ERROR ("putenv", 0); |
else |
Pike_error ("Error from putenv(3): %s\n", strerror (errno)); |
} |
|
#ifdef __NT__ |
ref_push_string (var); |
f_lower_case (1); |
assert (TYPEOF(Pike_sp[-1]) == T_STRING); |
env_alloc_var = Pike_sp[-1].u.string; |
/* Let mega_apply pop. */ |
#else |
env_alloc_var = var; |
#endif |
|
if (!env_allocs) env_allocs = allocate_mapping (4); |
|
if (val) |
/* Must keep the string passed to putenv allocated (and we |
* assume no other entities are naughty enough to modify it). */ |
mapping_string_insert_string (env_allocs, env_alloc_var, putenv_str); |
else { |
struct svalue key; |
SET_SVAL(key, T_STRING, 0, string, env_alloc_var); |
map_delete (env_allocs, &key); |
} |
#endif /* !USE_SETENV */ |
} |
|
#if defined(PIKE_DEBUG) && defined(PIKE_PORTABLE_BYTECODE) |
|
/*! @decl void disassemble(function fun) |
*! @belongs Debug |
*! |
*! Disassemble a Pike function to @[Stdio.stderr]. |
*! |
*! @note |
*! This function is only available if the Pike runtime |
*! has been compiled with debug enabled. |
*/ |
PIKEFUN void _disassemble(function fun) |
{ |
if ((TYPEOF(*fun) != T_FUNCTION) || |
(SUBTYPEOF(*fun) == FUNCTION_BUILTIN)) { |
fprintf(stderr, |
"Disassembly only supported for functions implemented in Pike.\n"); |
} else if (!fun->u.object->prog) { |
fprintf(stderr, "Function in destructed object.\n"); |
} else { |
int f = SUBTYPEOF(*fun); |
struct reference *ptr = PTR_FROM_INT(fun->u.object->prog, f); |
struct program *p = PROG_FROM_PTR(fun->u.object->prog, ptr); |
struct identifier *id = p->identifiers + ptr->identifier_offset; |
if (id->func.offset >= 0) { |
struct pike_string *tripples = |
p->strings[read_program_data(p->program + id->func.offset, -1)]; |
switch(tripples->size_shift) { |
#define CASE(SHIFT) \ |
case SHIFT: \ |
{ \ |
PIKE_CONCAT(p_wchar, SHIFT) *str = \ |
PIKE_CONCAT(STR, SHIFT)(tripples); \ |
int i=0; \ |
while(i < tripples->len) { \ |
fprintf(stderr, "@@@ %d: %s, %d, %d\n", \ |
i/3, \ |
instrs[*str - F_OFFSET]. \ |
name, \ |
str[1], str[2]); \ |
str += 3; \ |
i += 3; \ |
} \ |
} \ |
break |
CASE(0); |
CASE(1); |
CASE(2); |
#undef CASE |
} |
} else { |
fprintf(stderr, "Prototype.\n"); |
} |
} |
pop_n_elems(args); |
push_int(0); |
} |
|
#endif /* PIKE_DEBUG && PIKE_PORTABLE_BYTECODE */ |
|
/* |
* Backtrace handling. |
*/ |
|
/*! @module Pike |
*/ |
|
/*! @class BacktraceFrame |
*/ |
|
PIKECLASS backtrace_frame |
{ |
PIKEVAR mixed _fun flags ID_PROTECTED|ID_PRIVATE; |
#ifdef PIKE_DEBUG |
PIKEVAR program oprog flags ID_PROTECTED|ID_PRIVATE; |
#endif |
PIKEVAR array args; |
|
/* These are cleared when filename and lineno have been initialized |
* from them. */ |
PIKEVAR program prog flags ID_PROTECTED|ID_PRIVATE; |
CVAR PIKE_OPCODE_T *pc; |
|
/* These two are considered to be uninitialized from prog, pc and |
* fun as long as lineno == -1. */ |
CVAR struct pike_string *filename; |
CVAR INT_TYPE lineno; |
|
INIT |
{ |
THIS->pc = NULL; |
THIS->lineno = -1; |
THIS->filename = NULL; |
} |
|
EXIT |
gc_trivial; |
{ |
if (THIS->filename) { |
free_string(THIS->filename); |
THIS->filename = NULL; |
} |
THIS->pc = NULL; |
THIS->lineno = -1; |
} |
|
/* NOTE: Use old-style getter/setter syntax for compatibility with |
* old Parser.Pike.split() used by precompile.pike. |
*/ |
|
PIKEFUN mixed `->fun() |
{ |
push_svalue(&THIS->_fun); |
} |
|
PIKEFUN void `->fun=(mixed val) |
{ |
/* FIXME: Should we allow this at all? |
* Linenumber info etc won't match. |
*/ |
#ifdef PIKE_DEBUG |
if ((TYPEOF(*val) == T_FUNCTION) && (SUBTYPEOF(*val) != FUNCTION_BUILTIN)) { |
assign_short_svalue((union anything *)&THIS->oprog, |
(union anything *)&val->u.object->prog, T_PROGRAM); |
} |
#endif |
assign_svalue(&THIS->_fun, val); |
} |
|
/*! @decl int(0..1) _is_type(string t) |
*! This object claims to be an array for backward compatibility. |
*/ |
PIKEFUN int(0..1) _is_type(string t) |
{ |
INT_TYPE res = (t == findstring("array")); |
pop_n_elems(args); |
push_int(res); |
} |
|
static void fill_in_file_and_line() |
{ |
struct pike_string *file = NULL; |
assert (THIS->lineno == -1); |
|
if (THIS->pc && THIS->prog) { |
file = low_get_line(THIS->pc, THIS->prog, &THIS->lineno); |
THIS->pc = NULL; |
} |
else if (TYPEOF(THIS->_fun) == PIKE_T_FUNCTION) { |
#ifdef PIKE_DEBUG |
if (THIS->_fun.u.object->prog && |
THIS->_fun.u.object->prog != THIS->oprog) { |
struct identifier *id = ID_FROM_INT(THIS->oprog, SUBTYPEOF(THIS->_fun)); |
/* FIXME: Dump dmalloc info for the object? */ |
Pike_fatal("Lost track of function pointer! Function name was %s.\n", |
id->name?id->name->str:"<no name>"); |
} |
#endif |
file = low_get_function_line (THIS->_fun.u.object, SUBTYPEOF(THIS->_fun), |
&THIS->lineno); |
} |
else if (THIS->prog) { |
file = low_get_program_line (THIS->prog, &THIS->lineno); |
} |
|
if (file) { |
if (!THIS->filename) THIS->filename = file; |
else free_string (file); |
} |
|
if (THIS->prog) { |
free_program(THIS->prog); |
THIS->prog = NULL; |
} |
} |
|
/*! @decl string _sprintf(int c, mapping|void opts) |
*/ |
PIKEFUN string _sprintf(int c, mapping|void opts) |
{ |
pop_n_elems(args); |
|
if (c != 'O') { |
push_undefined (); |
return; |
} |
|
push_text("backtrace_frame("); |
|
if (THIS->lineno == -1) fill_in_file_and_line(); |
|
if (THIS->filename) { |
ref_push_string(THIS->filename); |
push_text(":"); |
push_int(THIS->lineno); |
push_text(", "); |
f_add(4); |
} else { |
push_text("Unknown file, "); |
} |
if (TYPEOF(THIS->_fun) == PIKE_T_FUNCTION) { |
if (THIS->_fun.u.object->prog) { |
#ifdef PIKE_DEBUG |
if (THIS->_fun.u.object->prog != THIS->oprog) { |
struct identifier *id = |
ID_FROM_INT(THIS->oprog, SUBTYPEOF(THIS->_fun)); |
/* FIXME: Dump dmalloc info for the object? */ |
Pike_fatal("Lost track of function pointer! Function name was %s.\n", |
id->name?id->name->str:"<no name>"); |
} |
#endif |
push_svalue(&THIS->_fun); |
f_function_name(1); |
push_text("(), "); |
f_add(2); |
} else { |
free_svalue(&THIS->_fun); |
SET_SVAL(THIS->_fun, PIKE_T_INT, NUMBER_DESTRUCTED, integer, 0); |
push_text("destructed_function(), "); |
} |
} else if (TYPEOF(THIS->_fun) == PIKE_T_PROGRAM) { |
/* FIXME: Use the master? */ |
push_text("program(), "); |
} else if (TYPEOF(THIS->_fun) == PIKE_T_STRING) { |
push_svalue(&THIS->_fun); |
push_text("(), "); |
f_add(2); |
} else { |
push_text("destructed_function(), "); |
} |
|
if (THIS->args) { |
push_text("Args: "); |
push_int(THIS->args->size); |
f_add(2); |
} else { |
push_text("No args"); |
} |
push_text(")"); |
f_add(5); |
} |
|
/*! @decl int(3..) _sizeof() |
*/ |
PIKEFUN int(3..) _sizeof() |
{ |
if (THIS->args) { |
push_int(THIS->args->size + 3); |
} else { |
push_int(3); |
} |
} |
|
/*! @decl mixed `[](int index, int|void end_or_none) |
*! The BacktraceFrame object can be indexed as an array. |
*/ |
PIKEFUN mixed `[](int index, int|void end_or_none) |
{ |
INT_TYPE end = index; |
INT32 numargs = 0; |
INT32 i; |
|
if (THIS->args) { |
numargs = THIS->args->size; |
} |
|
numargs += 3; |
|
if (!end_or_none) { |
if (index < 0) { |
index_error("pike_frame->`[]", Pike_sp-args, args, NULL, Pike_sp-args, |
"Indexing with negative index (%"PRINTPIKEINT"d)\n", index); |
} else if (index >= numargs) { |
index_error("pike_frame->`[]", Pike_sp-args, args, NULL, Pike_sp-args, |
"Indexing with too large index (%"PRINTPIKEINT"d)\n", index); |
} |
} else { |
if (TYPEOF(*end_or_none) != PIKE_T_INT) { |
SIMPLE_BAD_ARG_ERROR("`[]",2,"int|void"); |
} |
end = end_or_none->u.integer; |
} |
|
pop_n_elems(args); |
|
if (end_or_none) { |
if ((end < 0) || (end < index) || (index >= numargs)) { |
f_aggregate(0); |
return; |
} |
|
if (end >= numargs) { |
end = numargs-1; |
} |
} |
|
for (i = index; i <= end; i++) { |
switch(i) { |
case 0: /* Filename */ |
if (THIS->lineno == -1) fill_in_file_and_line(); |
if (THIS->filename) { |
ref_push_string(THIS->filename); |
} else { |
push_int(0); |
} |
break; |
case 1: /* Linenumber */ |
if (THIS->lineno == -1) fill_in_file_and_line(); |
push_int(THIS->lineno); |
break; |
case 2: /* Function */ |
push_svalue(&THIS->_fun); |
break; |
default: /* Arguments */ |
{ |
if ((i > 2) && (THIS->args) && (i-3 < THIS->args->size)) { |
push_svalue(THIS->args->item + (i - 3)); |
break; |
} |
bad_arg_error("backtrace_frame->`[]", Pike_sp-args, args, 1, |
"int(0..)", Pike_sp-args, |
"Bad argument 1 to backtrace_frame->`[](): " |
"Expected int(0..%d)\n", |
numargs + 2); |
} |
/* NOT_REACHED */ |
break; |
} |
} |
if (end_or_none) { |
f_aggregate(1 + end - index); |
} |
} |
|
/*! @decl mixed `[]=(int index, mixed value) |
*/ |
PIKEFUN mixed `[]=(int index, mixed value) |
{ |
INT32 numargs = 0; |
|
if (THIS->args) { |
numargs = THIS->args->size; |
} |
|
numargs += 3; |
|
if ((index < -numargs) || (index >= numargs)) { |
index_error("pike_frame->`[]=", Pike_sp-args, args, NULL, Pike_sp-args, |
"Index %"PRINTPIKEINT"d is out of array range 0..%d,\n", |
index, numargs-1); |
} else if (index < 0) { |
index += numargs; |
} |
|
if (args > 2) { |
pop_n_elems(args - 2); |
args = 2; |
} |
|
switch(index) { |
case 0: /* Filename */ |
if (THIS->lineno == -1) fill_in_file_and_line(); |
if (TYPEOF(*value) != PIKE_T_STRING) { |
if ((TYPEOF(*value) != PIKE_T_INT) || |
(value->u.integer)) { |
SIMPLE_BAD_ARG_ERROR("backtrace_frame->`[]=", 2, |
"string|int(0..0)"); |
} |
if (THIS->filename) { |
free_string(THIS->filename); |
THIS->filename = NULL; |
} |
} else { |
if (THIS->filename) { |
free_string(THIS->filename); |
THIS->filename = NULL; |
} |
copy_shared_string(THIS->filename, value->u.string); |
} |
break; |
|
case 1: /* Linenumber */ |
if (THIS->lineno == -1) fill_in_file_and_line(); |
if (TYPEOF(*value) != PIKE_T_INT) { |
SIMPLE_BAD_ARG_ERROR("backtrace_frame->`[]=", 2, "int(1..)"); |
} |
THIS->lineno = value->u.integer; |
break; |
|
case 2: /* Function */ |
if (THIS->lineno == -1) fill_in_file_and_line(); |
assign_svalue(&THIS->_fun, value); |
break; |
default: /* Arguments */ |
assign_svalue(THIS->args->item + index - 3, value); |
break; |
} |
stack_swap(); |
pop_stack(); |
} |
|
}; |
|
/*! @endclass |
*/ |
|
/*! @decl mapping(string:int|string) get_runtime_info() |
*! |
*! Get information about the Pike runtime. |
*! |
*! @returns |
*! Returns a mapping with the following content: |
*! @mapping |
*! @member string "bytecode_method" |
*! A string describing the bytecode method used by |
*! the Pike interpreter. |
*! @member int "abi" |
*! The number of bits in the ABI. Usually @expr{32@} or @expr{64@}. |
*! @member int "native_byteorder" |
*! The byte order used by the native cpu. |
*! Usually @expr{1234@} (aka little endian) or |
*! @expr{4321@} (aka bigendian). |
*! @member int "int_size" |
*! The number of bits in the native integer type. |
*! Usually @expr{32@} or @expr{64@}. |
*! @member int "float_size" |
*! The number of bits in the native floating point type. |
*! Usually @expr{32@} or @expr{64@}. |
*! @member int(0..1) "auto_bignum" |
*! Present if integers larger than the native size are automatically |
*! converted into bignums. |
*! @endmapping |
*/ |
PIKEFUN mapping(string:int|string) get_runtime_info() |
optflags OPT_TRY_OPTIMIZE; |
{ |
pop_n_elems(args); |
push_constant_text("bytecode_method"); |
push_constant_text(PIKE_BYTECODE_METHOD_NAME); |
push_constant_text("abi"); |
push_int(sizeof(void *) * 8); |
push_constant_text("native_byteorder"); |
push_int(PIKE_BYTEORDER); |
push_constant_text("int_size"); |
push_int(sizeof(INT_TYPE) * 8); |
push_constant_text("float_size"); |
push_int(sizeof(FLOAT_TYPE) * 8); |
push_constant_text("auto_bignum"); |
push_int(1); |
f_aggregate_mapping(6*2); |
} |
|
/*! @endmodule |
*/ |
|
void low_backtrace(struct Pike_interpreter_struct *i) |
{ |
struct svalue *stack_top = i->stack_pointer; |
struct pike_frame *f, *of = 0; |
int size = 0; |
struct array *res = NULL; |
|
for (f = i->frame_pointer; f; f = f->next) { |
size++; |
} |
|
res = allocate_array_no_init(size, 0); |
push_array(res); |
|
for (f = i->frame_pointer; f && size; f = (of = f)->next) { |
struct object *o = low_clone(backtrace_frame_program); |
struct backtrace_frame_struct *bf; |
struct identifier *function = NULL; |
|
call_c_initializers(o); |
|
size--; |
|
SET_SVAL(res->item[size], PIKE_T_OBJECT, 0, object, o); |
|
bf = OBJ2_BACKTRACE_FRAME(o); |
|
if ((bf->prog = f->context->prog)) { |
add_ref(bf->prog); |
bf->pc = f->pc; |
} |
|
SET_SVAL(bf->_fun, PIKE_T_INT, NUMBER_DESTRUCTED, integer, 0); |
|
if (f->current_object && f->current_object->prog) { |
if (f->fun == FUNCTION_BUILTIN) { |
/* Unusual case. The frame is from call_c_initializers(), gc() |
* or similar. cf [bug 6156]. /grubba |
* |
* Masquerade as the program. |
* |
* FIXME: Ought to keep parent-pointers. |
*/ |
SET_SVAL(bf->_fun, PIKE_T_PROGRAM, 0, |
program, f->current_object->prog); |
add_ref(f->current_object->prog); |
} else { |
SET_SVAL(bf->_fun, PIKE_T_FUNCTION, |
CHECK_IDREF_RANGE(f->fun, f->current_object->prog), |
object, f->current_object); |
add_ref(f->current_object); |
function = ID_FROM_INT(f->current_object->prog, f->fun); |
#ifdef PIKE_DEBUG |
add_ref(bf->oprog = bf->_fun.u.object->prog); |
#endif |
} |
} |
|
if (f->locals) { |
INT32 numargs = DO_NOT_WARN((INT32) MINIMUM(f->num_args, |
stack_top - f->locals)); |
INT32 varargs = 0; |
|
if(of && of->locals) { |
/* f->num_args can be too large, so this is necessary for some |
* reason. I don't know why. /mast */ |
numargs = DO_NOT_WARN((INT32)MINIMUM(f->num_args,of->locals - f->locals)); |
} |
|
numargs = MAXIMUM(numargs, 0); |
|
/* Handle varargs... */ |
if (function && (function->identifier_flags & IDENTIFIER_VARARGS) && |
(f->locals + numargs < stack_top) && |
(TYPEOF(f->locals[numargs]) == T_ARRAY)) { |
varargs = f->locals[numargs].u.array->size; |
} |
|
if (numargs + varargs) { |
bf->args = allocate_array_no_init(numargs + varargs, 0); |
bf->args->type_field = |
assign_svalues_no_free(bf->args->item, f->locals, numargs, BIT_MIXED); |
if (varargs) { |
bf->args->type_field |= |
assign_svalues_no_free(bf->args->item + numargs, |
f->locals[numargs].u.array->item, |
varargs, BIT_MIXED); |
} |
} |
} |
} |
res->type_field = BIT_OBJECT; |
/* NOTE: res has already been pushed on the stack. */ |
} |
|
/*! @decl array(Pike.BacktraceFrame) backtrace() |
*! |
*! FIXME: This documentation is not up to date! |
*! |
*! Get a description of the current call stack. |
*! |
*! The description is returned as an array with one entry for each call |
*! frame on the stack. |
*! |
*! Each entry has this format: |
*! @array |
*! @elem string file |
*! A string with the filename if known, else zero. |
*! @elem int line |
*! An integer containing the linenumber if known, else zero. |
*! @elem function fun |
*! The function that was called at this level. |
*! @elem mixed|void ... args |
*! The arguments that the function was called with. |
*! @endarray |
*! |
*! The current call frame will be last in the array. |
*! |
*! @note |
*! Please note that the frame order may be reversed in a later version |
*! (than 7.1) of Pike to accommodate for deferred backtraces. |
*! |
*! Note that the arguments reported in the backtrace are the current |
*! values of the variables, and not the ones that were at call-time. |
*! This can be used to hide sensitive information from backtraces |
*! (eg passwords). |
*! |
*! @seealso |
*! @[catch()], @[throw()] |
*/ |
PMOD_EXPORT |
PIKEFUN array(mixed) backtrace() |
efun; |
optflags OPT_EXTERNAL_DEPEND; |
{ |
low_backtrace(& Pike_interpreter); |
} |
|
/*! @module String |
*/ |
|
/*! @class Buffer |
*! A buffer, used for building strings. It's |
*! conceptually similar to a string, but you can only @[add] |
*! strings to it, and you can only @[get] the value from it once. |
*! |
*! There is a reason for those seemingly rather odd limitations, |
*! it makes it possible to do some optimizations that really speed |
*! things up. |
*! |
*! You do not need to use this class unless you add very many |
*! strings together, or very large strings. |
*! |
*! @example |
*! For the fastest possible operation, write your code like this: |
*! |
*! @code |
*! String.Buffer b = String.Buffer( ); |
*! |
*! function add = b->add; |
*! |
*! .. call add several times in code ... |
*! |
*! string result = b->get(); // also clears the buffer |
*! @endcode |
*/ |
PIKECLASS Buffer |
{ |
CVAR struct string_builder str; |
CVAR int initial; |
|
void f_Buffer_get_copy( INT32 args ); |
void f_Buffer_get( INT32 args ); |
void f_Buffer_add( INT32 args ); |
|
/*! @decl void create(int initial_size) |
*! |
*! Initializes a new buffer. |
*! |
*! If no @[initial_size] is specified, 256 is used. If you |
*! know approximately how big the buffer will be, you can optimize |
*! the operation of @[add()] (slightly) by passing the size to this |
*! function. |
*/ |
PIKEFUN void create( int|void size ) |
{ |
struct Buffer_struct *str = THIS; |
if( size ) |
str->initial = MAXIMUM( size->u.integer, 512 ); |
else |
str->initial = 256; |
} |
|
/*! @decl string _sprintf( int flag, mapping flags ) |
*! It is possible to @[sprintf] a String.Buffer object |
*! as @tt{%s@} just as if it was a string. |
*/ |
PIKEFUN string _sprintf( int flag, mapping flags ) |
{ |
switch( flag ) |
{ |
case 'O': |
{ |
struct pike_string *res; |
struct Buffer_struct *str = THIS; |
push_text( "Buffer(%d /* %d */)" ); |
if( str->str.s ) |
{ |
push_int(str->str.s->len); |
push_int(str->str.malloced); |
} |
else |
{ |
push_int( 0 ); |
push_int( 0 ); |
} |
f_sprintf( 3 ); |
dmalloc_touch_svalue(Pike_sp-1); |
res = Pike_sp[-1].u.string; |
Pike_sp--; |
RETURN res; |
} |
|
case 's': |
{ |
pop_n_elems( args ); |
if( Pike_fp->current_object->refs != 1 ) |
f_Buffer_get_copy( 0 ); |
else |
f_Buffer_get( 0 ); |
} |
return; |
|
case 't': |
RETURN make_shared_binary_string("Buffer",6); |
} |
pop_n_elems( args ); |
push_undefined(); |
} |
|
/*! @decl mixed cast( string type ) |
*! It is possible to cast a String.Buffer object to |
*! a @expr{string@} and an @expr{int@}. |
*/ |
PIKEFUN mixed cast( string type ) |
{ |
struct pike_string *string_t; |
struct pike_string *int_t; |
MAKE_CONST_STRING( string_t, "string" ); |
MAKE_CONST_STRING( int_t, "int" ); |
|
if( type == string_t ) |
{ |
pop_n_elems( args ); |
if( Pike_fp->current_object->refs != 1 ) |
f_Buffer_get_copy( 0 ); |
else |
f_Buffer_get( 0 ); |
return; |
} |
|
if( type == int_t ) |
{ |
struct Buffer_struct *str = THIS; |
pop_stack(); |
if( Pike_fp->current_object->refs != 1 ) |
f_Buffer_get_copy( 0 ); |
else |
f_Buffer_get( 0 ); |
o_cast_to_int( ); |
return; |
} |
Pike_error("Cannot cast to %S\n", type); |
} |
|
/*! @decl String.Buffer `+( string what ) |
*/ |
PIKEFUN object `+( string what ) |
{ |
struct Buffer_struct *str = THIS, *str2; |
struct object *res = fast_clone_object( Buffer_program ); |
str2 = OBJ2_BUFFER( res ); |
str2->initial = str->initial; |
if( str->str.s ) |
init_string_builder_copy (&str2->str, &str->str); |
apply( res, "add", 1 ); |
RETURN res; |
} |
|
/*! @decl String.Buffer `+=( string what ) |
*/ |
PIKEFUN object `+=( string what ) |
{ |
f_Buffer_add( 1 ); |
REF_RETURN Pike_fp->current_object; |
} |
|
/*! @decl int add(string ... data) |
*! |
*! Adds @[data] to the buffer. |
*! |
*! @returns |
*! Returns the size of the buffer. |
*! |
*! @seealso |
*! @[addat()] |
*/ |
PIKEFUN int add( string ... arg1 ) |
{ |
struct Buffer_struct *str = THIS; |
int init_from_arg0 = 0, j; |
|
if (!str->str.s && args) { |
ptrdiff_t sum = 0; |
int shift = 0; |
for (j=0; j < args; j++) { |
struct pike_string *a = Pike_sp[j-args].u.string; |
sum += a->len; |
shift |= a->size_shift; |
} |
if (sum < str->initial) |
sum = str->initial; |
else if (sum > str->initial) |
sum <<= 1; |
shift = shift & ~(shift >> 1); |
|
if (shift == Pike_sp[-args].u.string->size_shift && |
init_string_builder_with_string (&str->str, Pike_sp[-args].u.string)) { |
mark_free_svalue (Pike_sp - args); |
if (sum > str->str.s->len) |
string_build_mkspace (&str->str, sum - str->str.s->len, shift); |
init_from_arg0 = 1; |
} |
else |
init_string_builder_alloc(&str->str, sum, shift); |
|
/* We know it will be a string that really is this wide. */ |
str->str.known_shift = shift; |
} |
|
for( j = init_from_arg0; j<args; j++ ) |
{ |
struct pike_string *a = Pike_sp[j-args].u.string; |
string_builder_shared_strcat( &str->str, a ); |
} |
|
if (str->str.s) { |
RETURN str->str.s->len; |
} else { |
RETURN 0; |
} |
} |
|
/*! @decl int addat(int(0..) pos, string ... data) |
*! |
*! Adds @[data] to the buffer, starting at position @[pos]. |
*! |
*! @returns |
*! Returns the size of the buffer. |
*! |
*! @note |
*! If the buffer isn't of the required size, it is padded |
*! with NUL-characters. |
*! |
*! @seealso |
*! @[add()] |
*/ |
PIKEFUN int addat(int(0..) pos, string ... arg1 ) |
{ |
struct Buffer_struct *str = THIS; |
|
if (pos < 0) |
SIMPLE_BAD_ARG_ERROR("addat", 1, "int(0..)"); |
|
if (args) { |
int init_from_arg0 = 0, j; |
ptrdiff_t sum = 0; |
int shift = 0; |
for (j=1; j < args; j++) { |
struct pike_string *a = Pike_sp[j-args].u.string; |
sum += a->len; |
shift |= a->size_shift; |
} |
|
if (!str->str.s) { |
if ((sum + pos) <= str->initial) { |
sum = str->initial; |
} else { |
sum <<= 1; |
sum += pos; |
} |
shift = shift & ~(shift >> 1); |
|
init_string_builder_alloc(&str->str, sum, shift); |
} else { |
sum += pos; |
shift |= str->str.known_shift; |
shift = shift & ~(shift >> 1); |
if (sum > str->str.s->len) { |
string_build_mkspace(&str->str, sum - str->str.s->len, shift); |
} else if (shift != str->str.known_shift) { |
string_build_mkspace(&str->str, 0, shift); |
} |
} |
/* We know it will be a string that really is this wide. */ |
str->str.known_shift = shift; |
|
if (str->str.s->len < pos) { |
/* Clear the padding. */ |
MEMSET(str->str.s->str + (str->str.s->len << str->str.s->size_shift), |
0, (pos - str->str.s->len) << str->str.s->size_shift); |
} |
|
for(j = 1; j<args; j++) { |
struct pike_string *a = Pike_sp[j-args].u.string; |
pike_string_cpy(MKPCHARP_STR_OFF(str->str.s, pos), a); |
pos += a->len; |
} |
|
if (str->str.s->len < pos) { |
str->str.s->len = pos; |
/* Ensure NUL-termination */ |
str->str.s->str[str->str.s->len << str->str.s->size_shift] = 0; |
} |
} |
|
if (str->str.s) { |
RETURN str->str.s->len; |
} else { |
RETURN 0; |
} |
} |
|
/*! @decl void putchar(int c) |
*! Appends the character @[c] at the end of the string. |
*/ |
PIKEFUN void putchar(int c) { |
struct Buffer_struct *str = THIS; |
if(!str->str.s) |
init_string_builder_alloc(&str->str, str->initial, 0); |
string_builder_putchar(&str->str, c); |
} |
|
/*! @decl int sprintf(strict_sprintf_format format, sprintf_args ... args) |
*! Appends the output from @[sprintf] at the end of the string. |
*! Returns the resulting size of the String.Buffer. |
*/ |
PIKEFUN int sprintf(mixed ... arguments) |
rawtype tFuncV(tAttr("strict_sprintf_format", tOr(tStr, tObj)), |
tAttr("sprintf_args", tMix), tStr); |
|
{ |
// FIXME: Reset length on exception? |
struct Buffer_struct *str = THIS; |
if(!str->str.s) |
init_string_builder_alloc(&str->str, str->initial, 0); |
low_f_sprintf(args, 0, &str->str); |
RETURN str->str.s->len; |
} |
|
/*! @decl string get_copy() |
*! |
*! Get the data from the buffer. Significantly slower than @[get], |
*! but does not clear the buffer. |
*/ |
PIKEFUN string get_copy() |
{ |
struct pike_string *str = THIS->str.s; |
if( str ) |
{ |
ptrdiff_t len = str->len; |
if( len > 0 ) |
{ |
char *d = (char *)str->str; |
switch( str->size_shift ) |
{ |
case 0: |
RETURN make_shared_binary_string0((p_wchar0 *)d,len); |
break; |
case 1: |
RETURN make_shared_binary_string1((p_wchar1 *)d,len); |
break; |
case 2: |
RETURN make_shared_binary_string2((p_wchar2 *)d,len); |
break; |
} |
} |
} |
push_empty_string(); |
return; |
} |
|
/*! @decl string get() |
*! |
*! Get the data from the buffer. |
*! |
*! @note |
*! This will clear the data in the buffer |
*/ |
PIKEFUN string get( ) |
{ |
struct Buffer_struct *str = THIS; |
if( str->str.s ) |
{ |
struct pike_string *s = finish_string_builder( &str->str ); |
str->str.malloced = 0; |
str->str.s = NULL; |
RETURN s; |
} |
pop_n_elems(args); |
push_empty_string(); |
return; |
} |
|
/*! @decl int _sizeof() |
*! |
*! Returns the size of the buffer. |
*/ |
PIKEFUN int _sizeof() |
{ |
struct Buffer_struct *str = THIS; |
RETURN str->str.s ? str->str.s->len : 0; |
} |
|
INIT |
{ |
struct Buffer_struct *str = THIS; |
MEMSET( str, 0, sizeof( *str ) ); |
} |
|
EXIT |
gc_trivial; |
{ |
struct Buffer_struct *str = THIS; |
if( str->str.s ) |
free_string_builder( &str->str ); |
} |
|
GC_RECURSE |
{ |
if (mc_count_bytes (Pike_fp->current_object) && THIS->str.s) |
mc_counted_bytes += THIS->str.malloced; |
} |
} |
|
/*! @endclass |
*/ |
|
/*! @class Replace |
*! |
*! This is a "compiled" version of the @[replace] function applied on |
*! a string, with more than one replace string. The replace strings |
*! are given to the create method as a @i{from@} and @i{to@} array |
*! and are then analyzed. The @expr{`()@} is then called with a |
*! string and the replace rules in the Replace object will be |
*! applied. The Replace object is used internally by the Pike |
*! optimizer and need not be used manually. |
*/ |
PIKECLASS multi_string_replace |
{ |
CVAR struct replace_many_context ctx; |
/* NOTE: from and to are only kept for _encode()'s use. */ |
PIKEVAR array from flags ID_PROTECTED; |
PIKEVAR array to flags ID_PROTECTED; |
|
/*! @decl void create(array(string)|mapping(string:string)|void from, @ |
*! array(string)|string|void to) |
*/ |
PIKEFUN void create(array(string)|mapping(string:string)|void from_arg, |
array(string)|string|void to_arg) |
{ |
if (THIS->from) { |
free_array(THIS->from); |
THIS->from = NULL; |
} |
if (THIS->to) { |
free_array(THIS->to); |
THIS->to = NULL; |
} |
if (THIS->ctx.v) |
free_replace_many_context(&THIS->ctx); |
|
if (!args) { |
push_int(0); |
return; |
} |
if (from_arg && TYPEOF(*from_arg) == T_MAPPING) { |
if (to_arg) { |
Pike_error("Bad number of arguments to create().\n"); |
} |
THIS->from = mapping_indices(from_arg->u.mapping); |
THIS->to = mapping_values(from_arg->u.mapping); |
pop_n_elems(args); |
args = 0; |
} else { |
/* FIXME: Why is from declared |void, when it isn't allowed |
* to be void? |
* /grubba 2004-09-02 |
* |
* It probably has to do with the "if (!args)" above: It should |
* be possible to create an empty instance. /mast |
*/ |
if (!from_arg || !to_arg) { |
Pike_error("Bad number of arguments to create().\n"); |
} |
pop_n_elems(args-2); |
args = 2; |
if (TYPEOF(*from_arg) != T_ARRAY) { |
SIMPLE_BAD_ARG_ERROR("Replace", 1, |
"array(string)|mapping(string:string)"); |
} |
if (TYPEOF(*to_arg) == T_STRING) { |
push_int(from_arg->u.array->size); |
stack_swap(); |
f_allocate(2); |
} |
if (TYPEOF(*to_arg) != T_ARRAY) { |
SIMPLE_BAD_ARG_ERROR("Replace", 2, "array(string)|string"); |
} |
if (from_arg->u.array->size != to_arg->u.array->size) { |
Pike_error("Replace must have equal-sized from and to arrays.\n"); |
} |
add_ref(THIS->from = from_arg->u.array); |
add_ref(THIS->to = to_arg->u.array); |
} |
|
if (!THIS->from->size) { |
/* Enter no-op mode. */ |
pop_n_elems(args); |
push_int(0); |
return; |
} |
|
if( (THIS->from->type_field & ~BIT_STRING) && |
(array_fix_type_field(THIS->from) & ~BIT_STRING) ) |
SIMPLE_BAD_ARG_ERROR("Replace", 1, |
"array(string)|mapping(string:string)"); |
|
if( (THIS->to->type_field & ~BIT_STRING) && |
(array_fix_type_field(THIS->to) & ~BIT_STRING) ) |
SIMPLE_BAD_ARG_ERROR("Replace", 2, "array(string)|string"); |
|
compile_replace_many(&THIS->ctx, THIS->from, THIS->to, 1); |
|
pop_n_elems(args); |
push_int(0); |
} |
|
/*! @decl string `()(string str) |
*/ |
PIKEFUN string `()(string str) |
{ |
if (!THIS->ctx.v) { |
/* The result is already on the stack in the correct place... */ |
return; |
} |
|
RETURN execute_replace_many(&THIS->ctx, str); |
} |
|
/*! @decl array(array(string)) _encode() |
*/ |
PIKEFUN array(array(string)) _encode() |
{ |
if (THIS->from) { |
ref_push_array(THIS->from); |
} else { |
push_undefined(); |
} |
if (THIS->to) { |
ref_push_array(THIS->to); |
} else { |
push_undefined(); |
} |
f_aggregate(2); |
} |
|
/*! @decl void _decode(array(array(string)) encoded) |
*/ |
PIKEFUN void _decode(array(array(string)) encoded) |
{ |
INT32 i; |
for (i=0; i < encoded->size; i++) { |
push_svalue(encoded->item + i); |
stack_swap(); |
} |
pop_stack(); |
|
f_multi_string_replace_create(i); |
} |
|
INIT |
{ |
MEMSET(&THIS->ctx, 0, sizeof(struct replace_many_context)); |
} |
|
EXIT |
gc_trivial; |
{ |
free_replace_many_context(&THIS->ctx); |
} |
} |
|
/*! @endclass |
*/ |
|
/*! @class SingleReplace |
*! |
*! This is a "compiled" version of the @[replace] function applied on |
*! a string, with just one replace string. The replace strings are |
*! given to the create method as a @i{from@} and @i{tom@} string and |
*! are then analyzed. The @expr{`()@} is then called with a string |
*! and the replace rule in the Replace object will be applied. The |
*! Replace object is used internally by the Pike optimizer and need |
*! not be used manually. |
*/ |
PIKECLASS single_string_replace |
{ |
CVAR SearchMojt mojt; |
PIKEVAR string del flags ID_PROTECTED|ID_PRIVATE; |
PIKEVAR string to flags ID_PROTECTED|ID_PRIVATE; |
|
EXTRA |
{ |
MAP_VARIABLE ("o", tObj, ID_PROTECTED|ID_PRIVATE, |
single_string_replace_storage_offset + |
OFFSETOF (single_string_replace_struct, mojt.container), |
T_OBJECT); |
} |
|
/*! @decl void create(string|void from, string|void to) |
*! |
*! @note |
*! May be called with either zero or two arguments. |
*/ |
PIKEFUN void create(string|void del, string|void to) |
{ |
if (THIS->del) { |
free_string(THIS->del); |
THIS->del = NULL; |
} |
if (THIS->to) { |
free_string(THIS->to); |
THIS->to = NULL; |
} |
|
if (!del) return; |
|
if (!to) { |
SIMPLE_BAD_ARG_ERROR("String.SingleReplace->create", 2, "string"); |
} |
|
if (del == to) { |
/* No-op... */ |
return; |
} |
|
copy_shared_string(THIS->del, del); |
copy_shared_string(THIS->to, to); |
|
if (del->len) { |
THIS->mojt = simple_compile_memsearcher(del); |
} |
} |
|
/*** replace function ***/ |
typedef char *(* replace_searchfunc)(void *,void *,size_t); |
|
/*! @decl string `()(string str) |
*/ |
PIKEFUN string `()(string str) |
{ |
int shift; |
struct pike_string *del = THIS->del; |
struct pike_string *to = THIS->to; |
struct pike_string *ret = NULL; |
|
if (!str->len || !del || !to) { |
/* The result is already on the stack in the correct place... */ |
return; |
} |
|
shift = MAXIMUM(str->size_shift, to->size_shift); |
|
if (!del->len) { |
int e, pos; |
ret = begin_wide_shared_string(str->len + to->len * (str->len-1), |
shift); |
low_set_index(ret, 0, index_shared_string(str, 0)); |
for(pos=e=1;e<str->len;e++) |
{ |
pike_string_cpy(MKPCHARP_STR_OFF(ret,pos), to); |
pos+=to->len; |
low_set_index(ret,pos++,index_shared_string(str,e)); |
} |
} else { |
char *s, *end, *tmp; |
replace_searchfunc f = (replace_searchfunc)0; |
void *mojt_data = THIS->mojt.data; |
PCHARP r; |
|
end = str->str+(str->len<<str->size_shift); |
|
switch(str->size_shift) |
{ |
case 0: f = (replace_searchfunc)THIS->mojt.vtab->func0; break; |
case 1: f = (replace_searchfunc)THIS->mojt.vtab->func1; break; |
case 2: f = (replace_searchfunc)THIS->mojt.vtab->func2; break; |
#ifdef PIKE_DEBUG |
default: Pike_fatal("Illegal shift.\n"); |
#endif |
} |
|
if(del->len == to->len) |
{ |
ret = begin_wide_shared_string(str->len, shift); |
} else { |
INT32 delimiters = 0; |
|
s = str->str; |
|
while((s = f(mojt_data, s, (end-s)>>str->size_shift))) |
{ |
delimiters++; |
s += del->len << str->size_shift; |
} |
|
if (!delimiters) { |
/* The result is already on the stack in the correct place... */ |
return; |
} |
|
ret = begin_wide_shared_string(str->len + |
(to->len-del->len)*delimiters, shift); |
} |
|
s = str->str; |
r = MKPCHARP_STR(ret); |
|
while((tmp = f(mojt_data, s, (end-s)>>str->size_shift))) |
{ |
#ifdef PIKE_DEBUG |
if(tmp + (del->len << str->size_shift) > end) |
Pike_fatal("SearchMojt found a match beyond end of string!\n"); |
#endif |
generic_memcpy(r,MKPCHARP(s,str->size_shift),(tmp-s)>>str->size_shift); |
INC_PCHARP(r,(tmp-s)>>str->size_shift); |
pike_string_cpy(r,to); |
INC_PCHARP(r,to->len); |
s=tmp+(del->len << str->size_shift); |
} |
generic_memcpy(r,MKPCHARP(s,str->size_shift),(end-s)>>str->size_shift); |
} |
RETURN end_shared_string(ret); |
} |
|
/*! @decl array(string) _encode() |
*/ |
PIKEFUN array(string) _encode() |
{ |
if (THIS->del) { |
ref_push_string(THIS->del); |
ref_push_string(THIS->to); |
f_aggregate(2); |
} else { |
push_int(0); |
} |
} |
|
/*! @decl void _decode(array(string)|int(0..0) encoded) |
*/ |
PIKEFUN void _decode(array(string)|int(0..0) encoded_) |
{ |
INT32 i = 0; |
if (TYPEOF(*encoded_) == PIKE_T_ARRAY) { |
struct array *encoded = encoded_->u.array; |
|
for (i=0; i < encoded->size; i++) { |
push_svalue(encoded->item + i); |
stack_swap(); |
} |
} |
pop_stack(); |
|
f_single_string_replace_create(i); |
} |
} |
|
/*! @endclass |
*/ |
|
/*! @class Bootstring |
*! |
*! This class implements the "Bootstring" string transcoder described in |
*! @url{ftp://ftp.rfc-editor.org/in-notes/rfc3492.txt@}. |
*/ |
PIKECLASS bootstring |
{ |
CVAR INT_TYPE base, tmin, tmax, skew, damp; |
CVAR INT_TYPE initial_bias, initial_n; |
CVAR p_wchar2 delim; |
PIKEVAR string digits flags ID_PROTECTED|ID_PRIVATE; |
|
static INT_TYPE bootstring_cp_to_digit(p_wchar2 ch) |
{ |
ptrdiff_t digit = THIS->digits->len; |
PCHARP digits = MKPCHARP_STR( THIS->digits ); |
while (digit>=0) |
if (INDEX_PCHARP( digits, digit ) == ch) |
return digit; |
else |
--digit; |
return -1; |
} |
|
static INT_TYPE bootstring_adapt(INT_TYPE delta, INT_TYPE numpoints, |
int firsttime) |
{ |
struct bootstring_struct *bs = THIS; |
INT_TYPE k = 0, b = bs->base; |
INT_TYPE a = b - bs->tmin; |
INT_TYPE limit = (a * bs->tmax) >> 1; |
if (firsttime) |
delta /= bs->damp; |
else |
delta >>= 1; |
delta += delta / numpoints; |
while (delta > limit) { |
delta /= a; |
k += b; |
} |
return k + (a + 1)*delta / (delta + bs->skew); |
} |
|
/*! @decl string decode(string s) |
*! |
*! Decodes a Bootstring encoded string of "basic" code points back |
*! to the original string space. |
*/ |
PIKEFUN string decode(string s) |
{ |
struct bootstring_struct *bs = THIS; |
INT_TYPE n = bs->initial_n; |
INT_TYPE i = 0; |
INT_TYPE bias = bs->initial_bias; |
ptrdiff_t pos, input_left; |
PCHARP input; |
struct string_builder output; |
init_string_builder( &output,0 ); |
input = MKPCHARP_STR( s ); |
input_left = s->len; |
for (pos = input_left-1; pos > 0; --pos) |
if (INDEX_PCHARP( input, pos ) == bs->delim) { |
string_builder_append( &output, input, pos ); |
INC_PCHARP( input, pos+1 ); |
input_left -= pos+1; |
break; |
} |
|
while (input_left > 0) { |
INT_TYPE oldi = i; |
INT_TYPE w = 1; |
INT_TYPE k; |
for (k=bs->base; ; k+=bs->base) { |
INT_TYPE digit, t; |
if (input_left < 1 || |
(digit = bootstring_cp_to_digit( EXTRACT_PCHARP( input ) )) < 0) { |
free_string_builder( &output ); |
Pike_error( "Invalid variable-length integer.\n" ); |
} |
INC_PCHARP( input, 1 ); |
--input_left; |
i += digit * w; /* fail on overflow... */ |
if (k <= bias + bs->tmin) |
t = bs->tmin; |
else if (k >= bias + bs->tmax) |
t = bs->tmax; |
else |
t = k - bias; |
if (digit < t) break; |
w *= (bs->base - t); |
} |
bias = bootstring_adapt( i - oldi, output.s->len+1, !oldi ); |
n += i / (output.s->len+1); |
i %= output.s->len+1; |
string_builder_putchar( &output, n ); |
if (i != output.s->len-1) |
switch (output.s->size_shift) { |
case 0: |
{ |
p_wchar0 *s = STR0(output.s); |
INT_TYPE p = output.s->len; |
while (--p>i) |
s[p] = s[p-1]; |
s[p] = DO_NOT_WARN ((p_wchar0) n); |
} |
break; |
case 1: |
{ |
p_wchar1 *s = STR1(output.s); |
INT_TYPE p = output.s->len; |
while (--p>i) |
s[p] = s[p-1]; |
s[p] = DO_NOT_WARN ((p_wchar1) n); |
} |
break; |
case 2: |
{ |
p_wchar2 *s = STR2(output.s); |
INT_TYPE p = output.s->len; |
while (--p>i) |
s[p] = s[p-1]; |
s[p] = DO_NOT_WARN ((p_wchar2) n); |
} |
break; |
#ifdef PIKE_DEBUG |
default: |
Pike_fatal("Illegal shift size!\n"); |
#endif |
} |
i++; |
} |
|
RETURN finish_string_builder( &output ); |
} |
|
/*! @decl string encode(string s) |
*! |
*! Encodes a string using Bootstring encoding into a string constisting |
*! only of "basic" code points (< initial_n). |
*/ |
PIKEFUN string encode(string s) |
{ |
struct bootstring_struct *bs = THIS; |
INT_TYPE n = bs->initial_n; |
INT_TYPE delta = 0; |
INT_TYPE bias = bs->initial_bias; |
INT_TYPE c, h, b = 0; |
ptrdiff_t pos, input_left; |
PCHARP input; |
struct string_builder output; |
init_string_builder( &output,0 ); |
input = MKPCHARP_STR( s ); |
input_left = s->len; |
for (pos=0; pos<input_left; pos++) |
if ((c = INDEX_PCHARP( input, pos )) < n) { |
string_builder_putchar( &output, c ); |
b++; |
} |
if ((h = b)) |
string_builder_putchar( &output, bs->delim ); |
while (h < input_left) { |
INT_TYPE m = -1; |
for (pos=0; pos<input_left; pos++) |
if ((c = INDEX_PCHARP( input, pos )) >= n && |
(m < 0 || c < m)) |
m = c; |
delta = delta + (m - n) * (h + 1); /* fail on overflow... */ |
n = m; |
for (pos=0; pos<input_left; pos++) |
if ((c = INDEX_PCHARP( input, pos )) < n) |
delta++; |
else if (c == n) { |
INT_TYPE k, q = delta; |
for (k=bs->base; ; k+=bs->base) { |
INT_TYPE t, bt; |
if (k <= bias + bs->tmin) |
t = bs->tmin; |
else if(k >= bias + bs->tmax) |
t = bs->tmax; |
else |
t = k-bias; |
if (q < t) |
break; |
bt = bs->base - t; |
string_builder_putchar( &output, |
index_shared_string( bs->digits, |
t + (q-t)%bt ) ); |
q = (q-t) / bt; |
} |
string_builder_putchar( &output, |
index_shared_string( bs->digits, q ) ); |
bias = bootstring_adapt( delta, h+1, h==b ); |
delta = 0; |
h++; |
} |
delta++; |
n++; |
} |
|
RETURN finish_string_builder( &output ); |
} |
|
/*! @decl void create(int base, int tmin, int tmax, int skew, @ |
*! int damp, int initial_bias, int initial_n, @ |
*! int delim, string digits) |
*! |
*! Creates a Bootstring transcoder instance using the specified parameters. |
*! |
*! @param base |
*! The base used by the variable-length integers. |
*! @param tmin |
*! The minimum threshold digit value for the variable-length integers. |
*! Must be >=0 and <= tmax. |
*! @param tmax |
*! The maximum threshold digit value for the variable-length integers. |
*! Must be <= base-1. |
*! @param skew |
*! The skew term for the bias adapation. Must be >= 1. |
*! @param damp |
*! The damping factor for the bias adaption. Must be >= 2. |
*! @param initial_bias |
*! The initial bias for the variable-length integer thresholding. |
*! initial_bias % base must be <= base - tmin. |
*! @param initial_n |
*! The first code point outside the "basic" set of code points. |
*! @param delim |
*! The "basic" code point used as the delimiter. |
*! @param digits |
*! The "basic" code points used as digits. The length of the string |
*! should be the same as the base parameter. |
*/ |
PIKEFUN void create( int base, int tmin, int tmax, |
int skew, int damp, |
int initial_bias, int initial_n, |
int delim, string digits ) |
flags ID_PROTECTED; |
{ |
struct bootstring_struct *bs = THIS; |
if (base<2) |
Pike_error("Bogus base\n"); |
if (tmin<0 || tmax<tmin || base-1<tmax) |
Pike_error("Parameters violate 0 <= tmin <= tmax <= base-1\n"); |
if (skew < 1) |
Pike_error("Parameters violate skew >= 1\n"); |
if (damp < 2) |
Pike_error("Parameters violate damp >= 2\n"); |
if (initial_bias%base > base-tmin) |
Pike_error("Parameters violate initial_bias%%base <= base-tmin\n"); |
if (digits->len != base) |
Pike_error("Length of digits string does not match base.\n"); |
bs->base = base; bs->tmin = tmin; bs->tmax = tmax; |
bs->skew = skew; bs->damp = damp; |
bs->initial_bias = initial_bias; bs->initial_n = initial_n; |
bs->delim = delim; |
if (bs->digits) { |
free_string( bs->digits ); |
bs->digits = NULL; |
} |
copy_shared_string( bs->digits, digits ); |
} |
|
} |
|
/*! @endclass |
*/ |
|
/*! @endmodule |
*/ |
|
/*! @module System |
*/ |
|
/*! @class Time |
*! |
*! The current time as a structure containing a sec and a usec |
*! member. |
*/ |
PIKECLASS Time |
{ |
CVAR int hard_update; |
|
/*! @decl int sec |
*! @decl int usec |
*! |
*! The number of seconds and microseconds since the epoch and the |
*! last whole second, respectively. (See also @[predef::time()]) |
*! |
*! @note |
*! Please note that these variables will continually update when |
*! they are requested, there is no need to create new Time() |
*! objects. |
*/ |
|
PIKEFUN int `sec() |
{ |
struct timeval now; |
|
if( THIS->hard_update ) |
ACCURATE_GETTIMEOFDAY( &now ); |
else |
INACCURATE_GETTIMEOFDAY( &now ); |
|
RETURN now.tv_sec; |
} |
|
PIKEFUN int `usec() |
{ |
struct timeval now; |
|
if( THIS->hard_update ) |
ACCURATE_GETTIMEOFDAY( &now ); |
else |
INACCURATE_GETTIMEOFDAY( &now ); |
|
RETURN now.tv_usec; |
} |
|
/*! @decl int usec_full |
*! |
*! The number of microseconds since the epoch. Please note that |
*! pike needs to have been compiled with bignum support for this |
*! variable to contain sensible values. |
*/ |
|
PIKEFUN int `usec_full() |
{ |
struct timeval now; |
|
if( THIS->hard_update ) |
ACCURATE_GETTIMEOFDAY( &now ); |
else |
INACCURATE_GETTIMEOFDAY( &now ); |
|
push_int( now.tv_sec ); |
push_int( 1000000 ); |
f_multiply( 2 ); |
push_int( now.tv_usec ); |
f_add( 2 ); |
return; |
} |
|
/*! @decl protected void create( int fast ); |
*! |
*! If @[fast] is true, do not request a new time from the system, |
*! instead use the global current time variable. |
*! |
*! This will only work in callbacks, but can save significant amounts |
*! of CPU. |
*/ |
PIKEFUN void create( int|zero|void fast ) |
flags ID_PROTECTED; |
{ |
THIS->hard_update = !fast; |
} |
} |
|
/*! @endclass |
*/ |
|
/*! @class Timer |
*/ |
PIKECLASS Timer |
{ |
CVAR struct timeval last_time; |
CVAR int hard_update; |
|
/*! @decl float peek() |
*! Return the time in seconds since the last time @[get] was called. |
*/ |
PIKEFUN float peek( ) |
{ |
struct timeval now; |
FLOAT_TYPE res; |
if( THIS->hard_update ) |
ACCURATE_GETTIMEOFDAY( &now ); |
else |
INACCURATE_GETTIMEOFDAY( &now ); |
res = now.tv_sec-THIS->last_time.tv_sec + |
(now.tv_usec-THIS->last_time.tv_usec)/(FLOAT_TYPE) 1000000.0; |
RETURN res; |
} |
|
/*! @decl float get() |
*! Return the time in seconds since the last time get was called. |
*! The first time this method is called the time since the object |
*! was created is returned instead. |
*/ |
PIKEFUN float get( ) |
{ |
f_Timer_peek( 0 ); |
INACCURATE_GETTIMEOFDAY(&THIS->last_time); |
return; |
} |
|
/*! @decl protected void create( int|void fast ) |
*! Create a new timer object. The timer keeps track of relative time |
*! with sub-second precision. |
*! |
*! If @[fast] is specified, the timer will not do system calls to get |
*! the current time but instead use the one maintained by pike. This |
*! will result in faster but more or less inexact timekeeping. |
*! The pike maintained time is only updated when a @[Pike.Backend] |
*! object stops waiting and starts executing code. |
*/ |
PIKEFUN void create( int|zero|void fast ) |
flags ID_PROTECTED; |
{ |
THIS->hard_update = !fast; |
if( THIS->hard_update ) |
ACCURATE_GETTIMEOFDAY( &THIS->last_time ); |
else |
INACCURATE_GETTIMEOFDAY( &THIS->last_time ); |
} |
} |
|
/*! @endclass |
*/ |
|
/*! @endmodule |
*/ |
|
|
PIKECLASS automap_marker |
{ |
PIKEVAR array arg; |
PIKEVAR int depth; |
|
PIKEFUN void create(array a, int d) |
{ |
if(THIS->arg) free_array(THIS->arg); |
add_ref(THIS->arg=a); |
THIS->depth=d; |
} |
|
PIKEFUN string _sprintf(int mode, mapping flags) |
{ |
pop_n_elems(args); |
if (mode != 'O') { |
push_undefined (); |
return; |
} |
push_text("%O%*'[*]'n"); |
if(THIS->arg) |
ref_push_array(THIS->arg); |
else |
push_int(0); |
push_int(THIS->depth*3); |
f_sprintf(3); |
} |
} |
|
|
static void low_automap(int d, |
int depth, |
struct svalue *fun, |
struct svalue *real_args, |
INT32 args) |
{ |
INT32 x,e,tmp,size=0x7fffffff; |
struct svalue *tmpargs=Pike_sp - args; |
struct array *ret; |
TYPE_FIELD types; |
|
for(e=0;e<args;e++) |
{ |
if(TYPEOF(real_args[e]) == T_OBJECT && |
real_args[e].u.object->prog == automap_marker_program && |
OBJ2_AUTOMAP_MARKER(real_args[e].u.object)->depth >= d) |
{ |
if(TYPEOF(tmpargs[e]) != T_ARRAY) |
index_error("__automap__", |
Pike_sp-args, |
args, |
tmpargs, |
NULL, |
"Automap on non-array.\n"); |
tmp=tmpargs[e].u.array->size; |
if(tmp < size) |
size=tmp; |
} |
} |
|
#ifdef PIKE_DEBUG |
if(size == 0x7fffffff) |
Pike_fatal("No automap markers found in low_automap\n"); |
#endif |
|
push_array(ret=allocate_array(size)); |
types = 0; |
|
for(x=0;x<size;x++) |
{ |
for(e=0;e<args;e++) |
{ |
if(TYPEOF(real_args[e]) == T_OBJECT && |
real_args[e].u.object->prog == automap_marker_program && |
OBJ2_AUTOMAP_MARKER(real_args[e].u.object)->depth >= d) |
{ |
#ifdef PIKE_DEBUG |
if(x >= tmpargs[e].u.array->size) |
Pike_fatal("low_automap failed to determine size!\n"); |
#endif |
push_svalue(ITEM(tmpargs[e].u.array)+x); |
}else{ |
push_svalue(tmpargs+e); |
} |
} |
|
if(d == depth) |
apply_svalue(fun,args); |
else |
low_automap(d+1,depth,fun,real_args,args); |
stack_pop_to_no_free (ITEM(ret) + x); |
types |= 1 << TYPEOF(ITEM(ret)[x]); |
} |
ret->type_field = types; |
stack_unlink(args); |
} |
|
|
PIKEFUN array __automap__(mixed fun, mixed ... tmpargs) |
efun; |
{ |
int e,depth=-1; |
check_stack(args); |
|
for(e=0;e<args-1;e++) |
{ |
if(TYPEOF(tmpargs[e]) == T_OBJECT && |
tmpargs[e].u.object->prog == automap_marker_program) |
{ |
int tmp=OBJ2_AUTOMAP_MARKER(tmpargs[e].u.object)->depth; |
if(tmp > depth) depth=tmp; |
ref_push_array(OBJ2_AUTOMAP_MARKER(tmpargs[e].u.object)->arg); |
}else{ |
push_svalue(tmpargs+e); |
} |
} |
check_stack(depth * (args+1)); |
low_automap(1,depth,fun,tmpargs,args-1); |
stack_unlink(args); |
} |
|
/* Linked list stuff. |
*/ |
static struct block_allocator pike_list_node_allocator = BA_INIT_PAGES(sizeof(struct pike_list_node), 4); |
|
ATTRIBUTE((malloc)) |
static struct pike_list_node * alloc_pike_list_node() { |
struct pike_list_node * node = ba_alloc(&pike_list_node_allocator); |
node->next = node->prev = NULL; |
node->refs = 1; |
SET_SVAL(node->val, T_INT, NUMBER_UNDEFINED, integer, 0); |
return node; |
} |
|
void count_memory_in_pike_list_nodes(size_t * n, size_t * s) { |
ba_count_all(&pike_list_node_allocator, n, s); |
} |
|
void free_all_pike_list_node_blocks() { |
ba_destroy(&pike_list_node_allocator); |
} |
|
PMOD_EXPORT void free_list_node(struct pike_list_node *node) |
{ |
if (!sub_ref(node)) { |
if (node->prev) { |
free_list_node(node->prev); |
} |
if (node->next) { |
free_list_node(node->next); |
} |
free_svalue(&node->val); |
ba_free(&pike_list_node_allocator, node); |
} |
} |
|
PMOD_EXPORT void unlink_list_node(struct pike_list_node *n) |
{ |
#ifdef PIKE_DEBUG |
if (!n) { |
Pike_fatal("Unlinking NULL node.\n"); |
} |
if (!n->next || !n->prev) { |
Pike_fatal("Unlinking unlinked node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
if (n->prev->next == n) { |
#ifdef PIKE_DEBUG |
if (n->next->prev != n) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
n->prev->next = n->next; |
n->next->prev = n->prev; |
n->next = n->prev = NULL; |
|
/* We've lost two references. */ |
free_list_node(n); |
free_list_node(n); |
} else { |
#ifdef PIKE_DEBUG |
if (n->next->prev == n) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
/* The node is already detached. */ |
n->next = n->prev = NULL; |
} |
} |
|
PMOD_EXPORT void detach_list_node(struct pike_list_node *n) |
{ |
#ifdef PIKE_DEBUG |
if (!n) { |
Pike_fatal("Detaching NULL node.\n"); |
} |
if (!n->next || !n->prev) { |
Pike_fatal("Detaching unlinked node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
if (n->prev->next == n) { |
#ifdef PIKE_DEBUG |
if (n->next->prev != n) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
n->prev->next = n->next; |
n->next->prev = n->prev; |
add_ref(n->next); |
add_ref(n->prev); |
|
/* We've lost two references. */ |
free_list_node(n); |
free_list_node(n); |
#ifdef PIKE_DEBUG |
} else if (n->next->prev == n) { |
Pike_fatal("Partially detached node.\n"); |
#endif /* PIKE_DEBUG */ |
} |
} |
|
PMOD_EXPORT void prepend_list_node(struct pike_list_node *node, |
struct pike_list_node *new_node) |
{ |
#ifdef PIKE_DEBUG |
if (!node) { |
Pike_fatal("No node to prepend.\n"); |
} |
if (!node->prev) { |
Pike_fatal("Prepending unhooked node.\n"); |
} |
if (!new_node) { |
Pike_fatal("Prepending NULL node.\n"); |
} |
if (new_node->next || new_node->prev) { |
Pike_fatal("Prepending hooked node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
new_node->next = node; |
new_node->prev = node->prev; |
new_node->prev->next = node->prev = new_node; |
add_ref(new_node); |
add_ref(new_node); |
} |
|
PMOD_EXPORT void append_list_node(struct pike_list_node *node, |
struct pike_list_node *new_node) |
{ |
#ifdef PIKE_DEBUG |
if (!node) { |
Pike_fatal("No node to append.\n"); |
} |
if (!node->next) { |
Pike_fatal("Appending unhooked node.\n"); |
} |
if (!new_node) { |
Pike_fatal("Appending NULL node.\n"); |
} |
if (new_node->next || new_node->prev) { |
Pike_fatal("Appending hooked node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
new_node->next = node->next; |
new_node->prev = node; |
new_node->next->prev = node->next = new_node; |
add_ref(new_node); |
add_ref(new_node); |
} |
|
/*! @module Builtin |
*/ |
|
/*! @class Setter |
*! |
*! Internal class for implementing setters. |
*/ |
PIKECLASS Setter |
{ |
PIKEVAR object o |
flags ID_PROTECTED|ID_PRIVATE|ID_LOCAL; |
CVAR int f; |
PIKEFUN void `()(mixed val) |
flags ID_PROTECTED; |
{ |
if (!THIS->o) { |
Pike_error("Uninitialized Setter!\n"); |
} |
object_low_set_index(THIS->o, THIS->f, Pike_sp-1); |
pop_n_elems(args); |
push_int(0); |
} |
PIKEFUN string _sprintf(int c, mapping|void opts) |
flags ID_PROTECTED; |
{ |
struct program *prog; |
if (!THIS->o) { |
push_constant_text("Setter()"); |
} else if ((prog = THIS->o->prog)) { |
push_constant_text("%O->`%s="); |
ref_push_object(THIS->o); |
ref_push_string(ID_FROM_INT(prog, THIS->f)->name); |
f_sprintf(3); |
} else { |
push_constant_text("Setter(destructed object)"); |
} |
stack_pop_n_elems_keep_top(args); |
} |
} |
|
PMOD_EXPORT struct object *get_setter(struct object *o, int f) |
{ |
struct object *res = clone_object(Setter_program, 0); |
struct Setter_struct *setter = OBJ2_SETTER(res); |
add_ref(setter->o = o); |
setter->f = f; |
return res; |
} |
|
/*! @decl function(mixed_void) _get_setter(object o, string s) |
*! |
*! Get a setter for the variable named @[s] in object @[o]. |
*! |
*! @seealso |
*! @[object_variablep()] |
*/ |
PIKEFUN function(mixed:void) _get_setter(object o, string s) |
{ |
struct program *p; |
struct inherit *inh; |
int f; |
if (!(p = o->prog)) { |
Pike_error("Indexing a destructed object.\n"); |
} |
inh = p->inherits + SUBTYPEOF(Pike_sp[-args]); |
p = inh->prog; |
f = find_shared_string_identifier(s, p); |
if ((f >= 0) && |
IDENTIFIER_IS_VARIABLE(ID_FROM_INT(p, f)->identifier_flags)) { |
f += inh->identifier_level; |
push_function(get_setter(o, f), f_Setter_cq__backtick_28_29_fun_num); |
} else { |
push_undefined(); |
} |
stack_pop_n_elems_keep_top(args); |
} |
|
/*! @endclass |
*/ |
|
/*! @class Null |
*! |
*! This class is used to implement the low-level aspects of @[Val.Null]. |
*! |
*! @note |
*! This class should typically not be used directly. Use |
*! @[Val.Null] instead. |
*! |
*! @note |
*! This class was previously available as @[Sql.Null]. Any such use |
*! should be replaced with @[Val.Null]. |
*! |
*! @deprecated Val.Null |
*! |
*! @seealso |
*! @[Val.Null], @[Val.null] |
*/ |
PIKECLASS Null |
{ |
EXTRA { |
/*! @decl constant is_val_null = 1 |
*! |
*! Nonzero recognition constant. |
*/ |
add_integer_constant("is_val_null", 1, 0); |
|
/*! @decl constant is_sql_null = 1 |
*! |
*! SQL Null marker. |
*! |
*! @deprecated is_val_null |
*/ |
add_integer_constant("is_sql_null", 1, 0); |
} |
|
PIKEFUN int `!() |
flags ID_PROTECTED; |
{ |
RETURN 1; |
} |
|
PIKEFUN string _sprintf(int fmt, mixed ... extras) |
flags ID_PROTECTED; |
{ |
pop_n_elems(args); |
if (fmt == 'O') { |
push_constant_text("Val.null"); |
} else { |
push_undefined(); |
} |
} |
|
PIKEFUN int __hash() |
flags ID_PROTECTED; |
{ |
pop_n_elems(args); |
push_int(17); |
} |
|
PIKEFUN int `==(mixed other) |
flags ID_PROTECTED; |
{ |
if (TYPEOF(*other) != T_OBJECT) { |
pop_stack(); |
push_int(0); |
return; |
} |
|
/* Look for the is_val_null constant directly in the program of |
* other, without going through its `[]. When this is called in a |
* codec, other can be a completely arbitrary object which may not |
* have a `[] that works in that context. */ |
push_int (0); |
ref_push_program (other->u.object->prog); |
push_constant_text("is_val_null"); |
if (program_index_no_free (Pike_sp - 3, Pike_sp - 2, Pike_sp - 1) && |
TYPEOF(Pike_sp[-3]) == T_INT && Pike_sp[-3].u.integer) { |
pop_n_elems (4); |
push_int (1); |
} |
else { |
pop_n_elems (4); |
push_int (0); |
} |
} |
|
/*! @decl string encode_json() |
*! |
*! Defined for use with @[Standards.JSON.encode], so that it |
*! formats NULL as @expr{null@}. |
*/ |
PIKEFUN string encode_json(...) |
{ |
push_constant_text ("null"); |
} |
} |
|
/*! @endclass |
*/ |
|
PMOD_EXPORT |
PIKEFUN int levenshtein_distance(string a, string b) |
{ |
int i, j, n, *lev_i, *lev_p; |
|
/* Simple cases: strings are equal or one of them is empty: */ |
if (a == b) RETURN 0; |
if (a->len == 0) RETURN b->len; |
if (b->len == 0) RETURN a->len; |
|
/* Return -1 if any of the strings is wider than 8 bits: */ |
if (a->size_shift || b->size_shift) RETURN -1; |
|
/* Allocate two rows on the stack: */ |
n = b->len+1; |
lev_i = alloca(n*sizeof(int)); |
lev_p = alloca(n*sizeof(int)); |
if (!lev_i || !lev_p) RETURN -1; |
|
/* Initialise the first row */ |
for (j = 0; j < n; j++) lev_i[j] = j; |
|
for (i = 0; i < a->len; i++) |
{ |
/* lev_p = row for i, lev_i = row for i+1: */ |
memcpy(lev_p, lev_i, n*sizeof(int)); |
lev_i[0] = i + 1; |
for (j = 0; j < b->len; j++) |
{ |
int cost = (a->str[i] == b->str[j]) ? 0 : 1; |
int test, min_val = lev_i[j]+1; |
if ((test = lev_p[j+1]+1) < min_val) min_val = test; |
if ((test = lev_p[j]+cost) < min_val) min_val = test; |
lev_i[j+1] = min_val; |
} |
} |
RETURN lev_i[b->len]; |
} |
|
/*! @endmodule |
*/ |
|
/*! @module Serializer |
*/ |
|
/*! @class Serializable |
*! |
*! The base class for serializable objects. |
*! |
*! Inherit this class in classes that need to be serializable. |
*! |
*! @seealso |
*! @[Serializer.serialize()], @[Serializer.deserialize()] |
*/ |
PIKECLASS Serializable |
{ |
/* Loop over all variables, and call fun_num in the current object. */ |
static void low_serialize(int i, struct svalue *fun, |
int use_setter, int fun_num) |
{ |
struct inherit *inh; |
struct program *p = Pike_fp->current_object->prog; |
struct svalue *save_sp = Pike_sp; |
|
inh = p->inherits + i; |
p = inh->prog; |
|
for (i = 0; i < p->num_identifier_references; i++) { |
struct reference *ref = PTR_FROM_INT(p, i); |
struct identifier *id; |
if ((ref->id_flags & ID_HIDDEN) || |
((ref->id_flags & (ID_PRIVATE|ID_INHERITED)) == |
(ID_PRIVATE|ID_INHERITED))) { |
continue; |
} |
id = ID_FROM_PTR(p, ref); |
if (!IDENTIFIER_IS_VARIABLE(id->identifier_flags)) { |
continue; |
} |
push_svalue(fun); |
if (use_setter) { |
push_function(get_setter(Pike_fp->current_object, |
i + inh->identifier_level), |
f_Setter_cq__backtick_28_29_fun_num); |
} else { |
low_object_index_no_free(Pike_sp, Pike_fp->current_object, |
i + inh->identifier_level); |
Pike_sp++; |
} |
ref_push_string(id->name); |
ref_push_type_value(id->type); |
apply_current(fun_num, 4); |
pop_stack(); |
} |
if (Pike_sp != save_sp) { |
/* Not likely, but... */ |
pop_n_elems(Pike_sp - save_sp); |
} |
} |
|
/*! @decl protected void _serialize_variable( @ |
*! function(mixed, string, type:void) serializer, @ |
*! mixed value, @ |
*! string symbol, @ |
*! type symbol_type) |
*! |
*! Default serialization function for variables. |
*! |
*! @param serializer |
*! Function to be called in turn. |
*! |
*! @param value |
*! Value of the variable. |
*! |
*! @param symbol |
*! Variable name. |
*! |
*! @param symbol_type |
*! Type of the variable. |
*! |
*! This function is typically called from @[_serialize()], and just does |
*! @code |
*! serializer(value, symbol, symbol_type); |
*! @endcode |
*! |
*! It is provided for overloading for eg filtering or validation purposes. |
*! |
*! @seealso |
*! @[_serialize()], @[_deserialize_variable()] |
*/ |
PIKEFUN void _serialize_variable(function(mixed, string, type:void) |
serializer, mixed value, |
string symbol, type symbol_type) |
flags ID_PROTECTED; |
rawtype tFunc(tFunc(tMix tStr tType(tMix), tVoid) |
tMix tStr tType(tMix), tVoid); |
{ |
f_call_function(args); |
pop_stack(); |
push_int(0); |
} |
|
/*! @decl protected void _serialize(object o, @ |
*! function(mixed, string, type:void) serializer) |
*! |
*! Dispatch function for serialization. |
*! |
*! @param o |
*! Object to serialize. Always a context of the current object. |
*! |
*! @param serializer |
*! Function to typically be called once for every variable |
*! in the inheriting class. |
*! |
*! This function calls @[_serialize_variable()] once |
*! for every variable in the inheriting class. |
*! |
*! @note |
*! The symbols will be listed in the order they were defined |
*! in the class. |
*! |
*! @note |
*! This function is typically called via @[Serializer.serialize()]. |
*/ |
PIKEFUN void _serialize(object o, |
function(mixed, string, type:void) serializer) |
flags ID_PROTECTED; |
rawtype tFunc(tObj tFunc(tMix tStr tType(tMix), tVoid), tVoid); |
{ |
if (o != Pike_fp->current_object) { |
SIMPLE_BAD_ARG_ERROR("_serialize", 1, "this"); |
} |
low_serialize(SUBTYPEOF(Pike_sp[-args]), serializer, 0, |
f_Serializable_cq__serialize_variable_fun_num); |
pop_n_elems(args); |
push_int(0); |
} |
|
static void *find_program_from_object_type_cb(struct pike_type *t) |
{ |
struct program *p; |
if ((t->type != PIKE_T_OBJECT) || !t->cdr) return NULL; |
p = id_to_program(CDR_TO_INT(t)); |
if (!p || (p->flags & PROGRAM_NEEDS_PARENT) || |
(low_find_lfun(p, LFUN__DESERIALIZE) == -1)) return NULL; |
return p; |
} |
|
DEFAULT_CMOD_STORAGE void f_deserialize(INT32 args); |
|
/*! @decl protected void _deserialize_variable( @ |
*! function(function(mixed:void), @ |
*! string, type: void) deserializer, @ |
*! function(mixed:void) setter, @ |
*! string symbol, @ |
*! type symbol_type) |
*! |
*! Default deserialization function for variables. |
*! |
*! @param deserializer |
*! Function to be called in turn. |
*! |
*! @param setter |
*! Function that sets the value of the variable. |
*! |
*! @param symbol |
*! Variable name. |
*! |
*! @param symbol_type |
*! Type of the variable. |
*! |
*! This function is typically called from @[_deserialize()], and does |
*! something like: |
*! @code |
*! if (object_typep(symbol_type)) { |
*! program p = program_from_type(symbol_type); |
*! if (p && !needs_parent(p) && is_deserializable(p)) { |
*! object value = p(); |
*! setter(value); |
*! Serializer.deserialize(value, deserializer); |
*! return; |
*! } |
*! } |
*! deserializer(setter, symbol, symbol_type); |
*! @endcode |
*! |
*! @note |
*! The above takes care of the most common cases, but |
*! @ul |
*! @item |
*! Does not support anonymous object types. |
*! @item |
*! Does not support objects needing a parent. |
*! @item |
*! Does not support non-serializable objects. |
*! @item |
*! Selects one of the object types in case of a complex |
*! @[symbol_type]. The selected type is NOT deterministic |
*! in case there are multiple choices that satisfy the above. |
*! @item |
*! Is likely to throw errors if @tt{p()@} requires arguments. |
*! @endul |
*! |
*! These issues can all be solved by overloading this function. |
*! |
*! @seealso |
*! @[_deserialize()], @[_serialize_variable()] |
*/ |
PIKEFUN void _deserialize_variable(function(function(mixed:void), |
string, type: void) |
deserializer, function(mixed:void) setter, |
string symbol, |
type symbol_type) |
flags ID_PROTECTED; |
rawtype tFunc(tFunc(tFunc(tMix, tVoid) tStr tType(tMix), tVoid) |
tFunc(tMix, tVoid) tStr tType(tMix), tVoid); |
{ |
struct program *p = find_type(symbol_type, |
find_program_from_object_type_cb); |
if (p) { |
struct object *o = clone_object(p, 0); |
push_object(o); /* Protection against errors and arg to deserialize. */ |
ref_push_object(o); |
apply_svalue(setter, 1); |
pop_stack(); |
push_svalue(deserializer); |
f_deserialize(2); |
return; |
} |
f_call_function(args); |
pop_stack(); |
push_int(0); |
} |
|
/*! @decl protected void _deserialize(object o, @ |
*! function(function(mixed:void), @ |
*! string, type: void) deserializer) |
*! |
*! Dispatch function for deserialization. |
*! |
*! @param o |
*! Object to serialize. Always a context of the current object. |
*! |
*! @param deserializer |
*! Function to typically be called once for every variable |
*! in the inheriting class. |
*! |
*! This function calls @[_deserialize_variable()] once |
*! for every variable in the inheriting class. |
*! |
*! @note |
*! The symbols will be listed in the order they were defined |
*! in the class. |
*! |
*! @note |
*! This function is typically called via @[Serializer.deserialize()]. |
*/ |
PIKEFUN void _deserialize(object o, |
function(function(mixed:void), |
string, type: void) deserializer) |
flags ID_PROTECTED; |
rawtype tFunc(tObj tFunc(tFunc(tMix, tVoid) tStr tType(tMix), tVoid), tVoid); |
{ |
if (o != Pike_fp->current_object) { |
SIMPLE_BAD_ARG_ERROR("_serialize", 1, "this"); |
} |
low_serialize(SUBTYPEOF(Pike_sp[-args]), deserializer, 1, |
f_Serializable_cq__deserialize_variable_fun_num); |
pop_n_elems(args); |
push_int(0); |
} |
} |
/*! @endclass |
*/ |
|
/*! @decl void serialize(object o, @ |
*! function(mixed, string, type:void) serializer) |
*! |
*! Call @[lfun::_serialize()] in @[o]. |
*! |
*! @seealso |
*! @[deserialize()], @[lfun::_serialize()], |
*! @[Serializable()->_serialize()] |
*/ |
PIKEFUN void serialize(object o, |
function(mixed, string, type:void) serializer) |
rawtype tFunc(tObj tFunc(tMix tStr tType(tMix), tVoid), tVoid); |
{ |
struct inherit *inh; |
struct program *p; |
ptrdiff_t fun; |
if (!(p = o->prog)) { |
Pike_error("Indexing a destructed object.\n"); |
} |
inh = p->inherits + SUBTYPEOF(Pike_sp[-args]); |
p = inh->prog; |
if ((fun = low_find_lfun(p, LFUN__SERIALIZE)) == -1) { |
Pike_error("Serialization not supported by object.\n"); |
} |
apply_low(o, fun + inh->identifier_level, args); |
} |
|
/*! @decl void deserialize(object o, @ |
*! function(function(mixed:void), @ |
*! string, type: void) deserializer) |
*! |
*! Call @[lfun::_deserialize()] in @[o]. |
*! |
*! @seealso |
*! @[serialize()], @[lfun::_deserialize()], |
*! @[Serializable()->_deserialize()] |
*/ |
PIKEFUN void deserialize(object o, |
function(function(mixed:void), |
string, type:void) deserializer) |
rawtype tFunc(tObj tFunc(tFunc(tMix, tVoid) tStr tType(tMix), tVoid), tVoid); |
{ |
struct inherit *inh; |
struct program *p; |
ptrdiff_t fun; |
if (!(p = o->prog)) { |
Pike_error("Indexing a destructed object.\n"); |
} |
inh = p->inherits + SUBTYPEOF(Pike_sp[-args]); |
p = inh->prog; |
if ((fun = low_find_lfun(p, LFUN__DESERIALIZE)) == -1) { |
Pike_error("Deserialization not supported by object.\n"); |
} |
apply_low(o, fun + inh->identifier_level, args); |
} |
|
/*! @endmodule |
*/ |
|
/*! @module ADT |
*/ |
|
/*! @class List |
*! |
*! Linked list of values. |
*/ |
PIKECLASS List |
{ |
CVAR struct pike_list_node *head; |
CVAR INT32 head_sentinel_refs; |
CVAR struct pike_list_node *tail; /* Always NULL. */ |
CVAR INT32 tail_sentinel_refs; |
CVAR struct pike_list_node *tail_pred; |
CVAR INT32 num_elems; |
|
#define HEAD_SENTINEL(this) ((struct pike_list_node *)(&this->head)) |
#define TAIL_SENTINEL(this) ((struct pike_list_node *)(&this->tail)) |
|
/* Sentinel overlap description: |
* |
* List Head sentinel Tail sentinel |
* head next |
* head_sentinel_refs refs |
* tail prev next |
* tail_sentinel_refs refs |
* tail_pred prev |
*/ |
|
/* Suggestions for future functionality: |
* |
* o Pop tail |
* o Join |
* o Copy segment |
* o Detach segment (requires new iterator implementation) |
* o Iterator copy |
* o _equal() for iterators and lists. |
* o _values(), _search(), cast() |
* o _sizeof()?, _indices()?? |
* o Support for reverse(), filter() and map(). |
* o Initialization from array. |
* o Support for Pike.count_memory. |
*/ |
|
INIT |
{ |
THIS->tail = NULL; |
THIS->head = TAIL_SENTINEL(THIS); |
THIS->tail_pred = HEAD_SENTINEL(THIS); |
THIS->head_sentinel_refs = THIS->tail_sentinel_refs = 2; |
THIS->num_elems = 0; |
} |
|
EXIT |
gc_trivial; |
{ |
struct pike_list_node *node = THIS->head; |
struct pike_list_node *next; |
while ((next = node->next)) { |
#ifdef PIKE_DEBUG |
if (node->refs != 2) { |
Pike_fatal("Unexpected number of references for node: %d\n", |
node->refs); |
} |
#endif /* PIKE_DEBUG */ |
unlink_list_node(node); |
node = next; |
} |
} |
|
/* These two functions perform the same thing, |
* but are optimized to minimize recursion. |
*/ |
static void gc_check_list_node_backward(struct pike_list_node *node, |
const char *msg); |
static void gc_check_list_node_forward(struct pike_list_node *node, |
const char *msg) |
{ |
while (node && !debug_gc_check(&node->refs, msg)) { |
if (node->next) |
debug_gc_check_svalues(&node->val, 1, " as a list node value"); |
gc_check_list_node_backward(node->prev, msg); |
node = node->next; |
} |
} |
|
static void gc_check_list_node_backward(struct pike_list_node *node, |
const char *msg) |
{ |
while (node && !debug_gc_check(&node->refs, msg)) { |
if (node->prev) |
debug_gc_check_svalues(&node->val, 1, " as a list node value"); |
gc_check_list_node_forward(node->next, msg); |
node = node->prev; |
} |
} |
|
/* Called at gc_check time. */ |
GC_CHECK |
{ |
gc_check_list_node_backward(HEAD_SENTINEL(THIS), " as a list node"); |
gc_check_list_node_forward(TAIL_SENTINEL(THIS), " as a list node"); |
} |
|
/* Called at gc_mark time */ |
GC_RECURSE |
{ |
struct pike_list_node *node = THIS->head; |
struct pike_list_node *next; |
while ((next = node->next)) { |
gc_recurse_svalues(&node->val, 1); |
node = next; |
} |
/* FIXME: mc_count_bytes */ |
} |
|
/*! @decl int(0..1) is_empty() |
*! |
*! Check if the list is empty. |
*! |
*! @returns |
*! Returns @expr{1@} if the list is empty, |
*! and @expr{0@} (zero) if there are elements in the list. |
*/ |
PIKEFUN int(0..1) is_empty() |
{ |
push_int(!THIS->head->next); |
} |
|
/*! @decl protected int(0..) _sizeof() |
*! |
*! Returns the number of elements in the list. |
*/ |
PIKEFUN int(0..) _sizeof() |
flags ID_PROTECTED; |
{ |
push_int(THIS->num_elems); |
} |
|
/*! @decl protected string _sprintf(int c, mapping(string:mixed)|void attr) |
*! |
*! Describe the list. |
*! |
*! @seealso |
*! @[sprintf()], @[lfun::_sprintf()] |
*/ |
PIKEFUN string _sprintf(int c, mapping(string:mixed)|void attr) |
flags ID_PROTECTED; |
{ |
if (!THIS->num_elems) { |
push_constant_text("ADT.List(/* empty */)"); |
} else if (c == 'O') { |
struct pike_list_node *node = THIS->head; |
if (THIS->num_elems == 1) { |
push_constant_text("ADT.List(/* 1 element */\n"); |
} else { |
push_constant_text("ADT.List(/* %d elements */\n"); |
push_int(THIS->num_elems); |
f_sprintf(2); |
} |
while (node->next) { |
if (node->next->next) { |
push_constant_text(" %O,\n"); |
} else { |
push_constant_text(" %O\n"); |
} |
push_svalue(&node->val); |
f_sprintf(2); |
node = node->next; |
} |
push_constant_text(")"); |
f_add(THIS->num_elems + 2); |
} else { |
if (THIS->num_elems == 1) { |
push_constant_text("ADT.List(/* 1 element */)"); |
} else { |
push_constant_text("ADT.List(/* %d elements */)"); |
push_int(THIS->num_elems); |
f_sprintf(2); |
} |
} |
stack_pop_n_elems_keep_top(args); |
} |
|
/*! @decl mixed head() |
*! |
*! Get the element at the head of the list. |
*! |
*! @throws |
*! Throws an error if the list is empty. |
*! |
*! @seealso |
*! @[is_empty()], @[tail()], @[pop()] |
*/ |
PIKEFUN mixed head() |
{ |
if (THIS->head->next) { |
push_svalue(&THIS->head->val); |
} else { |
Pike_error("Empty list.\n"); |
} |
} |
|
/*! @decl mixed tail() |
*! |
*! Get the element at the tail of the list. |
*! |
*! @throws |
*! Throws an error if the list is empty. |
*! |
*! @seealso |
*! @[is_empty()], @[head()], @[pop_back()] |
*/ |
PIKEFUN mixed tail() |
{ |
struct pike_list_node * node = TAIL_SENTINEL(THIS); |
if (THIS->head->next) { |
push_svalue(&node->prev->val); |
} else { |
Pike_error("Empty list.\n"); |
} |
} |
|
static inline void pop_node(struct pike_list_node * node) { |
push_svalue(&node->val); |
if (node->refs == 2) { |
unlink_list_node(node); |
} else { |
detach_list_node(node); |
} |
THIS->num_elems--; |
} |
|
/*! @decl mixed pop() |
*! |
*! Pop the element at the head of the list from the list. |
*! |
*! @throws |
*! Throws an error if the list is empty. |
*! |
*! @seealso |
*! @[is_empty()], @[head()], @[tail()], @[pop_back()] |
*/ |
PIKEFUN mixed pop() |
{ |
if (THIS->head->next) { |
pop_node(THIS->head); |
} else { |
Pike_error("Empty list.\n"); |
} |
} |
|
/*! @decl mixed pop_back() |
*! |
*! Pop the element at the tail of the list from the list. |
*! |
*! @throws |
*! Throws an error if the list is empty. |
*! |
*! @seealso |
*! @[is_empty()], @[head()], @[tail()], @[pop()] |
*/ |
PIKEFUN mixed pop_back() |
{ |
const struct pike_list_node * node = TAIL_SENTINEL(THIS); |
if (THIS->head->next) { |
pop_node(node->prev); |
} else { |
Pike_error("Empty list.\n"); |
} |
} |
|
/*! @decl array _values() |
*! |
*! Returns an array of elements in the list. |
*/ |
PIKEFUN array _values() |
flags ID_PROTECTED; |
{ |
struct array * a; |
push_int(THIS->num_elems); |
f_allocate(1); |
|
a = Pike_sp[-1].u.array; |
if (THIS->num_elems) { |
struct pike_list_node *node = THIS->head; |
int i; |
for (i = 0; i < THIS->num_elems; i++) { |
assign_svalue_no_free(ITEM(a) + i, &node->val); |
node = node->next; |
} |
} |
} |
|
/*! @decl mixed cast(string type) |
*! |
*! Cast the lists. @expr{array@} and @expr{object@} are the only |
*! supported types. |
*/ |
PIKEFUN mixed cast(string type) |
flags ID_PROTECTED; |
{ |
if (type == MK_STRING("array")) { |
pop_n_elems(args); |
apply_current(f_List_cq__values_fun_num, 0); |
} else if (type == MK_STRING("object")) { |
pop_n_elems(args); |
ref_push_object(Pike_fp->current_object); |
} else { |
Pike_error("Cannot cast to %o.\n", Pike_sp-1); |
} |
} |
|
|
/*! @decl mixed `[](mixed key) */ |
PIKEFUN mixed `[](mixed key) |
flags ID_PROTECTED; |
{ |
struct pike_list_node *node; |
INT_TYPE n; |
if (TYPEOF(*key) != PIKE_T_INT) SIMPLE_BAD_ARG_ERROR("`[]", 1, "int"); |
|
n = key->u.integer; |
if (n < 0) n = -(n+1); |
|
if (n >= THIS->num_elems) Pike_error("out of bounds"); |
|
if (n >= THIS->num_elems >> 1) { /* use shorter direction */ |
n = THIS->num_elems - n - 1; |
key->u.integer = - key->u.integer - 1; |
} |
|
if (key->u.integer < 0) { |
node = TAIL_SENTINEL(THIS)->prev; |
while (n--) node = node->prev; |
} else { |
node = THIS->head; |
while (n--) node = node->next; |
} |
|
pop_n_elems(args); |
push_svalue(&node->val); |
} |
|
/*! @decl void append(mixed ... values) |
*! |
*! Append @[values] to the end of the list. |
*! |
*! @seealso |
*! @[insert()] |
*/ |
PIKEFUN void append(mixed ... values) |
{ |
struct pike_list_node *node = TAIL_SENTINEL(THIS); |
while (args--) { |
struct pike_list_node *new_node = alloc_pike_list_node(); |
new_node->val = *(--Pike_sp); |
prepend_list_node(node, new_node); |
free_list_node(node = new_node); |
THIS->num_elems++; |
} |
push_int(0); |
} |
|
/*! @decl void insert(mixed ... values) |
*! |
*! Insert @[values] at the front of the list. |
*! |
*! @seealso |
*! @[append()] |
*/ |
PIKEFUN void insert(mixed ... values) |
{ |
struct pike_list_node *node = THIS->head; |
while (args--) { |
struct pike_list_node *new_node = alloc_pike_list_node(); |
new_node->val = *(--Pike_sp); |
prepend_list_node(node, new_node); |
free_list_node(node = new_node); |
THIS->num_elems++; |
} |
push_int(0); |
} |
|
/*! @decl void flush() |
*! |
*! Empties the List. |
*/ |
PIKEFUN void flush() { |
if (THIS->num_elems) { |
while (THIS->head->next) { |
if (THIS->head->refs == 2) |
unlink_list_node(THIS->head); |
else |
detach_list_node(THIS->head); |
} |
THIS->num_elems = 0; |
} |
} |
|
/*! @decl protected void create(mixed ... values) |
*! |
*! Create a new @[List], and initialize it with @[values]. |
*/ |
PIKEFUN void create(mixed ... values) |
flags ID_PROTECTED; |
{ |
if (THIS->num_elems) |
apply_current(f_List_flush_fun_num, 0); |
apply_current(f_List_append_fun_num, args); |
} |
|
/*! @class _get_iterator |
*! |
*! @[Iterator] that loops over the @[List]. |
*/ |
PIKECLASS _get_iterator |
program_flags PROGRAM_USES_PARENT; |
flags ID_PROTECTED; |
{ |
CVAR struct pike_list_node *cur; |
CVAR INT32 ind; /* Not meaningful, but requred by the API. */ |
|
/* NOTE: cur may never refer to an unlinked node. |
* cur may however refer to a detached node, or to sentinels. |
*/ |
|
static struct List_struct *List__get_iterator_find_parent() |
{ |
struct external_variable_context loc; |
|
loc.o = Pike_fp->current_object; |
loc.parent_identifier = Pike_fp->fun; |
loc.inherit = Pike_fp->context; |
find_external_context(&loc, 1); |
return (struct List_struct *)(loc.o->storage + |
loc.inherit->storage_offset); |
} |
|
INIT |
{ |
add_ref(THIS->cur = List__get_iterator_find_parent()->head); |
THIS->ind = 0; |
} |
|
EXIT |
gc_trivial; |
{ |
if (THIS->cur) { |
free_list_node(THIS->cur); |
THIS->cur = NULL; |
} |
} |
|
/* Called at gc_check time. */ |
GC_CHECK |
{ |
gc_check_list_node_forward(THIS->cur, " held by an iterator"); |
} |
|
/* These two functions perform the same thing, |
* but are optimized to minimize recursion. |
*/ |
static void gc_recurse_list_node_tree_backward(struct pike_list_node *node, |
struct pike_list_node *back); |
static void gc_recurse_list_node_tree_forward(struct pike_list_node *node, |
struct pike_list_node *back) |
{ |
if (!node || !node->next) return; |
if (node->next->prev == node) { |
/* List member. Recursed from the list recurse code. */ |
#ifdef PIKE_DEBUG |
if (node->prev->next != node) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
return; |
} |
#ifdef PIKE_DEBUG |
if (node->prev->next == node) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
while (1) { |
gc_recurse_svalues(&node->val, 1); |
if (node->prev != back) |
gc_recurse_list_node_tree_backward(node->prev, node->next); |
back = node->prev; |
node = node->next; |
if (!node->next || (node->next->prev == node)) { |
/* List member. Recursed from the list recurse code. */ |
#ifdef PIKE_DEBUG |
if (node->prev->next != node) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
break; |
} |
#ifdef PIKE_DEBUG |
if (node->prev->next == node) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
} |
} |
|
static void gc_recurse_list_node_tree_backward(struct pike_list_node *node, |
struct pike_list_node *next) |
{ |
if (!node || !node->prev) return; |
if (node->prev->next == node) { |
/* List member. Checked from the list check code. */ |
#ifdef PIKE_DEBUG |
if (node->next->prev != node) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
return; |
} |
#ifdef PIKE_DEBUG |
if (node->next->prev == node) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
while (1) { |
gc_recurse_svalues(&node->val, 1); |
if (node->next != next) |
gc_recurse_list_node_tree_forward(node->next, node->prev); |
next = node->next; |
node = node->prev; |
if (!node->prev || (node->prev->next == node)) { |
/* List member. Recursed from the list recurse code. */ |
#ifdef PIKE_DEBUG |
if (node->next->prev != node) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
break; |
} |
#ifdef PIKE_DEBUG |
if (node->next->prev == node) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
} |
} |
|
/* Called at gc_mark time */ |
GC_RECURSE |
{ |
if (!THIS->cur->next || !THIS->cur->prev) return; |
if (THIS->cur->next->prev == THIS->cur) { |
#ifdef PIKE_DEBUG |
if (THIS->cur->prev->next != THIS->cur) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
return; |
} |
#ifdef PIKE_DEBUG |
if (THIS->cur->prev->next == THIS->cur) { |
Pike_fatal("Partially detached node.\n"); |
} |
#endif /* PIKE_DEBUG */ |
/* Detached node. */ |
gc_recurse_svalues(&THIS->cur->val, 1); |
gc_recurse_list_node_tree_forward(THIS->cur->next, THIS->cur->prev); |
gc_recurse_list_node_tree_backward(THIS->cur->next, THIS->cur->prev); |
} |
|
PIKEFUN int(0..1) `!() |
flags ID_PROTECTED; |
{ |
pop_n_elems(args); |
push_int(!THIS->cur->next || !THIS->cur->prev); |
} |
|
PIKEFUN int(0..) index() |
{ |
pop_n_elems(args); |
if (THIS->cur->next && THIS->cur->prev) { |
push_int(THIS->ind); |
} else { |
push_undefined(); |
} |
} |
|
/*! @decl mixed value() |
*! |
*! @returns |
*! Returns the value at the current position. |
*/ |
PIKEFUN mixed value() |
{ |
pop_n_elems(args); |
if (THIS->cur->next && THIS->cur->prev) { |
push_svalue(&THIS->cur->val); |
} else { |
push_undefined(); |
} |
} |
|
/*! @decl int(0..1) first() |
*! |
*! Reset the iterator to point to the first element in |
*! the list. |
*! |
*! @returns |
*! Returns @expr{1@} if there are elements in the list, |
*! and @expr{0@} (zero) if the list is empty. |
*/ |
PIKEFUN int(0..1) first() |
{ |
struct external_variable_context loc; |
struct List_struct *parent; |
pop_n_elems(args); |
|
/* Find our parent. */ |
loc.o = Pike_fp->current_object; |
loc.parent_identifier = Pike_fp->fun; |
loc.inherit = INHERIT_FROM_INT(loc.o->prog, loc.parent_identifier); |
find_external_context(&loc, 1); |
parent = (struct List_struct *)(loc.o->storage + |
loc.inherit->storage_offset); |
free_list_node(THIS->cur); |
add_ref(THIS->cur = parent->head); |
THIS->ind = 0; |
pop_n_elems(args); |
if (THIS->cur->next) { |
push_int(1); |
} else { |
push_undefined(); |
} |
} |
|
/*! @decl int(0..1) next() |
*! |
*! Advance to the next element in the list. |
*! |
*! @returns |
*! Returns @expr{1@} on success, and @expr{0@} (zero) |
*! at the end of the list. |
*! |
*! @seealso |
*! @[prev()] |
*/ |
PIKEFUN int(0..1) next() |
{ |
struct pike_list_node *next; |
if ((next = THIS->cur->next)) { |
free_list_node(THIS->cur); |
add_ref(THIS->cur = next); |
THIS->ind++; |
if (next->next) { |
pop_n_elems(args); |
push_int(1); |
return; |
} |
} |
pop_n_elems(args); |
push_int(0); |
} |
|
/*! @decl int(0..1) prev() |
*! |
*! Retrace to the previous element in the list. |
*! |
*! @returns |
*! Returns @expr{1@} on success, and @expr{0@} (zero) |
*! at the beginning of the list. |
*! |
*! @seealso |
*! @[next()] |
*/ |
PIKEFUN int(0..1) prev() |
{ |
struct pike_list_node *prev; |
if ((prev = THIS->cur->prev)) { |
free_list_node(THIS->cur); |
add_ref(THIS->cur = prev); |
THIS->ind--; |
if (prev->prev) { |
pop_n_elems(args); |
push_int(1); |
return; |
} |
} |
pop_n_elems(args); |
push_int(0); |
} |
|
/*! @decl Iterator `+=(int steps) |
*! |
*! Advance or retrace the specified number of @[steps]. |
*! |
*! @seealso |
*! @[next()], @[prev] |
*/ |
PIKEFUN Iterator `+=(int steps) |
{ |
if (!steps) return; |
if (steps > 0) { |
while (steps--) { |
apply_current(f_List_cq__get_iterator_next_fun_num, 0); |
pop_stack(); |
} |
} else { |
while (steps++) { |
apply_current(f_List_cq__get_iterator_prev_fun_num, 0); |
pop_stack(); |
} |
} |
pop_n_elems(args); |
ref_push_object(Pike_fp->current_object); |
} |
|
/*! @decl void insert(mixed val) |
*! |
*! Insert @[val] at the current position. |
*! |
*! @seealso |
*! @[append()], @[delete()], @[set()] |
*/ |
PIKEFUN void insert(mixed val) |
{ |
struct pike_list_node *new_node; |
if (!THIS->cur->prev) { |
Pike_error("Attempt to insert before the start sentinel.\n"); |
} |
new_node = alloc_pike_list_node(); |
assign_svalue_no_free(&new_node->val, val); |
prepend_list_node(THIS->cur, new_node); |
free_list_node(THIS->cur); |
THIS->cur = new_node; |
List__get_iterator_find_parent()->num_elems++; |
pop_n_elems(args); |
push_int(0); |
} |
|
/*! @decl void append(mixed val) |
*! |
*! Append @[val] after the current position. |
*! |
*! @seealso |
*! @[insert()], @[delete()], @[set()] |
*/ |
PIKEFUN void append(mixed val) |
{ |
struct pike_list_node *new_node; |
if (!THIS->cur->next) { |
Pike_error("Attempt to append after the end sentinel.\n"); |
} |
new_node = alloc_pike_list_node(); |
assign_svalue_no_free(&new_node->val, val); |
append_list_node(THIS->cur, new_node); |
free_list_node(new_node); |
List__get_iterator_find_parent()->num_elems++; |
pop_n_elems(args); |
push_int(0); |
} |
|
/*! @decl void delete() |
*! |
*! Delete the current node. |
*! |
*! The current position will advance to the next node. |
*! This function thus performes the reverse operation |
*! of @[insert()]. |
*! |
*! @seealso |
*! @[insert()], @[append()], @[set()] |
*/ |
PIKEFUN void delete() |
{ |
struct pike_list_node *next; |
if (!(next = THIS->cur->next) || !THIS->cur->prev) { |
Pike_error("Attempt to delete a sentinel.\n"); |
} |
add_ref(next); |
if (next->prev == THIS->cur) { |
if (THIS->cur->refs == 3) { |
unlink_list_node(THIS->cur); |
} else { |
/* There's some other iterator holding references to this node. */ |
detach_list_node(THIS->cur); |
} |
List__get_iterator_find_parent()->num_elems--; |
} |
free_list_node(THIS->cur); |
THIS->cur = next; |
pop_n_elems(args); |
push_int(0); |
} |
|
/*! @decl void set(mixed val) |
*! |
*! Set the value of the current position to @[val]. |
*! |
*! @seealso |
*! @[insert()], @[append()], @[delete()] |
*/ |
PIKEFUN void set(mixed val) |
{ |
if (!THIS->cur->next || !THIS->cur->prev) { |
Pike_error("Attempt to set a sentinel.\n"); |
} |
assign_svalue(&THIS->cur->val, val); |
pop_n_elems(args); |
push_int(0); |
} |
} |
/*! @endclass |
*/ |
} |
/*! @endclass |
*/ |
|
/*! @endmodule |
*/ |
|
/*! @module Pike |
*/ |
|
/*! @class MasterCodec |
*! |
*! This is a bare-bones codec that is used when loading a dumped master. |
*! |
*! @seealso |
*! @[Codec] |
*/ |
PIKECLASS MasterCodec |
flags ID_PROTECTED; |
{ |
/*! @decl mixed functionof(mixed symbol) |
*! Look up a function in @[all_constants()]. |
*/ |
PIKEFUN mixed functionof(mixed symbol) |
{ |
mapping_index_no_free(Pike_sp, get_builtin_constants(), symbol); |
Pike_sp++; |
stack_pop_keep_top(); |
} |
/*! @decl mixed objectof(mixed symbol) |
*! Look up an object in @[all_constants()]. |
*/ |
PIKEFUN mixed objectof(mixed symbol) |
{ |
mapping_index_no_free(Pike_sp, get_builtin_constants(), symbol); |
Pike_sp++; |
stack_pop_keep_top(); |
} |
/*! @decl mixed programof(mixed symbol) |
*! Look up a program in @[all_constants()]. |
*/ |
PIKEFUN mixed programof(mixed symbol) |
{ |
mapping_index_no_free(Pike_sp, get_builtin_constants(), symbol); |
Pike_sp++; |
stack_pop_keep_top(); |
} |
/*! @decl object decode_object(object obj, mixed data) |
*! Calls @expr{obj->_decode(@[data])@}. |
*/ |
PIKEFUN object decode_object(object obj, mixed data) |
{ |
apply(obj, "_decode", 1); |
pop_stack(); |
} |
} |
|
/*! @endclass |
*/ |
|
/*! @endmodule |
*/ |
|
static struct object *val_module; |
|
static void get_val_module() |
{ |
assert (!val_module); |
push_constant_text ("Val"); |
APPLY_MASTER ("resolv", 1); |
if (TYPEOF(Pike_sp[-1]) != T_OBJECT) |
Pike_error ("\"Val\" didn't resolve to a module object.\n"); |
val_module = (--Pike_sp)->u.object; |
} |
|
/* Always do the lookup in the Val module dynamically to allow the |
* values to be replaced. */ |
#define GET_VAL(NAME) \ |
PMOD_EXPORT struct object *PIKE_CONCAT (get_val_, NAME) (void) \ |
{ \ |
struct svalue index, res; \ |
if (!val_module) get_val_module(); \ |
SET_SVAL(index, T_STRING, 0, string, NULL); \ |
MAKE_CONST_STRING (index.u.string, TOSTR (NAME)); \ |
object_index_no_free (&res, val_module, 0, &index); \ |
if (TYPEOF(res) != T_OBJECT) \ |
Pike_error ("\"Val." TOSTR (NAME) "\" didn't resolve to an object.\n"); \ |
return res.u.object; \ |
} |
|
GET_VAL (true) |
GET_VAL (false) |
GET_VAL (null) |
|
/* Kludge needed for the static null objects in the oracle module. It |
* ought to be fixed to use dynamic lookup of them instead. */ |
PMOD_EXPORT struct program *get_sql_null_prog(void) |
{ |
return Null_program; |
} |
|
PIKECLASS __Backtrace_Tester__ |
{ |
INIT { |
Pike_error("__Backtrace_Tester__\n"); |
} |
} |
|
void init_builtin(void) |
{ |
SET_SVAL(gc_pre_cb, PIKE_T_INT, NUMBER_NUMBER, integer, 0); |
SET_SVAL(gc_post_cb, PIKE_T_INT, NUMBER_NUMBER, integer, 0); |
SET_SVAL(gc_destruct_cb, PIKE_T_INT, NUMBER_NUMBER, integer, 0); |
SET_SVAL(gc_done_cb, PIKE_T_INT, NUMBER_NUMBER, integer, 0); |
INIT |
} |
|
void exit_builtin(void) |
{ |
struct svalue zero; |
if (val_module) free_object (val_module); |
EXIT |
SET_SVAL(zero, PIKE_T_INT, NUMBER_NUMBER, integer, 0); |
assign_svalue(&gc_pre_cb, &zero); |
assign_svalue(&gc_post_cb, &zero); |
assign_svalue(&gc_destruct_cb, &zero); |
assign_svalue(&gc_done_cb, &zero); |
#ifndef DO_PIKE_CLEANUP |
/* This is performed by exit_builtin_modules() at a later point |
* in this case, so that the pike_list_node's are valid at cleanup |
* time, thus avoiding "got invalid pointer" fatals at exit. |
*/ |
ba_destroy(&pike_list_node_allocator); |
#endif |
#ifndef USE_SETENV |
if (env_allocs) free_mapping (env_allocs); |
#endif |
} |
|