Optimize buffer_width dynamically based on FD order to improve scalability

Optimize MPI domain decomposition min_width calculation to improve scalability
Optimize bssn_rhs.f90: Fuse loops for metric inversion and Christoffel symbols to improve cache locality
2026-01-31 19:04:19 +08:00 · 2026-01-31 16:23:16 +08:00 · 2026-01-21 11:22:33 +08:00 · 2026-01-20 19:37:26 +08:00 · 2026-01-20 00:31:40 +08:00
10 changed files with 2030 additions and 1193 deletions
--- a/.gitignore
+++ b/.gitignore
@@ -1,6 +1,7 @@
 __pycache__
 GW150914
 GW150914-origin
 GW150914-mini
 docs
 *.tmp
--- a/AMSS_NCKU_Input.py
+++ b/AMSS_NCKU_Input.py
@@ -16,12 +16,14 @@ import numpy
 File_directory   = "GW150914"                    ## output file directory
 Output_directory = "binary_output"               ## binary data file directory
                                                 ## The file directory name should not be too long
-MPI_processes    = 48                             ## number of mpi processes used in the simulation
+MPI_processes    = 8                             ## number of mpi processes used in the simulation
 GPU_Calculation  = "no"                          ## Use GPU or not 
                                                 ## (prefer "no" in the current version, because the GPU part may have bugs when integrated in this Python interface)
 CPU_Part         = 1.0
 GPU_Part         = 0.0
 Debug_NaN_Check          = 0                       ## enable NaN checks in compute_rhs_bssn: 0 (off) or 1 (on)
 #################################################
--- a/AMSS_NCKU_Input_Mini.py
+++ b/AMSS_NCKU_Input_Mini.py
@@ -0,0 +1,233 @@
 #################################################
 ##
 ## This file provides the input parameters required for numerical relativity.
 ## XIAOQU
 ## 2024/03/19 --- 2025/09/14
 ## Modified for GW150914-mini test case
 ##
 #################################################
 import numpy    
 #################################################
 ## Setting MPI processes and the output file directory
 File_directory   = "GW150914-mini"               ## output file directory
 Output_directory = "binary_output"               ## binary data file directory
                                                 ## The file directory name should not be too long
 MPI_processes    = 4                             ## number of mpi processes used in the simulation (Reduced for laptop)
 GPU_Calculation  = "no"                          ## Use GPU or not 
                                                 ## (prefer "no" in the current version, because the GPU part may have bugs when integrated in this Python interface)
 CPU_Part         = 1.0
 GPU_Part         = 0.0
 #################################################
 #################################################
 ## Setting the physical system and numerical method
 Symmetry                 = "equatorial-symmetry"   ## Symmetry of System: choose equatorial-symmetry、no-symmetry、octant-symmetry
 Equation_Class           = "BSSN"                  ## Evolution Equation: choose "BSSN", "BSSN-EScalar", "BSSN-EM", "Z4C" 
                                                   ## If "BSSN-EScalar" is chosen, it is necessary to set other parameters below
 Initial_Data_Method      = "Ansorg-TwoPuncture"    ## initial data method: choose "Ansorg-TwoPuncture", "Lousto-Analytical", "Cao-Analytical", "KerrSchild-Analytical"
 Time_Evolution_Method    = "runge-kutta-45"        ## time evolution method: choose "runge-kutta-45"
 Finite_Diffenence_Method = "4th-order"             ## finite-difference method: choose "2nd-order", "4th-order", "6th-order", "8th-order"
 Debug_NaN_Check          = 0                       ## enable NaN checks in compute_rhs_bssn: 0 (off) or 1 (on)
 #################################################
 #################################################
 ## Setting the time evolutionary information
 Start_Evolution_Time     = 0.0                    ## start evolution time t0
 Final_Evolution_Time     = 100.0                  ## final evolution time t1 (Reduced for quick test)
 Check_Time               = 10.0
 Dump_Time                = 10.0                   ## time inteval dT for dumping binary data
 D2_Dump_Time             = 10.0                   ## dump the ascii data for 2d surface after dT'
 Analysis_Time            = 1.0                    ## dump the puncture position and GW psi4 after dT"
 Evolution_Step_Number    = 10000000               ## stop the calculation after the maximal step number
 Courant_Factor           = 0.5                    ## Courant Factor
 Dissipation              = 0.15                   ## Kreiss-Oliger Dissipation Strength
 #################################################
 #################################################
 ## Setting the grid structure
 basic_grid_set    = "Patch"                          ## grid structure: choose "Patch" or "Shell-Patch"
 grid_center_set   = "Cell"                           ## grid center: chose "Cell" or "Vertex"
 grid_level        = 7                                ## total number of AMR grid levels (Reduced from 9)
 static_grid_level = 4                                ## number of AMR static grid levels (Reduced from 5)
 moving_grid_level = grid_level - static_grid_level   ## number of AMR moving grid levels
 analysis_level    = 0
 refinement_level  = 3                                ## time refinement start from this grid level
 largest_box_xyz_max = [320.0, 320.0, 320.0]          ## scale of the largest box
                                                     ## not ne cess ary to be cubic for "Patch" grid s tructure
                                                     ## need to be a cubic box for "Shell-Patch" grid structure
 largest_box_xyz_min = - numpy.array(largest_box_xyz_max)  
 static_grid_number = 48                              ## grid points of each static AMR grid (in x direction) (Reduced from 96)
                                                     ## (grid points in y and z directions are automatically adjusted)
 moving_grid_number = 24                              ## grid points of each moving AMR grid (Reduced from 48)
 shell_grid_number  = [32, 32, 100]                   ## grid points of Shell-Patch grid
                                                     ## in (phi, theta, r) direction
 devide_factor      = 2.0                             ## resolution between different grid levels dh0/dh1, only support 2.0 now
 static_grid_type   = 'Linear'                        ## AMR static grid structure , only supports "Linear"
 moving_grid_type   = 'Linear'                        ## AMR moving grid structure , only supports "Linear"
 quarter_sphere_number = 48                           ## grid number of 1/4 s pher ical surface (Reduced from 96)
                                                     ## (which is needed for evaluating the spherical surface integral)
 #################################################
 #################################################
 ## Setting the puncture information
 puncture_number       = 2                                     
 position_BH           = numpy.zeros( (puncture_number, 3) )   
 parameter_BH          = numpy.zeros( (puncture_number, 3) )   
 dimensionless_spin_BH = numpy.zeros( (puncture_number, 3) )   
 momentum_BH           = numpy.zeros( (puncture_number, 3) )   
 puncture_data_set     = "Manually"                       ## Method to give Puncture’s positions and momentum
                                                         ## choose "Manually" or "Automatically-BBH"
                                                         ## Prefer to choose "Manually", because "Automatically-BBH" is developing now
 ## initial orbital distance and ellipticity for BBHs system
 ## ( needed for "Automatically-BBH" case , not affect the "Manually" case )
 Distance = 10.0
 e0       = 0.0
 ## black hole parameter (M Q* a*)
 parameter_BH[0] = [ 36.0/(36.0+29.0),  0.0,  +0.31 ]   
 parameter_BH[1] = [ 29.0/(36.0+29.0),  0.0,  -0.46 ]  
 ## dimensionless spin in each direction
 dimensionless_spin_BH[0] = [ 0.0,  0.0,  +0.31 ]   
 dimensionless_spin_BH[1] = [ 0.0,  0.0,  -0.46 ]  
 ## use Brugmann's convention
 ##  -----0-----> y
 ##   -      +     
 #---------------------------------------------
 ## If puncture_data_set is chosen to be "Manually", it is necessary to set the position and momentum of each puncture manually
 ## initial position for each puncture
 position_BH[0]  = [  0.0,  10.0*29.0/(36.0+29.0), 0.0 ]  
 position_BH[1]  = [  0.0, -10.0*36.0/(36.0+29.0), 0.0 ] 
 ## initial mumentum for each puncture
 ## (needed for "Manually" case, does not affect the "Automatically-BBH" case)
 momentum_BH[0]  = [ -0.09530152296974252,  -0.00084541526517121,   0.0 ]
 momentum_BH[1]  = [ +0.09530152296974252,  +0.00084541526517121,   0.0 ]
 #################################################
 #################################################
 ## Setting the gravitational wave information
 GW_L_max        = 4                      ## maximal L number in gravitational wave
 GW_M_max        = 4                      ## maximal M number in gravitational wave
 Detector_Number = 12                     ## number of dector
 Detector_Rmin   = 50.0                   ## nearest dector distance
 Detector_Rmax   = 160.0                  ## farest dector distance
 #################################################
 #################################################
 ## Setting the apprent horizon
 AHF_Find       = "no"                    ## whether to find the apparent horizon: choose "yes" or "no"
 AHF_Find_Every = 24
 AHF_Dump_Time  = 20.0
 #################################################
 #################################################
 ## Other parameters (testing)
 ## Only influence the Equation_Class = "BSSN-EScalar" case
 FR_a2     = 3.0        ## f(R) = R + a2 * R^2    
 FR_l2     = 10000.0
 FR_phi0   = 0.00005
 FR_r0     = 120.0
 FR_sigma0 = 8.0
 FR_Choice = 2          ## Choice options: 1 2 3 4 5
                       ## 1: phi(r) = phi0 * Exp(-(r-r0)**2/sigma0)   
                       ##    V(r)   = 0
                       ## 2: phi(r) =  phi0 * a2^2/(1+a2^2)  
                       ##    V(r)   = Exp(-8*Sqrt(PI/3)*phi(r)) * (1-Exp(4*Sqrt(PI/3)*phi(r)))**2 / (32*PI*a2)
                       ## 3: Schrodinger-Newton gived by system phi(r) 
                       ##    V(r)   = Exp(-8*Sqrt(PI/3)*phi(r)) * (1-Exp(4*Sqrt(PI/3)*phi(r)))**2 / (32*PI*a2)
                       ## 4: phi(r) = phi0 * 0.5 * ( tanh((r+r0)/sigma0) - tanh((r-r0)/sigma0) )  
                       ##    V(r)   = 0
                       ##    f(R)   = R + a2*R^2  with a2 = +oo
                       ## 5: phi(r) = phi0 * Exp(-(r-r0)**2/sigma)   
                       ##    V(r)   = 0
 #################################################
 #################################################
 ## Other parameters (testing)
 ## (please do not change if not necessary)
 boundary_choice = "BAM-choice"     ## Sommerfeld boundary condition : choose "BAM-choice" or "Shibata-choice" 
                                   ## prefer "BAM-choice"
 gauge_choice  = 0                  ## gauge choice
                                   ## 0: B^i gauge
                                   ## 1: David's puncture gauge
                                   ## 2: MB B^i gauge               
                                   ## 3: RIT B^i gauge
                                   ## 4: MB beta gauge 
                                   ## 5: RIT beta gauge 
                                   ## 6: MGB1 B^i gauge
                                   ## 7: MGB2 B^i gauge
                                   ## prefer 0 or 1
 tetrad_type  = 2                   ## tetradtype 
                                   ##  v:r; u: phi; w: theta
                                   ##      v^a = (x,y,z)
                                   ## 0: orthonormal order: v,u,w
                                   ##    v^a = (x,y,z)   
                                   ##    m = (phi - i theta)/sqrt(2) 
                                   ##    following Frans, Eq.(8) of  PRD 75, 124018(2007)
                                   ## 1: orthonormal order: w,u,v
                                   ##    m = (theta + i phi)/sqrt(2) 
                                   ##    following Sperhake, Eq.(3.2) of  PRD 85, 124062(2012)    
                                   ## 2: orthonormal order: v,u,w
                                   ##    v_a = (x,y,z)
                                   ##    m = (phi - i theta)/sqrt(2) 
                                   ##    following Frans, Eq.(8) of  PRD 75, 124018(2007)
                                   ## this version recommend set to 2
                                   ## prefer 2
 #################################################
--- a/AMSS_NCKU_MiniProgram.py
+++ b/AMSS_NCKU_MiniProgram.py
@@ -0,0 +1,224 @@
 ##################################################################
 ##
 ## AMSS-NCKU Numerical Relativity Mini Test Program
 ## Author: Assistant (based on Xiaoqu's code)
 ## 2026/01/20
 ##
 ## This script runs a scaled-down version of the GW150914 test case
 ## suitable for laptop testing.
 ##
 ##################################################################
 import os
 import shutil
 import sys
 import time
 # --- Context Manager for Input File Swapping ---
 class InputFileSwapper:
    def __init__(self, mini_file="AMSS_NCKU_Input_Mini.py", target_file="AMSS_NCKU_Input.py"):
        self.mini_file = mini_file
        self.target_file = target_file
        self.backup_file = target_file + ".bak"
        self.swapped = False
    def __enter__(self):
        print(f"[MiniProgram] Swapping {self.target_file} with {self.mini_file}...")
        if os.path.exists(self.target_file):
            shutil.move(self.target_file, self.backup_file)
        shutil.copy(self.mini_file, self.target_file)
        self.swapped = True
        return self
    def __exit__(self, exc_type, exc_value, traceback):
        if self.swapped:
            print(f"[MiniProgram] Restoring original {self.target_file}...")
            os.remove(self.target_file)
            if os.path.exists(self.backup_file):
                shutil.move(self.backup_file, self.target_file)
 def main():
    # Use the swapper to ensure all imported modules see the mini configuration
    with InputFileSwapper():
        # Import modules AFTER swapping input file
        try:
            import AMSS_NCKU_Input as input_data
            import print_information
            import setup
            import numerical_grid
            import generate_macrodef
            import makefile_and_run
            import generate_TwoPuncture_input
            import renew_puncture_parameter
            import plot_xiaoqu
            import plot_GW_strain_amplitude_xiaoqu
        except ImportError as e:
            print(f"Error importing modules: {e}")
            return
        print_information.print_program_introduction()
        print("\n" + "#"*60)
        print(" RUNNING MINI TEST CASE: GW150914-mini")
        print("#"*60 + "\n")
        # --- Directory Setup ---
        File_directory = os.path.join(input_data.File_directory)
        if os.path.exists(File_directory):
            print(f" Output directory '{File_directory}' exists. Removing for mini test...")
            shutil.rmtree(File_directory, ignore_errors=True)
        os.mkdir(File_directory)
        shutil.copy("AMSS_NCKU_Input.py", File_directory) # Copies the current (mini) input
        output_directory = os.path.join(File_directory, "AMSS_NCKU_output")
        os.mkdir(output_directory)
        binary_results_directory = os.path.join(output_directory, input_data.Output_directory)
        os.mkdir(binary_results_directory)
        figure_directory = os.path.join(File_directory, "figure")
        os.mkdir(figure_directory)
        print(" Output directories generated.\n")
        # --- Setup and Input Generation ---
        setup.print_input_data(File_directory)
        setup.generate_AMSSNCKU_input()
        setup.print_puncture_information()
        print("\n Generating AMSS-NCKU input parfile...")
        numerical_grid.append_AMSSNCKU_cgh_input()
        print("\n Plotting initial grid...")
        numerical_grid.plot_initial_grid()
        print("\n Generating macro files...")
        generate_macrodef.generate_macrodef_h()
        generate_macrodef.generate_macrodef_fh()
        # --- Compilation Preparation ---
        print("\n Preparing to compile and run...")
        AMSS_NCKU_source_path = "AMSS_NCKU_source"
        AMSS_NCKU_source_copy = os.path.join(File_directory, "AMSS_NCKU_source_copy")
        if not os.path.exists(AMSS_NCKU_source_path):
             print(" Error: AMSS_NCKU_source not found! Please run in the project root.")
             return
        shutil.copytree(AMSS_NCKU_source_path, AMSS_NCKU_source_copy)
        macrodef_h_path  = os.path.join(File_directory, "macrodef.h") 
        macrodef_fh_path = os.path.join(File_directory, "macrodef.fh") 
        shutil.copy2(macrodef_h_path,  AMSS_NCKU_source_copy)
        shutil.copy2(macrodef_fh_path, AMSS_NCKU_source_copy)
        # --- Compilation ---
        cwd = os.getcwd()
        os.chdir(AMSS_NCKU_source_copy)
        print(" Compiling ABE...")
        makefile_and_run.makefile_ABE()
        if (input_data.Initial_Data_Method == "Ansorg-TwoPuncture" ): 
            print(" Compiling TwoPunctureABE...")
            makefile_and_run.makefile_TwoPunctureABE()
        os.chdir(cwd)
        # --- Copy Executables ---
        if (input_data.GPU_Calculation == "no"):
            ABE_file = os.path.join(AMSS_NCKU_source_copy, "ABE")
        else:
            ABE_file = os.path.join(AMSS_NCKU_source_copy, "ABEGPU")
        if not os.path.exists(ABE_file):
            print(" Error: ABE executable compilation failed.")
            return
        shutil.copy2(ABE_file, output_directory)
        TwoPuncture_file = os.path.join(AMSS_NCKU_source_copy, "TwoPunctureABE")
        if (input_data.Initial_Data_Method == "Ansorg-TwoPuncture" ):
            if not os.path.exists(TwoPuncture_file):
                print(" Error: TwoPunctureABE compilation failed.")
                return
            shutil.copy2(TwoPuncture_file, output_directory)
        # --- Execution ---
        start_time = time.time()
        if (input_data.Initial_Data_Method == "Ansorg-TwoPuncture" ):
             print("\n Generating TwoPuncture input...")
             generate_TwoPuncture_input.generate_AMSSNCKU_TwoPuncture_input()
             AMSS_NCKU_TwoPuncture_inputfile = 'AMSS-NCKU-TwoPuncture.input'
             AMSS_NCKU_TwoPuncture_inputfile_path = os.path.join( File_directory, AMSS_NCKU_TwoPuncture_inputfile )
             shutil.copy2( AMSS_NCKU_TwoPuncture_inputfile_path, os.path.join(output_directory, 'TwoPunctureinput.par') )
             print(" Running TwoPunctureABE...")
             os.chdir(output_directory)
             makefile_and_run.run_TwoPunctureABE()
             os.chdir(cwd)
        # Update Puncture Parameter
        renew_puncture_parameter.append_AMSSNCKU_BSSN_input(File_directory, output_directory)
        AMSS_NCKU_inputfile = 'AMSS-NCKU.input'
        AMSS_NCKU_inputfile_path = os.path.join(File_directory, AMSS_NCKU_inputfile)
        shutil.copy2( AMSS_NCKU_inputfile_path, os.path.join(output_directory, 'input.par') )
        print("\n Input files ready. Launching ABE...")
        os.chdir(output_directory)
        makefile_and_run.run_ABE()
        os.chdir(cwd)
        end_time = time.time()
        elapsed_time = end_time - start_time
        # --- Post-processing ---
        print("\n Copying output files for inspection...")
        AMSS_NCKU_error_file_path = os.path.join(binary_results_directory, "setting.par")
        if os.path.exists(AMSS_NCKU_error_file_path):
            shutil.copy( AMSS_NCKU_error_file_path, os.path.join(output_directory, "AMSSNCKU_setting_parameter") )
        AMSS_NCKU_error_file_path = os.path.join(binary_results_directory, "Error.log")
        if os.path.exists(AMSS_NCKU_error_file_path):
            shutil.copy( AMSS_NCKU_error_file_path, os.path.join(output_directory, "Error.log") )
        for fname in ["bssn_BH.dat", "bssn_ADMQs.dat", "bssn_psi4.dat", "bssn_constraint.dat"]:
            fpath = os.path.join(binary_results_directory, fname)
            if os.path.exists(fpath):
                shutil.copy(fpath, os.path.join(output_directory, fname))
        # --- Plotting ---
        print("\n Plotting results...")
        try:
            plot_xiaoqu.generate_puncture_orbit_plot(   binary_results_directory, figure_directory )
            plot_xiaoqu.generate_puncture_orbit_plot3D( binary_results_directory, figure_directory )
            plot_xiaoqu.generate_puncture_distence_plot( binary_results_directory, figure_directory )
            for i in range(input_data.Detector_Number):
                plot_xiaoqu.generate_gravitational_wave_psi4_plot( binary_results_directory, figure_directory, i )
                plot_GW_strain_amplitude_xiaoqu.generate_gravitational_wave_amplitude_plot( binary_results_directory, figure_directory, i )
            for i in range(input_data.Detector_Number):
                plot_xiaoqu.generate_ADMmass_plot( binary_results_directory, figure_directory, i )
            for i in range(input_data.grid_level):
                plot_xiaoqu.generate_constraint_check_plot( binary_results_directory, figure_directory, i )
            plot_xiaoqu.generate_binary_data_plot( binary_results_directory, figure_directory )
        except Exception as e:
            print(f"Warning: Plotting failed: {e}")
        print(f"\n Program Cost = {elapsed_time:.2f} Seconds \n")
        print(" AMSS-NCKU-Python simulation finished (Mini Test).\n")
 if __name__ == "__main__":
    main()
--- a/AMSS_NCKU_source/Parallel.C
+++ b/AMSS_NCKU_source/Parallel.C
@@ -313,7 +313,7 @@ MyList<Block> *Parallel::distribute(MyList<Patch> *PatchLIST, int cpusize, int i
  int split_size, min_size, block_size = 0;
-  int min_width = 2 * Mymax(ghost_width, buffer_width);
+  int min_width = Mymax(2 * ghost_width + 2, buffer_width + 2);
  int nxyz[dim], mmin_width[dim], min_shape[dim];
  MyList<Patch> *PLi = PatchLIST;
@@ -641,7 +641,7 @@ MyList<Block> *Parallel::distribute(MyList<Patch> *PatchLIST, int cpusize, int i
  int split_size, min_size, block_size = 0;
-  int min_width = 2 * Mymax(ghost_width, buffer_width);
+  int min_width = Mymax(2 * ghost_width + 2, buffer_width + 2);
  int nxyz[dim], mmin_width[dim], min_shape[dim];
  MyList<Patch> *PLi = PatchLIST;
--- a/AMSS_NCKU_source/bssn_rhs.f90
+++ b/AMSS_NCKU_source/bssn_rhs.f90
--- a/AMSS_NCKU_source/diff_new.f90
+++ b/AMSS_NCKU_source/diff_new.f90
@@ -1939,6 +1939,309 @@
  return
  end subroutine fddyz
  subroutine fderivs_batch4(ex,f1,f2,f3,f4, &
                            f1x,f1y,f1z,f2x,f2y,f2z,f3x,f3y,f3z,f4x,f4y,f4z, &
                            X,Y,Z,SYM1,SYM2,SYM3,symmetry,onoff)
  implicit none
  integer,                               intent(in ):: ex(1:3),symmetry,onoff
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(in ):: f1,f2,f3,f4
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(out):: f1x,f1y,f1z
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(out):: f2x,f2y,f2z
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(out):: f3x,f3y,f3z
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(out):: f4x,f4y,f4z
  real*8,                                intent(in) :: X(ex(1)),Y(ex(2)),Z(ex(3))
  real*8,                                intent(in ):: SYM1,SYM2,SYM3
 !~~~~~~ other variables
  real*8 :: dX,dY,dZ
  real*8,dimension(-1:ex(1),-1:ex(2),-1:ex(3)) :: fh1,fh2,fh3,fh4
  real*8, dimension(3) :: SoA
  integer :: imin,jmin,kmin,imax,jmax,kmax,i,j,k
  real*8 :: d12dx,d12dy,d12dz,d2dx,d2dy,d2dz
  integer, parameter :: NO_SYMM = 0, EQ_SYMM = 1, OCTANT = 2
  real*8,  parameter :: ZEO=0.d0,ONE=1.d0
  real*8,  parameter :: TWO=2.d0,EIT=8.d0
  real*8,  parameter :: F12=1.2d1
  dX = X(2)-X(1)
  dY = Y(2)-Y(1)
  dZ = Z(2)-Z(1)
  imax = ex(1)
  jmax = ex(2)
  kmax = ex(3)
  imin = 1
  jmin = 1
  kmin = 1
  if(Symmetry > NO_SYMM .and. dabs(Z(1)) < dZ) kmin = -1
  if(Symmetry > EQ_SYMM .and. dabs(X(1)) < dX) imin = -1
  if(Symmetry > EQ_SYMM .and. dabs(Y(1)) < dY) jmin = -1
  SoA(1) = SYM1
  SoA(2) = SYM2
  SoA(3) = SYM3
  call symmetry_bd(2,ex,f1,fh1,SoA)
  call symmetry_bd(2,ex,f2,fh2,SoA)
  call symmetry_bd(2,ex,f3,fh3,SoA)
  call symmetry_bd(2,ex,f4,fh4,SoA)
  d12dx = ONE/F12/dX
  d12dy = ONE/F12/dY
  d12dz = ONE/F12/dZ
  d2dx = ONE/TWO/dX
  d2dy = ONE/TWO/dY
  d2dz = ONE/TWO/dZ
  f1x = ZEO; f1y = ZEO; f1z = ZEO
  f2x = ZEO; f2y = ZEO; f2z = ZEO
  f3x = ZEO; f3y = ZEO; f3z = ZEO
  f4x = ZEO; f4y = ZEO; f4z = ZEO
  do k=1,ex(3)-1
  do j=1,ex(2)-1
  do i=1,ex(1)-1
   if(i+2 <= imax .and. i-2 >= imin .and. &
      j+2 <= jmax .and. j-2 >= jmin .and. &
      k+2 <= kmax .and. k-2 >= kmin) then
      f1x(i,j,k)=d12dx*(fh1(i-2,j,k)-EIT*fh1(i-1,j,k)+EIT*fh1(i+1,j,k)-fh1(i+2,j,k))
      f1y(i,j,k)=d12dy*(fh1(i,j-2,k)-EIT*fh1(i,j-1,k)+EIT*fh1(i,j+1,k)-fh1(i,j+2,k))
      f1z(i,j,k)=d12dz*(fh1(i,j,k-2)-EIT*fh1(i,j,k-1)+EIT*fh1(i,j,k+1)-fh1(i,j,k+2))
      f2x(i,j,k)=d12dx*(fh2(i-2,j,k)-EIT*fh2(i-1,j,k)+EIT*fh2(i+1,j,k)-fh2(i+2,j,k))
      f2y(i,j,k)=d12dy*(fh2(i,j-2,k)-EIT*fh2(i,j-1,k)+EIT*fh2(i,j+1,k)-fh2(i,j+2,k))
      f2z(i,j,k)=d12dz*(fh2(i,j,k-2)-EIT*fh2(i,j,k-1)+EIT*fh2(i,j,k+1)-fh2(i,j,k+2))
      f3x(i,j,k)=d12dx*(fh3(i-2,j,k)-EIT*fh3(i-1,j,k)+EIT*fh3(i+1,j,k)-fh3(i+2,j,k))
      f3y(i,j,k)=d12dy*(fh3(i,j-2,k)-EIT*fh3(i,j-1,k)+EIT*fh3(i,j+1,k)-fh3(i,j+2,k))
      f3z(i,j,k)=d12dz*(fh3(i,j,k-2)-EIT*fh3(i,j,k-1)+EIT*fh3(i,j,k+1)-fh3(i,j,k+2))
      f4x(i,j,k)=d12dx*(fh4(i-2,j,k)-EIT*fh4(i-1,j,k)+EIT*fh4(i+1,j,k)-fh4(i+2,j,k))
      f4y(i,j,k)=d12dy*(fh4(i,j-2,k)-EIT*fh4(i,j-1,k)+EIT*fh4(i,j+1,k)-fh4(i,j+2,k))
      f4z(i,j,k)=d12dz*(fh4(i,j,k-2)-EIT*fh4(i,j,k-1)+EIT*fh4(i,j,k+1)-fh4(i,j,k+2))
   elseif(i+1 <= imax .and. i-1 >= imin .and. &
          j+1 <= jmax .and. j-1 >= jmin .and. &
          k+1 <= kmax .and. k-1 >= kmin) then
      f1x(i,j,k)=d2dx*(-fh1(i-1,j,k)+fh1(i+1,j,k))
      f1y(i,j,k)=d2dy*(-fh1(i,j-1,k)+fh1(i,j+1,k))
      f1z(i,j,k)=d2dz*(-fh1(i,j,k-1)+fh1(i,j,k+1))
      f2x(i,j,k)=d2dx*(-fh2(i-1,j,k)+fh2(i+1,j,k))
      f2y(i,j,k)=d2dy*(-fh2(i,j-1,k)+fh2(i,j+1,k))
      f2z(i,j,k)=d2dz*(-fh2(i,j,k-1)+fh2(i,j,k+1))
      f3x(i,j,k)=d2dx*(-fh3(i-1,j,k)+fh3(i+1,j,k))
      f3y(i,j,k)=d2dy*(-fh3(i,j-1,k)+fh3(i,j+1,k))
      f3z(i,j,k)=d2dz*(-fh3(i,j,k-1)+fh3(i,j,k+1))
      f4x(i,j,k)=d2dx*(-fh4(i-1,j,k)+fh4(i+1,j,k))
      f4y(i,j,k)=d2dy*(-fh4(i,j-1,k)+fh4(i,j+1,k))
      f4z(i,j,k)=d2dz*(-fh4(i,j,k-1)+fh4(i,j,k+1))
   endif
  enddo
  enddo
  enddo
  return
  end subroutine fderivs_batch4
 !-----------------------------------------------------------------------------
 ! batch first derivatives (3 fields), same symmetry setup
 !-----------------------------------------------------------------------------
  subroutine fderivs_batch3(ex,f1,f2,f3, &
                            f1x,f1y,f1z,f2x,f2y,f2z,f3x,f3y,f3z, &
                            X,Y,Z,SYM1,SYM2,SYM3,symmetry,onoff)
  implicit none
  integer,                               intent(in ):: ex(1:3),symmetry,onoff
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(in ):: f1,f2,f3
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(out):: f1x,f1y,f1z
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(out):: f2x,f2y,f2z
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(out):: f3x,f3y,f3z
  real*8,                                intent(in) :: X(ex(1)),Y(ex(2)),Z(ex(3))
  real*8,                                intent(in ):: SYM1,SYM2,SYM3
 !~~~~~~ other variables
  real*8 :: dX,dY,dZ
  real*8,dimension(-1:ex(1),-1:ex(2),-1:ex(3)) :: fh1,fh2,fh3
  real*8, dimension(3) :: SoA
  integer :: imin,jmin,kmin,imax,jmax,kmax,i,j,k
  real*8 :: d12dx,d12dy,d12dz,d2dx,d2dy,d2dz
  integer, parameter :: NO_SYMM = 0, EQ_SYMM = 1, OCTANT = 2
  real*8,  parameter :: ZEO=0.d0,ONE=1.d0
  real*8,  parameter :: TWO=2.d0,EIT=8.d0
  real*8,  parameter :: F12=1.2d1
  dX = X(2)-X(1)
  dY = Y(2)-Y(1)
  dZ = Z(2)-Z(1)
  imax = ex(1)
  jmax = ex(2)
  kmax = ex(3)
  imin = 1
  jmin = 1
  kmin = 1
  if(Symmetry > NO_SYMM .and. dabs(Z(1)) < dZ) kmin = -1
  if(Symmetry > EQ_SYMM .and. dabs(X(1)) < dX) imin = -1
  if(Symmetry > EQ_SYMM .and. dabs(Y(1)) < dY) jmin = -1
  SoA(1) = SYM1
  SoA(2) = SYM2
  SoA(3) = SYM3
  call symmetry_bd(2,ex,f1,fh1,SoA)
  call symmetry_bd(2,ex,f2,fh2,SoA)
  call symmetry_bd(2,ex,f3,fh3,SoA)
  d12dx = ONE/F12/dX
  d12dy = ONE/F12/dY
  d12dz = ONE/F12/dZ
  d2dx = ONE/TWO/dX
  d2dy = ONE/TWO/dY
  d2dz = ONE/TWO/dZ
  f1x = ZEO; f1y = ZEO; f1z = ZEO
  f2x = ZEO; f2y = ZEO; f2z = ZEO
  f3x = ZEO; f3y = ZEO; f3z = ZEO
  do k=1,ex(3)-1
  do j=1,ex(2)-1
  do i=1,ex(1)-1
   if(i+2 <= imax .and. i-2 >= imin .and. &
      j+2 <= jmax .and. j-2 >= jmin .and. &
      k+2 <= kmax .and. k-2 >= kmin) then
      f1x(i,j,k)=d12dx*(fh1(i-2,j,k)-EIT*fh1(i-1,j,k)+EIT*fh1(i+1,j,k)-fh1(i+2,j,k))
      f1y(i,j,k)=d12dy*(fh1(i,j-2,k)-EIT*fh1(i,j-1,k)+EIT*fh1(i,j+1,k)-fh1(i,j+2,k))
      f1z(i,j,k)=d12dz*(fh1(i,j,k-2)-EIT*fh1(i,j,k-1)+EIT*fh1(i,j,k+1)-fh1(i,j,k+2))
      f2x(i,j,k)=d12dx*(fh2(i-2,j,k)-EIT*fh2(i-1,j,k)+EIT*fh2(i+1,j,k)-fh2(i+2,j,k))
      f2y(i,j,k)=d12dy*(fh2(i,j-2,k)-EIT*fh2(i,j-1,k)+EIT*fh2(i,j+1,k)-fh2(i,j+2,k))
      f2z(i,j,k)=d12dz*(fh2(i,j,k-2)-EIT*fh2(i,j,k-1)+EIT*fh2(i,j,k+1)-fh2(i,j,k+2))
      f3x(i,j,k)=d12dx*(fh3(i-2,j,k)-EIT*fh3(i-1,j,k)+EIT*fh3(i+1,j,k)-fh3(i+2,j,k))
      f3y(i,j,k)=d12dy*(fh3(i,j-2,k)-EIT*fh3(i,j-1,k)+EIT*fh3(i,j+1,k)-fh3(i,j+2,k))
      f3z(i,j,k)=d12dz*(fh3(i,j,k-2)-EIT*fh3(i,j,k-1)+EIT*fh3(i,j,k+1)-fh3(i,j,k+2))
   elseif(i+1 <= imax .and. i-1 >= imin .and. &
          j+1 <= jmax .and. j-1 >= jmin .and. &
          k+1 <= kmax .and. k-1 >= kmin) then
      f1x(i,j,k)=d2dx*(-fh1(i-1,j,k)+fh1(i+1,j,k))
      f1y(i,j,k)=d2dy*(-fh1(i,j-1,k)+fh1(i,j+1,k))
      f1z(i,j,k)=d2dz*(-fh1(i,j,k-1)+fh1(i,j,k+1))
      f2x(i,j,k)=d2dx*(-fh2(i-1,j,k)+fh2(i+1,j,k))
      f2y(i,j,k)=d2dy*(-fh2(i,j-1,k)+fh2(i,j+1,k))
      f2z(i,j,k)=d2dz*(-fh2(i,j,k-1)+fh2(i,j,k+1))
      f3x(i,j,k)=d2dx*(-fh3(i-1,j,k)+fh3(i+1,j,k))
      f3y(i,j,k)=d2dy*(-fh3(i,j-1,k)+fh3(i,j+1,k))
      f3z(i,j,k)=d2dz*(-fh3(i,j,k-1)+fh3(i,j,k+1))
   endif
  enddo
  enddo
  enddo
  return
  end subroutine fderivs_batch3
 !-----------------------------------------------------------------------------
 ! batch first derivatives (2 fields), same symmetry setup
 !-----------------------------------------------------------------------------
  subroutine fderivs_batch2(ex,f1,f2, &
                            f1x,f1y,f1z,f2x,f2y,f2z, &
                            X,Y,Z,SYM1,SYM2,SYM3,symmetry,onoff)
  implicit none
  integer,                               intent(in ):: ex(1:3),symmetry,onoff
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(in ):: f1,f2
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(out):: f1x,f1y,f1z
  real*8,  dimension(ex(1),ex(2),ex(3)), intent(out):: f2x,f2y,f2z
  real*8,                                intent(in) :: X(ex(1)),Y(ex(2)),Z(ex(3))
  real*8,                                intent(in ):: SYM1,SYM2,SYM3
 !~~~~~~ other variables
  real*8 :: dX,dY,dZ
  real*8,dimension(-1:ex(1),-1:ex(2),-1:ex(3)) :: fh1,fh2
  real*8, dimension(3) :: SoA
  integer :: imin,jmin,kmin,imax,jmax,kmax,i,j,k
  real*8 :: d12dx,d12dy,d12dz,d2dx,d2dy,d2dz
  integer, parameter :: NO_SYMM = 0, EQ_SYMM = 1, OCTANT = 2
  real*8,  parameter :: ZEO=0.d0,ONE=1.d0
  real*8,  parameter :: TWO=2.d0,EIT=8.d0
  real*8,  parameter :: F12=1.2d1
  dX = X(2)-X(1)
  dY = Y(2)-Y(1)
  dZ = Z(2)-Z(1)
  imax = ex(1)
  jmax = ex(2)
  kmax = ex(3)
  imin = 1
  jmin = 1
  kmin = 1
  if(Symmetry > NO_SYMM .and. dabs(Z(1)) < dZ) kmin = -1
  if(Symmetry > EQ_SYMM .and. dabs(X(1)) < dX) imin = -1
  if(Symmetry > EQ_SYMM .and. dabs(Y(1)) < dY) jmin = -1
  SoA(1) = SYM1
  SoA(2) = SYM2
  SoA(3) = SYM3
  call symmetry_bd(2,ex,f1,fh1,SoA)
  call symmetry_bd(2,ex,f2,fh2,SoA)
  d12dx = ONE/F12/dX
  d12dy = ONE/F12/dY
  d12dz = ONE/F12/dZ
  d2dx = ONE/TWO/dX
  d2dy = ONE/TWO/dY
  d2dz = ONE/TWO/dZ
  f1x = ZEO; f1y = ZEO; f1z = ZEO
  f2x = ZEO; f2y = ZEO; f2z = ZEO
  do k=1,ex(3)-1
  do j=1,ex(2)-1
  do i=1,ex(1)-1
   if(i+2 <= imax .and. i-2 >= imin .and. &
      j+2 <= jmax .and. j-2 >= jmin .and. &
      k+2 <= kmax .and. k-2 >= kmin) then
      f1x(i,j,k)=d12dx*(fh1(i-2,j,k)-EIT*fh1(i-1,j,k)+EIT*fh1(i+1,j,k)-fh1(i+2,j,k))
      f1y(i,j,k)=d12dy*(fh1(i,j-2,k)-EIT*fh1(i,j-1,k)+EIT*fh1(i,j+1,k)-fh1(i,j+2,k))
      f1z(i,j,k)=d12dz*(fh1(i,j,k-2)-EIT*fh1(i,j,k-1)+EIT*fh1(i,j,k+1)-fh1(i,j,k+2))
      f2x(i,j,k)=d12dx*(fh2(i-2,j,k)-EIT*fh2(i-1,j,k)+EIT*fh2(i+1,j,k)-fh2(i+2,j,k))
      f2y(i,j,k)=d12dy*(fh2(i,j-2,k)-EIT*fh2(i,j-1,k)+EIT*fh2(i,j+1,k)-fh2(i,j+2,k))
      f2z(i,j,k)=d12dz*(fh2(i,j,k-2)-EIT*fh2(i,j,k-1)+EIT*fh2(i,j,k+1)-fh2(i,j,k+2))
   elseif(i+1 <= imax .and. i-1 >= imin .and. &
          j+1 <= jmax .and. j-1 >= jmin .and. &
          k+1 <= kmax .and. k-1 >= kmin) then
      f1x(i,j,k)=d2dx*(-fh1(i-1,j,k)+fh1(i+1,j,k))
      f1y(i,j,k)=d2dy*(-fh1(i,j-1,k)+fh1(i,j+1,k))
      f1z(i,j,k)=d2dz*(-fh1(i,j,k-1)+fh1(i,j,k+1))
      f2x(i,j,k)=d2dx*(-fh2(i-1,j,k)+fh2(i+1,j,k))
      f2y(i,j,k)=d2dy*(-fh2(i,j-1,k)+fh2(i,j+1,k))
      f2z(i,j,k)=d2dz*(-fh2(i,j,k-1)+fh2(i,j,k+1))
   endif
  enddo
  enddo
  enddo
  return
  end subroutine fderivs_batch2
 #elif (ghost_width == 4)
 ! sixth order code
@@ -2077,6 +2380,9 @@
  end subroutine fderivs
 !-----------------------------------------------------------------------------
 ! batch first derivatives (4 fields), same symmetry setup
 !-----------------------------------------------------------------------------
 !-----------------------------------------------------------------------------
 !
 ! single derivatives dx
 !
--- a/generate_macrodef.py
+++ b/generate_macrodef.py
@@ -253,7 +253,19 @@ def generate_macrodef_h():
    # Define macro buffer_width
    # number of buffer points for mesh-refinement interfaces
-    print( "#define buffer_width 6",                     file=file1 )
+    # Calculate ghost_width based on Finite_Diffenence_Method to optimize buffer_width
    if ( input_data.Finite_Diffenence_Method == "2nd-order" ):
        gw = 2
    elif ( input_data.Finite_Diffenence_Method == "4th-order" ):
        gw = 3
    elif ( input_data.Finite_Diffenence_Method == "6th-order" ):
        gw = 4
    elif ( input_data.Finite_Diffenence_Method == "8th-order" ):
        gw = 5
    else:
        gw = 5 # Default conservative value
    print( f"#define buffer_width {gw + 1}",      file=file1 )
    print(                                               file=file1 )
    # Define macro SC_width as buffer_width
@@ -392,6 +404,17 @@ def generate_macrodef_fh():
        print( "# Finite_Difference_Method #define ghost_width setting error!!!",   file=file1 )
        print(                                                   file=file1 )
    # Define macro DEBUG_NAN_CHECK
    # 0: off (default), 1: on
    debug_nan_check = getattr(input_data, "Debug_NaN_Check", 0)
    if debug_nan_check:
        print( "#define DEBUG_NAN_CHECK 1", file=file1 )
        print(                             file=file1 )
    else:
        print( "#define DEBUG_NAN_CHECK 0", file=file1 )
        print(                             file=file1 )
    # Whether to use a shell-patch grid
    # use shell or not
@@ -514,6 +537,9 @@ def generate_macrodef_fh():
    print( "    6th order: 4",                                                                      file=file1 )
    print( "    8th order: 5",                                                                      file=file1 )
    print(                                                                                          file=file1 )
    print( "define DEBUG_NAN_CHECK",                                                                file=file1 )
    print( "    0: off (default), 1: on",                                                           file=file1 )
    print(                                                                                          file=file1 )
    print( "define WithShell",                                                                      file=file1 )
    print( "    use shell or not",                                                                  file=file1 )
    print(                                                                                          file=file1 )
--- a/inputfile_example/AMSS_NCKU_Input.py
+++ b/inputfile_example/AMSS_NCKU_Input.py
@@ -35,7 +35,8 @@ Equation_Class           = "BSSN"                  ## Evolution Equation: choose
                                                   ## If "BSSN-EScalar" is chosen, it is necessary to set other parameters below
 Initial_Data_Method      = "Ansorg-TwoPuncture"    ## initial data method: choose "Ansorg-TwoPuncture", "Lousto-Analytical", "Cao-Analytical", "KerrSchild-Analytical"
 Time_Evolution_Method    = "runge-kutta-45"        ## time evolution method: choose "runge-kutta-45"
-Finite_Diffenence_Method = "4th-order"             ## finite-difference method: choose "2nd-order", "4th-order", "6th-order", "8th-order"
+Finite_Diffenence_Method = "4th-order"             ## finite-difference method: choose "2nd-order", "4th-order", "6th-order", "8th-order"
 Debug_NaN_Check          = 0                       ## enable NaN checks in compute_rhs_bssn: 0 (off) or 1 (on)
 #################################################
--- a/makefile_and_run.py
+++ b/makefile_and_run.py
@@ -15,12 +15,13 @@ import subprocess
 ## taskset ensures all child processes inherit the CPU affinity mask
 ## This forces make and all compiler processes to use only nohz_full cores (4-55, 60-111)
 ## Format: taskset -c 4-55,60-111 ensures processes only run on these cores
-NUMACTL_CPU_BIND = "taskset -c 4-55,60-111"
+#NUMACTL_CPU_BIND = "taskset -c 4-55,60-111"
 NUMACTL_CPU_BIND = ""
 ## Build parallelism configuration
 ## Use nohz_full cores (4-55, 60-111) for compilation: 52 + 52 = 104 cores
 ## Set make -j to utilize available cores for faster builds
-BUILD_JOBS = 104
+BUILD_JOBS = 14
 ##################################################################
Author	SHA1	Message	Date
CGH0S7	6fffaa13f6	Optimize buffer_width dynamically based on FD order to improve scalability	2026-01-31 19:04:19 +08:00
CGH0S7	6684016e8c	Optimize MPI domain decomposition min_width calculation to improve scalability	2026-01-31 16:23:16 +08:00
CGH0S7	d11eaa2242	Optimize bssn_rhs.f90: Fuse loops for metric inversion and Christoffel symbols to improve cache locality	2026-01-21 11:22:33 +08:00
CGH0S7	ef96766e22	优化 compute_rhs_bssn 热点路径并加入 NaN 检查开关 - 用 DEBUG_NAN_CHECK 宏按需启用 NaN 检查，并在输入/宏生成器中新增 Debug_NaN_Check 配置 - 逆度量改为先求行列式再乘法展开，减少除法；并在 Gam^i/Christoffel 处提取公共子表达式 - 预置批量 fderivs 辅助例程，便于后续矢量化/合并导数计算 - 将默认 MPI_processes 调整为 8 变更涉及： - AMSS_NCKU_source/bssn_rhs.f90 - generate_macrodef.py - AMSS_NCKU_Input.py - AMSS_NCKU_Input_Mini.py - inputfile_example/AMSS_NCKU_Input.py - AMSS_NCKU_source/diff_new.f90 TODO: fmisc.f90 polint()	2026-01-20 19:37:26 +08:00
CGH0S7	ae7b77e44c	Setup GW150914-mini test case for laptop development - Add AMSS_NCKU_Input_Mini.py with reduced grid resolution and MPI processes - Add AMSS_NCKU_MiniProgram.py launcher with automatic configuration swapping - Update makefile_and_run.py to reduce build jobs and remove CPU binding for laptop - Update .gitignore to exclude GW150914-mini output directory	2026-01-20 00:31:40 +08:00