template out the plasma neutrino derivatives

networks/CNO_extras/actual_rhs.H

@@ -794,8 +794,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -1197,7 +1197,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);

networks/ECSN/actual_rhs.H

@@ -412,8 +412,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, dsnuda, dsnudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, dsnuda, dsnudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, dsnuda, dsnudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -629,7 +629,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, dsnuda, dsnudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, dsnuda, dsnudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, dsnuda, dsnudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * dsnuda + (zion[j-1] - state.zbar) * state.abar * dsnudz);

networks/ase/actual_rhs.H

@@ -1093,8 +1093,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -1646,7 +1646,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);

networks/ignition_reaclib/C-burn-simple/actual_rhs.H

@@ -212,8 +212,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -309,7 +309,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);

networks/ignition_reaclib/URCA-simple/actual_rhs.H

@@ -234,8 +234,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -343,7 +343,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);

networks/nova/actual_rhs.H

@@ -487,8 +487,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -746,7 +746,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);

networks/nova2/actual_rhs.H

@@ -727,8 +727,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -1058,7 +1058,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);

networks/partition_test/actual_rhs.H

@@ -202,8 +202,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -335,7 +335,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);

networks/rhs.H

@@ -1348,9 +1348,10 @@ void rhs (burn_t& burn_state, Array1D<Real, 1, nrhs>& ydot)
 
     // Evaluate the neutrino cooling.
 #ifdef NEUTRINOS
+    constexpr int do_derivatives{0};
     Real sneut, dsneutdt, dsneutdd, dsnuda, dsnudz;
-    sneut5(burn_state.T, burn_state.rho, burn_state.abar, burn_state.zbar,
-           sneut, dsneutdt, dsneutdd, dsnuda, dsnudz);
+    sneut5<do_derivatives>(burn_state.T, burn_state.rho, burn_state.abar, burn_state.zbar,
+                           sneut, dsneutdt, dsneutdd, dsnuda, dsnudz);
 #else
     Real sneut = 0.0;
 #endif
@@ -1495,8 +1496,9 @@ void jac (burn_t& burn_state, ArrayUtil::MathArray2D<1, neqs, 1, neqs>& jac)
     // Evaluate the neutrino cooling.
 #ifdef NEUTRINOS
     Real sneut, dsneutdt, dsneutdd, dsnuda, dsnudz;
-    sneut5(burn_state.T, burn_state.rho, burn_state.abar, burn_state.zbar,
-           sneut, dsneutdt, dsneutdd, dsnuda, dsnudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(burn_state.T, burn_state.rho, burn_state.abar, burn_state.zbar,
+                           sneut, dsneutdt, dsneutdd, dsnuda, dsnudz);
 #else
     Real sneut = 0.0, dsneutdt = 0.0, dsneutdd = 0.0, dsnuda = 0.0, dsnudz = 0.0;
     amrex::ignore_unused(sneut, dsneutdd);

networks/sn160/actual_rhs.H

@@ -10396,8 +10396,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -18028,7 +18028,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);

networks/subch_approx/actual_rhs.H

@@ -1375,8 +1375,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -1928,7 +1928,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);

networks/subch_full/actual_rhs.H

@@ -1603,8 +1603,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -2390,7 +2390,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);

networks/subch_simple/actual_rhs.H

@@ -1227,8 +1227,8 @@ void actual_rhs (burn_t& state, Array1D<Real, 1, neqs>& ydot)
     // Get the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{0};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     // Append the energy equation (this is erg/g/s)
 
@@ -1723,7 +1723,8 @@ void actual_jac(const burn_t& state, MatrixType& jac)
     // Account for the thermal neutrino losses
 
     Real sneut, dsneutdt, dsneutdd, snuda, snudz;
-    sneut5(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
+    constexpr int do_derivatives{1};
+    sneut5<do_derivatives>(state.T, state.rho, state.abar, state.zbar, sneut, dsneutdt, dsneutdd, snuda, snudz);
 
     for (int j = 1; j <= NumSpec; ++j) {
        Real b1 = (-state.abar * state.abar * snuda + (zion[j-1] - state.zbar) * state.abar * snudz);