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mirror of https://github.com/VCMP-SqMod/SqMod.git synced 2024-11-08 08:47:17 +01:00
SqMod/external/MaxmindDB/maxminddb.c
Sandu Liviu Catalin 70e5f0ba21 Migrated the host module to C++ exceptions as well.
Also enabled the latest C++ revision in the project.
Replaced the Random library with the one provided by C++11.
Implemented a simple AES256 encryption class.
Various other fixes and improvements.
2016-03-10 05:57:13 +02:00

2046 lines
64 KiB
C

#if HAVE_CONFIG_H
#include <config.h>
#endif
#include "maxminddb.h"
#include "maxminddb-compat-util.h"
#include <assert.h>
#include <errno.h>
#include <fcntl.h>
#include <inttypes.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <sys/stat.h>
#ifdef _WIN32
#include <windows.h>
#include <ws2ipdef.h>
#else
#include <arpa/inet.h>
#include <sys/mman.h>
#include <unistd.h>
#endif
#define MMDB_DATA_SECTION_SEPARATOR (16)
#define MAXIMUM_DATA_STRUCTURE_DEPTH (512)
#ifdef MMDB_DEBUG
#define LOCAL
#define NO_PROTO
#define DEBUG_FUNC
#define DEBUG_MSG(msg) fprintf(stderr, msg "\n")
#define DEBUG_MSGF(fmt, ...) fprintf(stderr, fmt "\n", __VA_ARGS__)
#define DEBUG_BINARY(fmt, byte) \
do { \
char *binary = byte_to_binary(byte); \
if (NULL == binary) { \
fprintf(stderr, "Malloc failed in DEBUG_BINARY\n"); \
abort(); \
} \
fprintf(stderr, fmt "\n", binary); \
free(binary); \
} while (0)
#define DEBUG_NL fprintf(stderr, "\n")
#else
#define LOCAL static
#define NO_PROTO static
#define DEBUG_MSG(...)
#define DEBUG_MSGF(...)
#define DEBUG_BINARY(...)
#define DEBUG_NL
#endif
#ifdef MMDB_DEBUG
DEBUG_FUNC char *byte_to_binary(uint8_t byte)
{
char *bits = malloc(sizeof(char) * 9);
if (NULL == bits) {
return bits;
}
for (uint8_t i = 0; i < 8; i++) {
bits[i] = byte & (128 >> i) ? '1' : '0';
}
bits[8] = '\0';
return bits;
}
DEBUG_FUNC char *type_num_to_name(uint8_t num)
{
switch (num) {
case 0:
return "extended";
case 1:
return "pointer";
case 2:
return "utf8_string";
case 3:
return "double";
case 4:
return "bytes";
case 5:
return "uint16";
case 6:
return "uint32";
case 7:
return "map";
case 8:
return "int32";
case 9:
return "uint64";
case 10:
return "uint128";
case 11:
return "array";
case 12:
return "container";
case 13:
return "end_marker";
case 14:
return "boolean";
case 15:
return "float";
default:
return "unknown type";
}
}
#endif
/* None of the values we check on the lhs are bigger than uint32_t, so on
* platforms where SIZE_MAX is a 64-bit integer, this would be a no-op, and it
* makes the compiler complain if we do the check anyway. */
#if SIZE_MAX == UINT32_MAX
#define MAYBE_CHECK_SIZE_OVERFLOW(lhs, rhs, error) \
if ((lhs) > (rhs)) { \
return error; \
}
#else
#define MAYBE_CHECK_SIZE_OVERFLOW(...)
#endif
typedef struct record_info_s {
uint16_t record_length;
uint32_t (*left_record_getter)(const uint8_t *);
uint32_t (*right_record_getter)(const uint8_t *);
uint8_t right_record_offset;
} record_info_s;
#define METADATA_MARKER "\xab\xcd\xefMaxMind.com"
/* This is 128kb */
#define METADATA_BLOCK_MAX_SIZE 131072
/* *INDENT-OFF* */
/* --prototypes automatically generated by dev-bin/regen-prototypes.pl - don't remove this comment */
LOCAL int map_file(MMDB_s *const mmdb);
LOCAL const uint8_t *find_metadata(const uint8_t *file_content,
ssize_t file_size, uint32_t *metadata_size);
LOCAL int read_metadata(MMDB_s *mmdb);
LOCAL MMDB_s make_fake_metadata_db(MMDB_s *mmdb);
LOCAL int value_for_key_as_uint16(MMDB_entry_s *start, char *key,
uint16_t *value);
LOCAL int value_for_key_as_uint32(MMDB_entry_s *start, char *key,
uint32_t *value);
LOCAL int value_for_key_as_uint64(MMDB_entry_s *start, char *key,
uint64_t *value);
LOCAL int value_for_key_as_string(MMDB_entry_s *start, char *key,
char const **value);
LOCAL int populate_languages_metadata(MMDB_s *mmdb, MMDB_s *metadata_db,
MMDB_entry_s *metadata_start);
LOCAL int populate_description_metadata(MMDB_s *mmdb, MMDB_s *metadata_db,
MMDB_entry_s *metadata_start);
LOCAL int resolve_any_address(const char *ipstr, struct addrinfo **addresses);
LOCAL int find_address_in_search_tree(MMDB_s *mmdb, uint8_t *address,
sa_family_t address_family,
MMDB_lookup_result_s *result);
LOCAL record_info_s record_info_for_database(MMDB_s *mmdb);
LOCAL int find_ipv4_start_node(MMDB_s *mmdb);
LOCAL int populate_result(MMDB_s *mmdb, uint32_t node_count, uint32_t value,
uint16_t netmask, MMDB_lookup_result_s *result);
LOCAL uint32_t get_left_28_bit_record(const uint8_t *record);
LOCAL uint32_t get_right_28_bit_record(const uint8_t *record);
LOCAL int path_length(va_list va_path);
LOCAL int lookup_path_in_array(const char *path_elem, MMDB_s *mmdb,
MMDB_entry_data_s *entry_data);
LOCAL int lookup_path_in_map(const char *path_elem, MMDB_s *mmdb,
MMDB_entry_data_s *entry_data);
LOCAL int skip_map_or_array(MMDB_s *mmdb, MMDB_entry_data_s *entry_data);
LOCAL int decode_one_follow(MMDB_s *mmdb, uint32_t offset,
MMDB_entry_data_s *entry_data);
LOCAL int decode_one(MMDB_s *mmdb, uint32_t offset,
MMDB_entry_data_s *entry_data);
LOCAL int get_ext_type(int raw_ext_type);
LOCAL uint32_t get_ptr_from(uint8_t ctrl, uint8_t const *const ptr,
int ptr_size);
LOCAL int get_entry_data_list(MMDB_s *mmdb, uint32_t offset,
MMDB_entry_data_list_s *const entry_data_list,
int depth);
LOCAL float get_ieee754_float(const uint8_t *restrict p);
LOCAL double get_ieee754_double(const uint8_t *restrict p);
LOCAL uint32_t get_uint32(const uint8_t *p);
LOCAL uint32_t get_uint24(const uint8_t *p);
LOCAL uint32_t get_uint16(const uint8_t *p);
LOCAL uint64_t get_uintX(const uint8_t *p, int length);
LOCAL int32_t get_sintX(const uint8_t *p, int length);
LOCAL MMDB_entry_data_list_s *new_entry_data_list(void);
LOCAL void free_mmdb_struct(MMDB_s *const mmdb);
LOCAL void free_languages_metadata(MMDB_s *mmdb);
LOCAL void free_descriptions_metadata(MMDB_s *mmdb);
LOCAL MMDB_entry_data_list_s *dump_entry_data_list(
FILE *stream, MMDB_entry_data_list_s *entry_data_list, int indent,
int *status);
LOCAL void print_indentation(FILE *stream, int i);
LOCAL char *bytes_to_hex(uint8_t *bytes, uint32_t size);
/* --prototypes end - don't remove this comment-- */
/* *INDENT-ON* */
#define CHECKED_DECODE_ONE(mmdb, offset, entry_data) \
do { \
int status = decode_one(mmdb, offset, entry_data); \
if (MMDB_SUCCESS != status) { \
return status; \
} \
} while (0)
#define CHECKED_DECODE_ONE_FOLLOW(mmdb, offset, entry_data) \
do { \
int status = decode_one_follow(mmdb, offset, entry_data); \
if (MMDB_SUCCESS != status) { \
return status; \
} \
} while (0)
#define FREE_AND_SET_NULL(p) { free((void *)(p)); (p) = NULL; }
int MMDB_open(const char *const filename, uint32_t flags, MMDB_s *const mmdb)
{
int status = MMDB_SUCCESS;
mmdb->file_content = NULL;
mmdb->data_section = NULL;
mmdb->metadata.database_type = NULL;
mmdb->metadata.languages.count = 0;
mmdb->metadata.description.count = 0;
mmdb->filename = mmdb_strdup(filename);
if (NULL == mmdb->filename) {
status = MMDB_OUT_OF_MEMORY_ERROR;
goto cleanup;
}
if ((flags & MMDB_MODE_MASK) == 0) {
flags |= MMDB_MODE_MMAP;
}
mmdb->flags = flags;
if (MMDB_SUCCESS != (status = map_file(mmdb)) ) {
goto cleanup;
}
#ifdef _WIN32
WSADATA wsa;
WSAStartup(MAKEWORD(2, 2), &wsa);
#endif
uint32_t metadata_size = 0;
const uint8_t *metadata = find_metadata(mmdb->file_content, mmdb->file_size,
&metadata_size);
if (NULL == metadata) {
status = MMDB_INVALID_METADATA_ERROR;
goto cleanup;
}
mmdb->metadata_section = metadata;
mmdb->metadata_section_size = metadata_size;
status = read_metadata(mmdb);
if (MMDB_SUCCESS != status) {
goto cleanup;
}
if (mmdb->metadata.binary_format_major_version != 2) {
status = MMDB_UNKNOWN_DATABASE_FORMAT_ERROR;
goto cleanup;
}
uint32_t search_tree_size = mmdb->metadata.node_count *
mmdb->full_record_byte_size;
mmdb->data_section = mmdb->file_content + search_tree_size;
if (search_tree_size > (uint32_t)mmdb->file_size) {
status = MMDB_INVALID_METADATA_ERROR;
goto cleanup;
}
mmdb->data_section_size = mmdb->file_size - search_tree_size;
mmdb->metadata_section = metadata;
mmdb->ipv4_start_node.node_value = 0;
mmdb->ipv4_start_node.netmask = 0;
cleanup:
if (MMDB_SUCCESS != status) {
int saved_errno = errno;
free_mmdb_struct(mmdb);
errno = saved_errno;
}
return status;
}
#ifdef _WIN32
LOCAL int map_file(MMDB_s *const mmdb)
{
ssize_t size;
int status = MMDB_SUCCESS;
HANDLE mmh = NULL;
HANDLE fd = CreateFileA(mmdb->filename, GENERIC_READ, FILE_SHARE_READ, NULL,
OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, NULL);
if (fd == INVALID_HANDLE_VALUE) {
status = MMDB_FILE_OPEN_ERROR;
goto cleanup;
}
size = GetFileSize(fd, NULL);
if (size == INVALID_FILE_SIZE) {
status = MMDB_FILE_OPEN_ERROR;
goto cleanup;
}
mmh = CreateFileMappingA(fd, NULL, PAGE_READONLY, 0, size, NULL);
/* Microsoft documentation for CreateFileMapping indicates this returns
NULL not INVALID_HANDLE_VALUE on error */
if (NULL == mmh) {
status = MMDB_IO_ERROR;
goto cleanup;
}
uint8_t *file_content =
(uint8_t *)MapViewOfFile(mmh, FILE_MAP_READ, 0, 0, 0);
if (file_content == NULL) {
status = MMDB_IO_ERROR;
goto cleanup;
}
mmdb->file_size = size;
mmdb->file_content = file_content;
cleanup:;
int saved_errno = errno;
if (INVALID_HANDLE_VALUE != fd) {
CloseHandle(fd);
}
if (NULL != mmh) {
CloseHandle(mmh);
}
errno = saved_errno;
return status;
}
#else
LOCAL int map_file(MMDB_s *const mmdb)
{
ssize_t size;
int status = MMDB_SUCCESS;
int fd = open(mmdb->filename, O_RDONLY);
struct stat s;
if (fd < 0 || fstat(fd, &s)) {
status = MMDB_FILE_OPEN_ERROR;
goto cleanup;
}
size = s.st_size;
if (size < 0 || size != s.st_size) {
status = MMDB_OUT_OF_MEMORY_ERROR;
goto cleanup;
}
uint8_t *file_content =
(uint8_t *)mmap(NULL, size, PROT_READ, MAP_SHARED, fd, 0);
if (MAP_FAILED == file_content) {
if (ENOMEM == errno) {
status = MMDB_OUT_OF_MEMORY_ERROR;
} else {
status = MMDB_IO_ERROR;
}
goto cleanup;
}
mmdb->file_size = size;
mmdb->file_content = file_content;
cleanup:;
int saved_errno = errno;
if (fd >= 0) {
close(fd);
}
errno = saved_errno;
return status;
}
#endif
LOCAL const uint8_t *find_metadata(const uint8_t *file_content,
ssize_t file_size, uint32_t *metadata_size)
{
const ssize_t marker_len = sizeof(METADATA_MARKER) - 1;
ssize_t max_size = file_size >
METADATA_BLOCK_MAX_SIZE ? METADATA_BLOCK_MAX_SIZE :
file_size;
uint8_t *search_area = (uint8_t *)(file_content + (file_size - max_size));
uint8_t *start = search_area;
uint8_t *tmp;
do {
tmp = mmdb_memmem(search_area, max_size,
METADATA_MARKER, marker_len);
if (NULL != tmp) {
max_size -= tmp - search_area;
search_area = tmp;
/* Continue searching just after the marker we just read, in case
* there are multiple markers in the same file. This would be odd
* but is certainly not impossible. */
max_size -= marker_len;
search_area += marker_len;
}
} while (NULL != tmp);
if (search_area == start) {
return NULL;
}
*metadata_size = max_size;
return search_area;
}
LOCAL int read_metadata(MMDB_s *mmdb)
{
/* We need to create a fake MMDB_s struct in order to decode values from
the metadata. The metadata is basically just like the data section, so we
want to use the same functions we use for the data section to get metadata
values. */
MMDB_s metadata_db = make_fake_metadata_db(mmdb);
MMDB_entry_s metadata_start = {
.mmdb = &metadata_db,
.offset = 0
};
int status =
value_for_key_as_uint32(&metadata_start, "node_count",
&mmdb->metadata.node_count);
if (MMDB_SUCCESS != status) {
return status;
}
if (!mmdb->metadata.node_count) {
DEBUG_MSG("could not find node_count value in metadata");
return MMDB_INVALID_METADATA_ERROR;
}
status = value_for_key_as_uint16(&metadata_start, "record_size",
&mmdb->metadata.record_size);
if (MMDB_SUCCESS != status) {
return status;
}
if (!mmdb->metadata.record_size) {
DEBUG_MSG("could not find record_size value in metadata");
return MMDB_INVALID_METADATA_ERROR;
}
if (mmdb->metadata.record_size != 24 && mmdb->metadata.record_size != 28
&& mmdb->metadata.record_size != 32) {
DEBUG_MSGF("bad record size in metadata: %i",
mmdb->metadata.record_size);
return MMDB_UNKNOWN_DATABASE_FORMAT_ERROR;
}
status = value_for_key_as_uint16(&metadata_start, "ip_version",
&mmdb->metadata.ip_version);
if (MMDB_SUCCESS != status) {
return status;
}
if (!mmdb->metadata.ip_version) {
DEBUG_MSG("could not find ip_version value in metadata");
return MMDB_INVALID_METADATA_ERROR;
}
if (!(mmdb->metadata.ip_version == 4 || mmdb->metadata.ip_version == 6)) {
DEBUG_MSGF("ip_version value in metadata is not 4 or 6 - it was %i",
mmdb->metadata.ip_version);
return MMDB_INVALID_METADATA_ERROR;
}
status = value_for_key_as_string(&metadata_start, "database_type",
&mmdb->metadata.database_type);
if (MMDB_SUCCESS != status) {
DEBUG_MSG("error finding database_type value in metadata");
return status;
}
status =
populate_languages_metadata(mmdb, &metadata_db, &metadata_start);
if (MMDB_SUCCESS != status) {
DEBUG_MSG("could not populate languages from metadata");
return status;
}
status = value_for_key_as_uint16(
&metadata_start, "binary_format_major_version",
&mmdb->metadata.binary_format_major_version);
if (MMDB_SUCCESS != status) {
return status;
}
if (!mmdb->metadata.binary_format_major_version) {
DEBUG_MSG(
"could not find binary_format_major_version value in metadata");
return MMDB_INVALID_METADATA_ERROR;
}
status = value_for_key_as_uint16(
&metadata_start, "binary_format_minor_version",
&mmdb->metadata.binary_format_minor_version);
if (MMDB_SUCCESS != status) {
return status;
}
status = value_for_key_as_uint64(&metadata_start, "build_epoch",
&mmdb->metadata.build_epoch);
if (MMDB_SUCCESS != status) {
return status;
}
if (!mmdb->metadata.build_epoch) {
DEBUG_MSG("could not find build_epoch value in metadata");
return MMDB_INVALID_METADATA_ERROR;
}
status = populate_description_metadata(mmdb, &metadata_db, &metadata_start);
if (MMDB_SUCCESS != status) {
DEBUG_MSG("could not populate description from metadata");
return status;
}
mmdb->full_record_byte_size = mmdb->metadata.record_size * 2 / 8U;
mmdb->depth = mmdb->metadata.ip_version == 4 ? 32 : 128;
return MMDB_SUCCESS;
}
LOCAL MMDB_s make_fake_metadata_db(MMDB_s *mmdb)
{
MMDB_s fake_metadata_db = {
.data_section = mmdb->metadata_section,
.data_section_size = mmdb->metadata_section_size
};
return fake_metadata_db;
}
LOCAL int value_for_key_as_uint16(MMDB_entry_s *start, char *key,
uint16_t *value)
{
MMDB_entry_data_s entry_data;
const char *path[] = { key, NULL };
int status = MMDB_aget_value(start, &entry_data, path);
if (MMDB_SUCCESS != status) {
return status;
}
if (MMDB_DATA_TYPE_UINT16 != entry_data.type) {
DEBUG_MSGF("expect uint16 for %s but received %s", key,
type_num_to_name(
entry_data.type));
return MMDB_INVALID_METADATA_ERROR;
}
*value = entry_data.uint16;
return MMDB_SUCCESS;
}
LOCAL int value_for_key_as_uint32(MMDB_entry_s *start, char *key,
uint32_t *value)
{
MMDB_entry_data_s entry_data;
const char *path[] = { key, NULL };
int status = MMDB_aget_value(start, &entry_data, path);
if (MMDB_SUCCESS != status) {
return status;
}
if (MMDB_DATA_TYPE_UINT32 != entry_data.type) {
DEBUG_MSGF("expect uint32 for %s but received %s", key,
type_num_to_name(
entry_data.type));
return MMDB_INVALID_METADATA_ERROR;
}
*value = entry_data.uint32;
return MMDB_SUCCESS;
}
LOCAL int value_for_key_as_uint64(MMDB_entry_s *start, char *key,
uint64_t *value)
{
MMDB_entry_data_s entry_data;
const char *path[] = { key, NULL };
int status = MMDB_aget_value(start, &entry_data, path);
if (MMDB_SUCCESS != status) {
return status;
}
if (MMDB_DATA_TYPE_UINT64 != entry_data.type) {
DEBUG_MSGF("expect uint64 for %s but received %s", key,
type_num_to_name(
entry_data.type));
return MMDB_INVALID_METADATA_ERROR;
}
*value = entry_data.uint64;
return MMDB_SUCCESS;
}
LOCAL int value_for_key_as_string(MMDB_entry_s *start, char *key,
char const **value)
{
MMDB_entry_data_s entry_data;
const char *path[] = { key, NULL };
int status = MMDB_aget_value(start, &entry_data, path);
if (MMDB_SUCCESS != status) {
return status;
}
if (MMDB_DATA_TYPE_UTF8_STRING != entry_data.type) {
DEBUG_MSGF("expect string for %s but received %s", key,
type_num_to_name(
entry_data.type));
return MMDB_INVALID_METADATA_ERROR;
}
*value = mmdb_strndup((char *)entry_data.utf8_string, entry_data.data_size);
if (NULL == *value) {
return MMDB_OUT_OF_MEMORY_ERROR;
}
return MMDB_SUCCESS;
}
LOCAL int populate_languages_metadata(MMDB_s *mmdb, MMDB_s *metadata_db,
MMDB_entry_s *metadata_start)
{
MMDB_entry_data_s entry_data;
const char *path[] = { "languages", NULL };
int status = MMDB_aget_value(metadata_start, &entry_data, path);
if (MMDB_SUCCESS != status) {
return status;
}
if (MMDB_DATA_TYPE_ARRAY != entry_data.type) {
return MMDB_INVALID_METADATA_ERROR;
}
MMDB_entry_s array_start = {
.mmdb = metadata_db,
.offset = entry_data.offset
};
MMDB_entry_data_list_s *member;
status = MMDB_get_entry_data_list(&array_start, &member);
if (MMDB_SUCCESS != status) {
return status;
}
MMDB_entry_data_list_s *first_member = member;
uint32_t array_size = member->entry_data.data_size;
MAYBE_CHECK_SIZE_OVERFLOW(array_size, SIZE_MAX / sizeof(char *),
MMDB_INVALID_METADATA_ERROR);
mmdb->metadata.languages.count = 0;
mmdb->metadata.languages.names = malloc(array_size * sizeof(char *));
if (NULL == mmdb->metadata.languages.names) {
return MMDB_OUT_OF_MEMORY_ERROR;
}
for (uint32_t i = 0; i < array_size; i++) {
member = member->next;
if (MMDB_DATA_TYPE_UTF8_STRING != member->entry_data.type) {
return MMDB_INVALID_METADATA_ERROR;
}
mmdb->metadata.languages.names[i] =
mmdb_strndup((char *)member->entry_data.utf8_string,
member->entry_data.data_size);
if (NULL == mmdb->metadata.languages.names[i]) {
return MMDB_OUT_OF_MEMORY_ERROR;
}
// We assign this as we go so that if we fail a malloc and need to
// free it, the count is right.
mmdb->metadata.languages.count = i + 1;
}
MMDB_free_entry_data_list(first_member);
return MMDB_SUCCESS;
}
LOCAL int populate_description_metadata(MMDB_s *mmdb, MMDB_s *metadata_db,
MMDB_entry_s *metadata_start)
{
MMDB_entry_data_s entry_data;
const char *path[] = { "description", NULL };
int status = MMDB_aget_value(metadata_start, &entry_data, path);
if (MMDB_SUCCESS != status) {
return status;
}
if (MMDB_DATA_TYPE_MAP != entry_data.type) {
return MMDB_INVALID_METADATA_ERROR;
}
MMDB_entry_s map_start = {
.mmdb = metadata_db,
.offset = entry_data.offset
};
MMDB_entry_data_list_s *member;
status = MMDB_get_entry_data_list(&map_start, &member);
if (MMDB_SUCCESS != status) {
return status;
}
MMDB_entry_data_list_s *first_member = member;
uint32_t map_size = member->entry_data.data_size;
mmdb->metadata.description.count = 0;
if (0 == map_size) {
mmdb->metadata.description.descriptions = NULL;
goto cleanup;
}
MAYBE_CHECK_SIZE_OVERFLOW(map_size, SIZE_MAX / sizeof(MMDB_description_s *),
MMDB_INVALID_METADATA_ERROR);
mmdb->metadata.description.descriptions =
malloc(map_size * sizeof(MMDB_description_s *));
if (NULL == mmdb->metadata.description.descriptions) {
status = MMDB_OUT_OF_MEMORY_ERROR;
goto cleanup;
}
for (uint32_t i = 0; i < map_size; i++) {
mmdb->metadata.description.descriptions[i] =
malloc(sizeof(MMDB_description_s));
if (NULL == mmdb->metadata.description.descriptions[i]) {
status = MMDB_OUT_OF_MEMORY_ERROR;
goto cleanup;
}
mmdb->metadata.description.count = i + 1;
mmdb->metadata.description.descriptions[i]->language = NULL;
mmdb->metadata.description.descriptions[i]->description = NULL;
member = member->next;
if (MMDB_DATA_TYPE_UTF8_STRING != member->entry_data.type) {
status = MMDB_INVALID_METADATA_ERROR;
goto cleanup;
}
mmdb->metadata.description.descriptions[i]->language =
mmdb_strndup((char *)member->entry_data.utf8_string,
member->entry_data.data_size);
if (NULL == mmdb->metadata.description.descriptions[i]->language) {
status = MMDB_OUT_OF_MEMORY_ERROR;
goto cleanup;
}
member = member->next;
if (MMDB_DATA_TYPE_UTF8_STRING != member->entry_data.type) {
status = MMDB_INVALID_METADATA_ERROR;
goto cleanup;
}
mmdb->metadata.description.descriptions[i]->description =
mmdb_strndup((char *)member->entry_data.utf8_string,
member->entry_data.data_size);
if (NULL == mmdb->metadata.description.descriptions[i]->description) {
status = MMDB_OUT_OF_MEMORY_ERROR;
goto cleanup;
}
}
cleanup:
MMDB_free_entry_data_list(first_member);
return status;
}
MMDB_lookup_result_s MMDB_lookup_string(MMDB_s *const mmdb,
const char *const ipstr,
int *const gai_error,
int *const mmdb_error)
{
MMDB_lookup_result_s result = {
.found_entry = false,
.netmask = 0,
.entry = {
.mmdb = mmdb,
.offset = 0
}
};
struct addrinfo *addresses = NULL;
*gai_error = resolve_any_address(ipstr, &addresses);
if (!*gai_error) {
result = MMDB_lookup_sockaddr(mmdb, addresses->ai_addr, mmdb_error);
}
if (NULL != addresses) {
freeaddrinfo(addresses);
}
return result;
}
LOCAL int resolve_any_address(const char *ipstr, struct addrinfo **addresses)
{
struct addrinfo hints = {
.ai_family = AF_UNSPEC,
.ai_flags = AI_NUMERICHOST,
// We set ai_socktype so that we only get one result back
.ai_socktype = SOCK_STREAM
};
int gai_status = getaddrinfo(ipstr, NULL, &hints, addresses);
if (gai_status) {
return gai_status;
}
return 0;
}
MMDB_lookup_result_s MMDB_lookup_sockaddr(
MMDB_s *const mmdb,
const struct sockaddr *const sockaddr,
int *const mmdb_error)
{
MMDB_lookup_result_s result = {
.found_entry = false,
.netmask = 0,
.entry = {
.mmdb = mmdb,
.offset = 0
}
};
uint8_t mapped_address[16], *address;
if (mmdb->metadata.ip_version == 4) {
if (sockaddr->sa_family == AF_INET6) {
*mmdb_error = MMDB_IPV6_LOOKUP_IN_IPV4_DATABASE_ERROR;
return result;
}
address = (uint8_t *)&((struct sockaddr_in *)sockaddr)->sin_addr.s_addr;
} else {
if (sockaddr->sa_family == AF_INET6) {
address =
(uint8_t *)&((struct sockaddr_in6 *)sockaddr)->sin6_addr.
s6_addr;
} else {
address = mapped_address;
memset(address, 0, 12);
memcpy(address + 12,
&((struct sockaddr_in *)sockaddr)->sin_addr.s_addr, 4);
}
}
*mmdb_error =
find_address_in_search_tree(mmdb, address, sockaddr->sa_family,
&result);
return result;
}
LOCAL int find_address_in_search_tree(MMDB_s *mmdb, uint8_t *address,
sa_family_t address_family,
MMDB_lookup_result_s *result)
{
record_info_s record_info = record_info_for_database(mmdb);
if (0 == record_info.right_record_offset) {
return MMDB_UNKNOWN_DATABASE_FORMAT_ERROR;
}
DEBUG_NL;
DEBUG_MSG("Looking for address in search tree");
uint32_t node_count = mmdb->metadata.node_count;
uint32_t value = 0;
uint16_t max_depth0 = mmdb->depth - 1;
uint16_t start_bit = max_depth0;
if (mmdb->metadata.ip_version == 6 && address_family == AF_INET) {
int mmdb_error = find_ipv4_start_node(mmdb);
if (MMDB_SUCCESS != mmdb_error) {
return mmdb_error;
}
DEBUG_MSGF("IPv4 start node is %u (netmask %u)",
mmdb->ipv4_start_node.node_value,
mmdb->ipv4_start_node.netmask);
/* We have an IPv6 database with no IPv4 data */
if (mmdb->ipv4_start_node.node_value >= node_count) {
return populate_result(mmdb, node_count,
mmdb->ipv4_start_node.node_value,
mmdb->ipv4_start_node.netmask,
result);
}
value = mmdb->ipv4_start_node.node_value;
start_bit -= mmdb->ipv4_start_node.netmask;
}
const uint8_t *search_tree = mmdb->file_content;
const uint8_t *record_pointer;
for (int current_bit = start_bit; current_bit >= 0; current_bit--) {
uint8_t bit_is_true =
address[(max_depth0 - current_bit) >> 3]
& (1U << (~(max_depth0 - current_bit) & 7)) ? 1 : 0;
DEBUG_MSGF("Looking at bit %i - bit's value is %i", current_bit,
bit_is_true);
DEBUG_MSGF(" current node = %u", value);
record_pointer = &search_tree[value * record_info.record_length];
if (record_pointer + record_info.record_length > mmdb->data_section) {
return MMDB_CORRUPT_SEARCH_TREE_ERROR;
}
if (bit_is_true) {
record_pointer += record_info.right_record_offset;
value = record_info.right_record_getter(record_pointer);
} else {
value = record_info.left_record_getter(record_pointer);
}
/* Ideally we'd check to make sure that a record never points to a
* previously seen value, but that's more complicated. For now, we can
* at least check that we don't end up at the top of the tree again. */
if (0 == value) {
DEBUG_MSGF(" %s record has a value of 0",
bit_is_true ? "right" : "left");
return MMDB_CORRUPT_SEARCH_TREE_ERROR;
}
if (value >= node_count) {
return populate_result(mmdb, node_count, value, current_bit, result);
} else {
DEBUG_MSGF(" proceeding to search tree node %i", value);
}
}
DEBUG_MSG(
"Reached the end of the address bits without leaving the search tree");
// We should not be able to reach this return. If we do, something very bad happened.
return MMDB_CORRUPT_SEARCH_TREE_ERROR;
}
LOCAL record_info_s record_info_for_database(MMDB_s *mmdb)
{
record_info_s record_info = {
.record_length = mmdb->full_record_byte_size,
.right_record_offset = 0
};
if (record_info.record_length == 6) {
record_info.left_record_getter = &get_uint24;
record_info.right_record_getter = &get_uint24;
record_info.right_record_offset = 3;
} else if (record_info.record_length == 7) {
record_info.left_record_getter = &get_left_28_bit_record;
record_info.right_record_getter = &get_right_28_bit_record;
record_info.right_record_offset = 3;
} else if (record_info.record_length == 8) {
record_info.left_record_getter = &get_uint32;
record_info.right_record_getter = &get_uint32;
record_info.right_record_offset = 4;
} else {
assert(false);
}
return record_info;
}
LOCAL int find_ipv4_start_node(MMDB_s *mmdb)
{
/* In a pathological case of a database with a single node search tree,
* this check will be true even after we've found the IPv4 start node, but
* that doesn't seem worth trying to fix. */
if (mmdb->ipv4_start_node.node_value != 0) {
return MMDB_SUCCESS;
}
record_info_s record_info = record_info_for_database(mmdb);
const uint8_t *search_tree = mmdb->file_content;
uint32_t node_value = 0;
const uint8_t *record_pointer;
uint32_t netmask;
for (netmask = 0; netmask < 96; netmask++) {
record_pointer = &search_tree[node_value * record_info.record_length];
if (record_pointer + record_info.record_length > mmdb->data_section) {
return MMDB_CORRUPT_SEARCH_TREE_ERROR;
}
node_value = record_info.left_record_getter(record_pointer);
/* This can happen if there's no IPv4 data _or_ if there is a subnet
* with data that contains the entire IPv4 range (like ::/64) */
if (node_value >= mmdb->metadata.node_count) {
break;
}
}
mmdb->ipv4_start_node.node_value = node_value;
mmdb->ipv4_start_node.netmask = netmask;
return MMDB_SUCCESS;
}
LOCAL int populate_result(MMDB_s *mmdb, uint32_t node_count, uint32_t value,
uint16_t netmask, MMDB_lookup_result_s *result)
{
uint32_t offset = value - node_count;
DEBUG_MSGF(" data section offset is %i (record value = %i)", offset, value);
if (offset > mmdb->data_section_size) {
return MMDB_CORRUPT_SEARCH_TREE_ERROR;
}
result->netmask = mmdb->depth - netmask;
result->entry.offset = offset;
result->found_entry = result->entry.offset > 0 ? true : false;
return MMDB_SUCCESS;
}
LOCAL uint32_t get_left_28_bit_record(const uint8_t *record)
{
return record[0] * 65536 + record[1] * 256 + record[2] +
((record[3] & 0xf0) << 20);
}
LOCAL uint32_t get_right_28_bit_record(const uint8_t *record)
{
uint32_t value = get_uint32(record);
return value & 0xfffffff;
}
int MMDB_read_node(MMDB_s *const mmdb, uint32_t node_number,
MMDB_search_node_s *const node)
{
record_info_s record_info = record_info_for_database(mmdb);
if (0 == record_info.right_record_offset) {
return MMDB_UNKNOWN_DATABASE_FORMAT_ERROR;
}
if (node_number > mmdb->metadata.node_count) {
return MMDB_INVALID_NODE_NUMBER_ERROR;
}
const uint8_t *search_tree = mmdb->file_content;
const uint8_t *record_pointer =
&search_tree[node_number * record_info.record_length];
node->left_record = record_info.left_record_getter(record_pointer);
record_pointer += record_info.right_record_offset;
node->right_record = record_info.right_record_getter(record_pointer);
return MMDB_SUCCESS;
}
int MMDB_get_value(MMDB_entry_s *const start,
MMDB_entry_data_s *const entry_data,
...)
{
va_list path;
va_start(path, entry_data);
int status = MMDB_vget_value(start, entry_data, path);
va_end(path);
return status;
}
int MMDB_vget_value(MMDB_entry_s *const start,
MMDB_entry_data_s *const entry_data,
va_list va_path)
{
int length = path_length(va_path);
const char *path_elem;
int i = 0;
MAYBE_CHECK_SIZE_OVERFLOW(length, SIZE_MAX / sizeof(const char *) - 1,
MMDB_INVALID_METADATA_ERROR);
const char **path = malloc((length + 1) * sizeof(const char *));
if (NULL == path) {
return MMDB_OUT_OF_MEMORY_ERROR;
}
while (NULL != (path_elem = va_arg(va_path, char *))) {
path[i] = path_elem;
i++;
}
path[i] = NULL;
int status = MMDB_aget_value(start, entry_data, path);
free((char **)path);
return status;
}
LOCAL int path_length(va_list va_path)
{
int i = 0;
const char *ignore;
va_list path_copy;
va_copy(path_copy, va_path);
while (NULL != (ignore = va_arg(path_copy, char *))) {
i++;
}
va_end(path_copy);
return i;
}
int MMDB_aget_value(MMDB_entry_s *const start,
MMDB_entry_data_s *const entry_data,
const char *const *const path)
{
MMDB_s *mmdb = start->mmdb;
uint32_t offset = start->offset;
memset(entry_data, 0, sizeof(MMDB_entry_data_s));
DEBUG_NL;
DEBUG_MSG("looking up value by path");
CHECKED_DECODE_ONE_FOLLOW(mmdb, offset, entry_data);
DEBUG_NL;
DEBUG_MSGF("top level element is a %s", type_num_to_name(entry_data->type));
/* Can this happen? It'd probably represent a pathological case under
* normal use, but there's nothing preventing someone from passing an
* invalid MMDB_entry_s struct to this function */
if (!entry_data->has_data) {
return MMDB_INVALID_LOOKUP_PATH_ERROR;
}
const char *path_elem;
int i = 0;
while (NULL != (path_elem = path[i++])) {
DEBUG_NL;
DEBUG_MSGF("path elem = %s", path_elem);
/* XXX - it'd be good to find a quicker way to skip through these
entries that doesn't involve decoding them
completely. Basically we need to just use the size from the
control byte to advance our pointer rather than calling
decode_one(). */
if (entry_data->type == MMDB_DATA_TYPE_ARRAY) {
int status = lookup_path_in_array(path_elem, mmdb, entry_data);
if (MMDB_SUCCESS != status) {
memset(entry_data, 0, sizeof(MMDB_entry_data_s));
return status;
}
} else if (entry_data->type == MMDB_DATA_TYPE_MAP) {
int status = lookup_path_in_map(path_elem, mmdb, entry_data);
if (MMDB_SUCCESS != status) {
memset(entry_data, 0, sizeof(MMDB_entry_data_s));
return status;
}
} else {
/* Once we make the code traverse maps & arrays without calling
* decode_one() we can get rid of this. */
memset(entry_data, 0, sizeof(MMDB_entry_data_s));
return MMDB_LOOKUP_PATH_DOES_NOT_MATCH_DATA_ERROR;
}
}
return MMDB_SUCCESS;
}
LOCAL int lookup_path_in_array(const char *path_elem, MMDB_s *mmdb,
MMDB_entry_data_s *entry_data)
{
uint32_t size = entry_data->data_size;
char *first_invalid;
int saved_errno = errno;
errno = 0;
int array_index = strtol(path_elem, &first_invalid, 10);
if (array_index < 0 || ERANGE == errno) {
errno = saved_errno;
return MMDB_INVALID_LOOKUP_PATH_ERROR;
}
errno = saved_errno;
if (*first_invalid || (uint32_t)array_index >= size) {
return MMDB_LOOKUP_PATH_DOES_NOT_MATCH_DATA_ERROR;
}
for (int i = 0; i < array_index; i++) {
/* We don't want to follow a pointer here. If the next element is a
* pointer we simply skip it and keep going */
CHECKED_DECODE_ONE(mmdb, entry_data->offset_to_next, entry_data);
int status = skip_map_or_array(mmdb, entry_data);
if (MMDB_SUCCESS != status) {
return status;
}
}
MMDB_entry_data_s value;
CHECKED_DECODE_ONE_FOLLOW(mmdb, entry_data->offset_to_next, &value);
memcpy(entry_data, &value, sizeof(MMDB_entry_data_s));
return MMDB_SUCCESS;
}
LOCAL int lookup_path_in_map(const char *path_elem, MMDB_s *mmdb,
MMDB_entry_data_s *entry_data)
{
uint32_t size = entry_data->data_size;
uint32_t offset = entry_data->offset_to_next;
size_t path_elem_len = strlen(path_elem);
while (size-- > 0) {
MMDB_entry_data_s key, value;
CHECKED_DECODE_ONE_FOLLOW(mmdb, offset, &key);
uint32_t offset_to_value = key.offset_to_next;
if (MMDB_DATA_TYPE_UTF8_STRING != key.type) {
return MMDB_INVALID_DATA_ERROR;
}
if (key.data_size == path_elem_len &&
!memcmp(path_elem, key.utf8_string, path_elem_len)) {
DEBUG_MSG("found key matching path elem");
CHECKED_DECODE_ONE_FOLLOW(mmdb, offset_to_value, &value);
memcpy(entry_data, &value, sizeof(MMDB_entry_data_s));
return MMDB_SUCCESS;
} else {
/* We don't want to follow a pointer here. If the next element is
* a pointer we simply skip it and keep going */
CHECKED_DECODE_ONE(mmdb, offset_to_value, &value);
int status = skip_map_or_array(mmdb, &value);
if (MMDB_SUCCESS != status) {
return status;
}
offset = value.offset_to_next;
}
}
memset(entry_data, 0, sizeof(MMDB_entry_data_s));
return MMDB_LOOKUP_PATH_DOES_NOT_MATCH_DATA_ERROR;
}
LOCAL int skip_map_or_array(MMDB_s *mmdb, MMDB_entry_data_s *entry_data)
{
if (entry_data->type == MMDB_DATA_TYPE_MAP) {
uint32_t size = entry_data->data_size;
while (size-- > 0) {
CHECKED_DECODE_ONE(mmdb, entry_data->offset_to_next, entry_data); // key
CHECKED_DECODE_ONE(mmdb, entry_data->offset_to_next, entry_data); // value
int status = skip_map_or_array(mmdb, entry_data);
if (MMDB_SUCCESS != status) {
return status;
}
}
} else if (entry_data->type == MMDB_DATA_TYPE_ARRAY) {
uint32_t size = entry_data->data_size;
while (size-- > 0) {
CHECKED_DECODE_ONE(mmdb, entry_data->offset_to_next, entry_data); // value
int status = skip_map_or_array(mmdb, entry_data);
if (MMDB_SUCCESS != status) {
return status;
}
}
}
return MMDB_SUCCESS;
}
LOCAL int decode_one_follow(MMDB_s *mmdb, uint32_t offset,
MMDB_entry_data_s *entry_data)
{
CHECKED_DECODE_ONE(mmdb, offset, entry_data);
if (entry_data->type == MMDB_DATA_TYPE_POINTER) {
uint32_t next = entry_data->offset_to_next;
CHECKED_DECODE_ONE(mmdb, entry_data->pointer, entry_data);
/* Pointers to pointers are illegal under the spec */
if (entry_data->type == MMDB_DATA_TYPE_POINTER) {
DEBUG_MSG("pointer points to another pointer");
return MMDB_INVALID_DATA_ERROR;
}
/* The pointer could point to any part of the data section but the
* next entry for this particular offset may be the one after the
* pointer, not the one after whatever the pointer points to. This
* depends on whether the pointer points to something that is a simple
* value or a compound value. For a compound value, the next one is
* the one after the pointer result, not the one after the pointer. */
if (entry_data->type != MMDB_DATA_TYPE_MAP
&& entry_data->type != MMDB_DATA_TYPE_ARRAY) {
entry_data->offset_to_next = next;
}
}
return MMDB_SUCCESS;
}
#if !MMDB_UINT128_IS_BYTE_ARRAY
NO_PROTO mmdb_uint128_t get_uint128(const uint8_t *p, int length)
{
mmdb_uint128_t value = 0;
while (length-- > 0) {
value <<= 8;
value += *p++;
}
return value;
}
#endif
LOCAL int decode_one(MMDB_s *mmdb, uint32_t offset,
MMDB_entry_data_s *entry_data)
{
const uint8_t *mem = mmdb->data_section;
if (offset + 1 > mmdb->data_section_size) {
return MMDB_INVALID_DATA_ERROR;
}
entry_data->offset = offset;
entry_data->has_data = true;
DEBUG_NL;
DEBUG_MSGF("Offset: %i", offset);
uint8_t ctrl = mem[offset++];
DEBUG_BINARY("Control byte: %s", ctrl);
int type = (ctrl >> 5) & 7;
DEBUG_MSGF("Type: %i (%s)", type, type_num_to_name(type));
if (type == MMDB_DATA_TYPE_EXTENDED) {
if (offset + 1 > mmdb->data_section_size) {
return MMDB_INVALID_DATA_ERROR;
}
type = get_ext_type(mem[offset++]);
DEBUG_MSGF("Extended type: %i (%s)", type, type_num_to_name(type));
}
entry_data->type = type;
if (type == MMDB_DATA_TYPE_POINTER) {
int psize = (ctrl >> 3) & 3;
DEBUG_MSGF("Pointer size: %i", psize);
if (offset + psize + 1 > mmdb->data_section_size) {
return MMDB_INVALID_DATA_ERROR;
}
entry_data->pointer = get_ptr_from(ctrl, &mem[offset], psize);
DEBUG_MSGF("Pointer to: %i", entry_data->pointer);
entry_data->data_size = psize + 1;
entry_data->offset_to_next = offset + psize + 1;
return MMDB_SUCCESS;
}
uint32_t size = ctrl & 31;
switch (size) {
case 29:
if (offset + 1 > mmdb->data_section_size) {
return MMDB_INVALID_DATA_ERROR;
}
size = 29 + mem[offset++];
break;
case 30:
if (offset + 2 > mmdb->data_section_size) {
return MMDB_INVALID_DATA_ERROR;
}
size = 285 + get_uint16(&mem[offset]);
offset += 2;
break;
case 31:
if (offset + 3 > mmdb->data_section_size) {
return MMDB_INVALID_DATA_ERROR;
}
size = 65821 + get_uint24(&mem[offset]);
offset += 3;
default:
break;
}
DEBUG_MSGF("Size: %i", size);
if (type == MMDB_DATA_TYPE_MAP || type == MMDB_DATA_TYPE_ARRAY) {
entry_data->data_size = size;
entry_data->offset_to_next = offset;
return MMDB_SUCCESS;
}
if (type == MMDB_DATA_TYPE_BOOLEAN) {
entry_data->boolean = size ? true : false;
entry_data->data_size = 0;
entry_data->offset_to_next = offset;
DEBUG_MSGF("boolean value: %s", entry_data->boolean ? "true" : "false");
return MMDB_SUCCESS;
}
// check that the data doesn't extend past the end of the memory
// buffer
if (offset + size > mmdb->data_section_size) {
return MMDB_INVALID_DATA_ERROR;
}
if (type == MMDB_DATA_TYPE_UINT16) {
if (size > 2) {
return MMDB_INVALID_DATA_ERROR;
}
entry_data->uint16 = (uint16_t)get_uintX(&mem[offset], size);
DEBUG_MSGF("uint16 value: %u", entry_data->uint16);
} else if (type == MMDB_DATA_TYPE_UINT32) {
if (size > 4) {
return MMDB_INVALID_DATA_ERROR;
}
entry_data->uint32 = (uint32_t)get_uintX(&mem[offset], size);
DEBUG_MSGF("uint32 value: %u", entry_data->uint32);
} else if (type == MMDB_DATA_TYPE_INT32) {
if (size > 4) {
return MMDB_INVALID_DATA_ERROR;
}
entry_data->int32 = get_sintX(&mem[offset], size);
DEBUG_MSGF("int32 value: %i", entry_data->int32);
} else if (type == MMDB_DATA_TYPE_UINT64) {
if (size > 8) {
return MMDB_INVALID_DATA_ERROR;
}
entry_data->uint64 = get_uintX(&mem[offset], size);
DEBUG_MSGF("uint64 value: %" PRIu64, entry_data->uint64);
} else if (type == MMDB_DATA_TYPE_UINT128) {
if (size > 16) {
return MMDB_INVALID_DATA_ERROR;
}
#if MMDB_UINT128_IS_BYTE_ARRAY
memset(entry_data->uint128, 0, 16);
if (size > 0) {
memcpy(entry_data->uint128 + 16 - size, &mem[offset], size);
}
#else
entry_data->uint128 = get_uint128(&mem[offset], size);
#endif
} else if (type == MMDB_DATA_TYPE_FLOAT) {
if (size != 4) {
return MMDB_INVALID_DATA_ERROR;
}
size = 4;
entry_data->float_value = get_ieee754_float(&mem[offset]);
DEBUG_MSGF("float value: %f", entry_data->float_value);
} else if (type == MMDB_DATA_TYPE_DOUBLE) {
if (size != 8) {
return MMDB_INVALID_DATA_ERROR;
}
size = 8;
entry_data->double_value = get_ieee754_double(&mem[offset]);
DEBUG_MSGF("double value: %f", entry_data->double_value);
} else if (type == MMDB_DATA_TYPE_UTF8_STRING) {
entry_data->utf8_string = size == 0 ? "" : (char *)&mem[offset];
entry_data->data_size = size;
#ifdef MMDB_DEBUG
char *string = mmdb_strndup(entry_data->utf8_string,
size > 50 ? 50 : size);
if (NULL == string) {
abort();
}
DEBUG_MSGF("string value: %s", string);
free(string);
#endif
} else if (type == MMDB_DATA_TYPE_BYTES) {
entry_data->bytes = &mem[offset];
entry_data->data_size = size;
}
entry_data->offset_to_next = offset + size;
return MMDB_SUCCESS;
}
LOCAL int get_ext_type(int raw_ext_type)
{
return 7 + raw_ext_type;
}
LOCAL uint32_t get_ptr_from(uint8_t ctrl, uint8_t const *const ptr,
int ptr_size)
{
uint32_t new_offset;
switch (ptr_size) {
case 0:
new_offset = (ctrl & 7) * 256 + ptr[0];
break;
case 1:
new_offset = 2048 + (ctrl & 7) * 65536 + ptr[0] * 256 + ptr[1];
break;
case 2:
new_offset = 2048 + 524288 + (ctrl & 7) * 16777216 + get_uint24(ptr);
break;
case 3:
default:
new_offset = get_uint32(ptr);
break;
}
return MMDB_DATA_SECTION_SEPARATOR + new_offset;
}
int MMDB_get_metadata_as_entry_data_list(
MMDB_s *const mmdb, MMDB_entry_data_list_s **const entry_data_list)
{
MMDB_s metadata_db = make_fake_metadata_db(mmdb);
MMDB_entry_s metadata_start = {
.mmdb = &metadata_db,
.offset = 0
};
return MMDB_get_entry_data_list(&metadata_start, entry_data_list);
}
int MMDB_get_entry_data_list(
MMDB_entry_s *start, MMDB_entry_data_list_s **const entry_data_list)
{
*entry_data_list = new_entry_data_list();
if (NULL == *entry_data_list) {
return MMDB_OUT_OF_MEMORY_ERROR;
}
return get_entry_data_list(start->mmdb, start->offset, *entry_data_list, 0);
}
LOCAL int get_entry_data_list(MMDB_s *mmdb, uint32_t offset,
MMDB_entry_data_list_s *const entry_data_list,
int depth)
{
if (depth >= MAXIMUM_DATA_STRUCTURE_DEPTH) {
DEBUG_MSG("reached the maximum data structure depth");
return MMDB_INVALID_DATA_ERROR;
}
depth++;
CHECKED_DECODE_ONE(mmdb, offset, &entry_data_list->entry_data);
switch (entry_data_list->entry_data.type) {
case MMDB_DATA_TYPE_POINTER:
{
uint32_t next_offset = entry_data_list->entry_data.offset_to_next;
uint32_t last_offset;
CHECKED_DECODE_ONE(mmdb, last_offset =
entry_data_list->entry_data.pointer,
&entry_data_list->entry_data);
/* Pointers to pointers are illegal under the spec */
if (entry_data_list->entry_data.type == MMDB_DATA_TYPE_POINTER) {
DEBUG_MSG("pointer points to another pointer");
return MMDB_INVALID_DATA_ERROR;
}
if (entry_data_list->entry_data.type == MMDB_DATA_TYPE_ARRAY
|| entry_data_list->entry_data.type == MMDB_DATA_TYPE_MAP) {
int status =
get_entry_data_list(mmdb, last_offset, entry_data_list,
depth);
if (MMDB_SUCCESS != status) {
return status;
}
}
entry_data_list->entry_data.offset_to_next = next_offset;
}
break;
case MMDB_DATA_TYPE_ARRAY:
{
uint32_t array_size = entry_data_list->entry_data.data_size;
uint32_t array_offset = entry_data_list->entry_data.offset_to_next;
MMDB_entry_data_list_s *previous = entry_data_list;
while (array_size-- > 0) {
MMDB_entry_data_list_s *entry_data_list_to = previous->next =
new_entry_data_list();
if (NULL == entry_data_list_to) {
return MMDB_OUT_OF_MEMORY_ERROR;
}
int status =
get_entry_data_list(mmdb, array_offset, entry_data_list_to,
depth);
if (MMDB_SUCCESS != status) {
return status;
}
array_offset = entry_data_list_to->entry_data.offset_to_next;
while (previous->next) {
previous = previous->next;
}
}
entry_data_list->entry_data.offset_to_next = array_offset;
}
break;
case MMDB_DATA_TYPE_MAP:
{
uint32_t size = entry_data_list->entry_data.data_size;
offset = entry_data_list->entry_data.offset_to_next;
MMDB_entry_data_list_s *previous = entry_data_list;
while (size-- > 0) {
MMDB_entry_data_list_s *entry_data_list_to = previous->next =
new_entry_data_list();
if (NULL == entry_data_list_to) {
return MMDB_OUT_OF_MEMORY_ERROR;
}
int status =
get_entry_data_list(mmdb, offset, entry_data_list_to,
depth);
if (MMDB_SUCCESS != status) {
return status;
}
while (previous->next) {
previous = previous->next;
}
offset = entry_data_list_to->entry_data.offset_to_next;
entry_data_list_to = previous->next =
new_entry_data_list();
if (NULL == entry_data_list_to) {
return MMDB_OUT_OF_MEMORY_ERROR;
}
status = get_entry_data_list(mmdb, offset, entry_data_list_to,
depth);
if (MMDB_SUCCESS != status) {
return status;
}
while (previous->next) {
previous = previous->next;
}
offset = entry_data_list_to->entry_data.offset_to_next;
}
entry_data_list->entry_data.offset_to_next = offset;
}
break;
default:
break;
}
return MMDB_SUCCESS;
}
LOCAL float get_ieee754_float(const uint8_t *restrict p)
{
volatile float f;
uint8_t *q = (void *)&f;
#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
q[3] = p[0];
q[2] = p[1];
q[1] = p[2];
q[0] = p[3];
#else
memcpy(q, p, 4);
#endif
return f;
}
LOCAL double get_ieee754_double(const uint8_t *restrict p)
{
volatile double d;
uint8_t *q = (void *)&d;
#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
q[7] = p[0];
q[6] = p[1];
q[5] = p[2];
q[4] = p[3];
q[3] = p[4];
q[2] = p[5];
q[1] = p[6];
q[0] = p[7];
#else
memcpy(q, p, 8);
#endif
return d;
}
LOCAL uint32_t get_uint32(const uint8_t *p)
{
return p[0] * 16777216U + p[1] * 65536 + p[2] * 256 + p[3];
}
LOCAL uint32_t get_uint24(const uint8_t *p)
{
return p[0] * 65536U + p[1] * 256 + p[2];
}
LOCAL uint32_t get_uint16(const uint8_t *p)
{
return p[0] * 256U + p[1];
}
LOCAL uint64_t get_uintX(const uint8_t *p, int length)
{
uint64_t value = 0;
while (length-- > 0) {
value <<= 8;
value += *p++;
}
return value;
}
LOCAL int32_t get_sintX(const uint8_t *p, int length)
{
return (int32_t)get_uintX(p, length);
}
LOCAL MMDB_entry_data_list_s *new_entry_data_list(void)
{
/* We need calloc here in order to ensure that the ->next pointer in the
* struct doesn't point to some random address. */
return calloc(1, sizeof(MMDB_entry_data_list_s));
}
void MMDB_free_entry_data_list(MMDB_entry_data_list_s *const entry_data_list)
{
if (entry_data_list == NULL) {
return;
}
if (entry_data_list->next) {
MMDB_free_entry_data_list(entry_data_list->next);
}
free(entry_data_list);
}
void MMDB_close(MMDB_s *const mmdb)
{
free_mmdb_struct(mmdb);
}
LOCAL void free_mmdb_struct(MMDB_s *const mmdb)
{
if (!mmdb) {
return;
}
if (NULL != mmdb->filename) {
FREE_AND_SET_NULL(mmdb->filename);
}
if (NULL != mmdb->file_content) {
#ifdef _WIN32
UnmapViewOfFile(mmdb->file_content);
/* Winsock is only initialized if open was successful so we only have
* to cleanup then. */
WSACleanup();
#else
munmap((void *)mmdb->file_content, mmdb->file_size);
#endif
}
if (NULL != mmdb->metadata.database_type) {
FREE_AND_SET_NULL(mmdb->metadata.database_type);
}
free_languages_metadata(mmdb);
free_descriptions_metadata(mmdb);
}
LOCAL void free_languages_metadata(MMDB_s *mmdb)
{
if (!mmdb->metadata.languages.count) {
return;
}
for (size_t i = 0; i < mmdb->metadata.languages.count; i++) {
FREE_AND_SET_NULL(mmdb->metadata.languages.names[i]);
}
FREE_AND_SET_NULL(mmdb->metadata.languages.names);
}
LOCAL void free_descriptions_metadata(MMDB_s *mmdb)
{
if (!mmdb->metadata.description.count) {
return;
}
for (size_t i = 0; i < mmdb->metadata.description.count; i++) {
if (NULL != mmdb->metadata.description.descriptions[i]) {
if (NULL !=
mmdb->metadata.description.descriptions[i]->language) {
FREE_AND_SET_NULL(
mmdb->metadata.description.descriptions[i]->language);
}
if (NULL !=
mmdb->metadata.description.descriptions[i]->description) {
FREE_AND_SET_NULL(
mmdb->metadata.description.descriptions[i]->description);
}
FREE_AND_SET_NULL(mmdb->metadata.description.descriptions[i]);
}
}
FREE_AND_SET_NULL(mmdb->metadata.description.descriptions);
}
const char *MMDB_lib_version(void)
{
return PACKAGE_VERSION;
}
int MMDB_dump_entry_data_list(FILE *const stream,
MMDB_entry_data_list_s *const entry_data_list,
int indent)
{
int status;
dump_entry_data_list(stream, entry_data_list, indent, &status);
return status;
}
LOCAL MMDB_entry_data_list_s *dump_entry_data_list(
FILE *stream, MMDB_entry_data_list_s *entry_data_list, int indent,
int *status)
{
switch (entry_data_list->entry_data.type) {
case MMDB_DATA_TYPE_MAP:
{
uint32_t size = entry_data_list->entry_data.data_size;
print_indentation(stream, indent);
fprintf(stream, "{\n");
indent += 2;
for (entry_data_list = entry_data_list->next;
size && entry_data_list; size--) {
if (MMDB_DATA_TYPE_UTF8_STRING !=
entry_data_list->entry_data.type) {
*status = MMDB_INVALID_DATA_ERROR;
return NULL;
}
char *key =
mmdb_strndup(
(char *)entry_data_list->entry_data.utf8_string,
entry_data_list->entry_data.data_size);
if (NULL == key) {
*status = MMDB_OUT_OF_MEMORY_ERROR;
return NULL;
}
print_indentation(stream, indent);
fprintf(stream, "\"%s\": \n", key);
free(key);
entry_data_list = entry_data_list->next;
entry_data_list =
dump_entry_data_list(stream, entry_data_list, indent + 2,
status);
if (MMDB_SUCCESS != *status) {
return NULL;
}
}
indent -= 2;
print_indentation(stream, indent);
fprintf(stream, "}\n");
}
break;
case MMDB_DATA_TYPE_ARRAY:
{
uint32_t size = entry_data_list->entry_data.data_size;
print_indentation(stream, indent);
fprintf(stream, "[\n");
indent += 2;
for (entry_data_list = entry_data_list->next;
size && entry_data_list; size--) {
entry_data_list =
dump_entry_data_list(stream, entry_data_list, indent,
status);
if (MMDB_SUCCESS != *status) {
return NULL;
}
}
indent -= 2;
print_indentation(stream, indent);
fprintf(stream, "]\n");
}
break;
case MMDB_DATA_TYPE_UTF8_STRING:
{
char *string =
mmdb_strndup((char *)entry_data_list->entry_data.utf8_string,
entry_data_list->entry_data.data_size);
if (NULL == string) {
*status = MMDB_OUT_OF_MEMORY_ERROR;
return NULL;
}
print_indentation(stream, indent);
fprintf(stream, "\"%s\" <utf8_string>\n", string);
free(string);
entry_data_list = entry_data_list->next;
}
break;
case MMDB_DATA_TYPE_BYTES:
{
char *hex_string =
bytes_to_hex((uint8_t *)entry_data_list->entry_data.bytes,
entry_data_list->entry_data.data_size);
if (NULL == hex_string) {
*status = MMDB_OUT_OF_MEMORY_ERROR;
return NULL;
}
print_indentation(stream, indent);
fprintf(stream, "%s <bytes>\n", hex_string);
free(hex_string);
entry_data_list = entry_data_list->next;
}
break;
case MMDB_DATA_TYPE_DOUBLE:
print_indentation(stream, indent);
fprintf(stream, "%f <double>\n",
entry_data_list->entry_data.double_value);
entry_data_list = entry_data_list->next;
break;
case MMDB_DATA_TYPE_FLOAT:
print_indentation(stream, indent);
fprintf(stream, "%f <float>\n",
entry_data_list->entry_data.float_value);
entry_data_list = entry_data_list->next;
break;
case MMDB_DATA_TYPE_UINT16:
print_indentation(stream, indent);
fprintf(stream, "%u <uint16>\n", entry_data_list->entry_data.uint16);
entry_data_list = entry_data_list->next;
break;
case MMDB_DATA_TYPE_UINT32:
print_indentation(stream, indent);
fprintf(stream, "%u <uint32>\n", entry_data_list->entry_data.uint32);
entry_data_list = entry_data_list->next;
break;
case MMDB_DATA_TYPE_BOOLEAN:
print_indentation(stream, indent);
fprintf(stream, "%s <boolean>\n",
entry_data_list->entry_data.boolean ? "true" : "false");
entry_data_list = entry_data_list->next;
break;
case MMDB_DATA_TYPE_UINT64:
print_indentation(stream, indent);
fprintf(stream, "%" PRIu64 " <uint64>\n",
entry_data_list->entry_data.uint64);
entry_data_list = entry_data_list->next;
break;
case MMDB_DATA_TYPE_UINT128:
print_indentation(stream, indent);
#if MMDB_UINT128_IS_BYTE_ARRAY
char *hex_string =
bytes_to_hex((uint8_t *)entry_data_list->entry_data.uint128, 16);
if (NULL == hex_string) {
*status = MMDB_OUT_OF_MEMORY_ERROR;
return NULL;
}
fprintf(stream, "0x%s <uint128>\n", hex_string);
free(hex_string);
#else
uint64_t high = entry_data_list->entry_data.uint128 >> 64;
uint64_t low = (uint64_t)entry_data_list->entry_data.uint128;
fprintf(stream, "0x%016" PRIX64 "%016" PRIX64 " <uint128>\n", high,
low);
#endif
entry_data_list = entry_data_list->next;
break;
case MMDB_DATA_TYPE_INT32:
print_indentation(stream, indent);
fprintf(stream, "%d <int32>\n", entry_data_list->entry_data.int32);
entry_data_list = entry_data_list->next;
break;
default:
*status = MMDB_INVALID_DATA_ERROR;
return NULL;
}
*status = MMDB_SUCCESS;
return entry_data_list;
}
LOCAL void print_indentation(FILE *stream, int i)
{
char buffer[1024];
int size = i >= 1024 ? 1023 : i;
memset(buffer, 32, size);
buffer[size] = '\0';
fputs(buffer, stream);
}
LOCAL char *bytes_to_hex(uint8_t *bytes, uint32_t size)
{
char *hex_string;
MAYBE_CHECK_SIZE_OVERFLOW(size, SIZE_MAX / 2 - 1, NULL);
hex_string = malloc((size * 2) + 1);
if (NULL == hex_string) {
return NULL;
}
for (uint32_t i = 0; i < size; i++) {
sprintf(hex_string + (2 * i), "%02X", bytes[i]);
}
return hex_string;
}
const char *MMDB_strerror(int error_code)
{
switch (error_code) {
case MMDB_SUCCESS:
return "Success (not an error)";
case MMDB_FILE_OPEN_ERROR:
return "Error opening the specified MaxMind DB file";
case MMDB_CORRUPT_SEARCH_TREE_ERROR:
return "The MaxMind DB file's search tree is corrupt";
case MMDB_INVALID_METADATA_ERROR:
return "The MaxMind DB file contains invalid metadata";
case MMDB_IO_ERROR:
return "An attempt to read data from the MaxMind DB file failed";
case MMDB_OUT_OF_MEMORY_ERROR:
return "A memory allocation call failed";
case MMDB_UNKNOWN_DATABASE_FORMAT_ERROR:
return
"The MaxMind DB file is in a format this library can't handle (unknown record size or binary format version)";
case MMDB_INVALID_DATA_ERROR:
return
"The MaxMind DB file's data section contains bad data (unknown data type or corrupt data)";
case MMDB_INVALID_LOOKUP_PATH_ERROR:
return
"The lookup path contained an invalid value (like a negative integer for an array index)";
case MMDB_LOOKUP_PATH_DOES_NOT_MATCH_DATA_ERROR:
return
"The lookup path does not match the data (key that doesn't exist, array index bigger than the array, expected array or map where none exists)";
case MMDB_INVALID_NODE_NUMBER_ERROR:
return
"The MMDB_read_node function was called with a node number that does not exist in the search tree";
case MMDB_IPV6_LOOKUP_IN_IPV4_DATABASE_ERROR:
return
"You attempted to look up an IPv6 address in an IPv4-only database";
default:
return "Unknown error code";
}
}