[614] | 1 | !-------------------------------------------------------------------------- |
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| 2 | !---------------------------- caldyn_solver ---------------------------------- |
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| 3 | ! |
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| 4 | ! Compute pressure (pres) and Exner function (pk) |
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| 5 | ! kappa = R/Cp |
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| 6 | ! 1-kappa = Cv/Cp |
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| 7 | ! Cp/Cv = 1/(1-kappa) |
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| 8 | gamma = 1./(1.-kappa) |
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| 9 | vreff = Rd*Treff/preff ! reference specific volume |
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[658] | 10 | Cvd = 1./(cpp-Rd) |
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| 11 | Rd_preff = kappa*cpp/preff |
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[614] | 12 | SELECT CASE(caldyn_thermo) |
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| 13 | CASE(thermo_theta) |
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| 14 | !$OMP DO SCHEDULE(STATIC) |
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| 15 | DO ij = 1, primal_num |
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[658] | 16 | !DIR$ SIMD |
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[614] | 17 | DO l = 1, llm |
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[658] | 18 | rho_ij = 1./(geopot(l+1,ij)-geopot(l,ij)) |
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| 19 | rho_ij = rho_ij*g*rhodz(l,ij) |
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| 20 | X_ij = Rd_preff*theta(l,ij,1)*rho_ij |
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[614] | 21 | ! kappa.theta.rho = p/exner |
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| 22 | ! => X = (p/p0)/(exner/Cp) |
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| 23 | ! = (p/p0)^(1-kappa) |
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| 24 | pres(l,ij) = preff*(X_ij**gamma) ! pressure |
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| 25 | ! Compute Exner function (needed by compute_caldyn_fast) |
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| 26 | ! other formulae possible if exponentiation is slow |
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| 27 | pk(l,ij) = cpp*((pres(l,ij)/preff)**kappa) ! Exner |
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| 28 | END DO |
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| 29 | END DO |
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| 30 | !$OMP END DO |
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| 31 | CASE(thermo_entropy) |
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| 32 | !$OMP DO SCHEDULE(STATIC) |
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| 33 | DO ij = 1, primal_num |
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[658] | 34 | !DIR$ SIMD |
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[614] | 35 | DO l = 1, llm |
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[658] | 36 | rho_ij = 1./(geopot(l+1,ij)-geopot(l,ij)) |
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| 37 | rho_ij = rho_ij*g*rhodz(l,ij) |
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| 38 | T_ij = Treff*exp( (theta(l,ij,1)+Rd*log(vreff*rho_ij))*Cvd ) |
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[614] | 39 | pres(l,ij) = rho_ij*Rd*T_ij |
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| 40 | pk(l,ij) = T_ij |
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| 41 | END DO |
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| 42 | END DO |
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| 43 | !$OMP END DO |
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| 44 | CASE DEFAULT |
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| 45 | STOP |
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| 46 | END SELECT |
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| 47 | ! We need a barrier here because we compute pres above and do a vertical difference below |
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| 48 | !$OMP BARRIER |
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| 49 | !$OMP DO SCHEDULE(STATIC) |
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| 50 | DO ij = 1, primal_num |
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| 51 | l=1 |
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| 52 | ! Lower BC |
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| 53 | dW(l,ij) = (1./g)*(pbot-rho_bot*(geopot(l,ij)-PHI_BOT(ij))-pres(l,ij)) - m_il(l,ij) |
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| 54 | W(l,ij) = W(l,ij)+tau*dW(l,ij) ! update W |
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| 55 | dPhi(l,ij) = g*g*W(l,ij)/m_il(l,ij) |
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[658] | 56 | !DIR$ SIMD |
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[614] | 57 | DO l = 2, llm |
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| 58 | dW(l,ij) = (1./g)*(pres(l-1,ij)-pres(l,ij)) - m_il(l,ij) |
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| 59 | W(l,ij) = W(l,ij)+tau*dW(l,ij) ! update W |
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| 60 | dPhi(l,ij) = g*g*W(l,ij)/m_il(l,ij) |
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| 61 | END DO |
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| 62 | l=llm+1 |
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| 63 | ! Top BC |
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| 64 | dW(l,ij) = (1./g)*(pres(l-1,ij)-ptop) - m_il(l,ij) |
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| 65 | W(l,ij) = W(l,ij)+tau*dW(l,ij) ! update W |
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| 66 | dPhi(l,ij) = g*g*W(l,ij)/m_il(l,ij) |
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| 67 | END DO |
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| 68 | !$OMP END DO |
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| 69 | ! We need a barrier here because we update W above and do a vertical average below |
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| 70 | !$OMP BARRIER |
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| 71 | !$OMP DO SCHEDULE(STATIC) |
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| 72 | DO ij = 1, primal_num |
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[658] | 73 | !DIR$ SIMD |
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[614] | 74 | DO l = 1, llm |
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| 75 | ! compute du = -0.5*g^2.grad(w^2) |
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| 76 | berni(l,ij) = (-.25*g*g)*((W(l,ij)/m_il(l,ij))**2 + (W(l+1,ij)/m_il(l+1,ij))**2 ) |
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| 77 | END DO |
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| 78 | END DO |
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| 79 | !$OMP END DO |
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| 80 | !$OMP DO SCHEDULE(STATIC) |
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| 81 | DO edge = 1, edge_num |
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| 82 | ij_left = left(edge) |
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| 83 | ij_right = right(edge) |
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[658] | 84 | !DIR$ SIMD |
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[614] | 85 | DO l = 1, llm |
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| 86 | du(l,edge) = 1.*(berni(l,ij_left)-berni(l,ij_right)) |
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| 87 | END DO |
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| 88 | END DO |
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| 89 | !$OMP END DO |
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| 90 | !---------------------------- caldyn_solver ---------------------------------- |
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| 91 | !-------------------------------------------------------------------------- |
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