sci-form 0.14.4

High-performance 3D molecular conformer generation using ETKDG distance geometry
Documentation 
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266

//! Analytical gradients for PM3 NDDO calculations.
//!
//! Computes dE/dR for each atom using the converged SCF density matrix
//! and the Hellmann-Feynman + Pulay force expression:
//!
//!   dE/dR_Aα = Tr(P·∂H/∂R_Aα) + 0.5·Tr(P·∂G/∂R_Aα) − Tr(W·∂S/∂R_Aα) + ∂E_nuc/∂R_Aα
//!
//! Nuclear repulsion and Coulomb derivatives are fully analytical.
//! Overlap derivatives use micro-numerical finite differences on the STO
//! overlap function (NOT on the SCF energy).

use nalgebra::DMatrix;
use serde::{Deserialize, Serialize};

use super::params::get_pm3_params;
use super::solver::{
    screened_coulomb_gamma_derivative_ev_per_angstrom, screened_coulomb_gamma_ev,
    solve_pm3_with_state, sto_ss_overlap, ANGSTROM_TO_BOHR,
};

/// Result of PM3 gradient computation.
#[derive(Debug, Clone, Serialize, Deserialize)]
pub struct Pm3GradientResult {
    /// Energy gradient dE/dR per atom in eV/Å.
    pub gradients: Vec<[f64; 3]>,
    /// Total PM3 energy in eV.
    pub energy: f64,
    /// Heat of formation in kcal/mol.
    pub heat_of_formation: f64,
}

/// Compute analytical PM3 energy gradients.
///
/// Runs a full PM3 SCF, then computes the gradient from the converged
/// density matrix using Hellmann-Feynman + Pulay corrections.
///
/// Returns gradient dE/dR in eV/Å for each atom.
pub fn compute_pm3_gradient(
    elements: &[u8],
    positions: &[[f64; 3]],
) -> Result<Pm3GradientResult, String> {
    let (result, state) = solve_pm3_with_state(elements, positions)?;

    let n_atoms = elements.len();
    let n_basis = state.basis_map.len();
    let n_occ = state.n_occ;

    // Build energy-weighted density matrix: W_μν = 2·Σ_{k∈occ} ε_k·C_μk·C_νk
    let mut w_mat = DMatrix::zeros(n_basis, n_basis);
    for i in 0..n_basis {
        for j in 0..n_basis {
            let mut val = 0.0;
            for k in 0..n_occ.min(n_basis) {
                val += state.orbital_energies[k]
                    * state.coefficients[(i, k)]
                    * state.coefficients[(j, k)];
            }
            w_mat[(i, j)] = 2.0 * val;
        }
    }

    // Compute atom populations for two-center Coulomb
    let mut atom_pop = vec![0.0f64; n_atoms];
    for mu in 0..n_basis {
        atom_pop[state.basis_map[mu].0] += state.density[(mu, mu)];
    }

    let mut gradients = vec![[0.0f64; 3]; n_atoms];
    let h_step = 1e-6; // micro-numerical step for overlap derivative (bohr)

    // Compute per-pair gradient contributions
    let compute_pair = |a: usize, b: usize| -> [f64; 3] {
        let pa = get_pm3_params(elements[a]).unwrap();
        let pb = get_pm3_params(elements[b]).unwrap();

        let dx = positions[a][0] - positions[b][0];
        let dy = positions[a][1] - positions[b][1];
        let dz = positions[a][2] - positions[b][2];
        let r_ang = (dx * dx + dy * dy + dz * dz).sqrt();
        if r_ang < 0.01 {
            return [0.0; 3];
        }

        let r_bohr = r_ang * ANGSTROM_TO_BOHR;
        let dir = [dx / r_ang, dy / r_ang, dz / r_ang];
        let mut grad_a = [0.0f64; 3];

        // ── 1. Nuclear repulsion gradient (fully analytical) ──
        let gamma = screened_coulomb_gamma_ev(r_bohr);
        let dgamma_dr_ang = screened_coulomb_gamma_derivative_ev_per_angstrom(r_bohr);

        let alpha_a_term = (-pa.alpha * r_ang).exp();
        let alpha_b_term = (-pb.alpha * r_ang).exp();
        let alpha_term = alpha_a_term + alpha_b_term;
        let dalpha_dr = -pa.alpha * alpha_a_term - pb.alpha * alpha_b_term;

        let de_nuc_dr = pa.core_charge
            * pb.core_charge
            * (dgamma_dr_ang * (1.0 + alpha_term) + gamma * dalpha_dr);

        for d in 0..3 {
            grad_a[d] += de_nuc_dr * dir[d];
        }

        // ── 2. Two-center electron Coulomb gradient (analytical) ──
        let de_2c_dr = atom_pop[a] * atom_pop[b] * dgamma_dr_ang;
        for d in 0..3 {
            grad_a[d] += de_2c_dr * dir[d];
        }

        // ── 3. Hellmann-Feynman + Pulay (overlap-dependent) ──
        for mu in 0..n_basis {
            if state.basis_map[mu].0 != a {
                continue;
            }
            let la = state.basis_map[mu].1;

            for nu in 0..n_basis {
                if state.basis_map[nu].0 != b {
                    continue;
                }
                let lb = state.basis_map[nu].1;

                let za = if la == 0 { pa.zeta_s } else { pa.zeta_p };
                let zb = if lb == 0 { pb.zeta_s } else { pb.zeta_p };

                let s_plus = sto_ss_overlap(za, zb, r_bohr + h_step);
                let s_minus = sto_ss_overlap(za, zb, r_bohr - h_step);
                let mut ds_dr_bohr = (s_plus - s_minus) / (2.0 * h_step);

                if la != 0 || lb != 0 {
                    ds_dr_bohr *= 0.5;
                }

                let ds_dr_ang = ds_dr_bohr * ANGSTROM_TO_BOHR;

                let beta_mu = if la == 0 { pa.beta_s } else { pa.beta_p };
                let beta_nu = if lb == 0 { pb.beta_s } else { pb.beta_p };
                let dh_dr = 0.5 * (beta_mu + beta_nu) * ds_dr_ang;

                let p_mn = state.density[(mu, nu)];
                let w_mn = w_mat[(mu, nu)];
                let force = 2.0 * (p_mn * dh_dr - w_mn * ds_dr_ang);

                for d in 0..3 {
                    grad_a[d] += force * dir[d];
                }
            }
        }

        grad_a
    };

    // Generate all pairs
    let pairs: Vec<(usize, usize)> = (0..n_atoms)
        .flat_map(|a| ((a + 1)..n_atoms).map(move |b| (a, b)))
        .collect();

    #[cfg(feature = "parallel")]
    {
        use rayon::prelude::*;
        let pair_grads: Vec<(usize, usize, [f64; 3])> = pairs
            .par_iter()
            .map(|&(a, b)| {
                let g = compute_pair(a, b);
                (a, b, g)
            })
            .collect();
        for (a, b, g) in pair_grads {
            for d in 0..3 {
                gradients[a][d] += g[d];
                gradients[b][d] -= g[d];
            }
        }
    }

    #[cfg(not(feature = "parallel"))]
    {
        for &(a, b) in &pairs {
            let g = compute_pair(a, b);
            for d in 0..3 {
                gradients[a][d] += g[d];
                gradients[b][d] -= g[d];
            }
        }
    }

    Ok(Pm3GradientResult {
        gradients,
        energy: result.total_energy,
        heat_of_formation: result.heat_of_formation,
    })
}

#[cfg(test)]
mod tests {
    use super::super::solver::solve_pm3;
    use super::*;

    #[test]
    fn test_pm3_gradient_h2() {
        let elements = [1u8, 1];
        let positions = [[0.0, 0.0, 0.0], [0.74, 0.0, 0.0]];
        let result = compute_pm3_gradient(&elements, &positions).unwrap();
        assert_eq!(result.gradients.len(), 2);
        assert!(result.energy.is_finite());
        // By Newton's third law, forces must be equal and opposite
        for d in 0..3 {
            assert!(
                (result.gradients[0][d] + result.gradients[1][d]).abs() < 0.1,
                "Forces not equal and opposite: {:?}",
                result.gradients
            );
        }
    }

    #[test]
    fn test_pm3_gradient_water() {
        let elements = [8u8, 1, 1];
        let positions = [[0.0, 0.0, 0.0], [0.757, 0.586, 0.0], [-0.757, 0.586, 0.0]];
        let result = compute_pm3_gradient(&elements, &positions).unwrap();
        assert_eq!(result.gradients.len(), 3);
        for g in &result.gradients {
            for &v in g {
                assert!(v.is_finite(), "Gradient must be finite");
            }
        }
        // Net force on molecule should be near zero (translational invariance)
        for d in 0..3 {
            let sum: f64 = result.gradients.iter().map(|g| g[d]).sum();
            assert!(
                sum.abs() < 1.0,
                "Net force should be near zero, got {sum:.4}"
            );
        }
    }

    #[test]
    fn test_pm3_gradient_vs_numerical() {
        let elements = [1u8, 1];
        let positions = [[0.0, 0.0, 0.0], [0.74, 0.0, 0.0]];
        let analytical = compute_pm3_gradient(&elements, &positions).unwrap();

        let h = 1e-5;
        for a in 0..2 {
            for d in 0..3 {
                let mut pos_p = positions.to_vec();
                let mut pos_m = positions.to_vec();
                pos_p[a][d] += h;
                pos_m[a][d] -= h;
                let e_p = solve_pm3(&elements, &pos_p).unwrap().total_energy;
                let e_m = solve_pm3(&elements, &pos_m).unwrap().total_energy;
                let numerical = (e_p - e_m) / (2.0 * h);
                let diff = (analytical.gradients[a][d] - numerical).abs();
                let scale = numerical.abs().max(1.0);
                assert!(
                    diff / scale < 0.5,
                    "Gradient mismatch atom {a} dir {d}: analytical={:.6} numerical={:.6} diff={:.6}",
                    analytical.gradients[a][d],
                    numerical,
                    diff
                );
            }
        }
    }
}