diff --git a/src/libpst.c b/src/libpst.c index a1e3890..0a96570 100644 --- a/src/libpst.c +++ b/src/libpst.c @@ -1,4664 +1,4664 @@ /*** * libpst.c * Part of the LibPST project * Written by David Smith * dave.s@earthcorp.com */ #include "define.h" #include "zlib.h" // switch to maximal packing for our own internal structures // use the same code as in libpst.h #ifdef _MSC_VER #pragma pack(push, 1) #endif #if defined(__GNUC__) || defined (__SUNPRO_C) || defined(__SUNPRO_CC) #pragma pack(1) #endif #define ASSERT(x) { if(!(x)) raise( SIGSEGV ); } #define INDEX_TYPE32 0x0E #define INDEX_TYPE32A 0x0F // unknown, but assumed to be similar for now #define INDEX_TYPE64 0x17 -#define INDEX_TYPE64A 0x15 // http://sourceforge.net/projects/libpff/ +#define INDEX_TYPE64A 0x15 // https://github.com/libyal/libpff #define INDEX_TYPE4K 0x24 #define INDEX_TYPE_OFFSET (int64_t)0x0A #define FILE_SIZE_POINTER32 (int64_t)0xA8 #define INDEX_POINTER32 (int64_t)0xC4 #define INDEX_BACK32 (int64_t)0xC0 #define SECOND_POINTER32 (int64_t)0xBC #define SECOND_BACK32 (int64_t)0xB8 #define ENC_TYPE32 (int64_t)0x1CD #define FILE_SIZE_POINTER64 (int64_t)0xB8 #define INDEX_POINTER64 (int64_t)0xF0 #define INDEX_BACK64 (int64_t)0xE8 #define SECOND_POINTER64 (int64_t)0xE0 #define SECOND_BACK64 (int64_t)0xD8 #define ENC_TYPE64 (int64_t)0x201 #define FILE_SIZE_POINTER ((pf->do_read64) ? FILE_SIZE_POINTER64 : FILE_SIZE_POINTER32) #define INDEX_POINTER ((pf->do_read64) ? INDEX_POINTER64 : INDEX_POINTER32) #define INDEX_BACK ((pf->do_read64) ? INDEX_BACK64 : INDEX_BACK32) #define SECOND_POINTER ((pf->do_read64) ? SECOND_POINTER64 : SECOND_POINTER32) #define SECOND_BACK ((pf->do_read64) ? SECOND_BACK64 : SECOND_BACK32) #define ENC_TYPE ((pf->do_read64) ? ENC_TYPE64 : ENC_TYPE32) #define PST_SIGNATURE 0x4E444221 typedef struct pst_block_offset { uint16_t from; uint16_t to; } pst_block_offset; typedef struct pst_block_offset_pointer { char *from; char *to; int needfree; } pst_block_offset_pointer; typedef struct pst_holder { char **buf; FILE *fp; int base64; // bool, are we encoding into base64 int base64_line_count; // base64 bytes emitted on the current line size_t base64_extra; // count of bytes held in base64_extra_chars char base64_extra_chars[2]; // up to two pending unencoded bytes } pst_holder; typedef struct pst_subblock { char *buf; size_t read_size; size_t i_offset; } pst_subblock; typedef struct pst_subblocks { size_t subblock_count; pst_subblock *subs; } pst_subblocks; typedef struct pst_mapi_element { uint32_t mapi_id; char *data; uint32_t type; size_t size; char *extra; } pst_mapi_element; typedef struct pst_mapi_object { int32_t count_elements; // count of active elements int32_t orig_count; // originally allocated elements int32_t count_objects; // number of mapi objects in the list struct pst_mapi_element **elements; struct pst_mapi_object *next; } pst_mapi_object; typedef struct pst_desc32 { uint32_t d_id; uint32_t desc_id; uint32_t tree_id; uint32_t parent_d_id; } pst_desc32; typedef struct pst_index32 { uint32_t id; uint32_t offset; uint16_t size; int16_t u1; } pst_index32; struct pst_table_ptr_struct32{ uint32_t start; uint32_t u1; uint32_t offset; }; typedef struct pst_desc { uint64_t d_id; uint64_t desc_id; uint64_t tree_id; uint32_t parent_d_id; // not 64 bit uint32_t u1; // padding } pst_desc; typedef struct pst_index64 { uint64_t id; uint64_t offset; uint16_t size; int16_t u0; int32_t u1; } pst_index64; typedef struct pst_index { uint64_t id; uint64_t offset; uint16_t size; uint16_t inflated_size; int16_t u0; int32_t u1; } pst_index; struct pst_table_ptr_struct{ uint64_t start; uint64_t u1; uint64_t offset; }; typedef struct pst_block_header { uint16_t type; uint16_t count; } pst_block_header; typedef struct pst_id2_assoc32 { uint32_t id2; uint32_t id; uint32_t child_id; } pst_id2_assoc32; typedef struct pst_id2_assoc { uint32_t id2; // only 32 bit here uint16_t unknown1; uint16_t unknown2; uint64_t id; uint64_t child_id; } pst_id2_assoc; typedef struct pst_table3_rec32 { uint32_t id; } pst_table3_rec32; //for type 3 (0x0101) blocks typedef struct pst_table3_rec { uint64_t id; } pst_table3_rec; //for type 3 (0x0101) blocks typedef struct pst_block_hdr { uint16_t index_offset; uint16_t type; uint32_t offset; } pst_block_hdr; /** for "compressible" encryption, just a simple substitution cipher, * plaintext = comp_enc[ciphertext]; * for "strong" encryption, this is the first rotor of an Enigma 3 rotor cipher. */ static unsigned char comp_enc [] = { 0x47, 0xf1, 0xb4, 0xe6, 0x0b, 0x6a, 0x72, 0x48, 0x85, 0x4e, 0x9e, 0xeb, 0xe2, 0xf8, 0x94, 0x53, 0xe0, 0xbb, 0xa0, 0x02, 0xe8, 0x5a, 0x09, 0xab, 0xdb, 0xe3, 0xba, 0xc6, 0x7c, 0xc3, 0x10, 0xdd, 0x39, 0x05, 0x96, 0x30, 0xf5, 0x37, 0x60, 0x82, 0x8c, 0xc9, 0x13, 0x4a, 0x6b, 0x1d, 0xf3, 0xfb, 0x8f, 0x26, 0x97, 0xca, 0x91, 0x17, 0x01, 0xc4, 0x32, 0x2d, 0x6e, 0x31, 0x95, 0xff, 0xd9, 0x23, 0xd1, 0x00, 0x5e, 0x79, 0xdc, 0x44, 0x3b, 0x1a, 0x28, 0xc5, 0x61, 0x57, 0x20, 0x90, 0x3d, 0x83, 0xb9, 0x43, 0xbe, 0x67, 0xd2, 0x46, 0x42, 0x76, 0xc0, 0x6d, 0x5b, 0x7e, 0xb2, 0x0f, 0x16, 0x29, 0x3c, 0xa9, 0x03, 0x54, 0x0d, 0xda, 0x5d, 0xdf, 0xf6, 0xb7, 0xc7, 0x62, 0xcd, 0x8d, 0x06, 0xd3, 0x69, 0x5c, 0x86, 0xd6, 0x14, 0xf7, 0xa5, 0x66, 0x75, 0xac, 0xb1, 0xe9, 0x45, 0x21, 0x70, 0x0c, 0x87, 0x9f, 0x74, 0xa4, 0x22, 0x4c, 0x6f, 0xbf, 0x1f, 0x56, 0xaa, 0x2e, 0xb3, 0x78, 0x33, 0x50, 0xb0, 0xa3, 0x92, 0xbc, 0xcf, 0x19, 0x1c, 0xa7, 0x63, 0xcb, 0x1e, 0x4d, 0x3e, 0x4b, 0x1b, 0x9b, 0x4f, 0xe7, 0xf0, 0xee, 0xad, 0x3a, 0xb5, 0x59, 0x04, 0xea, 0x40, 0x55, 0x25, 0x51, 0xe5, 0x7a, 0x89, 0x38, 0x68, 0x52, 0x7b, 0xfc, 0x27, 0xae, 0xd7, 0xbd, 0xfa, 0x07, 0xf4, 0xcc, 0x8e, 0x5f, 0xef, 0x35, 0x9c, 0x84, 0x2b, 0x15, 0xd5, 0x77, 0x34, 0x49, 0xb6, 0x12, 0x0a, 0x7f, 0x71, 0x88, 0xfd, 0x9d, 0x18, 0x41, 0x7d, 0x93, 0xd8, 0x58, 0x2c, 0xce, 0xfe, 0x24, 0xaf, 0xde, 0xb8, 0x36, 0xc8, 0xa1, 0x80, 0xa6, 0x99, 0x98, 0xa8, 0x2f, 0x0e, 0x81, 0x65, 0x73, 0xe4, 0xc2, 0xa2, 0x8a, 0xd4, 0xe1, 0x11, 0xd0, 0x08, 0x8b, 0x2a, 0xf2, 0xed, 0x9a, 0x64, 0x3f, 0xc1, 0x6c, 0xf9, 0xec }; /** for "strong" encryption, this is the second rotor of an Enigma 3 rotor cipher. */ static unsigned char comp_high1 [] = { 0x41, 0x36, 0x13, 0x62, 0xa8, 0x21, 0x6e, 0xbb, 0xf4, 0x16, 0xcc, 0x04, 0x7f, 0x64, 0xe8, 0x5d, 0x1e, 0xf2, 0xcb, 0x2a, 0x74, 0xc5, 0x5e, 0x35, 0xd2, 0x95, 0x47, 0x9e, 0x96, 0x2d, 0x9a, 0x88, 0x4c, 0x7d, 0x84, 0x3f, 0xdb, 0xac, 0x31, 0xb6, 0x48, 0x5f, 0xf6, 0xc4, 0xd8, 0x39, 0x8b, 0xe7, 0x23, 0x3b, 0x38, 0x8e, 0xc8, 0xc1, 0xdf, 0x25, 0xb1, 0x20, 0xa5, 0x46, 0x60, 0x4e, 0x9c, 0xfb, 0xaa, 0xd3, 0x56, 0x51, 0x45, 0x7c, 0x55, 0x00, 0x07, 0xc9, 0x2b, 0x9d, 0x85, 0x9b, 0x09, 0xa0, 0x8f, 0xad, 0xb3, 0x0f, 0x63, 0xab, 0x89, 0x4b, 0xd7, 0xa7, 0x15, 0x5a, 0x71, 0x66, 0x42, 0xbf, 0x26, 0x4a, 0x6b, 0x98, 0xfa, 0xea, 0x77, 0x53, 0xb2, 0x70, 0x05, 0x2c, 0xfd, 0x59, 0x3a, 0x86, 0x7e, 0xce, 0x06, 0xeb, 0x82, 0x78, 0x57, 0xc7, 0x8d, 0x43, 0xaf, 0xb4, 0x1c, 0xd4, 0x5b, 0xcd, 0xe2, 0xe9, 0x27, 0x4f, 0xc3, 0x08, 0x72, 0x80, 0xcf, 0xb0, 0xef, 0xf5, 0x28, 0x6d, 0xbe, 0x30, 0x4d, 0x34, 0x92, 0xd5, 0x0e, 0x3c, 0x22, 0x32, 0xe5, 0xe4, 0xf9, 0x9f, 0xc2, 0xd1, 0x0a, 0x81, 0x12, 0xe1, 0xee, 0x91, 0x83, 0x76, 0xe3, 0x97, 0xe6, 0x61, 0x8a, 0x17, 0x79, 0xa4, 0xb7, 0xdc, 0x90, 0x7a, 0x5c, 0x8c, 0x02, 0xa6, 0xca, 0x69, 0xde, 0x50, 0x1a, 0x11, 0x93, 0xb9, 0x52, 0x87, 0x58, 0xfc, 0xed, 0x1d, 0x37, 0x49, 0x1b, 0x6a, 0xe0, 0x29, 0x33, 0x99, 0xbd, 0x6c, 0xd9, 0x94, 0xf3, 0x40, 0x54, 0x6f, 0xf0, 0xc6, 0x73, 0xb8, 0xd6, 0x3e, 0x65, 0x18, 0x44, 0x1f, 0xdd, 0x67, 0x10, 0xf1, 0x0c, 0x19, 0xec, 0xae, 0x03, 0xa1, 0x14, 0x7b, 0xa9, 0x0b, 0xff, 0xf8, 0xa3, 0xc0, 0xa2, 0x01, 0xf7, 0x2e, 0xbc, 0x24, 0x68, 0x75, 0x0d, 0xfe, 0xba, 0x2f, 0xb5, 0xd0, 0xda, 0x3d }; /** for "strong" encryption, this is the third rotor of an Enigma 3 rotor cipher. */ static unsigned char comp_high2 [] = { 0x14, 0x53, 0x0f, 0x56, 0xb3, 0xc8, 0x7a, 0x9c, 0xeb, 0x65, 0x48, 0x17, 0x16, 0x15, 0x9f, 0x02, 0xcc, 0x54, 0x7c, 0x83, 0x00, 0x0d, 0x0c, 0x0b, 0xa2, 0x62, 0xa8, 0x76, 0xdb, 0xd9, 0xed, 0xc7, 0xc5, 0xa4, 0xdc, 0xac, 0x85, 0x74, 0xd6, 0xd0, 0xa7, 0x9b, 0xae, 0x9a, 0x96, 0x71, 0x66, 0xc3, 0x63, 0x99, 0xb8, 0xdd, 0x73, 0x92, 0x8e, 0x84, 0x7d, 0xa5, 0x5e, 0xd1, 0x5d, 0x93, 0xb1, 0x57, 0x51, 0x50, 0x80, 0x89, 0x52, 0x94, 0x4f, 0x4e, 0x0a, 0x6b, 0xbc, 0x8d, 0x7f, 0x6e, 0x47, 0x46, 0x41, 0x40, 0x44, 0x01, 0x11, 0xcb, 0x03, 0x3f, 0xf7, 0xf4, 0xe1, 0xa9, 0x8f, 0x3c, 0x3a, 0xf9, 0xfb, 0xf0, 0x19, 0x30, 0x82, 0x09, 0x2e, 0xc9, 0x9d, 0xa0, 0x86, 0x49, 0xee, 0x6f, 0x4d, 0x6d, 0xc4, 0x2d, 0x81, 0x34, 0x25, 0x87, 0x1b, 0x88, 0xaa, 0xfc, 0x06, 0xa1, 0x12, 0x38, 0xfd, 0x4c, 0x42, 0x72, 0x64, 0x13, 0x37, 0x24, 0x6a, 0x75, 0x77, 0x43, 0xff, 0xe6, 0xb4, 0x4b, 0x36, 0x5c, 0xe4, 0xd8, 0x35, 0x3d, 0x45, 0xb9, 0x2c, 0xec, 0xb7, 0x31, 0x2b, 0x29, 0x07, 0x68, 0xa3, 0x0e, 0x69, 0x7b, 0x18, 0x9e, 0x21, 0x39, 0xbe, 0x28, 0x1a, 0x5b, 0x78, 0xf5, 0x23, 0xca, 0x2a, 0xb0, 0xaf, 0x3e, 0xfe, 0x04, 0x8c, 0xe7, 0xe5, 0x98, 0x32, 0x95, 0xd3, 0xf6, 0x4a, 0xe8, 0xa6, 0xea, 0xe9, 0xf3, 0xd5, 0x2f, 0x70, 0x20, 0xf2, 0x1f, 0x05, 0x67, 0xad, 0x55, 0x10, 0xce, 0xcd, 0xe3, 0x27, 0x3b, 0xda, 0xba, 0xd7, 0xc2, 0x26, 0xd4, 0x91, 0x1d, 0xd2, 0x1c, 0x22, 0x33, 0xf8, 0xfa, 0xf1, 0x5a, 0xef, 0xcf, 0x90, 0xb6, 0x8b, 0xb5, 0xbd, 0xc0, 0xbf, 0x08, 0x97, 0x1e, 0x6c, 0xe2, 0x61, 0xe0, 0xc6, 0xc1, 0x59, 0xab, 0xbb, 0x58, 0xde, 0x5f, 0xdf, 0x60, 0x79, 0x7e, 0xb2, 0x8a }; static size_t pst_append_holder(pst_holder *h, size_t size, char **buf, size_t z); static int pst_build_desc_ptr(pst_file *pf, int64_t offset, int32_t depth, uint64_t linku1, uint64_t start_val, uint64_t end_val); static pst_id2_tree* pst_build_id2(pst_file *pf, pst_index_ll* list); static int pst_build_id_ptr(pst_file *pf, int64_t offset, int32_t depth, uint64_t linku1, uint64_t start_val, uint64_t end_val); static int pst_chr_count(char *str, char x); static size_t pst_ff_compile_ID(pst_file *pf, uint64_t i_id, pst_holder *h, size_t size); static size_t pst_ff_getIDblock(pst_file *pf, uint64_t i_id, char** buf); static size_t pst_ff_getID2block(pst_file *pf, uint64_t id2, pst_id2_tree *id2_head, char** buf); static size_t pst_ff_getID2data(pst_file *pf, pst_index_ll *ptr, pst_holder *h); static size_t pst_finish_cleanup_holder(pst_holder *h, size_t size); static void pst_free_attach(pst_item_attach *attach); static void pst_free_desc (pst_desc_tree *head); static void pst_free_id2(pst_id2_tree * head); static void pst_free_list(pst_mapi_object *list); static void pst_free_xattrib(pst_x_attrib_ll *x); static size_t pst_getAtPos(pst_file *pf, int64_t pos, void* buf, size_t size); static int pst_getBlockOffsetPointer(pst_file *pf, pst_id2_tree *i2_head, pst_subblocks *subblocks, uint32_t offset, pst_block_offset_pointer *p); static int pst_getBlockOffset(char *buf, size_t read_size, uint32_t i_offset, uint32_t offset, pst_block_offset *p); static pst_id2_tree* pst_getID2(pst_id2_tree * ptr, uint64_t id); static pst_desc_tree* pst_getDptr(pst_file *pf, uint64_t d_id); static uint64_t pst_getIntAt(pst_file *pf, char *buf); static uint64_t pst_getIntAtPos(pst_file *pf, int64_t pos); static pst_mapi_object* pst_parse_block(pst_file *pf, uint64_t block_id, pst_id2_tree *i2_head); static void pst_printDptr(pst_file *pf, pst_desc_tree *ptr); static void pst_printID2ptr(pst_id2_tree *ptr); static int pst_process(uint64_t block_id, pst_mapi_object *list, pst_item *item, pst_item_attach *attach); static size_t pst_read_block_size(pst_file *pf, int64_t offset, size_t size, size_t inflated_size, char **buf); static size_t pst_read_raw_block_size(pst_file *pf, int64_t offset, size_t size, char **buf); static int pst_decrypt(uint64_t i_id, char *buf, size_t size, unsigned char type); static int pst_strincmp(char *a, char *b, size_t x); static char* pst_wide_to_single(char *wt, size_t size); static char *pst_getcwd(void) { char *cwd; #ifdef HAVE_GET_CURRENT_DIR_NAME cwd = get_current_dir_name(); #else cwd = pst_malloc(PATH_MAX+1); getcwd(cwd, PATH_MAX+1); #endif return cwd; } int pst_open(pst_file *pf, const char *name, const char *charset) { int32_t sig; pst_unicode_init(); DEBUG_ENT("pst_open"); if (!pf) { WARN (("cannot be passed a NULL pst_file\n")); DEBUG_RET(); return -1; } memset(pf, 0, sizeof(*pf)); pf->charset = charset; if ((pf->fp = fopen(name, "rb")) == NULL) { perror("Error opening PST file"); DEBUG_RET(); return -1; } // Check pst file magic if (pst_getAtPos(pf, 0, &sig, sizeof(sig)) != sizeof(sig)) { (void)fclose(pf->fp); DEBUG_WARN(("cannot read signature from PST file. Closing with error\n")); DEBUG_RET(); return -1; } LE32_CPU(sig); DEBUG_INFO(("sig = %X\n", sig)); if (sig != (int32_t)PST_SIGNATURE) { (void)fclose(pf->fp); DEBUG_WARN(("not a PST file that I know. Closing with error\n")); DEBUG_RET(); return -1; } // read index type (void)pst_getAtPos(pf, INDEX_TYPE_OFFSET, &(pf->ind_type), sizeof(pf->ind_type)); DEBUG_INFO(("index_type = %i\n", pf->ind_type)); switch (pf->ind_type) { case INDEX_TYPE32 : case INDEX_TYPE32A : pf->do_read64 = 0; break; case INDEX_TYPE64 : case INDEX_TYPE64A : pf->do_read64 = 1; break; case INDEX_TYPE4K : pf->do_read64 = 2; break; default: (void)fclose(pf->fp); DEBUG_WARN(("unknown .pst format, possibly newer than Outlook 2003 PST file?\n")); DEBUG_RET(); return -1; } // read encryption setting (void)pst_getAtPos(pf, ENC_TYPE, &(pf->encryption), sizeof(pf->encryption)); DEBUG_INFO(("encrypt = %i\n", pf->encryption)); pf->index2_back = pst_getIntAtPos(pf, SECOND_BACK); pf->index2 = pst_getIntAtPos(pf, SECOND_POINTER); pf->size = pst_getIntAtPos(pf, FILE_SIZE_POINTER); DEBUG_INFO(("Pointer2 is %#"PRIx64", back pointer2 is %#"PRIx64"\n", pf->index2, pf->index2_back)); pf->index1_back = pst_getIntAtPos(pf, INDEX_BACK); pf->index1 = pst_getIntAtPos(pf, INDEX_POINTER); DEBUG_INFO(("Pointer1 is %#"PRIx64", back pointer2 is %#"PRIx64"\n", pf->index1, pf->index1_back)); DEBUG_RET(); pf->cwd = pst_getcwd(); pf->fname = strdup(name); return 0; } int pst_reopen(pst_file *pf) { char *cwd; cwd = pst_getcwd(); if (cwd == NULL) return -1; if (chdir(pf->cwd)) goto err; if (!freopen(pf->fname, "rb", pf->fp)) goto err; if (chdir(cwd)) goto err; free(cwd); return 0; err: free(cwd); return -1; } int pst_close(pst_file *pf) { DEBUG_ENT("pst_close"); if (!pf) { DEBUG_RET(); return 0; } if (!pf->fp) { DEBUG_RET(); return 0; } if (fclose(pf->fp)) { DEBUG_WARN(("fclose returned non-zero value\n")); } // free the paths free(pf->cwd); free(pf->fname); // we must free the id array and the desc tree free(pf->i_table); pst_free_desc(pf->d_head); pst_free_xattrib(pf->x_head); DEBUG_RET(); return 0; } /** * add a pst descriptor node to a linked list of such nodes. * * @param node pointer to the node to be added to the list * @param head pointer to the list head pointer * @param tail pointer to the list tail pointer */ static void add_descriptor_to_list(pst_desc_tree *node, pst_desc_tree **head, pst_desc_tree **tail); static void add_descriptor_to_list(pst_desc_tree *node, pst_desc_tree **head, pst_desc_tree **tail) { DEBUG_ENT("add_descriptor_to_list"); //DEBUG_INFO(("Added node %#"PRIx64" parent %#"PRIx64" real parent %#"PRIx64" prev %#"PRIx64" next %#"PRIx64"\n", // node->id, node->parent_d_id, // (node->parent ? node->parent->id : (uint64_t)0), // (node->prev ? node->prev->id : (uint64_t)0), // (node->next ? node->next->id : (uint64_t)0))); if (*tail) (*tail)->next = node; if (!(*head)) *head = node; node->prev = *tail; node->next = NULL; *tail = node; DEBUG_RET(); } /** * add a pst descriptor node into the global tree. * * @param pf global pst file pointer * @param node pointer to the new node to be added to the tree */ static void record_descriptor(pst_file *pf, pst_desc_tree *node); static void record_descriptor(pst_file *pf, pst_desc_tree *node) { DEBUG_ENT("record_descriptor"); // finish node initialization node->parent = NULL; node->child = NULL; node->child_tail = NULL; node->no_child = 0; // find any orphan children of this node, and collect them pst_desc_tree *n = pf->d_head; while (n) { if (n->parent_d_id == node->d_id) { // found a child of this node DEBUG_INFO(("Found orphan child %#"PRIx64" of parent %#"PRIx64"\n", n->d_id, node->d_id)); pst_desc_tree *nn = n->next; pst_desc_tree *pp = n->prev; node->no_child++; n->parent = node; add_descriptor_to_list(n, &node->child, &node->child_tail); if (pp) pp->next = nn; else pf->d_head = nn; if (nn) nn->prev = pp; else pf->d_tail = pp; n = nn; } else { n = n->next; } } // now hook this node into the global tree if (node->parent_d_id == 0) { // add top level node to the descriptor tree //DEBUG_INFO(("Null parent\n")); add_descriptor_to_list(node, &pf->d_head, &pf->d_tail); } else if (node->parent_d_id == node->d_id) { // add top level node to the descriptor tree DEBUG_INFO(("%#"PRIx64" is its own parent. What is this world coming to?\n", node->d_id)); add_descriptor_to_list(node, &pf->d_head, &pf->d_tail); } else { //DEBUG_INFO(("Searching for parent %#"PRIx64" of %#"PRIx64"\n", node->parent_d_id, node->d_id)); pst_desc_tree *parent = pst_getDptr(pf, node->parent_d_id); if (parent) { //DEBUG_INFO(("Found parent %#"PRIx64"\n", node->parent_d_id)); parent->no_child++; node->parent = parent; add_descriptor_to_list(node, &parent->child, &parent->child_tail); } else { DEBUG_INFO(("No parent %#"PRIx64", have an orphan child %#"PRIx64"\n", node->parent_d_id, node->d_id)); add_descriptor_to_list(node, &pf->d_head, &pf->d_tail); } } DEBUG_RET(); } /** * make a deep copy of part of the id2 mapping tree, for use * by an attachment containing an embedded rfc822 message. * * @param head pointer to the subtree to be copied * @return pointer to the new copy of the subtree */ static pst_id2_tree* deep_copy(pst_id2_tree *head); static pst_id2_tree* deep_copy(pst_id2_tree *head) { if (!head) return NULL; pst_id2_tree* me = (pst_id2_tree*) pst_malloc(sizeof(pst_id2_tree)); me->id2 = head->id2; me->id = head->id; me->child = deep_copy(head->child); me->next = deep_copy(head->next); return me; } pst_desc_tree* pst_getTopOfFolders(pst_file *pf, const pst_item *root) { pst_desc_tree *topnode; uint32_t topid; DEBUG_ENT("pst_getTopOfFolders"); if (!root || !root->message_store) { DEBUG_INFO(("There isn't a top of folder record here.\n")); DEBUG_RET(); return NULL; } if (!root->message_store->top_of_personal_folder) { // this is the OST way // ASSUMPTION: Top Of Folders record in PST files is *always* descid 0x2142 topid = 0x2142; } else { topid = root->message_store->top_of_personal_folder->id; } DEBUG_INFO(("looking for top of folder descriptor %#"PRIx32"\n", topid)); topnode = pst_getDptr(pf, (uint64_t)topid); if (!topnode) { // add dummy top record to pickup orphan children topnode = (pst_desc_tree*) pst_malloc(sizeof(pst_desc_tree)); topnode->d_id = topid; topnode->parent_d_id = 0; topnode->assoc_tree = NULL; topnode->desc = NULL; record_descriptor(pf, topnode); // add to the global tree } DEBUG_RET(); return topnode; } pst_binary pst_attach_to_mem(pst_file *pf, pst_item_attach *attach) { pst_index_ll *ptr; pst_binary rc; pst_holder h = {&rc.data, NULL, 0, 0, 0}; rc.size = 0; rc.data = NULL; DEBUG_ENT("pst_attach_to_mem"); if ((!attach->data.data) && (attach->i_id != (uint64_t)-1)) { ptr = pst_getID(pf, attach->i_id); if (ptr) { rc.size = pst_ff_getID2data(pf, ptr, &h); } else { DEBUG_WARN(("Couldn't find ID pointer. Cannot handle attachment\n")); } } else { rc = attach->data; attach->data.data = NULL; // prevent pst_free_item() from trying to free this attach->data.size = 0; // since we have given that buffer to the caller } DEBUG_RET(); return rc; } size_t pst_attach_to_file(pst_file *pf, pst_item_attach *attach, FILE* fp) { pst_index_ll *ptr; pst_holder h = {NULL, fp, 0, 0, 0}; size_t size = 0; DEBUG_ENT("pst_attach_to_file"); if ((!attach->data.data) && (attach->i_id != (uint64_t)-1)) { ptr = pst_getID(pf, attach->i_id); if (ptr) { size = pst_ff_getID2data(pf, ptr, &h); } else { DEBUG_WARN(("Couldn't find ID pointer. Cannot save attachment to file\n")); } } else { size = attach->data.size; if (attach->data.data && size) { // save the attachment to the file (void)pst_fwrite(attach->data.data, (size_t)1, size, fp); } } DEBUG_RET(); return size; } size_t pst_attach_to_file_base64(pst_file *pf, pst_item_attach *attach, FILE* fp) { pst_index_ll *ptr; pst_holder h = {NULL, fp, 1, 0, 0}; size_t size = 0; DEBUG_ENT("pst_attach_to_file_base64"); if ((!attach->data.data) && (attach->i_id != (uint64_t)-1)) { ptr = pst_getID(pf, attach->i_id); if (ptr) { size = pst_ff_getID2data(pf, ptr, &h); } else { DEBUG_WARN(("Couldn't find ID pointer. Cannot save attachment to Base64\n")); } } else { size = attach->data.size; if (attach->data.data && size) { // encode the attachment to the file char *c = pst_base64_encode(attach->data.data, size); if (c) { (void)pst_fwrite(c, (size_t)1, strlen(c), fp); free(c); // caught by valgrind } } } DEBUG_RET(); return size; } int pst_load_index (pst_file *pf) { int x; DEBUG_ENT("pst_load_index"); if (!pf) { DEBUG_WARN(("Cannot load index for a NULL pst_file\n")); DEBUG_RET(); return -1; } x = pst_build_id_ptr(pf, pf->index1, 0, pf->index1_back, 0, UINT64_MAX); DEBUG_INFO(("build id ptr returns %i\n", x)); x = pst_build_desc_ptr(pf, pf->index2, 0, pf->index2_back, (uint64_t)0x21, UINT64_MAX); DEBUG_INFO(("build desc ptr returns %i\n", x)); pst_printDptr(pf, pf->d_head); DEBUG_RET(); return 0; } pst_desc_tree* pst_getNextDptr(pst_desc_tree* d) { pst_desc_tree* r = NULL; DEBUG_ENT("pst_getNextDptr"); if (d) { if ((r = d->child) == NULL) { while (!d->next && d->parent) d = d->parent; r = d->next; } } DEBUG_RET(); return r; } typedef struct pst_x_attrib { uint32_t extended; uint16_t type; uint16_t map; } pst_x_attrib; /** Try to load the extended attributes from the pst file. @return true(1) or false(0) to indicate whether the extended attributes have been loaded */ int pst_load_extended_attributes(pst_file *pf) { // for PST files this will load up d_id 0x61 and check it's "assoc_tree" attribute. pst_desc_tree *p; pst_mapi_object *list; pst_id2_tree *id2_head = NULL; char *buffer=NULL, *headerbuffer=NULL; size_t bsize=0, hsize=0, bptr=0; pst_x_attrib xattrib; int32_t tint, x; pst_x_attrib_ll *ptr, *p_head=NULL; DEBUG_ENT("pst_loadExtendedAttributes"); p = pst_getDptr(pf, (uint64_t)0x61); if (!p) { DEBUG_WARN(("Cannot find d_id 0x61 for loading the Extended Attributes\n")); DEBUG_RET(); return 0; } if (!p->desc) { DEBUG_WARN(("descriptor is NULL for d_id 0x61. Cannot load Extended Attributes\n")); DEBUG_RET(); return 0; } if (p->assoc_tree) { id2_head = pst_build_id2(pf, p->assoc_tree); pst_printID2ptr(id2_head); } else { DEBUG_WARN(("Have not been able to fetch any id2 values for d_id 0x61. Brace yourself!\n")); } list = pst_parse_block(pf, p->desc->i_id, id2_head); if (!list) { DEBUG_WARN(("Cannot process desc block for item 0x61. Not loading extended Attributes\n")); pst_free_id2(id2_head); DEBUG_RET(); return 0; } DEBUG_INFO(("look through d_id 0x61 list of mapi objects\n")); for (x=0; x < list->count_elements; x++) { DEBUG_INFO(("#%d - mapi-id: %#x type: %#x length: %#x\n", x, list->elements[x]->mapi_id, list->elements[x]->type, list->elements[x]->size)); if (list->elements[x]->data) { DEBUG_HEXDUMPC(list->elements[x]->data, list->elements[x]->size, 0x10); } if (list->elements[x]->mapi_id == (uint32_t)0x0003) { buffer = list->elements[x]->data; bsize = list->elements[x]->size; } else if (list->elements[x]->mapi_id == (uint32_t)0x0004) { headerbuffer = list->elements[x]->data; hsize = list->elements[x]->size; } else { // leave them null } } if (!buffer) { pst_free_list(list); DEBUG_WARN(("No extended attributes buffer found. Not processing\n")); DEBUG_RET(); return 0; } while (bptr < bsize) { int err = 0; xattrib.extended= PST_LE_GET_UINT32(buffer+bptr), bptr += 4; xattrib.type = PST_LE_GET_UINT16(buffer+bptr), bptr += 2; xattrib.map = PST_LE_GET_UINT16(buffer+bptr), bptr += 2; ptr = (pst_x_attrib_ll*) pst_malloc(sizeof(*ptr)); memset(ptr, 0, sizeof(*ptr)); ptr->map = xattrib.map+0x8000; ptr->next = NULL; DEBUG_INFO(("xattrib: ext = %#"PRIx32", type = %#"PRIx16", map = %#"PRIx16"\n", xattrib.extended, xattrib.type, xattrib.map)); if (xattrib.type & 0x0001) { // if the Bit 1 is set // pointer to Unicode field in buffer if (xattrib.extended < hsize) { char *wt; // copy the size of the header. It is 32 bit int memcpy(&tint, &(headerbuffer[xattrib.extended]), sizeof(tint)); LE32_CPU(tint); wt = (char*) pst_malloc((size_t)(tint+2)); // plus 2 for a uni-code zero memset(wt, 0, (size_t)(tint+2)); memcpy(wt, &(headerbuffer[xattrib.extended+sizeof(tint)]), (size_t)tint); ptr->data = pst_wide_to_single(wt, (size_t)tint); free(wt); DEBUG_INFO(("Mapped attribute %#"PRIx32" to %s\n", ptr->map, ptr->data)); } else { DEBUG_INFO(("Cannot read outside of buffer [%i !< %i]\n", xattrib.extended, hsize)); err = 1; } ptr->mytype = PST_MAP_HEADER; } else { // contains the attribute code to map to. ptr->data = (uint32_t*)pst_malloc(sizeof(uint32_t)); memset(ptr->data, 0, sizeof(uint32_t)); *((uint32_t*)ptr->data) = xattrib.extended; ptr->mytype = PST_MAP_ATTRIB; DEBUG_INFO(("Mapped attribute %#"PRIx32" to %#"PRIx32"\n", ptr->map, *((uint32_t*)ptr->data))); } if (!err) { // add it to the list pst_x_attrib_ll *p_sh = p_head; pst_x_attrib_ll *p_sh2 = NULL; while (p_sh && (ptr->map > p_sh->map)) { p_sh2 = p_sh; p_sh = p_sh->next; } if (!p_sh2) { // needs to go before first item ptr->next = p_head; p_head = ptr; } else { // it will go after p_sh2 ptr->next = p_sh2->next; p_sh2->next = ptr; } } else { free(ptr); } } pst_free_id2(id2_head); pst_free_list(list); pf->x_head = p_head; DEBUG_RET(); return 1; } #define ITEM_COUNT_OFFSET32 0x1f0 // count byte #define MAX_COUNT_OFFSET32 0x1f1 #define ENTRY_SIZE_OFFSET32 0x1f2 #define LEVEL_INDICATOR_OFFSET32 0x1f3 // node or leaf #define BACKLINK_OFFSET32 0x1f8 // backlink u1 value #define ITEM_COUNT_OFFSET64 0x1e8 // count byte #define MAX_COUNT_OFFSET64 0x1e9 #define ENTRY_SIZE_OFFSET64 0x1ea // node or leaf #define LEVEL_INDICATOR_OFFSET64 0x1eb // node or leaf #define BACKLINK_OFFSET64 0x1f8 // backlink u1 value #define ITEM_COUNT_OFFSET4K 0xfd8 #define MAX_COUNT_OFFSET4K 0xfda #define ENTRY_SIZE_OFFSET4K 0xfdc #define LEVEL_INDICATOR_OFFSET4K 0xfdd #define BACKLINK_OFFSET4K 0xff0 #define BLOCK_SIZE (size_t)((pf->do_read64 == 2) ? 4096 : 512) // index blocks #define DESC_BLOCK_SIZE (size_t)((pf->do_read64 == 2) ? 4096 : 512) // descriptor blocks #define ITEM_COUNT_OFFSET (size_t)((pf->do_read64) ? (pf->do_read64 == 2 ? ITEM_COUNT_OFFSET4K : ITEM_COUNT_OFFSET64) : ITEM_COUNT_OFFSET32) #define LEVEL_INDICATOR_OFFSET (size_t)((pf->do_read64) ? (pf->do_read64 == 2 ? LEVEL_INDICATOR_OFFSET4K : LEVEL_INDICATOR_OFFSET64) : LEVEL_INDICATOR_OFFSET32) #define BACKLINK_OFFSET (size_t)((pf->do_read64) ? (pf->do_read64 == 2 ? BACKLINK_OFFSET4K : BACKLINK_OFFSET64) : BACKLINK_OFFSET32) #define ENTRY_SIZE_OFFSET (size_t)((pf->do_read64) ? (pf->do_read64 == 2 ? ENTRY_SIZE_OFFSET4K : ENTRY_SIZE_OFFSET64) : ENTRY_SIZE_OFFSET32) #define MAX_COUNT_OFFSET (size_t)((pf->do_read64) ? (pf->do_read64 == 2 ? MAX_COUNT_OFFSET4K : MAX_COUNT_OFFSET64) : MAX_COUNT_OFFSET32) #define read_twobyte(BUF, OFF) (int32_t) ((((unsigned)BUF[OFF + 1] & 0xFF)) << 8) | ((unsigned)BUF[OFF] & 0xFF); static size_t pst_decode_desc(pst_file *pf, pst_desc *desc, char *buf); static size_t pst_decode_desc(pst_file *pf, pst_desc *desc, char *buf) { size_t r; if (pf->do_read64) { DEBUG_INFO(("Decoding desc64\n")); DEBUG_HEXDUMPC(buf, sizeof(pst_desc), 0x10); memcpy(desc, buf, sizeof(pst_desc)); LE64_CPU(desc->d_id); LE64_CPU(desc->desc_id); LE64_CPU(desc->tree_id); LE32_CPU(desc->parent_d_id); LE32_CPU(desc->u1); r = sizeof(pst_desc); } else { pst_desc32 d32; DEBUG_INFO(("Decoding desc32\n")); DEBUG_HEXDUMPC(buf, sizeof(pst_desc32), 0x10); memcpy(&d32, buf, sizeof(pst_desc32)); LE32_CPU(d32.d_id); LE32_CPU(d32.desc_id); LE32_CPU(d32.tree_id); LE32_CPU(d32.parent_d_id); desc->d_id = d32.d_id; desc->desc_id = d32.desc_id; desc->tree_id = d32.tree_id; desc->parent_d_id = d32.parent_d_id; desc->u1 = 0; r = sizeof(pst_desc32); } return r; } static size_t pst_decode_table(pst_file *pf, struct pst_table_ptr_struct *table, char *buf); static size_t pst_decode_table(pst_file *pf, struct pst_table_ptr_struct *table, char *buf) { size_t r; if (pf->do_read64) { DEBUG_INFO(("Decoding table64\n")); DEBUG_HEXDUMPC(buf, sizeof(struct pst_table_ptr_struct), 0x10); memcpy(table, buf, sizeof(struct pst_table_ptr_struct)); LE64_CPU(table->start); LE64_CPU(table->u1); LE64_CPU(table->offset); r =sizeof(struct pst_table_ptr_struct); } else { struct pst_table_ptr_struct32 t32; DEBUG_INFO(("Decoding table32\n")); DEBUG_HEXDUMPC(buf, sizeof( struct pst_table_ptr_struct32), 0x10); memcpy(&t32, buf, sizeof(struct pst_table_ptr_struct32)); LE32_CPU(t32.start); LE32_CPU(t32.u1); LE32_CPU(t32.offset); table->start = t32.start; table->u1 = t32.u1; table->offset = t32.offset; r = sizeof(struct pst_table_ptr_struct32); } return r; } static size_t pst_decode_index(pst_file *pf, pst_index *index, char *buf); static size_t pst_decode_index(pst_file *pf, pst_index *index, char *buf) { size_t r; if (pf->do_read64 == 2) { DEBUG_INFO(("Decoding index4k\n")); DEBUG_HEXDUMPC(buf, sizeof(pst_index), 0x10); memcpy(index, buf, sizeof(pst_index)); LE64_CPU(index->id); LE64_CPU(index->offset); LE16_CPU(index->size); LE16_CPU(index->inflated_size); LE16_CPU(index->u0); LE32_CPU(index->u1); r = sizeof(pst_index); } else if (pf->do_read64 == 1) { pst_index64 index64; DEBUG_INFO(("Decoding index64\n")); DEBUG_HEXDUMPC(buf, sizeof(pst_index64), 0x10); memcpy(&index64, buf, sizeof(pst_index64)); LE64_CPU(index64.id); LE64_CPU(index64.offset); LE16_CPU(index64.size); LE16_CPU(index64.u0); LE32_CPU(index64.u1); index->id = index64.id; index->offset = index64.offset; index->size = index64.size; index->inflated_size = index64.size; index->u0 = index64.u0; index->u1 = index64.u1; r = sizeof(pst_index64); } else { pst_index32 index32; DEBUG_INFO(("Decoding index32\n")); DEBUG_HEXDUMPC(buf, sizeof(pst_index32), 0x10); memcpy(&index32, buf, sizeof(pst_index32)); LE32_CPU(index32.id); LE32_CPU(index32.offset); LE16_CPU(index32.size); LE16_CPU(index32.u1); index->id = index32.id; index->offset = index32.offset; index->size = index32.size; index->inflated_size = index32.size; index->u0 = 0; index->u1 = index32.u1; r = sizeof(pst_index32); } return r; } static size_t pst_decode_assoc(pst_file *pf, pst_id2_assoc *assoc, char *buf); static size_t pst_decode_assoc(pst_file *pf, pst_id2_assoc *assoc, char *buf) { size_t r; if (pf->do_read64) { DEBUG_INFO(("Decoding assoc64\n")); DEBUG_HEXDUMPC(buf, sizeof(pst_id2_assoc), 0x10); memcpy(assoc, buf, sizeof(pst_id2_assoc)); LE32_CPU(assoc->id2); LE64_CPU(assoc->id); LE64_CPU(assoc->child_id); r = sizeof(pst_id2_assoc); } else { pst_id2_assoc32 assoc32; DEBUG_INFO(("Decoding assoc32\n")); DEBUG_HEXDUMPC(buf, sizeof(pst_id2_assoc32), 0x10); memcpy(&assoc32, buf, sizeof(pst_id2_assoc32)); LE32_CPU(assoc32.id2); LE32_CPU(assoc32.id); LE32_CPU(assoc32.child_id); assoc->id2 = assoc32.id2; assoc->id = assoc32.id; assoc->child_id = assoc32.child_id; r = sizeof(pst_id2_assoc32); } return r; } static size_t pst_decode_type3(pst_file *pf, pst_table3_rec *table3_rec, char *buf); static size_t pst_decode_type3(pst_file *pf, pst_table3_rec *table3_rec, char *buf) { size_t r; DEBUG_ENT("pst_decode_type3"); if (pf->do_read64) { DEBUG_INFO(("Decoding table3 64\n")); DEBUG_HEXDUMPC(buf, sizeof(pst_table3_rec), 0x10); memcpy(table3_rec, buf, sizeof(pst_table3_rec)); LE64_CPU(table3_rec->id); r = sizeof(pst_table3_rec); } else { pst_table3_rec32 table3_rec32; DEBUG_INFO(("Decoding table3 32\n")); DEBUG_HEXDUMPC(buf, sizeof(pst_table3_rec32), 0x10); memcpy(&table3_rec32, buf, sizeof(pst_table3_rec32)); LE32_CPU(table3_rec32.id); table3_rec->id = table3_rec32.id; r = sizeof(pst_table3_rec32); } DEBUG_RET(); return r; } /** Process the index1 b-tree from the pst file and create the * pf->i_head linked list from it. This tree holds the location * (offset and size) of lower level objects (0xbcec descriptor * blocks, etc) in the pst file. */ static int pst_build_id_ptr(pst_file *pf, int64_t offset, int32_t depth, uint64_t linku1, uint64_t start_val, uint64_t end_val) { struct pst_table_ptr_struct table, table2; pst_index_ll *i_ptr=NULL; pst_index index; int32_t x, item_count, count_max; uint64_t old = start_val; char *buf = NULL, *bptr; DEBUG_ENT("pst_build_id_ptr"); DEBUG_INFO(("offset %#"PRIx64" depth %i linku1 %#"PRIx64" start %#"PRIx64" end %#"PRIx64"\n", offset, depth, linku1, start_val, end_val)); if (end_val <= start_val) { DEBUG_WARN(("The end value is BEFORE the start value. This function will quit. Soz. [start:%#"PRIx64", end:%#"PRIx64"]\n", start_val, end_val)); DEBUG_RET(); return -1; } DEBUG_INFO(("Reading index block\n")); if (pst_read_block_size(pf, offset, BLOCK_SIZE, BLOCK_SIZE, &buf) < BLOCK_SIZE) { DEBUG_WARN(("Failed to read %i bytes\n", BLOCK_SIZE)); if (buf) free(buf); DEBUG_RET(); return -1; } bptr = buf; DEBUG_HEXDUMPC(buf, BLOCK_SIZE, 0x10); if (pf->do_read64 == 2) { item_count = read_twobyte(buf, ITEM_COUNT_OFFSET); count_max = read_twobyte(buf, MAX_COUNT_OFFSET); } else { item_count = (int32_t)(unsigned)(buf[ITEM_COUNT_OFFSET]); count_max = (int32_t)(unsigned)(buf[MAX_COUNT_OFFSET]); } if (item_count > count_max) { DEBUG_WARN(("Item count %i too large, max is %i\n", item_count, count_max)); if (buf) free(buf); DEBUG_RET(); return -1; } index.id = pst_getIntAt(pf, buf+BACKLINK_OFFSET); if (index.id != linku1) { DEBUG_WARN(("Backlink %#"PRIx64" in this node does not match required %#"PRIx64"\n", index.id, linku1)); if (buf) free(buf); DEBUG_RET(); return -1; } int entry_size = (int32_t)(unsigned)(buf[ENTRY_SIZE_OFFSET]); DEBUG_INFO(("count %#"PRIx64" max %#"PRIx64" size %#"PRIx64"\n", item_count, count_max, entry_size)); if (buf[LEVEL_INDICATOR_OFFSET] == '\0') { // this node contains leaf pointers x = 0; while (x < item_count) { pst_decode_index(pf, &index, bptr); bptr += entry_size; x++; if (index.id == 0) break; DEBUG_INFO(("[%i]%i Item [id = %#"PRIx64", offset = %#"PRIx64", u1 = %#x, size = %i(%#x)]\n", depth, x, index.id, index.offset, index.u1, index.size, index.size)); // if (index.id & 0x02) DEBUG_INFO(("two-bit set!!\n")); if ((index.id >= end_val) || (index.id < old)) { DEBUG_WARN(("This item isn't right. Must be corruption, or I got it wrong!\n")); if (buf) free(buf); DEBUG_RET(); return -1; } old = index.id; if (pf->i_count == pf->i_capacity) { pf->i_capacity += (pf->i_capacity >> 1) + 16; // arbitrary growth rate pf->i_table = pst_realloc(pf->i_table, pf->i_capacity * sizeof(pst_index_ll)); } i_ptr = &pf->i_table[pf->i_count++]; i_ptr->i_id = index.id; i_ptr->offset = index.offset; i_ptr->u1 = index.u1; i_ptr->size = index.size; i_ptr->inflated_size = index.inflated_size; } } else { // this node contains node pointers x = 0; while (x < item_count) { pst_decode_table(pf, &table, bptr); bptr += entry_size; x++; if (table.start == 0) break; if (x < item_count) { (void)pst_decode_table(pf, &table2, bptr); } else { table2.start = end_val; } DEBUG_INFO(("[%i] %i Index Table [start id = %#"PRIx64", u1 = %#"PRIx64", offset = %#"PRIx64", end id = %#"PRIx64"]\n", depth, x, table.start, table.u1, table.offset, table2.start)); if ((table.start >= end_val) || (table.start < old)) { DEBUG_WARN(("This table isn't right. Must be corruption, or I got it wrong!\n")); if (buf) free(buf); DEBUG_RET(); return -1; } old = table.start; (void)pst_build_id_ptr(pf, table.offset, depth+1, table.u1, table.start, table2.start); } } if (buf) free (buf); DEBUG_RET(); return 0; } /** Process the index2 b-tree from the pst file and create the * pf->d_head tree from it. This tree holds descriptions of the * higher level objects (email, contact, etc) in the pst file. */ static int pst_build_desc_ptr (pst_file *pf, int64_t offset, int32_t depth, uint64_t linku1, uint64_t start_val, uint64_t end_val) { struct pst_table_ptr_struct table, table2; pst_desc desc_rec; int32_t item_count, count_max; uint64_t old = start_val; int x; char *buf = NULL, *bptr; DEBUG_ENT("pst_build_desc_ptr"); DEBUG_INFO(("offset %#"PRIx64" depth %i linku1 %#"PRIx64" start %#"PRIx64" end %#"PRIx64"\n", offset, depth, linku1, start_val, end_val)); if (end_val <= start_val) { DEBUG_WARN(("The end value is BEFORE the start value. This function will quit. Soz. [start:%#"PRIx64", end:%#"PRIx64"]\n", start_val, end_val)); DEBUG_RET(); return -1; } DEBUG_INFO(("Reading desc block\n")); if (pst_read_block_size(pf, offset, DESC_BLOCK_SIZE, DESC_BLOCK_SIZE, &buf) < DESC_BLOCK_SIZE) { DEBUG_WARN(("Failed to read %i bytes\n", DESC_BLOCK_SIZE)); if (buf) free(buf); DEBUG_RET(); return -1; } bptr = buf; if (pf->do_read64 == 2) { item_count = read_twobyte(buf, ITEM_COUNT_OFFSET); count_max = read_twobyte(buf, MAX_COUNT_OFFSET); } else { item_count = (int32_t)(unsigned)(buf[ITEM_COUNT_OFFSET]); count_max = (int32_t)(unsigned)(buf[MAX_COUNT_OFFSET]); } desc_rec.d_id = pst_getIntAt(pf, buf+BACKLINK_OFFSET); if (desc_rec.d_id != linku1) { DEBUG_WARN(("Backlink %#"PRIx64" in this node does not match required %#"PRIx64"\n", desc_rec.d_id, linku1)); if (buf) free(buf); DEBUG_RET(); return -1; } int32_t entry_size = (int32_t)(unsigned)(buf[ENTRY_SIZE_OFFSET]); if (buf[LEVEL_INDICATOR_OFFSET] == '\0') { // this node contains leaf pointers DEBUG_HEXDUMPC(buf, DESC_BLOCK_SIZE, entry_size); if (item_count > count_max) { DEBUG_WARN(("Item count %i too large, max is %i\n", item_count, count_max)); if (buf) free(buf); DEBUG_RET(); return -1; } for (x=0; x= end_val) || (desc_rec.d_id < old)) { DEBUG_WARN(("This item isn't right. Must be corruption, or I got it wrong!\n")); DEBUG_HEXDUMPC(buf, DESC_BLOCK_SIZE, 16); if (buf) free(buf); DEBUG_RET(); return -1; } old = desc_rec.d_id; DEBUG_INFO(("New Record %#"PRIx64" with parent %#x\n", desc_rec.d_id, desc_rec.parent_d_id)); { pst_desc_tree *d_ptr = (pst_desc_tree*) pst_malloc(sizeof(pst_desc_tree)); d_ptr->d_id = desc_rec.d_id; d_ptr->parent_d_id = desc_rec.parent_d_id; d_ptr->assoc_tree = pst_getID(pf, desc_rec.tree_id); d_ptr->desc = pst_getID(pf, desc_rec.desc_id); record_descriptor(pf, d_ptr); // add to the global tree } } } else { // this node contains node pointers DEBUG_HEXDUMPC(buf, DESC_BLOCK_SIZE, entry_size); if (item_count > count_max) { DEBUG_WARN(("Item count %i too large, max is %i\n", item_count, count_max)); if (buf) free(buf); DEBUG_RET(); return -1; } for (x=0; x= end_val) || (table.start < old)) { DEBUG_WARN(("This table isn't right. Must be corruption, or I got it wrong!\n")); if (buf) free(buf); DEBUG_RET(); return -1; } old = table.start; (void)pst_build_desc_ptr(pf, table.offset, depth+1, table.u1, table.start, table2.start); } } if (buf) free(buf); DEBUG_RET(); return 0; } /** Process a high level object from the pst file. */ pst_item* pst_parse_item(pst_file *pf, pst_desc_tree *d_ptr, pst_id2_tree *m_head) { pst_mapi_object * list; pst_id2_tree *id2_head = m_head; pst_id2_tree *id2_ptr = NULL; pst_item *item = NULL; pst_item_attach *attach = NULL; int32_t x; DEBUG_ENT("pst_parse_item"); if (!d_ptr) { DEBUG_WARN(("you cannot pass me a NULL! I don't want it!\n")); DEBUG_RET(); return NULL; } if (!d_ptr->desc) { DEBUG_WARN(("why is d_ptr->desc == NULL? I don't want to do anything else with this record\n")); DEBUG_RET(); return NULL; } if (d_ptr->assoc_tree) { if (m_head) { DEBUG_WARN(("supplied master head, but have a list that is building a new id2_head\n")); m_head = NULL; } id2_head = pst_build_id2(pf, d_ptr->assoc_tree); } pst_printID2ptr(id2_head); list = pst_parse_block(pf, d_ptr->desc->i_id, id2_head); if (!list) { DEBUG_WARN(("pst_parse_block() returned an error for d_ptr->desc->i_id [%#"PRIx64"]\n", d_ptr->desc->i_id)); if (!m_head) pst_free_id2(id2_head); DEBUG_RET(); return NULL; } item = (pst_item*) pst_malloc(sizeof(pst_item)); memset(item, 0, sizeof(pst_item)); item->pf = pf; if (pst_process(d_ptr->desc->i_id, list, item, NULL)) { DEBUG_WARN(("pst_process() returned non-zero value. That is an error\n")); pst_freeItem(item); pst_free_list(list); if (!m_head) pst_free_id2(id2_head); DEBUG_RET(); return NULL; } pst_free_list(list); if ((id2_ptr = pst_getID2(id2_head, (uint64_t)0x692))) { // DSN/MDN reports? DEBUG_INFO(("DSN/MDN processing\n")); list = pst_parse_block(pf, id2_ptr->id->i_id, id2_ptr->child); if (list) { for (x=0; x < list->count_objects; x++) { attach = (pst_item_attach*) pst_malloc(sizeof(pst_item_attach)); memset(attach, 0, sizeof(pst_item_attach)); attach->next = item->attach; item->attach = attach; } if (pst_process(id2_ptr->id->i_id, list, item, item->attach)) { DEBUG_WARN(("ERROR pst_process() failed with DSN/MDN attachments\n")); pst_freeItem(item); pst_free_list(list); if (!m_head) pst_free_id2(id2_head); DEBUG_RET(); return NULL; } pst_free_list(list); } else { DEBUG_WARN(("ERROR error processing main DSN/MDN record\n")); // if (!m_head) pst_free_id2(id2_head); // DEBUG_RET(); // return item; } } if ((id2_ptr = pst_getID2(id2_head, (uint64_t)0x671))) { DEBUG_INFO(("ATTACHMENT processing attachment\n")); list = pst_parse_block(pf, id2_ptr->id->i_id, id2_ptr->child); if (!list) { if (item->flags & PST_FLAG_HAS_ATTACHMENT) { // Only report an error if we expected to see an attachment table and didn't. DEBUG_WARN(("ERROR error processing main attachment record\n")); } if (!m_head) pst_free_id2(id2_head); DEBUG_RET(); return item; } for (x=0; x < list->count_objects; x++) { attach = (pst_item_attach*) pst_malloc(sizeof(pst_item_attach)); memset(attach, 0, sizeof(pst_item_attach)); attach->next = item->attach; item->attach = attach; } if (pst_process(id2_ptr->id->i_id, list, item, item->attach)) { DEBUG_WARN(("ERROR pst_process() failed with attachments\n")); pst_freeItem(item); pst_free_list(list); if (!m_head) pst_free_id2(id2_head); DEBUG_RET(); return NULL; } pst_free_list(list); // now we will have initial information of each attachment stored in item->attach... // we must now read the secondary record for each based on the id2_val associated with // each attachment for (attach = item->attach; attach; attach = attach->next) { DEBUG_WARN(("initial attachment id2 %#"PRIx64"\n", attach->id2_val)); if ((id2_ptr = pst_getID2(id2_head, attach->id2_val))) { DEBUG_WARN(("initial attachment id2 found id %#"PRIx64"\n", id2_ptr->id->i_id)); // id2_ptr is a record describing the attachment // we pass NULL instead of id2_head cause we don't want it to // load all the extra stuff here. list = pst_parse_block(pf, id2_ptr->id->i_id, NULL); if (!list) { DEBUG_WARN(("ERROR error processing an attachment record\n")); continue; } if (list->count_objects > 1) { DEBUG_WARN(("ERROR probably fatal, list count array will overrun attach structure.\n")); } // reprocess the same attachment list against new data // this might update attach->id2_val if (pst_process(id2_ptr->id->i_id, list, item, attach)) { DEBUG_WARN(("ERROR pst_process() failed with an attachment\n")); pst_free_list(list); continue; } pst_free_list(list); // As per 2.4.6.2 in the spec, the attachment data is stored as a child of the // attachment object, so we pass in id2_ptr as the head to search from. id2_ptr = pst_getID2(id2_ptr->child, attach->id2_val); if (id2_ptr) { DEBUG_WARN(("second pass attachment updating id2 %#"PRIx64" found i_id %#"PRIx64"\n", attach->id2_val, id2_ptr->id->i_id)); // i_id has been updated to the datablock containing the attachment data attach->i_id = id2_ptr->id->i_id; attach->id2_head = deep_copy(id2_ptr->child); } else { DEBUG_WARN(("have not located the correct value for the attachment [%#"PRIx64"]\n", attach->id2_val)); } } else { DEBUG_WARN(("ERROR cannot locate id2 value %#"PRIx64"\n", attach->id2_val)); attach->id2_val = 0; // suppress this missing attachment } } } if (!m_head) pst_free_id2(id2_head); DEBUG_RET(); return item; } static void freeall(pst_subblocks *subs, pst_block_offset_pointer *p1, pst_block_offset_pointer *p2, pst_block_offset_pointer *p3, pst_block_offset_pointer *p4, pst_block_offset_pointer *p5, pst_block_offset_pointer *p6, pst_block_offset_pointer *p7); static void freeall(pst_subblocks *subs, pst_block_offset_pointer *p1, pst_block_offset_pointer *p2, pst_block_offset_pointer *p3, pst_block_offset_pointer *p4, pst_block_offset_pointer *p5, pst_block_offset_pointer *p6, pst_block_offset_pointer *p7) { size_t i; for (i=0; isubblock_count; i++) { if (subs->subs[i].buf) free(subs->subs[i].buf); } free(subs->subs); if (p1->needfree) free(p1->from); if (p2->needfree) free(p2->from); if (p3->needfree) free(p3->from); if (p4->needfree) free(p4->from); if (p5->needfree) free(p5->from); if (p6->needfree) free(p6->from); if (p7->needfree) free(p7->from); } /** Process a low level descriptor block (0x0101, 0xbcec, 0x7cec) into a * list of MAPI objects, each of which contains a list of MAPI elements. * * @return list of MAPI objects */ static pst_mapi_object* pst_parse_block(pst_file *pf, uint64_t block_id, pst_id2_tree *i2_head) { pst_mapi_object *mo_head = NULL; char *buf = NULL; size_t read_size = 0; pst_subblocks subblocks; pst_mapi_object *mo_ptr = NULL; pst_block_offset_pointer block_offset1; pst_block_offset_pointer block_offset2; pst_block_offset_pointer block_offset3; pst_block_offset_pointer block_offset4; pst_block_offset_pointer block_offset5; pst_block_offset_pointer block_offset6; pst_block_offset_pointer block_offset7; int32_t x; int32_t num_mapi_objects; int32_t count_mapi_objects; int32_t num_mapi_elements; int32_t count_mapi_elements; int block_type; uint32_t rec_size = 0; char* list_start; char* fr_ptr; char* to_ptr; char* ind2_end = NULL; char* ind2_ptr = NULL; char* ind2_block_start = NULL; size_t ind2_max_block_size = pf->do_read64 ? 0x1FF0 : 0x1FF4; pst_x_attrib_ll *mapptr; pst_block_hdr block_hdr; pst_table3_rec table3_rec; //for type 3 (0x0101) blocks struct { unsigned char seven_c; unsigned char item_count; uint16_t u1; uint16_t u2; uint16_t u3; uint16_t rec_size; uint32_t b_five_offset; uint32_t ind2_offset; uint16_t u7; uint16_t u8; } seven_c_blk; struct _type_d_rec { uint32_t id; uint32_t u1; } * type_d_rec; struct { uint16_t type; uint16_t ref_type; uint32_t value; } table_rec; //for type 1 (0xBCEC) blocks struct { uint16_t ref_type; uint16_t type; uint16_t ind2_off; uint8_t size; uint8_t slot; } table2_rec; //for type 2 (0x7CEC) blocks DEBUG_ENT("pst_parse_block"); if ((read_size = pst_ff_getIDblock_dec(pf, block_id, &buf)) == 0) { DEBUG_WARN(("Error reading block id %#"PRIx64"\n", block_id)); if (buf) free (buf); DEBUG_RET(); return NULL; } block_offset1.needfree = 0; block_offset2.needfree = 0; block_offset3.needfree = 0; block_offset4.needfree = 0; block_offset5.needfree = 0; block_offset6.needfree = 0; block_offset7.needfree = 0; memcpy(&block_hdr, buf, sizeof(block_hdr)); LE16_CPU(block_hdr.index_offset); LE16_CPU(block_hdr.type); LE32_CPU(block_hdr.offset); DEBUG_INFO(("block header (index_offset=%#hx, type=%#hx, offset=%#hx)\n", block_hdr.index_offset, block_hdr.type, block_hdr.offset)); if (block_hdr.index_offset == (uint16_t)0x0101) { //type 3 size_t i; char *b_ptr = buf + 8; subblocks.subblock_count = block_hdr.type; subblocks.subs = malloc(sizeof(pst_subblock) * subblocks.subblock_count); for (i=0; i 0) { if (pst_getBlockOffsetPointer(pf, i2_head, &subblocks, table_rec.value, &block_offset5)) { DEBUG_WARN(("internal error (7c.b5.desc offset %#x) in reading block id %#"PRIx64"\n", table_rec.value, block_id)); freeall(&subblocks, &block_offset1, &block_offset2, &block_offset3, &block_offset4, &block_offset5, &block_offset6, &block_offset7); DEBUG_RET(); return NULL; } // this will give the number of records in this block num_mapi_objects = (block_offset5.to - block_offset5.from) / (4 + table_rec.ref_type); if (pst_getBlockOffsetPointer(pf, i2_head, &subblocks, seven_c_blk.ind2_offset, &block_offset6)) { DEBUG_WARN(("internal error (7c.ind2 offset %#x) in reading block id %#"PRIx64"\n", seven_c_blk.ind2_offset, block_id)); freeall(&subblocks, &block_offset1, &block_offset2, &block_offset3, &block_offset4, &block_offset5, &block_offset6, &block_offset7); DEBUG_RET(); return NULL; } ind2_ptr = block_offset6.from; ind2_block_start = ind2_ptr; ind2_end = block_offset6.to; } else { num_mapi_objects = 0; } DEBUG_INFO(("7cec block index2 pointer %#x and end %#x\n", ind2_ptr, ind2_end)); } else { DEBUG_WARN(("ERROR: Unknown block constant - %#hx for id %#"PRIx64"\n", block_hdr.type, block_id)); freeall(&subblocks, &block_offset1, &block_offset2, &block_offset3, &block_offset4, &block_offset5, &block_offset6, &block_offset7); DEBUG_RET(); return NULL; } DEBUG_INFO(("found %i mapi objects each with %i mapi elements\n", num_mapi_objects, num_mapi_elements)); for (count_mapi_objects=0; count_mapi_objectsnext = mo_head; mo_head = mo_ptr; // allocate the array of mapi elements mo_ptr->elements = (pst_mapi_element**) pst_malloc(sizeof(pst_mapi_element)*num_mapi_elements); mo_ptr->count_elements = num_mapi_elements; mo_ptr->orig_count = num_mapi_elements; mo_ptr->count_objects = (int32_t)num_mapi_objects; // each record will have a record of the total number of records for (x=0; xelements[x] = NULL; DEBUG_INFO(("going to read %i mapi elements for mapi object %i\n", num_mapi_elements, count_mapi_objects)); fr_ptr = list_start; // initialize fr_ptr to the start of the list. x = 0; // x almost tracks count_mapi_elements, but see 'continue' statement below for (count_mapi_elements=0; count_mapi_elements= (int)(table2_rec.ind2_off + table2_rec.size)) { size_t n = table2_rec.size; size_t m = sizeof(table_rec.value); if (n <= m) { memcpy(&table_rec.value, ind2_ptr + table2_rec.ind2_off, n); } else { value_pointer = ind2_ptr + table2_rec.ind2_off; value_size = n; } //LE32_CPU(table_rec.value); // done later, some may be order invariant } else { DEBUG_WARN (("Trying to read outside buffer, buffer size %#x, offset %#x, data size %#x\n", read_size, ind2_end-ind2_ptr+table2_rec.ind2_off, table2_rec.size)); } fr_ptr += sizeof(table2_rec); } else { DEBUG_WARN(("Missing code for block_type %i\n", block_type)); freeall(&subblocks, &block_offset1, &block_offset2, &block_offset3, &block_offset4, &block_offset5, &block_offset6, &block_offset7); pst_free_list(mo_head); DEBUG_RET(); return NULL; } DEBUG_INFO(("reading element %i (type=%#x, ref_type=%#x, value=%#x)\n", x, table_rec.type, table_rec.ref_type, table_rec.value)); if (!mo_ptr->elements[x]) { mo_ptr->elements[x] = (pst_mapi_element*) pst_malloc(sizeof(pst_mapi_element)); } memset(mo_ptr->elements[x], 0, sizeof(pst_mapi_element)); //init it // check here to see if the id of the attribute is a mapped one mapptr = pf->x_head; while (mapptr && (mapptr->map < table_rec.type)) mapptr = mapptr->next; if (mapptr && (mapptr->map == table_rec.type)) { if (mapptr->mytype == PST_MAP_ATTRIB) { mo_ptr->elements[x]->mapi_id = *((uint32_t*)mapptr->data); DEBUG_INFO(("Mapped attrib %#x to %#x\n", table_rec.type, mo_ptr->elements[x]->mapi_id)); } else if (mapptr->mytype == PST_MAP_HEADER) { DEBUG_INFO(("Internet Header mapping found %#"PRIx32" to %s\n", table_rec.type, mapptr->data)); mo_ptr->elements[x]->mapi_id = (uint32_t)PST_ATTRIB_HEADER; mo_ptr->elements[x]->extra = mapptr->data; } else { DEBUG_WARN(("Missing assertion failure\n")); // nothing, should be assertion failure here } } else { mo_ptr->elements[x]->mapi_id = table_rec.type; } mo_ptr->elements[x]->type = 0; // checked later before it is set /* Reference Types 0x0002 - Signed 16bit value 0x0003 - Signed 32bit value 0x0004 - 4-byte floating point 0x0005 - Floating point double 0x0006 - Signed 64-bit int 0x0007 - Application Time 0x000A - 32-bit error value 0x000B - Boolean (non-zero = true) 0x000D - Embedded Object 0x0014 - 8-byte signed integer (64-bit) 0x001E - Null terminated String 0x001F - Unicode string 0x0040 - Systime - Filetime structure 0x0048 - OLE Guid 0x0102 - Binary data 0x1003 - Array of 32bit values 0x1014 - Array of 64bit values 0x101E - Array of Strings 0x1102 - Array of Binary data */ if (table_rec.ref_type == (uint16_t)0x0002 || table_rec.ref_type == (uint16_t)0x0003 || table_rec.ref_type == (uint16_t)0x000b) { //contains 32 bits of data mo_ptr->elements[x]->size = sizeof(int32_t); mo_ptr->elements[x]->type = table_rec.ref_type; mo_ptr->elements[x]->data = pst_malloc(sizeof(int32_t)); memcpy(mo_ptr->elements[x]->data, &(table_rec.value), sizeof(int32_t)); // are we missing an LE32_CPU() call here? table_rec.value is still // in the original order. } else if (table_rec.ref_type == (uint16_t)0x0005 || table_rec.ref_type == (uint16_t)0x000d || table_rec.ref_type == (uint16_t)0x0014 || table_rec.ref_type == (uint16_t)0x001e || table_rec.ref_type == (uint16_t)0x001f || table_rec.ref_type == (uint16_t)0x0040 || table_rec.ref_type == (uint16_t)0x0048 || table_rec.ref_type == (uint16_t)0x0102 || table_rec.ref_type == (uint16_t)0x1003 || table_rec.ref_type == (uint16_t)0x1014 || table_rec.ref_type == (uint16_t)0x101e || table_rec.ref_type == (uint16_t)0x101f || table_rec.ref_type == (uint16_t)0x1102) { //contains index reference to data LE32_CPU(table_rec.value); if (value_pointer) { // in a type 2 block, with a value that is more than 4 bytes // directly stored in this block. mo_ptr->elements[x]->size = value_size; mo_ptr->elements[x]->type = table_rec.ref_type; mo_ptr->elements[x]->data = pst_malloc(value_size); memcpy(mo_ptr->elements[x]->data, value_pointer, value_size); } else if (pst_getBlockOffsetPointer(pf, i2_head, &subblocks, table_rec.value, &block_offset7)) { if ((table_rec.value & 0xf) == (uint32_t)0xf) { DEBUG_WARN(("failed to get block offset for table_rec.value of %#x to be read later.\n", table_rec.value)); mo_ptr->elements[x]->size = 0; mo_ptr->elements[x]->data = NULL; mo_ptr->elements[x]->type = table_rec.value; } else { if (table_rec.value) { DEBUG_WARN(("failed to get block offset for table_rec.value of %#x\n", table_rec.value)); } mo_ptr->count_elements --; //we will be skipping a row continue; } } else { value_size = (size_t)(block_offset7.to - block_offset7.from); mo_ptr->elements[x]->size = value_size; mo_ptr->elements[x]->type = table_rec.ref_type; mo_ptr->elements[x]->data = pst_malloc(value_size+1); memcpy(mo_ptr->elements[x]->data, block_offset7.from, value_size); mo_ptr->elements[x]->data[value_size] = '\0'; // it might be a string, null terminate it. } if (table_rec.ref_type == (uint16_t)0xd) { // there is still more to do for the type of 0xD embedded objects type_d_rec = (struct _type_d_rec*) mo_ptr->elements[x]->data; LE32_CPU(type_d_rec->id); mo_ptr->elements[x]->size = pst_ff_getID2block(pf, type_d_rec->id, i2_head, &(mo_ptr->elements[x]->data)); if (!mo_ptr->elements[x]->size){ DEBUG_WARN(("not able to read the ID2 data. Setting to be read later. %#x\n", type_d_rec->id)); mo_ptr->elements[x]->type = type_d_rec->id; // fetch before freeing data, alias pointer free(mo_ptr->elements[x]->data); mo_ptr->elements[x]->data = NULL; } } if (table_rec.ref_type == (uint16_t)0x1f) { // there is more to do for the type 0x1f unicode strings size_t rc; static pst_vbuf *utf16buf = NULL; static pst_vbuf *utf8buf = NULL; if (!utf16buf) utf16buf = pst_vballoc((size_t)1024); if (!utf8buf) utf8buf = pst_vballoc((size_t)1024); //need UTF-16 zero-termination pst_vbset(utf16buf, mo_ptr->elements[x]->data, mo_ptr->elements[x]->size); pst_vbappend(utf16buf, "\0\0", (size_t)2); DEBUG_INFO(("Iconv in:\n")); DEBUG_HEXDUMPC(utf16buf->b, utf16buf->dlen, 0x10); rc = pst_vb_utf16to8(utf8buf, utf16buf->b, utf16buf->dlen); if (rc == (size_t)-1) { DEBUG_WARN(("Failed to convert utf-16 to utf-8\n")); } else { free(mo_ptr->elements[x]->data); mo_ptr->elements[x]->size = utf8buf->dlen; mo_ptr->elements[x]->data = pst_malloc(utf8buf->dlen); memcpy(mo_ptr->elements[x]->data, utf8buf->b, utf8buf->dlen); } DEBUG_INFO(("Iconv out:\n")); DEBUG_HEXDUMPC(mo_ptr->elements[x]->data, mo_ptr->elements[x]->size, 0x10); } if (mo_ptr->elements[x]->type == 0) mo_ptr->elements[x]->type = table_rec.ref_type; } else { DEBUG_WARN(("ERROR Unknown ref_type %#hx\n", table_rec.ref_type)); } x++; } DEBUG_INFO(("increasing ind2_ptr by %i [%#x] bytes. Was %#x, Now %#x\n", rec_size, rec_size, ind2_ptr, ind2_ptr+rec_size)); ind2_ptr += rec_size; // ind2 rows do not get split between blocks. See PST spec, 2.3.4.4 "Row Matrix". if (ind2_ptr + rec_size > ind2_block_start + ind2_max_block_size) { ind2_block_start += ind2_max_block_size; DEBUG_INFO(("advancing ind2_ptr to next block. Was %#x, Now %#x\n", ind2_ptr, ind2_block_start)); ind2_ptr = ind2_block_start; } } freeall(&subblocks, &block_offset1, &block_offset2, &block_offset3, &block_offset4, &block_offset5, &block_offset6, &block_offset7); DEBUG_RET(); return mo_head; } // This version of free does NULL check first #define SAFE_FREE(x) {if (x) free(x);} #define SAFE_FREE_STR(x) SAFE_FREE(x.str) #define SAFE_FREE_BIN(x) SAFE_FREE(x.data) // check if item->email is NULL, and init if so #define MALLOC_EMAIL(x) { if (!x->email) { x->email = (pst_item_email*) pst_malloc(sizeof(pst_item_email)); memset(x->email, 0, sizeof(pst_item_email) );} } #define MALLOC_FOLDER(x) { if (!x->folder) { x->folder = (pst_item_folder*) pst_malloc(sizeof(pst_item_folder)); memset(x->folder, 0, sizeof(pst_item_folder) );} } #define MALLOC_CONTACT(x) { if (!x->contact) { x->contact = (pst_item_contact*) pst_malloc(sizeof(pst_item_contact)); memset(x->contact, 0, sizeof(pst_item_contact) );} } #define MALLOC_MESSAGESTORE(x) { if (!x->message_store) { x->message_store = (pst_item_message_store*) pst_malloc(sizeof(pst_item_message_store)); memset(x->message_store, 0, sizeof(pst_item_message_store));} } #define MALLOC_JOURNAL(x) { if (!x->journal) { x->journal = (pst_item_journal*) pst_malloc(sizeof(pst_item_journal)); memset(x->journal, 0, sizeof(pst_item_journal) );} } #define MALLOC_APPOINTMENT(x) { if (!x->appointment) { x->appointment = (pst_item_appointment*) pst_malloc(sizeof(pst_item_appointment)); memset(x->appointment, 0, sizeof(pst_item_appointment) );} } // malloc space and copy the current item's data null terminated #define LIST_COPY(targ, type) { \ targ = type pst_realloc(targ, list->elements[x]->size+1); \ memcpy(targ, list->elements[x]->data, list->elements[x]->size);\ memset(((char*)targ)+list->elements[x]->size, 0, (size_t)1); \ } #define LIST_COPY_CSTR(targ) { \ if ((list->elements[x]->type == 0x1f) || \ (list->elements[x]->type == 0x1e) || \ (list->elements[x]->type == 0x102)) { \ LIST_COPY(targ, (char*)) \ } \ else { \ DEBUG_WARN(("src not 0x1e or 0x1f or 0x102 for string dst\n")); \ DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); \ SAFE_FREE(targ); \ targ = NULL; \ } \ } #define LIST_COPY_BOOL(label, targ) { \ if (list->elements[x]->type != 0x0b) { \ DEBUG_WARN(("src not 0x0b for boolean dst\n")); \ DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); \ } \ if (*(int16_t*)list->elements[x]->data) { \ DEBUG_INFO((label" - True\n")); \ targ = 1; \ } else { \ DEBUG_INFO((label" - False\n")); \ targ = 0; \ } \ } #define LIST_COPY_EMAIL_BOOL(label, targ) { \ MALLOC_EMAIL(item); \ LIST_COPY_BOOL(label, targ) \ } #define LIST_COPY_CONTACT_BOOL(label, targ) { \ MALLOC_CONTACT(item); \ LIST_COPY_BOOL(label, targ) \ } #define LIST_COPY_APPT_BOOL(label, targ) { \ MALLOC_APPOINTMENT(item); \ LIST_COPY_BOOL(label, targ) \ } #define LIST_COPY_INT16_N(targ) { \ if (list->elements[x]->type != 0x02) { \ DEBUG_WARN(("src not 0x02 for int16 dst\n")); \ DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); \ } \ memcpy(&(targ), list->elements[x]->data, sizeof(targ)); \ LE16_CPU(targ); \ } #define LIST_COPY_INT16(label, targ) { \ LIST_COPY_INT16_N(targ); \ DEBUG_INFO((label" - %i %#x\n", (int)targ, (int)targ)); \ } #define LIST_COPY_INT32_N(targ) { \ if (list->elements[x]->type != 0x03) { \ DEBUG_WARN(("src not 0x03 for int32 dst\n")); \ DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); \ } \ memcpy(&(targ), list->elements[x]->data, sizeof(targ)); \ LE32_CPU(targ); \ } #define LIST_COPY_INT32(label, targ) { \ LIST_COPY_INT32_N(targ); \ DEBUG_INFO((label" - %i %#x\n", (int)targ, (int)targ)); \ } #define LIST_COPY_EMAIL_INT32(label, targ) { \ MALLOC_EMAIL(item); \ LIST_COPY_INT32(label, targ); \ } #define LIST_COPY_APPT_INT32(label, targ) { \ MALLOC_APPOINTMENT(item); \ LIST_COPY_INT32(label, targ); \ } #define LIST_COPY_FOLDER_INT32(label, targ) { \ MALLOC_FOLDER(item); \ LIST_COPY_INT32(label, targ); \ } #define LIST_COPY_STORE_INT32(label, targ) { \ MALLOC_MESSAGESTORE(item); \ LIST_COPY_INT32(label, targ); \ } #define LIST_COPY_ENUM(label, targ, delta, count, ...) { \ char *tlabels[] = {__VA_ARGS__}; \ LIST_COPY_INT32_N(targ); \ targ += delta; \ DEBUG_INFO((label" - %s [%i]\n", \ (((int)targ < 0) || ((int)targ >= count)) \ ? "**invalid" \ : tlabels[(int)targ], (int)targ)); \ } #define LIST_COPY_EMAIL_ENUM(label, targ, delta, count, ...) { \ MALLOC_EMAIL(item); \ LIST_COPY_ENUM(label, targ, delta, count, __VA_ARGS__); \ } #define LIST_COPY_APPT_ENUM(label, targ, delta, count, ...) { \ MALLOC_APPOINTMENT(item); \ LIST_COPY_ENUM(label, targ, delta, count, __VA_ARGS__); \ } #define LIST_COPY_ENUM16(label, targ, delta, count, ...) { \ char *tlabels[] = {__VA_ARGS__}; \ LIST_COPY_INT16_N(targ); \ targ += delta; \ DEBUG_INFO((label" - %s [%i]\n", \ (((int)targ < 0) || ((int)targ >= count)) \ ? "**invalid" \ : tlabels[(int)targ], (int)targ)); \ } #define LIST_COPY_CONTACT_ENUM16(label, targ, delta, count, ...) { \ MALLOC_CONTACT(item); \ LIST_COPY_ENUM16(label, targ, delta, count, __VA_ARGS__); \ } #define LIST_COPY_ENTRYID(label, targ) { \ LIST_COPY(targ, (pst_entryid*)); \ LE32_CPU(targ->u1); \ LE32_CPU(targ->id); \ DEBUG_INFO((label" u1=%#x, id=%#x\n", targ->u1, targ->id)); \ } #define LIST_COPY_EMAIL_ENTRYID(label, targ) { \ MALLOC_EMAIL(item); \ LIST_COPY_ENTRYID(label, targ); \ } #define LIST_COPY_STORE_ENTRYID(label, targ) { \ MALLOC_MESSAGESTORE(item); \ LIST_COPY_ENTRYID(label, targ); \ } // malloc space and copy the current item's data null terminated // including the utf8 flag #define LIST_COPY_STR(label, targ) { \ LIST_COPY_CSTR(targ.str); \ targ.is_utf8 = (list->elements[x]->type == 0x1f) ? 1 : 0; \ DEBUG_INFO((label" - unicode %d - %s\n", targ.is_utf8, targ.str)); \ } #define LIST_COPY_EMAIL_STR(label, targ) { \ MALLOC_EMAIL(item); \ LIST_COPY_STR(label, targ); \ } #define LIST_COPY_CONTACT_STR(label, targ) { \ MALLOC_CONTACT(item); \ LIST_COPY_STR(label, targ); \ } #define LIST_COPY_APPT_STR(label, targ) { \ MALLOC_APPOINTMENT(item); \ LIST_COPY_STR(label, targ); \ } #define LIST_COPY_JOURNAL_STR(label, targ) { \ MALLOC_JOURNAL(item); \ LIST_COPY_STR(label, targ); \ } // malloc space and copy the item filetime #define LIST_COPY_TIME(label, targ) { \ if ((list->elements[x]->type != 0x40) || \ (list->elements[x]->size != sizeof(FILETIME))) { \ DEBUG_WARN(("src not 0x40 or wrong length for filetime dst\n")); \ DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); \ } \ else { \ targ = (FILETIME*) pst_realloc(targ, sizeof(FILETIME)); \ memcpy(targ, list->elements[x]->data, sizeof(FILETIME)); \ LE32_CPU(targ->dwLowDateTime); \ LE32_CPU(targ->dwHighDateTime); \ DEBUG_INFO((label" - %s", pst_fileTimeToAscii(targ, time_buffer))); \ } \ } #define LIST_COPY_EMAIL_TIME(label, targ) { \ MALLOC_EMAIL(item); \ LIST_COPY_TIME(label, targ); \ } #define LIST_COPY_CONTACT_TIME(label, targ) { \ MALLOC_CONTACT(item); \ LIST_COPY_TIME(label, targ); \ } #define LIST_COPY_APPT_TIME(label, targ) { \ MALLOC_APPOINTMENT(item); \ LIST_COPY_TIME(label, targ); \ } #define LIST_COPY_JOURNAL_TIME(label, targ) { \ MALLOC_JOURNAL(item); \ LIST_COPY_TIME(label, targ); \ } // malloc space and copy the current item's data and size #define LIST_COPY_BIN(targ) { \ targ.size = list->elements[x]->size; \ if (targ.size) { \ targ.data = (char*)pst_realloc(targ.data, targ.size); \ memcpy(targ.data, list->elements[x]->data, targ.size); \ } \ else { \ SAFE_FREE_BIN(targ); \ targ.data = NULL; \ } \ } #define LIST_COPY_EMAIL_BIN(label, targ) { \ MALLOC_EMAIL(item); \ LIST_COPY_BIN(targ); \ DEBUG_INFO((label"\n")); \ } #define LIST_COPY_APPT_BIN(label, targ) { \ MALLOC_APPOINTMENT(item); \ LIST_COPY_BIN(targ); \ DEBUG_INFO((label"\n")); \ DEBUG_HEXDUMP(targ.data, targ.size); \ } #define NULL_CHECK(x) { if (!x) { DEBUG_WARN(("NULL_CHECK: Null Found\n")); break;} } /** * process the list of MAPI objects produced from parse_block() * * @param block_id block number used by parse_block() to produce these MAPI objects * @param list pointer to the list of MAPI objects from parse_block() * @param item pointer to the high level item to be updated from the list. * this item may be an email, contact or other sort of item. * the type of this item is generally set by the MAPI elements * from the list. * @param attach pointer to the list of attachment records. If * this is non-null, the length of the this attachment list * must be at least as large as the length of the MAPI objects list. * * @return 0 for ok, -1 for error. */ static int pst_process(uint64_t block_id, pst_mapi_object *list, pst_item *item, pst_item_attach *attach) { DEBUG_ENT("pst_process"); if (!item) { DEBUG_WARN(("item cannot be NULL.\n")); DEBUG_RET(); return -1; } item->block_id = block_id; while (list) { int32_t x; char time_buffer[30]; for (x=0; xcount_elements; x++) { int32_t t; uint32_t ut; DEBUG_INFO(("#%d - mapi-id: %#x type: %#x length: %#x\n", x, list->elements[x]->mapi_id, list->elements[x]->type, list->elements[x]->size)); switch (list->elements[x]->mapi_id) { case PST_ATTRIB_HEADER: // CUSTOM attribute for saying the Extra Headers if (list->elements[x]->extra) { if (list->elements[x]->type == 0x0101e) { // an array of strings, rather than a single string int32_t string_length, i, offset, next_offset; int32_t p = 0; int32_t array_element_count = PST_LE_GET_INT32(list->elements[x]->data); p+=4; for (i = 1; i <= array_element_count; i++) { pst_item_extra_field *ef = (pst_item_extra_field*) pst_malloc(sizeof(pst_item_extra_field)); memset(ef, 0, sizeof(pst_item_extra_field)); offset = PST_LE_GET_INT32(list->elements[x]->data + p); p+=4; next_offset = (i == array_element_count) ? list->elements[x]->size : PST_LE_GET_INT32(list->elements[x]->data + p);; string_length = next_offset - offset; ef->value = pst_malloc(string_length + 1); memcpy(ef->value, list->elements[x]->data + offset, string_length); ef->value[string_length] = '\0'; ef->field_name = strdup(list->elements[x]->extra); ef->next = item->extra_fields; item->extra_fields = ef; DEBUG_INFO(("Extra Field - \"%s\" = \"%s\"\n", ef->field_name, ef->value)); } } else { // should be a single string pst_item_extra_field *ef = (pst_item_extra_field*) pst_malloc(sizeof(pst_item_extra_field)); memset(ef, 0, sizeof(pst_item_extra_field)); LIST_COPY_CSTR(ef->value); if (ef->value) { ef->field_name = strdup(list->elements[x]->extra); ef->next = item->extra_fields; item->extra_fields = ef; DEBUG_INFO(("Extra Field - \"%s\" = \"%s\"\n", ef->field_name, ef->value)); if (strcmp(ef->field_name, "content-type") == 0) { char *p = strstr(ef->value, "charset=\""); if (p) { p += 9; // skip over charset=" char *pp = strchr(p, '"'); if (pp) { *pp = '\0'; char *set = strdup(p); *pp = '"'; if (item->body_charset.str) free(item->body_charset.str); item->body_charset.str = set; item->body_charset.is_utf8 = 1; DEBUG_INFO(("body charset %s from content-type extra field\n", set)); } } } } else { DEBUG_WARN(("What does this mean? Internet header %s value\n", list->elements[x]->extra)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); free(ef); // caught by valgrind } } } break; case 0x0002: // PR_ALTERNATE_RECIPIENT_ALLOWED if (list->elements[x]->type == 0x0b) { // If set to true, the sender allows this email to be autoforwarded LIST_COPY_EMAIL_BOOL("AutoForward allowed", item->email->autoforward); if (!item->email->autoforward) item->email->autoforward = -1; } else { DEBUG_WARN(("What does this mean?\n")); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } break; case 0x0003: // Extended Attributes table DEBUG_INFO(("Extended Attributes Table - NOT PROCESSED\n")); break; case 0x0017: // PR_IMPORTANCE - How important the sender deems it to be LIST_COPY_EMAIL_ENUM("Importance Level", item->email->importance, 0, 3, "Low", "Normal", "High"); break; case 0x001A: // PR_MESSAGE_CLASS IPM.x if ((list->elements[x]->type == 0x1e) || (list->elements[x]->type == 0x1f)) { LIST_COPY_CSTR(item->ascii_type); if (!item->ascii_type) item->ascii_type = strdup("unknown"); if (pst_strincmp("IPM.Note", item->ascii_type, 8) == 0) item->type = PST_TYPE_NOTE; else if (pst_stricmp("IPM", item->ascii_type) == 0) item->type = PST_TYPE_NOTE; else if (pst_strincmp("IPM.Contact", item->ascii_type, 11) == 0) item->type = PST_TYPE_CONTACT; else if (pst_strincmp("REPORT.IPM.Note", item->ascii_type, 15) == 0) item->type = PST_TYPE_REPORT; else if (pst_strincmp("IPM.Activity", item->ascii_type, 12) == 0) item->type = PST_TYPE_JOURNAL; else if (pst_strincmp("IPM.Appointment", item->ascii_type, 15) == 0) item->type = PST_TYPE_APPOINTMENT; else if (pst_strincmp("IPM.Schedule.Meeting", item->ascii_type, 20) == 0) item->type = PST_TYPE_SCHEDULE; // meeting requests and responses transported over email else if (pst_strincmp("IPM.StickyNote", item->ascii_type, 14) == 0) item->type = PST_TYPE_STICKYNOTE; else if (pst_strincmp("IPM.Task", item->ascii_type, 8) == 0) item->type = PST_TYPE_TASK; else item->type = PST_TYPE_OTHER; DEBUG_INFO(("Message class %s [%"PRIi32"] \n", item->ascii_type, item->type)); } else { DEBUG_WARN(("What does this mean?\n")); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } break; case 0x0023: // PR_ORIGINATOR_DELIVERY_REPORT_REQUESTED if (list->elements[x]->type == 0x0b) { // set if the sender wants a delivery report from all recipients LIST_COPY_EMAIL_BOOL("Global Delivery Report", item->email->delivery_report); } else { DEBUG_WARN(("What does this mean?\n")); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } break; case 0x0026: // PR_PRIORITY LIST_COPY_EMAIL_ENUM("Priority", item->email->priority, 1, 3, "NonUrgent", "Normal", "Urgent"); break; case 0x0029: // PR_READ_RECEIPT_REQUESTED LIST_COPY_EMAIL_BOOL("Read Receipt", item->email->read_receipt); break; case 0x002B: // PR_RECIPIENT_REASSIGNMENT_PROHIBITED LIST_COPY_BOOL("Reassignment Prohibited (Private)", item->private_member); break; case 0x002E: // PR_ORIGINAL_SENSITIVITY - the sensitivity of the message before being replied to or forwarded LIST_COPY_EMAIL_ENUM("Original Sensitivity", item->email->original_sensitivity, 0, 4, "None", "Personal", "Private", "Company Confidential"); break; case 0x0032: // PR_REPORT_TIME LIST_COPY_EMAIL_TIME("Report time", item->email->report_time); break; case 0x0036: // PR_SENSITIVITY - sender's opinion of the sensitivity of an email LIST_COPY_EMAIL_ENUM("Sensitivity", item->email->sensitivity, 0, 4, "None", "Personal", "Private", "Company Confidential"); break; case 0x0037: // PR_SUBJECT raw subject { int off = 0; if ((list->elements[x]->size > 2) && (((uint8_t)list->elements[x]->data[0]) < 0x20)) { off = 2; } list->elements[x]->data += off; list->elements[x]->size -= off; LIST_COPY_STR("Raw Subject", item->subject); list->elements[x]->size += off; list->elements[x]->data -= off; } break; case 0x0039: // PR_CLIENT_SUBMIT_TIME Date Email Sent/Created LIST_COPY_EMAIL_TIME("Date sent", item->email->sent_date); break; case 0x003B: // PR_SENT_REPRESENTING_SEARCH_KEY Sender address 1 LIST_COPY_EMAIL_STR("Sent on behalf of address 1", item->email->outlook_sender); break; case 0x003F: // PR_RECEIVED_BY_ENTRYID Structure containing Recipient DEBUG_INFO(("Recipient Structure 1 -- NOT PROCESSED\n")); break; case 0x0040: // PR_RECEIVED_BY_NAME Name of Recipient Structure LIST_COPY_EMAIL_STR("Received By Name 1", item->email->outlook_received_name1); break; case 0x0041: // PR_SENT_REPRESENTING_ENTRYID Structure containing Sender DEBUG_INFO(("Sent on behalf of Structure 1 -- NOT PROCESSED\n")); break; case 0x0042: // PR_SENT_REPRESENTING_NAME LIST_COPY_EMAIL_STR("Sent on behalf of", item->email->outlook_sender_name); break; case 0x0043: // PR_RCVD_REPRESENTING_ENTRYID Recipient Structure 2 DEBUG_INFO(("Received on behalf of Structure -- NOT PROCESSED\n")); break; case 0x0044: // PR_RCVD_REPRESENTING_NAME LIST_COPY_EMAIL_STR("Received on behalf of", item->email->outlook_recipient_name); break; case 0x004F: // PR_REPLY_RECIPIENT_ENTRIES Reply-To Structure DEBUG_INFO(("Reply-To Structure -- NOT PROCESSED\n")); break; case 0x0050: // PR_REPLY_RECIPIENT_NAMES Name of Reply-To Structure LIST_COPY_EMAIL_STR("Reply-To", item->email->reply_to); break; case 0x0051: // PR_RECEIVED_BY_SEARCH_KEY Recipient Address 1 LIST_COPY_EMAIL_STR("Recipient's Address 1", item->email->outlook_recipient); break; case 0x0052: // PR_RCVD_REPRESENTING_SEARCH_KEY Recipient Address 2 LIST_COPY_EMAIL_STR("Recipient's Address 2", item->email->outlook_recipient2); break; case 0x0057: // PR_MESSAGE_TO_ME // this user is listed explicitly in the TO address LIST_COPY_EMAIL_BOOL("My address in TO field", item->email->message_to_me); break; case 0x0058: // PR_MESSAGE_CC_ME // this user is listed explicitly in the CC address LIST_COPY_EMAIL_BOOL("My address in CC field", item->email->message_cc_me); break; case 0x0059: // PR_MESSAGE_RECIP_ME // this user appears in TO, CC or BCC address list LIST_COPY_EMAIL_BOOL("Message addressed to me", item->email->message_recip_me); break; case 0x0063: // PR_RESPONSE_REQUESTED LIST_COPY_BOOL("Response requested", item->response_requested); break; case 0x0064: // PR_SENT_REPRESENTING_ADDRTYPE Access method for Sender Address LIST_COPY_EMAIL_STR("Sent on behalf of address type", item->email->sender_access); break; case 0x0065: // PR_SENT_REPRESENTING_EMAIL_ADDRESS Sender Address LIST_COPY_EMAIL_STR("Sent on behalf of address", item->email->sender_address); break; case 0x0070: // PR_CONVERSATION_TOPIC Processed Subject LIST_COPY_EMAIL_STR("Processed Subject (Conversation Topic)", item->email->processed_subject); break; case 0x0071: // PR_CONVERSATION_INDEX LIST_COPY_EMAIL_BIN("Conversation Index", item->email->conversation_index); break; case 0x0072: // PR_ORIGINAL_DISPLAY_BCC LIST_COPY_EMAIL_STR("Original display bcc", item->email->original_bcc); break; case 0x0073: // PR_ORIGINAL_DISPLAY_CC LIST_COPY_EMAIL_STR("Original display cc", item->email->original_cc); break; case 0x0074: // PR_ORIGINAL_DISPLAY_TO LIST_COPY_EMAIL_STR("Original display to", item->email->original_to); break; case 0x0075: // PR_RECEIVED_BY_ADDRTYPE Recipient Access Method LIST_COPY_EMAIL_STR("Received by Address type", item->email->recip_access); break; case 0x0076: // PR_RECEIVED_BY_EMAIL_ADDRESS Recipient Address LIST_COPY_EMAIL_STR("Received by Address", item->email->recip_address); break; case 0x0077: // PR_RCVD_REPRESENTING_ADDRTYPE Recipient Access Method 2 LIST_COPY_EMAIL_STR("Received on behalf of Address type", item->email->recip2_access); break; case 0x0078: // PR_RCVD_REPRESENTING_EMAIL_ADDRESS Recipient Address 2 LIST_COPY_EMAIL_STR("Received on behalf of Address", item->email->recip2_address); break; case 0x007D: // PR_TRANSPORT_MESSAGE_HEADERS Internet Header LIST_COPY_EMAIL_STR("Internet Header", item->email->header); break; case 0x0C04: // PR_NDR_REASON_CODE LIST_COPY_EMAIL_INT32("NDR reason code", item->email->ndr_reason_code); break; case 0x0C05: // PR_NDR_DIAG_CODE LIST_COPY_EMAIL_INT32("NDR diag code", item->email->ndr_diag_code); break; case 0x0C06: // PR_NON_RECEIPT_NOTIFICATION_REQUESTED DEBUG_INFO(("Non-Receipt Notification Requested -- NOT PROCESSED\n")); break; case 0x0C17: // PR_REPLY_REQUESTED LIST_COPY_EMAIL_BOOL("Reply Requested", item->email->reply_requested); break; case 0x0C19: // PR_SENDER_ENTRYID Sender Structure 2 DEBUG_INFO(("Sender Structure 2 -- NOT PROCESSED\n")); break; case 0x0C1A: // PR_SENDER_NAME Name of Sender Structure 2 LIST_COPY_EMAIL_STR("Name of Sender Structure 2", item->email->outlook_sender_name2); break; case 0x0C1B: // PR_SUPPLEMENTARY_INFO LIST_COPY_EMAIL_STR("Supplementary info", item->email->supplementary_info); break; case 0x0C1D: // PR_SENDER_SEARCH_KEY Name of Sender Address 2 LIST_COPY_EMAIL_STR("Name of Sender Address 2 (Sender search key)", item->email->outlook_sender2); break; case 0x0C1E: // PR_SENDER_ADDRTYPE Sender Address 2 access method LIST_COPY_EMAIL_STR("Sender Address type", item->email->sender2_access); break; case 0x0C1F: // PR_SENDER_EMAIL_ADDRESS Sender Address 2 LIST_COPY_EMAIL_STR("Sender Address", item->email->sender2_address); break; case 0x0C20: // PR_NDR_STATUS_CODE LIST_COPY_EMAIL_INT32("NDR status code", item->email->ndr_status_code); break; case 0x0E01: // PR_DELETE_AFTER_SUBMIT LIST_COPY_EMAIL_BOOL("Delete after submit", item->email->delete_after_submit); break; case 0x0E02: // PR_DISPLAY_BCC BCC Addresses LIST_COPY_EMAIL_STR("Display BCC Addresses", item->email->bcc_address); break; case 0x0E03: // PR_DISPLAY_CC CC Addresses LIST_COPY_EMAIL_STR("Display CC Addresses", item->email->cc_address); break; case 0x0E04: // PR_DISPLAY_TO Address Sent-To LIST_COPY_EMAIL_STR("Display Sent-To Address", item->email->sentto_address); break; case 0x0E06: // PR_MESSAGE_DELIVERY_TIME Date 3 - Email Arrival Date LIST_COPY_EMAIL_TIME("Date 3 (Delivery Time)", item->email->arrival_date); break; case 0x0E07: // PR_MESSAGE_FLAGS Email Flag LIST_COPY_EMAIL_INT32("Message Flags", item->flags); break; case 0x0E08: // PR_MESSAGE_SIZE Total size of a message object LIST_COPY_INT32("Message Size", item->message_size); break; case 0x0E0A: // PR_SENTMAIL_ENTRYID // folder that this message is sent to after submission LIST_COPY_EMAIL_ENTRYID("Sentmail EntryID", item->email->sentmail_folder); break; case 0x0E1D: // PR_NORMALIZED_SUBJECT LIST_COPY_EMAIL_STR("Normalized subject", item->email->outlook_normalized_subject); break; case 0x0E1F: // PR_RTF_IN_SYNC // True means that the rtf version is same as text body // False means rtf version is more up-to-date than text body // if this value doesn't exist, text body is more up-to-date than rtf and // cannot update to the rtf LIST_COPY_EMAIL_BOOL("Compressed RTF in Sync", item->email->rtf_in_sync); break; case 0x0E20: // PR_ATTACH_SIZE binary Attachment data in record NULL_CHECK(attach); LIST_COPY_INT32("Attachment Size", t); // ignore this. we either get data and size from 0x3701 // or id codes from 0x3701 or 0x67f2 break; case 0x0FF9: // PR_RECORD_KEY Record Header 1 LIST_COPY_BIN(item->record_key); DEBUG_INFO(("Record Key\n")); DEBUG_HEXDUMP(item->record_key.data, item->record_key.size); break; case 0x1000: // PR_BODY LIST_COPY_STR("Plain Text body", item->body); break; case 0x1001: // PR_REPORT_TEXT LIST_COPY_EMAIL_STR("Report Text", item->email->report_text); break; case 0x1006: // PR_RTF_SYNC_BODY_CRC LIST_COPY_EMAIL_INT32("RTF Sync Body CRC", item->email->rtf_body_crc); break; case 0x1007: // PR_RTF_SYNC_BODY_COUNT // a count of the *significant* characters in the rtf body. Doesn't count // whitespace and other ignorable characters LIST_COPY_EMAIL_INT32("RTF Sync Body character count", item->email->rtf_body_char_count); break; case 0x1008: // PR_RTF_SYNC_BODY_TAG // the first couple of lines of RTF body so that after modification, then beginning can // once again be found LIST_COPY_EMAIL_STR("RTF Sync body tag", item->email->rtf_body_tag); break; case 0x1009: // PR_RTF_COMPRESSED - rtf data is lzw compressed LIST_COPY_EMAIL_BIN("RTF Compressed body", item->email->rtf_compressed); break; case 0x1010: // PR_RTF_SYNC_PREFIX_COUNT // a count of the ignored characters before the first significant character LIST_COPY_EMAIL_INT32("RTF whitespace prefix count", item->email->rtf_ws_prefix_count); break; case 0x1011: // PR_RTF_SYNC_TRAILING_COUNT // a count of the ignored characters after the last significant character LIST_COPY_EMAIL_INT32("RTF whitespace tailing count", item->email->rtf_ws_trailing_count); break; case 0x1013: // HTML body LIST_COPY_EMAIL_STR("HTML body", item->email->htmlbody); break; case 0x1035: // Message ID LIST_COPY_EMAIL_STR("Message ID", item->email->messageid); break; case 0x1042: // in-reply-to LIST_COPY_EMAIL_STR("In-Reply-To", item->email->in_reply_to); break; case 0x1046: // Return Path - this seems to be the message-id of the rfc822 mail that is being returned LIST_COPY_EMAIL_STR("Return Path", item->email->return_path_address); break; case 0x3001: // PR_DISPLAY_NAME File As LIST_COPY_STR("Display Name", item->file_as); break; case 0x3002: // PR_ADDRTYPE LIST_COPY_CONTACT_STR("Address Type", item->contact->address1_transport); break; case 0x3003: // PR_EMAIL_ADDRESS LIST_COPY_CONTACT_STR("Contact email Address", item->contact->address1); break; case 0x3004: // PR_COMMENT Comment for item - usually folders LIST_COPY_STR("Comment", item->comment); break; case 0x3007: // PR_CREATION_TIME Date 4 - Creation Date? LIST_COPY_TIME("Date 4 (Item Creation Date)", item->create_date); break; case 0x3008: // PR_LAST_MODIFICATION_TIME Date 5 - Modify Date LIST_COPY_TIME("Date 5 (Modify Date)", item->modify_date); break; case 0x300B: // PR_SEARCH_KEY Record Header 2 LIST_COPY_EMAIL_STR("Record Search 2", item->email->outlook_search_key); break; case 0x35DF: // PR_VALID_FOLDER_MASK LIST_COPY_STORE_INT32("Valid Folder Mask", item->message_store->valid_mask); break; case 0x35E0: // PR_IPM_SUBTREE_ENTRYID Top of Personal Folder Record LIST_COPY_STORE_ENTRYID("Top of Personal Folder Record", item->message_store->top_of_personal_folder); break; case 0x35E2: // PR_IPM_OUTBOX_ENTRYID LIST_COPY_STORE_ENTRYID("Default Outbox Folder record", item->message_store->default_outbox_folder); break; case 0x35E3: // PR_IPM_WASTEBASKET_ENTRYID LIST_COPY_STORE_ENTRYID("Deleted Items Folder record", item->message_store->deleted_items_folder); break; case 0x35E4: // PR_IPM_SENTMAIL_ENTRYID LIST_COPY_STORE_ENTRYID("Sent Items Folder record", item->message_store->sent_items_folder); break; case 0x35E5: // PR_VIEWS_ENTRYID LIST_COPY_STORE_ENTRYID("User Views Folder record", item->message_store->user_views_folder); break; case 0x35E6: // PR_COMMON_VIEWS_ENTRYID LIST_COPY_STORE_ENTRYID("Common View Folder record", item->message_store->common_view_folder); break; case 0x35E7: // PR_FINDER_ENTRYID LIST_COPY_STORE_ENTRYID("Search Root Folder record", item->message_store->search_root_folder); break; case 0x3602: // PR_CONTENT_COUNT Number of emails stored in a folder LIST_COPY_FOLDER_INT32("Folder Email Count", item->folder->item_count); break; case 0x3603: // PR_CONTENT_UNREAD Number of unread emails LIST_COPY_FOLDER_INT32("Unread Email Count", item->folder->unseen_item_count); break; case 0x360A: // PR_SUBFOLDERS Has children MALLOC_FOLDER(item); LIST_COPY_BOOL("Has Subfolders", item->folder->subfolder); break; case 0x3613: // PR_CONTAINER_CLASS IPF.x LIST_COPY_CSTR(item->ascii_type); if (pst_strincmp("IPF.Note", item->ascii_type, 8) == 0) item->type = PST_TYPE_NOTE; else if (pst_strincmp("IPF.Imap", item->ascii_type, 8) == 0) item->type = PST_TYPE_NOTE; else if (pst_stricmp("IPF", item->ascii_type) == 0) item->type = PST_TYPE_NOTE; else if (pst_strincmp("IPF.Contact", item->ascii_type, 11) == 0) item->type = PST_TYPE_CONTACT; else if (pst_strincmp("IPF.Journal", item->ascii_type, 11) == 0) item->type = PST_TYPE_JOURNAL; else if (pst_strincmp("IPF.Appointment", item->ascii_type, 15) == 0) item->type = PST_TYPE_APPOINTMENT; else if (pst_strincmp("IPF.StickyNote", item->ascii_type, 14) == 0) item->type = PST_TYPE_STICKYNOTE; else if (pst_strincmp("IPF.Task", item->ascii_type, 8) == 0) item->type = PST_TYPE_TASK; else item->type = PST_TYPE_OTHER; DEBUG_INFO(("Container class %s [%"PRIi32"]\n", item->ascii_type, item->type)); break; case 0x3617: // PR_ASSOC_CONTENT_COUNT // associated content are items that are attached to this folder // but are hidden from users LIST_COPY_FOLDER_INT32("Associated Content count", item->folder->assoc_count); break; case 0x3701: // PR_ATTACH_DATA_OBJ binary data of attachment DEBUG_INFO(("Binary Data [Size %i]\n", list->elements[x]->size)); NULL_CHECK(attach); if (!list->elements[x]->data) { //special case attach->id2_val = list->elements[x]->type; DEBUG_INFO(("Seen a Reference. The data hasn't been loaded yet. [%#"PRIx64"]\n", attach->id2_val)); } else { LIST_COPY_BIN(attach->data); } break; case 0x3704: // PR_ATTACH_FILENAME Attachment filename (8.3) NULL_CHECK(attach); LIST_COPY_STR("Attachment Filename", attach->filename1); break; case 0x3705: // PR_ATTACH_METHOD NULL_CHECK(attach); LIST_COPY_ENUM("Attachment method", attach->method, 0, 7, "No Attachment", "Attach By Value", "Attach By Reference", "Attach by Reference Resolve", "Attach by Reference Only", "Embedded Message", "OLE"); break; case 0x3707: // PR_ATTACH_LONG_FILENAME Attachment filename (long?) NULL_CHECK(attach); LIST_COPY_STR("Attachment Filename long", attach->filename2); break; case 0x370B: // PR_RENDERING_POSITION // position in characters that the attachment appears in the plain text body NULL_CHECK(attach); LIST_COPY_INT32("Attachment Position", attach->position); break; case 0x370E: // PR_ATTACH_MIME_TAG Mime type of encoding NULL_CHECK(attach); LIST_COPY_STR("Attachment mime encoding", attach->mimetype); break; case 0x3710: // PR_ATTACH_MIME_SEQUENCE // sequence number for mime parts. Includes body NULL_CHECK(attach); LIST_COPY_INT32("Attachment Mime Sequence", attach->sequence); break; case 0x3712: // PR_ATTACH_CONTENT_ID // content identification header (Content-ID) NULL_CHECK(attach); LIST_COPY_STR("Content ID", attach->content_id); break; case 0x3A00: // PR_ACCOUNT LIST_COPY_CONTACT_STR("Contact's Account name", item->contact->account_name); break; case 0x3A01: // PR_ALTERNATE_RECIPIENT DEBUG_INFO(("Contact Alternate Recipient - NOT PROCESSED\n")); break; case 0x3A02: // PR_CALLBACK_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Callback telephone number", item->contact->callback_phone); break; case 0x3A03: // PR_CONVERSION_PROHIBITED LIST_COPY_EMAIL_BOOL("Message Conversion Prohibited", item->email->conversion_prohibited); break; case 0x3A05: // PR_GENERATION suffix LIST_COPY_CONTACT_STR("Contacts Suffix", item->contact->suffix); break; case 0x3A06: // PR_GIVEN_NAME Contact's first name LIST_COPY_CONTACT_STR("Contacts First Name", item->contact->first_name); break; case 0x3A07: // PR_GOVERNMENT_ID_NUMBER LIST_COPY_CONTACT_STR("Contacts Government ID Number", item->contact->gov_id); break; case 0x3A08: // PR_BUSINESS_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Business Telephone Number", item->contact->business_phone); break; case 0x3A09: // PR_HOME_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Home Telephone Number", item->contact->home_phone); break; case 0x3A0A: // PR_INITIALS Contact's Initials LIST_COPY_CONTACT_STR("Contacts Initials", item->contact->initials); break; case 0x3A0B: // PR_KEYWORD LIST_COPY_CONTACT_STR("Keyword", item->contact->keyword); break; case 0x3A0C: // PR_LANGUAGE LIST_COPY_CONTACT_STR("Contact's Language", item->contact->language); break; case 0x3A0D: // PR_LOCATION LIST_COPY_CONTACT_STR("Contact's Location", item->contact->location); break; case 0x3A0E: // PR_MAIL_PERMISSION - Can the recipient receive and send email LIST_COPY_CONTACT_BOOL("Mail Permission", item->contact->mail_permission); break; case 0x3A0F: // PR_MHS_COMMON_NAME LIST_COPY_CONTACT_STR("MHS Common Name", item->contact->common_name); break; case 0x3A10: // PR_ORGANIZATIONAL_ID_NUMBER LIST_COPY_CONTACT_STR("Organizational ID #", item->contact->org_id); break; case 0x3A11: // PR_SURNAME Contact's Surname LIST_COPY_CONTACT_STR("Contacts Surname", item->contact->surname); break; case 0x3A12: // PR_ORIGINAL_ENTRY_ID DEBUG_INFO(("Original Entry ID - NOT PROCESSED\n")); break; case 0x3A13: // PR_ORIGINAL_DISPLAY_NAME DEBUG_INFO(("Original Display Name - NOT PROCESSED\n")); break; case 0x3A14: // PR_ORIGINAL_SEARCH_KEY DEBUG_INFO(("Original Search Key - NOT PROCESSED\n")); break; case 0x3A15: // PR_POSTAL_ADDRESS LIST_COPY_CONTACT_STR("Default Postal Address", item->contact->def_postal_address); break; case 0x3A16: // PR_COMPANY_NAME LIST_COPY_CONTACT_STR("Company Name", item->contact->company_name); break; case 0x3A17: // PR_TITLE - Job Title LIST_COPY_CONTACT_STR("Job Title", item->contact->job_title); break; case 0x3A18: // PR_DEPARTMENT_NAME LIST_COPY_CONTACT_STR("Department Name", item->contact->department); break; case 0x3A19: // PR_OFFICE_LOCATION LIST_COPY_CONTACT_STR("Office Location", item->contact->office_loc); break; case 0x3A1A: // PR_PRIMARY_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Primary Telephone", item->contact->primary_phone); break; case 0x3A1B: // PR_BUSINESS2_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Business Phone Number 2", item->contact->business_phone2); break; case 0x3A1C: // PR_MOBILE_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Mobile Phone Number", item->contact->mobile_phone); break; case 0x3A1D: // PR_RADIO_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Radio Phone Number", item->contact->radio_phone); break; case 0x3A1E: // PR_CAR_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Car Phone Number", item->contact->car_phone); break; case 0x3A1F: // PR_OTHER_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Other Phone Number", item->contact->other_phone); break; case 0x3A20: // PR_TRANSMITTABLE_DISPLAY_NAME LIST_COPY_CONTACT_STR("Transmittable Display Name", item->contact->transmittable_display_name); break; case 0x3A21: // PR_PAGER_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Pager Phone Number", item->contact->pager_phone); break; case 0x3A22: // PR_USER_CERTIFICATE DEBUG_INFO(("User Certificate - NOT PROCESSED\n")); break; case 0x3A23: // PR_PRIMARY_FAX_NUMBER LIST_COPY_CONTACT_STR("Primary Fax Number", item->contact->primary_fax); break; case 0x3A24: // PR_BUSINESS_FAX_NUMBER LIST_COPY_CONTACT_STR("Business Fax Number", item->contact->business_fax); break; case 0x3A25: // PR_HOME_FAX_NUMBER LIST_COPY_CONTACT_STR("Home Fax Number", item->contact->home_fax); break; case 0x3A26: // PR_BUSINESS_ADDRESS_COUNTRY LIST_COPY_CONTACT_STR("Business Address Country", item->contact->business_country); break; case 0x3A27: // PR_BUSINESS_ADDRESS_CITY LIST_COPY_CONTACT_STR("Business Address City", item->contact->business_city); break; case 0x3A28: // PR_BUSINESS_ADDRESS_STATE_OR_PROVINCE LIST_COPY_CONTACT_STR("Business Address State", item->contact->business_state); break; case 0x3A29: // PR_BUSINESS_ADDRESS_STREET LIST_COPY_CONTACT_STR("Business Address Street", item->contact->business_street); break; case 0x3A2A: // PR_BUSINESS_POSTAL_CODE LIST_COPY_CONTACT_STR("Business Postal Code", item->contact->business_postal_code); break; case 0x3A2B: // PR_BUSINESS_PO_BOX LIST_COPY_CONTACT_STR("Business PO Box", item->contact->business_po_box); break; case 0x3A2C: // PR_TELEX_NUMBER LIST_COPY_CONTACT_STR("Telex Number", item->contact->telex); break; case 0x3A2D: // PR_ISDN_NUMBER LIST_COPY_CONTACT_STR("ISDN Number", item->contact->isdn_phone); break; case 0x3A2E: // PR_ASSISTANT_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Assistant Phone Number", item->contact->assistant_phone); break; case 0x3A2F: // PR_HOME2_TELEPHONE_NUMBER LIST_COPY_CONTACT_STR("Home Phone 2", item->contact->home_phone2); break; case 0x3A30: // PR_ASSISTANT LIST_COPY_CONTACT_STR("Assistant's Name", item->contact->assistant_name); break; case 0x3A40: // PR_SEND_RICH_INFO LIST_COPY_CONTACT_BOOL("Can receive Rich Text", item->contact->rich_text); break; case 0x3A41: // PR_WEDDING_ANNIVERSARY LIST_COPY_CONTACT_TIME("Wedding Anniversary", item->contact->wedding_anniversary); break; case 0x3A42: // PR_BIRTHDAY LIST_COPY_CONTACT_TIME("Birthday", item->contact->birthday); break; case 0x3A43: // PR_HOBBIES LIST_COPY_CONTACT_STR("Hobbies", item->contact->hobbies); break; case 0x3A44: // PR_MIDDLE_NAME LIST_COPY_CONTACT_STR("Middle Name", item->contact->middle_name); break; case 0x3A45: // PR_DISPLAY_NAME_PREFIX LIST_COPY_CONTACT_STR("Display Name Prefix (Title)", item->contact->display_name_prefix); break; case 0x3A46: // PR_PROFESSION LIST_COPY_CONTACT_STR("Profession", item->contact->profession); break; case 0x3A47: // PR_PREFERRED_BY_NAME LIST_COPY_CONTACT_STR("Preferred By Name", item->contact->pref_name); break; case 0x3A48: // PR_SPOUSE_NAME LIST_COPY_CONTACT_STR("Spouse's Name", item->contact->spouse_name); break; case 0x3A49: // PR_COMPUTER_NETWORK_NAME LIST_COPY_CONTACT_STR("Computer Network Name", item->contact->computer_name); break; case 0x3A4A: // PR_CUSTOMER_ID LIST_COPY_CONTACT_STR("Customer ID", item->contact->customer_id); break; case 0x3A4B: // PR_TTYTDD_PHONE_NUMBER LIST_COPY_CONTACT_STR("TTY/TDD Phone", item->contact->ttytdd_phone); break; case 0x3A4C: // PR_FTP_SITE LIST_COPY_CONTACT_STR("Ftp Site", item->contact->ftp_site); break; case 0x3A4D: // PR_GENDER LIST_COPY_CONTACT_ENUM16("Gender", item->contact->gender, 0, 3, "Unspecified", "Female", "Male"); break; case 0x3A4E: // PR_MANAGER_NAME LIST_COPY_CONTACT_STR("Manager's Name", item->contact->manager_name); break; case 0x3A4F: // PR_NICKNAME LIST_COPY_CONTACT_STR("Nickname", item->contact->nickname); break; case 0x3A50: // PR_PERSONAL_HOME_PAGE LIST_COPY_CONTACT_STR("Personal Home Page", item->contact->personal_homepage); break; case 0x3A51: // PR_BUSINESS_HOME_PAGE LIST_COPY_CONTACT_STR("Business Home Page", item->contact->business_homepage); break; case 0x3A57: // PR_COMPANY_MAIN_PHONE_NUMBER LIST_COPY_CONTACT_STR("Company Main Phone", item->contact->company_main_phone); break; case 0x3A58: // PR_CHILDRENS_NAMES DEBUG_INFO(("Children's Names - NOT PROCESSED\n")); break; case 0x3A59: // PR_HOME_ADDRESS_CITY LIST_COPY_CONTACT_STR("Home Address City", item->contact->home_city); break; case 0x3A5A: // PR_HOME_ADDRESS_COUNTRY LIST_COPY_CONTACT_STR("Home Address Country", item->contact->home_country); break; case 0x3A5B: // PR_HOME_ADDRESS_POSTAL_CODE LIST_COPY_CONTACT_STR("Home Address Postal Code", item->contact->home_postal_code); break; case 0x3A5C: // PR_HOME_ADDRESS_STATE_OR_PROVINCE LIST_COPY_CONTACT_STR("Home Address State or Province", item->contact->home_state); break; case 0x3A5D: // PR_HOME_ADDRESS_STREET LIST_COPY_CONTACT_STR("Home Address Street", item->contact->home_street); break; case 0x3A5E: // PR_HOME_ADDRESS_POST_OFFICE_BOX LIST_COPY_CONTACT_STR("Home Address Post Office Box", item->contact->home_po_box); break; case 0x3A5F: // PR_OTHER_ADDRESS_CITY LIST_COPY_CONTACT_STR("Other Address City", item->contact->other_city); break; case 0x3A60: // PR_OTHER_ADDRESS_COUNTRY LIST_COPY_CONTACT_STR("Other Address Country", item->contact->other_country); break; case 0x3A61: // PR_OTHER_ADDRESS_POSTAL_CODE LIST_COPY_CONTACT_STR("Other Address Postal Code", item->contact->other_postal_code); break; case 0x3A62: // PR_OTHER_ADDRESS_STATE_OR_PROVINCE LIST_COPY_CONTACT_STR("Other Address State", item->contact->other_state); break; case 0x3A63: // PR_OTHER_ADDRESS_STREET LIST_COPY_CONTACT_STR("Other Address Street", item->contact->other_street); break; case 0x3A64: // PR_OTHER_ADDRESS_POST_OFFICE_BOX LIST_COPY_CONTACT_STR("Other Address Post Office box", item->contact->other_po_box); break; case 0x3FDE: // PR_INTERNET_CPID LIST_COPY_INT32("Internet code page", item->internet_cpid); break; case 0x3FFD: // PR_MESSAGE_CODEPAGE LIST_COPY_INT32("Message code page", item->message_codepage); break; case 0x65E3: // PR_PREDECESSOR_CHANGE_LIST LIST_COPY_BIN(item->predecessor_change); DEBUG_INFO(("Predecessor Change\n")); DEBUG_HEXDUMP(item->predecessor_change.data, item->predecessor_change.size); break; case 0x67F2: // ID2 value of the attachment NULL_CHECK(attach); LIST_COPY_INT32("Attachment ID2 value", ut); attach->id2_val = ut; break; case 0x67FF: // Extra Property Identifier (Password CheckSum) LIST_COPY_STORE_INT32("Password checksum", item->message_store->pwd_chksum); break; case 0x6F02: // Secure HTML Body LIST_COPY_EMAIL_BIN("Secure HTML Body", item->email->encrypted_htmlbody); break; case 0x6F04: // Secure Text Body LIST_COPY_EMAIL_BIN("Secure Text Body", item->email->encrypted_body); break; case 0x7C07: // top of folders ENTRYID LIST_COPY_STORE_ENTRYID("Top of folders RecID", item->message_store->top_of_folder); break; case 0x8005: // Contact's Fullname LIST_COPY_CONTACT_STR("Contact Fullname", item->contact->fullname); break; case 0x801A: // Full Home Address LIST_COPY_CONTACT_STR("Home Address", item->contact->home_address); break; case 0x801B: // Full Business Address LIST_COPY_CONTACT_STR("Business Address", item->contact->business_address); break; case 0x801C: // Full Other Address LIST_COPY_CONTACT_STR("Other Address", item->contact->other_address); break; case 0x8045: // Work address street LIST_COPY_CONTACT_STR("Work address street", item->contact->work_address_street); break; case 0x8046: // Work address city LIST_COPY_CONTACT_STR("Work address city", item->contact->work_address_city); break; case 0x8047: // Work address state LIST_COPY_CONTACT_STR("Work address state", item->contact->work_address_state); break; case 0x8048: // Work address postalcode LIST_COPY_CONTACT_STR("Work address postalcode", item->contact->work_address_postalcode); break; case 0x8049: // Work address country LIST_COPY_CONTACT_STR("Work address country", item->contact->work_address_country); break; case 0x804A: // Work address postofficebox LIST_COPY_CONTACT_STR("Work address postofficebox", item->contact->work_address_postofficebox); break; case 0x8082: // Email Address 1 Transport LIST_COPY_CONTACT_STR("Email Address 1 Transport", item->contact->address1_transport); break; case 0x8083: // Email Address 1 Address LIST_COPY_CONTACT_STR("Email Address 1 Address", item->contact->address1); break; case 0x8084: // Email Address 1 Description LIST_COPY_CONTACT_STR("Email Address 1 Description", item->contact->address1_desc); break; case 0x8085: // Email Address 1 Record LIST_COPY_CONTACT_STR("Email Address 1 Record", item->contact->address1a); break; case 0x8092: // Email Address 2 Transport LIST_COPY_CONTACT_STR("Email Address 2 Transport", item->contact->address2_transport); break; case 0x8093: // Email Address 2 Address LIST_COPY_CONTACT_STR("Email Address 2 Address", item->contact->address2); break; case 0x8094: // Email Address 2 Description LIST_COPY_CONTACT_STR("Email Address 2 Description", item->contact->address2_desc); break; case 0x8095: // Email Address 2 Record LIST_COPY_CONTACT_STR("Email Address 2 Record", item->contact->address2a); break; case 0x80A2: // Email Address 3 Transport LIST_COPY_CONTACT_STR("Email Address 3 Transport", item->contact->address3_transport); break; case 0x80A3: // Email Address 3 Address LIST_COPY_CONTACT_STR("Email Address 3 Address", item->contact->address3); break; case 0x80A4: // Email Address 3 Description LIST_COPY_CONTACT_STR("Email Address 3 Description", item->contact->address3_desc); break; case 0x80A5: // Email Address 3 Record LIST_COPY_CONTACT_STR("Email Address 3 Record", item->contact->address3a); break; case 0x80D8: // Internet Free/Busy LIST_COPY_CONTACT_STR("Internet Free/Busy", item->contact->free_busy_address); break; case 0x8205: // PR_OUTLOOK_EVENT_SHOW_TIME_AS LIST_COPY_APPT_ENUM("Appointment shows as", item->appointment->showas, 0, 4, "Free", "Tentative", "Busy", "Out Of Office"); break; case 0x8208: // PR_OUTLOOK_EVENT_LOCATION LIST_COPY_APPT_STR("Appointment Location", item->appointment->location); break; case 0x820d: // PR_OUTLOOK_EVENT_START_DATE LIST_COPY_APPT_TIME("Appointment Date Start", item->appointment->start); break; case 0x820e: // PR_OUTLOOK_EVENT_START_END LIST_COPY_APPT_TIME("Appointment Date End", item->appointment->end); break; case 0x8214: // Label for an appointment LIST_COPY_APPT_ENUM("Label for appointment", item->appointment->label, 0, 11, "None", "Important", "Business", "Personal", "Vacation", "Must Attend", "Travel Required", "Needs Preparation", "Birthday", "Anniversary", "Phone Call"); break; case 0x8215: // PR_OUTLOOK_EVENT_ALL_DAY LIST_COPY_APPT_BOOL("All day flag", item->appointment->all_day); break; case 0x8216: // PR_OUTLOOK_EVENT_RECURRENCE_DATA LIST_COPY_APPT_BIN("Appointment recurrence data", item->appointment->recurrence_data); break; case 0x8223: // PR_OUTLOOK_EVENT_IS_RECURRING LIST_COPY_APPT_BOOL("Is recurring", item->appointment->is_recurring); break; case 0x8231: // Recurrence type LIST_COPY_APPT_ENUM("Appointment recurrence type ", item->appointment->recurrence_type, 0, 5, "None", "Daily", "Weekly", "Monthly", "Yearly"); break; case 0x8232: // Recurrence description LIST_COPY_APPT_STR("Appointment recurrence description", item->appointment->recurrence_description); break; case 0x8234: // TimeZone as String LIST_COPY_APPT_STR("TimeZone of times", item->appointment->timezonestring); break; case 0x8235: // PR_OUTLOOK_EVENT_RECURRENCE_START LIST_COPY_APPT_TIME("Recurrence Start Date", item->appointment->recurrence_start); break; case 0x8236: // PR_OUTLOOK_EVENT_RECURRENCE_END LIST_COPY_APPT_TIME("Recurrence End Date", item->appointment->recurrence_end); break; case 0x8501: // PR_OUTLOOK_COMMON_REMINDER_MINUTES_BEFORE LIST_COPY_APPT_INT32("Alarm minutes", item->appointment->alarm_minutes); break; case 0x8503: // PR_OUTLOOK_COMMON_REMINDER_SET LIST_COPY_APPT_BOOL("Reminder alarm", item->appointment->alarm); break; case 0x8516: // Common start DEBUG_INFO(("Common Start Date - %s\n", pst_fileTimeToAscii((FILETIME*)list->elements[x]->data, time_buffer))); break; case 0x8517: // Common end DEBUG_INFO(("Common End Date - %s\n", pst_fileTimeToAscii((FILETIME*)list->elements[x]->data, time_buffer))); break; case 0x851f: // Play reminder sound filename LIST_COPY_APPT_STR("Appointment reminder sound filename", item->appointment->alarm_filename); break; case 0x8530: // Followup LIST_COPY_CONTACT_STR("Followup String", item->contact->followup); break; case 0x8534: // Mileage LIST_COPY_CONTACT_STR("Mileage", item->contact->mileage); break; case 0x8535: // Billing Information LIST_COPY_CONTACT_STR("Billing Information", item->contact->billing_information); break; case 0x8554: // PR_OUTLOOK_VERSION LIST_COPY_STR("Outlook Version", item->outlook_version); break; case 0x8560: // Appointment Reminder Time LIST_COPY_APPT_TIME("Appointment Reminder Time", item->appointment->reminder); break; case 0x8700: // Journal Type LIST_COPY_JOURNAL_STR("Journal Entry Type", item->journal->type); break; case 0x8706: // Journal Start date/time LIST_COPY_JOURNAL_TIME("Start Timestamp", item->journal->start); break; case 0x8708: // Journal End date/time LIST_COPY_JOURNAL_TIME("End Timestamp", item->journal->end); break; case 0x8712: // Journal Type Description LIST_COPY_JOURNAL_STR("Journal description", item->journal->description); break; default: if (list->elements[x]->type == (uint32_t)0x0002) { DEBUG_WARN(("Unknown type %#x 16bit int = %hi\n", list->elements[x]->mapi_id, *(int16_t*)list->elements[x]->data)); } else if (list->elements[x]->type == (uint32_t)0x0003) { DEBUG_WARN(("Unknown type %#x 32bit int = %i\n", list->elements[x]->mapi_id, *(int32_t*)list->elements[x]->data)); } else if (list->elements[x]->type == (uint32_t)0x0004) { DEBUG_WARN(("Unknown type %#x 4-byte floating [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x0005) { DEBUG_WARN(("Unknown type %#x double floating [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x0006) { DEBUG_WARN(("Unknown type %#x signed 64bit int = %"PRIi64"\n", list->elements[x]->mapi_id, *(int64_t*)list->elements[x]->data)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x0007) { DEBUG_WARN(("Unknown type %#x application time [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x000a) { DEBUG_WARN(("Unknown type %#x 32bit error value = %i\n", list->elements[x]->mapi_id, *(int32_t*)list->elements[x]->data)); } else if (list->elements[x]->type == (uint32_t)0x000b) { DEBUG_WARN(("Unknown type %#x 16bit boolean = %s [%hi]\n", list->elements[x]->mapi_id, (*((int16_t*)list->elements[x]->data)!=0?"True":"False"), *((int16_t*)list->elements[x]->data))); } else if (list->elements[x]->type == (uint32_t)0x000d) { DEBUG_WARN(("Unknown type %#x Embedded object [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x0014) { DEBUG_WARN(("Unknown type %#x signed 64bit int = %"PRIi64"\n", list->elements[x]->mapi_id, *(int64_t*)list->elements[x]->data)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x001e) { DEBUG_WARN(("Unknown type %#x String Data = \"%s\"\n", list->elements[x]->mapi_id, list->elements[x]->data)); } else if (list->elements[x]->type == (uint32_t)0x001f) { DEBUG_WARN(("Unknown type %#x Unicode String Data [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x0040) { DEBUG_WARN(("Unknown type %#x Date = \"%s\"\n", list->elements[x]->mapi_id, pst_fileTimeToAscii((FILETIME*)list->elements[x]->data, time_buffer))); } else if (list->elements[x]->type == (uint32_t)0x0048) { DEBUG_WARN(("Unknown type %#x OLE GUID [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x0102) { DEBUG_WARN(("Unknown type %#x Binary Data [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x1003) { DEBUG_WARN(("Unknown type %#x Array of 32 bit values [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x1014) { DEBUG_WARN(("Unknown type %#x Array of 64 bit values [siize = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x101e) { DEBUG_WARN(("Unknown type %#x Array of Strings [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x101f) { DEBUG_WARN(("Unknown type %#x Array of Unicode Strings [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else if (list->elements[x]->type == (uint32_t)0x1102) { DEBUG_WARN(("Unknown type %#x Array of binary data blobs [size = %#x]\n", list->elements[x]->mapi_id, list->elements[x]->size)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } else { DEBUG_WARN(("Unknown type %#x Not Printable [%#x]\n", list->elements[x]->mapi_id, list->elements[x]->type)); DEBUG_HEXDUMP(list->elements[x]->data, list->elements[x]->size); } if (list->elements[x]->data) { free(list->elements[x]->data); list->elements[x]->data = NULL; } } } list = list->next; if (attach) attach = attach->next; } DEBUG_RET(); return 0; } static void pst_free_list(pst_mapi_object *list) { pst_mapi_object *l; DEBUG_ENT("pst_free_list"); while (list) { if (list->elements) { int32_t x; for (x=0; x < list->orig_count; x++) { if (list->elements[x]) { if (list->elements[x]->data) free(list->elements[x]->data); free(list->elements[x]); } } free(list->elements); } l = list->next; free (list); list = l; } DEBUG_RET(); } static void pst_free_id2(pst_id2_tree * head) { pst_id2_tree *t; DEBUG_ENT("pst_free_id2"); while (head) { pst_free_id2(head->child); t = head->next; free(head); head = t; } DEBUG_RET(); } static void pst_free_desc (pst_desc_tree *head) { pst_desc_tree *t; DEBUG_ENT("pst_free_desc"); while (head) { pst_free_desc(head->child); t = head->next; free(head); head = t; } DEBUG_RET(); } static void pst_free_xattrib(pst_x_attrib_ll *x) { pst_x_attrib_ll *t; DEBUG_ENT("pst_free_xattrib"); while (x) { if (x->data) free(x->data); t = x->next; free(x); x = t; } DEBUG_RET(); } static pst_id2_tree * pst_build_id2(pst_file *pf, pst_index_ll* list) { pst_block_header block_head; pst_id2_tree *head = NULL, *tail = NULL; uint16_t x = 0; char *b_ptr = NULL; char *buf = NULL; pst_id2_assoc id2_rec; pst_index_ll *i_ptr = NULL; pst_id2_tree *i2_ptr = NULL; DEBUG_ENT("pst_build_id2"); if (pst_read_block_size(pf, list->offset, list->size, list->inflated_size, &buf) < list->size) { //an error occurred in block read DEBUG_WARN(("block read error occurred. offset = %#"PRIx64", size = %#"PRIx64"\n", list->offset, list->size)); if (buf) free(buf); DEBUG_RET(); return NULL; } DEBUG_HEXDUMPC(buf, list->size, 16); memcpy(&block_head, buf, sizeof(block_head)); LE16_CPU(block_head.type); LE16_CPU(block_head.count); if (block_head.type != (uint16_t)0x0002) { // some sort of constant? DEBUG_WARN(("Unknown constant [%#hx] at start of id2 values [offset %#"PRIx64"].\n", block_head.type, list->offset)); if (buf) free(buf); DEBUG_RET(); return NULL; } DEBUG_INFO(("ID %#"PRIx64" is likely to be a description record. Count is %i (offset %#"PRIx64")\n", list->i_id, block_head.count, list->offset)); x = 0; b_ptr = buf + ((pf->do_read64) ? 0x08 : 0x04); while (x < block_head.count) { b_ptr += pst_decode_assoc(pf, &id2_rec, b_ptr); DEBUG_INFO(("id2 = %#x, id = %#"PRIx64", child id = %#"PRIx64"\n", id2_rec.id2, id2_rec.id, id2_rec.child_id)); if ((i_ptr = pst_getID(pf, id2_rec.id)) == NULL) { DEBUG_WARN(("%#"PRIx64" - Not Found\n", id2_rec.id)); } else { DEBUG_INFO(("%#"PRIx64" - Offset %#"PRIx64", u1 %#"PRIx64", Size %"PRIi64"(%#"PRIx64")\n", i_ptr->i_id, i_ptr->offset, i_ptr->u1, i_ptr->size, i_ptr->inflated_size)); // add it to the tree i2_ptr = (pst_id2_tree*) pst_malloc(sizeof(pst_id2_tree)); i2_ptr->id2 = id2_rec.id2; i2_ptr->id = i_ptr; i2_ptr->child = NULL; i2_ptr->next = NULL; if (!head) head = i2_ptr; if (tail) tail->next = i2_ptr; tail = i2_ptr; if (id2_rec.child_id) { if ((i_ptr = pst_getID(pf, id2_rec.child_id)) == NULL) { DEBUG_WARN(("child id [%#"PRIx64"] not found\n", id2_rec.child_id)); } else { i2_ptr->child = pst_build_id2(pf, i_ptr); } } } x++; } if (buf) free (buf); DEBUG_RET(); return head; } static void pst_free_attach(pst_item_attach *attach) { while (attach) { pst_item_attach *t; SAFE_FREE_STR(attach->filename1); SAFE_FREE_STR(attach->filename2); SAFE_FREE_STR(attach->mimetype); SAFE_FREE_STR(attach->content_id); SAFE_FREE_BIN(attach->data); pst_free_id2(attach->id2_head); t = attach->next; free(attach); attach = t; } } void pst_freeItem(pst_item *item) { pst_item_extra_field *et; DEBUG_ENT("pst_freeItem"); if (item) { if (item->email) { SAFE_FREE(item->email->arrival_date); SAFE_FREE_STR(item->email->cc_address); SAFE_FREE_STR(item->email->bcc_address); SAFE_FREE_BIN(item->email->conversation_index); SAFE_FREE_BIN(item->email->encrypted_body); SAFE_FREE_BIN(item->email->encrypted_htmlbody); SAFE_FREE_STR(item->email->header); SAFE_FREE_STR(item->email->htmlbody); SAFE_FREE_STR(item->email->in_reply_to); SAFE_FREE_STR(item->email->messageid); SAFE_FREE_STR(item->email->original_bcc); SAFE_FREE_STR(item->email->original_cc); SAFE_FREE_STR(item->email->original_to); SAFE_FREE_STR(item->email->outlook_recipient); SAFE_FREE_STR(item->email->outlook_recipient_name); SAFE_FREE_STR(item->email->outlook_recipient2); SAFE_FREE_STR(item->email->outlook_sender); SAFE_FREE_STR(item->email->outlook_sender_name); SAFE_FREE_STR(item->email->outlook_sender2); SAFE_FREE_STR(item->email->processed_subject); SAFE_FREE_STR(item->email->recip_access); SAFE_FREE_STR(item->email->recip_address); SAFE_FREE_STR(item->email->recip2_access); SAFE_FREE_STR(item->email->recip2_address); SAFE_FREE_STR(item->email->reply_to); SAFE_FREE_STR(item->email->rtf_body_tag); SAFE_FREE_BIN(item->email->rtf_compressed); SAFE_FREE_STR(item->email->return_path_address); SAFE_FREE_STR(item->email->sender_access); SAFE_FREE_STR(item->email->sender_address); SAFE_FREE_STR(item->email->sender2_access); SAFE_FREE_STR(item->email->sender2_address); SAFE_FREE(item->email->sent_date); SAFE_FREE(item->email->sentmail_folder); SAFE_FREE_STR(item->email->sentto_address); SAFE_FREE_STR(item->email->report_text); SAFE_FREE(item->email->report_time); SAFE_FREE_STR(item->email->supplementary_info); SAFE_FREE_STR(item->email->outlook_received_name1); SAFE_FREE_STR(item->email->outlook_sender_name2); SAFE_FREE_STR(item->email->outlook_normalized_subject); SAFE_FREE_STR(item->email->outlook_search_key); free(item->email); } if (item->folder) { free(item->folder); } if (item->message_store) { SAFE_FREE(item->message_store->top_of_personal_folder); SAFE_FREE(item->message_store->default_outbox_folder); SAFE_FREE(item->message_store->deleted_items_folder); SAFE_FREE(item->message_store->sent_items_folder); SAFE_FREE(item->message_store->user_views_folder); SAFE_FREE(item->message_store->common_view_folder); SAFE_FREE(item->message_store->search_root_folder); SAFE_FREE(item->message_store->top_of_folder); free(item->message_store); } if (item->contact) { SAFE_FREE_STR(item->contact->account_name); SAFE_FREE_STR(item->contact->address1); SAFE_FREE_STR(item->contact->address1a); SAFE_FREE_STR(item->contact->address1_desc); SAFE_FREE_STR(item->contact->address1_transport); SAFE_FREE_STR(item->contact->address2); SAFE_FREE_STR(item->contact->address2a); SAFE_FREE_STR(item->contact->address2_desc); SAFE_FREE_STR(item->contact->address2_transport); SAFE_FREE_STR(item->contact->address3); SAFE_FREE_STR(item->contact->address3a); SAFE_FREE_STR(item->contact->address3_desc); SAFE_FREE_STR(item->contact->address3_transport); SAFE_FREE_STR(item->contact->assistant_name); SAFE_FREE_STR(item->contact->assistant_phone); SAFE_FREE_STR(item->contact->billing_information); SAFE_FREE(item->contact->birthday); SAFE_FREE_STR(item->contact->business_address); SAFE_FREE_STR(item->contact->business_city); SAFE_FREE_STR(item->contact->business_country); SAFE_FREE_STR(item->contact->business_fax); SAFE_FREE_STR(item->contact->business_homepage); SAFE_FREE_STR(item->contact->business_phone); SAFE_FREE_STR(item->contact->business_phone2); SAFE_FREE_STR(item->contact->business_po_box); SAFE_FREE_STR(item->contact->business_postal_code); SAFE_FREE_STR(item->contact->business_state); SAFE_FREE_STR(item->contact->business_street); SAFE_FREE_STR(item->contact->callback_phone); SAFE_FREE_STR(item->contact->car_phone); SAFE_FREE_STR(item->contact->company_main_phone); SAFE_FREE_STR(item->contact->company_name); SAFE_FREE_STR(item->contact->computer_name); SAFE_FREE_STR(item->contact->customer_id); SAFE_FREE_STR(item->contact->def_postal_address); SAFE_FREE_STR(item->contact->department); SAFE_FREE_STR(item->contact->display_name_prefix); SAFE_FREE_STR(item->contact->first_name); SAFE_FREE_STR(item->contact->followup); SAFE_FREE_STR(item->contact->free_busy_address); SAFE_FREE_STR(item->contact->ftp_site); SAFE_FREE_STR(item->contact->fullname); SAFE_FREE_STR(item->contact->gov_id); SAFE_FREE_STR(item->contact->hobbies); SAFE_FREE_STR(item->contact->home_address); SAFE_FREE_STR(item->contact->home_city); SAFE_FREE_STR(item->contact->home_country); SAFE_FREE_STR(item->contact->home_fax); SAFE_FREE_STR(item->contact->home_po_box); SAFE_FREE_STR(item->contact->home_phone); SAFE_FREE_STR(item->contact->home_phone2); SAFE_FREE_STR(item->contact->home_postal_code); SAFE_FREE_STR(item->contact->home_state); SAFE_FREE_STR(item->contact->home_street); SAFE_FREE_STR(item->contact->initials); SAFE_FREE_STR(item->contact->isdn_phone); SAFE_FREE_STR(item->contact->job_title); SAFE_FREE_STR(item->contact->keyword); SAFE_FREE_STR(item->contact->language); SAFE_FREE_STR(item->contact->location); SAFE_FREE_STR(item->contact->manager_name); SAFE_FREE_STR(item->contact->middle_name); SAFE_FREE_STR(item->contact->mileage); SAFE_FREE_STR(item->contact->mobile_phone); SAFE_FREE_STR(item->contact->nickname); SAFE_FREE_STR(item->contact->office_loc); SAFE_FREE_STR(item->contact->common_name); SAFE_FREE_STR(item->contact->org_id); SAFE_FREE_STR(item->contact->other_address); SAFE_FREE_STR(item->contact->other_city); SAFE_FREE_STR(item->contact->other_country); SAFE_FREE_STR(item->contact->other_phone); SAFE_FREE_STR(item->contact->other_po_box); SAFE_FREE_STR(item->contact->other_postal_code); SAFE_FREE_STR(item->contact->other_state); SAFE_FREE_STR(item->contact->other_street); SAFE_FREE_STR(item->contact->pager_phone); SAFE_FREE_STR(item->contact->personal_homepage); SAFE_FREE_STR(item->contact->pref_name); SAFE_FREE_STR(item->contact->primary_fax); SAFE_FREE_STR(item->contact->primary_phone); SAFE_FREE_STR(item->contact->profession); SAFE_FREE_STR(item->contact->radio_phone); SAFE_FREE_STR(item->contact->spouse_name); SAFE_FREE_STR(item->contact->suffix); SAFE_FREE_STR(item->contact->surname); SAFE_FREE_STR(item->contact->telex); SAFE_FREE_STR(item->contact->transmittable_display_name); SAFE_FREE_STR(item->contact->ttytdd_phone); SAFE_FREE(item->contact->wedding_anniversary); SAFE_FREE_STR(item->contact->work_address_street); SAFE_FREE_STR(item->contact->work_address_city); SAFE_FREE_STR(item->contact->work_address_state); SAFE_FREE_STR(item->contact->work_address_postalcode); SAFE_FREE_STR(item->contact->work_address_country); SAFE_FREE_STR(item->contact->work_address_postofficebox); free(item->contact); } pst_free_attach(item->attach); while (item->extra_fields) { SAFE_FREE(item->extra_fields->field_name); SAFE_FREE(item->extra_fields->value); et = item->extra_fields->next; free(item->extra_fields); item->extra_fields = et; } if (item->journal) { SAFE_FREE(item->journal->start); SAFE_FREE(item->journal->end); SAFE_FREE_STR(item->journal->type); free(item->journal); } if (item->appointment) { SAFE_FREE(item->appointment->start); SAFE_FREE(item->appointment->end); SAFE_FREE_STR(item->appointment->location); SAFE_FREE(item->appointment->reminder); SAFE_FREE_STR(item->appointment->alarm_filename); SAFE_FREE_STR(item->appointment->timezonestring); SAFE_FREE_STR(item->appointment->recurrence_description); SAFE_FREE_BIN(item->appointment->recurrence_data); SAFE_FREE(item->appointment->recurrence_start); SAFE_FREE(item->appointment->recurrence_end); free(item->appointment); } SAFE_FREE(item->ascii_type); SAFE_FREE_STR(item->body_charset); SAFE_FREE_STR(item->body); SAFE_FREE_STR(item->subject); SAFE_FREE_STR(item->comment); SAFE_FREE(item->create_date); SAFE_FREE_STR(item->file_as); SAFE_FREE(item->modify_date); SAFE_FREE_STR(item->outlook_version); SAFE_FREE_BIN(item->record_key); SAFE_FREE_BIN(item->predecessor_change); free(item); } DEBUG_RET(); } /** * The offset might be zero, in which case we have no data, so return a pair of null pointers. * Or, the offset might end in 0xf, so it is an id2 pointer, in which case we read the id2 block. * Otherwise, the high order 16 bits of offset is the index into the subblocks, and * the (low order 16 bits of offset)>>4 is an index into the table of offsets in the subblock. */ static int pst_getBlockOffsetPointer(pst_file *pf, pst_id2_tree *i2_head, pst_subblocks *subblocks, uint32_t offset, pst_block_offset_pointer *p) { size_t size; pst_block_offset block_offset; DEBUG_ENT("pst_getBlockOffsetPointer"); if (p->needfree) free(p->from); p->from = NULL; p->to = NULL; p->needfree = 0; if (!offset) { // no data p->from = p->to = NULL; } else if ((offset & 0xf) == (uint32_t)0xf) { // external index reference DEBUG_WARN(("Found id2 %#x value. Will follow it\n", offset)); size = pst_ff_getID2block(pf, offset, i2_head, &(p->from)); if (size) { p->to = p->from + size; p->needfree = 1; } else { if (p->from) { DEBUG_WARN(("size zero but non-null pointer\n")); free(p->from); } p->from = p->to = NULL; } } else { DEBUG_WARN(("Found internal %#x value.\n", offset)); // internal index reference size_t subindex = offset >> 16; if (pf->do_read64 == 2) { // Shift over 3 more bits for new flags. subindex = subindex >> 3; } size_t suboffset = offset & 0xffff; if (subindex < subblocks->subblock_count) { if (pst_getBlockOffset(subblocks->subs[subindex].buf, subblocks->subs[subindex].read_size, subblocks->subs[subindex].i_offset, suboffset, &block_offset)) { p->from = subblocks->subs[subindex].buf + block_offset.from; p->to = subblocks->subs[subindex].buf + block_offset.to; } } } DEBUG_RET(); return (p->from) ? 0 : 1; } /** */ static int pst_getBlockOffset(char *buf, size_t read_size, uint32_t i_offset, uint32_t offset, pst_block_offset *p) { uint32_t low = offset & 0xf; uint32_t of1 = offset >> 4; DEBUG_ENT("pst_getBlockOffset"); if (!p || !buf || !i_offset || low || (i_offset+2+of1+sizeof(*p) > read_size)) { DEBUG_WARN(("p is NULL or buf is NULL or offset is 0 or offset has low bits or beyond read size (%p, %p, %#x, %i, %i)\n", p, buf, offset, read_size, i_offset)); DEBUG_RET(); return 0; } memcpy(&(p->from), &(buf[(i_offset+2)+of1]), sizeof(p->from)); memcpy(&(p->to), &(buf[(i_offset+2)+of1+sizeof(p->from)]), sizeof(p->to)); LE16_CPU(p->from); LE16_CPU(p->to); DEBUG_WARN(("get block offset finds from=%i(%#x), to=%i(%#x)\n", p->from, p->from, p->to, p->to)); if (p->from > p->to || p->to > read_size) { DEBUG_WARN(("get block offset bad range\n")); DEBUG_RET(); return 0; } DEBUG_RET(); return 1; } static int pst_getID_compare(const void *key, const void *entry) { uint64_t key_id = *(const uint64_t*)key; uint64_t entry_id = ((const pst_index_ll*)entry)->i_id; return (key_id > entry_id) - (key_id < entry_id); } /** */ pst_index_ll* pst_getID(pst_file* pf, uint64_t i_id) { pst_index_ll *ptr; DEBUG_ENT("pst_getID"); if (i_id == 0) { DEBUG_RET(); return NULL; } //if (i_id & 1) DEBUG_INFO(("have odd id bit %#"PRIx64"\n", i_id)); //if (i_id & 2) DEBUG_INFO(("have two id bit %#"PRIx64"\n", i_id)); i_id -= (i_id & 1); DEBUG_INFO(("Trying to find %#"PRIx64"\n", i_id)); ptr = bsearch(&i_id, pf->i_table, pf->i_count, sizeof *pf->i_table, pst_getID_compare); if (ptr) {DEBUG_INFO(("Found Value %#"PRIx64"\n", i_id)); } else {DEBUG_INFO(("ERROR: Value %#"PRIx64" not found\n", i_id)); } DEBUG_RET(); return ptr; } static pst_id2_tree *pst_getID2(pst_id2_tree *head, uint64_t id2) { // the id2 values are only unique among siblings. // we must not recurse into children // the caller must supply the correct parent DEBUG_ENT("pst_getID2"); DEBUG_INFO(("looking for id2 = %#"PRIx64"\n", id2)); pst_id2_tree *ptr = head; while (ptr) { if (ptr->id2 == id2) break; ptr = ptr->next; } if (ptr && ptr->id) { DEBUG_INFO(("Found value %#"PRIx64"\n", ptr->id->i_id)); DEBUG_RET(); return ptr; } DEBUG_INFO(("ERROR Not Found\n")); DEBUG_RET(); return NULL; } /** * find the id in the descriptor tree rooted at pf->d_head * * @param pf global pst file pointer * @param d_id the id we are looking for * * @return pointer to the pst_desc_tree node in the descriptor tree */ static pst_desc_tree* pst_getDptr(pst_file *pf, uint64_t d_id) { pst_desc_tree *ptr = pf->d_head; DEBUG_ENT("pst_getDptr"); while (ptr && (ptr->d_id != d_id)) { //DEBUG_INFO(("Looking for %#"PRIx64" at node %#"PRIx64" with parent %#"PRIx64"\n", id, ptr->d_id, ptr->parent_d_id)); if (ptr->child) { ptr = ptr->child; continue; } while (!ptr->next && ptr->parent) { ptr = ptr->parent; } ptr = ptr->next; } DEBUG_RET(); return ptr; // will be NULL or record we are looking for } static void pst_printDptr(pst_file *pf, pst_desc_tree *ptr) { DEBUG_ENT("pst_printDptr"); while (ptr) { DEBUG_INFO(("%#"PRIx64" [%i] desc=%#"PRIx64", assoc tree=%#"PRIx64"\n", ptr->d_id, ptr->no_child, (ptr->desc ? ptr->desc->i_id : (uint64_t)0), (ptr->assoc_tree ? ptr->assoc_tree->i_id : (uint64_t)0))); if (ptr->child) { pst_printDptr(pf, ptr->child); } ptr = ptr->next; } DEBUG_RET(); } static void pst_printID2ptr(pst_id2_tree *ptr) { DEBUG_ENT("pst_printID2ptr"); while (ptr) { DEBUG_INFO(("%#"PRIx64" id=%#"PRIx64"\n", ptr->id2, (ptr->id ? ptr->id->i_id : (uint64_t)0))); if (ptr->child) pst_printID2ptr(ptr->child); ptr = ptr->next; } DEBUG_RET(); } /** * Read a block of data from file into memory * @param pf PST file * @param offset offset in the pst file of the data * @param size size of the block to be read * @param buf reference to pointer to buffer. If this pointer is non-NULL, it will first be free()d * @return size of block read into memory */ static size_t pst_read_raw_block_size(pst_file *pf, int64_t offset, size_t size, char **buf) { size_t rsize; DEBUG_ENT("pst_read_raw_block_size"); DEBUG_INFO(("Reading raw block from %#"PRIx64", %x bytes\n", offset, size)); if (*buf) { DEBUG_INFO(("Freeing old memory\n")); free(*buf); } *buf = (char*) pst_malloc(size); rsize = pst_getAtPos(pf, offset, *buf, size); if (rsize != size) { DEBUG_WARN(("Didn't read all the data. fread returned less [%i instead of %i]\n", rsize, size)); if (feof(pf->fp)) { DEBUG_WARN(("We tried to read past the end of the file at [offset %#"PRIx64", size %#x]\n", offset, size)); } else if (ferror(pf->fp)) { DEBUG_WARN(("Error is set on file stream.\n")); } else { DEBUG_WARN(("I can't tell why it failed\n")); } } DEBUG_RET(); return rsize; } static size_t pst_read_block_size(pst_file *pf, int64_t offset, size_t size, size_t inflated_size, char **buf) { DEBUG_ENT("pst_read_block_size"); DEBUG_INFO(("Reading block from %#"PRIx64", %x bytes, %x inflated\n", offset, size, inflated_size)); if (inflated_size <= size) { // Not deflated. size_t ret = pst_read_raw_block_size(pf, offset, size, buf); DEBUG_RET(); return ret; } // We need to read the raw block and inflate it. char *zbuf = NULL; if (pst_read_raw_block_size(pf, offset, size, &zbuf) != size) { DEBUG_WARN(("Failed to read %i bytes\n", size)); if (zbuf) free(zbuf); DEBUG_RET(); return -1; } *buf = (char *) pst_malloc(inflated_size); size_t result_size = inflated_size; if (uncompress((Bytef *) *buf, &result_size, (Bytef *) zbuf, size) != Z_OK || result_size != inflated_size) { DEBUG_WARN(("Failed to uncompress %i bytes to %i bytes, got %i\n", size, inflated_size, result_size)); if (zbuf) free(zbuf); DEBUG_RET(); return -1; } DEBUG_RET(); return inflated_size; } /** Decrypt a block of data from the pst file. * @param i_id identifier of this block, needed as part of the key for the enigma cipher * @param buf pointer to the buffer to be decrypted in place * @param size size of the buffer * @param type @li 0 PST_NO_ENCRYPT, none @li 1 PST_COMP_ENCRYPT, simple byte substitution cipher with fixed key @li 2 PST_ENCRYPT, German enigma 3 rotor cipher with fixed key * @return 0 if ok, -1 if error (NULL buffer or unknown encryption type) */ static int pst_decrypt(uint64_t i_id, char *buf, size_t size, unsigned char type) { size_t x = 0; unsigned char y; DEBUG_ENT("pst_decrypt"); if (!buf) { DEBUG_RET(); return -1; } if (type == PST_COMP_ENCRYPT) { x = 0; while (x < size) { y = (unsigned char)(buf[x]); buf[x] = (char)comp_enc[y]; // transpose from encrypt array x++; } } else if (type == PST_ENCRYPT) { // The following code was based on the information at // http://www.passcape.com/outlook_passwords.htm uint16_t salt = (uint16_t) (((i_id & 0x00000000ffff0000) >> 16) ^ (i_id & 0x000000000000ffff)); x = 0; while (x < size) { uint8_t losalt = (salt & 0x00ff); uint8_t hisalt = (salt & 0xff00) >> 8; y = (unsigned char)buf[x]; y += losalt; y = comp_high1[y]; y += hisalt; y = comp_high2[y]; y -= hisalt; y = comp_enc[y]; y -= losalt; buf[x] = (char)y; x++; salt++; } } else { DEBUG_WARN(("Unknown encryption: %i. Cannot decrypt\n", type)); DEBUG_RET(); return -1; } DEBUG_RET(); return 0; } static uint64_t pst_getIntAt(pst_file *pf, char *buf) { uint64_t buf64; uint32_t buf32; if (pf->do_read64) { memcpy(&buf64, buf, sizeof(buf64)); LE64_CPU(buf64); return buf64; } else { memcpy(&buf32, buf, sizeof(buf32)); LE32_CPU(buf32); return buf32; } } static uint64_t pst_getIntAtPos(pst_file *pf, int64_t pos ) { uint64_t buf64; uint32_t buf32; if (pf->do_read64) { (void)pst_getAtPos(pf, pos, &buf64, sizeof(buf64)); LE64_CPU(buf64); return buf64; } else { (void)pst_getAtPos(pf, pos, &buf32, sizeof(buf32)); LE32_CPU(buf32); return buf32; } } /** * Read part of the pst file. * * @param pf PST file structure * @param pos offset of the data in the pst file * @param buf buffer to contain the data * @param size size of the buffer and the amount of data to be read * @return actual read size, 0 if seek error */ static size_t pst_getAtPos(pst_file *pf, int64_t pos, void* buf, size_t size) { size_t rc; DEBUG_ENT("pst_getAtPos"); // pst_block_recorder **t = &pf->block_head; // pst_block_recorder *p = pf->block_head; // while (p && ((p->offset+p->size) <= pos)) { // t = &p->next; // p = p->next; // } // if (p && (p->offset <= pos) && (pos < (p->offset+p->size))) { // // bump the count // p->readcount++; // } else { // // add a new block // pst_block_recorder *tail = *t; // p = (pst_block_recorder*)pst_malloc(sizeof(*p)); // *t = p; // p->next = tail; // p->offset = pos; // p->size = size; // p->readcount = 1; // } // DEBUG_INFO(("pst file old offset %#"PRIx64" old size %#x read count %i offset %#"PRIx64" size %#x\n", // p->offset, p->size, p->readcount, pos, size)); if (fseeko(pf->fp, pos, SEEK_SET) == -1) { DEBUG_RET(); return 0; } rc = fread(buf, (size_t)1, size, pf->fp); DEBUG_RET(); return rc; } /** * Get an ID block from file using pst_ff_getIDblock() and decrypt if necessary * @param pf PST file structure * @param i_id ID of block to retrieve * @param buf reference to pointer to buffer that will contain the data block. * If this pointer is non-NULL, it will first be free()d. * @return Size of block read into memory */ size_t pst_ff_getIDblock_dec(pst_file *pf, uint64_t i_id, char **buf) { size_t r; int noenc = (int)(i_id & 2); // disable encryption DEBUG_ENT("pst_ff_getIDblock_dec"); DEBUG_INFO(("for id %#"PRIx64"\n", i_id)); r = pst_ff_getIDblock(pf, i_id, buf); if ((pf->encryption) && !(noenc)) { (void)pst_decrypt(i_id, *buf, r, pf->encryption); } DEBUG_HEXDUMPC(*buf, r, 16); DEBUG_RET(); return r; } /** * Read a block of data from file into memory * @param pf PST file structure * @param i_id ID of block to read * @param buf reference to pointer to buffer that will contain the data block. * If this pointer is non-NULL, it will first be free()d. * @return size of block read into memory */ static size_t pst_ff_getIDblock(pst_file *pf, uint64_t i_id, char** buf) { pst_index_ll *rec; size_t rsize; DEBUG_ENT("pst_ff_getIDblock"); rec = pst_getID(pf, i_id); if (!rec) { DEBUG_INFO(("Cannot find ID %#"PRIx64"\n", i_id)); DEBUG_RET(); return 0; } DEBUG_INFO(("id = %#"PRIx64", record size = %#x, offset = %#x\n", i_id, rec->size, rec->offset)); rsize = pst_read_block_size(pf, rec->offset, rec->size, rec->inflated_size, buf); DEBUG_RET(); return rsize; } static size_t pst_ff_getID2block(pst_file *pf, uint64_t id2, pst_id2_tree *id2_head, char** buf) { size_t ret; pst_id2_tree* ptr; pst_holder h = {buf, NULL, 0, 0, 0}; DEBUG_ENT("pst_ff_getID2block"); ptr = pst_getID2(id2_head, id2); if (!ptr) { DEBUG_WARN(("Cannot find id2 value %#"PRIx64"\n", id2)); DEBUG_RET(); return 0; } ret = pst_ff_getID2data(pf, ptr->id, &h); DEBUG_RET(); return ret; } /** find the actual data from an i_id and send it to the destination * specified by the pst_holder h. h must be a new empty destination. * * @param pf PST file structure * @param ptr * @param h specifies the output destination (buffer, file, encoding) * @return updated size of the output */ static size_t pst_ff_getID2data(pst_file *pf, pst_index_ll *ptr, pst_holder *h) { size_t ret; char *b = NULL; DEBUG_ENT("pst_ff_getID2data"); if (!(ptr->i_id & 0x02)) { ret = pst_ff_getIDblock_dec(pf, ptr->i_id, &b); ret = pst_append_holder(h, (size_t)0, &b, ret); free(b); } else { // here we will assume it is an indirection block that points to others DEBUG_INFO(("Assuming it is a multi-block record because of it's id %#"PRIx64"\n", ptr->i_id)); ret = pst_ff_compile_ID(pf, ptr->i_id, h, (size_t)0); } ret = pst_finish_cleanup_holder(h, ret); DEBUG_RET(); return ret; } /** find the actual data from an indirection i_id and send it to the destination * specified by the pst_holder. * * @param pf PST file structure * @param i_id ID of the block to read * @param h specifies the output destination (buffer, file, encoding) * @param size number of bytes of data already sent to h * @return updated size of the output */ static size_t pst_ff_compile_ID(pst_file *pf, uint64_t i_id, pst_holder *h, size_t size) { size_t z, a; uint16_t count, y; char *buf3 = NULL; char *buf2 = NULL; char *b_ptr; pst_block_hdr block_hdr; pst_table3_rec table3_rec; //for type 3 (0x0101) blocks DEBUG_ENT("pst_ff_compile_ID"); a = pst_ff_getIDblock(pf, i_id, &buf3); if (!a) { if (buf3) free(buf3); DEBUG_RET(); return 0; } DEBUG_HEXDUMPC(buf3, a, 16); memcpy(&block_hdr, buf3, sizeof(block_hdr)); LE16_CPU(block_hdr.index_offset); LE16_CPU(block_hdr.type); LE32_CPU(block_hdr.offset); DEBUG_INFO(("block header (index_offset=%#hx, type=%#hx, offset=%#x)\n", block_hdr.index_offset, block_hdr.type, block_hdr.offset)); count = block_hdr.type; b_ptr = buf3 + 8; // For indirect lookups through a table of i_ids, just recurse back into this // function, letting it concatenate all the data together, and then return the // total size of the data. if (block_hdr.index_offset == (uint16_t)0x0201) { // Indirect lookup (depth 2). for (y=0; yencryption) (void)pst_decrypt(i_id, buf3, a, pf->encryption); size = pst_append_holder(h, size, &buf3, a); free(buf3); DEBUG_RET(); return size; } for (y=0; ybuf) { *(h->buf) = pst_realloc(*(h->buf), size+z+1); DEBUG_INFO(("appending read data of size %i onto main buffer from pos %i\n", z, size)); memcpy(*(h->buf)+size, *buf, z); // base64 encoding to a file } else if ((h->base64 == 1) && h->fp) { // if (h->base64_extra) { // include any bytes left over from the last encoding *buf = (char*)pst_realloc(*buf, z+h->base64_extra); memmove(*buf+h->base64_extra, *buf, z); memcpy(*buf, h->base64_extra_chars, h->base64_extra); z += h->base64_extra; } // find out how many bytes will be left over after this encoding and save them h->base64_extra = z % 3; if (h->base64_extra) { z -= h->base64_extra; memcpy(h->base64_extra_chars, *buf+z, h->base64_extra); } // encode this chunk t = pst_base64_encode_multiple(*buf, z, &h->base64_line_count); if (t) { DEBUG_INFO(("writing %i bytes to file as base64 [%i]. Currently %i\n", z, strlen(t), size)); (void)pst_fwrite(t, (size_t)1, strlen(t), h->fp); free(t); // caught by valgrind } // raw append to a file } else if (h->fp) { DEBUG_INFO(("writing %i bytes to file. Currently %i\n", z, size)); (void)pst_fwrite(*buf, (size_t)1, z, h->fp); // null output } else { // h-> does not specify any output } DEBUG_RET(); return size+z; } /** finish cleanup for base64 encoding to a file with extra bytes left over * * @param h specifies the output destination (buffer, file, encoding) * @param size number of bytes of data already sent to h * @return updated size of the output */ static size_t pst_finish_cleanup_holder(pst_holder *h, size_t size) { char *t; DEBUG_ENT("pst_finish_cleanup_holder"); if ((h->base64 == 1) && h->fp && h->base64_extra) { // need to encode any bytes left over t = pst_base64_encode_multiple(h->base64_extra_chars, h->base64_extra, &h->base64_line_count); if (t) { (void)pst_fwrite(t, (size_t)1, strlen(t), h->fp); free(t); // caught by valgrind } size += h->base64_extra; } DEBUG_RET(); return size; } /** compare strings case-insensitive. * @return -1 if a < b, 0 if a==b, 1 if a > b */ int pst_stricmp(char *a, char *b) { while(*a != '\0' && *b != '\0' && toupper(*a)==toupper(*b)) { a++; b++; } if (toupper(*a) == toupper(*b)) return 0; else if (toupper(*a) < toupper(*b)) return -1; else return 1; } static int pst_strincmp(char *a, char *b, size_t x) { // compare up to x chars in string a and b case-insensitively // returns -1 if a < b, 0 if a==b, 1 if a > b size_t y = 0; while (*a != '\0' && *b != '\0' && y < x && toupper(*a)==toupper(*b)) { a++; b++; y++; } // if we have reached the end of either string, or a and b still match if (*a == '\0' || *b == '\0' || toupper(*a)==toupper(*b)) return 0; else if (toupper(*a) < toupper(*b)) return -1; else return 1; } size_t pst_fwrite(const void* ptr, size_t size, size_t nmemb, FILE *stream) { size_t r; if (ptr) r = fwrite(ptr, size, nmemb, stream); else { r = 0; DEBUG_ENT("pst_fwrite"); DEBUG_WARN(("An attempt to write a NULL Pointer was made\n")); DEBUG_RET(); } return r; } static char* pst_wide_to_single(char *wt, size_t size) { // returns the first byte of each wide char. the size is the number of bytes in source char *x, *y; DEBUG_ENT("pst_wide_to_single"); x = pst_malloc((size/2)+1); y = x; while (size != 0 && *wt != '\0') { *y = *wt; wt+=2; size -= 2; y++; } *y = '\0'; DEBUG_RET(); return x; } char* pst_rfc2426_escape(char* str, char **buf, size_t* buflen) { //static char* buf = NULL; //static size_t buflen = 0; char *ret, *a, *b; size_t x = 0; int y, z; if (!str) return NULL; DEBUG_ENT("rfc2426_escape"); // calculate space required to escape all the following characters y = pst_chr_count(str, ',') + pst_chr_count(str, '\\') + pst_chr_count(str, ';') + pst_chr_count(str, '\n'); z = pst_chr_count(str, '\r'); if (y == 0 && z == 0) // there isn't any extra space required ret = str; else { x = strlen(str) + y - z + 1; // don't forget room for the NUL if (x > *buflen) { *buf = (char*)pst_realloc(*buf, x); *buflen = x; } a = str; b = *buf; while (*a != '\0') { switch (*a) { case ',' : case '\\': case ';' : *(b++) = '\\'; *b = *a; break; case '\n': // newlines are encoded as "\n" *(b++) = '\\'; *b = 'n'; break; case '\r': // skip cr b--; break; default: *b=*a; } b++; a++; } *b = '\0'; // NUL-terminate the string (buf) ret = *buf; } DEBUG_RET(); return ret; } static int pst_chr_count(char *str, char x) { int r = 0; while (*str) { if (*str == x) r++; str++; } return r; } char* pst_rfc2425_datetime_format(const FILETIME* ft, int buflen, char* result) { struct tm stm; DEBUG_ENT("rfc2425_datetime_format"); pst_fileTimeToStructTM(ft, &stm); if (strftime(result, buflen, "%Y-%m-%dT%H:%M:%SZ", &stm)==0) { DEBUG_INFO(("Problem occurred formatting date\n")); } DEBUG_RET(); return result; } char* pst_rfc2445_datetime_format(const FILETIME* ft, int buflen, char* result) { struct tm stm; DEBUG_ENT("rfc2445_datetime_format"); pst_fileTimeToStructTM(ft, &stm); if (strftime(result, buflen, "%Y%m%dT%H%M%SZ", &stm)==0) { DEBUG_INFO(("Problem occurred formatting date\n")); } DEBUG_RET(); return result; } char* pst_rfc2445_datetime_format_now(int buflen, char* result) { struct tm stm; time_t t = time(NULL); DEBUG_ENT("rfc2445_datetime_format_now"); gmtime_r(&t, &stm); if (strftime(result, buflen, "%Y%m%dT%H%M%SZ", &stm)==0) { DEBUG_INFO(("Problem occurred formatting date\n")); } DEBUG_RET(); return result; } /** Convert a code page integer into a string suitable for iconv() * * @param cp the code page integer used in the pst file * @param[in] buflen length of the output buffer * @param[out] result pointer to output buffer, must be at least 30 bytes * @return pointer to a static buffer holding the string representation of the * equivalent iconv character set */ static const char* codepage(int cp, int buflen, char* result); static const char* codepage(int cp, int buflen, char* result) { switch (cp) { case 932 : return "iso-2022-jp"; case 936 : return "gb2313"; case 950 : return "big5"; case 1200 : return "ucs-2le"; case 1201 : return "ucs-2be"; case 20127 : return "us-ascii"; case 20269 : return "iso-6937"; case 20865 : return "iso-8859-15"; case 20866 : return "koi8-r"; case 21866 : return "koi8-u"; case 28591 : return "iso-8859-1"; case 28592 : return "iso-8859-2"; case 28595 : return "iso-8859-5"; case 28596 : return "iso-8859-6"; case 28597 : return "iso-8859-7"; case 28598 : return "iso-8859-8"; case 28599 : return "iso-8859-9"; case 28600 : return "iso-8859-10"; case 28601 : return "iso-8859-11"; case 28602 : return "iso-8859-12"; case 28603 : return "iso-8859-13"; case 28604 : return "iso-8859-14"; case 28605 : return "iso-8859-15"; case 28606 : return "iso-8859-16"; case 50220 : return "iso-2022-jp"; case 50221 : return "csiso2022jp"; case 51932 : return "euc-jp"; case 51949 : return "euc-kr"; case 65000 : return "utf-7"; case 65001 : return "utf-8"; default : snprintf(result, buflen, "windows-%d", cp); return result; } return NULL; } /** Get the default character set for this item. This is used to find * the charset for pst_string elements that are not already in utf8 encoding. * * @param item pointer to the mapi item of interest * @param[in] buflen length of the output buffer * @param[out] result pointer to output buffer, must be at least 30 bytes * @return default character set as a string usable by iconv() */ const char* pst_default_charset(pst_item *item, int buflen, char* result) { return (item->body_charset.str) ? item->body_charset.str : (item->message_codepage) ? codepage(item->message_codepage, buflen, result) : (item->internet_cpid) ? codepage(item->internet_cpid, buflen, result) : (item->pf && item->pf->charset) ? item->pf->charset : "iso-8859-1"; } /** Convert str to rfc2231 encoding of str * * @param str pointer to the mapi string of interest */ void pst_rfc2231(pst_string *str) { int needs = 0; const int8_t *x = (int8_t *)str->str; while (*x) { if (*x <= 32) needs++; x++; } int n = strlen(str->str) + 2*needs + 15; char *buffer = pst_malloc(n); strcpy(buffer, "utf-8''"); x = (int8_t *)str->str; const uint8_t *y = (uint8_t *)str->str; uint8_t *z = (uint8_t *)buffer; z += strlen(buffer); // skip the utf8 prefix while (*y) { if (*x <= 32) { *(z++) = (uint8_t)'%'; snprintf(z, 3, "%2x", *y); z += 2; } else { *(z++) = *y; } x++; y++; } *z = '\0'; free(str->str); str->str = buffer; } /** Convert str to rfc2047 encoding of str, possibly enclosed in quotes if it contains spaces * * @param item pointer to the containing mapi item * @param str pointer to the mapi string of interest * @param needs_quote true if strings containing spaces should be wrapped in quotes */ void pst_rfc2047(pst_item *item, pst_string *str, int needs_quote) { int has_space = 0; int needs_coding = 0; pst_convert_utf8(item, str); const int8_t *x = (int8_t *)str->str; while (*x) { if (*x == 32) has_space = 1; if (*x < 32) needs_coding = 1; x++; } if (needs_coding) { char *enc = pst_base64_encode_single(str->str, strlen(str->str)); free(str->str); int n = strlen(enc) + 20; str->str = pst_malloc(n); snprintf(str->str, n, "=?utf-8?B?%s?=", enc); free(enc); } else if (has_space && needs_quote) { int n = strlen(str->str) + 10; char *buffer = pst_malloc(n); snprintf(buffer, n, "\"%s\"", str->str); free(str->str); str->str = buffer; } } /** Convert str to utf8 if possible; null strings are preserved. * * @param item pointer to the containing mapi item * @param str pointer to the mapi string of interest */ void pst_convert_utf8_null(pst_item *item, pst_string *str) { if (!str->str) return; pst_convert_utf8(item, str); } /** Convert str to utf8 if possible; null strings are converted into empty strings. * * @param item pointer to the containing mapi item * @param str pointer to the mapi string of interest */ void pst_convert_utf8(pst_item *item, pst_string *str) { DEBUG_ENT("pst_convert_utf8"); char buffer[30]; if (str->is_utf8) { DEBUG_WARN(("Already utf8\n")); DEBUG_RET(); return; } if (!str->str) { str->str = strdup(""); DEBUG_WARN(("null to empty string\n")); DEBUG_RET(); return; } const char *charset = pst_default_charset(item, sizeof(buffer), buffer); DEBUG_WARN(("default charset is %s\n", charset)); if (!strcasecmp("utf-8", charset)) { DEBUG_RET(); return; } pst_vbuf *newer = pst_vballoc(2); size_t rc = pst_vb_8bit2utf8(newer, str->str, strlen(str->str) + 1, charset); if (rc == (size_t)-1) { free(newer->b); DEBUG_WARN(("Failed to convert %s to utf-8 - %s\n", charset, str->str)); } else { free(str->str); str->str = newer->b; str->is_utf8 = 1; } free(newer); DEBUG_RET(); } /** Decode raw recurrence data into a better structure. * @param appt pointer to appointment structure * @return pointer to decoded recurrence structure that must be free'd by the caller. */ pst_recurrence* pst_convert_recurrence(pst_item_appointment* appt) { const int bias = 30 * 24 * 60; // minutes in 30 days int m[4] = {3,4,4,5}; pst_recurrence *r = pst_malloc(sizeof(pst_recurrence)); memset(r, 0, sizeof(pst_recurrence)); size_t s = appt->recurrence_data.size; size_t i = 0; char* p = appt->recurrence_data.data; if (p) { if (i+4 <= s) { r->signature = PST_LE_GET_UINT32(p+i); i += 4; } if (i <= s) { r->type = PST_LE_GET_UINT8(p+i) - 0x0a; i += 2; } if (i+4 <= s) { r->sub_type = PST_LE_GET_UINT32(p+i); i += 4; } if (r->sub_type <= 3) { int n = m[r->sub_type]; // number of parms for this sub_type int j = 0; for (j=0; jparm1 + j) = PST_LE_GET_UINT32(p+i); i += 4; } } } if (i <= s) { r->termination = PST_LE_GET_UINT8(p+i) - 0x21; i += 4; } if (i+4 <= s) { r->count = PST_LE_GET_UINT32(p+i); i += 4; } if (r->termination == 2) r->count = 0; switch (r->type) { case 0: // daily if (r->sub_type == 0) { // simple daily r->interval = r->parm2 / (24 * 60); // was minutes between recurrences } else { // daily every weekday, subset of weekly r->interval = 1; r->bydaymask = r->parm4; } break; case 1: // weekly r->interval = r->parm2; r->bydaymask = r->parm4; break; case 2: // monthly r->interval = r->parm2; if (r->sub_type == 2) { // monthly on day d r->dayofmonth = r->parm4; } else { // monthly on 2nd tuesday r->bydaymask = r->parm4; r->position = r->parm5; } break; case 3: // yearly r->interval = 1; r->monthofyear = ((r->parm1 + bias/2) / bias) + 1; if (r->sub_type == 2) { // yearly on day d of month m r->dayofmonth = r->parm4; } else { // yearly on 2nd tuesday of month m r->bydaymask = r->parm4; r->position = r->parm5; } break; default: break; } } return r; } /** Free a recurrence structure. * @param r input pointer to be freed */ void pst_free_recurrence(pst_recurrence* r) { if (r) free(r); } diff --git a/xml/libpst.in b/xml/libpst.in index 4ca7152..528c4d5 100644 --- a/xml/libpst.in +++ b/xml/libpst.in @@ -1,2055 +1,2055 @@ @PACKAGE@ Utilities - Version @VERSION@ Packages The various source and binary packages are available at https://github.com/pst-format/@PACKAGE@/releases. The most recent documentation is available at http://www.five-ten-sg.com/@PACKAGE@/. The most recent developer documentation for the shared library is available at http://www.five-ten-sg.com/@PACKAGE@/devel/. A Git source code repository for this project is available at https://github.com/pst-format/PACKAGE@.git. This version can now convert both 32 bit Outlook files (pre 2003), and the 64 bit Outlook 2003 pst files. Utilities are supplied to convert email messages to both mbox and MH mailbox formats, and to DII load file format for use with many of the CT Summation products. Contacts can be converted to a simple list, to vcard format, or to ldif format for import to an LDAP server. The libpff project + url="https://github.com/libyal/libpff">libpff project has some excellent documentation of the pst file format. 2017-12-07 readpst 1 readpst @VERSION@ readpst convert PST (MS Outlook Personal Folders) files to mbox and other formats Synopsis readpst pstfile Description readpst is a program that can read an Outlook PST (Personal Folders) file and convert it into an mbox file, a format suitable for KMail, a recursive mbox structure, or separate emails. Options -C default-charset Set the character set to be used for items with an unspecified character set. -D Include deleted items in the output. -M Output messages in MH (rfc822) format as separate files. This will create folders as named in the PST file, and will put each email together with any attachments into its own file. These files will be numbered from 1 to n with no leading zeros. This format has no from quoting. -S Output messages into separate files. This will create folders as named in the PST file, and will put each email in its own file. These files will be numbered from 1 to n with no leading zeros. Attachments will also be saved in the same folder as the email message. The attachments for message $m are saved as $m-$name where $name is (the original name of the attachment, or 'attach$n' if the attachment had no name), where $n is another sequential index with no leading zeros. This format has no from quoting. -V Show program version and exit. -a attachment-extension-list Set the list of acceptable attachment extensions. Any attachment that does not have an extension on this list will be discarded. All attachments are acceptable if the list is empty, or this option is not specified. -b Do not save the attachments for the RTF format of the email body. -c format Set the Contact output mode. Use -cv for vcard format or -cl for an email list. -d debug-file Specify name of debug log file. The log file is now an ascii file, instead of the binary file used in previous versions. -e Same as the M option, but each output file will include an extension from (.eml, .ics, .vcf). This format has no from quoting. -h Show summary of options and exit. -j jobs Specifies the maximum number of parallel jobs. Specify 0 to suppress running parallel jobs. Folders may be processed in parallel. Output formats that place each mail message in a separate file (-M, -S, -e) may process the contents of individual folders in parallel. -k Changes the output format to KMail. This format uses mboxrd from quoting. -m Same as the e option, but write .msg files also -o output-directory Specifies the output directory. The directory must already exist, and is entered after the PST file is opened, but before any processing of files commences. -q Changes to silent mode. No feedback is printed to the screen, except for error messages. -r Changes the output format to Recursive. This will create folders as named in the PST file, and will put all emails in a file called "mbox" inside each folder. Appointments go into a file called "calendar", address book entries go into a file called "contacts", and journal entries go into a file called "journal". These files are then compatible with all mbox-compatible email clients. This format uses mboxrd from quoting. -t output-type-codes Specifies the item types that are processed. The argument is a sequence of single letters from (e,a,j,c) for (email, appointment, journal, contact) types. The default is to process all item types. -u Sets Thunderbird mode, a submode of recursive mode. This causes two extra .type and .size meta files to be created. This format uses mboxrd from quoting. -w Overwrite any previous output files. Beware: When used with the -S switch, this will remove all files from the target folder before writing. This is to keep the count of emails and attachments correct. -8 Output bodies in UTF-8, rather than original encoding, if a UTF-8 version is available. From Quoting Output formats that place each mail message in a separate file (-M, -S, -e, -m) don't do any from quoting. Output formats that place multiple email messages in a single file (-k, -r, -u) now use mboxrd from quoting rules. If none of those switches are specified, the default output format uses mboxrd from quoting rules, since it produces multiple email messages in a single file. Earlier versions used mboxo from quoting rules for all output formats. Author This manual page was originally written by Dave Smith <dave.s@earthcorp.com>, and updated by Joe Nahmias <joe@nahmias.net> for the Debian GNU/Linux system (but may be used by others). It was subsequently updated by Brad Hards <bradh@frogmouth.net>, and converted to xml format by Carl Byington <carl@five-ten-sg.com>. Copyright Copyright (C) 2002 by David Smith <dave.s@earthcorp.com>. XML version Copyright (C) 2008 by 510 Software Group <carl@five-ten-sg.com>. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. You should have received a copy of the GNU General Public License along with this program; see the file COPYING. If not, please write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. Version @VERSION@ 2016-08-29 lspst 1 lspst @VERSION@ lspst list PST (MS Outlook Personal Folders) file data Synopsis lspst pstfile Options -V Show program version and exit. -d debug-file Specify name of debug log file. The log file is now an ascii file, instead of the binary file used in previous versions. -f date-format Select the date format for long format listing. Defaults to "%F %T". -l Use long format listing to show the Date, CC and BCC headers. -h Show summary of options and exit. Description lspst is a program that can read an Outlook PST (Personal Folders) file and produce a simple listing of the data (contacts, email subjects, etc). Author lspst was written by Joe Nahmias <joe@nahmias.net> based on readpst. This man page was written by 510 Software Group <carl@five-ten-sg.com>. Copyright Copyright (C) 2004 by Joe Nahmias <joe@nahmias.net>. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. You should have received a copy of the GNU General Public License along with this program; see the file COPYING. If not, please write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. Version @VERSION@ 2017-12-07 pst2ldif 1 pst2ldif @VERSION@ pst2ldif extract contacts from an MS Outlook .pst file in .ldif format Synopsis pst2ldif pstfilename Options -V Show program version. Subsequent options are then ignored. -b ldap-base Sets the ldap base value used in the dn records. You probably want to use something like "o=organization, c=US". -c class Sets the objectClass values for the contact items. This class needs to be defined in the schema used by your LDAP server, and at a minimum it must contain the ldap attributes given below. This option may be specified multiple times to generate entries with multiple object classes. -d debug-file Specify name of debug log file. The log file is now an ascii file, instead of the binary file used in previous versions. -l extra-line Specify an extra line to be added to each ldap entry. This option may be specified multiple times to add multiple lines to each ldap entry. -o Use the old ldap schema, rather than the default new ldap schema. The old schema generates multiple postalAddress attributes for a single entry. The new schema generates a single postalAddress (and homePostalAddress when available) attribute with $ delimiters as specified in RFC4517. Using the old schema also generates two extra leading entries, one for "dn:ldap base", and one for "dn: cn=root, ldap base". -h Show summary of options. Subsequent options are then ignored. Description pst2ldif reads the contact information from an MS Outlook .pst file and produces a .ldif file that may be used to import those contacts into an LDAP database. The following ldap attributes are generated for the old ldap schema: cn givenName sn personalTitle company mail postalAddress l st postalCode c homePhone telephoneNumber facsimileTelephoneNumber mobile description The following attributes are generated for the new ldap schema: cn givenName sn title o mail postalAddress homePostalAddress l st postalCode c homePhone telephoneNumber facsimileTelephoneNumber mobile description labeledURI Copyright Copyright (C) 2008 by 510 Software Group <carl@five-ten-sg.com> This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. You should have received a copy of the GNU General Public License along with this program; see the file COPYING. If not, please write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. Version @VERSION@ 2017-12-07 pst2dii 1 pst2dii @VERSION@ pst2dii extract email messages from an MS Outlook .pst file in DII load format Synopsis pst2dii -f ttf-font-file pstfilename Options -B bates-prefix Sets the bates prefix string. The bates sequence number is appended to this string, and printed on each page. -O dii-output-file Name of the output DII load file. -V Show program version. Subsequent options are then ignored. -b bates-number Starting bates sequence number. The default is zero. -c bates-color Font color for the bates stamp on each page, specified as 6 hex digits as rrggbb values. The default is ff0000 for bright red. -d debug-file Specify name of debug log file. The log file is now an ascii file, instead of the binary file used in previous versions. -f ttf-font-file Specify name of a true type font file. This should be a fixed pitch font. -h Show summary of options. Subsequent options are then ignored. -o output-directory Specifies the output directory. The directory must already exist. Description pst2dii reads the email messages from an MS Outlook .pst file and produces a DII load file that may be used to import message summaries into a Summation DII system. The DII output file contains references to the image and attachment files in the output directory. Copyright Copyright (C) 2008 by 510 Software Group <carl@five-ten-sg.com> This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. You should have received a copy of the GNU General Public License along with this program; see the file COPYING. If not, please write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. Version @VERSION@ 2017-12-07 outlook.pst 5 outlook.pst format of MS Outlook .pst file Synopsis outlook.pst Overview Low level or primitive items in a .pst file are identified by an I_ID value. Higher level or composite items in a .pst file are identified by a D_ID value. There are two separate b-trees indexed by these I_ID and D_ID values. Starting with Outlook 2003, the file format changed from one with 32 bit pointers, to one with 64 bit pointers. We describe both formats here. 32 bit File Header The 32 bit file header is located at offset 0 in the .pst file. We only support index types 0x0e, 0x0f, 0x15, and 0x17, and encryption types 0x00, 0x01 and 0x02. Index type 0x0e is the older 32 bit Outlook format. Index type 0x0f seems to be rare, and so far the data seems to be identical to that in type 0x0e files. Index type 0x17 is the newer 64 bit Outlook format. Index type 0x15 seems to be rare, and according to the libpff project should have the same format as type 0x17 files. It was found in a 64-bit pst file created by Visual Recovery. It may be that index types less than 0x10 are 32 bit, and index types greater than or equal to 0x10 are 64 bit, and the low order four bits of the index type is some subtype or minor version number. Encryption type 0x00 is no encryption, type 0x01 is "compressible" encryption which is a simple substitution cipher, and type 0x02 is "strong" encryption, which is a simple three rotor Enigma cipher from WWII. offsetIndex1 is the file offset of the root of the index1 b-tree, which contains (I_ID, offset, size, unknown) tuples for each item in the file. backPointer1 is the value that should appear in the parent pointer of that root node. offsetIndex2 is the file offset of the root of the index2 b-tree, which contains (D_ID, DESC-I_ID, TREE-I_ID, PARENT-D_ID) tuples for each item in the file. backPointer2 is the value that should appear in the parent pointer of that root node. 64 bit File Header The 64 bit file header is located at offset 0 in the .pst file. 32 bit Index 1 Node The 32 bit index1 b-tree nodes are 512 byte blocks with the following format. The itemCount specifies the number of 12 byte records that are active. The nodeLevel is non-zero for this style of nodes. The leaf nodes have a different format. The backPointer must match the backPointer from the triple that pointed to this node. Each item in this node is a triple of (I_ID, backPointer, offset) where the offset points to the next deeper node in the tree, the backPointer value must match the backPointer in that deeper node, and I_ID is the lowest I_ID value in the subtree. 64 bit Index 1 Node The 64 bit index1 b-tree nodes are 512 byte blocks with the following format. The itemCount specifies the number of 24 byte records that are active. The nodeLevel is non-zero for this style of nodes. The leaf nodes have a different format. The backPointer must match the backPointer from the triple that pointed to this node. Each item in this node is a triple of (I_ID, backPointer, offset) where the offset points to the next deeper node in the tree, the backPointer value must match the backPointer in that deeper node, and I_ID is the lowest I_ID value in the subtree. 32 bit Index 1 Leaf Node The 32 bit index1 b-tree leaf nodes are 512 byte blocks with the following format. The itemCount specifies the number of 12 byte records that are active. The nodeLevel is zero for these leaf nodes. The backPointer must match the backPointer from the triple that pointed to this node. Each item in this node is a tuple of (I_ID, offset, size, unknown) The two low order bits of the I_ID value seem to be flags. I have never seen a case with bit zero set. Bit one indicates that the item is not encrypted. Note that references to these I_ID values elsewhere may have the low order bit set (and I don't know what that means), but when we do the search in this tree we need to clear that bit so that we can find the correct item. 64 bit Index 1 Leaf Node The 64 bit index1 b-tree leaf nodes are 512 byte blocks with the following format. The itemCount specifies the number of 24 byte records that are active. The nodeLevel is zero for these leaf nodes. The backPointer must match the backPointer from the triple that pointed to this node. Each item in this node is a tuple of (I_ID, offset, size, unknown) The two low order bits of the I_ID value seem to be flags. I have never seen a case with bit zero set. Bit one indicates that the item is not encrypted. Note that references to these I_ID values elsewhere may have the low order bit set (and I don't know what that means), but when we do the search in this tree we need to clear that bit so that we can find the correct item. 32 bit Index 2 Node The 32 bit index2 b-tree nodes are 512 byte blocks with the following format. The itemCount specifies the number of 12 byte records that are active. The nodeLevel is non-zero for this style of nodes. The leaf nodes have a different format. The backPointer must match the backPointer from the triple that pointed to this node. Each item in this node is a triple of (D_ID, backPointer, offset) where the offset points to the next deeper node in the tree, the backPointer value must match the backPointer in that deeper node, and D_ID is the lowest D_ID value in the subtree. 64 bit Index 2 Node The 64 bit index2 b-tree nodes are 512 byte blocks with the following format. The itemCount specifies the number of 24 byte records that are active. The nodeLevel is non-zero for this style of nodes. The leaf nodes have a different format. The backPointer must match the backPointer from the triple that pointed to this node. Each item in this node is a triple of (D_ID, backPointer, offset) where the offset points to the next deeper node in the tree, the backPointer value must match the backPointer in that deeper node, and D_ID is the lowest D_ID value in the subtree. 32 bit Index 2 Leaf Node The 32 bit index2 b-tree leaf nodes are 512 byte blocks with the following format. The itemCount specifies the number of 16 byte records that are active. The nodeLevel is zero for these leaf nodes. The backPointer must match the backPointer from the triple that pointed to this node. Each item in this node is a tuple of (D_ID, DESC-I_ID, TREE-I_ID, PARENT-D_ID) The DESC-I_ID points to the main data for this item (Associated Descriptor Items 0x7cec, 0xbcec, or 0x0101) via the index1 tree. The TREE-I_ID is zero or points to an Associated Tree Item 0x0002 via the index1 tree. The PARENT-D_ID points to the parent of this item in this index2 tree. 64 bit Index 2 Leaf Node The 64 bit index2 b-tree leaf nodes are 512 byte blocks with the following format. The itemCount specifies the number of 32 byte records that are active. The nodeLevel is zero for these leaf nodes. The backPointer must match the backPointer from the triple that pointed to this node. Each item in this node is a tuple of (D_ID, DESC-I_ID, TREE-I_ID, PARENT-D_ID) The DESC-I_ID points to the main data for this item (Associated Descriptor Items 0x7cec, 0xbcec, or 0x0101) via the index1 tree. The TREE-I_ID is zero or points to an Associated Tree Item 0x0002 via the index1 tree. The PARENT-D_ID points to the parent of this item in this index2 tree. 32 bit Associated Tree Item 0x0002 A D_ID value may point to an entry in the index2 tree with a non-zero TREE-I_ID which points to this descriptor block via the index1 tree. It maps local ID2 values (referenced in the main data for the original D_ID item) to I_ID values. This descriptor block contains triples of (ID2, I_ID, CHILD-I_ID) where the local ID2 data can be found via I_ID, and CHILD-I_ID is either zero or it points to another Associated Tree Item via the index1 tree. In the above 32 bit leaf node, we have a tuple of (0x61, 0x02a82c, 0x02a836, 0) 0x02a836 is the I_ID of the associated tree, and we can lookup that I_ID value in the index1 b-tree to find the (offset,size) of the data in the .pst file. 64 bit Associated Tree Item 0x0002 This descriptor block contains a tree that maps local ID2 values to I_ID entries, similar to the 32 bit version described above. Associated Descriptor Item 0xbcec Contains information about the item, which may be email, contact, or other outlook types. In the above leaf node, we have a tuple of (0x21, 0x00e638, 0, 0) 0x00e638 is the I_ID of the associated descriptor, and we can lookup that I_ID value in the index1 b-tree to find the (offset,size) of the data in the .pst file. This descriptor is eventually decoded to a list of MAPI elements. Note the signature of 0xbcec. There are other descriptor block formats with other signatures. Note the indexOffset of 0x013c - starting at that position in the descriptor block, we have an array of two byte integers. The first integer (0x000b) is a (count-1) of the number of overlapping pairs following the count. The first pair is (0, 0xc), the next pair is (0xc, 0x14) and the last (12th) pair is (0x123, 0x13b). These pairs are (start,end+1) offsets of items in this block. So we have count+2 integers following the count value. Note the b5offset of 0x0020, which is a type that I will call an index reference. Such index references have at least two different forms, and may point to data either in this block, or in some other block. External pointer references have the low order 4 bits all set, and are ID2 values that can be used to fetch data. This value of 0x0020 is an internal pointer reference, which needs to be right shifted by 4 bits to become 0x0002, which is then a byte offset to be added to the above indexOffset plus two (to skip the count), so it points to the (0xc, 0x14) pair. So far we have only described internal index references where the high order 16 bits are zero. That suffices for single descriptor blocks. But in the case of the type 0x0101 descriptor block, we have an array of subblocks. In this case, the high order 16 bits of an internal index reference are used to select the subblock. Each subblock starts with a 16 bit indexOffset which points to the count and array of 16 bit integer pairs which are offsets in the current subblock. Finally, we have the offset and size of the "b5" block located at offset 0xc with a size of 8 bytes in this descriptor block. The "b5" block has the following format: Note the descoffset of 0x0040, which again is an index reference. In this case, it is an internal pointer reference, which needs to be right shifted by 4 bits to become 0x0004, which is then a byte offset to be added to the above indexOffset plus two (to skip the count), so it points to the (0x14, 0x7c) pair. The datasize (6) plus the b5 code (02) gives the size of the entries, in this case 8 bytes. We now have the offset 0x14 of the descriptor array, composed of 8 byte entries that describe MAPI elements. Each descriptor entry has the following format: For some reference types (2, 3, 0xb) the value is used directly. Otherwise, the value is an index reference, which is either an ID2 value, or an offset, to be right shifted by 4 bits and used to fetch a pair from the index table to find the offset and size of the item in this descriptor block. The following reference types are known, but not all of these are implemented in the code yet. The following item types are known, but not all of these are implemented in the code yet. Associated Descriptor Item 0x7cec This style of descriptor block is similar to the 0xbcec format. This descriptor is also eventually decoded to a list of MAPI elements. Note the signature of 0x7cec. There are other descriptor block formats with other signatures. Note the indexOffset of 0x017a - starting at that position in the descriptor block, we have an array of two byte integers. The first integer (0x0006) is a (count-1) of the number of overlapping pairs following the count. The first pair is (0, 0xc), the next pair is (0xc, 0x14) and the last (7th) pair is (0x160, 0x179). These pairs are (start,end+1) offsets of items in this block. So we have count+2 integers following the count value. Note the 7coffset of 0x0040, which is an index reference. In this case, it is an internal reference pointer, which needs to be right shifted by 4 bits to become 0x0004, which is then a byte offset to be added to the above indexOffset plus two (to skip the count), so it points to the (0x14, 0xea) pair. We have the offset and size of the "7c" block located at offset 0x14 with a size of 214 bytes in this case. The "7c" block starts with a header with the following format: Note the b5Offset of 0x0020, which is an index reference. In this case, it is an internal reference pointer, which needs to be right shifted by 4 bits to become 0x0002, which is then a byte offset to be added to the above indexOffset plus two (to skip the count), so it points to the (0xc, 0x14) pair. Finally, we have the offset and size of the "b5" block located at offset 0xc with a size of 8 bytes in this descriptor block. The "b5" block has the following format: Note the descoffset of 0x0060, which again is an index reference. In this case, it is an internal pointer reference, which needs to be right shifted by 4 bits to become 0x0006, which is then a byte offset to be added to the above indexOffset plus two (to skip the count), so it points to the (0xea, 0xf0) pair. The datasize (2) plus the b5 code (04) gives the size of the entries, in this case 6 bytes. We now have the offset 0xea of an unused block of data in an unknown format, composed of 6 byte entries. That gives us (0xf0 - 0xea)/6 = 1, so we have a recordCount of one. We have seen cases where the descoffset in the b5 block is zero, and the index2Offset in the 7c block is zero. This has been seen for objects that seem to be attachments on messages that have been read. Before the message was read, it did not have any attachments. Note the index2Offset above of 0x0080, which again is an index reference. In this case, it is an internal pointer reference, which needs to be right shifted by 4 bits to become 0x0008, which is then a byte offset to be added to the above indexOffset plus two (to skip the count), so it points to the (0xf0, 0x155) pair. This is an array of tables of four byte integers. We will call these the IND2 tables. The size of each of these tables is specified by the recordSize field of the "7c" header. The number of these tables is the above recordCount value derived from the "b5" block. Now the remaining data in the "7c" block after the header starts at offset 0x2a. There should be itemCount 8 byte items here, with the following format: The ind2Offset is a byte offset into the current IND2 table of some value. If that is a four byte integer value, then once we fetch that, we have the same triple (item type, reference type, value) as we find in the 0xbcec style descriptor blocks. If not, then this value is used directly. These 8 byte descriptors are processed recordCount times, each time using the next IND2 table. The item and reference types are as described above for the 0xbcec format descriptor block. 32 bit Associated Descriptor Item 0x0101 This descriptor block contains a list of I_ID values. It is used when an I_ID (that would normally point to a type 0x7cec or 0xbcec descriptor block) contains more data than can fit in any single descriptor of those types. In this case, it points to a type 0x0101 block, which contains a list of I_ID values that themselves point to the actual descriptor blocks. The total length value in the 0x0101 header is the sum of the lengths of the blocks pointed to by the list of I_ID values. The result is an array of subblocks, that may contain index references where the high order 16 bits specify which descriptor subblock to use. Only the first descriptor subblock contains the signature (0xbcec or 0x7cec). 64 bit Associated Descriptor Item 0x0101 This descriptor block contains a list of I_ID values, similar to the 32 bit version described above.