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source: trunk/src/oleaut32/variant.c@ 8346

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Last change on this file since 8346 was 7916, checked in by sandervl, 24 years ago
Wine 20020215 resync + added extended logging
File size: 117.1 KB

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1	/*
2	* VARIANT
3	*
4	* Copyright 1998 Jean-Claude Cote
5	*
6	* NOTES
7	* This implements the low-level and hi-level APIs for manipulating VARIANTs.
8	* The low-level APIs are used to do data coercion between different data types.
9	* The hi-level APIs are built on top of these low-level APIs and handle
10	* initialization, copying, destroying and changing the type of VARIANTs.
11	*
12	* TODO:
13	* - The Variant APIs do not support international languages, currency
14	* types, number formating and calendar. They only support U.S. English format.
15	* - The Variant APIs do not the following types: IUknown, IDispatch, DECIMAL and SafeArray.
16	* The prototypes for these are commented out in the oleauto.h file. They need
17	* to be implemented and cases need to be added to the switches of the existing APIs.
18	* - The parsing of date for the VarDateFromStr is not complete.
19	* - The date manipulations do not support dates prior to 1900.
20	* - The parsing does not accept as many formats as the Windows implementation.
21	*/
22	#ifdef __WIN32OS2__
23	#define HAVE_FLOAT_H
24	#define WINE_LARGE_INTEGER
25	#include "oleaut32.h"
26
27	#endif
28
29	#include "config.h"
30
31	#include <string.h>
32	#include <stdlib.h>
33	#include <stdio.h>
34	#include <math.h>
35	#include <time.h>
36
37	#ifdef HAVE_FLOAT_H
38	# include <float.h>
39	#endif
40
41	#include "windef.h"
42	#include "oleauto.h"
43	#include "heap.h"
44	#include "debugtools.h"
45	#include "winerror.h"
46	#include "parsedt.h"
47
48	DEFAULT_DEBUG_CHANNEL(ole);
49
50	#define SYSDUPSTRING(str) SysAllocStringLen((str), SysStringLen(str))
51
52	#ifndef FLT_MAX
53	# ifdef MAXFLOAT
54	# define FLT_MAX MAXFLOAT
55	# else
56	# error "Can't find #define for MAXFLOAT/FLT_MAX"
57	# endif
58	#endif
59
60	#undef CHAR_MAX
61	#undef CHAR_MIN
62	static const char CHAR_MAX = 127;
63	static const char CHAR_MIN = -128;
64	static const BYTE UI1_MAX = 255;
65	static const BYTE UI1_MIN = 0;
66	static const unsigned short UI2_MAX = 65535;
67	static const unsigned short UI2_MIN = 0;
68	static const short I2_MAX = 32767;
69	static const short I2_MIN = -32768;
70	static const unsigned long UI4_MAX = 4294967295U;
71	static const unsigned long UI4_MIN = 0;
72	static const long I4_MAX = 2147483647;
73	static const long I4_MIN = -(2147483648U);
74	static const DATE DATE_MIN = -657434;
75	static const DATE DATE_MAX = 2958465;
76
77
78	/* This mask is used to set a flag in wReserved1 of
79	* the VARIANTARG structure. The flag indicates if
80	* the API function is using an inner variant or not.
81	*/
82	#define PROCESSING_INNER_VARIANT 0x0001
83
84	/* General use buffer.
85	*/
86	#define BUFFER_MAX 1024
87	static char pBuffer[BUFFER_MAX];
88
89	/*
90	* Note a leap year is one that is a multiple of 4
91	* but not of a 100. Except if it is a multiple of
92	* 400 then it is a leap year.
93	*/
94	/* According to postgreSQL date parsing functions there is
95	* a leap year when this expression is true.
96	* (((y % 4) == 0) && (((y % 100) != 0) \|\| ((y % 400) == 0)))
97	* So according to this there is 365.2515 days in one year.
98	* One + every four years: 1/4 -> 365.25
99	* One - every 100 years: 1/100 -> 365.01
100	* One + every 400 years: 1/400 -> 365.0025
101	*/
102	/* static const double DAYS_IN_ONE_YEAR = 365.2515;
103	*
104	* ^^ Might this be the key to an easy way to factor large prime numbers?
105	* Let's try using arithmetic. <lawson_whitney@juno.com> 7 Mar 2000
106	*/
107	static const double DAYS_IN_ONE_YEAR = 365.2425;
108
109
110	/******************************************************************************
111	* DateTimeStringToTm [INTERNAL]
112	*
113	* Converts a string representation of a date and/or time to a tm structure.
114	*
115	* Note this function uses the postgresql date parsing functions found
116	* in the parsedt.c file.
117	*
118	* Returns TRUE if successful.
119	*
120	* Note: This function does not parse the day of the week,
121	* daylight savings time. It will only fill the followin fields in
122	* the tm struct, tm_sec, tm_min, tm_hour, tm_year, tm_day, tm_mon.
123	*
124	******************************************************************************/
125	static BOOL DateTimeStringToTm( OLECHAR* strIn, DWORD dwFlags, struct tm* pTm )
126	{
127	BOOL res = FALSE;
128	double fsec;
129	int tzp;
130	int dtype;
131	int nf;
132	char *field[MAXDATEFIELDS];
133	int ftype[MAXDATEFIELDS];
134	char lowstr[MAXDATELEN + 1];
135	char* strDateTime = NULL;
136
137	/* Convert the string to ASCII since this is the only format
138	* postgesql can handle.
139	*/
140	strDateTime = HEAP_strdupWtoA( GetProcessHeap(), 0, strIn );
141
142	if( strDateTime != NULL )
143	{
144	/* Make sure we don't go over the maximum length
145	* accepted by postgesql.
146	*/
147	if( strlen( strDateTime ) <= MAXDATELEN )
148	{
149	if( ParseDateTime( strDateTime, lowstr, field, ftype, MAXDATEFIELDS, &nf) == 0 )
150	{
151	if( dwFlags & VAR_DATEVALUEONLY )
152	{
153	/* Get the date information.
154	* It returns 0 if date information was
155	* present and 1 if only time information was present.
156	* -1 if an error occures.
157	*/
158	if( DecodeDateTime(field, ftype, nf, &dtype, pTm, &fsec, &tzp) == 0 )
159	{
160	/* Eliminate the time information since we
161	* were asked to get date information only.
162	*/
163	pTm->tm_sec = 0;
164	pTm->tm_min = 0;
165	pTm->tm_hour = 0;
166	res = TRUE;
167	}
168	}
169	if( dwFlags & VAR_TIMEVALUEONLY )
170	{
171	/* Get time information only.
172	*/
173	if( DecodeTimeOnly(field, ftype, nf, &dtype, pTm, &fsec) == 0 )
174	{
175	res = TRUE;
176	}
177	}
178	else
179	{
180	/* Get both date and time information.
181	* It returns 0 if date information was
182	* present and 1 if only time information was present.
183	* -1 if an error occures.
184	*/
185	if( DecodeDateTime(field, ftype, nf, &dtype, pTm, &fsec, &tzp) != -1 )
186	{
187	res = TRUE;
188	}
189	}
190	}
191	}
192	HeapFree( GetProcessHeap(), 0, strDateTime );
193	}
194
195	return res;
196	}
197
198
199
200
201
202
203	/******************************************************************************
204	* TmToDATE [INTERNAL]
205	*
206	* The date is implemented using an 8 byte floating-point number.
207	* Days are represented by whole numbers increments starting with 0.00 has
208	* being December 30 1899, midnight.
209	* The hours are expressed as the fractional part of the number.
210	* December 30 1899 at midnight = 0.00
211	* January 1 1900 at midnight = 2.00
212	* January 4 1900 at 6 AM = 5.25
213	* January 4 1900 at noon = 5.50
214	* December 29 1899 at midnight = -1.00
215	* December 18 1899 at midnight = -12.00
216	* December 18 1899 at 6AM = -12.25
217	* December 18 1899 at 6PM = -12.75
218	* December 19 1899 at midnight = -11.00
219	* The tm structure is as follows:
220	* struct tm {
221	* int tm_sec; seconds after the minute - [0,59]
222	* int tm_min; minutes after the hour - [0,59]
223	* int tm_hour; hours since midnight - [0,23]
224	* int tm_mday; day of the month - [1,31]
225	* int tm_mon; months since January - [0,11]
226	* int tm_year; years
227	* int tm_wday; days since Sunday - [0,6]
228	* int tm_yday; days since January 1 - [0,365]
229	* int tm_isdst; daylight savings time flag
230	* };
231	*
232	* Note: This function does not use the tm_wday, tm_yday, tm_wday,
233	* and tm_isdst fields of the tm structure. And only converts years
234	* after 1900.
235	*
236	* Returns TRUE if successful.
237	*/
238	static BOOL TmToDATE( struct tm* pTm, DATE *pDateOut )
239	{
240	int leapYear = 0;
241
242	if( (pTm->tm_year - 1900) < 0 ) return FALSE;
243
244	/* Start at 1. This is the way DATE is defined.
245	* January 1, 1900 at Midnight is 1.00.
246	* January 1, 1900 at 6AM is 1.25.
247	* and so on.
248	*/
249	*pDateOut = 1;
250
251	/* Add the number of days corresponding to
252	* tm_year.
253	*/
254	pDateOut += (pTm->tm_year - 1900) 365;
255
256	/* Add the leap days in the previous years between now and 1900.
257	* Note a leap year is one that is a multiple of 4
258	* but not of a 100. Except if it is a multiple of
259	* 400 then it is a leap year.
260	*/
261	*pDateOut += ( (pTm->tm_year - 1) / 4 ) - ( 1900 / 4 );
262	*pDateOut -= ( (pTm->tm_year - 1) / 100 ) - ( 1900 / 100 );
263	*pDateOut += ( (pTm->tm_year - 1) / 400 ) - ( 1900 / 400 );
264
265	/* Set the leap year flag if the
266	* current year specified by tm_year is a
267	* leap year. This will be used to add a day
268	* to the day count.
269	*/
270	if( isleap( pTm->tm_year ) )
271	leapYear = 1;
272
273	/* Add the number of days corresponding to
274	* the month.
275	*/
276	switch( pTm->tm_mon )
277	{
278	case 2:
279	*pDateOut += 31;
280	break;
281	case 3:
282	*pDateOut += ( 59 + leapYear );
283	break;
284	case 4:
285	*pDateOut += ( 90 + leapYear );
286	break;
287	case 5:
288	*pDateOut += ( 120 + leapYear );
289	break;
290	case 6:
291	*pDateOut += ( 151 + leapYear );
292	break;
293	case 7:
294	*pDateOut += ( 181 + leapYear );
295	break;
296	case 8:
297	*pDateOut += ( 212 + leapYear );
298	break;
299	case 9:
300	*pDateOut += ( 243 + leapYear );
301	break;
302	case 10:
303	*pDateOut += ( 273 + leapYear );
304	break;
305	case 11:
306	*pDateOut += ( 304 + leapYear );
307	break;
308	case 12:
309	*pDateOut += ( 334 + leapYear );
310	break;
311	}
312	/* Add the number of days in this month.
313	*/
314	*pDateOut += pTm->tm_mday;
315
316	/* Add the number of seconds, minutes, and hours
317	* to the DATE. Note these are the fracionnal part
318	* of the DATE so seconds / number of seconds in a day.
319	*/
320	*pDateOut += pTm->tm_hour / 24.0;
321	*pDateOut += pTm->tm_min / 1440.0;
322	*pDateOut += pTm->tm_sec / 86400.0;
323	return TRUE;
324	}
325
326	/******************************************************************************
327	* DateToTm [INTERNAL]
328	*
329	* This function converts a windows DATE to a tm structure.
330	*
331	* It does not fill all the fields of the tm structure.
332	* Here is a list of the fields that are filled:
333	* tm_sec, tm_min, tm_hour, tm_year, tm_day, tm_mon.
334	*
335	* Note this function does not support dates before the January 1, 1900
336	* or ( dateIn < 2.0 ).
337	*
338	* Returns TRUE if successful.
339	*/
340	static BOOL DateToTm( DATE dateIn, DWORD dwFlags, struct tm* pTm )
341	{
342	double decimalPart = 0.0;
343	double wholePart = 0.0;
344
345	/* Do not process dates smaller than January 1, 1900.
346	* Which corresponds to 2.0 in the windows DATE format.
347	*/
348	if( dateIn < 2.0 ) return FALSE;
349
350	memset(pTm,0,sizeof(*pTm));
351
352	/* Because of the nature of DATE format which
353	* associates 2.0 to January 1, 1900. We will
354	* remove 1.0 from the whole part of the DATE
355	* so that in the following code 1.0
356	* will correspond to January 1, 1900.
357	* This simplifies the processing of the DATE value.
358	*/
359	dateIn -= 1.0;
360
361	wholePart = (double) floor( dateIn );
362	decimalPart = fmod( dateIn, wholePart );
363
364	if( !(dwFlags & VAR_TIMEVALUEONLY) )
365	{
366	int nDay = 0;
367	int leapYear = 0;
368	double yearsSince1900 = 0;
369	/* Start at 1900, this is where the DATE time 0.0 starts.
370	*/
371	pTm->tm_year = 1900;
372	/* find in what year the day in the "wholePart" falls into.
373	* add the value to the year field.
374	*/
375	yearsSince1900 = floor( (wholePart / DAYS_IN_ONE_YEAR) + 0.001 );
376	pTm->tm_year += yearsSince1900;
377	/* determine if this is a leap year.
378	*/
379	if( isleap( pTm->tm_year ) )
380	{
381	leapYear = 1;
382	wholePart++;
383	}
384
385	/* find what day of that year the "wholePart" corresponds to.
386	* Note: nDay is in [1-366] format
387	*/
388	nDay = (int) ( wholePart - floor( yearsSince1900 * DAYS_IN_ONE_YEAR ) );
389	/* Set the tm_yday value.
390	* Note: The day must be converted from [1-366] to [0-365]
391	*/
392	/pTm->tm_yday = nDay - 1;/
393	/* find which month this day corresponds to.
394	*/
395	if( nDay <= 31 )
396	{
397	pTm->tm_mday = nDay;
398	pTm->tm_mon = 0;
399	}
400	else if( nDay <= ( 59 + leapYear ) )
401	{
402	pTm->tm_mday = nDay - 31;
403	pTm->tm_mon = 1;
404	}
405	else if( nDay <= ( 90 + leapYear ) )
406	{
407	pTm->tm_mday = nDay - ( 59 + leapYear );
408	pTm->tm_mon = 2;
409	}
410	else if( nDay <= ( 120 + leapYear ) )
411	{
412	pTm->tm_mday = nDay - ( 90 + leapYear );
413	pTm->tm_mon = 3;
414	}
415	else if( nDay <= ( 151 + leapYear ) )
416	{
417	pTm->tm_mday = nDay - ( 120 + leapYear );
418	pTm->tm_mon = 4;
419	}
420	else if( nDay <= ( 181 + leapYear ) )
421	{
422	pTm->tm_mday = nDay - ( 151 + leapYear );
423	pTm->tm_mon = 5;
424	}
425	else if( nDay <= ( 212 + leapYear ) )
426	{
427	pTm->tm_mday = nDay - ( 181 + leapYear );
428	pTm->tm_mon = 6;
429	}
430	else if( nDay <= ( 243 + leapYear ) )
431	{
432	pTm->tm_mday = nDay - ( 212 + leapYear );
433	pTm->tm_mon = 7;
434	}
435	else if( nDay <= ( 273 + leapYear ) )
436	{
437	pTm->tm_mday = nDay - ( 243 + leapYear );
438	pTm->tm_mon = 8;
439	}
440	else if( nDay <= ( 304 + leapYear ) )
441	{
442	pTm->tm_mday = nDay - ( 273 + leapYear );
443	pTm->tm_mon = 9;
444	}
445	else if( nDay <= ( 334 + leapYear ) )
446	{
447	pTm->tm_mday = nDay - ( 304 + leapYear );
448	pTm->tm_mon = 10;
449	}
450	else if( nDay <= ( 365 + leapYear ) )
451	{
452	pTm->tm_mday = nDay - ( 334 + leapYear );
453	pTm->tm_mon = 11;
454	}
455	}
456	if( !(dwFlags & VAR_DATEVALUEONLY) )
457	{
458	/* find the number of seconds in this day.
459	* fractional part times, hours, minutes, seconds.
460	*/
461	pTm->tm_hour = (int) ( decimalPart * 24 );
462	pTm->tm_min = (int) ( ( ( decimalPart * 24 ) - pTm->tm_hour ) * 60 );
463	pTm->tm_sec = (int) ( ( ( decimalPart * 24 * 60 ) - ( pTm->tm_hour * 60 ) - pTm->tm_min ) * 60 );
464	}
465	return TRUE;
466	}
467
468
469
470	/******************************************************************************
471	* SizeOfVariantData [INTERNAL]
472	*
473	* This function finds the size of the data referenced by a Variant based
474	* the type "vt" of the Variant.
475	*/
476	static int SizeOfVariantData( VARIANT* parg )
477	{
478	int size = 0;
479	switch( V_VT(parg) & VT_TYPEMASK )
480	{
481	case( VT_I2 ):
482	size = sizeof(short);
483	break;
484	case( VT_INT ):
485	size = sizeof(int);
486	break;
487	case( VT_I4 ):
488	size = sizeof(long);
489	break;
490	case( VT_UI1 ):
491	size = sizeof(BYTE);
492	break;
493	case( VT_UI2 ):
494	size = sizeof(unsigned short);
495	break;
496	case( VT_UINT ):
497	size = sizeof(unsigned int);
498	break;
499	case( VT_UI4 ):
500	size = sizeof(unsigned long);
501	break;
502	case( VT_R4 ):
503	size = sizeof(float);
504	break;
505	case( VT_R8 ):
506	size = sizeof(double);
507	break;
508	case( VT_DATE ):
509	size = sizeof(DATE);
510	break;
511	case( VT_BOOL ):
512	size = sizeof(VARIANT_BOOL);
513	break;
514	case( VT_BSTR ):
515	size = sizeof(void*);
516	break;
517	case( VT_CY ):
518	case( VT_DISPATCH ):
519	case( VT_UNKNOWN ):
520	case( VT_DECIMAL ):
521	default:
522	FIXME("Add size information for type vt=%d\n", V_VT(parg) & VT_TYPEMASK );
523	break;
524	}
525
526	return size;
527	}
528	/******************************************************************************
529	* StringDupAtoBstr [INTERNAL]
530	*
531	*/
532	static BSTR StringDupAtoBstr( char* strIn )
533	{
534	BSTR bstr = NULL;
535	OLECHAR* pNewString = NULL;
536	pNewString = HEAP_strdupAtoW( GetProcessHeap(), 0, strIn );
537	bstr = SysAllocString( pNewString );
538	HeapFree( GetProcessHeap(), 0, pNewString );
539	return bstr;
540	}
541
542	/******************************************************************************
543	* round [INTERNAL]
544	*
545	* Round the double value to the nearest integer value.
546	*/
547	static double round( double d )
548	{
549	double decimals = 0.0, integerValue = 0.0, roundedValue = 0.0;
550	BOOL bEvenNumber = FALSE;
551	int nSign = 0;
552
553	/* Save the sign of the number
554	*/
555	nSign = (d >= 0.0) ? 1 : -1;
556	d = fabs( d );
557
558	/* Remove the decimals.
559	*/
560	integerValue = floor( d );
561
562	/* Set the Even flag. This is used to round the number when
563	* the decimals are exactly 1/2. If the integer part is
564	* odd the number is rounded up. If the integer part
565	* is even the number is rounded down. Using this method
566	* numbers are rounded up\|down half the time.
567	*/
568	bEvenNumber = (((short)fmod(integerValue, 2)) == 0) ? TRUE : FALSE;
569
570	/* Remove the integral part of the number.
571	*/
572	decimals = d - integerValue;
573
574	/* Note: Ceil returns the smallest integer that is greater that x.
575	* and floor returns the largest integer that is less than or equal to x.
576	*/
577	if( decimals > 0.5 )
578	{
579	/* If the decimal part is greater than 1/2
580	*/
581	roundedValue = ceil( d );
582	}
583	else if( decimals < 0.5 )
584	{
585	/* If the decimal part is smaller than 1/2
586	*/
587	roundedValue = floor( d );
588	}
589	else
590	{
591	/* the decimals are exactly 1/2 so round according to
592	* the bEvenNumber flag.
593	*/
594	if( bEvenNumber )
595	{
596	roundedValue = floor( d );
597	}
598	else
599	{
600	roundedValue = ceil( d );
601	}
602	}
603
604	return roundedValue * nSign;
605	}
606
607	/******************************************************************************
608	* RemoveCharacterFromString [INTERNAL]
609	*
610	* Removes any of the characters in "strOfCharToRemove" from the "str" argument.
611	*/
612	static void RemoveCharacterFromString( LPSTR str, LPSTR strOfCharToRemove )
613	{
614	LPSTR pNewString = NULL;
615	LPSTR strToken = NULL;
616
617	/* Check if we have a valid argument
618	*/
619	if( str != NULL )
620	{
621	pNewString = strdup( str );
622	str[0] = '\0';
623	strToken = strtok( pNewString, strOfCharToRemove );
624	while( strToken != NULL ) {
625	strcat( str, strToken );
626	strToken = strtok( NULL, strOfCharToRemove );
627	}
628	free( pNewString );
629	}
630	return;
631	}
632
633	/******************************************************************************
634	* GetValidRealString [INTERNAL]
635	*
636	* Checks if the string is of proper format to be converted to a real value.
637	*/
638	static BOOL IsValidRealString( LPSTR strRealString )
639	{
640	/* Real values that have a decimal point are required to either have
641	* digits before or after the decimal point. We will assume that
642	* we do not have any digits at either position. If we do encounter
643	* some we will disable this flag.
644	*/
645	BOOL bDigitsRequired = TRUE;
646	/* Processed fields in the string representation of the real number.
647	*/
648	BOOL bWhiteSpaceProcessed = FALSE;
649	BOOL bFirstSignProcessed = FALSE;
650	BOOL bFirstDigitsProcessed = FALSE;
651	BOOL bDecimalPointProcessed = FALSE;
652	BOOL bSecondDigitsProcessed = FALSE;
653	BOOL bExponentProcessed = FALSE;
654	BOOL bSecondSignProcessed = FALSE;
655	BOOL bThirdDigitsProcessed = FALSE;
656	/* Assume string parameter "strRealString" is valid and try to disprove it.
657	*/
658	BOOL bValidRealString = TRUE;
659
660	/* Used to count the number of tokens in the "strRealString".
661	*/
662	LPSTR strToken = NULL;
663	int nTokens = 0;
664	LPSTR pChar = NULL;
665
666	/* Check if we have a valid argument
667	*/
668	if( strRealString == NULL )
669	{
670	bValidRealString = FALSE;
671	}
672
673	if( bValidRealString == TRUE )
674	{
675	/* Make sure we only have ONE token in the string.
676	*/
677	strToken = strtok( strRealString, " " );
678	while( strToken != NULL ) {
679	nTokens++;
680	strToken = strtok( NULL, " " );
681	}
682
683	if( nTokens != 1 )
684	{
685	bValidRealString = FALSE;
686	}
687	}
688
689
690	/* Make sure this token contains only valid characters.
691	* The string argument to atof has the following form:
692	* [whitespace] [sign] [digits] [.digits] [ {d \| D \| e \| E }[sign]digits]
693	* Whitespace consists of space and\|or <TAB> characters, which are ignored.
694	* Sign is either plus '+' or minus '-'.
695	* Digits are one or more decimal digits.
696	* Note: If no digits appear before the decimal point, at least one must
697	* appear after the decimal point.
698	* The decimal digits may be followed by an exponent.
699	* An Exponent consists of an introductory letter ( D, d, E, or e) and
700	* an optionally signed decimal integer.
701	*/
702	pChar = strRealString;
703	while( bValidRealString == TRUE && *pChar != '\0' )
704	{
705	switch( *pChar )
706	{
707	/* If whitespace...
708	*/
709	case ' ':
710	case '\t':
711	if( bWhiteSpaceProcessed \|\|
712	bFirstSignProcessed \|\|
713	bFirstDigitsProcessed \|\|
714	bDecimalPointProcessed \|\|
715	bSecondDigitsProcessed \|\|
716	bExponentProcessed \|\|
717	bSecondSignProcessed \|\|
718	bThirdDigitsProcessed )
719	{
720	bValidRealString = FALSE;
721	}
722	break;
723	/* If sign...
724	*/
725	case '+':
726	case '-':
727	if( bFirstSignProcessed == FALSE )
728	{
729	if( bFirstDigitsProcessed \|\|
730	bDecimalPointProcessed \|\|
731	bSecondDigitsProcessed \|\|
732	bExponentProcessed \|\|
733	bSecondSignProcessed \|\|
734	bThirdDigitsProcessed )
735	{
736	bValidRealString = FALSE;
737	}
738	bWhiteSpaceProcessed = TRUE;
739	bFirstSignProcessed = TRUE;
740	}
741	else if( bSecondSignProcessed == FALSE )
742	{
743	/* Note: The exponent must be present in
744	* order to accept the second sign...
745	*/
746	if( bExponentProcessed == FALSE \|\|
747	bThirdDigitsProcessed \|\|
748	bDigitsRequired )
749	{
750	bValidRealString = FALSE;
751	}
752	bFirstSignProcessed = TRUE;
753	bWhiteSpaceProcessed = TRUE;
754	bFirstDigitsProcessed = TRUE;
755	bDecimalPointProcessed = TRUE;
756	bSecondDigitsProcessed = TRUE;
757	bSecondSignProcessed = TRUE;
758	}
759	break;
760
761	/* If decimals...
762	*/
763	case '0':
764	case '1':
765	case '2':
766	case '3':
767	case '4':
768	case '5':
769	case '6':
770	case '7':
771	case '8':
772	case '9':
773	if( bFirstDigitsProcessed == FALSE )
774	{
775	if( bDecimalPointProcessed \|\|
776	bSecondDigitsProcessed \|\|
777	bExponentProcessed \|\|
778	bSecondSignProcessed \|\|
779	bThirdDigitsProcessed )
780	{
781	bValidRealString = FALSE;
782	}
783	bFirstSignProcessed = TRUE;
784	bWhiteSpaceProcessed = TRUE;
785	/* We have found some digits before the decimal point
786	* so disable the "Digits required" flag.
787	*/
788	bDigitsRequired = FALSE;
789	}
790	else if( bSecondDigitsProcessed == FALSE )
791	{
792	if( bExponentProcessed \|\|
793	bSecondSignProcessed \|\|
794	bThirdDigitsProcessed )
795	{
796	bValidRealString = FALSE;
797	}
798	bFirstSignProcessed = TRUE;
799	bWhiteSpaceProcessed = TRUE;
800	bFirstDigitsProcessed = TRUE;
801	bDecimalPointProcessed = TRUE;
802	/* We have found some digits after the decimal point
803	* so disable the "Digits required" flag.
804	*/
805	bDigitsRequired = FALSE;
806	}
807	else if( bThirdDigitsProcessed == FALSE )
808	{
809	/* Getting here means everything else should be processed.
810	* If we get anything else than a decimal following this
811	* digit it will be flagged by the other cases, so
812	* we do not really need to do anything in here.
813	*/
814	}
815	break;
816	/* If DecimalPoint...
817	*/
818	case '.':
819	if( bDecimalPointProcessed \|\|
820	bSecondDigitsProcessed \|\|
821	bExponentProcessed \|\|
822	bSecondSignProcessed \|\|
823	bThirdDigitsProcessed )
824	{
825	bValidRealString = FALSE;
826	}
827	bFirstSignProcessed = TRUE;
828	bWhiteSpaceProcessed = TRUE;
829	bFirstDigitsProcessed = TRUE;
830	bDecimalPointProcessed = TRUE;
831	break;
832	/* If Exponent...
833	*/
834	case 'e':
835	case 'E':
836	case 'd':
837	case 'D':
838	if( bExponentProcessed \|\|
839	bSecondSignProcessed \|\|
840	bThirdDigitsProcessed \|\|
841	bDigitsRequired )
842	{
843	bValidRealString = FALSE;
844	}
845	bFirstSignProcessed = TRUE;
846	bWhiteSpaceProcessed = TRUE;
847	bFirstDigitsProcessed = TRUE;
848	bDecimalPointProcessed = TRUE;
849	bSecondDigitsProcessed = TRUE;
850	bExponentProcessed = TRUE;
851	break;
852	default:
853	bValidRealString = FALSE;
854	break;
855	}
856	/* Process next character.
857	*/
858	pChar++;
859	}
860
861	/* If the required digits were not present we have an invalid
862	* string representation of a real number.
863	*/
864	if( bDigitsRequired == TRUE )
865	{
866	bValidRealString = FALSE;
867	}
868
869	return bValidRealString;
870	}
871
872
873	/******************************************************************************
874	* Coerce [INTERNAL]
875	*
876	* This function dispatches execution to the proper conversion API
877	* to do the necessary coercion.
878	*
879	* FIXME: Passing down dwFlags to the conversion functions is wrong, this
880	* is a different flagmask. Check MSDN.
881	*/
882	static HRESULT Coerce( VARIANTARG* pd, LCID lcid, ULONG dwFlags, VARIANTARG* ps, VARTYPE vt )
883	{
884	HRESULT res = S_OK;
885	unsigned short vtFrom = 0;
886	vtFrom = V_VT(ps) & VT_TYPEMASK;
887
888
889	/* Note: Since "long" and "int" values both have 4 bytes and are
890	* both signed integers "int" will be treated as "long" in the
891	* following code.
892	* The same goes for their unsigned versions.
893	*/
894
895	/* Trivial Case: If the coercion is from two types that are
896	* identical then we can blindly copy from one argument to another.*/
897	if ((vt==vtFrom))
898	{
899	return VariantCopy(pd,ps);
900	}
901
902	/* Cases requiring thought*/
903	switch( vt )
904	{
905
906	case( VT_EMPTY ):
907	res = VariantClear( pd );
908	break;
909	case( VT_NULL ):
910	res = VariantClear( pd );
911	if( res == S_OK )
912	{
913	V_VT(pd) = VT_NULL;
914	}
915	break;
916	case( VT_I1 ):
917	switch( vtFrom )
918	{
919	case( VT_I1 ):
920	res = VariantCopy( pd, ps );
921	break;
922	case( VT_I2 ):
923	res = VarI1FromI2( V_UNION(ps,iVal), &V_UNION(pd,cVal) );
924	break;
925	case( VT_INT ):
926	case( VT_I4 ):
927	res = VarI1FromI4( V_UNION(ps,lVal), &V_UNION(pd,cVal) );
928	break;
929	case( VT_UI1 ):
930	res = VarI1FromUI1( V_UNION(ps,bVal), &V_UNION(pd,cVal) );
931	break;
932	case( VT_UI2 ):
933	res = VarI1FromUI2( V_UNION(ps,uiVal), &V_UNION(pd,cVal) );
934	break;
935	case( VT_UINT ):
936	case( VT_UI4 ):
937	res = VarI1FromUI4( V_UNION(ps,ulVal), &V_UNION(pd,cVal) );
938	break;
939	case( VT_R4 ):
940	res = VarI1FromR4( V_UNION(ps,fltVal), &V_UNION(pd,cVal) );
941	break;
942	case( VT_R8 ):
943	res = VarI1FromR8( V_UNION(ps,dblVal), &V_UNION(pd,cVal) );
944	break;
945	case( VT_DATE ):
946	res = VarI1FromDate( V_UNION(ps,date), &V_UNION(pd,cVal) );
947	break;
948	case( VT_BOOL ):
949	res = VarI1FromBool( V_UNION(ps,boolVal), &V_UNION(pd,cVal) );
950	break;
951	case( VT_BSTR ):
952	res = VarI1FromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,cVal) );
953	break;
954	case( VT_CY ):
955	res = VarI1FromCy( V_UNION(ps,cyVal), &V_UNION(pd,cVal) );
956	break;
957	case( VT_DISPATCH ):
958	/res = VarI1FromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,cVal) );/
959	case( VT_DECIMAL ):
960	/res = VarI1FromDec( V_UNION(ps,decVal), &V_UNION(pd,cVal) );/
961	case( VT_UNKNOWN ):
962	default:
963	res = DISP_E_TYPEMISMATCH;
964	FIXME("Coercion from %d to %d\n", vtFrom, vt );
965	break;
966	}
967	break;
968
969	case( VT_I2 ):
970	switch( vtFrom )
971	{
972	case( VT_I1 ):
973	res = VarI2FromI1( V_UNION(ps,cVal), &V_UNION(pd,iVal) );
974	break;
975	case( VT_I2 ):
976	res = VariantCopy( pd, ps );
977	break;
978	case( VT_INT ):
979	case( VT_I4 ):
980	res = VarI2FromI4( V_UNION(ps,lVal), &V_UNION(pd,iVal) );
981	break;
982	case( VT_UI1 ):
983	res = VarI2FromUI1( V_UNION(ps,bVal), &V_UNION(pd,iVal) );
984	break;
985	case( VT_UI2 ):
986	res = VarI2FromUI2( V_UNION(ps,uiVal), &V_UNION(pd,iVal) );
987	break;
988	case( VT_UINT ):
989	case( VT_UI4 ):
990	res = VarI2FromUI4( V_UNION(ps,ulVal), &V_UNION(pd,iVal) );
991	break;
992	case( VT_R4 ):
993	res = VarI2FromR4( V_UNION(ps,fltVal), &V_UNION(pd,iVal) );
994	break;
995	case( VT_R8 ):
996	res = VarI2FromR8( V_UNION(ps,dblVal), &V_UNION(pd,iVal) );
997	break;
998	case( VT_DATE ):
999	res = VarI2FromDate( V_UNION(ps,date), &V_UNION(pd,iVal) );
1000	break;
1001	case( VT_BOOL ):
1002	res = VarI2FromBool( V_UNION(ps,boolVal), &V_UNION(pd,iVal) );
1003	break;
1004	case( VT_BSTR ):
1005	res = VarI2FromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,iVal) );
1006	break;
1007	case( VT_CY ):
1008	res = VarI2FromCy( V_UNION(ps,cyVal), &V_UNION(pd,iVal) );
1009	break;
1010	case( VT_DISPATCH ):
1011	/res = VarI2FromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,iVal) );/
1012	case( VT_DECIMAL ):
1013	/res = VarI2FromDec( V_UNION(ps,deiVal), &V_UNION(pd,iVal) );/
1014	case( VT_UNKNOWN ):
1015	default:
1016	res = DISP_E_TYPEMISMATCH;
1017	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1018	break;
1019	}
1020	break;
1021
1022	case( VT_INT ):
1023	case( VT_I4 ):
1024	switch( vtFrom )
1025	{
1026	case( VT_EMPTY ):
1027	V_UNION(pd,lVal) = 0;
1028	res = S_OK;
1029	break;
1030	case( VT_I1 ):
1031	res = VarI4FromI1( V_UNION(ps,cVal), &V_UNION(pd,lVal) );
1032	break;
1033	case( VT_I2 ):
1034	res = VarI4FromI2( V_UNION(ps,iVal), &V_UNION(pd,lVal) );
1035	break;
1036	case( VT_INT ):
1037	case( VT_I4 ):
1038	#ifdef __WIN32OS2__
1039	case( VT_HRESULT ):
1040	#endif
1041	res = VariantCopy( pd, ps );
1042	break;
1043	case( VT_UI1 ):
1044	res = VarI4FromUI1( V_UNION(ps,bVal), &V_UNION(pd,lVal) );
1045	break;
1046	case( VT_UI2 ):
1047	res = VarI4FromUI2( V_UNION(ps,uiVal), &V_UNION(pd,lVal) );
1048	break;
1049	case( VT_UINT ):
1050	case( VT_UI4 ):
1051	res = VarI4FromUI4( V_UNION(ps,ulVal), &V_UNION(pd,lVal) );
1052	break;
1053	case( VT_R4 ):
1054	res = VarI4FromR4( V_UNION(ps,fltVal), &V_UNION(pd,lVal) );
1055	break;
1056	case( VT_R8 ):
1057	res = VarI4FromR8( V_UNION(ps,dblVal), &V_UNION(pd,lVal) );
1058	break;
1059	case( VT_DATE ):
1060	res = VarI4FromDate( V_UNION(ps,date), &V_UNION(pd,lVal) );
1061	break;
1062	case( VT_BOOL ):
1063	res = VarI4FromBool( V_UNION(ps,boolVal), &V_UNION(pd,lVal) );
1064	break;
1065	case( VT_BSTR ):
1066	res = VarI4FromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,lVal) );
1067	break;
1068	case( VT_CY ):
1069	res = VarI4FromCy( V_UNION(ps,cyVal), &V_UNION(pd,lVal) );
1070	break;
1071	case( VT_DISPATCH ):
1072	/res = VarI4FromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,lVal) );/
1073	case( VT_DECIMAL ):
1074	/res = VarI4FromDec( V_UNION(ps,deiVal), &V_UNION(pd,lVal) );/
1075	case( VT_UNKNOWN ):
1076	default:
1077	res = DISP_E_TYPEMISMATCH;
1078	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1079	break;
1080	}
1081	break;
1082
1083	case( VT_UI1 ):
1084	switch( vtFrom )
1085	{
1086	case( VT_I1 ):
1087	res = VarUI1FromI1( V_UNION(ps,cVal), &V_UNION(pd,bVal) );
1088	break;
1089	case( VT_I2 ):
1090	res = VarUI1FromI2( V_UNION(ps,iVal), &V_UNION(pd,bVal) );
1091	break;
1092	case( VT_INT ):
1093	case( VT_I4 ):
1094	res = VarUI1FromI4( V_UNION(ps,lVal), &V_UNION(pd,bVal) );
1095	break;
1096	case( VT_UI1 ):
1097	res = VariantCopy( pd, ps );
1098	break;
1099	case( VT_UI2 ):
1100	res = VarUI1FromUI2( V_UNION(ps,uiVal), &V_UNION(pd,bVal) );
1101	break;
1102	case( VT_UINT ):
1103	case( VT_UI4 ):
1104	res = VarUI1FromUI4( V_UNION(ps,ulVal), &V_UNION(pd,bVal) );
1105	break;
1106	case( VT_R4 ):
1107	res = VarUI1FromR4( V_UNION(ps,fltVal), &V_UNION(pd,bVal) );
1108	break;
1109	case( VT_R8 ):
1110	res = VarUI1FromR8( V_UNION(ps,dblVal), &V_UNION(pd,bVal) );
1111	break;
1112	case( VT_DATE ):
1113	res = VarUI1FromDate( V_UNION(ps,date), &V_UNION(pd,bVal) );
1114	break;
1115	case( VT_BOOL ):
1116	res = VarUI1FromBool( V_UNION(ps,boolVal), &V_UNION(pd,bVal) );
1117	break;
1118	case( VT_BSTR ):
1119	res = VarUI1FromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,bVal) );
1120	break;
1121	case( VT_CY ):
1122	res = VarUI1FromCy( V_UNION(ps,cyVal), &V_UNION(pd,bVal) );
1123	break;
1124	case( VT_DISPATCH ):
1125	/res = VarUI1FromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,bVal) );/
1126	case( VT_DECIMAL ):
1127	/res = VarUI1FromDec( V_UNION(ps,deiVal), &V_UNION(pd,bVal) );/
1128	case( VT_UNKNOWN ):
1129	default:
1130	res = DISP_E_TYPEMISMATCH;
1131	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1132	break;
1133	}
1134	break;
1135
1136	case( VT_UI2 ):
1137	switch( vtFrom )
1138	{
1139	case( VT_I1 ):
1140	res = VarUI2FromI1( V_UNION(ps,cVal), &V_UNION(pd,uiVal) );
1141	break;
1142	case( VT_I2 ):
1143	res = VarUI2FromI2( V_UNION(ps,iVal), &V_UNION(pd,uiVal) );
1144	break;
1145	case( VT_INT ):
1146	case( VT_I4 ):
1147	res = VarUI2FromI4( V_UNION(ps,lVal), &V_UNION(pd,uiVal) );
1148	break;
1149	case( VT_UI1 ):
1150	res = VarUI2FromUI1( V_UNION(ps,bVal), &V_UNION(pd,uiVal) );
1151	break;
1152	case( VT_UI2 ):
1153	res = VariantCopy( pd, ps );
1154	break;
1155	case( VT_UINT ):
1156	case( VT_UI4 ):
1157	res = VarUI2FromUI4( V_UNION(ps,ulVal), &V_UNION(pd,uiVal) );
1158	break;
1159	case( VT_R4 ):
1160	res = VarUI2FromR4( V_UNION(ps,fltVal), &V_UNION(pd,uiVal) );
1161	break;
1162	case( VT_R8 ):
1163	res = VarUI2FromR8( V_UNION(ps,dblVal), &V_UNION(pd,uiVal) );
1164	break;
1165	case( VT_DATE ):
1166	res = VarUI2FromDate( V_UNION(ps,date), &V_UNION(pd,uiVal) );
1167	break;
1168	case( VT_BOOL ):
1169	res = VarUI2FromBool( V_UNION(ps,boolVal), &V_UNION(pd,uiVal) );
1170	break;
1171	case( VT_BSTR ):
1172	res = VarUI2FromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,uiVal) );
1173	break;
1174	case( VT_CY ):
1175	res = VarUI2FromCy( V_UNION(ps,cyVal), &V_UNION(pd,uiVal) );
1176	break;
1177	case( VT_DISPATCH ):
1178	/res = VarUI2FromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,uiVal) );/
1179	case( VT_DECIMAL ):
1180	/res = VarUI2FromDec( V_UNION(ps,deiVal), &V_UNION(pd,uiVal) );/
1181	case( VT_UNKNOWN ):
1182	default:
1183	res = DISP_E_TYPEMISMATCH;
1184	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1185	break;
1186	}
1187	break;
1188
1189	case( VT_UINT ):
1190	case( VT_UI4 ):
1191	switch( vtFrom )
1192	{
1193	case( VT_I1 ):
1194	res = VarUI4FromI1( V_UNION(ps,cVal), &V_UNION(pd,ulVal) );
1195	break;
1196	case( VT_I2 ):
1197	res = VarUI4FromI2( V_UNION(ps,iVal), &V_UNION(pd,ulVal) );
1198	break;
1199	case( VT_INT ):
1200	case( VT_I4 ):
1201	res = VarUI4FromI4( V_UNION(ps,lVal), &V_UNION(pd,ulVal) );
1202	break;
1203	case( VT_UI1 ):
1204	res = VarUI4FromUI1( V_UNION(ps,bVal), &V_UNION(pd,ulVal) );
1205	break;
1206	case( VT_UI2 ):
1207	res = VarUI4FromUI2( V_UNION(ps,uiVal), &V_UNION(pd,ulVal) );
1208	break;
1209	case( VT_UI4 ):
1210	res = VariantCopy( pd, ps );
1211	break;
1212	case( VT_R4 ):
1213	res = VarUI4FromR4( V_UNION(ps,fltVal), &V_UNION(pd,ulVal) );
1214	break;
1215	case( VT_R8 ):
1216	res = VarUI4FromR8( V_UNION(ps,dblVal), &V_UNION(pd,ulVal) );
1217	break;
1218	case( VT_DATE ):
1219	res = VarUI4FromDate( V_UNION(ps,date), &V_UNION(pd,ulVal) );
1220	break;
1221	case( VT_BOOL ):
1222	res = VarUI4FromBool( V_UNION(ps,boolVal), &V_UNION(pd,ulVal) );
1223	break;
1224	case( VT_BSTR ):
1225	res = VarUI4FromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,ulVal) );
1226	break;
1227	case( VT_CY ):
1228	res = VarUI4FromCy( V_UNION(ps,cyVal), &V_UNION(pd,ulVal) );
1229	break;
1230	case( VT_DISPATCH ):
1231	/res = VarUI4FromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,ulVal) );/
1232	case( VT_DECIMAL ):
1233	/res = VarUI4FromDec( V_UNION(ps,deiVal), &V_UNION(pd,ulVal) );/
1234	case( VT_UNKNOWN ):
1235	default:
1236	res = DISP_E_TYPEMISMATCH;
1237	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1238	break;
1239	}
1240	break;
1241
1242	case( VT_R4 ):
1243	switch( vtFrom )
1244	{
1245	case( VT_I1 ):
1246	res = VarR4FromI1( V_UNION(ps,cVal), &V_UNION(pd,fltVal) );
1247	break;
1248	case( VT_I2 ):
1249	res = VarR4FromI2( V_UNION(ps,iVal), &V_UNION(pd,fltVal) );
1250	break;
1251	case( VT_INT ):
1252	case( VT_I4 ):
1253	res = VarR4FromI4( V_UNION(ps,lVal), &V_UNION(pd,fltVal) );
1254	break;
1255	case( VT_UI1 ):
1256	res = VarR4FromUI1( V_UNION(ps,bVal), &V_UNION(pd,fltVal) );
1257	break;
1258	case( VT_UI2 ):
1259	res = VarR4FromUI2( V_UNION(ps,uiVal), &V_UNION(pd,fltVal) );
1260	break;
1261	case( VT_UINT ):
1262	case( VT_UI4 ):
1263	res = VarR4FromUI4( V_UNION(ps,ulVal), &V_UNION(pd,fltVal) );
1264	break;
1265	case( VT_R4 ):
1266	res = VariantCopy( pd, ps );
1267	break;
1268	case( VT_R8 ):
1269	res = VarR4FromR8( V_UNION(ps,dblVal), &V_UNION(pd,fltVal) );
1270	break;
1271	case( VT_DATE ):
1272	res = VarR4FromDate( V_UNION(ps,date), &V_UNION(pd,fltVal) );
1273	break;
1274	case( VT_BOOL ):
1275	res = VarR4FromBool( V_UNION(ps,boolVal), &V_UNION(pd,fltVal) );
1276	break;
1277	case( VT_BSTR ):
1278	res = VarR4FromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,fltVal) );
1279	break;
1280	case( VT_CY ):
1281	res = VarR4FromCy( V_UNION(ps,cyVal), &V_UNION(pd,fltVal) );
1282	break;
1283	case( VT_DISPATCH ):
1284	/res = VarR4FromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,fltVal) );/
1285	case( VT_DECIMAL ):
1286	/res = VarR4FromDec( V_UNION(ps,deiVal), &V_UNION(pd,fltVal) );/
1287	case( VT_UNKNOWN ):
1288	default:
1289	res = DISP_E_TYPEMISMATCH;
1290	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1291	break;
1292	}
1293	break;
1294
1295	case( VT_R8 ):
1296	switch( vtFrom )
1297	{
1298	case( VT_I1 ):
1299	res = VarR8FromI1( V_UNION(ps,cVal), &V_UNION(pd,dblVal) );
1300	break;
1301	case( VT_I2 ):
1302	res = VarR8FromI2( V_UNION(ps,iVal), &V_UNION(pd,dblVal) );
1303	break;
1304	case( VT_INT ):
1305	case( VT_I4 ):
1306	res = VarR8FromI4( V_UNION(ps,lVal), &V_UNION(pd,dblVal) );
1307	break;
1308	case( VT_UI1 ):
1309	res = VarR8FromUI1( V_UNION(ps,bVal), &V_UNION(pd,dblVal) );
1310	break;
1311	case( VT_UI2 ):
1312	res = VarR8FromUI2( V_UNION(ps,uiVal), &V_UNION(pd,dblVal) );
1313	break;
1314	case( VT_UINT ):
1315	case( VT_UI4 ):
1316	res = VarR8FromUI4( V_UNION(ps,ulVal), &V_UNION(pd,dblVal) );
1317	break;
1318	case( VT_R4 ):
1319	res = VarR8FromR4( V_UNION(ps,fltVal), &V_UNION(pd,dblVal) );
1320	break;
1321	case( VT_R8 ):
1322	res = VariantCopy( pd, ps );
1323	break;
1324	case( VT_DATE ):
1325	res = VarR8FromDate( V_UNION(ps,date), &V_UNION(pd,dblVal) );
1326	break;
1327	case( VT_BOOL ):
1328	res = VarR8FromBool( V_UNION(ps,boolVal), &V_UNION(pd,dblVal) );
1329	break;
1330	case( VT_BSTR ):
1331	res = VarR8FromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,dblVal) );
1332	break;
1333	case( VT_CY ):
1334	res = VarR8FromCy( V_UNION(ps,cyVal), &V_UNION(pd,dblVal) );
1335	break;
1336	case( VT_DISPATCH ):
1337	/res = VarR8FromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,dblVal) );/
1338	case( VT_DECIMAL ):
1339	/res = VarR8FromDec( V_UNION(ps,deiVal), &V_UNION(pd,dblVal) );/
1340	case( VT_UNKNOWN ):
1341	default:
1342	res = DISP_E_TYPEMISMATCH;
1343	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1344	break;
1345	}
1346	break;
1347
1348	case( VT_DATE ):
1349	switch( vtFrom )
1350	{
1351	case( VT_I1 ):
1352	res = VarDateFromI1( V_UNION(ps,cVal), &V_UNION(pd,date) );
1353	break;
1354	case( VT_I2 ):
1355	res = VarDateFromI2( V_UNION(ps,iVal), &V_UNION(pd,date) );
1356	break;
1357	case( VT_INT ):
1358	res = VarDateFromInt( V_UNION(ps,intVal), &V_UNION(pd,date) );
1359	break;
1360	case( VT_I4 ):
1361	res = VarDateFromI4( V_UNION(ps,lVal), &V_UNION(pd,date) );
1362	break;
1363	case( VT_UI1 ):
1364	res = VarDateFromUI1( V_UNION(ps,bVal), &V_UNION(pd,date) );
1365	break;
1366	case( VT_UI2 ):
1367	res = VarDateFromUI2( V_UNION(ps,uiVal), &V_UNION(pd,date) );
1368	break;
1369	case( VT_UINT ):
1370	res = VarDateFromUint( V_UNION(ps,uintVal), &V_UNION(pd,date) );
1371	break;
1372	case( VT_UI4 ):
1373	res = VarDateFromUI4( V_UNION(ps,ulVal), &V_UNION(pd,date) );
1374	break;
1375	case( VT_R4 ):
1376	res = VarDateFromR4( V_UNION(ps,fltVal), &V_UNION(pd,date) );
1377	break;
1378	case( VT_R8 ):
1379	res = VarDateFromR8( V_UNION(ps,dblVal), &V_UNION(pd,date) );
1380	break;
1381	case( VT_DATE ):
1382	res = VariantCopy( pd, ps );
1383	break;
1384	case( VT_BOOL ):
1385	res = VarDateFromBool( V_UNION(ps,boolVal), &V_UNION(pd,date) );
1386	break;
1387	case( VT_BSTR ):
1388	res = VarDateFromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,date) );
1389	break;
1390	case( VT_CY ):
1391	res = VarDateFromCy( V_UNION(ps,cyVal), &V_UNION(pd,date) );
1392	break;
1393	case( VT_DISPATCH ):
1394	/res = VarDateFromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,date) );/
1395	case( VT_DECIMAL ):
1396	/res = VarDateFromDec( V_UNION(ps,deiVal), &V_UNION(pd,date) );/
1397	case( VT_UNKNOWN ):
1398	default:
1399	res = DISP_E_TYPEMISMATCH;
1400	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1401	break;
1402	}
1403	break;
1404
1405	case( VT_BOOL ):
1406	switch( vtFrom )
1407	{
1408	case( VT_EMPTY ):
1409	res = S_OK;
1410	V_UNION(pd,boolVal) = VARIANT_FALSE;
1411	break;
1412	case( VT_I1 ):
1413	res = VarBoolFromI1( V_UNION(ps,cVal), &V_UNION(pd,boolVal) );
1414	break;
1415	case( VT_I2 ):
1416	res = VarBoolFromI2( V_UNION(ps,iVal), &V_UNION(pd,boolVal) );
1417	break;
1418	case( VT_INT ):
1419	res = VarBoolFromInt( V_UNION(ps,intVal), &V_UNION(pd,boolVal) );
1420	break;
1421	case( VT_I4 ):
1422	res = VarBoolFromI4( V_UNION(ps,lVal), &V_UNION(pd,boolVal) );
1423	break;
1424	case( VT_UI1 ):
1425	res = VarBoolFromUI1( V_UNION(ps,bVal), &V_UNION(pd,boolVal) );
1426	break;
1427	case( VT_UI2 ):
1428	res = VarBoolFromUI2( V_UNION(ps,uiVal), &V_UNION(pd,boolVal) );
1429	break;
1430	case( VT_UINT ):
1431	res = VarBoolFromUint( V_UNION(ps,uintVal), &V_UNION(pd,boolVal) );
1432	break;
1433	case( VT_UI4 ):
1434	res = VarBoolFromUI4( V_UNION(ps,ulVal), &V_UNION(pd,boolVal) );
1435	break;
1436	case( VT_R4 ):
1437	res = VarBoolFromR4( V_UNION(ps,fltVal), &V_UNION(pd,boolVal) );
1438	break;
1439	case( VT_R8 ):
1440	res = VarBoolFromR8( V_UNION(ps,dblVal), &V_UNION(pd,boolVal) );
1441	break;
1442	case( VT_DATE ):
1443	res = VarBoolFromDate( V_UNION(ps,date), &V_UNION(pd,boolVal) );
1444	break;
1445	case( VT_BOOL ):
1446	res = VariantCopy( pd, ps );
1447	break;
1448	case( VT_BSTR ):
1449	res = VarBoolFromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,boolVal) );
1450	break;
1451	case( VT_CY ):
1452	res = VarBoolFromCy( V_UNION(ps,cyVal), &V_UNION(pd,boolVal) );
1453	break;
1454	case( VT_DISPATCH ):
1455	/res = VarBoolFromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,boolVal) );/
1456	case( VT_DECIMAL ):
1457	/res = VarBoolFromDec( V_UNION(ps,deiVal), &V_UNION(pd,boolVal) );/
1458	case( VT_UNKNOWN ):
1459	default:
1460	res = DISP_E_TYPEMISMATCH;
1461	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1462	break;
1463	}
1464	break;
1465
1466	case( VT_BSTR ):
1467	switch( vtFrom )
1468	{
1469	case( VT_EMPTY ):
1470	if ((V_UNION(pd,bstrVal) = SysAllocStringLen(NULL, 0)))
1471	res = S_OK;
1472	else
1473	res = E_OUTOFMEMORY;
1474	break;
1475	case( VT_I1 ):
1476	res = VarBstrFromI1( V_UNION(ps,cVal), lcid, 0, &V_UNION(pd,bstrVal) );
1477	break;
1478	case( VT_I2 ):
1479	res = VarBstrFromI2( V_UNION(ps,iVal), lcid, 0, &V_UNION(pd,bstrVal) );
1480	break;
1481	case( VT_INT ):
1482	res = VarBstrFromInt( V_UNION(ps,intVal), lcid, 0, &V_UNION(pd,bstrVal) );
1483	break;
1484	case( VT_I4 ):
1485	res = VarBstrFromI4( V_UNION(ps,lVal), lcid, 0, &V_UNION(pd,bstrVal) );
1486	break;
1487	case( VT_UI1 ):
1488	res = VarBstrFromUI1( V_UNION(ps,bVal), lcid, 0, &V_UNION(pd,bstrVal) );
1489	break;
1490	case( VT_UI2 ):
1491	res = VarBstrFromUI2( V_UNION(ps,uiVal), lcid, 0, &V_UNION(pd,bstrVal) );
1492	break;
1493	case( VT_UINT ):
1494	res = VarBstrFromUint( V_UNION(ps,uintVal), lcid, 0, &V_UNION(pd,bstrVal) );
1495	break;
1496	case( VT_UI4 ):
1497	res = VarBstrFromUI4( V_UNION(ps,ulVal), lcid, 0, &V_UNION(pd,bstrVal) );
1498	break;
1499	case( VT_R4 ):
1500	res = VarBstrFromR4( V_UNION(ps,fltVal), lcid, 0, &V_UNION(pd,bstrVal) );
1501	break;
1502	case( VT_R8 ):
1503	res = VarBstrFromR8( V_UNION(ps,dblVal), lcid, 0, &V_UNION(pd,bstrVal) );
1504	break;
1505	case( VT_DATE ):
1506	res = VarBstrFromDate( V_UNION(ps,date), lcid, 0, &V_UNION(pd,bstrVal) );
1507	break;
1508	case( VT_BOOL ):
1509	res = VarBstrFromBool( V_UNION(ps,boolVal), lcid, 0, &V_UNION(pd,bstrVal) );
1510	break;
1511	case( VT_BSTR ):
1512	res = VariantCopy( pd, ps );
1513	break;
1514	case( VT_CY ):
1515	res = VarBstrFromCy( V_UNION(ps,cyVal), lcid, 0, &V_UNION(pd,bstrVal) );
1516	break;
1517	case( VT_DISPATCH ):
1518	/res = VarBstrFromDisp( V_UNION(ps,pdispVal), lcid, 0, &(pd,bstrVal) );/
1519	case( VT_DECIMAL ):
1520	/res = VarBstrFromDec( V_UNION(ps,deiVal), lcid, 0, &(pd,bstrVal) );/
1521	case( VT_UNKNOWN ):
1522	default:
1523	res = DISP_E_TYPEMISMATCH;
1524	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1525	break;
1526	}
1527	break;
1528
1529	case( VT_CY ):
1530	switch( vtFrom )
1531	{
1532	case( VT_I1 ):
1533	res = VarCyFromI1( V_UNION(ps,cVal), &V_UNION(pd,cyVal) );
1534	break;
1535	case( VT_I2 ):
1536	res = VarCyFromI2( V_UNION(ps,iVal), &V_UNION(pd,cyVal) );
1537	break;
1538	case( VT_INT ):
1539	res = VarCyFromInt( V_UNION(ps,intVal), &V_UNION(pd,cyVal) );
1540	break;
1541	case( VT_I4 ):
1542	res = VarCyFromI4( V_UNION(ps,lVal), &V_UNION(pd,cyVal) );
1543	break;
1544	case( VT_UI1 ):
1545	res = VarCyFromUI1( V_UNION(ps,bVal), &V_UNION(pd,cyVal) );
1546	break;
1547	case( VT_UI2 ):
1548	res = VarCyFromUI2( V_UNION(ps,uiVal), &V_UNION(pd,cyVal) );
1549	break;
1550	case( VT_UINT ):
1551	res = VarCyFromUint( V_UNION(ps,uintVal), &V_UNION(pd,cyVal) );
1552	break;
1553	case( VT_UI4 ):
1554	res = VarCyFromUI4( V_UNION(ps,ulVal), &V_UNION(pd,cyVal) );
1555	break;
1556	case( VT_R4 ):
1557	res = VarCyFromR4( V_UNION(ps,fltVal), &V_UNION(pd,cyVal) );
1558	break;
1559	case( VT_R8 ):
1560	res = VarCyFromR8( V_UNION(ps,dblVal), &V_UNION(pd,cyVal) );
1561	break;
1562	case( VT_DATE ):
1563	res = VarCyFromDate( V_UNION(ps,date), &V_UNION(pd,cyVal) );
1564	break;
1565	case( VT_BOOL ):
1566	res = VarCyFromBool( V_UNION(ps,date), &V_UNION(pd,cyVal) );
1567	break;
1568	case( VT_CY ):
1569	res = VariantCopy( pd, ps );
1570	break;
1571	case( VT_BSTR ):
1572	res = VarCyFromStr( V_UNION(ps,bstrVal), lcid, 0, &V_UNION(pd,cyVal) );
1573	break;
1574	case( VT_DISPATCH ):
1575	/res = VarCyFromDisp( V_UNION(ps,pdispVal), lcid, &V_UNION(pd,cyVal) );/
1576	case( VT_DECIMAL ):
1577	/res = VarCyFromDec( V_UNION(ps,deiVal), &V_UNION(pd,cyVal) );/
1578	break;
1579	case( VT_UNKNOWN ):
1580	default:
1581	res = DISP_E_TYPEMISMATCH;
1582	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1583	break;
1584	}
1585	break;
1586
1587	case( VT_UNKNOWN ):
1588	if (vtFrom == VT_DISPATCH)
1589	{
1590	res = IDispatch_QueryInterface(V_DISPATCH(ps), &IID_IUnknown, (LPVOID*)&V_UNKNOWN(pd));
1591	}
1592	else
1593	{
1594	res = DISP_E_TYPEMISMATCH;
1595	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1596	}
1597	break;
1598
1599	default:
1600	res = DISP_E_TYPEMISMATCH;
1601	FIXME("Coercion from %d to %d\n", vtFrom, vt );
1602	break;
1603	}
1604
1605	return res;
1606	}
1607
1608	/******************************************************************************
1609	* ValidateVtRange [INTERNAL]
1610	*
1611	* Used internally by the hi-level Variant API to determine
1612	* if the vartypes are valid.
1613	*/
1614	static HRESULT WINAPI ValidateVtRange( VARTYPE vt )
1615	{
1616	/* if by value we must make sure it is in the
1617	* range of the valid types.
1618	*/
1619	if( ( vt & VT_TYPEMASK ) > VT_MAXVALIDTYPE )
1620	{
1621	return DISP_E_BADVARTYPE;
1622	}
1623	return S_OK;
1624	}
1625
1626
1627	/******************************************************************************
1628	* ValidateVartype [INTERNAL]
1629	*
1630	* Used internally by the hi-level Variant API to determine
1631	* if the vartypes are valid.
1632	*/
1633	static HRESULT WINAPI ValidateVariantType( VARTYPE vt )
1634	{
1635	HRESULT res = S_OK;
1636
1637	/* check if we have a valid argument.
1638	*/
1639	if( vt & VT_BYREF )
1640	{
1641	/* if by reference check that the type is in
1642	* the valid range and that it is not of empty or null type
1643	*/
1644	if( ( vt & VT_TYPEMASK ) == VT_EMPTY \|\|
1645	( vt & VT_TYPEMASK ) == VT_NULL \|\|
1646	( vt & VT_TYPEMASK ) > VT_MAXVALIDTYPE )
1647	{
1648	res = E_INVALIDARG;
1649	}
1650
1651	}
1652	else
1653	{
1654	res = ValidateVtRange( vt );
1655	}
1656
1657	return res;
1658	}
1659
1660	/******************************************************************************
1661	* ValidateVt [INTERNAL]
1662	*
1663	* Used internally by the hi-level Variant API to determine
1664	* if the vartypes are valid.
1665	*/
1666	static HRESULT WINAPI ValidateVt( VARTYPE vt )
1667	{
1668	HRESULT res = S_OK;
1669
1670	/* check if we have a valid argument.
1671	*/
1672	if( vt & VT_BYREF )
1673	{
1674	/* if by reference check that the type is in
1675	* the valid range and that it is not of empty or null type
1676	*/
1677	if( ( vt & VT_TYPEMASK ) == VT_EMPTY \|\|
1678	( vt & VT_TYPEMASK ) == VT_NULL \|\|
1679	( vt & VT_TYPEMASK ) > VT_MAXVALIDTYPE )
1680	{
1681	res = DISP_E_BADVARTYPE;
1682	}
1683
1684	}
1685	else
1686	{
1687	res = ValidateVtRange( vt );
1688	}
1689
1690	return res;
1691	}
1692
1693
1694
1695
1696
1697	/******************************************************************************
1698	* VariantInit [OLEAUT32.8]
1699	*
1700	* Initializes the Variant. Unlike VariantClear it does not interpret
1701	* the current contents of the Variant.
1702	*/
1703	void WINAPI VariantInit(VARIANTARG* pvarg)
1704	{
1705	TRACE("(%p)\n",pvarg);
1706
1707	memset(pvarg, 0, sizeof (VARIANTARG));
1708	V_VT(pvarg) = VT_EMPTY;
1709
1710	return;
1711	}
1712
1713	/******************************************************************************
1714	* VariantClear [OLEAUT32.9]
1715	*
1716	* This function clears the VARIANT by setting the vt field to VT_EMPTY. It also
1717	* sets the wReservedX field to 0. The current contents of the VARIANT are
1718	* freed. If the vt is VT_BSTR the string is freed. If VT_DISPATCH the object is
1719	* released. If VT_ARRAY the array is freed.
1720	*/
1721	HRESULT WINAPI VariantClear(VARIANTARG* pvarg)
1722	{
1723	HRESULT res = S_OK;
1724	TRACE("(%p)\n",pvarg);
1725
1726	res = ValidateVariantType( V_VT(pvarg) );
1727	if( res == S_OK )
1728	{
1729	if( !( V_VT(pvarg) & VT_BYREF ) )
1730	{
1731	/*
1732	* The VT_ARRAY flag is a special case of a safe array.
1733	*/
1734	if ( (V_VT(pvarg) & VT_ARRAY) != 0)
1735	{
1736	SafeArrayDestroy(V_UNION(pvarg,parray));
1737	}
1738	else
1739	{
1740	switch( V_VT(pvarg) & VT_TYPEMASK )
1741	{
1742	case( VT_BSTR ):
1743	SysFreeString( V_UNION(pvarg,bstrVal) );
1744	break;
1745	case( VT_DISPATCH ):
1746	if(V_UNION(pvarg,pdispVal)!=NULL)
1747	ICOM_CALL(Release,V_UNION(pvarg,pdispVal));
1748	break;
1749	case( VT_VARIANT ):
1750	VariantClear(V_UNION(pvarg,pvarVal));
1751	break;
1752	case( VT_UNKNOWN ):
1753	if(V_UNION(pvarg,punkVal)!=NULL)
1754	ICOM_CALL(Release,V_UNION(pvarg,punkVal));
1755	break;
1756	case( VT_SAFEARRAY ):
1757	SafeArrayDestroy(V_UNION(pvarg,parray));
1758	break;
1759	default:
1760	break;
1761	}
1762	}
1763	}
1764
1765	/*
1766	* Empty all the fields and mark the type as empty.
1767	*/
1768	memset(pvarg, 0, sizeof (VARIANTARG));
1769	V_VT(pvarg) = VT_EMPTY;
1770	}
1771
1772	return res;
1773	}
1774
1775	/******************************************************************************
1776	* VariantCopy [OLEAUT32.10]
1777	*
1778	* Frees up the designation variant and makes a copy of the source.
1779	*/
1780	HRESULT WINAPI VariantCopy(VARIANTARG* pvargDest, VARIANTARG* pvargSrc)
1781	{
1782	HRESULT res = S_OK;
1783
1784	TRACE("(%p, %p), vt=%d\n", pvargDest, pvargSrc, V_VT(pvargSrc));
1785
1786	res = ValidateVariantType( V_VT(pvargSrc) );
1787
1788	/* If the pointer are to the same variant we don't need
1789	* to do anything.
1790	*/
1791	if( pvargDest != pvargSrc && res == S_OK )
1792	{
1793	res = VariantClear( pvargDest );
1794
1795	if( res == S_OK )
1796	{
1797	if( V_VT(pvargSrc) & VT_BYREF )
1798	{
1799	/* In the case of byreference we only need
1800	* to copy the pointer.
1801	*/
1802	pvargDest->n1.n2.n3 = pvargSrc->n1.n2.n3;
1803	V_VT(pvargDest) = V_VT(pvargSrc);
1804	}
1805	else
1806	{
1807	/*
1808	* The VT_ARRAY flag is another way to designate a safe array.
1809	*/
1810	if (V_VT(pvargSrc) & VT_ARRAY)
1811	{
1812	SafeArrayCopy(V_UNION(pvargSrc,parray), &V_UNION(pvargDest,parray));
1813	}
1814	else
1815	{
1816	/* In the case of by value we need to
1817	* copy the actual value. In the case of
1818	* VT_BSTR a copy of the string is made,
1819	* if VT_DISPATCH or VT_IUNKNOWN AddRef is
1820	* called to increment the object's reference count.
1821	*/
1822	switch( V_VT(pvargSrc) & VT_TYPEMASK )
1823	{
1824	case( VT_BSTR ):
1825	V_UNION(pvargDest,bstrVal) = SYSDUPSTRING( V_UNION(pvargSrc,bstrVal) );
1826	break;
1827	case( VT_DISPATCH ):
1828	V_UNION(pvargDest,pdispVal) = V_UNION(pvargSrc,pdispVal);
1829	if (V_UNION(pvargDest,pdispVal)!=NULL)
1830	ICOM_CALL(AddRef,V_UNION(pvargDest,pdispVal));
1831	break;
1832	case( VT_VARIANT ):
1833	VariantCopy(V_UNION(pvargDest,pvarVal),V_UNION(pvargSrc,pvarVal));
1834	break;
1835	case( VT_UNKNOWN ):
1836	V_UNION(pvargDest,punkVal) = V_UNION(pvargSrc,punkVal);
1837	if (V_UNION(pvargDest,pdispVal)!=NULL)
1838	ICOM_CALL(AddRef,V_UNION(pvargDest,punkVal));
1839	break;
1840	case( VT_SAFEARRAY ):
1841	SafeArrayCopy(V_UNION(pvargSrc,parray), &V_UNION(pvargDest,parray));
1842	break;
1843	default:
1844	pvargDest->n1.n2.n3 = pvargSrc->n1.n2.n3;
1845	break;
1846	}
1847	}
1848
1849	V_VT(pvargDest) = V_VT(pvargSrc);
1850	}
1851	}
1852	}
1853
1854	return res;
1855	}
1856
1857
1858	/******************************************************************************
1859	* VariantCopyInd [OLEAUT32.11]
1860	*
1861	* Frees up the destination variant and makes a copy of the source. If
1862	* the source is of type VT_BYREF it performs the necessary indirections.
1863	*/
1864	HRESULT WINAPI VariantCopyInd(VARIANT* pvargDest, VARIANTARG* pvargSrc)
1865	{
1866	HRESULT res = S_OK;
1867
1868	TRACE("(%p, %p)\n", pvargDest, pvargSrc);
1869
1870	res = ValidateVariantType( V_VT(pvargSrc) );
1871
1872	if( res != S_OK )
1873	return res;
1874
1875	if( V_VT(pvargSrc) & VT_BYREF )
1876	{
1877	VARIANTARG varg;
1878	VariantInit( &varg );
1879
1880	/* handle the in place copy.
1881	*/
1882	if( pvargDest == pvargSrc )
1883	{
1884	/* we will use a copy of the source instead.
1885	*/
1886	res = VariantCopy( &varg, pvargSrc );
1887	pvargSrc = &varg;
1888	}
1889
1890	if( res == S_OK )
1891	{
1892	res = VariantClear( pvargDest );
1893
1894	if( res == S_OK )
1895	{
1896	/*
1897	* The VT_ARRAY flag is another way to designate a safearray variant.
1898	*/
1899	if ( V_VT(pvargSrc) & VT_ARRAY)
1900	{
1901	SafeArrayCopy(*V_UNION(pvargSrc,pparray), &V_UNION(pvargDest,parray));
1902	}
1903	else
1904	{
1905	/* In the case of by reference we need
1906	* to copy the date pointed to by the variant.
1907	*/
1908
1909	/* Get the variant type.
1910	*/
1911	switch( V_VT(pvargSrc) & VT_TYPEMASK )
1912	{
1913	case( VT_BSTR ):
1914	V_UNION(pvargDest,bstrVal) = SYSDUPSTRING( *(V_UNION(pvargSrc,pbstrVal)) );
1915	break;
1916	case( VT_DISPATCH ):
1917	break;
1918	case( VT_VARIANT ):
1919	{
1920	/* Prevent from cycling. According to tests on
1921	* VariantCopyInd in Windows and the documentation
1922	* this API dereferences the inner Variants to only one depth.
1923	* If the inner Variant itself contains an
1924	* other inner variant the E_INVALIDARG error is
1925	* returned.
1926	*/
1927	if( pvargSrc->n1.n2.wReserved1 & PROCESSING_INNER_VARIANT )
1928	{
1929	/* If we get here we are attempting to deference
1930	* an inner variant that that is itself contained
1931	* in an inner variant so report E_INVALIDARG error.
1932	*/
1933	res = E_INVALIDARG;
1934	}
1935	else
1936	{
1937	/* Set the processing inner variant flag.
1938	* We will set this flag in the inner variant
1939	* that will be passed to the VariantCopyInd function.
1940	*/
1941	(V_UNION(pvargSrc,pvarVal))->n1.n2.wReserved1 \|= PROCESSING_INNER_VARIANT;
1942
1943	/* Dereference the inner variant.
1944	*/
1945	res = VariantCopyInd( pvargDest, V_UNION(pvargSrc,pvarVal) );
1946	/* We must also copy its type, I think.
1947	*/
1948	V_VT(pvargSrc) = V_VT(V_UNION(pvargSrc,pvarVal));
1949	}
1950	}
1951	break;
1952	case( VT_UNKNOWN ):
1953	break;
1954	case( VT_SAFEARRAY ):
1955	SafeArrayCopy(*V_UNION(pvargSrc,pparray), &V_UNION(pvargDest,parray));
1956	break;
1957	default:
1958	/* This is a by reference Variant which means that the union
1959	* part of the Variant contains a pointer to some data of
1960	* type "V_VT(pvargSrc) & VT_TYPEMASK".
1961	* We will deference this data in a generic fashion using
1962	* the void pointer "Variant.u.byref".
1963	* We will copy this data into the union of the destination
1964	* Variant.
1965	*/
1966	memcpy( &pvargDest->n1.n2.n3, V_UNION(pvargSrc,byref), SizeOfVariantData( pvargSrc ) );
1967	break;
1968	}
1969	}
1970
1971	V_VT(pvargDest) = V_VT(pvargSrc) & VT_TYPEMASK;
1972	}
1973	}
1974
1975	/* this should not fail.
1976	*/
1977	VariantClear( &varg );
1978	}
1979	else
1980	{
1981	res = VariantCopy( pvargDest, pvargSrc );
1982	}
1983
1984	return res;
1985	}
1986
1987	/******************************************************************************
1988	* VariantChangeType [OLEAUT32.12]
1989	*/
1990	HRESULT WINAPI VariantChangeType(VARIANTARG* pvargDest, VARIANTARG* pvargSrc,
1991	USHORT wFlags, VARTYPE vt)
1992	{
1993	return VariantChangeTypeEx( pvargDest, pvargSrc, 0, wFlags, vt );
1994	}
1995
1996	/******************************************************************************
1997	* VariantChangeTypeEx [OLEAUT32.147]
1998	*/
1999	HRESULT WINAPI VariantChangeTypeEx(VARIANTARG* pvargDest, VARIANTARG* pvargSrc,
2000	LCID lcid, USHORT wFlags, VARTYPE vt)
2001	{
2002	HRESULT res = S_OK;
2003	VARIANTARG varg;
2004	VariantInit( &varg );
2005
2006	TRACE("(%p, %p, %ld, %u, %u) vt=%d\n", pvargDest, pvargSrc, lcid, wFlags, vt, V_VT(pvargSrc));
2007
2008	/* validate our source argument.
2009	*/
2010	res = ValidateVariantType( V_VT(pvargSrc) );
2011
2012	/* validate the vartype.
2013	*/
2014	if( res == S_OK )
2015	{
2016	res = ValidateVt( vt );
2017	}
2018
2019	/* if we are doing an in-place conversion make a copy of the source.
2020	*/
2021	if( res == S_OK && pvargDest == pvargSrc )
2022	{
2023	res = VariantCopy( &varg, pvargSrc );
2024	pvargSrc = &varg;
2025	}
2026
2027	if( res == S_OK )
2028	{
2029	/* free up the destination variant.
2030	*/
2031	res = VariantClear( pvargDest );
2032	}
2033
2034	if( res == S_OK )
2035	{
2036	if( V_VT(pvargSrc) & VT_BYREF )
2037	{
2038	/* Convert the source variant to a "byvalue" variant.
2039	*/
2040	VARIANTARG Variant;
2041	VariantInit( &Variant );
2042	res = VariantCopyInd( &Variant, pvargSrc );
2043	if( res == S_OK )
2044	{
2045	res = Coerce( pvargDest, lcid, wFlags, &Variant, vt );
2046	/* this should not fail.
2047	*/
2048	VariantClear( &Variant );
2049	}
2050
2051	}
2052	else
2053	{
2054	/* Use the current "byvalue" source variant.
2055	*/
2056	res = Coerce( pvargDest, lcid, wFlags, pvargSrc, vt );
2057	}
2058	}
2059	/* this should not fail.
2060	*/
2061	VariantClear( &varg );
2062
2063	/* set the type of the destination
2064	*/
2065	if ( res == S_OK )
2066	V_VT(pvargDest) = vt;
2067
2068	return res;
2069	}
2070
2071
2072
2073
2074	/******************************************************************************
2075	* VarUI1FromI2 [OLEAUT32.130]
2076	*/
2077	HRESULT WINAPI VarUI1FromI2(short sIn, BYTE* pbOut)
2078	{
2079	TRACE("( %d, %p ), stub\n", sIn, pbOut );
2080
2081	/* Check range of value.
2082	*/
2083	if( sIn < UI1_MIN \|\| sIn > UI1_MAX )
2084	{
2085	return DISP_E_OVERFLOW;
2086	}
2087
2088	*pbOut = (BYTE) sIn;
2089
2090	return S_OK;
2091	}
2092
2093	/******************************************************************************
2094	* VarUI1FromI4 [OLEAUT32.131]
2095	*/
2096	HRESULT WINAPI VarUI1FromI4(LONG lIn, BYTE* pbOut)
2097	{
2098	TRACE("( %ld, %p ), stub\n", lIn, pbOut );
2099
2100	/* Check range of value.
2101	*/
2102	if( lIn < UI1_MIN \|\| lIn > UI1_MAX )
2103	{
2104	return DISP_E_OVERFLOW;
2105	}
2106
2107	*pbOut = (BYTE) lIn;
2108
2109	return S_OK;
2110	}
2111
2112
2113	/******************************************************************************
2114	* VarUI1FromR4 [OLEAUT32.132]
2115	*/
2116	HRESULT WINAPI VarUI1FromR4(FLOAT fltIn, BYTE* pbOut)
2117	{
2118	TRACE("( %f, %p ), stub\n", fltIn, pbOut );
2119
2120	/* Check range of value.
2121	*/
2122	fltIn = round( fltIn );
2123	if( fltIn < UI1_MIN \|\| fltIn > UI1_MAX )
2124	{
2125	return DISP_E_OVERFLOW;
2126	}
2127
2128	*pbOut = (BYTE) fltIn;
2129
2130	return S_OK;
2131	}
2132
2133	/******************************************************************************
2134	* VarUI1FromR8 [OLEAUT32.133]
2135	*/
2136	HRESULT WINAPI VarUI1FromR8(double dblIn, BYTE* pbOut)
2137	{
2138	TRACE("( %f, %p ), stub\n", dblIn, pbOut );
2139
2140	/* Check range of value.
2141	*/
2142	dblIn = round( dblIn );
2143	if( dblIn < UI1_MIN \|\| dblIn > UI1_MAX )
2144	{
2145	return DISP_E_OVERFLOW;
2146	}
2147
2148	*pbOut = (BYTE) dblIn;
2149
2150	return S_OK;
2151	}
2152
2153	/******************************************************************************
2154	* VarUI1FromDate [OLEAUT32.135]
2155	*/
2156	HRESULT WINAPI VarUI1FromDate(DATE dateIn, BYTE* pbOut)
2157	{
2158	TRACE("( %f, %p ), stub\n", dateIn, pbOut );
2159
2160	/* Check range of value.
2161	*/
2162	dateIn = round( dateIn );
2163	if( dateIn < UI1_MIN \|\| dateIn > UI1_MAX )
2164	{
2165	return DISP_E_OVERFLOW;
2166	}
2167
2168	*pbOut = (BYTE) dateIn;
2169
2170	return S_OK;
2171	}
2172
2173	/******************************************************************************
2174	* VarUI1FromBool [OLEAUT32.138]
2175	*/
2176	HRESULT WINAPI VarUI1FromBool(VARIANT_BOOL boolIn, BYTE* pbOut)
2177	{
2178	TRACE("( %d, %p ), stub\n", boolIn, pbOut );
2179
2180	*pbOut = (BYTE) boolIn;
2181
2182	return S_OK;
2183	}
2184
2185	/******************************************************************************
2186	* VarUI1FromI1 [OLEAUT32.237]
2187	*/
2188	HRESULT WINAPI VarUI1FromI1(CHAR cIn, BYTE* pbOut)
2189	{
2190	TRACE("( %c, %p ), stub\n", cIn, pbOut );
2191
2192	*pbOut = cIn;
2193
2194	return S_OK;
2195	}
2196
2197	/******************************************************************************
2198	* VarUI1FromUI2 [OLEAUT32.238]
2199	*/
2200	HRESULT WINAPI VarUI1FromUI2(USHORT uiIn, BYTE* pbOut)
2201	{
2202	TRACE("( %d, %p ), stub\n", uiIn, pbOut );
2203
2204	/* Check range of value.
2205	*/
2206	if( uiIn > UI1_MAX )
2207	{
2208	return DISP_E_OVERFLOW;
2209	}
2210
2211	*pbOut = (BYTE) uiIn;
2212
2213	return S_OK;
2214	}
2215
2216	/******************************************************************************
2217	* VarUI1FromUI4 [OLEAUT32.239]
2218	*/
2219	HRESULT WINAPI VarUI1FromUI4(ULONG ulIn, BYTE* pbOut)
2220	{
2221	TRACE("( %ld, %p ), stub\n", ulIn, pbOut );
2222
2223	/* Check range of value.
2224	*/
2225	if( ulIn > UI1_MAX )
2226	{
2227	return DISP_E_OVERFLOW;
2228	}
2229
2230	*pbOut = (BYTE) ulIn;
2231
2232	return S_OK;
2233	}
2234
2235
2236	/******************************************************************************
2237	* VarUI1FromStr [OLEAUT32.136]
2238	*/
2239	HRESULT WINAPI VarUI1FromStr(OLECHAR* strIn, LCID lcid, ULONG dwFlags, BYTE* pbOut)
2240	{
2241	double dValue = 0.0;
2242	LPSTR pNewString = NULL;
2243
2244	TRACE("( %p, 0x%08lx, 0x%08lx, %p ), stub\n", strIn, lcid, dwFlags, pbOut );
2245
2246	/* Check if we have a valid argument
2247	*/
2248	pNewString = HEAP_strdupWtoA( GetProcessHeap(), 0, strIn );
2249	RemoveCharacterFromString( pNewString, "," );
2250	if( IsValidRealString( pNewString ) == FALSE )
2251	{
2252	return DISP_E_TYPEMISMATCH;
2253	}
2254
2255	/* Convert the valid string to a floating point number.
2256	*/
2257	dValue = atof( pNewString );
2258
2259	/* We don't need the string anymore so free it.
2260	*/
2261	HeapFree( GetProcessHeap(), 0 , pNewString );
2262
2263	/* Check range of value.
2264	*/
2265	dValue = round( dValue );
2266	if( dValue < UI1_MIN \|\| dValue > UI1_MAX )
2267	{
2268	return DISP_E_OVERFLOW;
2269	}
2270
2271	*pbOut = (BYTE) dValue;
2272
2273	return S_OK;
2274	}
2275
2276	/**********************************************************************
2277	* VarUI1FromCy [OLEAUT32.134]
2278	* Convert currency to unsigned char
2279	*/
2280	HRESULT WINAPI VarUI1FromCy(CY cyIn, BYTE* pbOut) {
2281	double t = round((((double)cyIn.s.Hi * 4294967296.0) + (double)cyIn.s.Lo) / 10000);
2282
2283	if (t > UI1_MAX \|\| t < UI1_MIN) return DISP_E_OVERFLOW;
2284
2285	*pbOut = (BYTE)t;
2286	return S_OK;
2287	}
2288
2289	/******************************************************************************
2290	* VarI2FromUI1 [OLEAUT32.48]
2291	*/
2292	HRESULT WINAPI VarI2FromUI1(BYTE bIn, short* psOut)
2293	{
2294	TRACE("( 0x%08x, %p ), stub\n", bIn, psOut );
2295
2296	*psOut = (short) bIn;
2297
2298	return S_OK;
2299	}
2300
2301	/******************************************************************************
2302	* VarI2FromI4 [OLEAUT32.49]
2303	*/
2304	HRESULT WINAPI VarI2FromI4(LONG lIn, short* psOut)
2305	{
2306	TRACE("( %lx, %p ), stub\n", lIn, psOut );
2307
2308	/* Check range of value.
2309	*/
2310	if( lIn < I2_MIN \|\| lIn > I2_MAX )
2311	{
2312	return DISP_E_OVERFLOW;
2313	}
2314
2315	*psOut = (short) lIn;
2316
2317	return S_OK;
2318	}
2319
2320	/******************************************************************************
2321	* VarI2FromR4 [OLEAUT32.50]
2322	*/
2323	HRESULT WINAPI VarI2FromR4(FLOAT fltIn, short* psOut)
2324	{
2325	TRACE("( %f, %p ), stub\n", fltIn, psOut );
2326
2327	/* Check range of value.
2328	*/
2329	fltIn = round( fltIn );
2330	if( fltIn < I2_MIN \|\| fltIn > I2_MAX )
2331	{
2332	return DISP_E_OVERFLOW;
2333	}
2334
2335	*psOut = (short) fltIn;
2336
2337	return S_OK;
2338	}
2339
2340	/******************************************************************************
2341	* VarI2FromR8 [OLEAUT32.51]
2342	*/
2343	HRESULT WINAPI VarI2FromR8(double dblIn, short* psOut)
2344	{
2345	TRACE("( %f, %p ), stub\n", dblIn, psOut );
2346
2347	/* Check range of value.
2348	*/
2349	dblIn = round( dblIn );
2350	if( dblIn < I2_MIN \|\| dblIn > I2_MAX )
2351	{
2352	return DISP_E_OVERFLOW;
2353	}
2354
2355	*psOut = (short) dblIn;
2356
2357	return S_OK;
2358	}
2359
2360	/******************************************************************************
2361	* VarI2FromDate [OLEAUT32.53]
2362	*/
2363	HRESULT WINAPI VarI2FromDate(DATE dateIn, short* psOut)
2364	{
2365	TRACE("( %f, %p ), stub\n", dateIn, psOut );
2366
2367	/* Check range of value.
2368	*/
2369	dateIn = round( dateIn );
2370	if( dateIn < I2_MIN \|\| dateIn > I2_MAX )
2371	{
2372	return DISP_E_OVERFLOW;
2373	}
2374
2375	*psOut = (short) dateIn;
2376
2377	return S_OK;
2378	}
2379
2380	/******************************************************************************
2381	* VarI2FromBool [OLEAUT32.56]
2382	*/
2383	HRESULT WINAPI VarI2FromBool(VARIANT_BOOL boolIn, short* psOut)
2384	{
2385	TRACE("( %d, %p ), stub\n", boolIn, psOut );
2386
2387	*psOut = (short) boolIn;
2388
2389	return S_OK;
2390	}
2391
2392	/******************************************************************************
2393	* VarI2FromI1 [OLEAUT32.205]
2394	*/
2395	HRESULT WINAPI VarI2FromI1(CHAR cIn, short* psOut)
2396	{
2397	TRACE("( %c, %p ), stub\n", cIn, psOut );
2398
2399	*psOut = (short) cIn;
2400
2401	return S_OK;
2402	}
2403
2404	/******************************************************************************
2405	* VarI2FromUI2 [OLEAUT32.206]
2406	*/
2407	HRESULT WINAPI VarI2FromUI2(USHORT uiIn, short* psOut)
2408	{
2409	TRACE("( %d, %p ), stub\n", uiIn, psOut );
2410
2411	/* Check range of value.
2412	*/
2413	if( uiIn > I2_MAX )
2414	{
2415	return DISP_E_OVERFLOW;
2416	}
2417
2418	*psOut = (short) uiIn;
2419
2420	return S_OK;
2421	}
2422
2423	/******************************************************************************
2424	* VarI2FromUI4 [OLEAUT32.207]
2425	*/
2426	HRESULT WINAPI VarI2FromUI4(ULONG ulIn, short* psOut)
2427	{
2428	TRACE("( %lx, %p ), stub\n", ulIn, psOut );
2429
2430	/* Check range of value.
2431	*/
2432	if( ulIn < I2_MIN \|\| ulIn > I2_MAX )
2433	{
2434	return DISP_E_OVERFLOW;
2435	}
2436
2437	*psOut = (short) ulIn;
2438
2439	return S_OK;
2440	}
2441
2442	/******************************************************************************
2443	* VarI2FromStr [OLEAUT32.54]
2444	*/
2445	HRESULT WINAPI VarI2FromStr(OLECHAR* strIn, LCID lcid, ULONG dwFlags, short* psOut)
2446	{
2447	double dValue = 0.0;
2448	LPSTR pNewString = NULL;
2449
2450	TRACE("( %p, 0x%08lx, 0x%08lx, %p ), stub\n", strIn, lcid, dwFlags, psOut );
2451
2452	/* Check if we have a valid argument
2453	*/
2454	pNewString = HEAP_strdupWtoA( GetProcessHeap(), 0, strIn );
2455	RemoveCharacterFromString( pNewString, "," );
2456	if( IsValidRealString( pNewString ) == FALSE )
2457	{
2458	return DISP_E_TYPEMISMATCH;
2459	}
2460
2461	/* Convert the valid string to a floating point number.
2462	*/
2463	dValue = atof( pNewString );
2464
2465	/* We don't need the string anymore so free it.
2466	*/
2467	HeapFree( GetProcessHeap(), 0, pNewString );
2468
2469	/* Check range of value.
2470	*/
2471	dValue = round( dValue );
2472	if( dValue < I2_MIN \|\| dValue > I2_MAX )
2473	{
2474	return DISP_E_OVERFLOW;
2475	}
2476
2477	*psOut = (short) dValue;
2478
2479	return S_OK;
2480	}
2481
2482	/**********************************************************************
2483	* VarI2FromCy [OLEAUT32.52]
2484	* Convert currency to signed short
2485	*/
2486	HRESULT WINAPI VarI2FromCy(CY cyIn, short* psOut) {
2487	double t = round((((double)cyIn.s.Hi * 4294967296.0) + (double)cyIn.s.Lo) / 10000);
2488
2489	if (t > I2_MAX \|\| t < I2_MIN) return DISP_E_OVERFLOW;
2490
2491	*psOut = (SHORT)t;
2492	return S_OK;
2493	}
2494
2495	/******************************************************************************
2496	* VarI4FromUI1 [OLEAUT32.58]
2497	*/
2498	HRESULT WINAPI VarI4FromUI1(BYTE bIn, LONG* plOut)
2499	{
2500	TRACE("( %X, %p ), stub\n", bIn, plOut );
2501
2502	*plOut = (LONG) bIn;
2503
2504	return S_OK;
2505	}
2506
2507
2508	/******************************************************************************
2509	* VarI4FromR4 [OLEAUT32.60]
2510	*/
2511	HRESULT WINAPI VarI4FromR4(FLOAT fltIn, LONG* plOut)
2512	{
2513	TRACE("( %f, %p ), stub\n", fltIn, plOut );
2514
2515	/* Check range of value.
2516	*/
2517	fltIn = round( fltIn );
2518	if( fltIn < I4_MIN \|\| fltIn > I4_MAX )
2519	{
2520	return DISP_E_OVERFLOW;
2521	}
2522
2523	*plOut = (LONG) fltIn;
2524
2525	return S_OK;
2526	}
2527
2528	/******************************************************************************
2529	* VarI4FromR8 [OLEAUT32.61]
2530	*/
2531	HRESULT WINAPI VarI4FromR8(double dblIn, LONG* plOut)
2532	{
2533	TRACE("( %f, %p ), stub\n", dblIn, plOut );
2534
2535	/* Check range of value.
2536	*/
2537	dblIn = round( dblIn );
2538	if( dblIn < I4_MIN \|\| dblIn > I4_MAX )
2539	{
2540	return DISP_E_OVERFLOW;
2541	}
2542
2543	*plOut = (LONG) dblIn;
2544
2545	return S_OK;
2546	}
2547
2548	/******************************************************************************
2549	* VarI4FromDate [OLEAUT32.63]
2550	*/
2551	HRESULT WINAPI VarI4FromDate(DATE dateIn, LONG* plOut)
2552	{
2553	TRACE("( %f, %p ), stub\n", dateIn, plOut );
2554
2555	/* Check range of value.
2556	*/
2557	dateIn = round( dateIn );
2558	if( dateIn < I4_MIN \|\| dateIn > I4_MAX )
2559	{
2560	return DISP_E_OVERFLOW;
2561	}
2562
2563	*plOut = (LONG) dateIn;
2564
2565	return S_OK;
2566	}
2567
2568	/******************************************************************************
2569	* VarI4FromBool [OLEAUT32.66]
2570	*/
2571	HRESULT WINAPI VarI4FromBool(VARIANT_BOOL boolIn, LONG* plOut)
2572	{
2573	TRACE("( %d, %p ), stub\n", boolIn, plOut );
2574
2575	*plOut = (LONG) boolIn;
2576
2577	return S_OK;
2578	}
2579
2580	/******************************************************************************
2581	* VarI4FromI1 [OLEAUT32.209]
2582	*/
2583	HRESULT WINAPI VarI4FromI1(CHAR cIn, LONG* plOut)
2584	{
2585	TRACE("( %c, %p ), stub\n", cIn, plOut );
2586
2587	*plOut = (LONG) cIn;
2588
2589	return S_OK;
2590	}
2591
2592	/******************************************************************************
2593	* VarI4FromUI2 [OLEAUT32.210]
2594	*/
2595	HRESULT WINAPI VarI4FromUI2(USHORT uiIn, LONG* plOut)
2596	{
2597	TRACE("( %d, %p ), stub\n", uiIn, plOut );
2598
2599	*plOut = (LONG) uiIn;
2600
2601	return S_OK;
2602	}
2603
2604	/******************************************************************************
2605	* VarI4FromUI4 [OLEAUT32.211]
2606	*/
2607	HRESULT WINAPI VarI4FromUI4(ULONG ulIn, LONG* plOut)
2608	{
2609	TRACE("( %lx, %p ), stub\n", ulIn, plOut );
2610
2611	/* Check range of value.
2612	*/
2613	if( ulIn < I4_MIN \|\| ulIn > I4_MAX )
2614	{
2615	return DISP_E_OVERFLOW;
2616	}
2617
2618	*plOut = (LONG) ulIn;
2619
2620	return S_OK;
2621	}
2622
2623	/******************************************************************************
2624	* VarI4FromI2 [OLEAUT32.59]
2625	*/
2626	HRESULT WINAPI VarI4FromI2(short sIn, LONG* plOut)
2627	{
2628	TRACE("( %d, %p ), stub\n", sIn, plOut );
2629
2630	*plOut = (LONG) sIn;
2631
2632	return S_OK;
2633	}
2634
2635	/******************************************************************************
2636	* VarI4FromStr [OLEAUT32.64]
2637	*/
2638	HRESULT WINAPI VarI4FromStr(OLECHAR* strIn, LCID lcid, ULONG dwFlags, LONG* plOut)
2639	{
2640	double dValue = 0.0;
2641	LPSTR pNewString = NULL;
2642
2643	TRACE("( %p, 0x%08lx, 0x%08lx, %p ), stub\n", strIn, lcid, dwFlags, plOut );
2644
2645	/* Check if we have a valid argument
2646	*/
2647	pNewString = HEAP_strdupWtoA( GetProcessHeap(), 0, strIn );
2648	RemoveCharacterFromString( pNewString, "," );
2649	if( IsValidRealString( pNewString ) == FALSE )
2650	{
2651	return DISP_E_TYPEMISMATCH;
2652	}
2653
2654	/* Convert the valid string to a floating point number.
2655	*/
2656	dValue = atof( pNewString );
2657
2658	/* We don't need the string anymore so free it.
2659	*/
2660	HeapFree( GetProcessHeap(), 0, pNewString );
2661
2662	/* Check range of value.
2663	*/
2664	dValue = round( dValue );
2665	if( dValue < I4_MIN \|\| dValue > I4_MAX )
2666	{
2667	return DISP_E_OVERFLOW;
2668	}
2669
2670	*plOut = (LONG) dValue;
2671
2672	return S_OK;
2673	}
2674
2675	/**********************************************************************
2676	* VarI4FromCy [OLEAUT32.62]
2677	* Convert currency to signed long
2678	*/
2679	HRESULT WINAPI VarI4FromCy(CY cyIn, LONG* plOut) {
2680	double t = round((((double)cyIn.s.Hi * 4294967296.0) + (double)cyIn.s.Lo) / 10000);
2681
2682	if (t > I4_MAX \|\| t < I4_MIN) return DISP_E_OVERFLOW;
2683
2684	*plOut = (LONG)t;
2685	return S_OK;
2686	}
2687
2688	/******************************************************************************
2689	* VarR4FromUI1 [OLEAUT32.68]
2690	*/
2691	HRESULT WINAPI VarR4FromUI1(BYTE bIn, FLOAT* pfltOut)
2692	{
2693	TRACE("( %X, %p ), stub\n", bIn, pfltOut );
2694
2695	*pfltOut = (FLOAT) bIn;
2696
2697	return S_OK;
2698	}
2699
2700	/******************************************************************************
2701	* VarR4FromI2 [OLEAUT32.69]
2702	*/
2703	HRESULT WINAPI VarR4FromI2(short sIn, FLOAT* pfltOut)
2704	{
2705	TRACE("( %d, %p ), stub\n", sIn, pfltOut );
2706
2707	*pfltOut = (FLOAT) sIn;
2708
2709	return S_OK;
2710	}
2711
2712	/******************************************************************************
2713	* VarR4FromI4 [OLEAUT32.70]
2714	*/
2715	HRESULT WINAPI VarR4FromI4(LONG lIn, FLOAT* pfltOut)
2716	{
2717	TRACE("( %lx, %p ), stub\n", lIn, pfltOut );
2718
2719	*pfltOut = (FLOAT) lIn;
2720
2721	return S_OK;
2722	}
2723
2724	/******************************************************************************
2725	* VarR4FromR8 [OLEAUT32.71]
2726	*/
2727	HRESULT WINAPI VarR4FromR8(double dblIn, FLOAT* pfltOut)
2728	{
2729	TRACE("( %f, %p ), stub\n", dblIn, pfltOut );
2730
2731	/* Check range of value.
2732	*/
2733	if( dblIn < -(FLT_MAX) \|\| dblIn > FLT_MAX )
2734	{
2735	return DISP_E_OVERFLOW;
2736	}
2737
2738	*pfltOut = (FLOAT) dblIn;
2739
2740	return S_OK;
2741	}
2742
2743	/******************************************************************************
2744	* VarR4FromDate [OLEAUT32.73]
2745	*/
2746	HRESULT WINAPI VarR4FromDate(DATE dateIn, FLOAT* pfltOut)
2747	{
2748	TRACE("( %f, %p ), stub\n", dateIn, pfltOut );
2749
2750	/* Check range of value.
2751	*/
2752	if( dateIn < -(FLT_MAX) \|\| dateIn > FLT_MAX )
2753	{
2754	return DISP_E_OVERFLOW;
2755	}
2756
2757	*pfltOut = (FLOAT) dateIn;
2758
2759	return S_OK;
2760	}
2761
2762	/******************************************************************************
2763	* VarR4FromBool [OLEAUT32.76]
2764	*/
2765	HRESULT WINAPI VarR4FromBool(VARIANT_BOOL boolIn, FLOAT* pfltOut)
2766	{
2767	TRACE("( %d, %p ), stub\n", boolIn, pfltOut );
2768
2769	*pfltOut = (FLOAT) boolIn;
2770
2771	return S_OK;
2772	}
2773
2774	/******************************************************************************
2775	* VarR4FromI1 [OLEAUT32.213]
2776	*/
2777	HRESULT WINAPI VarR4FromI1(CHAR cIn, FLOAT* pfltOut)
2778	{
2779	TRACE("( %c, %p ), stub\n", cIn, pfltOut );
2780
2781	*pfltOut = (FLOAT) cIn;
2782
2783	return S_OK;
2784	}
2785
2786	/******************************************************************************
2787	* VarR4FromUI2 [OLEAUT32.214]
2788	*/
2789	HRESULT WINAPI VarR4FromUI2(USHORT uiIn, FLOAT* pfltOut)
2790	{
2791	TRACE("( %d, %p ), stub\n", uiIn, pfltOut );
2792
2793	*pfltOut = (FLOAT) uiIn;
2794
2795	return S_OK;
2796	}
2797
2798	/******************************************************************************
2799	* VarR4FromUI4 [OLEAUT32.215]
2800	*/
2801	HRESULT WINAPI VarR4FromUI4(ULONG ulIn, FLOAT* pfltOut)
2802	{
2803	TRACE("( %ld, %p ), stub\n", ulIn, pfltOut );
2804
2805	*pfltOut = (FLOAT) ulIn;
2806
2807	return S_OK;
2808	}
2809
2810	/******************************************************************************
2811	* VarR4FromStr [OLEAUT32.74]
2812	*/
2813	HRESULT WINAPI VarR4FromStr(OLECHAR* strIn, LCID lcid, ULONG dwFlags, FLOAT* pfltOut)
2814	{
2815	double dValue = 0.0;
2816	LPSTR pNewString = NULL;
2817
2818	TRACE("( %p, %ld, %ld, %p ), stub\n", strIn, lcid, dwFlags, pfltOut );
2819
2820	/* Check if we have a valid argument
2821	*/
2822	pNewString = HEAP_strdupWtoA( GetProcessHeap(), 0, strIn );
2823	RemoveCharacterFromString( pNewString, "," );
2824	if( IsValidRealString( pNewString ) == FALSE )
2825	{
2826	return DISP_E_TYPEMISMATCH;
2827	}
2828
2829	/* Convert the valid string to a floating point number.
2830	*/
2831	dValue = atof( pNewString );
2832
2833	/* We don't need the string anymore so free it.
2834	*/
2835	HeapFree( GetProcessHeap(), 0, pNewString );
2836
2837	/* Check range of value.
2838	*/
2839	if( dValue < -(FLT_MAX) \|\| dValue > FLT_MAX )
2840	{
2841	return DISP_E_OVERFLOW;
2842	}
2843
2844	*pfltOut = (FLOAT) dValue;
2845
2846	return S_OK;
2847	}
2848
2849	/**********************************************************************
2850	* VarR4FromCy [OLEAUT32.72]
2851	* Convert currency to float
2852	*/
2853	HRESULT WINAPI VarR4FromCy(CY cyIn, FLOAT* pfltOut) {
2854	pfltOut = (FLOAT)((((double)cyIn.s.Hi 4294967296.0) + (double)cyIn.s.Lo) / 10000);
2855
2856	return S_OK;
2857	}
2858
2859	/******************************************************************************
2860	* VarR8FromUI1 [OLEAUT32.78]
2861	*/
2862	HRESULT WINAPI VarR8FromUI1(BYTE bIn, double* pdblOut)
2863	{
2864	TRACE("( %d, %p ), stub\n", bIn, pdblOut );
2865
2866	*pdblOut = (double) bIn;
2867
2868	return S_OK;
2869	}
2870
2871	/******************************************************************************
2872	* VarR8FromI2 [OLEAUT32.79]
2873	*/
2874	HRESULT WINAPI VarR8FromI2(short sIn, double* pdblOut)
2875	{
2876	TRACE("( %d, %p ), stub\n", sIn, pdblOut );
2877
2878	*pdblOut = (double) sIn;
2879
2880	return S_OK;
2881	}
2882
2883	/******************************************************************************
2884	* VarR8FromI4 [OLEAUT32.80]
2885	*/
2886	HRESULT WINAPI VarR8FromI4(LONG lIn, double* pdblOut)
2887	{
2888	TRACE("( %ld, %p ), stub\n", lIn, pdblOut );
2889
2890	*pdblOut = (double) lIn;
2891
2892	return S_OK;
2893	}
2894
2895	/******************************************************************************
2896	* VarR8FromR4 [OLEAUT32.81]
2897	*/
2898	HRESULT WINAPI VarR8FromR4(FLOAT fltIn, double* pdblOut)
2899	{
2900	TRACE("( %f, %p ), stub\n", fltIn, pdblOut );
2901
2902	*pdblOut = (double) fltIn;
2903
2904	return S_OK;
2905	}
2906
2907	/******************************************************************************
2908	* VarR8FromDate [OLEAUT32.83]
2909	*/
2910	HRESULT WINAPI VarR8FromDate(DATE dateIn, double* pdblOut)
2911	{
2912	TRACE("( %f, %p ), stub\n", dateIn, pdblOut );
2913
2914	*pdblOut = (double) dateIn;
2915
2916	return S_OK;
2917	}
2918
2919	/******************************************************************************
2920	* VarR8FromBool [OLEAUT32.86]
2921	*/
2922	HRESULT WINAPI VarR8FromBool(VARIANT_BOOL boolIn, double* pdblOut)
2923	{
2924	TRACE("( %d, %p ), stub\n", boolIn, pdblOut );
2925
2926	*pdblOut = (double) boolIn;
2927
2928	return S_OK;
2929	}
2930
2931	/******************************************************************************
2932	* VarR8FromI1 [OLEAUT32.217]
2933	*/
2934	HRESULT WINAPI VarR8FromI1(CHAR cIn, double* pdblOut)
2935	{
2936	TRACE("( %c, %p ), stub\n", cIn, pdblOut );
2937
2938	*pdblOut = (double) cIn;
2939
2940	return S_OK;
2941	}
2942
2943	/******************************************************************************
2944	* VarR8FromUI2 [OLEAUT32.218]
2945	*/
2946	HRESULT WINAPI VarR8FromUI2(USHORT uiIn, double* pdblOut)
2947	{
2948	TRACE("( %d, %p ), stub\n", uiIn, pdblOut );
2949
2950	*pdblOut = (double) uiIn;
2951
2952	return S_OK;
2953	}
2954
2955	/******************************************************************************
2956	* VarR8FromUI4 [OLEAUT32.219]
2957	*/
2958	HRESULT WINAPI VarR8FromUI4(ULONG ulIn, double* pdblOut)
2959	{
2960	TRACE("( %ld, %p ), stub\n", ulIn, pdblOut );
2961
2962	*pdblOut = (double) ulIn;
2963
2964	return S_OK;
2965	}
2966
2967	/******************************************************************************
2968	* VarR8FromStr [OLEAUT32.84]
2969	*/
2970	HRESULT WINAPI VarR8FromStr(OLECHAR* strIn, LCID lcid, ULONG dwFlags, double* pdblOut)
2971	{
2972	double dValue = 0.0;
2973	LPSTR pNewString = NULL;
2974
2975	TRACE("( %p, %ld, %ld, %p ), stub\n", strIn, lcid, dwFlags, pdblOut );
2976
2977	/* Check if we have a valid argument
2978	*/
2979	pNewString = HEAP_strdupWtoA( GetProcessHeap(), 0, strIn );
2980	RemoveCharacterFromString( pNewString, "," );
2981	if( IsValidRealString( pNewString ) == FALSE )
2982	{
2983	return DISP_E_TYPEMISMATCH;
2984	}
2985
2986	/* Convert the valid string to a floating point number.
2987	*/
2988	dValue = atof( pNewString );
2989
2990	/* We don't need the string anymore so free it.
2991	*/
2992	HeapFree( GetProcessHeap(), 0, pNewString );
2993
2994	*pdblOut = dValue;
2995
2996	return S_OK;
2997	}
2998
2999	/**********************************************************************
3000	* VarR8FromCy [OLEAUT32.82]
3001	* Convert currency to double
3002	*/
3003	HRESULT WINAPI VarR8FromCy(CY cyIn, double* pdblOut) {
3004	pdblOut = (double)((((double)cyIn.s.Hi 4294967296.0) + (double)cyIn.s.Lo) / 10000);
3005
3006	return S_OK;
3007	}
3008
3009	/******************************************************************************
3010	* VarDateFromUI1 [OLEAUT32.88]
3011	*/
3012	HRESULT WINAPI VarDateFromUI1(BYTE bIn, DATE* pdateOut)
3013	{
3014	TRACE("( %d, %p ), stub\n", bIn, pdateOut );
3015
3016	*pdateOut = (DATE) bIn;
3017
3018	return S_OK;
3019	}
3020
3021	/******************************************************************************
3022	* VarDateFromI2 [OLEAUT32.89]
3023	*/
3024	HRESULT WINAPI VarDateFromI2(short sIn, DATE* pdateOut)
3025	{
3026	TRACE("( %d, %p ), stub\n", sIn, pdateOut );
3027
3028	*pdateOut = (DATE) sIn;
3029
3030	return S_OK;
3031	}
3032
3033	/******************************************************************************
3034	* VarDateFromI4 [OLEAUT32.90]
3035	*/
3036	HRESULT WINAPI VarDateFromI4(LONG lIn, DATE* pdateOut)
3037	{
3038	TRACE("( %ld, %p ), stub\n", lIn, pdateOut );
3039
3040	if( lIn < DATE_MIN \|\| lIn > DATE_MAX )
3041	{
3042	return DISP_E_OVERFLOW;
3043	}
3044
3045	*pdateOut = (DATE) lIn;
3046
3047	return S_OK;
3048	}
3049
3050	/******************************************************************************
3051	* VarDateFromR4 [OLEAUT32.91]
3052	*/
3053	HRESULT WINAPI VarDateFromR4(FLOAT fltIn, DATE* pdateOut)
3054	{
3055	TRACE("( %f, %p ), stub\n", fltIn, pdateOut );
3056
3057	if( ceil(fltIn) < DATE_MIN \|\| floor(fltIn) > DATE_MAX )
3058	{
3059	return DISP_E_OVERFLOW;
3060	}
3061
3062	*pdateOut = (DATE) fltIn;
3063
3064	return S_OK;
3065	}
3066
3067	/******************************************************************************
3068	* VarDateFromR8 [OLEAUT32.92]
3069	*/
3070	HRESULT WINAPI VarDateFromR8(double dblIn, DATE* pdateOut)
3071	{
3072	TRACE("( %f, %p ), stub\n", dblIn, pdateOut );
3073
3074	if( ceil(dblIn) < DATE_MIN \|\| floor(dblIn) > DATE_MAX )
3075	{
3076	return DISP_E_OVERFLOW;
3077	}
3078
3079	*pdateOut = (DATE) dblIn;
3080
3081	return S_OK;
3082	}
3083
3084	/******************************************************************************
3085	* VarDateFromStr [OLEAUT32.94]
3086	* The string representing the date is composed of two parts, a date and time.
3087	*
3088	* The format of the time is has follows:
3089	* hh[:mm][:ss][AM\|PM]
3090	* Whitespace can be inserted anywhere between these tokens. A whitespace consists
3091	* of space and/or tab characters, which are ignored.
3092	*
3093	* The formats for the date part are has follows:
3094	* mm/[dd/][yy]yy
3095	* [dd/]mm/[yy]yy
3096	* [yy]yy/mm/dd
3097	* January dd[,] [yy]yy
3098	* dd January [yy]yy
3099	* [yy]yy January dd
3100	* Whitespace can be inserted anywhere between these tokens.
3101	*
3102	* The formats for the date and time string are has follows.
3103	* date[whitespace][time]
3104	* [time][whitespace]date
3105	*
3106	* These are the only characters allowed in a string representing a date and time:
3107	* [A-Z] [a-z] [0-9] ':' '-' '/' ',' ' ' '\t'
3108	*/
3109	HRESULT WINAPI VarDateFromStr(OLECHAR* strIn, LCID lcid, ULONG dwFlags, DATE* pdateOut)
3110	{
3111	HRESULT ret = S_OK;
3112	struct tm TM;
3113
3114	memset( &TM, 0, sizeof(TM) );
3115
3116	TRACE("( %p, %lx, %lx, %p ), stub\n", strIn, lcid, dwFlags, pdateOut );
3117
3118	if( DateTimeStringToTm( strIn, dwFlags, &TM ) )
3119	{
3120	if( TmToDATE( &TM, pdateOut ) == FALSE )
3121	{
3122	ret = E_INVALIDARG;
3123	}
3124	}
3125	else
3126	{
3127	ret = DISP_E_TYPEMISMATCH;
3128	}
3129
3130
3131	return ret;
3132	}
3133
3134	/******************************************************************************
3135	* VarDateFromI1 [OLEAUT32.221]
3136	*/
3137	HRESULT WINAPI VarDateFromI1(CHAR cIn, DATE* pdateOut)
3138	{
3139	TRACE("( %c, %p ), stub\n", cIn, pdateOut );
3140
3141	*pdateOut = (DATE) cIn;
3142
3143	return S_OK;
3144	}
3145
3146	/******************************************************************************
3147	* VarDateFromUI2 [OLEAUT32.222]
3148	*/
3149	HRESULT WINAPI VarDateFromUI2(USHORT uiIn, DATE* pdateOut)
3150	{
3151	TRACE("( %d, %p ), stub\n", uiIn, pdateOut );
3152
3153	if( uiIn > DATE_MAX )
3154	{
3155	return DISP_E_OVERFLOW;
3156	}
3157
3158	*pdateOut = (DATE) uiIn;
3159
3160	return S_OK;
3161	}
3162
3163	/******************************************************************************
3164	* VarDateFromUI4 [OLEAUT32.223]
3165	*/
3166	HRESULT WINAPI VarDateFromUI4(ULONG ulIn, DATE* pdateOut)
3167	{
3168	TRACE("( %ld, %p ), stub\n", ulIn, pdateOut );
3169
3170	if( ulIn < DATE_MIN \|\| ulIn > DATE_MAX )
3171	{
3172	return DISP_E_OVERFLOW;
3173	}
3174
3175	*pdateOut = (DATE) ulIn;
3176
3177	return S_OK;
3178	}
3179
3180	/******************************************************************************
3181	* VarDateFromBool [OLEAUT32.96]
3182	*/
3183	HRESULT WINAPI VarDateFromBool(VARIANT_BOOL boolIn, DATE* pdateOut)
3184	{
3185	TRACE("( %d, %p ), stub\n", boolIn, pdateOut );
3186
3187	*pdateOut = (DATE) boolIn;
3188
3189	return S_OK;
3190	}
3191
3192	/**********************************************************************
3193	* VarDateFromCy [OLEAUT32.93]
3194	* Convert currency to date
3195	*/
3196	HRESULT WINAPI VarDateFromCy(CY cyIn, DATE* pdateOut) {
3197	pdateOut = (DATE)((((double)cyIn.s.Hi 4294967296.0) + (double)cyIn.s.Lo) / 10000);
3198
3199	if (pdateOut > DATE_MAX \|\| pdateOut < DATE_MIN) return DISP_E_TYPEMISMATCH;
3200	return S_OK;
3201	}
3202
3203	/******************************************************************************
3204	* VarBstrFromUI1 [OLEAUT32.108]
3205	*/
3206	HRESULT WINAPI VarBstrFromUI1(BYTE bVal, LCID lcid, ULONG dwFlags, BSTR* pbstrOut)
3207	{
3208	TRACE("( %d, %ld, %ld, %p ), stub\n", bVal, lcid, dwFlags, pbstrOut );
3209	sprintf( pBuffer, "%d", bVal );
3210
3211	*pbstrOut = StringDupAtoBstr( pBuffer );
3212
3213	return S_OK;
3214	}
3215
3216	/******************************************************************************
3217	* VarBstrFromI2 [OLEAUT32.109]
3218	*/
3219	HRESULT WINAPI VarBstrFromI2(short iVal, LCID lcid, ULONG dwFlags, BSTR* pbstrOut)
3220	{
3221	TRACE("( %d, %ld, %ld, %p ), stub\n", iVal, lcid, dwFlags, pbstrOut );
3222	sprintf( pBuffer, "%d", iVal );
3223	*pbstrOut = StringDupAtoBstr( pBuffer );
3224
3225	return S_OK;
3226	}
3227
3228	/******************************************************************************
3229	* VarBstrFromI4 [OLEAUT32.110]
3230	*/
3231	HRESULT WINAPI VarBstrFromI4(LONG lIn, LCID lcid, ULONG dwFlags, BSTR* pbstrOut)
3232	{
3233	TRACE("( %ld, %ld, %ld, %p ), stub\n", lIn, lcid, dwFlags, pbstrOut );
3234
3235	sprintf( pBuffer, "%ld", lIn );
3236	*pbstrOut = StringDupAtoBstr( pBuffer );
3237
3238	return S_OK;
3239	}
3240
3241	/******************************************************************************
3242	* VarBstrFromR4 [OLEAUT32.111]
3243	*/
3244	HRESULT WINAPI VarBstrFromR4(FLOAT fltIn, LCID lcid, ULONG dwFlags, BSTR* pbstrOut)
3245	{
3246	TRACE("( %f, %ld, %ld, %p ), stub\n", fltIn, lcid, dwFlags, pbstrOut );
3247
3248	sprintf( pBuffer, "%.7g", fltIn );
3249	*pbstrOut = StringDupAtoBstr( pBuffer );
3250
3251	return S_OK;
3252	}
3253
3254	/******************************************************************************
3255	* VarBstrFromR8 [OLEAUT32.112]
3256	*/
3257	HRESULT WINAPI VarBstrFromR8(double dblIn, LCID lcid, ULONG dwFlags, BSTR* pbstrOut)
3258	{
3259	TRACE("( %f, %ld, %ld, %p ), stub\n", dblIn, lcid, dwFlags, pbstrOut );
3260
3261	sprintf( pBuffer, "%.15g", dblIn );
3262	*pbstrOut = StringDupAtoBstr( pBuffer );
3263
3264	return S_OK;
3265	}
3266
3267	/******************************************************************************
3268	* VarBstrFromCy [OLEAUT32.113]
3269	*/
3270	HRESULT WINAPI VarBstrFromCy(CY cyIn, LCID lcid, ULONG dwFlags, BSTR *pbstrOut) {
3271	FIXME("([cyIn], %08lx, %08lx, %p), stub.\n", lcid, dwFlags, pbstrOut);
3272	return E_NOTIMPL;
3273	}
3274
3275
3276	/******************************************************************************
3277	* VarBstrFromDate [OLEAUT32.114]
3278	*
3279	* The date is implemented using an 8 byte floating-point number.
3280	* Days are represented by whole numbers increments starting with 0.00 as
3281	* being December 30 1899, midnight.
3282	* The hours are expressed as the fractional part of the number.
3283	* December 30 1899 at midnight = 0.00
3284	* January 1 1900 at midnight = 2.00
3285	* January 4 1900 at 6 AM = 5.25
3286	* January 4 1900 at noon = 5.50
3287	* December 29 1899 at midnight = -1.00
3288	* December 18 1899 at midnight = -12.00
3289	* December 18 1899 at 6AM = -12.25
3290	* December 18 1899 at 6PM = -12.75
3291	* December 19 1899 at midnight = -11.00
3292	* The tm structure is as follows:
3293	* struct tm {
3294	* int tm_sec; seconds after the minute - [0,59]
3295	* int tm_min; minutes after the hour - [0,59]
3296	* int tm_hour; hours since midnight - [0,23]
3297	* int tm_mday; day of the month - [1,31]
3298	* int tm_mon; months since January - [0,11]
3299	* int tm_year; years
3300	* int tm_wday; days since Sunday - [0,6]
3301	* int tm_yday; days since January 1 - [0,365]
3302	* int tm_isdst; daylight savings time flag
3303	* };
3304	*/
3305	HRESULT WINAPI VarBstrFromDate(DATE dateIn, LCID lcid, ULONG dwFlags, BSTR* pbstrOut)
3306	{
3307	struct tm TM;
3308	memset( &TM, 0, sizeof(TM) );
3309
3310	TRACE("( %f, %ld, %ld, %p ), stub\n", dateIn, lcid, dwFlags, pbstrOut );
3311
3312	if( DateToTm( dateIn, dwFlags, &TM ) == FALSE )
3313	{
3314	return E_INVALIDARG;
3315	}
3316
3317	if( dwFlags & VAR_DATEVALUEONLY )
3318	strftime( pBuffer, BUFFER_MAX, "%x", &TM );
3319	else if( dwFlags & VAR_TIMEVALUEONLY )
3320	strftime( pBuffer, BUFFER_MAX, "%X", &TM );
3321	else
3322	strftime( pBuffer, BUFFER_MAX, "%x %X", &TM );
3323
3324	*pbstrOut = StringDupAtoBstr( pBuffer );
3325
3326	return S_OK;
3327	}
3328
3329	/******************************************************************************
3330	* VarBstrFromBool [OLEAUT32.116]
3331	*/
3332	HRESULT WINAPI VarBstrFromBool(VARIANT_BOOL boolIn, LCID lcid, ULONG dwFlags, BSTR* pbstrOut)
3333	{
3334	TRACE("( %d, %ld, %ld, %p ), stub\n", boolIn, lcid, dwFlags, pbstrOut );
3335
3336	sprintf( pBuffer, (boolIn == VARIANT_FALSE) ? "False" : "True" );
3337
3338	*pbstrOut = StringDupAtoBstr( pBuffer );
3339
3340	return S_OK;
3341	}
3342
3343	/******************************************************************************
3344	* VarBstrFromI1 [OLEAUT32.229]
3345	*/
3346	HRESULT WINAPI VarBstrFromI1(CHAR cIn, LCID lcid, ULONG dwFlags, BSTR* pbstrOut)
3347	{
3348	TRACE("( %c, %ld, %ld, %p ), stub\n", cIn, lcid, dwFlags, pbstrOut );
3349	sprintf( pBuffer, "%d", cIn );
3350	*pbstrOut = StringDupAtoBstr( pBuffer );
3351
3352	return S_OK;
3353	}
3354
3355	/******************************************************************************
3356	* VarBstrFromUI2 [OLEAUT32.230]
3357	*/
3358	HRESULT WINAPI VarBstrFromUI2(USHORT uiIn, LCID lcid, ULONG dwFlags, BSTR* pbstrOut)
3359	{
3360	TRACE("( %d, %ld, %ld, %p ), stub\n", uiIn, lcid, dwFlags, pbstrOut );
3361	sprintf( pBuffer, "%d", uiIn );
3362	*pbstrOut = StringDupAtoBstr( pBuffer );
3363
3364	return S_OK;
3365	}
3366
3367	/******************************************************************************
3368	* VarBstrFromUI4 [OLEAUT32.231]
3369	*/
3370	HRESULT WINAPI VarBstrFromUI4(ULONG ulIn, LCID lcid, ULONG dwFlags, BSTR* pbstrOut)
3371	{
3372	TRACE("( %ld, %ld, %ld, %p ), stub\n", ulIn, lcid, dwFlags, pbstrOut );
3373	sprintf( pBuffer, "%ld", ulIn );
3374	*pbstrOut = StringDupAtoBstr( pBuffer );
3375
3376	return S_OK;
3377	}
3378
3379	/******************************************************************************
3380	* VarBoolFromUI1 [OLEAUT32.118]
3381	*/
3382	HRESULT WINAPI VarBoolFromUI1(BYTE bIn, VARIANT_BOOL* pboolOut)
3383	{
3384	TRACE("( %d, %p ), stub\n", bIn, pboolOut );
3385
3386	if( bIn == 0 )
3387	{
3388	*pboolOut = VARIANT_FALSE;
3389	}
3390	else
3391	{
3392	*pboolOut = VARIANT_TRUE;
3393	}
3394
3395	return S_OK;
3396	}
3397
3398	/******************************************************************************
3399	* VarBoolFromI2 [OLEAUT32.119]
3400	*/
3401	HRESULT WINAPI VarBoolFromI2(short sIn, VARIANT_BOOL* pboolOut)
3402	{
3403	TRACE("( %d, %p ), stub\n", sIn, pboolOut );
3404
3405	*pboolOut = (sIn) ? VARIANT_TRUE : VARIANT_FALSE;
3406
3407	return S_OK;
3408	}
3409
3410	/******************************************************************************
3411	* VarBoolFromI4 [OLEAUT32.120]
3412	*/
3413	HRESULT WINAPI VarBoolFromI4(LONG lIn, VARIANT_BOOL* pboolOut)
3414	{
3415	TRACE("( %ld, %p ), stub\n", lIn, pboolOut );
3416
3417	*pboolOut = (lIn) ? VARIANT_TRUE : VARIANT_FALSE;
3418
3419	return S_OK;
3420	}
3421
3422	/******************************************************************************
3423	* VarBoolFromR4 [OLEAUT32.121]
3424	*/
3425	HRESULT WINAPI VarBoolFromR4(FLOAT fltIn, VARIANT_BOOL* pboolOut)
3426	{
3427	TRACE("( %f, %p ), stub\n", fltIn, pboolOut );
3428
3429	*pboolOut = (fltIn == 0.0) ? VARIANT_FALSE : VARIANT_TRUE;
3430
3431	return S_OK;
3432	}
3433
3434	/******************************************************************************
3435	* VarBoolFromR8 [OLEAUT32.122]
3436	*/
3437	HRESULT WINAPI VarBoolFromR8(double dblIn, VARIANT_BOOL* pboolOut)
3438	{
3439	TRACE("( %f, %p ), stub\n", dblIn, pboolOut );
3440
3441	*pboolOut = (dblIn == 0.0) ? VARIANT_FALSE : VARIANT_TRUE;
3442
3443	return S_OK;
3444	}
3445
3446	/******************************************************************************
3447	* VarBoolFromDate [OLEAUT32.123]
3448	*/
3449	HRESULT WINAPI VarBoolFromDate(DATE dateIn, VARIANT_BOOL* pboolOut)
3450	{
3451	TRACE("( %f, %p ), stub\n", dateIn, pboolOut );
3452
3453	*pboolOut = (dateIn == 0.0) ? VARIANT_FALSE : VARIANT_TRUE;
3454
3455	return S_OK;
3456	}
3457
3458	/******************************************************************************
3459	* VarBoolFromStr [OLEAUT32.125]
3460	*/
3461	HRESULT WINAPI VarBoolFromStr(OLECHAR* strIn, LCID lcid, ULONG dwFlags, VARIANT_BOOL* pboolOut)
3462	{
3463	HRESULT ret = S_OK;
3464	char* pNewString = NULL;
3465
3466	TRACE("( %p, %ld, %ld, %p ), stub\n", strIn, lcid, dwFlags, pboolOut );
3467
3468	pNewString = HEAP_strdupWtoA( GetProcessHeap(), 0, strIn );
3469
3470	if( pNewString == NULL \|\| strlen( pNewString ) == 0 )
3471	{
3472	ret = DISP_E_TYPEMISMATCH;
3473	}
3474
3475	if( ret == S_OK )
3476	{
3477	if( strncasecmp( pNewString, "True", strlen( pNewString ) ) == 0 )
3478	{
3479	*pboolOut = VARIANT_TRUE;
3480	}
3481	else if( strncasecmp( pNewString, "False", strlen( pNewString ) ) == 0 )
3482	{
3483	*pboolOut = VARIANT_FALSE;
3484	}
3485	else
3486	{
3487	/* Try converting the string to a floating point number.
3488	*/
3489	double dValue = 0.0;
3490	HRESULT res = VarR8FromStr( strIn, lcid, dwFlags, &dValue );
3491	if( res != S_OK )
3492	{
3493	ret = DISP_E_TYPEMISMATCH;
3494	}
3495	else
3496	*pboolOut = (dValue == 0.0) ?
3497	VARIANT_FALSE : VARIANT_TRUE;
3498	}
3499	}
3500
3501	HeapFree( GetProcessHeap(), 0, pNewString );
3502
3503	return ret;
3504	}
3505
3506	/******************************************************************************
3507	* VarBoolFromI1 [OLEAUT32.233]
3508	*/
3509	HRESULT WINAPI VarBoolFromI1(CHAR cIn, VARIANT_BOOL* pboolOut)
3510	{
3511	TRACE("( %c, %p ), stub\n", cIn, pboolOut );
3512
3513	*pboolOut = (cIn == 0) ? VARIANT_FALSE : VARIANT_TRUE;
3514
3515	return S_OK;
3516	}
3517
3518	/******************************************************************************
3519	* VarBoolFromUI2 [OLEAUT32.234]
3520	*/
3521	HRESULT WINAPI VarBoolFromUI2(USHORT uiIn, VARIANT_BOOL* pboolOut)
3522	{
3523	TRACE("( %d, %p ), stub\n", uiIn, pboolOut );
3524
3525	*pboolOut = (uiIn == 0) ? VARIANT_FALSE : VARIANT_TRUE;
3526
3527	return S_OK;
3528	}
3529
3530	/******************************************************************************
3531	* VarBoolFromUI4 [OLEAUT32.235]
3532	*/
3533	HRESULT WINAPI VarBoolFromUI4(ULONG ulIn, VARIANT_BOOL* pboolOut)
3534	{
3535	TRACE("( %ld, %p ), stub\n", ulIn, pboolOut );
3536
3537	*pboolOut = (ulIn == 0) ? VARIANT_FALSE : VARIANT_TRUE;
3538
3539	return S_OK;
3540	}
3541
3542	/**********************************************************************
3543	* VarBoolFromCy [OLEAUT32.124]
3544	* Convert currency to boolean
3545	*/
3546	HRESULT WINAPI VarBoolFromCy(CY cyIn, VARIANT_BOOL* pboolOut) {
3547	if (cyIn.s.Hi \|\| cyIn.s.Lo) *pboolOut = -1;
3548	else *pboolOut = 0;
3549
3550	return S_OK;
3551	}
3552
3553	/******************************************************************************
3554	* VarI1FromUI1 [OLEAUT32.244]
3555	*/
3556	HRESULT WINAPI VarI1FromUI1(BYTE bIn, CHAR* pcOut)
3557	{
3558	TRACE("( %d, %p ), stub\n", bIn, pcOut );
3559
3560	/* Check range of value.
3561	*/
3562	if( bIn > CHAR_MAX )
3563	{
3564	return DISP_E_OVERFLOW;
3565	}
3566
3567	*pcOut = (CHAR) bIn;
3568
3569	return S_OK;
3570	}
3571
3572	/******************************************************************************
3573	* VarI1FromI2 [OLEAUT32.245]
3574	*/
3575	HRESULT WINAPI VarI1FromI2(short uiIn, CHAR* pcOut)
3576	{
3577	TRACE("( %d, %p ), stub\n", uiIn, pcOut );
3578
3579	if( uiIn > CHAR_MAX )
3580	{
3581	return DISP_E_OVERFLOW;
3582	}
3583
3584	*pcOut = (CHAR) uiIn;
3585
3586	return S_OK;
3587	}
3588
3589	/******************************************************************************
3590	* VarI1FromI4 [OLEAUT32.246]
3591	*/
3592	HRESULT WINAPI VarI1FromI4(LONG lIn, CHAR* pcOut)
3593	{
3594	TRACE("( %ld, %p ), stub\n", lIn, pcOut );
3595
3596	if( lIn < CHAR_MIN \|\| lIn > CHAR_MAX )
3597	{
3598	return DISP_E_OVERFLOW;
3599	}
3600
3601	*pcOut = (CHAR) lIn;
3602
3603	return S_OK;
3604	}
3605
3606	/******************************************************************************
3607	* VarI1FromR4 [OLEAUT32.247]
3608	*/
3609	HRESULT WINAPI VarI1FromR4(FLOAT fltIn, CHAR* pcOut)
3610	{
3611	TRACE("( %f, %p ), stub\n", fltIn, pcOut );
3612
3613	fltIn = round( fltIn );
3614	if( fltIn < CHAR_MIN \|\| fltIn > CHAR_MAX )
3615	{
3616	return DISP_E_OVERFLOW;
3617	}
3618
3619	*pcOut = (CHAR) fltIn;
3620
3621	return S_OK;
3622	}
3623
3624	/******************************************************************************
3625	* VarI1FromR8 [OLEAUT32.248]
3626	*/
3627	HRESULT WINAPI VarI1FromR8(double dblIn, CHAR* pcOut)
3628	{
3629	TRACE("( %f, %p ), stub\n", dblIn, pcOut );
3630
3631	dblIn = round( dblIn );
3632	if( dblIn < CHAR_MIN \|\| dblIn > CHAR_MAX )
3633	{
3634	return DISP_E_OVERFLOW;
3635	}
3636
3637	*pcOut = (CHAR) dblIn;
3638
3639	return S_OK;
3640	}
3641
3642	/******************************************************************************
3643	* VarI1FromDate [OLEAUT32.249]
3644	*/
3645	HRESULT WINAPI VarI1FromDate(DATE dateIn, CHAR* pcOut)
3646	{
3647	TRACE("( %f, %p ), stub\n", dateIn, pcOut );
3648
3649	dateIn = round( dateIn );
3650	if( dateIn < CHAR_MIN \|\| dateIn > CHAR_MAX )
3651	{
3652	return DISP_E_OVERFLOW;
3653	}
3654
3655	*pcOut = (CHAR) dateIn;
3656
3657	return S_OK;
3658	}
3659
3660	/******************************************************************************
3661	* VarI1FromStr [OLEAUT32.251]
3662	*/
3663	HRESULT WINAPI VarI1FromStr(OLECHAR* strIn, LCID lcid, ULONG dwFlags, CHAR* pcOut)
3664	{
3665	double dValue = 0.0;
3666	LPSTR pNewString = NULL;
3667
3668	TRACE("( %p, %ld, %ld, %p ), stub\n", strIn, lcid, dwFlags, pcOut );
3669
3670	/* Check if we have a valid argument
3671	*/
3672	pNewString = HEAP_strdupWtoA( GetProcessHeap(), 0, strIn );
3673	RemoveCharacterFromString( pNewString, "," );
3674	if( IsValidRealString( pNewString ) == FALSE )
3675	{
3676	return DISP_E_TYPEMISMATCH;
3677	}
3678
3679	/* Convert the valid string to a floating point number.
3680	*/
3681	dValue = atof( pNewString );
3682
3683	/* We don't need the string anymore so free it.
3684	*/
3685	HeapFree( GetProcessHeap(), 0, pNewString );
3686
3687	/* Check range of value.
3688	*/
3689	dValue = round( dValue );
3690	if( dValue < CHAR_MIN \|\| dValue > CHAR_MAX )
3691	{
3692	return DISP_E_OVERFLOW;
3693	}
3694
3695	*pcOut = (CHAR) dValue;
3696
3697	return S_OK;
3698	}
3699
3700	/******************************************************************************
3701	* VarI1FromBool [OLEAUT32.253]
3702	*/
3703	HRESULT WINAPI VarI1FromBool(VARIANT_BOOL boolIn, CHAR* pcOut)
3704	{
3705	TRACE("( %d, %p ), stub\n", boolIn, pcOut );
3706
3707	*pcOut = (CHAR) boolIn;
3708
3709	return S_OK;
3710	}
3711
3712	/******************************************************************************
3713	* VarI1FromUI2 [OLEAUT32.254]
3714	*/
3715	HRESULT WINAPI VarI1FromUI2(USHORT uiIn, CHAR* pcOut)
3716	{
3717	TRACE("( %d, %p ), stub\n", uiIn, pcOut );
3718
3719	if( uiIn > CHAR_MAX )
3720	{
3721	return DISP_E_OVERFLOW;
3722	}
3723
3724	*pcOut = (CHAR) uiIn;
3725
3726	return S_OK;
3727	}
3728
3729	/******************************************************************************
3730	* VarI1FromUI4 [OLEAUT32.255]
3731	*/
3732	HRESULT WINAPI VarI1FromUI4(ULONG ulIn, CHAR* pcOut)
3733	{
3734	TRACE("( %ld, %p ), stub\n", ulIn, pcOut );
3735
3736	if( ulIn > CHAR_MAX )
3737	{
3738	return DISP_E_OVERFLOW;
3739	}
3740
3741	*pcOut = (CHAR) ulIn;
3742
3743	return S_OK;
3744	}
3745
3746	/**********************************************************************
3747	* VarI1FromCy [OLEAUT32.250]
3748	* Convert currency to signed char
3749	*/
3750	HRESULT WINAPI VarI1FromCy(CY cyIn, CHAR* pcOut) {
3751	double t = round((((double)cyIn.s.Hi * 4294967296.0) + (double)cyIn.s.Lo) / 10000);
3752
3753	if (t > CHAR_MAX \|\| t < CHAR_MIN) return DISP_E_OVERFLOW;
3754
3755	*pcOut = (CHAR)t;
3756	return S_OK;
3757	}
3758
3759	/******************************************************************************
3760	* VarUI2FromUI1 [OLEAUT32.257]
3761	*/
3762	HRESULT WINAPI VarUI2FromUI1(BYTE bIn, USHORT* puiOut)
3763	{
3764	TRACE("( %d, %p ), stub\n", bIn, puiOut );
3765
3766	*puiOut = (USHORT) bIn;
3767
3768	return S_OK;
3769	}
3770
3771	/******************************************************************************
3772	* VarUI2FromI2 [OLEAUT32.258]
3773	*/
3774	HRESULT WINAPI VarUI2FromI2(short uiIn, USHORT* puiOut)
3775	{
3776	TRACE("( %d, %p ), stub\n", uiIn, puiOut );
3777
3778	if( uiIn < UI2_MIN )
3779	{
3780	return DISP_E_OVERFLOW;
3781	}
3782
3783	*puiOut = (USHORT) uiIn;
3784
3785	return S_OK;
3786	}
3787
3788	/******************************************************************************
3789	* VarUI2FromI4 [OLEAUT32.259]
3790	*/
3791	HRESULT WINAPI VarUI2FromI4(LONG lIn, USHORT* puiOut)
3792	{
3793	TRACE("( %ld, %p ), stub\n", lIn, puiOut );
3794
3795	if( lIn < UI2_MIN \|\| lIn > UI2_MAX )
3796	{
3797	return DISP_E_OVERFLOW;
3798	}
3799
3800	*puiOut = (USHORT) lIn;
3801
3802	return S_OK;
3803	}
3804
3805	/******************************************************************************
3806	* VarUI2FromR4 [OLEAUT32.260]
3807	*/
3808	HRESULT WINAPI VarUI2FromR4(FLOAT fltIn, USHORT* puiOut)
3809	{
3810	TRACE("( %f, %p ), stub\n", fltIn, puiOut );
3811
3812	fltIn = round( fltIn );
3813	if( fltIn < UI2_MIN \|\| fltIn > UI2_MAX )
3814	{
3815	return DISP_E_OVERFLOW;
3816	}
3817
3818	*puiOut = (USHORT) fltIn;
3819
3820	return S_OK;
3821	}
3822
3823	/******************************************************************************
3824	* VarUI2FromR8 [OLEAUT32.261]
3825	*/
3826	HRESULT WINAPI VarUI2FromR8(double dblIn, USHORT* puiOut)
3827	{
3828	TRACE("( %f, %p ), stub\n", dblIn, puiOut );
3829
3830	dblIn = round( dblIn );
3831	if( dblIn < UI2_MIN \|\| dblIn > UI2_MAX )
3832	{
3833	return DISP_E_OVERFLOW;
3834	}
3835
3836	*puiOut = (USHORT) dblIn;
3837
3838	return S_OK;
3839	}
3840
3841	/******************************************************************************
3842	* VarUI2FromDate [OLEAUT32.262]
3843	*/
3844	HRESULT WINAPI VarUI2FromDate(DATE dateIn, USHORT* puiOut)
3845	{
3846	TRACE("( %f, %p ), stub\n", dateIn, puiOut );
3847
3848	dateIn = round( dateIn );
3849	if( dateIn < UI2_MIN \|\| dateIn > UI2_MAX )
3850	{
3851	return DISP_E_OVERFLOW;
3852	}
3853
3854	*puiOut = (USHORT) dateIn;
3855
3856	return S_OK;
3857	}
3858
3859	/******************************************************************************
3860	* VarUI2FromStr [OLEAUT32.264]
3861	*/
3862	HRESULT WINAPI VarUI2FromStr(OLECHAR* strIn, LCID lcid, ULONG dwFlags, USHORT* puiOut)
3863	{
3864	double dValue = 0.0;
3865	LPSTR pNewString = NULL;
3866
3867	TRACE("( %p, %ld, %ld, %p ), stub\n", strIn, lcid, dwFlags, puiOut );
3868
3869	/* Check if we have a valid argument
3870	*/
3871	pNewString = HEAP_strdupWtoA( GetProcessHeap(), 0, strIn );
3872	RemoveCharacterFromString( pNewString, "," );
3873	if( IsValidRealString( pNewString ) == FALSE )
3874	{
3875	return DISP_E_TYPEMISMATCH;
3876	}
3877
3878	/* Convert the valid string to a floating point number.
3879	*/
3880	dValue = atof( pNewString );
3881
3882	/* We don't need the string anymore so free it.
3883	*/
3884	HeapFree( GetProcessHeap(), 0, pNewString );
3885
3886	/* Check range of value.
3887	*/
3888	dValue = round( dValue );
3889	if( dValue < UI2_MIN \|\| dValue > UI2_MAX )
3890	{
3891	return DISP_E_OVERFLOW;
3892	}
3893
3894	*puiOut = (USHORT) dValue;
3895
3896	return S_OK;
3897	}
3898
3899	/******************************************************************************
3900	* VarUI2FromBool [OLEAUT32.266]
3901	*/
3902	HRESULT WINAPI VarUI2FromBool(VARIANT_BOOL boolIn, USHORT* puiOut)
3903	{
3904	TRACE("( %d, %p ), stub\n", boolIn, puiOut );
3905
3906	*puiOut = (USHORT) boolIn;
3907
3908	return S_OK;
3909	}
3910
3911	/******************************************************************************
3912	* VarUI2FromI1 [OLEAUT32.267]
3913	*/
3914	HRESULT WINAPI VarUI2FromI1(CHAR cIn, USHORT* puiOut)
3915	{
3916	TRACE("( %c, %p ), stub\n", cIn, puiOut );
3917
3918	*puiOut = (USHORT) cIn;
3919
3920	return S_OK;
3921	}
3922
3923	/******************************************************************************
3924	* VarUI2FromUI4 [OLEAUT32.268]
3925	*/
3926	HRESULT WINAPI VarUI2FromUI4(ULONG ulIn, USHORT* puiOut)
3927	{
3928	TRACE("( %ld, %p ), stub\n", ulIn, puiOut );
3929
3930	if( ulIn < UI2_MIN \|\| ulIn > UI2_MAX )
3931	{
3932	return DISP_E_OVERFLOW;
3933	}
3934
3935	*puiOut = (USHORT) ulIn;
3936
3937	return S_OK;
3938	}
3939
3940	/******************************************************************************
3941	* VarUI4FromStr [OLEAUT32.277]
3942	*/
3943	HRESULT WINAPI VarUI4FromStr(OLECHAR* strIn, LCID lcid, ULONG dwFlags, ULONG* pulOut)
3944	{
3945	double dValue = 0.0;
3946	LPSTR pNewString = NULL;
3947
3948	TRACE("( %p, %ld, %ld, %p ), stub\n", strIn, lcid, dwFlags, pulOut );
3949
3950	/* Check if we have a valid argument
3951	*/
3952	pNewString = HEAP_strdupWtoA( GetProcessHeap(), 0, strIn );
3953	RemoveCharacterFromString( pNewString, "," );
3954	if( IsValidRealString( pNewString ) == FALSE )
3955	{
3956	return DISP_E_TYPEMISMATCH;
3957	}
3958
3959	/* Convert the valid string to a floating point number.
3960	*/
3961	dValue = atof( pNewString );
3962
3963	/* We don't need the string anymore so free it.
3964	*/
3965	HeapFree( GetProcessHeap(), 0, pNewString );
3966
3967	/* Check range of value.
3968	*/
3969	dValue = round( dValue );
3970	if( dValue < UI4_MIN \|\| dValue > UI4_MAX )
3971	{
3972	return DISP_E_OVERFLOW;
3973	}
3974
3975	*pulOut = (ULONG) dValue;
3976
3977	return S_OK;
3978	}
3979
3980	/**********************************************************************
3981	* VarUI2FromCy [OLEAUT32.263]
3982	* Convert currency to unsigned short
3983	*/
3984	HRESULT WINAPI VarUI2FromCy(CY cyIn, USHORT* pusOut) {
3985	double t = round((((double)cyIn.s.Hi * 4294967296.0) + (double)cyIn.s.Lo) / 10000);
3986
3987	if (t > UI2_MAX \|\| t < UI2_MIN) return DISP_E_OVERFLOW;
3988
3989	*pusOut = (USHORT)t;
3990
3991	return S_OK;
3992	}
3993
3994	/******************************************************************************
3995	* VarUI4FromUI1 [OLEAUT32.270]
3996	*/
3997	HRESULT WINAPI VarUI4FromUI1(BYTE bIn, ULONG* pulOut)
3998	{
3999	TRACE("( %d, %p ), stub\n", bIn, pulOut );
4000
4001	*pulOut = (USHORT) bIn;
4002
4003	return S_OK;
4004	}
4005
4006	/******************************************************************************
4007	* VarUI4FromI2 [OLEAUT32.271]
4008	*/
4009	HRESULT WINAPI VarUI4FromI2(short uiIn, ULONG* pulOut)
4010	{
4011	TRACE("( %d, %p ), stub\n", uiIn, pulOut );
4012
4013	if( uiIn < UI4_MIN )
4014	{
4015	return DISP_E_OVERFLOW;
4016	}
4017
4018	*pulOut = (ULONG) uiIn;
4019
4020	return S_OK;
4021	}
4022
4023	/******************************************************************************
4024	* VarUI4FromI4 [OLEAUT32.272]
4025	*/
4026	HRESULT WINAPI VarUI4FromI4(LONG lIn, ULONG* pulOut)
4027	{
4028	TRACE("( %ld, %p ), stub\n", lIn, pulOut );
4029
4030	if( lIn < UI4_MIN )
4031	{
4032	return DISP_E_OVERFLOW;
4033	}
4034
4035	*pulOut = (ULONG) lIn;
4036
4037	return S_OK;
4038	}
4039
4040	/******************************************************************************
4041	* VarUI4FromR4 [OLEAUT32.273]
4042	*/
4043	HRESULT WINAPI VarUI4FromR4(FLOAT fltIn, ULONG* pulOut)
4044	{
4045	fltIn = round( fltIn );
4046	if( fltIn < UI4_MIN \|\| fltIn > UI4_MAX )
4047	{
4048	return DISP_E_OVERFLOW;
4049	}
4050
4051	*pulOut = (ULONG) fltIn;
4052
4053	return S_OK;
4054	}
4055
4056	/******************************************************************************
4057	* VarUI4FromR8 [OLEAUT32.274]
4058	*/
4059	HRESULT WINAPI VarUI4FromR8(double dblIn, ULONG* pulOut)
4060	{
4061	TRACE("( %f, %p ), stub\n", dblIn, pulOut );
4062
4063	dblIn = round( dblIn );
4064	if( dblIn < UI4_MIN \|\| dblIn > UI4_MAX )
4065	{
4066	return DISP_E_OVERFLOW;
4067	}
4068
4069	*pulOut = (ULONG) dblIn;
4070
4071	return S_OK;
4072	}
4073
4074	/******************************************************************************
4075	* VarUI4FromDate [OLEAUT32.275]
4076	*/
4077	HRESULT WINAPI VarUI4FromDate(DATE dateIn, ULONG* pulOut)
4078	{
4079	TRACE("( %f, %p ), stub\n", dateIn, pulOut );
4080
4081	dateIn = round( dateIn );
4082	if( dateIn < UI4_MIN \|\| dateIn > UI4_MAX )
4083	{
4084	return DISP_E_OVERFLOW;
4085	}
4086
4087	*pulOut = (ULONG) dateIn;
4088
4089	return S_OK;
4090	}
4091
4092	/******************************************************************************
4093	* VarUI4FromBool [OLEAUT32.279]
4094	*/
4095	HRESULT WINAPI VarUI4FromBool(VARIANT_BOOL boolIn, ULONG* pulOut)
4096	{
4097	TRACE("( %d, %p ), stub\n", boolIn, pulOut );
4098
4099	*pulOut = (ULONG) boolIn;
4100
4101	return S_OK;
4102	}
4103
4104	/******************************************************************************
4105	* VarUI4FromI1 [OLEAUT32.280]
4106	*/
4107	HRESULT WINAPI VarUI4FromI1(CHAR cIn, ULONG* pulOut)
4108	{
4109	TRACE("( %c, %p ), stub\n", cIn, pulOut );
4110
4111	*pulOut = (ULONG) cIn;
4112
4113	return S_OK;
4114	}
4115
4116	/******************************************************************************
4117	* VarUI4FromUI2 [OLEAUT32.281]
4118	*/
4119	HRESULT WINAPI VarUI4FromUI2(USHORT uiIn, ULONG* pulOut)
4120	{
4121	TRACE("( %d, %p ), stub\n", uiIn, pulOut );
4122
4123	*pulOut = (ULONG) uiIn;
4124
4125	return S_OK;
4126	}
4127
4128	/**********************************************************************
4129	* VarUI4FromCy [OLEAUT32.276]
4130	* Convert currency to unsigned long
4131	*/
4132	HRESULT WINAPI VarUI4FromCy(CY cyIn, ULONG* pulOut) {
4133	double t = round((((double)cyIn.s.Hi * 4294967296.0) + (double)cyIn.s.Lo) / 10000);
4134
4135	if (t > UI4_MAX \|\| t < UI4_MIN) return DISP_E_OVERFLOW;
4136
4137	*pulOut = (ULONG)t;
4138
4139	return S_OK;
4140	}
4141
4142	/**********************************************************************
4143	* VarCyFromUI1 [OLEAUT32.98]
4144	* Convert unsigned char to currency
4145	*/
4146	HRESULT WINAPI VarCyFromUI1(BYTE bIn, CY* pcyOut) {
4147	pcyOut->s.Hi = 0;
4148	pcyOut->s.Lo = ((ULONG)bIn) * 10000;
4149
4150	return S_OK;
4151	}
4152
4153	/**********************************************************************
4154	* VarCyFromI2 [OLEAUT32.99]
4155	* Convert signed short to currency
4156	*/
4157	HRESULT WINAPI VarCyFromI2(short sIn, CY* pcyOut) {
4158	if (sIn < 0) pcyOut->s.Hi = -1;
4159	else pcyOut->s.Hi = 0;
4160	pcyOut->s.Lo = ((ULONG)sIn) * 10000;
4161
4162	return S_OK;
4163	}
4164
4165	/**********************************************************************
4166	* VarCyFromI4 [OLEAUT32.100]
4167	* Convert signed long to currency
4168	*/
4169	HRESULT WINAPI VarCyFromI4(LONG lIn, CY* pcyOut) {
4170	double t = (double)lIn * (double)10000;
4171	pcyOut->s.Hi = (LONG)(t / (double)4294967296.0);
4172	pcyOut->s.Lo = (ULONG)fmod(t, (double)4294967296.0);
4173	if (lIn < 0) pcyOut->s.Hi--;
4174
4175	return S_OK;
4176	}
4177
4178	/**********************************************************************
4179	* VarCyFromR4 [OLEAUT32.101]
4180	* Convert float to currency
4181	*/
4182	HRESULT WINAPI VarCyFromR4(FLOAT fltIn, CY* pcyOut) {
4183	double t = round((double)fltIn * (double)10000);
4184	pcyOut->s.Hi = (LONG)(t / (double)4294967296.0);
4185	pcyOut->s.Lo = (ULONG)fmod(t, (double)4294967296.0);
4186	if (fltIn < 0) pcyOut->s.Hi--;
4187
4188	return S_OK;
4189	}
4190
4191	/**********************************************************************
4192	* VarCyFromR8 [OLEAUT32.102]
4193	* Convert double to currency
4194	*/
4195	HRESULT WINAPI VarCyFromR8(double dblIn, CY* pcyOut) {
4196	double t = round(dblIn * (double)10000);
4197	pcyOut->s.Hi = (LONG)(t / (double)4294967296.0);
4198	pcyOut->s.Lo = (ULONG)fmod(t, (double)4294967296.0);
4199	if (dblIn < 0) pcyOut->s.Hi--;
4200
4201	return S_OK;
4202	}
4203
4204	/**********************************************************************
4205	* VarCyFromDate [OLEAUT32.103]
4206	* Convert date to currency
4207	*/
4208	HRESULT WINAPI VarCyFromDate(DATE dateIn, CY* pcyOut) {
4209	double t = round((double)dateIn * (double)10000);
4210	pcyOut->s.Hi = (LONG)(t / (double)4294967296.0);
4211	pcyOut->s.Lo = (ULONG)fmod(t, (double)4294967296.0);
4212	if (dateIn < 0) pcyOut->s.Hi--;
4213
4214	return S_OK;
4215	}
4216
4217	/**********************************************************************
4218	* VarCyFromStr [OLEAUT32.104]
4219	*/
4220	HRESULT WINAPI VarCyFromStr(OLECHAR strIn, LCID lcid, ULONG dwFlags, CY pcyOut) {
4221	FIXME("(%p, %08lx, %08lx, %p), stub.\n", strIn, lcid, dwFlags, pcyOut);
4222	return E_NOTIMPL;
4223	}
4224
4225
4226	/**********************************************************************
4227	* VarCyFromBool [OLEAUT32.106]
4228	* Convert boolean to currency
4229	*/
4230	HRESULT WINAPI VarCyFromBool(VARIANT_BOOL boolIn, CY* pcyOut) {
4231	if (boolIn < 0) pcyOut->s.Hi = -1;
4232	else pcyOut->s.Hi = 0;
4233	pcyOut->s.Lo = (ULONG)boolIn * (ULONG)10000;
4234
4235	return S_OK;
4236	}
4237
4238	/**********************************************************************
4239	* VarCyFromI1 [OLEAUT32.225]
4240	* Convert signed char to currency
4241	*/
4242	HRESULT WINAPI VarCyFromI1(signed char cIn, CY* pcyOut) {
4243	if (cIn < 0) pcyOut->s.Hi = -1;
4244	else pcyOut->s.Hi = 0;
4245	pcyOut->s.Lo = (ULONG)cIn * (ULONG)10000;
4246
4247	return S_OK;
4248	}
4249
4250	/**********************************************************************
4251	* VarCyFromUI2 [OLEAUT32.226]
4252	* Convert unsigned short to currency
4253	*/
4254	HRESULT WINAPI VarCyFromUI2(USHORT usIn, CY* pcyOut) {
4255	pcyOut->s.Hi = 0;
4256	pcyOut->s.Lo = (ULONG)usIn * (ULONG)10000;
4257
4258	return S_OK;
4259	}
4260
4261	/**********************************************************************
4262	* VarCyFromUI4 [OLEAUT32.227]
4263	* Convert unsigned long to currency
4264	*/
4265	HRESULT WINAPI VarCyFromUI4(ULONG ulIn, CY* pcyOut) {
4266	double t = (double)ulIn * (double)10000;
4267	pcyOut->s.Hi = (LONG)(t / (double)4294967296.0);
4268	pcyOut->s.Lo = (ULONG)fmod(t, (double)4294967296.0);
4269
4270	return S_OK;
4271	}
4272
4273
4274	/**********************************************************************
4275	* DosDateTimeToVariantTime [OLEAUT32.14]
4276	* Convert dos representation of time to the date and time representation
4277	* stored in a variant.
4278	*/
4279	INT WINAPI DosDateTimeToVariantTime(USHORT wDosDate, USHORT wDosTime,
4280	DATE *pvtime)
4281	{
4282	struct tm t;
4283
4284	TRACE("( 0x%x, 0x%x, %p ), stub\n", wDosDate, wDosTime, pvtime );
4285
4286	t.tm_sec = (wDosTime & 0x001f) * 2;
4287	t.tm_min = (wDosTime & 0x07e0) >> 5;
4288	t.tm_hour = (wDosTime & 0xf800) >> 11;
4289
4290	t.tm_mday = (wDosDate & 0x001f);
4291	t.tm_mon = (wDosDate & 0x01e0) >> 5;
4292	t.tm_year = ((wDosDate & 0xfe00) >> 9) + 1980;
4293
4294	return TmToDATE( &t, pvtime );
4295	}
4296
4297
4298	/**********************************************************************
4299	* VarParseNumFromStr [OLEAUT32.46]
4300	*/
4301	HRESULT WINAPI VarParseNumFromStr(OLECHAR * strIn, LCID lcid, ULONG dwFlags,
4302	NUMPARSE * pnumprs, BYTE * rgbDig)
4303	{
4304	int i,lastent=0;
4305	int cDig;
4306	FIXME("(%s,flags=%lx,....), partial stub!\n",debugstr_w(strIn),dwFlags);
4307	FIXME("numparse: cDig=%d, InFlags=%lx\n",pnumprs->cDig,pnumprs->dwInFlags);
4308
4309	/* The other struct components are to be set by us */
4310
4311	memset(rgbDig,0,pnumprs->cDig);
4312
4313	cDig = 0;
4314	for (i=0; strIn[i] ;i++) {
4315	if ((strIn[i]>='0') && (strIn[i]<='9')) {
4316	if (pnumprs->cDig > cDig) {
4317	*(rgbDig++)=strIn[i]-'0';
4318	cDig++;
4319	lastent = i;
4320	}
4321	}
4322	}
4323	pnumprs->cDig = cDig;
4324
4325	/* FIXME: Just patching some values in */
4326	pnumprs->nPwr10 = 0;
4327	pnumprs->nBaseShift = 0;
4328	pnumprs->cchUsed = lastent;
4329	pnumprs->dwOutFlags = NUMPRS_DECIMAL;
4330	return S_OK;
4331	}
4332
4333
4334	/**********************************************************************
4335	* VarNumFromParseNum [OLEAUT32.47]
4336	*/
4337	HRESULT WINAPI VarNumFromParseNum(NUMPARSE * pnumprs, BYTE * rgbDig,
4338	ULONG dwVtBits, VARIANT * pvar)
4339	{
4340	DWORD xint;
4341	int i;
4342	FIXME("(,dwVtBits=%lx,....), partial stub!\n",dwVtBits);
4343
4344	xint = 0;
4345	for (i=0;i<pnumprs->cDig;i++)
4346	xint = xint*10 + rgbDig[i];
4347
4348	VariantInit(pvar);
4349	if (dwVtBits & VTBIT_I4) {
4350	V_VT(pvar) = VT_I4;
4351	V_UNION(pvar,intVal) = xint;
4352	return S_OK;
4353	}
4354	if (dwVtBits & VTBIT_R8) {
4355	V_VT(pvar) = VT_R8;
4356	V_UNION(pvar,dblVal) = xint;
4357	return S_OK;
4358	} else {
4359	FIXME("vtbitmask is unsupported %lx\n",dwVtBits);
4360	return E_FAIL;
4361	}
4362	}
4363
4364
4365	/**********************************************************************
4366	* VariantTimeToDosDateTime [OLEAUT32.13]
4367	* Convert variant representation of time to the date and time representation
4368	* stored in dos.
4369	*/
4370	INT WINAPI VariantTimeToDosDateTime(DATE pvtime, USHORT wDosDate, USHORT wDosTime)
4371	{
4372	struct tm t;
4373	*wDosTime = 0;
4374	*wDosDate = 0;
4375
4376	TRACE("( 0x%x, 0x%x, %p ), stub\n", wDosDate, wDosTime, &pvtime );
4377
4378	if (DateToTm(pvtime, 0, &t) < 0) return 0;
4379
4380	wDosTime = wDosTime \| (t.tm_sec / 2);
4381	wDosTime = wDosTime \| (t.tm_min << 5);
4382	wDosTime = wDosTime \| (t.tm_hour << 11);
4383
4384	wDosDate = wDosDate \| t.tm_mday ;
4385	wDosDate = wDosDate \| t.tm_mon << 5;
4386	wDosDate = wDosDate \| ((t.tm_year - 1980) << 9) ;
4387
4388	return 1;
4389	}
4390
4391
4392	/***********************************************************************
4393	* SystemTimeToVariantTime [OLEAUT32.184]
4394	*/
4395	HRESULT WINAPI SystemTimeToVariantTime( LPSYSTEMTIME lpSystemTime, double *pvtime )
4396	{
4397	static const BYTE Days_Per_Month[] = {0, 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
4398	static const BYTE Days_Per_Month_LY[] = {0, 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
4399
4400	struct tm t;
4401
4402	TRACE(" %d/%d/%d %d:%d:%d\n",
4403	lpSystemTime->wMonth, lpSystemTime->wDay,
4404	lpSystemTime->wYear, lpSystemTime->wHour,
4405	lpSystemTime->wMinute, lpSystemTime->wSecond);
4406
4407	if (lpSystemTime->wYear >= 1900)
4408	{
4409	t.tm_sec = lpSystemTime->wSecond;
4410	t.tm_min = lpSystemTime->wMinute;
4411	t.tm_hour = lpSystemTime->wHour;
4412
4413	t.tm_mday = lpSystemTime->wDay;
4414	t.tm_mon = lpSystemTime->wMonth;
4415	t.tm_year = lpSystemTime->wYear;
4416
4417	return TmToDATE( &t, pvtime );
4418	}
4419	else
4420	{
4421	t.tm_sec = lpSystemTime->wSecond;
4422	t.tm_min = lpSystemTime->wMinute;
4423	t.tm_hour = lpSystemTime->wHour;
4424
4425	if (isleap(lpSystemTime->wYear) )
4426	t.tm_mday = Days_Per_Month_LY[13 - lpSystemTime->wMonth] - lpSystemTime->wDay;
4427	else
4428	t.tm_mday = Days_Per_Month[13 - lpSystemTime->wMonth] - lpSystemTime->wDay;
4429
4430	t.tm_mon = 13 - lpSystemTime->wMonth;
4431	t.tm_year = 1900 + 1899 - lpSystemTime->wYear;
4432
4433	TmToDATE( &t, pvtime );
4434
4435	pvtime = -1;
4436
4437	return 1;
4438	}
4439
4440	return 0;
4441	}
4442
4443	/***********************************************************************
4444	* VariantTimeToSystemTime [OLEAUT32.185]
4445	*/
4446	HRESULT WINAPI VariantTimeToSystemTime( double vtime, LPSYSTEMTIME lpSystemTime )
4447	{
4448	double t = 0, timeofday = 0;
4449
4450	static const BYTE Days_Per_Month[] = {0, 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
4451	static const BYTE Days_Per_Month_LY[] = {0, 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
4452
4453	/* The Month_Code is used to find the Day of the Week (LY = LeapYear)*/
4454	static const BYTE Month_Code[] = {0, 1, 4, 4, 0, 2, 5, 0, 3, 6, 1, 4, 6};
4455	static const BYTE Month_Code_LY[] = {0, 0, 3, 4, 0, 2, 5, 0, 3, 6, 1, 4, 6};
4456
4457	/* The Century_Code is used to find the Day of the Week */
4458	static const BYTE Century_Code[] = {0, 6, 4, 2};
4459
4460	struct tm r;
4461
4462	TRACE(" Variant = %f SYSTEMTIME ptr %p", vtime, lpSystemTime);
4463
4464	if (vtime >= 0)
4465	{
4466
4467	if (DateToTm(vtime, 0, &r ) <= 0) return 0;
4468
4469	lpSystemTime->wSecond = r.tm_sec;
4470	lpSystemTime->wMinute = r.tm_min;
4471	lpSystemTime->wHour = r.tm_hour;
4472	lpSystemTime->wDay = r.tm_mday;
4473	lpSystemTime->wMonth = r.tm_mon;
4474
4475	if (lpSystemTime->wMonth == 12)
4476	lpSystemTime->wMonth = 1;
4477	else
4478	lpSystemTime->wMonth++;
4479
4480	lpSystemTime->wYear = r.tm_year;
4481	}
4482	else
4483	{
4484	vtime = -1*vtime;
4485
4486	if (DateToTm(vtime, 0, &r ) <= 0) return 0;
4487
4488	lpSystemTime->wSecond = r.tm_sec;
4489	lpSystemTime->wMinute = r.tm_min;
4490	lpSystemTime->wHour = r.tm_hour;
4491
4492	lpSystemTime->wMonth = 13 - r.tm_mon;
4493
4494	if (lpSystemTime->wMonth == 1)
4495	lpSystemTime->wMonth = 12;
4496	else
4497	lpSystemTime->wMonth--;
4498
4499	lpSystemTime->wYear = 1899 - (r.tm_year - 1900);
4500
4501	if (!isleap(lpSystemTime->wYear) )
4502	lpSystemTime->wDay = Days_Per_Month[13 - lpSystemTime->wMonth] - r.tm_mday;
4503	else
4504	lpSystemTime->wDay = Days_Per_Month_LY[13 - lpSystemTime->wMonth] - r.tm_mday;
4505
4506
4507	}
4508
4509	if (!isleap(lpSystemTime->wYear))
4510	{
4511	/*
4512	(Century_Code+Month_Code+Year_Code+Day) % 7
4513
4514	The century code repeats every 400 years , so the array
4515	works out like this,
4516
4517	Century_Code[0] is for 16th/20th Centry
4518	Century_Code[1] is for 17th/21th Centry
4519	Century_Code[2] is for 18th/22th Centry
4520	Century_Code[3] is for 19th/23th Centry
4521
4522	The year code is found with the formula (year + (year / 4))
4523	the "year" must be between 0 and 99 .
4524
4525	The Month Code (Month_Code[1]) starts with January and
4526	ends with December.
4527	*/
4528
4529	lpSystemTime->wDayOfWeek = (
4530	Century_Code[(( (lpSystemTime->wYear+100) - lpSystemTime->wYear%100) /100) %4]+
4531	((lpSystemTime->wYear%100)+(lpSystemTime->wYear%100)/4)+
4532	Month_Code[lpSystemTime->wMonth]+
4533	lpSystemTime->wDay) % 7;
4534
4535	if (lpSystemTime->wDayOfWeek == 0) lpSystemTime->wDayOfWeek = 7;
4536	else lpSystemTime->wDayOfWeek -= 1;
4537	}
4538	else
4539	{
4540	lpSystemTime->wDayOfWeek = (
4541	Century_Code[(((lpSystemTime->wYear+100) - lpSystemTime->wYear%100)/100)%4]+
4542	((lpSystemTime->wYear%100)+(lpSystemTime->wYear%100)/4)+
4543	Month_Code_LY[lpSystemTime->wMonth]+
4544	lpSystemTime->wDay) % 7;
4545
4546	if (lpSystemTime->wDayOfWeek == 0) lpSystemTime->wDayOfWeek = 7;
4547	else lpSystemTime->wDayOfWeek -= 1;
4548	}
4549
4550	t = floor(vtime);
4551	timeofday = vtime - t;
4552
4553	lpSystemTime->wMilliseconds = (timeofday
4554	- lpSystemTime->wHour*(1/24)
4555	- lpSystemTime->wMinute*(1/1440)
4556	- lpSystemTime->wSecond(1/86400) )(1/5184000);
4557
4558	return 1;
4559	}
4560
4561	/***********************************************************************
4562	* VarUdateFromDate [OLEAUT32.331]
4563	*/
4564	HRESULT WINAPI VarUdateFromDate( DATE datein, ULONG dwFlags, UDATE *pudateout)
4565	{
4566	HRESULT i = 0;
4567	static const BYTE Days_Per_Month[] = {0, 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
4568	static const BYTE Days_Per_Month_LY[] = {0, 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
4569
4570	TRACE("DATE = %f\n", (double)datein);
4571	i = VariantTimeToSystemTime(datein, &(pudateout->st) );
4572
4573	if (i)
4574	{
4575	pudateout->wDayOfYear = 0;
4576
4577	if (isleap(pudateout->st.wYear))
4578	{
4579	for (i =1; i<pudateout->st.wMonth; i++)
4580	pudateout->wDayOfYear += Days_Per_Month[i];
4581	}
4582	else
4583	{
4584	for (i =1; i<pudateout->st.wMonth; i++)
4585	pudateout->wDayOfYear += Days_Per_Month_LY[i];
4586	}
4587
4588	pudateout->wDayOfYear += pudateout->st.wDay;
4589	dwFlags = 0; /VAR_VALIDDATE/
4590	}
4591	else dwFlags = 0;
4592
4593	return i;
4594	}
4595
4596	/***********************************************************************
4597	* VarDateFromUdate [OLEAUT32.330]
4598	*/
4599	HRESULT WINAPI VarDateFromUdate(UDATE *pudateout,
4600	ULONG dwFlags, DATE *datein)
4601	{
4602	HRESULT i;
4603	double t = 0;
4604	TRACE(" %d/%d/%d %d:%d:%d\n",
4605	pudateout->st.wMonth, pudateout->st.wDay,
4606	pudateout->st.wYear, pudateout->st.wHour,
4607	pudateout->st.wMinute, pudateout->st.wSecond);
4608
4609
4610	i = SystemTimeToVariantTime(&(pudateout->st), &t);
4611	*datein = t;
4612
4613	if (i) dwFlags = 0; /VAR_VALIDDATE/
4614	else dwFlags = 0;
4615
4616	return i;
4617	}
4618
4619
4620	/**********************************************************************
4621	* VarBstrCmp [OLEAUT32.440]
4622	*
4623	* flags can be:
4624	* NORM_IGNORECASE, NORM_IGNORENONSPACE, NORM_IGNORESYMBOLS
4625	* NORM_IGNORESTRINGWIDTH, NORM_IGNOREKANATYPE, NORM_IGNOREKASHIDA
4626	*
4627	*/
4628	HRESULT WINAPI VarBstrCmp(BSTR left, BSTR right, LCID lcid, DWORD flags)
4629	{
4630	DWORD r;
4631
4632	FIXME("( %s %s %ld %lx ) partial stub\n", debugstr_w(left), debugstr_w(right), lcid, flags);
4633
4634	if((!left) \|\| (!right))
4635	return VARCMP_NULL;
4636
4637	if(flags&NORM_IGNORECASE)
4638	r = lstrcmpiW(left,right);
4639	else
4640	r = lstrcmpW(left,right);
4641
4642	if(r<0)
4643	return VARCMP_LT;
4644	if(r>0)
4645	return VARCMP_GT;
4646
4647	return VARCMP_EQ;
4648	}
4649
4650	/**********************************************************************
4651	* VarBstrCat [OLEAUT32.439]
4652	*/
4653	HRESULT WINAPI VarBstrCat(BSTR left, BSTR right, BSTR *out)
4654	{
4655	BSTR result;
4656
4657	TRACE("( %s %s %p )\n", debugstr_w(left), debugstr_w(right), out);
4658
4659	if( (!left) \|\| (!right) \|\| (!out) )
4660	return 0;
4661
4662	result = SysAllocStringLen(left, lstrlenW(left)+lstrlenW(right));
4663	lstrcatW(result,right);
4664
4665	*out = result;
4666
4667	return 1;
4668	}
4669
4670	/**********************************************************************
4671	* VarCat [OLEAUT32.441]
4672	*/
4673	HRESULT WINAPI VarCat(LPVARIANT left, LPVARIANT right, LPVARIANT out)
4674	{
4675	/* Should we VariantClear out? */
4676	/* Can we handle array, vector, by ref etc. */
4677	if ((V_VT(left)&VT_TYPEMASK) == VT_NULL &&
4678	(V_VT(right)&VT_TYPEMASK) == VT_NULL)
4679	{
4680	V_VT(out) = VT_NULL;
4681	return S_OK;
4682	}
4683	else if (V_VT(left) == VT_BSTR && V_VT(right) == VT_BSTR)
4684	{
4685	V_VT(out) = VT_BSTR;
4686	VarBstrCat (V_BSTR(left), V_BSTR(right), &V_BSTR(out));
4687	return S_OK;
4688	}
4689	else
4690	FIXME ("types not supported\n");
4691	return S_OK;
4692	}

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