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annotate src/fftw-3.3.8/dft/simd/codlist.mk @ 169:223a55898ab9 tip default

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Add null config files
author Chris Cannam <cannam@all-day-breakfast.com>
date Mon, 02 Mar 2020 14:03:47 +0000
parents bd3cc4d1df30
children
rev   line source
cannam@167 1 # This file contains a standard list of DFT SIMD codelets. It is
cannam@167 2 # included by common/Makefile to generate the C files with the actual
cannam@167 3 # codelets in them. It is included by {sse,sse2,...}/Makefile to
cannam@167 4 # generate and compile stub files that include common/*.c
cannam@167 5
cannam@167 6 # You can customize FFTW for special needs, e.g. to handle certain
cannam@167 7 # sizes more efficiently, by adding new codelets to the lists of those
cannam@167 8 # included by default. If you change the list of codelets, any new
cannam@167 9 # ones you added will be automatically generated when you run the
cannam@167 10 # bootstrap script (see "Generating your own code" in the FFTW
cannam@167 11 # manual).
cannam@167 12
cannam@167 13 ###########################################################################
cannam@167 14 # n1fv_<n> is a hard-coded FFTW_FORWARD FFT of size <n>, using SIMD
cannam@167 15 N1F = n1fv_2.c n1fv_3.c n1fv_4.c n1fv_5.c n1fv_6.c n1fv_7.c n1fv_8.c \
cannam@167 16 n1fv_9.c n1fv_10.c n1fv_11.c n1fv_12.c n1fv_13.c n1fv_14.c n1fv_15.c \
cannam@167 17 n1fv_16.c n1fv_32.c n1fv_64.c n1fv_128.c n1fv_20.c n1fv_25.c
cannam@167 18
cannam@167 19 # as above, with restricted input vector stride
cannam@167 20 N2F = n2fv_2.c n2fv_4.c n2fv_6.c n2fv_8.c n2fv_10.c n2fv_12.c \
cannam@167 21 n2fv_14.c n2fv_16.c n2fv_32.c n2fv_64.c n2fv_20.c
cannam@167 22
cannam@167 23 # as above, but FFTW_BACKWARD
cannam@167 24 N1B = n1bv_2.c n1bv_3.c n1bv_4.c n1bv_5.c n1bv_6.c n1bv_7.c n1bv_8.c \
cannam@167 25 n1bv_9.c n1bv_10.c n1bv_11.c n1bv_12.c n1bv_13.c n1bv_14.c n1bv_15.c \
cannam@167 26 n1bv_16.c n1bv_32.c n1bv_64.c n1bv_128.c n1bv_20.c n1bv_25.c
cannam@167 27
cannam@167 28 N2B = n2bv_2.c n2bv_4.c n2bv_6.c n2bv_8.c n2bv_10.c n2bv_12.c \
cannam@167 29 n2bv_14.c n2bv_16.c n2bv_32.c n2bv_64.c n2bv_20.c
cannam@167 30
cannam@167 31 # split-complex codelets
cannam@167 32 N2S = n2sv_4.c n2sv_8.c n2sv_16.c n2sv_32.c n2sv_64.c
cannam@167 33
cannam@167 34 ###########################################################################
cannam@167 35 # t1fv_<r> is a "twiddle" FFT of size <r>, implementing a radix-r DIT step
cannam@167 36 # for an FFTW_FORWARD transform, using SIMD
cannam@167 37 T1F = t1fv_2.c t1fv_3.c t1fv_4.c t1fv_5.c t1fv_6.c t1fv_7.c t1fv_8.c \
cannam@167 38 t1fv_9.c t1fv_10.c t1fv_12.c t1fv_15.c t1fv_16.c t1fv_32.c t1fv_64.c \
cannam@167 39 t1fv_20.c t1fv_25.c
cannam@167 40
cannam@167 41 # same as t1fv_*, but with different twiddle storage scheme
cannam@167 42 T2F = t2fv_2.c t2fv_4.c t2fv_8.c t2fv_16.c t2fv_32.c t2fv_64.c \
cannam@167 43 t2fv_5.c t2fv_10.c t2fv_20.c t2fv_25.c
cannam@167 44 T3F = t3fv_4.c t3fv_8.c t3fv_16.c t3fv_32.c t3fv_5.c t3fv_10.c \
cannam@167 45 t3fv_20.c t3fv_25.c
cannam@167 46 T1FU = t1fuv_2.c t1fuv_3.c t1fuv_4.c t1fuv_5.c t1fuv_6.c t1fuv_7.c \
cannam@167 47 t1fuv_8.c t1fuv_9.c t1fuv_10.c
cannam@167 48
cannam@167 49 # as above, but FFTW_BACKWARD
cannam@167 50 T1B = t1bv_2.c t1bv_3.c t1bv_4.c t1bv_5.c t1bv_6.c t1bv_7.c t1bv_8.c \
cannam@167 51 t1bv_9.c t1bv_10.c t1bv_12.c t1bv_15.c t1bv_16.c t1bv_32.c t1bv_64.c \
cannam@167 52 t1bv_20.c t1bv_25.c
cannam@167 53
cannam@167 54 # same as t1bv_*, but with different twiddle storage scheme
cannam@167 55 T2B = t2bv_2.c t2bv_4.c t2bv_8.c t2bv_16.c t2bv_32.c t2bv_64.c \
cannam@167 56 t2bv_5.c t2bv_10.c t2bv_20.c t2bv_25.c
cannam@167 57 T3B = t3bv_4.c t3bv_8.c t3bv_16.c t3bv_32.c t3bv_5.c t3bv_10.c \
cannam@167 58 t3bv_20.c t3bv_25.c
cannam@167 59 T1BU = t1buv_2.c t1buv_3.c t1buv_4.c t1buv_5.c t1buv_6.c t1buv_7.c \
cannam@167 60 t1buv_8.c t1buv_9.c t1buv_10.c
cannam@167 61
cannam@167 62 # split-complex codelets
cannam@167 63 T1S = t1sv_2.c t1sv_4.c t1sv_8.c t1sv_16.c t1sv_32.c
cannam@167 64 T2S = t2sv_4.c t2sv_8.c t2sv_16.c t2sv_32.c
cannam@167 65
cannam@167 66 ###########################################################################
cannam@167 67 # q1fv_<r> is <r> twiddle FFTW_FORWARD FFTs of size <r> (DIF step),
cannam@167 68 # where the output is transposed, using SIMD. This is used for
cannam@167 69 # in-place transposes in sizes that are divisible by <r>^2. These
cannam@167 70 # codelets have size ~ <r>^2, so you should probably not use <r>
cannam@167 71 # bigger than 8 or so.
cannam@167 72 Q1F = q1fv_2.c q1fv_4.c q1fv_5.c q1fv_8.c
cannam@167 73
cannam@167 74 # as above, but FFTW_BACKWARD
cannam@167 75 Q1B = q1bv_2.c q1bv_4.c q1bv_5.c q1bv_8.c
cannam@167 76
cannam@167 77 ###########################################################################
cannam@167 78 SIMD_CODELETS = $(N1F) $(N1B) $(N2F) $(N2B) $(N2S) $(T1FU) $(T1F) \
cannam@167 79 $(T2F) $(T3F) $(T1BU) $(T1B) $(T2B) $(T3B) $(T1S) $(T2S) $(Q1F) $(Q1B)