Added some bispectrum computer

This commit is contained in:
Guilhem Lavaux 2016-11-22 07:56:12 +02:00
parent 0350a22a0b
commit 3d67b66ae0
6 changed files with 330 additions and 1 deletions

View File

@ -53,6 +53,7 @@ ENDIF(YORICK_SUPPORT)
find_program(CYTHON cython) find_program(CYTHON cython)
find_library(ZLIB z) find_library(ZLIB z)
find_library(DL_LIBRARY dl) find_library(DL_LIBRARY dl)
find_library(MATH_LIBRARY m)
set(NETCDF_FIND_REQUIRED ${YORICK_SUPPORT}) set(NETCDF_FIND_REQUIRED ${YORICK_SUPPORT})
set(GSL_FIND_REQUIRED TRUE) set(GSL_FIND_REQUIRED TRUE)

View File

@ -36,6 +36,7 @@ add_library(_cosmo_power MODULE ${CMAKE_CURRENT_BINARY_DIR}/_cosmo_power.cpp)
add_library(_cosmo_cic MODULE ${CMAKE_CURRENT_BINARY_DIR}/_cosmo_cic.cpp) add_library(_cosmo_cic MODULE ${CMAKE_CURRENT_BINARY_DIR}/_cosmo_cic.cpp)
add_library(_fast_interp MODULE ${CMAKE_CURRENT_BINARY_DIR}/_fast_interp.cpp) add_library(_fast_interp MODULE ${CMAKE_CURRENT_BINARY_DIR}/_fast_interp.cpp)
add_library(_project MODULE ${CMAKE_CURRENT_BINARY_DIR}/_project.cpp) add_library(_project MODULE ${CMAKE_CURRENT_BINARY_DIR}/_project.cpp)
add_library(_cosmo_bispectrum MODULE _cosmo_bispectrum.cpp)
SET(CMAKE_EXE_LINKER_FLAGS "${CMAKE_EXE_LINKER_FLAGS} -Bsymbolic-functions") SET(CMAKE_EXE_LINKER_FLAGS "${CMAKE_EXE_LINKER_FLAGS} -Bsymbolic-functions")
@ -44,6 +45,7 @@ target_link_libraries(_cosmo_power ${CosmoTool_local} ${PYTHON_LIBRARIES} ${GSL_
target_link_libraries(_cosmo_cic ${CosmoTool_local} ${PYTHON_LIBRARIES} ${GSL_LIBRARIES}) target_link_libraries(_cosmo_cic ${CosmoTool_local} ${PYTHON_LIBRARIES} ${GSL_LIBRARIES})
target_link_libraries(_project ${PYTHON_LIBRARIES}) target_link_libraries(_project ${PYTHON_LIBRARIES})
target_link_libraries(_fast_interp ${CosmoTool_local} ${PYTHON_LIBRARIES}) target_link_libraries(_fast_interp ${CosmoTool_local} ${PYTHON_LIBRARIES})
target_link_libraries(_cosmo_bispectrum ${MATH_LIBRARY})
# Discover where to put packages # Discover where to put packages
if (NOT PYTHON_SITE_PACKAGES) if (NOT PYTHON_SITE_PACKAGES)
@ -69,7 +71,7 @@ if (WIN32 AND NOT CYGWIN)
SET_TARGET_PROPERTIES(_cosmotool PROPERTIES SUFFIX ".pyd") SET_TARGET_PROPERTIES(_cosmotool PROPERTIES SUFFIX ".pyd")
endif (WIN32 AND NOT CYGWIN) endif (WIN32 AND NOT CYGWIN)
INSTALL(TARGETS _cosmotool _project _cosmo_power _cosmo_cic _fast_interp INSTALL(TARGETS _cosmotool _project _cosmo_power _cosmo_cic _fast_interp _cosmo_bispectrum
LIBRARY DESTINATION ${PYTHON_SITE_PACKAGES}/cosmotool LIBRARY DESTINATION ${PYTHON_SITE_PACKAGES}/cosmotool
) )

View File

@ -0,0 +1,194 @@
#include <iostream>
#include <boost/format.hpp>
#include <boost/multi_array.hpp>
#include <sys/types.h>
#include <cmath>
using std::cout;
using std::endl;
using boost::format;
#if defined _WIN32 || defined __CYGWIN__
#ifdef BUILDING_DLL
#ifdef __GNUC__
#define DLL_PUBLIC __attribute__ ((dllexport))
#else
#define DLL_PUBLIC __declspec(dllexport) // Note: actually gcc seems to also supports this syntax.
#endif
#else
#ifdef __GNUC__
#define DLL_PUBLIC __attribute__ ((dllimport))
#else
#define DLL_PUBLIC __declspec(dllimport) // Note: actually gcc seems to also supports this syntax.
#endif
#endif
#define DLL_LOCAL
#else
#if __GNUC__ >= 4
#define DLL_PUBLIC __attribute__ ((visibility ("default")))
#define DLL_LOCAL __attribute__ ((visibility ("hidden")))
#else
#define DLL_PUBLIC
#define DLL_LOCAL
#endif
#endif
struct ModeSet
{
size_t N1, N2, N3;
struct TriangleIterator
{
ssize_t i1, i2, i3;
size_t N1, N2, N3;
TriangleIterator& operator++() {
i3++;
if (i3==N3) { i3 = 0; i2++; }
if (i2==N2) { i2 = 0; i1++; }
return *this;
}
bool operator!=(const TriangleIterator& t) const {
return i1!=t.i1 || i2!=t.i2 || i3 != t.i3;
}
bool in_box() const {
ssize_t hN1 = N1/2, hN2 = N2/2, hN3 = N3/2;
return (i1 >= -hN1) && (i1 < hN1) && (i2 >= -hN2) && (i2 < hN2) && (i3 >= -hN3) && (i3 < hN3);
}
TriangleIterator operator+(const TriangleIterator& other_t) const {
TriangleIterator t = *this;
t.i1 = (t.i1+other_t.i1);
t.i2 = (t.i2+other_t.i2);
t.i3 = (t.i3+other_t.i3);
return t;
}
TriangleIterator real() const {
TriangleIterator t = *this;
if (t.i1 >= N1/2)
t.i1 -= N1;
if (t.i2 >= N2/2)
t.i2 -= N2;
return t;
}
double norm() const {
double r1 = i1, r2 = i3, r3 = i3;
return std::sqrt(r1*r1 + r2*r2 + r3*r3);
}
TriangleIterator& operator*() { return *this; }
};
ModeSet(size_t N1_, size_t N2_, size_t N3_)
: N1(N1_), N2(N2_), N3(N3_) {}
TriangleIterator begin() const {
TriangleIterator t;
t.i1 = t.i2 = t.i3 = 0;
t.N1 = N1;
t.N2 = N2;
t.N3 = N3;
return t;
}
TriangleIterator end() const {
TriangleIterator t;
t.i2 = t.i3 = 0;
t.i1 = N1;
t.N1 = N1;
t.N2 = N2;
t.N3 = N3;
return t;
}
};
extern "C" DLL_PUBLIC
void CosmoTool_compute_bispectrum(
double *delta_hat, size_t Nx, size_t Ny, size_t Nz,
size_t *Ntriangles,
double* B, double delta_k, size_t Nk )
{
// First remap to multi_array for easy access
size_t kNz = Nz/2+1;
boost::multi_array_ref<std::complex<double>, 3> a_delta(reinterpret_cast<std::complex<double>*>(delta_hat), boost::extents[Nx][Ny][kNz]);
boost::multi_array_ref<size_t, 3> a_Nt(Ntriangles, boost::extents[Nk][Nk][Nk]);
boost::multi_array_ref<std::complex<double>, 3> a_B(reinterpret_cast<std::complex<double>*>(B), boost::extents[Nk][Nk][Nk]);
typedef std::complex<double> CType;
// First loop over m1
for (auto m1 : ModeSet(Nx, Ny, kNz)) {
CType& v1 = a_delta[m1.i1][m1.i2][m1.i3];
// Second mode m2
for (auto m2 : ModeSet(Nx, Ny, kNz)) {
// Now derive m3
CType& v2 = a_delta[m2.i1][m2.i2][m2.i3];
auto m3 = (m1.real()+m2.real());
if (!m3.in_box())
continue;
size_t q1 = std::floor(m1.norm()/delta_k);
size_t q2 = std::floor(m2.norm()/delta_k);
size_t q3 = std::floor(m3.norm()/delta_k);
if (q1 > Nk || q2 > Nk || q3 > Nk)
continue;
CType prod = v1*v2;
// We use hermitic symmetry to get -m3, it is just the mode in m3 but conjugated.
if (m3.i3 > 0) {
if (m3.i1 < 0) m3.i1 += m3.N1;
if (m3.i2 < 0) m3.i2 += m3.N2;
prod *= std::conj(a_delta[m3.i1][m3.i2][m3.i3]);
} else {
m3.i1 = -m3.i1;
m3.i2 = -m3.i2;
if (m3.i1 < 0) m3.i1 += m3.N1;
if (m3.i2 < 0) m3.i2 += m3.N2;
prod *= a_delta[m3.i1][m3.i2][m3.i3];
}
// a_Nt[q1][q2][q3] ++;
// a_B[q1][q2][q3] += prod;
}
}
}
extern "C" DLL_PUBLIC
void CosmoTool_compute_powerspectrum(
double *delta_hat, size_t Nx, size_t Ny, size_t Nz,
size_t *Ncounts,
double* P, double delta_k, size_t Nk )
{
// First remap to multi_array for easy access
size_t kNz = Nz/2+1;
boost::multi_array_ref<std::complex<double>, 3> a_delta(reinterpret_cast<std::complex<double>*>(delta_hat), boost::extents[Nx][Ny][kNz]);
boost::multi_array_ref<size_t, 1> a_Nc(Ncounts, boost::extents[Nk]);
boost::multi_array_ref<double, 1> a_P(reinterpret_cast<double*>(P), boost::extents[Nk]);
typedef std::complex<double> CType;
// First loop over m1
for (auto m1 : ModeSet(Nx, Ny, kNz)) {
CType& v1 = a_delta[m1.i1][m1.i2][m1.i3];
size_t q1 = std::floor(m1.norm()/delta_k);
if (q1 > Nk)
continue;
a_Nc[q1] ++;
a_P[q1] += std::norm(v1);
}
}

View File

@ -14,6 +14,7 @@ except:
from .simu import loadRamsesAll, simpleWriteGadget, SimulationBare from .simu import loadRamsesAll, simpleWriteGadget, SimulationBare
from .timing import time_block, timeit, timeit_quiet from .timing import time_block, timeit, timeit_quiet
from .bispectrum import bispectrum, powerspectrum
try: try:
from .fftw import CubeFT from .fftw import CubeFT

View File

@ -0,0 +1,121 @@
import numpy as np
try:
import cffi
import os
_ffi = cffi.FFI()
_ffi.cdef("""
void CosmoTool_compute_bispectrum(
double *delta_hat, size_t Nx, size_t Ny, size_t Nz,
size_t *Ntriangles,
double* B, double delta_k, size_t Nk ) ;
""");
_pathlib = os.path.dirname(os.path.abspath(__file__))
_lib = _ffi.dlopen(os.path.join(_pathlib,"_cosmo_bispectrum.so"))
except Exception as e:
print(repr(e))
raise RuntimeError("Failed to initialize _cosmo_bispectrum module")
def bispectrum(delta, delta_k, Nk, fourier=True):
"""bispectrum(delta, fourier=True)
Args:
* delta: a 3d density field, can be Fourier modes if fourier set to True
Return:
* A 3d array of the binned bispectrum
"""
if len(delta.shape) != 3:
raise ValueError("Invalid shape for delta")
try:
delta_k = float(delta_k)
Nk = int(Nk)
except:
raise ValueError()
if not fourier:
delta = np.fft.rfftn(delta)
N1,N2,N3 = delta.shape
delta_hat_buf = np.empty((N1*N2*N3*2),dtype=np.double)
delta_hat_buf[::2] = delta.real.ravel()
delta_hat_buf[1::2] = delta.imag.ravel()
size_size = _ffi.sizeof("size_t")
if size_size == 4:
triangle_buf = np.zeros((Nk,Nk,Nk),dtype=np.int32)
elif size_size == 8:
triangle_buf = np.zeros((Nk,Nk,Nk),dtype=np.int64)
else:
raise RuntimeError("Internal error, do not know how to map size_t")
B_buf = np.zeros((Nk*Nk*Nk*4), dtype=np.double)
_lib.CosmoTool_compute_bispectrum( \
_ffi.cast("double *", delta_hat_buf.ctypes.data), \
N1, N2, N3, \
_ffi.cast("size_t *", triangle_buf.ctypes.data), \
_ffi.cast("double *", B_buf.ctypes.data), \
delta_k, \
Nk)
B_buf = B_buf.reshape((Nk,Nk,Nk,4))
return triangle_buf, B_buf[...,0]+1j*B_buf[...,1]
def powerspectrum(delta, delta_k, Nk, fourier=True):
"""powerspectrum(delta, fourier=True)
Args:
* delta: a 3d density field, can be Fourier modes if fourier set to True
Return:
* A 3d array of the binned bispectrum
"""
if len(delta.shape) != 3:
raise ValueError("Invalid shape for delta")
try:
delta_k = float(delta_k)
Nk = int(Nk)
except:
raise ValueError()
if not fourier:
delta = np.fft.rfftn(delta)
N1,N2,N3 = delta.shape
delta_hat_buf = np.empty((N1*N2*N3*2),dtype=np.double)
delta_hat_buf[::2] = delta.real.ravel()
delta_hat_buf[1::2] = delta.imag.ravel()
size_size = _ffi.sizeof("size_t")
if size_size == 4:
count_buf = np.zeros((Nk,),dtype=np.int32)
elif size_size == 8:
count_buf = np.zeros((Nk,),dtype=np.int64)
else:
raise RuntimeError("Internal error, do not know how to map size_t")
B_buf = np.zeros((Nk,), dtype=np.double)
_lib.CosmoTool_compute_bispectrum( \
_ffi.cast("double *", delta_hat_buf.ctypes.data), \
N1, N2, N3, \
_ffi.cast("size_t *", count_buf.ctypes.data), \
_ffi.cast("double *", B_buf.ctypes.data), \
delta_k, \
Nk)
return count_buf, B_buf[...]
if __name__=="__main__":
delta=np.zeros((16,16,16))
delta[0,0,0]=1
delta[3,2,1]=1
b = powerspectrum(delta, 1, 16, fourier=False)
a = bispectrum(delta, 1, 16, fourier=False)
print a[0].max()

View File

@ -0,0 +1,10 @@
import numpy as np
import cosmotool as ct
f=0.01
d=np.random.normal(size=(16,16,16))
rho = d + f *(d*d - np.average(d*d))
B = ct.bispectrum(rho, 1, 16, fourier=False)
P = ct.powerspectrum(rho, 1, 16, fourier=False)