void SkGridView::onSizeChange()
{
fScrollBar->setHeight(this->height());
fScrollBar->setLoc(this->locX() + this->width() - fScrollBar->width(), 0);
if (fCellSize.equals(0, 0))
{
fVisibleCount.set(0, 0);
return;
}
SkScalar rows = SkScalarDiv(this->height(), fCellSize.fY);
SkScalar cols = SkScalarDiv(this->width(), fCellSize.fX);
int y = SkScalarFloor(rows);
int x = SkScalarFloor(cols);
y = check_count(y, rows);
x = check_count(x, cols);
if (!fVisibleCount.equals(x, y))
{
fVisibleCount.set(x, y);
this->ensureSelectionIsVisible();
// this->dirtyStrCache();
}
}
static int
post_lb(POST_ARGS)
{
const char *p;
char *buf;
size_t sz;
check_count(mdoc, MDOC_ELEM, CHECK_WARN, CHECK_EQ, 1);
assert(mdoc->last->child);
assert(MDOC_TEXT == mdoc->last->child->type);
p = mdoc_a2lib(mdoc->last->child->string);
/* If lookup ok, replace with table value. */
if (p) {
free(mdoc->last->child->string);
mdoc->last->child->string = mandoc_strdup(p);
return(1);
}
/* If not, use "library ``xxxx''. */
sz = strlen(mdoc->last->child->string) +
2 + strlen("\\(lqlibrary\\(rq");
buf = mandoc_malloc(sz);
snprintf(buf, sz, "library \\(lq%s\\(rq",
mdoc->last->child->string);
free(mdoc->last->child->string);
mdoc->last->child->string = buf;
return(1);
}
inline void operator()(internal_node const& n)
{
typedef typename rtree::elements_type<internal_node>::type elements_type;
elements_type const& elements = rtree::elements(n);
// root internal node shouldn't contain 0 elements
if ( elements.empty()
|| !check_count(elements) )
{
result = false;
return;
}
size_t current_level_backup = m_current_level;
++m_current_level;
for ( typename elements_type::const_iterator it = elements.begin();
it != elements.end() && result == true ;
++it)
{
rtree::apply_visitor(*this, *it->second);
}
m_current_level = current_level_backup;
}
void init()
{
object me;
me = this_player();
me->add_temp("taohua/count", 13);
check_count(me, 13);
return;
}
void operators()
{
bit_field BF_0(2);
bit_field BF_1(2);
check_count(BF_0);
//==
if(!(BF_0 == BF_1)){
LOG; ++fail;
}
//!=
if(BF_0 != BF_1){
LOG; ++fail;
}
//&=
BF_0 &= BF_1;
if(BF_0[0] != 0){
LOG; ++fail;
}
check_count(BF_0);
//^=
BF_0 ^= BF_1;
if(BF_0[0] != 0){
LOG; ++fail;
}
check_count(BF_0);
//|=
BF_0 |= BF_1;
if(BF_0[0] != 0){
LOG; ++fail;
}
check_count(BF_0);
//~
~BF_0;
if(BF_0[0] != 1){
LOG; ++fail;
}
check_count(BF_0);
//=
BF_0 = BF_1;
if(BF_0[0] != 0){
LOG; ++fail;
}
check_count(BF_0);
//bitgroup_vector::proxy assignment test
BF_0[0] = BF_0[1] = 1;
if(BF_0[0] != 1 || BF_0[1] != 1){
LOG; ++fail;
}
check_count(BF_0);
}
void assignment()
{
//starting with every bit off, turn every even bit on
boost::uint64_t test_size = 16;
bit_field BF(test_size);
for(boost::uint64_t x=0; x<test_size; ++x){
if(x % 2 == 0){
BF[x] = true;
}
}
check_count(BF);
//make sure every even bit on
for(boost::uint64_t x=0; x<test_size; ++x){
if(x % 2 == 0){
if(BF[x] != true){
LOG; ++fail;
}
}
}
check_count(BF);
//starting with every bit on, turn every even bit off
BF.set();
for(boost::uint64_t x=0; x<test_size; ++x){
if(x % 2 == 0){
BF[x] = false;
}
}
check_count(BF);
//make sure every even bit off
for(boost::uint64_t x=0; x<test_size; ++x){
if(x % 2 == 0){
if(BF[x] != false){
LOG; ++fail;
}
}
}
check_count(BF);
}
inline void operator()(leaf const& n)
{
typedef typename rtree::elements_type<leaf>::type elements_type;
elements_type const& elements = rtree::elements(n);
// empty leaf in non-root node
if ( ( m_current_level > 0 && elements.empty() )
|| !check_count(elements) )
{
result = false;
}
}
void named_functions()
{
bit_field BF(1);
//size function
if(BF.size() != 1){
LOG; ++fail;
}
//reset function
BF[0] = 1;
if(BF[0] != 1){
LOG; ++fail;
}
check_count(BF);
BF.reset();
if(BF[0] == 1){
LOG; ++fail;
}
check_count(BF);
}
void counting()
{
if(r==1&&c==(n+1))
{ // all combinations exhausted
printf("THE NUMBER OF SOLUTIONS ARE: %ld\n",count);
exit(1);
}
if(r==n+1)
{ //a possible solution reached
r=n;
c=pos[r];
mat[r][c]=' ';
c=c+1;
counting();
}
if((c<=n)&&(check_fnc(r,c)) )
{
mat[r][c]='q'; //to check the postion in current row
if(check_count())
{
count++;
if(count==1||count==2)
disp();
}
pos[r]=c;
r=r+1;
c=1;
counting();
}
else
{
if(c<n)
{
c++;
counting();
}
else
{ // to move from curent row to the previous one and rearranging the previous one
c=pos[r];
mat[r][c]=' ';
r=r-1;
c=pos[r];
mat[r][c]=' ';
c=c+1;
counting();
}
}
}
void solve(int a, int b) {
// 长除法
int i;
int mod;
if(a % b == 0) {
fprintf(fout, "%d.", dec[0]);
count = len(dec[0]) + 1;
for( i = 1 ; i < p ; i++ ) {
fprintf(fout, "%hi", dec[i]);
check_count();
}
fprintf(fout, "%d\n", a/b);
return;
}else{
dec[p] = a / b;
res[p] = a % b;
mod = a % b;
if(hash[mod]) {
// 进入循环处理阶段
fprintf(fout, "%d.", dec[0]);
count = len(dec[0]) + 1;
i = 0;
while(1) {
if(res[i] == mod) {
fprintf(fout, "(%d", dec[i+1]);
check_count();
check_count();
break;
}
fprintf(fout, "%d", dec[i+1]);
check_count();
i = i + 1;
}
i = i + 1;
while(1) {
if(res[i] == mod) {
fprintf(fout, ")\n");
check_count();
break;
}
fprintf(fout, "%d", dec[i+1]);
check_count();
i = i + 1;
}
return;
}
hash[mod] = 1;
solve(res[p++]*10, b);
}
}
static int
post_an(POST_ARGS)
{
struct mdoc_node *np;
np = mdoc->last;
if (AUTH__NONE != np->norm->An.auth && np->child) {
check_count(mdoc, MDOC_ELEM, CHECK_WARN, CHECK_EQ, 0);
return(1);
}
/*
* FIXME: make this ewarn and make sure that the front-ends
* don't print the arguments.
*/
if (AUTH__NONE != np->norm->An.auth || np->child)
return(1);
mdoc_nmsg(mdoc, np, MANDOCERR_NOARGS);
return(1);
}
static int
ebool(struct mdoc *mdoc)
{
if (NULL == mdoc->last->child) {
mdoc_nmsg(mdoc, mdoc->last, MANDOCERR_MACROEMPTY);
mdoc_node_delete(mdoc, mdoc->last);
return(1);
}
check_count(mdoc, MDOC_ELEM, CHECK_WARN, CHECK_EQ, 1);
assert(MDOC_TEXT == mdoc->last->child->type);
if (0 == strcmp(mdoc->last->child->string, "on"))
return(1);
if (0 == strcmp(mdoc->last->child->string, "off"))
return(1);
mdoc_nmsg(mdoc, mdoc->last, MANDOCERR_BADBOOL);
return(1);
}
static int
ewarn_ge1(POST_ARGS)
{
return(check_count(mdoc, MDOC_ELEM, CHECK_WARN, CHECK_GT, 0));
}
int main(int argc, char *argv[]) {
boost::scoped_ptr<pg::tempdb> db;
try {
db.reset(new pg::tempdb);
} catch (const std::exception &e) {
std::cerr << "Unable to setup database: " << e.what() << "\n";
return 77; // <-- code to skip this test.
}
try {
boost::shared_ptr<middle_pgsql_t> mid_pgsql(new middle_pgsql_t());
options_t options;
options.conninfo = db->conninfo().c_str();
options.num_procs = 1;
options.prefix = "osm2pgsql_test";
options.tblsslim_index = "tablespacetest";
options.tblsslim_data = "tablespacetest";
options.slim = 1;
boost::shared_ptr<geometry_processor> processor =
geometry_processor::create("point", &options);
export_list columns;
{ taginfo info; info.name = "amenity"; info.type = "text"; columns.add(OSMTYPE_NODE, info); }
boost::shared_ptr<output_multi_t> out_test(new output_multi_t("foobar_amenities", processor, columns, mid_pgsql.get(), options));
osmdata_t osmdata(mid_pgsql, out_test);
boost::scoped_ptr<parse_delegate_t> parser(new parse_delegate_t(options.extra_attributes, options.bbox, options.projection));
osmdata.start();
if (parser->streamFile("pbf", "tests/liechtenstein-2013-08-03.osm.pbf", options.sanitize, &osmdata) != 0) {
throw std::runtime_error("Unable to read input file `tests/liechtenstein-2013-08-03.osm.pbf'.");
}
parser.reset(NULL);
osmdata.stop();
// start a new connection to run tests on
pg::conn_ptr test_conn = pg::conn::connect(db->conninfo());
check_count(test_conn, 1,
"select count(*) from pg_catalog.pg_class "
"where relname = 'osm2pgsql_test_foobar_amenities'");
check_count(test_conn, 244,
"select count(*) from osm2pgsql_test_foobar_amenities");
check_count(test_conn, 36,
"select count(*) from osm2pgsql_test_foobar_amenities where amenity='parking'");
check_count(test_conn, 34,
"select count(*) from osm2pgsql_test_foobar_amenities where amenity='bench'");
check_count(test_conn, 1,
"select count(*) from osm2pgsql_test_foobar_amenities where amenity='vending_machine'");
return 0;
} catch (const std::exception &e) {
std::cerr << "ERROR: " << e.what() << std::endl;
} catch (...) {
std::cerr << "UNKNOWN ERROR" << std::endl;
}
return 1;
}
int main(int argc, char *argv[]) {
boost::scoped_ptr<pg::tempdb> db;
try {
db.reset(new pg::tempdb);
} catch (const std::exception &e) {
std::cerr << "Unable to setup database: " << e.what() << "\n";
return 77; // <-- code to skip this test.
}
try {
boost::shared_ptr<middle_pgsql_t> mid_pgsql(new middle_pgsql_t());
options_t options;
options.conninfo = db->conninfo().c_str();
options.num_procs = 1;
options.prefix = "osm2pgsql_test";
options.tblsslim_index = "tablespacetest";
options.tblsslim_data = "tablespacetest";
options.slim = 1;
boost::shared_ptr<geometry_processor> processor =
geometry_processor::create("line", &options);
export_list columns;
{ taginfo info; info.name = "highway"; info.type = "text"; columns.add(OSMTYPE_WAY, info); }
boost::shared_ptr<output_multi_t> out_test(new output_multi_t("foobar_highways", processor, columns, mid_pgsql.get(), options));
osmdata_t osmdata(mid_pgsql, out_test);
boost::scoped_ptr<parse_delegate_t> parser(new parse_delegate_t(options.extra_attributes, options.bbox, options.projection));
osmdata.start();
if (parser->streamFile("pbf", "tests/liechtenstein-2013-08-03.osm.pbf", options.sanitize, &osmdata) != 0) {
throw std::runtime_error("Unable to read input file `tests/liechtenstein-2013-08-03.osm.pbf'.");
}
parser.reset(NULL);
osmdata.stop();
// start a new connection to run tests on
pg::conn_ptr test_conn = pg::conn::connect(db->conninfo());
check_count(test_conn, 1, "select count(*) from pg_catalog.pg_class where relname = 'osm2pgsql_test_foobar_highways'");
check_count(test_conn, 2753, "select count(*) from osm2pgsql_test_foobar_highways");
//check that we have the right spread
check_count(test_conn, 13, "select count(*) from osm2pgsql_test_foobar_highways where highway='bridleway'");
check_count(test_conn, 3, "select count(*) from osm2pgsql_test_foobar_highways where highway='construction'");
check_count(test_conn, 96, "select count(*) from osm2pgsql_test_foobar_highways where highway='cycleway'");
check_count(test_conn, 249, "select count(*) from osm2pgsql_test_foobar_highways where highway='footway'");
check_count(test_conn, 18, "select count(*) from osm2pgsql_test_foobar_highways where highway='living_street'");
check_count(test_conn, 171, "select count(*) from osm2pgsql_test_foobar_highways where highway='path'");
check_count(test_conn, 6, "select count(*) from osm2pgsql_test_foobar_highways where highway='pedestrian'");
check_count(test_conn, 81, "select count(*) from osm2pgsql_test_foobar_highways where highway='primary'");
check_count(test_conn, 842, "select count(*) from osm2pgsql_test_foobar_highways where highway='residential'");
check_count(test_conn, 3, "select count(*) from osm2pgsql_test_foobar_highways where highway='road'");
check_count(test_conn, 90, "select count(*) from osm2pgsql_test_foobar_highways where highway='secondary'");
check_count(test_conn, 1, "select count(*) from osm2pgsql_test_foobar_highways where highway='secondary_link'");
check_count(test_conn, 352, "select count(*) from osm2pgsql_test_foobar_highways where highway='service'");
check_count(test_conn, 34, "select count(*) from osm2pgsql_test_foobar_highways where highway='steps'");
check_count(test_conn, 33, "select count(*) from osm2pgsql_test_foobar_highways where highway='tertiary'");
check_count(test_conn, 597, "select count(*) from osm2pgsql_test_foobar_highways where highway='track'");
check_count(test_conn, 164, "select count(*) from osm2pgsql_test_foobar_highways where highway='unclassified'");
return 0;
} catch (const std::exception &e) {
std::cerr << "ERROR: " << e.what() << std::endl;
} catch (...) {
std::cerr << "UNKNOWN ERROR" << std::endl;
}
return 1;
}
static void
test_filter(CamelMimeFilter *f, const char *inname, const char *outname)
{
CamelStreamMem *in, *out;
CamelStream *indisk, *outdisk, *filter;
int id;
camel_test_push("Data file `%s'", inname);
camel_test_push("setup");
indisk = camel_stream_fs_new_with_name(inname, O_RDONLY, 0);
check(indisk);
outdisk = camel_stream_fs_new_with_name(outname, O_RDONLY, 0);
check(outdisk);
out = (CamelStreamMem *)camel_stream_mem_new();
check(camel_stream_write_to_stream(outdisk, (CamelStream *)out) > 0);
camel_test_pull();
camel_test_push("reading through filter stream");
in = (CamelStreamMem *)camel_stream_mem_new();
filter = (CamelStream *)camel_stream_filter_new_with_stream(indisk);
check_count(indisk, 2);
id = camel_stream_filter_add((CamelStreamFilter *)filter, f);
check_count(f, 2);
check(camel_stream_write_to_stream(filter, (CamelStream *)in) > 0);
check_msg(in->buffer->len == out->buffer->len
&& memcmp(in->buffer->data, out->buffer->data, in->buffer->len) == 0,
"Buffer content mismatch, %d != %d, in = '%.*s' != out = '%.*s'", in->buffer->len, out->buffer->len,
in->buffer->len, in->buffer->data, out->buffer->len, out->buffer->data);
camel_test_pull();
camel_stream_filter_remove((CamelStreamFilter *)filter, id);
check_count(f, 1);
camel_mime_filter_reset(f);
check_unref(filter, 1);
check_count(indisk, 1);
check_count(f, 1);
check_unref(in, 1);
check(camel_stream_reset(indisk) == 0);
camel_test_push("writing through filter stream");
in = (CamelStreamMem *)camel_stream_mem_new();
filter = (CamelStream *)camel_stream_filter_new_with_stream((CamelStream *)in);
check_count(in, 2);
id = camel_stream_filter_add((CamelStreamFilter *)filter, f);
check_count(f, 2);
check(camel_stream_write_to_stream(indisk, filter) > 0);
check(camel_stream_flush(filter) == 0);
check_msg(in->buffer->len == out->buffer->len
&& memcmp(in->buffer->data, out->buffer->data, in->buffer->len) == 0,
"Buffer content mismatch, %d != %d, in = '%.*s' != out = '%.*s'", in->buffer->len, out->buffer->len,
in->buffer->len, in->buffer->data, out->buffer->len, out->buffer->data);
camel_stream_filter_remove((CamelStreamFilter *)filter, id);
check_unref(filter, 1);
check_unref(in, 1);
check_unref(indisk, 1);
check_unref(outdisk, 1);
check_unref(out, 1);
camel_test_pull();
camel_test_pull();
}
int mouse_doing(void)
{
int fd = 0;
int mx = 512;
int my = 384;
char victory = -1;
mouse_info_t mouse_info;
fd = open("/dev/input/mice",O_RDWR|O_NONBLOCK);
if(fd < 0 )
{
perror("open");
exit(1);
}
draw_cursor(mx,my);
print_choice();
while(1)
{
if(get_mouse_info(fd,&mouse_info) > 0)
{
repair_shape(mx,my);
mx += mouse_info.dx;
my += mouse_info.dy;
mx = (mx >= 0) ? mx:0;
my = (my >= 0) ? my:0;
if(mx >= (fb_info.w - C_WIDTH))
{
mx = fb_info.w - C_WIDTH;
}
if(my >= (fb_info.h - C_HEIGHT))
{
my = fb_info.h - C_HEIGHT;
}
draw_cursor(mx,my);
switch(mouse_info.button)
{
case 1:
//printf("%d\n", event.button);
repair_shape(mx, my);
if((draw_one_chess(mx,my)) == 0)
{
check_count(mx,my);
victory = check_all();
}
draw_cursor(mx, my);
break;
case 2:
break;
case 4:
break;
default :
break;
}
if(victory == 1)
{
printf("Player %d won!\n",who);
printf("Continue ? y/n \n");
if(getchar() == '\n')
{
break;
}
else
{
memset((u8_t *)fb_info.fb_mem, 0, fb_info.w*fb_info.h*fb_info.bpp/8);
memset(board, 0, H_NUM*V_NUM);
draw_board();
print_choice();
color_choice = 0x000000ff;
who = 1;
victory = -1;
mx = 512;
my = 384;
draw_cursor(mx, my);
}
getchar();
}
}
usleep(100);
}
return 0;
}
static cairo_test_status_t
draw (cairo_t *cr, int width, int height)
{
const cairo_test_context_t *ctx = cairo_test_get_context (cr);
cairo_surface_t *surface;
cairo_t *cr2;
cairo_rectangle_list_t *rectangle_list;
const char *phase;
cairo_bool_t uses_clip_rects;
surface = cairo_surface_create_similar (cairo_get_group_target (cr),
CAIRO_CONTENT_COLOR, 100, 100);
/* don't use cr accidentally */
cr = NULL;
cr2 = cairo_create (surface);
cairo_surface_destroy (surface);
/* Check the surface type so we ignore cairo_copy_clip_rectangle_list failures
* on surface types that don't use rectangle lists for clipping.
* Default to FALSE for the internal surface types, (meta, test-fallback, etc.)
*/
switch (cairo_surface_get_type (surface)) {
case CAIRO_SURFACE_TYPE_IMAGE:
case CAIRO_SURFACE_TYPE_XLIB:
case CAIRO_SURFACE_TYPE_XCB:
case CAIRO_SURFACE_TYPE_GLITZ:
case CAIRO_SURFACE_TYPE_WIN32:
case CAIRO_SURFACE_TYPE_BEOS:
case CAIRO_SURFACE_TYPE_DIRECTFB:
uses_clip_rects = TRUE;
break;
case CAIRO_SURFACE_TYPE_QUARTZ:
case CAIRO_SURFACE_TYPE_PDF:
case CAIRO_SURFACE_TYPE_PS:
case CAIRO_SURFACE_TYPE_SVG:
case CAIRO_SURFACE_TYPE_OS2:
default:
uses_clip_rects = FALSE;
break;
}
/* first, test basic stuff. This should not be clipped, it should
return the surface rectangle. */
phase = "No clip set";
rectangle_list = cairo_copy_clip_rectangle_list (cr2);
if (!check_count (ctx, phase, uses_clip_rects, rectangle_list, 1) ||
!check_clip_extents (ctx, phase, cr2, 0, 0, 100, 100) ||
!check_rectangles_contain (ctx, phase, uses_clip_rects, rectangle_list, 0, 0, 100, 100)) {
cairo_rectangle_list_destroy (rectangle_list);
return CAIRO_TEST_FAILURE;
}
cairo_rectangle_list_destroy (rectangle_list);
/* Test simple clip rect. */
phase = "Simple clip rect";
cairo_save (cr2);
cairo_rectangle (cr2, 10, 10, 80, 80);
cairo_clip (cr2);
rectangle_list = cairo_copy_clip_rectangle_list (cr2);
if (!check_count (ctx, phase, uses_clip_rects, rectangle_list, 1) ||
!check_clip_extents (ctx, phase, cr2, 10, 10, 80, 80) ||
!check_rectangles_contain (ctx, phase, uses_clip_rects, rectangle_list, 10, 10, 80, 80)) {
cairo_rectangle_list_destroy (rectangle_list);
return CAIRO_TEST_FAILURE;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr2);
/* Test everything clipped out. */
phase = "All clipped out";
cairo_save (cr2);
cairo_clip (cr2);
rectangle_list = cairo_copy_clip_rectangle_list (cr2);
if (!check_count (ctx, phase, uses_clip_rects, rectangle_list, 0)) {
cairo_rectangle_list_destroy (rectangle_list);
return CAIRO_TEST_FAILURE;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr2);
/* test two clip rects */
phase = "Two clip rects";
cairo_save (cr2);
cairo_rectangle (cr2, 10, 10, 10, 10);
cairo_rectangle (cr2, 20, 20, 10, 10);
cairo_clip (cr2);
cairo_rectangle (cr2, 15, 15, 10, 10);
cairo_clip (cr2);
rectangle_list = cairo_copy_clip_rectangle_list (cr2);
if (!check_count (ctx, phase, uses_clip_rects, rectangle_list, 2) ||
!check_clip_extents (ctx, phase, cr2, 15, 15, 10, 10) ||
!check_rectangles_contain (ctx, phase, uses_clip_rects, rectangle_list, 15, 15, 5, 5) ||
!check_rectangles_contain (ctx, phase, uses_clip_rects, rectangle_list, 20, 20, 5, 5)) {
cairo_rectangle_list_destroy (rectangle_list);
return CAIRO_TEST_FAILURE;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr2);
/* test non-rectangular clip */
phase = "Nonrectangular clip";
cairo_save (cr2);
cairo_move_to (cr2, 0, 0);
cairo_line_to (cr2, 100, 100);
cairo_line_to (cr2, 100, 0);
cairo_close_path (cr2);
cairo_clip (cr2);
rectangle_list = cairo_copy_clip_rectangle_list (cr2);
/* can't get this in one tight user-space rectangle */
if (!check_unrepresentable (ctx, phase, rectangle_list) ||
!check_clip_extents (ctx, phase, cr2, 0, 0, 100, 100)) {
cairo_rectangle_list_destroy (rectangle_list);
return CAIRO_TEST_FAILURE;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr2);
phase = "User space, simple scale, getting clip with same transform";
cairo_save (cr2);
cairo_scale (cr2, 2, 2);
cairo_rectangle (cr2, 5, 5, 40, 40);
cairo_clip (cr2);
rectangle_list = cairo_copy_clip_rectangle_list (cr2);
if (!check_count (ctx, phase, uses_clip_rects, rectangle_list, 1) ||
!check_clip_extents (ctx, phase, cr2, 5, 5, 40, 40) ||
!check_rectangles_contain (ctx, phase, uses_clip_rects, rectangle_list, 5, 5, 40, 40)) {
cairo_rectangle_list_destroy (rectangle_list);
return CAIRO_TEST_FAILURE;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr2);
phase = "User space, simple scale, getting clip with no transform";
cairo_save (cr2);
cairo_save (cr2);
cairo_scale (cr2, 2, 2);
cairo_rectangle (cr2, 5, 5, 40, 40);
cairo_restore (cr2);
cairo_clip (cr2);
rectangle_list = cairo_copy_clip_rectangle_list (cr2);
if (!check_count (ctx, phase, uses_clip_rects, rectangle_list, 1) ||
!check_clip_extents (ctx, phase, cr2, 10, 10, 80, 80) ||
!check_rectangles_contain (ctx, phase, uses_clip_rects, rectangle_list, 10, 10, 80, 80)) {
cairo_rectangle_list_destroy (rectangle_list);
return CAIRO_TEST_FAILURE;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr2);
phase = "User space, rotation, getting clip with no transform";
cairo_save (cr2);
cairo_save (cr2);
cairo_rotate (cr2, 12);
cairo_rectangle (cr2, 5, 5, 40, 40);
cairo_restore (cr2);
cairo_clip (cr2);
rectangle_list = cairo_copy_clip_rectangle_list (cr2);
if (!check_unrepresentable (ctx, phase, rectangle_list)) {
cairo_rectangle_list_destroy (rectangle_list);
return CAIRO_TEST_FAILURE;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr2);
cairo_destroy (cr2);
return CAIRO_TEST_SUCCESS;
}
static void driver_tests(void)
{
MMRESULT rc;
DWORD dwACMVersion = acmGetVersion();
if (winetest_interactive) {
trace("ACM version = %u.%02u build %u%s\n",
HIWORD(dwACMVersion) >> 8,
HIWORD(dwACMVersion) & 0xff,
LOWORD(dwACMVersion),
LOWORD(dwACMVersion) == 0 ? " (Retail)" : "");
}
check_count(ACM_METRIC_COUNT_CODECS);
check_count(ACM_METRIC_COUNT_CONVERTERS);
check_count(ACM_METRIC_COUNT_DISABLED);
check_count(ACM_METRIC_COUNT_DRIVERS);
check_count(ACM_METRIC_COUNT_FILTERS);
check_count(ACM_METRIC_COUNT_HARDWARE);
check_count(ACM_METRIC_COUNT_LOCAL_CODECS);
check_count(ACM_METRIC_COUNT_LOCAL_CONVERTERS);
check_count(ACM_METRIC_COUNT_LOCAL_DISABLED);
check_count(ACM_METRIC_COUNT_LOCAL_DRIVERS);
check_count(ACM_METRIC_COUNT_LOCAL_FILTERS);
if (winetest_interactive)
trace("enabled drivers:\n");
rc = acmDriverEnum(DriverEnumProc, 0, 0);
ok(rc == MMSYSERR_NOERROR,
"acmDriverEnum() failed, rc=%08x, should be 0x%08x\n",
rc, MMSYSERR_NOERROR);
}
static int
eerr_ge1(POST_ARGS)
{
return(check_count(mdoc, MDOC_ELEM, CHECK_ERROR, CHECK_GT, 0));
}
static int
post_rs(POST_ARGS)
{
struct mdoc_node *nn, *next, *prev;
int i, j;
switch (mdoc->last->type) {
case (MDOC_HEAD):
check_count(mdoc, MDOC_HEAD, CHECK_WARN, CHECK_EQ, 0);
return(1);
case (MDOC_BODY):
if (mdoc->last->child)
break;
check_count(mdoc, MDOC_BODY, CHECK_WARN, CHECK_GT, 0);
return(1);
default:
return(1);
}
/*
* Make sure only certain types of nodes are allowed within the
* the `Rs' body. Delete offending nodes and raise a warning.
* Do this before re-ordering for the sake of clarity.
*/
next = NULL;
for (nn = mdoc->last->child; nn; nn = next) {
for (i = 0; i < RSORD_MAX; i++)
if (nn->tok == rsord[i])
break;
if (i < RSORD_MAX) {
if (MDOC__J == rsord[i])
mdoc->last->norm->Rs.child_J = nn;
next = nn->next;
continue;
}
next = nn->next;
mdoc_nmsg(mdoc, nn, MANDOCERR_CHILD);
mdoc_node_delete(mdoc, nn);
}
/*
* The full `Rs' block needs special handling to order the
* sub-elements according to `rsord'. Pick through each element
* and correctly order it. This is a insertion sort.
*/
next = NULL;
for (nn = mdoc->last->child->next; nn; nn = next) {
/* Determine order of `nn'. */
for (i = 0; i < RSORD_MAX; i++)
if (rsord[i] == nn->tok)
break;
/*
* Remove `nn' from the chain. This somewhat
* repeats mdoc_node_unlink(), but since we're
* just re-ordering, there's no need for the
* full unlink process.
*/
if (NULL != (next = nn->next))
next->prev = nn->prev;
if (NULL != (prev = nn->prev))
prev->next = nn->next;
nn->prev = nn->next = NULL;
/*
* Scan back until we reach a node that's
* ordered before `nn'.
*/
for ( ; prev ; prev = prev->prev) {
/* Determine order of `prev'. */
for (j = 0; j < RSORD_MAX; j++)
if (rsord[j] == prev->tok)
break;
if (j <= i)
break;
}
/*
* Set `nn' back into its correct place in front
* of the `prev' node.
*/
nn->prev = prev;
if (prev) {
if (prev->next)
prev->next->prev = nn;
nn->next = prev->next;
prev->next = nn;
} else {
mdoc->last->child->prev = nn;
nn->next = mdoc->last->child;
mdoc->last->child = nn;
}
}
return(1);
}
int main(int argc, char *argv[]) {
boost::scoped_ptr<pg::tempdb> db;
try {
db.reset(new pg::tempdb);
} catch (const std::exception &e) {
std::cerr << "Unable to setup database: " << e.what() << "\n";
return 77; // <-- code to skip this test.
}
try {
boost::shared_ptr<middle_pgsql_t> mid_pgsql(new middle_pgsql_t());
options_t options;
options.conninfo = db->conninfo().c_str();
options.num_procs = 1;
options.prefix = "osm2pgsql_test";
options.tblsslim_index = "tablespacetest";
options.tblsslim_data = "tablespacetest";
options.slim = 1;
boost::shared_ptr<geometry_processor> processor = geometry_processor::create("polygon", &options);
export_list columns;
{ taginfo info; info.name = "building"; info.type = "text"; columns.add(OSMTYPE_WAY, info); }
boost::shared_ptr<output_multi_t> out_test(new output_multi_t("foobar_buildings", processor, columns, mid_pgsql.get(), options));
osmdata_t osmdata(mid_pgsql, out_test);
boost::scoped_ptr<parse_delegate_t> parser(new parse_delegate_t(options.extra_attributes, options.bbox, options.projection));
osmdata.start();
if (parser->streamFile("pbf", "tests/liechtenstein-2013-08-03.osm.pbf", options.sanitize, &osmdata) != 0) {
throw std::runtime_error("Unable to read input file `tests/liechtenstein-2013-08-03.osm.pbf'.");
}
parser.reset(NULL);
osmdata.stop();
// start a new connection to run tests on
pg::conn_ptr test_conn = pg::conn::connect(db->conninfo());
check_count(test_conn, 1, "select count(*) from pg_catalog.pg_class where relname = 'osm2pgsql_test_foobar_buildings'");
check_count(test_conn, 0, "select count(*) from osm2pgsql_test_foobar_buildings where building is null");
check_count(test_conn, 3723, "select count(*) from osm2pgsql_test_foobar_buildings");
//check that we have the right spread
check_count(test_conn, 1, "select count(*) from osm2pgsql_test_foobar_buildings where building='barn'");
check_count(test_conn, 1, "select count(*) from osm2pgsql_test_foobar_buildings where building='chapel'");
check_count(test_conn, 5, "select count(*) from osm2pgsql_test_foobar_buildings where building='church'");
check_count(test_conn, 3, "select count(*) from osm2pgsql_test_foobar_buildings where building='commercial'");
check_count(test_conn, 6, "select count(*) from osm2pgsql_test_foobar_buildings where building='farm'");
check_count(test_conn, 1, "select count(*) from osm2pgsql_test_foobar_buildings where building='garage'");
check_count(test_conn, 2, "select count(*) from osm2pgsql_test_foobar_buildings where building='glasshouse'");
check_count(test_conn, 1, "select count(*) from osm2pgsql_test_foobar_buildings where building='greenhouse'");
check_count(test_conn, 153, "select count(*) from osm2pgsql_test_foobar_buildings where building='house'");
check_count(test_conn, 4, "select count(*) from osm2pgsql_test_foobar_buildings where building='hut'");
check_count(test_conn, 8, "select count(*) from osm2pgsql_test_foobar_buildings where building='industrial'");
check_count(test_conn, 200, "select count(*) from osm2pgsql_test_foobar_buildings where building='residential'");
check_count(test_conn, 6, "select count(*) from osm2pgsql_test_foobar_buildings where building='roof'");
check_count(test_conn, 4, "select count(*) from osm2pgsql_test_foobar_buildings where building='school'");
check_count(test_conn, 2, "select count(*) from osm2pgsql_test_foobar_buildings where building='station'");
check_count(test_conn, 3, "select count(*) from osm2pgsql_test_foobar_buildings where building='warehouse'");
check_count(test_conn, 3323, "select count(*) from osm2pgsql_test_foobar_buildings where building='yes'");
return 0;
} catch (const std::exception &e) {
std::cerr << "ERROR: " << e.what() << std::endl;
} catch (...) {
std::cerr << "UNKNOWN ERROR" << std::endl;
}
return 1;
}
static int
hwarn_eq1(POST_ARGS)
{
return(check_count(mdoc, MDOC_HEAD, CHECK_WARN, CHECK_EQ, 1));
}
static int
hwarn_le1(POST_ARGS)
{
return(check_count(mdoc, MDOC_HEAD, CHECK_WARN, CHECK_LT, 2));
}
static cairo_test_status_t
preamble (cairo_test_context_t *ctx)
{
cairo_surface_t *surface;
cairo_t *cr;
cairo_rectangle_list_t *rectangle_list;
const char *phase;
cairo_status_t status;
surface = cairo_image_surface_create (CAIRO_FORMAT_ARGB32, 0, 0);
cr = cairo_create (surface);
cairo_surface_destroy (surface);
/* first, test basic stuff. This should not be clipped, it should
return the surface rectangle. */
phase = "No clip set";
rectangle_list = cairo_copy_clip_rectangle_list (cr);
if (! check_count (ctx, phase, rectangle_list, 1) ||
! check_clip_extents (ctx, phase, cr, 0, 0, 100, 100) ||
! check_rectangles_contain (ctx, phase, rectangle_list, 0, 0, 100, 100))
{
goto FAIL;
}
cairo_rectangle_list_destroy (rectangle_list);
/* Test simple clip rect. */
phase = "Simple clip rect";
cairo_save (cr);
cairo_rectangle (cr, 10, 10, 80, 80);
cairo_clip (cr);
rectangle_list = cairo_copy_clip_rectangle_list (cr);
if (! check_count (ctx, phase, rectangle_list, 1) ||
! check_clip_extents (ctx, phase, cr, 10, 10, 80, 80) ||
! check_rectangles_contain (ctx, phase, rectangle_list, 10, 10, 80, 80))
{
goto FAIL;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr);
/* Test everything clipped out. */
phase = "All clipped out";
cairo_save (cr);
cairo_clip (cr);
rectangle_list = cairo_copy_clip_rectangle_list (cr);
if (! check_count (ctx, phase, rectangle_list, 0))
{
goto FAIL;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr);
/* test two clip rects */
phase = "Two clip rects";
cairo_save (cr);
cairo_rectangle (cr, 10, 10, 10, 10);
cairo_rectangle (cr, 20, 20, 10, 10);
cairo_clip (cr);
cairo_rectangle (cr, 15, 15, 10, 10);
cairo_clip (cr);
rectangle_list = cairo_copy_clip_rectangle_list (cr);
if (! check_count (ctx, phase, rectangle_list, 2) ||
! check_clip_extents (ctx, phase, cr, 15, 15, 10, 10) ||
! check_rectangles_contain (ctx, phase, rectangle_list, 15, 15, 5, 5) ||
! check_rectangles_contain (ctx, phase, rectangle_list, 20, 20, 5, 5))
{
goto FAIL;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr);
/* test non-rectangular clip */
phase = "Nonrectangular clip";
cairo_save (cr);
cairo_move_to (cr, 0, 0);
cairo_line_to (cr, 100, 100);
cairo_line_to (cr, 100, 0);
cairo_close_path (cr);
cairo_clip (cr);
rectangle_list = cairo_copy_clip_rectangle_list (cr);
/* can't get this in one tight user-space rectangle */
if (! check_unrepresentable (ctx, phase, rectangle_list) ||
! check_clip_extents (ctx, phase, cr, 0, 0, 100, 100))
{
goto FAIL;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr);
phase = "User space, simple scale, getting clip with same transform";
cairo_save (cr);
cairo_scale (cr, 2, 2);
cairo_rectangle (cr, 5, 5, 40, 40);
cairo_clip (cr);
rectangle_list = cairo_copy_clip_rectangle_list (cr);
if (! check_count (ctx, phase, rectangle_list, 1) ||
! check_clip_extents (ctx, phase, cr, 5, 5, 40, 40) ||
! check_rectangles_contain (ctx, phase, rectangle_list, 5, 5, 40, 40))
{
goto FAIL;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr);
phase = "User space, simple scale, getting clip with no transform";
cairo_save (cr);
cairo_save (cr);
cairo_scale (cr, 2, 2);
cairo_rectangle (cr, 5, 5, 40, 40);
cairo_restore (cr);
cairo_clip (cr);
rectangle_list = cairo_copy_clip_rectangle_list (cr);
if (! check_count (ctx, phase, rectangle_list, 1) ||
! check_clip_extents (ctx, phase, cr, 10, 10, 80, 80) ||
! check_rectangles_contain (ctx, phase, rectangle_list, 10, 10, 80, 80))
{
goto FAIL;
}
cairo_rectangle_list_destroy (rectangle_list);
cairo_restore (cr);
phase = "User space, rotation, getting clip with no transform";
cairo_save (cr);
cairo_save (cr);
cairo_rotate (cr, 12);
cairo_rectangle (cr, 5, 5, 40, 40);
cairo_restore (cr);
cairo_clip (cr);
rectangle_list = cairo_copy_clip_rectangle_list (cr);
if (! check_unrepresentable (ctx, phase, rectangle_list))
goto FAIL;
FAIL:
cairo_rectangle_list_destroy (rectangle_list);
status = cairo_status (cr);
cairo_destroy (cr);
return cairo_test_status_from_status (ctx, status);
}
int main(int argc, char *argv[]) {
std::unique_ptr<pg::tempdb> db;
try {
db.reset(new pg::tempdb);
} catch (const std::exception &e) {
std::cerr << "Unable to setup database: " << e.what() << "\n";
return 77; // <-- code to skip this test.
}
try {
options_t options;
options.conninfo = db->conninfo().c_str();
options.num_procs = 1;
options.slim = true;
options.projection.reset(new reprojection(PROJ_LATLONG));
options.output_backend = "multi";
options.style = "tests/test_output_multi_line_trivial.style.json";
//setup the front (input)
parse_delegate_t parser(options.extra_attributes, options.bbox, options.projection, options.append);
//setup the middle
std::shared_ptr<middle_t> middle = middle_t::create_middle(options.slim);
//setup the backend (output)
std::vector<std::shared_ptr<output_t> > outputs = output_t::create_outputs(middle.get(), options);
//let osmdata orchestrate between the middle and the outs
osmdata_t osmdata(middle, outputs);
osmdata.start();
parser.stream_file("libxml2", "tests/test_output_multi_line_storage.osm", &osmdata);
osmdata.stop();
// start a new connection to run tests on
pg::conn_ptr test_conn = pg::conn::connect(db->conninfo());
check_count(test_conn, 1, "select count(*) from pg_catalog.pg_class where relname = 'test_line'");
check_count(test_conn, 3, "select count(*) from test_line");
//check that we have the number of vertexes in each linestring
check_count(test_conn, 3, "SELECT ST_NumPoints(way) FROM test_line WHERE osm_id = 1");
check_count(test_conn, 2, "SELECT ST_NumPoints(way) FROM test_line WHERE osm_id = 2");
check_count(test_conn, 2, "SELECT ST_NumPoints(way) FROM test_line WHERE osm_id = 3");
check_count(test_conn, 3, "SELECT COUNT(*) FROM test_line WHERE foo = 'bar'");
return 0;
} catch (const std::exception &e) {
std::cerr << "ERROR: " << e.what() << std::endl;
} catch (...) {
std::cerr << "UNKNOWN ERROR" << std::endl;
}
return 1;
}
static irqreturn_t msm_ts_irq(int irq, void *dev_id)
{
struct msm_ts *ts = dev_id;
struct msm_ts_platform_data *pdata = ts->pdata;
uint32_t tmp, num_op, num_samp;
uint32_t tssc_avg12, tssc_avg34, tssc_status, tssc_ctl;
int x, y, z1, z2;
int was_down;
int down;
tssc_ctl = tssc_readl(ts, TSSC_CTL);
tssc_status = tssc_readl(ts, TSSC_STATUS);
tssc_avg12 = tssc_readl(ts, TSSC_AVG_12);
tssc_avg34 = tssc_readl(ts, TSSC_AVG_34);
tssc_writel(ts, s_sampling_int, TSSC_SAMPLING_INT);
setup_next_sample(ts);
#if defined(CONFIG_MACH_MSM7X27_SWIFT)
y = tssc_avg12 & 0xffff;
x = tssc_avg12 >> 16;
z1 = 255;
z2 = 0;
#else /* original */
x = tssc_avg12 & 0xffff;
y = tssc_avg12 >> 16;
z1 = tssc_avg34 & 0xffff;
z2 = tssc_avg34 >> 16;
#endif
/* invert the inputs if necessary */
if (pdata->inv_x)
x = pdata->inv_x - x;
if (pdata->inv_y)
y = pdata->inv_y - y;
if (x < 0)
x = 0;
if (y < 0)
y = 0;
down = !(tssc_ctl & TSSC_CTL_PENUP_IRQ);
was_down = ts->ts_down;
ts->ts_down = down;
/* no valid data */
if (down && !(tssc_ctl & TSSC_CTL_DATA_FLAG))
return IRQ_HANDLED;
if (msm_tsdebug & 2)
printk("%s: down=%d, x=%d, y=%d, z1=%d, z2=%d, status %x\n",
__func__, down, x, y, z1, z2, tssc_status);
if (!was_down && down) {
struct ts_virt_key *vkey = NULL;
if (pdata->vkeys_y && (y > pdata->virt_y_start))
vkey = find_virt_key(ts, pdata->vkeys_y, x);
if (!vkey && ts->pdata->vkeys_x && (x > pdata->virt_x_start))
vkey = find_virt_key(ts, pdata->vkeys_x, y);
if (vkey) {
WARN_ON(ts->vkey_down != NULL);
if (msm_tsdebug)
printk(KERN_INFO "%s: virtual key down %d\n",
__func__, vkey->key);
ts->vkey_down = vkey;
input_report_key(ts->input_dev, vkey->key, 1);
input_sync(ts->input_dev);
return IRQ_HANDLED;
}
} else if (ts->vkey_down != NULL) {
if (!down) {
if (msm_tsdebug)
printk(KERN_INFO "%s: virtual key up %d\n", __func__,
ts->vkey_down->key);
input_report_key(ts->input_dev, ts->vkey_down->key, 0);
input_sync(ts->input_dev);
ts->vkey_down = NULL;
}
if (y > 650)
mod_timer(&ts->timer,
jiffies + msecs_to_jiffies(s_penup_time));
return IRQ_HANDLED;
}
if (down) {
if ((check_count(ts, x, y) != false) && (ts_check_region(ts, x, y) != false)) {
input_report_abs(ts->input_dev, ABS_X, x);
input_report_abs(ts->input_dev, ABS_Y, y);
input_report_abs(ts->input_dev, ABS_PRESSURE, z1);
input_report_key(ts->input_dev, BTN_TOUCH, down);
input_sync(ts->input_dev);
}
mod_timer(&ts->timer,
jiffies + msecs_to_jiffies(TS_PENUP_TIMEOUT_MS));
} else {
input_report_key(ts->input_dev, BTN_TOUCH, down);
input_sync(ts->input_dev);
}
ts->count = down;
touch_press = down;
if (down == 0)
ts->count1 = down;
return IRQ_HANDLED;
}
