#include <ceed.h>
#include <ceed/backend.h>
#include <ceed/jit-tools.h>
#include <assert.h>
#include <stdbool.h>
#include <string.h>
#include <hip/hip_runtime.h>
#include "../hip/ceed-hip-common.h"
#include "../hip/ceed-hip-compile.h"
#include "ceed-hip-ref.h"
static int CeedOperatorDestroy_Hip(CeedOperator op) {
CeedOperator_Hip *impl;
CeedCallBackend(CeedOperatorGetData(op, &impl));
for (CeedInt i = 0; i < impl->num_inputs + impl->num_outputs; i++) {
CeedCallBackend(CeedVectorDestroy(&impl->e_vecs[i]));
}
CeedCallBackend(CeedFree(&impl->e_vecs));
for (CeedInt i = 0; i < impl->num_inputs; i++) {
CeedCallBackend(CeedVectorDestroy(&impl->q_vecs_in[i]));
}
CeedCallBackend(CeedFree(&impl->q_vecs_in));
for (CeedInt i = 0; i < impl->num_outputs; i++) {
CeedCallBackend(CeedVectorDestroy(&impl->q_vecs_out[i]));
}
CeedCallBackend(CeedFree(&impl->q_vecs_out));
for (CeedInt i = 0; i < impl->num_active_in; i++) {
CeedCallBackend(CeedVectorDestroy(&impl->qf_active_in[i]));
}
CeedCallBackend(CeedFree(&impl->qf_active_in));
if (impl->diag) {
Ceed ceed;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
CeedCallHip(ceed, hipModuleUnload(impl->diag->module));
CeedCallBackend(CeedFree(&impl->diag->h_e_mode_in));
CeedCallBackend(CeedFree(&impl->diag->h_e_mode_out));
CeedCallHip(ceed, hipFree(impl->diag->d_e_mode_in));
CeedCallHip(ceed, hipFree(impl->diag->d_e_mode_out));
CeedCallHip(ceed, hipFree(impl->diag->d_identity));
CeedCallHip(ceed, hipFree(impl->diag->d_interp_in));
CeedCallHip(ceed, hipFree(impl->diag->d_interp_out));
CeedCallHip(ceed, hipFree(impl->diag->d_grad_in));
CeedCallHip(ceed, hipFree(impl->diag->d_grad_out));
CeedCallBackend(CeedElemRestrictionDestroy(&impl->diag->point_block_diag_rstr));
CeedCallBackend(CeedVectorDestroy(&impl->diag->elem_diag));
CeedCallBackend(CeedVectorDestroy(&impl->diag->point_block_elem_diag));
}
CeedCallBackend(CeedFree(&impl->diag));
if (impl->asmb) {
Ceed ceed;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
CeedCallHip(ceed, hipModuleUnload(impl->asmb->module));
CeedCallHip(ceed, hipFree(impl->asmb->d_B_in));
CeedCallHip(ceed, hipFree(impl->asmb->d_B_out));
}
CeedCallBackend(CeedFree(&impl->asmb));
CeedCallBackend(CeedFree(&impl));
return CEED_ERROR_SUCCESS;
}
static int CeedOperatorSetupFields_Hip(CeedQFunction qf, CeedOperator op, bool is_input, CeedVector *e_vecs, CeedVector *q_vecs, CeedInt start_e,
CeedInt num_fields, CeedInt Q, CeedInt num_elem) {
Ceed ceed;
CeedQFunctionField *qf_fields;
CeedOperatorField *op_fields;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
if (is_input) {
CeedCallBackend(CeedOperatorGetFields(op, NULL, &op_fields, NULL, NULL));
CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_fields, NULL, NULL));
} else {
CeedCallBackend(CeedOperatorGetFields(op, NULL, NULL, NULL, &op_fields));
CeedCallBackend(CeedQFunctionGetFields(qf, NULL, NULL, NULL, &qf_fields));
}
for (CeedInt i = 0; i < num_fields; i++) {
bool is_strided, skip_restriction;
CeedSize q_size;
CeedInt dim, size;
CeedEvalMode e_mode;
CeedVector vec;
CeedElemRestriction elem_rstr;
CeedBasis basis;
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_fields[i], &e_mode));
is_strided = false;
skip_restriction = false;
if (e_mode != CEED_EVAL_WEIGHT) {
CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_fields[i], &elem_rstr));
if (is_input) {
CeedCallBackend(CeedOperatorFieldGetVector(op_fields[i], &vec));
if (vec != CEED_VECTOR_ACTIVE) {
if (e_mode == CEED_EVAL_NONE) {
CeedCallBackend(CeedElemRestrictionIsStrided(elem_rstr, &is_strided));
if (is_strided) {
CeedCallBackend(CeedElemRestrictionHasBackendStrides(elem_rstr, &skip_restriction));
}
}
}
}
if (skip_restriction) {
e_vecs[i + start_e] = NULL;
} else {
CeedCallBackend(CeedElemRestrictionCreateVector(elem_rstr, NULL, &e_vecs[i + start_e]));
}
}
switch (e_mode) {
case CEED_EVAL_NONE:
CeedCallBackend(CeedQFunctionFieldGetSize(qf_fields[i], &size));
q_size = (CeedSize)num_elem * Q * size;
CeedCallBackend(CeedVectorCreate(ceed, q_size, &q_vecs[i]));
break;
case CEED_EVAL_INTERP:
CeedCallBackend(CeedQFunctionFieldGetSize(qf_fields[i], &size));
q_size = (CeedSize)num_elem * Q * size;
CeedCallBackend(CeedVectorCreate(ceed, q_size, &q_vecs[i]));
break;
case CEED_EVAL_GRAD:
CeedCallBackend(CeedOperatorFieldGetBasis(op_fields[i], &basis));
CeedCallBackend(CeedQFunctionFieldGetSize(qf_fields[i], &size));
CeedCallBackend(CeedBasisGetDimension(basis, &dim));
q_size = (CeedSize)num_elem * Q * size;
CeedCallBackend(CeedVectorCreate(ceed, q_size, &q_vecs[i]));
break;
case CEED_EVAL_WEIGHT: CeedCallBackend(CeedOperatorFieldGetBasis(op_fields[i], &basis));
q_size = (CeedSize)num_elem * Q;
CeedCallBackend(CeedVectorCreate(ceed, q_size, &q_vecs[i]));
CeedCallBackend(CeedBasisApply(basis, num_elem, CEED_NOTRANSPOSE, CEED_EVAL_WEIGHT, CEED_VECTOR_NONE, q_vecs[i]));
break;
case CEED_EVAL_DIV:
break; case CEED_EVAL_CURL:
break; }
}
return CEED_ERROR_SUCCESS;
}
static int CeedOperatorSetup_Hip(CeedOperator op) {
Ceed ceed;
bool is_setup_done;
CeedInt Q, num_elem, num_input_fields, num_output_fields;
CeedQFunctionField *qf_input_fields, *qf_output_fields;
CeedQFunction qf;
CeedOperatorField *op_input_fields, *op_output_fields;
CeedOperator_Hip *impl;
CeedCallBackend(CeedOperatorIsSetupDone(op, &is_setup_done));
if (is_setup_done) return CEED_ERROR_SUCCESS;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
CeedCallBackend(CeedOperatorGetData(op, &impl));
CeedCallBackend(CeedOperatorGetQFunction(op, &qf));
CeedCallBackend(CeedOperatorGetNumQuadraturePoints(op, &Q));
CeedCallBackend(CeedOperatorGetNumElements(op, &num_elem));
CeedCallBackend(CeedOperatorGetFields(op, &num_input_fields, &op_input_fields, &num_output_fields, &op_output_fields));
CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_input_fields, NULL, &qf_output_fields));
CeedCallBackend(CeedCalloc(num_input_fields + num_output_fields, &impl->e_vecs));
CeedCallBackend(CeedCalloc(CEED_FIELD_MAX, &impl->q_vecs_in));
CeedCallBackend(CeedCalloc(CEED_FIELD_MAX, &impl->q_vecs_out));
impl->num_inputs = num_input_fields;
impl->num_outputs = num_output_fields;
CeedCallBackend(CeedOperatorSetupFields_Hip(qf, op, true, impl->e_vecs, impl->q_vecs_in, 0, num_input_fields, Q, num_elem));
CeedCallBackend(CeedOperatorSetupFields_Hip(qf, op, false, impl->e_vecs, impl->q_vecs_out, num_input_fields, num_output_fields, Q, num_elem));
CeedCallBackend(CeedOperatorSetSetupDone(op));
return CEED_ERROR_SUCCESS;
}
static inline int CeedOperatorSetupInputs_Hip(CeedInt num_input_fields, CeedQFunctionField *qf_input_fields, CeedOperatorField *op_input_fields,
CeedVector in_vec, const bool skip_active, CeedScalar *e_data[2 * CEED_FIELD_MAX],
CeedOperator_Hip *impl, CeedRequest *request) {
for (CeedInt i = 0; i < num_input_fields; i++) {
CeedEvalMode e_mode;
CeedVector vec;
CeedElemRestriction elem_rstr;
CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec));
if (vec == CEED_VECTOR_ACTIVE) {
if (skip_active) continue;
else vec = in_vec;
}
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_input_fields[i], &e_mode));
if (e_mode == CEED_EVAL_WEIGHT) { } else {
CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec));
CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_input_fields[i], &elem_rstr));
if (vec == CEED_VECTOR_ACTIVE) vec = in_vec;
if (!impl->e_vecs[i]) {
CeedCallBackend(CeedVectorGetArrayRead(vec, CEED_MEM_DEVICE, (const CeedScalar **)&e_data[i]));
} else {
CeedCallBackend(CeedElemRestrictionApply(elem_rstr, CEED_NOTRANSPOSE, vec, impl->e_vecs[i], request));
CeedCallBackend(CeedVectorGetArrayRead(impl->e_vecs[i], CEED_MEM_DEVICE, (const CeedScalar **)&e_data[i]));
}
}
}
return CEED_ERROR_SUCCESS;
}
static inline int CeedOperatorInputBasis_Hip(CeedInt num_elem, CeedQFunctionField *qf_input_fields, CeedOperatorField *op_input_fields,
CeedInt num_input_fields, const bool skip_active, CeedScalar *e_data[2 * CEED_FIELD_MAX],
CeedOperator_Hip *impl) {
for (CeedInt i = 0; i < num_input_fields; i++) {
CeedInt elem_size, size;
CeedEvalMode e_mode;
CeedElemRestriction elem_rstr;
CeedBasis basis;
if (skip_active) {
CeedVector vec;
CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec));
if (vec == CEED_VECTOR_ACTIVE) continue;
}
CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_input_fields[i], &elem_rstr));
CeedCallBackend(CeedElemRestrictionGetElementSize(elem_rstr, &elem_size));
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_input_fields[i], &e_mode));
CeedCallBackend(CeedQFunctionFieldGetSize(qf_input_fields[i], &size));
switch (e_mode) {
case CEED_EVAL_NONE:
CeedCallBackend(CeedVectorSetArray(impl->q_vecs_in[i], CEED_MEM_DEVICE, CEED_USE_POINTER, e_data[i]));
break;
case CEED_EVAL_INTERP:
CeedCallBackend(CeedOperatorFieldGetBasis(op_input_fields[i], &basis));
CeedCallBackend(CeedBasisApply(basis, num_elem, CEED_NOTRANSPOSE, CEED_EVAL_INTERP, impl->e_vecs[i], impl->q_vecs_in[i]));
break;
case CEED_EVAL_GRAD:
CeedCallBackend(CeedOperatorFieldGetBasis(op_input_fields[i], &basis));
CeedCallBackend(CeedBasisApply(basis, num_elem, CEED_NOTRANSPOSE, CEED_EVAL_GRAD, impl->e_vecs[i], impl->q_vecs_in[i]));
break;
case CEED_EVAL_WEIGHT:
break; case CEED_EVAL_DIV:
break; case CEED_EVAL_CURL:
break; }
}
return CEED_ERROR_SUCCESS;
}
static inline int CeedOperatorRestoreInputs_Hip(CeedInt num_input_fields, CeedQFunctionField *qf_input_fields, CeedOperatorField *op_input_fields,
const bool skip_active, CeedScalar *e_data[2 * CEED_FIELD_MAX], CeedOperator_Hip *impl) {
for (CeedInt i = 0; i < num_input_fields; i++) {
CeedEvalMode e_mode;
CeedVector vec;
if (skip_active) {
CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec));
if (vec == CEED_VECTOR_ACTIVE) continue;
}
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_input_fields[i], &e_mode));
if (e_mode == CEED_EVAL_WEIGHT) { } else {
if (!impl->e_vecs[i]) { CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec));
CeedCallBackend(CeedVectorRestoreArrayRead(vec, (const CeedScalar **)&e_data[i]));
} else {
CeedCallBackend(CeedVectorRestoreArrayRead(impl->e_vecs[i], (const CeedScalar **)&e_data[i]));
}
}
}
return CEED_ERROR_SUCCESS;
}
static int CeedOperatorApplyAdd_Hip(CeedOperator op, CeedVector in_vec, CeedVector out_vec, CeedRequest *request) {
CeedInt Q, num_elem, elem_size, num_input_fields, num_output_fields, size;
CeedScalar *e_data[2 * CEED_FIELD_MAX] = {NULL};
CeedQFunctionField *qf_input_fields, *qf_output_fields;
CeedQFunction qf;
CeedOperatorField *op_input_fields, *op_output_fields;
CeedOperator_Hip *impl;
CeedCallBackend(CeedOperatorGetData(op, &impl));
CeedCallBackend(CeedOperatorGetQFunction(op, &qf));
CeedCallBackend(CeedOperatorGetNumQuadraturePoints(op, &Q));
CeedCallBackend(CeedOperatorGetNumElements(op, &num_elem));
CeedCallBackend(CeedOperatorGetFields(op, &num_input_fields, &op_input_fields, &num_output_fields, &op_output_fields));
CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_input_fields, NULL, &qf_output_fields));
CeedCallBackend(CeedOperatorSetup_Hip(op));
CeedCallBackend(CeedOperatorSetupInputs_Hip(num_input_fields, qf_input_fields, op_input_fields, in_vec, false, e_data, impl, request));
CeedCallBackend(CeedOperatorInputBasis_Hip(num_elem, qf_input_fields, op_input_fields, num_input_fields, false, e_data, impl));
for (CeedInt i = 0; i < num_output_fields; i++) {
CeedEvalMode e_mode;
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_output_fields[i], &e_mode));
if (e_mode == CEED_EVAL_NONE) {
CeedCallBackend(CeedVectorGetArrayWrite(impl->e_vecs[i + impl->num_inputs], CEED_MEM_DEVICE, &e_data[i + num_input_fields]));
CeedCallBackend(CeedVectorSetArray(impl->q_vecs_out[i], CEED_MEM_DEVICE, CEED_USE_POINTER, e_data[i + num_input_fields]));
}
}
CeedCallBackend(CeedQFunctionApply(qf, num_elem * Q, impl->q_vecs_in, impl->q_vecs_out));
for (CeedInt i = 0; i < num_output_fields; i++) {
CeedEvalMode e_mode;
CeedElemRestriction elem_rstr;
CeedBasis basis;
CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_output_fields[i], &elem_rstr));
CeedCallBackend(CeedElemRestrictionGetElementSize(elem_rstr, &elem_size));
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_output_fields[i], &e_mode));
CeedCallBackend(CeedQFunctionFieldGetSize(qf_output_fields[i], &size));
switch (e_mode) {
case CEED_EVAL_NONE:
break;
case CEED_EVAL_INTERP:
CeedCallBackend(CeedOperatorFieldGetBasis(op_output_fields[i], &basis));
CeedCallBackend(CeedBasisApply(basis, num_elem, CEED_TRANSPOSE, CEED_EVAL_INTERP, impl->q_vecs_out[i], impl->e_vecs[i + impl->num_inputs]));
break;
case CEED_EVAL_GRAD:
CeedCallBackend(CeedOperatorFieldGetBasis(op_output_fields[i], &basis));
CeedCallBackend(CeedBasisApply(basis, num_elem, CEED_TRANSPOSE, CEED_EVAL_GRAD, impl->q_vecs_out[i], impl->e_vecs[i + impl->num_inputs]));
break;
case CEED_EVAL_WEIGHT: {
Ceed ceed;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_WEIGHT cannot be an output evaluation mode");
break; }
case CEED_EVAL_DIV:
break; case CEED_EVAL_CURL:
break; }
}
for (CeedInt i = 0; i < num_output_fields; i++) {
CeedEvalMode e_mode;
CeedVector vec;
CeedElemRestriction elem_rstr;
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_output_fields[i], &e_mode));
if (e_mode == CEED_EVAL_NONE) {
CeedCallBackend(CeedVectorRestoreArray(impl->e_vecs[i + impl->num_inputs], &e_data[i + num_input_fields]));
}
CeedCallBackend(CeedOperatorFieldGetVector(op_output_fields[i], &vec));
CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_output_fields[i], &elem_rstr));
if (vec == CEED_VECTOR_ACTIVE) vec = out_vec;
CeedCallBackend(CeedElemRestrictionApply(elem_rstr, CEED_TRANSPOSE, impl->e_vecs[i + impl->num_inputs], vec, request));
}
CeedCallBackend(CeedOperatorRestoreInputs_Hip(num_input_fields, qf_input_fields, op_input_fields, false, e_data, impl));
return CEED_ERROR_SUCCESS;
}
static inline int CeedOperatorLinearAssembleQFunctionCore_Hip(CeedOperator op, bool build_objects, CeedVector *assembled, CeedElemRestriction *rstr,
CeedRequest *request) {
Ceed ceed, ceed_parent;
CeedSize q_size;
CeedInt num_active_in, num_active_out, Q, num_elem, num_input_fields, num_output_fields, size;
CeedScalar *assembled_array, *e_data[2 * CEED_FIELD_MAX] = {NULL};
CeedVector *active_in;
CeedQFunctionField *qf_input_fields, *qf_output_fields;
CeedQFunction qf;
CeedOperatorField *op_input_fields, *op_output_fields;
CeedOperator_Hip *impl;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
CeedCallBackend(CeedOperatorGetFallbackParentCeed(op, &ceed_parent));
CeedCallBackend(CeedOperatorGetData(op, &impl));
CeedCallBackend(CeedOperatorGetQFunction(op, &qf));
CeedCallBackend(CeedOperatorGetNumQuadraturePoints(op, &Q));
CeedCallBackend(CeedOperatorGetNumElements(op, &num_elem));
CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_input_fields, NULL, &qf_output_fields));
CeedCallBackend(CeedOperatorGetFields(op, &num_input_fields, &op_input_fields, &num_output_fields, &op_output_fields));
active_in = impl->qf_active_in;
num_active_in = impl->num_active_in;
num_active_out = impl->num_active_out;
CeedCallBackend(CeedOperatorSetup_Hip(op));
CeedCallBackend(CeedOperatorSetupInputs_Hip(num_input_fields, qf_input_fields, op_input_fields, NULL, true, e_data, impl, request));
if (!num_active_in) {
for (CeedInt i = 0; i < num_input_fields; i++) {
CeedScalar *q_vec_array;
CeedVector vec;
CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec));
if (vec == CEED_VECTOR_ACTIVE) {
CeedCallBackend(CeedQFunctionFieldGetSize(qf_input_fields[i], &size));
CeedCallBackend(CeedVectorSetValue(impl->q_vecs_in[i], 0.0));
CeedCallBackend(CeedVectorGetArray(impl->q_vecs_in[i], CEED_MEM_DEVICE, &q_vec_array));
CeedCallBackend(CeedRealloc(num_active_in + size, &active_in));
for (CeedInt field = 0; field < size; field++) {
q_size = (CeedSize)Q * num_elem;
CeedCallBackend(CeedVectorCreate(ceed, q_size, &active_in[num_active_in + field]));
CeedCallBackend(
CeedVectorSetArray(active_in[num_active_in + field], CEED_MEM_DEVICE, CEED_USE_POINTER, &q_vec_array[field * Q * num_elem]));
}
num_active_in += size;
CeedCallBackend(CeedVectorRestoreArray(impl->q_vecs_in[i], &q_vec_array));
}
}
impl->num_active_in = num_active_in;
impl->qf_active_in = active_in;
}
if (!num_active_out) {
for (CeedInt i = 0; i < num_output_fields; i++) {
CeedVector vec;
CeedCallBackend(CeedOperatorFieldGetVector(op_output_fields[i], &vec));
if (vec == CEED_VECTOR_ACTIVE) {
CeedCallBackend(CeedQFunctionFieldGetSize(qf_output_fields[i], &size));
num_active_out += size;
}
}
impl->num_active_out = num_active_out;
}
CeedCheck(num_active_in > 0 && num_active_out > 0, ceed, CEED_ERROR_BACKEND, "Cannot assemble QFunction without active inputs and outputs");
if (build_objects) {
CeedSize l_size = (CeedSize)num_elem * Q * num_active_in * num_active_out;
CeedInt strides[3] = {1, num_elem * Q, Q};
CeedCallBackend(CeedElemRestrictionCreateStrided(ceed_parent, num_elem, Q, num_active_in * num_active_out,
num_active_in * num_active_out * num_elem * Q, strides, rstr));
CeedCallBackend(CeedVectorCreate(ceed_parent, l_size, assembled));
}
CeedCallBackend(CeedVectorSetValue(*assembled, 0.0));
CeedCallBackend(CeedVectorGetArray(*assembled, CEED_MEM_DEVICE, &assembled_array));
CeedCallBackend(CeedOperatorInputBasis_Hip(num_elem, qf_input_fields, op_input_fields, num_input_fields, true, e_data, impl));
for (CeedInt in = 0; in < num_active_in; in++) {
CeedCallBackend(CeedVectorSetValue(active_in[in], 1.0));
if (num_active_in > 1) {
CeedCallBackend(CeedVectorSetValue(active_in[(in + num_active_in - 1) % num_active_in], 0.0));
}
for (CeedInt out = 0; out < num_output_fields; out++) {
CeedVector vec;
CeedCallBackend(CeedOperatorFieldGetVector(op_output_fields[out], &vec));
if (vec == CEED_VECTOR_ACTIVE) {
CeedCallBackend(CeedVectorSetArray(impl->q_vecs_out[out], CEED_MEM_DEVICE, CEED_USE_POINTER, assembled_array));
CeedCallBackend(CeedQFunctionFieldGetSize(qf_output_fields[out], &size));
assembled_array += size * Q * num_elem; }
}
CeedCallBackend(CeedQFunctionApply(qf, Q * num_elem, impl->q_vecs_in, impl->q_vecs_out));
}
for (CeedInt out = 0; out < num_output_fields; out++) {
CeedVector vec;
CeedCallBackend(CeedOperatorFieldGetVector(op_output_fields[out], &vec));
if (vec == CEED_VECTOR_ACTIVE) {
CeedCallBackend(CeedVectorTakeArray(impl->q_vecs_out[out], CEED_MEM_DEVICE, NULL));
}
}
CeedCallBackend(CeedOperatorRestoreInputs_Hip(num_input_fields, qf_input_fields, op_input_fields, true, e_data, impl));
CeedCallBackend(CeedVectorRestoreArray(*assembled, &assembled_array));
return CEED_ERROR_SUCCESS;
}
static int CeedOperatorLinearAssembleQFunction_Hip(CeedOperator op, CeedVector *assembled, CeedElemRestriction *rstr, CeedRequest *request) {
return CeedOperatorLinearAssembleQFunctionCore_Hip(op, true, assembled, rstr, request);
}
static int CeedOperatorLinearAssembleQFunctionUpdate_Hip(CeedOperator op, CeedVector assembled, CeedElemRestriction rstr, CeedRequest *request) {
return CeedOperatorLinearAssembleQFunctionCore_Hip(op, false, &assembled, &rstr, request);
}
static inline int CeedOperatorAssembleDiagonalSetup_Hip(CeedOperator op, CeedInt use_ceedsize_idx) {
Ceed ceed;
char *diagonal_kernel_path, *diagonal_kernel_source;
CeedInt num_input_fields, num_output_fields, num_e_mode_in = 0, num_comp = 0, dim = 1, num_e_mode_out = 0;
CeedEvalMode *e_mode_in = NULL, *e_mode_out = NULL;
CeedElemRestriction rstr_in = NULL, rstr_out = NULL;
CeedBasis basis_in = NULL, basis_out = NULL;
CeedQFunctionField *qf_fields;
CeedQFunction qf;
CeedOperatorField *op_fields;
CeedOperator_Hip *impl;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
CeedCallBackend(CeedOperatorGetQFunction(op, &qf));
CeedCallBackend(CeedQFunctionGetNumArgs(qf, &num_input_fields, &num_output_fields));
CeedCallBackend(CeedOperatorGetFields(op, NULL, &op_fields, NULL, NULL));
CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_fields, NULL, NULL));
for (CeedInt i = 0; i < num_input_fields; i++) {
CeedVector vec;
CeedCallBackend(CeedOperatorFieldGetVector(op_fields[i], &vec));
if (vec == CEED_VECTOR_ACTIVE) {
CeedEvalMode e_mode;
CeedElemRestriction rstr;
CeedCallBackend(CeedOperatorFieldGetBasis(op_fields[i], &basis_in));
CeedCallBackend(CeedBasisGetNumComponents(basis_in, &num_comp));
CeedCallBackend(CeedBasisGetDimension(basis_in, &dim));
CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_fields[i], &rstr));
CeedCheck(!rstr_in || rstr_in == rstr, ceed, CEED_ERROR_BACKEND,
"Backend does not implement multi-field non-composite operator diagonal assembly");
rstr_in = rstr;
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_fields[i], &e_mode));
switch (e_mode) {
case CEED_EVAL_NONE:
case CEED_EVAL_INTERP:
CeedCallBackend(CeedRealloc(num_e_mode_in + 1, &e_mode_in));
e_mode_in[num_e_mode_in] = e_mode;
num_e_mode_in += 1;
break;
case CEED_EVAL_GRAD:
CeedCallBackend(CeedRealloc(num_e_mode_in + dim, &e_mode_in));
for (CeedInt d = 0; d < dim; d++) e_mode_in[num_e_mode_in + d] = e_mode;
num_e_mode_in += dim;
break;
case CEED_EVAL_WEIGHT:
case CEED_EVAL_DIV:
case CEED_EVAL_CURL:
break; }
}
}
CeedCallBackend(CeedOperatorGetFields(op, NULL, NULL, NULL, &op_fields));
CeedCallBackend(CeedQFunctionGetFields(qf, NULL, NULL, NULL, &qf_fields));
for (CeedInt i = 0; i < num_output_fields; i++) {
CeedVector vec;
CeedCallBackend(CeedOperatorFieldGetVector(op_fields[i], &vec));
if (vec == CEED_VECTOR_ACTIVE) {
CeedEvalMode e_mode;
CeedElemRestriction rstr;
CeedCallBackend(CeedOperatorFieldGetBasis(op_fields[i], &basis_out));
CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_fields[i], &rstr));
CeedCheck(!rstr_out || rstr_out == rstr, ceed, CEED_ERROR_BACKEND,
"Backend does not implement multi-field non-composite operator diagonal assembly");
rstr_out = rstr;
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_fields[i], &e_mode));
switch (e_mode) {
case CEED_EVAL_NONE:
case CEED_EVAL_INTERP:
CeedCallBackend(CeedRealloc(num_e_mode_out + 1, &e_mode_out));
e_mode_out[num_e_mode_out] = e_mode;
num_e_mode_out += 1;
break;
case CEED_EVAL_GRAD:
CeedCallBackend(CeedRealloc(num_e_mode_out + dim, &e_mode_out));
for (CeedInt d = 0; d < dim; d++) e_mode_out[num_e_mode_out + d] = e_mode;
num_e_mode_out += dim;
break;
case CEED_EVAL_WEIGHT:
case CEED_EVAL_DIV:
case CEED_EVAL_CURL:
break; }
}
}
CeedCallBackend(CeedOperatorGetData(op, &impl));
CeedCallBackend(CeedCalloc(1, &impl->diag));
CeedOperatorDiag_Hip *diag = impl->diag;
diag->basis_in = basis_in;
diag->basis_out = basis_out;
diag->h_e_mode_in = e_mode_in;
diag->h_e_mode_out = e_mode_out;
diag->num_e_mode_in = num_e_mode_in;
diag->num_e_mode_out = num_e_mode_out;
CeedCallBackend(CeedGetJitAbsolutePath(ceed, "ceed/jit-source/hip/hip-ref-operator-assemble-diagonal.h", &diagonal_kernel_path));
CeedDebug256(ceed, CEED_DEBUG_COLOR_SUCCESS, "----- Loading Diagonal Assembly Kernel Source -----\n");
CeedCallBackend(CeedLoadSourceToBuffer(ceed, diagonal_kernel_path, &diagonal_kernel_source));
CeedDebug256(ceed, CEED_DEBUG_COLOR_SUCCESS, "----- Loading Diagonal Assembly Source Complete! -----\n");
CeedInt num_modes, num_qpts;
CeedCallBackend(CeedBasisGetNumNodes(basis_in, &num_modes));
CeedCallBackend(CeedBasisGetNumQuadraturePoints(basis_in, &num_qpts));
diag->num_modes = num_modes;
CeedCallBackend(CeedCompile_Hip(ceed, diagonal_kernel_source, &diag->module, 6, "NUMEMODEIN", num_e_mode_in, "NUMEMODEOUT", num_e_mode_out,
"NNODES", num_modes, "NQPTS", num_qpts, "NCOMP", num_comp, "CEEDSIZE", use_ceedsize_idx));
CeedCallBackend(CeedGetKernel_Hip(ceed, diag->module, "linearDiagonal", &diag->linearDiagonal));
CeedCallBackend(CeedGetKernel_Hip(ceed, diag->module, "linearPointBlockDiagonal", &diag->linearPointBlock));
CeedCallBackend(CeedFree(&diagonal_kernel_path));
CeedCallBackend(CeedFree(&diagonal_kernel_source));
const CeedInt q_bytes = num_qpts * sizeof(CeedScalar);
const CeedInt interp_bytes = q_bytes * num_modes;
const CeedInt grad_bytes = q_bytes * num_modes * dim;
const CeedInt e_mode_bytes = sizeof(CeedEvalMode);
const CeedScalar *interp_in, *interp_out, *grad_in, *grad_out;
CeedScalar *identity = NULL;
bool is_eval_none = false;
for (CeedInt i = 0; i < num_e_mode_in; i++) is_eval_none = is_eval_none || (e_mode_in[i] == CEED_EVAL_NONE);
for (CeedInt i = 0; i < num_e_mode_out; i++) is_eval_none = is_eval_none || (e_mode_out[i] == CEED_EVAL_NONE);
if (is_eval_none) {
CeedCallBackend(CeedCalloc(num_qpts * num_modes, &identity));
for (CeedInt i = 0; i < (num_modes < num_qpts ? num_modes : num_qpts); i++) identity[i * num_modes + i] = 1.0;
CeedCallHip(ceed, hipMalloc((void **)&diag->d_identity, interp_bytes));
CeedCallHip(ceed, hipMemcpy(diag->d_identity, identity, interp_bytes, hipMemcpyHostToDevice));
}
CeedCallBackend(CeedBasisGetInterp(basis_in, &interp_in));
CeedCallHip(ceed, hipMalloc((void **)&diag->d_interp_in, interp_bytes));
CeedCallHip(ceed, hipMemcpy(diag->d_interp_in, interp_in, interp_bytes, hipMemcpyHostToDevice));
CeedCallBackend(CeedBasisGetInterp(basis_out, &interp_out));
CeedCallHip(ceed, hipMalloc((void **)&diag->d_interp_out, interp_bytes));
CeedCallHip(ceed, hipMemcpy(diag->d_interp_out, interp_out, interp_bytes, hipMemcpyHostToDevice));
CeedCallBackend(CeedBasisGetGrad(basis_in, &grad_in));
CeedCallHip(ceed, hipMalloc((void **)&diag->d_grad_in, grad_bytes));
CeedCallHip(ceed, hipMemcpy(diag->d_grad_in, grad_in, grad_bytes, hipMemcpyHostToDevice));
CeedCallBackend(CeedBasisGetGrad(basis_out, &grad_out));
CeedCallHip(ceed, hipMalloc((void **)&diag->d_grad_out, grad_bytes));
CeedCallHip(ceed, hipMemcpy(diag->d_grad_out, grad_out, grad_bytes, hipMemcpyHostToDevice));
CeedCallHip(ceed, hipMalloc((void **)&diag->d_e_mode_in, num_e_mode_in * e_mode_bytes));
CeedCallHip(ceed, hipMemcpy(diag->d_e_mode_in, e_mode_in, num_e_mode_in * e_mode_bytes, hipMemcpyHostToDevice));
CeedCallHip(ceed, hipMalloc((void **)&diag->d_e_mode_out, num_e_mode_out * e_mode_bytes));
CeedCallHip(ceed, hipMemcpy(diag->d_e_mode_out, e_mode_out, num_e_mode_out * e_mode_bytes, hipMemcpyHostToDevice));
diag->diag_rstr = rstr_out;
return CEED_ERROR_SUCCESS;
}
static inline int CeedOperatorAssembleDiagonalCore_Hip(CeedOperator op, CeedVector assembled, CeedRequest *request, const bool is_point_block) {
Ceed ceed;
CeedSize assembled_length = 0, assembled_qf_length = 0;
CeedInt use_ceedsize_idx = 0, num_elem;
CeedScalar *elem_diag_array;
const CeedScalar *assembled_qf_array;
CeedVector assembled_qf = NULL;
CeedElemRestriction rstr = NULL;
CeedOperator_Hip *impl;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
CeedCallBackend(CeedOperatorGetData(op, &impl));
CeedCallBackend(CeedOperatorLinearAssembleQFunctionBuildOrUpdate(op, &assembled_qf, &rstr, request));
CeedCallBackend(CeedElemRestrictionDestroy(&rstr));
CeedCallBackend(CeedVectorGetLength(assembled, &assembled_length));
CeedCallBackend(CeedVectorGetLength(assembled_qf, &assembled_qf_length));
if ((assembled_length > INT_MAX) || (assembled_qf_length > INT_MAX)) use_ceedsize_idx = 1;
if (!impl->diag) CeedCallBackend(CeedOperatorAssembleDiagonalSetup_Hip(op, use_ceedsize_idx));
CeedOperatorDiag_Hip *diag = impl->diag;
assert(diag != NULL);
if (is_point_block && !diag->point_block_diag_rstr) {
CeedCallBackend(CeedOperatorCreateActivePointBlockRestriction(diag->diag_rstr, &diag->point_block_diag_rstr));
}
CeedElemRestriction diag_rstr = is_point_block ? diag->point_block_diag_rstr : diag->diag_rstr;
CeedVector elem_diag = is_point_block ? diag->point_block_elem_diag : diag->elem_diag;
if (!elem_diag) {
CeedCallBackend(CeedElemRestrictionCreateVector(diag_rstr, NULL, &elem_diag));
if (is_point_block) diag->point_block_elem_diag = elem_diag;
else diag->elem_diag = elem_diag;
}
CeedCallBackend(CeedVectorSetValue(elem_diag, 0.0));
CeedCallBackend(CeedVectorGetArray(elem_diag, CEED_MEM_DEVICE, &elem_diag_array));
CeedCallBackend(CeedVectorGetArrayRead(assembled_qf, CEED_MEM_DEVICE, &assembled_qf_array));
CeedCallBackend(CeedElemRestrictionGetNumElements(diag_rstr, &num_elem));
int elem_per_block = 1;
int grid = num_elem / elem_per_block + ((num_elem / elem_per_block * elem_per_block < num_elem) ? 1 : 0);
void *args[] = {(void *)&num_elem, &diag->d_identity, &diag->d_interp_in, &diag->d_grad_in, &diag->d_interp_out,
&diag->d_grad_out, &diag->d_e_mode_in, &diag->d_e_mode_out, &assembled_qf_array, &elem_diag_array};
if (is_point_block) {
CeedCallBackend(CeedRunKernelDim_Hip(ceed, diag->linearPointBlock, grid, diag->num_modes, 1, elem_per_block, args));
} else {
CeedCallBackend(CeedRunKernelDim_Hip(ceed, diag->linearDiagonal, grid, diag->num_modes, 1, elem_per_block, args));
}
CeedCallBackend(CeedVectorRestoreArray(elem_diag, &elem_diag_array));
CeedCallBackend(CeedVectorRestoreArrayRead(assembled_qf, &assembled_qf_array));
CeedCallBackend(CeedElemRestrictionApply(diag_rstr, CEED_TRANSPOSE, elem_diag, assembled, request));
CeedCallBackend(CeedVectorDestroy(&assembled_qf));
return CEED_ERROR_SUCCESS;
}
static int CeedOperatorLinearAssembleAddDiagonal_Hip(CeedOperator op, CeedVector assembled, CeedRequest *request) {
CeedCallBackend(CeedOperatorAssembleDiagonalCore_Hip(op, assembled, request, false));
return CEED_ERROR_SUCCESS;
}
static int CeedOperatorLinearAssembleAddPointBlockDiagonal_Hip(CeedOperator op, CeedVector assembled, CeedRequest *request) {
CeedCallBackend(CeedOperatorAssembleDiagonalCore_Hip(op, assembled, request, true));
return CEED_ERROR_SUCCESS;
}
static int CeedSingleOperatorAssembleSetup_Hip(CeedOperator op, CeedInt use_ceedsize_idx) {
Ceed ceed;
CeedInt num_input_fields, num_output_fields, num_e_mode_in = 0, dim = 1, num_B_in_mats_to_load = 0, size_B_in = 0, num_qpts = 0, elem_size = 0,
num_e_mode_out = 0, num_B_out_mats_to_load = 0, size_B_out = 0, num_elem, num_comp;
CeedEvalMode *eval_mode_in = NULL, *eval_mode_out = NULL;
CeedElemRestriction rstr_in = NULL, rstr_out = NULL;
CeedBasis basis_in = NULL, basis_out = NULL;
CeedQFunctionField *qf_fields;
CeedQFunction qf;
CeedOperatorField *input_fields, *output_fields;
CeedOperator_Hip *impl;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
CeedCallBackend(CeedOperatorGetData(op, &impl));
CeedCallBackend(CeedOperatorGetFields(op, &num_input_fields, &input_fields, &num_output_fields, &output_fields));
CeedCallBackend(CeedOperatorGetQFunction(op, &qf));
CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_fields, NULL, NULL));
for (CeedInt i = 0; i < num_input_fields; i++) {
CeedVector vec;
CeedCallBackend(CeedOperatorFieldGetVector(input_fields[i], &vec));
if (vec == CEED_VECTOR_ACTIVE) {
CeedEvalMode eval_mode;
CeedCallBackend(CeedOperatorFieldGetBasis(input_fields[i], &basis_in));
CeedCallBackend(CeedBasisGetDimension(basis_in, &dim));
CeedCallBackend(CeedBasisGetNumQuadraturePoints(basis_in, &num_qpts));
CeedCallBackend(CeedOperatorFieldGetElemRestriction(input_fields[i], &rstr_in));
CeedCallBackend(CeedElemRestrictionGetElementSize(rstr_in, &elem_size));
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_fields[i], &eval_mode));
if (eval_mode != CEED_EVAL_NONE) {
CeedCallBackend(CeedRealloc(num_B_in_mats_to_load + 1, &eval_mode_in));
eval_mode_in[num_B_in_mats_to_load] = eval_mode;
num_B_in_mats_to_load += 1;
if (eval_mode == CEED_EVAL_GRAD) {
num_e_mode_in += dim;
size_B_in += dim * elem_size * num_qpts;
} else {
num_e_mode_in += 1;
size_B_in += elem_size * num_qpts;
}
}
}
}
CeedCallBackend(CeedQFunctionGetFields(qf, NULL, NULL, NULL, &qf_fields));
for (CeedInt i = 0; i < num_output_fields; i++) {
CeedVector vec;
CeedCallBackend(CeedOperatorFieldGetVector(output_fields[i], &vec));
if (vec == CEED_VECTOR_ACTIVE) {
CeedEvalMode eval_mode;
CeedCallBackend(CeedOperatorFieldGetBasis(output_fields[i], &basis_out));
CeedCallBackend(CeedOperatorFieldGetElemRestriction(output_fields[i], &rstr_out));
CeedCheck(!rstr_out || rstr_out == rstr_in, ceed, CEED_ERROR_BACKEND, "Backend does not implement multi-field non-composite operator assembly");
CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_fields[i], &eval_mode));
if (eval_mode != CEED_EVAL_NONE) {
CeedCallBackend(CeedRealloc(num_B_out_mats_to_load + 1, &eval_mode_out));
eval_mode_out[num_B_out_mats_to_load] = eval_mode;
num_B_out_mats_to_load += 1;
if (eval_mode == CEED_EVAL_GRAD) {
num_e_mode_out += dim;
size_B_out += dim * elem_size * num_qpts;
} else {
num_e_mode_out += 1;
size_B_out += elem_size * num_qpts;
}
}
}
}
CeedCheck(num_e_mode_in > 0 && num_e_mode_out > 0, ceed, CEED_ERROR_UNSUPPORTED, "Cannot assemble operator without inputs/outputs");
CeedCallBackend(CeedElemRestrictionGetNumElements(rstr_in, &num_elem));
CeedCallBackend(CeedElemRestrictionGetNumComponents(rstr_in, &num_comp));
CeedCallBackend(CeedCalloc(1, &impl->asmb));
CeedOperatorAssemble_Hip *asmb = impl->asmb;
asmb->num_elem = num_elem;
int elem_per_block = 1;
asmb->elem_per_block = elem_per_block;
CeedInt block_size = elem_size * elem_size * elem_per_block;
char *assembly_kernel_path, *assembly_kernel_source;
CeedCallBackend(CeedGetJitAbsolutePath(ceed, "ceed/jit-source/hip/hip-ref-operator-assemble.h", &assembly_kernel_path));
CeedDebug256(ceed, CEED_DEBUG_COLOR_SUCCESS, "----- Loading Assembly Kernel Source -----\n");
CeedCallBackend(CeedLoadSourceToBuffer(ceed, assembly_kernel_path, &assembly_kernel_source));
CeedDebug256(ceed, CEED_DEBUG_COLOR_SUCCESS, "----- Loading Assembly Source Complete! -----\n");
bool fallback = block_size > 1024;
if (fallback) { block_size = elem_size * elem_per_block;
asmb->block_size_x = elem_size;
asmb->block_size_y = 1;
} else { asmb->block_size_x = elem_size;
asmb->block_size_y = elem_size;
}
CeedCallBackend(CeedCompile_Hip(ceed, assembly_kernel_source, &asmb->module, 8, "NELEM", num_elem, "NUMEMODEIN", num_e_mode_in, "NUMEMODEOUT",
num_e_mode_out, "NQPTS", num_qpts, "NNODES", elem_size, "BLOCK_SIZE", block_size, "NCOMP", num_comp, "CEEDSIZE",
use_ceedsize_idx));
CeedCallBackend(CeedGetKernel_Hip(ceed, asmb->module, fallback ? "linearAssembleFallback" : "linearAssemble", &asmb->linearAssemble));
CeedCallBackend(CeedFree(&assembly_kernel_path));
CeedCallBackend(CeedFree(&assembly_kernel_source));
const CeedScalar *interp_in, *grad_in;
CeedCallBackend(CeedBasisGetInterp(basis_in, &interp_in));
CeedCallBackend(CeedBasisGetGrad(basis_in, &grad_in));
const CeedInt in_bytes = size_B_in * sizeof(CeedScalar);
CeedInt mat_start = 0;
CeedCallHip(ceed, hipMalloc((void **)&asmb->d_B_in, in_bytes));
for (int i = 0; i < num_B_in_mats_to_load; i++) {
CeedEvalMode eval_mode = eval_mode_in[i];
if (eval_mode == CEED_EVAL_INTERP) {
CeedCallHip(ceed, hipMemcpy(&asmb->d_B_in[mat_start], interp_in, elem_size * num_qpts * sizeof(CeedScalar), hipMemcpyHostToDevice));
mat_start += elem_size * num_qpts;
} else if (eval_mode == CEED_EVAL_GRAD) {
CeedCallHip(ceed, hipMemcpy(&asmb->d_B_in[mat_start], grad_in, dim * elem_size * num_qpts * sizeof(CeedScalar), hipMemcpyHostToDevice));
mat_start += dim * elem_size * num_qpts;
}
}
const CeedScalar *interp_out, *grad_out;
if (basis_out == basis_in) {
interp_out = interp_in;
grad_out = grad_in;
} else {
CeedCallBackend(CeedBasisGetInterp(basis_out, &interp_out));
CeedCallBackend(CeedBasisGetGrad(basis_out, &grad_out));
}
const CeedInt out_bytes = size_B_out * sizeof(CeedScalar);
mat_start = 0;
CeedCallHip(ceed, hipMalloc((void **)&asmb->d_B_out, out_bytes));
for (int i = 0; i < num_B_out_mats_to_load; i++) {
CeedEvalMode eval_mode = eval_mode_out[i];
if (eval_mode == CEED_EVAL_INTERP) {
CeedCallHip(ceed, hipMemcpy(&asmb->d_B_out[mat_start], interp_out, elem_size * num_qpts * sizeof(CeedScalar), hipMemcpyHostToDevice));
mat_start += elem_size * num_qpts;
} else if (eval_mode == CEED_EVAL_GRAD) {
CeedCallHip(ceed, hipMemcpy(&asmb->d_B_out[mat_start], grad_out, dim * elem_size * num_qpts * sizeof(CeedScalar), hipMemcpyHostToDevice));
mat_start += dim * elem_size * num_qpts;
}
}
return CEED_ERROR_SUCCESS;
}
static int CeedSingleOperatorAssemble_Hip(CeedOperator op, CeedInt offset, CeedVector values) {
Ceed ceed;
CeedSize values_length = 0, assembled_qf_length = 0;
CeedInt use_ceedsize_idx = 0;
CeedScalar *values_array;
const CeedScalar *qf_array;
CeedVector assembled_qf = NULL;
CeedElemRestriction rstr_q = NULL;
CeedOperator_Hip *impl;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
CeedCallBackend(CeedOperatorGetData(op, &impl));
CeedCallBackend(CeedOperatorLinearAssembleQFunctionBuildOrUpdate(op, &assembled_qf, &rstr_q, CEED_REQUEST_IMMEDIATE));
CeedCallBackend(CeedElemRestrictionDestroy(&rstr_q));
CeedCallBackend(CeedVectorGetArray(values, CEED_MEM_DEVICE, &values_array));
values_array += offset;
CeedCallBackend(CeedVectorGetArrayRead(assembled_qf, CEED_MEM_DEVICE, &qf_array));
CeedCallBackend(CeedVectorGetLength(values, &values_length));
CeedCallBackend(CeedVectorGetLength(assembled_qf, &assembled_qf_length));
if ((values_length > INT_MAX) || (assembled_qf_length > INT_MAX)) use_ceedsize_idx = 1;
if (!impl->asmb) {
CeedCallBackend(CeedSingleOperatorAssembleSetup_Hip(op, use_ceedsize_idx));
assert(impl->asmb != NULL);
}
const CeedInt num_elem = impl->asmb->num_elem;
const CeedInt elem_per_block = impl->asmb->elem_per_block;
const CeedInt grid = num_elem / elem_per_block + ((num_elem / elem_per_block * elem_per_block < num_elem) ? 1 : 0);
void *args[] = {&impl->asmb->d_B_in, &impl->asmb->d_B_out, &qf_array, &values_array};
CeedCallBackend(
CeedRunKernelDim_Hip(ceed, impl->asmb->linearAssemble, grid, impl->asmb->block_size_x, impl->asmb->block_size_y, elem_per_block, args));
CeedCallBackend(CeedVectorRestoreArray(values, &values_array));
CeedCallBackend(CeedVectorRestoreArrayRead(assembled_qf, &qf_array));
CeedCallBackend(CeedVectorDestroy(&assembled_qf));
return CEED_ERROR_SUCCESS;
}
int CeedOperatorCreate_Hip(CeedOperator op) {
Ceed ceed;
CeedOperator_Hip *impl;
CeedCallBackend(CeedOperatorGetCeed(op, &ceed));
CeedCallBackend(CeedCalloc(1, &impl));
CeedCallBackend(CeedOperatorSetData(op, impl));
CeedCallBackend(CeedSetBackendFunction(ceed, "Operator", op, "LinearAssembleQFunction", CeedOperatorLinearAssembleQFunction_Hip));
CeedCallBackend(CeedSetBackendFunction(ceed, "Operator", op, "LinearAssembleQFunctionUpdate", CeedOperatorLinearAssembleQFunctionUpdate_Hip));
CeedCallBackend(CeedSetBackendFunction(ceed, "Operator", op, "LinearAssembleAddDiagonal", CeedOperatorLinearAssembleAddDiagonal_Hip));
CeedCallBackend(
CeedSetBackendFunction(ceed, "Operator", op, "LinearAssembleAddPointBlockDiagonal", CeedOperatorLinearAssembleAddPointBlockDiagonal_Hip));
CeedCallBackend(CeedSetBackendFunction(ceed, "Operator", op, "LinearAssembleSingle", CeedSingleOperatorAssemble_Hip));
CeedCallBackend(CeedSetBackendFunction(ceed, "Operator", op, "ApplyAdd", CeedOperatorApplyAdd_Hip));
CeedCallBackend(CeedSetBackendFunction(ceed, "Operator", op, "Destroy", CeedOperatorDestroy_Hip));
return CEED_ERROR_SUCCESS;
}