icu/source/common/utrace.c - nest-learning-thermostat/5.0/icu - Git at Google

 /*
 *******************************************************************************
 *   Copyright (C) 2003-2008, International Business Machines
 *   Corporation and others.  All Rights Reserved.
 *******************************************************************************
 *   file name:  utrace.c
 *   encoding:   US-ASCII
 *   tab size:   8 (not used)
 *   indentation:4
 */

 #define   UTRACE_IMPL
 #include "unicode/utrace.h"
 #include "utracimp.h"
 #include "cstring.h"
 #include "uassert.h"
 #include "ucln_cmn.h"


 static UTraceEntry     *pTraceEntryFunc = NULL;
 static UTraceExit      *pTraceExitFunc  = NULL;
 static UTraceData      *pTraceDataFunc  = NULL;
 static const void      *gTraceContext   = NULL;

 U_EXPORT int32_t
 utrace_level = UTRACE_ERROR;

 U_CAPI void U_EXPORT2
 utrace_entry(int32_t fnNumber) {
     if (pTraceEntryFunc != NULL) {
         (*pTraceEntryFunc)(gTraceContext, fnNumber);
     }
 }


 static const char gExitFmt[]             = "Returns.";
 static const char gExitFmtValue[]        = "Returns %d.";
 static const char gExitFmtStatus[]       = "Returns.  Status = %d.";
 static const char gExitFmtValueStatus[]  = "Returns %d.  Status = %d.";
 static const char gExitFmtPtrStatus[]    = "Returns %d.  Status = %p.";

 U_CAPI void U_EXPORT2
 utrace_exit(int32_t fnNumber, int32_t returnType, ...) {
     if (pTraceExitFunc != NULL) {
         va_list     args;
         const char *fmt;

         switch (returnType) {
         case 0:
             fmt = gExitFmt;
             break;
         case UTRACE_EXITV_I32:
             fmt = gExitFmtValue;
             break;
         case UTRACE_EXITV_STATUS:
             fmt = gExitFmtStatus;
             break;
         case UTRACE_EXITV_I32 | UTRACE_EXITV_STATUS:
             fmt = gExitFmtValueStatus;
             break;
         case UTRACE_EXITV_PTR | UTRACE_EXITV_STATUS:
             fmt = gExitFmtPtrStatus;
             break;
         default:
             U_ASSERT(FALSE);
             fmt = gExitFmt;
         }

         va_start(args, returnType);
         (*pTraceExitFunc)(gTraceContext, fnNumber, fmt, args);
         va_end(args);
     }
 }


 U_CAPI void U_EXPORT2
 utrace_data(int32_t fnNumber, int32_t level, const char *fmt, ...) {
     if (pTraceDataFunc != NULL) {
            va_list args;
            va_start(args, fmt );
            (*pTraceDataFunc)(gTraceContext, fnNumber, level, fmt, args);
            va_end(args);
     }
 }


 static void outputChar(char c, char *outBuf, int32_t *outIx, int32_t capacity, int32_t indent) {
     int32_t i;
     /* Check whether a start of line indenting is needed.  Three cases:
      *   1.  At the start of the first line  (output index == 0).
      *   2.  At the start of subsequent lines  (preceeding char in buffer == '\n')
      *   3.  When preflighting buffer len (buffer capacity is exceeded), when
      *       a \n is output.  Ideally we wouldn't do the indent until the following char
      *       is received, but that won't work because there's no place to remember that
      *       the preceding char was \n.  Meaning that we may overstimate the
      *       buffer size needed.  No harm done.
      */
     if (*outIx==0 ||   /* case 1. */
         (c!='\n' && c!=0 && *outIx < capacity && outBuf[(*outIx)-1]=='\n') ||  /* case 2. */
         (c=='\n' && *outIx>=capacity))    /* case 3 */
     {
         /* At the start of a line.  Indent. */
         for(i=0; i<indent; i++) {
             if (*outIx < capacity) {
                 outBuf[*outIx] = ' ';
             }
             (*outIx)++;
         }
     }

     if (*outIx < capacity) {
         outBuf[*outIx] = c;
     }
     if (c != 0) {
         /* Nulls only appear as end-of-string terminators.  Move them to the output
          *  buffer, but do not update the length of the buffer, so that any
          *  following output will overwrite the null. */
         (*outIx)++;
     }
 }

 static void outputHexBytes(int64_t val, int32_t charsToOutput,
                            char *outBuf, int32_t *outIx, int32_t capacity) {
     static const char gHexChars[] = "0123456789abcdef";
     int32_t shiftCount;
     for  (shiftCount=(charsToOutput-1)*4; shiftCount >= 0; shiftCount-=4) {
         char c = gHexChars[(val >> shiftCount) & 0xf];
         outputChar(c, outBuf, outIx, capacity, 0);
     }
 }

 /* Output a pointer value in hex.  Work with any size of pointer   */
 static void outputPtrBytes(void *val, char *outBuf, int32_t *outIx, int32_t capacity) {
     int32_t  i;
     int32_t  incVal = 1;              /* +1 for big endian, -1 for little endian          */
     char     *p     = (char *)&val;   /* point to current byte to output in the ptr val  */

 #if !U_IS_BIG_ENDIAN
     /* Little Endian.  Move p to most significant end of the value      */
     incVal = -1;
     p += sizeof(void *) - 1;
 #endif

     /* Loop through the bytes of the ptr as it sits in memory, from
      * most significant to least significant end                    */
     for (i=0; i<sizeof(void *); i++) {
         outputHexBytes(*p, 2, outBuf, outIx, capacity);
         p += incVal;
     }
 }

 static void outputString(const char *s, char *outBuf, int32_t *outIx, int32_t capacity, int32_t indent) {
     int32_t i = 0;
     char    c;
     if (s==NULL) {
         s = "*NULL*";
     }
     do {
         c = s[i++];
         outputChar(c, outBuf, outIx, capacity, indent);
     } while (c != 0);
 }


 static void outputUString(const UChar *s, int32_t len,
                           char *outBuf, int32_t *outIx, int32_t capacity, int32_t indent) {
     int32_t i = 0;
     UChar   c;
     if (s==NULL) {
         outputString(NULL, outBuf, outIx, capacity, indent);
         return;
     }

     for (i=0; i<len || len==-1; i++) {
         c = s[i];
         outputHexBytes(c, 4, outBuf, outIx, capacity);
         outputChar(' ', outBuf, outIx, capacity, indent);
         if (len == -1 && c==0) {
             break;
         }
     }
 }

 U_CAPI int32_t U_EXPORT2
 utrace_vformat(char *outBuf, int32_t capacity, int32_t indent, const char *fmt, va_list args) {
     int32_t   outIx  = 0;
     int32_t   fmtIx  = 0;
     char      fmtC;
     char      c;
     int32_t   intArg;
     int64_t   longArg = 0;
     char      *ptrArg;

     /*   Loop runs once for each character in the format string.
      */
     for (;;) {
         fmtC = fmt[fmtIx++];
         if (fmtC != '%') {
             /* Literal character, not part of a %sequence.  Just copy it to the output. */
             outputChar(fmtC, outBuf, &outIx, capacity, indent);
             if (fmtC == 0) {
                 /* We hit the null that terminates the format string.
                  * This is the normal (and only) exit from the loop that
                  * interprets the format
                  */
                 break;
             }
             continue;
         }

         /* We encountered a '%'.  Pick up the following format char */
         fmtC = fmt[fmtIx++];

         switch (fmtC) {
         case 'c':
             /* single 8 bit char   */
             c = (char)va_arg(args, int32_t);
             outputChar(c, outBuf, &outIx, capacity, indent);
             break;

         case 's':
             /* char * string, null terminated.  */
             ptrArg = va_arg(args, char *);
             outputString((const char *)ptrArg, outBuf, &outIx, capacity, indent);
             break;

         case 'S':
             /* UChar * string, with length, len==-1 for null terminated. */
             ptrArg = va_arg(args, void *);             /* Ptr    */
             intArg =(int32_t)va_arg(args, int32_t);    /* Length */
             outputUString((const UChar *)ptrArg, intArg, outBuf, &outIx, capacity, indent);
             break;

         case 'b':
             /*  8 bit int  */
             intArg = va_arg(args, int);
             outputHexBytes(intArg, 2, outBuf, &outIx, capacity);
             break;

         case 'h':
             /*  16 bit int  */
             intArg = va_arg(args, int);
             outputHexBytes(intArg, 4, outBuf, &outIx, capacity);
             break;

         case 'd':
             /*  32 bit int  */
             intArg = va_arg(args, int);
             outputHexBytes(intArg, 8, outBuf, &outIx, capacity);
             break;

         case 'l':
             /*  64 bit long  */
             longArg = va_arg(args, int64_t);
             outputHexBytes(longArg, 16, outBuf, &outIx, capacity);
             break;

         case 'p':
             /*  Pointers.   */
             ptrArg = va_arg(args, void *);
             outputPtrBytes(ptrArg, outBuf, &outIx, capacity);
             break;

         case 0:
             /* Single '%' at end of fmt string.  Output as literal '%'.
              * Back up index into format string so that the terminating null will be
              * re-fetched in the outer loop, causing it to terminate.
              */
             outputChar('%', outBuf, &outIx, capacity, indent);
             fmtIx--;
             break;

         case 'v':
             {
                 /* Vector of values, e.g. %vh */
                 char     vectorType;
                 int32_t  vectorLen;
                 const char   *i8Ptr;
                 int16_t  *i16Ptr;
                 int32_t  *i32Ptr;
                 int64_t  *i64Ptr;
                 void     **ptrPtr;
                 int32_t   charsToOutput = 0;
                 int32_t   i;

                 vectorType = fmt[fmtIx];    /* b, h, d, l, p, etc. */
                 if (vectorType != 0) {
                     fmtIx++;
                 }
                 i8Ptr = (const char *)va_arg(args, void*);
                 i16Ptr = (int16_t *)i8Ptr;
                 i32Ptr = (int32_t *)i8Ptr;
                 i64Ptr = (int64_t *)i8Ptr;
                 ptrPtr = (void **)i8Ptr;
                 vectorLen =(int32_t)va_arg(args, int32_t);
                 if (ptrPtr == NULL) {
                     outputString("*NULL* ", outBuf, &outIx, capacity, indent);
                 } else {
                     for (i=0; i<vectorLen || vectorLen==-1; i++) {
                         switch (vectorType) {
                         case 'b':
                             charsToOutput = 2;
                             longArg = *i8Ptr++;
                             break;
                         case 'h':
                             charsToOutput = 4;
                             longArg = *i16Ptr++;
                             break;
                         case 'd':
                             charsToOutput = 8;
                             longArg = *i32Ptr++;
                             break;
                         case 'l':
                             charsToOutput = 16;
                             longArg = *i64Ptr++;
                             break;
                         case 'p':
                             charsToOutput = 0;
                             outputPtrBytes(*ptrPtr, outBuf, &outIx, capacity);
                             longArg = *ptrPtr==NULL? 0: 1;    /* test for null terminated array. */
                             ptrPtr++;
                             break;
                         case 'c':
                             charsToOutput = 0;
                             outputChar(*i8Ptr, outBuf, &outIx, capacity, indent);
                             longArg = *i8Ptr;    /* for test for null terminated array. */
                             i8Ptr++;
                             break;
                         case 's':
                             charsToOutput = 0;
                             outputString(*ptrPtr, outBuf, &outIx, capacity, indent);
                             outputChar('\n', outBuf, &outIx, capacity, indent);
                             longArg = *ptrPtr==NULL? 0: 1;   /* for test for null term. array. */
                             ptrPtr++;
                             break;

                         case 'S':
                             charsToOutput = 0;
                             outputUString((const UChar *)*ptrPtr, -1, outBuf, &outIx, capacity, indent);
                             outputChar('\n', outBuf, &outIx, capacity, indent);
                             longArg = *ptrPtr==NULL? 0: 1;   /* for test for null term. array. */
                             ptrPtr++;
                             break;


                         }
                         if (charsToOutput > 0) {
                             outputHexBytes(longArg, charsToOutput, outBuf, &outIx, capacity);
                             outputChar(' ', outBuf, &outIx, capacity, indent);
                         }
                         if (vectorLen == -1 && longArg == 0) {
                             break;
                         }
                     }
                 }
                 outputChar('[', outBuf, &outIx, capacity, indent);
                 outputHexBytes(vectorLen, 8, outBuf, &outIx, capacity);
                 outputChar(']', outBuf, &outIx, capacity, indent);
             }
             break;


         default:
             /* %. in format string, where . is some character not in the set
              *    of recognized format chars.  Just output it as if % wasn't there.
              *    (Covers "%%" outputing a single '%')
              */
              outputChar(fmtC, outBuf, &outIx, capacity, indent);
         }
     }
     outputChar(0, outBuf, &outIx, capacity, indent);  /* Make sure that output is null terminated  */
     return outIx + 1;     /* outIx + 1 because outIx does not increment when outputing final null. */
 }


 U_CAPI int32_t U_EXPORT2
 utrace_format(char *outBuf, int32_t capacity,
                 int32_t indent, const char *fmt,  ...) {
     int32_t retVal;
     va_list args;
     va_start(args, fmt );
     retVal = utrace_vformat(outBuf, capacity, indent, fmt, args);
     va_end(args);
     return retVal;
 }


 U_CAPI void U_EXPORT2
 utrace_setFunctions(const void *context,
                     UTraceEntry *e, UTraceExit *x, UTraceData *d) {
     pTraceEntryFunc = e;
     pTraceExitFunc  = x;
     pTraceDataFunc  = d;
     gTraceContext   = context;
 }


 U_CAPI void U_EXPORT2
 utrace_getFunctions(const void **context,
                     UTraceEntry **e, UTraceExit **x, UTraceData **d) {
     *e = pTraceEntryFunc;
     *x = pTraceExitFunc;
     *d = pTraceDataFunc;
     *context = gTraceContext;
 }

 U_CAPI void U_EXPORT2
 utrace_setLevel(int32_t level) {
     if (level < UTRACE_OFF) {
         level = UTRACE_OFF;
     }
     if (level > UTRACE_VERBOSE) {
         level = UTRACE_VERBOSE;
     }
     utrace_level = level;
 }

 U_CAPI int32_t U_EXPORT2
 utrace_getLevel() {
     return utrace_level;
 }


 U_CFUNC UBool
 utrace_cleanup() {
     pTraceEntryFunc = NULL;
     pTraceExitFunc  = NULL;
     pTraceDataFunc  = NULL;
     utrace_level    = UTRACE_OFF;
     gTraceContext   = NULL;
     return TRUE;
 }


 static const char * const
 trFnName[] = {
     "u_init",
     "u_cleanup",
     NULL
 };


 static const char * const
 trConvNames[] = {
     "ucnv_open",
     "ucnv_openPackage",
     "ucnv_openAlgorithmic",
     "ucnv_clone",
     "ucnv_close",
     "ucnv_flushCache",
     "ucnv_load",
     "ucnv_unload",
     NULL
 };


 static const char * const
 trCollNames[] = {
     "ucol_open",
     "ucol_close",
     "ucol_strcoll",
     "ucol_getSortKey",
     "ucol_getLocale",
     "ucol_nextSortKeyPart",
     "ucol_strcollIter",
     NULL
 };


 U_CAPI const char * U_EXPORT2
 utrace_functionName(int32_t fnNumber) {
     if(UTRACE_FUNCTION_START <= fnNumber && fnNumber < UTRACE_FUNCTION_LIMIT) {
         return trFnName[fnNumber];
     } else if(UTRACE_CONVERSION_START <= fnNumber && fnNumber < UTRACE_CONVERSION_LIMIT) {
         return trConvNames[fnNumber - UTRACE_CONVERSION_START];
     } else if(UTRACE_COLLATION_START <= fnNumber && fnNumber < UTRACE_COLLATION_LIMIT){
         return trCollNames[fnNumber - UTRACE_COLLATION_START];
     } else {
         return "[BOGUS Trace Function Number]";
     }
 }
	/*
	*******************************************************************************
	* Copyright (C) 2003-2008, International Business Machines
	* Corporation and others. All Rights Reserved.
	*******************************************************************************
	* file name: utrace.c
	* encoding: US-ASCII
	* tab size: 8 (not used)
	* indentation:4
	*/

	#define UTRACE_IMPL
	#include "unicode/utrace.h"
	#include "utracimp.h"
	#include "cstring.h"
	#include "uassert.h"
	#include "ucln_cmn.h"


	static UTraceEntry *pTraceEntryFunc = NULL;
	static UTraceExit *pTraceExitFunc = NULL;
	static UTraceData *pTraceDataFunc = NULL;
	static const void *gTraceContext = NULL;

	U_EXPORT int32_t
	utrace_level = UTRACE_ERROR;

	U_CAPI void U_EXPORT2
	utrace_entry(int32_t fnNumber) {
	if (pTraceEntryFunc != NULL) {
	(*pTraceEntryFunc)(gTraceContext, fnNumber);
	}
	}


	static const char gExitFmt[] = "Returns.";
	static const char gExitFmtValue[] = "Returns %d.";
	static const char gExitFmtStatus[] = "Returns. Status = %d.";
	static const char gExitFmtValueStatus[] = "Returns %d. Status = %d.";
	static const char gExitFmtPtrStatus[] = "Returns %d. Status = %p.";

	U_CAPI void U_EXPORT2
	utrace_exit(int32_t fnNumber, int32_t returnType, ...) {
	if (pTraceExitFunc != NULL) {
	va_list args;
	const char *fmt;

	switch (returnType) {
	case 0:
	fmt = gExitFmt;
	break;
	case UTRACE_EXITV_I32:
	fmt = gExitFmtValue;
	break;
	case UTRACE_EXITV_STATUS:
	fmt = gExitFmtStatus;
	break;
	case UTRACE_EXITV_I32 \| UTRACE_EXITV_STATUS:
	fmt = gExitFmtValueStatus;
	break;
	case UTRACE_EXITV_PTR \| UTRACE_EXITV_STATUS:
	fmt = gExitFmtPtrStatus;
	break;
	default:
	U_ASSERT(FALSE);
	fmt = gExitFmt;
	}

	va_start(args, returnType);
	(*pTraceExitFunc)(gTraceContext, fnNumber, fmt, args);
	va_end(args);
	}
	}



	U_CAPI void U_EXPORT2
	utrace_data(int32_t fnNumber, int32_t level, const char *fmt, ...) {
	if (pTraceDataFunc != NULL) {
	va_list args;
	va_start(args, fmt );
	(*pTraceDataFunc)(gTraceContext, fnNumber, level, fmt, args);
	va_end(args);
	}
	}


	static void outputChar(char c, char outBuf, int32_t outIx, int32_t capacity, int32_t indent) {
	int32_t i;
	/* Check whether a start of line indenting is needed. Three cases:
	* 1. At the start of the first line (output index == 0).
	* 2. At the start of subsequent lines (preceeding char in buffer == '\n')
	* 3. When preflighting buffer len (buffer capacity is exceeded), when
	* a \n is output. Ideally we wouldn't do the indent until the following char
	* is received, but that won't work because there's no place to remember that
	* the preceding char was \n. Meaning that we may overstimate the
	* buffer size needed. No harm done.
	*/
	if (outIx==0 \|\| / case 1. */
	(c!='\n' && c!=0 && outIx < capacity && outBuf[(outIx)-1]=='\n') \|\| /* case 2. */
	(c=='\n' && outIx>=capacity)) / case 3 */
	{
	/* At the start of a line. Indent. */
	for(i=0; i<indent; i++) {
	if (*outIx < capacity) {
	outBuf[*outIx] = ' ';
	}
	(*outIx)++;
	}
	}

	if (*outIx < capacity) {
	outBuf[*outIx] = c;
	}
	if (c != 0) {
	/* Nulls only appear as end-of-string terminators. Move them to the output
	* buffer, but do not update the length of the buffer, so that any
	* following output will overwrite the null. */
	(*outIx)++;
	}
	}

	static void outputHexBytes(int64_t val, int32_t charsToOutput,
	char outBuf, int32_t outIx, int32_t capacity) {
	static const char gHexChars[] = "0123456789abcdef";
	int32_t shiftCount;
	for (shiftCount=(charsToOutput-1)*4; shiftCount >= 0; shiftCount-=4) {
	char c = gHexChars[(val >> shiftCount) & 0xf];
	outputChar(c, outBuf, outIx, capacity, 0);
	}
	}

	/* Output a pointer value in hex. Work with any size of pointer */
	static void outputPtrBytes(void val, char outBuf, int32_t *outIx, int32_t capacity) {
	int32_t i;
	int32_t incVal = 1; /* +1 for big endian, -1 for little endian */
	char p = (char )&val; /* point to current byte to output in the ptr val */

	#if !U_IS_BIG_ENDIAN
	/* Little Endian. Move p to most significant end of the value */
	incVal = -1;
	p += sizeof(void *) - 1;
	#endif

	/* Loop through the bytes of the ptr as it sits in memory, from
	* most significant to least significant end */
	for (i=0; i<sizeof(void *); i++) {
	outputHexBytes(*p, 2, outBuf, outIx, capacity);
	p += incVal;
	}
	}

	static void outputString(const char s, char outBuf, int32_t *outIx, int32_t capacity, int32_t indent) {
	int32_t i = 0;
	char c;
	if (s==NULL) {
	s = "NULL";
	}
	do {
	c = s[i++];
	outputChar(c, outBuf, outIx, capacity, indent);
	} while (c != 0);
	}



	static void outputUString(const UChar *s, int32_t len,
	char outBuf, int32_t outIx, int32_t capacity, int32_t indent) {
	int32_t i = 0;
	UChar c;
	if (s==NULL) {
	outputString(NULL, outBuf, outIx, capacity, indent);
	return;
	}

	for (i=0; i<len \|\| len==-1; i++) {
	c = s[i];
	outputHexBytes(c, 4, outBuf, outIx, capacity);
	outputChar(' ', outBuf, outIx, capacity, indent);
	if (len == -1 && c==0) {
	break;
	}
	}
	}

	U_CAPI int32_t U_EXPORT2
	utrace_vformat(char outBuf, int32_t capacity, int32_t indent, const char fmt, va_list args) {
	int32_t outIx = 0;
	int32_t fmtIx = 0;
	char fmtC;
	char c;
	int32_t intArg;
	int64_t longArg = 0;
	char *ptrArg;

	/* Loop runs once for each character in the format string.
	*/
	for (;;) {
	fmtC = fmt[fmtIx++];
	if (fmtC != '%') {
	/* Literal character, not part of a %sequence. Just copy it to the output. */
	outputChar(fmtC, outBuf, &outIx, capacity, indent);
	if (fmtC == 0) {
	/* We hit the null that terminates the format string.
	* This is the normal (and only) exit from the loop that
	* interprets the format
	*/
	break;
	}
	continue;
	}

	/* We encountered a '%'. Pick up the following format char */
	fmtC = fmt[fmtIx++];

	switch (fmtC) {
	case 'c':
	/* single 8 bit char */
	c = (char)va_arg(args, int32_t);
	outputChar(c, outBuf, &outIx, capacity, indent);
	break;

	case 's':
	/* char * string, null terminated. */
	ptrArg = va_arg(args, char *);
	outputString((const char *)ptrArg, outBuf, &outIx, capacity, indent);
	break;

	case 'S':
	/* UChar * string, with length, len==-1 for null terminated. */
	ptrArg = va_arg(args, void ); / Ptr */
	intArg =(int32_t)va_arg(args, int32_t); /* Length */
	outputUString((const UChar *)ptrArg, intArg, outBuf, &outIx, capacity, indent);
	break;

	case 'b':
	/* 8 bit int */
	intArg = va_arg(args, int);
	outputHexBytes(intArg, 2, outBuf, &outIx, capacity);
	break;

	case 'h':
	/* 16 bit int */
	intArg = va_arg(args, int);
	outputHexBytes(intArg, 4, outBuf, &outIx, capacity);
	break;

	case 'd':
	/* 32 bit int */
	intArg = va_arg(args, int);
	outputHexBytes(intArg, 8, outBuf, &outIx, capacity);
	break;

	case 'l':
	/* 64 bit long */
	longArg = va_arg(args, int64_t);
	outputHexBytes(longArg, 16, outBuf, &outIx, capacity);
	break;

	case 'p':
	/* Pointers. */
	ptrArg = va_arg(args, void *);
	outputPtrBytes(ptrArg, outBuf, &outIx, capacity);
	break;

	case 0:
	/* Single '%' at end of fmt string. Output as literal '%'.
	* Back up index into format string so that the terminating null will be
	* re-fetched in the outer loop, causing it to terminate.
	*/
	outputChar('%', outBuf, &outIx, capacity, indent);
	fmtIx--;
	break;

	case 'v':
	{
	/* Vector of values, e.g. %vh */
	char vectorType;
	int32_t vectorLen;
	const char *i8Ptr;
	int16_t *i16Ptr;
	int32_t *i32Ptr;
	int64_t *i64Ptr;
	void **ptrPtr;
	int32_t charsToOutput = 0;
	int32_t i;

	vectorType = fmt[fmtIx]; /* b, h, d, l, p, etc. */
	if (vectorType != 0) {
	fmtIx++;
	}
	i8Ptr = (const char )va_arg(args, void);
	i16Ptr = (int16_t *)i8Ptr;
	i32Ptr = (int32_t *)i8Ptr;
	i64Ptr = (int64_t *)i8Ptr;
	ptrPtr = (void **)i8Ptr;
	vectorLen =(int32_t)va_arg(args, int32_t);
	if (ptrPtr == NULL) {
	outputString("NULL ", outBuf, &outIx, capacity, indent);
	} else {
	for (i=0; i<vectorLen \|\| vectorLen==-1; i++) {
	switch (vectorType) {
	case 'b':
	charsToOutput = 2;
	longArg = *i8Ptr++;
	break;
	case 'h':
	charsToOutput = 4;
	longArg = *i16Ptr++;
	break;
	case 'd':
	charsToOutput = 8;
	longArg = *i32Ptr++;
	break;
	case 'l':
	charsToOutput = 16;
	longArg = *i64Ptr++;
	break;
	case 'p':
	charsToOutput = 0;
	outputPtrBytes(*ptrPtr, outBuf, &outIx, capacity);
	longArg = ptrPtr==NULL? 0: 1; / test for null terminated array. */
	ptrPtr++;
	break;
	case 'c':
	charsToOutput = 0;
	outputChar(*i8Ptr, outBuf, &outIx, capacity, indent);
	longArg = i8Ptr; / for test for null terminated array. */
	i8Ptr++;
	break;
	case 's':
	charsToOutput = 0;
	outputString(*ptrPtr, outBuf, &outIx, capacity, indent);
	outputChar('\n', outBuf, &outIx, capacity, indent);
	longArg = ptrPtr==NULL? 0: 1; / for test for null term. array. */
	ptrPtr++;
	break;

	case 'S':
	charsToOutput = 0;
	outputUString((const UChar )ptrPtr, -1, outBuf, &outIx, capacity, indent);
	outputChar('\n', outBuf, &outIx, capacity, indent);
	longArg = ptrPtr==NULL? 0: 1; / for test for null term. array. */
	ptrPtr++;
	break;


	}
	if (charsToOutput > 0) {
	outputHexBytes(longArg, charsToOutput, outBuf, &outIx, capacity);
	outputChar(' ', outBuf, &outIx, capacity, indent);
	}
	if (vectorLen == -1 && longArg == 0) {
	break;
	}
	}
	}
	outputChar('[', outBuf, &outIx, capacity, indent);
	outputHexBytes(vectorLen, 8, outBuf, &outIx, capacity);
	outputChar(']', outBuf, &outIx, capacity, indent);
	}
	break;


	default:
	/* %. in format string, where . is some character not in the set
	* of recognized format chars. Just output it as if % wasn't there.
	* (Covers "%%" outputing a single '%')
	*/
	outputChar(fmtC, outBuf, &outIx, capacity, indent);
	}
	}
	outputChar(0, outBuf, &outIx, capacity, indent); /* Make sure that output is null terminated */
	return outIx + 1; /* outIx + 1 because outIx does not increment when outputing final null. */
	}




	U_CAPI int32_t U_EXPORT2
	utrace_format(char *outBuf, int32_t capacity,
	int32_t indent, const char *fmt, ...) {
	int32_t retVal;
	va_list args;
	va_start(args, fmt );
	retVal = utrace_vformat(outBuf, capacity, indent, fmt, args);
	va_end(args);
	return retVal;
	}


	U_CAPI void U_EXPORT2
	utrace_setFunctions(const void *context,
	UTraceEntry e, UTraceExit x, UTraceData *d) {
	pTraceEntryFunc = e;
	pTraceExitFunc = x;
	pTraceDataFunc = d;
	gTraceContext = context;
	}


	U_CAPI void U_EXPORT2
	utrace_getFunctions(const void **context,
	UTraceEntry e, UTraceExit x, UTraceData **d) {
	*e = pTraceEntryFunc;
	*x = pTraceExitFunc;
	*d = pTraceDataFunc;
	*context = gTraceContext;
	}

	U_CAPI void U_EXPORT2
	utrace_setLevel(int32_t level) {
	if (level < UTRACE_OFF) {
	level = UTRACE_OFF;
	}
	if (level > UTRACE_VERBOSE) {
	level = UTRACE_VERBOSE;
	}
	utrace_level = level;
	}

	U_CAPI int32_t U_EXPORT2
	utrace_getLevel() {
	return utrace_level;
	}


	U_CFUNC UBool
	utrace_cleanup() {
	pTraceEntryFunc = NULL;
	pTraceExitFunc = NULL;
	pTraceDataFunc = NULL;
	utrace_level = UTRACE_OFF;
	gTraceContext = NULL;
	return TRUE;
	}


	static const char * const
	trFnName[] = {
	"u_init",
	"u_cleanup",
	NULL
	};


	static const char * const
	trConvNames[] = {
	"ucnv_open",
	"ucnv_openPackage",
	"ucnv_openAlgorithmic",
	"ucnv_clone",
	"ucnv_close",
	"ucnv_flushCache",
	"ucnv_load",
	"ucnv_unload",
	NULL
	};


	static const char * const
	trCollNames[] = {
	"ucol_open",
	"ucol_close",
	"ucol_strcoll",
	"ucol_getSortKey",
	"ucol_getLocale",
	"ucol_nextSortKeyPart",
	"ucol_strcollIter",
	NULL
	};


	U_CAPI const char * U_EXPORT2
	utrace_functionName(int32_t fnNumber) {
	if(UTRACE_FUNCTION_START <= fnNumber && fnNumber < UTRACE_FUNCTION_LIMIT) {
	return trFnName[fnNumber];
	} else if(UTRACE_CONVERSION_START <= fnNumber && fnNumber < UTRACE_CONVERSION_LIMIT) {
	return trConvNames[fnNumber - UTRACE_CONVERSION_START];
	} else if(UTRACE_COLLATION_START <= fnNumber && fnNumber < UTRACE_COLLATION_LIMIT){
	return trCollNames[fnNumber - UTRACE_COLLATION_START];
	} else {
	return "[BOGUS Trace Function Number]";
	}
	}