void data_subscribe(TTPtr self, t_symbol *relativeAddress, long argc, t_atom *argv)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
TTAddress returnedAddress;
TTNodePtr returnedNode = NULL;
TTNodePtr returnedContextNode = NULL;
// for relative address
if (TTAddress(relativeAddress->s_name).getType() == kAddressRelative) {
jamoma_subscriber_create((t_object*)x, x->wrappedObject, TTAddress(jamoma_parse_dieze((t_object*)x, relativeAddress)->s_name), x->subscriberObject, returnedAddress, &returnedNode, &returnedContextNode);
#ifndef JMOD_MESSAGE
#ifndef JMOD_RETURN
// if a j.parameter is registered under the root : reset to the default value our self
if (returnedContextNode == accessApplicationLocalDirectory->getRoot())
{
TTBoolean initialized;
x->wrappedObject.get("initialized", initialized);
if (!initialized)
x->wrappedObject.send(kTTSym_Init);
}
#endif
#endif
}
else
object_error((t_object*)x, "can't register because %s is not a relative address", relativeAddress->s_name);
}
TTErr convertUpperCasedNameInAddress(TTSymbol upperCasedName, TTAddress& convertedInAddress)
{
TTUInt32 upperCasedNameSize = strlen(upperCasedName.c_str());
TTCString upperCasedNameCString = new char[upperCasedNameSize+1];
TTUInt32 nbUpperCase = 0;
TTUInt32 i;
TTCString convertedNameCString = NULL;
TTUInt32 convertedNameSize = 0;
strncpy(upperCasedNameCString, upperCasedName.c_str(), upperCasedNameSize+1);
// "ExampleName" to "example/name"
// "anyOtherExample" to "any/other/example"
if ((upperCasedNameCString[0] > 64 && upperCasedNameCString[0] < 91) || (upperCasedNameCString[0] > 96 && upperCasedNameCString[0] < 123)) {
// count how many upper-case letter there are in the TTName after the first letter
for (i=1; i<upperCasedNameSize; i++) {
if (upperCasedNameCString[i] > 64 && upperCasedNameCString[i] < 91)
nbUpperCase++;
}
// prepare the convertedName
convertedNameSize = upperCasedNameSize + nbUpperCase;
convertedNameCString = new char[convertedNameSize+1];
// convert first letter to lower-case if needed
if (upperCasedNameCString[0] > 64 && upperCasedNameCString[0] < 91)
convertedNameCString[0] = upperCasedNameCString[0] + 32;
else
convertedNameCString[0] = upperCasedNameCString[0];
// copy each letter while checking upper-case letter to replace them by a / + lower-case letter
nbUpperCase = 0;
for (i=1; i<upperCasedNameSize; i++) {
if (upperCasedNameCString[i] > 64 && upperCasedNameCString[i] < 91) {
convertedNameCString[i + nbUpperCase] = '/';
convertedNameCString[i + nbUpperCase + 1] = upperCasedNameCString[i] + 32;
nbUpperCase++;
}
else
convertedNameCString[i + nbUpperCase] = upperCasedNameCString[i];
}
// ends the CString with a NULL letter
convertedNameCString[convertedNameSize] = 0;
convertedInAddress = TTAddress(convertedNameCString);
delete convertedNameCString;
convertedNameCString = NULL;
}
else
convertedInAddress = TTAddress(upperCasedName);
delete upperCasedNameCString;
upperCasedNameCString = NULL;
return kTTErrNone;
}
void out_subscribe(TTPtr self)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
TTAddress signalAddress;
TTAddress outputAddress;
TTAddress inputAddress;
TTValue v, args;
TTNodePtr returnedNode = NULL;
TTNodePtr returnedContextNode = NULL;
TTAddress returnedAddress, parentAddress;
TTString formatDescription, sInstance;
t_object *modelOrView = NULL;
#ifdef J_OUT_TILDE
signalAddress = TTAddress("audio");
#endif
#ifdef J_OUT_MULTI
signalAddress = TTAddress("audio");
#endif
#ifndef J_OUT_TILDE
#ifndef J_OUT_MULTI
signalAddress = TTAddress("data");
#endif
#endif
// edit "signal/out.instance" address
outputAddress = signalAddress.appendAddress(TTAddress("out")).appendInstance(EXTRA->instance);
// if the subscription is successful
if (!jamoma_subscriber_create((t_eobj*)x, x->wrappedObject, outputAddress, x->subscriberObject, returnedAddress, &returnedNode, &returnedContextNode)) {
// get patcher
x->patcherPtr = ((t_eobj*)x)->o_canvas;
// update instance symbol in case of duplicate instance
EXTRA->instance = returnedAddress.getInstance();
// observe /parent/in address in order to link/unlink with an Input object below
returnedNode->getParent()->getAddress(parentAddress);
inputAddress = parentAddress.appendAddress(TTAddress("in")).appendInstance(EXTRA->instance);
x->wrappedObject.set("inputAddress", inputAddress);
// get model or view object
jamoma_patcher_get_model_or_view(x->patcherPtr, &modelOrView);
// notify the model there is something new concerning signal processing
if (modelOrView)
object_method_typed(modelOrView, gensym("output_created"), 0, NULL, NULL);
}
}
void model_preset_amenities(TTPtr self)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
TTAddress modelAdrs;
TTValue v, a, args, none;
TTAddress presetAddress;
// get model:address
EXTRA->modelInfo->get(kTTSym_address, v);
modelAdrs = v[0];
// create the preset manager
jamoma_presetManager_create((t_object*)x, *EXTRA->presetManager);
// suscribe it under a preset node
presetAddress = modelAdrs.appendAddress(TTAddress("preset"));
args = TTValue(presetAddress, *EXTRA->presetManager, x->patcherPtr);
if (!MaxApplication.send("ObjectRegister", args, none)) {
EXTRA->presetManager->set(kTTSym_address, modelAdrs);
defer_low(x, (method)model_preset_default, 0, 0, 0L);
}
}
void node_subscribe(TTPtr self, t_symbol* relativeAddress, long argc, t_atom* argv)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
TTAddress returnedAddress;
TTNodePtr returnedNode = NULL;
TTNodePtr returnedContextNode = NULL;
// for relative address
if (TTAddress(relativeAddress->s_name).getType() == kAddressRelative) {
if(!jamoma_subscriber_create((t_eobj*)x, x->wrappedObject, TTAddress(relativeAddress->s_name), x->subscriberObject, returnedAddress, &returnedNode, &returnedContextNode))
pd_error((t_object*)x, "error when registering %s", relativeAddress->s_name);
}
else
pd_error((t_object*)x, "can't register because %s is not a relative address", relativeAddress->s_name);
}
// Create
void *init_new(t_symbol *s, long argc, t_atom *argv)
{
long attrstart = attr_args_offset(argc, argv); // support normal arguments
t_init *x = (t_init *)object_alloc(g_init_class);
t_symbol *relativeAddress = _sym_nothing; // could be used to binds on a sub level j.hub
if (attrstart && argv)
atom_arg_getsym(&relativeAddress, 0, attrstart, argv);
if (x) {
x->outlets = (TTHandle)sysmem_newptr(sizeof(TTPtr) * 2);
x->outlets[end_out] = bangout(x);
x->outlets[start_out] = bangout(x);
x->patcherNode = NULL;
x->address = TTAddress(jamoma_parse_dieze((t_object*)x, relativeAddress)->s_name);
attr_args_process(x, argc, argv); // handle attribute args
// The following must be deferred because we have to interrogate our box,
// and our box is not yet valid until we have finished instantiating the object.
// Trying to use a loadbang method instead is also not fully successful (as of Max 5.0.6)
defer_low((t_object*)x, (method)init_subscribe, NULL, 0, 0);
}
return (x); // Return the pointer
}
TTErr makeInternals_data(TTPtr self, TTAddress address, TTSymbol name, t_symbol *callbackMethod, TTPtr context, TTSymbol service, TTObject& returnedData, TTBoolean deferlow)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
TTValue baton, v, out;
TTAddress dataAddress, dataRelativeAddress;
TTNodePtr dataNode;
returnedData = TTObject(kTTSym_Data, service);
baton = TTValue(TTPtr(x), TTPtr(callbackMethod), deferlow);
returnedData.set(kTTSym_baton, baton);
returnedData.set(kTTSym_function, TTPtr(&jamoma_callback_return_value));
// absolute registration
dataAddress = address.appendAddress(TTAddress(name));
v = TTValue(dataAddress, returnedData, context);
out = MaxApplication.send("ObjectRegister", v);
// retreive relative effective address
dataAddress = out[0];
dataNode = TTNodePtr((TTPtr)out[1]);
dataNode->getAddress(dataRelativeAddress, address);
// absolute registration case : set the address in second position (see in unregister method)
v = TTValue(returnedData, dataAddress);
x->internals->append(dataRelativeAddress, v);
JamomaDebug object_post((t_object*)x, "makes internal \"%s\" %s at : %s", dataRelativeAddress.c_str(), service.c_str(), dataAddress.c_str());
return kTTErrNone;
}
TTErr makeInternals_sender(TTPtr self, TTAddress address, TTSymbol name, TTObject& returnedSender, TTBoolean appendNameAsAttribute)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
TTValue v;
TTAddress adrs;
// check the internals do not exist yet
if (!x->internals->lookup(name, v)) {
returnedSender = v[0];
JamomaDebug object_post((t_object*)x, "makeInternals_sender : \"%s\" internal already exists", name.c_str());
return kTTErrNone;
}
returnedSender = TTObject(kTTSym_Sender);
// edit address
if (appendNameAsAttribute)
adrs = address.appendAttribute(name);
else
adrs = address.appendAddress(TTAddress(name.c_str()));
// default registration case : store object only (see in unregister method)
x->internals->append(name, returnedSender);
// set address attribute
returnedSender.set(kTTSym_address, adrs);
JamomaDebug object_post((t_object*)x, "makes internal \"%s\" sender to bind on : %s", name.c_str(), adrs.c_str());
return kTTErrNone;
}
TTErr makeInternals_viewer(TTPtr self, TTAddress address, TTSymbol name, t_symbol *callbackMethod, TTObject& returnedViewer, TTBoolean deferlow)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
TTValue v, baton;
TTAddress adrs;
// check the internals do not exist yet
if (!x->internals->lookup(name, v)) {
returnedViewer = v[0];
JamomaDebug object_post((t_object*)x, "makeInternals_viewer : \"%s\" internal already exists", name.c_str());
return kTTErrNone;
}
returnedViewer = TTObject(kTTSym_Viewer);
baton = TTValue(TTPtr(x), TTPtr(callbackMethod), deferlow);
returnedViewer.set(kTTSym_baton, baton);
returnedViewer.set(kTTSym_function, TTPtr(&jamoma_callback_return_value));
// edit address
adrs = address.appendAddress(TTAddress(name));
// default registration case : store object only (see in unregister method)
x->internals->append(name, returnedViewer);
// set address attribute (after registration as the value can be updated in the same time)
returnedViewer.set(kTTSym_address, adrs);
JamomaDebug object_post((t_object*)x, "makes internal \"%s\" viewer to bind on : %s", name.c_str(), adrs.c_str());
return kTTErrNone;
}
void WrappedMapperClass_new(TTPtr self, long argc, t_atom *argv)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
t_symbol *relativeAddress;
long attrstart = attr_args_offset(argc, argv); // support normal arguments
// possible relativeAddress
if (attrstart && argv)
relativeAddress = atom_getsym(argv);
else
relativeAddress = _sym_nothing;
if (relativeAddress) x->address = TTAddress(relativeAddress->s_name);
jamoma_mapper_create((t_object*)x, x->wrappedObject);
// Make two outlets
x->outlets = (TTHandle)sysmem_newptr(sizeof(TTPtr));
x->outlets[data_out] = outlet_new((t_object*)x, NULL); // anything outlet to output data
x->dumpOut = outlet_new((t_object*)x, NULL);
// handle attribute args
attr_args_process(x, argc, argv);
// Prepare extra data
x->extra = (t_extra*)malloc(sizeof(t_extra));
EXTRA->arguments = new TTValue();
jamoma_ttvalue_from_Atom(*EXTRA->arguments, _sym_nothing, argc, argv);
// The following must be deferred because we have to interrogate our box,
// and our box is not yet valid until we have finished instantiating the object.
// Trying to use a loadbang method instead is also not fully successful (as of Max 5.0.6)
// map_subscribe(x);
// defer_low((t_object*)x, (method)map_subscribe, NULL, 0, 0);
}
void data_address(TTPtr self, t_symbol *address)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
// Avoid succession of address changes
if (!EXTRA->changingAddress) {
EXTRA->changingAddress = YES;
// filter repetitions
if (!(x->arrayAddress == TTAddress(address->s_name))) {
if (!x->iterateInternals) {
// unregister internals
wrappedModularClass_unregister(x);
x->arraySize = 0;
// rebuild internals
defer(self,(method)data_new_address, address, 0, NULL);
// for array mode : output the array once afterward
if (x->arrayAttrFormat == gensym("array")) {
TTValue array;
t_symbol *msg;
long argc = 0;
t_atom *argv = NULL;
TTBoolean shifted = NO;
data_edit_array(self, array);
jamoma_ttvalue_to_typed_Atom(array, &msg, &argc, &argv, shifted);
// avoid blank before data
if (msg == _sym_nothing)
outlet_atoms(x->outlets[data_out], argc, argv);
else
outlet_anything(x->outlets[data_out], msg, argc, argv);
if (shifted)
argv--;
sysmem_freeptr(argv);
}
}
}
EXTRA->changingAddress = NO;
return;
}
object_error((t_object*)x, "can't change to %s address. Please defer low", address->s_name);
}
TTErr makeInternals_receiver(TTPtr self, TTAddress address, TTSymbol name, t_symbol *callbackMethod, TTObject& returnedReceiver, TTBoolean deferlow, TTBoolean appendNameAsAttribute)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
TTValue v, args, baton;
TTObject returnValueCallback, empty;
TTAddress adrs;
// check the internals do not exist yet
if (!x->internals->lookup(name, v)) {
returnedReceiver = v[0];
JamomaDebug object_post((t_object*)x, "makeInternals_receiver : \"%s\" internal already exists", name.c_str());
returnedReceiver.send("Get");
return kTTErrNone;
}
// prepare arguments
// we don't want the address back
args.append(empty);
returnValueCallback = TTObject("callback");
baton = TTValue(TTPtr(x), TTPtr(callbackMethod), deferlow);
returnValueCallback.set(kTTSym_baton, baton);
returnValueCallback.set(kTTSym_function, TTPtr(&jamoma_callback_return_value));
args.append(returnValueCallback);
returnedReceiver = TTObject(kTTSym_Receiver, args);
// edit address
if (appendNameAsAttribute)
adrs = address.appendAttribute(name);
else
adrs = address.appendAddress(TTAddress(name.c_str()));
// default registration case : store object only (see in unregister method)
x->internals->append(name, returnedReceiver);
// set address attribute (after registration as the value can be updated in the same time)
returnedReceiver.set(kTTSym_address, adrs);
JamomaDebug object_post((t_object*)x, "makes internal \"%s\" receiver to bind on : %s", name.c_str(), adrs.c_str());
return kTTErrNone;
}
void data_new_address(TTPtr self, t_symbol *relativeAddress)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
long argc = 0;
t_atom *argv = NULL;
TTUInt32 number;
TTUInt32 i;
TTAddress newAddress = relativeAddress->s_name;
TTAddress returnedAddress;
TTNodePtr returnedNode = NULL;
TTNodePtr returnedContextNode = NULL;
t_symbol *instanceAddress;
TTObject anObject;
TTObject aSubscriber;
TTValue v;
x->useInternals = YES;
x->internals->clear();
x->internals->setThreadProtection(YES);
x->cursor = kTTSymEmpty;
x->arrayAddress = newAddress;
if (x->arrayAddress.getType() == kAddressRelative) {
number = jamoma_parse_bracket(relativeAddress, x->arrayFormatInteger, x->arrayFormatString);
// don't resize to 0
if (number && number <= MAX_ARRAY_SIZE) {
// Starts iteration on internals
x->iterateInternals = YES;
x->arraySize = number;
EXTRA->objectsSorted->clear();
for (i = 1; i <= x->arraySize; i++) {
jamoma_edit_numeric_instance(x->arrayFormatInteger, &instanceAddress, i);
// create a data
#ifdef JMOD_MESSAGE
data_array_create(self, anObject, kTTSym_message, i);
#endif
#if JMOD_RETURN
data_array_create(self, anObject, kTTSym_return, i);
#endif
#ifndef JMOD_MESSAGE
#ifndef JMOD_RETURN
data_array_create(self, anObject, kTTSym_parameter, i);
#endif
#endif
if (!jamoma_subscriber_create((t_object*)x, anObject, TTAddress(instanceAddress->s_name), aSubscriber, returnedAddress, &returnedNode, &returnedContextNode)) {
if (aSubscriber.valid()) {
// append the data to the internals table
v = TTValue(anObject);
v.append(TTSymbol(instanceAddress->s_name));
v.append(aSubscriber);
x->internals->append(TTSymbol(instanceAddress->s_name), v);
// inverse objects order for iteration purpose (see in data_array_return_value : array mode)
EXTRA->objectsSorted->insert(0, anObject);
}
}
}
// Ends iteration on internals
x->iterateInternals = NO;
// handle args
jamoma_ttvalue_to_Atom(x->arrayArgs, &argc, &argv);
if (argc && argv)
attr_args_process(x, argc, argv);
// select all datas
wrappedModularClass_ArraySelect(self, gensym("*"), 0, NULL);
#ifndef JMOD_MESSAGE
// init all datas created dynamically
if (!EXTRA->firstArray)
defer((t_object*)x, (method)wrappedModularClass_anything, _sym_init, 0, NULL);
#endif
}
else if (number > MAX_ARRAY_SIZE)
object_error((t_object*)x, "the size is greater than the maximum array size (%d)", MAX_ARRAY_SIZE);
EXTRA->firstArray = NO;
}
else
object_error((t_object*)x, "can't register because %s is not a relative address", relativeAddress->s_name);
}
// Create
void* allpassmod_new(t_symbol* s, long argc, t_atom* argv)
{
t_allpassmod* x = (t_allpassmod*)object_alloc(s_allpassmod_class);
long attrstart = attr_args_offset(argc, argv); // support normal arguments
TTString name = "/";
TTPtr context = TTPtr(x);
TTValue none;
object_obex_lookup(x, gensym("#P"), (t_object**)&context);
if (attrstart) {
if (atom_getsym(argv)->s_name[0] == '/')
name += atom_getsym(argv)->s_name + 1;
else
name += atom_getsym(argv)->s_name;
}
else
name += s->s_name;
x->name = TTAddress(name); // need to cache so we can free
// 1. Create the DSP objects
x->allpass = TTAudioObject("allpass.1", 2);
x->signalOut = TTObject(kTTSym_audiosignal, 2);
x->signalIn = TTObject(kTTSym_audiosignal, 2);
// 2. Create the "model" container
{
TTValue container_args; // TODO: (optional) pass address callback and value callback (these are both for the activity return mechanism)
x->model = TTObject(kTTSym_Container, container_args);
x->model.set(kTTSym_tags, kTTSym_model);
TTValue registration_args(x->name, x->model, context);
MaxApplication.send("ObjectRegister", registration_args, none);
x->model.set("address", x->name);
}
// 3. Create the "clear" message
{
x->message_clear = TTObject(kTTSym_Data, kTTSym_message);
x->message_clear.set(kTTSym_baton, TTPtr(x));
x->message_clear.set(kTTSym_function, TTPtr(allpassmod_parameter_clear_callback));
x->message_clear.set(kTTSym_type, kTTSym_none);
x->message_clear.set(kTTSym_description, TTSymbol("Clear the filter history"));
TTAddress address = x->name.appendAddress("/clear");
TTValue registration_args(address, x->message_clear, context);
MaxApplication.send("ObjectRegister", registration_args, none);
}
// 4. Create the "gain" parameter (linear)
{
x->parameter_coefficient = TTObject(kTTSym_Data, kTTSym_parameter);
x->parameter_coefficient.set(kTTSym_baton, TTPtr(x));
x->parameter_coefficient.set(kTTSym_function, TTPtr(allpassmod_parameter_coefficient_callback));
x->parameter_coefficient.set(kTTSym_type, kTTSym_decimal);
x->parameter_coefficient.set(kTTSym_valueDefault, 0.7);
x->parameter_coefficient.set(kTTSym_description, TTSymbol("Gain coefficient"));
TTAddress address = x->name.appendAddress("/coefficient");
TTValue registration_args(address, x->parameter_coefficient, context);
MaxApplication.send("ObjectRegister", registration_args, none);
}
// 5. Create the "delay" parameter (milliseconds)
{
x->parameter_delay = TTObject(kTTSym_Data, kTTSym_parameter);
x->parameter_delay.set(kTTSym_baton, TTPtr(x));
x->parameter_delay.set(kTTSym_function, TTPtr(allpassmod_parameter_delay_callback));
x->parameter_delay.set(kTTSym_type, kTTSym_decimal);
x->parameter_delay.set(kTTSym_valueDefault, 0.2);
x->parameter_delay.set(kTTSym_description, TTSymbol("Delay time"));
TTAddress address = x->name.appendAddress("/delay");
TTValue registration_args(address, x->parameter_delay, context);
MaxApplication.send("ObjectRegister", registration_args, none);
}
// 6. Create the Input access points
{
// left input
{
x->in_left = TTObject("Input.audio");
TTAddress address = x->name.appendAddress("/in.left");
TTValue registration_args(address, x->in_left, context);
MaxApplication.send("ObjectRegister", registration_args, none);
}
// right input
{
x->in_right = TTObject("Input.audio");
TTAddress address = x->name.appendAddress("/in.right");
TTValue registration_args(address, x->in_right, context);
MaxApplication.send("ObjectRegister", registration_args, none);
}
}
// 7. Create the Output access points
{
// left output
{
x->out_left = TTObject("Output.audio");
TTAddress address = x->name.appendAddress("/out.left");
TTValue registration_args(address, x->out_left, context);
MaxApplication.send("ObjectRegister", registration_args, none);
}
// right output
{
x->out_right = TTObject("Output.audio");
TTAddress address = x->name.appendAddress("/out.right");
TTValue registration_args(address, x->out_right, context);
MaxApplication.send("ObjectRegister", registration_args, none);
}
}
// 8. Add the preset functions
{
x->preset = TTObject(kTTSym_PresetManager);
x->preset.set("address", x->name);
TTAddress address = x->name.appendAddress("/preset");
TTValue registration_args(address, x->preset, context);
MaxApplication.send("ObjectRegister", registration_args, none);
// load a preset file and recall the first preset
{
TTValue out;
TTObject xmlHandler("XmlHandler");
// set the object attr of the above object to be the PresetManager
xmlHandler.set("object", x->preset);
// TODO : get the filepath as an argument
TTSymbol path;
xmlHandler.send("Read", path, out);
// recall the first preset
x->preset.send("Recall", 1, none);
}
}
// 9. Initialize the module (set default values, etc)
x->model.send("Init");
// 10. Do some final Max-specific stuff
dsp_setup((t_pxobject*)x, 2);
x->obj.z_misc = Z_NO_INPLACE;
for (int i=0; i < 2; i++)
outlet_new((t_pxobject*)x, "signal");
attr_args_process(x, argc, argv);
return x;
}
void in_subscribe(TTPtr self)
{
WrappedModularInstancePtr x = (WrappedModularInstancePtr)self;
TTAddress inputAddress;
TTAddress outputAddress;
TTValue v, args;
TTNodePtr returnedNode = NULL;
TTNodePtr returnedContextNode = NULL;
TTAddress returnedAddress, parentAddress;
TTDataPtr aData;
TTString formatDescription, sInstance;
SymbolPtr inDescription;
inputAddress = TTAddress("in").appendInstance(EXTRA->instance);
// if the subscription is successful
if (!jamoma_subscriber_create((ObjectPtr)x, x->wrappedObject, inputAddress, &x->subscriberObject, returnedAddress, &returnedNode, &returnedContextNode)) {
// get patcher
x->patcherPtr = jamoma_patcher_get((ObjectPtr)x);
// update instance symbol in case of duplicate instance
EXTRA->instance = returnedAddress.getInstance();
// observe /parent/out address in order to link/unlink with an Input object below
returnedNode->getParent()->getAddress(parentAddress);
outputAddress = parentAddress.appendAddress(TTAddress("out")).appendInstance(EXTRA->instance);
x->wrappedObject->setAttributeValue(TTSymbol("outputAddress"), outputAddress);
#ifdef JCOM_IN_TILDE
// make internal data to return amplitude
v = TTValue(0., 1.);
formatDescription = "instant amplitude of %s input";
sInstance = EXTRA->instance.c_str();
jamoma_edit_string_instance(formatDescription, &inDescription, sInstance);
makeInternals_data(x, returnedAddress, TTSymbol("amplitude"), NULL, x->patcherPtr, kTTSym_return, (TTObjectBasePtr*)&aData);
aData->setAttributeValue(kTTSym_type, kTTSym_decimal);
aData->setAttributeValue(kTTSym_tag, kTTSym_generic);
aData->setAttributeValue(kTTSym_rangeBounds, v);
aData->setAttributeValue(kTTSym_description, TTSymbol(inDescription->s_name));
aData->setAttributeValue(kTTSym_dataspace, TTSymbol("gain"));
aData->setAttributeValue(kTTSym_dataspaceUnit, TTSymbol("linear"));
// make internal data to parameter in/amplitude/active
makeInternals_data(x, returnedAddress, TTSymbol("amplitude/active"), gensym("return_amplitude_active"), x->patcherPtr, kTTSym_parameter, (TTObjectBasePtr*)&aData);
aData->setAttributeValue(kTTSym_type, kTTSym_integer);
aData->setAttributeValue(kTTSym_tag, kTTSym_generic);
v = TTValue((int)EXTRA->pollInterval);
aData->setAttributeValue(kTTSym_valueDefault, v);
v = TTValue(0, 1000);
aData->setAttributeValue(kTTSym_rangeBounds, v);
aData->setAttributeValue(kTTSym_rangeClipmode, kTTSym_low);
aData->setAttributeValue(kTTSym_description, TTSymbol("set the sample rate of the amplitude follower"));
// launch the clock to update amplitude regulary
EXTRA->clock = clock_new(x, (method)in_update_amplitude);
if (EXTRA->pollInterval)
clock_delay(EXTRA->clock, EXTRA->pollInterval);
#endif
// expose bypass and mute attributes of TTInput as TTData in the tree structure
x->subscriberObject->exposeAttribute(x->wrappedObject, kTTSym_bypass, kTTSym_parameter, &aData);
aData->setAttributeValue(kTTSym_type, kTTSym_boolean);
aData->setAttributeValue(kTTSym_tag, kTTSym_generic);
aData->setAttributeValue(kTTSym_description, TTSymbol("When active, this attribute bypasses the model's processing algtorithm, letting incoming signal pass through unaffected"));
v = TTValue(0);
aData->setAttributeValue(kTTSym_valueDefault, v);
x->subscriberObject->exposeAttribute(x->wrappedObject, kTTSym_mute, kTTSym_parameter, &aData);
aData->setAttributeValue(kTTSym_type, kTTSym_boolean);
aData->setAttributeValue(kTTSym_tag, kTTSym_generic);
aData->setAttributeValue(kTTSym_description, TTSymbol("When active, this attribute turns off model's inputs."));
v = TTValue(0);
aData->setAttributeValue(kTTSym_valueDefault, v);
}
}
void TTNodeLibTestMiscellaneous(int& errorCount, int& testAssertionCount)
{
TTTestLog("\n");
TTTestLog("Miscellaneous Tests");
// test convertUpperCasedName global method
TTSymbol testSymbolA = "TestSymbolName";
TTSymbol testSymbolB = "testSymbolName";
TTSymbol testSymbolC = "testsymbolname";
TTAddress result;
convertUpperCasedNameInAddress(testSymbolA, result);
TTTestAssertion("convertUpperCasedName: Test passes if \"TestSymbolName\" is converted in \"test/symbol/name\"",
result == TTAddress("test/symbol/name"),
testAssertionCount,
errorCount);
convertUpperCasedNameInAddress(testSymbolB, result);
TTTestAssertion("convertUpperCasedName: Test passes if \"testSymbolName\" is converted in \"test/symbol/name\"",
result == TTAddress("test/symbol/name"),
testAssertionCount,
errorCount);
convertUpperCasedNameInAddress(testSymbolC, result);
TTTestAssertion("convertUpperCasedName: Test passes if \"testsymbolname\" is not converted",
result == testSymbolC,
testAssertionCount,
errorCount);
// test TTSymbol to TTAdress casting
TTValue testValue = TTValue(TTSymbol("directory:/gran/parent/name.instance:attribute"));
TTAddress testAddress;
testAddress = testValue[0];
TTSymbol directory = testAddress.getDirectory();
TTAddress parent = testAddress.getParent();
TTSymbol name = testAddress.getName();
TTSymbol instance = testAddress.getInstance();
TTSymbol attribute = testAddress.getAttribute();
TTAddressType type = testAddress.getType();
TTBoolean t1 = directory == TTSymbol("directory");
TTBoolean t2 = parent == TTAddress("/gran/parent");
TTBoolean t3 = name == TTSymbol("name");
TTBoolean t4 = instance == TTSymbol("instance");
TTBoolean t5 = attribute == TTSymbol("attribute");
TTBoolean t6 = type == kAddressAbsolute;
TTTestAssertion("TTValue::get : Test2 fails if a TTSymbol contained into a value is not casted into a TTAddress during a get method",
directory == TTSymbol("directory") &&
parent == TTAddress("/gran/parent") &&
name == TTSymbol("name") &&
instance == TTSymbol("instance") &&
attribute == TTSymbol("attribute") &&
type == kAddressAbsolute,
testAssertionCount,
errorCount);
// test TTSymbol for TTHash access when a key is stored using a TTAddress
TTHash testTable;
TTAddress keyAddress = TTAddress("testKeyAddress");
TTValue keyValue;
TTErr err;
testTable.append(keyAddress, keyValue); // store a value into the table using "testKeyAddress" address
testValue = TTValue(TTSymbol("testKeyAddress")); // store a "testKeyAddress" symbol into a value
testAddress = testValue[0]; // get it as an address
err = testTable.lookup(testAddress, keyValue); // use the address to lookup the table
TTTestAssertion("TTHash::lookup : Test fails if a TTSymbol cannot be used as storage key for TTHash table when the lookup key is a TTAddress",
err == kTTErrNone,
testAssertionCount,
errorCount);
// The test below fails but it have been added only to check the opposite operation.
// For instant we don't need this test to pass so it is commented out until we need this feature.
/* test TTAddress for TTHash access when a key is stored using a TTSymbol
TTSymbol keySymbol = TTSymbol("testKeySymbol");
TTSymbol testSymbol;
testTable.append(keySymbol, keyValue); // store a value into the table using "testKeySymbol" symbol
testValue = TTValue(TTAddress("testKeySymbol")); // store a "testKeySymbol" address into a value
testSymbol = testValue[0]; // get it as an symbol
err = testTable.lookup(testSymbol, keyValue); // use the symbol to lookup the table
TTTestAssertion("TTHash::lookup : Test fails if a TTAddress cannot be used as storage key for TTHash table when the lookup key is a TTSymbol",
err == kTTErrNone,
testAssertionCount,
errorCount);
*/
}
void TTNodeLibTestAddressItem(int& errorCount, int& testAssertionCount)
{
TTAddressItemPtr aNamespace, aParent, n, f;
TTSymbol aSymbol(kTTSymEmpty);
TTBoolean aSelection, empty;
TTUInt8 size;
TTErr err;
TTTestLog("\n");
TTTestLog("Testing Address Item management");
// The first test checks item creation and member access
aNamespace = new TTAddressItem(kTTSymEmpty);
aSymbol = aNamespace->getSymbol();
aParent = aNamespace->getParent();
aSelection = aNamespace->getSelection();
empty = aNamespace->isEmpty();
TTTestAssertion("TTAddressItem: Test fails if the namespace is not empty",
empty &&
aSymbol == NO_NAME &&
aParent == NULL &&
aSelection == NO,
testAssertionCount,
errorCount);
// The second set of tests checks item management
n = new TTAddressItem(TTSymbol("test"));
aNamespace->merge(n);
TTTestAssertion("TTAddressItem: Test fails if the namespace size is not equal 1",
aNamespace->getSize() == 1,
testAssertionCount,
errorCount);
f = aNamespace->getItem(n->getSymbol());
if (f) {
aSymbol = f->getSymbol();
aParent = f->getParent();
aSelection = f->getSelection();
empty = f->isEmpty();
}
TTTestAssertion("TTAddressItem: Test fails if the namespace is not named \"test\" or have no parent",
empty &&
aSymbol == TTSymbol("test") &&
aParent == aNamespace &&
aSelection == NO,
testAssertionCount,
errorCount);
aNamespace->destroy(n);
TTTestAssertion("TTAddressItem: Test fails if the namespace is not empty",
aNamespace->isEmpty(),
testAssertionCount,
errorCount);
// The third set of tests checks item management using TTAddress
aNamespace->clear();
aNamespace->append(TTAddress("/parent/name"), &f);
aNamespace->append(TTAddress("/parent/name.instance"), &f);
aSymbol = aNamespace->getSymbol();
size = aNamespace->getSize();
TTTestAssertion("TTAddressItem: Test fails if the namespace is not named \"\" and size is not equal 1",
size == 1 &&
aSymbol == kTTSymEmpty,
testAssertionCount,
errorCount);
f = NULL;
err = aNamespace->find(TTAddress("/parent"), &f);
if (!err) {
aSymbol = f->getSymbol();
aParent = f->getParent();
aSelection = f->getSelection();
empty = f->isEmpty();
}
TTTestAssertion("TTAddressItem: Test fails if the namespace is not named \"\" or have no parent or no child",
!empty &&
aSymbol == kTTSymEmpty &&
aParent == aNamespace->getItem(TTSymbol("parent")) &&
aSelection == NO,
testAssertionCount,
errorCount);
n = f;
f = NULL;
err = aNamespace->find(TTAddress("/parent/name"), &f);
if (!err) {
aSymbol = f->getSymbol();
aParent = f->getParent();
aSelection = f->getSelection();
empty = f->isEmpty();
}
TTTestAssertion("TTAddressItem: Test fails if the namespace is not named \"\" or have no parent or is not empty",
empty &&
aSymbol == kTTSymEmpty &&
aParent == n->getItem(TTSymbol("name")) &&
aSelection == NO,
testAssertionCount,
errorCount);
n = f;
f = NULL;
err = aNamespace->find(TTAddress("/parent/name.instance"), &f);
if (!err) {
aSymbol = f->getSymbol();
aParent = f->getParent();
aSelection = f->getSelection();
empty = f->isEmpty();
}
TTTestAssertion("TTAddressItem: Test fails if the namespace is not named \"instance\" or have no parent or is not empty",
empty &&
aSymbol == TTSymbol("instance") &&
aParent == n->getParent() &&
aSelection == NO,
testAssertionCount,
errorCount);
f = NULL;
aNamespace->append(TTAddress("/parent/name.other"), &f);
size = f->getParent()->getSize(); // have to be 3 because there are the empty, "instance" and "other" instances
TTTestAssertion("TTAddressItem: Test fails if size is not equal to 3",
size == 3,
testAssertionCount,
errorCount);
}
void TTNodeLibTestAddressParsing(int& errorCount, int& testAssertionCount)
{
TTTestLog("\n");
TTTestLog("Testing Address Parsing");
TTAddress testAddress1("directory1:/gran/parent1/name1.instance1:attribute1");
TTSymbol directory1 = testAddress1.getDirectory();
TTAddress parent1 = testAddress1.getParent();
TTSymbol name1 = testAddress1.getName();
TTSymbol instance1 = testAddress1.getInstance();
TTSymbol attribute1 = testAddress1.getAttribute();
TTAddressType type1 = testAddress1.getType();
TTAddress testAddress2("/gran/parent2/name2.instance2");
TTSymbol directory2 = testAddress2.getDirectory();
TTAddress parent2 = testAddress2.getParent();
TTSymbol name2 = testAddress2.getName();
TTSymbol instance2 = testAddress2.getInstance();
TTSymbol attribute2 = testAddress2.getAttribute();
TTAddressType type2 = testAddress2.getType();
TTAddress testAddress3("parent3/name3.instance3");
TTSymbol directory3 = testAddress3.getDirectory();
TTAddress parent3 = testAddress3.getParent();
TTSymbol name3 = testAddress3.getName();
TTSymbol instance3 = testAddress3.getInstance();
TTSymbol attribute3 = testAddress3.getAttribute();
TTAddressType type3 = testAddress3.getType();
TTAddress testAddress4("/");
TTSymbol directory4 = testAddress4.getDirectory();
TTAddress parent4 = testAddress4.getParent();
TTSymbol name4 = testAddress4.getName();
TTSymbol instance4 = testAddress4.getInstance();
TTSymbol attribute4 = testAddress4.getAttribute();
TTAddressType type4 = testAddress4.getType();
TTAddress testAddress5(":attribute5");
TTSymbol directory5 = testAddress5.getDirectory();
TTAddress parent5 = testAddress5.getParent();
TTSymbol name5 = testAddress5.getName();
TTSymbol instance5 = testAddress5.getInstance();
TTSymbol attribute5 = testAddress5.getAttribute();
TTAddressType type5 = testAddress5.getType();
TTAddress testAddress6("/gran/parent6.0/name6.0:attribute6");
TTSymbol directory6 = testAddress6.getDirectory();
TTAddress parent6 = testAddress6.getParent();
TTSymbol name6 = testAddress6.getName();
TTSymbol instance6 = testAddress6.getInstance();
TTSymbol attribute6 = testAddress6.getAttribute();
TTAddressType type6 = testAddress6.getType();
TTAddress testAddress7("/*.*");
TTSymbol directory7 = testAddress7.getDirectory();
TTAddress parent7 = testAddress7.getParent();
TTSymbol name7 = testAddress7.getName();
TTSymbol instance7 = testAddress7.getInstance();
TTSymbol attribute7 = testAddress7.getAttribute();
TTAddressType type7 = testAddress7.getType();
// The first set of tests checks parsing of addresses
TTTestAssertion("TTAddress: Test fails if parsing of testAddress1 is bad",
directory1 == TTSymbol("directory1") &&
parent1 == TTAddress("/gran/parent1") &&
name1 == TTSymbol("name1") &&
instance1 == TTSymbol("instance1") &&
attribute1 == TTSymbol("attribute1") &&
type1 == kAddressAbsolute,
testAssertionCount,
errorCount);
TTTestAssertion("TTAddress: Test fails if parsing of testAddress2 is bad",
directory2 == NO_DIRECTORY &&
parent2 == TTAddress("/gran/parent2") &&
name2 == TTSymbol("name2") &&
instance2 == TTSymbol("instance2") &&
attribute2 == NO_ATTRIBUTE &&
type2 == kAddressAbsolute,
testAssertionCount,
errorCount);
TTTestAssertion("TTAddress: Test fails if parsing of testAddress3 is bad",
directory3 == NO_DIRECTORY &&
parent3 == TTAddress("parent3") &&
name3 == TTSymbol("name3") &&
instance3 == TTSymbol("instance3") &&
attribute3 == NO_ATTRIBUTE &&
type3 == kAddressRelative,
testAssertionCount,
errorCount);
TTTestAssertion("TTAddress: Test fails if parsing of testAddress4 is bad",
directory4 == NO_DIRECTORY &&
parent4 == NO_PARENT &&
name4 == S_SEPARATOR &&
instance4 == NO_INSTANCE &&
attribute4 == NO_ATTRIBUTE &&
type4 == kAddressAbsolute,
testAssertionCount,
errorCount);
TTTestAssertion("TTAddress: Test fails if parsing of testAddress5 is bad",
directory5 == NO_DIRECTORY &&
parent5 == NO_PARENT &&
name5 == NO_NAME &&
instance5 == NO_INSTANCE &&
attribute5 == TTSymbol("attribute5") &&
type5 == kAddressRelative,
testAssertionCount,
errorCount);
TTTestAssertion("TTAddress: Test fails if parsing of testAddress6 is bad",
directory6 == NO_DIRECTORY &&
parent6 == TTAddress("/gran/parent6") &&
name6 == TTSymbol("name6") &&
instance6 == NO_INSTANCE &&
attribute6 == TTSymbol("attribute6") &&
type6 == kAddressAbsolute,
testAssertionCount,
errorCount);
TTTestAssertion("TTAddress: Test fails if parsing of testAddress7 is bad",
directory7 == NO_DIRECTORY &&
parent7 == kTTAdrsRoot &&
name7 == S_WILDCARD &&
instance7 == S_WILDCARD &&
attribute7 == NO_ATTRIBUTE &&
type7 == kAddressAbsolute,
testAssertionCount,
errorCount);
}
void TTNodeLibTestAddressMethods(int& errorCount, int& testAssertionCount)
{
TTAddress testAddressA("directory:/gran/parent/name.instance:attribute");
TTAddress testAddressB("/parent/name");
TTAddress testAddressC("name");
TTAddress testAddressD("/gran/parent");
TTAddress testAddressE("directory:/gran/parent");
TTAddress testAddressF("name.instance:attribute");
TTAddress testAddressG("/name.instance:attribute");
TTSymbol testSymbolA("");
TTSymbol resultSymbol;
TTAddress resultAddress;
TTAddress part1, part2;
// the first set of tests checks the getNameInstance method
TTTestLog("\n");
TTTestLog("Testing Address getNameInstance Method");
resultSymbol = testAddressA.getNameInstance();
TTTestAssertion("TTAddress: Test passes if the getNameInstance() method returns \"name.instance\"",
resultSymbol == TTSymbol("name.instance"),
testAssertionCount,
errorCount);
resultSymbol = testAddressB.getNameInstance();
TTTestAssertion("TTAddress: Test passes if the getNameInstance() method returns \"name\"",
resultSymbol == TTSymbol("name"),
testAssertionCount,
errorCount);
resultSymbol = testAddressC.getNameInstance();
TTTestAssertion("TTAddress: Test passes if the getNameInstance() method returns \"name\"",
resultSymbol == TTSymbol("name"),
testAssertionCount,
errorCount);
resultSymbol = kTTAdrsEmpty.getNameInstance();
TTTestAssertion("TTAddress: Test passes if the getNameInstance() method returns kTTSymEmpty",
resultSymbol == kTTSymEmpty,
testAssertionCount,
errorCount);
// the second set of tests checks the appendAddress method
TTTestLog("\n");
TTTestLog("Testing Address appendAddress Method");
resultAddress = testAddressD.appendAddress(kTTAdrsEmpty);
TTTestAssertion("TTAddress: Test passes if the appendAddress() method returns the same address",
resultAddress == testAddressD,
testAssertionCount,
errorCount);
resultAddress = kTTAdrsEmpty.appendAddress(testAddressD);
TTTestAssertion("TTAddress: Test passes if the appendAddress() method returns the same address",
resultAddress == testAddressD,
testAssertionCount,
errorCount);
resultAddress = kTTAdrsRoot.appendAddress(testAddressD);
TTTestAssertion("TTAddress: Test passes if the appendAddress() method returns the same address",
resultAddress == testAddressD,
testAssertionCount,
errorCount);
resultAddress = kTTAdrsEmpty.appendAddress(testAddressE);
TTTestAssertion("TTAddress: Test passes if the appendAddress() method returns the same address",
resultAddress == testAddressE,
testAssertionCount,
errorCount);
resultAddress = kTTAdrsRoot.appendAddress(testAddressE);
TTTestAssertion("TTAddress: Test passes if the appendAddress() method returns the same address",
resultAddress == testAddressE,
testAssertionCount,
errorCount);
resultAddress = testAddressD.appendAddress(testAddressF);
TTTestAssertion("TTAddress: Test passes if the appendAddress() method returns \"/gran/parent/name.instance:attribute\"",
resultAddress == TTAddress("/gran/parent/name.instance:attribute"),
testAssertionCount,
errorCount);
resultAddress = testAddressD.appendAddress(testAddressG);
TTTestAssertion("TTAddress: Test passes if the appendAddress() method returns \"/gran/parent/name.instance:attribute\"",
resultAddress == TTAddress("/gran/parent/name.instance:attribute"),
testAssertionCount,
errorCount);
// This test checks appendInstance() and appendAttribute() methods
resultAddress = kTTAdrsRoot.appendAddress(TTAddress("name")).appendInstance(TTAddress("instance")).appendAttribute(TTAddress("attribute"));
TTTestAssertion("TTAddress: Test passes if appendAddress + appendInstance + appendAttribute methods returns \"/name.instance:attribute\"",
resultAddress == TTAddress("/name.instance:attribute"),
testAssertionCount,
errorCount);
// the third set of tests checks the splitAt method
TTTestLog("\n");
TTTestLog("Testing Address splitAt Method");
testAddressA.splitAt(0, part1, part2);
TTTestAssertion("TTAddress: Test passes if splitAt method returns \"directory:/\" and \"gran/parent/name.instance:attribute\"",
part1 == TTAddress("directory:/") &&
part2 == TTAddress("gran/parent/name.instance:attribute"),
testAssertionCount,
errorCount);
testAddressA.splitAt(1, part1, part2);
TTTestAssertion("TTAddress: Test passes if splitAt method returns \"directory:/gran\" and \"parent/name.instance:attribute\"",
part1 == TTAddress("directory:/gran") &&
part2 == TTAddress("parent/name.instance:attribute"),
testAssertionCount,
errorCount);
testAddressA.splitAt(2, part1, part2);
TTTestAssertion("TTAddress: Test passes if splitAt method returns \"directory:/gran/parent\" and \"name.instance:attribute\"",
part1 == TTAddress("directory:/gran/parent") &&
part2 == TTAddress("name.instance:attribute"),
testAssertionCount,
errorCount);
// the fourth set of tests checks the countSeparator method
TTTestLog("\n");
TTTestLog("Testing Address countSeparator Method");
/*
// the fift set of tests checks the listNameInstance method
TTTestLog("\n");
TTTestLog("Testing Address listNameInstance Method");
*/
}
