cosmopolitan/third_party/python/Modules/_decimal/libmpdec/sixstep.c

/*-*- mode:c;indent-tabs-mode:nil;c-basic-offset:4;tab-width:8;coding:utf-8 -*-│
│ vi: set et ft=c ts=4 sts=4 sw=4 fenc=utf-8                               :vi │
╞══════════════════════════════════════════════════════════════════════════════╡
│ Copyright (c) 2008-2016 Stefan Krah. All rights reserved.                    │
│                                                                              │
│ Redistribution and use in source and binary forms, with or without           │
│ modification, are permitted provided that the following conditions           │
│ are met:                                                                     │
│                                                                              │
│ 1. Redistributions of source code must retain the above copyright            │
│    notice, this list of conditions and the following disclaimer.             │
│                                                                              │
│ 2. Redistributions in binary form must reproduce the above copyright         │
│    notice, this list of conditions and the following disclaimer in           │
│    the documentation and/or other materials provided with the                │
│    distribution.                                                             │
│                                                                              │
│ THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS "AS IS" AND         │
│ ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE        │
│ IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR           │
│ PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS         │
│ BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,          │
│ OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT         │
│ OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR           │
│ BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,        │
│ WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE         │
│ OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,            │
│ EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.                           │
╚─────────────────────────────────────────────────────────────────────────────*/
#include "third_party/python/Modules/_decimal/libmpdec/bits.h"
#include "third_party/python/Modules/_decimal/libmpdec/difradix2.h"
#include "third_party/python/Modules/_decimal/libmpdec/mpdecimal.h"
#include "third_party/python/Modules/_decimal/libmpdec/numbertheory.h"
#include "third_party/python/Modules/_decimal/libmpdec/sixstep.h"
#include "third_party/python/Modules/_decimal/libmpdec/transpose.h"
#include "third_party/python/Modules/_decimal/libmpdec/umodarith.h"
__static_yoink("libmpdec_notice");

/*
                Cache Efficient Matrix Fourier Transform
                          for arrays of form 2ⁿ


The Six Step Transform
══════════════════════

In libmpdec, the six-step transform is the Matrix Fourier Transform in
disguise. It is called six-step transform after a variant that appears
in [1]. The algorithm requires that the input array can be viewed as an
R×C matrix.


Algorithm six-step (forward transform)
──────────────────────────────────────

  1a) Transpose the matrix.

  1b) Apply a length R FNT to each row.

  1c) Transpose the matrix.

  2) Multiply each matrix element (addressed by j×C+m) by r**(j×m).

  3) Apply a length C FNT to each row.

  4) Transpose the matrix.

Note that steps 1a) - 1c) are exactly equivalent to step 1) of the Matrix
Fourier Transform. For large R, it is faster to transpose twice and do
a transform on the rows than to perform a column transpose directly.


Algorithm six-step (inverse transform)
──────────────────────────────────────

  0) View the matrix as a C×R matrix.

  1) Transpose the matrix, producing an R×C matrix.

  2) Apply a length C FNT to each row.

  3) Multiply each matrix element (addressed by i×C+n) by r**(i×n).

  4a) Transpose the matrix.

  4b) Apply a length R FNT to each row.

  4c) Transpose the matrix.

Again, steps 4a) - 4c) are equivalent to step 4) of the Matrix Fourier
Transform.


──

  [1] David H. Bailey: FFTs in External or Hierarchical Memory
      http://crd.lbl.gov/~dhbailey/dhbpapers/
*/

/* forward transform with sign = -1 */
int
six_step_fnt(mpd_uint_t *a, mpd_size_t n, int modnum)
{
    struct fnt_params *tparams;
    mpd_size_t log2n, C, R;
    mpd_uint_t kernel;
    mpd_uint_t umod;
    mpd_uint_t *x, w0, w1, wstep;
    mpd_size_t i, k;
    assert(ispower2(n));
    assert(n >= 16);
    assert(n <= MPD_MAXTRANSFORM_2N);
    log2n = mpd_bsr(n);
    C = ((mpd_size_t)1) << (log2n / 2);  /* number of columns */
    R = ((mpd_size_t)1) << (log2n - (log2n / 2)); /* number of rows */
    /* Transpose the matrix. */
    if (!transpose_pow2(a, R, C)) {
        return 0;
    }
    /* Length R transform on the rows. */
    if ((tparams = _mpd_init_fnt_params(R, -1, modnum)) == NULL) {
        return 0;
    }
    for (x = a; x < a+n; x += R) {
        fnt_dif2(x, R, tparams);
    }
    /* Transpose the matrix. */
    if (!transpose_pow2(a, C, R)) {
        mpd_free(tparams);
        return 0;
    }
    /* Multiply each matrix element (addressed by i*C+k) by r**(i*k). */
    SETMODULUS(modnum);
    kernel = _mpd_getkernel(n, -1, modnum);
    for (i = 1; i < R; i++) {
        w0 = 1;                  /* r**(i*0): initial value for k=0 */
        w1 = POWMOD(kernel, i);  /* r**(i*1): initial value for k=1 */
        wstep = MULMOD(w1, w1);  /* r**(2*i) */
        for (k = 0; k < C; k += 2) {
            mpd_uint_t x0 = a[i*C+k];
            mpd_uint_t x1 = a[i*C+k+1];
            MULMOD2(&x0, w0, &x1, w1);
            MULMOD2C(&w0, &w1, wstep);  /* r**(i*(k+2)) = r**(i*k) * r**(2*i) */
            a[i*C+k] = x0;
            a[i*C+k+1] = x1;
        }
    }
    /* Length C transform on the rows. */
    if (C != R) {
        mpd_free(tparams);
        if ((tparams = _mpd_init_fnt_params(C, -1, modnum)) == NULL) {
            return 0;
        }
    }
    for (x = a; x < a+n; x += C) {
        fnt_dif2(x, C, tparams);
    }
    mpd_free(tparams);
#if 0
    /* An unordered transform is sufficient for convolution. */
    /* Transpose the matrix. */
    if (!transpose_pow2(a, R, C)) {
        return 0;
    }
#endif
    return 1;
}

/* reverse transform, sign = 1 */
int
inv_six_step_fnt(mpd_uint_t *a, mpd_size_t n, int modnum)
{
    struct fnt_params *tparams;
    mpd_size_t log2n, C, R;
    mpd_uint_t kernel;
    mpd_uint_t umod;
    mpd_uint_t *x, w0, w1, wstep;
    mpd_size_t i, k;
    assert(ispower2(n));
    assert(n >= 16);
    assert(n <= MPD_MAXTRANSFORM_2N);
    log2n = mpd_bsr(n);
    C = ((mpd_size_t)1) << (log2n / 2); /* number of columns */
    R = ((mpd_size_t)1) << (log2n - (log2n / 2)); /* number of rows */
#if 0
    /* An unordered transform is sufficient for convolution. */
    /* Transpose the matrix, producing an R*C matrix. */
    if (!transpose_pow2(a, C, R)) {
        return 0;
    }
#endif
    /* Length C transform on the rows. */
    if ((tparams = _mpd_init_fnt_params(C, 1, modnum)) == NULL) {
        return 0;
    }
    for (x = a; x < a+n; x += C) {
        fnt_dif2(x, C, tparams);
    }
    /* Multiply each matrix element (addressed by i*C+k) by r**(i*k). */
    SETMODULUS(modnum);
    kernel = _mpd_getkernel(n, 1, modnum);
    for (i = 1; i < R; i++) {
        w0 = 1;
        w1 = POWMOD(kernel, i);
        wstep = MULMOD(w1, w1);
        for (k = 0; k < C; k += 2) {
            mpd_uint_t x0 = a[i*C+k];
            mpd_uint_t x1 = a[i*C+k+1];
            MULMOD2(&x0, w0, &x1, w1);
            MULMOD2C(&w0, &w1, wstep);
            a[i*C+k] = x0;
            a[i*C+k+1] = x1;
        }
    }
    /* Transpose the matrix. */
    if (!transpose_pow2(a, R, C)) {
        mpd_free(tparams);
        return 0;
    }
    /* Length R transform on the rows. */
    if (R != C) {
        mpd_free(tparams);
        if ((tparams = _mpd_init_fnt_params(R, 1, modnum)) == NULL) {
            return 0;
        }
    }
    for (x = a; x < a+n; x += R) {
        fnt_dif2(x, R, tparams);
    }
    mpd_free(tparams);
    /* Transpose the matrix. */
    if (!transpose_pow2(a, C, R)) {
        return 0;
    }
    return 1;
}
-												Undiamond Python headers

This change gets the Python codebase into a state where it conforms to
the conventions of this codebase. It's now possible to include headers
from Python, without worrying about ordering. Python has traditionally
solved that problem by "diamonding" everything in Python.h, but that's
problematic since it means any change to any Python header invalidates
all the build artifacts. Lastly it makes tooling not work. Since it is
hard to explain to Emacs when I press C-c C-h to add an import line it
shouldn't add the header that actually defines the symbol, and instead
do follow the nonstandard Python convention.

Progress has been made on letting Python load source code from the zip
executable structure via the standard C library APIs. System calss now
recognizes zip!FILENAME alternative URIs as equivalent to zip:FILENAME
since Python uses colon as its delimiter.

Some progress has been made on embedding the notice license terms into
the Python object code. This is easier said than done since Python has
an extremely complicated ownership story.

- Some termios APIs have been added
- Implement rewinddir() dirstream API
- GetCpuCount() API added to Cosmopolitan Libc
- More bugs in Cosmopolitan Libc have been fixed
- zipobj.com now has flags for mangling the path
- Fixed bug a priori with sendfile() on certain BSDs
- Polyfill F_DUPFD and F_DUPFD_CLOEXEC across platforms
- FIOCLEX / FIONCLEX now polyfilled for fast O_CLOEXEC changes
- APE now supports a hybrid solution to no-self-modify for builds
- Many BSD-only magnums added, e.g. O_SEARCH, O_SHLOCK, SF_NODISKIO

											
										
										
											2021-08-12 00:42:14 -07:00
+								/*-*- mode:c;indent-tabs-mode:nil;c-basic-offset:4;tab-width:8;coding:utf-8 -*-│
-												Make whitespace changes

Status lines for Emacs and Vim have been added to Python sources so
they'll be easier to edit using Python's preferred coding style.

Some DNS helper functions have been broken up into multiple files. It's
nice to have one function per file whenever possible, since that way we
don't need -ffunction-sections.  Another reason it's good to have small
source files, is because the build will be enforcing resource limits on
compilation and testing soon.

											
										
										
											2021-08-13 03:20:45 -07:00
+								│ vi: set et ft=c ts=4 sts=4 sw=4 fenc=utf-8                               :vi │
-												Undiamond Python headers

This change gets the Python codebase into a state where it conforms to
the conventions of this codebase. It's now possible to include headers
from Python, without worrying about ordering. Python has traditionally
solved that problem by "diamonding" everything in Python.h, but that's
problematic since it means any change to any Python header invalidates
all the build artifacts. Lastly it makes tooling not work. Since it is
hard to explain to Emacs when I press C-c C-h to add an import line it
shouldn't add the header that actually defines the symbol, and instead
do follow the nonstandard Python convention.

Progress has been made on letting Python load source code from the zip
executable structure via the standard C library APIs. System calss now
recognizes zip!FILENAME alternative URIs as equivalent to zip:FILENAME
since Python uses colon as its delimiter.

Some progress has been made on embedding the notice license terms into
the Python object code. This is easier said than done since Python has
an extremely complicated ownership story.

- Some termios APIs have been added
- Implement rewinddir() dirstream API
- GetCpuCount() API added to Cosmopolitan Libc
- More bugs in Cosmopolitan Libc have been fixed
- zipobj.com now has flags for mangling the path
- Fixed bug a priori with sendfile() on certain BSDs
- Polyfill F_DUPFD and F_DUPFD_CLOEXEC across platforms
- FIOCLEX / FIONCLEX now polyfilled for fast O_CLOEXEC changes
- APE now supports a hybrid solution to no-self-modify for builds
- Many BSD-only magnums added, e.g. O_SEARCH, O_SHLOCK, SF_NODISKIO

											
										
										
											2021-08-12 00:42:14 -07:00
+								╞══════════════════════════════════════════════════════════════════════════════╡
 								│ Copyright (c) 2008-2016 Stefan Krah. All rights reserved.                    │
 								│                                                                              │
 								│ Redistribution and use in source and binary forms, with or without           │
 								│ modification, are permitted provided that the following conditions           │
 								│ are met:                                                                     │
 								│                                                                              │
 								│ 1. Redistributions of source code must retain the above copyright            │
 								│    notice, this list of conditions and the following disclaimer.             │
 								│                                                                              │
 								│ 2. Redistributions in binary form must reproduce the above copyright         │
 								│    notice, this list of conditions and the following disclaimer in           │
 								│    the documentation and/or other materials provided with the                │
 								│    distribution.                                                             │
 								│                                                                              │
 								│ THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS "AS IS" AND         │
 								│ ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE        │
 								│ IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR           │
 								│ PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS         │
 								│ BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,          │
 								│ OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT         │
 								│ OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR           │
 								│ BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,        │
 								│ WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE         │
 								│ OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,            │
 								│ EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.                           │
 								╚─────────────────────────────────────────────────────────────────────────────*/
 								#include "third_party/python/Modules/_decimal/libmpdec/bits.h"
 								#include "third_party/python/Modules/_decimal/libmpdec/difradix2.h"
 								#include "third_party/python/Modules/_decimal/libmpdec/mpdecimal.h"
 								#include "third_party/python/Modules/_decimal/libmpdec/numbertheory.h"
 								#include "third_party/python/Modules/_decimal/libmpdec/sixstep.h"
 								#include "third_party/python/Modules/_decimal/libmpdec/transpose.h"
 								#include "third_party/python/Modules/_decimal/libmpdec/umodarith.h"
-												Release Cosmopolitan v3.3

This change upgrades to GCC 12.3 and GNU binutils 2.42. The GNU linker
appears to have changed things so that only a single de-duplicated str
table is present in the binary, and it gets placed wherever the linker
wants, regardless of what the linker script says. To cope with that we
need to stop using .ident to embed licenses. As such, this change does
significant work to revamp how third party licenses are defined in the
codebase, using `.section .notice,"aR",@progbits`.

This new GCC 12.3 toolchain has support for GNU indirect functions. It
lets us support __target_clones__ for the first time. This is used for
optimizing the performance of libc string functions such as strlen and
friends so far on x86, by ensuring AVX systems favor a second codepath
that uses VEX encoding. It shaves some latency off certain operations.
It's a useful feature to have for scientific computing for the reasons
explained by the test/libcxx/openmp_test.cc example which compiles for
fifteen different microarchitectures. Thanks to the upgrades, it's now
also possible to use newer instruction sets, such as AVX512FP16, VNNI.

Cosmo now uses the %gs register on x86 by default for TLS. Doing it is
helpful for any program that links `cosmo_dlopen()`. Such programs had
to recompile their binaries at startup to change the TLS instructions.
That's not great, since it means every page in the executable needs to
be faulted. The work of rewriting TLS-related x86 opcodes, is moved to
fixupobj.com instead. This is great news for MacOS x86 users, since we
previously needed to morph the binary every time for that platform but
now that's no longer necessary. The only platforms where we need fixup
of TLS x86 opcodes at runtime are now Windows, OpenBSD, and NetBSD. On
Windows we morph TLS to point deeper into the TIB, based on a TlsAlloc
assignment, and on OpenBSD/NetBSD we morph %gs back into %fs since the
kernels do not allow us to specify a value for the %gs register.

OpenBSD users are now required to use APE Loader to run Cosmo binaries
and assimilation is no longer possible. OpenBSD kernel needs to change
to allow programs to specify a value for the %gs register, or it needs
to stop marking executable pages loaded by the kernel as mimmutable().

This release fixes __constructor__, .ctor, .init_array, and lastly the
.preinit_array so they behave the exact same way as glibc.

We no longer use hex constants to define math.h symbols like M_PI.

											
										
										
											2024-02-20 11:12:09 -08:00
+								__static_yoink("libmpdec_notice");
-												python-3.6.zip added from Github

README.cosmo contains the necessary links.

											
										
										
											2021-08-08 09:38:33 +05:30
-												Make numerous improvements

- Python static hello world now 1.8mb
- Python static fully loaded now 10mb
- Python HTTPS client now uses MbedTLS
- Python REPL now completes import stmts
- Increase stack size for Python for now
- Begin synthesizing posixpath and ntpath
- Restore Python \N{UNICODE NAME} support
- Restore Python NFKD symbol normalization
- Add optimized code path for Intel SHA-NI
- Get more Python unit tests passing faster
- Get Python help() pagination working on NT
- Python hashlib now supports MbedTLS PBKDF2
- Make memcpy/memmove/memcmp/bcmp/etc. faster
- Add Mersenne Twister and Vigna to LIBC_RAND
- Provide privileged __printf() for error code
- Fix zipos opendir() so that it reports ENOTDIR
- Add basic chmod() implementation for Windows NT
- Add Cosmo's best functions to Python cosmo module
- Pin function trace indent depth to that of caller
- Show memory diagram on invalid access in MODE=dbg
- Differentiate stack overflow on crash in MODE=dbg
- Add stb_truetype and tools for analyzing font files
- Upgrade to UNICODE 13 and reduce its binary footprint
- COMPILE.COM now logs resource usage of build commands
- Start implementing basic poll() support on bare metal
- Set getauxval(AT_EXECFN) to GetModuleFileName() on NT
- Add descriptions to strerror() in non-TINY build modes
- Add COUNTBRANCH() macro to help with micro-optimizations
- Make error / backtrace / asan / memory code more unbreakable
- Add fast perfect C implementation of μ-Law and a-Law audio codecs
- Make strtol() functions consistent with other libc implementations
- Improve Linenoise implementation (see also github.com/jart/bestline)
- COMPILE.COM now suppresses stdout/stderr of successful build commands

											
										
										
											2021-09-27 22:58:51 -07:00
+								/*
 								                Cache Efficient Matrix Fourier Transform
 								                          for arrays of form 2ⁿ
-												python-3.6.zip added from Github

README.cosmo contains the necessary links.

											
										
										
											2021-08-08 09:38:33 +05:30
-												Make numerous improvements

- Python static hello world now 1.8mb
- Python static fully loaded now 10mb
- Python HTTPS client now uses MbedTLS
- Python REPL now completes import stmts
- Increase stack size for Python for now
- Begin synthesizing posixpath and ntpath
- Restore Python \N{UNICODE NAME} support
- Restore Python NFKD symbol normalization
- Add optimized code path for Intel SHA-NI
- Get more Python unit tests passing faster
- Get Python help() pagination working on NT
- Python hashlib now supports MbedTLS PBKDF2
- Make memcpy/memmove/memcmp/bcmp/etc. faster
- Add Mersenne Twister and Vigna to LIBC_RAND
- Provide privileged __printf() for error code
- Fix zipos opendir() so that it reports ENOTDIR
- Add basic chmod() implementation for Windows NT
- Add Cosmo's best functions to Python cosmo module
- Pin function trace indent depth to that of caller
- Show memory diagram on invalid access in MODE=dbg
- Differentiate stack overflow on crash in MODE=dbg
- Add stb_truetype and tools for analyzing font files
- Upgrade to UNICODE 13 and reduce its binary footprint
- COMPILE.COM now logs resource usage of build commands
- Start implementing basic poll() support on bare metal
- Set getauxval(AT_EXECFN) to GetModuleFileName() on NT
- Add descriptions to strerror() in non-TINY build modes
- Add COUNTBRANCH() macro to help with micro-optimizations
- Make error / backtrace / asan / memory code more unbreakable
- Add fast perfect C implementation of μ-Law and a-Law audio codecs
- Make strtol() functions consistent with other libc implementations
- Improve Linenoise implementation (see also github.com/jart/bestline)
- COMPILE.COM now suppresses stdout/stderr of successful build commands

											
										
										
											2021-09-27 22:58:51 -07:00
+								The Six Step Transform
 								══════════════════════
 								In libmpdec, the six-step transform is the Matrix Fourier Transform in
 								disguise. It is called six-step transform after a variant that appears
 								in [1]. The algorithm requires that the input array can be viewed as an
 								R×C matrix.
 								Algorithm six-step (forward transform)
 								──────────────────────────────────────
 a) Transpose the matrix.
 b) Apply a length R FNT to each row.
 c) Transpose the matrix.
 ) Multiply each matrix element (addressed by j×C+m) by r**(j×m).
 ) Apply a length C FNT to each row.
 ) Transpose the matrix.
 								Note that steps 1a) - 1c) are exactly equivalent to step 1) of the Matrix
 								Fourier Transform. For large R, it is faster to transpose twice and do
 								a transform on the rows than to perform a column transpose directly.
 								Algorithm six-step (inverse transform)
 								──────────────────────────────────────
 ) View the matrix as a C×R matrix.
 ) Transpose the matrix, producing an R×C matrix.
 ) Apply a length C FNT to each row.
 ) Multiply each matrix element (addressed by i×C+n) by r**(i×n).
 a) Transpose the matrix.
 b) Apply a length R FNT to each row.
 c) Transpose the matrix.
 								Again, steps 4a) - 4c) are equivalent to step 4) of the Matrix Fourier
 								Transform.
 								──
 								  [1] David H. Bailey: FFTs in External or Hierarchical Memory
 								      http://crd.lbl.gov/~dhbailey/dhbpapers/
 								*/
-												python-3.6.zip added from Github

README.cosmo contains the necessary links.

											
										
										
											2021-08-08 09:38:33 +05:30
 								/* forward transform with sign = -1 */
 								int
 								six_step_fnt(mpd_uint_t *a, mpd_size_t n, int modnum)
 								{
 								    struct fnt_params *tparams;
 								    mpd_size_t log2n, C, R;
 								    mpd_uint_t kernel;
 								    mpd_uint_t umod;
 								    mpd_uint_t *x, w0, w1, wstep;
 								    mpd_size_t i, k;
 								    assert(ispower2(n));
 								    assert(n >= 16);
 								    assert(n <= MPD_MAXTRANSFORM_2N);
 								    log2n = mpd_bsr(n);
 								    C = ((mpd_size_t)1) << (log2n / 2);  /* number of columns */
 								    R = ((mpd_size_t)1) << (log2n - (log2n / 2)); /* number of rows */
 								    /* Transpose the matrix. */
 								    if (!transpose_pow2(a, R, C)) {
 								        return 0;
 								    }
 								    /* Length R transform on the rows. */
 								    if ((tparams = _mpd_init_fnt_params(R, -1, modnum)) == NULL) {
 								        return 0;
 								    }
 								    for (x = a; x < a+n; x += R) {
 								        fnt_dif2(x, R, tparams);
 								    }
 								    /* Transpose the matrix. */
 								    if (!transpose_pow2(a, C, R)) {
 								        mpd_free(tparams);
 								        return 0;
 								    }
 								    /* Multiply each matrix element (addressed by i*C+k) by r**(i*k). */
 								    SETMODULUS(modnum);
 								    kernel = _mpd_getkernel(n, -1, modnum);
 								    for (i = 1; i < R; i++) {
 								        w0 = 1;                  /* r**(i*0): initial value for k=0 */
 								        w1 = POWMOD(kernel, i);  /* r**(i*1): initial value for k=1 */
 								        wstep = MULMOD(w1, w1);  /* r**(2*i) */
 								        for (k = 0; k < C; k += 2) {
 								            mpd_uint_t x0 = a[i*C+k];
 								            mpd_uint_t x1 = a[i*C+k+1];
 								            MULMOD2(&x0, w0, &x1, w1);
 								            MULMOD2C(&w0, &w1, wstep);  /* r**(i*(k+2)) = r**(i*k) * r**(2*i) */
 								            a[i*C+k] = x0;
 								            a[i*C+k+1] = x1;
 								        }
 								    }
 								    /* Length C transform on the rows. */
 								    if (C != R) {
 								        mpd_free(tparams);
 								        if ((tparams = _mpd_init_fnt_params(C, -1, modnum)) == NULL) {
 								            return 0;
 								        }
 								    }
 								    for (x = a; x < a+n; x += C) {
 								        fnt_dif2(x, C, tparams);
 								    }
 								    mpd_free(tparams);
 								#if 0
 								    /* An unordered transform is sufficient for convolution. */
 								    /* Transpose the matrix. */
 								    if (!transpose_pow2(a, R, C)) {
 								        return 0;
 								    }
 								#endif
 								    return 1;
 								}
 								/* reverse transform, sign = 1 */
 								int
 								inv_six_step_fnt(mpd_uint_t *a, mpd_size_t n, int modnum)
 								{
 								    struct fnt_params *tparams;
 								    mpd_size_t log2n, C, R;
 								    mpd_uint_t kernel;
 								    mpd_uint_t umod;
 								    mpd_uint_t *x, w0, w1, wstep;
 								    mpd_size_t i, k;
 								    assert(ispower2(n));
 								    assert(n >= 16);
 								    assert(n <= MPD_MAXTRANSFORM_2N);
 								    log2n = mpd_bsr(n);
 								    C = ((mpd_size_t)1) << (log2n / 2); /* number of columns */
 								    R = ((mpd_size_t)1) << (log2n - (log2n / 2)); /* number of rows */
 								#if 0
 								    /* An unordered transform is sufficient for convolution. */
 								    /* Transpose the matrix, producing an R*C matrix. */
 								    if (!transpose_pow2(a, C, R)) {
 								        return 0;
 								    }
 								#endif
 								    /* Length C transform on the rows. */
 								    if ((tparams = _mpd_init_fnt_params(C, 1, modnum)) == NULL) {
 								        return 0;
 								    }
 								    for (x = a; x < a+n; x += C) {
 								        fnt_dif2(x, C, tparams);
 								    }
 								    /* Multiply each matrix element (addressed by i*C+k) by r**(i*k). */
 								    SETMODULUS(modnum);
 								    kernel = _mpd_getkernel(n, 1, modnum);
 								    for (i = 1; i < R; i++) {
 								        w0 = 1;
 								        w1 = POWMOD(kernel, i);
 								        wstep = MULMOD(w1, w1);
 								        for (k = 0; k < C; k += 2) {
 								            mpd_uint_t x0 = a[i*C+k];
 								            mpd_uint_t x1 = a[i*C+k+1];
 								            MULMOD2(&x0, w0, &x1, w1);
 								            MULMOD2C(&w0, &w1, wstep);
 								            a[i*C+k] = x0;
 								            a[i*C+k+1] = x1;
 								        }
 								    }
 								    /* Transpose the matrix. */
 								    if (!transpose_pow2(a, R, C)) {
 								        mpd_free(tparams);
 								        return 0;
 								    }
 								    /* Length R transform on the rows. */
 								    if (R != C) {
 								        mpd_free(tparams);
 								        if ((tparams = _mpd_init_fnt_params(R, 1, modnum)) == NULL) {
 								            return 0;
 								        }
 								    }
 								    for (x = a; x < a+n; x += R) {
 								        fnt_dif2(x, R, tparams);
 								    }
 								    mpd_free(tparams);
 								    /* Transpose the matrix. */
 								    if (!transpose_pow2(a, C, R)) {
 								        return 0;
 								    }
 								    return 1;
 								}