#include "sp-mesh-array.h"

#include "sp-mesh-gradient.h"

#include "sp-mesh-row.h"

#include "sp-mesh-patch.h"

#include "sp-stop.h"

#include "preferences.h"

#include "sp-ellipse.h"

#include "sp-star.h"

#include "svg/css-ostringstream.h"

#include "display/drawing.h"

#include "display/drawing-context.h"

#include "display/cairo-utils.h"

#include "document.h"

#include "sp-root.h"

#include "style.h"

#include "svg/svg-color.h"

#include "2geom/line.h"

#include "xml/repr.h"

#include <cmath>

#include <algorithm>

enum { ROW, COL };

void swap_p( Geom::Point *p1, Geom::Point *p2 ) {

Geom::Point temp = *p1;

*p1 = *p2;

*p2 = temp;

};

SPMeshPatchI::SPMeshPatchI( std::vector<std::vector< SPMeshNode* > > * n, int r, int c ) {

nodes = n;

row = r*3; // Convert from patch array to node array

col = c*3;

uint i = 0;

if( row != 0 ) i = 1;

for( ; i < 4; ++i ) {

if( nodes->size() < row+i+1 ) {

std::vector< SPMeshNode* > row;

nodes->push_back( row );

}

uint j = 0;

if( col != 0 ) j = 1;

for( ; j < 4; ++j ) {

if( (*nodes)[row+i].size() < col+j+1 ){

SPMeshNode* node = new SPMeshNode;

// Ensure all nodes know their type.

node->node_type = MG_NODE_TYPE_HANDLE;

if( (i == 0 || i == 3) && (j == 0 || j == 3 ) ) node->node_type = MG_NODE_TYPE_CORNER;

if( (i == 1 || i == 2) && (j == 1 || j == 2 ) ) node->node_type = MG_NODE_TYPE_TENSOR;

(*nodes)[row+i].push_back( node );

}

}

}

}

Geom::Point SPMeshPatchI::getPoint( uint s, uint pt ) {

assert( s < 4 );

assert( pt < 4 );

Geom::Point p;

switch ( s ) {

case 0:

p = (*nodes)[ row ][ col+pt ]->p;

break;

case 1:

p = (*nodes)[ row+pt ][ col+3 ]->p;

break;

case 2:

p = (*nodes)[ row+3 ][ col+3-pt ]->p;

break;

case 3:

p = (*nodes)[ row+3-pt ][ col ]->p;

break;

}

return p;

};

std::vector< Geom::Point > SPMeshPatchI::getPointsForSide( uint i ) {

assert( i < 4 );

std::vector< Geom::Point> points;

points.push_back( getPoint( i, 0 ) );

points.push_back( getPoint( i, 1 ) );

points.push_back( getPoint( i, 2 ) );

points.push_back( getPoint( i, 3 ) );

return points;

};

void SPMeshPatchI::setPoint( uint s, uint pt, Geom::Point p, bool set ) {

assert( s < 4 );

assert( pt < 4 );

NodeType node_type = MG_NODE_TYPE_CORNER;

if( pt == 1 || pt == 2 ) node_type = MG_NODE_TYPE_HANDLE;

// std::cout << "SPMeshPatchI::setPoint: s: " << s

// << " pt: " << pt

// << " p: " << p

// << " node_type: " << node_type

// << " set: " << set

// << " row: " << row

// << " col: " << col << std::endl;

switch ( s ) {

case 0:

(*nodes)[ row ][ col+pt ]->p = p;

(*nodes)[ row ][ col+pt ]->set = set;

(*nodes)[ row ][ col+pt ]->node_type = node_type;

break;

case 1:

(*nodes)[ row+pt ][ col+3 ]->p = p;

(*nodes)[ row+pt ][ col+3 ]->set = set;

(*nodes)[ row+pt ][ col+3 ]->node_type = node_type;

break;

case 2:

(*nodes)[ row+3 ][ col+3-pt ]->p = p;

(*nodes)[ row+3 ][ col+3-pt ]->set = set;

(*nodes)[ row+3 ][ col+3-pt ]->node_type = node_type;

break;

case 3:

(*nodes)[ row+3-pt ][ col ]->p = p;

(*nodes)[ row+3-pt ][ col ]->set = set;

(*nodes)[ row+3-pt ][ col ]->node_type = node_type;

break;

}

};

gchar SPMeshPatchI::getPathType( uint s ) {

assert( s < 4 );

gchar type = 'x';

switch ( s ) {

case 0:

type = (*nodes)[ row ][ col+1 ]->path_type;

break;

case 1:

type = (*nodes)[ row+1 ][ col+3 ]->path_type;

break;

case 2:

type = (*nodes)[ row+3 ][ col+2 ]->path_type;

break;

case 3:

type = (*nodes)[ row+2 ][ col ]->path_type;

break;

}

return type;

};

void SPMeshPatchI::setPathType( uint s, gchar t ) {

assert( s < 4 );

switch ( s ) {

case 0:

(*nodes)[ row ][ col+1 ]->path_type = t;

(*nodes)[ row ][ col+2 ]->path_type = t;

break;

case 1:

(*nodes)[ row+1 ][ col+3 ]->path_type = t;

(*nodes)[ row+2 ][ col+3 ]->path_type = t;

break;

case 2:

(*nodes)[ row+3 ][ col+1 ]->path_type = t;

(*nodes)[ row+3 ][ col+2 ]->path_type = t;

break;

case 3:

(*nodes)[ row+1 ][ col ]->path_type = t;

(*nodes)[ row+2 ][ col ]->path_type = t;

break;

}

};

void SPMeshPatchI::setTensorPoint( uint i, Geom::Point p ) {

assert( i < 4 );

switch ( i ) {

case 0:

(*nodes)[ row + 1 ][ col + 1 ]->p = p;

(*nodes)[ row + 1 ][ col + 1 ]->set = true;

(*nodes)[ row + 1 ][ col + 1 ]->node_type = MG_NODE_TYPE_TENSOR;

break;

case 1:

(*nodes)[ row + 1 ][ col + 2 ]->p = p;

(*nodes)[ row + 1 ][ col + 2 ]->set = true;

(*nodes)[ row + 1 ][ col + 2 ]->node_type = MG_NODE_TYPE_TENSOR;

break;

case 2:

(*nodes)[ row + 2 ][ col + 2 ]->p = p;

(*nodes)[ row + 2 ][ col + 2 ]->set = true;

(*nodes)[ row + 2 ][ col + 2 ]->node_type = MG_NODE_TYPE_TENSOR;

break;

case 3:

(*nodes)[ row + 2 ][ col + 1 ]->p = p;

(*nodes)[ row + 2 ][ col + 1 ]->set = true;

(*nodes)[ row + 2 ][ col + 1 ]->node_type = MG_NODE_TYPE_TENSOR;

break;

}

}

bool SPMeshPatchI::tensorIsSet() {

for( uint i = 0; i < 4; ++i ) {

if( tensorIsSet( i ) ) {

return true;

}

}

return false;

}

bool SPMeshPatchI::tensorIsSet( uint i ) {

assert( i < 4 );

bool set = false;

switch ( i ) {

case 0:

set = (*nodes)[ row + 1 ][ col + 1 ]->set;

break;

case 1:

set = (*nodes)[ row + 1 ][ col + 2 ]->set;

break;

case 2:

set = (*nodes)[ row + 2 ][ col + 2 ]->set;

break;

case 3:

set = (*nodes)[ row + 2 ][ col + 1 ]->set;

break;

}

return set;

}

Geom::Point SPMeshPatchI::getTensorPoint( uint k ) {

assert( k < 4 );

uint i, j;

switch ( k ) {

case 0:

i = 1; j = 1;

break;

case 1:

i = 1; j = 2;

break;

case 2:

i = 2; j = 2;

break;

case 3:

i = 2; j = 1;

break;

}

Geom::Point p;

if( (*nodes)[ row + i ][ col + j ]->set ) {

p = (*nodes)[ row + i ][ col + j ]->p;

} else {

p = coonsTensorPoint( k );

}

return p;

}

Geom::Point SPMeshPatchI::coonsTensorPoint( uint i ) {

Geom::Point t;

Geom::Point p[4][4]; // Points in PDF notation

p[0][0] = getPoint( 0, 0 );

p[0][1] = getPoint( 0, 1 );

p[0][2] = getPoint( 0, 2 );

p[0][3] = getPoint( 0, 3 );

p[1][0] = getPoint( 3, 2 );

p[1][3] = getPoint( 1, 1 );

p[2][0] = getPoint( 3, 1 );

p[2][3] = getPoint( 1, 2 );

p[3][0] = getPoint( 2, 3 );

p[3][1] = getPoint( 2, 2 );

p[3][2] = getPoint( 2, 1 );

p[3][3] = getPoint( 2, 0 );

switch ( i ) {

case 0:

t = ( -4.0 * p[0][0] +

6.0 * ( p[0][1] + p[1][0] ) +

-2.0 * ( p[0][3] + p[3][0] ) +

3.0 * ( p[3][1] + p[1][3] ) +

-1.0 * p[3][3] ) / 9.0;

break;

case 1:

t = ( -4.0 * p[0][3] +

6.0 * ( p[0][2] + p[1][3] ) +

-2.0 * ( p[0][0] + p[3][3] ) +

3.0 * ( p[3][2] + p[1][0] ) +

-1.0 * p[3][0] ) / 9.0;

break;

case 2:

t = ( -4.0 * p[3][3] +

6.0 * ( p[3][2] + p[2][3] ) +

-2.0 * ( p[3][0] + p[0][3] ) +

3.0 * ( p[0][2] + p[2][0] ) +

-1.0 * p[0][0] ) / 9.0;

break;

case 3:

t = ( -4.0 * p[3][0] +

6.0 * ( p[3][1] + p[2][0] ) +

-2.0 * ( p[3][3] + p[0][0] ) +

3.0 * ( p[0][1] + p[2][3] ) +

-1.0 * p[0][3] ) / 9.0;

break;

default:

g_warning( "Impossible!" );

}

return t;

}

void SPMeshPatchI::updateNodes() {

// std::cout << "SPMeshPatchI::updateNodes: " << row << "," << col << std::endl;

// Handles first (tensors require update handles).

for( uint i = 0; i < 4; ++i ) {

for( uint j = 0; j < 4; ++j ) {

if( (*nodes)[ row + i ][ col + j ]->set == false ) {

if( (*nodes)[ row + i ][ col + j ]->node_type == MG_NODE_TYPE_HANDLE ) {

// If a handle is not set it is because the side is a line.

// Set node points 1/3 of the way between corners.

if( i == 0 || i == 3 ) {

Geom::Point p0 = ( (*nodes)[ row + i ][ col ]->p );

Geom::Point p3 = ( (*nodes)[ row + i ][ col + 3 ]->p );

Geom::Point dp = (p3 - p0)/3.0;

if( j == 2 ) dp *= 2.0;

(*nodes)[ row + i ][ col + j ]->p = p0 + dp;

}

if( j == 0 || j == 3 ) {

Geom::Point p0 = ( (*nodes)[ row ][ col + j ]->p );

Geom::Point p3 = ( (*nodes)[ row + 3 ][ col + j ]->p );

Geom::Point dp = (p3 - p0)/3.0;

if( i == 2 ) dp *= 2.0;

(*nodes)[ row + i ][ col + j ]->p = p0 + dp;

}

}

}

}

}

// Update tensor nodes

for( uint i = 1; i < 3; ++i ) {

for( uint j = 1; j < 3; ++j ) {

if( (*nodes)[ row + i ][ col + j ]->set == false ) {

(*nodes)[ row + i ][ col + j ]->node_type = MG_NODE_TYPE_TENSOR;

uint t = 0;

if( i == 1 && j == 2 ) t = 1;

if( i == 2 && j == 2 ) t = 2;

if( i == 2 && j == 1 ) t = 3;

(*nodes)[ row + i ][ col + j ]->p = coonsTensorPoint( t );

// std::cout << "Update node: " << i << ", " << j << " " << coonsTensorPoint( t ) << std::endl;

}

}

}

}

SPColor SPMeshPatchI::getColor( uint i ) {

assert( i < 4 );

SPColor color;

switch ( i ) {

case 0:

color = (*nodes)[ row ][ col ]->color;

break;

case 1:

color = (*nodes)[ row ][ col+3 ]->color;

break;

case 2:

color = (*nodes)[ row+3 ][ col+3 ]->color;

break;

case 3:

color = (*nodes)[ row+3 ][ col ]->color;

break;

}

return color;

};

void SPMeshPatchI::setColor( uint i, SPColor color ) {

assert( i < 4 );

switch ( i ) {

case 0:

(*nodes)[ row ][ col ]->color = color;

break;

case 1:

(*nodes)[ row ][ col+3 ]->color = color;

break;

case 2:

(*nodes)[ row+3 ][ col+3 ]->color = color;

break;

case 3:

(*nodes)[ row+3 ][ col ]->color = color;

break;

}

};

gdouble SPMeshPatchI::getOpacity( uint i ) {

assert( i < 4 );

gdouble opacity;

switch ( i ) {

case 0:

opacity = (*nodes)[ row ][ col ]->opacity;

break;

case 1:

opacity = (*nodes)[ row ][ col+3 ]->opacity;

break;

case 2:

opacity = (*nodes)[ row+3 ][ col+3 ]->opacity;

break;

case 3:

opacity = (*nodes)[ row+3 ][ col ]->opacity;

break;

}

return opacity;

};

void SPMeshPatchI::setOpacity( uint i, gdouble opacity ) {

assert( i < 4 );

switch ( i ) {

case 0:

(*nodes)[ row ][ col ]->opacity = opacity;

break;

case 1:

(*nodes)[ row ][ col+3 ]->opacity = opacity;

break;

case 2:

(*nodes)[ row+3 ][ col+3 ]->opacity = opacity;

break;

case 3:

(*nodes)[ row+3 ][ col ]->opacity = opacity;

break;

}

};

SPMeshNodeArray::SPMeshNodeArray( SPMeshGradient *mg ) {

read( mg );

};

void SPMeshNodeArray::read( SPMeshGradient *mg_in ) {

mg = mg_in;

clear();

Geom::Point current_p( mg->x.computed, mg->y.computed );

// std::cout << "SPMeshNodeArray::read: p: " << current_p << std::endl;

uint max_column = 0;

uint irow = 0; // Corresponds to top of patch being read in.

for ( SPObject *ro = mg->firstChild() ; ro ; ro = ro->getNext() ) {

if (SP_IS_MESHROW(ro)) {

uint icolumn = 0; // Corresponds to left of patch being read in.

for ( SPObject *po = ro->firstChild() ; po ; po = po->getNext() ) {

if (SP_IS_MESHPATCH(po)) {

SPMeshPatch *patch = SP_MESHPATCH(po);

// std::cout << "SPMeshNodeArray::read: row size: " << nodes.size() << std::endl;

SPMeshPatchI new_patch( &nodes, irow, icolumn ); // Adds new nodes.

// std::cout << " after: " << nodes.size() << std::endl;

gint istop = 0;

// Only 'top' side defined for first row.

if( irow != 0 ) ++istop;

for ( SPObject *so = po->firstChild() ; so ; so = so->getNext() ) {

if (SP_IS_STOP(so)) {

if( istop > 3 ) {

// std::cout << " Mesh Gradient: Too many stops: " << istop << std::endl;

break;

}

SPStop *stop = SP_STOP(so);

// Handle top of first row.

if( istop == 0 && icolumn == 0 ) {

// First patch in mesh.

new_patch.setPoint( 0, 0, current_p );

}

// First point is always already defined by previous side (stop).

current_p = new_patch.getPoint( istop, 0 );

// If side closes patch, then we read one less point.

bool closed = false;

if( icolumn == 0 && istop == 3 ) closed = true;

if( icolumn > 0 && istop == 2 ) closed = true;

// Copy path and then replace commas by spaces so we can use stringstream to parse

std::string path_string = *(stop->path_string);

std::replace(path_string.begin(),path_string.end(),',',' ');

// std::cout << " path_string: " << path_string << std::endl;

// std::cout << " current_p: " << current_p << std::endl;

std::stringstream os( path_string );

// Determine type of path

char path_type;

os >> path_type;

new_patch.setPathType( istop, path_type );

gdouble x, y;

Geom::Point p, dp;

uint max;

switch ( path_type ) {

case 'l':

if( !closed ) {

os >> x >> y;

if( !os.fail() ) {

dp = Geom::Point( x, y );

new_patch.setPoint( istop, 3, current_p + dp );

} else {

std::cout << "Failed to read l" << std::endl;

}

}

// To facilitate some side operations, set handles to 1/3 and

// 2/3 distance between corner points but flag as unset.

p = new_patch.getPoint( istop, 3 );

dp = (p - current_p)/3.0; // Calculate since may not be set if closed.

// std::cout << " istop: " << istop

// << " dp: " << dp

// << " p: " << p

// << " current_p: " << current_p

// << std::endl;

new_patch.setPoint( istop, 1, current_p + dp, false );

new_patch.setPoint( istop, 2, current_p + 2.0 * dp, false );

break;

case 'L':

if( !closed ) {

os >> x >> y;

if( !os.fail() ) {

p = Geom::Point( x, y );

new_patch.setPoint( istop, 3, p );

} else {

std::cout << "Failed to read L" << std::endl;

}

}

// To facilitate some side operations, set handles to 1/3 and

// 2/3 distance between corner points but flag as unset.

p = new_patch.getPoint( istop, 3 );

dp = (p - current_p)/3.0;

new_patch.setPoint( istop, 1, current_p + dp, false );

new_patch.setPoint( istop, 2, current_p + 2.0 * dp, false );

break;

case 'c':

max = 4;

if( closed ) max = 3;

for( uint i = 1; i < max; ++i ) {

os >> x >> y;

if( !os.fail() ) {

p = Geom::Point( x, y );

p += current_p;

new_patch.setPoint( istop, i, p );

} else {

std::cout << "Failed to read c: " << i << std::endl;

}

}

break;

case 'C':

max = 4;

if( closed ) max = 3;

for( uint i = 1; i < max; ++i ) {

os >> x >> y;

if( !os.fail() ) {

p = Geom::Point( x, y );

new_patch.setPoint( istop, i, p );

} else {

std::cout << "Failed to read C: " << i << std::endl;

}

}

break;

default:

// should not reach

std::cout << "Path Error: unhandled path type: " << path_type << std::endl;

}

current_p = new_patch.getPoint( istop, 3 );

// Color

if( (istop == 0 && irow == 0 && icolumn > 0) || (istop == 1 && irow > 0 ) ) {

// skip

} else {

SPColor color = stop->getEffectiveColor();

double opacity = stop->opacity;

new_patch.setColor( istop, color );

new_patch.setOpacity( istop, opacity );

}

}

++istop;

} // Loop over stops

// Read in tensor string after stops since tensor nodes defined relative to corner nodes.

// Copy string and then replace commas by spaces so we can use stringstream to parse XXXX

if( patch->tensor_string ) {

std::string tensor_string = *(patch->tensor_string);

std::replace(tensor_string.begin(),tensor_string.end(),',',' ');

// std::cout << " tensor_string: " << tensor_string << std::endl;

std::stringstream os( tensor_string );

for( uint i = 0; i < 4; ++i ) {

double x = 0.0;

double y = 0.0;

os >> x >> y;

if( !os.fail() ) {

new_patch.setTensorPoint( i, new_patch.getPoint( i, 0 ) + Geom::Point( x, y ) );

} else {

std::cout << "Failed to read p: " << i << std::endl;

break;

}

}

}

}

++icolumn;

if( max_column < icolumn ) max_column = icolumn;

}

}

++irow;

}

// Insure we have a true array.

for( uint i = 0; i < nodes.size(); ++i ) {

nodes[ i ].resize( max_column * 3 + 1 );

}

// Set node edge.

for( uint i = 0; i < nodes.size(); ++i ) {

for( uint j = 0; j < nodes[i].size(); ++j ) {

nodes[i][j]->node_edge = MG_NODE_EDGE_NONE;

if( i == 0 ) nodes[i][j]->node_edge |= MG_NODE_EDGE_TOP;

if( i == nodes.size() - 1 ) nodes[i][j]->node_edge |= MG_NODE_EDGE_BOTTOM;

if( j == 0 ) nodes[i][j]->node_edge |= MG_NODE_EDGE_RIGHT;

if( j == nodes[i].size() - 1 ) nodes[i][j]->node_edge |= MG_NODE_EDGE_LEFT;

}

}

// std::cout << "SPMeshNodeArray::Read: result:" << std::endl;

// print();

drag_valid = false;

built = true;

};

void SPMeshNodeArray::write( SPMeshGradient *mg ) {

// std::cout << "SPMeshNodeArray::write: entrance:" << std::endl;

// print();

using Geom::X;

using Geom::Y;

// First we must delete reprs for old mesh rows and patches.

GSList *descendant_reprs = NULL;

GSList *descendant_objects = NULL;

for ( SPObject *row = mg->firstChild(); row; row = row->getNext() ) {

descendant_reprs = g_slist_prepend (descendant_reprs, row->getRepr());

descendant_objects = g_slist_prepend (descendant_objects, row );

for ( SPObject *patch = row->firstChild(); patch; patch = patch->getNext() ) {

descendant_reprs = g_slist_prepend (descendant_reprs, patch->getRepr());

descendant_objects = g_slist_prepend (descendant_objects, patch );

for ( SPObject *stop = patch->firstChild(); stop; stop = stop->getNext() ) {

descendant_reprs = g_slist_prepend (descendant_reprs, stop->getRepr());

descendant_objects = g_slist_prepend (descendant_objects, stop );

}

}

}

for ( GSList *i = descendant_objects; i != NULL; i = i->next ) {

SPObject *descendant = SP_OBJECT (i->data);

descendant->deleteObject();

}

for ( GSList *i = descendant_reprs; i != NULL; i = i->next ) {

Inkscape::XML::Node *repr = (Inkscape::XML::Node *) i->data;

sp_repr_unparent( repr );

}

// Now we build new reprs

Inkscape::XML::Node *mesh = mg->getRepr();

SPMeshNodeArray* array = &(mg->array);

SPMeshPatchI patch0( &(array->nodes), 0, 0 );

Geom::Point current_p = patch0.getPoint( 0, 0 ); // Side 0, point 0

sp_repr_set_svg_double( mesh, "x", current_p[X] );

sp_repr_set_svg_double( mesh, "y", current_p[Y] );

Geom::Point current_p2( mg->x.computed, mg->y.computed );

Inkscape::XML::Document *xml_doc = mesh->document();

uint rows = array->patch_rows();

for( uint i = 0; i < rows; ++i ) {

// Write row

Inkscape::XML::Node *row = xml_doc->createElement("svg:meshRow");

mesh->appendChild( row ); // No attributes

uint columns = array->patch_columns();

for( uint j = 0; j < columns; ++j ) {

// Write patch

Inkscape::XML::Node *patch = xml_doc->createElement("svg:meshPatch");

SPMeshPatchI patchi( &(array->nodes), i, j );

// Add tensor

if( patchi.tensorIsSet() ) {

std::stringstream is;

for( uint k = 0; k < 4; ++k ) {

Geom::Point p = patchi.getTensorPoint( k ) - patchi.getPoint( k, 0 );

is << p[X] << "," << p[Y];

if( k < 3 ) is << " ";

}

patch->setAttribute("tensor", is.str().c_str());

// std::cout << " SPMeshNodeArray::write: tensor: " << is.str() << std::endl;

}

row->appendChild( patch );

// Write sides

for( uint k = 0; k < 4; ++k ) {

// Only first row has top stop

if( k == 0 && i != 0 ) continue;

// Only first column has left stop

if( k == 3 && j != 0 ) continue;

Inkscape::XML::Node *stop = xml_doc->createElement("svg:stop");

// Add path

std::stringstream is;

char path_type = patchi.getPathType( k );

is << path_type;

std::vector< Geom::Point> p = patchi.getPointsForSide( k );

current_p = patchi.getPoint( k, 0 );

switch ( path_type ) {

case 'l':

is << " "

<< ( p[3][X] - current_p[X] ) << ","

<< ( p[3][Y] - current_p[Y] );

break;

case 'L':

is << " "

<< p[3][X] << ","

<< p[3][Y];

break;

case 'c':

is << " "

<< ( p[1][X] - current_p[X] ) << ","

<< ( p[1][Y] - current_p[Y] ) << " "

<< ( p[2][X] - current_p[X] ) << ","

<< ( p[2][Y] - current_p[Y] ) << " "

<< ( p[3][X] - current_p[X] ) << ","

<< ( p[3][Y] - current_p[Y] );

break;

case 'C':

is << " "

<< p[1][X] << ","

<< p[1][Y] << " "

<< p[2][X] << ","

<< p[2][Y] << " "

<< p[3][X] << ","

<< p[3][Y];

break;

case 'z':

case 'Z':

std::cout << "sp_meshgradient_repr_write: bad path type" << path_type << std::endl;

break;

default:

std::cout << "sp_meshgradient_repr_write: unhandled path type" << path_type << std::endl;

}

stop->setAttribute("path", is.str().c_str());

// std::cout << "SPMeshNodeArray::write: path: " << is.str().c_str() << std::endl;

// Add stop-color

if( ( k == 0 && i == 0 && j == 0 ) ||

( k == 1 && i == 0 ) ||

( k == 2 ) ||

( k == 3 && j == 0 ) ) {

// Why are we setting attribute and not style?

//stop->setAttribute("stop-color", patchi.getColor(k).toString().c_str() );

//stop->setAttribute("stop-opacity", patchi.getOpacity(k) );

Inkscape::CSSOStringStream os;

os << "stop-color:" << patchi.getColor(k).toString() << ";stop-opacity:" << patchi.getOpacity(k);

stop->setAttribute("style", os.str().c_str());

}

patch->appendChild( stop );

}

}

}

}

SPColor default_color( SPItem *item ) {

// Set initial color to the color of the object before adding the mesh.

// This is a bit tricky as at the moment, a "vector" gradient is created

// before reaching here, replacing the original solid color. But the first

// stop will be that of the original object color.

SPColor color( 0.5, 0.0, 0.5 );

if ( item->style ) {

SPStyle const &style = *(item->style);

SPIPaint const &paint = ( style.fill ); // Could pick between style.fill/style.stroke

if ( paint.isColor() ) {

color = paint.value.color;

} else if ( paint.isPaintserver() ) {

SPObject const *server = style.getFillPaintServer();

if ( SP_IS_GRADIENT(server) ) {

SPGradient *vector = SP_GRADIENT( server )->getVector();

SPStop *firstStop = (vector) ?

vector->getFirstStop() : SP_GRADIENT( server )->getFirstStop();

if ( firstStop ) {

if (firstStop->currentColor) {

Glib::ustring str = firstStop->getStyleProperty("color", NULL);

if( !str.empty() ) {

guint32 rgb = sp_svg_read_color( str.c_str(), 0 );

color = SPColor( rgb );

}

} else {

color = firstStop->specified_color;

}

}

}

}

} else {

std::cout << " SPMeshNodeArray: No style" << std::endl;

}

return color;

}

void SPMeshNodeArray::create( SPMeshGradient *mg, SPItem *item, Geom::OptRect bbox ) {

// std::cout << "SPMeshNodeArray::create: Entrance" << std::endl;

if( !bbox ) {

// Set default size to bounding box if size not given.

std::cout << "SPMeshNodeArray::create(): bbox empty" << std::endl;

Geom::OptRect bbox = item->geometricBounds();

}

if( !bbox ) {

std::cout << "SPMeshNodeArray::create: ERROR: No bounding box!" << std::endl;

return;

}

Geom::Coord const width = bbox->dimensions()[Geom::X];

Geom::Coord const height = bbox->dimensions()[Geom::Y];

Geom::Point center = bbox->midpoint();

// Must keep repr and array in sync. We have two choices:

// Build the repr first and the "read" it.

// Construct the array and the "write" it.

// We'll do the second.

// Remove any existing mesh. We could chose to simply scale an existing mesh...

//clear();

// We get called twice when a new mesh is created...WHY?

// return if we've already constructed the mesh.

if( nodes.size() != 0 ) return;

// Get default color

SPColor color = default_color( item );

// Get preferences

Inkscape::Preferences *prefs = Inkscape::Preferences::get();

uint prows = prefs->getInt("/tools/mesh/mesh_rows", 1);

uint pcols = prefs->getInt("/tools/mesh/mesh_cols", 1);

SPGradientMeshType mesh_type =

(SPGradientMeshType) prefs->getInt("/tools/mesh/mesh_type", SP_GRADIENT_MESH_TYPE_NORMAL);

if( mesh_type == SP_GRADIENT_MESH_TYPE_CONICAL ) {

// Conical gradient.. for any shape/path using geometric bounding box.

gdouble rx = width/2.0;

gdouble ry = height/2.0;

// Start and end angles

gdouble start = 0.0;

gdouble end = 2.0 * M_PI;

if ( SP_IS_STAR( item ) ) {

// But if it is a star... use star parameters!

SPStar* star = SP_STAR( item );

center = star->center;

rx = star->r[0];

ry = star->r[0];

start = star->arg[0];

end = start + 2.0 * M_PI;

}

if ( SP_IS_ARC( item ) ) {

// For arcs use set start/stop

SPArc* arc = SP_ARC( item );

center[Geom::X] = arc->cx.computed;

center[Geom::Y] = arc->cy.computed;

rx = arc->rx.computed;

ry = arc->ry.computed;

start = arc->start;

end = arc->end;

}

// std::cout << " start: " << start << " end: " << end << std::endl;

// IS THIS NECESSARY?

Inkscape::XML::Node *repr = mg->getRepr();

sp_repr_set_svg_double( repr, "x", center[Geom::X] + rx * cos(start) );

sp_repr_set_svg_double( repr, "y", center[Geom::Y] + ry * sin(start) );

uint sections = pcols;

// If less sections, arc approximation error too great. (Check!)

if( sections < 4 ) sections = 4;

double arc = (end - start) / (double)sections;

// See: http://en.wikipedia.org/wiki/B%C3%A9zier_curve

gdouble kappa = 4.0/3.0 * tan(arc/4.0);

gdouble lenx = rx * kappa;

gdouble leny = ry * kappa;

gdouble s = start;

for( uint i = 0; i < sections; ++i ) {

SPMeshPatchI patch( &nodes, 0, i );

gdouble x0 = center[Geom::X] + rx * cos(s);

gdouble y0 = center[Geom::Y] + ry * sin(s);

gdouble x1 = x0 - lenx * sin(s);

gdouble y1 = y0 + leny * cos(s);

s += arc;

gdouble x3 = center[Geom::X] + rx * cos(s);

gdouble y3 = center[Geom::Y] + ry * sin(s);

gdouble x2 = x3 + lenx * sin(s);

gdouble y2 = y3 - leny * cos(s);

patch.setPoint( 0, 0, Geom::Point( x0, y0 ) );

patch.setPoint( 0, 1, Geom::Point( x1, y1 ) );

patch.setPoint( 0, 2, Geom::Point( x2, y2 ) );

patch.setPoint( 0, 3, Geom::Point( x3, y3 ) );

patch.setPoint( 2, 0, center );

patch.setPoint( 3, 0, center );

for( uint k = 0; k < 4; ++k ) {

patch.setPathType( k, 'l' );

patch.setColor( k, color );

patch.setOpacity( k, 1.0 );

}

patch.setPathType( 0, 'c' );

// Set handle and tensor nodes.

patch.updateNodes();

}

split_row( 0, prows );

} else {

// Normal grid meshes

if( SP_IS_ARC( item ) ) {

// std::cout << "We've got ourselves an arc!" << std::endl;

SPArc* arc = SP_ARC( item );

center[Geom::X] = arc->cx.computed;

center[Geom::Y] = arc->cy.computed;

gdouble rx = arc->rx.computed;

gdouble ry = arc->ry.computed;

gdouble s = -3.0/2.0 * M_PI_2;

Inkscape::XML::Node *repr = mg->getRepr();

sp_repr_set_svg_double( repr, "x", center[Geom::X] + rx * cos(s) );

sp_repr_set_svg_double( repr, "y", center[Geom::Y] + ry * sin(s) );

gdouble lenx = rx * 4*tan(M_PI_2/4)/3;

gdouble leny = ry * 4*tan(M_PI_2/4)/3;

SPMeshPatchI patch( &nodes, 0, 0 );

for( uint i = 0; i < 4; ++i ) {

gdouble x0 = center[Geom::X] + rx * cos(s);

gdouble y0 = center[Geom::Y] + ry * sin(s);

gdouble x1 = x0 + lenx * cos(s + M_PI_2);

gdouble y1 = y0 + leny * sin(s + M_PI_2);

s += M_PI_2;

gdouble x3 = center[Geom::X] + rx * cos(s);

gdouble y3 = center[Geom::Y] + ry * sin(s);

gdouble x2 = x3 + lenx * cos(s - M_PI_2);

gdouble y2 = y3 + leny * sin(s - M_PI_2);

Geom::Point p1( x1, y1 );

Geom::Point p2( x2, y2 );

Geom::Point p3( x3, y3 );

patch.setPoint( i, 1, p1 );

patch.setPoint( i, 2, p2 );

patch.setPoint( i, 3, p3 );

patch.setPathType( i, 'c' );

patch.setColor( i, color );

patch.setOpacity( i, 1.0 );

}

// Fill out tensor points

patch.updateNodes();

split_row( 0, prows );

split_column( 0, pcols );

// END Arc

} else if ( SP_IS_STAR( item ) ) {

// Do simplest thing... assume star is not rounded or randomized.

// (It should be easy to handle the rounded/randomized cases by making

// the appropriate star class function public.)

SPStar* star = SP_STAR( item );

uint sides = star->sides;

// std::cout << "We've got ourselves an star! Sides: " << sides << std::endl;

Geom::Point p0 = sp_star_get_xy( star, SP_STAR_POINT_KNOT1, 0 );

Inkscape::XML::Node *repr = mg->getRepr();

sp_repr_set_svg_double( repr, "x", p0[Geom::X] );

sp_repr_set_svg_double( repr, "y", p0[Geom::Y] );

for( uint i = 0; i < sides; ++i ) {

if( star->flatsided ) {

SPMeshPatchI patch( &nodes, 0, i );

patch.setPoint( 0, 0, sp_star_get_xy( star, SP_STAR_POINT_KNOT1, i ) );

uint ii = i+1;

if( ii == sides ) ii = 0;

patch.setPoint( 1, 0, sp_star_get_xy( star, SP_STAR_POINT_KNOT1, ii ) );

patch.setPoint( 2, 0, star->center );

patch.setPoint( 3, 0, star->center );

for( uint s = 0; s < 4; ++s ) {

patch.setPathType( s, 'l' );

patch.setColor( s, color );

patch.setOpacity( s, 1.0 );

}

// Set handle and tensor nodes.

patch.updateNodes();

} else {

SPMeshPatchI patch0( &nodes, 0, 2*i );

patch0.setPoint( 0, 0, sp_star_get_xy( star, SP_STAR_POINT_KNOT1, i ) );

patch0.setPoint( 1, 0, sp_star_get_xy( star, SP_STAR_POINT_KNOT2, i ) );

patch0.setPoint( 2, 0, star->center );

patch0.setPoint( 3, 0, star->center );

uint ii = i+1;

if( ii == sides ) ii = 0;

SPMeshPatchI patch1( &nodes, 0, 2*i+1 );

patch1.setPoint( 0, 0, sp_star_get_xy( star, SP_STAR_POINT_KNOT2, i ) );

patch1.setPoint( 1, 0, sp_star_get_xy( star, SP_STAR_POINT_KNOT1, ii ) );

patch1.setPoint( 2, 0, star->center );

patch1.setPoint( 3, 0, star->center );

for( uint s = 0; s < 4; ++s ) {

patch0.setPathType( s, 'l' );

patch0.setColor( s, color );

patch0.setOpacity( s, 1.0 );

patch1.setPathType( s, 'l' );

patch1.setColor( s, color );

patch1.setOpacity( s, 1.0 );

}

// Set handle and tensor nodes.

patch0.updateNodes();

patch1.updateNodes();

}

}

//print();

split_row( 0, prows );

//split_column( 0, pcols );

} else {

// Generic

Inkscape::XML::Node *repr = mg->getRepr();

sp_repr_set_svg_double(repr, "x", bbox->min()[Geom::X]);

sp_repr_set_svg_double(repr, "y", bbox->min()[Geom::Y]);

// Get node array size

uint nrows = prows * 3 + 1;

uint ncols = pcols * 3 + 1;

gdouble dx = width / (gdouble)(ncols-1.0);

gdouble dy = height / (gdouble)(nrows-1.0);

Geom::Point p0( mg->x.computed, mg->y.computed );

for( uint i = 0; i < nrows; ++i ) {

std::vector< SPMeshNode* > row;

for( uint j = 0; j < ncols; ++j ) {

SPMeshNode* node = new SPMeshNode;

node->p = p0 + Geom::Point( j * dx, i * dy );

node->node_edge = MG_NODE_EDGE_NONE;

if( i == 0 ) node->node_edge |= MG_NODE_EDGE_TOP;

if( i == nrows -1 ) node->node_edge |= MG_NODE_EDGE_BOTTOM;

if( j == 0 ) node->node_edge |= MG_NODE_EDGE_LEFT;

if( j == ncols -1 ) node->node_edge |= MG_NODE_EDGE_RIGHT;

if( i%3 == 0 ) {

if( j%3 == 0) {

// Corner

node->node_type = MG_NODE_TYPE_CORNER;

node->set = true;

node->color = color;

node->opacity = 1.0;

} else {

// Side

node->node_type = MG_NODE_TYPE_HANDLE;

node->set = true;

node->path_type = 'c';

}

} else {

if( j%3 == 0) {

// Side

node->node_type = MG_NODE_TYPE_HANDLE;

node->set = true;

node->path_type = 'c';

} else {

// Tensor

node->node_type = MG_NODE_TYPE_TENSOR;

node->set = false;

}

}

row.push_back( node );

}

nodes.push_back( row );

}

// End normal

}

} // If conical

//print();

// Write repr

write( mg );

}

void SPMeshNodeArray::clear() {

for( uint i = 0; i < nodes.size(); ++i ) {

for( uint j = 0; j < nodes[i].size(); ++j ) {

if( nodes[i][j] ) {

delete nodes[i][j];

}

}

for( uint i = 0; i < nodes.size(); ++i ) {

nodes[i].clear();

}

nodes.clear();

}

};

void SPMeshNodeArray::print() {

for( uint i = 0; i < nodes.size(); ++i ) {

std::cout << "New node row:" << std::endl;

for( uint j = 0; j < nodes[i].size(); ++j ) {

if( nodes[i][j] ) {

std::cout.width(4);

std::cout << " Node: " << i << "," << j << ": "

<< nodes[i][j]->p

<< " Node type: " << nodes[i][j]->node_type

<< " Node edge: " << nodes[i][j]->node_edge

<< " Set: " << nodes[i][j]->set

<< " Path type: " << nodes[i][j]->path_type

<< std::endl;

} else {

std::cout << "Error: missing mesh node." << std::endl;

}

} // Loop over patches

} // Loop over rows

};

uint SPMeshNodeArray::patch_rows() {

return nodes.size()/3;

}

uint SPMeshNodeArray::patch_columns() {

return nodes[0].size()/3;

}

bool SPMeshNodeArray::adjacent_corners( uint i, uint j, SPMeshNode* n[4] ) {

// This works as all corners have indices and they

// are numbered in order by row and column (and

// the node array is rectangular).

bool adjacent = false;

uint c1 = i;

uint c2 = j;

if( j < i ) {

c1 = j;

c2 = i;

}

// Number of corners in a row of patches.

uint ncorners = patch_columns() + 1;

uint crow1 = c1 / ncorners;

uint crow2 = c2 / ncorners;

uint ccol1 = c1 % ncorners;

uint ccol2 = c2 % ncorners;

uint nrow = crow1 * 3;

uint ncol = ccol1 * 3;

// std::cout << " i: " << i

// << " j: " << j

// << " ncorners: " << ncorners

// << " c1: " << c1

// << " crow1: " << crow1

// << " ccol1: " << ccol1

// << " c2: " << c2

// << " crow2: " << crow2

// << " ccol2: " << ccol2

// << " nrow: " << nrow

// << " ncol: " << ncol

// << std::endl;

// Check for horizontal neighbors

if ( crow1 == crow2 && (ccol2 - ccol1) == 1 ) {

adjacent = true;

for( uint k = 0; k < 4; ++k ) {

n[k] = nodes[nrow][ncol+k];

}

}

// Check for vertical neighbors

if ( ccol1 == ccol2 && (crow2 - crow1) == 1 ) {

adjacent = true;

for( uint k = 0; k < 4; ++k ) {

n[k] = nodes[nrow+k][ncol];

}

}

return adjacent;

}

uint SPMeshNodeArray::side_toggle( std::vector<uint> corners ) {

uint toggled = 0;

if( corners.size() < 2 ) return 0;

for( uint i = 0; i < corners.size()-1; ++i ) {

for( uint j = i+1; j < corners.size(); ++j ) {

SPMeshNode* n[4];

if( adjacent_corners( corners[i], corners[j], n ) ) {

gchar path_type = n[1]->path_type;

switch (path_type)

{

case 'L':

n[1]->path_type = 'C';

n[2]->path_type = 'C';

n[1]->set = true;

n[2]->set = true;

break;

case 'l':

n[1]->path_type = 'c';

n[2]->path_type = 'c';

n[1]->set = true;

n[2]->set = true;

break;

case 'C': {

n[1]->path_type = 'L';

n[2]->path_type = 'L';

n[1]->set = false;

n[2]->set = false;

// 'L' acts as if handles are 1/3 of path length from corners.

Geom::Point dp = (n[3]->p - n[0]->p)/3.0;

n[1]->p = n[0]->p + dp;

n[2]->p = n[3]->p - dp;

break;

}

case 'c': {

n[1]->path_type = 'l';

n[2]->path_type = 'l';

n[1]->set = false;

n[2]->set = false;

// 'l' acts as if handles are 1/3 of path length from corners.

Geom::Point dp = (n[3]->p - n[0]->p)/3.0;

n[1]->p = n[0]->p + dp;

n[2]->p = n[3]->p - dp;

// std::cout << "Toggle sides: "

// << n[0]->p << " "

// << n[1]->p << " "

// << n[2]->p << " "

// << n[3]->p << " "

// << dp << std::endl;

break;

}

default:

std::cout << "Toggle sides: Invalid path type: " << path_type << std::endl;

}

++toggled;

}

}

}

if( toggled > 0 ) built = false;

return toggled;

}

uint SPMeshNodeArray::side_arc( std::vector<uint> corners ) {

if( corners.size() < 2 ) return 0;

uint arced = 0;

for( uint i = 0; i < corners.size()-1; ++i ) {

for( uint j = i+1; j < corners.size(); ++j ) {

SPMeshNode* n[4];

if( adjacent_corners( corners[i], corners[j], n ) ) {

gchar path_type = n[1]->path_type;

switch (path_type)

{

case 'L':

case 'l':

std::cout << "SPMeshNodeArray::arc_sides: Can't convert straight lines to arcs.";

break;

case 'C':

case 'c': {

Geom::Ray ray1( n[0]->p, n[1]->p );

Geom::Ray ray2( n[3]->p, n[2]->p );

if( !are_parallel( (Geom::Line)ray1, (Geom::Line)ray2 ) ) {

Geom::OptCrossing crossing = intersection( ray1, ray2 );

if( crossing ) {

Geom::Point intersection = ray1.pointAt( (*crossing).ta );

const double f = 4.0/3.0 * tan( M_PI/2.0/4.0 );

Geom::Point h1 = intersection - n[0]->p;

Geom::Point h2 = intersection - n[3]->p;

n[1]->p = n[0]->p + f*h1;

n[2]->p = n[3]->p + f*h2;

++arced;

} else {

std::cout << "SPMeshNodeArray::arc_sides: No crossing, can't turn into arc." << std::endl;

}

} else {

std::cout << "SPMeshNodeArray::arc_sides: Handles parallel, can't turn into arc." << std::endl;

}

break;

}

default:

std::cout << "SPMeshNodeArray::arc_sides: Invalid path type: " << n[1]->path_type << std::endl;

}

}

}

}

if( arced > 0 ) built = false;

return arced;

}

uint SPMeshNodeArray::tensor_toggle( std::vector<uint> corners ) {

// std::cout << "SPMeshNodeArray::tensor_toggle" << std::endl;

if( corners.size() < 4 ) return 0;

uint toggled = 0;

// Number of corners in a row of patches.

uint ncorners = patch_columns() + 1;

for( uint i = 0; i < corners.size()-3; ++i ) {

for( uint j = i+1; j < corners.size()-2; ++j ) {

for( uint k = j+1; k < corners.size()-1; ++k ) {

for( uint l = k+1; l < corners.size(); ++l ) {

uint c[4];

c[0] = corners[i];

c[1] = corners[j];

c[2] = corners[k];

c[3] = corners[l];

std::sort( c, c+4 );

// Check we have four corners of one patch selected

if( c[1]-c[0] == 1 &&

c[3]-c[2] == 1 &&

c[2]-c[0] == ncorners &&

c[3]-c[1] == ncorners &&

c[0] % ncorners < ncorners - 1 ) {

// Patch

uint prow = c[0] / ncorners;

uint pcol = c[0] % ncorners;

// Upper left node of patch

uint irow = prow * 3;

uint jcol = pcol * 3;

// std::cout << "tensor::toggle: "

// << c[0] << ", "

// << c[1] << ", "

// << c[2] << ", "

// << c[3] << std::endl;

// std::cout << "tensor::toggle: "

// << " irow: " << irow

// << " jcol: " << jcol

// << " prow: " << prow

// << " pcol: " << pcol

// << std::endl;

SPMeshPatchI patch( &nodes, prow, pcol );

patch.updateNodes();

if( patch.tensorIsSet() ) {

// Unset tensor points

nodes[irow+1][jcol+1]->set = false;

nodes[irow+1][jcol+2]->set = false;

nodes[irow+2][jcol+1]->set = false;

nodes[irow+2][jcol+2]->set = false;

} else {

// Set tensor points

nodes[irow+1][jcol+1]->set = true;

nodes[irow+1][jcol+2]->set = true;

nodes[irow+2][jcol+1]->set = true;

nodes[irow+2][jcol+2]->set = true;

}

++toggled;

}

}

}

}

}

if( toggled > 0 ) built = false;

return toggled;

}

uint SPMeshNodeArray::color_smooth( std::vector<uint> corners ) {

// std::cout << "SPMeshNodeArray::color_smooth" << std::endl;

uint smoothed = 0;

// Number of corners in a row of patches.

uint ncorners = patch_columns() + 1;

// Number of node rows and columns

uint ncols = patch_columns() * 3 + 1;

uint nrows = patch_rows() * 3 + 1;

for( uint i = 0; i < corners.size(); ++i ) {

uint corner = corners[i];

// std::cout << "SPMeshNodeArray::color_smooth: " << i << " " << corner << std::endl;

// Node row & col

uint nrow = (corner / ncorners) * 3;

uint ncol = (corner % ncorners) * 3;

SPMeshNode* n[7];

for( uint s = 0; s < 2; ++s ) {

bool smooth = false;

// Find neighboring nodes

if( s == 0 ) {

// Horizontal

if( ncol > 2 && ncol+3 < ncols) {

for( uint j = 0; j < 7; ++j ) {

n[j] = nodes[ nrow ][ ncol - 3 + j ];

}

smooth = true;

}

} else {

// Vertical

if( nrow > 2 && nrow+3 < nrows) {

for( uint j = 0; j < 7; ++j ) {

n[j] = nodes[ nrow - 3 + j ][ ncol ];

}

smooth = true;

}

}

if( smooth ) {

// Let the smoothing begin

// std::cout << " checking: " << ncol << " " << nrow << std::endl;

// Get initial slopes using closest handles.

double slope[2][3];

double slope_ave[3];

double slope_diff[3];

// Color of corners

SPColor color0 = n[0]->color;

SPColor color3 = n[3]->color;

SPColor color6 = n[6]->color;

// Distance nodes from selected corner

Geom::Point d[7];

for( uint k = 0; k < 7; ++k ) {

d[k]= n[k]->p - n[3]->p;

// std::cout << " d[" << k << "]: " << d[k].length() << std::endl;

}

double sdm = -1.0; // Slope Diff Max

uint cdm = 0; // Color Diff Max (Which color has the maximum difference in slopes)

for( uint c = 0; c < 3; ++c ) {

if( d[2].length() != 0.0 ) {

slope[0][c] = (color3.v.c[c] - color0.v.c[c]) / d[2].length();

}

if( d[4].length() != 0.0 ) {

slope[1][c] = (color6.v.c[c] - color3.v.c[c]) / d[4].length();

}

slope_ave[c] = (slope[0][c]+slope[1][c]) / 2.0;

slope_diff[c] = (slope[0][c]-slope[1][c]);

// std::cout << " color: " << c << " :"

// << color0.v.c[c] << " "

// << color3.v.c[c] << " "

// << color6.v.c[c]

// << " slope: "

// << slope[0][c] << " "

// << slope[1][c]

// << " slope_ave: " << slope_ave[c]

// << " slope_diff: " << slope_diff[c]

// << std::endl;

// Find color with maximum difference

if( std::abs( slope_diff[c] ) > sdm ) {

sdm = std::abs( slope_diff[c] );

cdm = c;

}

}

// std::cout << " cdm: " << cdm << std::endl;

// Find new handle positions:

double length_left = d[0].length();

double length_right = d[6].length();

if( slope_ave[ cdm ] != 0.0 ) {

length_left = std::abs( (color3.v.c[cdm] - color0.v.c[cdm]) / slope_ave[ cdm ] );

length_right = std::abs( (color6.v.c[cdm] - color3.v.c[cdm]) / slope_ave[ cdm ] );

}

// Move closest handle a maximum of mid point... but don't shorten

double max = 0.8;

if( length_left > max * d[0].length() && length_left > d[2].length() ) {

std::cout << " Can't smooth left side" << std::endl;

length_left = std::max( max * d[0].length(), d[2].length() );

}

if( length_right > max * d[6].length() && length_right > d[4].length() ) {

std::cout << " Can't smooth right side" << std::endl;

length_right = std::max( max * d[6].length(), d[4].length() );

}

if( d[2].length() != 0.0 ) d[2] *= length_left/d[2].length();

if( d[4].length() != 0.0 ) d[4] *= length_right/d[4].length();

// std::cout << " length_left: " << length_left

// << " d[0]: " << d[0].length()

// << " length_right: " << length_right

// << " d[6]: " << d[6].length()

// << std::endl;

n[2]->p = n[3]->p + d[2];

n[4]->p = n[3]->p + d[4];

++smoothed;

}

}

}

if( smoothed > 0 ) built = false;

return smoothed;

}

uint SPMeshNodeArray::color_pick( std::vector<uint> icorners, SPItem* item ) {

// std::cout << "SPMeshNodeArray::color_pick" << std::endl;

uint picked = 0;

// Code inspired from clone tracing

// Setup...

// We need a copy of the drawing so we can hide the mesh.

Inkscape::Drawing *pick_drawing = new Inkscape::Drawing();

unsigned pick_visionkey = SPItem::display_key_new(1);

SPDocument *pick_doc = mg->document;

pick_drawing->setRoot(pick_doc->getRoot()->invoke_show(*pick_drawing, pick_visionkey, SP_ITEM_SHOW_DISPLAY));

item->invoke_hide(pick_visionkey);

pick_doc->getRoot()->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

pick_doc->ensureUpToDate();

//gdouble pick_zoom = 1.0; // zoom;

//pick_drawing->root()->setTransform(Geom::Scale(pick_zoom));

pick_drawing->update();

// std::cout << " transform: " << std::endl;

// std::cout << item->transform << std::endl;

// std::cout << " i2doc: " << std::endl;

// std::cout << item->i2doc_affine() << std::endl;

// std::cout << " i2dt: " << std::endl;

// std::cout << item->i2dt_affine() << std::endl;

// std::cout << " dt2i: " << std::endl;

// std::cout << item->dt2i_affine() << std::endl;

SPGradient* gr = SP_GRADIENT( mg );

// if( gr->gradientTransform_set ) {

// std::cout << " gradient transform set: " << std::endl;

// std::cout << gr->gradientTransform << std::endl;

// } else {

// std::cout << " gradient transform not set! " << std::endl;

// }

// Do picking

for( uint i = 0; i < icorners.size(); ++i ) {

uint corner = icorners[i];

SPMeshNode* n = corners[ corner ];

// Region to average over

Geom::Point p = n->p;

// std::cout << " p: " << p << std::endl;

p *= gr->gradientTransform;

// std::cout << " p: " << p << std::endl;

// If on edge, move inward

uint cols = patch_columns()+1;

uint rows = patch_rows()+1;

uint col = corner % cols;

uint row = corner / cols;

uint ncol = col * 3;

uint nrow = row * 3;

double size = 3.0;

// Top edge

if( row == 0 ) {

Geom::Point dp = nodes[nrow+1][ncol]->p - p;

p += unit_vector( dp ) * size;

}

// Right edge

if( col == cols-1 ) {

Geom::Point dp = nodes[nrow][ncol-1]->p - p;

p += unit_vector( dp ) * size;

}

// Bottom edge

if( row == rows-1 ) {

Geom::Point dp = nodes[nrow-1][ncol]->p - p;

p += unit_vector( dp ) * size;

}

// Left edge

if( col == 0 ) {

Geom::Point dp = nodes[nrow][ncol+1]->p - p;

p += unit_vector( dp ) * size;

}

Geom::Rect box( p[Geom::X]-size/2.0, p[Geom::Y]-size/2.0,

p[Geom::X]+size/2.0, p[Geom::Y]+size/2.0 );

/* Item integer bbox in points */

Geom::IntRect ibox = box.roundOutwards();

/* Find visible area */

cairo_surface_t *s = cairo_image_surface_create(CAIRO_FORMAT_ARGB32, ibox.width(), ibox.height());

Inkscape::DrawingContext ct(s, ibox.min());

/* Render copy and pick color */

pick_drawing->render(ct, ibox);

double R = 0, G = 0, B = 0, A = 0;

ink_cairo_surface_average_color(s, R, G, B, A);

cairo_surface_destroy(s);

// std::cout << " p: " << p

// << " box: " << ibox

// << " R: " << R

// << " G: " << G

// << " B: " << B

// << std::endl;

n->color.set( R, G, B );

}

pick_doc->getRoot()->invoke_hide(pick_visionkey);

delete pick_drawing;

if( picked > 0 ) built = false;

return picked;

}

void SPMeshNodeArray::update_handles( uint corner, std::vector< uint > selected, Geom::Point p_old, MeshNodeOperation op ) {

assert( drag_valid );

// std::cout << "SPMeshNodeArray::update_handles: "

// << " corner: " << corner

// << " op: " << op

// << std::endl;

// Find number of patch rows and columns

uint mrow = patch_rows();

uint mcol = patch_columns();

// Number of corners in a row of patches.

uint ncorners = mcol + 1;

// Find corner row/column

uint crow = corner / ncorners;

uint ccol = corner % ncorners;

// Find node row/column

uint nrow = crow * 3;

uint ncol = ccol * 3;

// std::cout << " mrow: " << mrow

// << " mcol: " << mcol

// << " crow: " << crow

// << " ccol: " << ccol

// << " ncorners: " << ncorners

// << " nrow: " << nrow

// << " ncol: " << ncol

// << std::endl;

// New corner mesh coordinate.

Geom::Point p_new = nodes[nrow][ncol]->p;

// Corner point move dpg in mesh coordinate system.

Geom::Point dp = p_new - p_old;

// std::cout << " p_old: " << p_old << std::endl;

// std::cout << " p_new: " << p_new << std::endl;

// std::cout << " dp: " << dp << std::endl;

// STEP 1: ONLY DO DIRECT MOVE

bool patch[4];

patch[0] = patch[1] = patch[2] = patch[3] = false;

if( ccol > 0 && crow > 0 ) patch[0] = true;

if( ccol < mcol && crow > 0 ) patch[1] = true;

if( ccol < mcol && crow < mrow ) patch[2] = true;

if( ccol > 0 && crow < mrow ) patch[3] = true;

// std::cout << patch[0] << " "

// << patch[1] << " "

// << patch[2] << " "

// << patch[3] << std::endl;

// Move handles

if( patch[0] || patch[1] ) {

if( nodes[nrow-1][ncol]->path_type == 'l' ||

nodes[nrow-1][ncol]->path_type == 'L' ) {

Geom::Point s = (nodes[nrow-3][ncol]->p - nodes[nrow][ncol]->p)/3.0;

nodes[nrow-1][ncol ]->p = nodes[nrow][ncol]->p + s;

nodes[nrow-2][ncol ]->p = nodes[nrow-3][ncol]->p - s;

} else {

nodes[nrow-1][ncol ]->p += dp;

}

}

if( patch[1] || patch[2] ) {

if( nodes[nrow ][ncol+1]->path_type == 'l' ||

nodes[nrow ][ncol+1]->path_type == 'L' ) {

Geom::Point s = (nodes[nrow][ncol+3]->p - nodes[nrow][ncol]->p)/3.0;

nodes[nrow ][ncol+1]->p = nodes[nrow][ncol]->p + s;

nodes[nrow ][ncol+2]->p = nodes[nrow][ncol+3]->p - s;

} else {

nodes[nrow ][ncol+1]->p += dp;

}

}

if( patch[2] || patch[3] ) {

if( nodes[nrow+1][ncol ]->path_type == 'l' ||

nodes[nrow+1][ncol ]->path_type == 'L' ) {

Geom::Point s = (nodes[nrow+3][ncol]->p - nodes[nrow][ncol]->p)/3.0;

nodes[nrow+1][ncol ]->p = nodes[nrow][ncol]->p + s;

nodes[nrow+2][ncol ]->p = nodes[nrow+3][ncol]->p - s;

} else {

nodes[nrow+1][ncol ]->p += dp;

}

}

if( patch[3] || patch[0] ) {

if( nodes[nrow ][ncol-1]->path_type == 'l' ||

nodes[nrow ][ncol-1]->path_type == 'L' ) {

Geom::Point s = (nodes[nrow][ncol-3]->p - nodes[nrow][ncol]->p)/3.0;

nodes[nrow ][ncol-1]->p = nodes[nrow][ncol]->p + s;

nodes[nrow ][ncol-2]->p = nodes[nrow][ncol-3]->p - s;

} else {

nodes[nrow ][ncol-1]->p += dp;

}

}

// Move tensors

if( patch[0] ) nodes[nrow-1][ncol-1]->p += dp;

if( patch[1] ) nodes[nrow-1][ncol+1]->p += dp;

if( patch[2] ) nodes[nrow+1][ncol+1]->p += dp;

if( patch[3] ) nodes[nrow+1][ncol-1]->p += dp;

// // Check if neighboring corners are selected.

// bool do_scale = false;

// bool do_scale_xp = do_scale;

// bool do_scale_xn = do_scale;

// bool do_scale_yp = do_scale;

// bool do_scale_yn = do_scale;

// if( ccol < mcol+1 ) {

// if( std::find( sc.begin(), sc.end(), point_i + 1 ) != sc.end() ) {

// do_scale_xp = false;

// std::cout << " Not scaling x+" << std::endl;

// }

// }

// if( ccol > 0 ) {

// if( std::find( sc.begin(), sc.end(), point_i - 1 ) != sc.end() ) {

// do_scale_xn = false;

// std::cout << " Not scaling x-" << std::endl;

// }

// }

// if( crow < mrow+1 ) {

// if( std::find( sc.begin(), sc.end(), point_i + ncorners ) != sc.end() ) {

// do_scale_yp = false;

// std::cout << " Not scaling y+" << std::endl;

// }

// }

// if( crow > 0 ) {

// if( std::find( sc.begin(), sc.end(), point_i - ncorners ) != sc.end() ) {

// do_scale_yn = false;

// std::cout << " Not scaling y-" << std::endl;

// }

// }

// // We have four patches to adjust...

// for ( uint k = 0; k < 4; ++k ) {

// bool do_scale_x = do_scale;

// bool do_scale_y = do_scale;

// SPMeshNode* pnodes[4][4];

// // Load up matrix

// switch (k) {

// case 0:

// if( crow < mrow+1 && ccol < mcol+1 ) {

// // Bottom right patch

// do_scale_x = do_scale_xp;

// do_scale_y = do_scale_yp;

// for( uint i = 0; i < 4; ++i ) {

// for( uint j = 0; j< 4; ++j ) {

// pnodes[i][j] = mg->array.nodes[nrow+i][nrow+j];

// }

// }

// }

// break;

// case 1:

// if( crow < mrow+1 && ccol > 0 ) {

// // Bottom left patch (note x, y swapped)

// do_scale_y = do_scale_xn;

// do_scale_x = do_scale_yp;

// for( uint i = 0; i < 4; ++i ) {

// for( uint j = 0; j< 4; ++j ) {

// pnodes[j][i] = mg->array.nodes[nrow+i][nrow-j];

// }

// }

// }

// break;

// case 2:

// if( crow > 0 && ccol > 0 ) {

// // Top left patch

// do_scale_x = do_scale_xn;

// do_scale_y = do_scale_yn;

// for( uint i = 0; i < 4; ++i ) {

// for( uint j = 0; j< 4; ++j ) {

// pnodes[i][j] = mg->array.nodes[nrow-i][nrow-j];

// }

// }

// }

// break;

// case 3:

// if( crow > 0 && ccol < mcol+1 ) {

// // Top right patch (note x, y swapped)

// do_scale_y = do_scale_xp;

// do_scale_x = do_scale_yn;

// for( uint i = 0; i < 4; ++i ) {

// for( uint j = 0; j< 4; ++j ) {

// pnodes[j][i] = mg->array.nodes[nrow-i][nrow+j];

// }

// }

// }

// break;

// }

// // Now we must move points in both x and y.

// // There are upto six points to move: P01, P02, P11, P12, P21, P22.

// // (The points P10, P20 will be moved in another branch of the loop.

// // The points P03, P13, P23, P33, P32, P31, P30 are not moved.)

// //

// // P00 P01 P02 P03

// // P10 P11 P12 P13

// // P20 P21 P22 P23

// // P30 P31 P32 P33

// //

// // The goal is to preserve the direction of the handle!

// Geom::Point dsx_new = pnodes[0][3]->p - pnodes[0][0]->p; // New side x

// Geom::Point dsy_new = pnodes[3][0]->p - pnodes[0][0]->p; // New side y

// Geom::Point dsx_old = pnodes[0][3]->p - pcg_old; // Old side x

// Geom::Point dsy_old = pnodes[3][0]->p - pcg_old; // Old side y

// double scale_factor_x = 1.0;

// if( dsx_old.length() != 0.0 ) scale_factor_x = dsx_new.length()/dsx_old.length();

// double scale_factor_y = 1.0;

// if( dsy_old.length() != 0.0 ) scale_factor_y = dsy_new.length()/dsy_old.length();

// if( do_scalex && do_scaley ) {

// // We have six point to move.

// // P01

// Geom::Point dp01 = pnodes[0][1] - pcg_old;

// dp01 *= scale_factor_x;

// pnodes[0][1] = pnodes[0][0] + dp01;

// // P02

// Geom::Point dp02 = pnodes[0][2] - pnodes[0][3];

// dp02 *= scale_factor_x;

// pnodes[0][2] = pnodes[0][3] + dp02;

// // P11

// Geom::Point dp11 = pnodes[1][1] - pcg_old;

// dp11 *= scale_factor_x;

// pnodes[1][1] = pnodes[0][0] + dp11;

// // P21

// Geom::Point dp21 = pnodes[2][1] - pnodes[3][0];

// dp21 *= scale_factor_x;

// dp21 *= scale_factor_y;

// pnodes[2][1] = pnodes[3][0] + dp21;

// Geom::Point dsx1 = pnodes[0][1]->p -

}

guint32 average_color(guint32 c1, guint32 c2, gdouble p);

void SPMeshNodeArray::split_row( uint row, uint n ) {

double nn = n;

if( n > 1 ) split_row( row, (nn-1)/nn );

if( n > 2 ) split_row( row, n-1 );

}

void SPMeshNodeArray::split_column( uint col, uint n ) {

double nn = n;

if( n > 1 ) split_column( col, (nn-1)/nn );

if( n > 2 ) split_column( col, n-1 );

}

void SPMeshNodeArray::split_row( uint row, double coord ) {

// std::cout << "Splitting row: " << row << " at " << coord << std::endl;

// print();

assert( coord >= 0.0 && coord <= 1.0 );

assert( row < patch_rows() );

built = false;

// First step is to ensure that handle and tensor points are up-to-date if they are not set.

// (We can't do this on the fly as we overwrite the necessary points to do the calculation

// during the update.)

for( uint j = 0; j < patch_columns(); ++ j ) {

SPMeshPatchI patch( &nodes, row, j );

patch.updateNodes();

}

// Add three new rows of empty nodes

for( uint i = 0; i < 3; ++i ) {

std::vector< SPMeshNode* > new_row;

for( uint j = 0; j < nodes[0].size(); ++j ) {

SPMeshNode* new_node = new SPMeshNode;

new_row.push_back( new_node );

}

nodes.insert( nodes.begin()+3*(row+1), new_row );

}

uint i = 3 * row; // Convert from patch row to node row

for( uint j = 0; j < nodes[i].size(); ++j ) {

// std::cout << "Splitting row: column: " << j << std::endl;

Geom::Point p[4];

for( uint k = 0; k < 4; ++k ) {

uint n = k;

if( k == 3 ) n = 6; // Bottom patch row has been shifted by new rows

p[k] = nodes[i+n][j]->p;

// std::cout << p[k] << std::endl;

}

Geom::BezierCurveN<3> b( p[0], p[1], p[2], p[3] );

std::pair<Geom::BezierCurveN<3>, Geom::BezierCurveN<3> > b_new =

b.subdivide( coord );

// Update points

for( uint n = 0; n < 4; ++n ) {

nodes[i+n ][j]->p = b_new.first[n];

nodes[i+n+3][j]->p = b_new.second[n];

// std::cout << b_new.first[n] << " " << b_new.second[n] << std::endl;

}

if( nodes[i][j]->node_type == MG_NODE_TYPE_CORNER ) {

// We are splitting a side

// Path type stored in handles.

gchar path_type = nodes[i+1][j]->path_type;

nodes[i+4][j]->path_type = path_type;

nodes[i+5][j]->path_type = path_type;

bool set = nodes[i+1][j]->set;

nodes[i+4][j]->set = set;

nodes[i+5][j]->set = set;

nodes[i+4][j]->node_type = MG_NODE_TYPE_HANDLE;

nodes[i+5][j]->node_type = MG_NODE_TYPE_HANDLE;

// Color stored in corners

guint c0 = nodes[i ][j]->color.toRGBA32( 1.0 );

guint c1 = nodes[i+6][j]->color.toRGBA32( 1.0 );

gdouble o0 = nodes[i ][j]->opacity;

gdouble o1 = nodes[i+6][j]->opacity;

guint cnew = average_color( c0, c1, coord );

gdouble onew = o0 * (1.0 - coord) + o1 * coord;

nodes[i+3][j]->color.set( cnew );

nodes[i+3][j]->opacity = onew;

nodes[i+3][j]->node_type = MG_NODE_TYPE_CORNER;

nodes[i+3][j]->set = true;

} else {

// We are splitting a middle

bool set = nodes[i+1][j]->set || nodes[i+1][j]->set;

nodes[i+4][j]->set = set;

nodes[i+5][j]->set = set;

nodes[i+4][j]->node_type = MG_NODE_TYPE_TENSOR;

nodes[i+5][j]->node_type = MG_NODE_TYPE_TENSOR;

// Path type, if different, choose l -> L -> c -> C.

gchar path_type0 = nodes[i ][j]->path_type;

gchar path_type1 = nodes[i+6][j]->path_type;

gchar path_type = 'l';

if( path_type0 == 'L' || path_type1 == 'L') path_type = 'L';

if( path_type0 == 'c' || path_type1 == 'c') path_type = 'c';

if( path_type0 == 'C' || path_type1 == 'C') path_type = 'C';

nodes[i+3][j]->path_type = path_type;

nodes[i+3][j]->node_type = MG_NODE_TYPE_HANDLE;

if( path_type == 'c' || path_type == 'C' ) nodes[i+3][j]->set = true;

}

nodes[i+3][j]->node_edge = MG_NODE_EDGE_NONE;

nodes[i+4][j]->node_edge = MG_NODE_EDGE_NONE;

nodes[i+5][j]->node_edge = MG_NODE_EDGE_NONE;;

if( j == 0 ) {

nodes[i+3][j]->node_edge |= MG_NODE_EDGE_LEFT;

nodes[i+4][j]->node_edge |= MG_NODE_EDGE_LEFT;

nodes[i+5][j]->node_edge |= MG_NODE_EDGE_LEFT;

}

if( j == nodes[i].size() - 1 ) {

nodes[i+3][j]->node_edge |= MG_NODE_EDGE_RIGHT;

nodes[i+4][j]->node_edge |= MG_NODE_EDGE_RIGHT;

nodes[i+5][j]->node_edge |= MG_NODE_EDGE_RIGHT;

}

}

// std::cout << "Splitting row: result:" << std::endl;

// print();

}

void SPMeshNodeArray::split_column( uint col, double coord ) {

// std::cout << "Splitting column: " << col << " at " << coord << std::endl;

// print();

assert( coord >= 0.0 && coord <= 1.0 );

assert( col < patch_columns() );

built = false;

// First step is to ensure that handle and tensor points are up-to-date if they are not set.

// (We can't do this on the fly as we overwrite the necessary points to do the calculation

// during the update.)

for( uint i = 0; i < patch_rows(); ++ i ) {

SPMeshPatchI patch( &nodes, i, col );

patch.updateNodes();

}

uint j = 3 * col; // Convert from patch column to node column

for( uint i = 0; i < nodes.size(); ++i ) {

// std::cout << "Splitting column: row: " << i << std::endl;

Geom::Point p[4];

for( uint k = 0; k < 4; ++k ) {

p[k] = nodes[i][j+k]->p;

}

Geom::BezierCurveN<3> b( p[0], p[1], p[2], p[3] );

std::pair<Geom::BezierCurveN<3>, Geom::BezierCurveN<3> > b_new =

b.subdivide( coord );

// Add three new nodes

for( uint n = 0; n < 3; ++n ) {

SPMeshNode* new_node = new SPMeshNode;

nodes[i].insert( nodes[i].begin()+j+3, new_node );

}

// Update points

for( uint n = 0; n < 4; ++n ) {

nodes[i][j+n]->p = b_new.first[n];

nodes[i][j+n+3]->p = b_new.second[n];

}

if( nodes[i][j]->node_type == MG_NODE_TYPE_CORNER ) {

// We are splitting a side

// Path type stored in handles.

gchar path_type = nodes[i][j+1]->path_type;

nodes[i][j+4]->path_type = path_type;

nodes[i][j+5]->path_type = path_type;

bool set = nodes[i][j+1]->set;

nodes[i][j+4]->set = set;

nodes[i][j+5]->set = set;

nodes[i][j+4]->node_type = MG_NODE_TYPE_HANDLE;

nodes[i][j+5]->node_type = MG_NODE_TYPE_HANDLE;

// Color stored in corners

guint c0 = nodes[i][j ]->color.toRGBA32( 1.0 );

guint c1 = nodes[i][j+6]->color.toRGBA32( 1.0 );

gdouble o0 = nodes[i][j ]->opacity;

gdouble o1 = nodes[i][j+6]->opacity;

guint cnew = average_color( c0, c1, coord );

gdouble onew = o0 * (1.0 - coord) + o1 * coord;

nodes[i][j+3]->color.set( cnew );

nodes[i][j+3]->opacity = onew;

nodes[i][j+3]->node_type = MG_NODE_TYPE_CORNER;

nodes[i][j+3]->set = true;

} else {

// We are splitting a middle

bool set = nodes[i][j+1]->set || nodes[i][j+2]->set;

nodes[i][j+4]->set = set;

nodes[i][j+5]->set = set;

nodes[i][j+4]->node_type = MG_NODE_TYPE_TENSOR;

nodes[i][j+5]->node_type = MG_NODE_TYPE_TENSOR;

// Path type, if different, choose l -> L -> c -> C.

gchar path_type0 = nodes[i][j ]->path_type;

gchar path_type1 = nodes[i][j+6]->path_type;

gchar path_type = 'l';

if( path_type0 == 'L' || path_type1 == 'L') path_type = 'L';

if( path_type0 == 'c' || path_type1 == 'c') path_type = 'c';

if( path_type0 == 'C' || path_type1 == 'C') path_type = 'C';

nodes[i][j+3]->path_type = path_type;

nodes[i][j+3]->node_type = MG_NODE_TYPE_HANDLE;

if( path_type == 'c' || path_type == 'C' ) nodes[i][j+3]->set = true;

}

nodes[i][j+3]->node_edge = MG_NODE_EDGE_NONE;

nodes[i][j+4]->node_edge = MG_NODE_EDGE_NONE;

nodes[i][j+5]->node_edge = MG_NODE_EDGE_NONE;;

if( i == 0 ) {

nodes[i][j+3]->node_edge |= MG_NODE_EDGE_TOP;

nodes[i][j+4]->node_edge |= MG_NODE_EDGE_TOP;

nodes[i][j+5]->node_edge |= MG_NODE_EDGE_TOP;

}

if( i == nodes.size() - 1 ) {

nodes[i][j+3]->node_edge |= MG_NODE_EDGE_BOTTOM;

nodes[i][j+4]->node_edge |= MG_NODE_EDGE_BOTTOM;

nodes[i][j+5]->node_edge |= MG_NODE_EDGE_BOTTOM;

}

}

// std::cout << "Splitting col: result:" << std::endl;

// print();

}