static void DNSSD_API enum_reply(DNSServiceRef client, const DNSServiceFlags flags, uint32_t ifIndex,
DNSServiceErrorType errorCode, const char *replyDomain, void *context)
{
DNSServiceFlags partialflags = flags & ~(kDNSServiceFlagsMoreComing | kDNSServiceFlagsAdd | kDNSServiceFlagsDefault);
int labels = 0, depth = 0, i, initial = 0;
char text[64];
const char *label[128];
(void)client; // Unused
(void)ifIndex; // Unused
(void)context; // Unused
// 1. Print the header
if (num_printed++ == 0) printf("Timestamp Recommended %s domain\n", operation == 'E' ? "Registration" : "Browsing");
printtimestamp();
if (errorCode)
printf("Error code %d\n", errorCode);
else if (!*replyDomain)
printf("Error: No reply domain\n");
else
{
printf("%-10s", DomainMsg(flags));
printf("%-8s", (flags & kDNSServiceFlagsMoreComing) ? "(More)" : "");
if (partialflags) printf("Flags: %4X ", partialflags);
else printf(" ");
// 2. Count the labels
while (*replyDomain)
{
label[labels++] = replyDomain;
replyDomain = GetNextLabel(replyDomain, text);
}
// 3. Decide if we're going to clump the last two or three labels (e.g. "apple.com", or "nicta.com.au")
if (labels >= 3 && replyDomain - label[labels-1] <= 3 && label[labels-1] - label[labels-2] <= 4) initial = 3;
else if (labels >= 2 && replyDomain - label[labels-1] <= 4) initial = 2;
else initial = 1;
labels -= initial;
// 4. Print the initial one-, two- or three-label clump
for (i=0; i<initial; i++)
{
GetNextLabel(label[labels+i], text);
if (i>0) printf(".");
printf("%s", text);
}
printf("\n");
// 5. Print the remainder of the hierarchy
for (depth=0; depth<labels; depth++)
{
printf(" ");
for (i=0; i<=depth; i++) printf("- ");
GetNextLabel(label[labels-1-depth], text);
printf("> %s\n", text);
}
}
if (!(flags & kDNSServiceFlagsMoreComing)) fflush(stdout);
}
static void DNSSD_API resolve_reply(DNSServiceRef client, const DNSServiceFlags flags, uint32_t ifIndex, DNSServiceErrorType errorCode,
const char *fullname, const char *hosttarget, uint16_t opaqueport, uint16_t txtLen, const unsigned char *txtRecord, void *context)
{
union {
uint16_t s;
u_char b[2];
} port = { opaqueport };
uint16_t PortAsNumber = ((uint16_t)port.b[0]) << 8 | port.b[1];
(void)client; // Unused
(void)ifIndex; // Unused
(void)context; // Unused
printtimestamp();
if (errorCode) printf("Error code %d\n", errorCode);
else
{
printf("%s can be reached at %s:%u", fullname, hosttarget, PortAsNumber);
if (flags) printf(" Flags: %X", flags);
// Don't show degenerate TXT records containing nothing but a single empty string
if (txtLen > 1) {
printf("\n");
ShowTXTRecord(txtLen, txtRecord);
}
printf("\n");
}
if (!(flags & kDNSServiceFlagsMoreComing)) fflush(stdout);
}
static void myTimerCallBack(void)
{
DNSServiceErrorType err = kDNSServiceErr_Unknown;
switch (operation)
{
case 'A':
{
switch (addtest)
{
case 0: printf("Adding Test HINFO record\n");
err = DNSServiceAddRecord(client, &record, 0, kDNSServiceType_HINFO, sizeof(myhinfoW), &myhinfoW[0], 0);
addtest = 1;
break;
case 1: printf("Updating Test HINFO record\n");
err = DNSServiceUpdateRecord(client, record, 0, sizeof(myhinfoX), &myhinfoX[0], 0);
addtest = 2;
break;
case 2: printf("Removing Test HINFO record\n");
err = DNSServiceRemoveRecord(client, record, 0);
addtest = 0;
break;
}
}
break;
case 'U':
{
if (updatetest[1] != 'Z') updatetest[1]++;
else updatetest[1] = 'A';
updatetest[0] = 3 - updatetest[0];
updatetest[2] = updatetest[1];
printtimestamp();
printf("Updating Test TXT record to %c\n", updatetest[1]);
err = DNSServiceUpdateRecord(client, NULL, 0, 1+updatetest[0], &updatetest[0], 0);
}
break;
case 'N':
{
printf("Adding big NULL record\n");
err = DNSServiceAddRecord(client, &record, 0, kDNSServiceType_NULL, sizeof(bigNULL), &bigNULL[0], 0);
if (err) printf("Failed: %d\n", err); else printf("Succeeded\n");
timeOut = LONG_TIME;
}
break;
}
if (err != kDNSServiceErr_NoError)
{
fprintf(stderr, "DNSService add/update/remove failed %ld\n", (long int)err);
stopNow = 1;
}
}
static void DNSSD_API browse_reply(DNSServiceRef client, const DNSServiceFlags flags, uint32_t ifIndex, DNSServiceErrorType errorCode,
const char *replyName, const char *replyType, const char *replyDomain, void *context)
{
char *op = (flags & kDNSServiceFlagsAdd) ? "Add" : "Rmv";
(void)client; // Unused
(void)context; // Unused
if (num_printed++ == 0) printf("Timestamp A/R Flags if %-25s %-25s %s\n", "Domain", "Service Type", "Instance Name");
printtimestamp();
if (errorCode) printf("Error code %d\n", errorCode);
else printf("%s%6X%3d %-25s %-25s %s\n", op, flags, ifIndex, replyDomain, replyType, replyName);
if (!(flags & kDNSServiceFlagsMoreComing)) fflush(stdout);
}
static void DNSSD_API qr_reply(DNSServiceRef sdRef, const DNSServiceFlags flags, uint32_t ifIndex, DNSServiceErrorType errorCode,
const char *fullname, uint16_t rrtype, uint16_t rrclass, uint16_t rdlen, const void *rdata, uint32_t ttl, void *context)
{
char *op = (flags & kDNSServiceFlagsAdd) ? "Add" : "Rmv";
const unsigned char *rd = rdata;
const unsigned char *end = (const unsigned char *) rdata + rdlen;
char rdb[1000];
int unknowntype = 0;
(void)sdRef; // Unused
(void)flags; // Unused
(void)ifIndex; // Unused
(void)ttl; // Unused
(void)context; // Unused
if (num_printed++ == 0) printf("Timestamp A/R Flags if %-30s%4s%4s Rdata\n", "Name", "T", "C");
printtimestamp();
if (errorCode)
printf("Error code %d\n", errorCode);
else
{
switch (rrtype)
{
case kDNSServiceType_A:
sprintf(rdb, "%d.%d.%d.%d", rd[0], rd[1], rd[2], rd[3]);
break;
case kDNSServiceType_AAAA:
sprintf(rdb, "%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X",
rd[0x0], rd[0x1], rd[0x2], rd[0x3], rd[0x4], rd[0x5], rd[0x6], rd[0x7],
rd[0x8], rd[0x9], rd[0xA], rd[0xB], rd[0xC], rd[0xD], rd[0xE], rd[0xF]);
break;
break;
default :
sprintf(rdb, "%d bytes%s", rdlen, rdlen ? ":" : "");
unknowntype = 1;
break;
}
printf("%s%6X%3d %-30s%4d%4d %s", op, flags, ifIndex, fullname, rrtype, rrclass, rdb);
if (unknowntype) while (rd < end) printf(" %02X", *rd++);
printf("\n");
if (operation == 'C')
if (flags & kDNSServiceFlagsAdd)
DNSServiceReconfirmRecord(flags, ifIndex, fullname, rrtype, rrclass, rdlen, rdata);
}
if (!(flags & kDNSServiceFlagsMoreComing)) fflush(stdout);
}
// DNSXEnableProxy Callback from the Daemon
static void dnsproxy_reply(DNSXConnRef connRef, DNSXErrorType errCode)
{
(void) connRef;
printtimestamp();
switch (errCode)
{
case kDNSX_NoError : printf(" SUCCESS \n"); break;
case kDNSX_DictError : printf(" DICT ERROR \n"); break;
case kDNSX_DaemonNotRunning : printf(" NO DAEMON \n");
DNSXRefDeAlloc(ClientRef); break;
case kDNSX_Engaged : printf(" ENGAGED \n");
DNSXRefDeAlloc(ClientRef); break;
case kDNSX_UnknownErr :
default : printf("UNKNOWN ERR \n");
DNSXRefDeAlloc(ClientRef); break;
}
}
static void DNSSD_API port_mapping_create_reply(DNSServiceRef sdref, DNSServiceFlags flags, uint32_t ifIndex, DNSServiceErrorType errorCode, uint32_t publicAddress, uint32_t protocol, uint16_t privatePort, uint16_t publicPort, uint32_t ttl, void *context)
{
(void)sdref; // Unused
(void)context; // Unused
(void)flags; // Unused
if (num_printed++ == 0) printf("Timestamp if %-20s %-15s %-15s %-15s %-6s\n", "External Address", "Protocol", "Internal Port", "External Port", "TTL");
printtimestamp();
if (errorCode && errorCode != kDNSServiceErr_DoubleNAT) printf("Error code %d\n", errorCode);
else
{
const unsigned char *digits = (const unsigned char *)&publicAddress;
char addr[256];
snprintf(addr, sizeof(addr), "%d.%d.%d.%d", digits[0], digits[1], digits[2], digits[3]);
printf("%-4d %-20s %-15d %-15d %-15d %-6d%s\n", ifIndex, addr, protocol, ntohs(privatePort), ntohs(publicPort), ttl, errorCode == kDNSServiceErr_DoubleNAT ? " Double NAT" : "");
}
fflush(stdout);
}
// DNSXEnableProxy Callback from the Daemon
static void dnsproxy_reply(DNSXConnRef connRef, DNSXErrorType errCode)
{
(void) connRef;
printtimestamp();
switch (errCode)
{
case kDNSX_NoError : printf(" SUCCESS \n");
break;
case kDNSX_DaemonNotRunning : printf(" NO DAEMON \n");
DNSXRefDeAlloc(ClientRef); break;
case kDNSX_BadParam : printf(" BAD PARAMETER \n");
DNSXRefDeAlloc(ClientRef); break;
case kDNSX_UnknownErr :
default : printf(" UNKNOWN ERR \n");
DNSXRefDeAlloc(ClientRef); break;
}
fflush(NULL);
}
static void DNSSD_API addrinfo_reply(DNSServiceRef sdref, DNSServiceFlags flags, uint32_t interfaceIndex, DNSServiceErrorType errorCode, const char *hostname, const struct sockaddr *address, uint32_t ttl, void *context)
{
char *op = (flags & kDNSServiceFlagsAdd) ? "Add" : "Rmv";
char addr[256] = "";
(void) sdref;
(void) context;
if (num_printed++ == 0) printf("Timestamp A/R Flags if %-25s %-44s %s\n", "Hostname", "Address", "TTL");
printtimestamp();
if (address && address->sa_family == AF_INET)
{
const unsigned char *b = (const unsigned char *) &((struct sockaddr_in *)address)->sin_addr;
snprintf(addr, sizeof(addr), "%d.%d.%d.%d", b[0], b[1], b[2], b[3]);
}
else if (address && address->sa_family == AF_INET6)
{
char if_name[IFNAMSIZ]; // Older Linux distributions don't define IF_NAMESIZE
const struct sockaddr_in6 *s6 = (const struct sockaddr_in6 *)address;
const unsigned char *b = (const unsigned char * )&s6->sin6_addr;
if (!if_indextoname(s6->sin6_scope_id, if_name))
snprintf(if_name, sizeof(if_name), "<%d>", s6->sin6_scope_id);
snprintf(addr, sizeof(addr), "%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X%%%s",
b[0x0], b[0x1], b[0x2], b[0x3], b[0x4], b[0x5], b[0x6], b[0x7],
b[0x8], b[0x9], b[0xA], b[0xB], b[0xC], b[0xD], b[0xE], b[0xF], if_name);
}
printf("%s%6X%3d %-25s %-44s %d", op, flags, interfaceIndex, hostname, addr, ttl);
if (errorCode)
{
if (errorCode == kDNSServiceErr_NoSuchRecord) printf(" No Such Record");
else printf(" Error code %d", errorCode);
}
printf("\n");
if (!(flags & kDNSServiceFlagsMoreComing)) fflush(stdout);
}
int main(int argc, char **argv)
{
DNSXErrorType err;
// Default i/p intf is lo0 and o/p intf is primary interface
IfIndex Ipintfs[MaxInputIf] = {1, 0, 0, 0, 0};
IfIndex Opintf = kDNSIfindexAny;
// Extract program name from argv[0], which by convention contains the path to this executable
const char *a0 = strrchr(argv[0], kFilePathSep) + 1;
if (a0 == (const char *)1)
a0 = argv[0];
// Must run as root
if (0 != geteuid())
{
fprintf(stderr, "%s MUST run as root!!\n", a0);
exit(-1);
}
if ((sizeof(argv) == 8))
printf("dnsctl running in 64-bit mode\n");
else if ((sizeof(argv) == 4))
printf("dnsctl running in 32-bit mode\n");
// expects atleast one argument
if (argc < 2)
goto Usage;
if ( !strcmp(argv[1], "-DP") || !strcmp(argv[1], "-dp") )
{
if (argc == 2)
{
printtimestamp();
printf("Proceeding to Enable DNSProxy on mDNSResponder with Default Parameters\n");
dispatch_queue_t my_Q = dispatch_queue_create("com.apple.dnsctl.callback_queue", NULL);
err = DNSXEnableProxy(&ClientRef, kDNSProxyEnable, Ipintfs, Opintf, my_Q, dnsproxy_reply);
}
else if (argc > 2)
{
argc--;
argv++;
if (!strcmp(argv[1], "-o"))
{
Opintf = if_nametoindex(argv[2]);
if (!Opintf)
Opintf = atoi(argv[2]);
if (!Opintf)
{
fprintf(stderr, "Could not parse o/p interface [%s]: Passing default primary \n", argv[2]);
Opintf = kDNSIfindexAny;
}
argc -= 2;
argv += 2;
}
if (argc > 2 && !strcmp(argv[1], "-i"))
{
int i;
argc--;
argv++;
for (i = 0; i < MaxInputIf && argc > 1; i++)
{
Ipintfs[i] = if_nametoindex(argv[1]);
if (!Ipintfs[i])
Ipintfs[i] = atoi(argv[1]);
if (!Ipintfs[i])
{
fprintf(stderr, "Could not parse i/p interface [%s]: Passing default lo0 \n", argv[2]);
Ipintfs[i] = 1;
}
argc--;
argv++;
}
}
printtimestamp();
printf("Proceeding to Enable DNSProxy on mDNSResponder \n");
dispatch_queue_t my_Q = dispatch_queue_create("com.apple.dnsctl.callback_queue", NULL);
err = DNSXEnableProxy(&ClientRef, kDNSProxyEnable, Ipintfs, Opintf, my_Q, dnsproxy_reply);
}
}
else
{
goto Usage;
}
dispatch_main();
Usage:
print_usage(a0);
return 0;
}
static void DNSSD_API qr_reply(DNSServiceRef sdref, const DNSServiceFlags flags, uint32_t ifIndex, DNSServiceErrorType errorCode,
const char *fullname, uint16_t rrtype, uint16_t rrclass, uint16_t rdlen, const void *rdata, uint32_t ttl, void *context)
{
char *op = (flags & kDNSServiceFlagsAdd) ? "Add" : "Rmv";
const unsigned char *rd = rdata;
const unsigned char *end = (const unsigned char *) rdata + rdlen;
char rdb[1000] = "", *p = rdb;
int unknowntype = 0;
(void)sdref; // Unused
(void)flags; // Unused
(void)ifIndex; // Unused
(void)ttl; // Unused
(void)context; // Unused
if (num_printed++ == 0) printf("Timestamp A/R Flags if %-30s%4s%4s Rdata\n", "Name", "T", "C");
printtimestamp();
if (!errorCode)
{
switch (rrtype)
{
case kDNSServiceType_A:
snprintf(rdb, sizeof(rdb), "%d.%d.%d.%d", rd[0], rd[1], rd[2], rd[3]);
break;
case kDNSServiceType_NS:
case kDNSServiceType_CNAME:
case kDNSServiceType_PTR:
case kDNSServiceType_DNAME:
p += snprintd(p, sizeof(rdb), &rd);
break;
case kDNSServiceType_SOA:
p += snprintd(p, rdb + sizeof(rdb) - p, &rd); // mname
p += snprintf(p, rdb + sizeof(rdb) - p, " ");
p += snprintd(p, rdb + sizeof(rdb) - p, &rd); // rname
p += snprintf(p, rdb + sizeof(rdb) - p, " Ser %d Ref %d Ret %d Exp %d Min %d",
ntohl(((uint32_t*)rd)[0]), ntohl(((uint32_t*)rd)[1]), ntohl(((uint32_t*)rd)[2]), ntohl(((uint32_t*)rd)[3]), ntohl(((uint32_t*)rd)[4]));
break;
case kDNSServiceType_AAAA:
snprintf(rdb, sizeof(rdb), "%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X:%02X%02X",
rd[0x0], rd[0x1], rd[0x2], rd[0x3], rd[0x4], rd[0x5], rd[0x6], rd[0x7],
rd[0x8], rd[0x9], rd[0xA], rd[0xB], rd[0xC], rd[0xD], rd[0xE], rd[0xF]);
break;
case kDNSServiceType_SRV:
p += snprintf(p, rdb + sizeof(rdb) - p, "%d %d %d ", // priority, weight, port
ntohs(*(unsigned short*)rd), ntohs(*(unsigned short*)(rd+2)), ntohs(*(unsigned short*)(rd+4)));
rd += 6;
p += snprintd(p, rdb + sizeof(rdb) - p, &rd); // target host
break;
default : snprintf(rdb, sizeof(rdb), "%d bytes%s", rdlen, rdlen ? ":" : ""); unknowntype = 1; break;
}
}
printf("%s%6X%3d %-30s%4d%4d %s", op, flags, ifIndex, fullname, rrtype, rrclass, rdb);
if (unknowntype) while (rd < end) printf(" %02X", *rd++);
if (errorCode)
{
if (errorCode == kDNSServiceErr_NoSuchRecord) printf("No Such Record");
else printf("Error code %d", errorCode);
}
printf("\n");
if (operation == 'C')
if (flags & kDNSServiceFlagsAdd)
DNSServiceReconfirmRecord(flags, ifIndex, fullname, rrtype, rrclass, rdlen, rdata);
if (!(flags & kDNSServiceFlagsMoreComing)) fflush(stdout);
}
int main(int argc, char **argv) {
uint32_t length; // length of the BlockHeader message
BlockHeader *bhmsg = NULL; // serialized BlockHeader message
Blob *bmsg = NULL; // serialized Blob message (size is given in the header)
FILE * fd;
char lenbuf[4];
unsigned char *buf = NULL;
enum {
osmheader,
osmdata
} state = osmheader;
if (argc == 2) {
fd = fopen(argv[1], "r");
if (fd == NULL) {
fprintf(stderr, "Can't open %s", argv[1]);
return -1;
}
} else {
fd = stdin;
}
fputs_unlocked("<?xml version='1.0' encoding='UTF-8'?>\n<osm version=\"0.6\" generator=\"" PACKAGE_STRING "\">""\n", stdout);
do {
if (!fread(lenbuf, 4, 1, fd)) break;
length = ntohl(*((uint32_t *) lenbuf)); // convert the buffer to a value
if (verbose) fprintf(stderr, "Length BlockHeader: %d\n", length);
if (length == 0 || length > MAX_BLOCK_HEADER_SIZE) {
if (feof(fd)) {
break;
}
fprintf(stderr, "Block Header isn't present or exceeds minimum/maximum size\n");
return 1;
}
/* Since we know the length of the BlockHeader now, we can allocate it */
buf = (unsigned char *) malloc(length * sizeof(unsigned char));
if (buf == NULL) {
fprintf (stderr, "Error allocating BlockHeader buffer\n");
return 1;
}
/* We are reading the BlockHeader */
if(! fread(buf, length, 1, fd)) break;
bhmsg = block_header__unpack (NULL, length, buf);
free(buf);
if (bhmsg == NULL) {
fprintf(stderr, "Error unpacking BlockHeader message\n");
return 1;
}
length = bhmsg->datasize;
if (verbose) fprintf(stderr, "Type: %s\nLength: %u\n", bhmsg->type, length);
if (length <= 0 || length > MAX_BLOB_SIZE) {
fprintf(stderr, "Blob isn't present or exceeds minimum/maximum size\n");
return 1;
}
if (strcmp(bhmsg->type, "OSMHeader") == 0) {
state = osmheader;
} else if (strcmp(bhmsg->type, "OSMData") == 0) {
state = osmdata;
}
block_header__free_unpacked (bhmsg, &protobuf_c_system_allocator);
/* We are now reading the 'Blob' */
buf = (unsigned char *) malloc(length * sizeof(unsigned char *));
if(! fread(buf, length, 1, fd)) break;
bmsg = blob__unpack (NULL, length, buf);
if (bmsg == NULL) {
fprintf(stderr, "Error unpacking Blob message\n");
return 1;
}
free(buf);
unsigned char *uncompressed;
if (bmsg->has_raw) {
uncompressed = bmsg->raw.data;
bmsg->raw_size = bmsg->raw.len; // I wonder if we should do this.
} else {
uncompressed = handleCompressedBlob(bmsg);
if (uncompressed == NULL) {
fprintf(stderr, "Uncompression failed\n");
return 1;
}
}
if (state == osmheader) {
HeaderBlock *hmsg = header_block__unpack (NULL, bmsg->raw_size, uncompressed);
if (hmsg == NULL) {
fprintf(stderr, "Error unpacking HeaderBlock message\n");
return 1;
}
if (verbose) fprintf(stderr, "%s\n", hmsg->required_features[0]);
header_block__free_unpacked (hmsg, &protobuf_c_system_allocator);
} else if (state == osmdata) {
/*
* Unpack Block and check if all went well
*/
PrimitiveBlock *pmsg = primitive_block__unpack (NULL, bmsg->raw_size, uncompressed);
if (pmsg == NULL) {
fprintf(stderr, "Error unpacking PrimitiveBlock message\n");
return 1;
}
double lat_offset = NANO_DEGREE * pmsg->lat_offset;
double lon_offset = NANO_DEGREE * pmsg->lon_offset;
double granularity = NANO_DEGREE * pmsg->granularity;
if (verbose) fprintf(stderr, "\t""Granularity: %d""\n", pmsg->granularity);
if (verbose) fprintf(stderr, "\t""Primitive groups: %li""\n", pmsg->n_primitivegroup);
for (unsigned int j = 0; j < pmsg->n_primitivegroup; j++) {
if (verbose) fprintf(stderr,"\t\t""Nodes: %li""\n"\
"\t\t""Ways: %li""\n"\
"\t\t""Relations: %li""\n",
(pmsg->primitivegroup[j]->dense ?
pmsg->primitivegroup[j]->dense->n_id :
pmsg->primitivegroup[j]->n_nodes),
pmsg->primitivegroup[j]->n_ways,
pmsg->primitivegroup[j]->n_relations);
/* TODO: Nodes is *untested* */
if (pmsg->primitivegroup[j]->n_nodes > 0) {
for (unsigned k = 0; k < pmsg->primitivegroup[j]->n_nodes; k++) {
Node *node = pmsg->primitivegroup[j]->nodes[k];
printf("\t""<node id=\"%li\" lat=\"%.07f\" lon=\"%.07f\"",
node->id,
lat_offset + (node->lat * granularity),
lon_offset + (node->lon * granularity));
if (node->info) {
Info *info = node->info;
if (info->has_version) {
printnumericattribute("version", info->version);
}
if (info->has_changeset) {
printnumericattribute("changeset", info->changeset);
}
if (info->has_user_sid) {
ProtobufCBinaryData user = pmsg->stringtable->s[info->user_sid];
printuser(user);
}
if (info->has_uid) {
printnumericattribute("uid", info->uid);
}
if (info->has_timestamp) {
printtimestamp("timestamp", info->timestamp);
}
}
if (node->n_keys == 0 || node->n_vals == 0) {
fputs_unlocked("/>""\n", stdout);
} else {
fputs_unlocked(">""\n", stdout);
for (unsigned l = 0; l < node->n_keys; l++) {
ProtobufCBinaryData key = pmsg->stringtable->s[node->keys[l]];
ProtobufCBinaryData val = pmsg->stringtable->s[node->vals[l]];
printtag(key, val);
}
fputs_unlocked("\t""</node>""\n", stdout);
}
}
}
else
if (pmsg->primitivegroup[j]->n_ways > 0) {
for (unsigned k = 0; k < pmsg->primitivegroup[j]->n_ways; k++) {
Way *way = pmsg->primitivegroup[j]->ways[k];
printsotid("way", way->id);
if (way->info) {
Info *info = way->info;
if (info->has_version) {
printnumericattribute("version", info->version);
}
if (info->has_changeset) {
printnumericattribute("changeset", info->changeset);
}
if (info->has_user_sid) {
ProtobufCBinaryData user = pmsg->stringtable->s[info->user_sid];
printuser(user);
}
if (info->has_uid) {
printnumericattribute("uid", info->uid);
}
if (info->has_timestamp) {
printtimestamp("timestamp", info->timestamp);
}
}
if ((way->n_keys == 0 || way->n_vals == 0) && way->n_refs == 0) {
fputs_unlocked("/>""\n", stdout);
} else {
long int deltaref = 0;
fputs_unlocked(">""\n", stdout);
for (unsigned l = 0; l < way->n_refs; l++) {
deltaref += way->refs[l];
printnd(deltaref);
}
for (unsigned l = 0; l < way->n_keys; l++) {
ProtobufCBinaryData key = pmsg->stringtable->s[way->keys[l]];
ProtobufCBinaryData val = pmsg->stringtable->s[way->vals[l]];
printtag(key, val);
}
fputs_unlocked("\t""</way>""\n", stdout);
}
}
}
else
if (pmsg->primitivegroup[j]->n_relations > 0) {
for (unsigned k = 0; k < pmsg->primitivegroup[j]->n_relations; k++) {
Relation *relation = pmsg->primitivegroup[j]->relations[k];
printsotid("relation", relation->id);
if (relation->info) {
Info *info = relation->info;
if (info->has_version) {
printnumericattribute("version", info->version);
}
if (info->has_changeset) {
printnumericattribute("changeset", info->changeset);
}
if (info->has_user_sid) {
ProtobufCBinaryData user = pmsg->stringtable->s[info->user_sid];
printuser(user);
}
if (info->has_uid) {
printnumericattribute("uid", info->uid);
}
if (info->has_timestamp) {
printtimestamp("timestamp", info->timestamp);
}
}
if ((relation->n_keys == 0 || relation->n_vals == 0) && relation->n_memids == 0) {
fputs_unlocked("/>""\n", stdout);
} else {
long int deltamemids = 0;
fputs_unlocked(">""\n", stdout);
for (unsigned l = 0; l < relation->n_memids; l++) {
char *type;
ProtobufCBinaryData role = pmsg->stringtable->s[relation->roles_sid[l]];
deltamemids += relation->memids[l];
switch (relation->types[l]) {
case RELATION__MEMBER_TYPE__NODE:
type = "node";
break;
case RELATION__MEMBER_TYPE__WAY:
type = "way";
break;
case RELATION__MEMBER_TYPE__RELATION:
type = "relation";
break;
default:
fprintf(stderr, "Unsupported type: %u""\n", relation->types[l]);
return 1;
}
printmember(type, deltamemids, role);
}
for (unsigned l = 0; l < relation->n_keys; l++) {
ProtobufCBinaryData key = pmsg->stringtable->s[relation->keys[l]];
ProtobufCBinaryData val = pmsg->stringtable->s[relation->vals[l]];
printtag(key, val);
}
fputs_unlocked("\t""</relation>""\n", stdout);
}
}
}
else
if (pmsg->primitivegroup[j]->n_changesets > 0) {
for (unsigned k = 0; k < pmsg->primitivegroup[j]->n_changesets; k++) {
ChangeSet *changeset = pmsg->primitivegroup[j]->changesets[k];
printsotid("changeset", changeset->id);
if (changeset->info) {
Info *info = changeset->info;
/* Not in Changeset
if (info->has_version) {
printnumericattribute("version", info->version);
}
if (info->has_changeset) {
printnumericattribute("changeset", info->changeset);
}*/
if (info->has_user_sid) {
ProtobufCBinaryData user = pmsg->stringtable->s[info->user_sid];
printuser(user);
}
if (info->has_uid) {
printnumericattribute("uid", info->uid);
}
if (info->has_timestamp) {
printtimestamp("created_at", info->timestamp);
if (changeset->has_closetime_delta) {
printtimestamp("closed_at", (info->timestamp + changeset->closetime_delta));
}
}
}
printf(" open=\"%s\" min_lon=\"%.07f\" min_lat=\"%.07f\" max_lon=\"%.07f\" max_lat=\"%.07f\"",
(changeset->open ? "true" : "false"),
lat_offset + (changeset->bbox->left * granularity),
lon_offset + (changeset->bbox->bottom * granularity),
lat_offset + (changeset->bbox->right * granularity),
lon_offset + (changeset->bbox->top * granularity));
if (changeset->n_keys == 0 || changeset->n_vals == 0) {
fputs_unlocked("/>""\n", stdout);
} else {
fputs_unlocked(">""\n", stdout);
for (unsigned l = 0; l < changeset->n_keys; l++) {
ProtobufCBinaryData key = pmsg->stringtable->s[changeset->keys[l]];
ProtobufCBinaryData val = pmsg->stringtable->s[changeset->vals[l]];
printtag(key, val);
}
fputs_unlocked("\t""</changeset>""\n", stdout);
}
}
}
else
if (pmsg->primitivegroup[j]->dense) {
unsigned l = 0;
unsigned long int deltaid = 0;
long int deltalat = 0;
long int deltalon = 0;
unsigned long int deltatimestamp = 0;
unsigned long int deltachangeset = 0;
long int deltauid = 0;
unsigned long int deltauser_sid = 0;
DenseNodes *dense = pmsg->primitivegroup[j]->dense;
for (unsigned k = 0; k < dense->n_id; k++) {
unsigned char has_tags = 0;
deltaid += dense->id[k];
deltalat += dense->lat[k];
deltalon += dense->lon[k];
printf("\t""<node id=\"%li\" lat=\"%.07f\" lon=\"%.07f\"", deltaid,
lat_offset + (deltalat * granularity),
lon_offset + (deltalon * granularity));
if (dense->denseinfo) {
DenseInfo *denseinfo = dense->denseinfo;
deltatimestamp += denseinfo->timestamp[k];
deltachangeset += denseinfo->changeset[k];
deltauid += denseinfo->uid[k];
deltauser_sid += denseinfo->user_sid[k];
printnumericattribute("version", denseinfo->version[k]);
printnumericattribute("changeset", deltachangeset);
if (deltauid != -1) { // osmosis devs failed to read the specs
printuser(pmsg->stringtable->s[deltauser_sid]);
printnumericattribute("uid", deltauid);
}
printtimestamp("timestamp", deltatimestamp);
}
if (l < dense->n_keys_vals) {
while (dense->keys_vals[l] != 0 && l < dense->n_keys_vals) {
if (has_tags < 1) {
has_tags++;
fputs_unlocked(">\n", stdout);
}
ProtobufCBinaryData key = pmsg->stringtable->s[dense->keys_vals[l]];
ProtobufCBinaryData val = pmsg->stringtable->s[dense->keys_vals[l+1]];
printtag(key, val);
l += 2;
}
l += 1;
}
if (has_tags < 1) {
fputs_unlocked("/>""\n", stdout);
} else {
fputs_unlocked("\t""</node>""\n", stdout);
}
}
}
}
primitive_block__free_unpacked (pmsg, &protobuf_c_system_allocator);
}
if (!bmsg->has_raw) free(uncompressed);
blob__free_unpacked (bmsg, &protobuf_c_system_allocator);
} while (!feof(fd));
fputs_unlocked("</osm>""\n", stdout);
if (!feof(fd)) {
fprintf(stderr, "Input processing terminated early\n");
return 1;
}
return 0;
}
