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/* a30d2613dcfdef81475a9d1a349134d2d42722172fdaa7d5bb12ed2aa74b9596 (2.4.6+)
__ __ _
___\ \/ /_ __ __ _| |_
/ _ \\ /| '_ \ / _` | __|
| __// \| |_) | (_| | |_
\___/_/\_\ .__/ \__,_|\__|
|_| XML parser
Copyright (c) 1997-2000 Thai Open Source Software Center Ltd
Copyright (c) 2000 Clark Cooper <coopercc@users.sourceforge.net>
Copyright (c) 2000-2006 Fred L. Drake, Jr. <fdrake@users.sourceforge.net>
Copyright (c) 2001-2002 Greg Stein <gstein@users.sourceforge.net>
Copyright (c) 2002-2016 Karl Waclawek <karl@waclawek.net>
Copyright (c) 2005-2009 Steven Solie <steven@solie.ca>
Copyright (c) 2016 Eric Rahm <erahm@mozilla.com>
Copyright (c) 2016-2022 Sebastian Pipping <sebastian@pipping.org>
Copyright (c) 2016 Gaurav <g.gupta@samsung.com>
Copyright (c) 2016 Thomas Beutlich <tc@tbeu.de>
Copyright (c) 2016 Gustavo Grieco <gustavo.grieco@imag.fr>
Copyright (c) 2016 Pascal Cuoq <cuoq@trust-in-soft.com>
Copyright (c) 2016 Ed Schouten <ed@nuxi.nl>
Copyright (c) 2017-2018 Rhodri James <rhodri@wildebeest.org.uk>
Copyright (c) 2017 Václav Slavík <vaclav@slavik.io>
Copyright (c) 2017 Viktor Szakats <commit@vsz.me>
Copyright (c) 2017 Chanho Park <chanho61.park@samsung.com>
Copyright (c) 2017 Rolf Eike Beer <eike@sf-mail.de>
Copyright (c) 2017 Hans Wennborg <hans@chromium.org>
Copyright (c) 2018 Anton Maklakov <antmak.pub@gmail.com>
Copyright (c) 2018 Benjamin Peterson <benjamin@python.org>
Copyright (c) 2018 Marco Maggi <marco.maggi-ipsu@poste.it>
Copyright (c) 2018 Mariusz Zaborski <oshogbo@vexillium.org>
Copyright (c) 2019 David Loffredo <loffredo@steptools.com>
Copyright (c) 2019-2020 Ben Wagner <bungeman@chromium.org>
Copyright (c) 2019 Vadim Zeitlin <vadim@zeitlins.org>
Copyright (c) 2021 Dong-hee Na <donghee.na@python.org>
Copyright (c) 2022 Samanta Navarro <ferivoz@riseup.net>
Licensed under the MIT license:
Permission is hereby granted, free of charge, to any person obtaining
a copy of this software and associated documentation files (the
"Software"), to deal in the Software without restriction, including
without limitation the rights to use, copy, modify, merge, publish,
distribute, sublicense, and/or sell copies of the Software, and to permit
persons to whom the Software is furnished to do so, subject to the
following conditions:
The above copyright notice and this permission notice shall be included
in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN
NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM,
DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR
OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE
USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#define XML_BUILDING_EXPAT 1
#include <expat_config.h>
#if ! defined(_GNU_SOURCE)
# define _GNU_SOURCE 1 /* syscall prototype */
#endif
#ifdef _WIN32
/* force stdlib to define rand_s() */
# if ! defined(_CRT_RAND_S)
# define _CRT_RAND_S
# endif
#endif
#include <stddef.h>
#include <string.h> /* memset(), memcpy() */
#include <assert.h>
#include <limits.h> /* UINT_MAX */
#include <stdio.h> /* fprintf */
#include <stdlib.h> /* getenv, rand_s */
#include <stdint.h> /* uintptr_t */
#include <math.h> /* isnan */
#ifdef _WIN32
# define getpid GetCurrentProcessId
#else
# include <sys/time.h> /* gettimeofday() */
# include <sys/types.h> /* getpid() */
# include <unistd.h> /* getpid() */
# include <fcntl.h> /* O_RDONLY */
# include <errno.h>
#endif
#ifdef _WIN32
# include "winconfig.h"
#endif
#include "ascii.h"
#include "expat.h"
#include "siphash.h"
#if defined(HAVE_GETRANDOM) || defined(HAVE_SYSCALL_GETRANDOM)
# if defined(HAVE_GETRANDOM)
# include <sys/random.h> /* getrandom */
# else
# include <unistd.h> /* syscall */
# include <sys/syscall.h> /* SYS_getrandom */
# endif
# if ! defined(GRND_NONBLOCK)
# define GRND_NONBLOCK 0x0001
# endif /* defined(GRND_NONBLOCK) */
#endif /* defined(HAVE_GETRANDOM) || defined(HAVE_SYSCALL_GETRANDOM) */
#if defined(HAVE_LIBBSD) \
&& (defined(HAVE_ARC4RANDOM_BUF) || defined(HAVE_ARC4RANDOM))
# include <bsd/stdlib.h>
#endif
#if defined(_WIN32) && ! defined(LOAD_LIBRARY_SEARCH_SYSTEM32)
# define LOAD_LIBRARY_SEARCH_SYSTEM32 0x00000800
#endif
#if ! defined(HAVE_GETRANDOM) && ! defined(HAVE_SYSCALL_GETRANDOM) \
&& ! defined(HAVE_ARC4RANDOM_BUF) && ! defined(HAVE_ARC4RANDOM) \
&& ! defined(XML_DEV_URANDOM) && ! defined(_WIN32) \
&& ! defined(XML_POOR_ENTROPY)
# error You do not have support for any sources of high quality entropy \
enabled. For end user security, that is probably not what you want. \
\
Your options include: \
* Linux >=3.17 + glibc >=2.25 (getrandom): HAVE_GETRANDOM, \
* Linux >=3.17 + glibc (including <2.25) (syscall SYS_getrandom): HAVE_SYSCALL_GETRANDOM, \
* BSD / macOS >=10.7 (arc4random_buf): HAVE_ARC4RANDOM_BUF, \
* BSD / macOS (including <10.7) (arc4random): HAVE_ARC4RANDOM, \
* libbsd (arc4random_buf): HAVE_ARC4RANDOM_BUF + HAVE_LIBBSD, \
* libbsd (arc4random): HAVE_ARC4RANDOM + HAVE_LIBBSD, \
* Linux (including <3.17) / BSD / macOS (including <10.7) (/dev/urandom): XML_DEV_URANDOM, \
* Windows >=Vista (rand_s): _WIN32. \
\
If insist on not using any of these, bypass this error by defining \
XML_POOR_ENTROPY; you have been warned. \
\
If you have reasons to patch this detection code away or need changes \
to the build system, please open a bug. Thank you!
#endif
#ifdef XML_UNICODE
# define XML_ENCODE_MAX XML_UTF16_ENCODE_MAX
# define XmlConvert XmlUtf16Convert
# define XmlGetInternalEncoding XmlGetUtf16InternalEncoding
# define XmlGetInternalEncodingNS XmlGetUtf16InternalEncodingNS
# define XmlEncode XmlUtf16Encode
# define MUST_CONVERT(enc, s) (! (enc)->isUtf16 || (((uintptr_t)(s)) & 1))
typedef unsigned short ICHAR;
#else
# define XML_ENCODE_MAX XML_UTF8_ENCODE_MAX
# define XmlConvert XmlUtf8Convert
# define XmlGetInternalEncoding XmlGetUtf8InternalEncoding
# define XmlGetInternalEncodingNS XmlGetUtf8InternalEncodingNS
# define XmlEncode XmlUtf8Encode
# define MUST_CONVERT(enc, s) (! (enc)->isUtf8)
typedef char ICHAR;
#endif
#ifndef XML_NS
# define XmlInitEncodingNS XmlInitEncoding
# define XmlInitUnknownEncodingNS XmlInitUnknownEncoding
# undef XmlGetInternalEncodingNS
# define XmlGetInternalEncodingNS XmlGetInternalEncoding
# define XmlParseXmlDeclNS XmlParseXmlDecl
#endif
#ifdef XML_UNICODE
# ifdef XML_UNICODE_WCHAR_T
# define XML_T(x) (const wchar_t) x
# define XML_L(x) L##x
# else
# define XML_T(x) (const unsigned short)x
# define XML_L(x) x
# endif
#else
# define XML_T(x) x
# define XML_L(x) x
#endif
/* Round up n to be a multiple of sz, where sz is a power of 2. */
#define ROUND_UP(n, sz) (((n) + ((sz)-1)) & ~((sz)-1))
/* Do safe (NULL-aware) pointer arithmetic */
#define EXPAT_SAFE_PTR_DIFF(p, q) (((p) && (q)) ? ((p) - (q)) : 0)
#include "internal.h"
#include "xmltok.h"
#include "xmlrole.h"
typedef const XML_Char *KEY;
typedef struct {
KEY name;
} NAMED;
typedef struct {
NAMED **v;
unsigned char power;
size_t size;
size_t used;
const XML_Memory_Handling_Suite *mem;
} HASH_TABLE;
static size_t keylen(KEY s);
static void copy_salt_to_sipkey(XML_Parser parser, struct sipkey *key);
/* For probing (after a collision) we need a step size relative prime
to the hash table size, which is a power of 2. We use double-hashing,
since we can calculate a second hash value cheaply by taking those bits
of the first hash value that were discarded (masked out) when the table
index was calculated: index = hash & mask, where mask = table->size - 1.
We limit the maximum step size to table->size / 4 (mask >> 2) and make
it odd, since odd numbers are always relative prime to a power of 2.
*/
#define SECOND_HASH(hash, mask, power) \
((((hash) & ~(mask)) >> ((power)-1)) & ((mask) >> 2))
#define PROBE_STEP(hash, mask, power) \
((unsigned char)((SECOND_HASH(hash, mask, power)) | 1))
typedef struct {
NAMED **p;
NAMED **end;
} HASH_TABLE_ITER;
#define INIT_TAG_BUF_SIZE 32 /* must be a multiple of sizeof(XML_Char) */
#define INIT_DATA_BUF_SIZE 1024
#define INIT_ATTS_SIZE 16
#define INIT_ATTS_VERSION 0xFFFFFFFF
#define INIT_BLOCK_SIZE 1024
#define INIT_BUFFER_SIZE 1024
#define EXPAND_SPARE 24
typedef struct binding {
struct prefix *prefix;
struct binding *nextTagBinding;
struct binding *prevPrefixBinding;
const struct attribute_id *attId;
XML_Char *uri;
int uriLen;
int uriAlloc;
} BINDING;
typedef struct prefix {
const XML_Char *name;
BINDING *binding;
} PREFIX;
typedef struct {
const XML_Char *str;
const XML_Char *localPart;
const XML_Char *prefix;
int strLen;
int uriLen;
int prefixLen;
} TAG_NAME;
/* TAG represents an open element.
The name of the element is stored in both the document and API
encodings. The memory buffer 'buf' is a separately-allocated
memory area which stores the name. During the XML_Parse()/
XMLParseBuffer() when the element is open, the memory for the 'raw'
version of the name (in the document encoding) is shared with the
document buffer. If the element is open across calls to
XML_Parse()/XML_ParseBuffer(), the buffer is re-allocated to
contain the 'raw' name as well.
A parser re-uses these structures, maintaining a list of allocated
TAG objects in a free list.
*/
typedef struct tag {
struct tag *parent; /* parent of this element */
const char *rawName; /* tagName in the original encoding */
int rawNameLength;
TAG_NAME name; /* tagName in the API encoding */
char *buf; /* buffer for name components */
char *bufEnd; /* end of the buffer */
BINDING *bindings;
} TAG;
typedef struct {
const XML_Char *name;
const XML_Char *textPtr;
int textLen; /* length in XML_Chars */
int processed; /* # of processed bytes - when suspended */
const XML_Char *systemId;
const XML_Char *base;
const XML_Char *publicId;
const XML_Char *notation;
XML_Bool open;
XML_Bool is_param;
XML_Bool is_internal; /* true if declared in internal subset outside PE */
} ENTITY;
typedef struct {
enum XML_Content_Type type;
enum XML_Content_Quant quant;
const XML_Char *name;
int firstchild;
int lastchild;
int childcnt;
int nextsib;
} CONTENT_SCAFFOLD;
#define INIT_SCAFFOLD_ELEMENTS 32
typedef struct block {
struct block *next;
int size;
XML_Char s[1];
} BLOCK;
typedef struct {
BLOCK *blocks;
BLOCK *freeBlocks;
const XML_Char *end;
XML_Char *ptr;
XML_Char *start;
const XML_Memory_Handling_Suite *mem;
} STRING_POOL;
/* The XML_Char before the name is used to determine whether
an attribute has been specified. */
typedef struct attribute_id {
XML_Char *name;
PREFIX *prefix;
XML_Bool maybeTokenized;
XML_Bool xmlns;
} ATTRIBUTE_ID;
typedef struct {
const ATTRIBUTE_ID *id;
XML_Bool isCdata;
const XML_Char *value;
} DEFAULT_ATTRIBUTE;
typedef struct {
unsigned long version;
unsigned long hash;
const XML_Char *uriName;
} NS_ATT;
typedef struct {
const XML_Char *name;
PREFIX *prefix;
const ATTRIBUTE_ID *idAtt;
int nDefaultAtts;
int allocDefaultAtts;
DEFAULT_ATTRIBUTE *defaultAtts;
} ELEMENT_TYPE;
typedef struct {
HASH_TABLE generalEntities;
HASH_TABLE elementTypes;
HASH_TABLE attributeIds;
HASH_TABLE prefixes;
STRING_POOL pool;
STRING_POOL entityValuePool;
/* false once a parameter entity reference has been skipped */
XML_Bool keepProcessing;
/* true once an internal or external PE reference has been encountered;
this includes the reference to an external subset */
XML_Bool hasParamEntityRefs;
XML_Bool standalone;
#ifdef XML_DTD
/* indicates if external PE has been read */
XML_Bool paramEntityRead;
HASH_TABLE paramEntities;
#endif /* XML_DTD */
PREFIX defaultPrefix;
/* === scaffolding for building content model === */
XML_Bool in_eldecl;
CONTENT_SCAFFOLD *scaffold;
unsigned contentStringLen;
unsigned scaffSize;
unsigned scaffCount;
int scaffLevel;
int *scaffIndex;
} DTD;
typedef struct open_internal_entity {
const char *internalEventPtr;
const char *internalEventEndPtr;
struct open_internal_entity *next;
ENTITY *entity;
int startTagLevel;
XML_Bool betweenDecl; /* WFC: PE Between Declarations */
} OPEN_INTERNAL_ENTITY;
enum XML_Account {
XML_ACCOUNT_DIRECT, /* bytes directly passed to the Expat parser */
XML_ACCOUNT_ENTITY_EXPANSION, /* intermediate bytes produced during entity
expansion */
XML_ACCOUNT_NONE /* i.e. do not account, was accounted already */
};
#ifdef XML_DTD
typedef unsigned long long XmlBigCount;
typedef struct accounting {
XmlBigCount countBytesDirect;
XmlBigCount countBytesIndirect;
int debugLevel;
float maximumAmplificationFactor; // >=1.0
unsigned long long activationThresholdBytes;
} ACCOUNTING;
typedef struct entity_stats {
unsigned int countEverOpened;
unsigned int currentDepth;
unsigned int maximumDepthSeen;
int debugLevel;
} ENTITY_STATS;
#endif /* XML_DTD */
typedef enum XML_Error PTRCALL Processor(XML_Parser parser, const char *start,
const char *end, const char **endPtr);
static Processor prologProcessor;
static Processor prologInitProcessor;
static Processor contentProcessor;
static Processor cdataSectionProcessor;
#ifdef XML_DTD
static Processor ignoreSectionProcessor;
static Processor externalParEntProcessor;
static Processor externalParEntInitProcessor;
static Processor entityValueProcessor;
static Processor entityValueInitProcessor;
#endif /* XML_DTD */
static Processor epilogProcessor;
static Processor errorProcessor;
static Processor externalEntityInitProcessor;
static Processor externalEntityInitProcessor2;
static Processor externalEntityInitProcessor3;
static Processor externalEntityContentProcessor;
static Processor internalEntityProcessor;
static enum XML_Error handleUnknownEncoding(XML_Parser parser,
const XML_Char *encodingName);
static enum XML_Error processXmlDecl(XML_Parser parser, int isGeneralTextEntity,
const char *s, const char *next);
static enum XML_Error initializeEncoding(XML_Parser parser);
static enum XML_Error doProlog(XML_Parser parser, const ENCODING *enc,
const char *s, const char *end, int tok,
const char *next, const char **nextPtr,
XML_Bool haveMore, XML_Bool allowClosingDoctype,
enum XML_Account account);
static enum XML_Error processInternalEntity(XML_Parser parser, ENTITY *entity,
XML_Bool betweenDecl);
static enum XML_Error doContent(XML_Parser parser, int startTagLevel,
const ENCODING *enc, const char *start,
const char *end, const char **endPtr,
XML_Bool haveMore, enum XML_Account account);
static enum XML_Error doCdataSection(XML_Parser parser, const ENCODING *,
const char **startPtr, const char *end,
const char **nextPtr, XML_Bool haveMore,
enum XML_Account account);
#ifdef XML_DTD
static enum XML_Error doIgnoreSection(XML_Parser parser, const ENCODING *,
const char **startPtr, const char *end,
const char **nextPtr, XML_Bool haveMore);
#endif /* XML_DTD */
static void freeBindings(XML_Parser parser, BINDING *bindings);
static enum XML_Error storeAtts(XML_Parser parser, const ENCODING *,
const char *s, TAG_NAME *tagNamePtr,
BINDING **bindingsPtr,
enum XML_Account account);
static enum XML_Error addBinding(XML_Parser parser, PREFIX *prefix,
const ATTRIBUTE_ID *attId, const XML_Char *uri,
BINDING **bindingsPtr);
static int defineAttribute(ELEMENT_TYPE *type, ATTRIBUTE_ID *, XML_Bool isCdata,
XML_Bool isId, const XML_Char *dfltValue,
XML_Parser parser);
static enum XML_Error storeAttributeValue(XML_Parser parser, const ENCODING *,
XML_Bool isCdata, const char *,
const char *, STRING_POOL *,
enum XML_Account account);
static enum XML_Error appendAttributeValue(XML_Parser parser, const ENCODING *,
XML_Bool isCdata, const char *,
const char *, STRING_POOL *,
enum XML_Account account);
static ATTRIBUTE_ID *getAttributeId(XML_Parser parser, const ENCODING *enc,
const char *start, const char *end);
static int setElementTypePrefix(XML_Parser parser, ELEMENT_TYPE *);
static enum XML_Error storeEntityValue(XML_Parser parser, const ENCODING *enc,
const char *start, const char *end,
enum XML_Account account);
static int reportProcessingInstruction(XML_Parser parser, const ENCODING *enc,
const char *start, const char *end);
static int reportComment(XML_Parser parser, const ENCODING *enc,
const char *start, const char *end);
static void reportDefault(XML_Parser parser, const ENCODING *enc,
const char *start, const char *end);
static const XML_Char *getContext(XML_Parser parser);
static XML_Bool setContext(XML_Parser parser, const XML_Char *context);
static void FASTCALL normalizePublicId(XML_Char *s);
static DTD *dtdCreate(const XML_Memory_Handling_Suite *ms);
/* do not call if m_parentParser != NULL */
static void dtdReset(DTD *p, const XML_Memory_Handling_Suite *ms);
static void dtdDestroy(DTD *p, XML_Bool isDocEntity,
const XML_Memory_Handling_Suite *ms);
static int dtdCopy(XML_Parser oldParser, DTD *newDtd, const DTD *oldDtd,
const XML_Memory_Handling_Suite *ms);
static int copyEntityTable(XML_Parser oldParser, HASH_TABLE *, STRING_POOL *,
const HASH_TABLE *);
static NAMED *lookup(XML_Parser parser, HASH_TABLE *table, KEY name,
size_t createSize);
static void FASTCALL hashTableInit(HASH_TABLE *,
const XML_Memory_Handling_Suite *ms);
static void FASTCALL hashTableClear(HASH_TABLE *);
static void FASTCALL hashTableDestroy(HASH_TABLE *);
static void FASTCALL hashTableIterInit(HASH_TABLE_ITER *, const HASH_TABLE *);
static NAMED *FASTCALL hashTableIterNext(HASH_TABLE_ITER *);
static void FASTCALL poolInit(STRING_POOL *,
const XML_Memory_Handling_Suite *ms);
static void FASTCALL poolClear(STRING_POOL *);
static void FASTCALL poolDestroy(STRING_POOL *);
static XML_Char *poolAppend(STRING_POOL *pool, const ENCODING *enc,
const char *ptr, const char *end);
static XML_Char *poolStoreString(STRING_POOL *pool, const ENCODING *enc,
const char *ptr, const char *end);
static XML_Bool FASTCALL poolGrow(STRING_POOL *pool);
static const XML_Char *FASTCALL poolCopyString(STRING_POOL *pool,
const XML_Char *s);
static const XML_Char *poolCopyStringN(STRING_POOL *pool, const XML_Char *s,
int n);
static const XML_Char *FASTCALL poolAppendString(STRING_POOL *pool,
const XML_Char *s);
static int FASTCALL nextScaffoldPart(XML_Parser parser);
static XML_Content *build_model(XML_Parser parser);
static ELEMENT_TYPE *getElementType(XML_Parser parser, const ENCODING *enc,
const char *ptr, const char *end);
static XML_Char *copyString(const XML_Char *s,
const XML_Memory_Handling_Suite *memsuite);
static unsigned long generate_hash_secret_salt(XML_Parser parser);
static XML_Bool startParsing(XML_Parser parser);
static XML_Parser parserCreate(const XML_Char *encodingName,
const XML_Memory_Handling_Suite *memsuite,
const XML_Char *nameSep, DTD *dtd);
static void parserInit(XML_Parser parser, const XML_Char *encodingName);
#ifdef XML_DTD
static float accountingGetCurrentAmplification(XML_Parser rootParser);
static void accountingReportStats(XML_Parser originParser, const char *epilog);
static void accountingOnAbort(XML_Parser originParser);
static void accountingReportDiff(XML_Parser rootParser,
unsigned int levelsAwayFromRootParser,
const char *before, const char *after,
ptrdiff_t bytesMore, int source_line,
enum XML_Account account);
static XML_Bool accountingDiffTolerated(XML_Parser originParser, int tok,
const char *before, const char *after,
int source_line,
enum XML_Account account);
static void entityTrackingReportStats(XML_Parser parser, ENTITY *entity,
const char *action, int sourceLine);
static void entityTrackingOnOpen(XML_Parser parser, ENTITY *entity,
int sourceLine);
static void entityTrackingOnClose(XML_Parser parser, ENTITY *entity,
int sourceLine);
static XML_Parser getRootParserOf(XML_Parser parser,
unsigned int *outLevelDiff);
#endif /* XML_DTD */
static unsigned long getDebugLevel(const char *variableName,
unsigned long defaultDebugLevel);
#define poolStart(pool) ((pool)->start)
#define poolEnd(pool) ((pool)->ptr)
#define poolLength(pool) ((pool)->ptr - (pool)->start)
#define poolChop(pool) ((void)--(pool->ptr))
#define poolLastChar(pool) (((pool)->ptr)[-1])
#define poolDiscard(pool) ((pool)->ptr = (pool)->start)
#define poolFinish(pool) ((pool)->start = (pool)->ptr)
#define poolAppendChar(pool, c) \
(((pool)->ptr == (pool)->end && ! poolGrow(pool)) \
? 0 \
: ((*((pool)->ptr)++ = c), 1))
struct XML_ParserStruct {
/* The first member must be m_userData so that the XML_GetUserData
macro works. */
void *m_userData;
void *m_handlerArg;
char *m_buffer;
const XML_Memory_Handling_Suite m_mem;
/* first character to be parsed */
const char *m_bufferPtr;
/* past last character to be parsed */
char *m_bufferEnd;
/* allocated end of m_buffer */
const char *m_bufferLim;
XML_Index m_parseEndByteIndex;
const char *m_parseEndPtr;
XML_Char *m_dataBuf;
XML_Char *m_dataBufEnd;
XML_StartElementHandler m_startElementHandler;
XML_EndElementHandler m_endElementHandler;
XML_CharacterDataHandler m_characterDataHandler;
XML_ProcessingInstructionHandler m_processingInstructionHandler;
XML_CommentHandler m_commentHandler;
XML_StartCdataSectionHandler m_startCdataSectionHandler;
XML_EndCdataSectionHandler m_endCdataSectionHandler;
XML_DefaultHandler m_defaultHandler;
XML_StartDoctypeDeclHandler m_startDoctypeDeclHandler;
XML_EndDoctypeDeclHandler m_endDoctypeDeclHandler;
XML_UnparsedEntityDeclHandler m_unparsedEntityDeclHandler;
XML_NotationDeclHandler m_notationDeclHandler;
XML_StartNamespaceDeclHandler m_startNamespaceDeclHandler;
XML_EndNamespaceDeclHandler m_endNamespaceDeclHandler;
XML_NotStandaloneHandler m_notStandaloneHandler;
XML_ExternalEntityRefHandler m_externalEntityRefHandler;
XML_Parser m_externalEntityRefHandlerArg;
XML_SkippedEntityHandler m_skippedEntityHandler;
XML_UnknownEncodingHandler m_unknownEncodingHandler;
XML_ElementDeclHandler m_elementDeclHandler;
XML_AttlistDeclHandler m_attlistDeclHandler;
XML_EntityDeclHandler m_entityDeclHandler;
XML_XmlDeclHandler m_xmlDeclHandler;
const ENCODING *m_encoding;
INIT_ENCODING m_initEncoding;
const ENCODING *m_internalEncoding;
const XML_Char *m_protocolEncodingName;
XML_Bool m_ns;
XML_Bool m_ns_triplets;
void *m_unknownEncodingMem;
void *m_unknownEncodingData;
void *m_unknownEncodingHandlerData;
void(XMLCALL *m_unknownEncodingRelease)(void *);
PROLOG_STATE m_prologState;
Processor *m_processor;
enum XML_Error m_errorCode;
const char *m_eventPtr;
const char *m_eventEndPtr;
const char *m_positionPtr;
OPEN_INTERNAL_ENTITY *m_openInternalEntities;
OPEN_INTERNAL_ENTITY *m_freeInternalEntities;
XML_Bool m_defaultExpandInternalEntities;
int m_tagLevel;
ENTITY *m_declEntity;
const XML_Char *m_doctypeName;
const XML_Char *m_doctypeSysid;
const XML_Char *m_doctypePubid;
const XML_Char *m_declAttributeType;
const XML_Char *m_declNotationName;
const XML_Char *m_declNotationPublicId;
ELEMENT_TYPE *m_declElementType;
ATTRIBUTE_ID *m_declAttributeId;
XML_Bool m_declAttributeIsCdata;
XML_Bool m_declAttributeIsId;
DTD *m_dtd;
const XML_Char *m_curBase;
TAG *m_tagStack;
TAG *m_freeTagList;
BINDING *m_inheritedBindings;
BINDING *m_freeBindingList;
int m_attsSize;
int m_nSpecifiedAtts;
int m_idAttIndex;
ATTRIBUTE *m_atts;
NS_ATT *m_nsAtts;
unsigned long m_nsAttsVersion;
unsigned char m_nsAttsPower;
#ifdef XML_ATTR_INFO
XML_AttrInfo *m_attInfo;
#endif
POSITION m_position;
STRING_POOL m_tempPool;
STRING_POOL m_temp2Pool;
char *m_groupConnector;
unsigned int m_groupSize;
XML_Char m_namespaceSeparator;
XML_Parser m_parentParser;
XML_ParsingStatus m_parsingStatus;
#ifdef XML_DTD
XML_Bool m_isParamEntity;
XML_Bool m_useForeignDTD;
enum XML_ParamEntityParsing m_paramEntityParsing;
#endif
unsigned long m_hash_secret_salt;
#ifdef XML_DTD
ACCOUNTING m_accounting;
ENTITY_STATS m_entity_stats;
#endif
};
#define MALLOC(parser, s) (parser->m_mem.malloc_fcn((s)))
#define REALLOC(parser, p, s) (parser->m_mem.realloc_fcn((p), (s)))
#define FREE(parser, p) (parser->m_mem.free_fcn((p)))
XML_Parser XMLCALL
XML_ParserCreate(const XML_Char *encodingName) {
return XML_ParserCreate_MM(encodingName, NULL, NULL);
}
XML_Parser XMLCALL
XML_ParserCreateNS(const XML_Char *encodingName, XML_Char nsSep) {
XML_Char tmp[2] = {nsSep, 0};
return XML_ParserCreate_MM(encodingName, NULL, tmp);
}
static const XML_Char implicitContext[]
= {ASCII_x, ASCII_m, ASCII_l, ASCII_EQUALS, ASCII_h,
ASCII_t, ASCII_t, ASCII_p, ASCII_COLON, ASCII_SLASH,
ASCII_SLASH, ASCII_w, ASCII_w, ASCII_w, ASCII_PERIOD,
ASCII_w, ASCII_3, ASCII_PERIOD, ASCII_o, ASCII_r,
ASCII_g, ASCII_SLASH, ASCII_X, ASCII_M, ASCII_L,
ASCII_SLASH, ASCII_1, ASCII_9, ASCII_9, ASCII_8,
ASCII_SLASH, ASCII_n, ASCII_a, ASCII_m, ASCII_e,
ASCII_s, ASCII_p, ASCII_a, ASCII_c, ASCII_e,
'\0'};
/* To avoid warnings about unused functions: */
#if ! defined(HAVE_ARC4RANDOM_BUF) && ! defined(HAVE_ARC4RANDOM)
# if defined(HAVE_GETRANDOM) || defined(HAVE_SYSCALL_GETRANDOM)
/* Obtain entropy on Linux 3.17+ */
static int
writeRandomBytes_getrandom_nonblock(void *target, size_t count) {
int success = 0; /* full count bytes written? */
size_t bytesWrittenTotal = 0;
const unsigned int getrandomFlags = GRND_NONBLOCK;
do {
void *const currentTarget = (void *)((char *)target + bytesWrittenTotal);
const size_t bytesToWrite = count - bytesWrittenTotal;
const int bytesWrittenMore =
# if defined(HAVE_GETRANDOM)
getrandom(currentTarget, bytesToWrite, getrandomFlags);
# else
syscall(SYS_getrandom, currentTarget, bytesToWrite, getrandomFlags);
# endif
if (bytesWrittenMore > 0) {
bytesWrittenTotal += bytesWrittenMore;
if (bytesWrittenTotal >= count)
success = 1;
}
} while (! success && (errno == EINTR));
return success;
}
# endif /* defined(HAVE_GETRANDOM) || defined(HAVE_SYSCALL_GETRANDOM) */
# if ! defined(_WIN32) && defined(XML_DEV_URANDOM)
/* Extract entropy from /dev/urandom */
static int
writeRandomBytes_dev_urandom(void *target, size_t count) {
int success = 0; /* full count bytes written? */
size_t bytesWrittenTotal = 0;
const int fd = open("/dev/urandom", O_RDONLY);
if (fd < 0) {
return 0;
}
do {
void *const currentTarget = (void *)((char *)target + bytesWrittenTotal);
const size_t bytesToWrite = count - bytesWrittenTotal;
const ssize_t bytesWrittenMore = read(fd, currentTarget, bytesToWrite);
if (bytesWrittenMore > 0) {
bytesWrittenTotal += bytesWrittenMore;
if (bytesWrittenTotal >= count)
success = 1;
}
} while (! success && (errno == EINTR));
close(fd);
return success;
}
# endif /* ! defined(_WIN32) && defined(XML_DEV_URANDOM) */
#endif /* ! defined(HAVE_ARC4RANDOM_BUF) && ! defined(HAVE_ARC4RANDOM) */
#if defined(HAVE_ARC4RANDOM) && ! defined(HAVE_ARC4RANDOM_BUF)
static void
writeRandomBytes_arc4random(void *target, size_t count) {
size_t bytesWrittenTotal = 0;
while (bytesWrittenTotal < count) {
const uint32_t random32 = arc4random();
size_t i = 0;
for (; (i < sizeof(random32)) && (bytesWrittenTotal < count);
i++, bytesWrittenTotal++) {
const uint8_t random8 = (uint8_t)(random32 >> (i * 8));
((uint8_t *)target)[bytesWrittenTotal] = random8;
}
}
}
#endif /* defined(HAVE_ARC4RANDOM) && ! defined(HAVE_ARC4RANDOM_BUF) */
#ifdef _WIN32
/* Provide declaration of rand_s() for MinGW-32 (not 64, which has it),
as it didn't declare it in its header prior to version 5.3.0 of its
runtime package (mingwrt, containing stdlib.h). The upstream fix
was introduced at https://osdn.net/projects/mingw/ticket/39658 . */
# if defined(__MINGW32__) && defined(__MINGW32_VERSION) \
&& __MINGW32_VERSION < 5003000L && ! defined(__MINGW64_VERSION_MAJOR)
__declspec(dllimport) int rand_s(unsigned int *);
# endif
/* Obtain entropy on Windows using the rand_s() function which
* generates cryptographically secure random numbers. Internally it
* uses RtlGenRandom API which is present in Windows XP and later.
*/
static int
writeRandomBytes_rand_s(void *target, size_t count) {
size_t bytesWrittenTotal = 0;
while (bytesWrittenTotal < count) {
unsigned int random32 = 0;
size_t i = 0;
if (rand_s(&random32))
return 0; /* failure */
for (; (i < sizeof(random32)) && (bytesWrittenTotal < count);
i++, bytesWrittenTotal++) {
const uint8_t random8 = (uint8_t)(random32 >> (i * 8));
((uint8_t *)target)[bytesWrittenTotal] = random8;
}
}
return 1; /* success */
}
#endif /* _WIN32 */
#if ! defined(HAVE_ARC4RANDOM_BUF) && ! defined(HAVE_ARC4RANDOM)
static unsigned long
gather_time_entropy(void) {
# ifdef _WIN32
FILETIME ft;
GetSystemTimeAsFileTime(&ft); /* never fails */
return ft.dwHighDateTime ^ ft.dwLowDateTime;
# else
struct timeval tv;
int gettimeofday_res;
gettimeofday_res = gettimeofday(&tv, NULL);
# if defined(NDEBUG)
(void)gettimeofday_res;
# else
assert(gettimeofday_res == 0);
# endif /* defined(NDEBUG) */
/* Microseconds time is <20 bits entropy */
return tv.tv_usec;
# endif
}
#endif /* ! defined(HAVE_ARC4RANDOM_BUF) && ! defined(HAVE_ARC4RANDOM) */
static unsigned long
ENTROPY_DEBUG(const char *label, unsigned long entropy) {
if (getDebugLevel("EXPAT_ENTROPY_DEBUG", 0) >= 1u) {
fprintf(stderr, "expat: Entropy: %s --> 0x%0*lx (%lu bytes)\n", label,
(int)sizeof(entropy) * 2, entropy, (unsigned long)sizeof(entropy));
}
return entropy;
}
static unsigned long
generate_hash_secret_salt(XML_Parser parser) {
unsigned long entropy;
(void)parser;
/* "Failproof" high quality providers: */
#if defined(HAVE_ARC4RANDOM_BUF)
arc4random_buf(&entropy, sizeof(entropy));
return ENTROPY_DEBUG("arc4random_buf", entropy);
#elif defined(HAVE_ARC4RANDOM)
writeRandomBytes_arc4random((void *)&entropy, sizeof(entropy));
return ENTROPY_DEBUG("arc4random", entropy);
#else
/* Try high quality providers first .. */
# ifdef _WIN32
if (writeRandomBytes_rand_s((void *)&entropy, sizeof(entropy))) {
return ENTROPY_DEBUG("rand_s", entropy);
}
# elif defined(HAVE_GETRANDOM) || defined(HAVE_SYSCALL_GETRANDOM)
if (writeRandomBytes_getrandom_nonblock((void *)&entropy, sizeof(entropy))) {
return ENTROPY_DEBUG("getrandom", entropy);
}
# endif
# if ! defined(_WIN32) && defined(XML_DEV_URANDOM)
if (writeRandomBytes_dev_urandom((void *)&entropy, sizeof(entropy))) {
return ENTROPY_DEBUG("/dev/urandom", entropy);
}
# endif /* ! defined(_WIN32) && defined(XML_DEV_URANDOM) */
/* .. and self-made low quality for backup: */
/* Process ID is 0 bits entropy if attacker has local access */
entropy = gather_time_entropy() ^ getpid();
/* Factors are 2^31-1 and 2^61-1 (Mersenne primes M31 and M61) */
if (sizeof(unsigned long) == 4) {
return ENTROPY_DEBUG("fallback(4)", entropy * 2147483647);
} else {
return ENTROPY_DEBUG("fallback(8)",
entropy * (unsigned long)2305843009213693951ULL);
}
#endif
}
static unsigned long
get_hash_secret_salt(XML_Parser parser) {
if (parser->m_parentParser != NULL)
return get_hash_secret_salt(parser->m_parentParser);
return parser->m_hash_secret_salt;
}
static XML_Bool /* only valid for root parser */
startParsing(XML_Parser parser) {
/* hash functions must be initialized before setContext() is called */
if (parser->m_hash_secret_salt == 0)
parser->m_hash_secret_salt = generate_hash_secret_salt(parser);
if (parser->m_ns) {
/* implicit context only set for root parser, since child
parsers (i.e. external entity parsers) will inherit it
*/
return setContext(parser, implicitContext);
}
return XML_TRUE;
}
XML_Parser XMLCALL
XML_ParserCreate_MM(const XML_Char *encodingName,
const XML_Memory_Handling_Suite *memsuite,
const XML_Char *nameSep) {
return parserCreate(encodingName, memsuite, nameSep, NULL);
}
static XML_Parser
parserCreate(const XML_Char *encodingName,
const XML_Memory_Handling_Suite *memsuite, const XML_Char *nameSep,
DTD *dtd) {
XML_Parser parser;
if (memsuite) {
XML_Memory_Handling_Suite *mtemp;
parser = memsuite->malloc_fcn(sizeof(struct XML_ParserStruct));
if (parser != NULL) {
mtemp = (XML_Memory_Handling_Suite *)&(parser->m_mem);
mtemp->malloc_fcn = memsuite->malloc_fcn;
mtemp->realloc_fcn = memsuite->realloc_fcn;
mtemp->free_fcn = memsuite->free_fcn;
}
} else {
XML_Memory_Handling_Suite *mtemp;
parser = (XML_Parser)malloc(sizeof(struct XML_ParserStruct));
if (parser != NULL) {
mtemp = (XML_Memory_Handling_Suite *)&(parser->m_mem);
mtemp->malloc_fcn = malloc;
mtemp->realloc_fcn = realloc;
mtemp->free_fcn = free;
}
}
if (! parser)
return parser;
parser->m_buffer = NULL;
parser->m_bufferLim = NULL;
parser->m_attsSize = INIT_ATTS_SIZE;
parser->m_atts
= (ATTRIBUTE *)MALLOC(parser, parser->m_attsSize * sizeof(ATTRIBUTE));
if (parser->m_atts == NULL) {
FREE(parser, parser);
return NULL;
}
#ifdef XML_ATTR_INFO
parser->m_attInfo = (XML_AttrInfo *)MALLOC(
parser, parser->m_attsSize * sizeof(XML_AttrInfo));
if (parser->m_attInfo == NULL) {
FREE(parser, parser->m_atts);
FREE(parser, parser);
return NULL;
}
#endif
parser->m_dataBuf
= (XML_Char *)MALLOC(parser, INIT_DATA_BUF_SIZE * sizeof(XML_Char));
if (parser->m_dataBuf == NULL) {
FREE(parser, parser->m_atts);
#ifdef XML_ATTR_INFO
FREE(parser, parser->m_attInfo);
#endif
FREE(parser, parser);
return NULL;
}
parser->m_dataBufEnd = parser->m_dataBuf + INIT_DATA_BUF_SIZE;
if (dtd)
parser->m_dtd = dtd;
else {
parser->m_dtd = dtdCreate(&parser->m_mem);
if (parser->m_dtd == NULL) {
FREE(parser, parser->m_dataBuf);
FREE(parser, parser->m_atts);
#ifdef XML_ATTR_INFO
FREE(parser, parser->m_attInfo);
#endif
FREE(parser, parser);
return NULL;
}
}
parser->m_freeBindingList = NULL;
parser->m_freeTagList = NULL;
parser->m_freeInternalEntities = NULL;
parser->m_groupSize = 0;
parser->m_groupConnector = NULL;
parser->m_unknownEncodingHandler = NULL;
parser->m_unknownEncodingHandlerData = NULL;
parser->m_namespaceSeparator = ASCII_EXCL;
parser->m_ns = XML_FALSE;
parser->m_ns_triplets = XML_FALSE;
parser->m_nsAtts = NULL;
parser->m_nsAttsVersion = 0;
parser->m_nsAttsPower = 0;
parser->m_protocolEncodingName = NULL;
poolInit(&parser->m_tempPool, &(parser->m_mem));
poolInit(&parser->m_temp2Pool, &(parser->m_mem));
parserInit(parser, encodingName);
if (encodingName && ! parser->m_protocolEncodingName) {
XML_ParserFree(parser);
return NULL;
}
if (nameSep) {
parser->m_ns = XML_TRUE;
parser->m_internalEncoding = XmlGetInternalEncodingNS();
parser->m_namespaceSeparator = *nameSep;
} else {
parser->m_internalEncoding = XmlGetInternalEncoding();
}
return parser;
}
static void
parserInit(XML_Parser parser, const XML_Char *encodingName) {
parser->m_processor = prologInitProcessor;
XmlPrologStateInit(&parser->m_prologState);
if (encodingName != NULL) {
parser->m_protocolEncodingName = copyString(encodingName, &(parser->m_mem));
}
parser->m_curBase = NULL;
XmlInitEncoding(&parser->m_initEncoding, &parser->m_encoding, 0);
parser->m_userData = NULL;
parser->m_handlerArg = NULL;
parser->m_startElementHandler = NULL;
parser->m_endElementHandler = NULL;
parser->m_characterDataHandler = NULL;
parser->m_processingInstructionHandler = NULL;
parser->m_commentHandler = NULL;
parser->m_startCdataSectionHandler = NULL;
parser->m_endCdataSectionHandler = NULL;
parser->m_defaultHandler = NULL;
parser->m_startDoctypeDeclHandler = NULL;
parser->m_endDoctypeDeclHandler = NULL;
parser->m_unparsedEntityDeclHandler = NULL;
parser->m_notationDeclHandler = NULL;
parser->m_startNamespaceDeclHandler = NULL;
parser->m_endNamespaceDeclHandler = NULL;
parser->m_notStandaloneHandler = NULL;
parser->m_externalEntityRefHandler = NULL;
parser->m_externalEntityRefHandlerArg = parser;
parser->m_skippedEntityHandler = NULL;
parser->m_elementDeclHandler = NULL;
parser->m_attlistDeclHandler = NULL;
parser->m_entityDeclHandler = NULL;
parser->m_xmlDeclHandler = NULL;
parser->m_bufferPtr = parser->m_buffer;
parser->m_bufferEnd = parser->m_buffer;
parser->m_parseEndByteIndex = 0;
parser->m_parseEndPtr = NULL;
parser->m_declElementType = NULL;
parser->m_declAttributeId = NULL;
parser->m_declEntity = NULL;
parser->m_doctypeName = NULL;
parser->m_doctypeSysid = NULL;
parser->m_doctypePubid = NULL;
parser->m_declAttributeType = NULL;
parser->m_declNotationName = NULL;
parser->m_declNotationPublicId = NULL;
parser->m_declAttributeIsCdata = XML_FALSE;
parser->m_declAttributeIsId = XML_FALSE;
memset(&parser->m_position, 0, sizeof(POSITION));
parser->m_errorCode = XML_ERROR_NONE;
parser->m_eventPtr = NULL;
parser->m_eventEndPtr = NULL;
parser->m_positionPtr = NULL;
parser->m_openInternalEntities = NULL;
parser->m_defaultExpandInternalEntities = XML_TRUE;
parser->m_tagLevel = 0;
parser->m_tagStack = NULL;
parser->m_inheritedBindings = NULL;
parser->m_nSpecifiedAtts = 0;
parser->m_unknownEncodingMem = NULL;
parser->m_unknownEncodingRelease = NULL;
parser->m_unknownEncodingData = NULL;
parser->m_parentParser = NULL;
parser->m_parsingStatus.parsing = XML_INITIALIZED;
#ifdef XML_DTD
parser->m_isParamEntity = XML_FALSE;
parser->m_useForeignDTD = XML_FALSE;
parser->m_paramEntityParsing = XML_PARAM_ENTITY_PARSING_NEVER;
#endif
parser->m_hash_secret_salt = 0;
#ifdef XML_DTD
memset(&parser->m_accounting, 0, sizeof(ACCOUNTING));
parser->m_accounting.debugLevel = getDebugLevel("EXPAT_ACCOUNTING_DEBUG", 0u);
parser->m_accounting.maximumAmplificationFactor
= EXPAT_BILLION_LAUGHS_ATTACK_PROTECTION_MAXIMUM_AMPLIFICATION_DEFAULT;
parser->m_accounting.activationThresholdBytes
= EXPAT_BILLION_LAUGHS_ATTACK_PROTECTION_ACTIVATION_THRESHOLD_DEFAULT;
memset(&parser->m_entity_stats, 0, sizeof(ENTITY_STATS));
parser->m_entity_stats.debugLevel = getDebugLevel("EXPAT_ENTITY_DEBUG", 0u);
#endif
}
/* moves list of bindings to m_freeBindingList */
static void FASTCALL
moveToFreeBindingList(XML_Parser parser, BINDING *bindings) {
while (bindings) {
BINDING *b = bindings;
bindings = bindings->nextTagBinding;
b->nextTagBinding = parser->m_freeBindingList;
parser->m_freeBindingList = b;
}
}
XML_Bool XMLCALL
XML_ParserReset(XML_Parser parser, const XML_Char *encodingName) {
TAG *tStk;
OPEN_INTERNAL_ENTITY *openEntityList;
if (parser == NULL)
return XML_FALSE;
if (parser->m_parentParser)
return XML_FALSE;
/* move m_tagStack to m_freeTagList */
tStk = parser->m_tagStack;
while (tStk) {
TAG *tag = tStk;
tStk = tStk->parent;
tag->parent = parser->m_freeTagList;
moveToFreeBindingList(parser, tag->bindings);
tag->bindings = NULL;
parser->m_freeTagList = tag;
}
/* move m_openInternalEntities to m_freeInternalEntities */
openEntityList = parser->m_openInternalEntities;
while (openEntityList) {
OPEN_INTERNAL_ENTITY *openEntity = openEntityList;
openEntityList = openEntity->next;
openEntity->next = parser->m_freeInternalEntities;
parser->m_freeInternalEntities = openEntity;
}
moveToFreeBindingList(parser, parser->m_inheritedBindings);
FREE(parser, parser->m_unknownEncodingMem);
if (parser->m_unknownEncodingRelease)
parser->m_unknownEncodingRelease(parser->m_unknownEncodingData);
poolClear(&parser->m_tempPool);
poolClear(&parser->m_temp2Pool);
FREE(parser, (void *)parser->m_protocolEncodingName);
parser->m_protocolEncodingName = NULL;
parserInit(parser, encodingName);
dtdReset(parser->m_dtd, &parser->m_mem);
return XML_TRUE;
}
enum XML_Status XMLCALL
XML_SetEncoding(XML_Parser parser, const XML_Char *encodingName) {
if (parser == NULL)
return XML_STATUS_ERROR;
/* Block after XML_Parse()/XML_ParseBuffer() has been called.
XXX There's no way for the caller to determine which of the
XXX possible error cases caused the XML_STATUS_ERROR return.
*/
if (parser->m_parsingStatus.parsing == XML_PARSING
|| parser->m_parsingStatus.parsing == XML_SUSPENDED)
return XML_STATUS_ERROR;
/* Get rid of any previous encoding name */
FREE(parser, (void *)parser->m_protocolEncodingName);
if (encodingName == NULL)
/* No new encoding name */
parser->m_protocolEncodingName = NULL;
else {
/* Copy the new encoding name into allocated memory */
parser->m_protocolEncodingName = copyString(encodingName, &(parser->m_mem));
if (! parser->m_protocolEncodingName)
return XML_STATUS_ERROR;
}
return XML_STATUS_OK;
}
XML_Parser XMLCALL
XML_ExternalEntityParserCreate(XML_Parser oldParser, const XML_Char *context,
const XML_Char *encodingName) {
XML_Parser parser = oldParser;
DTD *newDtd = NULL;
DTD *oldDtd;
XML_StartElementHandler oldStartElementHandler;
XML_EndElementHandler oldEndElementHandler;
XML_CharacterDataHandler oldCharacterDataHandler;
XML_ProcessingInstructionHandler oldProcessingInstructionHandler;
XML_CommentHandler oldCommentHandler;
XML_StartCdataSectionHandler oldStartCdataSectionHandler;
XML_EndCdataSectionHandler oldEndCdataSectionHandler;
XML_DefaultHandler oldDefaultHandler;
XML_UnparsedEntityDeclHandler oldUnparsedEntityDeclHandler;
XML_NotationDeclHandler oldNotationDeclHandler;
XML_StartNamespaceDeclHandler oldStartNamespaceDeclHandler;
XML_EndNamespaceDeclHandler oldEndNamespaceDeclHandler;
XML_NotStandaloneHandler oldNotStandaloneHandler;
XML_ExternalEntityRefHandler oldExternalEntityRefHandler;
XML_SkippedEntityHandler oldSkippedEntityHandler;
XML_UnknownEncodingHandler oldUnknownEncodingHandler;
XML_ElementDeclHandler oldElementDeclHandler;
XML_AttlistDeclHandler oldAttlistDeclHandler;
XML_EntityDeclHandler oldEntityDeclHandler;
XML_XmlDeclHandler oldXmlDeclHandler;
ELEMENT_TYPE *oldDeclElementType;
void *oldUserData;
void *oldHandlerArg;
XML_Bool oldDefaultExpandInternalEntities;
XML_Parser oldExternalEntityRefHandlerArg;
#ifdef XML_DTD
enum XML_ParamEntityParsing oldParamEntityParsing;
int oldInEntityValue;
#endif
XML_Bool oldns_triplets;
/* Note that the new parser shares the same hash secret as the old
parser, so that dtdCopy and copyEntityTable can lookup values
from hash tables associated with either parser without us having
to worry which hash secrets each table has.
*/
unsigned long oldhash_secret_salt;
/* Validate the oldParser parameter before we pull everything out of it */
if (oldParser == NULL)
return NULL;
/* Stash the original parser contents on the stack */
oldDtd = parser->m_dtd;
oldStartElementHandler = parser->m_startElementHandler;
oldEndElementHandler = parser->m_endElementHandler;
oldCharacterDataHandler = parser->m_characterDataHandler;
oldProcessingInstructionHandler = parser->m_processingInstructionHandler;
oldCommentHandler = parser->m_commentHandler;
oldStartCdataSectionHandler = parser->m_startCdataSectionHandler;
oldEndCdataSectionHandler = parser->m_endCdataSectionHandler;
oldDefaultHandler = parser->m_defaultHandler;
oldUnparsedEntityDeclHandler = parser->m_unparsedEntityDeclHandler;
oldNotationDeclHandler = parser->m_notationDeclHandler;
oldStartNamespaceDeclHandler = parser->m_startNamespaceDeclHandler;
oldEndNamespaceDeclHandler = parser->m_endNamespaceDeclHandler;
oldNotStandaloneHandler = parser->m_notStandaloneHandler;
oldExternalEntityRefHandler = parser->m_externalEntityRefHandler;
oldSkippedEntityHandler = parser->m_skippedEntityHandler;
oldUnknownEncodingHandler = parser->m_unknownEncodingHandler;
oldElementDeclHandler = parser->m_elementDeclHandler;
oldAttlistDeclHandler = parser->m_attlistDeclHandler;
oldEntityDeclHandler = parser->m_entityDeclHandler;
oldXmlDeclHandler = parser->m_xmlDeclHandler;
oldDeclElementType = parser->m_declElementType;
oldUserData = parser->m_userData;
oldHandlerArg = parser->m_handlerArg;
oldDefaultExpandInternalEntities = parser->m_defaultExpandInternalEntities;
oldExternalEntityRefHandlerArg = parser->m_externalEntityRefHandlerArg;
#ifdef XML_DTD
oldParamEntityParsing = parser->m_paramEntityParsing;
oldInEntityValue = parser->m_prologState.inEntityValue;
#endif
oldns_triplets = parser->m_ns_triplets;
/* Note that the new parser shares the same hash secret as the old
parser, so that dtdCopy and copyEntityTable can lookup values
from hash tables associated with either parser without us having
to worry which hash secrets each table has.
*/
oldhash_secret_salt = parser->m_hash_secret_salt;
#ifdef XML_DTD
if (! context)
newDtd = oldDtd;
#endif /* XML_DTD */
/* Note that the magical uses of the pre-processor to make field
access look more like C++ require that `parser' be overwritten
here. This makes this function more painful to follow than it
would be otherwise.
*/
if (parser->m_ns) {
XML_Char tmp[2] = {parser->m_namespaceSeparator, 0};
parser = parserCreate(encodingName, &parser->m_mem, tmp, newDtd);
} else {
parser = parserCreate(encodingName, &parser->m_mem, NULL, newDtd);
}
if (! parser)
return NULL;
parser->m_startElementHandler = oldStartElementHandler;
parser->m_endElementHandler = oldEndElementHandler;
parser->m_characterDataHandler = oldCharacterDataHandler;
parser->m_processingInstructionHandler = oldProcessingInstructionHandler;
parser->m_commentHandler = oldCommentHandler;
parser->m_startCdataSectionHandler = oldStartCdataSectionHandler;
parser->m_endCdataSectionHandler = oldEndCdataSectionHandler;
parser->m_defaultHandler = oldDefaultHandler;
parser->m_unparsedEntityDeclHandler = oldUnparsedEntityDeclHandler;
parser->m_notationDeclHandler = oldNotationDeclHandler;
parser->m_startNamespaceDeclHandler = oldStartNamespaceDeclHandler;
parser->m_endNamespaceDeclHandler = oldEndNamespaceDeclHandler;
parser->m_notStandaloneHandler = oldNotStandaloneHandler;
parser->m_externalEntityRefHandler = oldExternalEntityRefHandler;
parser->m_skippedEntityHandler = oldSkippedEntityHandler;
parser->m_unknownEncodingHandler = oldUnknownEncodingHandler;
parser->m_elementDeclHandler = oldElementDeclHandler;
parser->m_attlistDeclHandler = oldAttlistDeclHandler;
parser->m_entityDeclHandler = oldEntityDeclHandler;
parser->m_xmlDeclHandler = oldXmlDeclHandler;
parser->m_declElementType = oldDeclElementType;
parser->m_userData = oldUserData;
if (oldUserData == oldHandlerArg)
parser->m_handlerArg = parser->m_userData;
else
parser->m_handlerArg = parser;
if (oldExternalEntityRefHandlerArg != oldParser)
parser->m_externalEntityRefHandlerArg = oldExternalEntityRefHandlerArg;
parser->m_defaultExpandInternalEntities = oldDefaultExpandInternalEntities;
parser->m_ns_triplets = oldns_triplets;
parser->m_hash_secret_salt = oldhash_secret_salt;
parser->m_parentParser = oldParser;
#ifdef XML_DTD
parser->m_paramEntityParsing = oldParamEntityParsing;
parser->m_prologState.inEntityValue = oldInEntityValue;
if (context) {
#endif /* XML_DTD */
if (! dtdCopy(oldParser, parser->m_dtd, oldDtd, &parser->m_mem)
|| ! setContext(parser, context)) {
XML_ParserFree(parser);
return NULL;
}
parser->m_processor = externalEntityInitProcessor;
#ifdef XML_DTD
} else {
/* The DTD instance referenced by parser->m_dtd is shared between the
document's root parser and external PE parsers, therefore one does not
need to call setContext. In addition, one also *must* not call
setContext, because this would overwrite existing prefix->binding
pointers in parser->m_dtd with ones that get destroyed with the external
PE parser. This would leave those prefixes with dangling pointers.
*/
parser->m_isParamEntity = XML_TRUE;
XmlPrologStateInitExternalEntity(&parser->m_prologState);
parser->m_processor = externalParEntInitProcessor;
}
#endif /* XML_DTD */
return parser;
}
static void FASTCALL
destroyBindings(BINDING *bindings, XML_Parser parser) {
for (;;) {
BINDING *b = bindings;
if (! b)
break;
bindings = b->nextTagBinding;
FREE(parser, b->uri);
FREE(parser, b);
}
}
void XMLCALL
XML_ParserFree(XML_Parser parser) {
TAG *tagList;
OPEN_INTERNAL_ENTITY *entityList;
if (parser == NULL)
return;
/* free m_tagStack and m_freeTagList */
tagList = parser->m_tagStack;
for (;;) {
TAG *p;
if (tagList == NULL) {
if (parser->m_freeTagList == NULL)
break;
tagList = parser->m_freeTagList;
parser->m_freeTagList = NULL;
}
p = tagList;
tagList = tagList->parent;
FREE(parser, p->buf);
destroyBindings(p->bindings, parser);
FREE(parser, p);
}
/* free m_openInternalEntities and m_freeInternalEntities */
entityList = parser->m_openInternalEntities;
for (;;) {
OPEN_INTERNAL_ENTITY *openEntity;
if (entityList == NULL) {
if (parser->m_freeInternalEntities == NULL)
break;
entityList = parser->m_freeInternalEntities;
parser->m_freeInternalEntities = NULL;
}
openEntity = entityList;
entityList = entityList->next;
FREE(parser, openEntity);
}
destroyBindings(parser->m_freeBindingList, parser);
destroyBindings(parser->m_inheritedBindings, parser);
poolDestroy(&parser->m_tempPool);
poolDestroy(&parser->m_temp2Pool);
FREE(parser, (void *)parser->m_protocolEncodingName);
#ifdef XML_DTD
/* external parameter entity parsers share the DTD structure
parser->m_dtd with the root parser, so we must not destroy it
*/
if (! parser->m_isParamEntity && parser->m_dtd)
#else
if (parser->m_dtd)
#endif /* XML_DTD */
dtdDestroy(parser->m_dtd, (XML_Bool)! parser->m_parentParser,
&parser->m_mem);
FREE(parser, (void *)parser->m_atts);
#ifdef XML_ATTR_INFO
FREE(parser, (void *)parser->m_attInfo);
#endif
FREE(parser, parser->m_groupConnector);
FREE(parser, parser->m_buffer);
FREE(parser, parser->m_dataBuf);
FREE(parser, parser->m_nsAtts);
FREE(parser, parser->m_unknownEncodingMem);
if (parser->m_unknownEncodingRelease)
parser->m_unknownEncodingRelease(parser->m_unknownEncodingData);
FREE(parser, parser);
}
void XMLCALL
XML_UseParserAsHandlerArg(XML_Parser parser) {
if (parser != NULL)
parser->m_handlerArg = parser;
}
enum XML_Error XMLCALL
XML_UseForeignDTD(XML_Parser parser, XML_Bool useDTD) {
if (parser == NULL)
return XML_ERROR_INVALID_ARGUMENT;
#ifdef XML_DTD
/* block after XML_Parse()/XML_ParseBuffer() has been called */
if (parser->m_parsingStatus.parsing == XML_PARSING
|| parser->m_parsingStatus.parsing == XML_SUSPENDED)
return XML_ERROR_CANT_CHANGE_FEATURE_ONCE_PARSING;
parser->m_useForeignDTD = useDTD;
return XML_ERROR_NONE;
#else
UNUSED_P(useDTD);
return XML_ERROR_FEATURE_REQUIRES_XML_DTD;
#endif
}
void XMLCALL
XML_SetReturnNSTriplet(XML_Parser parser, int do_nst) {
if (parser == NULL)
return;
/* block after XML_Parse()/XML_ParseBuffer() has been called */
if (parser->m_parsingStatus.parsing == XML_PARSING
|| parser->m_parsingStatus.parsing == XML_SUSPENDED)
return;
parser->m_ns_triplets = do_nst ? XML_TRUE : XML_FALSE;
}
void XMLCALL
XML_SetUserData(XML_Parser parser, void *p) {
if (parser == NULL)
return;
if (parser->m_handlerArg == parser->m_userData)
parser->m_handlerArg = parser->m_userData = p;
else
parser->m_userData = p;
}
enum XML_Status XMLCALL
XML_SetBase(XML_Parser parser, const XML_Char *p) {
if (parser == NULL)
return XML_STATUS_ERROR;
if (p) {
p = poolCopyString(&parser->m_dtd->pool, p);
if (! p)
return XML_STATUS_ERROR;
parser->m_curBase = p;
} else
parser->m_curBase = NULL;
return XML_STATUS_OK;
}
const XML_Char *XMLCALL
XML_GetBase(XML_Parser parser) {
if (parser == NULL)
return NULL;
return parser->m_curBase;
}
int XMLCALL
XML_GetSpecifiedAttributeCount(XML_Parser parser) {
if (parser == NULL)
return -1;
return parser->m_nSpecifiedAtts;
}
int XMLCALL
XML_GetIdAttributeIndex(XML_Parser parser) {
if (parser == NULL)
return -1;
return parser->m_idAttIndex;
}
#ifdef XML_ATTR_INFO
const XML_AttrInfo *XMLCALL
XML_GetAttributeInfo(XML_Parser parser) {
if (parser == NULL)
return NULL;
return parser->m_attInfo;
}
#endif
void XMLCALL
XML_SetElementHandler(XML_Parser parser, XML_StartElementHandler start,
XML_EndElementHandler end) {
if (parser == NULL)
return;
parser->m_startElementHandler = start;
parser->m_endElementHandler = end;
}
void XMLCALL
XML_SetStartElementHandler(XML_Parser parser, XML_StartElementHandler start) {
if (parser != NULL)
parser->m_startElementHandler = start;
}
void XMLCALL
XML_SetEndElementHandler(XML_Parser parser, XML_EndElementHandler end) {
if (parser != NULL)
parser->m_endElementHandler = end;
}
void XMLCALL
XML_SetCharacterDataHandler(XML_Parser parser,
XML_CharacterDataHandler handler) {
if (parser != NULL)
parser->m_characterDataHandler = handler;
}
void XMLCALL
XML_SetProcessingInstructionHandler(XML_Parser parser,
XML_ProcessingInstructionHandler handler) {
if (parser != NULL)
parser->m_processingInstructionHandler = handler;
}
void XMLCALL
XML_SetCommentHandler(XML_Parser parser, XML_CommentHandler handler) {
if (parser != NULL)
parser->m_commentHandler = handler;
}
void XMLCALL
XML_SetCdataSectionHandler(XML_Parser parser,
XML_StartCdataSectionHandler start,
XML_EndCdataSectionHandler end) {
if (parser == NULL)
return;
parser->m_startCdataSectionHandler = start;
parser->m_endCdataSectionHandler = end;
}
void XMLCALL
XML_SetStartCdataSectionHandler(XML_Parser parser,
XML_StartCdataSectionHandler start) {
if (parser != NULL)
parser->m_startCdataSectionHandler = start;
}
void XMLCALL
XML_SetEndCdataSectionHandler(XML_Parser parser,
XML_EndCdataSectionHandler end) {
if (parser != NULL)
parser->m_endCdataSectionHandler = end;
}
void XMLCALL
XML_SetDefaultHandler(XML_Parser parser, XML_DefaultHandler handler) {
if (parser == NULL)
return;
parser->m_defaultHandler = handler;
parser->m_defaultExpandInternalEntities = XML_FALSE;
}
void XMLCALL
XML_SetDefaultHandlerExpand(XML_Parser parser, XML_DefaultHandler handler) {
if (parser == NULL)
return;
parser->m_defaultHandler = handler;
parser->m_defaultExpandInternalEntities = XML_TRUE;
}
void XMLCALL
XML_SetDoctypeDeclHandler(XML_Parser parser, XML_StartDoctypeDeclHandler start,
XML_EndDoctypeDeclHandler end) {
if (parser == NULL)
return;
parser->m_startDoctypeDeclHandler = start;
parser->m_endDoctypeDeclHandler = end;
}
void XMLCALL
XML_SetStartDoctypeDeclHandler(XML_Parser parser,
XML_StartDoctypeDeclHandler start) {
if (parser != NULL)
parser->m_startDoctypeDeclHandler = start;
}
void XMLCALL
XML_SetEndDoctypeDeclHandler(XML_Parser parser, XML_EndDoctypeDeclHandler end) {
if (parser != NULL)
parser->m_endDoctypeDeclHandler = end;
}
void XMLCALL
XML_SetUnparsedEntityDeclHandler(XML_Parser parser,
XML_UnparsedEntityDeclHandler handler) {
if (parser != NULL)
parser->m_unparsedEntityDeclHandler = handler;
}
void XMLCALL
XML_SetNotationDeclHandler(XML_Parser parser, XML_NotationDeclHandler handler) {
if (parser != NULL)
parser->m_notationDeclHandler = handler;
}
void XMLCALL
XML_SetNamespaceDeclHandler(XML_Parser parser,
XML_StartNamespaceDeclHandler start,
XML_EndNamespaceDeclHandler end) {
if (parser == NULL)
return;
parser->m_startNamespaceDeclHandler = start;
parser->m_endNamespaceDeclHandler = end;
}
void XMLCALL
XML_SetStartNamespaceDeclHandler(XML_Parser parser,
XML_StartNamespaceDeclHandler start) {
if (parser != NULL)
parser->m_startNamespaceDeclHandler = start;
}
void XMLCALL
XML_SetEndNamespaceDeclHandler(XML_Parser parser,
XML_EndNamespaceDeclHandler end) {
if (parser != NULL)
parser->m_endNamespaceDeclHandler = end;
}
void XMLCALL
XML_SetNotStandaloneHandler(XML_Parser parser,
XML_NotStandaloneHandler handler) {
if (parser != NULL)
parser->m_notStandaloneHandler = handler;
}
void XMLCALL
XML_SetExternalEntityRefHandler(XML_Parser parser,
XML_ExternalEntityRefHandler handler) {
if (parser != NULL)
parser->m_externalEntityRefHandler = handler;
}
void XMLCALL
XML_SetExternalEntityRefHandlerArg(XML_Parser parser, void *arg) {
if (parser == NULL)
return;
if (arg)
parser->m_externalEntityRefHandlerArg = (XML_Parser)arg;
else
parser->m_externalEntityRefHandlerArg = parser;
}
void XMLCALL
XML_SetSkippedEntityHandler(XML_Parser parser,
XML_SkippedEntityHandler handler) {
if (parser != NULL)
parser->m_skippedEntityHandler = handler;
}
void XMLCALL
XML_SetUnknownEncodingHandler(XML_Parser parser,
XML_UnknownEncodingHandler handler, void *data) {
if (parser == NULL)
return;
parser->m_unknownEncodingHandler = handler;
parser->m_unknownEncodingHandlerData = data;
}
void XMLCALL
XML_SetElementDeclHandler(XML_Parser parser, XML_ElementDeclHandler eldecl) {
if (parser != NULL)
parser->m_elementDeclHandler = eldecl;
}
void XMLCALL
XML_SetAttlistDeclHandler(XML_Parser parser, XML_AttlistDeclHandler attdecl) {
if (parser != NULL)
parser->m_attlistDeclHandler = attdecl;
}
void XMLCALL
XML_SetEntityDeclHandler(XML_Parser parser, XML_EntityDeclHandler handler) {
if (parser != NULL)
parser->m_entityDeclHandler = handler;
}
void XMLCALL
XML_SetXmlDeclHandler(XML_Parser parser, XML_XmlDeclHandler handler) {
if (parser != NULL)
parser->m_xmlDeclHandler = handler;
}
int XMLCALL
XML_SetParamEntityParsing(XML_Parser parser,
enum XML_ParamEntityParsing peParsing) {
if (parser == NULL)
return 0;
/* block after XML_Parse()/XML_ParseBuffer() has been called */
if (parser->m_parsingStatus.parsing == XML_PARSING
|| parser->m_parsingStatus.parsing == XML_SUSPENDED)
return 0;
#ifdef XML_DTD
parser->m_paramEntityParsing = peParsing;
return 1;
#else
return peParsing == XML_PARAM_ENTITY_PARSING_NEVER;
#endif
}
int XMLCALL
XML_SetHashSalt(XML_Parser parser, unsigned long hash_salt) {
if (parser == NULL)
return 0;
if (parser->m_parentParser)
return XML_SetHashSalt(parser->m_parentParser, hash_salt);
/* block after XML_Parse()/XML_ParseBuffer() has been called */
if (parser->m_parsingStatus.parsing == XML_PARSING
|| parser->m_parsingStatus.parsing == XML_SUSPENDED)
return 0;
parser->m_hash_secret_salt = hash_salt;
return 1;
}
enum XML_Status XMLCALL
XML_Parse(XML_Parser parser, const char *s, int len, int isFinal) {
if ((parser == NULL) || (len < 0) || ((s == NULL) && (len != 0))) {
if (parser != NULL)
parser->m_errorCode = XML_ERROR_INVALID_ARGUMENT;
return XML_STATUS_ERROR;
}
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
parser->m_errorCode = XML_ERROR_SUSPENDED;
return XML_STATUS_ERROR;
case XML_FINISHED:
parser->m_errorCode = XML_ERROR_FINISHED;
return XML_STATUS_ERROR;
case XML_INITIALIZED:
if (parser->m_parentParser == NULL && ! startParsing(parser)) {
parser->m_errorCode = XML_ERROR_NO_MEMORY;
return XML_STATUS_ERROR;
}
/* fall through */
default:
parser->m_parsingStatus.parsing = XML_PARSING;
}
if (len == 0) {
parser->m_parsingStatus.finalBuffer = (XML_Bool)isFinal;
if (! isFinal)
return XML_STATUS_OK;
parser->m_positionPtr = parser->m_bufferPtr;
parser->m_parseEndPtr = parser->m_bufferEnd;
/* If data are left over from last buffer, and we now know that these
data are the final chunk of input, then we have to check them again
to detect errors based on that fact.
*/
parser->m_errorCode
= parser->m_processor(parser, parser->m_bufferPtr,
parser->m_parseEndPtr, &parser->m_bufferPtr);
if (parser->m_errorCode == XML_ERROR_NONE) {
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
/* It is hard to be certain, but it seems that this case
* cannot occur. This code is cleaning up a previous parse
* with no new data (since len == 0). Changing the parsing
* state requires getting to execute a handler function, and
* there doesn't seem to be an opportunity for that while in
* this circumstance.
*
* Given the uncertainty, we retain the code but exclude it
* from coverage tests.
*
* LCOV_EXCL_START
*/
XmlUpdatePosition(parser->m_encoding, parser->m_positionPtr,
parser->m_bufferPtr, &parser->m_position);
parser->m_positionPtr = parser->m_bufferPtr;
return XML_STATUS_SUSPENDED;
/* LCOV_EXCL_STOP */
case XML_INITIALIZED:
case XML_PARSING:
parser->m_parsingStatus.parsing = XML_FINISHED;
/* fall through */
default:
return XML_STATUS_OK;
}
}
parser->m_eventEndPtr = parser->m_eventPtr;
parser->m_processor = errorProcessor;
return XML_STATUS_ERROR;
}
#ifndef XML_CONTEXT_BYTES
else if (parser->m_bufferPtr == parser->m_bufferEnd) {
const char *end;
int nLeftOver;
enum XML_Status result;
/* Detect overflow (a+b > MAX <==> b > MAX-a) */
if ((XML_Size)len > ((XML_Size)-1) / 2 - parser->m_parseEndByteIndex) {
parser->m_errorCode = XML_ERROR_NO_MEMORY;
parser->m_eventPtr = parser->m_eventEndPtr = NULL;
parser->m_processor = errorProcessor;
return XML_STATUS_ERROR;
}
parser->m_parseEndByteIndex += len;
parser->m_positionPtr = s;
parser->m_parsingStatus.finalBuffer = (XML_Bool)isFinal;
parser->m_errorCode
= parser->m_processor(parser, s, parser->m_parseEndPtr = s + len, &end);
if (parser->m_errorCode != XML_ERROR_NONE) {
parser->m_eventEndPtr = parser->m_eventPtr;
parser->m_processor = errorProcessor;
return XML_STATUS_ERROR;
} else {
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
result = XML_STATUS_SUSPENDED;
break;
case XML_INITIALIZED:
case XML_PARSING:
if (isFinal) {
parser->m_parsingStatus.parsing = XML_FINISHED;
return XML_STATUS_OK;
}
/* fall through */
default:
result = XML_STATUS_OK;
}
}
XmlUpdatePosition(parser->m_encoding, parser->m_positionPtr, end,
&parser->m_position);
nLeftOver = s + len - end;
if (nLeftOver) {
if (parser->m_buffer == NULL
|| nLeftOver > parser->m_bufferLim - parser->m_buffer) {
/* avoid _signed_ integer overflow */
char *temp = NULL;
const int bytesToAllocate = (int)((unsigned)len * 2U);
if (bytesToAllocate > 0) {
temp = (char *)REALLOC(parser, parser->m_buffer, bytesToAllocate);
}
if (temp == NULL) {
parser->m_errorCode = XML_ERROR_NO_MEMORY;
parser->m_eventPtr = parser->m_eventEndPtr = NULL;
parser->m_processor = errorProcessor;
return XML_STATUS_ERROR;
}
parser->m_buffer = temp;
parser->m_bufferLim = parser->m_buffer + bytesToAllocate;
}
memcpy(parser->m_buffer, end, nLeftOver);
}
parser->m_bufferPtr = parser->m_buffer;
parser->m_bufferEnd = parser->m_buffer + nLeftOver;
parser->m_positionPtr = parser->m_bufferPtr;
parser->m_parseEndPtr = parser->m_bufferEnd;
parser->m_eventPtr = parser->m_bufferPtr;
parser->m_eventEndPtr = parser->m_bufferPtr;
return result;
}
#endif /* not defined XML_CONTEXT_BYTES */
else {
void *buff = XML_GetBuffer(parser, len);
if (buff == NULL)
return XML_STATUS_ERROR;
else {
memcpy(buff, s, len);
return XML_ParseBuffer(parser, len, isFinal);
}
}
}
enum XML_Status XMLCALL
XML_ParseBuffer(XML_Parser parser, int len, int isFinal) {
const char *start;
enum XML_Status result = XML_STATUS_OK;
if (parser == NULL)
return XML_STATUS_ERROR;
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
parser->m_errorCode = XML_ERROR_SUSPENDED;
return XML_STATUS_ERROR;
case XML_FINISHED:
parser->m_errorCode = XML_ERROR_FINISHED;
return XML_STATUS_ERROR;
case XML_INITIALIZED:
/* Has someone called XML_GetBuffer successfully before? */
if (! parser->m_bufferPtr) {
parser->m_errorCode = XML_ERROR_NO_BUFFER;
return XML_STATUS_ERROR;
}
if (parser->m_parentParser == NULL && ! startParsing(parser)) {
parser->m_errorCode = XML_ERROR_NO_MEMORY;
return XML_STATUS_ERROR;
}
/* fall through */
default:
parser->m_parsingStatus.parsing = XML_PARSING;
}
start = parser->m_bufferPtr;
parser->m_positionPtr = start;
parser->m_bufferEnd += len;
parser->m_parseEndPtr = parser->m_bufferEnd;
parser->m_parseEndByteIndex += len;
parser->m_parsingStatus.finalBuffer = (XML_Bool)isFinal;
parser->m_errorCode = parser->m_processor(
parser, start, parser->m_parseEndPtr, &parser->m_bufferPtr);
if (parser->m_errorCode != XML_ERROR_NONE) {
parser->m_eventEndPtr = parser->m_eventPtr;
parser->m_processor = errorProcessor;
return XML_STATUS_ERROR;
} else {
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
result = XML_STATUS_SUSPENDED;
break;
case XML_INITIALIZED:
case XML_PARSING:
if (isFinal) {
parser->m_parsingStatus.parsing = XML_FINISHED;
return result;
}
default:; /* should not happen */
}
}
XmlUpdatePosition(parser->m_encoding, parser->m_positionPtr,
parser->m_bufferPtr, &parser->m_position);
parser->m_positionPtr = parser->m_bufferPtr;
return result;
}
void *XMLCALL
XML_GetBuffer(XML_Parser parser, int len) {
if (parser == NULL)
return NULL;
if (len < 0) {
parser->m_errorCode = XML_ERROR_NO_MEMORY;
return NULL;
}
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
parser->m_errorCode = XML_ERROR_SUSPENDED;
return NULL;
case XML_FINISHED:
parser->m_errorCode = XML_ERROR_FINISHED;
return NULL;
default:;
}
if (len > EXPAT_SAFE_PTR_DIFF(parser->m_bufferLim, parser->m_bufferEnd)) {
#ifdef XML_CONTEXT_BYTES
int keep;
#endif /* defined XML_CONTEXT_BYTES */
/* Do not invoke signed arithmetic overflow: */
int neededSize = (int)((unsigned)len
+ (unsigned)EXPAT_SAFE_PTR_DIFF(
parser->m_bufferEnd, parser->m_bufferPtr));
if (neededSize < 0) {
parser->m_errorCode = XML_ERROR_NO_MEMORY;
return NULL;
}
#ifdef XML_CONTEXT_BYTES
keep = (int)EXPAT_SAFE_PTR_DIFF(parser->m_bufferPtr, parser->m_buffer);
if (keep > XML_CONTEXT_BYTES)
keep = XML_CONTEXT_BYTES;
/* Detect and prevent integer overflow */
if (keep > INT_MAX - neededSize) {
parser->m_errorCode = XML_ERROR_NO_MEMORY;
return NULL;
}
neededSize += keep;
#endif /* defined XML_CONTEXT_BYTES */
if (neededSize
<= EXPAT_SAFE_PTR_DIFF(parser->m_bufferLim, parser->m_buffer)) {
#ifdef XML_CONTEXT_BYTES
if (keep < EXPAT_SAFE_PTR_DIFF(parser->m_bufferPtr, parser->m_buffer)) {
int offset
= (int)EXPAT_SAFE_PTR_DIFF(parser->m_bufferPtr, parser->m_buffer)
- keep;
/* The buffer pointers cannot be NULL here; we have at least some bytes
* in the buffer */
memmove(parser->m_buffer, &parser->m_buffer[offset],
parser->m_bufferEnd - parser->m_bufferPtr + keep);
parser->m_bufferEnd -= offset;
parser->m_bufferPtr -= offset;
}
#else
if (parser->m_buffer && parser->m_bufferPtr) {
memmove(parser->m_buffer, parser->m_bufferPtr,
EXPAT_SAFE_PTR_DIFF(parser->m_bufferEnd, parser->m_bufferPtr));
parser->m_bufferEnd
= parser->m_buffer
+ EXPAT_SAFE_PTR_DIFF(parser->m_bufferEnd, parser->m_bufferPtr);
parser->m_bufferPtr = parser->m_buffer;
}
#endif /* not defined XML_CONTEXT_BYTES */
} else {
char *newBuf;
int bufferSize
= (int)EXPAT_SAFE_PTR_DIFF(parser->m_bufferLim, parser->m_bufferPtr);
if (bufferSize == 0)
bufferSize = INIT_BUFFER_SIZE;
do {
/* Do not invoke signed arithmetic overflow: */
bufferSize = (int)(2U * (unsigned)bufferSize);
} while (bufferSize < neededSize && bufferSize > 0);
if (bufferSize <= 0) {
parser->m_errorCode = XML_ERROR_NO_MEMORY;
return NULL;
}
newBuf = (char *)MALLOC(parser, bufferSize);
if (newBuf == 0) {
parser->m_errorCode = XML_ERROR_NO_MEMORY;
return NULL;
}
parser->m_bufferLim = newBuf + bufferSize;
#ifdef XML_CONTEXT_BYTES
if (parser->m_bufferPtr) {
memcpy(newBuf, &parser->m_bufferPtr[-keep],
EXPAT_SAFE_PTR_DIFF(parser->m_bufferEnd, parser->m_bufferPtr)
+ keep);
FREE(parser, parser->m_buffer);
parser->m_buffer = newBuf;
parser->m_bufferEnd
= parser->m_buffer
+ EXPAT_SAFE_PTR_DIFF(parser->m_bufferEnd, parser->m_bufferPtr)
+ keep;
parser->m_bufferPtr = parser->m_buffer + keep;
} else {
/* This must be a brand new buffer with no data in it yet */
parser->m_bufferEnd = newBuf;
parser->m_bufferPtr = parser->m_buffer = newBuf;
}
#else
if (parser->m_bufferPtr) {
memcpy(newBuf, parser->m_bufferPtr,
EXPAT_SAFE_PTR_DIFF(parser->m_bufferEnd, parser->m_bufferPtr));
FREE(parser, parser->m_buffer);
parser->m_bufferEnd
= newBuf
+ EXPAT_SAFE_PTR_DIFF(parser->m_bufferEnd, parser->m_bufferPtr);
} else {
/* This must be a brand new buffer with no data in it yet */
parser->m_bufferEnd = newBuf;
}
parser->m_bufferPtr = parser->m_buffer = newBuf;
#endif /* not defined XML_CONTEXT_BYTES */
}
parser->m_eventPtr = parser->m_eventEndPtr = NULL;
parser->m_positionPtr = NULL;
}
return parser->m_bufferEnd;
}
enum XML_Status XMLCALL
XML_StopParser(XML_Parser parser, XML_Bool resumable) {
if (parser == NULL)
return XML_STATUS_ERROR;
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
if (resumable) {
parser->m_errorCode = XML_ERROR_SUSPENDED;
return XML_STATUS_ERROR;
}
parser->m_parsingStatus.parsing = XML_FINISHED;
break;
case XML_FINISHED:
parser->m_errorCode = XML_ERROR_FINISHED;
return XML_STATUS_ERROR;
default:
if (resumable) {
#ifdef XML_DTD
if (parser->m_isParamEntity) {
parser->m_errorCode = XML_ERROR_SUSPEND_PE;
return XML_STATUS_ERROR;
}
#endif
parser->m_parsingStatus.parsing = XML_SUSPENDED;
} else
parser->m_parsingStatus.parsing = XML_FINISHED;
}
return XML_STATUS_OK;
}
enum XML_Status XMLCALL
XML_ResumeParser(XML_Parser parser) {
enum XML_Status result = XML_STATUS_OK;
if (parser == NULL)
return XML_STATUS_ERROR;
if (parser->m_parsingStatus.parsing != XML_SUSPENDED) {
parser->m_errorCode = XML_ERROR_NOT_SUSPENDED;
return XML_STATUS_ERROR;
}
parser->m_parsingStatus.parsing = XML_PARSING;
parser->m_errorCode = parser->m_processor(
parser, parser->m_bufferPtr, parser->m_parseEndPtr, &parser->m_bufferPtr);
if (parser->m_errorCode != XML_ERROR_NONE) {
parser->m_eventEndPtr = parser->m_eventPtr;
parser->m_processor = errorProcessor;
return XML_STATUS_ERROR;
} else {
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
result = XML_STATUS_SUSPENDED;
break;
case XML_INITIALIZED:
case XML_PARSING:
if (parser->m_parsingStatus.finalBuffer) {
parser->m_parsingStatus.parsing = XML_FINISHED;
return result;
}
default:;
}
}
XmlUpdatePosition(parser->m_encoding, parser->m_positionPtr,
parser->m_bufferPtr, &parser->m_position);
parser->m_positionPtr = parser->m_bufferPtr;
return result;
}
void XMLCALL
XML_GetParsingStatus(XML_Parser parser, XML_ParsingStatus *status) {
if (parser == NULL)
return;
assert(status != NULL);
*status = parser->m_parsingStatus;
}
enum XML_Error XMLCALL
XML_GetErrorCode(XML_Parser parser) {
if (parser == NULL)
return XML_ERROR_INVALID_ARGUMENT;
return parser->m_errorCode;
}
XML_Index XMLCALL
XML_GetCurrentByteIndex(XML_Parser parser) {
if (parser == NULL)
return -1;
if (parser->m_eventPtr)
return (XML_Index)(parser->m_parseEndByteIndex
- (parser->m_parseEndPtr - parser->m_eventPtr));
return -1;
}
int XMLCALL
XML_GetCurrentByteCount(XML_Parser parser) {
if (parser == NULL)
return 0;
if (parser->m_eventEndPtr && parser->m_eventPtr)
return (int)(parser->m_eventEndPtr - parser->m_eventPtr);
return 0;
}
const char *XMLCALL
XML_GetInputContext(XML_Parser parser, int *offset, int *size) {
#ifdef XML_CONTEXT_BYTES
if (parser == NULL)
return NULL;
if (parser->m_eventPtr && parser->m_buffer) {
if (offset != NULL)
*offset = (int)(parser->m_eventPtr - parser->m_buffer);
if (size != NULL)
*size = (int)(parser->m_bufferEnd - parser->m_buffer);
return parser->m_buffer;
}
#else
(void)parser;
(void)offset;
(void)size;
#endif /* defined XML_CONTEXT_BYTES */
return (const char *)0;
}
XML_Size XMLCALL
XML_GetCurrentLineNumber(XML_Parser parser) {
if (parser == NULL)
return 0;
if (parser->m_eventPtr && parser->m_eventPtr >= parser->m_positionPtr) {
XmlUpdatePosition(parser->m_encoding, parser->m_positionPtr,
parser->m_eventPtr, &parser->m_position);
parser->m_positionPtr = parser->m_eventPtr;
}
return parser->m_position.lineNumber + 1;
}
XML_Size XMLCALL
XML_GetCurrentColumnNumber(XML_Parser parser) {
if (parser == NULL)
return 0;
if (parser->m_eventPtr && parser->m_eventPtr >= parser->m_positionPtr) {
XmlUpdatePosition(parser->m_encoding, parser->m_positionPtr,
parser->m_eventPtr, &parser->m_position);
parser->m_positionPtr = parser->m_eventPtr;
}
return parser->m_position.columnNumber;
}
void XMLCALL
XML_FreeContentModel(XML_Parser parser, XML_Content *model) {
if (parser != NULL)
FREE(parser, model);
}
void *XMLCALL
XML_MemMalloc(XML_Parser parser, size_t size) {
if (parser == NULL)
return NULL;
return MALLOC(parser, size);
}
void *XMLCALL
XML_MemRealloc(XML_Parser parser, void *ptr, size_t size) {
if (parser == NULL)
return NULL;
return REALLOC(parser, ptr, size);
}
void XMLCALL
XML_MemFree(XML_Parser parser, void *ptr) {
if (parser != NULL)
FREE(parser, ptr);
}
void XMLCALL
XML_DefaultCurrent(XML_Parser parser) {
if (parser == NULL)
return;
if (parser->m_defaultHandler) {
if (parser->m_openInternalEntities)
reportDefault(parser, parser->m_internalEncoding,
parser->m_openInternalEntities->internalEventPtr,
parser->m_openInternalEntities->internalEventEndPtr);
else
reportDefault(parser, parser->m_encoding, parser->m_eventPtr,
parser->m_eventEndPtr);
}
}
const XML_LChar *XMLCALL
XML_ErrorString(enum XML_Error code) {
switch (code) {
case XML_ERROR_NONE:
return NULL;
case XML_ERROR_NO_MEMORY:
return XML_L("out of memory");
case XML_ERROR_SYNTAX:
return XML_L("syntax error");
case XML_ERROR_NO_ELEMENTS:
return XML_L("no element found");
case XML_ERROR_INVALID_TOKEN:
return XML_L("not well-formed (invalid token)");
case XML_ERROR_UNCLOSED_TOKEN:
return XML_L("unclosed token");
case XML_ERROR_PARTIAL_CHAR:
return XML_L("partial character");
case XML_ERROR_TAG_MISMATCH:
return XML_L("mismatched tag");
case XML_ERROR_DUPLICATE_ATTRIBUTE:
return XML_L("duplicate attribute");
case XML_ERROR_JUNK_AFTER_DOC_ELEMENT:
return XML_L("junk after document element");
case XML_ERROR_PARAM_ENTITY_REF:
return XML_L("illegal parameter entity reference");
case XML_ERROR_UNDEFINED_ENTITY:
return XML_L("undefined entity");
case XML_ERROR_RECURSIVE_ENTITY_REF:
return XML_L("recursive entity reference");
case XML_ERROR_ASYNC_ENTITY:
return XML_L("asynchronous entity");
case XML_ERROR_BAD_CHAR_REF:
return XML_L("reference to invalid character number");
case XML_ERROR_BINARY_ENTITY_REF:
return XML_L("reference to binary entity");
case XML_ERROR_ATTRIBUTE_EXTERNAL_ENTITY_REF:
return XML_L("reference to external entity in attribute");
case XML_ERROR_MISPLACED_XML_PI:
return XML_L("XML or text declaration not at start of entity");
case XML_ERROR_UNKNOWN_ENCODING:
return XML_L("unknown encoding");
case XML_ERROR_INCORRECT_ENCODING:
return XML_L("encoding specified in XML declaration is incorrect");
case XML_ERROR_UNCLOSED_CDATA_SECTION:
return XML_L("unclosed CDATA section");
case XML_ERROR_EXTERNAL_ENTITY_HANDLING:
return XML_L("error in processing external entity reference");
case XML_ERROR_NOT_STANDALONE:
return XML_L("document is not standalone");
case XML_ERROR_UNEXPECTED_STATE:
return XML_L("unexpected parser state - please send a bug report");
case XML_ERROR_ENTITY_DECLARED_IN_PE:
return XML_L("entity declared in parameter entity");
case XML_ERROR_FEATURE_REQUIRES_XML_DTD:
return XML_L("requested feature requires XML_DTD support in Expat");
case XML_ERROR_CANT_CHANGE_FEATURE_ONCE_PARSING:
return XML_L("cannot change setting once parsing has begun");
/* Added in 1.95.7. */
case XML_ERROR_UNBOUND_PREFIX:
return XML_L("unbound prefix");
/* Added in 1.95.8. */
case XML_ERROR_UNDECLARING_PREFIX:
return XML_L("must not undeclare prefix");
case XML_ERROR_INCOMPLETE_PE:
return XML_L("incomplete markup in parameter entity");
case XML_ERROR_XML_DECL:
return XML_L("XML declaration not well-formed");
case XML_ERROR_TEXT_DECL:
return XML_L("text declaration not well-formed");
case XML_ERROR_PUBLICID:
return XML_L("illegal character(s) in public id");
case XML_ERROR_SUSPENDED:
return XML_L("parser suspended");
case XML_ERROR_NOT_SUSPENDED:
return XML_L("parser not suspended");
case XML_ERROR_ABORTED:
return XML_L("parsing aborted");
case XML_ERROR_FINISHED:
return XML_L("parsing finished");
case XML_ERROR_SUSPEND_PE:
return XML_L("cannot suspend in external parameter entity");
/* Added in 2.0.0. */
case XML_ERROR_RESERVED_PREFIX_XML:
return XML_L(
"reserved prefix (xml) must not be undeclared or bound to another namespace name");
case XML_ERROR_RESERVED_PREFIX_XMLNS:
return XML_L("reserved prefix (xmlns) must not be declared or undeclared");
case XML_ERROR_RESERVED_NAMESPACE_URI:
return XML_L(
"prefix must not be bound to one of the reserved namespace names");
/* Added in 2.2.5. */
case XML_ERROR_INVALID_ARGUMENT: /* Constant added in 2.2.1, already */
return XML_L("invalid argument");
/* Added in 2.3.0. */
case XML_ERROR_NO_BUFFER:
return XML_L(
"a successful prior call to function XML_GetBuffer is required");
/* Added in 2.4.0. */
case XML_ERROR_AMPLIFICATION_LIMIT_BREACH:
return XML_L(
"limit on input amplification factor (from DTD and entities) breached");
}
return NULL;
}
const XML_LChar *XMLCALL
XML_ExpatVersion(void) {
/* V1 is used to string-ize the version number. However, it would
string-ize the actual version macro *names* unless we get them
substituted before being passed to V1. CPP is defined to expand
a macro, then rescan for more expansions. Thus, we use V2 to expand
the version macros, then CPP will expand the resulting V1() macro
with the correct numerals. */
/* ### I'm assuming cpp is portable in this respect... */
#define V1(a, b, c) XML_L(#a) XML_L(".") XML_L(#b) XML_L(".") XML_L(#c)
#define V2(a, b, c) XML_L("expat_") V1(a, b, c)
return V2(XML_MAJOR_VERSION, XML_MINOR_VERSION, XML_MICRO_VERSION);
#undef V1
#undef V2
}
XML_Expat_Version XMLCALL
XML_ExpatVersionInfo(void) {
XML_Expat_Version version;
version.major = XML_MAJOR_VERSION;
version.minor = XML_MINOR_VERSION;
version.micro = XML_MICRO_VERSION;
return version;
}
const XML_Feature *XMLCALL
XML_GetFeatureList(void) {
static const XML_Feature features[] = {
{XML_FEATURE_SIZEOF_XML_CHAR, XML_L("sizeof(XML_Char)"),
sizeof(XML_Char)},
{XML_FEATURE_SIZEOF_XML_LCHAR, XML_L("sizeof(XML_LChar)"),
sizeof(XML_LChar)},
#ifdef XML_UNICODE
{XML_FEATURE_UNICODE, XML_L("XML_UNICODE"), 0},
#endif
#ifdef XML_UNICODE_WCHAR_T
{XML_FEATURE_UNICODE_WCHAR_T, XML_L("XML_UNICODE_WCHAR_T"), 0},
#endif
#ifdef XML_DTD
{XML_FEATURE_DTD, XML_L("XML_DTD"), 0},
#endif
#ifdef XML_CONTEXT_BYTES
{XML_FEATURE_CONTEXT_BYTES, XML_L("XML_CONTEXT_BYTES"),
XML_CONTEXT_BYTES},
#endif
#ifdef XML_MIN_SIZE
{XML_FEATURE_MIN_SIZE, XML_L("XML_MIN_SIZE"), 0},
#endif
#ifdef XML_NS
{XML_FEATURE_NS, XML_L("XML_NS"), 0},
#endif
#ifdef XML_LARGE_SIZE
{XML_FEATURE_LARGE_SIZE, XML_L("XML_LARGE_SIZE"), 0},
#endif
#ifdef XML_ATTR_INFO
{XML_FEATURE_ATTR_INFO, XML_L("XML_ATTR_INFO"), 0},
#endif
#ifdef XML_DTD
/* Added in Expat 2.4.0. */
{XML_FEATURE_BILLION_LAUGHS_ATTACK_PROTECTION_MAXIMUM_AMPLIFICATION_DEFAULT,
XML_L("XML_BLAP_MAX_AMP"),
(long int)
EXPAT_BILLION_LAUGHS_ATTACK_PROTECTION_MAXIMUM_AMPLIFICATION_DEFAULT},
{XML_FEATURE_BILLION_LAUGHS_ATTACK_PROTECTION_ACTIVATION_THRESHOLD_DEFAULT,
XML_L("XML_BLAP_ACT_THRES"),
EXPAT_BILLION_LAUGHS_ATTACK_PROTECTION_ACTIVATION_THRESHOLD_DEFAULT},
#endif
{XML_FEATURE_END, NULL, 0}};
return features;
}
#ifdef XML_DTD
XML_Bool XMLCALL
XML_SetBillionLaughsAttackProtectionMaximumAmplification(
XML_Parser parser, float maximumAmplificationFactor) {
if ((parser == NULL) || (parser->m_parentParser != NULL)
|| isnan(maximumAmplificationFactor)
|| (maximumAmplificationFactor < 1.0f)) {
return XML_FALSE;
}
parser->m_accounting.maximumAmplificationFactor = maximumAmplificationFactor;
return XML_TRUE;
}
XML_Bool XMLCALL
XML_SetBillionLaughsAttackProtectionActivationThreshold(
XML_Parser parser, unsigned long long activationThresholdBytes) {
if ((parser == NULL) || (parser->m_parentParser != NULL)) {
return XML_FALSE;
}
parser->m_accounting.activationThresholdBytes = activationThresholdBytes;
return XML_TRUE;
}
#endif /* XML_DTD */
/* Initially tag->rawName always points into the parse buffer;
for those TAG instances opened while the current parse buffer was
processed, and not yet closed, we need to store tag->rawName in a more
permanent location, since the parse buffer is about to be discarded.
*/
static XML_Bool
storeRawNames(XML_Parser parser) {
TAG *tag = parser->m_tagStack;
while (tag) {
int bufSize;
int nameLen = sizeof(XML_Char) * (tag->name.strLen + 1);
size_t rawNameLen;
char *rawNameBuf = tag->buf + nameLen;
/* Stop if already stored. Since m_tagStack is a stack, we can stop
at the first entry that has already been copied; everything
below it in the stack is already been accounted for in a
previous call to this function.
*/
if (tag->rawName == rawNameBuf)
break;
/* For re-use purposes we need to ensure that the
size of tag->buf is a multiple of sizeof(XML_Char).
*/
rawNameLen = ROUND_UP(tag->rawNameLength, sizeof(XML_Char));
/* Detect and prevent integer overflow. */
if (rawNameLen > (size_t)INT_MAX - nameLen)
return XML_FALSE;
bufSize = nameLen + (int)rawNameLen;
if (bufSize > tag->bufEnd - tag->buf) {
char *temp = (char *)REALLOC(parser, tag->buf, bufSize);
if (temp == NULL)
return XML_FALSE;
/* if tag->name.str points to tag->buf (only when namespace
processing is off) then we have to update it
*/
if (tag->name.str == (XML_Char *)tag->buf)
tag->name.str = (XML_Char *)temp;
/* if tag->name.localPart is set (when namespace processing is on)
then update it as well, since it will always point into tag->buf
*/
if (tag->name.localPart)
tag->name.localPart
= (XML_Char *)temp + (tag->name.localPart - (XML_Char *)tag->buf);
tag->buf = temp;
tag->bufEnd = temp + bufSize;
rawNameBuf = temp + nameLen;
}
memcpy(rawNameBuf, tag->rawName, tag->rawNameLength);
tag->rawName = rawNameBuf;
tag = tag->parent;
}
return XML_TRUE;
}
static enum XML_Error PTRCALL
contentProcessor(XML_Parser parser, const char *start, const char *end,
const char **endPtr) {
enum XML_Error result = doContent(
parser, 0, parser->m_encoding, start, end, endPtr,
(XML_Bool)! parser->m_parsingStatus.finalBuffer, XML_ACCOUNT_DIRECT);
if (result == XML_ERROR_NONE) {
if (! storeRawNames(parser))
return XML_ERROR_NO_MEMORY;
}
return result;
}
static enum XML_Error PTRCALL
externalEntityInitProcessor(XML_Parser parser, const char *start,
const char *end, const char **endPtr) {
enum XML_Error result = initializeEncoding(parser);
if (result != XML_ERROR_NONE)
return result;
parser->m_processor = externalEntityInitProcessor2;
return externalEntityInitProcessor2(parser, start, end, endPtr);
}
static enum XML_Error PTRCALL
externalEntityInitProcessor2(XML_Parser parser, const char *start,
const char *end, const char **endPtr) {
const char *next = start; /* XmlContentTok doesn't always set the last arg */
int tok = XmlContentTok(parser->m_encoding, start, end, &next);
switch (tok) {
case XML_TOK_BOM:
#ifdef XML_DTD
if (! accountingDiffTolerated(parser, tok, start, next, __LINE__,
XML_ACCOUNT_DIRECT)) {
accountingOnAbort(parser);
return XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
}
#endif /* XML_DTD */
/* If we are at the end of the buffer, this would cause the next stage,
i.e. externalEntityInitProcessor3, to pass control directly to
doContent (by detecting XML_TOK_NONE) without processing any xml text
declaration - causing the error XML_ERROR_MISPLACED_XML_PI in doContent.
*/
if (next == end && ! parser->m_parsingStatus.finalBuffer) {
*endPtr = next;
return XML_ERROR_NONE;
}
start = next;
break;
case XML_TOK_PARTIAL:
if (! parser->m_parsingStatus.finalBuffer) {
*endPtr = start;
return XML_ERROR_NONE;
}
parser->m_eventPtr = start;
return XML_ERROR_UNCLOSED_TOKEN;
case XML_TOK_PARTIAL_CHAR:
if (! parser->m_parsingStatus.finalBuffer) {
*endPtr = start;
return XML_ERROR_NONE;
}
parser->m_eventPtr = start;
return XML_ERROR_PARTIAL_CHAR;
}
parser->m_processor = externalEntityInitProcessor3;
return externalEntityInitProcessor3(parser, start, end, endPtr);
}
static enum XML_Error PTRCALL
externalEntityInitProcessor3(XML_Parser parser, const char *start,
const char *end, const char **endPtr) {
int tok;
const char *next = start; /* XmlContentTok doesn't always set the last arg */
parser->m_eventPtr = start;
tok = XmlContentTok(parser->m_encoding, start, end, &next);
/* Note: These bytes are accounted later in:
- processXmlDecl
- externalEntityContentProcessor
*/
parser->m_eventEndPtr = next;
switch (tok) {
case XML_TOK_XML_DECL: {
enum XML_Error result;
result = processXmlDecl(parser, 1, start, next);
if (result != XML_ERROR_NONE)
return result;
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
*endPtr = next;
return XML_ERROR_NONE;
case XML_FINISHED:
return XML_ERROR_ABORTED;
default:
start = next;
}
} break;
case XML_TOK_PARTIAL:
if (! parser->m_parsingStatus.finalBuffer) {
*endPtr = start;
return XML_ERROR_NONE;
}
return XML_ERROR_UNCLOSED_TOKEN;
case XML_TOK_PARTIAL_CHAR:
if (! parser->m_parsingStatus.finalBuffer) {
*endPtr = start;
return XML_ERROR_NONE;
}
return XML_ERROR_PARTIAL_CHAR;
}
parser->m_processor = externalEntityContentProcessor;
parser->m_tagLevel = 1;
return externalEntityContentProcessor(parser, start, end, endPtr);
}
static enum XML_Error PTRCALL
externalEntityContentProcessor(XML_Parser parser, const char *start,
const char *end, const char **endPtr) {
enum XML_Error result
= doContent(parser, 1, parser->m_encoding, start, end, endPtr,
(XML_Bool)! parser->m_parsingStatus.finalBuffer,
XML_ACCOUNT_ENTITY_EXPANSION);
if (result == XML_ERROR_NONE) {
if (! storeRawNames(parser))
return XML_ERROR_NO_MEMORY;
}
return result;
}
static enum XML_Error
doContent(XML_Parser parser, int startTagLevel, const ENCODING *enc,
const char *s, const char *end, const char **nextPtr,
XML_Bool haveMore, enum XML_Account account) {
/* save one level of indirection */
DTD *const dtd = parser->m_dtd;
const char **eventPP;
const char **eventEndPP;
if (enc == parser->m_encoding) {
eventPP = &parser->m_eventPtr;
eventEndPP = &parser->m_eventEndPtr;
} else {
eventPP = &(parser->m_openInternalEntities->internalEventPtr);
eventEndPP = &(parser->m_openInternalEntities->internalEventEndPtr);
}
*eventPP = s;
for (;;) {
const char *next = s; /* XmlContentTok doesn't always set the last arg */
int tok = XmlContentTok(enc, s, end, &next);
#ifdef XML_DTD
const char *accountAfter
= ((tok == XML_TOK_TRAILING_RSQB) || (tok == XML_TOK_TRAILING_CR))
? (haveMore ? s /* i.e. 0 bytes */ : end)
: next;
if (! accountingDiffTolerated(parser, tok, s, accountAfter, __LINE__,
account)) {
accountingOnAbort(parser);
return XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
}
#endif
*eventEndPP = next;
switch (tok) {
case XML_TOK_TRAILING_CR:
if (haveMore) {
*nextPtr = s;
return XML_ERROR_NONE;
}
*eventEndPP = end;
if (parser->m_characterDataHandler) {
XML_Char c = 0xA;
parser->m_characterDataHandler(parser->m_handlerArg, &c, 1);
} else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, end);
/* We are at the end of the final buffer, should we check for
XML_SUSPENDED, XML_FINISHED?
*/
if (startTagLevel == 0)
return XML_ERROR_NO_ELEMENTS;
if (parser->m_tagLevel != startTagLevel)
return XML_ERROR_ASYNC_ENTITY;
*nextPtr = end;
return XML_ERROR_NONE;
case XML_TOK_NONE:
if (haveMore) {
*nextPtr = s;
return XML_ERROR_NONE;
}
if (startTagLevel > 0) {
if (parser->m_tagLevel != startTagLevel)
return XML_ERROR_ASYNC_ENTITY;
*nextPtr = s;
return XML_ERROR_NONE;
}
return XML_ERROR_NO_ELEMENTS;
case XML_TOK_INVALID:
*eventPP = next;
return XML_ERROR_INVALID_TOKEN;
case XML_TOK_PARTIAL:
if (haveMore) {
*nextPtr = s;
return XML_ERROR_NONE;
}
return XML_ERROR_UNCLOSED_TOKEN;
case XML_TOK_PARTIAL_CHAR:
if (haveMore) {
*nextPtr = s;
return XML_ERROR_NONE;
}
return XML_ERROR_PARTIAL_CHAR;
case XML_TOK_ENTITY_REF: {
const XML_Char *name;
ENTITY *entity;
XML_Char ch = (XML_Char)XmlPredefinedEntityName(
enc, s + enc->minBytesPerChar, next - enc->minBytesPerChar);
if (ch) {
#ifdef XML_DTD
/* NOTE: We are replacing 4-6 characters original input for 1 character
* so there is no amplification and hence recording without
* protection. */
accountingDiffTolerated(parser, tok, (char *)&ch,
((char *)&ch) + sizeof(XML_Char), __LINE__,
XML_ACCOUNT_ENTITY_EXPANSION);
#endif /* XML_DTD */
if (parser->m_characterDataHandler)
parser->m_characterDataHandler(parser->m_handlerArg, &ch, 1);
else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
break;
}
name = poolStoreString(&dtd->pool, enc, s + enc->minBytesPerChar,
next - enc->minBytesPerChar);
if (! name)
return XML_ERROR_NO_MEMORY;
entity = (ENTITY *)lookup(parser, &dtd->generalEntities, name, 0);
poolDiscard(&dtd->pool);
/* First, determine if a check for an existing declaration is needed;
if yes, check that the entity exists, and that it is internal,
otherwise call the skipped entity or default handler.
*/
if (! dtd->hasParamEntityRefs || dtd->standalone) {
if (! entity)
return XML_ERROR_UNDEFINED_ENTITY;
else if (! entity->is_internal)
return XML_ERROR_ENTITY_DECLARED_IN_PE;
} else if (! entity) {
if (parser->m_skippedEntityHandler)
parser->m_skippedEntityHandler(parser->m_handlerArg, name, 0);
else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
break;
}
if (entity->open)
return XML_ERROR_RECURSIVE_ENTITY_REF;
if (entity->notation)
return XML_ERROR_BINARY_ENTITY_REF;
if (entity->textPtr) {
enum XML_Error result;
if (! parser->m_defaultExpandInternalEntities) {
if (parser->m_skippedEntityHandler)
parser->m_skippedEntityHandler(parser->m_handlerArg, entity->name,
0);
else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
break;
}
result = processInternalEntity(parser, entity, XML_FALSE);
if (result != XML_ERROR_NONE)
return result;
} else if (parser->m_externalEntityRefHandler) {
const XML_Char *context;
entity->open = XML_TRUE;
context = getContext(parser);
entity->open = XML_FALSE;
if (! context)
return XML_ERROR_NO_MEMORY;
if (! parser->m_externalEntityRefHandler(
parser->m_externalEntityRefHandlerArg, context, entity->base,
entity->systemId, entity->publicId))
return XML_ERROR_EXTERNAL_ENTITY_HANDLING;
poolDiscard(&parser->m_tempPool);
} else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
break;
}
case XML_TOK_START_TAG_NO_ATTS:
/* fall through */
case XML_TOK_START_TAG_WITH_ATTS: {
TAG *tag;
enum XML_Error result;
XML_Char *toPtr;
if (parser->m_freeTagList) {
tag = parser->m_freeTagList;
parser->m_freeTagList = parser->m_freeTagList->parent;
} else {
tag = (TAG *)MALLOC(parser, sizeof(TAG));
if (! tag)
return XML_ERROR_NO_MEMORY;
tag->buf = (char *)MALLOC(parser, INIT_TAG_BUF_SIZE);
if (! tag->buf) {
FREE(parser, tag);
return XML_ERROR_NO_MEMORY;
}
tag->bufEnd = tag->buf + INIT_TAG_BUF_SIZE;
}
tag->bindings = NULL;
tag->parent = parser->m_tagStack;
parser->m_tagStack = tag;
tag->name.localPart = NULL;
tag->name.prefix = NULL;
tag->rawName = s + enc->minBytesPerChar;
tag->rawNameLength = XmlNameLength(enc, tag->rawName);
++parser->m_tagLevel;
{
const char *rawNameEnd = tag->rawName + tag->rawNameLength;
const char *fromPtr = tag->rawName;
toPtr = (XML_Char *)tag->buf;
for (;;) {
int bufSize;
int convLen;
const enum XML_Convert_Result convert_res
= XmlConvert(enc, &fromPtr, rawNameEnd, (ICHAR **)&toPtr,
(ICHAR *)tag->bufEnd - 1);
convLen = (int)(toPtr - (XML_Char *)tag->buf);
if ((fromPtr >= rawNameEnd)
|| (convert_res == XML_CONVERT_INPUT_INCOMPLETE)) {
tag->name.strLen = convLen;
break;
}
bufSize = (int)(tag->bufEnd - tag->buf) << 1;
{
char *temp = (char *)REALLOC(parser, tag->buf, bufSize);
if (temp == NULL)
return XML_ERROR_NO_MEMORY;
tag->buf = temp;
tag->bufEnd = temp + bufSize;
toPtr = (XML_Char *)temp + convLen;
}
}
}
tag->name.str = (XML_Char *)tag->buf;
*toPtr = XML_T('\0');
result
= storeAtts(parser, enc, s, &(tag->name), &(tag->bindings), account);
if (result)
return result;
if (parser->m_startElementHandler)
parser->m_startElementHandler(parser->m_handlerArg, tag->name.str,
(const XML_Char **)parser->m_atts);
else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
poolClear(&parser->m_tempPool);
break;
}
case XML_TOK_EMPTY_ELEMENT_NO_ATTS:
/* fall through */
case XML_TOK_EMPTY_ELEMENT_WITH_ATTS: {
const char *rawName = s + enc->minBytesPerChar;
enum XML_Error result;
BINDING *bindings = NULL;
XML_Bool noElmHandlers = XML_TRUE;
TAG_NAME name;
name.str = poolStoreString(&parser->m_tempPool, enc, rawName,
rawName + XmlNameLength(enc, rawName));
if (! name.str)
return XML_ERROR_NO_MEMORY;
poolFinish(&parser->m_tempPool);
result = storeAtts(parser, enc, s, &name, &bindings,
XML_ACCOUNT_NONE /* token spans whole start tag */);
if (result != XML_ERROR_NONE) {
freeBindings(parser, bindings);
return result;
}
poolFinish(&parser->m_tempPool);
if (parser->m_startElementHandler) {
parser->m_startElementHandler(parser->m_handlerArg, name.str,
(const XML_Char **)parser->m_atts);
noElmHandlers = XML_FALSE;
}
if (parser->m_endElementHandler) {
if (parser->m_startElementHandler)
*eventPP = *eventEndPP;
parser->m_endElementHandler(parser->m_handlerArg, name.str);
noElmHandlers = XML_FALSE;
}
if (noElmHandlers && parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
poolClear(&parser->m_tempPool);
freeBindings(parser, bindings);
}
if ((parser->m_tagLevel == 0)
&& (parser->m_parsingStatus.parsing != XML_FINISHED)) {
if (parser->m_parsingStatus.parsing == XML_SUSPENDED)
parser->m_processor = epilogProcessor;
else
return epilogProcessor(parser, next, end, nextPtr);
}
break;
case XML_TOK_END_TAG:
if (parser->m_tagLevel == startTagLevel)
return XML_ERROR_ASYNC_ENTITY;
else {
int len;
const char *rawName;
TAG *tag = parser->m_tagStack;
parser->m_tagStack = tag->parent;
tag->parent = parser->m_freeTagList;
parser->m_freeTagList = tag;
rawName = s + enc->minBytesPerChar * 2;
len = XmlNameLength(enc, rawName);
if (len != tag->rawNameLength
|| memcmp(tag->rawName, rawName, len) != 0) {
*eventPP = rawName;
return XML_ERROR_TAG_MISMATCH;
}
--parser->m_tagLevel;
if (parser->m_endElementHandler) {
const XML_Char *localPart;
const XML_Char *prefix;
XML_Char *uri;
localPart = tag->name.localPart;
if (parser->m_ns && localPart) {
/* localPart and prefix may have been overwritten in
tag->name.str, since this points to the binding->uri
buffer which gets re-used; so we have to add them again
*/
uri = (XML_Char *)tag->name.str + tag->name.uriLen;
/* don't need to check for space - already done in storeAtts() */
while (*localPart)
*uri++ = *localPart++;
prefix = (XML_Char *)tag->name.prefix;
if (parser->m_ns_triplets && prefix) {
*uri++ = parser->m_namespaceSeparator;
while (*prefix)
*uri++ = *prefix++;
}
*uri = XML_T('\0');
}
parser->m_endElementHandler(parser->m_handlerArg, tag->name.str);
} else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
while (tag->bindings) {
BINDING *b = tag->bindings;
if (parser->m_endNamespaceDeclHandler)
parser->m_endNamespaceDeclHandler(parser->m_handlerArg,
b->prefix->name);
tag->bindings = tag->bindings->nextTagBinding;
b->nextTagBinding = parser->m_freeBindingList;
parser->m_freeBindingList = b;
b->prefix->binding = b->prevPrefixBinding;
}
if ((parser->m_tagLevel == 0)
&& (parser->m_parsingStatus.parsing != XML_FINISHED)) {
if (parser->m_parsingStatus.parsing == XML_SUSPENDED)
parser->m_processor = epilogProcessor;
else
return epilogProcessor(parser, next, end, nextPtr);
}
}
break;
case XML_TOK_CHAR_REF: {
int n = XmlCharRefNumber(enc, s);
if (n < 0)
return XML_ERROR_BAD_CHAR_REF;
if (parser->m_characterDataHandler) {
XML_Char buf[XML_ENCODE_MAX];
parser->m_characterDataHandler(parser->m_handlerArg, buf,
XmlEncode(n, (ICHAR *)buf));
} else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
} break;
case XML_TOK_XML_DECL:
return XML_ERROR_MISPLACED_XML_PI;
case XML_TOK_DATA_NEWLINE:
if (parser->m_characterDataHandler) {
XML_Char c = 0xA;
parser->m_characterDataHandler(parser->m_handlerArg, &c, 1);
} else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
break;
case XML_TOK_CDATA_SECT_OPEN: {
enum XML_Error result;
if (parser->m_startCdataSectionHandler)
parser->m_startCdataSectionHandler(parser->m_handlerArg);
/* BEGIN disabled code */
/* Suppose you doing a transformation on a document that involves
changing only the character data. You set up a defaultHandler
and a characterDataHandler. The defaultHandler simply copies
characters through. The characterDataHandler does the
transformation and writes the characters out escaping them as
necessary. This case will fail to work if we leave out the
following two lines (because & and < inside CDATA sections will
be incorrectly escaped).
However, now we have a start/endCdataSectionHandler, so it seems
easier to let the user deal with this.
*/
else if (0 && parser->m_characterDataHandler)
parser->m_characterDataHandler(parser->m_handlerArg, parser->m_dataBuf,
0);
/* END disabled code */
else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
result
= doCdataSection(parser, enc, &next, end, nextPtr, haveMore, account);
if (result != XML_ERROR_NONE)
return result;
else if (! next) {
parser->m_processor = cdataSectionProcessor;
return result;
}
} break;
case XML_TOK_TRAILING_RSQB:
if (haveMore) {
*nextPtr = s;
return XML_ERROR_NONE;
}
if (parser->m_characterDataHandler) {
if (MUST_CONVERT(enc, s)) {
ICHAR *dataPtr = (ICHAR *)parser->m_dataBuf;
XmlConvert(enc, &s, end, &dataPtr, (ICHAR *)parser->m_dataBufEnd);
parser->m_characterDataHandler(
parser->m_handlerArg, parser->m_dataBuf,
(int)(dataPtr - (ICHAR *)parser->m_dataBuf));
} else
parser->m_characterDataHandler(
parser->m_handlerArg, (XML_Char *)s,
(int)((XML_Char *)end - (XML_Char *)s));
} else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, end);
/* We are at the end of the final buffer, should we check for
XML_SUSPENDED, XML_FINISHED?
*/
if (startTagLevel == 0) {
*eventPP = end;
return XML_ERROR_NO_ELEMENTS;
}
if (parser->m_tagLevel != startTagLevel) {
*eventPP = end;
return XML_ERROR_ASYNC_ENTITY;
}
*nextPtr = end;
return XML_ERROR_NONE;
case XML_TOK_DATA_CHARS: {
XML_CharacterDataHandler charDataHandler = parser->m_characterDataHandler;
if (charDataHandler) {
if (MUST_CONVERT(enc, s)) {
for (;;) {
ICHAR *dataPtr = (ICHAR *)parser->m_dataBuf;
const enum XML_Convert_Result convert_res = XmlConvert(
enc, &s, next, &dataPtr, (ICHAR *)parser->m_dataBufEnd);
*eventEndPP = s;
charDataHandler(parser->m_handlerArg, parser->m_dataBuf,
(int)(dataPtr - (ICHAR *)parser->m_dataBuf));
if ((convert_res == XML_CONVERT_COMPLETED)
|| (convert_res == XML_CONVERT_INPUT_INCOMPLETE))
break;
*eventPP = s;
}
} else
charDataHandler(parser->m_handlerArg, (XML_Char *)s,
(int)((XML_Char *)next - (XML_Char *)s));
} else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
} break;
case XML_TOK_PI:
if (! reportProcessingInstruction(parser, enc, s, next))
return XML_ERROR_NO_MEMORY;
break;
case XML_TOK_COMMENT:
if (! reportComment(parser, enc, s, next))
return XML_ERROR_NO_MEMORY;
break;
default:
/* All of the tokens produced by XmlContentTok() have their own
* explicit cases, so this default is not strictly necessary.
* However it is a useful safety net, so we retain the code and
* simply exclude it from the coverage tests.
*
* LCOV_EXCL_START
*/
if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
break;
/* LCOV_EXCL_STOP */
}
*eventPP = s = next;
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
*nextPtr = next;
return XML_ERROR_NONE;
case XML_FINISHED:
return XML_ERROR_ABORTED;
default:;
}
}
/* not reached */
}
/* This function does not call free() on the allocated memory, merely
* moving it to the parser's m_freeBindingList where it can be freed or
* reused as appropriate.
*/
static void
freeBindings(XML_Parser parser, BINDING *bindings) {
while (bindings) {
BINDING *b = bindings;
/* m_startNamespaceDeclHandler will have been called for this
* binding in addBindings(), so call the end handler now.
*/
if (parser->m_endNamespaceDeclHandler)
parser->m_endNamespaceDeclHandler(parser->m_handlerArg, b->prefix->name);
bindings = bindings->nextTagBinding;
b->nextTagBinding = parser->m_freeBindingList;
parser->m_freeBindingList = b;
b->prefix->binding = b->prevPrefixBinding;
}
}
/* Precondition: all arguments must be non-NULL;
Purpose:
- normalize attributes
- check attributes for well-formedness
- generate namespace aware attribute names (URI, prefix)
- build list of attributes for startElementHandler
- default attributes
- process namespace declarations (check and report them)
- generate namespace aware element name (URI, prefix)
*/
static enum XML_Error
storeAtts(XML_Parser parser, const ENCODING *enc, const char *attStr,
TAG_NAME *tagNamePtr, BINDING **bindingsPtr,
enum XML_Account account) {
DTD *const dtd = parser->m_dtd; /* save one level of indirection */
ELEMENT_TYPE *elementType;
int nDefaultAtts;
const XML_Char **appAtts; /* the attribute list for the application */
int attIndex = 0;
int prefixLen;
int i;
int n;
XML_Char *uri;
int nPrefixes = 0;
BINDING *binding;
const XML_Char *localPart;
/* lookup the element type name */
elementType
= (ELEMENT_TYPE *)lookup(parser, &dtd->elementTypes, tagNamePtr->str, 0);
if (! elementType) {
const XML_Char *name = poolCopyString(&dtd->pool, tagNamePtr->str);
if (! name)
return XML_ERROR_NO_MEMORY;
elementType = (ELEMENT_TYPE *)lookup(parser, &dtd->elementTypes, name,
sizeof(ELEMENT_TYPE));
if (! elementType)
return XML_ERROR_NO_MEMORY;
if (parser->m_ns && ! setElementTypePrefix(parser, elementType))
return XML_ERROR_NO_MEMORY;
}
nDefaultAtts = elementType->nDefaultAtts;
/* get the attributes from the tokenizer */
n = XmlGetAttributes(enc, attStr, parser->m_attsSize, parser->m_atts);
/* Detect and prevent integer overflow */
if (n > INT_MAX - nDefaultAtts) {
return XML_ERROR_NO_MEMORY;
}
if (n + nDefaultAtts > parser->m_attsSize) {
int oldAttsSize = parser->m_attsSize;
ATTRIBUTE *temp;
#ifdef XML_ATTR_INFO
XML_AttrInfo *temp2;
#endif
/* Detect and prevent integer overflow */
if ((nDefaultAtts > INT_MAX - INIT_ATTS_SIZE)
|| (n > INT_MAX - (nDefaultAtts + INIT_ATTS_SIZE))) {
return XML_ERROR_NO_MEMORY;
}
parser->m_attsSize = n + nDefaultAtts + INIT_ATTS_SIZE;
/* Detect and prevent integer overflow.
* The preprocessor guard addresses the "always false" warning
* from -Wtype-limits on platforms where
* sizeof(unsigned int) < sizeof(size_t), e.g. on x86_64. */
#if UINT_MAX >= SIZE_MAX
if ((unsigned)parser->m_attsSize > (size_t)(-1) / sizeof(ATTRIBUTE)) {
parser->m_attsSize = oldAttsSize;
return XML_ERROR_NO_MEMORY;
}
#endif
temp = (ATTRIBUTE *)REALLOC(parser, (void *)parser->m_atts,
parser->m_attsSize * sizeof(ATTRIBUTE));
if (temp == NULL) {
parser->m_attsSize = oldAttsSize;
return XML_ERROR_NO_MEMORY;
}
parser->m_atts = temp;
#ifdef XML_ATTR_INFO
/* Detect and prevent integer overflow.
* The preprocessor guard addresses the "always false" warning
* from -Wtype-limits on platforms where
* sizeof(unsigned int) < sizeof(size_t), e.g. on x86_64. */
# if UINT_MAX >= SIZE_MAX
if ((unsigned)parser->m_attsSize > (size_t)(-1) / sizeof(XML_AttrInfo)) {
parser->m_attsSize = oldAttsSize;
return XML_ERROR_NO_MEMORY;
}
# endif
temp2 = (XML_AttrInfo *)REALLOC(parser, (void *)parser->m_attInfo,
parser->m_attsSize * sizeof(XML_AttrInfo));
if (temp2 == NULL) {
parser->m_attsSize = oldAttsSize;
return XML_ERROR_NO_MEMORY;
}
parser->m_attInfo = temp2;
#endif
if (n > oldAttsSize)
XmlGetAttributes(enc, attStr, n, parser->m_atts);
}
appAtts = (const XML_Char **)parser->m_atts;
for (i = 0; i < n; i++) {
ATTRIBUTE *currAtt = &parser->m_atts[i];
#ifdef XML_ATTR_INFO
XML_AttrInfo *currAttInfo = &parser->m_attInfo[i];
#endif
/* add the name and value to the attribute list */
ATTRIBUTE_ID *attId
= getAttributeId(parser, enc, currAtt->name,
currAtt->name + XmlNameLength(enc, currAtt->name));
if (! attId)
return XML_ERROR_NO_MEMORY;
#ifdef XML_ATTR_INFO
currAttInfo->nameStart
= parser->m_parseEndByteIndex - (parser->m_parseEndPtr - currAtt->name);
currAttInfo->nameEnd
= currAttInfo->nameStart + XmlNameLength(enc, currAtt->name);
currAttInfo->valueStart = parser->m_parseEndByteIndex
- (parser->m_parseEndPtr - currAtt->valuePtr);
currAttInfo->valueEnd = parser->m_parseEndByteIndex
- (parser->m_parseEndPtr - currAtt->valueEnd);
#endif
/* Detect duplicate attributes by their QNames. This does not work when
namespace processing is turned on and different prefixes for the same
namespace are used. For this case we have a check further down.
*/
if ((attId->name)[-1]) {
if (enc == parser->m_encoding)
parser->m_eventPtr = parser->m_atts[i].name;
return XML_ERROR_DUPLICATE_ATTRIBUTE;
}
(attId->name)[-1] = 1;
appAtts[attIndex++] = attId->name;
if (! parser->m_atts[i].normalized) {
enum XML_Error result;
XML_Bool isCdata = XML_TRUE;
/* figure out whether declared as other than CDATA */
if (attId->maybeTokenized) {
int j;
for (j = 0; j < nDefaultAtts; j++) {
if (attId == elementType->defaultAtts[j].id) {
isCdata = elementType->defaultAtts[j].isCdata;
break;
}
}
}
/* normalize the attribute value */
result = storeAttributeValue(
parser, enc, isCdata, parser->m_atts[i].valuePtr,
parser->m_atts[i].valueEnd, &parser->m_tempPool, account);
if (result)
return result;
appAtts[attIndex] = poolStart(&parser->m_tempPool);
poolFinish(&parser->m_tempPool);
} else {
/* the value did not need normalizing */
appAtts[attIndex] = poolStoreString(&parser->m_tempPool, enc,
parser->m_atts[i].valuePtr,
parser->m_atts[i].valueEnd);
if (appAtts[attIndex] == 0)
return XML_ERROR_NO_MEMORY;
poolFinish(&parser->m_tempPool);
}
/* handle prefixed attribute names */
if (attId->prefix) {
if (attId->xmlns) {
/* deal with namespace declarations here */
enum XML_Error result = addBinding(parser, attId->prefix, attId,
appAtts[attIndex], bindingsPtr);
if (result)
return result;
--attIndex;
} else {
/* deal with other prefixed names later */
attIndex++;
nPrefixes++;
(attId->name)[-1] = 2;
}
} else
attIndex++;
}
/* set-up for XML_GetSpecifiedAttributeCount and XML_GetIdAttributeIndex */
parser->m_nSpecifiedAtts = attIndex;
if (elementType->idAtt && (elementType->idAtt->name)[-1]) {
for (i = 0; i < attIndex; i += 2)
if (appAtts[i] == elementType->idAtt->name) {
parser->m_idAttIndex = i;
break;
}
} else
parser->m_idAttIndex = -1;
/* do attribute defaulting */
for (i = 0; i < nDefaultAtts; i++) {
const DEFAULT_ATTRIBUTE *da = elementType->defaultAtts + i;
if (! (da->id->name)[-1] && da->value) {
if (da->id->prefix) {
if (da->id->xmlns) {
enum XML_Error result = addBinding(parser, da->id->prefix, da->id,
da->value, bindingsPtr);
if (result)
return result;
} else {
(da->id->name)[-1] = 2;
nPrefixes++;
appAtts[attIndex++] = da->id->name;
appAtts[attIndex++] = da->value;
}
} else {
(da->id->name)[-1] = 1;
appAtts[attIndex++] = da->id->name;
appAtts[attIndex++] = da->value;
}
}
}
appAtts[attIndex] = 0;
/* expand prefixed attribute names, check for duplicates,
and clear flags that say whether attributes were specified */
i = 0;
if (nPrefixes) {
int j; /* hash table index */
unsigned long version = parser->m_nsAttsVersion;
/* Detect and prevent invalid shift */
if (parser->m_nsAttsPower >= sizeof(unsigned int) * 8 /* bits per byte */) {
return XML_ERROR_NO_MEMORY;
}
unsigned int nsAttsSize = 1u << parser->m_nsAttsPower;
unsigned char oldNsAttsPower = parser->m_nsAttsPower;
/* size of hash table must be at least 2 * (# of prefixed attributes) */
if ((nPrefixes << 1)
>> parser->m_nsAttsPower) { /* true for m_nsAttsPower = 0 */
NS_ATT *temp;
/* hash table size must also be a power of 2 and >= 8 */
while (nPrefixes >> parser->m_nsAttsPower++)
;
if (parser->m_nsAttsPower < 3)
parser->m_nsAttsPower = 3;
/* Detect and prevent invalid shift */
if (parser->m_nsAttsPower >= sizeof(nsAttsSize) * 8 /* bits per byte */) {
/* Restore actual size of memory in m_nsAtts */
parser->m_nsAttsPower = oldNsAttsPower;
return XML_ERROR_NO_MEMORY;
}
nsAttsSize = 1u << parser->m_nsAttsPower;
/* Detect and prevent integer overflow.
* The preprocessor guard addresses the "always false" warning
* from -Wtype-limits on platforms where
* sizeof(unsigned int) < sizeof(size_t), e.g. on x86_64. */
#if UINT_MAX >= SIZE_MAX
if (nsAttsSize > (size_t)(-1) / sizeof(NS_ATT)) {
/* Restore actual size of memory in m_nsAtts */
parser->m_nsAttsPower = oldNsAttsPower;
return XML_ERROR_NO_MEMORY;
}
#endif
temp = (NS_ATT *)REALLOC(parser, parser->m_nsAtts,
nsAttsSize * sizeof(NS_ATT));
if (! temp) {
/* Restore actual size of memory in m_nsAtts */
parser->m_nsAttsPower = oldNsAttsPower;
return XML_ERROR_NO_MEMORY;
}
parser->m_nsAtts = temp;
version = 0; /* force re-initialization of m_nsAtts hash table */
}
/* using a version flag saves us from initializing m_nsAtts every time */
if (! version) { /* initialize version flags when version wraps around */
version = INIT_ATTS_VERSION;
for (j = nsAttsSize; j != 0;)
parser->m_nsAtts[--j].version = version;
}
parser->m_nsAttsVersion = --version;
/* expand prefixed names and check for duplicates */
for (; i < attIndex; i += 2) {
const XML_Char *s = appAtts[i];
if (s[-1] == 2) { /* prefixed */
ATTRIBUTE_ID *id;
const BINDING *b;
unsigned long uriHash;
struct siphash sip_state;
struct sipkey sip_key;
copy_salt_to_sipkey(parser, &sip_key);
sip24_init(&sip_state, &sip_key);
((XML_Char *)s)[-1] = 0; /* clear flag */
id = (ATTRIBUTE_ID *)lookup(parser, &dtd->attributeIds, s, 0);
if (! id || ! id->prefix) {
/* This code is walking through the appAtts array, dealing
* with (in this case) a prefixed attribute name. To be in
* the array, the attribute must have already been bound, so
* has to have passed through the hash table lookup once
* already. That implies that an entry for it already
* exists, so the lookup above will return a pointer to
* already allocated memory. There is no opportunaity for
* the allocator to fail, so the condition above cannot be
* fulfilled.
*
* Since it is difficult to be certain that the above
* analysis is complete, we retain the test and merely
* remove the code from coverage tests.
*/
return XML_ERROR_NO_MEMORY; /* LCOV_EXCL_LINE */
}
b = id->prefix->binding;
if (! b)
return XML_ERROR_UNBOUND_PREFIX;
for (j = 0; j < b->uriLen; j++) {
const XML_Char c = b->uri[j];
if (! poolAppendChar(&parser->m_tempPool, c))
return XML_ERROR_NO_MEMORY;
}
sip24_update(&sip_state, b->uri, b->uriLen * sizeof(XML_Char));
while (*s++ != XML_T(ASCII_COLON))
;
sip24_update(&sip_state, s, keylen(s) * sizeof(XML_Char));
do { /* copies null terminator */
if (! poolAppendChar(&parser->m_tempPool, *s))
return XML_ERROR_NO_MEMORY;
} while (*s++);
uriHash = (unsigned long)sip24_final(&sip_state);
{ /* Check hash table for duplicate of expanded name (uriName).
Derived from code in lookup(parser, HASH_TABLE *table, ...).
*/
unsigned char step = 0;
unsigned long mask = nsAttsSize - 1;
j = uriHash & mask; /* index into hash table */
while (parser->m_nsAtts[j].version == version) {
/* for speed we compare stored hash values first */
if (uriHash == parser->m_nsAtts[j].hash) {
const XML_Char *s1 = poolStart(&parser->m_tempPool);
const XML_Char *s2 = parser->m_nsAtts[j].uriName;
/* s1 is null terminated, but not s2 */
for (; *s1 == *s2 && *s1 != 0; s1++, s2++)
;
if (*s1 == 0)
return XML_ERROR_DUPLICATE_ATTRIBUTE;
}
if (! step)
step = PROBE_STEP(uriHash, mask, parser->m_nsAttsPower);
j < step ? (j += nsAttsSize - step) : (j -= step);
}
}
if (parser->m_ns_triplets) { /* append namespace separator and prefix */
parser->m_tempPool.ptr[-1] = parser->m_namespaceSeparator;
s = b->prefix->name;
do {
if (! poolAppendChar(&parser->m_tempPool, *s))
return XML_ERROR_NO_MEMORY;
} while (*s++);
}
/* store expanded name in attribute list */
s = poolStart(&parser->m_tempPool);
poolFinish(&parser->m_tempPool);
appAtts[i] = s;
/* fill empty slot with new version, uriName and hash value */
parser->m_nsAtts[j].version = version;
parser->m_nsAtts[j].hash = uriHash;
parser->m_nsAtts[j].uriName = s;
if (! --nPrefixes) {
i += 2;
break;
}
} else /* not prefixed */
((XML_Char *)s)[-1] = 0; /* clear flag */
}
}
/* clear flags for the remaining attributes */
for (; i < attIndex; i += 2)
((XML_Char *)(appAtts[i]))[-1] = 0;
for (binding = *bindingsPtr; binding; binding = binding->nextTagBinding)
binding->attId->name[-1] = 0;
if (! parser->m_ns)
return XML_ERROR_NONE;
/* expand the element type name */
if (elementType->prefix) {
binding = elementType->prefix->binding;
if (! binding)
return XML_ERROR_UNBOUND_PREFIX;
localPart = tagNamePtr->str;
while (*localPart++ != XML_T(ASCII_COLON))
;
} else if (dtd->defaultPrefix.binding) {
binding = dtd->defaultPrefix.binding;
localPart = tagNamePtr->str;
} else
return XML_ERROR_NONE;
prefixLen = 0;
if (parser->m_ns_triplets && binding->prefix->name) {
for (; binding->prefix->name[prefixLen++];)
; /* prefixLen includes null terminator */
}
tagNamePtr->localPart = localPart;
tagNamePtr->uriLen = binding->uriLen;
tagNamePtr->prefix = binding->prefix->name;
tagNamePtr->prefixLen = prefixLen;
for (i = 0; localPart[i++];)
; /* i includes null terminator */
/* Detect and prevent integer overflow */
if (binding->uriLen > INT_MAX - prefixLen
|| i > INT_MAX - (binding->uriLen + prefixLen)) {
return XML_ERROR_NO_MEMORY;
}
n = i + binding->uriLen + prefixLen;
if (n > binding->uriAlloc) {
TAG *p;
/* Detect and prevent integer overflow */
if (n > INT_MAX - EXPAND_SPARE) {
return XML_ERROR_NO_MEMORY;
}
/* Detect and prevent integer overflow.
* The preprocessor guard addresses the "always false" warning
* from -Wtype-limits on platforms where
* sizeof(unsigned int) < sizeof(size_t), e.g. on x86_64. */
#if UINT_MAX >= SIZE_MAX
if ((unsigned)(n + EXPAND_SPARE) > (size_t)(-1) / sizeof(XML_Char)) {
return XML_ERROR_NO_MEMORY;
}
#endif
uri = (XML_Char *)MALLOC(parser, (n + EXPAND_SPARE) * sizeof(XML_Char));
if (! uri)
return XML_ERROR_NO_MEMORY;
binding->uriAlloc = n + EXPAND_SPARE;
memcpy(uri, binding->uri, binding->uriLen * sizeof(XML_Char));
for (p = parser->m_tagStack; p; p = p->parent)
if (p->name.str == binding->uri)
p->name.str = uri;
FREE(parser, binding->uri);
binding->uri = uri;
}
/* if m_namespaceSeparator != '\0' then uri includes it already */
uri = binding->uri + binding->uriLen;
memcpy(uri, localPart, i * sizeof(XML_Char));
/* we always have a namespace separator between localPart and prefix */
if (prefixLen) {
uri += i - 1;
*uri = parser->m_namespaceSeparator; /* replace null terminator */
memcpy(uri + 1, binding->prefix->name, prefixLen * sizeof(XML_Char));
}
tagNamePtr->str = binding->uri;
return XML_ERROR_NONE;
}
/* addBinding() overwrites the value of prefix->binding without checking.
Therefore one must keep track of the old value outside of addBinding().
*/
static enum XML_Error
addBinding(XML_Parser parser, PREFIX *prefix, const ATTRIBUTE_ID *attId,
const XML_Char *uri, BINDING **bindingsPtr) {
static const XML_Char xmlNamespace[]
= {ASCII_h, ASCII_t, ASCII_t, ASCII_p, ASCII_COLON,
ASCII_SLASH, ASCII_SLASH, ASCII_w, ASCII_w, ASCII_w,
ASCII_PERIOD, ASCII_w, ASCII_3, ASCII_PERIOD, ASCII_o,
ASCII_r, ASCII_g, ASCII_SLASH, ASCII_X, ASCII_M,
ASCII_L, ASCII_SLASH, ASCII_1, ASCII_9, ASCII_9,
ASCII_8, ASCII_SLASH, ASCII_n, ASCII_a, ASCII_m,
ASCII_e, ASCII_s, ASCII_p, ASCII_a, ASCII_c,
ASCII_e, '\0'};
static const int xmlLen = (int)sizeof(xmlNamespace) / sizeof(XML_Char) - 1;
static const XML_Char xmlnsNamespace[]
= {ASCII_h, ASCII_t, ASCII_t, ASCII_p, ASCII_COLON, ASCII_SLASH,
ASCII_SLASH, ASCII_w, ASCII_w, ASCII_w, ASCII_PERIOD, ASCII_w,
ASCII_3, ASCII_PERIOD, ASCII_o, ASCII_r, ASCII_g, ASCII_SLASH,
ASCII_2, ASCII_0, ASCII_0, ASCII_0, ASCII_SLASH, ASCII_x,
ASCII_m, ASCII_l, ASCII_n, ASCII_s, ASCII_SLASH, '\0'};
static const int xmlnsLen
= (int)sizeof(xmlnsNamespace) / sizeof(XML_Char) - 1;
XML_Bool mustBeXML = XML_FALSE;
XML_Bool isXML = XML_TRUE;
XML_Bool isXMLNS = XML_TRUE;
BINDING *b;
int len;
/* empty URI is only valid for default namespace per XML NS 1.0 (not 1.1) */
if (*uri == XML_T('\0') && prefix->name)
return XML_ERROR_UNDECLARING_PREFIX;
if (prefix->name && prefix->name[0] == XML_T(ASCII_x)
&& prefix->name[1] == XML_T(ASCII_m)
&& prefix->name[2] == XML_T(ASCII_l)) {
/* Not allowed to bind xmlns */
if (prefix->name[3] == XML_T(ASCII_n) && prefix->name[4] == XML_T(ASCII_s)
&& prefix->name[5] == XML_T('\0'))
return XML_ERROR_RESERVED_PREFIX_XMLNS;
if (prefix->name[3] == XML_T('\0'))
mustBeXML = XML_TRUE;
}
for (len = 0; uri[len]; len++) {
if (isXML && (len > xmlLen || uri[len] != xmlNamespace[len]))
isXML = XML_FALSE;
if (! mustBeXML && isXMLNS
&& (len > xmlnsLen || uri[len] != xmlnsNamespace[len]))
isXMLNS = XML_FALSE;
// NOTE: While Expat does not validate namespace URIs against RFC 3986,
// we have to at least make sure that the XML processor on top of
// Expat (that is splitting tag names by namespace separator into
// 2- or 3-tuples (uri-local or uri-local-prefix)) cannot be confused
// by an attacker putting additional namespace separator characters
// into namespace declarations. That would be ambiguous and not to
// be expected.
if (parser->m_ns && (uri[len] == parser->m_namespaceSeparator)) {
return XML_ERROR_SYNTAX;
}
}
isXML = isXML && len == xmlLen;
isXMLNS = isXMLNS && len == xmlnsLen;
if (mustBeXML != isXML)
return mustBeXML ? XML_ERROR_RESERVED_PREFIX_XML
: XML_ERROR_RESERVED_NAMESPACE_URI;
if (isXMLNS)
return XML_ERROR_RESERVED_NAMESPACE_URI;
if (parser->m_namespaceSeparator)
len++;
if (parser->m_freeBindingList) {
b = parser->m_freeBindingList;
if (len > b->uriAlloc) {
/* Detect and prevent integer overflow */
if (len > INT_MAX - EXPAND_SPARE) {
return XML_ERROR_NO_MEMORY;
}
/* Detect and prevent integer overflow.
* The preprocessor guard addresses the "always false" warning
* from -Wtype-limits on platforms where
* sizeof(unsigned int) < sizeof(size_t), e.g. on x86_64. */
#if UINT_MAX >= SIZE_MAX
if ((unsigned)(len + EXPAND_SPARE) > (size_t)(-1) / sizeof(XML_Char)) {
return XML_ERROR_NO_MEMORY;
}
#endif
XML_Char *temp = (XML_Char *)REALLOC(
parser, b->uri, sizeof(XML_Char) * (len + EXPAND_SPARE));
if (temp == NULL)
return XML_ERROR_NO_MEMORY;
b->uri = temp;
b->uriAlloc = len + EXPAND_SPARE;
}
parser->m_freeBindingList = b->nextTagBinding;
} else {
b = (BINDING *)MALLOC(parser, sizeof(BINDING));
if (! b)
return XML_ERROR_NO_MEMORY;
/* Detect and prevent integer overflow */
if (len > INT_MAX - EXPAND_SPARE) {
return XML_ERROR_NO_MEMORY;
}
/* Detect and prevent integer overflow.
* The preprocessor guard addresses the "always false" warning
* from -Wtype-limits on platforms where
* sizeof(unsigned int) < sizeof(size_t), e.g. on x86_64. */
#if UINT_MAX >= SIZE_MAX
if ((unsigned)(len + EXPAND_SPARE) > (size_t)(-1) / sizeof(XML_Char)) {
return XML_ERROR_NO_MEMORY;
}
#endif
b->uri
= (XML_Char *)MALLOC(parser, sizeof(XML_Char) * (len + EXPAND_SPARE));
if (! b->uri) {
FREE(parser, b);
return XML_ERROR_NO_MEMORY;
}
b->uriAlloc = len + EXPAND_SPARE;
}
b->uriLen = len;
memcpy(b->uri, uri, len * sizeof(XML_Char));
if (parser->m_namespaceSeparator)
b->uri[len - 1] = parser->m_namespaceSeparator;
b->prefix = prefix;
b->attId = attId;
b->prevPrefixBinding = prefix->binding;
/* NULL binding when default namespace undeclared */
if (*uri == XML_T('\0') && prefix == &parser->m_dtd->defaultPrefix)
prefix->binding = NULL;
else
prefix->binding = b;
b->nextTagBinding = *bindingsPtr;
*bindingsPtr = b;
/* if attId == NULL then we are not starting a namespace scope */
if (attId && parser->m_startNamespaceDeclHandler)
parser->m_startNamespaceDeclHandler(parser->m_handlerArg, prefix->name,
prefix->binding ? uri : 0);
return XML_ERROR_NONE;
}
/* The idea here is to avoid using stack for each CDATA section when
the whole file is parsed with one call.
*/
static enum XML_Error PTRCALL
cdataSectionProcessor(XML_Parser parser, const char *start, const char *end,
const char **endPtr) {
enum XML_Error result = doCdataSection(
parser, parser->m_encoding, &start, end, endPtr,
(XML_Bool)! parser->m_parsingStatus.finalBuffer, XML_ACCOUNT_DIRECT);
if (result != XML_ERROR_NONE)
return result;
if (start) {
if (parser->m_parentParser) { /* we are parsing an external entity */
parser->m_processor = externalEntityContentProcessor;
return externalEntityContentProcessor(parser, start, end, endPtr);
} else {
parser->m_processor = contentProcessor;
return contentProcessor(parser, start, end, endPtr);
}
}
return result;
}
/* startPtr gets set to non-null if the section is closed, and to null if
the section is not yet closed.
*/
static enum XML_Error
doCdataSection(XML_Parser parser, const ENCODING *enc, const char **startPtr,
const char *end, const char **nextPtr, XML_Bool haveMore,
enum XML_Account account) {
const char *s = *startPtr;
const char **eventPP;
const char **eventEndPP;
if (enc == parser->m_encoding) {
eventPP = &parser->m_eventPtr;
*eventPP = s;
eventEndPP = &parser->m_eventEndPtr;
} else {
eventPP = &(parser->m_openInternalEntities->internalEventPtr);
eventEndPP = &(parser->m_openInternalEntities->internalEventEndPtr);
}
*eventPP = s;
*startPtr = NULL;
for (;;) {
const char *next = s; /* in case of XML_TOK_NONE or XML_TOK_PARTIAL */
int tok = XmlCdataSectionTok(enc, s, end, &next);
#ifdef XML_DTD
if (! accountingDiffTolerated(parser, tok, s, next, __LINE__, account)) {
accountingOnAbort(parser);
return XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
}
#else
UNUSED_P(account);
#endif
*eventEndPP = next;
switch (tok) {
case XML_TOK_CDATA_SECT_CLOSE:
if (parser->m_endCdataSectionHandler)
parser->m_endCdataSectionHandler(parser->m_handlerArg);
/* BEGIN disabled code */
/* see comment under XML_TOK_CDATA_SECT_OPEN */
else if (0 && parser->m_characterDataHandler)
parser->m_characterDataHandler(parser->m_handlerArg, parser->m_dataBuf,
0);
/* END disabled code */
else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
*startPtr = next;
*nextPtr = next;
if (parser->m_parsingStatus.parsing == XML_FINISHED)
return XML_ERROR_ABORTED;
else
return XML_ERROR_NONE;
case XML_TOK_DATA_NEWLINE:
if (parser->m_characterDataHandler) {
XML_Char c = 0xA;
parser->m_characterDataHandler(parser->m_handlerArg, &c, 1);
} else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
break;
case XML_TOK_DATA_CHARS: {
XML_CharacterDataHandler charDataHandler = parser->m_characterDataHandler;
if (charDataHandler) {
if (MUST_CONVERT(enc, s)) {
for (;;) {
ICHAR *dataPtr = (ICHAR *)parser->m_dataBuf;
const enum XML_Convert_Result convert_res = XmlConvert(
enc, &s, next, &dataPtr, (ICHAR *)parser->m_dataBufEnd);
*eventEndPP = next;
charDataHandler(parser->m_handlerArg, parser->m_dataBuf,
(int)(dataPtr - (ICHAR *)parser->m_dataBuf));
if ((convert_res == XML_CONVERT_COMPLETED)
|| (convert_res == XML_CONVERT_INPUT_INCOMPLETE))
break;
*eventPP = s;
}
} else
charDataHandler(parser->m_handlerArg, (XML_Char *)s,
(int)((XML_Char *)next - (XML_Char *)s));
} else if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
} break;
case XML_TOK_INVALID:
*eventPP = next;
return XML_ERROR_INVALID_TOKEN;
case XML_TOK_PARTIAL_CHAR:
if (haveMore) {
*nextPtr = s;
return XML_ERROR_NONE;
}
return XML_ERROR_PARTIAL_CHAR;
case XML_TOK_PARTIAL:
case XML_TOK_NONE:
if (haveMore) {
*nextPtr = s;
return XML_ERROR_NONE;
}
return XML_ERROR_UNCLOSED_CDATA_SECTION;
default:
/* Every token returned by XmlCdataSectionTok() has its own
* explicit case, so this default case will never be executed.
* We retain it as a safety net and exclude it from the coverage
* statistics.
*
* LCOV_EXCL_START
*/
*eventPP = next;
return XML_ERROR_UNEXPECTED_STATE;
/* LCOV_EXCL_STOP */
}
*eventPP = s = next;
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
*nextPtr = next;
return XML_ERROR_NONE;
case XML_FINISHED:
return XML_ERROR_ABORTED;
default:;
}
}
/* not reached */
}
#ifdef XML_DTD
/* The idea here is to avoid using stack for each IGNORE section when
the whole file is parsed with one call.
*/
static enum XML_Error PTRCALL
ignoreSectionProcessor(XML_Parser parser, const char *start, const char *end,
const char **endPtr) {
enum XML_Error result
= doIgnoreSection(parser, parser->m_encoding, &start, end, endPtr,
(XML_Bool)! parser->m_parsingStatus.finalBuffer);
if (result != XML_ERROR_NONE)
return result;
if (start) {
parser->m_processor = prologProcessor;
return prologProcessor(parser, start, end, endPtr);
}
return result;
}
/* startPtr gets set to non-null is the section is closed, and to null
if the section is not yet closed.
*/
static enum XML_Error
doIgnoreSection(XML_Parser parser, const ENCODING *enc, const char **startPtr,
const char *end, const char **nextPtr, XML_Bool haveMore) {
const char *next = *startPtr; /* in case of XML_TOK_NONE or XML_TOK_PARTIAL */
int tok;
const char *s = *startPtr;
const char **eventPP;
const char **eventEndPP;
if (enc == parser->m_encoding) {
eventPP = &parser->m_eventPtr;
*eventPP = s;
eventEndPP = &parser->m_eventEndPtr;
} else {
/* It's not entirely clear, but it seems the following two lines
* of code cannot be executed. The only occasions on which 'enc'
* is not 'encoding' are when this function is called
* from the internal entity processing, and IGNORE sections are an
* error in internal entities.
*
* Since it really isn't clear that this is true, we keep the code
* and just remove it from our coverage tests.
*
* LCOV_EXCL_START
*/
eventPP = &(parser->m_openInternalEntities->internalEventPtr);
eventEndPP = &(parser->m_openInternalEntities->internalEventEndPtr);
/* LCOV_EXCL_STOP */
}
*eventPP = s;
*startPtr = NULL;
tok = XmlIgnoreSectionTok(enc, s, end, &next);
# ifdef XML_DTD
if (! accountingDiffTolerated(parser, tok, s, next, __LINE__,
XML_ACCOUNT_DIRECT)) {
accountingOnAbort(parser);
return XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
}
# endif
*eventEndPP = next;
switch (tok) {
case XML_TOK_IGNORE_SECT:
if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
*startPtr = next;
*nextPtr = next;
if (parser->m_parsingStatus.parsing == XML_FINISHED)
return XML_ERROR_ABORTED;
else
return XML_ERROR_NONE;
case XML_TOK_INVALID:
*eventPP = next;
return XML_ERROR_INVALID_TOKEN;
case XML_TOK_PARTIAL_CHAR:
if (haveMore) {
*nextPtr = s;
return XML_ERROR_NONE;
}
return XML_ERROR_PARTIAL_CHAR;
case XML_TOK_PARTIAL:
case XML_TOK_NONE:
if (haveMore) {
*nextPtr = s;
return XML_ERROR_NONE;
}
return XML_ERROR_SYNTAX; /* XML_ERROR_UNCLOSED_IGNORE_SECTION */
default:
/* All of the tokens that XmlIgnoreSectionTok() returns have
* explicit cases to handle them, so this default case is never
* executed. We keep it as a safety net anyway, and remove it
* from our test coverage statistics.
*
* LCOV_EXCL_START
*/
*eventPP = next;
return XML_ERROR_UNEXPECTED_STATE;
/* LCOV_EXCL_STOP */
}
/* not reached */
}
#endif /* XML_DTD */
static enum XML_Error
initializeEncoding(XML_Parser parser) {
const char *s;
#ifdef XML_UNICODE
char encodingBuf[128];
/* See comments about `protocolEncodingName` in parserInit() */
if (! parser->m_protocolEncodingName)
s = NULL;
else {
int i;
for (i = 0; parser->m_protocolEncodingName[i]; i++) {
if (i == sizeof(encodingBuf) - 1
|| (parser->m_protocolEncodingName[i] & ~0x7f) != 0) {
encodingBuf[0] = '\0';
break;
}
encodingBuf[i] = (char)parser->m_protocolEncodingName[i];
}
encodingBuf[i] = '\0';
s = encodingBuf;
}
#else
s = parser->m_protocolEncodingName;
#endif
if ((parser->m_ns ? XmlInitEncodingNS : XmlInitEncoding)(
&parser->m_initEncoding, &parser->m_encoding, s))
return XML_ERROR_NONE;
return handleUnknownEncoding(parser, parser->m_protocolEncodingName);
}
static enum XML_Error
processXmlDecl(XML_Parser parser, int isGeneralTextEntity, const char *s,
const char *next) {
const char *encodingName = NULL;
const XML_Char *storedEncName = NULL;
const ENCODING *newEncoding = NULL;
const char *version = NULL;
const char *versionend;
const XML_Char *storedversion = NULL;
int standalone = -1;
#ifdef XML_DTD
if (! accountingDiffTolerated(parser, XML_TOK_XML_DECL, s, next, __LINE__,
XML_ACCOUNT_DIRECT)) {
accountingOnAbort(parser);
return XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
}
#endif
if (! (parser->m_ns ? XmlParseXmlDeclNS : XmlParseXmlDecl)(
isGeneralTextEntity, parser->m_encoding, s, next, &parser->m_eventPtr,
&version, &versionend, &encodingName, &newEncoding, &standalone)) {
if (isGeneralTextEntity)
return XML_ERROR_TEXT_DECL;
else
return XML_ERROR_XML_DECL;
}
if (! isGeneralTextEntity && standalone == 1) {
parser->m_dtd->standalone = XML_TRUE;
#ifdef XML_DTD
if (parser->m_paramEntityParsing
== XML_PARAM_ENTITY_PARSING_UNLESS_STANDALONE)
parser->m_paramEntityParsing = XML_PARAM_ENTITY_PARSING_NEVER;
#endif /* XML_DTD */
}
if (parser->m_xmlDeclHandler) {
if (encodingName != NULL) {
storedEncName = poolStoreString(
&parser->m_temp2Pool, parser->m_encoding, encodingName,
encodingName + XmlNameLength(parser->m_encoding, encodingName));
if (! storedEncName)
return XML_ERROR_NO_MEMORY;
poolFinish(&parser->m_temp2Pool);
}
if (version) {
storedversion
= poolStoreString(&parser->m_temp2Pool, parser->m_encoding, version,
versionend - parser->m_encoding->minBytesPerChar);
if (! storedversion)
return XML_ERROR_NO_MEMORY;
}
parser->m_xmlDeclHandler(parser->m_handlerArg, storedversion, storedEncName,
standalone);
} else if (parser->m_defaultHandler)
reportDefault(parser, parser->m_encoding, s, next);
if (parser->m_protocolEncodingName == NULL) {
if (newEncoding) {
/* Check that the specified encoding does not conflict with what
* the parser has already deduced. Do we have the same number
* of bytes in the smallest representation of a character? If
* this is UTF-16, is it the same endianness?
*/
if (newEncoding->minBytesPerChar != parser->m_encoding->minBytesPerChar
|| (newEncoding->minBytesPerChar == 2
&& newEncoding != parser->m_encoding)) {
parser->m_eventPtr = encodingName;
return XML_ERROR_INCORRECT_ENCODING;
}
parser->m_encoding = newEncoding;
} else if (encodingName) {
enum XML_Error result;
if (! storedEncName) {
storedEncName = poolStoreString(
&parser->m_temp2Pool, parser->m_encoding, encodingName,
encodingName + XmlNameLength(parser->m_encoding, encodingName));
if (! storedEncName)
return XML_ERROR_NO_MEMORY;
}
result = handleUnknownEncoding(parser, storedEncName);
poolClear(&parser->m_temp2Pool);
if (result == XML_ERROR_UNKNOWN_ENCODING)
parser->m_eventPtr = encodingName;
return result;
}
}
if (storedEncName || storedversion)
poolClear(&parser->m_temp2Pool);
return XML_ERROR_NONE;
}
static enum XML_Error
handleUnknownEncoding(XML_Parser parser, const XML_Char *encodingName) {
if (parser->m_unknownEncodingHandler) {
XML_Encoding info;
int i;
for (i = 0; i < 256; i++)
info.map[i] = -1;
info.convert = NULL;
info.data = NULL;
info.release = NULL;
if (parser->m_unknownEncodingHandler(parser->m_unknownEncodingHandlerData,
encodingName, &info)) {
ENCODING *enc;
parser->m_unknownEncodingMem = MALLOC(parser, XmlSizeOfUnknownEncoding());
if (! parser->m_unknownEncodingMem) {
if (info.release)
info.release(info.data);
return XML_ERROR_NO_MEMORY;
}
enc = (parser->m_ns ? XmlInitUnknownEncodingNS : XmlInitUnknownEncoding)(
parser->m_unknownEncodingMem, info.map, info.convert, info.data);
if (enc) {
parser->m_unknownEncodingData = info.data;
parser->m_unknownEncodingRelease = info.release;
parser->m_encoding = enc;
return XML_ERROR_NONE;
}
}
if (info.release != NULL)
info.release(info.data);
}
return XML_ERROR_UNKNOWN_ENCODING;
}
static enum XML_Error PTRCALL
prologInitProcessor(XML_Parser parser, const char *s, const char *end,
const char **nextPtr) {
enum XML_Error result = initializeEncoding(parser);
if (result != XML_ERROR_NONE)
return result;
parser->m_processor = prologProcessor;
return prologProcessor(parser, s, end, nextPtr);
}
#ifdef XML_DTD
static enum XML_Error PTRCALL
externalParEntInitProcessor(XML_Parser parser, const char *s, const char *end,
const char **nextPtr) {
enum XML_Error result = initializeEncoding(parser);
if (result != XML_ERROR_NONE)
return result;
/* we know now that XML_Parse(Buffer) has been called,
so we consider the external parameter entity read */
parser->m_dtd->paramEntityRead = XML_TRUE;
if (parser->m_prologState.inEntityValue) {
parser->m_processor = entityValueInitProcessor;
return entityValueInitProcessor(parser, s, end, nextPtr);
} else {
parser->m_processor = externalParEntProcessor;
return externalParEntProcessor(parser, s, end, nextPtr);
}
}
static enum XML_Error PTRCALL
entityValueInitProcessor(XML_Parser parser, const char *s, const char *end,
const char **nextPtr) {
int tok;
const char *start = s;
const char *next = start;
parser->m_eventPtr = start;
for (;;) {
tok = XmlPrologTok(parser->m_encoding, start, end, &next);
/* Note: Except for XML_TOK_BOM below, these bytes are accounted later in:
- storeEntityValue
- processXmlDecl
*/
parser->m_eventEndPtr = next;
if (tok <= 0) {
if (! parser->m_parsingStatus.finalBuffer && tok != XML_TOK_INVALID) {
*nextPtr = s;
return XML_ERROR_NONE;
}
switch (tok) {
case XML_TOK_INVALID:
return XML_ERROR_INVALID_TOKEN;
case XML_TOK_PARTIAL:
return XML_ERROR_UNCLOSED_TOKEN;
case XML_TOK_PARTIAL_CHAR:
return XML_ERROR_PARTIAL_CHAR;
case XML_TOK_NONE: /* start == end */
default:
break;
}
/* found end of entity value - can store it now */
return storeEntityValue(parser, parser->m_encoding, s, end,
XML_ACCOUNT_DIRECT);
} else if (tok == XML_TOK_XML_DECL) {
enum XML_Error result;
result = processXmlDecl(parser, 0, start, next);
if (result != XML_ERROR_NONE)
return result;
/* At this point, m_parsingStatus.parsing cannot be XML_SUSPENDED. For
* that to happen, a parameter entity parsing handler must have attempted
* to suspend the parser, which fails and raises an error. The parser can
* be aborted, but can't be suspended.
*/
if (parser->m_parsingStatus.parsing == XML_FINISHED)
return XML_ERROR_ABORTED;
*nextPtr = next;
/* stop scanning for text declaration - we found one */
parser->m_processor = entityValueProcessor;
return entityValueProcessor(parser, next, end, nextPtr);
}
/* If we are at the end of the buffer, this would cause XmlPrologTok to
return XML_TOK_NONE on the next call, which would then cause the
function to exit with *nextPtr set to s - that is what we want for other
tokens, but not for the BOM - we would rather like to skip it;
then, when this routine is entered the next time, XmlPrologTok will
return XML_TOK_INVALID, since the BOM is still in the buffer
*/
else if (tok == XML_TOK_BOM && next == end
&& ! parser->m_parsingStatus.finalBuffer) {
# ifdef XML_DTD
if (! accountingDiffTolerated(parser, tok, s, next, __LINE__,
XML_ACCOUNT_DIRECT)) {
accountingOnAbort(parser);
return XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
}
# endif
*nextPtr = next;
return XML_ERROR_NONE;
}
/* If we get this token, we have the start of what might be a
normal tag, but not a declaration (i.e. it doesn't begin with
"<!"). In a DTD context, that isn't legal.
*/
else if (tok == XML_TOK_INSTANCE_START) {
*nextPtr = next;
return XML_ERROR_SYNTAX;
}
start = next;
parser->m_eventPtr = start;
}
}
static enum XML_Error PTRCALL
externalParEntProcessor(XML_Parser parser, const char *s, const char *end,
const char **nextPtr) {
const char *next = s;
int tok;
tok = XmlPrologTok(parser->m_encoding, s, end, &next);
if (tok <= 0) {
if (! parser->m_parsingStatus.finalBuffer && tok != XML_TOK_INVALID) {
*nextPtr = s;
return XML_ERROR_NONE;
}
switch (tok) {
case XML_TOK_INVALID:
return XML_ERROR_INVALID_TOKEN;
case XML_TOK_PARTIAL:
return XML_ERROR_UNCLOSED_TOKEN;
case XML_TOK_PARTIAL_CHAR:
return XML_ERROR_PARTIAL_CHAR;
case XML_TOK_NONE: /* start == end */
default:
break;
}
}
/* This would cause the next stage, i.e. doProlog to be passed XML_TOK_BOM.
However, when parsing an external subset, doProlog will not accept a BOM
as valid, and report a syntax error, so we have to skip the BOM, and
account for the BOM bytes.
*/
else if (tok == XML_TOK_BOM) {
if (! accountingDiffTolerated(parser, tok, s, next, __LINE__,
XML_ACCOUNT_DIRECT)) {
accountingOnAbort(parser);
return XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
}
s = next;
tok = XmlPrologTok(parser->m_encoding, s, end, &next);
}
parser->m_processor = prologProcessor;
return doProlog(parser, parser->m_encoding, s, end, tok, next, nextPtr,
(XML_Bool)! parser->m_parsingStatus.finalBuffer, XML_TRUE,
XML_ACCOUNT_DIRECT);
}
static enum XML_Error PTRCALL
entityValueProcessor(XML_Parser parser, const char *s, const char *end,
const char **nextPtr) {
const char *start = s;
const char *next = s;
const ENCODING *enc = parser->m_encoding;
int tok;
for (;;) {
tok = XmlPrologTok(enc, start, end, &next);
/* Note: These bytes are accounted later in:
- storeEntityValue
*/
if (tok <= 0) {
if (! parser->m_parsingStatus.finalBuffer && tok != XML_TOK_INVALID) {
*nextPtr = s;
return XML_ERROR_NONE;
}
switch (tok) {
case XML_TOK_INVALID:
return XML_ERROR_INVALID_TOKEN;
case XML_TOK_PARTIAL:
return XML_ERROR_UNCLOSED_TOKEN;
case XML_TOK_PARTIAL_CHAR:
return XML_ERROR_PARTIAL_CHAR;
case XML_TOK_NONE: /* start == end */
default:
break;
}
/* found end of entity value - can store it now */
return storeEntityValue(parser, enc, s, end, XML_ACCOUNT_DIRECT);
}
start = next;
}
}
#endif /* XML_DTD */
static enum XML_Error PTRCALL
prologProcessor(XML_Parser parser, const char *s, const char *end,
const char **nextPtr) {
const char *next = s;
int tok = XmlPrologTok(parser->m_encoding, s, end, &next);
return doProlog(parser, parser->m_encoding, s, end, tok, next, nextPtr,
(XML_Bool)! parser->m_parsingStatus.finalBuffer, XML_TRUE,
XML_ACCOUNT_DIRECT);
}
static enum XML_Error
doProlog(XML_Parser parser, const ENCODING *enc, const char *s, const char *end,
int tok, const char *next, const char **nextPtr, XML_Bool haveMore,
XML_Bool allowClosingDoctype, enum XML_Account account) {
#ifdef XML_DTD
static const XML_Char externalSubsetName[] = {ASCII_HASH, '\0'};
#endif /* XML_DTD */
static const XML_Char atypeCDATA[]
= {ASCII_C, ASCII_D, ASCII_A, ASCII_T, ASCII_A, '\0'};
static const XML_Char atypeID[] = {ASCII_I, ASCII_D, '\0'};
static const XML_Char atypeIDREF[]
= {ASCII_I, ASCII_D, ASCII_R, ASCII_E, ASCII_F, '\0'};
static const XML_Char atypeIDREFS[]
= {ASCII_I, ASCII_D, ASCII_R, ASCII_E, ASCII_F, ASCII_S, '\0'};
static const XML_Char atypeENTITY[]
= {ASCII_E, ASCII_N, ASCII_T, ASCII_I, ASCII_T, ASCII_Y, '\0'};
static const XML_Char atypeENTITIES[]
= {ASCII_E, ASCII_N, ASCII_T, ASCII_I, ASCII_T,
ASCII_I, ASCII_E, ASCII_S, '\0'};
static const XML_Char atypeNMTOKEN[]
= {ASCII_N, ASCII_M, ASCII_T, ASCII_O, ASCII_K, ASCII_E, ASCII_N, '\0'};
static const XML_Char atypeNMTOKENS[]
= {ASCII_N, ASCII_M, ASCII_T, ASCII_O, ASCII_K,
ASCII_E, ASCII_N, ASCII_S, '\0'};
static const XML_Char notationPrefix[]
= {ASCII_N, ASCII_O, ASCII_T, ASCII_A, ASCII_T,
ASCII_I, ASCII_O, ASCII_N, ASCII_LPAREN, '\0'};
static const XML_Char enumValueSep[] = {ASCII_PIPE, '\0'};
static const XML_Char enumValueStart[] = {ASCII_LPAREN, '\0'};
#ifndef XML_DTD
UNUSED_P(account);
#endif
/* save one level of indirection */
DTD *const dtd = parser->m_dtd;
const char **eventPP;
const char **eventEndPP;
enum XML_Content_Quant quant;
if (enc == parser->m_encoding) {
eventPP = &parser->m_eventPtr;
eventEndPP = &parser->m_eventEndPtr;
} else {
eventPP = &(parser->m_openInternalEntities->internalEventPtr);
eventEndPP = &(parser->m_openInternalEntities->internalEventEndPtr);
}
for (;;) {
int role;
XML_Bool handleDefault = XML_TRUE;
*eventPP = s;
*eventEndPP = next;
if (tok <= 0) {
if (haveMore && tok != XML_TOK_INVALID) {
*nextPtr = s;
return XML_ERROR_NONE;
}
switch (tok) {
case XML_TOK_INVALID:
*eventPP = next;
return XML_ERROR_INVALID_TOKEN;
case XML_TOK_PARTIAL:
return XML_ERROR_UNCLOSED_TOKEN;
case XML_TOK_PARTIAL_CHAR:
return XML_ERROR_PARTIAL_CHAR;
case -XML_TOK_PROLOG_S:
tok = -tok;
break;
case XML_TOK_NONE:
#ifdef XML_DTD
/* for internal PE NOT referenced between declarations */
if (enc != parser->m_encoding
&& ! parser->m_openInternalEntities->betweenDecl) {
*nextPtr = s;
return XML_ERROR_NONE;
}
/* WFC: PE Between Declarations - must check that PE contains
complete markup, not only for external PEs, but also for
internal PEs if the reference occurs between declarations.
*/
if (parser->m_isParamEntity || enc != parser->m_encoding) {
if (XmlTokenRole(&parser->m_prologState, XML_TOK_NONE, end, end, enc)
== XML_ROLE_ERROR)
return XML_ERROR_INCOMPLETE_PE;
*nextPtr = s;
return XML_ERROR_NONE;
}
#endif /* XML_DTD */
return XML_ERROR_NO_ELEMENTS;
default:
tok = -tok;
next = end;
break;
}
}
role = XmlTokenRole(&parser->m_prologState, tok, s, next, enc);
#ifdef XML_DTD
switch (role) {
case XML_ROLE_INSTANCE_START: // bytes accounted in contentProcessor
case XML_ROLE_XML_DECL: // bytes accounted in processXmlDecl
case XML_ROLE_TEXT_DECL: // bytes accounted in processXmlDecl
break;
default:
if (! accountingDiffTolerated(parser, tok, s, next, __LINE__, account)) {
accountingOnAbort(parser);
return XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
}
}
#endif
switch (role) {
case XML_ROLE_XML_DECL: {
enum XML_Error result = processXmlDecl(parser, 0, s, next);
if (result != XML_ERROR_NONE)
return result;
enc = parser->m_encoding;
handleDefault = XML_FALSE;
} break;
case XML_ROLE_DOCTYPE_NAME:
if (parser->m_startDoctypeDeclHandler) {
parser->m_doctypeName
= poolStoreString(&parser->m_tempPool, enc, s, next);
if (! parser->m_doctypeName)
return XML_ERROR_NO_MEMORY;
poolFinish(&parser->m_tempPool);
parser->m_doctypePubid = NULL;
handleDefault = XML_FALSE;
}
parser->m_doctypeSysid = NULL; /* always initialize to NULL */
break;
case XML_ROLE_DOCTYPE_INTERNAL_SUBSET:
if (parser->m_startDoctypeDeclHandler) {
parser->m_startDoctypeDeclHandler(
parser->m_handlerArg, parser->m_doctypeName, parser->m_doctypeSysid,
parser->m_doctypePubid, 1);
parser->m_doctypeName = NULL;
poolClear(&parser->m_tempPool);
handleDefault = XML_FALSE;
}
break;
#ifdef XML_DTD
case XML_ROLE_TEXT_DECL: {
enum XML_Error result = processXmlDecl(parser, 1, s, next);
if (result != XML_ERROR_NONE)
return result;
enc = parser->m_encoding;
handleDefault = XML_FALSE;
} break;
#endif /* XML_DTD */
case XML_ROLE_DOCTYPE_PUBLIC_ID:
#ifdef XML_DTD
parser->m_useForeignDTD = XML_FALSE;
parser->m_declEntity = (ENTITY *)lookup(
parser, &dtd->paramEntities, externalSubsetName, sizeof(ENTITY));
if (! parser->m_declEntity)
return XML_ERROR_NO_MEMORY;
#endif /* XML_DTD */
dtd->hasParamEntityRefs = XML_TRUE;
if (parser->m_startDoctypeDeclHandler) {
XML_Char *pubId;
if (! XmlIsPublicId(enc, s, next, eventPP))
return XML_ERROR_PUBLICID;
pubId = poolStoreString(&parser->m_tempPool, enc,
s + enc->minBytesPerChar,
next - enc->minBytesPerChar);
if (! pubId)
return XML_ERROR_NO_MEMORY;
normalizePublicId(pubId);
poolFinish(&parser->m_tempPool);
parser->m_doctypePubid = pubId;
handleDefault = XML_FALSE;
goto alreadyChecked;
}
/* fall through */
case XML_ROLE_ENTITY_PUBLIC_ID:
if (! XmlIsPublicId(enc, s, next, eventPP))
return XML_ERROR_PUBLICID;
alreadyChecked:
if (dtd->keepProcessing && parser->m_declEntity) {
XML_Char *tem
= poolStoreString(&dtd->pool, enc, s + enc->minBytesPerChar,
next - enc->minBytesPerChar);
if (! tem)
return XML_ERROR_NO_MEMORY;
normalizePublicId(tem);
parser->m_declEntity->publicId = tem;
poolFinish(&dtd->pool);
/* Don't suppress the default handler if we fell through from
* the XML_ROLE_DOCTYPE_PUBLIC_ID case.
*/
if (parser->m_entityDeclHandler && role == XML_ROLE_ENTITY_PUBLIC_ID)
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_DOCTYPE_CLOSE:
if (allowClosingDoctype != XML_TRUE) {
/* Must not close doctype from within expanded parameter entities */
return XML_ERROR_INVALID_TOKEN;
}
if (parser->m_doctypeName) {
parser->m_startDoctypeDeclHandler(
parser->m_handlerArg, parser->m_doctypeName, parser->m_doctypeSysid,
parser->m_doctypePubid, 0);
poolClear(&parser->m_tempPool);
handleDefault = XML_FALSE;
}
/* parser->m_doctypeSysid will be non-NULL in the case of a previous
XML_ROLE_DOCTYPE_SYSTEM_ID, even if parser->m_startDoctypeDeclHandler
was not set, indicating an external subset
*/
#ifdef XML_DTD
if (parser->m_doctypeSysid || parser->m_useForeignDTD) {
XML_Bool hadParamEntityRefs = dtd->hasParamEntityRefs;
dtd->hasParamEntityRefs = XML_TRUE;
if (parser->m_paramEntityParsing
&& parser->m_externalEntityRefHandler) {
ENTITY *entity = (ENTITY *)lookup(parser, &dtd->paramEntities,
externalSubsetName, sizeof(ENTITY));
if (! entity) {
/* The external subset name "#" will have already been
* inserted into the hash table at the start of the
* external entity parsing, so no allocation will happen
* and lookup() cannot fail.
*/
return XML_ERROR_NO_MEMORY; /* LCOV_EXCL_LINE */
}
if (parser->m_useForeignDTD)
entity->base = parser->m_curBase;
dtd->paramEntityRead = XML_FALSE;
if (! parser->m_externalEntityRefHandler(
parser->m_externalEntityRefHandlerArg, 0, entity->base,
entity->systemId, entity->publicId))
return XML_ERROR_EXTERNAL_ENTITY_HANDLING;
if (dtd->paramEntityRead) {
if (! dtd->standalone && parser->m_notStandaloneHandler
&& ! parser->m_notStandaloneHandler(parser->m_handlerArg))
return XML_ERROR_NOT_STANDALONE;
}
/* if we didn't read the foreign DTD then this means that there
is no external subset and we must reset dtd->hasParamEntityRefs
*/
else if (! parser->m_doctypeSysid)
dtd->hasParamEntityRefs = hadParamEntityRefs;
/* end of DTD - no need to update dtd->keepProcessing */
}
parser->m_useForeignDTD = XML_FALSE;
}
#endif /* XML_DTD */
if (parser->m_endDoctypeDeclHandler) {
parser->m_endDoctypeDeclHandler(parser->m_handlerArg);
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_INSTANCE_START:
#ifdef XML_DTD
/* if there is no DOCTYPE declaration then now is the
last chance to read the foreign DTD
*/
if (parser->m_useForeignDTD) {
XML_Bool hadParamEntityRefs = dtd->hasParamEntityRefs;
dtd->hasParamEntityRefs = XML_TRUE;
if (parser->m_paramEntityParsing
&& parser->m_externalEntityRefHandler) {
ENTITY *entity = (ENTITY *)lookup(parser, &dtd->paramEntities,
externalSubsetName, sizeof(ENTITY));
if (! entity)
return XML_ERROR_NO_MEMORY;
entity->base = parser->m_curBase;
dtd->paramEntityRead = XML_FALSE;
if (! parser->m_externalEntityRefHandler(
parser->m_externalEntityRefHandlerArg, 0, entity->base,
entity->systemId, entity->publicId))
return XML_ERROR_EXTERNAL_ENTITY_HANDLING;
if (dtd->paramEntityRead) {
if (! dtd->standalone && parser->m_notStandaloneHandler
&& ! parser->m_notStandaloneHandler(parser->m_handlerArg))
return XML_ERROR_NOT_STANDALONE;
}
/* if we didn't read the foreign DTD then this means that there
is no external subset and we must reset dtd->hasParamEntityRefs
*/
else
dtd->hasParamEntityRefs = hadParamEntityRefs;
/* end of DTD - no need to update dtd->keepProcessing */
}
}
#endif /* XML_DTD */
parser->m_processor = contentProcessor;
return contentProcessor(parser, s, end, nextPtr);
case XML_ROLE_ATTLIST_ELEMENT_NAME:
parser->m_declElementType = getElementType(parser, enc, s, next);
if (! parser->m_declElementType)
return XML_ERROR_NO_MEMORY;
goto checkAttListDeclHandler;
case XML_ROLE_ATTRIBUTE_NAME:
parser->m_declAttributeId = getAttributeId(parser, enc, s, next);
if (! parser->m_declAttributeId)
return XML_ERROR_NO_MEMORY;
parser->m_declAttributeIsCdata = XML_FALSE;
parser->m_declAttributeType = NULL;
parser->m_declAttributeIsId = XML_FALSE;
goto checkAttListDeclHandler;
case XML_ROLE_ATTRIBUTE_TYPE_CDATA:
parser->m_declAttributeIsCdata = XML_TRUE;
parser->m_declAttributeType = atypeCDATA;
goto checkAttListDeclHandler;
case XML_ROLE_ATTRIBUTE_TYPE_ID:
parser->m_declAttributeIsId = XML_TRUE;
parser->m_declAttributeType = atypeID;
goto checkAttListDeclHandler;
case XML_ROLE_ATTRIBUTE_TYPE_IDREF:
parser->m_declAttributeType = atypeIDREF;
goto checkAttListDeclHandler;
case XML_ROLE_ATTRIBUTE_TYPE_IDREFS:
parser->m_declAttributeType = atypeIDREFS;
goto checkAttListDeclHandler;
case XML_ROLE_ATTRIBUTE_TYPE_ENTITY:
parser->m_declAttributeType = atypeENTITY;
goto checkAttListDeclHandler;
case XML_ROLE_ATTRIBUTE_TYPE_ENTITIES:
parser->m_declAttributeType = atypeENTITIES;
goto checkAttListDeclHandler;
case XML_ROLE_ATTRIBUTE_TYPE_NMTOKEN:
parser->m_declAttributeType = atypeNMTOKEN;
goto checkAttListDeclHandler;
case XML_ROLE_ATTRIBUTE_TYPE_NMTOKENS:
parser->m_declAttributeType = atypeNMTOKENS;
checkAttListDeclHandler:
if (dtd->keepProcessing && parser->m_attlistDeclHandler)
handleDefault = XML_FALSE;
break;
case XML_ROLE_ATTRIBUTE_ENUM_VALUE:
case XML_ROLE_ATTRIBUTE_NOTATION_VALUE:
if (dtd->keepProcessing && parser->m_attlistDeclHandler) {
const XML_Char *prefix;
if (parser->m_declAttributeType) {
prefix = enumValueSep;
} else {
prefix = (role == XML_ROLE_ATTRIBUTE_NOTATION_VALUE ? notationPrefix
: enumValueStart);
}
if (! poolAppendString(&parser->m_tempPool, prefix))
return XML_ERROR_NO_MEMORY;
if (! poolAppend(&parser->m_tempPool, enc, s, next))
return XML_ERROR_NO_MEMORY;
parser->m_declAttributeType = parser->m_tempPool.start;
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_IMPLIED_ATTRIBUTE_VALUE:
case XML_ROLE_REQUIRED_ATTRIBUTE_VALUE:
if (dtd->keepProcessing) {
if (! defineAttribute(parser->m_declElementType,
parser->m_declAttributeId,
parser->m_declAttributeIsCdata,
parser->m_declAttributeIsId, 0, parser))
return XML_ERROR_NO_MEMORY;
if (parser->m_attlistDeclHandler && parser->m_declAttributeType) {
if (*parser->m_declAttributeType == XML_T(ASCII_LPAREN)
|| (*parser->m_declAttributeType == XML_T(ASCII_N)
&& parser->m_declAttributeType[1] == XML_T(ASCII_O))) {
/* Enumerated or Notation type */
if (! poolAppendChar(&parser->m_tempPool, XML_T(ASCII_RPAREN))
|| ! poolAppendChar(&parser->m_tempPool, XML_T('\0')))
return XML_ERROR_NO_MEMORY;
parser->m_declAttributeType = parser->m_tempPool.start;
poolFinish(&parser->m_tempPool);
}
*eventEndPP = s;
parser->m_attlistDeclHandler(
parser->m_handlerArg, parser->m_declElementType->name,
parser->m_declAttributeId->name, parser->m_declAttributeType, 0,
role == XML_ROLE_REQUIRED_ATTRIBUTE_VALUE);
poolClear(&parser->m_tempPool);
handleDefault = XML_FALSE;
}
}
break;
case XML_ROLE_DEFAULT_ATTRIBUTE_VALUE:
case XML_ROLE_FIXED_ATTRIBUTE_VALUE:
if (dtd->keepProcessing) {
const XML_Char *attVal;
enum XML_Error result = storeAttributeValue(
parser, enc, parser->m_declAttributeIsCdata,
s + enc->minBytesPerChar, next - enc->minBytesPerChar, &dtd->pool,
XML_ACCOUNT_NONE);
if (result)
return result;
attVal = poolStart(&dtd->pool);
poolFinish(&dtd->pool);
/* ID attributes aren't allowed to have a default */
if (! defineAttribute(
parser->m_declElementType, parser->m_declAttributeId,
parser->m_declAttributeIsCdata, XML_FALSE, attVal, parser))
return XML_ERROR_NO_MEMORY;
if (parser->m_attlistDeclHandler && parser->m_declAttributeType) {
if (*parser->m_declAttributeType == XML_T(ASCII_LPAREN)
|| (*parser->m_declAttributeType == XML_T(ASCII_N)
&& parser->m_declAttributeType[1] == XML_T(ASCII_O))) {
/* Enumerated or Notation type */
if (! poolAppendChar(&parser->m_tempPool, XML_T(ASCII_RPAREN))
|| ! poolAppendChar(&parser->m_tempPool, XML_T('\0')))
return XML_ERROR_NO_MEMORY;
parser->m_declAttributeType = parser->m_tempPool.start;
poolFinish(&parser->m_tempPool);
}
*eventEndPP = s;
parser->m_attlistDeclHandler(
parser->m_handlerArg, parser->m_declElementType->name,
parser->m_declAttributeId->name, parser->m_declAttributeType,
attVal, role == XML_ROLE_FIXED_ATTRIBUTE_VALUE);
poolClear(&parser->m_tempPool);
handleDefault = XML_FALSE;
}
}
break;
case XML_ROLE_ENTITY_VALUE:
if (dtd->keepProcessing) {
enum XML_Error result
= storeEntityValue(parser, enc, s + enc->minBytesPerChar,
next - enc->minBytesPerChar, XML_ACCOUNT_NONE);
if (parser->m_declEntity) {
parser->m_declEntity->textPtr = poolStart(&dtd->entityValuePool);
parser->m_declEntity->textLen
= (int)(poolLength(&dtd->entityValuePool));
poolFinish(&dtd->entityValuePool);
if (parser->m_entityDeclHandler) {
*eventEndPP = s;
parser->m_entityDeclHandler(
parser->m_handlerArg, parser->m_declEntity->name,
parser->m_declEntity->is_param, parser->m_declEntity->textPtr,
parser->m_declEntity->textLen, parser->m_curBase, 0, 0, 0);
handleDefault = XML_FALSE;
}
} else
poolDiscard(&dtd->entityValuePool);
if (result != XML_ERROR_NONE)
return result;
}
break;
case XML_ROLE_DOCTYPE_SYSTEM_ID:
#ifdef XML_DTD
parser->m_useForeignDTD = XML_FALSE;
#endif /* XML_DTD */
dtd->hasParamEntityRefs = XML_TRUE;
if (parser->m_startDoctypeDeclHandler) {
parser->m_doctypeSysid = poolStoreString(&parser->m_tempPool, enc,
s + enc->minBytesPerChar,
next - enc->minBytesPerChar);
if (parser->m_doctypeSysid == NULL)
return XML_ERROR_NO_MEMORY;
poolFinish(&parser->m_tempPool);
handleDefault = XML_FALSE;
}
#ifdef XML_DTD
else
/* use externalSubsetName to make parser->m_doctypeSysid non-NULL
for the case where no parser->m_startDoctypeDeclHandler is set */
parser->m_doctypeSysid = externalSubsetName;
#endif /* XML_DTD */
if (! dtd->standalone
#ifdef XML_DTD
&& ! parser->m_paramEntityParsing
#endif /* XML_DTD */
&& parser->m_notStandaloneHandler
&& ! parser->m_notStandaloneHandler(parser->m_handlerArg))
return XML_ERROR_NOT_STANDALONE;
#ifndef XML_DTD
break;
#else /* XML_DTD */
if (! parser->m_declEntity) {
parser->m_declEntity = (ENTITY *)lookup(
parser, &dtd->paramEntities, externalSubsetName, sizeof(ENTITY));
if (! parser->m_declEntity)
return XML_ERROR_NO_MEMORY;
parser->m_declEntity->publicId = NULL;
}
#endif /* XML_DTD */
/* fall through */
case XML_ROLE_ENTITY_SYSTEM_ID:
if (dtd->keepProcessing && parser->m_declEntity) {
parser->m_declEntity->systemId
= poolStoreString(&dtd->pool, enc, s + enc->minBytesPerChar,
next - enc->minBytesPerChar);
if (! parser->m_declEntity->systemId)
return XML_ERROR_NO_MEMORY;
parser->m_declEntity->base = parser->m_curBase;
poolFinish(&dtd->pool);
/* Don't suppress the default handler if we fell through from
* the XML_ROLE_DOCTYPE_SYSTEM_ID case.
*/
if (parser->m_entityDeclHandler && role == XML_ROLE_ENTITY_SYSTEM_ID)
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_ENTITY_COMPLETE:
if (dtd->keepProcessing && parser->m_declEntity
&& parser->m_entityDeclHandler) {
*eventEndPP = s;
parser->m_entityDeclHandler(
parser->m_handlerArg, parser->m_declEntity->name,
parser->m_declEntity->is_param, 0, 0, parser->m_declEntity->base,
parser->m_declEntity->systemId, parser->m_declEntity->publicId, 0);
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_ENTITY_NOTATION_NAME:
if (dtd->keepProcessing && parser->m_declEntity) {
parser->m_declEntity->notation
= poolStoreString(&dtd->pool, enc, s, next);
if (! parser->m_declEntity->notation)
return XML_ERROR_NO_MEMORY;
poolFinish(&dtd->pool);
if (parser->m_unparsedEntityDeclHandler) {
*eventEndPP = s;
parser->m_unparsedEntityDeclHandler(
parser->m_handlerArg, parser->m_declEntity->name,
parser->m_declEntity->base, parser->m_declEntity->systemId,
parser->m_declEntity->publicId, parser->m_declEntity->notation);
handleDefault = XML_FALSE;
} else if (parser->m_entityDeclHandler) {
*eventEndPP = s;
parser->m_entityDeclHandler(
parser->m_handlerArg, parser->m_declEntity->name, 0, 0, 0,
parser->m_declEntity->base, parser->m_declEntity->systemId,
parser->m_declEntity->publicId, parser->m_declEntity->notation);
handleDefault = XML_FALSE;
}
}
break;
case XML_ROLE_GENERAL_ENTITY_NAME: {
if (XmlPredefinedEntityName(enc, s, next)) {
parser->m_declEntity = NULL;
break;
}
if (dtd->keepProcessing) {
const XML_Char *name = poolStoreString(&dtd->pool, enc, s, next);
if (! name)
return XML_ERROR_NO_MEMORY;
parser->m_declEntity = (ENTITY *)lookup(parser, &dtd->generalEntities,
name, sizeof(ENTITY));
if (! parser->m_declEntity)
return XML_ERROR_NO_MEMORY;
if (parser->m_declEntity->name != name) {
poolDiscard(&dtd->pool);
parser->m_declEntity = NULL;
} else {
poolFinish(&dtd->pool);
parser->m_declEntity->publicId = NULL;
parser->m_declEntity->is_param = XML_FALSE;
/* if we have a parent parser or are reading an internal parameter
entity, then the entity declaration is not considered "internal"
*/
parser->m_declEntity->is_internal
= ! (parser->m_parentParser || parser->m_openInternalEntities);
if (parser->m_entityDeclHandler)
handleDefault = XML_FALSE;
}
} else {
poolDiscard(&dtd->pool);
parser->m_declEntity = NULL;
}
} break;
case XML_ROLE_PARAM_ENTITY_NAME:
#ifdef XML_DTD
if (dtd->keepProcessing) {
const XML_Char *name = poolStoreString(&dtd->pool, enc, s, next);
if (! name)
return XML_ERROR_NO_MEMORY;
parser->m_declEntity = (ENTITY *)lookup(parser, &dtd->paramEntities,
name, sizeof(ENTITY));
if (! parser->m_declEntity)
return XML_ERROR_NO_MEMORY;
if (parser->m_declEntity->name != name) {
poolDiscard(&dtd->pool);
parser->m_declEntity = NULL;
} else {
poolFinish(&dtd->pool);
parser->m_declEntity->publicId = NULL;
parser->m_declEntity->is_param = XML_TRUE;
/* if we have a parent parser or are reading an internal parameter
entity, then the entity declaration is not considered "internal"
*/
parser->m_declEntity->is_internal
= ! (parser->m_parentParser || parser->m_openInternalEntities);
if (parser->m_entityDeclHandler)
handleDefault = XML_FALSE;
}
} else {
poolDiscard(&dtd->pool);
parser->m_declEntity = NULL;
}
#else /* not XML_DTD */
parser->m_declEntity = NULL;
#endif /* XML_DTD */
break;
case XML_ROLE_NOTATION_NAME:
parser->m_declNotationPublicId = NULL;
parser->m_declNotationName = NULL;
if (parser->m_notationDeclHandler) {
parser->m_declNotationName
= poolStoreString(&parser->m_tempPool, enc, s, next);
if (! parser->m_declNotationName)
return XML_ERROR_NO_MEMORY;
poolFinish(&parser->m_tempPool);
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_NOTATION_PUBLIC_ID:
if (! XmlIsPublicId(enc, s, next, eventPP))
return XML_ERROR_PUBLICID;
if (parser
->m_declNotationName) { /* means m_notationDeclHandler != NULL */
XML_Char *tem = poolStoreString(&parser->m_tempPool, enc,
s + enc->minBytesPerChar,
next - enc->minBytesPerChar);
if (! tem)
return XML_ERROR_NO_MEMORY;
normalizePublicId(tem);
parser->m_declNotationPublicId = tem;
poolFinish(&parser->m_tempPool);
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_NOTATION_SYSTEM_ID:
if (parser->m_declNotationName && parser->m_notationDeclHandler) {
const XML_Char *systemId = poolStoreString(&parser->m_tempPool, enc,
s + enc->minBytesPerChar,
next - enc->minBytesPerChar);
if (! systemId)
return XML_ERROR_NO_MEMORY;
*eventEndPP = s;
parser->m_notationDeclHandler(
parser->m_handlerArg, parser->m_declNotationName, parser->m_curBase,
systemId, parser->m_declNotationPublicId);
handleDefault = XML_FALSE;
}
poolClear(&parser->m_tempPool);
break;
case XML_ROLE_NOTATION_NO_SYSTEM_ID:
if (parser->m_declNotationPublicId && parser->m_notationDeclHandler) {
*eventEndPP = s;
parser->m_notationDeclHandler(
parser->m_handlerArg, parser->m_declNotationName, parser->m_curBase,
0, parser->m_declNotationPublicId);
handleDefault = XML_FALSE;
}
poolClear(&parser->m_tempPool);
break;
case XML_ROLE_ERROR:
switch (tok) {
case XML_TOK_PARAM_ENTITY_REF:
/* PE references in internal subset are
not allowed within declarations. */
return XML_ERROR_PARAM_ENTITY_REF;
case XML_TOK_XML_DECL:
return XML_ERROR_MISPLACED_XML_PI;
default:
return XML_ERROR_SYNTAX;
}
#ifdef XML_DTD
case XML_ROLE_IGNORE_SECT: {
enum XML_Error result;
if (parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
handleDefault = XML_FALSE;
result = doIgnoreSection(parser, enc, &next, end, nextPtr, haveMore);
if (result != XML_ERROR_NONE)
return result;
else if (! next) {
parser->m_processor = ignoreSectionProcessor;
return result;
}
} break;
#endif /* XML_DTD */
case XML_ROLE_GROUP_OPEN:
if (parser->m_prologState.level >= parser->m_groupSize) {
if (parser->m_groupSize) {
{
/* Detect and prevent integer overflow */
if (parser->m_groupSize > (unsigned int)(-1) / 2u) {
return XML_ERROR_NO_MEMORY;
}
char *const new_connector = (char *)REALLOC(
parser, parser->m_groupConnector, parser->m_groupSize *= 2);
if (new_connector == NULL) {
parser->m_groupSize /= 2;
return XML_ERROR_NO_MEMORY;
}
parser->m_groupConnector = new_connector;
}
if (dtd->scaffIndex) {
/* Detect and prevent integer overflow.
* The preprocessor guard addresses the "always false" warning
* from -Wtype-limits on platforms where
* sizeof(unsigned int) < sizeof(size_t), e.g. on x86_64. */
#if UINT_MAX >= SIZE_MAX
if (parser->m_groupSize > (size_t)(-1) / sizeof(int)) {
return XML_ERROR_NO_MEMORY;
}
#endif
int *const new_scaff_index = (int *)REALLOC(
parser, dtd->scaffIndex, parser->m_groupSize * sizeof(int));
if (new_scaff_index == NULL)
return XML_ERROR_NO_MEMORY;
dtd->scaffIndex = new_scaff_index;
}
} else {
parser->m_groupConnector
= (char *)MALLOC(parser, parser->m_groupSize = 32);
if (! parser->m_groupConnector) {
parser->m_groupSize = 0;
return XML_ERROR_NO_MEMORY;
}
}
}
parser->m_groupConnector[parser->m_prologState.level] = 0;
if (dtd->in_eldecl) {
int myindex = nextScaffoldPart(parser);
if (myindex < 0)
return XML_ERROR_NO_MEMORY;
assert(dtd->scaffIndex != NULL);
dtd->scaffIndex[dtd->scaffLevel] = myindex;
dtd->scaffLevel++;
dtd->scaffold[myindex].type = XML_CTYPE_SEQ;
if (parser->m_elementDeclHandler)
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_GROUP_SEQUENCE:
if (parser->m_groupConnector[parser->m_prologState.level] == ASCII_PIPE)
return XML_ERROR_SYNTAX;
parser->m_groupConnector[parser->m_prologState.level] = ASCII_COMMA;
if (dtd->in_eldecl && parser->m_elementDeclHandler)
handleDefault = XML_FALSE;
break;
case XML_ROLE_GROUP_CHOICE:
if (parser->m_groupConnector[parser->m_prologState.level] == ASCII_COMMA)
return XML_ERROR_SYNTAX;
if (dtd->in_eldecl
&& ! parser->m_groupConnector[parser->m_prologState.level]
&& (dtd->scaffold[dtd->scaffIndex[dtd->scaffLevel - 1]].type
!= XML_CTYPE_MIXED)) {
dtd->scaffold[dtd->scaffIndex[dtd->scaffLevel - 1]].type
= XML_CTYPE_CHOICE;
if (parser->m_elementDeclHandler)
handleDefault = XML_FALSE;
}
parser->m_groupConnector[parser->m_prologState.level] = ASCII_PIPE;
break;
case XML_ROLE_PARAM_ENTITY_REF:
#ifdef XML_DTD
case XML_ROLE_INNER_PARAM_ENTITY_REF:
dtd->hasParamEntityRefs = XML_TRUE;
if (! parser->m_paramEntityParsing)
dtd->keepProcessing = dtd->standalone;
else {
const XML_Char *name;
ENTITY *entity;
name = poolStoreString(&dtd->pool, enc, s + enc->minBytesPerChar,
next - enc->minBytesPerChar);
if (! name)
return XML_ERROR_NO_MEMORY;
entity = (ENTITY *)lookup(parser, &dtd->paramEntities, name, 0);
poolDiscard(&dtd->pool);
/* first, determine if a check for an existing declaration is needed;
if yes, check that the entity exists, and that it is internal,
otherwise call the skipped entity handler
*/
if (parser->m_prologState.documentEntity
&& (dtd->standalone ? ! parser->m_openInternalEntities
: ! dtd->hasParamEntityRefs)) {
if (! entity)
return XML_ERROR_UNDEFINED_ENTITY;
else if (! entity->is_internal) {
/* It's hard to exhaustively search the code to be sure,
* but there doesn't seem to be a way of executing the
* following line. There are two cases:
*
* If 'standalone' is false, the DTD must have no
* parameter entities or we wouldn't have passed the outer
* 'if' statement. That measn the only entity in the hash
* table is the external subset name "#" which cannot be
* given as a parameter entity name in XML syntax, so the
* lookup must have returned NULL and we don't even reach
* the test for an internal entity.
*
* If 'standalone' is true, it does not seem to be
* possible to create entities taking this code path that
* are not internal entities, so fail the test above.
*
* Because this analysis is very uncertain, the code is
* being left in place and merely removed from the
* coverage test statistics.
*/
return XML_ERROR_ENTITY_DECLARED_IN_PE; /* LCOV_EXCL_LINE */
}
} else if (! entity) {
dtd->keepProcessing = dtd->standalone;
/* cannot report skipped entities in declarations */
if ((role == XML_ROLE_PARAM_ENTITY_REF)
&& parser->m_skippedEntityHandler) {
parser->m_skippedEntityHandler(parser->m_handlerArg, name, 1);
handleDefault = XML_FALSE;
}
break;
}
if (entity->open)
return XML_ERROR_RECURSIVE_ENTITY_REF;
if (entity->textPtr) {
enum XML_Error result;
XML_Bool betweenDecl
= (role == XML_ROLE_PARAM_ENTITY_REF ? XML_TRUE : XML_FALSE);
result = processInternalEntity(parser, entity, betweenDecl);
if (result != XML_ERROR_NONE)
return result;
handleDefault = XML_FALSE;
break;
}
if (parser->m_externalEntityRefHandler) {
dtd->paramEntityRead = XML_FALSE;
entity->open = XML_TRUE;
entityTrackingOnOpen(parser, entity, __LINE__);
if (! parser->m_externalEntityRefHandler(
parser->m_externalEntityRefHandlerArg, 0, entity->base,
entity->systemId, entity->publicId)) {
entityTrackingOnClose(parser, entity, __LINE__);
entity->open = XML_FALSE;
return XML_ERROR_EXTERNAL_ENTITY_HANDLING;
}
entityTrackingOnClose(parser, entity, __LINE__);
entity->open = XML_FALSE;
handleDefault = XML_FALSE;
if (! dtd->paramEntityRead) {
dtd->keepProcessing = dtd->standalone;
break;
}
} else {
dtd->keepProcessing = dtd->standalone;
break;
}
}
#endif /* XML_DTD */
if (! dtd->standalone && parser->m_notStandaloneHandler
&& ! parser->m_notStandaloneHandler(parser->m_handlerArg))
return XML_ERROR_NOT_STANDALONE;
break;
/* Element declaration stuff */
case XML_ROLE_ELEMENT_NAME:
if (parser->m_elementDeclHandler) {
parser->m_declElementType = getElementType(parser, enc, s, next);
if (! parser->m_declElementType)
return XML_ERROR_NO_MEMORY;
dtd->scaffLevel = 0;
dtd->scaffCount = 0;
dtd->in_eldecl = XML_TRUE;
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_CONTENT_ANY:
case XML_ROLE_CONTENT_EMPTY:
if (dtd->in_eldecl) {
if (parser->m_elementDeclHandler) {
XML_Content *content
= (XML_Content *)MALLOC(parser, sizeof(XML_Content));
if (! content)
return XML_ERROR_NO_MEMORY;
content->quant = XML_CQUANT_NONE;
content->name = NULL;
content->numchildren = 0;
content->children = NULL;
content->type = ((role == XML_ROLE_CONTENT_ANY) ? XML_CTYPE_ANY
: XML_CTYPE_EMPTY);
*eventEndPP = s;
parser->m_elementDeclHandler(
parser->m_handlerArg, parser->m_declElementType->name, content);
handleDefault = XML_FALSE;
}
dtd->in_eldecl = XML_FALSE;
}
break;
case XML_ROLE_CONTENT_PCDATA:
if (dtd->in_eldecl) {
dtd->scaffold[dtd->scaffIndex[dtd->scaffLevel - 1]].type
= XML_CTYPE_MIXED;
if (parser->m_elementDeclHandler)
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_CONTENT_ELEMENT:
quant = XML_CQUANT_NONE;
goto elementContent;
case XML_ROLE_CONTENT_ELEMENT_OPT:
quant = XML_CQUANT_OPT;
goto elementContent;
case XML_ROLE_CONTENT_ELEMENT_REP:
quant = XML_CQUANT_REP;
goto elementContent;
case XML_ROLE_CONTENT_ELEMENT_PLUS:
quant = XML_CQUANT_PLUS;
elementContent:
if (dtd->in_eldecl) {
ELEMENT_TYPE *el;
const XML_Char *name;
size_t nameLen;
const char *nxt
= (quant == XML_CQUANT_NONE ? next : next - enc->minBytesPerChar);
int myindex = nextScaffoldPart(parser);
if (myindex < 0)
return XML_ERROR_NO_MEMORY;
dtd->scaffold[myindex].type = XML_CTYPE_NAME;
dtd->scaffold[myindex].quant = quant;
el = getElementType(parser, enc, s, nxt);
if (! el)
return XML_ERROR_NO_MEMORY;
name = el->name;
dtd->scaffold[myindex].name = name;
nameLen = 0;
for (; name[nameLen++];)
;
/* Detect and prevent integer overflow */
if (nameLen > UINT_MAX - dtd->contentStringLen) {
return XML_ERROR_NO_MEMORY;
}
dtd->contentStringLen += (unsigned)nameLen;
if (parser->m_elementDeclHandler)
handleDefault = XML_FALSE;
}
break;
case XML_ROLE_GROUP_CLOSE:
quant = XML_CQUANT_NONE;
goto closeGroup;
case XML_ROLE_GROUP_CLOSE_OPT:
quant = XML_CQUANT_OPT;
goto closeGroup;
case XML_ROLE_GROUP_CLOSE_REP:
quant = XML_CQUANT_REP;
goto closeGroup;
case XML_ROLE_GROUP_CLOSE_PLUS:
quant = XML_CQUANT_PLUS;
closeGroup:
if (dtd->in_eldecl) {
if (parser->m_elementDeclHandler)
handleDefault = XML_FALSE;
dtd->scaffLevel--;
dtd->scaffold[dtd->scaffIndex[dtd->scaffLevel]].quant = quant;
if (dtd->scaffLevel == 0) {
if (! handleDefault) {
XML_Content *model = build_model(parser);
if (! model)
return XML_ERROR_NO_MEMORY;
*eventEndPP = s;
parser->m_elementDeclHandler(
parser->m_handlerArg, parser->m_declElementType->name, model);
}
dtd->in_eldecl = XML_FALSE;
dtd->contentStringLen = 0;
}
}
break;
/* End element declaration stuff */
case XML_ROLE_PI:
if (! reportProcessingInstruction(parser, enc, s, next))
return XML_ERROR_NO_MEMORY;
handleDefault = XML_FALSE;
break;
case XML_ROLE_COMMENT:
if (! reportComment(parser, enc, s, next))
return XML_ERROR_NO_MEMORY;
handleDefault = XML_FALSE;
break;
case XML_ROLE_NONE:
switch (tok) {
case XML_TOK_BOM:
handleDefault = XML_FALSE;
break;
}
break;
case XML_ROLE_DOCTYPE_NONE:
if (parser->m_startDoctypeDeclHandler)
handleDefault = XML_FALSE;
break;
case XML_ROLE_ENTITY_NONE:
if (dtd->keepProcessing && parser->m_entityDeclHandler)
handleDefault = XML_FALSE;
break;
case XML_ROLE_NOTATION_NONE:
if (parser->m_notationDeclHandler)
handleDefault = XML_FALSE;
break;
case XML_ROLE_ATTLIST_NONE:
if (dtd->keepProcessing && parser->m_attlistDeclHandler)
handleDefault = XML_FALSE;
break;
case XML_ROLE_ELEMENT_NONE:
if (parser->m_elementDeclHandler)
handleDefault = XML_FALSE;
break;
} /* end of big switch */
if (handleDefault && parser->m_defaultHandler)
reportDefault(parser, enc, s, next);
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
*nextPtr = next;
return XML_ERROR_NONE;
case XML_FINISHED:
return XML_ERROR_ABORTED;
default:
s = next;
tok = XmlPrologTok(enc, s, end, &next);
}
}
/* not reached */
}
static enum XML_Error PTRCALL
epilogProcessor(XML_Parser parser, const char *s, const char *end,
const char **nextPtr) {
parser->m_processor = epilogProcessor;
parser->m_eventPtr = s;
for (;;) {
const char *next = NULL;
int tok = XmlPrologTok(parser->m_encoding, s, end, &next);
#ifdef XML_DTD
if (! accountingDiffTolerated(parser, tok, s, next, __LINE__,
XML_ACCOUNT_DIRECT)) {
accountingOnAbort(parser);
return XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
}
#endif
parser->m_eventEndPtr = next;
switch (tok) {
/* report partial linebreak - it might be the last token */
case -XML_TOK_PROLOG_S:
if (parser->m_defaultHandler) {
reportDefault(parser, parser->m_encoding, s, next);
if (parser->m_parsingStatus.parsing == XML_FINISHED)
return XML_ERROR_ABORTED;
}
*nextPtr = next;
return XML_ERROR_NONE;
case XML_TOK_NONE:
*nextPtr = s;
return XML_ERROR_NONE;
case XML_TOK_PROLOG_S:
if (parser->m_defaultHandler)
reportDefault(parser, parser->m_encoding, s, next);
break;
case XML_TOK_PI:
if (! reportProcessingInstruction(parser, parser->m_encoding, s, next))
return XML_ERROR_NO_MEMORY;
break;
case XML_TOK_COMMENT:
if (! reportComment(parser, parser->m_encoding, s, next))
return XML_ERROR_NO_MEMORY;
break;
case XML_TOK_INVALID:
parser->m_eventPtr = next;
return XML_ERROR_INVALID_TOKEN;
case XML_TOK_PARTIAL:
if (! parser->m_parsingStatus.finalBuffer) {
*nextPtr = s;
return XML_ERROR_NONE;
}
return XML_ERROR_UNCLOSED_TOKEN;
case XML_TOK_PARTIAL_CHAR:
if (! parser->m_parsingStatus.finalBuffer) {
*nextPtr = s;
return XML_ERROR_NONE;
}
return XML_ERROR_PARTIAL_CHAR;
default:
return XML_ERROR_JUNK_AFTER_DOC_ELEMENT;
}
parser->m_eventPtr = s = next;
switch (parser->m_parsingStatus.parsing) {
case XML_SUSPENDED:
*nextPtr = next;
return XML_ERROR_NONE;
case XML_FINISHED:
return XML_ERROR_ABORTED;
default:;
}
}
}
static enum XML_Error
processInternalEntity(XML_Parser parser, ENTITY *entity, XML_Bool betweenDecl) {
const char *textStart, *textEnd;
const char *next;
enum XML_Error result;
OPEN_INTERNAL_ENTITY *openEntity;
if (parser->m_freeInternalEntities) {
openEntity = parser->m_freeInternalEntities;
parser->m_freeInternalEntities = openEntity->next;
} else {
openEntity
= (OPEN_INTERNAL_ENTITY *)MALLOC(parser, sizeof(OPEN_INTERNAL_ENTITY));
if (! openEntity)
return XML_ERROR_NO_MEMORY;
}
entity->open = XML_TRUE;
#ifdef XML_DTD
entityTrackingOnOpen(parser, entity, __LINE__);
#endif
entity->processed = 0;
openEntity->next = parser->m_openInternalEntities;
parser->m_openInternalEntities = openEntity;
openEntity->entity = entity;
openEntity->startTagLevel = parser->m_tagLevel;
openEntity->betweenDecl = betweenDecl;
openEntity->internalEventPtr = NULL;
openEntity->internalEventEndPtr = NULL;
textStart = (const char *)entity->textPtr;
textEnd = (const char *)(entity->textPtr + entity->textLen);
/* Set a safe default value in case 'next' does not get set */
next = textStart;
#ifdef XML_DTD
if (entity->is_param) {
int tok
= XmlPrologTok(parser->m_internalEncoding, textStart, textEnd, &next);
result = doProlog(parser, parser->m_internalEncoding, textStart, textEnd,
tok, next, &next, XML_FALSE, XML_FALSE,
XML_ACCOUNT_ENTITY_EXPANSION);
} else
#endif /* XML_DTD */
result = doContent(parser, parser->m_tagLevel, parser->m_internalEncoding,
textStart, textEnd, &next, XML_FALSE,
XML_ACCOUNT_ENTITY_EXPANSION);
if (result == XML_ERROR_NONE) {
if (textEnd != next && parser->m_parsingStatus.parsing == XML_SUSPENDED) {
entity->processed = (int)(next - textStart);
parser->m_processor = internalEntityProcessor;
} else {
#ifdef XML_DTD
entityTrackingOnClose(parser, entity, __LINE__);
#endif /* XML_DTD */
entity->open = XML_FALSE;
parser->m_openInternalEntities = openEntity->next;
/* put openEntity back in list of free instances */
openEntity->next = parser->m_freeInternalEntities;
parser->m_freeInternalEntities = openEntity;
}
}
return result;
}
static enum XML_Error PTRCALL
internalEntityProcessor(XML_Parser parser, const char *s, const char *end,
const char **nextPtr) {
ENTITY *entity;
const char *textStart, *textEnd;
const char *next;
enum XML_Error result;
OPEN_INTERNAL_ENTITY *openEntity = parser->m_openInternalEntities;
if (! openEntity)
return XML_ERROR_UNEXPECTED_STATE;
entity = openEntity->entity;
textStart = ((const char *)entity->textPtr) + entity->processed;
textEnd = (const char *)(entity->textPtr + entity->textLen);
/* Set a safe default value in case 'next' does not get set */
next = textStart;
#ifdef XML_DTD
if (entity->is_param) {
int tok
= XmlPrologTok(parser->m_internalEncoding, textStart, textEnd, &next);
result = doProlog(parser, parser->m_internalEncoding, textStart, textEnd,
tok, next, &next, XML_FALSE, XML_TRUE,
XML_ACCOUNT_ENTITY_EXPANSION);
} else
#endif /* XML_DTD */
result = doContent(parser, openEntity->startTagLevel,
parser->m_internalEncoding, textStart, textEnd, &next,
XML_FALSE, XML_ACCOUNT_ENTITY_EXPANSION);
if (result != XML_ERROR_NONE)
return result;
else if (textEnd != next
&& parser->m_parsingStatus.parsing == XML_SUSPENDED) {
entity->processed = (int)(next - (const char *)entity->textPtr);
return result;
} else {
#ifdef XML_DTD
entityTrackingOnClose(parser, entity, __LINE__);
#endif
entity->open = XML_FALSE;
parser->m_openInternalEntities = openEntity->next;
/* put openEntity back in list of free instances */
openEntity->next = parser->m_freeInternalEntities;
parser->m_freeInternalEntities = openEntity;
}
#ifdef XML_DTD
if (entity->is_param) {
int tok;
parser->m_processor = prologProcessor;
tok = XmlPrologTok(parser->m_encoding, s, end, &next);
return doProlog(parser, parser->m_encoding, s, end, tok, next, nextPtr,
(XML_Bool)! parser->m_parsingStatus.finalBuffer, XML_TRUE,
XML_ACCOUNT_DIRECT);
} else
#endif /* XML_DTD */
{
parser->m_processor = contentProcessor;
/* see externalEntityContentProcessor vs contentProcessor */
return doContent(parser, parser->m_parentParser ? 1 : 0, parser->m_encoding,
s, end, nextPtr,
(XML_Bool)! parser->m_parsingStatus.finalBuffer,
XML_ACCOUNT_DIRECT);
}
}
static enum XML_Error PTRCALL
errorProcessor(XML_Parser parser, const char *s, const char *end,
const char **nextPtr) {
UNUSED_P(s);
UNUSED_P(end);
UNUSED_P(nextPtr);
return parser->m_errorCode;
}
static enum XML_Error
storeAttributeValue(XML_Parser parser, const ENCODING *enc, XML_Bool isCdata,
const char *ptr, const char *end, STRING_POOL *pool,
enum XML_Account account) {
enum XML_Error result
= appendAttributeValue(parser, enc, isCdata, ptr, end, pool, account);
if (result)
return result;
if (! isCdata && poolLength(pool) && poolLastChar(pool) == 0x20)
poolChop(pool);
if (! poolAppendChar(pool, XML_T('\0')))
return XML_ERROR_NO_MEMORY;
return XML_ERROR_NONE;
}
static enum XML_Error
appendAttributeValue(XML_Parser parser, const ENCODING *enc, XML_Bool isCdata,
const char *ptr, const char *end, STRING_POOL *pool,
enum XML_Account account) {
DTD *const dtd = parser->m_dtd; /* save one level of indirection */
#ifndef XML_DTD
UNUSED_P(account);
#endif
for (;;) {
const char *next
= ptr; /* XmlAttributeValueTok doesn't always set the last arg */
int tok = XmlAttributeValueTok(enc, ptr, end, &next);
#ifdef XML_DTD
if (! accountingDiffTolerated(parser, tok, ptr, next, __LINE__, account)) {
accountingOnAbort(parser);
return XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
}
#endif
switch (tok) {
case XML_TOK_NONE:
return XML_ERROR_NONE;
case XML_TOK_INVALID:
if (enc == parser->m_encoding)
parser->m_eventPtr = next;
return XML_ERROR_INVALID_TOKEN;
case XML_TOK_PARTIAL:
if (enc == parser->m_encoding)
parser->m_eventPtr = ptr;
return XML_ERROR_INVALID_TOKEN;
case XML_TOK_CHAR_REF: {
XML_Char buf[XML_ENCODE_MAX];
int i;
int n = XmlCharRefNumber(enc, ptr);
if (n < 0) {
if (enc == parser->m_encoding)
parser->m_eventPtr = ptr;
return XML_ERROR_BAD_CHAR_REF;
}
if (! isCdata && n == 0x20 /* space */
&& (poolLength(pool) == 0 || poolLastChar(pool) == 0x20))
break;
n = XmlEncode(n, (ICHAR *)buf);
/* The XmlEncode() functions can never return 0 here. That
* error return happens if the code point passed in is either
* negative or greater than or equal to 0x110000. The
* XmlCharRefNumber() functions will all return a number
* strictly less than 0x110000 or a negative value if an error
* occurred. The negative value is intercepted above, so
* XmlEncode() is never passed a value it might return an
* error for.
*/
for (i = 0; i < n; i++) {
if (! poolAppendChar(pool, buf[i]))
return XML_ERROR_NO_MEMORY;
}
} break;
case XML_TOK_DATA_CHARS:
if (! poolAppend(pool, enc, ptr, next))
return XML_ERROR_NO_MEMORY;
break;
case XML_TOK_TRAILING_CR:
next = ptr + enc->minBytesPerChar;
/* fall through */
case XML_TOK_ATTRIBUTE_VALUE_S:
case XML_TOK_DATA_NEWLINE:
if (! isCdata && (poolLength(pool) == 0 || poolLastChar(pool) == 0x20))
break;
if (! poolAppendChar(pool, 0x20))
return XML_ERROR_NO_MEMORY;
break;
case XML_TOK_ENTITY_REF: {
const XML_Char *name;
ENTITY *entity;
char checkEntityDecl;
XML_Char ch = (XML_Char)XmlPredefinedEntityName(
enc, ptr + enc->minBytesPerChar, next - enc->minBytesPerChar);
if (ch) {
#ifdef XML_DTD
/* NOTE: We are replacing 4-6 characters original input for 1 character
* so there is no amplification and hence recording without
* protection. */
accountingDiffTolerated(parser, tok, (char *)&ch,
((char *)&ch) + sizeof(XML_Char), __LINE__,
XML_ACCOUNT_ENTITY_EXPANSION);
#endif /* XML_DTD */
if (! poolAppendChar(pool, ch))
return XML_ERROR_NO_MEMORY;
break;
}
name = poolStoreString(&parser->m_temp2Pool, enc,
ptr + enc->minBytesPerChar,
next - enc->minBytesPerChar);
if (! name)
return XML_ERROR_NO_MEMORY;
entity = (ENTITY *)lookup(parser, &dtd->generalEntities, name, 0);
poolDiscard(&parser->m_temp2Pool);
/* First, determine if a check for an existing declaration is needed;
if yes, check that the entity exists, and that it is internal.
*/
if (pool == &dtd->pool) /* are we called from prolog? */
checkEntityDecl =
#ifdef XML_DTD
parser->m_prologState.documentEntity &&
#endif /* XML_DTD */
(dtd->standalone ? ! parser->m_openInternalEntities
: ! dtd->hasParamEntityRefs);
else /* if (pool == &parser->m_tempPool): we are called from content */
checkEntityDecl = ! dtd->hasParamEntityRefs || dtd->standalone;
if (checkEntityDecl) {
if (! entity)
return XML_ERROR_UNDEFINED_ENTITY;
else if (! entity->is_internal)
return XML_ERROR_ENTITY_DECLARED_IN_PE;
} else if (! entity) {
/* Cannot report skipped entity here - see comments on
parser->m_skippedEntityHandler.
if (parser->m_skippedEntityHandler)
parser->m_skippedEntityHandler(parser->m_handlerArg, name, 0);
*/
/* Cannot call the default handler because this would be
out of sync with the call to the startElementHandler.
if ((pool == &parser->m_tempPool) && parser->m_defaultHandler)
reportDefault(parser, enc, ptr, next);
*/
break;
}
if (entity->open) {
if (enc == parser->m_encoding) {
/* It does not appear that this line can be executed.
*
* The "if (entity->open)" check catches recursive entity
* definitions. In order to be called with an open
* entity, it must have gone through this code before and
* been through the recursive call to
* appendAttributeValue() some lines below. That call
* sets the local encoding ("enc") to the parser's
* internal encoding (internal_utf8 or internal_utf16),
* which can never be the same as the principle encoding.
* It doesn't appear there is another code path that gets
* here with entity->open being TRUE.
*
* Since it is not certain that this logic is watertight,
* we keep the line and merely exclude it from coverage
* tests.
*/
parser->m_eventPtr = ptr; /* LCOV_EXCL_LINE */
}
return XML_ERROR_RECURSIVE_ENTITY_REF;
}
if (entity->notation) {
if (enc == parser->m_encoding)
parser->m_eventPtr = ptr;
return XML_ERROR_BINARY_ENTITY_REF;
}
if (! entity->textPtr) {
if (enc == parser->m_encoding)
parser->m_eventPtr = ptr;
return XML_ERROR_ATTRIBUTE_EXTERNAL_ENTITY_REF;
} else {
enum XML_Error result;
const XML_Char *textEnd = entity->textPtr + entity->textLen;
entity->open = XML_TRUE;
#ifdef XML_DTD
entityTrackingOnOpen(parser, entity, __LINE__);
#endif
result = appendAttributeValue(parser, parser->m_internalEncoding,
isCdata, (const char *)entity->textPtr,
(const char *)textEnd, pool,
XML_ACCOUNT_ENTITY_EXPANSION);
#ifdef XML_DTD
entityTrackingOnClose(parser, entity, __LINE__);
#endif
entity->open = XML_FALSE;
if (result)
return result;
}
} break;
default:
/* The only token returned by XmlAttributeValueTok() that does
* not have an explicit case here is XML_TOK_PARTIAL_CHAR.
* Getting that would require an entity name to contain an
* incomplete XML character (e.g. \xE2\x82); however previous
* tokenisers will have already recognised and rejected such
* names before XmlAttributeValueTok() gets a look-in. This
* default case should be retained as a safety net, but the code
* excluded from coverage tests.
*
* LCOV_EXCL_START
*/
if (enc == parser->m_encoding)
parser->m_eventPtr = ptr;
return XML_ERROR_UNEXPECTED_STATE;
/* LCOV_EXCL_STOP */
}
ptr = next;
}
/* not reached */
}
static enum XML_Error
storeEntityValue(XML_Parser parser, const ENCODING *enc,
const char *entityTextPtr, const char *entityTextEnd,
enum XML_Account account) {
DTD *const dtd = parser->m_dtd; /* save one level of indirection */
STRING_POOL *pool = &(dtd->entityValuePool);
enum XML_Error result = XML_ERROR_NONE;
#ifdef XML_DTD
int oldInEntityValue = parser->m_prologState.inEntityValue;
parser->m_prologState.inEntityValue = 1;
#else
UNUSED_P(account);
#endif /* XML_DTD */
/* never return Null for the value argument in EntityDeclHandler,
since this would indicate an external entity; therefore we
have to make sure that entityValuePool.start is not null */
if (! pool->blocks) {
if (! poolGrow(pool))
return XML_ERROR_NO_MEMORY;
}
for (;;) {
const char *next
= entityTextPtr; /* XmlEntityValueTok doesn't always set the last arg */
int tok = XmlEntityValueTok(enc, entityTextPtr, entityTextEnd, &next);
#ifdef XML_DTD
if (! accountingDiffTolerated(parser, tok, entityTextPtr, next, __LINE__,
account)) {
accountingOnAbort(parser);
result = XML_ERROR_AMPLIFICATION_LIMIT_BREACH;
goto endEntityValue;
}
#endif
switch (tok) {
case XML_TOK_PARAM_ENTITY_REF:
#ifdef XML_DTD
if (parser->m_isParamEntity || enc != parser->m_encoding) {
const XML_Char *name;
ENTITY *entity;
name = poolStoreString(&parser->m_tempPool, enc,
entityTextPtr + enc->minBytesPerChar,
next - enc->minBytesPerChar);
if (! name) {
result = XML_ERROR_NO_MEMORY;
goto endEntityValue;
}
entity = (ENTITY *)lookup(parser, &dtd->paramEntities, name, 0);
poolDiscard(&parser->m_tempPool);
if (! entity) {
/* not a well-formedness error - see XML 1.0: WFC Entity Declared */
/* cannot report skipped entity here - see comments on
parser->m_skippedEntityHandler
if (parser->m_skippedEntityHandler)
parser->m_skippedEntityHandler(parser->m_handlerArg, name, 0);
*/
dtd->keepProcessing = dtd->standalone;
goto endEntityValue;
}
if (entity->open) {
if (enc == parser->m_encoding)
parser->m_eventPtr = entityTextPtr;
result = XML_ERROR_RECURSIVE_ENTITY_REF;
goto endEntityValue;
}
if (entity->systemId) {
if (parser->m_externalEntityRefHandler) {
dtd->paramEntityRead = XML_FALSE;
entity->open = XML_TRUE;
entityTrackingOnOpen(parser, entity, __LINE__);
if (! parser->m_externalEntityRefHandler(
parser->m_externalEntityRefHandlerArg, 0, entity->base,
entity->systemId, entity->publicId)) {
entityTrackingOnClose(parser, entity, __LINE__);
entity->open = XML_FALSE;
result = XML_ERROR_EXTERNAL_ENTITY_HANDLING;
goto endEntityValue;
}
entityTrackingOnClose(parser, entity, __LINE__);
entity->open = XML_FALSE;
if (! dtd->paramEntityRead)
dtd->keepProcessing = dtd->standalone;
} else
dtd->keepProcessing = dtd->standalone;
} else {
entity->open = XML_TRUE;
entityTrackingOnOpen(parser, entity, __LINE__);
result = storeEntityValue(
parser, parser->m_internalEncoding, (const char *)entity->textPtr,
(const char *)(entity->textPtr + entity->textLen),
XML_ACCOUNT_ENTITY_EXPANSION);
entityTrackingOnClose(parser, entity, __LINE__);
entity->open = XML_FALSE;
if (result)
goto endEntityValue;
}
break;
}
#endif /* XML_DTD */
/* In the internal subset, PE references are not legal
within markup declarations, e.g entity values in this case. */
parser->m_eventPtr = entityTextPtr;
result = XML_ERROR_PARAM_ENTITY_REF;
goto endEntityValue;
case XML_TOK_NONE:
result = XML_ERROR_NONE;
goto endEntityValue;
case XML_TOK_ENTITY_REF:
case XML_TOK_DATA_CHARS:
if (! poolAppend(pool, enc, entityTextPtr, next)) {
result = XML_ERROR_NO_MEMORY;
goto endEntityValue;
}
break;
case XML_TOK_TRAILING_CR:
next = entityTextPtr + enc->minBytesPerChar;
/* fall through */
case XML_TOK_DATA_NEWLINE:
if (pool->end == pool->ptr && ! poolGrow(pool)) {
result = XML_ERROR_NO_MEMORY;
goto endEntityValue;
}
*(pool->ptr)++ = 0xA;
break;
case XML_TOK_CHAR_REF: {
XML_Char buf[XML_ENCODE_MAX];
int i;
int n = XmlCharRefNumber(enc, entityTextPtr);
if (n < 0) {
if (enc == parser->m_encoding)
parser->m_eventPtr = entityTextPtr;
result = XML_ERROR_BAD_CHAR_REF;
goto endEntityValue;
}
n = XmlEncode(n, (ICHAR *)buf);
/* The XmlEncode() functions can never return 0 here. That
* error return happens if the code point passed in is either
* negative or greater than or equal to 0x110000. The
* XmlCharRefNumber() functions will all return a number
* strictly less than 0x110000 or a negative value if an error
* occurred. The negative value is intercepted above, so
* XmlEncode() is never passed a value it might return an
* error for.
*/
for (i = 0; i < n; i++) {
if (pool->end == pool->ptr && ! poolGrow(pool)) {
result = XML_ERROR_NO_MEMORY;
goto endEntityValue;
}
*(pool->ptr)++ = buf[i];
}
} break;
case XML_TOK_PARTIAL:
if (enc == parser->m_encoding)
parser->m_eventPtr = entityTextPtr;
result = XML_ERROR_INVALID_TOKEN;
goto endEntityValue;
case XML_TOK_INVALID:
if (enc == parser->m_encoding)
parser->m_eventPtr = next;
result = XML_ERROR_INVALID_TOKEN;
goto endEntityValue;
default:
/* This default case should be unnecessary -- all the tokens
* that XmlEntityValueTok() can return have their own explicit
* cases -- but should be retained for safety. We do however
* exclude it from the coverage statistics.
*
* LCOV_EXCL_START
*/
if (enc == parser->m_encoding)
parser->m_eventPtr = entityTextPtr;
result = XML_ERROR_UNEXPECTED_STATE;
goto endEntityValue;
/* LCOV_EXCL_STOP */
}
entityTextPtr = next;
}
endEntityValue:
#ifdef XML_DTD
parser->m_prologState.inEntityValue = oldInEntityValue;
#endif /* XML_DTD */
return result;
}
static void FASTCALL
normalizeLines(XML_Char *s) {
XML_Char *p;
for (;; s++) {
if (*s == XML_T('\0'))
return;
if (*s == 0xD)
break;
}
p = s;
do {
if (*s == 0xD) {
*p++ = 0xA;
if (*++s == 0xA)
s++;
} else
*p++ = *s++;
} while (*s);
*p = XML_T('\0');
}
static int
reportProcessingInstruction(XML_Parser parser, const ENCODING *enc,
const char *start, const char *end) {
const XML_Char *target;
XML_Char *data;
const char *tem;
if (! parser->m_processingInstructionHandler) {
if (parser->m_defaultHandler)
reportDefault(parser, enc, start, end);
return 1;
}
start += enc->minBytesPerChar * 2;
tem = start + XmlNameLength(enc, start);
target = poolStoreString(&parser->m_tempPool, enc, start, tem);
if (! target)
return 0;
poolFinish(&parser->m_tempPool);
data = poolStoreString(&parser->m_tempPool, enc, XmlSkipS(enc, tem),
end - enc->minBytesPerChar * 2);
if (! data)
return 0;
normalizeLines(data);
parser->m_processingInstructionHandler(parser->m_handlerArg, target, data);
poolClear(&parser->m_tempPool);
return 1;
}
static int
reportComment(XML_Parser parser, const ENCODING *enc, const char *start,
const char *end) {
XML_Char *data;
if (! parser->m_commentHandler) {
if (parser->m_defaultHandler)
reportDefault(parser, enc, start, end);
return 1;
}
data = poolStoreString(&parser->m_tempPool, enc,
start + enc->minBytesPerChar * 4,
end - enc->minBytesPerChar * 3);
if (! data)
return 0;
normalizeLines(data);
parser->m_commentHandler(parser->m_handlerArg, data);
poolClear(&parser->m_tempPool);
return 1;
}
static void
reportDefault(XML_Parser parser, const ENCODING *enc, const char *s,
const char *end) {
if (MUST_CONVERT(enc, s)) {
enum XML_Convert_Result convert_res;
const char **eventPP;
const char **eventEndPP;
if (enc == parser->m_encoding) {
eventPP = &parser->m_eventPtr;
eventEndPP = &parser->m_eventEndPtr;
} else {
/* To get here, two things must be true; the parser must be
* using a character encoding that is not the same as the
* encoding passed in, and the encoding passed in must need
* conversion to the internal format (UTF-8 unless XML_UNICODE
* is defined). The only occasions on which the encoding passed
* in is not the same as the parser's encoding are when it is
* the internal encoding (e.g. a previously defined parameter
* entity, already converted to internal format). This by
* definition doesn't need conversion, so the whole branch never
* gets executed.
*
* For safety's sake we don't delete these lines and merely
* exclude them from coverage statistics.
*
* LCOV_EXCL_START
*/
eventPP = &(parser->m_openInternalEntities->internalEventPtr);
eventEndPP = &(parser->m_openInternalEntities->internalEventEndPtr);
/* LCOV_EXCL_STOP */
}
do {
ICHAR *dataPtr = (ICHAR *)parser->m_dataBuf;
convert_res
= XmlConvert(enc, &s, end, &dataPtr, (ICHAR *)parser->m_dataBufEnd);
*eventEndPP = s;
parser->m_defaultHandler(parser->m_handlerArg, parser->m_dataBuf,
(int)(dataPtr - (ICHAR *)parser->m_dataBuf));
*eventPP = s;
} while ((convert_res != XML_CONVERT_COMPLETED)
&& (convert_res != XML_CONVERT_INPUT_INCOMPLETE));
} else
parser->m_defaultHandler(parser->m_handlerArg, (XML_Char *)s,
(int)((XML_Char *)end - (XML_Char *)s));
}
static int
defineAttribute(ELEMENT_TYPE *type, ATTRIBUTE_ID *attId, XML_Bool isCdata,
XML_Bool isId, const XML_Char *value, XML_Parser parser) {
DEFAULT_ATTRIBUTE *att;
if (value || isId) {
/* The handling of default attributes gets messed up if we have
a default which duplicates a non-default. */
int i;
for (i = 0; i < type->nDefaultAtts; i++)
if (attId == type->defaultAtts[i].id)
return 1;
if (isId && ! type->idAtt && ! attId->xmlns)
type->idAtt = attId;
}
if (type->nDefaultAtts == type->allocDefaultAtts) {
if (type->allocDefaultAtts == 0) {
type->allocDefaultAtts = 8;
type->defaultAtts = (DEFAULT_ATTRIBUTE *)MALLOC(
parser, type->allocDefaultAtts * sizeof(DEFAULT_ATTRIBUTE));
if (! type->defaultAtts) {
type->allocDefaultAtts = 0;
return 0;
}
} else {
DEFAULT_ATTRIBUTE *temp;
/* Detect and prevent integer overflow */
if (type->allocDefaultAtts > INT_MAX / 2) {
return 0;
}
int count = type->allocDefaultAtts * 2;
/* Detect and prevent integer overflow.
* The preprocessor guard addresses the "always false" warning
* from -Wtype-limits on platforms where
* sizeof(unsigned int) < sizeof(size_t), e.g. on x86_64. */
#if UINT_MAX >= SIZE_MAX
if ((unsigned)count > (size_t)(-1) / sizeof(DEFAULT_ATTRIBUTE)) {
return 0;
}
#endif
temp = (DEFAULT_ATTRIBUTE *)REALLOC(parser, type->defaultAtts,
(count * sizeof(DEFAULT_ATTRIBUTE)));
if (temp == NULL)
return 0;
type->allocDefaultAtts = count;
type->defaultAtts = temp;
}
}
att = type->defaultAtts + type->nDefaultAtts;
att->id = attId;
att->value = value;
att->isCdata = isCdata;
if (! isCdata)
attId->maybeTokenized = XML_TRUE;
type->nDefaultAtts += 1;
return 1;
}
static int
setElementTypePrefix(XML_Parser parser, ELEMENT_TYPE *elementType) {
DTD *const dtd = parser->m_dtd; /* save one level of indirection */
const XML_Char *name;
for (name = elementType->name; *name; name++) {
if (*name == XML_T(ASCII_COLON)) {
PREFIX *prefix;
const XML_Char *s;
for (s = elementType->name; s != name; s++) {
if (! poolAppendChar(&dtd->pool, *s))
return 0;
}
if (! poolAppendChar(&dtd->pool, XML_T('\0')))
return 0;
prefix = (PREFIX *)lookup(parser, &dtd->prefixes, poolStart(&dtd->pool),
sizeof(PREFIX));
if (! prefix)
return 0;
if (prefix->name == poolStart(&dtd->pool))
poolFinish(&dtd->pool);
else
poolDiscard(&dtd->pool);
elementType->prefix = prefix;
break;
}
}
return 1;
}
static ATTRIBUTE_ID *
getAttributeId(XML_Parser parser, const ENCODING *enc, const char *start,
const char *end) {
DTD *const dtd = parser->m_dtd; /* save one level of indirection */
ATTRIBUTE_ID *id;
const XML_Char *name;
if (! poolAppendChar(&dtd->pool, XML_T('\0')))
return NULL;
name = poolStoreString(&dtd->pool, enc, start, end);
if (! name)
return NULL;
/* skip quotation mark - its storage will be re-used (like in name[-1]) */
++name;
id = (ATTRIBUTE_ID *)lookup(parser, &dtd->attributeIds, name,
sizeof(ATTRIBUTE_ID));
if (! id)
return NULL;
if (id->name != name)
poolDiscard(&dtd->pool);
else {
poolFinish(&dtd->pool);
if (! parser->m_ns)
;
else if (name[0] == XML_T(ASCII_x) && name[1] == XML_T(ASCII_m)
&& name[2] == XML_T(ASCII_l) && name[3] == XML_T(ASCII_n)
&& name[4] == XML_T(ASCII_s)
&& (name[5] == XML_T('\0') || name[5] == XML_T(ASCII_COLON))) {
if (name[5] == XML_T('\0'))
id->prefix = &dtd->defaultPrefix;
else
id->prefix = (PREFIX *)lookup(parser, &dtd->prefixes, name + 6,
sizeof(PREFIX));
id->xmlns = XML_TRUE;
} else {
int i;
for (i = 0; name[i]; i++) {
/* attributes without prefix are *not* in the default namespace */
if (name[i] == XML_T(ASCII_COLON)) {
int j;
for (j = 0; j < i; j++) {
if (! poolAppendChar(&dtd->pool, name[j]))
return NULL;
}
if (! poolAppendChar(&dtd->pool, XML_T('\0')))
return NULL;
id->prefix = (PREFIX *)lookup(parser, &dtd->prefixes,
poolStart(&dtd->pool), sizeof(PREFIX));
if (! id->prefix)
return NULL;
if (id->prefix->name == poolStart(&dtd->pool))
poolFinish(&dtd->pool);
else
poolDiscard(&dtd->pool);
break;
}
}
}
}
return id;
}
#define CONTEXT_SEP XML_T(ASCII_FF)
static const XML_Char *
getContext(XML_Parser parser) {
DTD *const dtd = parser->m_dtd; /* save one level of indirection */
HASH_TABLE_ITER iter;
XML_Bool needSep = XML_FALSE;
if (dtd->defaultPrefix.binding) {
int i;
int len;
if (! poolAppendChar(&parser->m_tempPool, XML_T(ASCII_EQUALS)))
return NULL;
len = dtd->defaultPrefix.binding->uriLen;
if (parser->m_namespaceSeparator)
len--;
for (i = 0; i < len; i++) {
if (! poolAppendChar(&parser->m_tempPool,
dtd->defaultPrefix.binding->uri[i])) {
/* Because of memory caching, I don't believe this line can be
* executed.
*
* This is part of a loop copying the default prefix binding
* URI into the parser's temporary string pool. Previously,
* that URI was copied into the same string pool, with a
* terminating NUL character, as part of setContext(). When
* the pool was cleared, that leaves a block definitely big
* enough to hold the URI on the free block list of the pool.
* The URI copy in getContext() therefore cannot run out of
* memory.
*
* If the pool is used between the setContext() and
* getContext() calls, the worst it can do is leave a bigger
* block on the front of the free list. Given that this is
* all somewhat inobvious and program logic can be changed, we
* don't delete the line but we do exclude it from the test
* coverage statistics.
*/
return NULL; /* LCOV_EXCL_LINE */
}
}
needSep = XML_TRUE;
}
hashTableIterInit(&iter, &(dtd->prefixes));
for (;;) {
int i;
int len;
const XML_Char *s;
PREFIX *prefix = (PREFIX *)hashTableIterNext(&iter);
if (! prefix)
break;
if (! prefix->binding) {
/* This test appears to be (justifiable) paranoia. There does
* not seem to be a way of injecting a prefix without a binding
* that doesn't get errored long before this function is called.
* The test should remain for safety's sake, so we instead
* exclude the following line from the coverage statistics.
*/
continue; /* LCOV_EXCL_LINE */
}
if (needSep && ! poolAppendChar(&parser->m_tempPool, CONTEXT_SEP))
return NULL;
for (s = prefix->name; *s; s++)
if (! poolAppendChar(&parser->m_tempPool, *s))
return NULL;
if (! poolAppendChar(&parser->m_tempPool, XML_T(ASCII_EQUALS)))
return NULL;
len = prefix->binding->uriLen;
if (parser->m_namespaceSeparator)
len--;
for (i = 0; i < len; i++)
if (! poolAppendChar(&parser->m_tempPool, prefix->binding->uri[i]))
return NULL;
needSep = XML_TRUE;
}
hashTableIterInit(&iter, &(dtd->generalEntities));
for (;;) {
const XML_Char *s;
ENTITY *e = (ENTITY *)hashTableIterNext(&iter);
if (! e)
break;
if (! e->open)
continue;
if (needSep && ! poolAppendChar(&parser->m_tempPool, CONTEXT_SEP))
return NULL;
for (s = e->name; *s; s++)
if (! poolAppendChar(&parser->m_tempPool, *s))
return 0;
needSep = XML_TRUE;
}
if (! poolAppendChar(&parser->m_tempPool, XML_T('\0')))
return NULL;
return parser->m_tempPool.start;
}
static XML_Bool
setContext(XML_Parser parser, const XML_Char *context) {
DTD *const dtd = parser->m_dtd; /* save one level of indirection */
const XML_Char *s = context;
while (*context != XML_T('\0')) {
if (*s == CONTEXT_SEP || *s == XML_T('\0')) {
ENTITY *e;
if (! poolAppendChar(&parser->m_tempPool, XML_T('\0')))
return XML_FALSE;
e = (ENTITY *)lookup(parser, &dtd->generalEntities,
poolStart(&parser->m_tempPool), 0);
if (e)
e->open = XML_TRUE;
if (*s != XML_T('\0'))
s++;
context = s;
poolDiscard(&parser->m_tempPool);
} else if (*s == XML_T(ASCII_EQUALS)) {
PREFIX *prefix;
if (poolLength(&parser->m_tempPool) == 0)
prefix = &dtd->defaultPrefix;
else {
if (! poolAppendChar(&parser->m_tempPool, XML_T('\0')))
return XML_FALSE;
prefix
= (PREFIX *)lookup(parser, &dtd->prefixes,
poolStart(&parser->m_tempPool), sizeof(PREFIX));
if (! prefix)
return XML_FALSE;
if (prefix->name == poolStart(&parser->m_tempPool)) {
prefix->name = poolCopyString(&dtd->pool, prefix->name);
if (! prefix->name)
return XML_FALSE;
}
poolDiscard(&parser->m_tempPool);
}
for (context = s + 1; *context != CONTEXT_SEP && *context != XML_T('\0');
context++)
if (! poolAppendChar(&parser->m_tempPool, *context))
return XML_FALSE;
if (! poolAppendChar(&parser->m_tempPool, XML_T('\0')))
return XML_FALSE;
if (addBinding(parser, prefix, NULL, poolStart(&parser->m_tempPool),
&parser->m_inheritedBindings)
!= XML_ERROR_NONE)
return XML_FALSE;
poolDiscard(&parser->m_tempPool);
if (*context != XML_T('\0'))
++context;
s = context;
} else {
if (! poolAppendChar(&parser->m_tempPool, *s))
return XML_FALSE;
s++;
}
}
return XML_TRUE;
}
static void FASTCALL
normalizePublicId(XML_Char *publicId) {
XML_Char *p = publicId;
XML_Char *s;
for (s = publicId; *s; s++) {
switch (*s) {
case 0x20:
case 0xD:
case 0xA:
if (p != publicId && p[-1] != 0x20)
*p++ = 0x20;
break;
default:
*p++ = *s;
}
}
if (p != publicId && p[-1] == 0x20)
--p;
*p = XML_T('\0');
}
static DTD *
dtdCreate(const XML_Memory_Handling_Suite *ms) {
DTD *p = ms->malloc_fcn(sizeof(DTD));
if (p == NULL)
return p;
poolInit(&(p->pool), ms);
poolInit(&(p->entityValuePool), ms);
hashTableInit(&(p->generalEntities), ms);
hashTableInit(&(p->elementTypes), ms);
hashTableInit(&(p->attributeIds), ms);
hashTableInit(&(p->prefixes), ms);
#ifdef XML_DTD
p->paramEntityRead = XML_FALSE;
hashTableInit(&(p->paramEntities), ms);
#endif /* XML_DTD */
p->defaultPrefix.name = NULL;
p->defaultPrefix.binding = NULL;
p->in_eldecl = XML_FALSE;
p->scaffIndex = NULL;
p->scaffold = NULL;
p->scaffLevel = 0;
p->scaffSize = 0;
p->scaffCount = 0;
p->contentStringLen = 0;
p->keepProcessing = XML_TRUE;
p->hasParamEntityRefs = XML_FALSE;
p->standalone = XML_FALSE;
return p;
}
static void
dtdReset(DTD *p, const XML_Memory_Handling_Suite *ms) {
HASH_TABLE_ITER iter;
hashTableIterInit(&iter, &(p->elementTypes));
for (;;) {
ELEMENT_TYPE *e = (ELEMENT_TYPE *)hashTableIterNext(&iter);
if (! e)
break;
if (e->allocDefaultAtts != 0)
ms->free_fcn(e->defaultAtts);
}
hashTableClear(&(p->generalEntities));
#ifdef XML_DTD
p->paramEntityRead = XML_FALSE;
hashTableClear(&(p->paramEntities));
#endif /* XML_DTD */
hashTableClear(&(p->elementTypes));
hashTableClear(&(p->attributeIds));
hashTableClear(&(p->prefixes));
poolClear(&(p->pool));
poolClear(&(p->entityValuePool));
p->defaultPrefix.name = NULL;
p->defaultPrefix.binding = NULL;
p->in_eldecl = XML_FALSE;
ms->free_fcn(p->scaffIndex);
p->scaffIndex = NULL;
ms->free_fcn(p->scaffold);
p->scaffold = NULL;
p->scaffLevel = 0;
p->scaffSize = 0;
p->scaffCount = 0;
p->contentStringLen = 0;
p->keepProcessing = XML_TRUE;
p->hasParamEntityRefs = XML_FALSE;
p->standalone = XML_FALSE;
}
static void
dtdDestroy(DTD *p, XML_Bool isDocEntity, const XML_Memory_Handling_Suite *ms) {
HASH_TABLE_ITER iter;
hashTableIterInit(&iter, &(p->elementTypes));
for (;;) {
ELEMENT_TYPE *e = (ELEMENT_TYPE *)hashTableIterNext(&iter);
if (! e)
break;
if (e->allocDefaultAtts != 0)
ms->free_fcn(e->defaultAtts);
}
hashTableDestroy(&(p->generalEntities));
#ifdef XML_DTD
hashTableDestroy(&(p->paramEntities));
#endif /* XML_DTD */
hashTableDestroy(&(p->elementTypes));
hashTableDestroy(&(p->attributeIds));
hashTableDestroy(&(p->prefixes));
poolDestroy(&(p->pool));
poolDestroy(&(p->entityValuePool));
if (isDocEntity) {
ms->free_fcn(p->scaffIndex);
ms->free_fcn(p->scaffold);
}
ms->free_fcn(p);
}
/* Do a deep copy of the DTD. Return 0 for out of memory, non-zero otherwise.
The new DTD has already been initialized.
*/
static int
dtdCopy(XML_Parser oldParser, DTD *newDtd, const DTD *oldDtd,
const XML_Memory_Handling_Suite *ms) {
HASH_TABLE_ITER iter;
/* Copy the prefix table. */
hashTableIterInit(&iter, &(oldDtd->prefixes));
for (;;) {
const XML_Char *name;
const PREFIX *oldP = (PREFIX *)hashTableIterNext(&iter);
if (! oldP)
break;
name = poolCopyString(&(newDtd->pool), oldP->name);
if (! name)
return 0;
if (! lookup(oldParser, &(newDtd->prefixes), name, sizeof(PREFIX)))
return 0;
}
hashTableIterInit(&iter, &(oldDtd->attributeIds));
/* Copy the attribute id table. */
for (;;) {
ATTRIBUTE_ID *newA;
const XML_Char *name;
const ATTRIBUTE_ID *oldA = (ATTRIBUTE_ID *)hashTableIterNext(&iter);
if (! oldA)
break;
/* Remember to allocate the scratch byte before the name. */
if (! poolAppendChar(&(newDtd->pool), XML_T('\0')))
return 0;
name = poolCopyString(&(newDtd->pool), oldA->name);
if (! name)
return 0;
++name;
newA = (ATTRIBUTE_ID *)lookup(oldParser, &(newDtd->attributeIds), name,
sizeof(ATTRIBUTE_ID));
if (! newA)
return 0;
newA->maybeTokenized = oldA->maybeTokenized;
if (oldA->prefix) {
newA->xmlns = oldA->xmlns;
if (oldA->prefix == &oldDtd->defaultPrefix)
newA->prefix = &newDtd->defaultPrefix;
else
newA->prefix = (PREFIX *)lookup(oldParser, &(newDtd->prefixes),
oldA->prefix->name, 0);
}
}
/* Copy the element type table. */
hashTableIterInit(&iter, &(oldDtd->elementTypes));
for (;;) {
int i;
ELEMENT_TYPE *newE;
const XML_Char *name;
const ELEMENT_TYPE *oldE = (ELEMENT_TYPE *)hashTableIterNext(&iter);
if (! oldE)
break;
name = poolCopyString(&(newDtd->pool), oldE->name);
if (! name)
return 0;
newE = (ELEMENT_TYPE *)lookup(oldParser, &(newDtd->elementTypes), name,
sizeof(ELEMENT_TYPE));
if (! newE)
return 0;
if (oldE->nDefaultAtts) {
newE->defaultAtts
= ms->malloc_fcn(oldE->nDefaultAtts * sizeof(DEFAULT_ATTRIBUTE));
if (! newE->defaultAtts) {
return 0;
}
}
if (oldE->idAtt)
newE->idAtt = (ATTRIBUTE_ID *)lookup(oldParser, &(newDtd->attributeIds),
oldE->idAtt->name, 0);
newE->allocDefaultAtts = newE->nDefaultAtts = oldE->nDefaultAtts;
if (oldE->prefix)
newE->prefix = (PREFIX *)lookup(oldParser, &(newDtd->prefixes),
oldE->prefix->name, 0);
for (i = 0; i < newE->nDefaultAtts; i++) {
newE->defaultAtts[i].id = (ATTRIBUTE_ID *)lookup(
oldParser, &(newDtd->attributeIds), oldE->defaultAtts[i].id->name, 0);
newE->defaultAtts[i].isCdata = oldE->defaultAtts[i].isCdata;
if (oldE->defaultAtts[i].value) {
newE->defaultAtts[i].value
= poolCopyString(&(newDtd->pool), oldE->defaultAtts[i].value);
if (! newE->defaultAtts[i].value)
return 0;
} else
newE->defaultAtts[i].value = NULL;
}
}
/* Copy the entity tables. */
if (! copyEntityTable(oldParser, &(newDtd->generalEntities), &(newDtd->pool),
&(oldDtd->generalEntities)))
return 0;
#ifdef XML_DTD
if (! copyEntityTable(oldParser, &(newDtd->paramEntities), &(newDtd->pool),
&(oldDtd->paramEntities)))
return 0;
newDtd->paramEntityRead = oldDtd->paramEntityRead;
#endif /* XML_DTD */
newDtd->keepProcessing = oldDtd->keepProcessing;
newDtd->hasParamEntityRefs = oldDtd->hasParamEntityRefs;
newDtd->standalone = oldDtd->standalone;
/* Don't want deep copying for scaffolding */
newDtd->in_eldecl = oldDtd->in_eldecl;
newDtd->scaffold = oldDtd->scaffold;
newDtd->contentStringLen = oldDtd->contentStringLen;
newDtd->scaffSize = oldDtd->scaffSize;
newDtd->scaffLevel = oldDtd->scaffLevel;
newDtd->scaffIndex = oldDtd->scaffIndex;
return 1;
} /* End dtdCopy */
static int
copyEntityTable(XML_Parser oldParser, HASH_TABLE *newTable,
STRING_POOL *newPool, const HASH_TABLE *oldTable) {
HASH_TABLE_ITER iter;
const XML_Char *cachedOldBase = NULL;
const XML_Char *cachedNewBase = NULL;
hashTableIterInit(&iter, oldTable);
for (;;) {
ENTITY *newE;
const XML_Char *name;
const ENTITY *oldE = (ENTITY *)hashTableIterNext(&iter);
if (! oldE)
break;
name = poolCopyString(newPool, oldE->name);
if (! name)
return 0;
newE = (ENTITY *)lookup(oldParser, newTable, name, sizeof(ENTITY));
if (! newE)
return 0;
if (oldE->systemId) {
const XML_Char *tem = poolCopyString(newPool, oldE->systemId);
if (! tem)
return 0;
newE->systemId = tem;
if (oldE->base) {
if (oldE->base == cachedOldBase)
newE->base = cachedNewBase;
else {
cachedOldBase = oldE->base;
tem = poolCopyString(newPool, cachedOldBase);
if (! tem)
return 0;
cachedNewBase = newE->base = tem;
}
}
if (oldE->publicId) {
tem = poolCopyString(newPool, oldE->publicId);
if (! tem)
return 0;
newE->publicId = tem;
}
} else {
const XML_Char *tem
= poolCopyStringN(newPool, oldE->textPtr, oldE->textLen);
if (! tem)
return 0;
newE->textPtr = tem;
newE->textLen = oldE->textLen;
}
if (oldE->notation) {
const XML_Char *tem = poolCopyString(newPool, oldE->notation);
if (! tem)
return 0;
newE->notation = tem;
}
newE->is_param = oldE->is_param;
newE->is_internal = oldE->is_internal;
}
return 1;
}
#define INIT_POWER 6
static XML_Bool FASTCALL
keyeq(KEY s1, KEY s2) {
for (; *s1 == *s2; s1++, s2++)
if (*s1 == 0)
return XML_TRUE;
return XML_FALSE;
}
static size_t
keylen(KEY s) {
size_t len = 0;
for (; *s; s++, len++)
;
return len;
}
static void
copy_salt_to_sipkey(XML_Parser parser, struct sipkey *key) {
key->k[0] = 0;
key->k[1] = get_hash_secret_salt(parser);
}
static unsigned long FASTCALL
hash(XML_Parser parser, KEY s) {
struct siphash state;
struct sipkey key;
(void)sip24_valid;
copy_salt_to_sipkey(parser, &key);
sip24_init(&state, &key);
sip24_update(&state, s, keylen(s) * sizeof(XML_Char));
return (unsigned long)sip24_final(&state);
}
static NAMED *
lookup(XML_Parser parser, HASH_TABLE *table, KEY name, size_t createSize) {
size_t i;
if (table->size == 0) {
size_t tsize;
if (! createSize)
return NULL;
table->power = INIT_POWER;
/* table->size is a power of 2 */
table->size = (size_t)1 << INIT_POWER;
tsize = table->size * sizeof(NAMED *);
table->v = table->mem->malloc_fcn(tsize);
if (! table->v) {
table->size = 0;
return NULL;
}
memset(table->v, 0, tsize);
i = hash(parser, name) & ((unsigned long)table->size - 1);
} else {
unsigned long h = hash(parser, name);
unsigned long mask = (unsigned long)table->size - 1;
unsigned char step = 0;
i = h & mask;
while (table->v[i]) {
if (keyeq(name, table->v[i]->name))
return table->v[i];
if (! step)
step = PROBE_STEP(h, mask, table->power);
i < step ? (i += table->size - step) : (i -= step);
}
if (! createSize)
return NULL;
/* check for overflow (table is half full) */
if (table->used >> (table->power - 1)) {
unsigned char newPower = table->power + 1;
/* Detect and prevent invalid shift */
if (newPower >= sizeof(unsigned long) * 8 /* bits per byte */) {
return NULL;
}
size_t newSize = (size_t)1 << newPower;
unsigned long newMask = (unsigned long)newSize - 1;
/* Detect and prevent integer overflow */
if (newSize > (size_t)(-1) / sizeof(NAMED *)) {
return NULL;
}
size_t tsize = newSize * sizeof(NAMED *);
NAMED **newV = table->mem->malloc_fcn(tsize);
if (! newV)
return NULL;
memset(newV, 0, tsize);
for (i = 0; i < table->size; i++)
if (table->v[i]) {
unsigned long newHash = hash(parser, table->v[i]->name);
size_t j = newHash & newMask;
step = 0;
while (newV[j]) {
if (! step)
step = PROBE_STEP(newHash, newMask, newPower);
j < step ? (j += newSize - step) : (j -= step);
}
newV[j] = table->v[i];
}
table->mem->free_fcn(table->v);
table->v = newV;
table->power = newPower;
table->size = newSize;
i = h & newMask;
step = 0;
while (table->v[i]) {
if (! step)
step = PROBE_STEP(h, newMask, newPower);
i < step ? (i += newSize - step) : (i -= step);
}
}
}
table->v[i] = table->mem->malloc_fcn(createSize);
if (! table->v[i])
return NULL;
memset(table->v[i], 0, createSize);
table->v[i]->name = name;
(table->used)++;
return table->v[i];
}
static void FASTCALL
hashTableClear(HASH_TABLE *table) {
size_t i;
for (i = 0; i < table->size; i++) {
table->mem->free_fcn(table->v[i]);
table->v[i] = NULL;
}
table->used = 0;
}
static void FASTCALL
hashTableDestroy(HASH_TABLE *table) {
size_t i;
for (i = 0; i < table->size; i++)
table->mem->free_fcn(table->v[i]);
table->mem->free_fcn(table->v);
}
static void FASTCALL
hashTableInit(HASH_TABLE *p, const XML_Memory_Handling_Suite *ms) {
p->power = 0;
p->size = 0;
p->used = 0;
p->v = NULL;
p->mem = ms;
}
static void FASTCALL
hashTableIterInit(HASH_TABLE_ITER *iter, const HASH_TABLE *table) {
iter->p = table->v;
iter->end = iter->p ? iter->p + table->size : NULL;
}
static NAMED *FASTCALL
hashTableIterNext(HASH_TABLE_ITER *iter) {
while (iter->p != iter->end) {
NAMED *tem = *(iter->p)++;
if (tem)
return tem;
}
return NULL;
}
static void FASTCALL
poolInit(STRING_POOL *pool, const XML_Memory_Handling_Suite *ms) {
pool->blocks = NULL;
pool->freeBlocks = NULL;
pool->start = NULL;
pool->ptr = NULL;
pool->end = NULL;
pool->mem = ms;
}
static void FASTCALL
poolClear(STRING_POOL *pool) {
if (! pool->freeBlocks)
pool->freeBlocks = pool->blocks;
else {
BLOCK *p = pool->blocks;
while (p) {
BLOCK *tem = p->next;
p->next = pool->freeBlocks;
pool->freeBlocks = p;
p = tem;
}
}
pool->blocks = NULL;
pool->start = NULL;
pool->ptr = NULL;
pool->end = NULL;
}
static void FASTCALL
poolDestroy(STRING_POOL *pool) {
BLOCK *p = pool->blocks;
while (p) {
BLOCK *tem = p->next;
pool->mem->free_fcn(p);
p = tem;
}
p = pool->freeBlocks;
while (p) {
BLOCK *tem = p->next;
pool->mem->free_fcn(p);
p = tem;
}
}
static XML_Char *
poolAppend(STRING_POOL *pool, const ENCODING *enc, const char *ptr,
const char *end) {
if (! pool->ptr && ! poolGrow(pool))
return NULL;
for (;;) {
const enum XML_Convert_Result convert_res = XmlConvert(
enc, &ptr, end, (ICHAR **)&(pool->ptr), (ICHAR *)pool->end);
if ((convert_res == XML_CONVERT_COMPLETED)
|| (convert_res == XML_CONVERT_INPUT_INCOMPLETE))
break;
if (! poolGrow(pool))
return NULL;
}
return pool->start;
}
static const XML_Char *FASTCALL
poolCopyString(STRING_POOL *pool, const XML_Char *s) {
do {
if (! poolAppendChar(pool, *s))
return NULL;
} while (*s++);
s = pool->start;
poolFinish(pool);
return s;
}
static const XML_Char *
poolCopyStringN(STRING_POOL *pool, const XML_Char *s, int n) {
if (! pool->ptr && ! poolGrow(pool)) {
/* The following line is unreachable given the current usage of
* poolCopyStringN(). Currently it is called from exactly one
* place to copy the text of a simple general entity. By that
* point, the name of the entity is already stored in the pool, so
* pool->ptr cannot be NULL.
*
* If poolCopyStringN() is used elsewhere as it well might be,
* this line may well become executable again. Regardless, this
* sort of check shouldn't be removed lightly, so we just exclude
* it from the coverage statistics.
*/
return NULL; /* LCOV_EXCL_LINE */
}
for (; n > 0; --n, s++) {
if (! poolAppendChar(pool, *s))
return NULL;
}
s = pool->start;
poolFinish(pool);
return s;
}
static const XML_Char *FASTCALL
poolAppendString(STRING_POOL *pool, const XML_Char *s) {
while (*s) {
if (! poolAppendChar(pool, *s))
return NULL;
s++;
}
return pool->start;
}
static XML_Char *
poolStoreString(STRING_POOL *pool, const ENCODING *enc, const char *ptr,
const char *end) {
if (! poolAppend(pool, enc, ptr, end))
return NULL;
if (pool->ptr == pool->end && ! poolGrow(pool))
return NULL;
*(pool->ptr)++ = 0;
return pool->start;
}
static size_t
poolBytesToAllocateFor(int blockSize) {
/* Unprotected math would be:
** return offsetof(BLOCK, s) + blockSize * sizeof(XML_Char);
**
** Detect overflow, avoiding _signed_ overflow undefined behavior
** For a + b * c we check b * c in isolation first, so that addition of a
** on top has no chance of making us accept a small non-negative number
*/
const size_t stretch = sizeof(XML_Char); /* can be 4 bytes */
if (blockSize <= 0)
return 0;
if (blockSize > (int)(INT_MAX / stretch))
return 0;
{
const int stretchedBlockSize = blockSize * (int)stretch;
const int bytesToAllocate
= (int)(offsetof(BLOCK, s) + (unsigned)stretchedBlockSize);
if (bytesToAllocate < 0)
return 0;
return (size_t)bytesToAllocate;
}
}
static XML_Bool FASTCALL
poolGrow(STRING_POOL *pool) {
if (pool->freeBlocks) {
if (pool->start == 0) {
pool->blocks = pool->freeBlocks;
pool->freeBlocks = pool->freeBlocks->next;
pool->blocks->next = NULL;
pool->start = pool->blocks->s;
pool->end = pool->start + pool->blocks->size;
pool->ptr = pool->start;
return XML_TRUE;
}
if (pool->end - pool->start < pool->freeBlocks->size) {
BLOCK *tem = pool->freeBlocks->next;
pool->freeBlocks->next = pool->blocks;
pool->blocks = pool->freeBlocks;
pool->freeBlocks = tem;
memcpy(pool->blocks->s, pool->start,
(pool->end - pool->start) * sizeof(XML_Char));
pool->ptr = pool->blocks->s + (pool->ptr - pool->start);
pool->start = pool->blocks->s;
pool->end = pool->start + pool->blocks->size;
return XML_TRUE;
}
}
if (pool->blocks && pool->start == pool->blocks->s) {
BLOCK *temp;
int blockSize = (int)((unsigned)(pool->end - pool->start) * 2U);
size_t bytesToAllocate;
/* NOTE: Needs to be calculated prior to calling `realloc`
to avoid dangling pointers: */
const ptrdiff_t offsetInsideBlock = pool->ptr - pool->start;
if (blockSize < 0) {
/* This condition traps a situation where either more than
* INT_MAX/2 bytes have already been allocated. This isn't
* readily testable, since it is unlikely that an average
* machine will have that much memory, so we exclude it from the
* coverage statistics.
*/
return XML_FALSE; /* LCOV_EXCL_LINE */
}
bytesToAllocate = poolBytesToAllocateFor(blockSize);
if (bytesToAllocate == 0)
return XML_FALSE;
temp = (BLOCK *)pool->mem->realloc_fcn(pool->blocks,
(unsigned)bytesToAllocate);
if (temp == NULL)
return XML_FALSE;
pool->blocks = temp;
pool->blocks->size = blockSize;
pool->ptr = pool->blocks->s + offsetInsideBlock;
pool->start = pool->blocks->s;
pool->end = pool->start + blockSize;
} else {
BLOCK *tem;
int blockSize = (int)(pool->end - pool->start);
size_t bytesToAllocate;
if (blockSize < 0) {
/* This condition traps a situation where either more than
* INT_MAX bytes have already been allocated (which is prevented
* by various pieces of program logic, not least this one, never
* mind the unlikelihood of actually having that much memory) or
* the pool control fields have been corrupted (which could
* conceivably happen in an extremely buggy user handler
* function). Either way it isn't readily testable, so we
* exclude it from the coverage statistics.
*/
return XML_FALSE; /* LCOV_EXCL_LINE */
}
if (blockSize < INIT_BLOCK_SIZE)
blockSize = INIT_BLOCK_SIZE;
else {
/* Detect overflow, avoiding _signed_ overflow undefined behavior */
if ((int)((unsigned)blockSize * 2U) < 0) {
return XML_FALSE;
}
blockSize *= 2;
}
bytesToAllocate = poolBytesToAllocateFor(blockSize);
if (bytesToAllocate == 0)
return XML_FALSE;
tem = pool->mem->malloc_fcn(bytesToAllocate);
if (! tem)
return XML_FALSE;
tem->size = blockSize;
tem->next = pool->blocks;
pool->blocks = tem;
if (pool->ptr != pool->start)
memcpy(tem->s, pool->start, (pool->ptr - pool->start) * sizeof(XML_Char));
pool->ptr = tem->s + (pool->ptr - pool->start);
pool->start = tem->s;
pool->end = tem->s + blockSize;
}
return XML_TRUE;
}
static int FASTCALL
nextScaffoldPart(XML_Parser parser) {
DTD *const dtd = parser->m_dtd; /* save one level of indirection */
CONTENT_SCAFFOLD *me;
int next;
if (! dtd->scaffIndex) {
dtd->scaffIndex = (int *)MALLOC(parser, parser->m_groupSize * sizeof(int));
if (! dtd->scaffIndex)
return -1;
dtd->scaffIndex[0] = 0;
}
if (dtd->scaffCount >= dtd->scaffSize) {
CONTENT_SCAFFOLD *temp;
if (dtd->scaffold) {
/* Detect and prevent integer overflow */
if (dtd->scaffSize > UINT_MAX / 2u) {
return -1;
}
/* Detect and prevent integer overflow.
* The preprocessor guard addresses the "always false" warning
* from -Wtype-limits on platforms where
* sizeof(unsigned int) < sizeof(size_t), e.g. on x86_64. */
#if UINT_MAX >= SIZE_MAX
if (dtd->scaffSize > (size_t)(-1) / 2u / sizeof(CONTENT_SCAFFOLD)) {
return -1;
}
#endif
temp = (CONTENT_SCAFFOLD *)REALLOC(
parser, dtd->scaffold, dtd->scaffSize * 2 * sizeof(CONTENT_SCAFFOLD));
if (temp == NULL)
return -1;
dtd->scaffSize *= 2;
} else {
temp = (CONTENT_SCAFFOLD *)MALLOC(parser, INIT_SCAFFOLD_ELEMENTS
* sizeof(CONTENT_SCAFFOLD));
if (temp == NULL)
return -1;
dtd->scaffSize = INIT_SCAFFOLD_ELEMENTS;
}
dtd->scaffold = temp;
}
next = dtd->scaffCount++;
me = &dtd->scaffold[next];
if (dtd->scaffLevel) {
CONTENT_SCAFFOLD *parent
= &dtd->scaffold[dtd->scaffIndex[dtd->scaffLevel - 1]];
if (parent->lastchild) {
dtd->scaffold[parent->lastchild].nextsib = next;
}
if (! parent->childcnt)
parent->firstchild = next;
parent->lastchild = next;
parent->childcnt++;
}
me->firstchild = me->lastchild = me->childcnt = me->nextsib = 0;
return next;
}
static XML_Content *
build_model(XML_Parser parser) {
/* Function build_model transforms the existing parser->m_dtd->scaffold
* array of CONTENT_SCAFFOLD tree nodes into a new array of
* XML_Content tree nodes followed by a gapless list of zero-terminated
* strings. */
DTD *const dtd = parser->m_dtd; /* save one level of indirection */
XML_Content *ret;
XML_Char *str; /* the current string writing location */
/* Detect and prevent integer overflow.
* The preprocessor guard addresses the "always false" warning
* from -Wtype-limits on platforms where
* sizeof(unsigned int) < sizeof(size_t), e.g. on x86_64. */
#if UINT_MAX >= SIZE_MAX
if (dtd->scaffCount > (size_t)(-1) / sizeof(XML_Content)) {
return NULL;
}
if (dtd->contentStringLen > (size_t)(-1) / sizeof(XML_Char)) {
return NULL;
}
#endif
if (dtd->scaffCount * sizeof(XML_Content)
> (size_t)(-1) - dtd->contentStringLen * sizeof(XML_Char)) {
return NULL;
}
const size_t allocsize = (dtd->scaffCount * sizeof(XML_Content)
+ (dtd->contentStringLen * sizeof(XML_Char)));
ret = (XML_Content *)MALLOC(parser, allocsize);
if (! ret)
return NULL;
/* What follows is an iterative implementation (of what was previously done
* recursively in a dedicated function called "build_node". The old recursive
* build_node could be forced into stack exhaustion from input as small as a
* few megabyte, and so that was a security issue. Hence, a function call
* stack is avoided now by resolving recursion.)
*
* The iterative approach works as follows:
*
* - We have two writing pointers, both walking up the result array; one does
* the work, the other creates "jobs" for its colleague to do, and leads
* the way:
*
* - The faster one, pointer jobDest, always leads and writes "what job
* to do" by the other, once they reach that place in the
* array: leader "jobDest" stores the source node array index (relative
* to array dtd->scaffold) in field "numchildren".
*
* - The slower one, pointer dest, looks at the value stored in the
* "numchildren" field (which actually holds a source node array index
* at that time) and puts the real data from dtd->scaffold in.
*
* - Before the loop starts, jobDest writes source array index 0
* (where the root node is located) so that dest will have something to do
* when it starts operation.
*
* - Whenever nodes with children are encountered, jobDest appends
* them as new jobs, in order. As a result, tree node siblings are
* adjacent in the resulting array, for example:
*
* [0] root, has two children
* [1] first child of 0, has three children
* [3] first child of 1, does not have children
* [4] second child of 1, does not have children
* [5] third child of 1, does not have children
* [2] second child of 0, does not have children
*
* Or (the same data) presented in flat array view:
*
* [0] root, has two children
*
* [1] first child of 0, has three children
* [2] second child of 0, does not have children
*
* [3] first child of 1, does not have children
* [4] second child of 1, does not have children
* [5] third child of 1, does not have children
*
* - The algorithm repeats until all target array indices have been processed.
*/
XML_Content *dest = ret; /* tree node writing location, moves upwards */
XML_Content *const destLimit = &ret[dtd->scaffCount];
XML_Content *jobDest = ret; /* next free writing location in target array */
str = (XML_Char *)&ret[dtd->scaffCount];
/* Add the starting job, the root node (index 0) of the source tree */
(jobDest++)->numchildren = 0;
for (; dest < destLimit; dest++) {
/* Retrieve source tree array index from job storage */
const int src_node = (int)dest->numchildren;
/* Convert item */
dest->type = dtd->scaffold[src_node].type;
dest->quant = dtd->scaffold[src_node].quant;
if (dest->type == XML_CTYPE_NAME) {
const XML_Char *src;
dest->name = str;
src = dtd->scaffold[src_node].name;
for (;;) {
*str++ = *src;
if (! *src)
break;
src++;
}
dest->numchildren = 0;
dest->children = NULL;
} else {
unsigned int i;
int cn;
dest->name = NULL;
dest->numchildren = dtd->scaffold[src_node].childcnt;
dest->children = jobDest;
/* Append scaffold indices of children to array */
for (i = 0, cn = dtd->scaffold[src_node].firstchild;
i < dest->numchildren; i++, cn = dtd->scaffold[cn].nextsib)
(jobDest++)->numchildren = (unsigned int)cn;
}
}
return ret;
}
static ELEMENT_TYPE *
getElementType(XML_Parser parser, const ENCODING *enc, const char *ptr,
const char *end) {
DTD *const dtd = parser->m_dtd; /* save one level of indirection */
const XML_Char *name = poolStoreString(&dtd->pool, enc, ptr, end);
ELEMENT_TYPE *ret;
if (! name)
return NULL;
ret = (ELEMENT_TYPE *)lookup(parser, &dtd->elementTypes, name,
sizeof(ELEMENT_TYPE));
if (! ret)
return NULL;
if (ret->name != name)
poolDiscard(&dtd->pool);
else {
poolFinish(&dtd->pool);
if (! setElementTypePrefix(parser, ret))
return NULL;
}
return ret;
}
static XML_Char *
copyString(const XML_Char *s, const XML_Memory_Handling_Suite *memsuite) {
size_t charsRequired = 0;
XML_Char *result;
/* First determine how long the string is */
while (s[charsRequired] != 0) {
charsRequired++;
}
/* Include the terminator */
charsRequired++;
/* Now allocate space for the copy */
result = memsuite->malloc_fcn(charsRequired * sizeof(XML_Char));
if (result == NULL)
return NULL;
/* Copy the original into place */
memcpy(result, s, charsRequired * sizeof(XML_Char));
return result;
}
#ifdef XML_DTD
static float
accountingGetCurrentAmplification(XML_Parser rootParser) {
const XmlBigCount countBytesOutput
= rootParser->m_accounting.countBytesDirect
+ rootParser->m_accounting.countBytesIndirect;
const float amplificationFactor
= rootParser->m_accounting.countBytesDirect
? (countBytesOutput
/ (float)(rootParser->m_accounting.countBytesDirect))
: 1.0f;
assert(! rootParser->m_parentParser);
return amplificationFactor;
}
static void
accountingReportStats(XML_Parser originParser, const char *epilog) {
const XML_Parser rootParser = getRootParserOf(originParser, NULL);
assert(! rootParser->m_parentParser);
if (rootParser->m_accounting.debugLevel < 1) {
return;
}
const float amplificationFactor
= accountingGetCurrentAmplification(rootParser);
fprintf(stderr,
"expat: Accounting(%p): Direct " EXPAT_FMT_ULL(
"10") ", indirect " EXPAT_FMT_ULL("10") ", amplification %8.2f%s",
(void *)rootParser, rootParser->m_accounting.countBytesDirect,
rootParser->m_accounting.countBytesIndirect,
(double)amplificationFactor, epilog);
}
static void
accountingOnAbort(XML_Parser originParser) {
accountingReportStats(originParser, " ABORTING\n");
}
static void
accountingReportDiff(XML_Parser rootParser,
unsigned int levelsAwayFromRootParser, const char *before,
const char *after, ptrdiff_t bytesMore, int source_line,
enum XML_Account account) {
assert(! rootParser->m_parentParser);
fprintf(stderr,
" (+" EXPAT_FMT_PTRDIFF_T("6") " bytes %s|%d, xmlparse.c:%d) %*s\"",
bytesMore, (account == XML_ACCOUNT_DIRECT) ? "DIR" : "EXP",
levelsAwayFromRootParser, source_line, 10, "");
const char ellipis[] = "[..]";
const size_t ellipsisLength = sizeof(ellipis) /* because compile-time */ - 1;
const unsigned int contextLength = 10;
/* Note: Performance is of no concern here */
const char *walker = before;
if ((rootParser->m_accounting.debugLevel >= 3)
|| (after - before)
<= (ptrdiff_t)(contextLength + ellipsisLength + contextLength)) {
for (; walker < after; walker++) {
fprintf(stderr, "%s", unsignedCharToPrintable(walker[0]));
}
} else {
for (; walker < before + contextLength; walker++) {
fprintf(stderr, "%s", unsignedCharToPrintable(walker[0]));
}
fprintf(stderr, ellipis);
walker = after - contextLength;
for (; walker < after; walker++) {
fprintf(stderr, "%s", unsignedCharToPrintable(walker[0]));
}
}
fprintf(stderr, "\"\n");
}
static XML_Bool
accountingDiffTolerated(XML_Parser originParser, int tok, const char *before,
const char *after, int source_line,
enum XML_Account account) {
/* Note: We need to check the token type *first* to be sure that
* we can even access variable <after>, safely.
* E.g. for XML_TOK_NONE <after> may hold an invalid pointer. */
switch (tok) {
case XML_TOK_INVALID:
case XML_TOK_PARTIAL:
case XML_TOK_PARTIAL_CHAR:
case XML_TOK_NONE:
return XML_TRUE;
}
if (account == XML_ACCOUNT_NONE)
return XML_TRUE; /* because these bytes have been accounted for, already */
unsigned int levelsAwayFromRootParser;
const XML_Parser rootParser
= getRootParserOf(originParser, &levelsAwayFromRootParser);
assert(! rootParser->m_parentParser);
const int isDirect
= (account == XML_ACCOUNT_DIRECT) && (originParser == rootParser);
const ptrdiff_t bytesMore = after - before;
XmlBigCount *const additionTarget
= isDirect ? &rootParser->m_accounting.countBytesDirect
: &rootParser->m_accounting.countBytesIndirect;
/* Detect and avoid integer overflow */
if (*additionTarget > (XmlBigCount)(-1) - (XmlBigCount)bytesMore)
return XML_FALSE;
*additionTarget += bytesMore;
const XmlBigCount countBytesOutput
= rootParser->m_accounting.countBytesDirect
+ rootParser->m_accounting.countBytesIndirect;
const float amplificationFactor
= accountingGetCurrentAmplification(rootParser);
const XML_Bool tolerated
= (countBytesOutput < rootParser->m_accounting.activationThresholdBytes)
|| (amplificationFactor
<= rootParser->m_accounting.maximumAmplificationFactor);
if (rootParser->m_accounting.debugLevel >= 2) {
accountingReportStats(rootParser, "");
accountingReportDiff(rootParser, levelsAwayFromRootParser, before, after,
bytesMore, source_line, account);
}
return tolerated;
}
unsigned long long
testingAccountingGetCountBytesDirect(XML_Parser parser) {
if (! parser)
return 0;
return parser->m_accounting.countBytesDirect;
}
unsigned long long
testingAccountingGetCountBytesIndirect(XML_Parser parser) {
if (! parser)
return 0;
return parser->m_accounting.countBytesIndirect;
}
static void
entityTrackingReportStats(XML_Parser rootParser, ENTITY *entity,
const char *action, int sourceLine) {
assert(! rootParser->m_parentParser);
if (rootParser->m_entity_stats.debugLevel < 1)
return;
# if defined(XML_UNICODE)
const char *const entityName = "[..]";
# else
const char *const entityName = entity->name;
# endif
fprintf(
stderr,
"expat: Entities(%p): Count %9d, depth %2d/%2d %*s%s%s; %s length %d (xmlparse.c:%d)\n",
(void *)rootParser, rootParser->m_entity_stats.countEverOpened,
rootParser->m_entity_stats.currentDepth,
rootParser->m_entity_stats.maximumDepthSeen,
(rootParser->m_entity_stats.currentDepth - 1) * 2, "",
entity->is_param ? "%" : "&", entityName, action, entity->textLen,
sourceLine);
}
static void
entityTrackingOnOpen(XML_Parser originParser, ENTITY *entity, int sourceLine) {
const XML_Parser rootParser = getRootParserOf(originParser, NULL);
assert(! rootParser->m_parentParser);
rootParser->m_entity_stats.countEverOpened++;
rootParser->m_entity_stats.currentDepth++;
if (rootParser->m_entity_stats.currentDepth
> rootParser->m_entity_stats.maximumDepthSeen) {
rootParser->m_entity_stats.maximumDepthSeen++;
}
entityTrackingReportStats(rootParser, entity, "OPEN ", sourceLine);
}
static void
entityTrackingOnClose(XML_Parser originParser, ENTITY *entity, int sourceLine) {
const XML_Parser rootParser = getRootParserOf(originParser, NULL);
assert(! rootParser->m_parentParser);
entityTrackingReportStats(rootParser, entity, "CLOSE", sourceLine);
rootParser->m_entity_stats.currentDepth--;
}
static XML_Parser
getRootParserOf(XML_Parser parser, unsigned int *outLevelDiff) {
XML_Parser rootParser = parser;
unsigned int stepsTakenUpwards = 0;
while (rootParser->m_parentParser) {
rootParser = rootParser->m_parentParser;
stepsTakenUpwards++;
}
assert(! rootParser->m_parentParser);
if (outLevelDiff != NULL) {
*outLevelDiff = stepsTakenUpwards;
}
return rootParser;
}
const char *
unsignedCharToPrintable(unsigned char c) {
switch (c) {
case 0:
return "\\0";
case 1:
return "\\x1";
case 2:
return "\\x2";
case 3:
return "\\x3";
case 4:
return "\\x4";
case 5:
return "\\x5";
case 6:
return "\\x6";
case 7:
return "\\x7";
case 8:
return "\\x8";
case 9:
return "\\t";
case 10:
return "\\n";
case 11:
return "\\xB";
case 12:
return "\\xC";
case 13:
return "\\r";
case 14:
return "\\xE";
case 15:
return "\\xF";
case 16:
return "\\x10";
case 17:
return "\\x11";
case 18:
return "\\x12";
case 19:
return "\\x13";
case 20:
return "\\x14";
case 21:
return "\\x15";
case 22:
return "\\x16";
case 23:
return "\\x17";
case 24:
return "\\x18";
case 25:
return "\\x19";
case 26:
return "\\x1A";
case 27:
return "\\x1B";
case 28:
return "\\x1C";
case 29:
return "\\x1D";
case 30:
return "\\x1E";
case 31:
return "\\x1F";
case 32:
return " ";
case 33:
return "!";
case 34:
return "\\\"";
case 35:
return "#";
case 36:
return "$";
case 37:
return "%";
case 38:
return "&";
case 39:
return "'";
case 40:
return "(";
case 41:
return ")";
case 42:
return "*";
case 43:
return "+";
case 44:
return ",";
case 45:
return "-";
case 46:
return ".";
case 47:
return "/";
case 48:
return "0";
case 49:
return "1";
case 50:
return "2";
case 51:
return "3";
case 52:
return "4";
case 53:
return "5";
case 54:
return "6";
case 55:
return "7";
case 56:
return "8";
case 57:
return "9";
case 58:
return ":";
case 59:
return ";";
case 60:
return "<";
case 61:
return "=";
case 62:
return ">";
case 63:
return "?";
case 64:
return "@";
case 65:
return "A";
case 66:
return "B";
case 67:
return "C";
case 68:
return "D";
case 69:
return "E";
case 70:
return "F";
case 71:
return "G";
case 72:
return "H";
case 73:
return "I";
case 74:
return "J";
case 75:
return "K";
case 76:
return "L";
case 77:
return "M";
case 78:
return "N";
case 79:
return "O";
case 80:
return "P";
case 81:
return "Q";
case 82:
return "R";
case 83:
return "S";
case 84:
return "T";
case 85:
return "U";
case 86:
return "V";
case 87:
return "W";
case 88:
return "X";
case 89:
return "Y";
case 90:
return "Z";
case 91:
return "[";
case 92:
return "\\\\";
case 93:
return "]";
case 94:
return "^";
case 95:
return "_";
case 96:
return "`";
case 97:
return "a";
case 98:
return "b";
case 99:
return "c";
case 100:
return "d";
case 101:
return "e";
case 102:
return "f";
case 103:
return "g";
case 104:
return "h";
case 105:
return "i";
case 106:
return "j";
case 107:
return "k";
case 108:
return "l";
case 109:
return "m";
case 110:
return "n";
case 111:
return "o";
case 112:
return "p";
case 113:
return "q";
case 114:
return "r";
case 115:
return "s";
case 116:
return "t";
case 117:
return "u";
case 118:
return "v";
case 119:
return "w";
case 120:
return "x";
case 121:
return "y";
case 122:
return "z";
case 123:
return "{";
case 124:
return "|";
case 125:
return "}";
case 126:
return "~";
case 127:
return "\\x7F";
case 128:
return "\\x80";
case 129:
return "\\x81";
case 130:
return "\\x82";
case 131:
return "\\x83";
case 132:
return "\\x84";
case 133:
return "\\x85";
case 134:
return "\\x86";
case 135:
return "\\x87";
case 136:
return "\\x88";
case 137:
return "\\x89";
case 138:
return "\\x8A";
case 139:
return "\\x8B";
case 140:
return "\\x8C";
case 141:
return "\\x8D";
case 142:
return "\\x8E";
case 143:
return "\\x8F";
case 144:
return "\\x90";
case 145:
return "\\x91";
case 146:
return "\\x92";
case 147:
return "\\x93";
case 148:
return "\\x94";
case 149:
return "\\x95";
case 150:
return "\\x96";
case 151:
return "\\x97";
case 152:
return "\\x98";
case 153:
return "\\x99";
case 154:
return "\\x9A";
case 155:
return "\\x9B";
case 156:
return "\\x9C";
case 157:
return "\\x9D";
case 158:
return "\\x9E";
case 159:
return "\\x9F";
case 160:
return "\\xA0";
case 161:
return "\\xA1";
case 162:
return "\\xA2";
case 163:
return "\\xA3";
case 164:
return "\\xA4";
case 165:
return "\\xA5";
case 166:
return "\\xA6";
case 167:
return "\\xA7";
case 168:
return "\\xA8";
case 169:
return "\\xA9";
case 170:
return "\\xAA";
case 171:
return "\\xAB";
case 172:
return "\\xAC";
case 173:
return "\\xAD";
case 174:
return "\\xAE";
case 175:
return "\\xAF";
case 176:
return "\\xB0";
case 177:
return "\\xB1";
case 178:
return "\\xB2";
case 179:
return "\\xB3";
case 180:
return "\\xB4";
case 181:
return "\\xB5";
case 182:
return "\\xB6";
case 183:
return "\\xB7";
case 184:
return "\\xB8";
case 185:
return "\\xB9";
case 186:
return "\\xBA";
case 187:
return "\\xBB";
case 188:
return "\\xBC";
case 189:
return "\\xBD";
case 190:
return "\\xBE";
case 191:
return "\\xBF";
case 192:
return "\\xC0";
case 193:
return "\\xC1";
case 194:
return "\\xC2";
case 195:
return "\\xC3";
case 196:
return "\\xC4";
case 197:
return "\\xC5";
case 198:
return "\\xC6";
case 199:
return "\\xC7";
case 200:
return "\\xC8";
case 201:
return "\\xC9";
case 202:
return "\\xCA";
case 203:
return "\\xCB";
case 204:
return "\\xCC";
case 205:
return "\\xCD";
case 206:
return "\\xCE";
case 207:
return "\\xCF";
case 208:
return "\\xD0";
case 209:
return "\\xD1";
case 210:
return "\\xD2";
case 211:
return "\\xD3";
case 212:
return "\\xD4";
case 213:
return "\\xD5";
case 214:
return "\\xD6";
case 215:
return "\\xD7";
case 216:
return "\\xD8";
case 217:
return "\\xD9";
case 218:
return "\\xDA";
case 219:
return "\\xDB";
case 220:
return "\\xDC";
case 221:
return "\\xDD";
case 222:
return "\\xDE";
case 223:
return "\\xDF";
case 224:
return "\\xE0";
case 225:
return "\\xE1";
case 226:
return "\\xE2";
case 227:
return "\\xE3";
case 228:
return "\\xE4";
case 229:
return "\\xE5";
case 230:
return "\\xE6";
case 231:
return "\\xE7";
case 232:
return "\\xE8";
case 233:
return "\\xE9";
case 234:
return "\\xEA";
case 235:
return "\\xEB";
case 236:
return "\\xEC";
case 237:
return "\\xED";
case 238:
return "\\xEE";
case 239:
return "\\xEF";
case 240:
return "\\xF0";
case 241:
return "\\xF1";
case 242:
return "\\xF2";
case 243:
return "\\xF3";
case 244:
return "\\xF4";
case 245:
return "\\xF5";
case 246:
return "\\xF6";
case 247:
return "\\xF7";
case 248:
return "\\xF8";
case 249:
return "\\xF9";
case 250:
return "\\xFA";
case 251:
return "\\xFB";
case 252:
return "\\xFC";
case 253:
return "\\xFD";
case 254:
return "\\xFE";
case 255:
return "\\xFF";
default:
assert(0); /* never gets here */
return "dead code";
}
assert(0); /* never gets here */
}
#endif /* XML_DTD */
static unsigned long
getDebugLevel(const char *variableName, unsigned long defaultDebugLevel) {
const char *const valueOrNull = getenv(variableName);
if (valueOrNull == NULL) {
return defaultDebugLevel;
}
const char *const value = valueOrNull;
errno = 0;
char *afterValue = (char *)value;
unsigned long debugLevel = strtoul(value, &afterValue, 10);
if ((errno != 0) || (afterValue[0] != '\0')) {
errno = 0;
return defaultDebugLevel;
}
return debugLevel;
}