xref: /libCEED/include/ceed/jit-source/cuda/cuda-ref-operator-assemble-diagonal.h (revision d15030167e504f21b69a912dc34420b169f681b5) 
1 // Copyright (c) 2017-2026, Lawrence Livermore National Security, LLC and other CEED contributors.
2 // All Rights Reserved. See the top-level LICENSE and NOTICE files for details.
3 //
4 // SPDX-License-Identifier: BSD-2-Clause
5 //
6 // This file is part of CEED:  http://github.com/ceed
7 
8 /// @file
9 /// Internal header for CUDA operator diagonal assembly
10 #include <ceed/types.h>
11 
12 #if USE_CEEDSIZE
13 typedef CeedSize IndexType;
14 #else
15 typedef CeedInt IndexType;
16 #endif
17 
18 //------------------------------------------------------------------------------
19 // Get basis pointer
20 //------------------------------------------------------------------------------
21 static __device__ __inline__ void GetBasisPointer(const CeedScalar **basis_ptr, CeedEvalMode eval_modes, const CeedScalar *identity,
22                                                   const CeedScalar *interp, const CeedScalar *grad, const CeedScalar *div, const CeedScalar *curl) {
23   switch (eval_modes) {
24     case CEED_EVAL_NONE:
25       *basis_ptr = identity;
26       break;
27     case CEED_EVAL_INTERP:
28       *basis_ptr = interp;
29       break;
30     case CEED_EVAL_GRAD:
31       *basis_ptr = grad;
32       break;
33     case CEED_EVAL_DIV:
34       *basis_ptr = div;
35       break;
36     case CEED_EVAL_CURL:
37       *basis_ptr = curl;
38       break;
39     case CEED_EVAL_WEIGHT:
40       break;  // Caught by QF assembly
41   }
42 }
43 
44 //------------------------------------------------------------------------------
45 // Core code for diagonal assembly
46 //------------------------------------------------------------------------------
47 extern "C" __launch_bounds__(BLOCK_SIZE) __global__
48     void LinearDiagonal(const CeedInt num_elem, const CeedScalar *identity, const CeedScalar *interp_in, const CeedScalar *grad_in,
49                         const CeedScalar *div_in, const CeedScalar *curl_in, const CeedScalar *interp_out, const CeedScalar *grad_out,
50                         const CeedScalar *div_out, const CeedScalar *curl_out, const CeedEvalMode *eval_modes_in, const CeedEvalMode *eval_modes_out,
51                         const CeedScalar *__restrict__ assembled_qf_array, CeedScalar *__restrict__ elem_diag_array) {
52   const int tid = threadIdx.x;  // Running with P threads
53 
54   if (tid >= NUM_NODES) return;
55 
56   // Compute the diagonal of B^T D B
57   // Each element
58   for (IndexType e = blockIdx.x * blockDim.z + threadIdx.z; e < num_elem; e += gridDim.x * blockDim.z) {
59     // Each basis eval mode pair
60     IndexType    d_out               = 0;
61     CeedEvalMode eval_modes_out_prev = CEED_EVAL_NONE;
62 
63     for (IndexType e_out = 0; e_out < NUM_EVAL_MODES_OUT; e_out++) {
64       IndexType         d_in               = 0;
65       CeedEvalMode      eval_modes_in_prev = CEED_EVAL_NONE;
66       const CeedScalar *b_t                = NULL;
67 
68       GetBasisPointer(&b_t, eval_modes_out[e_out], identity, interp_out, grad_out, div_out, curl_out);
69       if (e_out == 0 || eval_modes_out[e_out] != eval_modes_out_prev) d_out = 0;
70       else b_t = &b_t[(++d_out) * NUM_QPTS * NUM_NODES];
71       eval_modes_out_prev = eval_modes_out[e_out];
72 
73       for (IndexType e_in = 0; e_in < NUM_EVAL_MODES_IN; e_in++) {
74         const CeedScalar *b = NULL;
75 
76         GetBasisPointer(&b, eval_modes_in[e_in], identity, interp_in, grad_in, div_in, curl_in);
77         if (e_in == 0 || eval_modes_in[e_in] != eval_modes_in_prev) d_in = 0;
78         else b = &b[(++d_in) * NUM_QPTS * NUM_NODES];
79         eval_modes_in_prev = eval_modes_in[e_in];
80 
81         // Each component
82         for (IndexType comp_out = 0; comp_out < NUM_COMP; comp_out++) {
83 #if USE_POINT_BLOCK
84           // Point block diagonal
85           for (IndexType comp_in = 0; comp_in < NUM_COMP; comp_in++) {
86             CeedScalar e_value = 0.;
87 
88             // Each qpoint/node pair
89             for (IndexType q = 0; q < NUM_QPTS; q++) {
90               const CeedScalar qf_value =
91                   assembled_qf_array[((((e_in * NUM_COMP + comp_in) * NUM_EVAL_MODES_OUT + e_out) * NUM_COMP + comp_out) * num_elem + e) * NUM_QPTS +
92                                      q];
93 
94               e_value += b_t[q * NUM_NODES + tid] * qf_value * b[q * NUM_NODES + tid];
95             }
96             elem_diag_array[((comp_out * NUM_COMP + comp_in) * num_elem + e) * NUM_NODES + tid] += e_value;
97           }
98 #else
99           // Diagonal only
100           CeedScalar e_value = 0.;
101 
102           // Each qpoint/node pair
103           for (IndexType q = 0; q < NUM_QPTS; q++) {
104             const CeedScalar qf_value =
105                 assembled_qf_array[((((e_in * NUM_COMP + comp_out) * NUM_EVAL_MODES_OUT + e_out) * NUM_COMP + comp_out) * num_elem + e) * NUM_QPTS +
106                                    q];
107 
108             e_value += b_t[q * NUM_NODES + tid] * qf_value * b[q * NUM_NODES + tid];
109           }
110           elem_diag_array[(comp_out * num_elem + e) * NUM_NODES + tid] += e_value;
111 #endif
112         }
113       }
114     }
115   }
116 }
117