scuffed-code/icu4c/source/extra/uconv/uconv.cpp
2004-03-25 00:36:30 +00:00

1396 lines
45 KiB
C++

/*****************************************************************************
*
* Copyright (C) 1999-2003, International Business Machines
* Corporation and others. All Rights Reserved.
*
******************************************************************************/
/*
* uconv(1): an iconv(1)-like converter using ICU.
*
* Original code by Jonas Utterström <jonas.utterstrom@vittran.norrnod.se>
* contributed in 1999.
*
* Conversion to the C conversion API and many improvements by
* Yves Arrouye <yves@realnames.com>, current maintainer.
*
* Markus Scherer maintainer from 2003.
* See source code repository history for changes.
*/
#include <unicode/utypes.h>
#include <unicode/ucnv.h>
#include <unicode/uenum.h>
#include <unicode/unistr.h>
#include <unicode/translit.h>
#include <unicode/uset.h>
#include <unicode/uclean.h>
#include <stdio.h>
#include <errno.h>
#include <string.h>
#include <stdlib.h>
#include "cmemory.h"
#include "cstring.h"
#include "ustrfmt.h"
#include "unicode/uwmsg.h"
#if defined(WIN32) || defined(U_CYGWIN)
#include <io.h>
#include <fcntl.h>
#endif
#ifdef UCONVMSG_LINK
/* below from the README */
#include "unicode/utypes.h"
#include "unicode/udata.h"
U_CFUNC char uconvmsg_dat[];
#endif
#define LENGTHOF(array) (int32_t)(sizeof(array)/sizeof((array)[0]))
#define DEFAULT_BUFSZ 4096
#define UCONVMSG "uconvmsg"
static UResourceBundle *gBundle = 0; /* Bundle containing messages. */
/*
* Initialize the message bundle so that message strings can be fetched
* by u_wmsg().
*
*/
static void initMsg(const char *pname) {
static int ps = 0;
if (!ps) {
char dataPath[2048]; /* XXX Sloppy: should be PATH_MAX. */
UErrorCode err = U_ZERO_ERROR;
ps = 1;
/* Set up our static data - if any */
#ifdef UCONVMSG_LINK
udata_setAppData(UCONVMSG, (const void*) uconvmsg_dat, &err);
if (U_FAILURE(err)) {
fprintf(stderr, "%s: warning, problem installing our static resource bundle data uconvmsg: %s - trying anyways.\n",
pname, u_errorName(err));
err = U_ZERO_ERROR; /* It may still fail */
}
#endif
/* Get messages. */
gBundle = u_wmsg_setPath(UCONVMSG, &err);
if (U_FAILURE(err)) {
fprintf(stderr,
"%s: warning: couldn't open bundle %s: %s\n",
pname, UCONVMSG, u_errorName(err));
#ifdef UCONVMSG_LINK
fprintf(stderr,
"%s: setAppData was called, internal data %s failed to load\n",
pname, UCONVMSG);
#endif
err = U_ZERO_ERROR;
/* that was try #1, try again with a path */
uprv_strcpy(dataPath, u_getDataDirectory());
uprv_strcat(dataPath, U_FILE_SEP_STRING);
uprv_strcat(dataPath, UCONVMSG);
gBundle = u_wmsg_setPath(dataPath, &err);
if (U_FAILURE(err)) {
fprintf(stderr,
"%s: warning: still couldn't open bundle %s: %s\n",
pname, dataPath, u_errorName(err));
fprintf(stderr, "%s: warning: messages will not be displayed\n", pname);
}
}
}
}
/* Mapping of callback names to the callbacks passed to the converter
API. */
static struct callback_ent {
const char *name;
UConverterFromUCallback fromu;
const void *fromuctxt;
UConverterToUCallback tou;
const void *touctxt;
} transcode_callbacks[] = {
{ "substitute",
UCNV_FROM_U_CALLBACK_SUBSTITUTE, 0,
UCNV_TO_U_CALLBACK_SUBSTITUTE, 0 },
{ "skip",
UCNV_FROM_U_CALLBACK_SKIP, 0,
UCNV_TO_U_CALLBACK_SKIP, 0 },
{ "stop",
UCNV_FROM_U_CALLBACK_STOP, 0,
UCNV_TO_U_CALLBACK_STOP, 0 },
{ "escape",
UCNV_FROM_U_CALLBACK_ESCAPE, 0,
UCNV_TO_U_CALLBACK_ESCAPE, 0},
{ "escape-icu",
UCNV_FROM_U_CALLBACK_ESCAPE, UCNV_ESCAPE_ICU,
UCNV_TO_U_CALLBACK_ESCAPE, UCNV_ESCAPE_ICU },
{ "escape-java",
UCNV_FROM_U_CALLBACK_ESCAPE, UCNV_ESCAPE_JAVA,
UCNV_TO_U_CALLBACK_ESCAPE, UCNV_ESCAPE_JAVA },
{ "escape-c",
UCNV_FROM_U_CALLBACK_ESCAPE, UCNV_ESCAPE_C,
UCNV_TO_U_CALLBACK_ESCAPE, UCNV_ESCAPE_C },
{ "escape-xml",
UCNV_FROM_U_CALLBACK_ESCAPE, UCNV_ESCAPE_XML_HEX,
UCNV_TO_U_CALLBACK_ESCAPE, UCNV_ESCAPE_XML_HEX },
{ "escape-xml-hex",
UCNV_FROM_U_CALLBACK_ESCAPE, UCNV_ESCAPE_XML_HEX,
UCNV_TO_U_CALLBACK_ESCAPE, UCNV_ESCAPE_XML_HEX },
{ "escape-xml-dec",
UCNV_FROM_U_CALLBACK_ESCAPE, UCNV_ESCAPE_XML_DEC,
UCNV_TO_U_CALLBACK_ESCAPE, UCNV_ESCAPE_XML_DEC },
{ "escape-unicode", UCNV_FROM_U_CALLBACK_ESCAPE, UCNV_ESCAPE_UNICODE,
UCNV_TO_U_CALLBACK_ESCAPE, UCNV_ESCAPE_UNICODE }
};
/* Return a pointer to a callback record given its name. */
static const struct callback_ent *findCallback(const char *name) {
int i, count =
sizeof(transcode_callbacks) / sizeof(*transcode_callbacks);
/* We'll do a linear search, there aren't many of them and bsearch()
may not be that portable. */
for (i = 0; i < count; ++i) {
if (!uprv_stricmp(name, transcode_callbacks[i].name)) {
return &transcode_callbacks[i];
}
}
return 0;
}
/* Print converter information. If lookfor is set, only that converter will
be printed, otherwise all converters will be printed. If canon is non
zero, tags and aliases for each converter are printed too, in the format
expected for convrters.txt(5). */
static int printConverters(const char *pname, const char *lookfor,
UBool canon)
{
UErrorCode err = U_ZERO_ERROR;
int32_t num;
uint16_t num_stds;
const char **stds;
/* If there is a specified name, just handle that now. */
if (lookfor) {
if (!canon) {
printf("%s\n", lookfor);
return 0;
} else {
/* Because we are printing a canonical name, we need the
true converter name. We've done that already except for
the default name (because we want to print the exact
name one would get when calling ucnv_getDefaultName()
in non-canon mode). But since we do not know at this
point if we have the default name or something else, we
need to normalize again to the canonical converter
name. */
const char *truename = ucnv_getAlias(lookfor, 0, &err);
if (U_SUCCESS(err)) {
lookfor = truename;
} else {
err = U_ZERO_ERROR;
}
}
}
/* Print converter names. We come here for one of two reasons: we
are printing all the names (lookfor was null), or we have a
single converter to print but in canon mode, hence we need to
get to it in order to print everything. */
num = ucnv_countAvailable();
if (num <= 0) {
initMsg(pname);
u_wmsg(stderr, "cantGetNames");
return -1;
}
if (lookfor) {
num = 1; /* We know where we want to be. */
}
num_stds = ucnv_countStandards();
stds = (const char **) uprv_malloc(num_stds * sizeof(*stds));
if (!stds) {
u_wmsg(stderr, "cantGetTag", u_wmsg_errorName(U_MEMORY_ALLOCATION_ERROR));
return -1;
} else {
uint16_t s;
if (canon) {
printf("{ ");
}
for (s = 0; s < num_stds; ++s) {
stds[s] = ucnv_getStandard(s, &err);
if (canon) {
printf("%s ", stds[s]);
}
if (U_FAILURE(err)) {
u_wmsg(stderr, "cantGetTag", u_wmsg_errorName(err));
return -1;
}
}
if (canon) {
puts("}");
}
}
for (int32_t i = 0; i < num; i++) {
const char *name;
uint16_t num_aliases;
/* Set the name either to what we are looking for, or
to the current converter name. */
if (lookfor) {
name = lookfor;
} else {
name = ucnv_getAvailableName(i);
}
/* Get all the aliases associated to the name. */
err = U_ZERO_ERROR;
num_aliases = ucnv_countAliases(name, &err);
if (U_FAILURE(err)) {
printf("%s", name);
UnicodeString str(name, "");
putchar('\t');
u_wmsg(stderr, "cantGetAliases", str.getTerminatedBuffer(),
u_wmsg_errorName(err));
return -1;
} else {
uint16_t a, s, t;
/* Write all the aliases and their tags. */
for (a = 0; a < num_aliases; ++a) {
const char *alias = ucnv_getAlias(name, a, &err);
if (U_FAILURE(err)) {
UnicodeString str(name, "");
putchar('\t');
u_wmsg(stderr, "cantGetAliases", str.getTerminatedBuffer(),
u_wmsg_errorName(err));
return -1;
}
/* Print the current alias so that it looks right. */
printf("%s%s%s", (canon ? (a == 0? "" : "\t" ) : "") ,
alias,
(canon ? "" : " "));
/* Look (slowly, linear searching) for a tag. */
if (canon) {
/* -1 to skip the last standard */
for (s = t = 0; s < num_stds-1; ++s) {
UEnumeration *nameEnum = ucnv_openStandardNames(name, stds[s], &err);
if (U_SUCCESS(err)) {
/* List the standard tags */
const char *standardName;
UBool isFirst = TRUE;
UErrorCode enumError = U_ZERO_ERROR;
while ((standardName = uenum_next(nameEnum, NULL, &enumError))) {
/* See if this alias is supported by this standard. */
if (!strcmp(standardName, alias)) {
if (!t) {
printf(" {");
t = 1;
}
/* Print a * after the default standard name */
printf(" %s%s", stds[s], (isFirst ? "*" : ""));
}
isFirst = FALSE;
}
}
}
if (t) {
printf(" }");
}
}
/* Terminate this entry. */
if (canon) {
puts("");
}
/* Move on. */
}
/* Terminate this entry. */
if (!canon) {
puts("");
}
}
}
/* Free temporary data. */
uprv_free(stds);
/* Success. */
return 0;
}
/* Print all available transliterators. If canon is non zero, print
one transliterator per line. */
static int printTransliterators(UBool canon)
{
#if UCONFIG_NO_TRANSLITERATION
printf("no transliterators available because of UCONFIG_NO_TRANSLITERATION, see uconfig.h\n");
return 1;
#else
int32_t numtrans = utrans_countAvailableIDs(), i;
int buflen = 512;
char *buf = (char *) uprv_malloc(buflen);
char staticbuf[512];
char sepchar = canon ? '\n' : ' ';
if (!buf) {
buf = staticbuf;
buflen = sizeof(staticbuf);
}
for (i = 0; i < numtrans; ++i) {
int32_t len = utrans_getAvailableID(i, buf, buflen);
if (len >= buflen - 1) {
if (buf != staticbuf) {
buflen <<= 1;
if (buflen < len) {
buflen = len + 64;
}
buf = (char *) uprv_realloc(buf, buflen);
if (!buf) {
buf = staticbuf;
buflen = sizeof(staticbuf);
}
}
utrans_getAvailableID(i, buf, buflen);
if (len >= buflen) {
uprv_strcpy(buf + buflen - 4, "..."); /* Truncate the name. */
}
}
printf("%s", buf);
if (i < numtrans - 1) {
putchar(sepchar);
}
}
/* Add a terminating newline if needed. */
if (sepchar != '\n') {
putchar('\n');
}
/* Free temporary data. */
if (buf != staticbuf) {
uprv_free(buf);
}
/* Success. */
return 0;
#endif
}
enum {
uSP = 0x20, // space
uCR = 0xd, // carriage return
uLF = 0xa, // line feed
uNL = 0x85, // newline
uLS = 0x2028, // line separator
uPS = 0x2029, // paragraph separator
uSig = 0xfeff // signature/BOM character
};
static inline int32_t
getChunkLimit(const UnicodeString &prev, const UnicodeString &s) {
// find one of
// CR, LF, CRLF, NL, LS, PS
// for paragraph ends (see UAX #13/Unicode 4)
// and include it in the chunk
// all of these characters are on the BMP
// do not include FF or VT in case they are part of a paragraph
// (important for bidi contexts)
static const UChar paraEnds[] = {
0xd, 0xa, 0x85, 0x2028, 0x2029
};
enum {
iCR, iLF, iNL, iLS, iPS, iCount
};
// first, see if there is a CRLF split between prev and s
if (prev.endsWith(paraEnds + iCR, 1)) {
if (s.startsWith(paraEnds + iLF, 1)) {
return 1; // split CRLF, include the LF
} else if (!s.isEmpty()) {
return 0; // complete the last chunk
} else {
return -1; // wait for actual further contents to arrive
}
}
const UChar *u = s.getBuffer(), *limit = u + s.length();
UChar c;
while (u < limit) {
c = *u++;
if (
((c < uSP) && (c == uCR || c == uLF)) ||
(c == uNL) ||
((c & uLS) == uLS)
) {
if (c == uCR) {
// check for CRLF
if (u == limit) {
return -1; // LF may be in the next chunk
} else if (*u == uLF) {
++u; // include the LF in this chunk
}
}
return (int32_t)(u - s.getBuffer());
}
}
return -1; // continue collecting the chunk
}
enum {
CNV_NO_FEFF, // cannot convert the U+FEFF Unicode signature character (BOM)
CNV_WITH_FEFF, // can convert the U+FEFF signature character
CNV_ADDS_FEFF // automatically adds/detects the U+FEFF signature character
};
static inline UChar
nibbleToHex(uint8_t n) {
n &= 0xf;
return
n <= 9 ?
(UChar)(0x30 + n) :
(UChar)((0x61 - 10) + n);
}
// check the converter's Unicode signature properties;
// the fromUnicode side of the converter must be in its initial state
// and will be reset again if it was used
static int32_t
cnvSigType(UConverter *cnv) {
UErrorCode err;
int32_t result;
// test if the output charset can convert U+FEFF
USet *set = uset_open(1, 0);
err = U_ZERO_ERROR;
ucnv_getUnicodeSet(cnv, set, UCNV_ROUNDTRIP_SET, &err);
if (U_SUCCESS(err) && uset_contains(set, uSig)) {
result = CNV_WITH_FEFF;
} else {
result = CNV_NO_FEFF; // an error occurred or U+FEFF cannot be converted
}
uset_close(set);
if (result == CNV_WITH_FEFF) {
// test if the output charset emits a signature anyway
const UChar a[1] = { 0x61 }; // "a"
const UChar *in;
char buffer[20];
char *out;
in = a;
out = buffer;
err = U_ZERO_ERROR;
ucnv_fromUnicode(cnv,
&out, buffer + sizeof(buffer),
&in, a + 1,
NULL, TRUE, &err);
ucnv_resetFromUnicode(cnv);
if (NULL != ucnv_detectUnicodeSignature(buffer, (int32_t)(out - buffer), NULL, &err) &&
U_SUCCESS(err)
) {
result = CNV_ADDS_FEFF;
}
}
return result;
}
class ConvertFile {
public:
ConvertFile() :
buf(NULL), outbuf(NULL), fromoffsets(NULL),
bufsz(0), signature(0) {}
void
setBufferSize(size_t bufferSize) {
bufsz = bufferSize;
buf = new char[2 * bufsz];
outbuf = buf + bufsz;
// +1 for an added U+FEFF in the intermediate Unicode buffer
fromoffsets = new int32_t[bufsz + 1];
}
~ConvertFile() {
delete [] buf;
delete [] fromoffsets;
}
UBool convertFile(const char *pname,
const char *fromcpage,
UConverterToUCallback toucallback,
const void *touctxt,
const char *tocpage,
UConverterFromUCallback fromucallback,
const void *fromuctxt,
UBool fallback,
const char *translit,
const char *infilestr,
FILE * outfile, int verbose);
private:
friend int main(int argc, char **argv);
char *buf, *outbuf;
int32_t *fromoffsets;
size_t bufsz;
int8_t signature; // add (1) or remove (-1) a U+FEFF Unicode signature character
};
// Convert a file from one encoding to another
UBool
ConvertFile::convertFile(const char *pname,
const char *fromcpage,
UConverterToUCallback toucallback,
const void *touctxt,
const char *tocpage,
UConverterFromUCallback fromucallback,
const void *fromuctxt,
UBool fallback,
const char *translit,
const char *infilestr,
FILE * outfile, int verbose)
{
FILE *infile;
UBool ret = TRUE;
UConverter *convfrom = 0;
UConverter *convto = 0;
UErrorCode err = U_ZERO_ERROR;
UBool flush;
const char *cbufp, *prevbufp;
char *bufp;
uint32_t infoffset = 0, outfoffset = 0; /* Where we are in the file, for error reporting. */
const UChar *unibuf, *unibufbp;
UChar *unibufp;
size_t rd, wr;
#if !UCONFIG_NO_TRANSLITERATION
Transliterator *t = 0; // Transliterator acting on Unicode data.
UnicodeString chunk; // One chunk of the text being collected for transformation.
#endif
UnicodeString u; // String to do the transliteration.
int32_t ulen;
// use conversion offsets for error messages
// unless a transliterator is used -
// a text transformation will reorder characters in unpredictable ways
UBool useOffsets = TRUE;
// Open the correct input file or connect to stdin for reading input
if (infilestr != 0 && strcmp(infilestr, "-")) {
infile = fopen(infilestr, "rb");
if (infile == 0) {
UnicodeString str1(infilestr, "");
str1.append((UChar32) 0);
UnicodeString str2(strerror(errno), "");
str2.append((UChar32) 0);
initMsg(pname);
u_wmsg(stderr, "cantOpenInputF", str1.getBuffer(), str2.getBuffer());
return FALSE;
}
} else {
infilestr = "-";
infile = stdin;
#if defined(WIN32) || defined(U_CYGWIN)
if (setmode(fileno(stdin), O_BINARY) == -1) {
initMsg(pname);
u_wmsg(stderr, "cantSetInBinMode");
return FALSE;
}
#endif
}
if (verbose) {
fprintf(stderr, "%s:\n", infilestr);
}
#if !UCONFIG_NO_TRANSLITERATION
// Create transliterator as needed.
if (translit != NULL && *translit) {
UParseError parse;
UnicodeString str(translit), pestr;
/* Create from rules or by ID as needed. */
parse.line = -1;
if (uprv_strchr(translit, ':') || uprv_strchr(translit, '>') || uprv_strchr(translit, '<') || uprv_strchr(translit, '>')) {
t = Transliterator::createFromRules("Uconv", str, UTRANS_FORWARD, parse, err);
} else {
t = Transliterator::createInstance(translit, UTRANS_FORWARD, err);
}
if (U_FAILURE(err)) {
str.append((UChar32) 0);
initMsg(pname);
if (parse.line >= 0) {
UChar linebuf[20], offsetbuf[20];
uprv_itou(linebuf, 20, parse.line, 10, 0);
uprv_itou(offsetbuf, 20, parse.offset, 10, 0);
u_wmsg(stderr, "cantCreateTranslitParseErr", str.getTerminatedBuffer(),
u_wmsg_errorName(err), linebuf, offsetbuf);
} else {
u_wmsg(stderr, "cantCreateTranslit", str.getTerminatedBuffer(),
u_wmsg_errorName(err));
}
if (t) {
delete t;
t = 0;
}
goto error_exit;
}
useOffsets = FALSE;
}
#endif
// Create codepage converter. If the codepage or its aliases weren't
// available, it returns NULL and a failure code. We also set the
// callbacks, and return errors in the same way.
convfrom = ucnv_open(fromcpage, &err);
if (U_FAILURE(err)) {
UnicodeString str(fromcpage, "");
initMsg(pname);
u_wmsg(stderr, "cantOpenFromCodeset", str.getTerminatedBuffer(),
u_wmsg_errorName(err));
goto error_exit;
}
ucnv_setToUCallBack(convfrom, toucallback, touctxt, 0, 0, &err);
if (U_FAILURE(err)) {
initMsg(pname);
u_wmsg(stderr, "cantSetCallback", u_wmsg_errorName(err));
goto error_exit;
}
convto = ucnv_open(tocpage, &err);
if (U_FAILURE(err)) {
UnicodeString str(tocpage, "");
initMsg(pname);
u_wmsg(stderr, "cantOpenToCodeset", str.getTerminatedBuffer(),
u_wmsg_errorName(err));
goto error_exit;
}
ucnv_setFromUCallBack(convto, fromucallback, fromuctxt, 0, 0, &err);
if (U_FAILURE(err)) {
initMsg(pname);
u_wmsg(stderr, "cantSetCallback", u_wmsg_errorName(err));
goto error_exit;
}
ucnv_setFallback(convto, fallback);
UBool willexit, fromSawEndOfBytes, toSawEndOfUnicode;
int8_t sig;
// OK, we can convert now.
sig = signature;
rd = 0;
do {
willexit = FALSE;
// input file offset at the beginning of the next buffer
infoffset += rd;
rd = fread(buf, 1, bufsz, infile);
if (ferror(infile) != 0) {
UnicodeString str(strerror(errno));
initMsg(pname);
u_wmsg(stderr, "cantRead", str.getTerminatedBuffer());
goto error_exit;
}
// Convert the read buffer into the new encoding via Unicode.
// After the call 'unibufp' will be placed behind the last
// character that was converted in the 'unibuf'.
// Also the 'cbufp' is positioned behind the last converted
// character.
// At the last conversion in the file, flush should be set to
// true so that we get all characters converted.
//
// The converter must be flushed at the end of conversion so
// that characters on hold also will be written.
cbufp = buf;
flush = (UBool)(rd != bufsz);
// convert until the input is consumed
do {
// remember the start of the current byte-to-Unicode conversion
prevbufp = cbufp;
unibuf = unibufp = u.getBuffer((int32_t)bufsz);
// Use bufsz instead of u.getCapacity() for the targetLimit
// so that we don't overflow fromoffsets[].
ucnv_toUnicode(convfrom, &unibufp, unibuf + bufsz, &cbufp,
buf + rd, useOffsets ? fromoffsets : NULL, flush, &err);
ulen = (int32_t)(unibufp - unibuf);
u.releaseBuffer(ulen);
// fromSawEndOfBytes indicates that ucnv_toUnicode() is done
// converting all of the input bytes.
// It works like this because ucnv_toUnicode() returns only under the
// following conditions:
// - an error occurred during conversion (an error code is set)
// - the target buffer is filled (the error code indicates an overflow)
// - the source is consumed
// That is, if the error code does not indicate a failure,
// not even an overflow, then the source must be consumed entirely.
fromSawEndOfBytes = (UBool)U_SUCCESS(err);
if (err == U_BUFFER_OVERFLOW_ERROR) {
err = U_ZERO_ERROR;
} else if (U_FAILURE(err)) {
char pos[32], errorBytes[32];
int8_t i, length, errorLength;
UErrorCode localError = U_ZERO_ERROR;
errorLength = (int8_t)sizeof(errorBytes);
ucnv_getInvalidChars(convfrom, errorBytes, &errorLength, &localError);
if (U_FAILURE(localError) || errorLength == 0) {
errorLength = 1;
}
// print the input file offset of the start of the error bytes:
// input file offset of the current byte buffer +
// length of the just consumed bytes -
// length of the error bytes
length =
(int8_t)sprintf(pos, "%d",
(int)(infoffset + (cbufp - buf) - errorLength));
// output the bytes that caused the error
UnicodeString str;
for (i = 0; i < errorLength; ++i) {
if (i > 0) {
str.append((UChar)uSP);
}
str.append(nibbleToHex((uint8_t)errorBytes[i] >> 4));
str.append(nibbleToHex((uint8_t)errorBytes[i]));
}
initMsg(pname);
u_wmsg(stderr, "problemCvtToU",
UnicodeString(pos, length, "").getTerminatedBuffer(),
str.getTerminatedBuffer(),
u_wmsg_errorName(err));
willexit = TRUE;
err = U_ZERO_ERROR; /* reset the error for the rest of the conversion. */
}
// Replaced a check for whether the input was consumed by
// looping until it is; message key "premEndInput" now obsolete.
if (ulen == 0) {
continue;
}
// remove a U+FEFF Unicode signature character if requested
if (sig < 0) {
if (u.charAt(0) == uSig) {
u.remove(0, 1);
// account for the removed UChar and offset
--ulen;
if (useOffsets) {
// remove an offset from fromoffsets[] as well
// to keep the array parallel with the UChars
memmove(fromoffsets, fromoffsets + 1, ulen * 4);
}
}
sig = 0;
}
#if !UCONFIG_NO_TRANSLITERATION
// Transliterate/transform if needed.
// For transformation, we use chunking code -
// collect Unicode input until, for example, an end-of-line,
// then transform and output-convert that and continue collecting.
// This makes the transformation result independent of the buffer size
// while avoiding the slower keyboard mode.
// The end-of-chunk characters are completely included in the
// transformed string in case they are to be transformed themselves.
if (t != NULL) {
UnicodeString out;
int32_t chunkLimit;
do {
chunkLimit = getChunkLimit(chunk, u);
if (chunkLimit < 0 && flush && fromSawEndOfBytes) {
// use all of the rest at the end of the text
chunkLimit = u.length();
}
if (chunkLimit >= 0) {
// complete the chunk and transform it
chunk.append(u, 0, chunkLimit);
u.remove(0, chunkLimit);
t->transliterate(chunk);
// append the transformation result to the result and empty the chunk
out.append(chunk);
chunk.remove();
} else {
// continue collecting the chunk
chunk.append(u);
break;
}
} while (!u.isEmpty());
u = out;
ulen = u.length();
}
#endif
// add a U+FEFF Unicode signature character if requested
// and possible/necessary
if (sig > 0) {
if (u.charAt(0) != uSig && cnvSigType(convto) == CNV_WITH_FEFF) {
u.insert(0, (UChar)uSig);
if (useOffsets) {
// insert a pseudo-offset into fromoffsets[] as well
// to keep the array parallel with the UChars
memmove(fromoffsets + 1, fromoffsets, ulen * 4);
fromoffsets[0] = -1;
}
// account for the additional UChar and offset
++ulen;
}
sig = 0;
}
// Convert the Unicode buffer into the destination codepage
// Again 'bufp' will be placed behind the last converted character
// And 'unibufp' will be placed behind the last converted unicode character
// At the last conversion flush should be set to true to ensure that
// all characters left get converted
unibuf = unibufbp = u.getBuffer();
do {
bufp = outbuf;
// Use fromSawEndOfBytes in addition to the flush flag -
// it indicates whether the intermediate Unicode string
// contains the very last UChars for the very last input bytes.
ucnv_fromUnicode(convto, &bufp, outbuf + bufsz,
&unibufbp,
unibuf + ulen,
NULL, (UBool)(flush && fromSawEndOfBytes), &err);
// toSawEndOfUnicode indicates that ucnv_fromUnicode() is done
// converting all of the intermediate UChars.
// See comment for fromSawEndOfBytes.
toSawEndOfUnicode = (UBool)U_SUCCESS(err);
if (err == U_BUFFER_OVERFLOW_ERROR) {
err = U_ZERO_ERROR;
} else if (U_FAILURE(err)) {
UChar errorUChars[4];
const char *errtag;
char pos[32];
UChar32 c;
int8_t i, length, errorLength;
UErrorCode localError = U_ZERO_ERROR;
errorLength = (int8_t)LENGTHOF(errorUChars);
ucnv_getInvalidUChars(convto, errorUChars, &errorLength, &localError);
if (U_FAILURE(localError) || errorLength == 0) {
// need at least 1 so that we don't access beyond the length of fromoffsets[]
errorLength = 1;
}
int32_t ferroffset;
if (useOffsets) {
// Unicode buffer offset of the start of the error UChars
ferroffset = (int32_t)((unibufbp - unibuf) - errorLength);
if (ferroffset < 0) {
// approximation - the character started in the previous Unicode buffer
ferroffset = 0;
}
// get the corresponding byte offset out of fromoffsets[]
// go back if the offset is not known for some of the UChars
int32_t fromoffset;
do {
fromoffset = fromoffsets[ferroffset];
} while (fromoffset < 0 && --ferroffset >= 0);
// total input file offset =
// input file offset of the current byte buffer +
// byte buffer offset of where the current Unicode buffer is converted from +
// fromoffsets[Unicode offset]
ferroffset = infoffset + (prevbufp - buf) + fromoffset;
errtag = "problemCvtFromU";
} else {
// Do not use fromoffsets if (t != NULL) because the Unicode text may
// be different from what the offsets refer to.
// output file offset
ferroffset = (int32_t)(outfoffset + (bufp - outbuf));
errtag = "problemCvtFromUOut";
}
length = (int8_t)sprintf(pos, "%u", ferroffset);
// output the code points that caused the error
UnicodeString str;
for (i = 0; i < errorLength;) {
if (i > 0) {
str.append((UChar)uSP);
}
U16_NEXT(errorUChars, i, errorLength, c);
if (c >= 0x100000) {
str.append(nibbleToHex((uint8_t)(c >> 20)));
}
if (c >= 0x10000) {
str.append(nibbleToHex((uint8_t)(c >> 16)));
}
str.append(nibbleToHex((uint8_t)(c >> 12)));
str.append(nibbleToHex((uint8_t)(c >> 8)));
str.append(nibbleToHex((uint8_t)(c >> 4)));
str.append(nibbleToHex((uint8_t)c));
}
initMsg(pname);
u_wmsg(stderr, errtag,
UnicodeString(pos, length, "").getTerminatedBuffer(),
str.getTerminatedBuffer(),
u_wmsg_errorName(err));
u_wmsg(stderr, "errorUnicode", str.getTerminatedBuffer());
willexit = TRUE;
err = U_ZERO_ERROR; /* reset the error for the rest of the conversion. */
}
// Replaced a check for whether the intermediate Unicode characters were all consumed by
// looping until they are; message key "premEnd" now obsolete.
// Finally, write the converted buffer to the output file
size_t outlen = (size_t) (bufp - outbuf);
outfoffset += (int32_t)(wr = fwrite(outbuf, 1, outlen, outfile));
if (wr != outlen) {
UnicodeString str(strerror(errno));
initMsg(pname);
u_wmsg(stderr, "cantWrite", str.getTerminatedBuffer());
willexit = TRUE;
}
if (willexit) {
goto error_exit;
}
} while (!toSawEndOfUnicode);
} while (!fromSawEndOfBytes);
} while (!flush); // Stop when we have flushed the
// converters (this means that it's
// the end of output)
goto normal_exit;
error_exit:
ret = FALSE;
normal_exit:
// Cleanup.
ucnv_close(convfrom);
ucnv_close(convto);
#if !UCONFIG_NO_TRANSLITERATION
delete t;
#endif
if (infile != stdin) {
fclose(infile);
}
return ret;
}
static void usage(const char *pname, int ecode) {
const UChar *msg;
int32_t msgLen;
UErrorCode err = U_ZERO_ERROR;
FILE *fp = ecode ? stderr : stdout;
int res;
initMsg(pname);
msg =
ures_getStringByKey(gBundle, ecode ? "lcUsageWord" : "ucUsageWord",
&msgLen, &err);
UnicodeString upname(pname, (int32_t)(uprv_strlen(pname) + 1));
UnicodeString mname(msg, msgLen + 1);
res = u_wmsg(fp, "usage", mname.getBuffer(), upname.getBuffer());
if (!ecode) {
if (!res) {
fputc('\n', fp);
}
if (!u_wmsg(fp, "help")) {
/* Now dump callbacks and finish. */
int i, count =
sizeof(transcode_callbacks) / sizeof(*transcode_callbacks);
for (i = 0; i < count; ++i) {
fprintf(fp, " %s", transcode_callbacks[i].name);
}
fputc('\n', fp);
}
}
exit(ecode);
}
extern int
main(int argc, char **argv)
{
FILE *outfile;
int ret = 0;
size_t bufsz = DEFAULT_BUFSZ;
const char *fromcpage = 0;
const char *tocpage = 0;
const char *translit = 0;
const char *outfilestr = 0;
UBool fallback = FALSE;
UConverterFromUCallback fromucallback = UCNV_FROM_U_CALLBACK_STOP;
const void *fromuctxt = 0;
UConverterToUCallback toucallback = UCNV_TO_U_CALLBACK_STOP;
const void *touctxt = 0;
char **iter, **remainArgv, **remainArgvLimit;
char **end = argv + argc;
const char *pname;
UBool printConvs = FALSE, printCanon = FALSE, printTranslits = FALSE;
const char *printName = 0;
UBool verbose = FALSE;
UErrorCode status = U_ZERO_ERROR;
ConvertFile cf;
/* Initialize ICU */
u_init(&status);
if (U_FAILURE(status)) {
fprintf(stderr, "%s: can not initialize ICU. status = %s\n",
argv[0], u_errorName(status));
exit(1);
}
// Get and prettify pname.
pname = uprv_strrchr(*argv, U_FILE_SEP_CHAR);
#ifdef WIN32
if (!pname) {
pname = uprv_strrchr(*argv, '/');
}
#endif
if (!pname) {
pname = *argv;
} else {
++pname;
}
// First, get the arguments from command-line
// to know the codepages to convert between
remainArgv = remainArgvLimit = argv + 1;
for (iter = argv + 1; iter != end; iter++) {
// Check for from charset
if (strcmp("-f", *iter) == 0 || !strcmp("--from-code", *iter)) {
iter++;
if (iter != end)
fromcpage = *iter;
else
usage(pname, 1);
} else if (strcmp("-t", *iter) == 0 || !strcmp("--to-code", *iter)) {
iter++;
if (iter != end)
tocpage = *iter;
else
usage(pname, 1);
} else if (strcmp("-x", *iter) == 0) {
iter++;
if (iter != end)
translit = *iter;
else
usage(pname, 1);
} else if (!strcmp("--fallback", *iter)) {
fallback = TRUE;
} else if (!strcmp("--no-fallback", *iter)) {
fallback = FALSE;
} else if (strcmp("-b", *iter) == 0 || !strcmp("--block-size", *iter)) {
iter++;
if (iter != end) {
bufsz = atoi(*iter);
if ((int) bufsz <= 0) {
initMsg(pname);
UnicodeString str(*iter);
initMsg(pname);
u_wmsg(stderr, "badBlockSize", str.getTerminatedBuffer());
return 3;
}
} else {
usage(pname, 1);
}
} else if (strcmp("-l", *iter) == 0 || !strcmp("--list", *iter)) {
if (printTranslits) {
usage(pname, 1);
}
printConvs = TRUE;
} else if (strcmp("--default-code", *iter) == 0) {
if (printTranslits) {
usage(pname, 1);
}
printName = ucnv_getDefaultName();
} else if (strcmp("--list-code", *iter) == 0) {
if (printTranslits) {
usage(pname, 1);
}
iter++;
if (iter != end) {
UErrorCode e = U_ZERO_ERROR;
printName = ucnv_getAlias(*iter, 0, &e);
if (U_FAILURE(e) || !printName) {
UnicodeString str(*iter);
initMsg(pname);
u_wmsg(stderr, "noSuchCodeset", str.getTerminatedBuffer());
return 2;
}
} else
usage(pname, 1);
} else if (strcmp("--canon", *iter) == 0) {
printCanon = TRUE;
} else if (strcmp("-L", *iter) == 0
|| !strcmp("--list-transliterators", *iter)) {
if (printConvs) {
usage(pname, 1);
}
printTranslits = TRUE;
} else if (strcmp("-h", *iter) == 0 || !strcmp("-?", *iter)
|| !strcmp("--help", *iter)) {
usage(pname, 0);
} else if (!strcmp("-c", *iter)) {
fromucallback = UCNV_FROM_U_CALLBACK_SKIP;
} else if (!strcmp("--to-callback", *iter)) {
iter++;
if (iter != end) {
const struct callback_ent *cbe = findCallback(*iter);
if (cbe) {
fromucallback = cbe->fromu;
fromuctxt = cbe->fromuctxt;
} else {
UnicodeString str(*iter);
initMsg(pname);
u_wmsg(stderr, "unknownCallback", str.getTerminatedBuffer());
return 4;
}
} else {
usage(pname, 1);
}
} else if (!strcmp("--from-callback", *iter)) {
iter++;
if (iter != end) {
const struct callback_ent *cbe = findCallback(*iter);
if (cbe) {
toucallback = cbe->tou;
touctxt = cbe->touctxt;
} else {
UnicodeString str(*iter);
initMsg(pname);
u_wmsg(stderr, "unknownCallback", str.getTerminatedBuffer());
return 4;
}
} else {
usage(pname, 1);
}
} else if (!strcmp("-i", *iter)) {
toucallback = UCNV_TO_U_CALLBACK_SKIP;
} else if (!strcmp("--callback", *iter)) {
iter++;
if (iter != end) {
const struct callback_ent *cbe = findCallback(*iter);
if (cbe) {
fromucallback = cbe->fromu;
fromuctxt = cbe->fromuctxt;
toucallback = cbe->tou;
touctxt = cbe->touctxt;
} else {
UnicodeString str(*iter);
initMsg(pname);
u_wmsg(stderr, "unknownCallback", str.getTerminatedBuffer());
return 4;
}
} else {
usage(pname, 1);
}
} else if (!strcmp("-s", *iter) || !strcmp("--silent", *iter)) {
verbose = FALSE;
} else if (!strcmp("-v", *iter) || !strcmp("--verbose", *iter)) {
verbose = TRUE;
} else if (!strcmp("-V", *iter) || !strcmp("--version", *iter)) {
printf("%s v2.1 ICU " U_ICU_VERSION "\n", pname);
return 0;
} else if (!strcmp("-o", *iter) || !strcmp("--output", *iter)) {
++iter;
if (iter != end && !outfilestr) {
outfilestr = *iter;
} else {
usage(pname, 1);
}
} else if (0 == strcmp("--add-signature", *iter)) {
cf.signature = 1;
} else if (0 == strcmp("--remove-signature", *iter)) {
cf.signature = -1;
} else if (**iter == '-' && (*iter)[1]) {
usage(pname, 1);
} else {
// move a non-option up in argv[]
*remainArgvLimit++ = *iter;
}
}
if (printConvs || printName) {
return printConverters(pname, printName, printCanon) ? 2 : 0;
} else if (printTranslits) {
return printTransliterators(printCanon) ? 3 : 0;
}
if (!fromcpage || !uprv_strcmp(fromcpage, "-")) {
fromcpage = ucnv_getDefaultName();
}
if (!tocpage || !uprv_strcmp(tocpage, "-")) {
tocpage = ucnv_getDefaultName();
}
// Open the correct output file or connect to stdout for reading input
if (outfilestr != 0 && strcmp(outfilestr, "-")) {
outfile = fopen(outfilestr, "wb");
if (outfile == 0) {
UnicodeString str1(outfilestr, "");
UnicodeString str2(strerror(errno), "");
initMsg(pname);
u_wmsg(stderr, "cantCreateOutputF",
str1.getBuffer(), str2.getBuffer());
return 1;
}
} else {
outfilestr = "-";
outfile = stdout;
#if defined(WIN32) || defined(U_CYGWIN)
if (setmode(fileno(outfile), O_BINARY) == -1) {
u_wmsg(stderr, "cantSetOutBinMode");
exit(-1);
}
#endif
}
/* Loop again on the arguments to find all the input files, and
convert them. */
cf.setBufferSize(bufsz);
if(remainArgv < remainArgvLimit) {
for (iter = remainArgv; iter != remainArgvLimit; iter++) {
if (!cf.convertFile(
pname, fromcpage, toucallback, touctxt, tocpage,
fromucallback, fromuctxt, fallback, translit, *iter,
outfile, verbose)
) {
goto error_exit;
}
}
} else {
if (!cf.convertFile(
pname, fromcpage, toucallback, touctxt, tocpage,
fromucallback, fromuctxt, fallback, translit, 0,
outfile, verbose)
) {
goto error_exit;
}
}
goto normal_exit;
error_exit:
ret = 1;
normal_exit:
if (outfile != stdout) {
fclose(outfile);
}
return ret;
}
/*
* Hey, Emacs, please set the following:
*
* Local Variables:
* indent-tabs-mode: nil
* End:
*
*/