double QuadQuality(const Vertex & a,const Vertex &b,const Vertex &c,const Vertex &d) { // calcul de 4 angles -- R2 A((R2)a),B((R2)b),C((R2)c),D((R2)d); R2 AB(B-A),BC(C-B),CD(D-C),DA(A-D); // Move(A),Line(B),Line(C),Line(D),Line(A); const Metric & Ma = a; const Metric & Mb = b; const Metric & Mc = c; const Metric & Md = d; double lAB=Norme2(AB); double lBC=Norme2(BC); double lCD=Norme2(CD); double lDA=Norme2(DA); AB /= lAB; BC /= lBC; CD /= lCD; DA /= lDA; // version aniso double cosDAB= Ma(DA,AB)/(Ma(DA)*Ma(AB)),sinDAB= Det(DA,AB); double cosABC= Mb(AB,BC)/(Mb(AB)*Mb(BC)),sinABC= Det(AB,BC); double cosBCD= Mc(BC,CD)/(Mc(BC)*Mc(CD)),sinBCD= Det(BC,CD); double cosCDA= Md(CD,DA)/(Md(CD)*Md(DA)),sinCDA= Det(CD,DA); double sinmin=Min(Min(sinDAB,sinABC),Min(sinBCD,sinCDA)); // cout << A << B << C << D ; // cout << " sinmin " << sinmin << " " << cosDAB << " " << cosABC << " " << cosBCD << " " << cosCDA << endl; // rattente(1); if (sinmin<=0) return sinmin; return 1.0-Max(Max(Abs(cosDAB),Abs(cosABC)),Max(Abs(cosBCD),Abs(cosCDA))); }
int main() { Mensch A; Mensch B; A.name = "Frank"; A.alter = 23; printMensch(A); setName(A, "Horst"); printMensch(A); A.name = "Doofkopf"; std::cout << A.name << "\n"; MenschKlasse Ma("Supermann", 111); Ma.printMensch(); // compile-time error // Ma.name ist private // Ma.name = "Doof"; }
int test_matrix() { Matrix Ma(2, 2); Matrix Mb(2, 2); int rows = 2; int cols = 2; std::vector<int>* a; a = new std::vector<int>[rows]; a[0].push_back (1); a[0].push_back(1); a[1].push_back (1); a[1].push_back(0); Ma.InitOfMatrix(a); Mb.InitOfMatrix(a); Ma.display(); Matrix Mc=Ma * Mb; Mc.display(); return 0; }
static void sha512(SHA *s, unsigned char *block) /* SHA-384/512 transform */ { W64 a, b, c, d, e, f, g, h, T1, T2; W64 W[80]; W64 *H = s->H64; int t; SHA64_SCHED(W, block); for (t = 16; t < 80; t++) W[t] = sigmaQ1(W[t-2]) + W[t-7] + sigmaQ0(W[t-15]) + W[t-16]; a = H[0]; b = H[1]; c = H[2]; d = H[3]; e = H[4]; f = H[5]; g = H[6]; h = H[7]; for (t = 0; t < 80; t++) { T1 = h + SIGMAQ1(e) + Ch(e, f, g) + K512[t] + W[t]; T2 = SIGMAQ0(a) + Ma(a, b, c); h = g; g = f; f = e; e = d + T1; d = c; c = b; b = a; a = T1 + T2; } H[0] += a; H[1] += b; H[2] += c; H[3] += d; H[4] += e; H[5] += f; H[6] += g; H[7] += h; }
bool FractureElasticityVoigt::evalStress (double lambda, double mu, double Gc, const SymmTensor& epsil, double* Phi, SymmTensor* sigma, Matrix* dSdE, bool postProc, bool printElm) const { PROFILE3("FractureEl::evalStress"); unsigned short int a = 0, b = 0; // Define a Lambda-function to set up the isotropic constitutive matrix auto&& setIsotropic = [this,a,b](Matrix& C, double lambda, double mu) mutable { for (a = 1; a <= C.rows(); a++) if (a > nsd) C(a,a) = mu; else { C(a,a) = 2.0*mu; for (b = 1; b <= nsd; b++) C(a,b) += lambda; } }; // Define some material constants double trEps = epsil.trace(); double C0 = trEps >= -epsZ ? Gc*lambda : lambda; double Cp = Gc*mu; if (trEps >= -epsZ && trEps <= epsZ) { // No strains, stress free configuration Phi[0] = 0.0; if (postProc) Phi[1] = Phi[2] = Phi[3] = 0.0; if (sigma) *sigma = 0.0; if (dSdE) setIsotropic(*dSdE,C0,Cp); return true; } // Calculate principal strains and the associated directions Vec3 eps; std::vector<SymmTensor> M(nsd,SymmTensor(nsd)); { PROFILE4("Tensor::principal"); if (!epsil.principal(eps,M.data())) return false; } // Split the strain tensor into positive and negative parts SymmTensor ePos(nsd), eNeg(nsd); for (a = 0; a < nsd; a++) if (eps[a] > 0.0) ePos += eps[a]*M[a]; else if (eps[a] < 0.0) eNeg += eps[a]*M[a]; if (sigma) { // Evaluate the stress tensor *sigma = C0*trEps; *sigma += 2.0*mu*(Gc*ePos + eNeg); } // Evaluate the tensile energy Phi[0] = mu*(ePos*ePos).trace(); if (trEps > 0.0) Phi[0] += 0.5*lambda*trEps*trEps; if (postProc) { // Evaluate the compressive energy Phi[1] = mu*(eNeg*eNeg).trace(); if (trEps < 0.0) Phi[1] += 0.5*lambda*trEps*trEps; // Evaluate the total strain energy Phi[2] = Gc*Phi[0] + Phi[1]; // Evaluate the bulk energy Phi[3] = Gc*(Phi[0] + Phi[1]); } else if (sigmaC > 0.0) // Evaluate the crack driving function Phi[0] = this->MieheCrit56(eps,lambda,mu); #if INT_DEBUG > 4 std::cout <<"eps_p = "<< eps <<"\n"; for (a = 0; a < nsd; a++) std::cout <<"M("<< 1+a <<") =\n"<< M[a]; std::cout <<"ePos =\n"<< ePos <<"eNeg =\n"<< eNeg; if (sigma) std::cout <<"sigma =\n"<< *sigma; std::cout <<"Phi = "<< Phi[0]; if (postProc) std::cout <<" "<< Phi[1] <<" "<< Phi[2] <<" "<< Phi[3]; std::cout << std::endl; #else if (printElm) { std::cout <<"g(c) = "<< Gc <<"\nepsilon =\n"<< epsil <<"eps_p = "<< eps <<"\nePos =\n"<< ePos <<"eNeg =\n"<< eNeg; if (sigma) std::cout <<"sigma =\n"<< *sigma; std::cout <<"Phi = "<< Phi[0]; if (postProc) std::cout <<" "<< Phi[1] <<" "<< Phi[2] <<" "<< Phi[3]; std::cout << std::endl; } #endif if (!dSdE) return true; else if (eps[0] == eps[nsd-1]) { // Hydrostatic pressure setIsotropic(*dSdE, C0, eps.x > 0.0 ? Cp : mu); return true; } typedef unsigned short int s_ind; // Convenience type definition // Define a Lambda-function to calculate (lower triangle of) the matrix Qa auto&& getQ = [this](Matrix& Q, const SymmTensor& Ma, double C) { if (C == 0.0) return; auto&& Mult = [Ma](s_ind i, s_ind j, s_ind k, s_ind l) { return Ma(i,j)*Ma(k,l); }; s_ind i, j, k, l, is, js; // Normal stresses and strains for (i = 1; i <= nsd; i++) for (j = 1; j <= i; j++) Q(i,j) += C*Mult(i,i,j,j); is = nsd+1; for (i = 1; i < nsd; i++) for (j = i+1; j <= nsd; j++, is++) { // Shear stress coupled to normal strain for (k = 1; k <= nsd; k++) Q(is,k) += C*Mult(i,j,k,k); // Shear stress coupled to shear strain js = nsd+1; for (k = 1; k < nsd; k++) for (l = k+1; js <= is; l++, js++) Q(is,js) += C*Mult(i,j,k,l); } }; // Define a Lambda-function to calculate (lower triangle of) the matrix Gab auto&& getG = [this](Matrix& G, const SymmTensor& Ma, const SymmTensor& Mb, double C) { if (C == 0.0) return; auto&& Mult = [Ma,Mb](s_ind i, s_ind j, s_ind k, s_ind l) { return Ma(i,k)*Mb(j,l) + Ma(i,l)*Mb(j,k) + Mb(i,k)*Ma(j,l) + Mb(i,l)*Ma(j,k); }; s_ind i, j, k, l, is, js; // Normal stresses and strains for (i = 1; i <= nsd; i++) for (j = 1; j <= i; j++) G(i,j) += C*Mult(i,i,j,j); is = nsd+1; for (i = 1; i < nsd; i++) for (j = i+1; j <= nsd; j++, is++) { // Shear stress coupled to normal strain for (k = 1; k <= nsd; k++) G(is,k) += C*Mult(i,j,k,k); // Shear stress coupled to shear strain js = nsd+1; for (k = 1; k < nsd; k++) for (l = k+1; js <= is; l++, js++) G(is,js) += C*Mult(i,j,k,l); } }; // Evaluate the stress tangent assuming Voigt notation and symmetry for (a = 1; a <= nsd; a++) for (b = 1; b <= a; b++) (*dSdE)(a,b) = C0; for (a = 0; a < nsd; a++) { double C1 = eps[a] >= 0.0 ? Cp : mu; getQ(*dSdE, M[a], 2.0*C1); if (eps[a] != 0.0) for (b = 0; b < nsd; b++) if (a != b && eps[a] != eps[b]) getG(*dSdE,M[a],M[b],C1/(1.0-eps[b]/eps[a])); } // Account for symmetry for (b = 2; b <= dSdE->rows(); b++) for (a = 1; a < b; a++) (*dSdE)(a,b) = (*dSdE)(b,a); return true; }