/// <summary>
/// Set the output value of ShadowedOutputNode. This is the same as for
/// the super class methodd, except that it updates the shadowing inputs
/// </summary>
/// <param name="index"></param>
/// <param name="value"></param>
/// <param name="t"></param>
/// <param name="send"></param>
/// <returns></returns>
public override DXTypeVals setOutputValue(int index, String value, DXTypeVals t, bool send)
{
DXTypeVals type;
Debug.Assert(value != null);
// Defer visual notification in case, we do more then one set*Value().
deferVisualNotification();
// When data-driven, outputs that have shadowing inputs are not sent and
// instead their shadows are sent..
int shadow_input = getShadowingInput(index);
if (shadow_input > 0)
{
type = base.setOutputValue(index, value, t, false);
if (type != DXTypeVals.UndefinedType)
{
value = getOutputValueString(index);
setInputValue(shadow_input, value, type, false);
if (send)
sendValues(false);
}
}
else
{
type = base.setOutputValue(index, value, t, send);
}
undeferVisualNotification();
return type;
}
/// <summary>
/// // We implement this for FileSelector node so that we can keep the
/// 2nd output (the basename of the full file name) up to date.
/// One should never use this method to set the 2nd output, only the 1st.
/// Well, this is used when we parse a .net file.
/// </summary>
/// <param name="index"></param>
/// <param name="value"></param>
/// <param name="t"></param>
/// <param name="send"></param>
/// <returns></returns>
public override DXTypeVals setOutputValue(int index, String value, DXTypeVals t, bool send)
{
Regex regex = new Regex(@"\\");
String localValue = regex.Replace(value, "/");
if (index == 2)
return base.setOutputValue(2, localValue, t, send);
DXTypeVals type = base.setOutputValue(1, localValue, t, false);
if (type != DXTypeVals.UndefinedType)
{
String basename = getOutputValueString(1);
basename = regex.Replace(basename, "/");
if (!basename.Contains("/"))
type = base.setOutputValue(2, value, type, send);
else
{
// Not quite sure what the code is trying to do here.
throw new Exception("Not Yet Implemented");
}
}
return type;
}
/// <summary>
/// Update any inputs that are being updated by the server (i.e. the
/// module that is doing the data-driven operations).
/// We update the values internally, and send the shadowing input
/// value back to the executive with an Executive() call.
/// We use the Executive call instead of a direct assignment, because if
/// we are currently in execute-on-change mode, the assignment would cause
/// extra executions.
/// The Executive() call (a dictionary update) avoids that.
/// </summary>
/// <param name="output_index"></param>
/// <param name="val"></param>
/// <param name="t"></param>
/// <returns></returns>
protected DXTypeVals setShadowedOutputSentFromServer(int output_index, String val,
DXTypeVals t)
{
// Set the values internally
// Set the output quietly instead of just setting it and not sending it
// for the following scenario with out the quietly:
//
// 1) Interactor->Echo, Execute echos 0
// (references GLOBAL main_Interactor_1_out_1)
// 2) Set Interactor:min value to 5, Execute echos 5
// (references LOCAL main_Interactor_1_out_1)
// 3) Tab up Interactor:min, Execute echos 0
// (references GLOBAL main_Interactor_1_out_1)
//
// So, setting the output quietly makes sure that the global value
// is up to date.
int input_index = getShadowingInput(output_index);
DXTypeVals type = setOutputValueQuietly(output_index, val, t);
if (type != DXTypeVals.UndefinedType)
{
clearOutputDirty(output_index);
setInputValueQuietly(input_index, val, type);
}
return type;
}
public ParamClass(int pIndex, int opIndex, DXTypeVals pType, ParamCats pcat)
{
paramIndex = pIndex;
oldParamIndex = opIndex;
paramType = pType;
category = pcat;
}
public override DXTypeVals setInputValue(int index, string value,
DXTypeVals type, bool send)
{
DXTypeVals result;
bool trans = translating;
translating = false;
switch (index)
{
case (int)Params.usevector:
if (trans)
{
if (value.StartsWith("1"))
value = "0";
else if (value.StartsWith("2"))
value = "1";
}
if (value == "NULL")
value = "0";
notifyUseVectorChange(!value.StartsWith("0"));
break;
case (int)Params.aaenabled:
if (trans)
{
if (value.StartsWith("1"))
value = "0";
else if (value.StartsWith("2"))
value = "1";
}
break;
case (int)Params.recenable:
if (trans)
{
if (value.StartsWith("1"))
value = "0";
else if (value.StartsWith("2"))
value = "1";
}
break;
case (int)Params.projection:
notifyProjectionChange(!value.StartsWith("0"));
break;
case (int)Params.render_mode:
if (value == "\"hardware\"" ||
value == "hardware")
value = "1";
else if (value == "\"software\"" ||
value == "software")
value = "0";
else if (trans)
{
if (value.StartsWith("1"))
value = "0";
else if (value.StartsWith("2"))
value = "1";
}
if (type == DXTypeVals.StringType)
type = DXTypeVals.FlagType;
break;
case (int)Params.button_up_approx:
case (int)Params.button_down_approx:
if (value == "\"flat\"")
value = "\"none\"";
break;
}
result = base.setInputValue(index, value, type, send);
translating = trans;
return result;
}
/// <summary>
/// For the given type, try and augment the given string value with
/// syntactic sugar to coerce the given value to the given type.
/// The types we can coerce are StringType, ListType, VectorType and
/// TensorType.
/// If the value is coerceable return a new string that does not need to
/// be coerced to the given value, otherwise return NULL.
/// On success, the returned string must be freed by the caller.
/// </summary>
/// <param name="val"></param>
/// <param name="type"></param>
/// <returns></returns>
public static String CoerceValue(String val, DXTypeVals type)
{
String s;
bool failed = true;
if (type == DXTypeVals.ValueType)
{
s = DXValue.CoerceValue(val, DXTypeVals.VectorType);
}
else
{
if (val == null)
s = "";
else
s = val.Trim();
if ((type == DXTypeVals.StringType) || (type == DXTypeVals.WhereType))
{
s = "\"" + s + "\"";
}
else if (type == DXTypeVals.ListType)
{
s = "{" + s + "}";
}
else if (type == DXTypeVals.TensorType || type == DXTypeVals.VectorType)
{
s = "[" + s + "]";
}
if (!DXValue.IsValidValue(s, type))
failed = true;
else
failed = false;
// Try and coerce a list with a single element (i.e. coerce both the
// element and the overall value.
if (failed && (long)(type & DXTypeVals.ListType) > 0)
{
DXTypeVals basetype = type & DXTypeVals.ListTypeMask;
String p = DXValue.CoerceValue(val, basetype);
if (p != null)
{
String p2 = DXValue.CoerceValue(p, type);
if (p2 != null)
{
s = p2;
failed = false;
}
}
}
if (failed)
{
s = null;
}
}
return s;
}
/// <summary>
/// Make sure all values (Scalar[List], Integer[List] and Vector[List]
/// components) are within the given ranges for each component.
/// 'val' is the given string value representing the Scalar, Integer or
/// Vector and 'valtype' is expected to be its type.
/// mins/maxs are arrays of minimum and maximum values for the
/// corresponding components (scalar and integer only have a single
/// component).
/// TRUE is returned if the value needs to be clamped to be within the
/// given ranges, FALSE otherwise. If clampedval is provided, then a
/// string is passed back which represents the clamped value.
/// </summary>
/// <param name="val"></param>
/// <param name="valtype"></param>
/// <param name="mins"></param>
/// <param name="maxs"></param>
/// <param name="clampedval"></param>
/// <returns></returns>
public static bool ClampVSIValue(String val, DXTypeVals valtype, ref double mins,
ref double maxs, ref String clampedval)
{
throw new Exception("Not yet implemented");
}
/// <summary>
/// Replace a list item in a list value.
/// null is returned on failure. Positions begin at 1.
/// This works on the same list types that NextListItem() does.
/// </summary>
/// <param name="list"></param>
/// <param name="item"></param>
/// <param name="listtype"></param>
/// <param name="position"></param>
/// <returns></returns>
public static String ReplaceListItem(String list, String item,
DXTypeVals listtype, int position)
{
throw new Exception("Not yet implemented");
}
/// <summary>
/// Get the next item from a list of the given type.
/// Currently, only ScalarListType, IntegerListType, VectorListType and
/// StringListType are supported.
/// Search for the item is started a s[*index], and upon a successfull,
/// return *index is updated to point to the character not parsed as a list.
/// item. If *index is less than zero then we parse the initial list
/// delimiter '{'. If buf is provided (!NULL), then the list item is copied
/// into it otherwise a new string is allocated to hold the list item. In
/// either case a pointer to the string holding the list item is returned .
/// upon success.
/// </summary>
/// <param name="s"></param>
/// <param name="index"></param>
/// <param name="listtype"></param>
/// <param name="buf"></param>
/// <returns></returns>
public static String NextListItem(String s, ref int index, DXTypeVals listtype,
ref String buf)
{
throw new Exception("Not yet implemented");
}
public bool setValue(String value, DXTypeVals type, bool coerce)
{
bool success = false;
if (this.value == null)
this.value = new DXValue();
if (type == DXTypeVals.UndefinedType && value == null)
{
this.value = null;
success = true;
}
else
{
ParameterDefinition pd = this.Definition;
bool typeMatch = false;
foreach (DXType dxt in pd.getTypes())
{
if (DXType.MatchType(type, dxt.getType()))
{
typeMatch = true;
break;
}
}
if (typeMatch && (
this.value.setValue(value, type) ||
(coerce && this.coerceAndSetValue(value, type))))
success = true;
else
success = false;
}
if (success)
{
setDirty();
if (type == DXTypeVals.UndefinedType && value == null)
setUnconnectedDefaultingStatus(true);
else
setUnconnectedDefaultingStatus(false);
}
return success;
}
/// <summary>
/// Set the value of this parameter to the value represented by v which
/// must match the given type. If coerce is TRUE, then try and add
/// syntactic sugar to make the value match the type.
/// </summary>
/// <param name="v"></param>
/// <param name="t"></param>
/// <param name="coerce"></param>
/// <returns></returns>
public bool setValue(String value, DXTypeVals type)
{
return setValue(value, type, true);
}
/// <summary>
/// Uset setValue(v,t,c) to set the stored value.
/// If the parameter is not defaulting, this is
/// the same as setValue, but if it is defaulting, then we set the
/// value but leave the parameter clean and defaulting.
/// </summary>
/// <param name="value"></param>
/// <param name="type"></param>
/// <returns></returns>
public bool setSetValue(String value, DXTypeVals type)
{
throw new Exception("Not Yet Implemented");
}
public ToggleNode(NodeDefinition nd, Network net, int instnc)
: base(nd, net, instnc)
{
outputType = DXTypeVals.UndefinedType;
is_set = false;
}
/// <summary>
/// Make sure the given output's current value complies with any attributes.
/// This is called by InteractorInstance::setOutputValue() which is
/// intern intended to be called by the Interactors.
/// If verification fails (returns FALSE), then a reason is expected to
/// placed in reason.
/// At this level we always return TRUE (assuming that there are no
/// attributes) and set *reason to NULL.
/// </summary>
/// <param name="output"></param>
/// <param name="val"></param>
/// <param name="t"></param>
/// <param name="reason"></param>
/// <returns></returns>
protected virtual bool verifyValueAgainstAttributes(int output,
String val, DXTypeVals t, ref String[] reason)
{
throw new Exception("Not Yet Implemented");
}
/// <summary>
/// Make sure the given value complies with any attributes and if so
/// set the value in the Node. This should generally be called from
/// interactors that can't directly enforce attributes. For example,
/// the Text style versus the Stepper style Vector interactor. The
/// Stepper style enforces its attributes itself, but the Text style
/// accepts any value and then must have the value checked for type
/// and attribute compliance.
/// If we fail because attribute verification fails, then *reason contains
/// the reason (as passed back by verifyValueAgainstAttributes()) for
/// failure.
/// </summary>
/// <param name="index"></param>
/// <param name="val"></param>
/// <param name="type"></param>
/// <param name="send"></param>
/// <param name="reason"></param>
/// <returns></returns>
public bool setAndVerifyOutput(int index, String val, DXTypeVals type,
bool send, ref String reason)
{
throw new Exception("Not Yet Implemented");
}
public static bool IsValidValue(String str, DXTypeVals type)
{
bool result = false;
int tuple = 0;
if (str == null)
return false;
str = str.Trim();
if (str == "" || str.ToLower() == "null")
result = true;
else if (type == DXTypeVals.FlagType)
{
Regex r = new Regex(@"^(true|false|\d+)$");
result = r.IsMatch(str);
}
else if (type == DXTypeVals.IntegerType)
{
Regex r = new Regex(Scanning.Scanner.IntegerOnlyPattern);
result = r.IsMatch(str);
}
else if (type == DXTypeVals.ScalarType)
{
Regex r = new Regex(Scanning.Scanner.DoubleOnlyPattern);
result = r.IsMatch(str);
}
else if (type == DXTypeVals.VectorType)
{
result = DXTensor.IsVector(str, ref tuple);
}
else if (type == DXTypeVals.TensorType)
{
result = DXTensor.IsTensor(str);
}
else if (type == DXTypeVals.ValueType)
{
DXTypeVals value_type = DXTypeVals.UndefinedType;
result = IsValue(str, ref value_type);
}
else if (type == DXTypeVals.StringType)
{
Regex r = new Regex(@"^""[^""]*""$");
result = r.IsMatch(str);
}
else if (type == DXTypeVals.ObjectType)
{
result = IsObject(str);
}
else if ((type & DXTypeVals.ListType) > 0)
{
DXTypeVals list_type = type & DXTypeVals.ListTypeMask;
result = IsList(str, list_type);
}
else if ((type & DXTypeVals.WhereType) > 0)
{
Regex r = new Regex(@"^""[^""]*""$");
result = r.IsMatch(str);
}
else if (type == DXTypeVals.UserType1 ||
type == DXTypeVals.UserType2 ||
type == DXTypeVals.UserType4 ||
type == DXTypeVals.UserType5 ||
type == DXTypeVals.UserType6 ||
type == DXTypeVals.DescriptionType)
{
return true;
}
return result;
}
public static bool IsValue(String str, ref DXTypeVals type)
{
int tuple = 0;
if (str == null)
return false;
Regex r = new Regex(Scanning.Scanner.DoubleOnlyPattern);
switch (type)
{
case DXTypeVals.ScalarType:
return r.IsMatch(str);
break;
case DXTypeVals.VectorType:
return DXTensor.IsVector(str, ref tuple);
break;
case DXTypeVals.TensorType:
return DXTensor.IsTensor(str);
break;
default:
if (r.IsMatch(str))
{
type = DXTypeVals.ScalarType;
return true;
}
if (DXTensor.IsVector(str, ref tuple))
{
type = DXTypeVals.VectorType;
return true;
}
if (DXTensor.IsTensor(str))
{
type = DXTypeVals.TensorType;
return true;
}
break;
}
return false;
}
/// <summary>
/// For the given type, try and augment the given string value with
/// syntactic sugar to coerce the given value to the given type.
/// The types we can coerce are StringType, ListType, VectorType and
/// TensorType.
/// </summary>
/// <param name="value"></param>
/// <param name="type"></param>
/// <returns>t/f indicating whether the value was successfully set</returns>
protected bool coerceAndSetValue(String value, DXTypeVals type)
{
String s = DXValue.CoerceValue(value, type);
bool r = false;
if (s != null)
{
r = this.value.setValue(s, type);
}
return r;
}
public static String NextListItem(String s, ref int index, DXTypeVals listtype)
{
String tmp = null;
return NextListItem(s, ref index, listtype, ref tmp);
}
protected DXTypeVals setInputAttributeFromServer(int index, String val, DXTypeVals t)
{
Parameter p = getInputParameter(index);
Debug.Assert(p is AttributeParameter);
bool was_dirty = p.IsDirty;
bool r = setInputAttributeParameter(index, val);
if (!was_dirty)
clearInputDirty(index);
Debug.Assert(r);
if (t == DXTypeVals.UndefinedType)
{
AttributeParameter ap = (AttributeParameter)p;
t = ap.getAttributeValueType();
}
return t;
}
/// <summary>
/// Assigns a string value of the specified type (DXType constant).
/// Returns TRUE if the new value has been assigned;
/// returns FALSE otherwise.
/// </summary>
/// <param name="str"></param>
/// <param name="type"></param>
/// <returns></returns>
public bool setValue(String strp, DXTypeVals typep)
{
bool result = false;
if (DXValue.IsValidValue(strp, typep))
{
this.clear();
this.type.setType(typep);
this.str = strp;
if (String.Compare(str, "NULL", true) == 0)
{
this.type.setType(typep);
}
else
{
// Convert the string to internal, native form according to type
double d; int v;
switch (typep)
{
case DXTypeVals.FlagType:
// The executive dow not recognize 'true' or 'false', so
// we convert them to integer values.
if (String.Compare(strp, "false", true) == 0)
{
this.integer = 0; this.scalar = 0;
this.str = "0";
}
else if (String.Compare(strp, "true", true) == 0)
{
this.integer = 1; this.scalar = 1;
this.str = "1";
}
else
{
v = int.Parse(strp); this.integer = v;
d = double.Parse(strp); this.scalar = d;
}
break;
case DXTypeVals.IntegerType:
v = int.Parse(strp); this.integer = v;
d = double.Parse(strp); this.scalar = d;
break;
case DXTypeVals.ScalarType:
d = double.Parse(strp); this.scalar = d;
if (strp.Contains("."))
this.str = this.scalar.ToString();
break;
case DXTypeVals.VectorType:
tensor = new DXTensor();
result = tensor.setValue(strp);
Debug.Assert(result);
break;
case DXTypeVals.TensorType:
case DXTypeVals.ValueType:
case DXTypeVals.StringType:
case DXTypeVals.ObjectType:
case DXTypeVals.WhereType:
case DXTypeVals.DescriptionType:
break;
default:
if ((typep & DXTypeVals.ListType) > 0)
{
List<String> toks;
String buf;
switch (typep & DXTypeVals.ListTypeMask)
{
case DXTypeVals.ScalarType:
// Convert '{ 1 2.0000 3.3 }' into '{ 1.0 2.0 3.3 }'
// Ignore lists specified with the elipsis '{ 1..2: 3}'
if (this.str.Contains(":") || this.str.Contains(".."))
break;
toks = Utils.StringTokenizer(strp, " ,\t{}", null);
buf = "{ ";
foreach (String tok in toks)
{
buf += double.Parse(tok).ToString("0.0") + " ";
}
buf += "}";
this.str = buf;
break;
case DXTypeVals.IntegerType:
// Ignore lists specified with the ellipsis '{ 1..2:3 }'
if (this.str.Contains(":") || this.str.Contains(".."))
break;
toks = Utils.StringTokenizer(strp, " ,\t{}", null);
buf = "{ ";
foreach (String tok in toks)
{
buf += int.Parse(tok).ToString() + " ";
}
buf += "}";
this.str = buf;
break;
case DXTypeVals.StringType:
toks = Utils.StringTokenizer(strp, " ,\t{}", null);
buf = "{ ";
foreach (String tok in toks)
{
buf += tok + " ";
}
buf += "}";
this.str = buf;
break;
case DXTypeVals.FlagType:
case DXTypeVals.VectorType:
case DXTypeVals.TensorType:
case DXTypeVals.ValueType:
break;
}
}
else if ((long)(typep & DXTypeVals.UserType1) > 0 ||
(long)(typep & DXTypeVals.UserType2) > 0 ||
(long)(typep & DXTypeVals.UserType4) > 0 ||
(long)(typep & DXTypeVals.UserType5) > 0 ||
(long)(typep & DXTypeVals.UserType6) > 0)
{ }
else
Debug.Assert(false);
break;
}
}
return true;
}
else
return false;
}
/// <summary>
/// Parse the floating point numbers out of either a ScalarList or a
/// VectorList. Numbers are parsed into an array created from within.
/// The values are placed into the array in the order they are encountered
/// in the list. In the case of VectorLists, all vectors in the list must
/// be of the same dimensionality.
/// The return value is the number of list items parsed out of the list.
/// *data is the allocated array of values.
/// *tuple is the dimensionality of the VectorList items (1 for ScalarList).
/// '*tuple * return-val' is the number of items in the *data array.
/// </summary>
/// <param name="list"></param>
/// <param name="listtype"></param>
/// <param name="data"></param>
/// <param name="tuple"></param>
/// <returns></returns>
public static int GetDoublesFromList(String list, DXTypeVals listtype,
ref double[] data, ref int tuple)
{
throw new Exception("Not yet implemented");
}
/// <summary>
/// Does the given string represent the given type?
/// </summary>
/// <param name="str"></param>
/// <param name="type"></param>
/// <returns></returns>
public bool Valid(String str, DXTypeVals type)
{
throw new Exception("Not Yet Implemented");
}
/// <summary>
/// Get the index'th list item from the given string which
/// is expected to be a list.
/// null is returned if the item was not found or if the listtype is wrong.
/// </summary>
/// <param name="list"></param>
/// <param name="index"></param>
/// <param name="listtype"></param>
/// <returns></returns>
public static String GetListItem(String list, int index, DXTypeVals listtype)
{
throw new Exception("Not yet implemented");
}
/// <summary>
/// Calls setOutputAndOtherInteractorValues to update all interactor
/// instances.
/// </summary>
/// <param name="index"></param>
/// <param name="value"></param>
/// <param name="type"></param>
/// <param name="send"></param>
/// <returns></returns>
public override DXTypeVals setOutputValue(int index, string value, DXTypeVals type, bool send)
{
// Set the output value of an interactor. This is the same as for
// Node::setOutputValue(), except that it also updates the interactors
// in this->instanceList with
// InteractorInstance->Interactor->updateDisplayedInteractorValue().
DXTypeVals dxtype;
dxtype = base.setOutputValue(index, value, type, send);
if ((dxtype != DXTypeVals.UndefinedType) &&
!isVisualNotificationDeferred())
{
foreach (InteractorInstance ii in instanceList)
{
Interactor interactor = ii.getInteractor();
if (interactor != null)
interactor.updateDisplayedInteractorValue();
}
}
return dxtype;
}
/// <summary>
/// Get the number of items in the list.
/// </summary>
/// <param name="list"></param>
/// <param name="listtype"></param>
/// <returns></returns>
public static int GetListItemCount(String list, DXTypeVals listtype)
{
throw new Exception("Not yet implemented");
}
public ParamClass(int pIndex, int opIndex, DXTypeVals pType)
{
paramIndex = pIndex;
oldParamIndex = opIndex;
paramType = pType;
category = ParamCats.unknown;
}
public static bool IsList(String str, DXTypeVals type)
{
bool r = IsListExplicit(str, type);
if (!r && ((type & DXTypeVals.ValueType) > 0))
r = IsListConstructor(str);
return r;
}
public static bool IsListExplicit(String str, DXTypeVals type)
{
bool lexed;
int tuple = 0, first_tuple = -1;
if (str == null)
return false;
str = str.Trim();
if (!str.StartsWith("{") ||
!str.EndsWith("}"))
return false;
str = str.Substring(1);
str = str.Substring(0, str.Length -1);
DXTypeVals value_type = DXTypeVals.UndefinedType;
List<String> toks = Utils.StringTokenizer(str, " ,\t", new String[] { "\"", "[]" });
Regex r;
int elements = 0;
foreach (String tok in toks)
{
switch (type)
{
case DXTypeVals.FlagType:
r = new Regex(@"^(true|false|\d+)$");
lexed = r.IsMatch(tok);
break;
case DXTypeVals.IntegerType:
r = new Regex(Scanning.Scanner.IntegerOnlyPattern);
lexed = r.IsMatch(tok);
break;
case DXTypeVals.ScalarType:
r = new Regex(Scanning.Scanner.DoubleOnlyPattern);
lexed = r.IsMatch(tok);
break;
case DXTypeVals.VectorType:
lexed = DXTensor.IsVector(tok, ref tuple);
if (elements == 0)
first_tuple = tuple;
else if (tuple != first_tuple)
return false;
break;
case DXTypeVals.TensorType:
lexed = DXTensor.IsTensor(tok);
break;
case DXTypeVals.ValueType:
lexed = IsValue(str, ref value_type);
break;
case DXTypeVals.StringType:
r = new Regex(@"^""[^""]*""$");
lexed = r.IsMatch(tok);
break;
default:
return false;
}
if (lexed)
elements++;
else
return false;
}
return true;
}
private DXTypeVals setIOValueQuietly(ref List<Parameter> io, int index,
String value, DXTypeVals t)
{
throw new Exception("Not Yet Implemented");
}
