/src/icu/source/i18n/umsg.cpp

Source (jump to first uncovered line)
// © 2016 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
/*
*******************************************************************************
*
*   Copyright (C) 1999-2012, International Business Machines
*   Corporation and others.  All Rights Reserved.
*
*******************************************************************************
*   file name:  umsg.cpp
*   encoding:   UTF-8
*   tab size:   8 (not used)
*   indentation:4
*
* This is a C wrapper to MessageFormat C++ API.
*
*   Change history:
*
*   08/5/2001  Ram         Added C wrappers for C++ API. Changed implementation of old API's
*                          Removed pattern parser.
* 
*/

#include "unicode/utypes.h"

#if !UCONFIG_NO_FORMATTING

#include "unicode/umsg.h"
#include "unicode/ustring.h"
#include "unicode/fmtable.h"
#include "unicode/msgfmt.h"
#include "unicode/unistr.h"
#include "cpputils.h"
#include "uassert.h"
#include "ustr_imp.h"

U_NAMESPACE_BEGIN
/**
 * This class isolates our access to private internal methods of
 * MessageFormat.  It is never instantiated; it exists only for C++
 * access management.
 */
class MessageFormatAdapter {
public:
    static const Formattable::Type* getArgTypeList(const MessageFormat& m,
                                                   int32_t& count);
    static UBool hasArgTypeConflicts(const MessageFormat& m) {
        return m.hasArgTypeConflicts;
    }
};
const Formattable::Type*
MessageFormatAdapter::getArgTypeList(const MessageFormat& m,
                                     int32_t& count) {
    return m.getArgTypeList(count);
}
U_NAMESPACE_END

U_NAMESPACE_USE

U_CAPI int32_t
u_formatMessage(const char  *locale,
                const UChar *pattern,
                int32_t     patternLength,
                UChar       *result,
                int32_t     resultLength,
                UErrorCode  *status,
                ...)
{
    va_list    ap;
    int32_t actLen;        
    //argument checking deferred to subsequent method calls
    // start vararg processing
    va_start(ap, status);

    actLen = u_vformatMessage(locale,pattern,patternLength,result,resultLength,ap,status);
    // end vararg processing
    va_end(ap);

    return actLen;
}

U_CAPI int32_t U_EXPORT2
u_vformatMessage(   const char  *locale,
                    const UChar *pattern,
                    int32_t     patternLength,
                    UChar       *result,
                    int32_t     resultLength,
                    va_list     ap,
                    UErrorCode  *status)

{
    //argument checking deferred to subsequent method calls
    UMessageFormat *fmt = umsg_open(pattern,patternLength,locale,NULL,status);
    int32_t retVal = umsg_vformat(fmt,result,resultLength,ap,status);
    umsg_close(fmt);
    return retVal;
}

U_CAPI int32_t
u_formatMessageWithError(const char *locale,
                        const UChar *pattern,
                        int32_t     patternLength,
                        UChar       *result,
                        int32_t     resultLength,
                        UParseError *parseError,
                        UErrorCode  *status,
                        ...)
{
    va_list    ap;
    int32_t actLen;
    //argument checking deferred to subsequent method calls
    // start vararg processing
    va_start(ap, status);

    actLen = u_vformatMessageWithError(locale,pattern,patternLength,result,resultLength,parseError,ap,status);

    // end vararg processing
    va_end(ap);
    return actLen;
}

U_CAPI int32_t U_EXPORT2
u_vformatMessageWithError(  const char  *locale,
                            const UChar *pattern,
                            int32_t     patternLength,
                            UChar       *result,
                            int32_t     resultLength,
                            UParseError *parseError,
                            va_list     ap,
                            UErrorCode  *status)

{
    //argument checking deferred to subsequent method calls
    UMessageFormat *fmt = umsg_open(pattern,patternLength,locale,parseError,status);
    int32_t retVal = umsg_vformat(fmt,result,resultLength,ap,status);
    umsg_close(fmt);
    return retVal;
}


// For parse, do the reverse of format:
//  1. Call through to the C++ APIs
//  2. Just assume the user passed in enough arguments.
//  3. Iterate through each formattable returned, and assign to the arguments
U_CAPI void
u_parseMessage( const char   *locale,
                const UChar  *pattern,
                int32_t      patternLength,
                const UChar  *source,
                int32_t      sourceLength,
                UErrorCode   *status,
                ...)
{
    va_list    ap;
    //argument checking deferred to subsequent method calls

    // start vararg processing
    va_start(ap, status);

    u_vparseMessage(locale,pattern,patternLength,source,sourceLength,ap,status);
    // end vararg processing
    va_end(ap);
}

U_CAPI void U_EXPORT2
u_vparseMessage(const char  *locale,
                const UChar *pattern,
                int32_t     patternLength,
                const UChar *source,
                int32_t     sourceLength,
                va_list     ap,
                UErrorCode  *status)
{
    //argument checking deferred to subsequent method calls
    UMessageFormat *fmt = umsg_open(pattern,patternLength,locale,NULL,status);
    int32_t count = 0;
    umsg_vparse(fmt,source,sourceLength,&count,ap,status);
    umsg_close(fmt);
}

U_CAPI void
u_parseMessageWithError(const char  *locale,
                        const UChar *pattern,
                        int32_t     patternLength,
                        const UChar *source,
                        int32_t     sourceLength,
                        UParseError *error,
                        UErrorCode  *status,
                        ...)
{
    va_list    ap;

    //argument checking deferred to subsequent method calls

    // start vararg processing
    va_start(ap, status);

    u_vparseMessageWithError(locale,pattern,patternLength,source,sourceLength,ap,error,status);
    // end vararg processing
    va_end(ap);
}
U_CAPI void U_EXPORT2
u_vparseMessageWithError(const char  *locale,
                         const UChar *pattern,
                         int32_t     patternLength,
                         const UChar *source,
                         int32_t     sourceLength,
                         va_list     ap,
                         UParseError *error,
                         UErrorCode* status)
{
    //argument checking deferred to subsequent method calls
    UMessageFormat *fmt = umsg_open(pattern,patternLength,locale,error,status);
    int32_t count = 0;
    umsg_vparse(fmt,source,sourceLength,&count,ap,status);
    umsg_close(fmt);
}
//////////////////////////////////////////////////////////////////////////////////
//
//  Message format C API
//
/////////////////////////////////////////////////////////////////////////////////


U_CAPI UMessageFormat* U_EXPORT2
umsg_open(  const UChar     *pattern,
            int32_t         patternLength,
            const  char     *locale,
            UParseError     *parseError,
            UErrorCode      *status)
{
    //check arguments
    if(status==NULL || U_FAILURE(*status))
    {
      return 0;
    }
    if(pattern==NULL||patternLength<-1){
        *status=U_ILLEGAL_ARGUMENT_ERROR;
        return 0;
    }

    UParseError tErr;
    if(parseError==NULL)
    {
        parseError = &tErr;
    }

    int32_t len = (patternLength == -1 ? u_strlen(pattern) : patternLength);
    UnicodeString patString(patternLength == -1, pattern, len);

    MessageFormat* retVal = new MessageFormat(patString,Locale(locale),*parseError,*status);
    if(retVal == NULL) {
        *status = U_MEMORY_ALLOCATION_ERROR;
        return NULL;
    }
    if (U_SUCCESS(*status) && MessageFormatAdapter::hasArgTypeConflicts(*retVal)) {
        *status = U_ARGUMENT_TYPE_MISMATCH;
    }
    return (UMessageFormat*)retVal;
}

U_CAPI void U_EXPORT2
umsg_close(UMessageFormat* format)
{
    //check arguments
    if(format==NULL){
        return;
    }
    delete (MessageFormat*) format;
}

U_CAPI UMessageFormat U_EXPORT2
umsg_clone(const UMessageFormat *fmt,
           UErrorCode *status)
{
    //check arguments
    if(status==NULL || U_FAILURE(*status)){
        return NULL;
    }
    if(fmt==NULL){
        *status = U_ILLEGAL_ARGUMENT_ERROR;
        return NULL;
    }
    UMessageFormat retVal = (UMessageFormat)((MessageFormat*)fmt)->clone();
    if(retVal == 0) {
        *status = U_MEMORY_ALLOCATION_ERROR;
        return 0;
    }
    return retVal;    
}

U_CAPI void  U_EXPORT2
umsg_setLocale(UMessageFormat *fmt, const char* locale)
{
    //check arguments
    if(fmt==NULL){
        return;
    }
    ((MessageFormat*)fmt)->setLocale(Locale(locale));   
}

U_CAPI const char*  U_EXPORT2
umsg_getLocale(const UMessageFormat *fmt)
{
    //check arguments
    if(fmt==NULL){
        return "";
    }
    return ((const MessageFormat*)fmt)->getLocale().getName();
}

U_CAPI void  U_EXPORT2
umsg_applyPattern(UMessageFormat *fmt,
                           const UChar* pattern,
                           int32_t patternLength,
                           UParseError* parseError,
                           UErrorCode* status)
{
    //check arguments
    UParseError tErr;
    if(status ==NULL||U_FAILURE(*status)){
        return ;
    }
    if(fmt==NULL || (pattern==NULL && patternLength!=0) || patternLength<-1) {
        *status=U_ILLEGAL_ARGUMENT_ERROR;
        return ;
    }

    if(parseError==NULL){
      parseError = &tErr;
    }

    // UnicodeString(pattern, -1) calls u_strlen().
    ((MessageFormat*)fmt)->applyPattern(UnicodeString(pattern,patternLength),*parseError,*status);  
}

U_CAPI int32_t  U_EXPORT2
umsg_toPattern(const UMessageFormat *fmt,
               UChar* result, 
               int32_t resultLength,
               UErrorCode* status)
{
    //check arguments
    if(status ==NULL||U_FAILURE(*status)){
        return -1;
    }
    if(fmt==NULL||resultLength<0 || (resultLength>0 && result==0)){
        *status=U_ILLEGAL_ARGUMENT_ERROR;
        return -1;
    }


    UnicodeString res;
    if(!(result==NULL && resultLength==0)) {
        // NULL destination for pure preflighting: empty dummy string
        // otherwise, alias the destination buffer
        res.setTo(result, 0, resultLength);
    }
    ((const MessageFormat*)fmt)->toPattern(res);
    return res.extract(result, resultLength, *status);
}

U_CAPI int32_t
umsg_format(    const UMessageFormat *fmt,
                UChar          *result,
                int32_t        resultLength,
                UErrorCode     *status,
                ...)
{
    va_list    ap;
    int32_t actLen;  
    //argument checking deferred to last method call umsg_vformat which
    //saves time when arguments are valid and we don't care when arguments are not
    //since we return an error anyway

    
    // start vararg processing
    va_start(ap, status);

    actLen = umsg_vformat(fmt,result,resultLength,ap,status);

    // end vararg processing
    va_end(ap);

    return actLen;
}

U_CAPI int32_t U_EXPORT2
umsg_vformat(   const UMessageFormat *fmt,
                UChar          *result,
                int32_t        resultLength,
                va_list        ap,
                UErrorCode     *status)
{
    //check arguments
    if(status==0 || U_FAILURE(*status))
    {
        return -1;
    }
    if(fmt==NULL||resultLength<0 || (resultLength>0 && result==0)) {
        *status=U_ILLEGAL_ARGUMENT_ERROR;
        return -1;
    }

    int32_t count =0;
    const Formattable::Type* argTypes =
        MessageFormatAdapter::getArgTypeList(*(const MessageFormat*)fmt, count);
    // Allocate at least one element.  Allocating an array of length
    // zero causes problems on some platforms (e.g. Win32).
    Formattable* args = new Formattable[count ? count : 1];

    // iterate through the vararg list, and get the arguments out
    for(int32_t i = 0; i < count; ++i) {
        
        UChar *stringVal;
        double tDouble=0;
        int32_t tInt =0;
        int64_t tInt64 = 0;
        UDate tempDate = 0;
        switch(argTypes[i]) {
        case Formattable::kDate:
            tempDate = va_arg(ap, UDate);
            args[i].setDate(tempDate);
            break;
            
        case Formattable::kDouble:
            tDouble =va_arg(ap, double);
            args[i].setDouble(tDouble);
            break;
            
        case Formattable::kLong:
            tInt = va_arg(ap, int32_t);
            args[i].setLong(tInt);
            break;

        case Formattable::kInt64:
            tInt64 = va_arg(ap, int64_t);
            args[i].setInt64(tInt64);
            break;
            
        case Formattable::kString:
            // For some reason, a temporary is needed
            stringVal = va_arg(ap, UChar*);
            if(stringVal){
                args[i].setString(UnicodeString(stringVal));
            }else{
                *status=U_ILLEGAL_ARGUMENT_ERROR;
            }
            break;
            
        case Formattable::kArray:
            // throw away this argument
            // this is highly platform-dependent, and probably won't work
            // so, if you try to skip arguments in the list (and not use them)
            // you'll probably crash
            va_arg(ap, int);
            break;

        case Formattable::kObject:
            // Unused argument number. Read and ignore a pointer argument.
            va_arg(ap, void*);
            break;

        default:
            // Unknown/unsupported argument type.
            UPRV_UNREACHABLE;
        }
    }
    UnicodeString resultStr;
    FieldPosition fieldPosition(FieldPosition::DONT_CARE);
    
    /* format the message */
    ((const MessageFormat*)fmt)->format(args,count,resultStr,fieldPosition,*status);

    delete[] args;

    if(U_FAILURE(*status)){
        return -1;
    }

    return resultStr.extract(result, resultLength, *status);
}

U_CAPI void
umsg_parse( const UMessageFormat *fmt,
            const UChar    *source,
            int32_t        sourceLength,
            int32_t        *count,
            UErrorCode     *status,
            ...)
{
    va_list    ap;
    //argument checking deferred to last method call umsg_vparse which
    //saves time when arguments are valid and we don't care when arguments are not
    //since we return an error anyway

    // start vararg processing
    va_start(ap, status);

    umsg_vparse(fmt,source,sourceLength,count,ap,status);

    // end vararg processing
    va_end(ap);
}

U_CAPI void U_EXPORT2
umsg_vparse(const UMessageFormat *fmt,
            const UChar    *source,
            int32_t        sourceLength,
            int32_t        *count,
            va_list        ap,
            UErrorCode     *status)
{
    //check arguments
    if(status==NULL||U_FAILURE(*status))
    {
        return;
    }
    if(fmt==NULL||source==NULL || sourceLength<-1 || count==NULL){
        *status=U_ILLEGAL_ARGUMENT_ERROR;
        return;
    }
    if(sourceLength==-1){
        sourceLength=u_strlen(source);
    }

    UnicodeString srcString(source,sourceLength);
    Formattable *args = ((const MessageFormat*)fmt)->parse(srcString,*count,*status);
    UDate *aDate;
    double *aDouble;
    UChar *aString;
    int32_t* aInt;
    int64_t* aInt64;
    UnicodeString temp;
    int len =0;
    // assign formattables to varargs
    for(int32_t i = 0; i < *count; i++) {
        switch(args[i].getType()) {

        case Formattable::kDate:
            aDate = va_arg(ap, UDate*);
            if(aDate){
                *aDate = args[i].getDate();
            }else{
                *status=U_ILLEGAL_ARGUMENT_ERROR;
            }
            break;

        case Formattable::kDouble:
            aDouble = va_arg(ap, double*);
            if(aDouble){
                *aDouble = args[i].getDouble();
            }else{
                *status=U_ILLEGAL_ARGUMENT_ERROR;
            }
            break;

        case Formattable::kLong:
            aInt = va_arg(ap, int32_t*);
            if(aInt){
                *aInt = (int32_t) args[i].getLong();
            }else{
                *status=U_ILLEGAL_ARGUMENT_ERROR;
            }
            break;

        case Formattable::kInt64:
            aInt64 = va_arg(ap, int64_t*);
            if(aInt64){
                *aInt64 = args[i].getInt64();
            }else{
                *status=U_ILLEGAL_ARGUMENT_ERROR;
            }
            break;

        case Formattable::kString:
            aString = va_arg(ap, UChar*);
            if(aString){
                args[i].getString(temp);
                len = temp.length();
                temp.extract(0,len,aString);
                aString[len]=0;
            }else{
                *status= U_ILLEGAL_ARGUMENT_ERROR;
            }
            break;

        case Formattable::kObject:
            // This will never happen because MessageFormat doesn't
            // support kObject.  When MessageFormat is changed to
            // understand MeasureFormats, modify this code to do the
            // right thing. [alan]
            UPRV_UNREACHABLE;

        // better not happen!
        case Formattable::kArray:
            UPRV_UNREACHABLE;
        }
    }

    // clean up
    delete [] args;
}

#define SINGLE_QUOTE      ((UChar)0x0027)
#define CURLY_BRACE_LEFT  ((UChar)0x007B)
#define CURLY_BRACE_RIGHT ((UChar)0x007D)

#define STATE_INITIAL 0
#define STATE_SINGLE_QUOTE 1
#define STATE_IN_QUOTE 2
#define STATE_MSG_ELEMENT 3

#define MAppend(c) if (len < destCapacity) dest[len++] = c; else len++

int32_t umsg_autoQuoteApostrophe(const UChar* pattern, 
                 int32_t patternLength,
                 UChar* dest,
                 int32_t destCapacity,
                 UErrorCode* ec)
{
    int32_t state = STATE_INITIAL;
    int32_t braceCount = 0;
    int32_t len = 0;

    if (ec == NULL || U_FAILURE(*ec)) {
        return -1;
    }

    if (pattern == NULL || patternLength < -1 || (dest == NULL && destCapacity > 0)) {
        *ec = U_ILLEGAL_ARGUMENT_ERROR;
        return -1;
    }
    U_ASSERT(destCapacity >= 0);

    if (patternLength == -1) {
        patternLength = u_strlen(pattern);
    }

    for (int i = 0; i < patternLength; ++i) {
        UChar c = pattern[i];
        switch (state) {
        case STATE_INITIAL:
            switch (c) {
            case SINGLE_QUOTE:
                state = STATE_SINGLE_QUOTE;
                break;
            case CURLY_BRACE_LEFT:
                state = STATE_MSG_ELEMENT;
                ++braceCount;
                break;
            }
            break;

        case STATE_SINGLE_QUOTE:
            switch (c) {
            case SINGLE_QUOTE:
                state = STATE_INITIAL;
                break;
            case CURLY_BRACE_LEFT:
            case CURLY_BRACE_RIGHT:
                state = STATE_IN_QUOTE;
                break;
            default:
                MAppend(SINGLE_QUOTE);
                state = STATE_INITIAL;
                break;
            }
        break;

        case STATE_IN_QUOTE:
            switch (c) {
            case SINGLE_QUOTE:
                state = STATE_INITIAL;
                break;
            }
            break;

        case STATE_MSG_ELEMENT:
            switch (c) {
            case CURLY_BRACE_LEFT:
                ++braceCount;
                break;
            case CURLY_BRACE_RIGHT:
                if (--braceCount == 0) {
                    state = STATE_INITIAL;
                }
                break;
            }
            break;

        default: // Never happens.
            break;
        }

        U_ASSERT(len >= 0);
        MAppend(c);
    }

    // End of scan
    if (state == STATE_SINGLE_QUOTE || state == STATE_IN_QUOTE) {
        MAppend(SINGLE_QUOTE);
    }

    return u_terminateUChars(dest, destCapacity, len, ec);
}

#endif /* #if !UCONFIG_NO_FORMATTING */

Coverage Report

Created: 2025-01-28 06:38

Line	Count	Source (jump to first uncovered line)
1		// © 2016 and later: Unicode, Inc. and others.
2		// License & terms of use: http://www.unicode.org/copyright.html
3		/*
4		*******************************************************************************
5		*
6		* Copyright (C) 1999-2012, International Business Machines
7		* Corporation and others. All Rights Reserved.
8		*
9		*******************************************************************************
10		* file name: umsg.cpp
11		* encoding: UTF-8
12		* tab size: 8 (not used)
13		* indentation:4
14		*
15		* This is a C wrapper to MessageFormat C++ API.
16		*
17		* Change history:
18		*
19		* 08/5/2001 Ram Added C wrappers for C++ API. Changed implementation of old API's
20		* Removed pattern parser.
21		*
22		*/
23
24		#include "unicode/utypes.h"
25
26		#if !UCONFIG_NO_FORMATTING
27
28		#include "unicode/umsg.h"
29		#include "unicode/ustring.h"
30		#include "unicode/fmtable.h"
31		#include "unicode/msgfmt.h"
32		#include "unicode/unistr.h"
33		#include "cpputils.h"
34		#include "uassert.h"
35		#include "ustr_imp.h"
36
37		U_NAMESPACE_BEGIN
38		/**
39		* This class isolates our access to private internal methods of
40		* MessageFormat. It is never instantiated; it exists only for C++
41		* access management.
42		*/
43		class MessageFormatAdapter {
44		public:
45		static const Formattable::Type* getArgTypeList(const MessageFormat& m,
46		int32_t& count);
47	0	static UBool hasArgTypeConflicts(const MessageFormat& m) {
48	0	return m.hasArgTypeConflicts;
49	0	}
50		};
51		const Formattable::Type*
52		MessageFormatAdapter::getArgTypeList(const MessageFormat& m,
53	0	int32_t& count) {
54	0	return m.getArgTypeList(count);
55	0	}
56		U_NAMESPACE_END
57
58		U_NAMESPACE_USE
59
60		U_CAPI int32_t
61		u_formatMessage(const char *locale,
62		const UChar *pattern,
63		int32_t patternLength,
64		UChar *result,
65		int32_t resultLength,
66		UErrorCode *status,
67		...)
68	0	{
69	0	va_list ap;
70	0	int32_t actLen;
71		//argument checking deferred to subsequent method calls
72		// start vararg processing
73	0	va_start(ap, status);
74
75	0	actLen = u_vformatMessage(locale,pattern,patternLength,result,resultLength,ap,status);
76		// end vararg processing
77	0	va_end(ap);
78
79	0	return actLen;
80	0	}
81
82		U_CAPI int32_t U_EXPORT2
83		u_vformatMessage( const char *locale,
84		const UChar *pattern,
85		int32_t patternLength,
86		UChar *result,
87		int32_t resultLength,
88		va_list ap,
89		UErrorCode *status)
90
91	0	{
92		//argument checking deferred to subsequent method calls
93	0	UMessageFormat *fmt = umsg_open(pattern,patternLength,locale,NULL,status);
94	0	int32_t retVal = umsg_vformat(fmt,result,resultLength,ap,status);
95	0	umsg_close(fmt);
96	0	return retVal;
97	0	}
98
99		U_CAPI int32_t
100		u_formatMessageWithError(const char *locale,
101		const UChar *pattern,
102		int32_t patternLength,
103		UChar *result,
104		int32_t resultLength,
105		UParseError *parseError,
106		UErrorCode *status,
107		...)
108	0	{
109	0	va_list ap;
110	0	int32_t actLen;
111		//argument checking deferred to subsequent method calls
112		// start vararg processing
113	0	va_start(ap, status);
114
115	0	actLen = u_vformatMessageWithError(locale,pattern,patternLength,result,resultLength,parseError,ap,status);
116
117		// end vararg processing
118	0	va_end(ap);
119	0	return actLen;
120	0	}
121
122		U_CAPI int32_t U_EXPORT2
123		u_vformatMessageWithError( const char *locale,
124		const UChar *pattern,
125		int32_t patternLength,
126		UChar *result,
127		int32_t resultLength,
128		UParseError *parseError,
129		va_list ap,
130		UErrorCode *status)
131
132	0	{
133		//argument checking deferred to subsequent method calls
134	0	UMessageFormat *fmt = umsg_open(pattern,patternLength,locale,parseError,status);
135	0	int32_t retVal = umsg_vformat(fmt,result,resultLength,ap,status);
136	0	umsg_close(fmt);
137	0	return retVal;
138	0	}
139
140
141		// For parse, do the reverse of format:
142		// 1. Call through to the C++ APIs
143		// 2. Just assume the user passed in enough arguments.
144		// 3. Iterate through each formattable returned, and assign to the arguments
145		U_CAPI void
146		u_parseMessage( const char *locale,
147		const UChar *pattern,
148		int32_t patternLength,
149		const UChar *source,
150		int32_t sourceLength,
151		UErrorCode *status,
152		...)
153	0	{
154	0	va_list ap;
155		//argument checking deferred to subsequent method calls
156
157		// start vararg processing
158	0	va_start(ap, status);
159
160	0	u_vparseMessage(locale,pattern,patternLength,source,sourceLength,ap,status);
161		// end vararg processing
162	0	va_end(ap);
163	0	}
164
165		U_CAPI void U_EXPORT2
166		u_vparseMessage(const char *locale,
167		const UChar *pattern,
168		int32_t patternLength,
169		const UChar *source,
170		int32_t sourceLength,
171		va_list ap,
172		UErrorCode *status)
173	0	{
174		//argument checking deferred to subsequent method calls
175	0	UMessageFormat *fmt = umsg_open(pattern,patternLength,locale,NULL,status);
176	0	int32_t count = 0;
177	0	umsg_vparse(fmt,source,sourceLength,&count,ap,status);
178	0	umsg_close(fmt);
179	0	}
180
181		U_CAPI void
182		u_parseMessageWithError(const char *locale,
183		const UChar *pattern,
184		int32_t patternLength,
185		const UChar *source,
186		int32_t sourceLength,
187		UParseError *error,
188		UErrorCode *status,
189		...)
190	0	{
191	0	va_list ap;
192
193		//argument checking deferred to subsequent method calls
194
195		// start vararg processing
196	0	va_start(ap, status);
197
198	0	u_vparseMessageWithError(locale,pattern,patternLength,source,sourceLength,ap,error,status);
199		// end vararg processing
200	0	va_end(ap);
201	0	}
202		U_CAPI void U_EXPORT2
203		u_vparseMessageWithError(const char *locale,
204		const UChar *pattern,
205		int32_t patternLength,
206		const UChar *source,
207		int32_t sourceLength,
208		va_list ap,
209		UParseError *error,
210		UErrorCode* status)
211	0	{
212		//argument checking deferred to subsequent method calls
213	0	UMessageFormat *fmt = umsg_open(pattern,patternLength,locale,error,status);
214	0	int32_t count = 0;
215	0	umsg_vparse(fmt,source,sourceLength,&count,ap,status);
216	0	umsg_close(fmt);
217	0	}
218		//////////////////////////////////////////////////////////////////////////////////
219		//
220		// Message format C API
221		//
222		/////////////////////////////////////////////////////////////////////////////////
223
224
225		U_CAPI UMessageFormat* U_EXPORT2
226		umsg_open( const UChar *pattern,
227		int32_t patternLength,
228		const char *locale,
229		UParseError *parseError,
230		UErrorCode *status)
231	0	{
232		//check arguments
233	0	if(status==NULL \|\| U_FAILURE(*status))
234	0	{
235	0	return 0;
236	0	}
237	0	if(pattern==NULL\|\|patternLength<-1){
238	0	*status=U_ILLEGAL_ARGUMENT_ERROR;
239	0	return 0;
240	0	}
241
242	0	UParseError tErr;
243	0	if(parseError==NULL)
244	0	{
245	0	parseError = &tErr;
246	0	}
247
248	0	int32_t len = (patternLength == -1 ? u_strlen(pattern) : patternLength);
249	0	UnicodeString patString(patternLength == -1, pattern, len);
250
251	0	MessageFormat* retVal = new MessageFormat(patString,Locale(locale),parseError,status);
252	0	if(retVal == NULL) {
253	0	*status = U_MEMORY_ALLOCATION_ERROR;
254	0	return NULL;
255	0	}
256	0	if (U_SUCCESS(status) && MessageFormatAdapter::hasArgTypeConflicts(retVal)) {
257	0	*status = U_ARGUMENT_TYPE_MISMATCH;
258	0	}
259	0	return (UMessageFormat*)retVal;
260	0	}
261
262		U_CAPI void U_EXPORT2
263		umsg_close(UMessageFormat* format)
264	0	{
265		//check arguments
266	0	if(format==NULL){
267	0	return;
268	0	}
269	0	delete (MessageFormat*) format;
270	0	}
271
272		U_CAPI UMessageFormat U_EXPORT2
273		umsg_clone(const UMessageFormat *fmt,
274		UErrorCode *status)
275	0	{
276		//check arguments
277	0	if(status==NULL \|\| U_FAILURE(*status)){
278	0	return NULL;
279	0	}
280	0	if(fmt==NULL){
281	0	*status = U_ILLEGAL_ARGUMENT_ERROR;
282	0	return NULL;
283	0	}
284	0	UMessageFormat retVal = (UMessageFormat)((MessageFormat*)fmt)->clone();
285	0	if(retVal == 0) {
286	0	*status = U_MEMORY_ALLOCATION_ERROR;
287	0	return 0;
288	0	}
289	0	return retVal;
290	0	}
291
292		U_CAPI void U_EXPORT2
293		umsg_setLocale(UMessageFormat fmt, const char locale)
294	0	{
295		//check arguments
296	0	if(fmt==NULL){
297	0	return;
298	0	}
299	0	((MessageFormat*)fmt)->setLocale(Locale(locale));
300	0	}
301
302		U_CAPI const char* U_EXPORT2
303		umsg_getLocale(const UMessageFormat *fmt)
304	0	{
305		//check arguments
306	0	if(fmt==NULL){
307	0	return "";
308	0	}
309	0	return ((const MessageFormat*)fmt)->getLocale().getName();
310	0	}
311
312		U_CAPI void U_EXPORT2
313		umsg_applyPattern(UMessageFormat *fmt,
314		const UChar* pattern,
315		int32_t patternLength,
316		UParseError* parseError,
317		UErrorCode* status)
318	0	{
319		//check arguments
320	0	UParseError tErr;
321	0	if(status ==NULL\|\|U_FAILURE(*status)){
322	0	return ;
323	0	}
324	0	if(fmt==NULL \|\| (pattern==NULL && patternLength!=0) \|\| patternLength<-1) {
325	0	*status=U_ILLEGAL_ARGUMENT_ERROR;
326	0	return ;
327	0	}
328
329	0	if(parseError==NULL){
330	0	parseError = &tErr;
331	0	}
332
333		// UnicodeString(pattern, -1) calls u_strlen().
334	0	((MessageFormat)fmt)->applyPattern(UnicodeString(pattern,patternLength),parseError,*status);
335	0	}
336
337		U_CAPI int32_t U_EXPORT2
338		umsg_toPattern(const UMessageFormat *fmt,
339		UChar* result,
340		int32_t resultLength,
341		UErrorCode* status)
342	0	{
343		//check arguments
344	0	if(status ==NULL\|\|U_FAILURE(*status)){
345	0	return -1;
346	0	}
347	0	if(fmt==NULL\|\|resultLength<0 \|\| (resultLength>0 && result==0)){
348	0	*status=U_ILLEGAL_ARGUMENT_ERROR;
349	0	return -1;
350	0	}
351
352
353	0	UnicodeString res;
354	0	if(!(result==NULL && resultLength==0)) {
355		// NULL destination for pure preflighting: empty dummy string
356		// otherwise, alias the destination buffer
357	0	res.setTo(result, 0, resultLength);
358	0	}
359	0	((const MessageFormat*)fmt)->toPattern(res);
360	0	return res.extract(result, resultLength, *status);
361	0	}
362
363		U_CAPI int32_t
364		umsg_format( const UMessageFormat *fmt,
365		UChar *result,
366		int32_t resultLength,
367		UErrorCode *status,
368		...)
369	0	{
370	0	va_list ap;
371	0	int32_t actLen;
372		//argument checking deferred to last method call umsg_vformat which
373		//saves time when arguments are valid and we don't care when arguments are not
374		//since we return an error anyway
375
376
377		// start vararg processing
378	0	va_start(ap, status);
379
380	0	actLen = umsg_vformat(fmt,result,resultLength,ap,status);
381
382		// end vararg processing
383	0	va_end(ap);
384
385	0	return actLen;
386	0	}
387
388		U_CAPI int32_t U_EXPORT2
389		umsg_vformat( const UMessageFormat *fmt,
390		UChar *result,
391		int32_t resultLength,
392		va_list ap,
393		UErrorCode *status)
394	0	{
395		//check arguments
396	0	if(status==0 \|\| U_FAILURE(*status))
397	0	{
398	0	return -1;
399	0	}
400	0	if(fmt==NULL\|\|resultLength<0 \|\| (resultLength>0 && result==0)) {
401	0	*status=U_ILLEGAL_ARGUMENT_ERROR;
402	0	return -1;
403	0	}
404
405	0	int32_t count =0;
406	0	const Formattable::Type* argTypes =
407	0	MessageFormatAdapter::getArgTypeList((const MessageFormat)fmt, count);
408		// Allocate at least one element. Allocating an array of length
409		// zero causes problems on some platforms (e.g. Win32).
410	0	Formattable* args = new Formattable[count ? count : 1];
411
412		// iterate through the vararg list, and get the arguments out
413	0	for(int32_t i = 0; i < count; ++i) {
414
415	0	UChar *stringVal;
416	0	double tDouble=0;
417	0	int32_t tInt =0;
418	0	int64_t tInt64 = 0;
419	0	UDate tempDate = 0;
420	0	switch(argTypes[i]) {
421	0	case Formattable::kDate:
422	0	tempDate = va_arg(ap, UDate);
423	0	args[i].setDate(tempDate);
424	0	break;
425
426	0	case Formattable::kDouble:
427	0	tDouble =va_arg(ap, double);
428	0	args[i].setDouble(tDouble);
429	0	break;
430
431	0	case Formattable::kLong:
432	0	tInt = va_arg(ap, int32_t);
433	0	args[i].setLong(tInt);
434	0	break;
435
436	0	case Formattable::kInt64:
437	0	tInt64 = va_arg(ap, int64_t);
438	0	args[i].setInt64(tInt64);
439	0	break;
440
441	0	case Formattable::kString:
442		// For some reason, a temporary is needed
443	0	stringVal = va_arg(ap, UChar*);
444	0	if(stringVal){
445	0	args[i].setString(UnicodeString(stringVal));
446	0	}else{
447	0	*status=U_ILLEGAL_ARGUMENT_ERROR;
448	0	}
449	0	break;
450
451	0	case Formattable::kArray:
452		// throw away this argument
453		// this is highly platform-dependent, and probably won't work
454		// so, if you try to skip arguments in the list (and not use them)
455		// you'll probably crash
456	0	va_arg(ap, int);
457	0	break;
458
459	0	case Formattable::kObject:
460		// Unused argument number. Read and ignore a pointer argument.
461	0	va_arg(ap, void*);
462	0	break;
463
464	0	default:
465		// Unknown/unsupported argument type.
466	0	UPRV_UNREACHABLE;
467	0	}
468	0	}
469	0	UnicodeString resultStr;
470	0	FieldPosition fieldPosition(FieldPosition::DONT_CARE);
471
472		/* format the message */
473	0	((const MessageFormat)fmt)->format(args,count,resultStr,fieldPosition,status);
474
475	0	delete[] args;
476
477	0	if(U_FAILURE(*status)){
478	0	return -1;
479	0	}
480
481	0	return resultStr.extract(result, resultLength, *status);
482	0	}
483
484		U_CAPI void
485		umsg_parse( const UMessageFormat *fmt,
486		const UChar *source,
487		int32_t sourceLength,
488		int32_t *count,
489		UErrorCode *status,
490		...)
491	0	{
492	0	va_list ap;
493		//argument checking deferred to last method call umsg_vparse which
494		//saves time when arguments are valid and we don't care when arguments are not
495		//since we return an error anyway
496
497		// start vararg processing
498	0	va_start(ap, status);
499
500	0	umsg_vparse(fmt,source,sourceLength,count,ap,status);
501
502		// end vararg processing
503	0	va_end(ap);
504	0	}
505
506		U_CAPI void U_EXPORT2
507		umsg_vparse(const UMessageFormat *fmt,
508		const UChar *source,
509		int32_t sourceLength,
510		int32_t *count,
511		va_list ap,
512		UErrorCode *status)
513	0	{
514		//check arguments
515	0	if(status==NULL\|\|U_FAILURE(*status))
516	0	{
517	0	return;
518	0	}
519	0	if(fmt==NULL\|\|source==NULL \|\| sourceLength<-1 \|\| count==NULL){
520	0	*status=U_ILLEGAL_ARGUMENT_ERROR;
521	0	return;
522	0	}
523	0	if(sourceLength==-1){
524	0	sourceLength=u_strlen(source);
525	0	}
526
527	0	UnicodeString srcString(source,sourceLength);
528	0	Formattable args = ((const MessageFormat)fmt)->parse(srcString,count,status);
529	0	UDate *aDate;
530	0	double *aDouble;
531	0	UChar *aString;
532	0	int32_t* aInt;
533	0	int64_t* aInt64;
534	0	UnicodeString temp;
535	0	int len =0;
536		// assign formattables to varargs
537	0	for(int32_t i = 0; i < *count; i++) {
538	0	switch(args[i].getType()) {
539
540	0	case Formattable::kDate:
541	0	aDate = va_arg(ap, UDate*);
542	0	if(aDate){
543	0	*aDate = args[i].getDate();
544	0	}else{
545	0	*status=U_ILLEGAL_ARGUMENT_ERROR;
546	0	}
547	0	break;
548
549	0	case Formattable::kDouble:
550	0	aDouble = va_arg(ap, double*);
551	0	if(aDouble){
552	0	*aDouble = args[i].getDouble();
553	0	}else{
554	0	*status=U_ILLEGAL_ARGUMENT_ERROR;
555	0	}
556	0	break;
557
558	0	case Formattable::kLong:
559	0	aInt = va_arg(ap, int32_t*);
560	0	if(aInt){
561	0	*aInt = (int32_t) args[i].getLong();
562	0	}else{
563	0	*status=U_ILLEGAL_ARGUMENT_ERROR;
564	0	}
565	0	break;
566
567	0	case Formattable::kInt64:
568	0	aInt64 = va_arg(ap, int64_t*);
569	0	if(aInt64){
570	0	*aInt64 = args[i].getInt64();
571	0	}else{
572	0	*status=U_ILLEGAL_ARGUMENT_ERROR;
573	0	}
574	0	break;
575
576	0	case Formattable::kString:
577	0	aString = va_arg(ap, UChar*);
578	0	if(aString){
579	0	args[i].getString(temp);
580	0	len = temp.length();
581	0	temp.extract(0,len,aString);
582	0	aString[len]=0;
583	0	}else{
584	0	*status= U_ILLEGAL_ARGUMENT_ERROR;
585	0	}
586	0	break;
587
588	0	case Formattable::kObject:
589		// This will never happen because MessageFormat doesn't
590		// support kObject. When MessageFormat is changed to
591		// understand MeasureFormats, modify this code to do the
592		// right thing. [alan]
593	0	UPRV_UNREACHABLE;
594
595		// better not happen!
596	0	case Formattable::kArray:
597	0	UPRV_UNREACHABLE;
598	0	}
599	0	}
600
601		// clean up
602	0	delete [] args;
603	0	}
604
605	0	#define SINGLE_QUOTE ((UChar)0x0027)
606	0	#define CURLY_BRACE_LEFT ((UChar)0x007B)
607	0	#define CURLY_BRACE_RIGHT ((UChar)0x007D)
608
609	0	#define STATE_INITIAL 0
610	0	#define STATE_SINGLE_QUOTE 1
611	0	#define STATE_IN_QUOTE 2
612	0	#define STATE_MSG_ELEMENT 3
613
614	0	#define MAppend(c) if (len < destCapacity) dest[len++] = c; else len++
615
616		int32_t umsg_autoQuoteApostrophe(const UChar* pattern,
617		int32_t patternLength,
618		UChar* dest,
619		int32_t destCapacity,
620		UErrorCode* ec)
621	0	{
622	0	int32_t state = STATE_INITIAL;
623	0	int32_t braceCount = 0;
624	0	int32_t len = 0;
625
626	0	if (ec == NULL \|\| U_FAILURE(*ec)) {
627	0	return -1;
628	0	}
629
630	0	if (pattern == NULL \|\| patternLength < -1 \|\| (dest == NULL && destCapacity > 0)) {
631	0	*ec = U_ILLEGAL_ARGUMENT_ERROR;
632	0	return -1;
633	0	}
634	0	U_ASSERT(destCapacity >= 0);
635
636	0	if (patternLength == -1) {
637	0	patternLength = u_strlen(pattern);
638	0	}
639
640	0	for (int i = 0; i < patternLength; ++i) {
641	0	UChar c = pattern[i];
642	0	switch (state) {
643	0	case STATE_INITIAL:
644	0	switch (c) {
645	0	case SINGLE_QUOTE:
646	0	state = STATE_SINGLE_QUOTE;
647	0	break;
648	0	case CURLY_BRACE_LEFT:
649	0	state = STATE_MSG_ELEMENT;
650	0	++braceCount;
651	0	break;
652	0	}
653	0	break;
654
655	0	case STATE_SINGLE_QUOTE:
656	0	switch (c) {
657	0	case SINGLE_QUOTE:
658	0	state = STATE_INITIAL;
659	0	break;
660	0	case CURLY_BRACE_LEFT:
661	0	case CURLY_BRACE_RIGHT:
662	0	state = STATE_IN_QUOTE;
663	0	break;
664	0	default:
665	0	MAppend(SINGLE_QUOTE);
666	0	state = STATE_INITIAL;
667	0	break;
668	0	}
669	0	break;
670
671	0	case STATE_IN_QUOTE:
672	0	switch (c) {
673	0	case SINGLE_QUOTE:
674	0	state = STATE_INITIAL;
675	0	break;
676	0	}
677	0	break;
678
679	0	case STATE_MSG_ELEMENT:
680	0	switch (c) {
681	0	case CURLY_BRACE_LEFT:
682	0	++braceCount;
683	0	break;
684	0	case CURLY_BRACE_RIGHT:
685	0	if (--braceCount == 0) {
686	0	state = STATE_INITIAL;
687	0	}
688	0	break;
689	0	}
690	0	break;
691
692	0	default: // Never happens.
693	0	break;
694	0	}
695
696	0	U_ASSERT(len >= 0);
697	0	MAppend(c);
698	0	}
699
700		// End of scan
701	0	if (state == STATE_SINGLE_QUOTE \|\| state == STATE_IN_QUOTE) {
702	0	MAppend(SINGLE_QUOTE);
703	0	}
704
705	0	return u_terminateUChars(dest, destCapacity, len, ec);
706	0	}
707
708		#endif /* #if !UCONFIG_NO_FORMATTING */