* Copyright (c) 1991-2000, University of Groningen, The Netherlands.
* Copyright (c) 2001-2004, The GROMACS development team.
* Copyright (c) 2013,2014,2015,2016,2017 by the GROMACS development team.
- * Copyright (c) 2018,2019,2020, by the GROMACS development team, led by
+ * Copyright (c) 2018,2019,2020,2021, by the GROMACS development team, led by
* Mark Abraham, David van der Spoel, Berk Hess, and Erik Lindahl,
* and including many others, as listed in the AUTHORS file in the
* top-level source directory and at http://www.gromacs.org.
#include <string>
#include "gromacs/applied_forces/awh/awh.h"
+#include "gromacs/applied_forces/awh/read_params.h"
#include "gromacs/fileio/enxio.h"
#include "gromacs/fileio/gmxfio.h"
#include "gromacs/fileio/xvgr.h"
#include "gromacs/topology/mtop_util.h"
#include "gromacs/trajectory/energyframe.h"
#include "gromacs/utility/arraysize.h"
+#include "gromacs/utility/enumerationhelpers.h"
#include "gromacs/utility/fatalerror.h"
-#include "gromacs/utility/mdmodulenotification.h"
+#include "gromacs/utility/mdmodulesnotifiers.h"
#include "gromacs/utility/smalloc.h"
#include "gromacs/utility/stringutil.h"
+#include "energydrifttracker.h"
+
//! Labels for energy file quantities
//! \{
+// NOLINTNEXTLINE(cppcoreguidelines-avoid-non-const-global-variables)
static const char* conrmsd_nm[] = { "Constr. rmsd", "Constr.2 rmsd" };
-static std::array<const char*, 3> boxs_nm = { "Box-X", "Box-Y", "Box-Z" };
+static constexpr std::array<const char*, 3> boxs_nm = { "Box-X", "Box-Y", "Box-Z" };
-static std::array<const char*, 6> tricl_boxs_nm = { "Box-XX", "Box-YY", "Box-ZZ",
- "Box-YX", "Box-ZX", "Box-ZY" };
+static constexpr std::array<const char*, 6> tricl_boxs_nm = { "Box-XX", "Box-YY", "Box-ZZ",
+ "Box-YX", "Box-ZX", "Box-ZY" };
+// NOLINTNEXTLINE(cppcoreguidelines-avoid-non-const-global-variables)
static const char* vol_nm[] = { "Volume" };
+// NOLINTNEXTLINE(cppcoreguidelines-avoid-non-const-global-variables)
static const char* dens_nm[] = { "Density" };
+// NOLINTNEXTLINE(cppcoreguidelines-avoid-non-const-global-variables)
static const char* pv_nm[] = { "pV" };
+// NOLINTNEXTLINE(cppcoreguidelines-avoid-non-const-global-variables)
static const char* enthalpy_nm[] = { "Enthalpy" };
-static std::array<const char*, 6> boxvel_nm = { "Box-Vel-XX", "Box-Vel-YY", "Box-Vel-ZZ",
- "Box-Vel-YX", "Box-Vel-ZX", "Box-Vel-ZY" };
+static constexpr std::array<const char*, 6> boxvel_nm = { "Box-Vel-XX", "Box-Vel-YY", "Box-Vel-ZZ",
+ "Box-Vel-YX", "Box-Vel-ZX", "Box-Vel-ZY" };
+
+const char* enumValueToString(NonBondedEnergyTerms enumValue)
+{
+ static constexpr gmx::EnumerationArray<NonBondedEnergyTerms, const char*> nonBondedEnergyTermTypeNames = {
+ "Coul-SR", "LJ-SR", "Buck-SR", "Coul-14", "LJ-14"
+ };
+ return nonBondedEnergyTermTypeNames[enumValue];
+}
-const char* egrp_nm[egNR + 1] = { "Coul-SR", "LJ-SR", "Buck-SR", "Coul-14", "LJ-14", nullptr };
//! \}
+static bool haveFepLambdaMoves(const t_inputrec& inputrec)
+{
+ return (inputrec.bExpanded && inputrec.expandedvals->elmcmove > LambdaMoveCalculation::No)
+ || (inputrec.efep != FreeEnergyPerturbationType::No && inputrec.bDoAwh
+ && awhHasFepLambdaDimension(*inputrec.awhParams));
+}
+
namespace gmx
{
* be written out to the .edr file.
*
* \todo Use more std containers.
- * \todo Remove GMX_CONSTRAINTVIR
* \todo Write free-energy output also to energy file (after adding more tests)
*/
-EnergyOutput::EnergyOutput(ener_file* fp_ene,
- const gmx_mtop_t* mtop,
- const t_inputrec* ir,
- const pull_t* pull_work,
- FILE* fp_dhdl,
- bool isRerun,
- const StartingBehavior startingBehavior,
- const MdModulesNotifier& mdModulesNotifier)
+EnergyOutput::EnergyOutput(ener_file* fp_ene,
+ const gmx_mtop_t& mtop,
+ const t_inputrec& inputrec,
+ const pull_t* pull_work,
+ FILE* fp_dhdl,
+ bool isRerun,
+ const StartingBehavior startingBehavior,
+ const bool simulationsShareState,
+ const MDModulesNotifiers& mdModulesNotifiers) :
+ haveFepLambdaMoves_(haveFepLambdaMoves(inputrec))
{
const char* ener_nm[F_NRE];
static const char* vir_nm[] = { "Vir-XX", "Vir-XY", "Vir-XZ", "Vir-YX", "Vir-YY",
"Vir-YZ", "Vir-ZX", "Vir-ZY", "Vir-ZZ" };
- static const char* sv_nm[] = { "ShakeVir-XX", "ShakeVir-XY", "ShakeVir-XZ",
- "ShakeVir-YX", "ShakeVir-YY", "ShakeVir-YZ",
- "ShakeVir-ZX", "ShakeVir-ZY", "ShakeVir-ZZ" };
- static const char* fv_nm[] = { "ForceVir-XX", "ForceVir-XY", "ForceVir-XZ",
- "ForceVir-YX", "ForceVir-YY", "ForceVir-YZ",
- "ForceVir-ZX", "ForceVir-ZY", "ForceVir-ZZ" };
static const char* pres_nm[] = { "Pres-XX", "Pres-XY", "Pres-XZ", "Pres-YX", "Pres-YY",
"Pres-YZ", "Pres-ZX", "Pres-ZY", "Pres-ZZ" };
static const char* surft_nm[] = { "#Surf*SurfTen" };
char** gnm;
char buf[256];
const char* bufi;
- int i, j, ni, nj, n, k, kk, ncon, nset;
+ int i, j, ni, nj, n, ncon, nset;
bool bBHAM, b14;
- if (EI_DYNAMICS(ir->eI))
+ if (EI_DYNAMICS(inputrec.eI))
{
- delta_t_ = ir->delta_t;
+ delta_t_ = inputrec.delta_t;
}
else
{
delta_t_ = 0;
}
- groups = &mtop->groups;
+ groups = &mtop.groups;
- bBHAM = (mtop->ffparams.numTypes() > 0) && (mtop->ffparams.functype[0] == F_BHAM);
+ bBHAM = (mtop.ffparams.numTypes() > 0) && (mtop.ffparams.functype[0] == F_BHAM);
b14 = (gmx_mtop_ftype_count(mtop, F_LJ14) > 0 || gmx_mtop_ftype_count(mtop, F_LJC14_Q) > 0);
ncon = gmx_mtop_ftype_count(mtop, F_CONSTR);
nset = gmx_mtop_ftype_count(mtop, F_SETTLE);
bool bConstr = (ncon > 0 || nset > 0) && !isRerun;
- bConstrVir_ = false;
nCrmsd_ = 0;
if (bConstr)
{
- if (ncon > 0 && ir->eConstrAlg == econtLINCS)
+ if (ncon > 0 && inputrec.eConstrAlg == ConstraintAlgorithm::Lincs)
{
nCrmsd_ = 1;
}
- bConstrVir_ = (getenv("GMX_CONSTRAINTVIR") != nullptr);
}
else
{
}
/* Energy monitoring */
- for (i = 0; i < egNR; i++)
+ for (auto& term : bEInd_)
{
- bEInd_[i] = false;
+ term = false;
}
// Setting true only to those energy terms, that have active interactions and
if (!isRerun)
{
- bEner_[F_EKIN] = EI_DYNAMICS(ir->eI);
- bEner_[F_ETOT] = EI_DYNAMICS(ir->eI);
- bEner_[F_TEMP] = EI_DYNAMICS(ir->eI);
+ bEner_[F_EKIN] = EI_DYNAMICS(inputrec.eI);
+ bEner_[F_ETOT] = EI_DYNAMICS(inputrec.eI);
+ bEner_[F_TEMP] = EI_DYNAMICS(inputrec.eI);
- bEner_[F_ECONSERVED] = integratorHasConservedEnergyQuantity(ir);
- bEner_[F_PDISPCORR] = (ir->eDispCorr != edispcNO);
+ bEner_[F_ECONSERVED] = integratorHasConservedEnergyQuantity(&inputrec);
+ bEner_[F_PDISPCORR] = (inputrec.eDispCorr != DispersionCorrectionType::No);
bEner_[F_PRES] = true;
}
- bEner_[F_LJ] = !bBHAM;
- bEner_[F_BHAM] = bBHAM;
- bEner_[F_EQM] = ir->bQMMM;
- bEner_[F_RF_EXCL] = (EEL_RF(ir->coulombtype) && ir->cutoff_scheme == ecutsGROUP);
- bEner_[F_COUL_RECIP] = EEL_FULL(ir->coulombtype);
- bEner_[F_LJ_RECIP] = EVDW_PME(ir->vdwtype);
+ bEner_[F_LJ] = !bBHAM;
+ bEner_[F_BHAM] = bBHAM;
+ bEner_[F_RF_EXCL] = (EEL_RF(inputrec.coulombtype) && inputrec.cutoff_scheme == CutoffScheme::Group);
+ bEner_[F_COUL_RECIP] = EEL_FULL(inputrec.coulombtype);
+ bEner_[F_LJ_RECIP] = EVDW_PME(inputrec.vdwtype);
bEner_[F_LJ14] = b14;
bEner_[F_COUL14] = b14;
bEner_[F_LJC14_Q] = false;
bEner_[F_LJC_PAIRS_NB] = false;
- bEner_[F_DVDL_COUL] = (ir->efep != efepNO) && ir->fepvals->separate_dvdl[efptCOUL];
- bEner_[F_DVDL_VDW] = (ir->efep != efepNO) && ir->fepvals->separate_dvdl[efptVDW];
- bEner_[F_DVDL_BONDED] = (ir->efep != efepNO) && ir->fepvals->separate_dvdl[efptBONDED];
- bEner_[F_DVDL_RESTRAINT] = (ir->efep != efepNO) && ir->fepvals->separate_dvdl[efptRESTRAINT];
- bEner_[F_DKDL] = (ir->efep != efepNO) && ir->fepvals->separate_dvdl[efptMASS];
- bEner_[F_DVDL] = (ir->efep != efepNO) && ir->fepvals->separate_dvdl[efptFEP];
+ bEner_[F_DVDL_COUL] = (inputrec.efep != FreeEnergyPerturbationType::No)
+ && inputrec.fepvals->separate_dvdl[FreeEnergyPerturbationCouplingType::Coul];
+ bEner_[F_DVDL_VDW] = (inputrec.efep != FreeEnergyPerturbationType::No)
+ && inputrec.fepvals->separate_dvdl[FreeEnergyPerturbationCouplingType::Vdw];
+ bEner_[F_DVDL_BONDED] = (inputrec.efep != FreeEnergyPerturbationType::No)
+ && inputrec.fepvals->separate_dvdl[FreeEnergyPerturbationCouplingType::Bonded];
+ bEner_[F_DVDL_RESTRAINT] =
+ (inputrec.efep != FreeEnergyPerturbationType::No)
+ && inputrec.fepvals->separate_dvdl[FreeEnergyPerturbationCouplingType::Restraint];
+ bEner_[F_DKDL] = (inputrec.efep != FreeEnergyPerturbationType::No)
+ && inputrec.fepvals->separate_dvdl[FreeEnergyPerturbationCouplingType::Mass];
+ bEner_[F_DVDL] = (inputrec.efep != FreeEnergyPerturbationType::No)
+ && inputrec.fepvals->separate_dvdl[FreeEnergyPerturbationCouplingType::Fep];
bEner_[F_CONSTR] = false;
bEner_[F_CONSTRNC] = false;
bEner_[F_COUL_SR] = true;
bEner_[F_EPOT] = true;
- bEner_[F_DISPCORR] = (ir->eDispCorr != edispcNO);
+ bEner_[F_DISPCORR] = (inputrec.eDispCorr != DispersionCorrectionType::No);
bEner_[F_DISRESVIOL] = (gmx_mtop_ftype_count(mtop, F_DISRES) > 0);
bEner_[F_ORIRESDEV] = (gmx_mtop_ftype_count(mtop, F_ORIRES) > 0);
- bEner_[F_COM_PULL] = ((ir->bPull && pull_have_potential(pull_work)) || ir->bRot);
+ bEner_[F_COM_PULL] = ((inputrec.bPull && pull_have_potential(*pull_work)) || inputrec.bRot);
- MdModulesEnergyOutputToDensityFittingRequestChecker mdModulesAddOutputToDensityFittingFieldRequest;
- mdModulesNotifier.simulationSetupNotifications_.notify(&mdModulesAddOutputToDensityFittingFieldRequest);
+ // Check MDModules for any energy output
+ MDModulesEnergyOutputToDensityFittingRequestChecker mdModulesAddOutputToDensityFittingFieldRequest;
+ mdModulesNotifiers.simulationSetupNotifier_.notify(&mdModulesAddOutputToDensityFittingFieldRequest);
bEner_[F_DENSITYFITTING] = mdModulesAddOutputToDensityFittingFieldRequest.energyOutputToDensityFitting_;
+ MDModulesEnergyOutputToQMMMRequestChecker mdModulesAddOutputToQMMMFieldRequest;
+ mdModulesNotifiers.simulationSetupNotifier_.notify(&mdModulesAddOutputToQMMMFieldRequest);
+
+ bEner_[F_EQM] = mdModulesAddOutputToQMMMFieldRequest.energyOutputToQMMM_;
// Counting the energy terms that will be printed and saving their names
f_nre_ = 0;
}
}
- epc_ = isRerun ? epcNO : ir->epc;
- bDiagPres_ = !TRICLINIC(ir->ref_p) && !isRerun;
- ref_p_ = (ir->ref_p[XX][XX] + ir->ref_p[YY][YY] + ir->ref_p[ZZ][ZZ]) / DIM;
- bTricl_ = TRICLINIC(ir->compress) || TRICLINIC(ir->deform);
- bDynBox_ = inputrecDynamicBox(ir);
- etc_ = isRerun ? etcNO : ir->etc;
- bNHC_trotter_ = inputrecNvtTrotter(ir) && !isRerun;
- bPrintNHChains_ = ir->bPrintNHChains && !isRerun;
- bMTTK_ = (inputrecNptTrotter(ir) || inputrecNphTrotter(ir)) && !isRerun;
- bMu_ = inputrecNeedMutot(ir);
+ epc_ = isRerun ? PressureCoupling::No : inputrec.epc;
+ bDiagPres_ = !TRICLINIC(inputrec.ref_p) && !isRerun;
+ ref_p_ = (inputrec.ref_p[XX][XX] + inputrec.ref_p[YY][YY] + inputrec.ref_p[ZZ][ZZ]) / DIM;
+ bTricl_ = TRICLINIC(inputrec.compress) || TRICLINIC(inputrec.deform);
+ bDynBox_ = inputrecDynamicBox(&inputrec);
+ etc_ = isRerun ? TemperatureCoupling::No : inputrec.etc;
+ bNHC_trotter_ = inputrecNvtTrotter(&inputrec) && !isRerun;
+ bPrintNHChains_ = inputrec.bPrintNHChains && !isRerun;
+ bMTTK_ = (inputrecNptTrotter(&inputrec) || inputrecNphTrotter(&inputrec)) && !isRerun;
+ bMu_ = inputrecNeedMutot(&inputrec);
bPres_ = !isRerun;
ebin_ = mk_ebin();
}
if (bDynBox_)
{
- ib_ = get_ebin_space(ebin_, bTricl_ ? tricl_boxs_nm.size() : boxs_nm.size(),
- bTricl_ ? tricl_boxs_nm.data() : boxs_nm.data(), unit_length);
+ ib_ = get_ebin_space(ebin_,
+ bTricl_ ? tricl_boxs_nm.size() : boxs_nm.size(),
+ bTricl_ ? tricl_boxs_nm.data() : boxs_nm.data(),
+ unit_length);
ivol_ = get_ebin_space(ebin_, 1, vol_nm, unit_volume);
idens_ = get_ebin_space(ebin_, 1, dens_nm, unit_density_SI);
if (bDiagPres_)
ienthalpy_ = get_ebin_space(ebin_, 1, enthalpy_nm, unit_energy);
}
}
- if (bConstrVir_)
- {
- isvir_ = get_ebin_space(ebin_, asize(sv_nm), sv_nm, unit_energy);
- ifvir_ = get_ebin_space(ebin_, asize(fv_nm), fv_nm, unit_energy);
- }
if (bPres_)
{
ivir_ = get_ebin_space(ebin_, asize(vir_nm), vir_nm, unit_energy);
ipres_ = get_ebin_space(ebin_, asize(pres_nm), pres_nm, unit_pres_bar);
isurft_ = get_ebin_space(ebin_, asize(surft_nm), surft_nm, unit_surft_bar);
}
- if (epc_ == epcPARRINELLORAHMAN || epc_ == epcMTTK)
+ if (epc_ == PressureCoupling::ParrinelloRahman || epc_ == PressureCoupling::Mttk)
{
ipc_ = get_ebin_space(ebin_, bTricl_ ? boxvel_nm.size() : DIM, boxvel_nm.data(), unit_vel);
}
{
imu_ = get_ebin_space(ebin_, asize(mu_nm), mu_nm, unit_dipole_D);
}
- if (ir->cos_accel != 0)
+ if (inputrec.cos_accel != 0)
{
ivcos_ = get_ebin_space(ebin_, asize(vcos_nm), vcos_nm, unit_vel);
ivisc_ = get_ebin_space(ebin_, asize(visc_nm), visc_nm, unit_invvisc_SI);
}
/* Energy monitoring */
- for (i = 0; i < egNR; i++)
+ for (auto& term : bEInd_)
{
- bEInd_[i] = false;
+ term = false;
}
- bEInd_[egCOULSR] = true;
- bEInd_[egLJSR] = true;
+ bEInd_[NonBondedEnergyTerms::CoulombSR] = true;
+ bEInd_[NonBondedEnergyTerms::LJSR] = true;
if (bBHAM)
{
- bEInd_[egLJSR] = false;
- bEInd_[egBHAMSR] = true;
+ bEInd_[NonBondedEnergyTerms::LJSR] = false;
+ bEInd_[NonBondedEnergyTerms::BuckinghamSR] = true;
}
if (b14)
{
- bEInd_[egLJ14] = true;
- bEInd_[egCOUL14] = true;
+ bEInd_[NonBondedEnergyTerms::LJ14] = true;
+ bEInd_[NonBondedEnergyTerms::Coulomb14] = true;
}
nEc_ = 0;
- for (i = 0; (i < egNR); i++)
+ for (auto term : bEInd_)
{
- if (bEInd_[i])
+ if (term)
{
nEc_++;
}
nEg_ = n;
nE_ = (n * (n + 1)) / 2;
- snew(igrp_, nE_);
+ igrp_.resize(nE_);
if (nE_ > 1)
{
n = 0;
snew(gnm, nEc_);
- for (k = 0; (k < nEc_); k++)
+ for (int k = 0; (k < nEc_); k++)
{
snew(gnm[k], STRLEN);
}
ni = groups->groups[SimulationAtomGroupType::EnergyOutput][i];
for (j = i; (j < gmx::ssize(groups->groups[SimulationAtomGroupType::EnergyOutput])); j++)
{
- nj = groups->groups[SimulationAtomGroupType::EnergyOutput][j];
- for (k = kk = 0; (k < egNR); k++)
+ nj = groups->groups[SimulationAtomGroupType::EnergyOutput][j];
+ int k = 0;
+ for (auto key : keysOf(bEInd_))
{
- if (bEInd_[k])
+ if (bEInd_[key])
{
- sprintf(gnm[kk], "%s:%s-%s", egrp_nm[k], *(groups->groupNames[ni]),
+ sprintf(gnm[k],
+ "%s:%s-%s",
+ enumValueToString(key),
+ *(groups->groupNames[ni]),
*(groups->groupNames[nj]));
- kk++;
+ k++;
}
}
igrp_[n] = get_ebin_space(ebin_, nEc_, gnm, unit_energy);
n++;
}
}
- for (k = 0; (k < nEc_); k++)
+ for (int k = 0; (k < nEc_); k++)
{
sfree(gnm[k]);
}
}
nTC_ = isRerun ? 0 : groups->groups[SimulationAtomGroupType::TemperatureCoupling].size();
- nNHC_ = ir->opts.nhchainlength; /* shorthand for number of NH chains */
+ nNHC_ = inputrec.opts.nhchainlength; /* shorthand for number of NH chains */
if (bMTTK_)
{
nTCP_ = 1; /* assume only one possible coupling system for barostat
{
nTCP_ = 0;
}
- if (etc_ == etcNOSEHOOVER)
+ if (etc_ == TemperatureCoupling::NoseHoover)
{
if (bNHC_trotter_)
{
{
mde_n_ = 2 * nTC_;
}
- if (epc_ == epcMTTK)
+ if (epc_ == PressureCoupling::Mttk)
{
mdeb_n_ = 2 * nNHC_ * nTCP_;
}
mdeb_n_ = 0;
}
- snew(tmp_r_, mde_n_);
+ tmp_r_.resize(mde_n_);
// TODO redo the group name memory management to make it more clear
char** grpnms;
snew(grpnms, std::max(mde_n_, mdeb_n_)); // Just in case mdeb_n_ > mde_n_
}
int allocated = 0;
- if (etc_ == etcNOSEHOOVER)
+ if (etc_ == TemperatureCoupling::NoseHoover)
{
if (bPrintNHChains_)
{
}
}
}
- else if (etc_ == etcBERENDSEN || etc_ == etcYES || etc_ == etcVRESCALE)
+ else if (etc_ == TemperatureCoupling::Berendsen || etc_ == TemperatureCoupling::Yes
+ || etc_ == TemperatureCoupling::VRescale)
{
for (i = 0; (i < nTC_); i++)
{
}
sfree(grpnms);
- nU_ = groups->groups[SimulationAtomGroupType::Acceleration].size();
- snew(tmp_v_, nU_);
- if (nU_ > 1)
- {
- snew(grpnms, 3 * nU_);
- for (i = 0; (i < nU_); i++)
- {
- ni = groups->groups[SimulationAtomGroupType::Acceleration][i];
- sprintf(buf, "Ux-%s", *(groups->groupNames[ni]));
- grpnms[3 * i + XX] = gmx_strdup(buf);
- sprintf(buf, "Uy-%s", *(groups->groupNames[ni]));
- grpnms[3 * i + YY] = gmx_strdup(buf);
- sprintf(buf, "Uz-%s", *(groups->groupNames[ni]));
- grpnms[3 * i + ZZ] = gmx_strdup(buf);
- }
- iu_ = get_ebin_space(ebin_, 3 * nU_, grpnms, unit_vel);
- for (i = 0; i < 3 * nU_; i++)
- {
- sfree(grpnms[i]);
- }
- sfree(grpnms);
- }
-
/* Note that fp_ene should be valid on the master rank and null otherwise */
if (fp_ene != nullptr && startingBehavior != StartingBehavior::RestartWithAppending)
{
/* check whether we're going to write dh histograms */
dhc_ = nullptr;
- if (ir->fepvals->separate_dhdl_file == esepdhdlfileNO)
+ if (inputrec.fepvals->separate_dhdl_file == SeparateDhdlFile::No)
{
/* Currently dh histograms are only written with dynamics */
- if (EI_DYNAMICS(ir->eI))
+ if (EI_DYNAMICS(inputrec.eI))
{
- snew(dhc_, 1);
-
- mde_delta_h_coll_init(dhc_, ir);
+ dhc_ = std::make_unique<t_mde_delta_h_coll>(inputrec);
}
fp_dhdl_ = nullptr;
- snew(dE_, ir->fepvals->n_lambda);
+ dE_.resize(inputrec.fepvals->n_lambda);
}
else
{
fp_dhdl_ = fp_dhdl;
- snew(dE_, ir->fepvals->n_lambda);
+ dE_.resize(inputrec.fepvals->n_lambda);
}
- if (ir->bSimTemp)
+ if (inputrec.bSimTemp)
{
- int i;
- snew(temperatures_, ir->fepvals->n_lambda);
- numTemperatures_ = ir->fepvals->n_lambda;
- for (i = 0; i < ir->fepvals->n_lambda; i++)
- {
- temperatures_[i] = ir->simtempvals->temperatures[i];
- }
+ temperatures_ = inputrec.simtempvals->temperatures;
}
- else
+
+ if (EI_MD(inputrec.eI) && !simulationsShareState)
{
- numTemperatures_ = 0;
+ conservedEnergyTracker_ = std::make_unique<EnergyDriftTracker>(mtop.natoms);
}
}
EnergyOutput::~EnergyOutput()
{
- sfree(igrp_);
- sfree(tmp_r_);
- sfree(tmp_v_);
done_ebin(ebin_);
- done_mde_delta_h_coll(dhc_);
- sfree(dE_);
- if (numTemperatures_ > 0)
- {
- sfree(temperatures_);
- }
}
} // namespace gmx
*/
static void print_lambda_vector(t_lambda* fep, int i, bool get_native_lambda, bool get_names, char* str)
{
- int j, k = 0;
+ int k = 0;
int Nsep = 0;
- for (j = 0; j < efptNR; j++)
+ for (auto j : keysOf(fep->separate_dvdl))
{
if (fep->separate_dvdl[j])
{
{
str += sprintf(str, "("); /* set the opening parenthesis*/
}
- for (j = 0; j < efptNR; j++)
+ for (auto j : keysOf(fep->separate_dvdl))
{
if (fep->separate_dvdl[j])
{
}
else
{
- str += sprintf(str, "%s", efpt_singular_names[j]);
+ str += sprintf(str, "%s", enumValueToStringSingular(j));
}
/* print comma for the next item */
if (k < Nsep - 1)
FILE* fp;
const char *dhdl = "dH/d\\lambda", *deltag = "\\DeltaH", *lambda = "\\lambda",
*lambdastate = "\\lambda state";
- int i, nsets, nsets_de, nsetsbegin;
- int n_lambda_terms = 0;
- t_lambda* fep = ir->fepvals; /* for simplicity */
- t_expanded* expand = ir->expandedvals;
- char lambda_vec_str[STRLEN], lambda_name_str[STRLEN];
+ int i, nsets, nsets_de, nsetsbegin;
+ int n_lambda_terms = 0;
+ t_lambda* fep = ir->fepvals.get(); /* for simplicity */
+ char lambda_vec_str[STRLEN], lambda_name_str[STRLEN];
int nsets_dhdl = 0;
int s = 0;
bool write_pV = false;
/* count the number of different lambda terms */
- for (i = 0; i < efptNR; i++)
+ for (auto i : keysOf(fep->separate_dvdl))
{
if (fep->separate_dvdl[i])
{
{
title = gmx::formatString("%s and %s", dhdl, deltag);
label_x = gmx::formatString("Time (ps)");
- label_y = gmx::formatString("%s and %s (%s %s)", dhdl, deltag, unit_energy,
- "[\\8l\\4]\\S-1\\N");
+ label_y = gmx::formatString(
+ "%s and %s (%s %s)", dhdl, deltag, unit_energy, "[\\8l\\4]\\S-1\\N");
}
fp = gmx_fio_fopen(filename, "w+");
xvgr_header(fp, title.c_str(), label_x, label_y, exvggtXNY, oenv);
{
buf = gmx::formatString("T = %g (K) ", ir->opts.ref_t[0]);
}
- if ((ir->efep != efepSLOWGROWTH) && (ir->efep != efepEXPANDED))
+ if ((ir->efep != FreeEnergyPerturbationType::SlowGrowth)
+ && (ir->efep != FreeEnergyPerturbationType::Expanded)
+ && !(ir->bDoAwh && awhHasFepLambdaDimension(*ir->awhParams)))
{
if ((fep->init_lambda >= 0) && (n_lambda_terms == 1))
{
{
print_lambda_vector(fep, fep->init_fep_state, true, false, lambda_vec_str);
print_lambda_vector(fep, fep->init_fep_state, true, true, lambda_name_str);
- buf += gmx::formatString("%s %d: %s = %s", lambdastate, fep->init_fep_state,
- lambda_name_str, lambda_vec_str);
+ buf += gmx::formatString(
+ "%s %d: %s = %s", lambdastate, fep->init_fep_state, lambda_name_str, lambda_vec_str);
}
}
xvgr_subtitle(fp, buf.c_str(), oenv);
nsets_dhdl = 0;
- if (fep->dhdl_derivatives == edhdlderivativesYES)
+ if (fep->dhdl_derivatives == DhDlDerivativeCalculation::Yes)
{
nsets_dhdl = n_lambda_terms;
}
nsets = nsets_dhdl + nsets_de; /* dhdl + fep differences */
- if (fep->n_lambda > 0 && (expand->elmcmove > elmcmoveNO))
+ if (haveFepLambdaMoves(*ir))
{
nsets += 1; /*add fep state for expanded ensemble */
}
- if (fep->edHdLPrintEnergy != edHdLPrintEnergyNO)
+ if (fep->edHdLPrintEnergy != FreeEnergyPrintEnergy::No)
{
nsets += 1; /* add energy to the dhdl as well */
}
nsetsextend = nsets;
- if ((ir->epc != epcNO) && (fep->n_lambda > 0) && (fep->init_lambda < 0))
+ if ((ir->epc != PressureCoupling::No) && (fep->n_lambda > 0) && (fep->init_lambda < 0))
{
nsetsextend += 1; /* for PV term, other terms possible if required for
the reduced potential (only needed with foreign
}
std::vector<std::string> setname(nsetsextend);
- if (expand->elmcmove > elmcmoveNO)
+ if (haveFepLambdaMoves(*ir))
{
/* state for the fep_vals, if we have alchemical sampling */
setname[s++] = "Thermodynamic state";
}
- if (fep->edHdLPrintEnergy != edHdLPrintEnergyNO)
+ if (fep->edHdLPrintEnergy != FreeEnergyPrintEnergy::No)
{
std::string energy;
switch (fep->edHdLPrintEnergy)
{
- case edHdLPrintEnergyPOTENTIAL:
+ case FreeEnergyPrintEnergy::Potential:
energy = gmx::formatString("%s (%s)", "Potential Energy", unit_energy);
break;
- case edHdLPrintEnergyTOTAL:
- case edHdLPrintEnergyYES:
+ case FreeEnergyPrintEnergy::Total:
+ case FreeEnergyPrintEnergy::Yes:
default: energy = gmx::formatString("%s (%s)", "Total Energy", unit_energy);
}
setname[s++] = energy;
}
- if (fep->dhdl_derivatives == edhdlderivativesYES)
+ if (fep->dhdl_derivatives == DhDlDerivativeCalculation::Yes)
{
- for (i = 0; i < efptNR; i++)
+ for (auto i : keysOf(fep->separate_dvdl))
{
if (fep->separate_dvdl[i])
{
{
lam = fep->all_lambda[i][fep->init_fep_state];
}
- derivative = gmx::formatString("%s %s = %.4f", dhdl, efpt_singular_names[i], lam);
+ derivative = gmx::formatString("%s %s = %.4f", dhdl, enumValueToStringSingular(i), lam);
}
setname[s++] = derivative;
}
* from this xvg legend.
*/
- if (expand->elmcmove > elmcmoveNO)
+ if (haveFepLambdaMoves(*ir))
{
nsetsbegin = 1; /* for including the expanded ensemble */
}
nsetsbegin = 0;
}
- if (fep->edHdLPrintEnergy != edHdLPrintEnergyNO)
+ if (fep->edHdLPrintEnergy != FreeEnergyPrintEnergy::No)
{
nsetsbegin += 1;
}
real tmass,
const gmx_enerdata_t* enerd,
const t_lambda* fep,
- const t_expanded* expand,
const matrix box,
PTCouplingArrays ptCouplingArrays,
int fep_state,
- const tensor svir,
- const tensor fvir,
const tensor vir,
const tensor pres,
const gmx_ekindata_t* ekind,
const rvec mu_tot,
const gmx::Constraints* constr)
{
- int j, k, kk, n, gid;
- real crmsd[2], tmp6[6];
- real bs[tricl_boxs_nm.size()], vol, dens, pv, enthalpy;
- real eee[egNR];
- double store_dhdl[efptNR];
- real store_energy = 0;
- real tmp;
+ int j, k, kk, n, gid;
+ real crmsd[2], tmp6[6];
+ real bs[tricl_boxs_nm.size()], vol, dens, enthalpy;
+ real eee[static_cast<int>(NonBondedEnergyTerms::Count)];
+ gmx::EnumerationArray<FreeEnergyPerturbationCouplingType, double> store_dhdl;
+ real store_energy = 0;
+ real tmp;
+ real pv = 0.0; // static analyzer warns about uninitialized variable warnings here.
/* Do NOT use the box in the state variable, but the separate box provided
* as an argument. This is because we sometimes need to write the box from
nboxs = boxs_nm.size();
}
vol = box[XX][XX] * box[YY][YY] * box[ZZ][ZZ];
- dens = (tmass * AMU) / (vol * NANO * NANO * NANO);
+ dens = (tmass * gmx::c_amu) / (vol * gmx::c_nano * gmx::c_nano * gmx::c_nano);
add_ebin(ebin_, ib_, nboxs, bs, bSum);
add_ebin(ebin_, ivol_, 1, &vol, bSum);
add_ebin(ebin_, idens_, 1, &dens, bSum);
{
/* This is pV (in kJ/mol). The pressure is the reference pressure,
not the instantaneous pressure */
- pv = vol * ref_p_ / PRESFAC;
+ pv = vol * ref_p_ / gmx::c_presfac;
add_ebin(ebin_, ipv_, 1, &pv, bSum);
enthalpy = pv + enerd->term[F_ETOT];
add_ebin(ebin_, ienthalpy_, 1, &enthalpy, bSum);
}
}
- if (bConstrVir_)
- {
- add_ebin(ebin_, isvir_, 9, svir[0], bSum);
- add_ebin(ebin_, ifvir_, 9, fvir[0], bSum);
- }
if (bPres_)
{
add_ebin(ebin_, ivir_, 9, vir[0], bSum);
tmp = (pres[ZZ][ZZ] - (pres[XX][XX] + pres[YY][YY]) * 0.5) * box[ZZ][ZZ];
add_ebin(ebin_, isurft_, 1, &tmp, bSum);
}
- if (epc_ == epcPARRINELLORAHMAN || epc_ == epcMTTK)
+ if (epc_ == PressureCoupling::ParrinelloRahman || epc_ == PressureCoupling::Mttk)
{
tmp6[0] = ptCouplingArrays.boxv[XX][XX];
tmp6[1] = ptCouplingArrays.boxv[YY][YY];
if (ekind && ekind->cosacc.cos_accel != 0)
{
vol = box[XX][XX] * box[YY][YY] * box[ZZ][ZZ];
- dens = (tmass * AMU) / (vol * NANO * NANO * NANO);
+ dens = (tmass * gmx::c_amu) / (vol * gmx::c_nano * gmx::c_nano * gmx::c_nano);
add_ebin(ebin_, ivcos_, 1, &(ekind->cosacc.vcos), bSum);
/* 1/viscosity, unit 1/(kg m^-1 s^-1) */
tmp = 1
- / (ekind->cosacc.cos_accel / (ekind->cosacc.vcos * PICO) * dens
- * gmx::square(box[ZZ][ZZ] * NANO / (2 * M_PI)));
+ / (ekind->cosacc.cos_accel / (ekind->cosacc.vcos * gmx::c_pico) * dens
+ * gmx::square(box[ZZ][ZZ] * gmx::c_nano / (2 * M_PI)));
add_ebin(ebin_, ivisc_, 1, &tmp, bSum);
}
if (nE_ > 1)
for (j = i; (j < nEg_); j++)
{
gid = GID(i, j, nEg_);
- for (k = kk = 0; (k < egNR); k++)
+ for (k = kk = 0; (k < static_cast<int>(NonBondedEnergyTerms::Count)); k++)
{
if (bEInd_[k])
{
- eee[kk++] = enerd->grpp.ener[k][gid];
+ eee[kk++] = enerd->grpp.energyGroupPairTerms[k][gid];
}
}
add_ebin(ebin_, igrp_[n], nEc_, eee, bSum);
{
tmp_r_[i] = ekind->tcstat[i].T;
}
- add_ebin(ebin_, itemp_, nTC_, tmp_r_, bSum);
+ add_ebin(ebin_, itemp_, nTC_, tmp_r_.data(), bSum);
- if (etc_ == etcNOSEHOOVER)
+ if (etc_ == TemperatureCoupling::NoseHoover)
{
/* whether to print Nose-Hoover chains: */
if (bPrintNHChains_)
tmp_r_[2 * k + 1] = ptCouplingArrays.nosehoover_vxi[k];
}
}
- add_ebin(ebin_, itc_, mde_n_, tmp_r_, bSum);
+ add_ebin(ebin_, itc_, mde_n_, tmp_r_.data(), bSum);
if (bMTTK_)
{
tmp_r_[2 * k + 1] = ptCouplingArrays.nhpres_vxi[k];
}
}
- add_ebin(ebin_, itcb_, mdeb_n_, tmp_r_, bSum);
+ add_ebin(ebin_, itcb_, mdeb_n_, tmp_r_.data(), bSum);
}
}
else
tmp_r_[2 * i] = ptCouplingArrays.nosehoover_xi[i];
tmp_r_[2 * i + 1] = ptCouplingArrays.nosehoover_vxi[i];
}
- add_ebin(ebin_, itc_, mde_n_, tmp_r_, bSum);
+ add_ebin(ebin_, itc_, mde_n_, tmp_r_.data(), bSum);
}
}
}
- else if (etc_ == etcBERENDSEN || etc_ == etcYES || etc_ == etcVRESCALE)
+ else if (etc_ == TemperatureCoupling::Berendsen || etc_ == TemperatureCoupling::Yes
+ || etc_ == TemperatureCoupling::VRescale)
{
for (int i = 0; (i < nTC_); i++)
{
tmp_r_[i] = ekind->tcstat[i].lambda;
}
- add_ebin(ebin_, itc_, nTC_, tmp_r_, bSum);
+ add_ebin(ebin_, itc_, nTC_, tmp_r_.data(), bSum);
}
}
- if (ekind && nU_ > 1)
- {
- for (int i = 0; (i < nU_); i++)
- {
- copy_rvec(ekind->grpstat[i].u, tmp_v_[i]);
- }
- add_ebin(ebin_, iu_, 3 * nU_, tmp_v_[0], bSum);
- }
-
ebin_increase_count(1, ebin_, bSum);
// BAR + thermodynamic integration values
{
/* zero for simulated tempering */
dE_[i] = foreignTerms.deltaH(i);
- if (numTemperatures_ > 0)
+ if (!temperatures_.empty())
{
- GMX_RELEASE_ASSERT(numTemperatures_ > fep_state,
+ GMX_RELEASE_ASSERT(gmx::ssize(temperatures_) > fep_state,
"Number of lambdas in state is bigger then in input record");
GMX_RELEASE_ASSERT(
- numTemperatures_ >= foreignTerms.numLambdas(),
+ gmx::ssize(temperatures_) >= foreignTerms.numLambdas(),
"Number of lambdas in energy data is bigger then in input record");
/* MRS: is this right, given the way we have defined the exchange probabilities? */
/* is this even useful to have at all? */
/* the current free energy state */
/* print the current state if we are doing expanded ensemble */
- if (expand->elmcmove > elmcmoveNO)
+ if (haveFepLambdaMoves_)
{
fprintf(fp_dhdl_, " %4d", fep_state);
}
/* total energy (for if the temperature changes */
- if (fep->edHdLPrintEnergy != edHdLPrintEnergyNO)
+ if (fep->edHdLPrintEnergy != FreeEnergyPrintEnergy::No)
{
switch (fep->edHdLPrintEnergy)
{
- case edHdLPrintEnergyPOTENTIAL: store_energy = enerd->term[F_EPOT]; break;
- case edHdLPrintEnergyTOTAL:
- case edHdLPrintEnergyYES:
+ case FreeEnergyPrintEnergy::Potential:
+ store_energy = enerd->term[F_EPOT];
+ break;
+ case FreeEnergyPrintEnergy::Total:
+ case FreeEnergyPrintEnergy::Yes:
default: store_energy = enerd->term[F_ETOT];
}
fprintf(fp_dhdl_, " %#.8g", store_energy);
}
- if (fep->dhdl_derivatives == edhdlderivativesYES)
+ if (fep->dhdl_derivatives == DhDlDerivativeCalculation::Yes)
{
- for (int i = 0; i < efptNR; i++)
+ for (auto i : keysOf(fep->separate_dvdl))
{
if (fep->separate_dvdl[i])
{
/* assumes F_DVDL is first */
- fprintf(fp_dhdl_, " %#.8g", enerd->term[F_DVDL + i]);
+ fprintf(fp_dhdl_, " %#.8g", enerd->term[F_DVDL + static_cast<int>(i)]);
}
}
}
{
fprintf(fp_dhdl_, " %#.8g", dE_[i]);
}
- if (bDynBox_ && bDiagPres_ && (epc_ != epcNO) && foreignTerms.numLambdas() > 0
- && (fep->init_lambda < 0))
+ if (bDynBox_ && bDiagPres_ && (epc_ != PressureCoupling::No)
+ && foreignTerms.numLambdas() > 0 && (fep->init_lambda < 0))
{
fprintf(fp_dhdl_, " %#.8g", pv); /* PV term only needed when
there are alternate state
if (dhc_ && bDoDHDL)
{
int idhdl = 0;
- for (int i = 0; i < efptNR; i++)
+ for (auto i : keysOf(fep->separate_dvdl))
{
if (fep->separate_dvdl[i])
{
/* assumes F_DVDL is first */
- store_dhdl[idhdl] = enerd->term[F_DVDL + i];
+ store_dhdl[idhdl] = enerd->term[F_DVDL + static_cast<int>(i)];
idhdl += 1;
}
}
store_energy = enerd->term[F_ETOT];
/* store_dh is dE */
- mde_delta_h_coll_add_dh(dhc_, static_cast<double>(fep_state), store_energy, pv,
- store_dhdl, dE_ + fep->lambda_start_n, time);
+ mde_delta_h_coll_add_dh(dhc_.get(),
+ static_cast<double>(fep_state),
+ store_energy,
+ pv,
+ store_dhdl,
+ dE_.data() + fep->lambda_start_n,
+ time);
}
}
+
+ if (conservedEnergyTracker_)
+ {
+ conservedEnergyTracker_->addPoint(
+ time, bEner_[F_ECONSERVED] ? enerd->term[F_ECONSERVED] : enerd->term[F_ETOT]);
+ }
}
void EnergyOutput::recordNonEnergyStep()
fprintf(log,
" %12s %12s\n"
" %12s %12.5f\n\n",
- "Step", "Time", gmx_step_str(steps, buf), time);
+ "Step",
+ "Time",
+ gmx_step_str(steps, buf),
+ time);
}
void EnergyOutput::printStepToEnergyFile(ener_file* fp_ene,
nr[i] = 0;
}
- if (bOR && fcd->orires->nr > 0)
+ if (bOR && fcd->orires)
{
t_oriresdata& orires = *fcd->orires;
diagonalize_orires_tensors(&orires);
- nr[enxOR] = orires.nr;
- block[enxOR] = orires.otav;
+ nr[enxOR] = orires.numRestraints;
+ block[enxOR] = orires.orientationsTimeAndEnsembleAv.data();
id[enxOR] = enxOR;
- nr[enxORI] = (orires.oinsl != orires.otav) ? orires.nr : 0;
- block[enxORI] = orires.oinsl;
+ nr[enxORI] = (orires.orientations.data() != orires.orientationsTimeAndEnsembleAv.data())
+ ? orires.numRestraints
+ : 0;
+ block[enxORI] = orires.orientations.data();
id[enxORI] = enxORI;
- nr[enxORT] = orires.nex * 12;
- block[enxORT] = orires.eig;
+ nr[enxORT] = ssize(orires.eigenOutput);
+ block[enxORT] = orires.eigenOutput.data();
id[enxORT] = enxORT;
}
fr.block[b].id = id[b];
fr.block[b].sub[0].nr = nr[b];
#if !GMX_DOUBLE
- fr.block[b].sub[0].type = xdr_datatype_float;
+ fr.block[b].sub[0].type = XdrDataType::Float;
fr.block[b].sub[0].fval = block[b];
#else
- fr.block[b].sub[0].type = xdr_datatype_double;
+ fr.block[b].sub[0].type = XdrDataType::Double;
fr.block[b].sub[0].dval = block[b];
#endif
}
fr.block[db].sub[0].nr = ndisre;
fr.block[db].sub[1].nr = ndisre;
#if !GMX_DOUBLE
- fr.block[db].sub[0].type = xdr_datatype_float;
- fr.block[db].sub[1].type = xdr_datatype_float;
+ fr.block[db].sub[0].type = XdrDataType::Float;
+ fr.block[db].sub[1].type = XdrDataType::Float;
fr.block[db].sub[0].fval = disres.rt;
fr.block[db].sub[1].fval = disres.rm3tav;
#else
- fr.block[db].sub[0].type = xdr_datatype_double;
- fr.block[db].sub[1].type = xdr_datatype_double;
+ fr.block[db].sub[0].type = XdrDataType::Double;
+ fr.block[db].sub[1].type = XdrDataType::Double;
fr.block[db].sub[0].dval = disres.rt;
fr.block[db].sub[1].dval = disres.rm3tav;
#endif
/* Free energy perturbation blocks */
if (dhc_)
{
- mde_delta_h_coll_handle_block(dhc_, &fr, fr.nblock);
+ mde_delta_h_coll_handle_block(dhc_.get(), &fr, fr.nblock);
}
/* we can now free & reset the data in the blocks */
if (dhc_)
{
- mde_delta_h_coll_reset(dhc_);
+ mde_delta_h_coll_reset(dhc_.get());
}
/* AWH bias blocks. */
free_enxframe(&fr);
if (log)
{
- if (bOR && fcd->orires->nr > 0)
+ if (bOR && fcd->orires)
{
- print_orires_log(log, fcd->orires);
+ print_orires_log(log, fcd->orires.get());
}
fprintf(log, " Energies (%s)\n", unit_energy);
}
}
-void EnergyOutput::printAnnealingTemperatures(FILE* log, const SimulationGroups* groups, t_grpopts* opts)
+void EnergyOutput::printAnnealingTemperatures(FILE* log, const SimulationGroups* groups, const t_grpopts* opts)
{
if (log)
{
{
for (int i = 0; i < opts->ngtc; i++)
{
- if (opts->annealing[i] != eannNO)
+ if (opts->annealing[i] != SimulatedAnnealing::No)
{
- fprintf(log, "Current ref_t for group %s: %8.1f\n",
+ fprintf(log,
+ "Current ref_t for group %s: %8.1f\n",
*(groups->groupNames[groups->groups[SimulationAtomGroupType::TemperatureCoupling][i]]),
opts->ref_t[i]);
}
fprintf(log, "\t<==== A V E R A G E S ====>\n");
fprintf(log, "\t<== ############### ======>\n\n");
- fprintf(log, "\tStatistics over %s steps using %s frames\n",
- gmx_step_str(ebin_->nsteps_sim, buf1), gmx_step_str(ebin_->nsum_sim, buf2));
+ fprintf(log,
+ "\tStatistics over %s steps using %s frames\n",
+ gmx_step_str(ebin_->nsteps_sim, buf1),
+ gmx_step_str(ebin_->nsum_sim, buf2));
fprintf(log, "\n");
fprintf(log, " Energies (%s)\n", unit_energy);
pr_ebin(log, ebin_, ib_, bTricl_ ? tricl_boxs_nm.size() : boxs_nm.size(), 5, eprAVER, true);
fprintf(log, "\n");
}
- if (bConstrVir_)
- {
- fprintf(log, " Constraint Virial (%s)\n", unit_energy);
- pr_ebin(log, ebin_, isvir_, 9, 3, eprAVER, false);
- fprintf(log, "\n");
- fprintf(log, " Force Virial (%s)\n", unit_energy);
- pr_ebin(log, ebin_, ifvir_, 9, 3, eprAVER, false);
- fprintf(log, "\n");
- }
if (bPres_)
{
fprintf(log, " Total Virial (%s)\n", unit_energy);
{
int padding = 8 - strlen(unit_energy);
fprintf(log, "%*sEpot (%s) ", padding, "", unit_energy);
- for (int i = 0; (i < egNR); i++)
+ for (auto key : keysOf(bEInd_))
{
- if (bEInd_[i])
+ if (bEInd_[key])
{
- fprintf(log, "%12s ", egrp_nm[i]);
+ fprintf(log, "%12s ", enumValueToString(key));
}
}
fprintf(log, "\n");
int nj = groups->groups[SimulationAtomGroupType::EnergyOutput][j];
int padding =
14 - (strlen(*(groups->groupNames[ni])) + strlen(*(groups->groupNames[nj])));
- fprintf(log, "%*s%s-%s", padding, "", *(groups->groupNames[ni]),
- *(groups->groupNames[nj]));
+ fprintf(log, "%*s%s-%s", padding, "", *(groups->groupNames[ni]), *(groups->groupNames[nj]));
pr_ebin(log, ebin_, igrp_[n], nEc_, nEc_, eprAVER, false);
n++;
}
pr_ebin(log, ebin_, itemp_, nTC_, 4, eprAVER, true);
fprintf(log, "\n");
}
- if (nU_ > 1)
- {
- fprintf(log, "%15s %12s %12s %12s\n", "Group", "Ux", "Uy", "Uz");
- for (int i = 0; (i < nU_); i++)
- {
- int ni = groups->groups[SimulationAtomGroupType::Acceleration][i];
- fprintf(log, "%15s", *groups->groupNames[ni]);
- pr_ebin(log, ebin_, iu_ + 3 * i, 3, 3, eprAVER, false);
- }
- fprintf(log, "\n");
- }
}
}
}
if (dhc_)
{
- mde_delta_h_coll_update_energyhistory(dhc_, enerhist);
+ mde_delta_h_coll_update_energyhistory(dhc_.get(), enerhist);
}
}
gmx_fatal(FARGS,
"Mismatch between number of energies in run input (%u) and checkpoint file (%zu "
"or %zu).",
- nener, enerhist.ener_sum.size(), enerhist.ener_sum_sim.size());
+ nener,
+ enerhist.ener_sum.size(),
+ enerhist.ener_sum_sim.size());
}
ebin_->nsteps = enerhist.nsteps;
}
if (dhc_)
{
- mde_delta_h_coll_restore_energyhistory(dhc_, enerhist.deltaHForeignLambdas.get());
+ mde_delta_h_coll_restore_energyhistory(dhc_.get(), enerhist.deltaHForeignLambdas.get());
}
}
return ebin_->nener;
}
+void EnergyOutput::printEnergyConservation(FILE* fplog, int simulationPart, bool usingMdIntegrator) const
+{
+ if (fplog == nullptr)
+ {
+ return;
+ }
+
+ if (conservedEnergyTracker_)
+ {
+ std::string partName = formatString("simulation part #%d", simulationPart);
+ fprintf(fplog, "\n%s\n", conservedEnergyTracker_->energyDriftString(partName).c_str());
+ }
+ else if (usingMdIntegrator)
+ {
+ fprintf(fplog,
+ "\nCannot report drift of the conserved energy quantity because simulations share "
+ "state\n\n");
+ }
+}
+
} // namespace gmx