private static void EvalMatrixD(AsyncArg arg, IExpression exprV1V2, double[,] res, int steps1, int[] progress, int index,
string var1, double step1, int start1, int end1, string var2, double step2, int steps2)
{
for (int n = start1; n < end1; n++)
{
if (arg.Token.IsCancellationRequested)
{
return;
}
double v1 = step1 * n;
IExpression substituted1 = ExprSimplifier.Substitute(exprV1V2, var1, new ExprConst(v1.ToString("f15")));
for (int j = 0; j < steps2; j++)
{
double v2 = step2 * j;
IExpression substituted2 = ExprSimplifier.Substitute(substituted1, var2, new ExprConst(v2.ToString("f15")));
substituted2 = ExprSimplifier.Simplify(substituted2);
res[n, j] = ExprDoubleSimplifier.CalcConstExpr(substituted2);
}
lock (progress)
{
progress[index]++;
int steps = 0;
foreach (int s in progress)
{
steps += s;
}
arg.Progress?.Report(steps / (float)steps1);
}
}
}
public static double[,] EvalMatrixD_OneThread(AsyncArg arg, IExpression expr, DependencySpace depSpace, string[] deps,
string var1, double len1, int steps1, string var2, double len2, int steps2)
{
expr = ExprUtils.GetCopy_Slow(expr);
foreach (string dep in deps)
{
Complex?val = depSpace.Get(dep);
if (val.HasValue)
{
expr = ExprSimplifier.Substitute(expr, dep, new ExprConst(val.Value.Real.ToString("f15")));
}
}
double[,] res = new double[steps1, steps2]; // t, x
for (int n = 0; n < steps1; n++)
{
if (arg.Token.IsCancellationRequested)
{
return(null);
}
double v1 = len1 * n / steps1;
IExpression substituted1 = ExprSimplifier.Substitute(expr, var1, new ExprConst(v1.ToString("f15")));
for (int j = 0; j < steps2; j++)
{
double v2 = len2 * j / steps2;
IExpression substituted2 = ExprSimplifier.Substitute(substituted1, var2, new ExprConst(v2.ToString("f15")));
substituted2 = ExprSimplifier.Simplify(substituted2);
res[n, j] = ExprDoubleSimplifier.CalcConstExpr(substituted2);
}
arg.Progress?.Report((n + 1) / (float)steps1);
}
return(res);
}
private void DrawExpectedSolution()
{
SolutionInput input = BuildInput();
IExpression expr = MainParser.Parse(input.v);
string[] deps = MainParser.GetDependencies(expr);
double T = double.Parse(input.T);
int M = int.Parse(input.t_count);
int N = int.Parse(input.x_count);
if (M > VISUALIZATION_HEIGHT)
{
M = VISUALIZATION_HEIGHT;
}
if (N > VISUALIZATION_WIDTH)
{
N = VISUALIZATION_WIDTH;
}
if (Dependencies.Get(MathAliases.ConvertName("chi")) == null)
{
Dependencies.Set(MathAliases.ConvertName("chi"), 0);
}
SwitchDrawButton(true);
calcBar.Value = 0;
var calcProgress = new Progress <double>(value => calcBar.Value = value);
ShowProgress();
Task.Run(() =>
{
AsyncArg arg = new AsyncArg(calcProgress, solveCancellation.Token);
double[,] sol = MainParser.EvalMatrixD(arg, expr, Dependencies, deps, "t", T, M, "x", 2 * Math.PI, N);
if (arg.Token.IsCancellationRequested)
{
return;
}
this.Dispatcher.Invoke(() =>
{
UpdateVisualization(sol, "U(x,t)");
SwitchDrawButton(false);
});
});
}
public static double[,] EvalMatrixD(AsyncArg arg, IExpression expr, DependencySpace depSpace, string[] deps,
string var1, double len1, int steps1, string var2, double len2, int steps2)
{
expr = ExprUtils.GetCopy_Slow(expr);
foreach (string dep in deps)
{
Complex?val = depSpace.Get(dep);
if (val.HasValue)
{
expr = ExprSimplifier.Substitute(expr, dep, new ExprConst(val.Value.Real.ToString("f15")));
}
}
double[,] res = new double[steps1, steps2]; // t, x
if (!ExprSimplifier.IsDependsOn(expr, var1))
{
double[] xArr = EvalArrayD(expr, depSpace, deps, var2, len2, steps2);
for (int j = 0; j < steps2; j++)
{
for (int i = 0; i < steps1; i++)
{
res[i, j] = xArr[j];
}
}
return(res);
}
if (!ExprSimplifier.IsDependsOn(expr, var2))
{
double[] xArr = EvalArrayD(expr, depSpace, deps, var1, len1, steps1);
for (int i = 0; i < steps1; i++)
{
for (int j = 0; j < steps2; j++)
{
res[i, j] = xArr[i];
}
}
return(res);
}
int[] progress = new int[Environment.ProcessorCount];
int interval = (int)Math.Ceiling(steps1 / (double)progress.Length);
Parallel.For(0, progress.Length, (index) => EvalMatrixD(arg, expr, res, steps1, progress, index,
var1, len1 / steps1, index * interval, Math.Min((index + 1) * interval, steps1), var2, len2 / steps2, steps2));
return(res);
}
private async void drawButton_ClickAsync(object sender, RoutedEventArgs e)
{
if (solveCancellation != null)
{
SwitchDrawButton(false);
return;
}
BuildSolver();
SwitchDrawButton(true);
calcBar.Value = 0;
var calcProgress = new Progress <double>(value => calcBar.Value = value);
ShowProgress();
Task.Run(() =>
{
AsyncArg asyncArg = new AsyncArg(calcProgress, solveCancellation.Token);
curSolver.Solve(method, asyncArg);
if (asyncArg.Token.IsCancellationRequested)
{
return;
}
this.Dispatcher.Invoke(() =>
{
textBlock_Khi.Text = "𝜒 = " + curSolver.Chi.ToString("f4");
var eigen = FilterInfo.UpdateEigen(filterBuilder.Filter, textBlock_critical, curSolver.Parameters);
Complex[] eigenvalies = eigen.Item1;
int k = -1;
bool isTuring = false;
for (int i = 0; i < eigenvalies.Length; i++)
{
if (eigenvalies[i].Real > 0 || Math.Abs(eigenvalies[i].Real) < 0.005)
{
if (eigenvalies[i].Imaginary > 0)
{
k = i;
isTuring = false;
break;
}
if (Math.Abs(eigenvalies[i].Imaginary) < 0.00001)
{
k = i;
isTuring = true;
break;
}
}
}
if (k >= 0)
{
Complex[] eigenvector = new Complex[eigenvalies.Length];
for (int i = 0; i < eigenvector.Length; i++)
{
eigenvector[i] = eigen.Item2[i, k];
}
int center = eigenvector.Length / 2;
string v;
if (isTuring)
{
v = SolutionInput.GenExpectedTuring(
(n) => (eigenvector[center + n] + eigenvector[center - n]).Real,
(n) => - (eigenvector[center + n] - eigenvector[center - n]).Imaginary,
center, true, 1);
}
else
{
v = SolutionInput.GenExpectedHopf(eigenvalies[k].Imaginary,
(n) => (eigenvector[center + n] + eigenvector[center - n]).Real,
(n) => - (eigenvector[center + n] - eigenvector[center - n]).Imaginary,
(n) => (eigenvector[center + n] + eigenvector[center - n]).Imaginary,
(n) => (eigenvector[center + n] - eigenvector[center - n]).Real,
center, true, 1);
}
foreach (UIParam param in parameters)
{
if (param.Name == "v")
{
param.Text = v;
break;
}
}
}
UpdateVisualization(curSolver.Solution, "u(x,T)");
SwitchDrawButton(false);
});
});
}
