kml_fft(f)_plan_many_dft_r2c
建立howmany组数据序列n维R2C变换的plan。其中,单个FFT的数据序列不需要是连续的,可以以跨步的形式提供。
接口定义
C interface:
kml_fft_plan kml_fft_plan_many_dft_r2c(int rank, const int *n, int howmany, double *in, const int *inembed, int istride, int idist, kml_fft_complex *out, const int *onembed, int ostride, int odist, unsigned flags);
kml_fftf_plan kml_fftf_plan_many_dft_r2c(int rank, const int *n, int howmany, float *in, const int *inembed, int istride, int idist, kml_fftf_complex *out, const int *onembed, int ostride, int odist, unsigned flags);
Fortran interface:
RES = KML_FFT_PLAN_MANY_DFT_R2C(RANK, N, HOWMANY, IN, INEMBED, ISTRIDE, IDIST, OUT, ONEMBED, OSTRIDE, ODIST, FLAGS);
RES = KML_FFTF_PLAN_MANY_DFT_R2C(RANK, N, HOWMANY, IN, INEMBED, ISTRIDE, IDIST, OUT, ONEMBED, OSTRIDE, ODIST, FLAGS);
返回值
函数返回一个kml_fft(f)_plan类型的结构体指针。将该对象作为参数传入kml_fft(f)_execute函数中使用,将对当前提供的输入in和输出out执行FFT变换;另外,也可以通过将该对象作为参数传入kml_fft(f)_execute_dft_r2c函数中以对新的输入in和输出out执行FFT变换。
如果函数返回非空指针,则表示plan执行成功,否则表示执行失败。
参数
参数名 |
数据类型 |
描述 |
输入/输出 |
|---|---|---|---|
rank |
int |
FFT变换的维度是rank,约束:1 ≤ rank ≤ 3。 |
输入 |
n |
const int* |
n是维度为rank的数组,包含FFT序列每一维度的大小,约束:n[i] ≥ 1, for i in 0 to rank - 1。 |
输入 |
howmany |
int |
howmany表示要多少个多维FFT变换。 |
输入 |
in |
|
输入待变换的数据。 |
输入 |
inembed |
const int* |
inembed是大小为rank的数组或者NULL,该数组表示FFT数据in存储的更大空间的每一维度的大小。 约束:inembed[i] ≥ n[i] for i in 0, rank-1 或者:如果inembed == NULL,则可以认为inembed与n相等 |
输入 |
istride |
int |
FFT输入序列的相继元素之间的间隔。 |
输入 |
idist |
int |
idist表示输入的每个FFT序列的间隔。 |
输入 |
out |
|
输出快速傅里叶变换后的数据。 |
输出 |
onembed |
const int* |
onembed是大小为rank的数组或者NULL,该数组表示FFT数据out存储的更大空间的每一维度的大小。 约束:onembed[i] ≥ n[i] for i in 0, rank-1 或者:如果onembed == NULL,则可以认为onembed与n相等 |
输入 |
ostride |
int |
FFT输出序列的相继元素之间的间隔。 |
输入 |
odist |
int |
odist表示输出的每个FFT序列的间隔。 |
输入 |
flags |
unsigned int |
planning选项,未使用。 |
输入 |
依赖
C: "kfft.h"
示例
C interface:
int rank = 1;
int *n;
n = (int*)kml_fft_malloc(sizeof(int) * rank);
n[0] = 4;
int howmany = 3;
int istride = 1;
int ostride = 1;
int idist = 4;
int odist = n[0] / 2 + 1;
double init[12] = {120, 8, 0, 0, 0, -8, -8, -8, -16, 0, -40, -8};
double *in;
in = (double*)kml_fft_malloc(sizeof(double) * 12);
for (int i = 0; i < 12; i++) {
in[i] = init[i];
}
kml_fft_complex *out;
out = (kml_fft_complex*)kml_fft_malloc(sizeof(kml_fft_complex) * (n[0] / 2 + 1) * howmany);
kml_fft_plan plan;
plan = kml_fft_plan_many_dft_r2c(rank, n, howmany, in, NULL, istride, idist, out, NULL, ostride, odist, KML_FFT_ESTIMATE);
kml_fft_execute_dft_r2c(plan, in, out);
kml_fft_destroy_plan(plan);
kml_fft_free(n);
kml_fft_free(in);
kml_fft_free(out);
/*
* out = {{1.280000e+02, 0.000000e+00}, {1.200000e+02, -8.000000e+00},
* {1.120000e+02, 0.000000e+00}, {-2.400000e+01, 0.000000e+00},
* {8.000000e+00, -0.000000e+00}, {8.000000e+00, 0.000000e+00},
* {-6.400000e+01, 0.000000e+00}, {2.400000e+01, -8.000000e+00},
* {-4.800000e+01, 0.000000e+00}}
*/
Fortran interface:
INTEGER(C_INT) :: RANK = 1
INTEGER(C_INT) :: N(1)
REAL(C_DOUBLE), DIMENSION(12) :: INIT
TYPE(C_DOUBLE), POINTER :: IN(:)
TYPE(KML_FFT_COMPLEX), POINTER :: OUT(:)
INTEGER, POINTER :: INEMBED(:), ONEMBED(:)
TYPE(C_PTR) :: PIN, POUT
INTEGER(C_INT) :: HOWMANY = 3
INTEGER(C_INT) :: ISTRIDE = 1
INTEGER(C_INT) :: OSTRIDE = 1
INTEGER(C_INT) :: IDIST = 4
INTEGER(C_INT) :: ODIST = 3
INTEGER(C_SIZE_T) :: RSIZE, CSIZE
RSIZE = 8 * 12
CSIZE = 16 * 9
PIN = KML_FFT_MALLOC(RSIZE)
POUT = KML_FFT_MALLOC(CSIZE)
CALL C_F_POINTER(PIN, IN, SHAPE=[12])
CALL C_F_POINTER(POUT, OUT, SHAPE=[9])
CALL C_F_POINTER(C_NULL_PTR, INEMBED, SHAPE=[0])
CALL C_F_POINTER(C_NULL_PTR, ONEMBED, SHAPE=[0])
N(1) = 4
DATA INIT/120, 8, 0, 0, 0, -8, -8, -8, -16, 0, -40, -8/
INTEGER :: I
DO WHILE(I <= 12)
IN(I) = INIT(I)
END DO
TYPE(C_PTR) :: PLAN
PLAN = KML_FFT_PLAN_MANY_DFT_R2C(RANK, N, HOWMANY, IN, INEMBED, ISTRIDE, IDIST, OUT, ONEMBED, OSTRIDE, ODIST, KML_FFT_ESTIMATE);
CALL KML_FFT_EXECUTE_DFT_R2C(PLAN, IN, OUT);
CALL KML_FFT_DESTROY_PLAN(PLAN)
CALL KML_FFT_FREE(PIN)
CALL KML_FFT_FREE(POUT)
!
! OUT = /1.280000E+02, 0.000000E+00, 1.200000E+02, -8.000000E+00,
! 1.120000E+02, 0.000000E+00, -2.400000E+01, 0.000000E+00,
! 8.000000E+00, -0.000000E+00, 8.000000E+00, 0.000000E+00,
! -6.400000E+01, 0.000000E+00, 2.400000E+01, -8.000000E+00,
! -4.800000E+01, 0.000000E+00/
!
