void bt_free(struct list_s *n, free_fn freev)
{
if(!n)
return;
freev(n->data[BT_VALUE]);
type_free(UnsignedLong, n->data[BT_COUNT]);
bt_free(n->data[BT_LEFT], freev);
bt_free(n->data[BT_RIGHT], freev);
list_free(n);
}
static void
vmem_destroy1(vmem_t *vm)
{
#if defined(QCACHE)
qc_destroy(vm);
#endif /* defined(QCACHE) */
if (vm->vm_hashlist != NULL) {
int i;
for (i = 0; i < vm->vm_hashsize; i++) {
bt_t *bt;
while ((bt = LIST_FIRST(&vm->vm_hashlist[i])) != NULL) {
KASSERT(bt->bt_type == BT_TYPE_SPAN_STATIC);
bt_free(vm, bt);
}
}
if (vm->vm_hashlist != &vm->vm_hash0) {
xfree(vm->vm_hashlist,
sizeof(struct vmem_hashlist *) * vm->vm_hashsize);
}
}
bt_freetrim(vm, 0);
VMEM_CONDVAR_DESTROY(vm);
VMEM_LOCK_DESTROY(vm);
xfree(vm, sizeof(*vm));
}
/*
* The matching process is defined as "each and every UUID
* specified in the "search pattern" must be present in the
* "target pattern". Here "search pattern" is the set of UUIDs
* specified by the service discovery client and "target pattern"
* is the set of UUIDs present in a service record.
*
* Return 1 if each and every UUID in the search
* pattern exists in the target pattern, 0 if the
* match succeeds and -1 on error.
*/
static int sdp_match_uuid(sdp_list_t *search, sdp_list_t *pattern)
{
/*
* The target is a sorted list, so we need not look
* at all elements to confirm existence of an element
* from the search pattern
*/
int patlen = sdp_list_len(pattern);
if (patlen < sdp_list_len(search))
return -1;
for (; search; search = search->next) {
uuid_t *uuid128;
void *data = search->data;
sdp_list_t *list;
if (data == NULL)
return -1;
// create 128-bit form of the search UUID
uuid128 = sdp_uuid_to_uuid128((uuid_t *)data);
list = sdp_list_find(pattern, uuid128, sdp_uuid128_cmp);
bt_free(uuid128);
if (!list)
return 0;
}
return 1;
}
void test_bt_1(CuTest* tc) {
int val;
int i;
bt* tree;
tree = bt_new(sizeof(int), 4);
printf("Empty:\n");
bt_print(tree, print_int);
printf("\n");
{
int vals[] = { 10, 5, 100, 10, 50, 50, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 200,200,200,200,200,250,150 };
for (i=0; i<sizeof(vals)/sizeof(int); i++) {
val = vals[i];
printf("Insert %i:\n", val);
bt_insert(tree, &val, 0, compare_ints);
//bt_print(tree, print_int);
printf("\n");
}
}
printf("Values: ");
for (i=0; i<tree->N; i++) {
int val = *(int*)bt_access(tree, i);
printf("%i ", val);
// these tests depend on the values in the "vals" array above.
if (i < 11) {
CuAssertIntEquals(tc, 1, val);
} else if (i < 12) {
CuAssertIntEquals(tc, 5, val);
} else if (i < 14) {
CuAssertIntEquals(tc, 10, val);
} else if (i < 16) {
CuAssertIntEquals(tc, 50, val);
} else if (i < 17) {
CuAssertIntEquals(tc, 100, val);
} else if (i < 18) {
CuAssertIntEquals(tc, 150, val);
} else if (i < 23) {
CuAssertIntEquals(tc, 200, val);
} else {
CuAssertIntEquals(tc, 250, val);
}
}
printf("\n");
{
int vals[] = { 0, 1, 2, 9, 10, 11, 49, 50, 51, 99, 100, 101, 149, 150, 151, 199, 200, 201, 249, 250, 251 };
int doesit[]={ 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0 };
for (i=0; i<sizeof(vals)/sizeof(int); i++) {
int youthink;
val = vals[i];
youthink = bt_contains(tree, &val, compare_ints);
printf("Contains %i: %s\n", val, (youthink ? "yes" : "no"));
CuAssertIntEquals(tc, doesit[i], youthink);
}
}
bt_free(tree);
}
void
check_version(int dev_id)
{
struct hci_version ver;
char *lmpver;
if ((typ.dd = hci_open_dev(dev_id)) < 0)
die("Could not open device\n");
if (hci_read_local_version(typ.dd, &ver, 1000) < 0)
die("Can't read version info hci0\n");
lmpver = lmp_vertostr(ver.lmp_ver);
if (strcmp(lmpver, "4.0")) {
printf("You need a Bluetooth 4.0 LE device\n");
bt_free(lmpver);
exit(1);
} else {
bt_free(lmpver);
}
hci_close_dev(typ.dd);
}
/* Search and connect
* Returns:
* -1 - critical error (exit persist mode)
* 1 - non critical error
* 0 - success
*/
static int do_connect(void)
{
inquiry_info *ii;
int reconnect = 0;
int i, n, r = 0;
do {
if (reconnect)
sleep(persist);
reconnect = 1;
if (cache.valid) {
/* Use cached bdaddr */
r = create_connection(cache.dst, &cache.bdaddr, 0);
if (r < 0) {
terminate = 1;
break;
}
continue;
}
syslog(LOG_INFO, "Inquiring");
/* FIXME: Should we use non general LAP here ? */
ii = NULL;
n = hci_inquiry(src_dev, search_duration, 0, NULL, &ii, 0);
if (n < 0) {
syslog(LOG_ERR, "Inquiry failed. %s(%d)", strerror(errno), errno);
continue;
}
for (i = 0; i < n; i++) {
char dst[40];
ba2str(&ii[i].bdaddr, dst);
r = create_connection(dst, &ii[i].bdaddr, 0);
if (r < 0) {
terminate = 1;
break;
}
}
bt_free(ii);
} while (!terminate && persist);
return r;
}
void test_bt_many(CuTest* tc) {
int val;
int i;
bt* tree;
printf("Inserting many items...\n");
tree = bt_new(sizeof(int), 32);
for (i=0; i<100000; i++) {
val = rand() % 1000;
bt_insert(tree, &val, 0, compare_ints);
//bt_check(tree);
}
printf("Checking...\n");
CuAssertIntEquals(tc, 0, bt_check(tree));
printf("Done.\n");
bt_free(tree);
}
static int
vmem_add1(vmem_t *vm, vmem_addr_t addr, vmem_size_t size, vm_flag_t flags,
int spanbttype)
{
bt_t *btspan;
bt_t *btfree;
KASSERT((flags & (VM_SLEEP|VM_NOSLEEP)) != 0);
KASSERT((~flags & (VM_SLEEP|VM_NOSLEEP)) != 0);
KASSERT(spanbttype == BT_TYPE_SPAN ||
spanbttype == BT_TYPE_SPAN_STATIC);
btspan = bt_alloc(vm, flags);
if (btspan == NULL) {
return ENOMEM;
}
btfree = bt_alloc(vm, flags);
if (btfree == NULL) {
bt_free(vm, btspan);
return ENOMEM;
}
btspan->bt_type = spanbttype;
btspan->bt_start = addr;
btspan->bt_size = size;
btfree->bt_type = BT_TYPE_FREE;
btfree->bt_start = addr;
btfree->bt_size = size;
VMEM_LOCK(vm);
bt_insseg_tail(vm, btspan);
bt_insseg(vm, btfree, btspan);
bt_insfree(vm, btfree);
vm->vm_size += size;
VMEM_UNLOCK(vm);
return 0;
}
int hpquads(startree_t* starkd,
codefile_t* codes,
quadfile_t* quads,
int Nside,
double scale_min_arcmin,
double scale_max_arcmin,
int dimquads,
int passes,
int Nreuses,
int Nloosen,
int id,
anbool scanoccupied,
void* sort_data,
int (*sort_func)(const void*, const void*),
int sort_size,
char** args, int argc) {
hpquads_t myhpquads;
hpquads_t* me = &myhpquads;
int i;
int pass;
anbool circle = TRUE;
double radius2;
il* hptotry;
int Nhptotry = 0;
int nquads;
double hprad;
double quadscale;
int skhp, sknside;
qfits_header* qhdr;
qfits_header* chdr;
int N;
int dimcodes;
int quadsize;
int NHP;
memset(me, 0, sizeof(hpquads_t));
if (Nside > HP_MAX_INT_NSIDE) {
ERROR("Error: maximum healpix Nside = %i", HP_MAX_INT_NSIDE);
return -1;
}
if (Nreuses > 255) {
ERROR("Error, reuse (-r) must be less than 256");
return -1;
}
me->Nside = Nside;
me->dimquads = dimquads;
NHP = 12 * Nside * Nside;
dimcodes = dimquad2dimcode(dimquads);
quadsize = sizeof(unsigned int) * dimquads;
logmsg("Nside=%i. Nside^2=%i. Number of healpixes=%i. Healpix side length ~ %g arcmin.\n",
me->Nside, me->Nside*me->Nside, NHP, healpix_side_length_arcmin(me->Nside));
me->sort_data = sort_data;
me->sort_func = sort_func;
me->sort_size = sort_size;
tic();
me->starkd = starkd;
N = startree_N(me->starkd);
logmsg("Star tree contains %i objects.\n", N);
// get the "HEALPIX" header from the skdt...
skhp = qfits_header_getint(startree_header(me->starkd), "HEALPIX", -1);
if (skhp == -1) {
if (!qfits_header_getboolean(startree_header(me->starkd), "ALLSKY", FALSE)) {
logmsg("Warning: skdt does not contain \"HEALPIX\" header. Code and quad files will not contain this header either.\n");
}
}
// likewise "HPNSIDE"
sknside = qfits_header_getint(startree_header(me->starkd), "HPNSIDE", 1);
if (sknside && Nside % sknside) {
logerr("Error: Nside (-n) must be a multiple of the star kdtree healpixelisation: %i\n", sknside);
return -1;
}
if (!scanoccupied && (N*(skhp == -1 ? 1 : sknside*sknside*12) < NHP)) {
logmsg("\n\n");
logmsg("NOTE, your star kdtree is sparse (has only a fraction of the stars expected)\n");
logmsg(" so you probably will get much faster results by setting the \"-E\" command-line\n");
logmsg(" flag.\n");
logmsg("\n\n");
}
quads->dimquads = me->dimquads;
codes->dimcodes = dimcodes;
quads->healpix = skhp;
codes->healpix = skhp;
quads->hpnside = sknside;
codes->hpnside = sknside;
if (id) {
quads->indexid = id;
codes->indexid = id;
}
qhdr = quadfile_get_header(quads);
chdr = codefile_get_header(codes);
add_headers(qhdr, args, argc, startree_header(me->starkd), circle, passes);
add_headers(chdr, args, argc, startree_header(me->starkd), circle, passes);
if (quadfile_write_header(quads)) {
ERROR("Couldn't write headers to quad file");
return -1;
}
if (codefile_write_header(codes)) {
ERROR("Couldn't write headers to code file");
return -1;
}
quads->numstars = codes->numstars = N;
me->quad_dist2_upper = arcmin2distsq(scale_max_arcmin);
me->quad_dist2_lower = arcmin2distsq(scale_min_arcmin);
codes->index_scale_upper = quads->index_scale_upper = distsq2rad(me->quad_dist2_upper);
codes->index_scale_lower = quads->index_scale_lower = distsq2rad(me->quad_dist2_lower);
me->nuses = calloc(N, sizeof(unsigned char));
// hprad = sqrt(2) * (healpix side length / 2.)
hprad = arcmin2dist(healpix_side_length_arcmin(Nside)) * M_SQRT1_2;
quadscale = 0.5 * sqrt(me->quad_dist2_upper);
// 1.01 for a bit of safety. we'll look at a few extra stars.
radius2 = square(1.01 * (hprad + quadscale));
me->radius2 = radius2;
logmsg("Healpix radius %g arcsec, quad scale %g arcsec, total %g arcsec\n",
distsq2arcsec(hprad*hprad),
distsq2arcsec(quadscale*quadscale),
distsq2arcsec(radius2));
hptotry = il_new(1024);
if (scanoccupied) {
logmsg("Scanning %i input stars...\n", N);
for (i=0; i<N; i++) {
double xyz[3];
int j;
if (startree_get(me->starkd, i, xyz)) {
ERROR("Failed to get star %i", i);
return -1;
}
j = xyzarrtohealpix(xyz, Nside);
il_insert_unique_ascending(hptotry, j);
if (log_get_level() > LOG_VERB) {
double ra,dec;
if (startree_get_radec(me->starkd, i, &ra, &dec)) {
ERROR("Failed to get RA,Dec for star %i\n", i);
return -1;
}
logdebug("star %i: RA,Dec %g,%g; xyz %g,%g,%g; hp %i\n",
i, ra, dec, xyz[0], xyz[1], xyz[2], j);
}
}
logmsg("Will check %zu healpixes.\n", il_size(hptotry));
if (log_get_level() > LOG_VERB) {
logdebug("Checking healpixes: [ ");
for (i=0; i<il_size(hptotry); i++)
logdebug("%i ", il_get(hptotry, i));
logdebug("]\n");
}
} else {
if (skhp == -1) {
// Try all healpixes.
il_free(hptotry);
hptotry = NULL;
Nhptotry = NHP;
} else {
// The star kdtree may itself be healpixed
int starhp, starx, stary;
// In that case, the healpixes we are interested in form a rectangle
// within a big healpix. These are the coords (in [0, Nside)) of
// that rectangle.
int x0, x1, y0, y1;
int x, y;
healpix_decompose_xy(skhp, &starhp, &starx, &stary, sknside);
x0 = starx * (Nside / sknside);
x1 = (starx+1) * (Nside / sknside);
y0 = stary * (Nside / sknside);
y1 = (stary+1) * (Nside / sknside);
for (y=y0; y<y1; y++) {
for (x=x0; x<x1; x++) {
int j = healpix_compose_xy(starhp, x, y, Nside);
il_append(hptotry, j);
}
}
assert(il_size(hptotry) == (Nside/sknside) * (Nside/sknside));
}
}
if (hptotry)
Nhptotry = il_size(hptotry);
me->quadlist = bl_new(65536, quadsize);
if (Nloosen)
me->retryhps = il_new(1024);
for (pass=0; pass<passes; pass++) {
char key[64];
int nthispass;
logmsg("Pass %i of %i.\n", pass+1, passes);
logmsg("Trying %i healpixes.\n", Nhptotry);
nthispass = build_quads(me, Nhptotry, hptotry, Nreuses);
logmsg("Made %i quads (out of %i healpixes) this pass.\n", nthispass, Nhptotry);
logmsg("Made %i quads so far.\n", (me->bigquadlist ? bt_size(me->bigquadlist) : 0) + (int)bl_size(me->quadlist));
sprintf(key, "PASS%i", pass+1);
fits_header_mod_int(chdr, key, nthispass, "quads created in this pass");
fits_header_mod_int(qhdr, key, nthispass, "quads created in this pass");
logmsg("Merging quads...\n");
if (!me->bigquadlist)
me->bigquadlist = bt_new(quadsize, 256);
for (i=0; i<bl_size(me->quadlist); i++) {
void* q = bl_access(me->quadlist, i);
bt_insert2(me->bigquadlist, q, FALSE, compare_quads, &me->dimquads);
}
bl_remove_all(me->quadlist);
}
il_free(hptotry);
hptotry = NULL;
if (Nloosen) {
int R;
for (R=Nreuses+1; R<=Nloosen; R++) {
il* trylist;
int nthispass;
logmsg("Loosening reuse maximum to %i...\n", R);
logmsg("Trying %zu healpixes.\n", il_size(me->retryhps));
if (!il_size(me->retryhps))
break;
trylist = me->retryhps;
me->retryhps = il_new(1024);
nthispass = build_quads(me, il_size(trylist), trylist, R);
logmsg("Made %i quads (out of %zu healpixes) this pass.\n", nthispass, il_size(trylist));
il_free(trylist);
for (i=0; i<bl_size(me->quadlist); i++) {
void* q = bl_access(me->quadlist, i);
bt_insert2(me->bigquadlist, q, FALSE, compare_quads, &me->dimquads);
}
bl_remove_all(me->quadlist);
}
}
if (me->retryhps)
il_free(me->retryhps);
kdtree_free_query(me->res);
me->res = NULL;
me->inds = NULL;
me->stars = NULL;
free(me->nuses);
me->nuses = NULL;
logmsg("Writing quads...\n");
// add the quads from the big-quadlist
nquads = bt_size(me->bigquadlist);
for (i=0; i<nquads; i++) {
unsigned int* q = bt_access(me->bigquadlist, i);
quad_write(codes, quads, q, me->starkd, me->dimquads, dimcodes);
}
// add the quads that were made during the final round.
for (i=0; i<bl_size(me->quadlist); i++) {
unsigned int* q = bl_access(me->quadlist, i);
quad_write(codes, quads, q, me->starkd, me->dimquads, dimcodes);
}
// fix output file headers.
if (quadfile_fix_header(quads)) {
ERROR("Failed to fix quadfile headers");
return -1;
}
if (codefile_fix_header(codes)) {
ERROR("Failed to fix codefile headers");
return -1;
}
bl_free(me->quadlist);
bt_free(me->bigquadlist);
toc();
logmsg("Done.\n");
return 0;
}
static DBusMessage *request_authorization(DBusConnection *conn,
DBusMessage *msg, void *data)
{
struct record_data *user_record;
struct service_adapter *serv_adapter = data;
sdp_record_t *record;
sdp_list_t *services;
const char *sender;
dbus_uint32_t handle;
const char *address;
struct pending_auth *auth;
char uuid_str[MAX_LEN_UUID_STR];
uuid_t *uuid, *uuid128;
bdaddr_t src;
if (dbus_message_get_args(msg, NULL, DBUS_TYPE_STRING, &address,
DBUS_TYPE_UINT32, &handle,
DBUS_TYPE_INVALID) == FALSE)
return NULL;
sender = dbus_message_get_sender(msg);
if (find_pending_by_sender(serv_adapter, sender))
return btd_error_does_not_exist(msg);
user_record = find_record(serv_adapter, handle, sender);
if (!user_record) {
user_record = find_record(serv_adapter_any, handle, sender);
if (!user_record)
return btd_error_not_authorized(msg);
}
record = sdp_record_find(user_record->handle);
if (record == NULL)
return btd_error_not_authorized(msg);
if (sdp_get_service_classes(record, &services) < 0) {
sdp_record_free(record);
return btd_error_not_authorized(msg);
}
if (services == NULL)
return btd_error_not_authorized(msg);
uuid = services->data;
uuid128 = sdp_uuid_to_uuid128(uuid);
sdp_list_free(services, bt_free);
if (sdp_uuid2strn(uuid128, uuid_str, MAX_LEN_UUID_STR) < 0) {
bt_free(uuid128);
return btd_error_not_authorized(msg);
}
bt_free(uuid128);
auth = g_new0(struct pending_auth, 1);
auth->msg = dbus_message_ref(msg);
auth->conn = dbus_connection_ref(connection);
auth->sender = user_record->sender;
memcpy(auth->uuid, uuid_str, MAX_LEN_UUID_STR);
str2ba(address, &auth->dst);
serv_adapter->pending_list = g_slist_append(serv_adapter->pending_list,
auth);
auth = next_pending(serv_adapter);
if (auth == NULL)
return btd_error_does_not_exist(msg);
if (serv_adapter->adapter)
adapter_get_address(serv_adapter->adapter, &src);
else
bacpy(&src, BDADDR_ANY);
if (btd_request_authorization(&src, &auth->dst, auth->uuid, auth_cb,
serv_adapter) < 0) {
serv_adapter->pending_list = g_slist_remove(serv_adapter->pending_list,
auth);
g_free(auth);
return btd_error_not_authorized(msg);
}
return NULL;
}
void extra_info(int dd, int dev_id, bdaddr_t* bdaddr)
{
uint16_t handle, offset;
uint8_t features[8], max_page = 0;
char name[249], *tmp;
char addr[19] = { 0 };
uint8_t mode, afh_map[10];
struct hci_version version;
struct hci_dev_info di;
struct hci_conn_info_req *cr;
int i, cc = 0;
if (hci_devinfo(dev_id, &di) < 0) {
perror("Can't get device info");
exit(1);
}
printf("Requesting information ...\n");
cr = malloc(sizeof(*cr) + sizeof(struct hci_conn_info));
if (!cr) {
perror("Can't get connection info");
exit(1);
}
bacpy(&cr->bdaddr, bdaddr);
cr->type = ACL_LINK;
if (ioctl(dd, HCIGETCONNINFO, (unsigned long) cr) < 0) {
if (hci_create_connection(dd, bdaddr,
htobs(di.pkt_type & ACL_PTYPE_MASK),
0, 0x01, &handle, 25000) < 0) {
perror("Can't create connection");
return;
}
sleep(1);
cc = 1;
} else
handle = htobs(cr->conn_info->handle);
ba2str(bdaddr, addr);
printf("\tBD Address: %s\n", addr);
if (hci_read_remote_name(dd, bdaddr, sizeof(name), name, 25000) == 0)
printf("\tDevice Name: %s\n", name);
if (hci_read_remote_version(dd, handle, &version, 20000) == 0) {
char *ver = lmp_vertostr(version.lmp_ver);
printf("\tLMP Version: %s (0x%x) LMP Subversion: 0x%x\n"
"\tManufacturer: %s (%d)\n",
ver ? ver : "n/a",
version.lmp_ver,
version.lmp_subver,
bt_compidtostr(version.manufacturer),
version.manufacturer);
if (ver)
bt_free(ver);
}
memset(features, 0, sizeof(features));
hci_read_remote_features(dd, handle, features, 20000);
if ((di.features[7] & LMP_EXT_FEAT) && (features[7] & LMP_EXT_FEAT))
hci_read_remote_ext_features(dd, handle, 0, &max_page,
features, 20000);
printf("\tFeatures%s: 0x%2.2x 0x%2.2x 0x%2.2x 0x%2.2x "
"0x%2.2x 0x%2.2x 0x%2.2x 0x%2.2x\n",
(max_page > 0) ? " page 0" : "",
features[0], features[1], features[2], features[3],
features[4], features[5], features[6], features[7]);
tmp = lmp_featurestostr(features, "\t\t", 63);
printf("%s\n", tmp);
bt_free(tmp);
for (i = 1; i <= max_page; i++) {
if (hci_read_remote_ext_features(dd, handle, i, NULL,
features, 20000) < 0)
continue;
printf("\tFeatures page %d: 0x%2.2x 0x%2.2x 0x%2.2x 0x%2.2x "
"0x%2.2x 0x%2.2x 0x%2.2x 0x%2.2x\n", i,
features[0], features[1], features[2], features[3],
features[4], features[5], features[6], features[7]);
}
if (hci_read_clock_offset(dd, handle, &offset, 1000) < 0) {
perror("Reading clock offset failed");
exit(1);
}
printf("\tClock offset: 0x%4.4x\n", btohs(offset));
if(hci_read_afh_map(dd, handle, &mode, afh_map, 1000) < 0) {
perror("HCI read AFH map request failed");
}
if(mode == 0x01) {
// DGS: Replace with call to btbb_print_afh_map - need a piconet
printf("\tAFH Map: 0x");
for(i=0; i<10; i++)
printf("%02x", afh_map[i]);
printf("\n");
} else {
printf("AFH disabled.\n");
}
free(cr);
if (cc) {
usleep(10000);
hci_disconnect(dd, handle, HCI_OE_USER_ENDED_CONNECTION, 10000);
}
}
static void getDevices(std::vector<al::Bluetooth>& devs){
/*
See cmd_inq and cmd_scan in tools/hcitool.c.
*/
/* From bluetooth/hci.h:
typedef struct {
bdaddr_t bdaddr;
uint8_t pscan_rep_mode;
uint8_t pscan_period_mode;
uint8_t pscan_mode;
uint8_t dev_class[3];
uint16_t clock_offset;
} __attribute__ ((packed)) inquiry_info;
*/
/*static const char *inq_help =
"Usage:\n"
"\tinq [--length=N] maximum inquiry duration in 1.28 s units\n"
"\t [--numrsp=N] specify maximum number of inquiry responses\n"
"\t [--iac=lap] specify the inquiry access code\n"
"\t [--flush] flush the inquiry cache\n";*/
// First determine if there is a Bluetooth controller
int dev_id = hci_get_route(NULL);
if (dev_id < 0) {
perror("Bluetooth not available");
return;
}
inquiry_info *info = NULL;
uint8_t lap[3] = { 0x33, 0x8b, 0x9e };
int num_rsp = 16; // max number responses
int length = 8; // max inquiry response time, in 1.28 s
int flags = 0;
char addr[18], name[249];
num_rsp = hci_inquiry(dev_id, length, num_rsp, lap, &info, flags);
if (num_rsp < 0) {
perror("Bluetooth HCI inquiry failed.");
return;
}
int dd = hci_open_dev(dev_id);
if (dd < 0) {
perror("Bluetooth HCI device open failed");
bt_free(info);
return;
}
Bluetooth bt;
for (int i = 0; i < num_rsp; i++) {
ba2str(&info[i].bdaddr, addr);
if(hci_read_remote_name_with_clock_offset(dd,
&info[i].bdaddr,
info[i].pscan_rep_mode,
info[i].clock_offset | 0x8000,
sizeof(name), name, 100000)
< 0){
strcpy(name, "n/a");
}
bt.mName = std::string(name);
bt.mAddr = std::string(addr);
bt.mClass= (unsigned(info[i].dev_class[2])<<16) | (unsigned(info[i].dev_class[1])<<8) | info[i].dev_class[0];
devs.push_back(bt);
}
/**/
bt_free(info);
}
lui_bt *bt_newA(tagitem *taglist)
{
tagitem *t;
lui_bt *bt;
SDL_Rect src, dst;
SDL_PixelFormat *format;
bt = calloc(1, sizeof(lui_bt));
if(!bt) return NULL;
bt->id = -1;
bt->type = GAD_BUTTON;
t = tag_next(&taglist);
while(t) {
switch(t->tag) {
case LUI_NAME:
bt->name = strdup((char *)t->data);
break;
case LUI_ID:
bt->id = t->data;
break;
case LUI_DATA:
bt->data = (void *)t->data;
break;
case LUI_ACTIVATEHOOK:
bt->onactivate = (void *)t->data;
break;
case LUI_XPOS:
bt->x = t->data;
break;
case LUI_YPOS:
bt->y = t->data;
break;
case LUI_WIDTH:
bt->w = t->data;
break;
case LUI_HEIGHT:
bt->h = t->data;
break;
case LUI_SCREEN:
bt->screen = (SDL_Surface *)t->data;
break;
case LBT_IMAGE:
bt->image = IMG_Load((char *)t->data);
break;
case LBT_HLIMAGE:
bt->hlimage = IMG_Load((char *)t->data);
break;
case LBT_CLICKIMAGE:
bt->click = IMG_Load((char *)t->data);
break;
case LBT_HLCLICKIMAGE:
bt->hlclick = IMG_Load((char *)t->data);
break;
case LBT_TILESET:
bt->tileset = (xitiles *)t->data;
break;
case LBT_TILE:
bt->tile = t->data;
break;
case LBT_HLTILE:
bt->hltile = t->data;
break;
case LBT_CLICKTILE:
bt->ctile = t->data;
break;
case LBT_HLCLICKTILE:
bt->hlctile = t->data;
break;
case LBT_TOGGLE:
bt->type = GAD_TOGGLE;
break;
}
t = tag_next(&taglist);
}
if(((!bt->image) && (!bt->tileset)) || (!bt->screen)) {
bt_free(bt);
return NULL;
}
if(!bt->w) {
if(bt->tileset) {
bt->w = bt->tileset->w;
} else {
bt->w = bt->image->w;
}
}
if(!bt->h) {
if(bt->tileset) {
bt->h = bt->tileset->h;
} else {
bt->h = bt->image->h;
}
}
format = bt->screen->format;
bt->store = SDL_CreateRGBSurface(SDL_RLEACCEL, bt->w, bt->h,
format->BitsPerPixel, format->Rmask, format->Gmask, format->Bmask, format->Amask);
bt->ia = iarea_new(IA_INPUT, IA_CTL_MOUSE, IA_MBUTTONS, IA_LMB_MASK,
IA_XPOS, bt->x, IA_YPOS, bt->y,
IA_WIDTH, bt->w, IA_HEIGHT, bt->h,
IA_CLICK_HOOK, bt_activate,
IA_PASS_HOOK, lui_highlight,
IA_DATA, bt, IA_ID, bt->id,
IA_DELAY, 75,
TAG_END);
src.x = bt->x;
src.y = bt->y;
src.w = bt->w;
src.h = bt->h;
dst.x = 0;
dst.y = 0;
SDL_BlitSurface(bt->screen, &src, bt->store, &dst);
if(!bt->ia) {
bt_free(bt);
return NULL;
}
bt->destroy = bt_free;
bt->activate = bt_activate;
bt->draw = bt_draw;
bt->highlight = bt_highlight;
return bt;
}
int
main() {
struct bt_node *root;
int i, n;
root = bt_node_new(651);
#if 0
n = 20;
/*
for(i = n; i >= 1; --i) {
root = bt_insert(root, i, i+1);
bt_dump(root);
}
printf("----------------\n");
root = bt_node_new(5);
*/
for(i = 1; i <= n; ++i) {
root = bt_insert(root, i, i+1);
}
bt_dump(root);
printf("----------------\n");
bt_save(root, "/tmp/large.bin");
root = bt_load("/tmp/large.bin");
bt_dump(root);
return 0;
#endif
n = 1000*1000;
//n = 20;
#if 1
struct timespec t0, t1, t2, t3, t4;
clock_gettime(CLOCK_MONOTONIC, &t0);
//for(i = n; i >= 1; i--) {
for(i = 1; i < n; i++) {
struct bt_entry *e;
char *key = calloc(20, 1);
sprintf(key, "key-%d", i);
root = bt_insert(root, key, strlen(key), i+1, 0);
continue;
e = bt_lookup(root, key, strlen(key)); /* immediate read-back */
if(e && e->value_offset != (uint32_t)i+1) {
printf("at k=[%d]: %d\n", i, e->value_offset);
}
}
clock_gettime(CLOCK_MONOTONIC, &t1);
printf("saving index of %d elements.\n", n);
bt_save(root, "/tmp/large.bin");
clock_gettime(CLOCK_MONOTONIC, &t2);
// bt_dump(root);
bt_free(root);
printf("saved.\n");
uint32_t offset, size;
char *key = malloc(40);
sprintf(key, "key-%d", 1 + (rand() % (n-1)));
if(0 == bt_find("/tmp/large.bin", key, strlen(key), &offset, &size)) {
printf("%s: offset=%d, size=%d\n", key, (int)offset, (int)size);
} else {
printf("could not find %s\n", key);
}
return 0;
// root = bt_load("/tmp/large.bin");
// clock_gettime(CLOCK_MONOTONIC, &t3);
// printf("loaded.\n");
bt_dump(root);
for(i = 1; i < n; i++) {
char *key = calloc(20, 1);
sprintf(key, "key-%d", i);
struct bt_entry *e = bt_lookup(root, key, strlen(key)); /* read-back after the whole insertion */
if(!e) {
printf("e=nil.\n");
} else if(e->value_offset != (uint32_t)i+1) {
printf("at k=[%d]: %d\n", i, e->value_offset);
}
}
clock_gettime(CLOCK_MONOTONIC, &t4);
printf("checked.\n");
float mili0 = t0.tv_sec * 1000 + t0.tv_nsec / 1000000;
float mili1 = t1.tv_sec * 1000 + t1.tv_nsec / 1000000;
float mili2 = t2.tv_sec * 1000 + t2.tv_nsec / 1000000;
float mili3 = t3.tv_sec * 1000 + t3.tv_nsec / 1000000;
float mili4 = t4.tv_sec * 1000 + t4.tv_nsec / 1000000;
printf("build time: %0.2f sec.\n", (mili1 - mili0)/1000.0);
printf("dump time: %0.2f sec.\n", (mili2 - mili1)/1000.0);
printf("reload time: %0.2f sec.\n", (mili3 - mili2)/1000.0);
printf("check time: %0.2f sec.\n", (mili4 - mili3)/1000.0);
/*
root = bt_node_new(5);
bt_insert(root, 706);
bt_insert(root, 176);
bt_insert(root, 601);
bt_insert(root, 153);
bt_insert(root, 513);
bt_insert(root, 773);
*/
#endif
return EXIT_SUCCESS;
}
