VTK/Marks: Difference between revisions

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== Initial Prototype ==
== Initial Prototype ==


The purpose of this prototype was to see how closely C++ code can resemble Protovis Javascript code. The properties are defined as boost::function objects. boost::lambda expressions (lines using the special _index and _d variables) may be used to specify functions. Alternately, free/static functions or function objects may be used. The bottom images show the results from both pieces of code.
The purpose of this prototype was to see how closely C++ code can resemble Protovis Javascript code. The properties are defined as boost::function instances. boost::lambda expressions (lines using the special _index and _d variables) may be used to specify functions. Alternately, free/static functions or function objects may be used. The bottom images show the results from both pieces of code.


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{| border="1"

Revision as of 19:56, 6 August 2010

Overview

Marks can be thought of as highly-configurable vectorized graphics items, or graphics item factories. They are a mid-level API built on more basic rendering primitives like lines, circles, etc. You want to use marks to make it easy to configure a set of primitives, where each primitive's properties will change depending on the item.

Protovis is an API description for marks with a reference implementation in javascript. Take a look at the protovis site for details on their design decisions and features.

In VTK, we want to explore a similar interface for marks in C++. The following is a possible technology stack for using marks in VTK. Qt could be incorporated as an alternative to OpenGL for publication-quality images.

Marks.png

Initial Prototype

The purpose of this prototype was to see how closely C++ code can resemble Protovis Javascript code. The properties are defined as boost::function instances. boost::lambda expressions (lines using the special _index and _d variables) may be used to specify functions. Alternately, free/static functions or function objects may be used. The bottom images show the results from both pieces of code.

Protovis C++

<source lang="javascript"> var data = pv.range(10).map(function(d) { return Math.random() + .1; }); </source>

<source lang="cpp">

 std::vector<double> vec;
 for (int i = 0; i < 10; ++i)
   {
   vec.push_back(vtkMath::Random() + 0.1);
   }
 VectorStorage* s = new VectorStorage(vec);
 Datum data(s);

</source>

<source lang="javascript"> // Sizing and scales. var w = 400,

   h = 250,
   x = pv.Scale.linear(0, 1.1).range(0, w),
   y = pv.Scale.ordinal(pv.range(10)).splitBanded(0, h, 4/5);</source>

<source lang="cpp">

 // Sizing and scales.
 int w = 400;
 int h = 250;
 LinearScale x(0, 1.1);
 x.range(0, w);
 OrdinalScale y(range(10));
 y.splitBanded(0, h, 4.0/5);

</source>

<source lang="javascript"> // The root panel. var vis = new pv.Panel()

   .width(w)
   .height(h)
   .bottom(20)
   .left(20)
   .right(10)
   .top(5);

</source>

<source lang="cpp">

 // The root panel.
 Panel vis;
 vis.width(w);
 vis.height(h);
 vis.bottom(20);
 vis.left(20);
 vis.right(10);
 vis.top(5);

</source>

<source lang="javascript"> // The bars. var bar = vis.add(pv.Bar)

   .data(data)
   .top(function() y(this.index))
   .height(y.range().band)
   .left(0)
   .width(x);

</source>

<source lang="cpp">

 // The bars.
 Bar* bar = vis.addBar();
 bar->data(data);
 bar->top(bind(y, _index));
 bar->height(y.band());
 bar->left(0);
 bar->width(x);

</source>

<source lang="javascript"> // The value label. bar.anchor("right").add(pv.Label)

   .textStyle("white")
   .text(function(d) d.toFixed(1));

</source>

<source lang="cpp">

 // The value label.
 Label* label = bar->anchor("right")->addLabel();
 label->textStyle(vtkColor4d(1, 1, 1, 1));
 label->text(bind(toFixed, _d, 1));

</source>

<source lang="javascript"> // The variable label. bar.anchor("left").add(pv.Label)

   .textMargin(5)
   .textAlign("right")
   .text(function() "ABCDEFGHIJK".charAt(this.index));

</source>

<source lang="cpp">

 // The variable label.
 Label* label2 = bar->anchor("left")->addLabel();
 label2->textMargin(5);
 label2->textAlign(vtkStdString("right"));
 label2->text(bind(charAt, vtkStdString("ABCDEFGHIJK"), _index));

</source>

<source lang="javascript"> // X-axis ticks. vis.add(pv.Rule)

   .data(x.ticks(5))
   .left(x)
   .strokeStyle(function(d) d ? "rgba(255,255,255,.3)" : "#000")
 .add(pv.Rule)
   .bottom(0)
   .height(5)
   .strokeStyle("#000")
 .anchor("bottom").add(pv.Label)
   .text(x.tickFormat);

</source>

<source lang="cpp">

 // X-axis ticks.
 Rule* rule = vis.addRule();
 rule->data(x.ticks(5));
 rule->left(x);
 rule->strokeStyle(if_then_else_return(_d[0] > 0, vtkColor4d(1, 1, 1, 0.3), vtkColor4d(0, 0, 0, 1)));
 Rule* rule2 = rule->addRule();
 rule2->bottom(0);
 rule2->height(5);
 rule2->strokeStyle(vtkColor4d(0, 0, 0, 1));
 Label* l = rule2->anchor("bottom")->addLabel();
 l->text(bind(toFixed, _d, 1));

</source>

<source lang="javascript"> // Render the scene. vis.render(); </source>

<source lang="cpp"> // Render the scene. vis.render(); </source>

ProtovisBarChart.png MarksBarChart.png

Fleshing Out the vtkMark API

The fundamental type would be vtkMark, the superclass of all mark types. Its interface would define how programmers would work with all marks in VTK. The following sections enumerate some possible use cases with code snippets showing what functionality the feature would allow.

Possible Supported Parameter Types

Description Example Code
Basic types (double, int, string, vtkVariant) <source lang="cpp">

vtkDotMark* m = vtkDotMark::New(); m->SetParameter("size", 10); </source>

Data object <source lang="cpp">

vtkDirectedGraph* g = vtkDirectedGraph::New(); //... vtkDotMark* m = vtkDotMark::New(); m->SetParameter("data", g); </source>

Pipeline output port <source lang="cpp">

vtkRandomGraphSource* s = vtkRandomGraphSource::New(); //... vtkDotMark* m = vtkDotMark::New(); m->SetParameter("data", s->GetOutputPort()); </source>

vtkArray <source lang="cpp">

vtkDenseArray<double>* a = vtkDenseArray<double>::New(); //... vtkDotMark* m = vtkDotMark::New(); m->SetParameter("size", a); </source>

vtkAbstractArray <source lang="cpp">

vtkDoubleArray* a = vtkDoubleArray::New(); //... vtkDotMark* m = vtkDotMark::New(); m->SetParameter("size", a); </source>

Data object + field type + array name <source lang="cpp">

vtkTable* t = vtkTable::New(); //... vtkDotMark* m = vtkDotMark::New(); m->SetParameter("size", t, vtkDataObject::ROW, "columnName"); </source>

Data object + field type + array name + component index <source lang="cpp">

vtkTable* t = vtkTable::New(); vtkDoubleArray* loc = vtkDoubleArray::New(); loc->SetNumberOfComponents(2); //... vtkDotMark* m = vtkDotMark::New(); m->SetParameter("left", t, vtkDataObject::ROW, "location", 0); m->SetParameter("bottom", t, vtkDataObject::ROW, "location", 1); </source>

Function pointer <source lang="cpp">

double MySize(vtkMark* m, int i) { return 10*i; } //... vtkDotMark* m = vtkDotMark::New(); m->SetParameter("size", &MySize); </source>

Functor (i.e. struct type with operator()) - requires SetParameter to be templated. <source lang="cpp">

struct MySize {

 double operator()(vtkMark* m, int i) { return 10*i; }

} //... vtkDotMark* m = vtkDotMark::New(); m->SetParameter("size", MySize()); </source>

Lambda function (boost::lambda)
Parameter strategies <source lang="cpp">

class vtkDoubleParameter {

 virtual double Get(vtkMark* m, int i) = 0;

}

class MySize : public vtkDoubleParameter { protected:

 double Get(vtkMark* m, int i) { return 10*i; }

} //... vtkDotMark* m = vtkDotMark::New(); m->SetParameter("size", MySize()); </source>

Override virtual methods in mark <source lang="cpp">

class vtkDotMark : public vtkMark { protected:

 virtual double GetSize(int i) { return 10; }

}

class MyMark : public vtkDotMark { protected:

 double GetSize(int i) { return 10*i; }

} //... MyMark* m = MyMark::New(); </source>

Inherit from parent mark <source lang="cpp">

vtkDotMark* parent = vtkDotMark::New(); parent->SetParameter("size", 10); vtkDotMark* child = vtkDotMark::New(); parent->Add(child); // Child has size 10 </source>


Possible Parameter Storage and Access

Named member variables

<source lang="cpp"> class vtkDotMark { public:

 ParamType GetSize() { return this->Size; }
 void SetSize(ParamType p) { this->Size = p; }

private:

 ParamType Size;

} </source>

Named member variables with import/export to name/value map

<source lang="cpp"> class vtkMark { public:

 ParamType GetParameter(string key)
 { this->ExportSettings()->GetParameter(key); }
 void SetParameter(string key, ParamType p)
 { this->ImportSettings(this->ExportSettings()->SetParameter(key, p)); }
 virtual void ImportSettings(vtkSettings* s) { }
 virtual vtkSettings* ExportSettings() { return vtkSettings::New(); }

}

class vtkDotMark { public:

 ParamType GetSize() { return this->Size; }
 void SetSize(ParamType p) { this->Size = p; }
 virtual vtkSettings* ExportSettings()
 { return this->Parent->ExportSettings()->SetParameter("size", this->Size); }
 virutal void ImportSettings(vtkSettings* s)
 { this->Size = s->GetParameter("size"); }

private:

 ParamType Size;

} </source>

Generic name/value map

<source lang="cpp"> class vtkMark { public:

 ParamType GetParameter(string key)
 { return this->Parameters[key].Valid ? this->Parameters[key] : this->Parent->GetParameter(key); }
 void SetParameter(string key, ParamType p)
 { this->Parameters[key] = p; }

private:

 map<string, ParamType> Parameters;

} </source>

Generic name/value map with setter/getter syntactic sugar for discoverability

<source lang="cpp"> class vtkDotMark : public vtkMark { public:

 ParamType GetSize() { return this->GetParameter("size"); }
 void SetSize(ParamType p) { this->SetParameter("size", p); }

} </source>

vtkInformation/value map

The idea here is that valid parameter names/types/bounds are queryable at runtime, instead of in an opaque map. <source lang="cpp"> class vtkMark { public:

 // Keys to describe parameters
 static vtkInformationIntegerKey* PARAMETER_TYPE();
 static vtkInformationStringKey* PARAMETER_NAME();
 static vtkInformationIntegerKey* PARAMETER_NUMBER_OF_COMPONENTS();
 static vtkInformationIntegerVectorKey* PARAMETER_INTEGER_BOUNDS();
 static vtkInformationDoubleVectorKey* PARAMETER_REAL_BOUNDS();
 int GetNumberOfParameters() { return this->ParameterInfo->size(); }
 vtkInformation* GetParameterInfo(int i) { return this->ParameterInfo[i]; }
 int GetParameterHandle(const char* name)
 { /* search ParameterInfo for name, return index */ }
 void SetParameter(int handle, ParamType p)
 { this->ParameterValues[handle] = p; }

protected:

 virtual void SetupParameters() = 0;
 vector<vtkInformation*> ParameterInfo;
 vector<ParamType> ParameterValues;

}

class vtkDotMark : public vtkMark { protected:

 void SetupParameters()
 {
   vtkInformation* sizeInfo = vtkInformation::New();
   double sizeBounds[2] = { 0., VTK_DOUBLE_MAX };
   sizeInfo->Set( vtkPointMark::PARAMETER_NAME(), "size" );
   sizeInfo->Set( vtkPointMark::PARAMETER_TYPE(), VTK_DOUBLE );
   sizeInfo->Set( vtkPointMark::PARAMETER_NUMBER_OF_COMPONENTS(), 1 );
   sizeInfo->Set( vtkPointMark::PARAMETER_REAL_BOUNDS(), sizeBounds, 2 );
   this->ParameterInfo.push_back(sizeInfo);
   this->ParameterValues.push_back(10);
 }

} </source>

Possible Other Features

  • Declarative API
  • Iterator support