void ARMAttributeParser::DIV_use(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"If Available", "Not Permitted", "Permitted"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::Advanced_SIMD_arch(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"Not Permitted", "NEONv1", "NEONv2+FMA", "ARMv8-a NEON"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::ABI_PCS_GOT_use(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *const Strings[] = {
"Not Permitted", "Direct", "GOT-Indirect"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::ABI_HardFP_use(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"Tag_FP_arch", "Single-Precision", "Reserved", "Tag_FP_arch (deprecated)"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::ABI_FP_number_model(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"Not Permitted", "Finite Only", "RTABI", "IEEE-754"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::ABI_PCS_wchar_t(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"Not Permitted", "Unknown", "2-byte", "Unknown", "4-byte"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::ABI_VFP_args(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"AAPCS", "AAPCS VFP", "Custom", "Not Permitted"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::ABI_PCS_RW_data(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"Absolute", "PC-relative", "SB-relative", "Not Permitted"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::ABI_FP_denormal(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *const Strings[] = {
"Unsupported", "IEEE-754", "Sign Only"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::ABI_enum_size(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"Not Permitted", "Packed", "Int32", "External Int32"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::PCS_config(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"None", "Bare Platform", "Linux Application", "Linux DSO", "Palm OS 2004",
"Reserved (Palm OS)", "Symbian OS 2004", "Reserved (Symbian OS)"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::FP_arch(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"Not Permitted", "VFPv1", "VFPv2", "VFPv3", "VFPv3-D16", "VFPv4",
"VFPv4-D16", "ARMv8-a FP", "ARMv8-a FP-D16"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::Virtualization_use(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"Not Permitted", "TrustZone", "Virtualization Extensions",
"TrustZone + Virtualization Extensions"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::CPU_arch(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"Pre-v4", "ARM v4", "ARM v4T", "ARM v5T", "ARM v5TE", "ARM v5TEJ", "ARM v6",
"ARM v6KZ", "ARM v6T2", "ARM v6K", "ARM v7", "ARM v6-M", "ARM v6S-M",
"ARM v7E-M", "ARM v8"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
void ARMAttributeParser::ABI_FP_optimization_goals(AttrType Tag,
const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"None", "Speed", "Aggressive Speed", "Size", "Aggressive Size", "Accuracy",
"Best Accuracy"
};
uint64_t Value = ParseInteger(Data, Offset);
StringRef ValueDesc =
(Value < array_lengthof(Strings)) ? Strings[Value] : nullptr;
PrintAttribute(Tag, Value, ValueDesc);
}
bool nsMediaFragmentURIParser::ParseXYWH(nsDependentSubstring aString)
{
int32_t x, y, w, h;
ClipUnit clipUnit;
// Determine units.
if (StringBeginsWith(aString, NS_LITERAL_STRING("pixel:"))) {
clipUnit = eClipUnit_Pixel;
aString.Rebind(aString, 6);
} else if (StringBeginsWith(aString, NS_LITERAL_STRING("percent:"))) {
clipUnit = eClipUnit_Percent;
aString.Rebind(aString, 8);
} else {
clipUnit = eClipUnit_Pixel;
}
// Read and validate coordinates.
if (ParseInteger(aString, x) && x >= 0 &&
ParseCommaSeparator(aString) &&
ParseInteger(aString, y) && y >= 0 &&
ParseCommaSeparator(aString) &&
ParseInteger(aString, w) && w > 0 &&
ParseCommaSeparator(aString) &&
ParseInteger(aString, h) && h > 0 &&
aString.Length() == 0) {
// Reject invalid percentage coordinates.
if (clipUnit == eClipUnit_Percent &&
(x + w > 100 || y + h > 100)) {
return false;
}
mClip.construct(x, y, w, h);
mClipUnit = clipUnit;
return true;
}
return false;
}
bool ObjectImporter::Import(std::wstring file, ImportedObjectData* rawData)
{
size_t first = file.find_last_of('\\') + 1;
size_t last = file.find_last_of('.');
rawData->name = file.substr(first, last-first);
std::wifstream in (file);
if(!in.is_open())
{
std::wstring msg = L"Failed to open file: \n";
msg.append(file);
MessageBox(0, msg.c_str(), L"Import error", 0);
return false;
}
else
{
std::wstring buff;
while (!in.eof())
{
in >> buff;
if(buff.size())
{
if(buff == ObjImpFormat::animationCount)
{
int count = 0;
if(!ParseInteger(in, count))
return false;
if(count)
{
rawData->animations.resize(count);
if(!ParseAnimationFile(in, rawData))
return false;
}
else
if(!ParseStandardFile(in, rawData))
return false;
}
else { ParseLine(in, true); }
}
}
in.close();
}
return true;
}
void NumericEdit::__EditCompleted( Edit& sender )
{
if ( busy )
return;
if ( sender.IsReadOnly() )
return;
busy = true;
try
{
double newValue;
bool hasChanged = false;
if ( isReal )
{
double tolerance = Pow10I<double>()( -int( precision + 1 ) );
newValue = ParseReal( sender.Text(), lowerBound, upperBound, tolerance );
newValue = Round( newValue, ActualPrecision( precision, newValue ) );
hasChanged = Sign( newValue ) != Sign( value ) || Abs( newValue - value ) > tolerance;
}
else
{
newValue = ParseInteger( sender.Text(), lowerBound, upperBound );
hasChanged = newValue != value;
}
if ( hasChanged )
{
value = newValue;
UpdateControls();
if ( onValueUpdated != 0 )
(onValueUpdatedReceiver->*onValueUpdated)( *this, value );
}
else
UpdateControls();
busy = false;
return;
}
ERROR_HANDLER
busy = false;
UpdateControls();
}
void Parser::ParseRenderer()
{
unsigned int bounce = 5;
unsigned int samplesPerPixel = 4;
while (HasNextTag())
{
std::string tag = NextTag();
if (tag == "bounce")
{
SkipSpace();
bounce = ParseInteger();
}
else if (tag == "sample")
{
SkipSpace();
samplesPerPixel = ParseInteger();
}
else if (tag == "/renderer")
{
renderer = new Renderer(bounce, samplesPerPixel);
break;
}
}
}
void ARMAttributeParser::CPU_arch_profile(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
uint64_t Encoded = ParseInteger(Data, Offset);
StringRef Profile;
switch (Encoded) {
default: Profile = "Unknown"; break;
case 'A': Profile = "Application"; break;
case 'R': Profile = "Real-time"; break;
case 'M': Profile = "Microcontroller"; break;
case 'S': Profile = "Classic"; break;
case '0': Profile = "None"; break;
}
PrintAttribute(Tag, Encoded, Profile);
}
double ParseDouble(const char* p)
{
float s = p[0]=='-' ? -1.0f : 1.0f;
p += (p[0]=='-') | (p[0]=='+');
double r = 0;
for(; p[0]>='0' && p[0]<='9'; ++p)
r = r*10.0 + (double)(p[0] - '0');
if(p[0]=='.' || p[0]==',')
{
double k = 0.1;
for(++p; p[0]>='0' && p[0]<='9'; ++p, k *= 0.1)
r += k*(double)(p[0] - '0');
}
if(p[0]=='e' || p[0]=='E')
r *= pow(10.0, (double)ParseInteger(p + 1));
return r*s;
}
void ARMAttributeParser::ABI_align_needed(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
static const char *Strings[] = {
"Not Permitted", "8-byte alignment", "4-byte alignment", "Reserved"
};
uint64_t Value = ParseInteger(Data, Offset);
std::string Description;
if (Value < array_lengthof(Strings))
Description = std::string(Strings[Value]);
else if (Value <= 12)
Description = std::string("8-byte alignment, ") + utostr(1 << Value)
+ std::string("-byte extended alignment");
else
Description = "Invalid";
PrintAttribute(Tag, Value, Description);
}
bool ParseStandardFile (std::wifstream& in, ImportedObjectData* d)
{
std::wstring flag;
bool result = true;
while(!in.eof())
{
in >> flag;
if(!in.eof())
{
if(flag == ObjImpFormat::vertexCount)
{
int count = 0;
if(!ParseInteger(in, count))
{
DisplayText("File:\n" + in.getloc().name() + "\nDoes not contain any vertex information");
return false;
}
else if(!count)
{
DisplayText("File:\n" + in.getloc().name() + "\nHas invalid vertex count (0)");
return false;
}
//No animations, then only one mesh is valid
d->objects.resize(1);
d->objects[0].vertex = new std::vector<VERTEX::VertexPNT>(count);
d->objects[0].material = 0;
}
else if(flag == ObjImpFormat::material) { d->objects[0].material = ParseMaterial(in); }
else if(flag == ObjImpFormat::v) { result = ParseV(in,d->objects[0]); }
else if(flag == ObjImpFormat::vt) { result = ParseVT(in,d->objects[0]); }
else if(flag == ObjImpFormat::vn) { result = ParseVN(in,d->objects[0]); }
else if(flag == ObjImpFormat::comment) { ParseLine(in, true); }
if(!result)
return result;
}
}
return result;
}
void ARMAttributeParser::compatibility(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
uint64_t Integer = ParseInteger(Data, Offset);
StringRef String = ParseString(Data, Offset);
DictScope AS(SW, "Attribute");
SW.printNumber("Tag", Tag);
SW.startLine() << "Value: " << Integer << ", " << String << '\n';
SW.printString("TagName", AttrTypeAsString(Tag, /*TagPrefix*/false));
switch (Integer) {
case 0:
SW.printString("Description", StringRef("No Specific Requirements"));
break;
case 1:
SW.printString("Description", StringRef("AEABI Conformant"));
break;
default:
SW.printString("Description", StringRef("AEABI Non-Conformant"));
break;
}
}
int ParseMaterial (std::wifstream& in)
{
ObjectMaterial::OBJECT_MATERIAL_DESC md;
md.device = D3DShell::self()->getDevice();
md.dc = D3DShell::self()->getDeviceContext();
md.name = ParseLine(in);
std::wstring buffer = L"";
bool done = false;
std::vector<std::streamoff> val;
do
{
in >> buffer;
if(buffer.size())
{
if(buffer == ObjImpFormat::ambient) { ParseVector4(in, md.ambient); }
else if(buffer == ObjImpFormat::diffuse) { ParseVector4(in, md.diffuse); }
else if(buffer == ObjImpFormat::specular) { ParseVector4(in, md.specular); }
else if(buffer == ObjImpFormat::specularPower) { ParseInteger(in, md.specualarPow); }
else if(buffer == ObjImpFormat::ambientTexture) { md.ambientTexture = ParseLine(in); }
else if(buffer == ObjImpFormat::diffuseTexture) { md.diffuseTexture = ParseLine(in); }
else if(buffer == ObjImpFormat::specularTexture) { md.specularTexture = ParseLine(in); }
else if(buffer == ObjImpFormat::glowTexture) { md.glowTexture = ParseLine(in); }
else if(buffer == ObjImpFormat::normalTexture) { md.normalTexture = ParseLine(in); }
else if(buffer == ObjImpFormat::comment) { ParseLine(in, true); }
else if(buffer == ObjImpFormat::endMaterial)
{
done = true;
//Return newly created material id
return MaterialHandler::AddMaterial(md);
}
}
} while (!done || !in.eof());
return -1;
}
//top level parse function
sgdm::StackGuard<JsonValue>&& JsonParser::ParsePrimary(){
switch(currentTok){
case tok_endl:
return std::move(Error("primary fail"));
case tok_identifier:
return std::move(ParseName());
case tok_integer:
return std::move(ParseInteger());
case tok_double:
return std::move(ParseDouble());
case '[':
return std::move(ParseArray(alloc));
case '{':
return std::move(ParseObject(alloc));
default:
return std::move(Error("unknown token found near place" + std::to_string(indexCount)));
}
sgdm::StackGuard<JsonValue>&& JsonParser::Parse(){
getNextTok();
return std::move(ParsePrimary(alloc));
}
void ARMAttributeParser::IntegerAttribute(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
SW.printNumber(ARMBuildAttrs::AttrTypeAsString(Tag),
ParseInteger(Data, Offset));
}
void ARMAttributeParser::nodefaults(AttrType Tag, const uint8_t *Data,
uint32_t &Offset) {
uint64_t Value = ParseInteger(Data, Offset);
PrintAttribute(Tag, Value, "Unspecified Tags UNDEFINED");
}
static int Open(vlc_object_t *object)
{
demux_t *demux = (demux_t*)object;
const uint8_t *peek;
if (vlc_stream_Peek(demux->s, &peek, 11) != 11)
return VLC_EGENERIC;
bool is_stl_25 = !memcmp(&peek[3], "STL25.01", 8);
bool is_stl_30 = !memcmp(&peek[3], "STL30.01", 8);
if (!is_stl_25 && !is_stl_30)
return VLC_EGENERIC;
const double fps = is_stl_25 ? 25 : 30;
uint8_t header[1024];
if (vlc_stream_Read(demux->s, header, sizeof(header)) != sizeof(header)) {
msg_Err(demux, "Incomplete EBU STL header");
return VLC_EGENERIC;
}
const int cct = ParseInteger(&header[12], 2);
const mtime_t program_start = ParseTextTimeCode(&header[256], fps);
const int tti_count = ParseInteger(&header[238], 5);
msg_Dbg(demux, "Detected EBU STL : CCT=%d TTI=%d start=%8.8s %"PRId64, cct, tti_count, &header[256], program_start);
demux_sys_t *sys = xmalloc(sizeof(*sys));
sys->next_date = 0;
sys->current = 0;
sys->count = 0;
sys->index = xcalloc(tti_count, sizeof(*sys->index));
bool comment = false;
stl_entry_t *s = &sys->index[0];
s->count = 0;
for (int i = 0; i < tti_count; i++) {
uint8_t tti[16];
if (vlc_stream_Read(demux->s, tti, 16) != 16 ||
vlc_stream_Read(demux->s, NULL, 112) != 112) {
msg_Warn(demux, "Incomplete EBU STL file");
break;
}
const int ebn = tti[3];
if (ebn >= 0xf0 && ebn <= 0xfd)
continue;
if (ebn == 0xfe)
continue;
if (s->count <= 0) {
comment = tti[15] != 0;
s->start = ParseTimeCode(&tti[5], fps) - program_start;
s->stop = ParseTimeCode(&tti[9], fps) - program_start;
s->index = i;
}
s->count++;
if (ebn == 0xff && !comment)
s = &sys->index[++sys->count];
if (ebn == 0xff && sys->count < tti_count)
s->count = 0;
}
if (sys->count > 0)
vlc_stream_Seek(demux->s, 1024 + 128LL * sys->index[0].index);
es_format_t fmt;
es_format_Init(&fmt, SPU_ES, VLC_CODEC_EBU_STL);
fmt.i_extra = sizeof(header);
fmt.p_extra = header;
sys->es = es_out_Add(demux->out, &fmt);
fmt.i_extra = 0;
fmt.p_extra = NULL;
es_format_Clean(&fmt);
demux->p_sys = sys;
demux->pf_demux = Demux;
demux->pf_control = Control;
return VLC_SUCCESS;
}
void NoiseFloorCommand(int client)
{
int nfc[MCHAIN],nfe[MCHAIN];
int ip, np;
int error;
int attempt;
int margin;
int index;
int code;
int timeout;
int ngot;
int nf[2*MCHAIN];
int nfmany;
char buffer[MBUFFER];
char *name;
int frequency;
int ht40;
int rxchain;
int reset;
int bandwidth;
//
// prepare beginning of error message in case we need to use it
//
error=0;
timeout= 100;
nfmany=1;
nf[0]=-110;
margin=MERROR;
attempt=MATTEMPT;
frequency= -1;
ht40=2;
bandwidth=BW_AUTOMATIC;
rxchain=0x7;
reset=0;
//
// parse arguments and do it
//
np=CommandParameterMany();
for(ip=0; ip<np; ip++)
{
name=CommandParameterName(ip);
index=ParameterSelectIndex(name,NoiseFloorParameter,sizeof(NoiseFloorParameter)/sizeof(NoiseFloorParameter[0]));
if(index>=0)
{
code=NoiseFloorParameter[index].code;
switch(code)
{
case LinkParameterFrequency:
ngot=ParseIntegerList(ip,name,&frequency,&NoiseFloorParameter[index]);
if(ngot<=0)
{
error++;
}
break;
case LinkParameterHt40:
ngot=ParseIntegerList(ip,name,&ht40,&NoiseFloorParameter[index]);
if(ngot<=0)
{
error++;
}
else
{
switch(ht40){
case 0:
bandwidth=BW_HT20;
break;
case 1:
bandwidth=BW_HT40_PLUS;
break;
case -1:
bandwidth=BW_HT40_MINUS;
break;
case 2:
bandwidth=BW_AUTOMATIC;
break;
default:
error++;
break;
}
}
break;
case LinkParameterChain:
case LinkParameterRxChain:
ngot=ParseIntegerList(ip,name,&rxchain,&NoiseFloorParameter[index]);
if(ngot<=0)
{
error++;
}
break;
case LinkParameterReset:
ngot=ParseIntegerList(ip,name,&reset,&NoiseFloorParameter[index]);
if(ngot<=0)
{
error++;
}
break;
case NoiseFloorValue:
nfmany=ParseInteger(ip,name,2*MCHAIN,nf);
if(nfmany<=0)
{
error++;
}
break;
case NoiseFloorTimeout:
ngot=ParseInteger(ip,name,1,&timeout);
if(ngot<=0)
{
error++;
}
break;
case NoiseFloorMargin:
ngot=ParseInteger(ip,name,1,&margin);
if(ngot<=0)
{
error++;
}
break;
case NoiseFloorAttempt:
ngot=ParseInteger(ip,name,1,&attempt);
if(ngot<=0)
{
error++;
}
break;
case LinkParameterBandwidth:
ngot=ParseIntegerList(ip,name,&bandwidth,&NoiseFloorParameter[index]);
if(ngot<=0)
{
error++;
}
break;
default:
ErrorPrint(ParseBadParameter,name);
error++;
break;
}
}
else
{
error++;
ErrorPrint(ParseBadParameter,name);
}
}
if(nfmany<=0)
{
SendError(client,"target noise floor value is required.");
error++;
}
if(reset)
{
if(frequency<=0)
{
SendError(client,"frequency is required.");
error++;
}
}
if(attempt>0 && (attempt%2)==0)
{
attempt++;
}
//
// do it
//
if(error==0)
{
//
// if there's no card loaded, return error
//
if(CardCheckAndLoad(-1)!=0)
{
ErrorPrint(CardNoneLoaded);
return;
}
if(frequency>0)
{
error=CardResetIfNeeded(frequency,rxchain,rxchain,reset,bandwidth);
if(error!=0)
{
return;
}
}
error=NoiseFloorDo(frequency,nf,nfmany,margin,attempt,timeout,0,nfc,nfe,MCHAIN);
if(error!=0)
{
SformatOutput(buffer,MBUFFER-1,"Noise Floor Calibration error = %d",error);
buffer[MBUFFER-1]=0;
SendError(client,buffer);
}
}
SendDone(client);
}
