src/third_party/mozjs-45/js/src/jsprf.cpp - cobalt - Git at Google

 /* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
  * vim: set ts=8 sts=4 et sw=4 tw=99:
  * This Source Code Form is subject to the terms of the Mozilla Public
  * License, v. 2.0. If a copy of the MPL was not distributed with this
  * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

 /*
  * Portable safe sprintf code.
  *
  * Author: Kipp E.B. Hickman
  */

 #include "jsprf.h"

 #include "mozilla/Snprintf.h"
 #include "mozilla/Vector.h"

 #include <stdarg.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>

 #include "jsalloc.h"
 #include "jspubtd.h"
 #include "jsstr.h"
 #include "jsutil.h"

 using namespace js;

 /*
  * Note: on some platforms va_list is defined as an array,
  * and requires array notation.
  */
 #ifdef HAVE_VA_COPY
 #define VARARGS_ASSIGN(foo, bar)        va_copy(foo, bar)
 #elif defined(HAVE_VA_LIST_AS_ARRAY)
 #define VARARGS_ASSIGN(foo, bar)        foo[0] = bar[0]
 #else
 #define VARARGS_ASSIGN(foo, bar)        (foo) = (bar)
 #endif

 struct SprintfState
 {
     bool (*stuff)(SprintfState* ss, const char* sp, size_t len);

     char* base;
     char* cur;
     size_t maxlen;

     int (*func)(void* arg, const char* sp, uint32_t len);
     void* arg;
 };

 /*
  * Numbered Argument State
  */
 struct NumArgState
 {
     int type;       // type of the current ap
     va_list ap;     // point to the corresponding position on ap
 };

 typedef mozilla::Vector<NumArgState, 20, js::SystemAllocPolicy> NumArgStateVector;


 #define TYPE_INT16      0
 #define TYPE_UINT16     1
 #define TYPE_INTN       2
 #define TYPE_UINTN      3
 #define TYPE_INT32      4
 #define TYPE_UINT32     5
 #define TYPE_INT64      6
 #define TYPE_UINT64     7
 #define TYPE_STRING     8
 #define TYPE_DOUBLE     9
 #define TYPE_INTSTR     10
 #define TYPE_WSTRING    11
 #define TYPE_UNKNOWN    20

 #define FLAG_LEFT       0x1
 #define FLAG_SIGNED     0x2
 #define FLAG_SPACED     0x4
 #define FLAG_ZEROS      0x8
 #define FLAG_NEG        0x10

 inline bool
 generic_write(SprintfState* ss, const char* src, size_t srclen)
 {
     return (*ss->stuff)(ss, src, srclen);
 }

 inline bool
 generic_write(SprintfState* ss, const char16_t* src, size_t srclen)
 {
     const size_t CHUNK_SIZE = 64;
     char chunk[CHUNK_SIZE];

     size_t j = 0;
     size_t i = 0;
     while (i < srclen) {
         // FIXME: truncates characters to 8 bits
         chunk[j++] = char(src[i++]);

         if (j == CHUNK_SIZE || i == srclen) {
             if (!(*ss->stuff)(ss, chunk, j))
                 return false;
             j = 0;
         }
     }
     return true;
 }

 // Fill into the buffer using the data in src
 template <typename Char>
 static bool
 fill2(SprintfState* ss, const Char* src, int srclen, int width, int flags)
 {
     char space = ' ';

     width -= srclen;
     if (width > 0 && (flags & FLAG_LEFT) == 0) {    // Right adjusting
         if (flags & FLAG_ZEROS)
             space = '0';
         while (--width >= 0) {
             if (!(*ss->stuff)(ss, &space, 1))
                 return false;
         }
     }

     // Copy out the source data
     if (!generic_write(ss, src, srclen))
         return false;

     if (width > 0 && (flags & FLAG_LEFT) != 0) {    // Left adjusting
         while (--width >= 0) {
             if (!(*ss->stuff)(ss, &space, 1))
                 return false;
         }
     }
     return true;
 }

 /*
  * Fill a number. The order is: optional-sign zero-filling conversion-digits
  */
 static bool
 fill_n(SprintfState* ss, const char* src, int srclen, int width, int prec, int type, int flags)
 {
     int zerowidth = 0;
     int precwidth = 0;
     int signwidth = 0;
     int leftspaces = 0;
     int rightspaces = 0;
     int cvtwidth;
     char sign;

     if ((type & 1) == 0) {
         if (flags & FLAG_NEG) {
             sign = '-';
             signwidth = 1;
         } else if (flags & FLAG_SIGNED) {
             sign = '+';
             signwidth = 1;
         } else if (flags & FLAG_SPACED) {
             sign = ' ';
             signwidth = 1;
         }
     }
     cvtwidth = signwidth + srclen;

     if (prec > 0) {
         if (prec > srclen) {
             precwidth = prec - srclen;          // Need zero filling
             cvtwidth += precwidth;
         }
     }

     if ((flags & FLAG_ZEROS) && (prec < 0)) {
         if (width > cvtwidth) {
             zerowidth = width - cvtwidth;       // Zero filling
             cvtwidth += zerowidth;
         }
     }

     if (flags & FLAG_LEFT) {
         if (width > cvtwidth) {
             // Space filling on the right (i.e. left adjusting)
             rightspaces = width - cvtwidth;
         }
     } else {
         if (width > cvtwidth) {
             // Space filling on the left (i.e. right adjusting)
             leftspaces = width - cvtwidth;
         }
     }
     while (--leftspaces >= 0) {
         if (!(*ss->stuff)(ss, " ", 1))
             return false;
     }
     if (signwidth) {
         if (!(*ss->stuff)(ss, &sign, 1))
             return false;
     }
     while (--precwidth >= 0) {
         if (!(*ss->stuff)(ss, "0", 1))
             return false;
     }
     while (--zerowidth >= 0) {
         if (!(*ss->stuff)(ss, "0", 1))
             return false;
     }
     if (!(*ss->stuff)(ss, src, uint32_t(srclen)))
         return false;
     while (--rightspaces >= 0) {
         if (!(*ss->stuff)(ss, " ", 1))
             return false;
     }
     return true;
 }

 /* Convert a long into its printable form. */
 static bool cvt_l(SprintfState* ss, long num, int width, int prec, int radix,
                   int type, int flags, const char* hexp)
 {
     char cvtbuf[100];
     char* cvt;
     int digits;

     // according to the man page this needs to happen
     if ((prec == 0) && (num == 0))
         return true;

     // Converting decimal is a little tricky. In the unsigned case we
     // need to stop when we hit 10 digits. In the signed case, we can
     // stop when the number is zero.
     cvt = cvtbuf + sizeof(cvtbuf);
     digits = 0;
     while (num) {
         int digit = (((unsigned long)num) % radix) & 0xF;
         *--cvt = hexp[digit];
         digits++;
         num = (long)(((unsigned long)num) / radix);
     }
     if (digits == 0) {
         *--cvt = '0';
         digits++;
     }

     // Now that we have the number converted without its sign, deal with
     // the sign and zero padding.
     return fill_n(ss, cvt, digits, width, prec, type, flags);
 }

 /* Convert a 64-bit integer into its printable form. */
 static bool cvt_ll(SprintfState* ss, int64_t num, int width, int prec, int radix,
                    int type, int flags, const char* hexp)
 {
     // According to the man page, this needs to happen.
     if (prec == 0 && num == 0)
         return true;

     // Converting decimal is a little tricky. In the unsigned case we
     // need to stop when we hit 10 digits. In the signed case, we can
     // stop when the number is zero.
     int64_t rad = int64_t(radix);
     char cvtbuf[100];
     char* cvt = cvtbuf + sizeof(cvtbuf);
     int digits = 0;
     while (num != 0) {
         int64_t quot = uint64_t(num) / rad;
         int64_t rem = uint64_t(num) % rad;
         int32_t digit = int32_t(rem);
         *--cvt = hexp[digit & 0xf];
         digits++;
         num = quot;
     }
     if (digits == 0) {
         *--cvt = '0';
         digits++;
     }

     // Now that we have the number converted without its sign, deal with
     // the sign and zero padding.
     return fill_n(ss, cvt, digits, width, prec, type, flags);
 }

 /*
  * Convert a double precision floating point number into its printable
  * form.
  */
 static bool cvt_f(SprintfState* ss, double d, const char* fmt0, const char* fmt1)
 {
     char fin[20];
     char fout[300];
     int amount = fmt1 - fmt0;

     MOZ_ASSERT((amount > 0) && (amount < (int)sizeof(fin)));
     if (amount >= (int)sizeof(fin)) {
         // Totally bogus % command to sprintf. Just ignore it
         return true;
     }
     js_memcpy(fin, fmt0, (size_t)amount);
     fin[amount] = 0;

     // Convert floating point using the native snprintf code
 #ifdef DEBUG
     {
         const char* p = fin;
         while (*p) {
             MOZ_ASSERT(*p != 'L');
             p++;
         }
     }
 #endif
     snprintf_literal(fout, fin, d);

     return (*ss->stuff)(ss, fout, strlen(fout));
 }

 static inline const char* generic_null_str(const char*) { return "(null)"; }
 static inline const char16_t* generic_null_str(const char16_t*) { return MOZ_UTF16("(null)"); }

 static inline size_t generic_strlen(const char* s) { return strlen(s); }
 static inline size_t generic_strlen(const char16_t* s) { return js_strlen(s); }

 /*
  * Convert a string into its printable form.  "width" is the output
  * width. "prec" is the maximum number of characters of "s" to output,
  * where -1 means until NUL.
  */
 template <typename Char>
 static bool
 cvt_s(SprintfState* ss, const Char* s, int width, int prec, int flags)
 {
     if (prec == 0)
         return true;
     if (!s)
         s = generic_null_str(s);

     // Limit string length by precision value
     int slen = int(generic_strlen(s));
     if (0 < prec && prec < slen)
         slen = prec;

     // and away we go
     return fill2(ss, s, slen, width, flags);
 }

 /*
  * BuildArgArray stands for Numbered Argument list Sprintf
  * for example,
  *      fmp = "%4$i, %2$d, %3s, %1d";
  * the number must start from 1, and no gap among them
  */
 static bool
 BuildArgArray(const char* fmt, va_list ap, NumArgStateVector& nas)
 {
     size_t number = 0, cn = 0, i;
     const char* p;
     char c;


     // First pass:
     // Detemine how many legal % I have got, then allocate space.

     p = fmt;
     i = 0;
     while ((c = *p++) != 0) {
         if (c != '%')
             continue;
         if ((c = *p++) == '%')          // skip %% case
             continue;

         while (c != 0) {
             if (c > '9' || c < '0') {
                 if (c == '$') {         // numbered argument case
                     if (i > 0)
                         MOZ_CRASH("Bad format string");
                     number++;
                 } else {                // non-numbered argument case
                     if (number > 0)
                         MOZ_CRASH("Bad format string");
                     i = 1;
                 }
                 break;
             }

             c = *p++;
         }
     }

     if (number == 0)
         return true;

     if (!nas.growByUninitialized(number))
         return false;

     for (i = 0; i < number; i++)
         nas[i].type = TYPE_UNKNOWN;


     // Second pass:
     // Set nas[].type.

     p = fmt;
     while ((c = *p++) != 0) {
         if (c != '%')
             continue;
         c = *p++;
         if (c == '%')
             continue;

         cn = 0;
         while (c && c != '$') {     // should improve error check later
             cn = cn*10 + c - '0';
             c = *p++;
         }

         if (!c || cn < 1 || cn > number)
             MOZ_CRASH("Bad format string");

         // nas[cn] starts from 0, and make sure nas[cn].type is not assigned.
         cn--;
         if (nas[cn].type != TYPE_UNKNOWN)
             continue;

         c = *p++;

         // width
         if (c == '*') {
             // not supported feature, for the argument is not numbered
             MOZ_CRASH("Bad format string");
         }

         while ((c >= '0') && (c <= '9')) {
             c = *p++;
         }

         // precision
         if (c == '.') {
             c = *p++;
             if (c == '*') {
                 // not supported feature, for the argument is not numbered
                 MOZ_CRASH("Bad format string");
             }

             while ((c >= '0') && (c <= '9')) {
                 c = *p++;
             }
         }

         // size
         nas[cn].type = TYPE_INTN;
         if (c == 'h') {
             nas[cn].type = TYPE_INT16;
             c = *p++;
         } else if (c == 'L') {
             // XXX not quite sure here
             nas[cn].type = TYPE_INT64;
             c = *p++;
         } else if (c == 'l') {
             nas[cn].type = TYPE_INT32;
             c = *p++;
             if (c == 'l') {
                 nas[cn].type = TYPE_INT64;
                 c = *p++;
             }
         } else if (c == 'z' || c == 'I') {
             static_assert(sizeof(size_t) == sizeof(int32_t) || sizeof(size_t) == sizeof(int64_t),
                           "size_t is not one of the expected sizes");
             nas[cn].type = sizeof(size_t) == sizeof(int64_t) ? TYPE_INT64 : TYPE_INT32;
             c = *p++;
         }

         // format
         switch (c) {
         case 'd':
         case 'c':
         case 'i':
         case 'o':
         case 'u':
         case 'x':
         case 'X':
             break;

         case 'e':
         case 'f':
         case 'g':
             nas[cn].type = TYPE_DOUBLE;
             break;

         case 'p':
             // XXX should use cpp
             if (sizeof(void*) == sizeof(int32_t)) {
                 nas[cn].type = TYPE_UINT32;
             } else if (sizeof(void*) == sizeof(int64_t)) {
                 nas[cn].type = TYPE_UINT64;
             } else if (sizeof(void*) == sizeof(int)) {
                 nas[cn].type = TYPE_UINTN;
             } else {
                 nas[cn].type = TYPE_UNKNOWN;
             }
             break;

         case 'C':
         case 'S':
         case 'E':
         case 'G':
             // XXX not supported I suppose
             MOZ_ASSERT(0);
             nas[cn].type = TYPE_UNKNOWN;
             break;

         case 's':
             nas[cn].type = (nas[cn].type == TYPE_UINT16) ? TYPE_WSTRING : TYPE_STRING;
             break;

         case 'n':
             nas[cn].type = TYPE_INTSTR;
             break;

         default:
             MOZ_ASSERT(0);
             nas[cn].type = TYPE_UNKNOWN;
             break;
         }

         // get a legal para.
         if (nas[cn].type == TYPE_UNKNOWN)
             MOZ_CRASH("Bad format string");
     }


     // Third pass:
     // Fill nas[].ap.

     cn = 0;
     while (cn < number) {
         if (nas[cn].type == TYPE_UNKNOWN) {
             cn++;
             continue;
         }

         VARARGS_ASSIGN(nas[cn].ap, ap);

         switch (nas[cn].type) {
         case TYPE_INT16:
         case TYPE_UINT16:
         case TYPE_INTN:
         case TYPE_UINTN:        (void) va_arg(ap, int);         break;
         case TYPE_INT32:        (void) va_arg(ap, int32_t);     break;
         case TYPE_UINT32:       (void) va_arg(ap, uint32_t);    break;
         case TYPE_INT64:        (void) va_arg(ap, int64_t);     break;
         case TYPE_UINT64:       (void) va_arg(ap, uint64_t);    break;
         case TYPE_STRING:       (void) va_arg(ap, char*);       break;
         case TYPE_WSTRING:      (void) va_arg(ap, char16_t*);   break;
         case TYPE_INTSTR:       (void) va_arg(ap, int*);        break;
         case TYPE_DOUBLE:       (void) va_arg(ap, double);      break;

         default: MOZ_CRASH();
         }

         cn++;
     }

     return true;
 }

 /*
  * The workhorse sprintf code.
  */
 static bool
 dosprintf(SprintfState* ss, const char* fmt, va_list ap)
 {
     char c;
     int flags, width, prec, radix, type;
     union {
         char ch;
         char16_t wch;
         int i;
         long l;
         int64_t ll;
         double d;
         const char* s;
         const char16_t* ws;
         int* ip;
     } u;
     const char* fmt0;
     static const char hex[] = "0123456789abcdef";
     static const char HEX[] = "0123456789ABCDEF";
     const char* hexp;
     int i;
     char pattern[20];
     const char* dolPt = nullptr;  // in "%4$.2f", dolPt will point to '.'

     // Build an argument array, IF the fmt is numbered argument
     // list style, to contain the Numbered Argument list pointers.

     NumArgStateVector nas;
     if (!BuildArgArray(fmt, ap, nas)) {
         // the fmt contains error Numbered Argument format, jliu@netscape.com
         MOZ_CRASH("Bad format string");
     }

     while ((c = *fmt++) != 0) {
         if (c != '%') {
             if (!(*ss->stuff)(ss, fmt - 1, 1))
                 return false;

             continue;
         }
         fmt0 = fmt - 1;

         // Gobble up the % format string. Hopefully we have handled all
         // of the strange cases!
         flags = 0;
         c = *fmt++;
         if (c == '%') {
             // quoting a % with %%
             if (!(*ss->stuff)(ss, fmt - 1, 1))
                 return false;

             continue;
         }

         if (!nas.empty()) {
             // the fmt contains the Numbered Arguments feature
             i = 0;
             while (c && c != '$') {         // should improve error check later
                 i = (i * 10) + (c - '0');
                 c = *fmt++;
             }

             if (nas[i - 1].type == TYPE_UNKNOWN)
                 MOZ_CRASH("Bad format string");

             ap = nas[i - 1].ap;
             dolPt = fmt;
             c = *fmt++;
         }

         // Examine optional flags.  Note that we do not implement the
         // '#' flag of sprintf().  The ANSI C spec. of the '#' flag is
         // somewhat ambiguous and not ideal, which is perhaps why
         // the various sprintf() implementations are inconsistent
         // on this feature.
         while ((c == '-') || (c == '+') || (c == ' ') || (c == '0')) {
             if (c == '-') flags |= FLAG_LEFT;
             if (c == '+') flags |= FLAG_SIGNED;
             if (c == ' ') flags |= FLAG_SPACED;
             if (c == '0') flags |= FLAG_ZEROS;
             c = *fmt++;
         }
         if (flags & FLAG_SIGNED) flags &= ~FLAG_SPACED;
         if (flags & FLAG_LEFT) flags &= ~FLAG_ZEROS;

         // width
         if (c == '*') {
             c = *fmt++;
             width = va_arg(ap, int);
         } else {
             width = 0;
             while ((c >= '0') && (c <= '9')) {
                 width = (width * 10) + (c - '0');
                 c = *fmt++;
             }
         }

         // precision
         prec = -1;
         if (c == '.') {
             c = *fmt++;
             if (c == '*') {
                 c = *fmt++;
                 prec = va_arg(ap, int);
             } else {
                 prec = 0;
                 while ((c >= '0') && (c <= '9')) {
                     prec = (prec * 10) + (c - '0');
                     c = *fmt++;
                 }
             }
         }

         // size
         type = TYPE_INTN;
         if (c == 'h') {
             type = TYPE_INT16;
             c = *fmt++;
         } else if (c == 'L') {
             // XXX not quite sure here
             type = TYPE_INT64;
             c = *fmt++;
         } else if (c == 'l') {
             type = TYPE_INT32;
             c = *fmt++;
             if (c == 'l') {
                 type = TYPE_INT64;
                 c = *fmt++;
             }
         } else if (c == 'z' || c == 'I') {
             static_assert(sizeof(size_t) == sizeof(int32_t) || sizeof(size_t) == sizeof(int64_t),
                           "size_t is not one of the expected sizes");
             type = sizeof(size_t) == sizeof(int64_t) ? TYPE_INT64 : TYPE_INT32;
             c = *fmt++;
         }

         // format
         hexp = hex;
         switch (c) {
           case 'd': case 'i':                   // decimal/integer
             radix = 10;
             goto fetch_and_convert;

           case 'o':                             // octal
             radix = 8;
             type |= 1;
             goto fetch_and_convert;

           case 'u':                             // unsigned decimal
             radix = 10;
             type |= 1;
             goto fetch_and_convert;

           case 'x':                             // unsigned hex
             radix = 16;
             type |= 1;
             goto fetch_and_convert;

           case 'X':                             // unsigned HEX
             radix = 16;
             hexp = HEX;
             type |= 1;
             goto fetch_and_convert;

           fetch_and_convert:
             switch (type) {
               case TYPE_INT16:
                 u.l = va_arg(ap, int);
                 if (u.l < 0) {
                     u.l = -u.l;
                     flags |= FLAG_NEG;
                 }
                 goto do_long;
               case TYPE_UINT16:
                 u.l = va_arg(ap, int) & 0xffff;
                 goto do_long;
               case TYPE_INTN:
                 u.l = va_arg(ap, int);
                 if (u.l < 0) {
                     u.l = -u.l;
                     flags |= FLAG_NEG;
                 }
                 goto do_long;
               case TYPE_UINTN:
                 u.l = (long)va_arg(ap, unsigned int);
                 goto do_long;

               case TYPE_INT32:
                 u.l = va_arg(ap, int32_t);
                 if (u.l < 0) {
                     u.l = -u.l;
                     flags |= FLAG_NEG;
                 }
                 goto do_long;
               case TYPE_UINT32:
                 u.l = (long)va_arg(ap, uint32_t);
               do_long:
                 if (!cvt_l(ss, u.l, width, prec, radix, type, flags, hexp))
                     return false;

                 break;

               case TYPE_INT64:
                 u.ll = va_arg(ap, int64_t);
                 if (u.ll < 0) {
                     u.ll = -u.ll;
                     flags |= FLAG_NEG;
                 }
                 goto do_longlong;
               case TYPE_UINT64:
                 u.ll = va_arg(ap, uint64_t);
               do_longlong:
                 if (!cvt_ll(ss, u.ll, width, prec, radix, type, flags, hexp))
                     return false;

                 break;
             }
             break;

           case 'e':
           case 'E':
           case 'f':
           case 'g':
             u.d = va_arg(ap, double);
             if (!nas.empty()) {
                 i = fmt - dolPt;
                 if (i < int(sizeof(pattern))) {
                     pattern[0] = '%';
                     js_memcpy(&pattern[1], dolPt, size_t(i));
                     if (!cvt_f(ss, u.d, pattern, &pattern[i + 1]))
                         return false;
                 }
             } else {
                 if (!cvt_f(ss, u.d, fmt0, fmt))
                     return false;
             }

             break;

           case 'c':
             if ((flags & FLAG_LEFT) == 0) {
                 while (width-- > 1) {
                     if (!(*ss->stuff)(ss, " ", 1))
                         return false;
                 }
             }
             switch (type) {
               case TYPE_INT16:
               case TYPE_INTN:
                 u.ch = va_arg(ap, int);
                 if (!(*ss->stuff)(ss, &u.ch, 1))
                     return false;
                 break;
             }
             if (flags & FLAG_LEFT) {
                 while (width-- > 1) {
                     if (!(*ss->stuff)(ss, " ", 1))
                         return false;
                 }
             }
             break;

           case 'p':
             if (sizeof(void*) == sizeof(int32_t)) {
                 type = TYPE_UINT32;
             } else if (sizeof(void*) == sizeof(int64_t)) {
                 type = TYPE_UINT64;
             } else if (sizeof(void*) == sizeof(int)) {
                 type = TYPE_UINTN;
             } else {
                 MOZ_ASSERT(0);
                 break;
             }
             radix = 16;
             goto fetch_and_convert;

 #if 0
           case 'C':
           case 'S':
           case 'E':
           case 'G':
             // XXX not supported I suppose
             MOZ_ASSERT(0);
             break;
 #endif

           case 's':
             if(type == TYPE_INT16) {
                 u.ws = va_arg(ap, const char16_t*);
                 if (!cvt_s(ss, u.ws, width, prec, flags))
                     return false;
             } else {
                 u.s = va_arg(ap, const char*);
                 if (!cvt_s(ss, u.s, width, prec, flags))
                     return false;
             }
             break;

           case 'n':
             u.ip = va_arg(ap, int*);
             if (u.ip) {
                 *u.ip = ss->cur - ss->base;
             }
             break;

           default:
             // Not a % token after all... skip it
 #if 0
             MOZ_ASSERT(0);
 #endif
             if (!(*ss->stuff)(ss, "%", 1))
                 return false;
             if (!(*ss->stuff)(ss, fmt - 1, 1))
                 return false;
         }
     }

     // Stuff trailing NUL
     if (!(*ss->stuff)(ss, "\0", 1))
         return false;

     return true;
 }

 /************************************************************************/

 /*
  * Stuff routine that automatically grows the js_malloc'd output buffer
  * before it overflows.
  */
 static bool
 GrowStuff(SprintfState* ss, const char* sp, size_t len)
 {
     ptrdiff_t off;
     char* newbase;
     size_t newlen;

     off = ss->cur - ss->base;
     if (off + len >= ss->maxlen) {
         /* Grow the buffer */
         newlen = ss->maxlen + ((len > 32) ? len : 32);
         newbase = static_cast<char*>(js_realloc(ss->base, newlen));
         if (!newbase) {
             /* Ran out of memory */
             return false;
         }
         ss->base = newbase;
         ss->maxlen = newlen;
         ss->cur = ss->base + off;
     }

     /* Copy data */
     while (len) {
         --len;
         *ss->cur++ = *sp++;
     }
     MOZ_ASSERT(size_t(ss->cur - ss->base) <= ss->maxlen);
     return true;
 }

 /*
  * sprintf into a js_malloc'd buffer
  */
 JS_PUBLIC_API(char*)
 JS_smprintf(const char* fmt, ...)
 {
     va_list ap;
     char* rv;

     va_start(ap, fmt);
     rv = JS_vsmprintf(fmt, ap);
     va_end(ap);
     return rv;
 }

 /*
  * Free memory allocated, for the caller, by JS_smprintf
  */
 JS_PUBLIC_API(void)
 JS_smprintf_free(char* mem)
 {
     js_free(mem);
 }

 JS_PUBLIC_API(char*)
 JS_vsmprintf(const char* fmt, va_list ap)
 {
     SprintfState ss;

     ss.stuff = GrowStuff;
     ss.base = 0;
     ss.cur = 0;
     ss.maxlen = 0;
     if (!dosprintf(&ss, fmt, ap)) {
         js_free(ss.base);
         return 0;
     }
     return ss.base;
 }

 /*
  * Stuff routine that discards overflow data
  */
 static bool
 LimitStuff(SprintfState* ss, const char* sp, size_t len)
 {
     size_t limit = ss->maxlen - (ss->cur - ss->base);

     if (len > limit)
         len = limit;
     while (len) {
         --len;
         *ss->cur++ = *sp++;
     }
     return true;
 }

 /*
  * sprintf into a fixed size buffer. Make sure there is a NUL at the end
  * when finished.
  */
 JS_PUBLIC_API(uint32_t)
 JS_snprintf(char* out, uint32_t outlen, const char* fmt, ...)
 {
     va_list ap;
     int rv;

     MOZ_ASSERT(int32_t(outlen) > 0);
     if (int32_t(outlen) <= 0)
         return 0;

     va_start(ap, fmt);
     rv = JS_vsnprintf(out, outlen, fmt, ap);
     va_end(ap);
     return rv;
 }

 JS_PUBLIC_API(uint32_t)
 JS_vsnprintf(char* out, uint32_t outlen, const char* fmt, va_list ap)
 {
     SprintfState ss;

     if (outlen == 0)
         return 0;

     ss.stuff = LimitStuff;
     ss.base = out;
     ss.cur = out;
     ss.maxlen = outlen;
     (void) dosprintf(&ss, fmt, ap);

     uint32_t charsWritten = ss.cur - ss.base;
     MOZ_ASSERT(charsWritten > 0);

     // If we didn't append a null then we must have hit the buffer limit. Write
     // a null terminator now and return a value indicating that we failed.
     if (ss.cur[-1] != '\0') {
         ss.cur[-1] = '\0';
         return outlen;
     }

     // Success: return the number of character written excluding the null
     // terminator.
     return charsWritten - 1;
 }

 JS_PUBLIC_API(char*)
 JS_sprintf_append(char* last, const char* fmt, ...)
 {
     va_list ap;
     char* rv;

     va_start(ap, fmt);
     rv = JS_vsprintf_append(last, fmt, ap);
     va_end(ap);
     return rv;
 }

 JS_PUBLIC_API(char*)
 JS_vsprintf_append(char* last, const char* fmt, va_list ap)
 {
     SprintfState ss;

     ss.stuff = GrowStuff;
     if (last) {
         size_t lastlen = strlen(last);
         ss.base = last;
         ss.cur = last + lastlen;
         ss.maxlen = lastlen;
     } else {
         ss.base = 0;
         ss.cur = 0;
         ss.maxlen = 0;
     }
     if (!dosprintf(&ss, fmt, ap)) {
         js_free(ss.base);
         return 0;
     }
     return ss.base;
 }

 #undef TYPE_INT16
 #undef TYPE_UINT16
 #undef TYPE_INTN
 #undef TYPE_UINTN
 #undef TYPE_INT32
 #undef TYPE_UINT32
 #undef TYPE_INT64
 #undef TYPE_UINT64
 #undef TYPE_STRING
 #undef TYPE_DOUBLE
 #undef TYPE_INTSTR
 #undef TYPE_WSTRING
 #undef TYPE_UNKNOWN

 #undef FLAG_LEFT
 #undef FLAG_SIGNED
 #undef FLAG_SPACED
 #undef FLAG_ZEROS
 #undef FLAG_NEG
	/* -- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 --
	* vim: set ts=8 sts=4 et sw=4 tw=99:
	* This Source Code Form is subject to the terms of the Mozilla Public
	* License, v. 2.0. If a copy of the MPL was not distributed with this
	* file, You can obtain one at http://mozilla.org/MPL/2.0/. */

	/*
	* Portable safe sprintf code.
	*
	* Author: Kipp E.B. Hickman
	*/

	#include "jsprf.h"

	#include "mozilla/Snprintf.h"
	#include "mozilla/Vector.h"

	#include <stdarg.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>

	#include "jsalloc.h"
	#include "jspubtd.h"
	#include "jsstr.h"
	#include "jsutil.h"

	using namespace js;

	/*
	* Note: on some platforms va_list is defined as an array,
	* and requires array notation.
	*/
	#ifdef HAVE_VA_COPY
	#define VARARGS_ASSIGN(foo, bar) va_copy(foo, bar)
	#elif defined(HAVE_VA_LIST_AS_ARRAY)
	#define VARARGS_ASSIGN(foo, bar) foo[0] = bar[0]
	#else
	#define VARARGS_ASSIGN(foo, bar) (foo) = (bar)
	#endif

	struct SprintfState
	{
	bool (stuff)(SprintfState ss, const char* sp, size_t len);

	char* base;
	char* cur;
	size_t maxlen;

	int (func)(void arg, const char* sp, uint32_t len);
	void* arg;
	};

	/*
	* Numbered Argument State
	*/
	struct NumArgState
	{
	int type; // type of the current ap
	va_list ap; // point to the corresponding position on ap
	};

	typedef mozilla::Vector<NumArgState, 20, js::SystemAllocPolicy> NumArgStateVector;


	#define TYPE_INT16 0
	#define TYPE_UINT16 1
	#define TYPE_INTN 2
	#define TYPE_UINTN 3
	#define TYPE_INT32 4
	#define TYPE_UINT32 5
	#define TYPE_INT64 6
	#define TYPE_UINT64 7
	#define TYPE_STRING 8
	#define TYPE_DOUBLE 9
	#define TYPE_INTSTR 10
	#define TYPE_WSTRING 11
	#define TYPE_UNKNOWN 20

	#define FLAG_LEFT 0x1
	#define FLAG_SIGNED 0x2
	#define FLAG_SPACED 0x4
	#define FLAG_ZEROS 0x8
	#define FLAG_NEG 0x10

	inline bool
	generic_write(SprintfState* ss, const char* src, size_t srclen)
	{
	return (*ss->stuff)(ss, src, srclen);
	}

	inline bool
	generic_write(SprintfState* ss, const char16_t* src, size_t srclen)
	{
	const size_t CHUNK_SIZE = 64;
	char chunk[CHUNK_SIZE];

	size_t j = 0;
	size_t i = 0;
	while (i < srclen) {
	// FIXME: truncates characters to 8 bits
	chunk[j++] = char(src[i++]);

	if (j == CHUNK_SIZE \|\| i == srclen) {
	if (!(*ss->stuff)(ss, chunk, j))
	return false;
	j = 0;
	}
	}
	return true;
	}

	// Fill into the buffer using the data in src
	template <typename Char>
	static bool
	fill2(SprintfState* ss, const Char* src, int srclen, int width, int flags)
	{
	char space = ' ';

	width -= srclen;
	if (width > 0 && (flags & FLAG_LEFT) == 0) { // Right adjusting
	if (flags & FLAG_ZEROS)
	space = '0';
	while (--width >= 0) {
	if (!(*ss->stuff)(ss, &space, 1))
	return false;
	}
	}

	// Copy out the source data
	if (!generic_write(ss, src, srclen))
	return false;

	if (width > 0 && (flags & FLAG_LEFT) != 0) { // Left adjusting
	while (--width >= 0) {
	if (!(*ss->stuff)(ss, &space, 1))
	return false;
	}
	}
	return true;
	}

	/*
	* Fill a number. The order is: optional-sign zero-filling conversion-digits
	*/
	static bool
	fill_n(SprintfState* ss, const char* src, int srclen, int width, int prec, int type, int flags)
	{
	int zerowidth = 0;
	int precwidth = 0;
	int signwidth = 0;
	int leftspaces = 0;
	int rightspaces = 0;
	int cvtwidth;
	char sign;

	if ((type & 1) == 0) {
	if (flags & FLAG_NEG) {
	sign = '-';
	signwidth = 1;
	} else if (flags & FLAG_SIGNED) {
	sign = '+';
	signwidth = 1;
	} else if (flags & FLAG_SPACED) {
	sign = ' ';
	signwidth = 1;
	}
	}
	cvtwidth = signwidth + srclen;

	if (prec > 0) {
	if (prec > srclen) {
	precwidth = prec - srclen; // Need zero filling
	cvtwidth += precwidth;
	}
	}

	if ((flags & FLAG_ZEROS) && (prec < 0)) {
	if (width > cvtwidth) {
	zerowidth = width - cvtwidth; // Zero filling
	cvtwidth += zerowidth;
	}
	}

	if (flags & FLAG_LEFT) {
	if (width > cvtwidth) {
	// Space filling on the right (i.e. left adjusting)
	rightspaces = width - cvtwidth;
	}
	} else {
	if (width > cvtwidth) {
	// Space filling on the left (i.e. right adjusting)
	leftspaces = width - cvtwidth;
	}
	}
	while (--leftspaces >= 0) {
	if (!(*ss->stuff)(ss, " ", 1))
	return false;
	}
	if (signwidth) {
	if (!(*ss->stuff)(ss, &sign, 1))
	return false;
	}
	while (--precwidth >= 0) {
	if (!(*ss->stuff)(ss, "0", 1))
	return false;
	}
	while (--zerowidth >= 0) {
	if (!(*ss->stuff)(ss, "0", 1))
	return false;
	}
	if (!(*ss->stuff)(ss, src, uint32_t(srclen)))
	return false;
	while (--rightspaces >= 0) {
	if (!(*ss->stuff)(ss, " ", 1))
	return false;
	}
	return true;
	}

	/* Convert a long into its printable form. */
	static bool cvt_l(SprintfState* ss, long num, int width, int prec, int radix,
	int type, int flags, const char* hexp)
	{
	char cvtbuf[100];
	char* cvt;
	int digits;

	// according to the man page this needs to happen
	if ((prec == 0) && (num == 0))
	return true;

	// Converting decimal is a little tricky. In the unsigned case we
	// need to stop when we hit 10 digits. In the signed case, we can
	// stop when the number is zero.
	cvt = cvtbuf + sizeof(cvtbuf);
	digits = 0;
	while (num) {
	int digit = (((unsigned long)num) % radix) & 0xF;
	*--cvt = hexp[digit];
	digits++;
	num = (long)(((unsigned long)num) / radix);
	}
	if (digits == 0) {
	*--cvt = '0';
	digits++;
	}

	// Now that we have the number converted without its sign, deal with
	// the sign and zero padding.
	return fill_n(ss, cvt, digits, width, prec, type, flags);
	}

	/* Convert a 64-bit integer into its printable form. */
	static bool cvt_ll(SprintfState* ss, int64_t num, int width, int prec, int radix,
	int type, int flags, const char* hexp)
	{
	// According to the man page, this needs to happen.
	if (prec == 0 && num == 0)
	return true;

	// Converting decimal is a little tricky. In the unsigned case we
	// need to stop when we hit 10 digits. In the signed case, we can
	// stop when the number is zero.
	int64_t rad = int64_t(radix);
	char cvtbuf[100];
	char* cvt = cvtbuf + sizeof(cvtbuf);
	int digits = 0;
	while (num != 0) {
	int64_t quot = uint64_t(num) / rad;
	int64_t rem = uint64_t(num) % rad;
	int32_t digit = int32_t(rem);
	*--cvt = hexp[digit & 0xf];
	digits++;
	num = quot;
	}
	if (digits == 0) {
	*--cvt = '0';
	digits++;
	}

	// Now that we have the number converted without its sign, deal with
	// the sign and zero padding.
	return fill_n(ss, cvt, digits, width, prec, type, flags);
	}

	/*
	* Convert a double precision floating point number into its printable
	* form.
	*/
	static bool cvt_f(SprintfState* ss, double d, const char* fmt0, const char* fmt1)
	{
	char fin[20];
	char fout[300];
	int amount = fmt1 - fmt0;

	MOZ_ASSERT((amount > 0) && (amount < (int)sizeof(fin)));
	if (amount >= (int)sizeof(fin)) {
	// Totally bogus % command to sprintf. Just ignore it
	return true;
	}
	js_memcpy(fin, fmt0, (size_t)amount);
	fin[amount] = 0;

	// Convert floating point using the native snprintf code
	#ifdef DEBUG
	{
	const char* p = fin;
	while (*p) {
	MOZ_ASSERT(*p != 'L');
	p++;
	}
	}
	#endif
	snprintf_literal(fout, fin, d);

	return (*ss->stuff)(ss, fout, strlen(fout));
	}

	static inline const char* generic_null_str(const char*) { return "(null)"; }
	static inline const char16_t* generic_null_str(const char16_t*) { return MOZ_UTF16("(null)"); }

	static inline size_t generic_strlen(const char* s) { return strlen(s); }
	static inline size_t generic_strlen(const char16_t* s) { return js_strlen(s); }

	/*
	* Convert a string into its printable form. "width" is the output
	* width. "prec" is the maximum number of characters of "s" to output,
	* where -1 means until NUL.
	*/
	template <typename Char>
	static bool
	cvt_s(SprintfState* ss, const Char* s, int width, int prec, int flags)
	{
	if (prec == 0)
	return true;
	if (!s)
	s = generic_null_str(s);

	// Limit string length by precision value
	int slen = int(generic_strlen(s));
	if (0 < prec && prec < slen)
	slen = prec;

	// and away we go
	return fill2(ss, s, slen, width, flags);
	}

	/*
	* BuildArgArray stands for Numbered Argument list Sprintf
	* for example,
	* fmp = "%4$i, %2$d, %3s, %1d";
	* the number must start from 1, and no gap among them
	*/
	static bool
	BuildArgArray(const char* fmt, va_list ap, NumArgStateVector& nas)
	{
	size_t number = 0, cn = 0, i;
	const char* p;
	char c;


	// First pass:
	// Detemine how many legal % I have got, then allocate space.

	p = fmt;
	i = 0;
	while ((c = *p++) != 0) {
	if (c != '%')
	continue;
	if ((c = *p++) == '%') // skip %% case
	continue;

	while (c != 0) {
	if (c > '9' \|\| c < '0') {
	if (c == '$') { // numbered argument case
	if (i > 0)
	MOZ_CRASH("Bad format string");
	number++;
	} else { // non-numbered argument case
	if (number > 0)
	MOZ_CRASH("Bad format string");
	i = 1;
	}
	break;
	}

	c = *p++;
	}
	}

	if (number == 0)
	return true;

	if (!nas.growByUninitialized(number))
	return false;

	for (i = 0; i < number; i++)
	nas[i].type = TYPE_UNKNOWN;


	// Second pass:
	// Set nas[].type.

	p = fmt;
	while ((c = *p++) != 0) {
	if (c != '%')
	continue;
	c = *p++;
	if (c == '%')
	continue;

	cn = 0;
	while (c && c != '$') { // should improve error check later
	cn = cn*10 + c - '0';
	c = *p++;
	}

	if (!c \|\| cn < 1 \|\| cn > number)
	MOZ_CRASH("Bad format string");

	// nas[cn] starts from 0, and make sure nas[cn].type is not assigned.
	cn--;
	if (nas[cn].type != TYPE_UNKNOWN)
	continue;

	c = *p++;

	// width
	if (c == '*') {
	// not supported feature, for the argument is not numbered
	MOZ_CRASH("Bad format string");
	}

	while ((c >= '0') && (c <= '9')) {
	c = *p++;
	}

	// precision
	if (c == '.') {
	c = *p++;
	if (c == '*') {
	// not supported feature, for the argument is not numbered
	MOZ_CRASH("Bad format string");
	}

	while ((c >= '0') && (c <= '9')) {
	c = *p++;
	}
	}

	// size
	nas[cn].type = TYPE_INTN;
	if (c == 'h') {
	nas[cn].type = TYPE_INT16;
	c = *p++;
	} else if (c == 'L') {
	// XXX not quite sure here
	nas[cn].type = TYPE_INT64;
	c = *p++;
	} else if (c == 'l') {
	nas[cn].type = TYPE_INT32;
	c = *p++;
	if (c == 'l') {
	nas[cn].type = TYPE_INT64;
	c = *p++;
	}
	} else if (c == 'z' \|\| c == 'I') {
	static_assert(sizeof(size_t) == sizeof(int32_t) \|\| sizeof(size_t) == sizeof(int64_t),
	"size_t is not one of the expected sizes");
	nas[cn].type = sizeof(size_t) == sizeof(int64_t) ? TYPE_INT64 : TYPE_INT32;
	c = *p++;
	}

	// format
	switch (c) {
	case 'd':
	case 'c':
	case 'i':
	case 'o':
	case 'u':
	case 'x':
	case 'X':
	break;

	case 'e':
	case 'f':
	case 'g':
	nas[cn].type = TYPE_DOUBLE;
	break;

	case 'p':
	// XXX should use cpp
	if (sizeof(void*) == sizeof(int32_t)) {
	nas[cn].type = TYPE_UINT32;
	} else if (sizeof(void*) == sizeof(int64_t)) {
	nas[cn].type = TYPE_UINT64;
	} else if (sizeof(void*) == sizeof(int)) {
	nas[cn].type = TYPE_UINTN;
	} else {
	nas[cn].type = TYPE_UNKNOWN;
	}
	break;

	case 'C':
	case 'S':
	case 'E':
	case 'G':
	// XXX not supported I suppose
	MOZ_ASSERT(0);
	nas[cn].type = TYPE_UNKNOWN;
	break;

	case 's':
	nas[cn].type = (nas[cn].type == TYPE_UINT16) ? TYPE_WSTRING : TYPE_STRING;
	break;

	case 'n':
	nas[cn].type = TYPE_INTSTR;
	break;

	default:
	MOZ_ASSERT(0);
	nas[cn].type = TYPE_UNKNOWN;
	break;
	}

	// get a legal para.
	if (nas[cn].type == TYPE_UNKNOWN)
	MOZ_CRASH("Bad format string");
	}


	// Third pass:
	// Fill nas[].ap.

	cn = 0;
	while (cn < number) {
	if (nas[cn].type == TYPE_UNKNOWN) {
	cn++;
	continue;
	}

	VARARGS_ASSIGN(nas[cn].ap, ap);

	switch (nas[cn].type) {
	case TYPE_INT16:
	case TYPE_UINT16:
	case TYPE_INTN:
	case TYPE_UINTN: (void) va_arg(ap, int); break;
	case TYPE_INT32: (void) va_arg(ap, int32_t); break;
	case TYPE_UINT32: (void) va_arg(ap, uint32_t); break;
	case TYPE_INT64: (void) va_arg(ap, int64_t); break;
	case TYPE_UINT64: (void) va_arg(ap, uint64_t); break;
	case TYPE_STRING: (void) va_arg(ap, char*); break;
	case TYPE_WSTRING: (void) va_arg(ap, char16_t*); break;
	case TYPE_INTSTR: (void) va_arg(ap, int*); break;
	case TYPE_DOUBLE: (void) va_arg(ap, double); break;

	default: MOZ_CRASH();
	}

	cn++;
	}

	return true;
	}

	/*
	* The workhorse sprintf code.
	*/
	static bool
	dosprintf(SprintfState* ss, const char* fmt, va_list ap)
	{
	char c;
	int flags, width, prec, radix, type;
	union {
	char ch;
	char16_t wch;
	int i;
	long l;
	int64_t ll;
	double d;
	const char* s;
	const char16_t* ws;
	int* ip;
	} u;
	const char* fmt0;
	static const char hex[] = "0123456789abcdef";
	static const char HEX[] = "0123456789ABCDEF";
	const char* hexp;
	int i;
	char pattern[20];
	const char* dolPt = nullptr; // in "%4$.2f", dolPt will point to '.'

	// Build an argument array, IF the fmt is numbered argument
	// list style, to contain the Numbered Argument list pointers.

	NumArgStateVector nas;
	if (!BuildArgArray(fmt, ap, nas)) {
	// the fmt contains error Numbered Argument format, jliu@netscape.com
	MOZ_CRASH("Bad format string");
	}

	while ((c = *fmt++) != 0) {
	if (c != '%') {
	if (!(*ss->stuff)(ss, fmt - 1, 1))
	return false;

	continue;
	}
	fmt0 = fmt - 1;

	// Gobble up the % format string. Hopefully we have handled all
	// of the strange cases!
	flags = 0;
	c = *fmt++;
	if (c == '%') {
	// quoting a % with %%
	if (!(*ss->stuff)(ss, fmt - 1, 1))
	return false;

	continue;
	}

	if (!nas.empty()) {
	// the fmt contains the Numbered Arguments feature
	i = 0;
	while (c && c != '$') { // should improve error check later
	i = (i * 10) + (c - '0');
	c = *fmt++;
	}

	if (nas[i - 1].type == TYPE_UNKNOWN)
	MOZ_CRASH("Bad format string");

	ap = nas[i - 1].ap;
	dolPt = fmt;
	c = *fmt++;
	}

	// Examine optional flags. Note that we do not implement the
	// '#' flag of sprintf(). The ANSI C spec. of the '#' flag is
	// somewhat ambiguous and not ideal, which is perhaps why
	// the various sprintf() implementations are inconsistent
	// on this feature.
	while ((c == '-') \|\| (c == '+') \|\| (c == ' ') \|\| (c == '0')) {
	if (c == '-') flags \|= FLAG_LEFT;
	if (c == '+') flags \|= FLAG_SIGNED;
	if (c == ' ') flags \|= FLAG_SPACED;
	if (c == '0') flags \|= FLAG_ZEROS;
	c = *fmt++;
	}
	if (flags & FLAG_SIGNED) flags &= ~FLAG_SPACED;
	if (flags & FLAG_LEFT) flags &= ~FLAG_ZEROS;

	// width
	if (c == '*') {
	c = *fmt++;
	width = va_arg(ap, int);
	} else {
	width = 0;
	while ((c >= '0') && (c <= '9')) {
	width = (width * 10) + (c - '0');
	c = *fmt++;
	}
	}

	// precision
	prec = -1;
	if (c == '.') {
	c = *fmt++;
	if (c == '*') {
	c = *fmt++;
	prec = va_arg(ap, int);
	} else {
	prec = 0;
	while ((c >= '0') && (c <= '9')) {
	prec = (prec * 10) + (c - '0');
	c = *fmt++;
	}
	}
	}

	// size
	type = TYPE_INTN;
	if (c == 'h') {
	type = TYPE_INT16;
	c = *fmt++;
	} else if (c == 'L') {
	// XXX not quite sure here
	type = TYPE_INT64;
	c = *fmt++;
	} else if (c == 'l') {
	type = TYPE_INT32;
	c = *fmt++;
	if (c == 'l') {
	type = TYPE_INT64;
	c = *fmt++;
	}
	} else if (c == 'z' \|\| c == 'I') {
	static_assert(sizeof(size_t) == sizeof(int32_t) \|\| sizeof(size_t) == sizeof(int64_t),
	"size_t is not one of the expected sizes");
	type = sizeof(size_t) == sizeof(int64_t) ? TYPE_INT64 : TYPE_INT32;
	c = *fmt++;
	}

	// format
	hexp = hex;
	switch (c) {
	case 'd': case 'i': // decimal/integer
	radix = 10;
	goto fetch_and_convert;

	case 'o': // octal
	radix = 8;
	type \|= 1;
	goto fetch_and_convert;

	case 'u': // unsigned decimal
	radix = 10;
	type \|= 1;
	goto fetch_and_convert;

	case 'x': // unsigned hex
	radix = 16;
	type \|= 1;
	goto fetch_and_convert;

	case 'X': // unsigned HEX
	radix = 16;
	hexp = HEX;
	type \|= 1;
	goto fetch_and_convert;

	fetch_and_convert:
	switch (type) {
	case TYPE_INT16:
	u.l = va_arg(ap, int);
	if (u.l < 0) {
	u.l = -u.l;
	flags \|= FLAG_NEG;
	}
	goto do_long;
	case TYPE_UINT16:
	u.l = va_arg(ap, int) & 0xffff;
	goto do_long;
	case TYPE_INTN:
	u.l = va_arg(ap, int);
	if (u.l < 0) {
	u.l = -u.l;
	flags \|= FLAG_NEG;
	}
	goto do_long;
	case TYPE_UINTN:
	u.l = (long)va_arg(ap, unsigned int);
	goto do_long;

	case TYPE_INT32:
	u.l = va_arg(ap, int32_t);
	if (u.l < 0) {
	u.l = -u.l;
	flags \|= FLAG_NEG;
	}
	goto do_long;
	case TYPE_UINT32:
	u.l = (long)va_arg(ap, uint32_t);
	do_long:
	if (!cvt_l(ss, u.l, width, prec, radix, type, flags, hexp))
	return false;

	break;

	case TYPE_INT64:
	u.ll = va_arg(ap, int64_t);
	if (u.ll < 0) {
	u.ll = -u.ll;
	flags \|= FLAG_NEG;
	}
	goto do_longlong;
	case TYPE_UINT64:
	u.ll = va_arg(ap, uint64_t);
	do_longlong:
	if (!cvt_ll(ss, u.ll, width, prec, radix, type, flags, hexp))
	return false;

	break;
	}
	break;

	case 'e':
	case 'E':
	case 'f':
	case 'g':
	u.d = va_arg(ap, double);
	if (!nas.empty()) {
	i = fmt - dolPt;
	if (i < int(sizeof(pattern))) {
	pattern[0] = '%';
	js_memcpy(&pattern[1], dolPt, size_t(i));
	if (!cvt_f(ss, u.d, pattern, &pattern[i + 1]))
	return false;
	}
	} else {
	if (!cvt_f(ss, u.d, fmt0, fmt))
	return false;
	}

	break;

	case 'c':
	if ((flags & FLAG_LEFT) == 0) {
	while (width-- > 1) {
	if (!(*ss->stuff)(ss, " ", 1))
	return false;
	}
	}
	switch (type) {
	case TYPE_INT16:
	case TYPE_INTN:
	u.ch = va_arg(ap, int);
	if (!(*ss->stuff)(ss, &u.ch, 1))
	return false;
	break;
	}
	if (flags & FLAG_LEFT) {
	while (width-- > 1) {
	if (!(*ss->stuff)(ss, " ", 1))
	return false;
	}
	}
	break;

	case 'p':
	if (sizeof(void*) == sizeof(int32_t)) {
	type = TYPE_UINT32;
	} else if (sizeof(void*) == sizeof(int64_t)) {
	type = TYPE_UINT64;
	} else if (sizeof(void*) == sizeof(int)) {
	type = TYPE_UINTN;
	} else {
	MOZ_ASSERT(0);
	break;
	}
	radix = 16;
	goto fetch_and_convert;

	#if 0
	case 'C':
	case 'S':
	case 'E':
	case 'G':
	// XXX not supported I suppose
	MOZ_ASSERT(0);
	break;
	#endif

	case 's':
	if(type == TYPE_INT16) {
	u.ws = va_arg(ap, const char16_t*);
	if (!cvt_s(ss, u.ws, width, prec, flags))
	return false;
	} else {
	u.s = va_arg(ap, const char*);
	if (!cvt_s(ss, u.s, width, prec, flags))
	return false;
	}
	break;

	case 'n':
	u.ip = va_arg(ap, int*);
	if (u.ip) {
	*u.ip = ss->cur - ss->base;
	}
	break;

	default:
	// Not a % token after all... skip it
	#if 0
	MOZ_ASSERT(0);
	#endif
	if (!(*ss->stuff)(ss, "%", 1))
	return false;
	if (!(*ss->stuff)(ss, fmt - 1, 1))
	return false;
	}
	}

	// Stuff trailing NUL
	if (!(*ss->stuff)(ss, "\0", 1))
	return false;

	return true;
	}

	/************************************************************************/

	/*
	* Stuff routine that automatically grows the js_malloc'd output buffer
	* before it overflows.
	*/
	static bool
	GrowStuff(SprintfState* ss, const char* sp, size_t len)
	{
	ptrdiff_t off;
	char* newbase;
	size_t newlen;

	off = ss->cur - ss->base;
	if (off + len >= ss->maxlen) {
	/* Grow the buffer */
	newlen = ss->maxlen + ((len > 32) ? len : 32);
	newbase = static_cast<char*>(js_realloc(ss->base, newlen));
	if (!newbase) {
	/* Ran out of memory */
	return false;
	}
	ss->base = newbase;
	ss->maxlen = newlen;
	ss->cur = ss->base + off;
	}

	/* Copy data */
	while (len) {
	--len;
	ss->cur++ = sp++;
	}
	MOZ_ASSERT(size_t(ss->cur - ss->base) <= ss->maxlen);
	return true;
	}

	/*
	* sprintf into a js_malloc'd buffer
	*/
	JS_PUBLIC_API(char*)
	JS_smprintf(const char* fmt, ...)
	{
	va_list ap;
	char* rv;

	va_start(ap, fmt);
	rv = JS_vsmprintf(fmt, ap);
	va_end(ap);
	return rv;
	}

	/*
	* Free memory allocated, for the caller, by JS_smprintf
	*/
	JS_PUBLIC_API(void)
	JS_smprintf_free(char* mem)
	{
	js_free(mem);
	}

	JS_PUBLIC_API(char*)
	JS_vsmprintf(const char* fmt, va_list ap)
	{
	SprintfState ss;

	ss.stuff = GrowStuff;
	ss.base = 0;
	ss.cur = 0;
	ss.maxlen = 0;
	if (!dosprintf(&ss, fmt, ap)) {
	js_free(ss.base);
	return 0;
	}
	return ss.base;
	}

	/*
	* Stuff routine that discards overflow data
	*/
	static bool
	LimitStuff(SprintfState* ss, const char* sp, size_t len)
	{
	size_t limit = ss->maxlen - (ss->cur - ss->base);

	if (len > limit)
	len = limit;
	while (len) {
	--len;
	ss->cur++ = sp++;
	}
	return true;
	}

	/*
	* sprintf into a fixed size buffer. Make sure there is a NUL at the end
	* when finished.
	*/
	JS_PUBLIC_API(uint32_t)
	JS_snprintf(char* out, uint32_t outlen, const char* fmt, ...)
	{
	va_list ap;
	int rv;

	MOZ_ASSERT(int32_t(outlen) > 0);
	if (int32_t(outlen) <= 0)
	return 0;

	va_start(ap, fmt);
	rv = JS_vsnprintf(out, outlen, fmt, ap);
	va_end(ap);
	return rv;
	}

	JS_PUBLIC_API(uint32_t)
	JS_vsnprintf(char* out, uint32_t outlen, const char* fmt, va_list ap)
	{
	SprintfState ss;

	if (outlen == 0)
	return 0;

	ss.stuff = LimitStuff;
	ss.base = out;
	ss.cur = out;
	ss.maxlen = outlen;
	(void) dosprintf(&ss, fmt, ap);

	uint32_t charsWritten = ss.cur - ss.base;
	MOZ_ASSERT(charsWritten > 0);

	// If we didn't append a null then we must have hit the buffer limit. Write
	// a null terminator now and return a value indicating that we failed.
	if (ss.cur[-1] != '\0') {
	ss.cur[-1] = '\0';
	return outlen;
	}

	// Success: return the number of character written excluding the null
	// terminator.
	return charsWritten - 1;
	}

	JS_PUBLIC_API(char*)
	JS_sprintf_append(char* last, const char* fmt, ...)
	{
	va_list ap;
	char* rv;

	va_start(ap, fmt);
	rv = JS_vsprintf_append(last, fmt, ap);
	va_end(ap);
	return rv;
	}

	JS_PUBLIC_API(char*)
	JS_vsprintf_append(char* last, const char* fmt, va_list ap)
	{
	SprintfState ss;

	ss.stuff = GrowStuff;
	if (last) {
	size_t lastlen = strlen(last);
	ss.base = last;
	ss.cur = last + lastlen;
	ss.maxlen = lastlen;
	} else {
	ss.base = 0;
	ss.cur = 0;
	ss.maxlen = 0;
	}
	if (!dosprintf(&ss, fmt, ap)) {
	js_free(ss.base);
	return 0;
	}
	return ss.base;
	}

	#undef TYPE_INT16
	#undef TYPE_UINT16
	#undef TYPE_INTN
	#undef TYPE_UINTN
	#undef TYPE_INT32
	#undef TYPE_UINT32
	#undef TYPE_INT64
	#undef TYPE_UINT64
	#undef TYPE_STRING
	#undef TYPE_DOUBLE
	#undef TYPE_INTSTR
	#undef TYPE_WSTRING
	#undef TYPE_UNKNOWN

	#undef FLAG_LEFT
	#undef FLAG_SIGNED
	#undef FLAG_SPACED
	#undef FLAG_ZEROS
	#undef FLAG_NEG