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Merge branch 'feature/gen-simd' into feature/doxygen

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# Conflicts:
#	Makefile.am
#	configure.ac
This commit is contained in:
Antonin Portelli 2016-11-19 13:11:13 +01:00
commit 97cddda49e
109 changed files with 6830 additions and 5158 deletions
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4
.travis.yml
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@ -9,10 +9,6 @@ matrix:
- os: osx
osx_image: xcode7.2
compiler: clang
- os: osx
osx_image: xcode7.2
compiler: gcc
env: VERSION=-5
- compiler: gcc
addons:
apt:

5
Makefile.am
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@ -3,5 +3,10 @@ SUBDIRS = lib benchmarks tests
include $(top_srcdir)/doxygen.inc
tests: all
$(MAKE) -C tests tests
.PHONY: tests doxygen-run doxygen-doc $(DX_PS_GOAL) $(DX_PDF_GOAL)
AM_CXXFLAGS += -I$(top_builddir)/include
ACLOCAL_AMFLAGS = -I m4

44
README
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@ -1,44 +0,0 @@
This library provides data parallel C++ container classes with internal memory layout
that is transformed to map efficiently to SIMD architectures. CSHIFT facilities
are provided, similar to HPF and cmfortran, and user control is given over the mapping of
array indices to both MPI tasks and SIMD processing elements.
* Identically shaped arrays then be processed with perfect data parallelisation.
* Such identically shapped arrays are called conformable arrays.
The transformation is based on the observation that Cartesian array processing involves
identical processing to be performed on different regions of the Cartesian array.
The library will (eventually) both geometrically decompose into MPI tasks and across SIMD lanes.
Data parallel array operations can then be specified with a SINGLE data parallel paradigm, but
optimally use MPI, OpenMP and SIMD parallelism under the hood. This is a significant simplification
for most programmers.
The layout transformations are parametrised by the SIMD vector length. This adapts according to the architecture.
Presently SSE2 (128 bit) AVX, AVX2 (256 bit) and IMCI and AVX512 (512 bit) targets are supported.
These are presented as
vRealF, vRealD, vComplexF, vComplexD
internal vector data types. These may be useful in themselves for other programmers.
The corresponding scalar types are named
RealF, RealD, ComplexF, ComplexD
MPI parallelism is UNIMPLEMENTED and for now only OpenMP and SIMD parallelism is present in the library.
You can give `configure' initial values for configuration parameters
by setting variables in the command line or in the environment. Here
is are examples:
./configure CXX=clang++ CXXFLAGS="-std=c++11 -O3 -msse4" --enable-simd=SSE4
./configure CXX=clang++ CXXFLAGS="-std=c++11 -O3 -mavx" --enable-simd=AVX1
./configure CXX=clang++ CXXFLAGS="-std=c++11 -O3 -mavx2" --enable-simd=AVX2
./configure CXX=icpc CXXFLAGS="-std=c++11 -O3 -mmic" --enable-simd=AVX512 --host=none

1
README Symbolic link
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@ -0,0 +1 @@
README.md

115
README.md
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@ -16,11 +16,27 @@
**Data parallel C++ mathematical object library.**
Please send all pull requests to the `develop` branch.
License: GPL v2.
Last update 2016/08/03.
Last update Nov 2016.
_Please do not send pull requests to the `master` branch which is reserved for releases._
### Bug report
_To help us tracking and solving more efficiently issues with Grid, please report problems using the issue system of GitHub rather than sending emails to Grid developers._
When you file an issue, please go though the following checklist:
1. Check that the code is pointing to the `HEAD` of `develop` or any commit in `master` which is tagged with a version number.
2. Give a description of the target platform (CPU, network, compiler). Please give the full CPU part description, using for example `cat /proc/cpuinfo | grep 'model name' | uniq` (Linux) or `sysctl machdep.cpu.brand_string` (macOS) and the full output the `--version` option of your compiler.
3. Give the exact `configure` command used.
4. Attach `config.log`.
5. Attach `config.summary`.
6. Attach the output of `make V=1`.
7. Describe the issue and any previous attempt to solve it. If relevant, show how to reproduce the issue using a minimal working example.
### Description
This library provides data parallel C++ container classes with internal memory layout
@ -29,7 +45,7 @@ are provided, similar to HPF and cmfortran, and user control is given over the m
array indices to both MPI tasks and SIMD processing elements.
* Identically shaped arrays then be processed with perfect data parallelisation.
* Such identically shapped arrays are called conformable arrays.
* Such identically shaped arrays are called conformable arrays.
The transformation is based on the observation that Cartesian array processing involves
identical processing to be performed on different regions of the Cartesian array.
@ -42,7 +58,7 @@ optimally use MPI, OpenMP and SIMD parallelism under the hood. This is a signifi
for most programmers.
The layout transformations are parametrised by the SIMD vector length. This adapts according to the architecture.
Presently SSE4 (128 bit) AVX, AVX2 (256 bit) and IMCI and AVX512 (512 bit) targets are supported (ARM NEON and BG/Q QPX on the way).
Presently SSE4 (128 bit) AVX, AVX2, QPX (256 bit), IMCI, and AVX512 (512 bit) targets are supported (ARM NEON on the way).
These are presented as `vRealF`, `vRealD`, `vComplexF`, and `vComplexD` internal vector data types. These may be useful in themselves for other programmers.
The corresponding scalar types are named `RealF`, `RealD`, `ComplexF` and `ComplexD`.
@ -50,7 +66,7 @@ The corresponding scalar types are named `RealF`, `RealD`, `ComplexF` and `Compl
MPI, OpenMP, and SIMD parallelism are present in the library.
Please see https://arxiv.org/abs/1512.03487 for more detail.
### Installation
### Quick start
First, start by cloning the repository:
``` bash
@ -71,12 +87,10 @@ mkdir build; cd build
../configure --enable-precision=double --enable-simd=AVX --enable-comms=mpi-auto --prefix=<path>
```
where `--enable-precision=` set the default precision (`single` or `double`),
`--enable-simd=` set the SIMD type (see possible values below), `--enable-
comms=` set the protocol used for communications (`none`, `mpi`, `mpi-auto` or
`shmem`), and `<path>` should be replaced by the prefix path where you want to
install Grid. The `mpi-auto` communication option set `configure` to determine
automatically how to link to MPI. Other options are available, use `configure
where `--enable-precision=` set the default precision,
`--enable-simd=` set the SIMD type, `--enable-
comms=`, and `<path>` should be replaced by the prefix path where you want to
install Grid. Other options are detailed in the next section, you can also use `configure
--help` to display them. Like with any other program using GNU autotool, the
`CXX`, `CXXFLAGS`, `LDFLAGS`, ... environment variables can be modified to
customise the build.
@ -92,25 +106,88 @@ To minimise the build time, only the tests at the root of the `tests` directory
``` bash
make -C tests/<subdir> tests
```
If you want to build all the tests at once just use `make tests`.
### Build configuration options
- `--prefix=<path>`: installation prefix for Grid.
- `--with-gmp=<path>`: look for GMP in the UNIX prefix `<path>`
- `--with-mpfr=<path>`: look for MPFR in the UNIX prefix `<path>`
- `--with-fftw=<path>`: look for FFTW in the UNIX prefix `<path>`
- `--enable-lapack[=<path>]`: enable LAPACK support in Lanczos eigensolver. A UNIX prefix containing the library can be specified (optional).
- `--enable-mkl[=<path>]`: use Intel MKL for FFT (and LAPACK if enabled) routines. A UNIX prefix containing the library can be specified (optional).
- `--enable-numa`: ???
- `--enable-simd=<code>`: setup Grid for the SIMD target `<code>` (default: `GEN`). A list of possible SIMD targets is detailed in a section below.
- `--enable-precision={single|double}`: set the default precision (default: `double`).
- `--enable-precision=<comm>`: Use `<comm>` for message passing (default: `none`). A list of possible SIMD targets is detailed in a section below.
- `--enable-rng={ranlux48|mt19937}`: choose the RNG (default: `ranlux48 `).
- `--disable-timers`: disable system dependent high-resolution timers.
- `--enable-chroma`: enable Chroma regression tests.
### Possible communication interfaces
The following options can be use with the `--enable-comms=` option to target different communication interfaces:
| `<comm>` | Description |
| -------------- | ------------------------------------------------------------- |
| `none` | no communications |
| `mpi[-auto]` | MPI communications |
| `mpi3[-auto]` | MPI communications using MPI 3 shared memory |
| `mpi3l[-auto]` | MPI communications using MPI 3 shared memory and leader model |
| `shmem ` | Cray SHMEM communications |
For the MPI interfaces the optional `-auto` suffix instructs the `configure` scripts to determine all the necessary compilation and linking flags. This is done by extracting the informations from the MPI wrapper specified in the environment variable `MPICXX` (if not specified `configure` will scan though a list of default names).
### Possible SIMD types
The following options can be use with the `--enable-simd=` option to target different SIMD instruction sets:
| String | Description |
| `<code>` | Description |
| ----------- | -------------------------------------- |
| `GEN` | generic portable vector code |
| `SSE4` | SSE 4.2 (128 bit) |
| `AVX` | AVX (256 bit) |
| `AVXFMA4` | AVX (256 bit) + FMA |
| `AVXFMA` | AVX (256 bit) + FMA |
| `AVXFMA4` | AVX (256 bit) + FMA4 |
| `AVX2` | AVX 2 (256 bit) |
| `AVX512` | AVX 512 bit |
| `AVX512MIC` | AVX 512 bit for Intel MIC architecture |
| `ICMI` | Intel ICMI instructions (512 bit) |
| `QPX` | QPX (256 bit) |
Alternatively, some CPU codenames can be directly used:
| String | Description |
| `<code>` | Description |
| ----------- | -------------------------------------- |
| `KNC` | [Intel Knights Corner](http://ark.intel.com/products/codename/57721/Knights-Corner) |
| `KNL` | [Intel Knights Landing](http://ark.intel.com/products/codename/48999/Knights-Landing) |
| `KNC` | [Intel Xeon Phi codename Knights Corner](http://ark.intel.com/products/codename/57721/Knights-Corner) |
| `KNL` | [Intel Xeon Phi codename Knights Landing](http://ark.intel.com/products/codename/48999/Knights-Landing) |
| `BGQ` | Blue Gene/Q |
#### Notes:
- We currently support AVX512 only for the Intel compiler. Support for GCC and clang will appear in future versions of Grid when the AVX512 support within GCC and clang will be more advanced.
- For BG/Q only [bgclang](http://trac.alcf.anl.gov/projects/llvm-bgq) is supported. We do not presently plan to support more compilers for this platform.
- BG/Q performances are currently rather poor. This is being investigated for future versions.
### Build setup for Intel Knights Landing platform
The following configuration is recommended for the Intel Knights Landing platform:
``` bash
../configure --enable-precision=double\
--enable-simd=KNL \
--enable-comms=mpi-auto \
--with-gmp=<path> \
--with-mpfr=<path> \
--enable-mkl \
CXX=icpc MPICXX=mpiicpc
```
where `<path>` is the UNIX prefix where GMP and MPFR are installed. If you are working on a Cray machine that does not use the `mpiicpc` wrapper, please use:
``` bash
../configure --enable-precision=double\
--enable-simd=KNL \
--enable-comms=mpi \
--with-gmp=<path> \
--with-mpfr=<path> \
--enable-mkl \
CXX=CC CC=cc
```

4
VERSION
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@ -1,4 +1,6 @@
Version : 0.5.0
Version : 0.6.0
- AVX512, AVX2, AVX, SSE good
- Clang 3.5 and above, ICPC v16 and above, GCC 4.9 and above
- MPI and MPI3
- HiRep, Smearing, Generic gauge group

240
benchmarks/Benchmark_comms.cc
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@ -42,15 +42,14 @@ int main (int argc, char ** argv)
int Nloop=10;
int nmu=0;
for(int mu=0;mu<4;mu++) if (mpi_layout[mu]>1) nmu++;
for(int mu=0;mu<Nd;mu++) if (mpi_layout[mu]>1) nmu++;
std::cout<<GridLogMessage << "===================================================================================================="<<std::endl;
std::cout<<GridLogMessage << "= Benchmarking concurrent halo exchange in "<<nmu<<" dimensions"<<std::endl;
std::cout<<GridLogMessage << "===================================================================================================="<<std::endl;
std::cout<<GridLogMessage << " L "<<"\t\t"<<" Ls "<<"\t\t"<<"bytes"<<"\t\t"<<"MB/s uni"<<"\t\t"<<"MB/s bidi"<<std::endl;
for(int lat=4;lat<=32;lat+=2){
int maxlat=16;
for(int lat=4;lat<=maxlat;lat+=2){
for(int Ls=1;Ls<=16;Ls*=2){
std::vector<int> latt_size ({lat*mpi_layout[0],
@ -125,7 +124,7 @@ int main (int argc, char ** argv)
std::cout<<GridLogMessage << " L "<<"\t\t"<<" Ls "<<"\t\t"<<"bytes"<<"\t\t"<<"MB/s uni"<<"\t\t"<<"MB/s bidi"<<std::endl;
for(int lat=4;lat<=32;lat+=2){
for(int lat=4;lat<=maxlat;lat+=2){
for(int Ls=1;Ls<=16;Ls*=2){
std::vector<int> latt_size ({lat,lat,lat,lat});
@ -194,128 +193,169 @@ int main (int argc, char ** argv)
}
}
#if 0
Nloop=100;
std::cout<<GridLogMessage << "===================================================================================================="<<std::endl;
std::cout<<GridLogMessage << "= Benchmarking sequential persistent halo exchange in "<<nmu<<" dimensions"<<std::endl;
std::cout<<GridLogMessage << "= Benchmarking concurrent STENCIL halo exchange in "<<nmu<<" dimensions"<<std::endl;
std::cout<<GridLogMessage << "===================================================================================================="<<std::endl;
std::cout<<GridLogMessage << " L "<<"\t\t"<<" Ls "<<"\t\t"<<"bytes"<<"\t\t"<<"MB/s uni"<<"\t\t"<<"MB/s bidi"<<std::endl;
for(int lat=4;lat<=32;lat+=2){
for(int lat=4;lat<=maxlat;lat+=2){
for(int Ls=1;Ls<=16;Ls*=2){
std::vector<int> latt_size ({lat,lat,lat,lat});
std::vector<int> latt_size ({lat*mpi_layout[0],
lat*mpi_layout[1],
lat*mpi_layout[2],
lat*mpi_layout[3]});
GridCartesian Grid(latt_size,simd_layout,mpi_layout);
std::vector<std::vector<HalfSpinColourVectorD> > xbuf(8,std::vector<HalfSpinColourVectorD>(lat*lat*lat*Ls));
std::vector<std::vector<HalfSpinColourVectorD> > rbuf(8,std::vector<HalfSpinColourVectorD>(lat*lat*lat*Ls));
std::vector<HalfSpinColourVectorD *> xbuf(8);
std::vector<HalfSpinColourVectorD *> rbuf(8);
Grid.ShmBufferFreeAll();
for(int d=0;d<8;d++){
xbuf[d] = (HalfSpinColourVectorD *)Grid.ShmBufferMalloc(lat*lat*lat*Ls*sizeof(HalfSpinColourVectorD));
rbuf[d] = (HalfSpinColourVectorD *)Grid.ShmBufferMalloc(lat*lat*lat*Ls*sizeof(HalfSpinColourVectorD));
}
int ncomm;
int bytes=lat*lat*lat*Ls*sizeof(HalfSpinColourVectorD);
double start=usecond();
for(int i=0;i<Nloop;i++){
std::vector<CartesianCommunicator::CommsRequest_t> empty;
std::vector<std::vector<CartesianCommunicator::CommsRequest_t> > requests_fwd(Nd,empty);
std::vector<std::vector<CartesianCommunicator::CommsRequest_t> > requests_bwd(Nd,empty);
std::vector<CartesianCommunicator::CommsRequest_t> requests;
for(int mu=0;mu<4;mu++){
ncomm=0;
if (mpi_layout[mu]>1 ) {
ncomm++;
int comm_proc;
int xmit_to_rank;
int recv_from_rank;
comm_proc=1;
Grid.ShiftedRanks(mu,comm_proc,xmit_to_rank,recv_from_rank);
Grid.SendToRecvFromInit(requests_fwd[mu],
(void *)&xbuf[mu][0],
xmit_to_rank,
(void *)&rbuf[mu][0],
recv_from_rank,
bytes);
comm_proc = mpi_layout[mu]-1;
Grid.ShiftedRanks(mu,comm_proc,xmit_to_rank,recv_from_rank);
Grid.SendToRecvFromInit(requests_bwd[mu],
(void *)&xbuf[mu+4][0],
xmit_to_rank,
(void *)&rbuf[mu+4][0],
recv_from_rank,
bytes);
}
}
{
double start=usecond();
for(int i=0;i<Nloop;i++){
for(int mu=0;mu<4;mu++){
if (mpi_layout[mu]>1 ) {
for(int mu=0;mu<4;mu++){
ncomm++;
int comm_proc=1;
int xmit_to_rank;
int recv_from_rank;
if (mpi_layout[mu]>1 ) {
Grid.SendToRecvFromBegin(requests_fwd[mu]);
Grid.SendToRecvFromComplete(requests_fwd[mu]);
Grid.SendToRecvFromBegin(requests_bwd[mu]);
Grid.SendToRecvFromComplete(requests_bwd[mu]);
}
}
Grid.Barrier();
}
Grid.ShiftedRanks(mu,comm_proc,xmit_to_rank,recv_from_rank);
Grid.StencilSendToRecvFromBegin(requests,
(void *)&xbuf[mu][0],
xmit_to_rank,
(void *)&rbuf[mu][0],
recv_from_rank,
bytes);
double stop=usecond();
double dbytes = bytes;
double xbytes = Nloop*dbytes*2.0*ncomm;
double rbytes = xbytes;
double bidibytes = xbytes+rbytes;
double time = stop-start;
std::cout<<GridLogMessage << lat<<"\t\t"<<Ls<<"\t\t"<<bytes<<"\t\t"<<xbytes/time<<"\t\t"<<bidibytes/time<<std::endl;
}
{
double start=usecond();
for(int i=0;i<Nloop;i++){
comm_proc = mpi_layout[mu]-1;
Grid.ShiftedRanks(mu,comm_proc,xmit_to_rank,recv_from_rank);
Grid.StencilSendToRecvFromBegin(requests,
(void *)&xbuf[mu+4][0],
xmit_to_rank,
(void *)&rbuf[mu+4][0],
recv_from_rank,
bytes);
for(int mu=0;mu<4;mu++){
if (mpi_layout[mu]>1 ) {
Grid.SendToRecvFromBegin(requests_fwd[mu]);
Grid.SendToRecvFromBegin(requests_bwd[mu]);
Grid.SendToRecvFromComplete(requests_fwd[mu]);
Grid.SendToRecvFromComplete(requests_bwd[mu]);
}
}
Grid.Barrier();
}
double stop=usecond();
double dbytes = bytes;
double xbytes = Nloop*dbytes*2.0*ncomm;
double rbytes = xbytes;
double bidibytes = xbytes+rbytes;
double time = stop-start;
std::cout<<GridLogMessage << lat<<"\t\t"<<Ls<<"\t\t"<<bytes<<"\t\t"<<xbytes/time<<"\t\t"<<bidibytes/time<<std::endl;
Grid.StencilSendToRecvFromComplete(requests);
Grid.Barrier();
}
double stop=usecond();
double dbytes = bytes;
double xbytes = Nloop*dbytes*2.0*ncomm;
double rbytes = xbytes;
double bidibytes = xbytes+rbytes;
double time = stop-start; // microseconds
std::cout<<GridLogMessage << lat<<"\t\t"<<Ls<<"\t\t"<<bytes<<"\t\t"<<xbytes/time<<"\t\t"<<bidibytes/time<<std::endl;
}
}
}
#endif
Nloop=100;
std::cout<<GridLogMessage << "===================================================================================================="<<std::endl;
std::cout<<GridLogMessage << "= Benchmarking sequential STENCIL halo exchange in "<<nmu<<" dimensions"<<std::endl;
std::cout<<GridLogMessage << "===================================================================================================="<<std::endl;
std::cout<<GridLogMessage << " L "<<"\t\t"<<" Ls "<<"\t\t"<<"bytes"<<"\t\t"<<"MB/s uni"<<"\t\t"<<"MB/s bidi"<<std::endl;
for(int lat=4;lat<=maxlat;lat+=2){
for(int Ls=1;Ls<=16;Ls*=2){
std::vector<int> latt_size ({lat*mpi_layout[0],
lat*mpi_layout[1],
lat*mpi_layout[2],
lat*mpi_layout[3]});
GridCartesian Grid(latt_size,simd_layout,mpi_layout);
std::vector<HalfSpinColourVectorD *> xbuf(8);
std::vector<HalfSpinColourVectorD *> rbuf(8);
Grid.ShmBufferFreeAll();
for(int d=0;d<8;d++){
xbuf[d] = (HalfSpinColourVectorD *)Grid.ShmBufferMalloc(lat*lat*lat*Ls*sizeof(HalfSpinColourVectorD));
rbuf[d] = (HalfSpinColourVectorD *)Grid.ShmBufferMalloc(lat*lat*lat*Ls*sizeof(HalfSpinColourVectorD));
}
int ncomm;
int bytes=lat*lat*lat*Ls*sizeof(HalfSpinColourVectorD);
double start=usecond();
for(int i=0;i<Nloop;i++){
std::vector<CartesianCommunicator::CommsRequest_t> requests;
ncomm=0;
for(int mu=0;mu<4;mu++){
if (mpi_layout[mu]>1 ) {
ncomm++;
int comm_proc=1;
int xmit_to_rank;
int recv_from_rank;
Grid.ShiftedRanks(mu,comm_proc,xmit_to_rank,recv_from_rank);
Grid.StencilSendToRecvFromBegin(requests,
(void *)&xbuf[mu][0],
xmit_to_rank,
(void *)&rbuf[mu][0],
recv_from_rank,
bytes);
// Grid.StencilSendToRecvFromComplete(requests);
// requests.resize(0);
comm_proc = mpi_layout[mu]-1;
Grid.ShiftedRanks(mu,comm_proc,xmit_to_rank,recv_from_rank);
Grid.StencilSendToRecvFromBegin(requests,
(void *)&xbuf[mu+4][0],
xmit_to_rank,
(void *)&rbuf[mu+4][0],
recv_from_rank,
bytes);
Grid.StencilSendToRecvFromComplete(requests);
requests.resize(0);
}
}
Grid.Barrier();
}
double stop=usecond();
double dbytes = bytes;
double xbytes = Nloop*dbytes*2.0*ncomm;
double rbytes = xbytes;
double bidibytes = xbytes+rbytes;
double time = stop-start; // microseconds
std::cout<<GridLogMessage << lat<<"\t\t"<<Ls<<"\t\t"<<bytes<<"\t\t"<<xbytes/time<<"\t\t"<<bidibytes/time<<std::endl;
}
}
Grid_finalize();
}

124
benchmarks/Benchmark_dwf.cc
View File

@ -44,7 +44,6 @@ struct scal {
Gamma::GammaT
};
bool overlapComms = false;
typedef WilsonFermion5D<DomainWallVec5dImplR> WilsonFermion5DR;
typedef WilsonFermion5D<DomainWallVec5dImplF> WilsonFermion5DF;
typedef WilsonFermion5D<DomainWallVec5dImplD> WilsonFermion5DD;
@ -54,15 +53,11 @@ int main (int argc, char ** argv)
{
Grid_init(&argc,&argv);
if( GridCmdOptionExists(argv,argv+argc,"--asynch") ){
overlapComms = true;
}
int threads = GridThread::GetThreads();
std::cout<<GridLogMessage << "Grid is setup to use "<<threads<<" threads"<<std::endl;
std::vector<int> latt4 = GridDefaultLatt();
const int Ls=16;
const int Ls=8;
GridCartesian * UGrid = SpaceTimeGrid::makeFourDimGrid(GridDefaultLatt(), GridDefaultSimd(Nd,vComplex::Nsimd()),GridDefaultMpi());
GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);
GridCartesian * FGrid = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);
@ -126,17 +121,24 @@ int main (int argc, char ** argv)
RealD NP = UGrid->_Nprocessors;
for(int doasm=1;doasm<2;doasm++){
QCD::WilsonKernelsStatic::AsmOpt=doasm;
DomainWallFermionR Dw(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,mass,M5);
std::cout<<GridLogMessage << "Naive wilson implementation "<<std::endl;
std::cout << GridLogMessage<< "Calling Dw"<<std::endl;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
std::cout << GridLogMessage<< "* Kernel options --dslash-generic, --dslash-unroll, --dslash-asm" <<std::endl;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
std::cout << GridLogMessage<< "* Benchmarking DomainWallFermionR::Dhop "<<std::endl;
std::cout << GridLogMessage<< "* Vectorising space-time by "<<vComplex::Nsimd()<<std::endl;
if ( sizeof(Real)==4 ) std::cout << GridLogMessage<< "* SINGLE precision "<<std::endl;
if ( sizeof(Real)==8 ) std::cout << GridLogMessage<< "* DOUBLE precision "<<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptGeneric ) std::cout << GridLogMessage<< "* Using GENERIC Nc WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptHandUnroll) std::cout << GridLogMessage<< "* Using Nc=3 WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptInlineAsm ) std::cout << GridLogMessage<< "* Using Asm Nc=3 WilsonKernels" <<std::endl;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
int ncall =100;
if (1) {
FGrid->Barrier();
Dw.ZeroCounters();
double t0=usecond();
for(int i=0;i<ncall;i++){
@ -145,6 +147,7 @@ int main (int argc, char ** argv)
__SSC_STOP;
}
double t1=usecond();
FGrid->Barrier();
double volume=Ls; for(int mu=0;mu<Nd;mu++) volume=volume*latt4[mu];
double flops=1344*volume*ncall;
@ -153,14 +156,26 @@ int main (int argc, char ** argv)
std::cout<<GridLogMessage << "norm result "<< norm2(result)<<std::endl;
std::cout<<GridLogMessage << "norm ref "<< norm2(ref)<<std::endl;
std::cout<<GridLogMessage << "mflop/s = "<< flops/(t1-t0)<<std::endl;
std::cout<<GridLogMessage << "mflop/s per node = "<< flops/(t1-t0)/NP<<std::endl;
std::cout<<GridLogMessage << "mflop/s per rank = "<< flops/(t1-t0)/NP<<std::endl;
err = ref-result;
std::cout<<GridLogMessage << "norm diff "<< norm2(err)<<std::endl;
assert (norm2(err)< 1.0e-4 );
Dw.Report();
}
if (1)
{
std::cout << GridLogMessage<< "*********************************************************" <<std::endl;
std::cout << GridLogMessage<< "* Benchmarking WilsonFermion5D<DomainWallVec5dImplR>::Dhop "<<std::endl;
std::cout << GridLogMessage<< "* Vectorising fifth dimension by "<<vComplex::Nsimd()<<std::endl;
if ( sizeof(Real)==4 ) std::cout << GridLogMessage<< "* SINGLE precision "<<std::endl;
if ( sizeof(Real)==8 ) std::cout << GridLogMessage<< "* DOUBLE precision "<<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptGeneric ) std::cout << GridLogMessage<< "* Using GENERIC Nc WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptHandUnroll) std::cout << GridLogMessage<< "* Using Nc=3 WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptInlineAsm ) std::cout << GridLogMessage<< "* Using Asm Nc=3 WilsonKernels" <<std::endl;
std::cout << GridLogMessage<< "*********************************************************" <<std::endl;
typedef WilsonFermion5D<DomainWallVec5dImplR> WilsonFermion5DR;
LatticeFermion ssrc(sFGrid);
LatticeFermion sref(sFGrid);
@ -179,6 +194,7 @@ int main (int argc, char ** argv)
pokeSite(tmp,ssrc,site);
}}}}}
std::cout<<GridLogMessage<< "src norms "<< norm2(src)<<" " <<norm2(ssrc)<<std::endl;
FGrid->Barrier();
double t0=usecond();
sDw.ZeroCounters();
for(int i=0;i<ncall;i++){
@ -187,29 +203,29 @@ int main (int argc, char ** argv)
__SSC_STOP;
}
double t1=usecond();
FGrid->Barrier();
double volume=Ls; for(int mu=0;mu<Nd;mu++) volume=volume*latt4[mu];
double flops=1344*volume*ncall;
std::cout<<GridLogMessage << "Called Dw s_inner "<<ncall<<" times in "<<t1-t0<<" us"<<std::endl;
std::cout<<GridLogMessage << "mflop/s = "<< flops/(t1-t0)<<std::endl;
std::cout<<GridLogMessage << "mflop/s per node = "<< flops/(t1-t0)/NP<<std::endl;
std::cout<<GridLogMessage << "mflop/s per rank = "<< flops/(t1-t0)/NP<<std::endl;
sDw.Report();
if(0){
for(int i=0;i< PerformanceCounter::NumTypes(); i++ ){
sDw.Dhop(ssrc,sresult,0);
PerformanceCounter Counter(i);
Counter.Start();
sDw.Dhop(ssrc,sresult,0);
Counter.Stop();
Counter.Report();
sDw.Dhop(ssrc,sresult,0);
PerformanceCounter Counter(i);
Counter.Start();
sDw.Dhop(ssrc,sresult,0);
Counter.Stop();
Counter.Report();
}
}
std::cout<<GridLogMessage<< "res norms "<< norm2(result)<<" " <<norm2(sresult)<<std::endl;
RealF sum=0;
RealD sum=0;
for(int x=0;x<latt4[0];x++){
for(int y=0;y<latt4[1];y++){
for(int z=0;z<latt4[2];z++){
@ -221,18 +237,18 @@ int main (int argc, char ** argv)
peekSite(simd,sresult,site);
sum=sum+norm2(normal-simd);
if (norm2(normal-simd) > 1.0e-6 ) {
std::cout << "site "<<x<<","<<y<<","<<z<<","<<t<<","<<s<<" "<<norm2(normal-simd)<<std::endl;
std::cout << "site "<<x<<","<<y<<","<<z<<","<<t<<","<<s<<" normal "<<normal<<std::endl;
std::cout << "site "<<x<<","<<y<<","<<z<<","<<t<<","<<s<<" simd "<<simd<<std::endl;
std::cout << "site "<<x<<","<<y<<","<<z<<","<<t<<","<<s<<" "<<norm2(normal-simd)<<std::endl;
std::cout << "site "<<x<<","<<y<<","<<z<<","<<t<<","<<s<<" normal "<<normal<<std::endl;
std::cout << "site "<<x<<","<<y<<","<<z<<","<<t<<","<<s<<" simd "<<simd<<std::endl;
}
}}}}}
std::cout<<GridLogMessage<<" difference between normal and simd is "<<sum<<std::endl;
assert (sum< 1.0e-4 );
if (1) {
LatticeFermion sr_eo(sFGrid);
LatticeFermion serr(sFGrid);
LatticeFermion ssrc_e (sFrbGrid);
LatticeFermion ssrc_o (sFrbGrid);
@ -244,24 +260,36 @@ int main (int argc, char ** argv)
setCheckerboard(sr_eo,ssrc_o);
setCheckerboard(sr_eo,ssrc_e);
serr = sr_eo-ssrc;
std::cout<<GridLogMessage << "EO src norm diff "<< norm2(serr)<<std::endl;
sr_e = zero;
sr_o = zero;
std::cout << GridLogMessage<< "*********************************************************" <<std::endl;
std::cout << GridLogMessage<< "* Benchmarking WilsonFermion5D<DomainWallVec5dImplR>::DhopEO "<<std::endl;
std::cout << GridLogMessage<< "* Vectorising fifth dimension by "<<vComplex::Nsimd()<<std::endl;
if ( sizeof(Real)==4 ) std::cout << GridLogMessage<< "* SINGLE precision "<<std::endl;
if ( sizeof(Real)==8 ) std::cout << GridLogMessage<< "* DOUBLE precision "<<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptGeneric ) std::cout << GridLogMessage<< "* Using GENERIC Nc WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptHandUnroll) std::cout << GridLogMessage<< "* Using Nc=3 WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptInlineAsm ) std::cout << GridLogMessage<< "* Using Asm Nc=3 WilsonKernels" <<std::endl;
std::cout << GridLogMessage<< "*********************************************************" <<std::endl;
FGrid->Barrier();
sDw.ZeroCounters();
sDw.stat.init("DhopEO");
double t0=usecond();
for (int i = 0; i < ncall; i++) {
sDw.DhopEO(ssrc_o, sr_e, DaggerNo);
}
double t1=usecond();
FGrid->Barrier();
sDw.stat.print();
double volume=Ls; for(int mu=0;mu<Nd;mu++) volume=volume*latt4[mu];
double flops=(1344.0*volume*ncall)/2;
std::cout<<GridLogMessage << "sDeo mflop/s = "<< flops/(t1-t0)<<std::endl;
std::cout<<GridLogMessage << "sDeo mflop/s per node "<< flops/(t1-t0)/NP<<std::endl;
std::cout<<GridLogMessage << "sDeo mflop/s per rank "<< flops/(t1-t0)/NP<<std::endl;
sDw.Report();
sDw.DhopEO(ssrc_o,sr_e,DaggerNo);
@ -271,9 +299,18 @@ int main (int argc, char ** argv)
pickCheckerboard(Even,ssrc_e,sresult);
pickCheckerboard(Odd ,ssrc_o,sresult);
ssrc_e = ssrc_e - sr_e;
RealD error = norm2(ssrc_e);
std::cout<<GridLogMessage << "sE norm diff "<< norm2(ssrc_e)<< " vec nrm"<<norm2(sr_e) <<std::endl;
ssrc_o = ssrc_o - sr_o;
error+= norm2(ssrc_o);
std::cout<<GridLogMessage << "sO norm diff "<< norm2(ssrc_o)<< " vec nrm"<<norm2(sr_o) <<std::endl;
if(error>1.0e-4) {
setCheckerboard(ssrc,ssrc_o);
setCheckerboard(ssrc,ssrc_e);
std::cout<< ssrc << std::endl;
}
}
@ -299,13 +336,13 @@ int main (int argc, char ** argv)
ref = -0.5*ref;
}
Dw.Dhop(src,result,1);
std::cout << GridLogMessage << "Naive wilson implementation Dag" << std::endl;
std::cout << GridLogMessage << "Compare to naive wilson implementation Dag to verify correctness" << std::endl;
std::cout<<GridLogMessage << "Called DwDag"<<std::endl;
std::cout<<GridLogMessage << "norm result "<< norm2(result)<<std::endl;
std::cout<<GridLogMessage << "norm ref "<< norm2(ref)<<std::endl;
err = ref-result;
std::cout<<GridLogMessage << "norm diff "<< norm2(err)<<std::endl;
assert(norm2(err)<1.0e-4);
LatticeFermion src_e (FrbGrid);
LatticeFermion src_o (FrbGrid);
LatticeFermion r_e (FrbGrid);
@ -313,26 +350,37 @@ int main (int argc, char ** argv)
LatticeFermion r_eo (FGrid);
std::cout<<GridLogMessage << "Calling Deo and Doe"<<std::endl;
std::cout<<GridLogMessage << "Calling Deo and Doe and assert Deo+Doe == Dunprec"<<std::endl;
pickCheckerboard(Even,src_e,src);
pickCheckerboard(Odd,src_o,src);
std::cout<<GridLogMessage << "src_e"<<norm2(src_e)<<std::endl;
std::cout<<GridLogMessage << "src_o"<<norm2(src_o)<<std::endl;
std::cout << GridLogMessage<< "*********************************************************" <<std::endl;
std::cout << GridLogMessage<< "* Benchmarking DomainWallFermionR::DhopEO "<<std::endl;
std::cout << GridLogMessage<< "* Vectorising space-time by "<<vComplex::Nsimd()<<std::endl;
if ( sizeof(Real)==4 ) std::cout << GridLogMessage<< "* SINGLE precision "<<std::endl;
if ( sizeof(Real)==8 ) std::cout << GridLogMessage<< "* DOUBLE precision "<<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptGeneric ) std::cout << GridLogMessage<< "* Using GENERIC Nc WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptHandUnroll) std::cout << GridLogMessage<< "* Using Nc=3 WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptInlineAsm ) std::cout << GridLogMessage<< "* Using Asm Nc=3 WilsonKernels" <<std::endl;
std::cout << GridLogMessage<< "*********************************************************" <<std::endl;
{
Dw.ZeroCounters();
FGrid->Barrier();
double t0=usecond();
for(int i=0;i<ncall;i++){
Dw.DhopEO(src_o,r_e,DaggerNo);
}
double t1=usecond();
FGrid->Barrier();
double volume=Ls; for(int mu=0;mu<Nd;mu++) volume=volume*latt4[mu];
double flops=(1344.0*volume*ncall)/2;
std::cout<<GridLogMessage << "Deo mflop/s = "<< flops/(t1-t0)<<std::endl;
std::cout<<GridLogMessage << "Deo mflop/s per node "<< flops/(t1-t0)/NP<<std::endl;
std::cout<<GridLogMessage << "Deo mflop/s per rank "<< flops/(t1-t0)/NP<<std::endl;
Dw.Report();
}
Dw.DhopEO(src_o,r_e,DaggerNo);
@ -348,14 +396,14 @@ int main (int argc, char ** argv)
err = r_eo-result;
std::cout<<GridLogMessage << "norm diff "<< norm2(err)<<std::endl;
assert(norm2(err)<1.0e-4);
pickCheckerboard(Even,src_e,err);
pickCheckerboard(Odd,src_o,err);
std::cout<<GridLogMessage << "norm diff even "<< norm2(src_e)<<std::endl;
std::cout<<GridLogMessage << "norm diff odd "<< norm2(src_o)<<std::endl;
}
assert(norm2(src_e)<1.0e-4);
assert(norm2(src_o)<1.0e-4);
Grid_finalize();
}

153
benchmarks/Benchmark_dwf_ntpf.cc
View File

@ -1,153 +0,0 @@
/*************************************************************************************
Grid physics library, www.github.com/paboyle/Grid
Source file: ./benchmarks/Benchmark_dwf.cc
Copyright (C) 2015
Author: Peter Boyle <paboyle@ph.ed.ac.uk>
Author: paboyle <paboyle@ph.ed.ac.uk>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
See the full license in the file "LICENSE" in the top level distribution directory
*************************************************************************************/
/* END LEGAL */
#include <Grid/Grid.h>
using namespace std;
using namespace Grid;
using namespace Grid::QCD;
template<class d>
struct scal {
d internal;
};
Gamma::GammaMatrix Gmu [] = {
Gamma::GammaX,
Gamma::GammaY,
Gamma::GammaZ,
Gamma::GammaT
};
bool overlapComms = false;
int main (int argc, char ** argv)
{
Grid_init(&argc,&argv);
if( GridCmdOptionExists(argv,argv+argc,"--asynch") ){
overlapComms = true;
}
int threads = GridThread::GetThreads();
std::cout<<GridLogMessage << "Grid is setup to use "<<threads<<" threads"<<std::endl;
std::vector<int> latt4 = GridDefaultLatt();
const int Ls=16;
GridCartesian * UGrid = SpaceTimeGrid::makeFourDimGrid(GridDefaultLatt(), GridDefaultSimd(Nd,vComplex::Nsimd()),GridDefaultMpi());
GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);
GridCartesian * FGrid = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);
GridRedBlackCartesian * FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,UGrid);
std::vector<int> seeds4({1,2,3,4});
std::vector<int> seeds5({5,6,7,8});
GridParallelRNG RNG4(UGrid); RNG4.SeedFixedIntegers(seeds4);
GridParallelRNG RNG5(FGrid); RNG5.SeedFixedIntegers(seeds5);
LatticeFermion src (FGrid); random(RNG5,src);
LatticeFermion result(FGrid); result=zero;
LatticeFermion ref(FGrid); ref=zero;
LatticeFermion tmp(FGrid);
LatticeFermion err(FGrid);
ColourMatrix cm = Complex(1.0,0.0);
LatticeGaugeField Umu(UGrid);
random(RNG4,Umu);
LatticeGaugeField Umu5d(FGrid);
// replicate across fifth dimension
for(int ss=0;ss<Umu._grid->oSites();ss++){
for(int s=0;s<Ls;s++){
Umu5d._odata[Ls*ss+s] = Umu._odata[ss];
}
}
////////////////////////////////////
// Naive wilson implementation
////////////////////////////////////
std::vector<LatticeColourMatrix> U(4,FGrid);
for(int mu=0;mu<Nd;mu++){
U[mu] = PeekIndex<LorentzIndex>(Umu5d,mu);
}
if (1)
{
ref = zero;
for(int mu=0;mu<Nd;mu++){
tmp = U[mu]*Cshift(src,mu+1,1);
ref=ref + tmp - Gamma(Gmu[mu])*tmp;
tmp =adj(U[mu])*src;
tmp =Cshift(tmp,mu+1,-1);
ref=ref + tmp + Gamma(Gmu[mu])*tmp;
}
ref = -0.5*ref;
}
RealD mass=0.1;
RealD M5 =1.8;
typename DomainWallFermionR::ImplParams params;
params.overlapCommsCompute = overlapComms;
RealD NP = UGrid->_Nprocessors;
QCD::WilsonKernelsStatic::AsmOpt=1;
DomainWallFermionR Dw(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,mass,M5,params);
std::cout<<GridLogMessage << "Calling Dw"<<std::endl;
int ncall =50;
if (1) {
double t0=usecond();
for(int i=0;i<ncall;i++){
Dw.Dhop(src,result,0);
}
double t1=usecond();
double volume=Ls; for(int mu=0;mu<Nd;mu++) volume=volume*latt4[mu];
double flops=1344*volume*ncall;
std::cout<<GridLogMessage << "Called Dw "<<ncall<<" times in "<<t1-t0<<" us"<<std::endl;
std::cout<<GridLogMessage << "norm result "<< norm2(result)<<std::endl;
std::cout<<GridLogMessage << "norm ref "<< norm2(ref)<<std::endl;
std::cout<<GridLogMessage << "mflop/s = "<< flops/(t1-t0)<<std::endl;
std::cout<<GridLogMessage << "mflop/s per node = "<< flops/(t1-t0)/NP<<std::endl;
err = ref-result;
std::cout<<GridLogMessage << "norm diff "<< norm2(err)<<std::endl;
// Dw.Report();
}
Grid_finalize();
}

22
benchmarks/Benchmark_dwf_sweep.cc
View File

@ -51,24 +51,26 @@ int main (int argc, char ** argv)
{
Grid_init(&argc,&argv);
const int Ls=16;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
std::cout << GridLogMessage<< "* Kernel options --dslash-generic, --dslash-unroll, --dslash-asm" <<std::endl;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptGeneric ) std::cout << GridLogMessage<< "* Using GENERIC Nc WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptHandUnroll) std::cout << GridLogMessage<< "* Using Nc=3 WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptInlineAsm ) std::cout << GridLogMessage<< "* Using Asm Nc=3 WilsonKernels" <<std::endl;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
const int Ls=8;
int threads = GridThread::GetThreads();
std::cout<<GridLogMessage << "Grid is setup to use "<<threads<<" threads"<<std::endl;
if ( getenv("ASMOPT") ) {
QCD::WilsonKernelsStatic::AsmOpt=1;
} else {
QCD::WilsonKernelsStatic::AsmOpt=0;
}
std::cout<<GridLogMessage << "=========================================================================="<<std::endl;
std::cout<<GridLogMessage << "= Benchmarking DWF"<<std::endl;
std::cout<<GridLogMessage << "=========================================================================="<<std::endl;
std::cout<<GridLogMessage << "Volume \t\t\tProcs \t Dw \t eoDw \t sDw \t eosDw (Mflop/s) "<<std::endl;
std::cout<<GridLogMessage << "=========================================================================="<<std::endl;
int Lmax=32;
int dmin=0;
int Lmax=16;
int dmin=2;
if ( getenv("LMAX") ) Lmax=atoi(getenv("LMAX"));
if ( getenv("DMIN") ) dmin=atoi(getenv("DMIN"));
for (int L=8;L<=Lmax;L*=2){

13
benchmarks/Benchmark_wilson_sweep.cc
View File

@ -58,6 +58,19 @@ int main (int argc, char ** argv)
std::vector<int> seeds({1,2,3,4});
RealD mass = 0.1;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
std::cout << GridLogMessage<< "* Kernel options --dslash-generic, --dslash-unroll, --dslash-asm" <<std::endl;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
std::cout << GridLogMessage<< "* Benchmarking WilsonFermionR::Dhop "<<std::endl;
std::cout << GridLogMessage<< "* Vectorising space-time by "<<vComplex::Nsimd()<<std::endl;
if ( sizeof(Real)==4 ) std::cout << GridLogMessage<< "* SINGLE precision "<<std::endl;
if ( sizeof(Real)==8 ) std::cout << GridLogMessage<< "* DOUBLE precision "<<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptGeneric ) std::cout << GridLogMessage<< "* Using GENERIC Nc WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptHandUnroll) std::cout << GridLogMessage<< "* Using Nc=3 WilsonKernels" <<std::endl;
if ( WilsonKernelsStatic::Opt == WilsonKernelsStatic::OptInlineAsm ) std::cout << GridLogMessage<< "* Using Asm Nc=3 WilsonKernels" <<std::endl;
std::cout << GridLogMessage<< "*****************************************************************" <<std::endl;
std::cout<<GridLogMessage << "============================================================================="<< std::endl;
std::cout<<GridLogMessage << "= Benchmarking Wilson" << std::endl;
std::cout<<GridLogMessage << "============================================================================="<< std::endl;

175
benchmarks/Benchmark_zmm.cc
View File

@ -1,175 +0,0 @@
/*************************************************************************************
Grid physics library, www.github.com/paboyle/Grid
Source file: ./tests/Test_zmm.cc
Copyright (C) 2015
Author: paboyle <paboyle@ph.ed.ac.uk>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
See the full license in the file "LICENSE" in the top level distribution directory
*************************************************************************************/
/* END LEGAL */
#include <Grid/Grid.h>
using namespace Grid;
using namespace Grid::QCD;
int bench(std::ofstream &os, std::vector<int> &latt4,int Ls);
int main(int argc,char **argv)
{
Grid_init(&argc,&argv);
std::ofstream os("zmm.dat");
os << "#V Ls Lxy Lzt C++ Asm OMP L1 " <<std::endl;
std::cout<<GridLogMessage << "====================================================================="<<std::endl;
std::cout<<GridLogMessage << "= Benchmarking ZMM"<<std::endl;
std::cout<<GridLogMessage << "====================================================================="<<std::endl;
std::cout<<GridLogMessage << "Volume \t\t\t\tC++DW/MFLOPs\tASM-DW/MFLOPs\tdiff"<<std::endl;
std::cout<<GridLogMessage << "====================================================================="<<std::endl;
for(int L=4;L<=32;L+=4){
for(int m=1;m<=2;m++){
for(int Ls=8;Ls<=16;Ls+=8){
std::vector<int> grid({L,L,m*L,m*L});
std::cout << GridLogMessage <<"\t";
for(int i=0;i<4;i++) {
std::cout << grid[i]<<"x";
}
std::cout << Ls<<"\t\t";
bench(os,grid,Ls);
}
}
}
}
int bench(std::ofstream &os, std::vector<int> &latt4,int Ls)
{
GridCartesian * UGrid = SpaceTimeGrid::makeFourDimGrid(latt4, GridDefaultSimd(Nd,vComplex::Nsimd()),GridDefaultMpi());
GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);
GridCartesian * FGrid = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);
GridRedBlackCartesian * FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,UGrid);
std::vector<int> simd_layout = GridDefaultSimd(Nd,vComplex::Nsimd());
std::vector<int> mpi_layout = GridDefaultMpi();
int threads = GridThread::GetThreads();
std::vector<int> seeds4({1,2,3,4});
std::vector<int> seeds5({5,6,7,8});
GridSerialRNG sRNG; sRNG.SeedFixedIntegers(seeds4);
LatticeFermion src (FGrid);
LatticeFermion tmp (FGrid);
LatticeFermion srce(FrbGrid);
LatticeFermion resulto(FrbGrid); resulto=zero;
LatticeFermion resulta(FrbGrid); resulta=zero;
LatticeFermion junk(FrbGrid); junk=zero;
LatticeFermion diff(FrbGrid);
LatticeGaugeField Umu(UGrid);
double mfc, mfa, mfo, mfl1;
GridParallelRNG RNG4(UGrid); RNG4.SeedFixedIntegers(seeds4);
GridParallelRNG RNG5(FGrid); RNG5.SeedFixedIntegers(seeds5);
random(RNG5,src);
#if 1
random(RNG4,Umu);
#else
int mmu=2;
std::vector<LatticeColourMatrix> U(4,UGrid);
for(int mu=0;mu<Nd;mu++){
U[mu] = PeekIndex<LorentzIndex>(Umu,mu);
if ( mu!=mmu ) U[mu] = zero;
if ( mu==mmu ) U[mu] = 1.0;
PokeIndex<LorentzIndex>(Umu,U[mu],mu);
}
#endif
pickCheckerboard(Even,srce,src);
RealD mass=0.1;
RealD M5 =1.8;
DomainWallFermionR Dw(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,mass,M5);
int ncall=50;
double t0=usecond();
for(int i=0;i<ncall;i++){
Dw.DhopOE(srce,resulto,0);
}
double t1=usecond();
double volume=Ls; for(int mu=0;mu<Nd;mu++) volume=volume*latt4[mu];
double flops=1344*volume/2;
mfc = flops*ncall/(t1-t0);
std::cout<<mfc<<"\t\t";
QCD::WilsonKernelsStatic::AsmOpt=1;
t0=usecond();
for(int i=0;i<ncall;i++){
Dw.DhopOE(srce,resulta,0);
}
t1=usecond();
mfa = flops*ncall/(t1-t0);
std::cout<<mfa<<"\t\t";
/*
int dag=DaggerNo;
t0=usecond();
for(int i=0;i<1;i++){
Dw.DhopInternalOMPbench(Dw.StencilEven,Dw.LebesgueEvenOdd,Dw.UmuOdd,srce,resulta,dag);
}
t1=usecond();
mfo = flops*100/(t1-t0);
std::cout<<GridLogMessage << "Called ASM-OMP Dw"<< " mflop/s = "<< mfo<<std::endl;
t0=usecond();
for(int i=0;i<1;i++){
Dw.DhopInternalL1bench(Dw.StencilEven,Dw.LebesgueEvenOdd,Dw.UmuOdd,srce,resulta,dag);
}
t1=usecond();
mfl1= flops*100/(t1-t0);
std::cout<<GridLogMessage << "Called ASM-L1 Dw"<< " mflop/s = "<< mfl1<<std::endl;
os << latt4[0]*latt4[1]*latt4[2]*latt4[3]<< " "<<Ls<<" "<< latt4[0] <<" " <<latt4[2]<< " "
<< mfc<<" "
<< mfa<<" "
<< mfo<<" "
<< mfl1<<std::endl;
*/
#if 0
for(int i=0;i< PerformanceCounter::NumTypes(); i++ ){
Dw.DhopOE(srce,resulta,0);
PerformanceCounter Counter(i);
Counter.Start();
Dw.DhopOE(srce,resulta,0);
Counter.Stop();
Counter.Report();
}
#endif
//resulta = (-0.5) * resulta;
diff = resulto-resulta;
std::cout<<norm2(diff)<<std::endl;
return 0;
}

10
benchmarks/Makefile.am
View File

@ -1 +1,11 @@
include Make.inc
simple: simple_su3_test.o simple_su3_expr.o simple_simd_test.o
EXTRA_LIBRARIES = libsimple_su3_test.a libsimple_su3_expr.a libsimple_simd_test.a
libsimple_su3_test_a_SOURCES = simple_su3_test.cc
libsimple_su3_expr_a_SOURCES = simple_su3_expr.cc
libsimple_simd_test_a_SOURCES = simple_simd_test.cc

11
benchmarks/simple_simd_test.cc Normal file
View File

@ -0,0 +1,11 @@
#include <Grid/Grid.h>
Grid::vRealD add(const Grid::vRealD &x, const Grid::vRealD &y)
{
return x+y;
}
Grid::vRealD sub(const Grid::vRealD &x, const Grid::vRealD &y)
{
return x-y;
}

2
benchmarks/simple_su3_expr.cc
View File

@ -25,7 +25,7 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
See the full license in the file "LICENSE" in the top level distribution directory
*************************************************************************************/
/* END LEGAL */
#include <Grid.h>
#include <Grid/Grid.h>
using namespace std;
using namespace Grid;

2
benchmarks/simple_su3_test.cc
View File

@ -25,7 +25,7 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
See the full license in the file "LICENSE" in the top level distribution directory
*************************************************************************************/
/* END LEGAL */
#include <Grid.h>
#include <Grid/Grid.h>
using namespace std;
using namespace Grid;

6
bootstrap.sh
View File

@ -1,18 +1,12 @@
#!/usr/bin/env bash
EIGEN_URL='http://bitbucket.org/eigen/eigen/get/3.2.9.tar.bz2'
FFTW_URL=http://www.fftw.org/fftw-3.3.4.tar.gz
echo "-- deploying Eigen source..."
wget ${EIGEN_URL} --no-check-certificate
./scripts/update_eigen.sh `basename ${EIGEN_URL}`
rm `basename ${EIGEN_URL}`
echo "-- copying fftw prototypes..."
wget ${FFTW_URL}
./scripts/update_fftw.sh `basename ${FFTW_URL}`
rm `basename ${FFTW_URL}`
echo '-- generating Make.inc files...'
./scripts/filelist
echo '-- generating configure script...'

299
configure.ac
View File

@ -1,5 +1,5 @@
AC_PREREQ([2.63])
AC_INIT([Grid], [0.5.1-dev], [https://github.com/paboyle/Grid], [Grid])
AC_INIT([Grid], [0.6.0], [https://github.com/paboyle/Grid], [Grid])
AC_CANONICAL_BUILD
AC_CANONICAL_HOST
AC_CANONICAL_TARGET
@ -9,22 +9,33 @@ AC_CONFIG_SRCDIR([lib/Grid.h])
AC_CONFIG_HEADERS([lib/Config.h])
m4_ifdef([AM_SILENT_RULES], [AM_SILENT_RULES([yes])])
############### Checks for programs
AC_LANG(C++)
CXXFLAGS="-O3 $CXXFLAGS"
AC_PROG_CXX
AC_PROG_RANLIB
############ openmp ###############
############### Get compiler informations
AC_LANG([C++])
AX_CXX_COMPILE_STDCXX_11([noext],[mandatory])
AX_COMPILER_VENDOR
AC_DEFINE_UNQUOTED([CXX_COMP_VENDOR],["$ax_cv_cxx_compiler_vendor"],
[vendor of C++ compiler that will compile the code])
AX_GXX_VERSION
AC_DEFINE_UNQUOTED([GXX_VERSION],["$GXX_VERSION"],
[version of g++ that will compile the code])
############### Checks for typedefs, structures, and compiler characteristics
AC_TYPE_SIZE_T
AC_TYPE_UINT32_T
AC_TYPE_UINT64_T
############### OpenMP
AC_OPENMP
ac_openmp=no
if test "${OPENMP_CXXFLAGS}X" != "X"; then
ac_openmp=yes
AM_CXXFLAGS="$OPENMP_CXXFLAGS $AM_CXXFLAGS"
AM_LDFLAGS="$OPENMP_CXXFLAGS $AM_LDFLAGS"
ac_openmp=yes
AM_CXXFLAGS="$OPENMP_CXXFLAGS $AM_CXXFLAGS"
AM_LDFLAGS="$OPENMP_CXXFLAGS $AM_LDFLAGS"
fi
############### Checks for header files
@ -37,12 +48,7 @@ AC_CHECK_HEADERS(execinfo.h)
AC_CHECK_DECLS([ntohll],[], [], [[#include <arpa/inet.h>]])
AC_CHECK_DECLS([be64toh],[], [], [[#include <arpa/inet.h>]])
############### Checks for typedefs, structures, and compiler characteristics
AC_TYPE_SIZE_T
AC_TYPE_UINT32_T
AC_TYPE_UINT64_T
############### GMP and MPFR #################
############### GMP and MPFR
AC_ARG_WITH([gmp],
[AS_HELP_STRING([--with-gmp=prefix],
[try this for a non-standard install prefix of the GMP library])],
@ -54,10 +60,17 @@ AC_ARG_WITH([mpfr],
[AM_CXXFLAGS="-I$with_mpfr/include $AM_CXXFLAGS"]
[AM_LDFLAGS="-L$with_mpfr/lib $AM_LDFLAGS"])
################## lapack ####################
############### FFTW3
AC_ARG_WITH([fftw],
[AS_HELP_STRING([--with-fftw=prefix],
[try this for a non-standard install prefix of the FFTW3 library])],
[AM_CXXFLAGS="-I$with_fftw/include $AM_CXXFLAGS"]
[AM_LDFLAGS="-L$with_fftw/lib $AM_LDFLAGS"])
############### lapack
AC_ARG_ENABLE([lapack],
[AC_HELP_STRING([--enable-lapack=yes|no|prefix], [enable LAPACK])],
[ac_LAPACK=${enable_lapack}],[ac_LAPACK=no])
[ac_LAPACK=${enable_lapack}], [ac_LAPACK=no])
case ${ac_LAPACK} in
no)
@ -67,59 +80,83 @@ case ${ac_LAPACK} in
*)
AM_CXXFLAGS="-I$ac_LAPACK/include $AM_CXXFLAGS"
AM_LDFLAGS="-L$ac_LAPACK/lib $AM_LDFLAGS"
AC_DEFINE([USE_LAPACK],[1],[use LAPACK])
AC_DEFINE([USE_LAPACK],[1],[use LAPACK]);;
esac
################## FFTW3 ####################
AC_ARG_WITH([fftw],
[AS_HELP_STRING([--with-fftw=prefix],
[try this for a non-standard install prefix of the FFTW3 library])],
[AM_CXXFLAGS="-I$with_fftw/include $AM_CXXFLAGS"]
[AM_LDFLAGS="-L$with_fftw/lib $AM_LDFLAGS"])
############### MKL
AC_ARG_ENABLE([mkl],
[AC_HELP_STRING([--enable-mkl=yes|no|prefix], [enable Intel MKL for LAPACK & FFTW])],
[ac_MKL=${enable_mkl}], [ac_MKL=no])
################ Get compiler informations
AC_LANG([C++])
AX_CXX_COMPILE_STDCXX_11([noext],[mandatory])
AX_COMPILER_VENDOR
AC_DEFINE_UNQUOTED([CXX_COMP_VENDOR],["$ax_cv_cxx_compiler_vendor"],
[vendor of C++ compiler that will compile the code])
AX_GXX_VERSION
AC_DEFINE_UNQUOTED([GXX_VERSION],["$GXX_VERSION"],
[version of g++ that will compile the code])
case ${ac_MKL} in
no)
;;
yes)
AC_DEFINE([USE_MKL], [1], [Define to 1 if you use the Intel MKL]);;
*)
AM_CXXFLAGS="-I$ac_MKL/include $AM_CXXFLAGS"
AM_LDFLAGS="-L$ac_MKL/lib $AM_LDFLAGS"
AC_DEFINE([USE_MKL], [1], [Define to 1 if you use the Intel MKL]);;
esac
############### first-touch
AC_ARG_ENABLE([numa],
[AC_HELP_STRING([--enable-numa=yes|no|prefix], [enable first touch numa opt])],
[ac_NUMA=${enable_NUMA}],[ac_NUMA=no])
case ${ac_NUMA} in
no)
;;
yes)
AC_DEFINE([GRID_NUMA],[1],[First touch numa locality]);;
*)
AC_DEFINE([GRID_NUMA],[1],[First touch numa locality]);;
esac
############### Checks for library functions
CXXFLAGS_CPY=$CXXFLAGS
LDFLAGS_CPY=$LDFLAGS
CXXFLAGS="$AM_CXXFLAGS $CXXFLAGS"
LDFLAGS="$AM_LDFLAGS $LDFLAGS"
AC_CHECK_FUNCS([gettimeofday])
AC_CHECK_LIB([gmp],[__gmpf_init],
[AC_CHECK_LIB([mpfr],[mpfr_init],
[AC_DEFINE([HAVE_LIBMPFR], [1], [Define to 1 if you have the `MPFR' library (-lmpfr).])]
[have_mpfr=true]
[LIBS="$LIBS -lmpfr"],
[AC_MSG_ERROR([MPFR library not found])])]
[AC_DEFINE([HAVE_LIBGMP], [1], [Define to 1 if you have the `GMP' library (-lgmp).])]
[have_gmp=true]
[LIBS="$LIBS -lgmp"],
[AC_MSG_WARN([**** GMP library not found, Grid can still compile but RHMC will not work ****])])
if test "${ac_MKL}x" != "nox"; then
AC_SEARCH_LIBS([mkl_set_interface_layer], [mkl_rt], [],
[AC_MSG_ERROR("MKL enabled but library not found")])
fi
AC_SEARCH_LIBS([__gmpf_init], [gmp],
[AC_SEARCH_LIBS([mpfr_init], [mpfr],
[AC_DEFINE([HAVE_LIBMPFR], [1],
[Define to 1 if you have the `MPFR' library])]
[have_mpfr=true], [AC_MSG_ERROR([MPFR library not found])])]
[AC_DEFINE([HAVE_LIBGMP], [1], [Define to 1 if you have the `GMP' library])]
[have_gmp=true])
if test "${ac_LAPACK}x" != "nox"; then
AC_CHECK_LIB([lapack],[LAPACKE_sbdsdc],[],
[AC_MSG_ERROR("LAPACK enabled but library not found")])
fi
AC_CHECK_LIB([fftw3],[fftw_execute],
[AC_DEFINE([HAVE_FFTW],[1],[Define to 1 if you have the `FFTW' library (-lfftw3).])]
[have_fftw=true]
[LIBS="$LIBS -lfftw3 -lfftw3f"],
[AC_MSG_WARN([**** FFTW library not found, Grid can still compile but FFT-based routines will not work ****])])
AC_SEARCH_LIBS([LAPACKE_sbdsdc], [lapack], [],
[AC_MSG_ERROR("LAPACK enabled but library not found")])
fi
AC_SEARCH_LIBS([fftw_execute], [fftw3],
[AC_SEARCH_LIBS([fftwf_execute], [fftw3f], [],
[AC_MSG_ERROR("single precision FFTW library not found")])]
[AC_DEFINE([HAVE_FFTW], [1], [Define to 1 if you have the `FFTW' library])]
[have_fftw=true])
CXXFLAGS=$CXXFLAGS_CPY
LDFLAGS=$LDFLAGS_CPY
############### SIMD instruction selection
AC_ARG_ENABLE([simd],[AC_HELP_STRING([--enable-simd=SSE4|AVX|AVXFMA4|AVX2|AVX512|AVX512MIC|IMCI|KNL|KNC],\
[Select instructions to be SSE4.0, AVX 1.0, AVX 2.0+FMA, AVX 512, IMCI])],\
[ac_SIMD=${enable_simd}],[ac_SIMD=GEN])
AC_ARG_ENABLE([simd],[AC_HELP_STRING([--enable-simd=code],
[select SIMD target (cf. README.md)])], [ac_SIMD=${enable_simd}], [ac_SIMD=GEN])
AC_ARG_ENABLE([gen-simd-width],
[AS_HELP_STRING([--enable-gen-simd-width=size],
[size (in bytes) of the generic SIMD vectors (default: 32)])],
[ac_gen_simd_width=$enable_gen_simd_width],
[ac_gen_simd_width=32])
case ${ax_cv_cxx_compiler_vendor} in
clang|gnu)
@ -133,17 +170,26 @@ case ${ax_cv_cxx_compiler_vendor} in
AVXFMA4)
AC_DEFINE([AVXFMA4],[1],[AVX intrinsics with FMA4])
SIMD_FLAGS='-mavx -mfma4';;
AVXFMA)
AC_DEFINE([AVXFMA],[1],[AVX intrinsics with FMA3])
SIMD_FLAGS='-mavx -mfma';;
AVX2)
AC_DEFINE([AVX2],[1],[AVX2 intrinsics])
SIMD_FLAGS='-mavx2 -mfma';;
AVX512|AVX512MIC|KNL)
AVX512)
AC_DEFINE([AVX512],[1],[AVX512 intrinsics])
SIMD_FLAGS='-mavx512f -mavx512pf -mavx512er -mavx512cd';;
IMCI|KNC)
KNC)
AC_DEFINE([IMCI],[1],[IMCI intrinsics for Knights Corner])
SIMD_FLAGS='';;
KNL)
AC_DEFINE([AVX512],[1],[AVX512 intrinsics])
SIMD_FLAGS='-march=knl';;
GEN)
AC_DEFINE([GENERIC_VEC],[1],[generic vector code])
AC_DEFINE([GEN],[1],[generic vector code])
AC_DEFINE_UNQUOTED([GEN_SIMD_WIDTH],[$ac_gen_simd_width],
[generic SIMD vector width (in bytes)])
SIMD_GEN_WIDTH_MSG=" (width= $ac_gen_simd_width)"
SIMD_FLAGS='';;
QPX|BGQ)
AC_DEFINE([QPX],[1],[QPX intrinsics for BG/Q])
@ -159,8 +205,8 @@ case ${ax_cv_cxx_compiler_vendor} in
AVX)
AC_DEFINE([AVX1],[1],[AVX intrinsics])
SIMD_FLAGS='-mavx -xavx';;
AVXFMA4)
AC_DEFINE([AVXFMA4],[1],[AVX intrinsics with FMA4])
AVXFMA)
AC_DEFINE([AVXFMA],[1],[AVX intrinsics with FMA4])
SIMD_FLAGS='-mavx -mfma';;
AVX2)
AC_DEFINE([AVX2],[1],[AVX2 intrinsics])
@ -168,14 +214,17 @@ case ${ax_cv_cxx_compiler_vendor} in
AVX512)
AC_DEFINE([AVX512],[1],[AVX512 intrinsics])
SIMD_FLAGS='-xcore-avx512';;
AVX512MIC|KNL)
AC_DEFINE([AVX512],[1],[AVX512 intrinsics for Knights Landing])
SIMD_FLAGS='-xmic-avx512';;
IMCI|KNC)
KNC)
AC_DEFINE([IMCI],[1],[IMCI Intrinsics for Knights Corner])
SIMD_FLAGS='';;
KNL)
AC_DEFINE([AVX512],[1],[AVX512 intrinsics for Knights Landing])
SIMD_FLAGS='-xmic-avx512';;
GEN)
AC_DEFINE([GENERIC_VEC],[1],[generic vector code])
AC_DEFINE([GEN],[1],[generic vector code])
AC_DEFINE([GEN_SIMD_WIDTH],[$ac_gen_simd_width],
[generic SIMD vector width (in bytes)])
SIMD_GEN_WIDTH_MSG=" (width= $ac_gen_simd_width)"
SIMD_FLAGS='';;
*)
AC_MSG_ERROR(["SIMD option ${ac_SIMD} not supported by the Intel compiler"]);;
@ -188,14 +237,18 @@ AM_CXXFLAGS="$SIMD_FLAGS $AM_CXXFLAGS"
AM_CFLAGS="$SIMD_FLAGS $AM_CFLAGS"
case ${ac_SIMD} in
AVX512|AVX512MIC|KNL)
AVX512|KNL)
AC_DEFINE([TEST_ZMM],[1],[compile ZMM test]);;
*)
;;
esac
############### precision selection
AC_ARG_ENABLE([precision],[AC_HELP_STRING([--enable-precision=single|double],[Select default word size of Real])],[ac_PRECISION=${enable_precision}],[ac_PRECISION=double])
############### Precision selection
AC_ARG_ENABLE([precision],
[AC_HELP_STRING([--enable-precision=single|double],
[Select default word size of Real])],
[ac_PRECISION=${enable_precision}],[ac_PRECISION=double])
case ${ac_PRECISION} in
single)
AC_DEFINE([GRID_DEFAULT_PRECISION_SINGLE],[1],[GRID_DEFAULT_PRECISION is SINGLE] )
@ -206,39 +259,56 @@ case ${ac_PRECISION} in
esac
############### communication type selection
AC_ARG_ENABLE([comms],[AC_HELP_STRING([--enable-comms=none|mpi|mpi-auto|shmem],[Select communications])],[ac_COMMS=${enable_comms}],[ac_COMMS=none])
AC_ARG_ENABLE([comms],[AC_HELP_STRING([--enable-comms=none|mpi|mpi-auto|mpi3|mpi3-auto|shmem],
[Select communications])],[ac_COMMS=${enable_comms}],[ac_COMMS=none])
case ${ac_COMMS} in
none)
AC_DEFINE([GRID_COMMS_NONE],[1],[GRID_COMMS_NONE] )
AC_DEFINE([GRID_COMMS_NONE],[1],[GRID_COMMS_NONE] )
comms_type='none'
;;
mpi-auto)
AC_DEFINE([GRID_COMMS_MPI],[1],[GRID_COMMS_MPI] )
LX_FIND_MPI
if test "x$have_CXX_mpi" = 'xno'; then AC_MSG_ERROR(["MPI not found"]); fi
AM_CXXFLAGS="$MPI_CXXFLAGS $AM_CXXFLAGS"
AM_CFLAGS="$MPI_CFLAGS $AM_CFLAGS"
AM_LDFLAGS="`echo $MPI_CXXLDFLAGS | sed -E 's/-l@<:@^ @:>@+//g'` $AM_LDFLAGS"
LIBS="`echo $MPI_CXXLDFLAGS | sed -E 's/-L@<:@^ @:>@+//g'` $LIBS"
mpi3l*)
AC_DEFINE([GRID_COMMS_MPI3L],[1],[GRID_COMMS_MPI3L] )
comms_type='mpi3l'
;;
mpi)
AC_DEFINE([GRID_COMMS_MPI],[1],[GRID_COMMS_MPI] )
mpi3*)
AC_DEFINE([GRID_COMMS_MPI3],[1],[GRID_COMMS_MPI3] )
comms_type='mpi3'
;;
mpi*)
AC_DEFINE([GRID_COMMS_MPI],[1],[GRID_COMMS_MPI] )
comms_type='mpi'
;;
shmem)
AC_DEFINE([GRID_COMMS_SHMEM],[1],[GRID_COMMS_SHMEM] )
AC_DEFINE([GRID_COMMS_SHMEM],[1],[GRID_COMMS_SHMEM] )
comms_type='shmem'
;;
*)
AC_MSG_ERROR([${ac_COMMS} unsupported --enable-comms option]);
AC_MSG_ERROR([${ac_COMMS} unsupported --enable-comms option]);
;;
esac
AM_CONDITIONAL(BUILD_COMMS_SHMEM,[ test "X${ac_COMMS}X" == "XshmemX" ])
AM_CONDITIONAL(BUILD_COMMS_MPI,[ test "X${ac_COMMS}X" == "XmpiX" || test "X${ac_COMMS}X" == "Xmpi-autoX" ])
AM_CONDITIONAL(BUILD_COMMS_NONE,[ test "X${ac_COMMS}X" == "XnoneX" ])
case ${ac_COMMS} in
*-auto)
LX_FIND_MPI
if test "x$have_CXX_mpi" = 'xno'; then AC_MSG_ERROR(["MPI not found"]); fi
AM_CXXFLAGS="$MPI_CXXFLAGS $AM_CXXFLAGS"
AM_CFLAGS="$MPI_CFLAGS $AM_CFLAGS"
AM_LDFLAGS="`echo $MPI_CXXLDFLAGS | sed -E 's/-l@<:@^ @:>@+//g'` $AM_LDFLAGS"
LIBS="`echo $MPI_CXXLDFLAGS | sed -E 's/-L@<:@^ @:>@+//g'` $LIBS";;
*)
;;
esac
AM_CONDITIONAL(BUILD_COMMS_SHMEM, [ test "${comms_type}X" == "shmemX" ])
AM_CONDITIONAL(BUILD_COMMS_MPI, [ test "${comms_type}X" == "mpiX" ])
AM_CONDITIONAL(BUILD_COMMS_MPI3, [ test "${comms_type}X" == "mpi3X" ] )
AM_CONDITIONAL(BUILD_COMMS_MPI3L, [ test "${comms_type}X" == "mpi3lX" ] )
AM_CONDITIONAL(BUILD_COMMS_NONE, [ test "${comms_type}X" == "noneX" ])
############### RNG selection
AC_ARG_ENABLE([rng],[AC_HELP_STRING([--enable-rng=ranlux48|mt19937],\
[Select Random Number Generator to be used])],\
[ac_RNG=${enable_rng}],[ac_RNG=ranlux48])
[Select Random Number Generator to be used])],\
[ac_RNG=${enable_rng}],[ac_RNG=ranlux48])
case ${ac_RNG} in
ranlux48)
@ -252,10 +322,11 @@ case ${ac_RNG} in
;;
esac
############### timer option
############### Timer option
AC_ARG_ENABLE([timers],[AC_HELP_STRING([--enable-timers],\
[Enable system dependent high res timers])],\
[ac_TIMERS=${enable_timers}],[ac_TIMERS=yes])
[Enable system dependent high res timers])],\
[ac_TIMERS=${enable_timers}],[ac_TIMERS=yes])
case ${ac_TIMERS} in
yes)
AC_DEFINE([TIMERS_ON],[1],[TIMERS_ON] )
@ -269,7 +340,9 @@ case ${ac_TIMERS} in
esac
############### Chroma regression test
AC_ARG_ENABLE([chroma],[AC_HELP_STRING([--enable-chroma],[Expect chroma compiled under c++11 ])],ac_CHROMA=yes,ac_CHROMA=no)
AC_ARG_ENABLE([chroma],[AC_HELP_STRING([--enable-chroma],
[Expect chroma compiled under c++11 ])],ac_CHROMA=yes,ac_CHROMA=no)
case ${ac_CHROMA} in
yes|no)
;;
@ -277,6 +350,7 @@ case ${ac_CHROMA} in
AC_MSG_ERROR([${ac_CHROMA} unsupported --enable-chroma option]);
;;
esac
AM_CONDITIONAL(BUILD_CHROMA_REGRESSION,[ test "X${ac_CHROMA}X" == "XyesX" ])
############### Doxygen
@ -313,34 +387,35 @@ AC_CONFIG_FILES(tests/qdpxx/Makefile)
AC_CONFIG_FILES(benchmarks/Makefile)
AC_OUTPUT
echo "
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
echo "~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Summary of configuration for $PACKAGE v$VERSION
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
----- PLATFORM ----------------------------------------
- architecture (build) : $build_cpu
- os (build) : $build_os
- architecture (target) : $target_cpu
- os (target) : $target_os
- compiler vendor : ${ax_cv_cxx_compiler_vendor}
- compiler version : ${ax_cv_gxx_version}
architecture (build) : $build_cpu
os (build) : $build_os
architecture (target) : $target_cpu
os (target) : $target_os
compiler vendor : ${ax_cv_cxx_compiler_vendor}
compiler version : ${ax_cv_gxx_version}
----- BUILD OPTIONS -----------------------------------
- SIMD : ${ac_SIMD}
- Threading : ${ac_openmp}
- Communications type : ${ac_COMMS}
- Default precision : ${ac_PRECISION}
- RNG choice : ${ac_RNG}
- GMP : `if test "x$have_gmp" = xtrue; then echo yes; else echo no; fi`
- LAPACK : ${ac_LAPACK}
- FFTW : `if test "x$have_fftw" = xtrue; then echo yes; else echo no; fi`
- build DOXYGEN documentation : `if test "$DX_FLAG_doc" = '1'; then echo yes; else echo no; fi`
SIMD : ${ac_SIMD}${SIMD_GEN_WIDTH_MSG}
Threading : ${ac_openmp}
Communications type : ${comms_type}
Default precision : ${ac_PRECISION}
RNG choice : ${ac_RNG}
GMP : `if test "x$have_gmp" = xtrue; then echo yes; else echo no; fi`
LAPACK : ${ac_LAPACK}
FFTW : `if test "x$have_fftw" = xtrue; then echo yes; else echo no; fi`
build DOXYGEN documentation : `if test "$DX_FLAG_doc" = '1'; then echo yes; else echo no; fi`
----- BUILD FLAGS -------------------------------------
- CXXFLAGS:
CXXFLAGS:
`echo ${AM_CXXFLAGS} ${CXXFLAGS} | tr ' ' '\n' | sed 's/^-/ -/g'`
- LDFLAGS:
LDFLAGS:
`echo ${AM_LDFLAGS} ${LDFLAGS} | tr ' ' '\n' | sed 's/^-/ -/g'`
- LIBS:
LIBS:
`echo ${LIBS} | tr ' ' '\n' | sed 's/^-/ -/g'`
-------------------------------------------------------
"
-------------------------------------------------------" > config.summary
echo ""
cat config.summary
echo ""

1130
doxygen.cfg.bak
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File diff suppressed because it is too large Load Diff

2
doxygen.inc
View File

@ -158,8 +158,6 @@ DX_CLEAN_LATEX = @DX_DOCDIR@/latex
endif DX_COND_latex
.PHONY: doxygen-run doxygen-doc $(DX_PS_GOAL) $(DX_PDF_GOAL)
.INTERMEDIATE: doxygen-run $(DX_PS_GOAL) $(DX_PDF_GOAL)
doxygen-run: @DX_DOCDIR@/@PACKAGE@.tag

129
lib/AlignedAllocator.h
View File

@ -40,14 +40,6 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
#include <mm_malloc.h>
#endif
#ifdef GRID_COMMS_SHMEM
extern "C" {
#include <mpp/shmem.h>
extern void * shmem_align(size_t, size_t);
extern void shmem_free(void *);
}
#endif
namespace Grid {
////////////////////////////////////////////////////////////////////
@ -65,28 +57,85 @@ public:
typedef _Tp value_type;
template<typename _Tp1> struct rebind { typedef alignedAllocator<_Tp1> other; };
alignedAllocator() throw() { }
alignedAllocator(const alignedAllocator&) throw() { }
template<typename _Tp1> alignedAllocator(const alignedAllocator<_Tp1>&) throw() { }
~alignedAllocator() throw() { }
pointer address(reference __x) const { return &__x; }
// const_pointer address(const_reference __x) const { return &__x; }
size_type max_size() const throw() { return size_t(-1) / sizeof(_Tp); }
pointer allocate(size_type __n, const void* _p= 0)
{
#ifdef HAVE_MM_MALLOC_H
_Tp * ptr = (_Tp *) _mm_malloc(__n*sizeof(_Tp),128);
#else
_Tp * ptr = (_Tp *) memalign(128,__n*sizeof(_Tp));
#endif
_Tp tmp;
#ifdef GRID_NUMA
#pragma omp parallel for schedule(static)
for(int i=0;i<__n;i++){
ptr[i]=tmp;
}
#endif
return ptr;
}
void deallocate(pointer __p, size_type) {
#ifdef HAVE_MM_MALLOC_H
_mm_free((void *)__p);
#else
free((void *)__p);
#endif
}
void construct(pointer __p, const _Tp& __val) { };
void construct(pointer __p) { };
void destroy(pointer __p) { };
};
template<typename _Tp> inline bool operator==(const alignedAllocator<_Tp>&, const alignedAllocator<_Tp>&){ return true; }
template<typename _Tp> inline bool operator!=(const alignedAllocator<_Tp>&, const alignedAllocator<_Tp>&){ return false; }
//////////////////////////////////////////////////////////////////////////////////////////
// MPI3 : comms must use shm region
// SHMEM: comms must use symmetric heap
//////////////////////////////////////////////////////////////////////////////////////////
#ifdef GRID_COMMS_SHMEM
_Tp *ptr = (_Tp *) shmem_align(__n*sizeof(_Tp),64);
extern "C" {
#include <mpp/shmem.h>
extern void * shmem_align(size_t, size_t);
extern void shmem_free(void *);
}
#define PARANOID_SYMMETRIC_HEAP
#endif
template<typename _Tp>
class commAllocator {
public:
typedef std::size_t size_type;
typedef std::ptrdiff_t difference_type;
typedef _Tp* pointer;
typedef const _Tp* const_pointer;
typedef _Tp& reference;
typedef const _Tp& const_reference;
typedef _Tp value_type;
template<typename _Tp1> struct rebind { typedef commAllocator<_Tp1> other; };
commAllocator() throw() { }
commAllocator(const commAllocator&) throw() { }
template<typename _Tp1> commAllocator(const commAllocator<_Tp1>&) throw() { }
~commAllocator() throw() { }
pointer address(reference __x) const { return &__x; }
size_type max_size() const throw() { return size_t(-1) / sizeof(_Tp); }
#ifdef GRID_COMMS_SHMEM
pointer allocate(size_type __n, const void* _p= 0)
{
#ifdef CRAY
_Tp *ptr = (_Tp *) shmem_align(__n*sizeof(_Tp),64);
#else
_Tp *ptr = (_Tp *) shmem_align(64,__n*sizeof(_Tp));
#endif
#ifdef PARANOID_SYMMETRIC_HEAP
static void * bcast;
static long psync[_SHMEM_REDUCE_SYNC_SIZE];
@ -96,55 +145,47 @@ public:
if ( bcast != ptr ) {
std::printf("inconsistent alloc pe %d %lx %lx \n",shmem_my_pe(),bcast,ptr);std::fflush(stdout);
BACKTRACEFILE();
// BACKTRACEFILE();
exit(0);
}
assert( bcast == (void *) ptr);
#endif
return ptr;
}
void deallocate(pointer __p, size_type) {
shmem_free((void *)__p);
}
#else
pointer allocate(size_type __n, const void* _p= 0)
{
#ifdef HAVE_MM_MALLOC_H
_Tp * ptr = (_Tp *) _mm_malloc(__n*sizeof(_Tp),128);
#else
_Tp * ptr = (_Tp *) memalign(128,__n*sizeof(_Tp));
#endif
#endif
_Tp tmp;
#undef FIRST_TOUCH_OPTIMISE
#ifdef FIRST_TOUCH_OPTIMISE
#pragma omp parallel for
for(int i=0;i<__n;i++){
ptr[i]=tmp;
}
#endif
return ptr;
}
void deallocate(pointer __p, size_type) {
#ifdef GRID_COMMS_SHMEM
shmem_free((void *)__p);
#else
#ifdef HAVE_MM_MALLOC_H
_mm_free((void *)__p);
#else
free((void *)__p);
#endif
#endif
}
#endif
void construct(pointer __p, const _Tp& __val) { };
void construct(pointer __p) { };
void destroy(pointer __p) { };
};
template<typename _Tp> inline bool operator==(const commAllocator<_Tp>&, const commAllocator<_Tp>&){ return true; }
template<typename _Tp> inline bool operator!=(const commAllocator<_Tp>&, const commAllocator<_Tp>&){ return false; }
template<typename _Tp> inline bool
operator==(const alignedAllocator<_Tp>&, const alignedAllocator<_Tp>&){ return true; }
template<typename _Tp> inline bool
operator!=(const alignedAllocator<_Tp>&, const alignedAllocator<_Tp>&){ return false; }
////////////////////////////////////////////////////////////////////////////////
// Template typedefs
////////////////////////////////////////////////////////////////////////////////
template<class T> using Vector = std::vector<T,alignedAllocator<T> >;
template<class T> using commVector = std::vector<T,commAllocator<T> >;
template<class T> using Matrix = std::vector<std::vector<T,alignedAllocator<T> > >;
}; // namespace Grid
#endif

8
lib/Cshift.h
View File

@ -38,6 +38,14 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
#include <Grid/cshift/Cshift_mpi.h>
#endif
#ifdef GRID_COMMS_MPI3
#include <Grid/cshift/Cshift_mpi.h>
#endif
#ifdef GRID_COMMS_MPI3L
#include <Grid/cshift/Cshift_mpi.h>
#endif
#ifdef GRID_COMMS_SHMEM
#include <Grid/cshift/Cshift_mpi.h> // uses same implementation of communicator
#endif

284
lib/FFT.h
View File

@ -29,9 +29,15 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
#ifndef _GRID_FFT_H_
#define _GRID_FFT_H_
#ifdef HAVE_FFTW
#ifdef HAVE_FFTW
#ifdef USE_MKL
#include <fftw/fftw3.h>
#else
#include <fftw3.h>
#endif
#endif
namespace Grid {
template<class scalar> struct FFTW { };
@ -98,179 +104,199 @@ namespace Grid {
#define FFTW_BACKWARD (+1)
#endif
class FFT {
class FFT {
private:
GridCartesian *vgrid;
GridCartesian *sgrid;
int Nd;
double flops;
double flops_call;
uint64_t usec;
std::vector<int> dimensions;
std::vector<int> processors;
std::vector<int> processor_coor;
public:
static const int forward=FFTW_FORWARD;
static const int backward=FFTW_BACKWARD;
double Flops(void) {return flops;}
double MFlops(void) {return flops/usec;}
double USec(void) {return (double)usec;}
FFT ( GridCartesian * grid ) :
vgrid(grid),
Nd(grid->_ndimension),
dimensions(grid->_fdimensions),
processors(grid->_processors),
processor_coor(grid->_processor_coor)
FFT ( GridCartesian * grid ) :
vgrid(grid),
Nd(grid->_ndimension),
dimensions(grid->_fdimensions),
processors(grid->_processors),
processor_coor(grid->_processor_coor)
{
flops=0;
usec =0;
std::vector<int> layout(Nd,1);
sgrid = new GridCartesian(dimensions,layout,processors);
};
~FFT ( void) {
delete sgrid;
~FFT ( void) {
delete sgrid;
}
template<class vobj>
void FFT_dim(Lattice<vobj> &result,const Lattice<vobj> &source,int dim, int inverse){
void FFT_dim_mask(Lattice<vobj> &result,const Lattice<vobj> &source,std::vector<int> mask,int sign){
conformable(result._grid,vgrid);
conformable(source._grid,vgrid);
Lattice<vobj> tmp(vgrid);
tmp = source;
for(int d=0;d<Nd;d++){
if( mask[d] ) {
FFT_dim(result,tmp,d,sign);
tmp=result;
}
}
}
template<class vobj>
void FFT_all_dim(Lattice<vobj> &result,const Lattice<vobj> &source,int sign){
std::vector<int> mask(Nd,1);
FFT_dim_mask(result,source,mask,sign);
}
template<class vobj>
void FFT_dim(Lattice<vobj> &result,const Lattice<vobj> &source,int dim, int sign){
#ifndef HAVE_FFTW
assert(0);
#else
conformable(result._grid,vgrid);
conformable(source._grid,vgrid);
int L = vgrid->_ldimensions[dim];
int G = vgrid->_fdimensions[dim];
std::vector<int> layout(Nd,1);
std::vector<int> pencil_gd(vgrid->_fdimensions);
pencil_gd[dim] = G*processors[dim];
pencil_gd[dim] = G*processors[dim];
// Pencil global vol LxLxGxLxL per node
GridCartesian pencil_g(pencil_gd,layout,processors);
// Construct pencils
typedef typename vobj::scalar_object sobj;
typedef typename sobj::scalar_type scalar;
Lattice<sobj> pgbuf(&pencil_g);
Lattice<vobj> ssource(vgrid); ssource =source;
Lattice<sobj> pgsource(&pencil_g);
Lattice<sobj> pgresult(&pencil_g); pgresult=zero;
#ifndef HAVE_FFTW
assert(0);
#else
typedef typename FFTW<scalar>::FFTW_scalar FFTW_scalar;
typedef typename FFTW<scalar>::FFTW_plan FFTW_plan;
{
int Ncomp = sizeof(sobj)/sizeof(scalar);
int Nlow = 1;
for(int d=0;d<dim;d++){
Nlow*=vgrid->_ldimensions[d];
}
int rank = 1; /* 1d transforms */
int n[] = {G}; /* 1d transforms of length G */
int howmany = Ncomp;
int odist,idist,istride,ostride;
idist = odist = 1; /* Distance between consecutive FT's */
istride = ostride = Ncomp*Nlow; /* distance between two elements in the same FT */
int *inembed = n, *onembed = n;
int sign = FFTW_FORWARD;
if (inverse) sign = FFTW_BACKWARD;
FFTW_plan p;
{
FFTW_scalar *in = (FFTW_scalar *)&pgsource._odata[0];
FFTW_scalar *out= (FFTW_scalar *)&pgresult._odata[0];
p = FFTW<scalar>::fftw_plan_many_dft(rank,n,howmany,
in,inembed,
istride,idist,
out,onembed,
ostride, odist,
sign,FFTW_ESTIMATE);
}
double add,mul,fma;
FFTW<scalar>::fftw_flops(p,&add,&mul,&fma);
flops_call = add+mul+2.0*fma;
GridStopWatch timer;
// Barrel shift and collect global pencil
for(int p=0;p<processors[dim];p++) {
for(int idx=0;idx<sgrid->lSites();idx++) {
std::vector<int> lcoor(Nd);
sgrid->LocalIndexToLocalCoor(idx,lcoor);
sobj s;
peekLocalSite(s,ssource,lcoor);
lcoor[dim]+=p*L;
pokeLocalSite(s,pgsource,lcoor);
}
ssource = Cshift(ssource,dim,L);
}
// Loop over orthog coords
int NN=pencil_g.lSites();
GridStopWatch Timer;
Timer.Start();
PARALLEL_FOR_LOOP
for(int idx=0;idx<NN;idx++) {
std::vector<int> lcoor(Nd);
pencil_g.LocalIndexToLocalCoor(idx,lcoor);
if ( lcoor[dim] == 0 ) { // restricts loop to plane at lcoor[dim]==0
FFTW_scalar *in = (FFTW_scalar *)&pgsource._odata[idx];
FFTW_scalar *out= (FFTW_scalar *)&pgresult._odata[idx];
FFTW<scalar>::fftw_execute_dft(p,in,out);
}
}
Timer.Stop();
usec += Timer.useconds();
flops+= flops_call*NN;
int pc = processor_coor[dim];
for(int idx=0;idx<sgrid->lSites();idx++) {
std::vector<int> lcoor(Nd);
sgrid->LocalIndexToLocalCoor(idx,lcoor);
std::vector<int> gcoor = lcoor;
// extract the result
sobj s;
gcoor[dim] = lcoor[dim]+L*pc;
peekLocalSite(s,pgresult,gcoor);
pokeLocalSite(s,result,lcoor);
}
FFTW<scalar>::fftw_destroy_plan(p);
int Ncomp = sizeof(sobj)/sizeof(scalar);
int Nlow = 1;
for(int d=0;d<dim;d++){
Nlow*=vgrid->_ldimensions[d];
}
int rank = 1; /* 1d transforms */
int n[] = {G}; /* 1d transforms of length G */
int howmany = Ncomp;
int odist,idist,istride,ostride;
idist = odist = 1; /* Distance between consecutive FT's */
istride = ostride = Ncomp*Nlow; /* distance between two elements in the same FT */
int *inembed = n, *onembed = n;
scalar div;
if ( sign == backward ) div = 1.0/G;
else if ( sign == forward ) div = 1.0;
else assert(0);
FFTW_plan p;
{
FFTW_scalar *in = (FFTW_scalar *)&pgbuf._odata[0];
FFTW_scalar *out= (FFTW_scalar *)&pgbuf._odata[0];
p = FFTW<scalar>::fftw_plan_many_dft(rank,n,howmany,
in,inembed,
istride,idist,
out,onembed,
ostride, odist,
sign,FFTW_ESTIMATE);
}
// Barrel shift and collect global pencil
std::vector<int> lcoor(Nd), gcoor(Nd);
result = source;
for(int p=0;p<processors[dim];p++) {
PARALLEL_REGION
{
std::vector<int> cbuf(Nd);
sobj s;
PARALLEL_FOR_LOOP_INTERN
for(int idx=0;idx<sgrid->lSites();idx++) {
sgrid->LocalIndexToLocalCoor(idx,cbuf);
peekLocalSite(s,result,cbuf);
cbuf[dim]+=p*L;
pokeLocalSite(s,pgbuf,cbuf);
}
}
result = Cshift(result,dim,L);
}
// Loop over orthog coords
int NN=pencil_g.lSites();
GridStopWatch timer;
timer.Start();
PARALLEL_REGION
{
std::vector<int> cbuf(Nd);
PARALLEL_FOR_LOOP_INTERN
for(int idx=0;idx<NN;idx++) {
pencil_g.LocalIndexToLocalCoor(idx, cbuf);
if ( cbuf[dim] == 0 ) { // restricts loop to plane at lcoor[dim]==0
FFTW_scalar *in = (FFTW_scalar *)&pgbuf._odata[idx];
FFTW_scalar *out= (FFTW_scalar *)&pgbuf._odata[idx];
FFTW<scalar>::fftw_execute_dft(p,in,out);
}
}
}
timer.Stop();
// performance counting
double add,mul,fma;
FFTW<scalar>::fftw_flops(p,&add,&mul,&fma);
flops_call = add+mul+2.0*fma;
usec += timer.useconds();
flops+= flops_call*NN;
// writing out result
int pc = processor_coor[dim];
PARALLEL_REGION
{
std::vector<int> clbuf(Nd), cgbuf(Nd);
sobj s;
PARALLEL_FOR_LOOP_INTERN
for(int idx=0;idx<sgrid->lSites();idx++) {
sgrid->LocalIndexToLocalCoor(idx,clbuf);
cgbuf = clbuf;
cgbuf[dim] = clbuf[dim]+L*pc;
peekLocalSite(s,pgbuf,cgbuf);
s = s * div;
pokeLocalSite(s,result,clbuf);
}
}
// destroying plan
FFTW<scalar>::fftw_destroy_plan(p);
#endif
}
};
}
#endif

5
lib/Grid.h
View File

@ -77,11 +77,10 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
#include <Grid/Stencil.h>
#include <Grid/Algorithms.h>
#include <Grid/parallelIO/BinaryIO.h>
#include <Grid/qcd/QCD.h>
#include <Grid/parallelIO/NerscIO.h>
#include <Grid/FFT.h>
#include <Grid/qcd/QCD.h>
#include <Grid/parallelIO/NerscIO.h>
#include <Grid/qcd/hmc/NerscCheckpointer.h>
#include <Grid/qcd/hmc/HmcRunner.h>

205
lib/Init.cc
View File

@ -44,9 +44,33 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
#include <Grid.h>
#include <algorithm>
#include <iterator>
#include <cstdlib>
#include <memory>
#include <fenv.h>
#ifdef __APPLE__
static int
feenableexcept (unsigned int excepts)
{
static fenv_t fenv;
unsigned int new_excepts = excepts & FE_ALL_EXCEPT,
old_excepts; // previous masks
if ( fegetenv (&fenv) ) return -1;
old_excepts = fenv.__control & FE_ALL_EXCEPT;
// unmask
fenv.__control &= ~new_excepts;
fenv.__mxcsr &= ~(new_excepts << 7);
return ( fesetenv (&fenv) ? -1 : old_excepts );
}
#endif
namespace Grid {
//////////////////////////////////////////////////////
// Convenience functions to access stadard command line arg
// driven parallelism controls
@ -123,6 +147,13 @@ void GridCmdOptionIntVector(std::string &str,std::vector<int> & vec)
return;
}
void GridCmdOptionInt(std::string &str,int & val)
{
std::stringstream ss(str);
ss>>val;
return;
}
void GridParseLayout(char **argv,int argc,
std::vector<int> &latt,
@ -153,14 +184,12 @@ void GridParseLayout(char **argv,int argc,
assert(ompthreads.size()==1);
GridThread::SetThreads(ompthreads[0]);
}
if( GridCmdOptionExists(argv,argv+argc,"--cores") ){
std::vector<int> cores(0);
int cores;
arg= GridCmdOptionPayload(argv,argv+argc,"--cores");
GridCmdOptionIntVector(arg,cores);
GridThread::SetCores(cores[0]);
GridCmdOptionInt(arg,cores);
GridThread::SetCores(cores);
}
}
std::string GridCmdVectorIntToString(const std::vector<int> & vec){
@ -169,33 +198,40 @@ std::string GridCmdVectorIntToString(const std::vector<int> & vec){
return oss.str();
}
/////////////////////////////////////////////////////////
//
// Reinit guard
/////////////////////////////////////////////////////////
static int Grid_is_initialised = 0;
void Grid_init(int *argc,char ***argv)
{
CartesianCommunicator::Init(argc,argv);
// Parse command line args.
GridLogger::StopWatch.Start();
std::string arg;
////////////////////////////////////
// Shared memory block size
////////////////////////////////////
if( GridCmdOptionExists(*argv,*argv+*argc,"--shm") ){
int MB;
arg= GridCmdOptionPayload(*argv,*argv+*argc,"--shm");
GridCmdOptionInt(arg,MB);
CartesianCommunicator::MAX_MPI_SHM_BYTES = MB*1024*1024;
}
CartesianCommunicator::Init(argc,argv);
////////////////////////////////////
// Logging
////////////////////////////////////
std::vector<std::string> logstreams;
std::string defaultLog("Error,Warning,Message,Performance");
GridCmdOptionCSL(defaultLog,logstreams);
GridLogConfigure(logstreams);
if( GridCmdOptionExists(*argv,*argv+*argc,"--help") ){
std::cout<<GridLogMessage<<"--help : this message"<<std::endl;
std::cout<<GridLogMessage<<"--debug-signals : catch sigsegv and print a blame report"<<std::endl;
std::cout<<GridLogMessage<<"--debug-stdout : print stdout from EVERY node"<<std::endl;
std::cout<<GridLogMessage<<"--decomposition : report on default omp,mpi and simd decomposition"<<std::endl;
std::cout<<GridLogMessage<<"--mpi n.n.n.n : default MPI decomposition"<<std::endl;
std::cout<<GridLogMessage<<"--threads n : default number of OMP threads"<<std::endl;
std::cout<<GridLogMessage<<"--grid n.n.n.n : default Grid size"<<std::endl;
std::cout<<GridLogMessage<<"--log list : comma separted list of streams from Error,Warning,Message,Performance,Iterative,Integrator,Debug,Colours"<<std::endl;
exit(EXIT_SUCCESS);
if( !GridCmdOptionExists(*argv,*argv+*argc,"--debug-stdout") ){
Grid_quiesce_nodes();
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--log") ){
@ -204,35 +240,39 @@ void Grid_init(int *argc,char ***argv)
GridLogConfigure(logstreams);
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--debug-signals") ){
Grid_debug_handler_init();
}
if( !GridCmdOptionExists(*argv,*argv+*argc,"--debug-stdout") ){
Grid_quiesce_nodes();
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--dslash-opt") ){
QCD::WilsonKernelsStatic::HandOpt=1;
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--lebesgue") ){
LebesgueOrder::UseLebesgueOrder=1;
////////////////////////////////////
// Help message
////////////////////////////////////
if( GridCmdOptionExists(*argv,*argv+*argc,"--help") ){
std::cout<<GridLogMessage<<" --help : this message"<<std::endl;
std::cout<<GridLogMessage<<std::endl;
std::cout<<GridLogMessage<<"Geometry:"<<std::endl;
std::cout<<GridLogMessage<<" --mpi n.n.n.n : default MPI decomposition"<<std::endl;
std::cout<<GridLogMessage<<" --threads n : default number of OMP threads"<<std::endl;
std::cout<<GridLogMessage<<" --grid n.n.n.n : default Grid size"<<std::endl;
std::cout<<GridLogMessage<<" --shm M : allocate M megabytes of shared memory for comms"<<std::endl;
std::cout<<GridLogMessage<<std::endl;
std::cout<<GridLogMessage<<"Verbose and debug:"<<std::endl;
std::cout<<GridLogMessage<<" --log list : comma separted list of streams from Error,Warning,Message,Performance,Iterative,Integrator,Debug,Colours"<<std::endl;
std::cout<<GridLogMessage<<" --decomposition : report on default omp,mpi and simd decomposition"<<std::endl;
std::cout<<GridLogMessage<<" --debug-signals : catch sigsegv and print a blame report"<<std::endl;
std::cout<<GridLogMessage<<" --debug-stdout : print stdout from EVERY node"<<std::endl;
std::cout<<GridLogMessage<<" --notimestamp : suppress millisecond resolution stamps"<<std::endl;
std::cout<<GridLogMessage<<std::endl;
std::cout<<GridLogMessage<<"Performance:"<<std::endl;
std::cout<<GridLogMessage<<" --dslash-generic: Wilson kernel for generic Nc"<<std::endl;
std::cout<<GridLogMessage<<" --dslash-unroll : Wilson kernel for Nc=3"<<std::endl;
std::cout<<GridLogMessage<<" --dslash-asm : Wilson kernel for AVX512"<<std::endl;
std::cout<<GridLogMessage<<" --lebesgue : Cache oblivious Lebesgue curve/Morton order/Z-graph stencil looping"<<std::endl;
std::cout<<GridLogMessage<<" --cacheblocking n.m.o.p : Hypercuboidal cache blocking"<<std::endl;
std::cout<<GridLogMessage<<std::endl;
exit(EXIT_SUCCESS);
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--cacheblocking") ){
arg= GridCmdOptionPayload(*argv,*argv+*argc,"--cacheblocking");
GridCmdOptionIntVector(arg,LebesgueOrder::Block);
}
GridParseLayout(*argv,*argc,
Grid_default_latt,
Grid_default_mpi);
if( GridCmdOptionExists(*argv,*argv+*argc,"--decomposition") ){
std::cout<<GridLogMessage<<"Grid Decomposition\n";
std::cout<<GridLogMessage<<"\tOpenMP threads : "<<GridThread::GetThreads()<<std::endl;
std::cout<<GridLogMessage<<"\tMPI tasks : "<<GridCmdVectorIntToString(GridDefaultMpi())<<std::endl;
std::cout<<GridLogMessage<<"\tvRealF : "<<sizeof(vRealF)*8 <<"bits ; " <<GridCmdVectorIntToString(GridDefaultSimd(4,vRealF::Nsimd()))<<std::endl;
std::cout<<GridLogMessage<<"\tvRealD : "<<sizeof(vRealD)*8 <<"bits ; " <<GridCmdVectorIntToString(GridDefaultSimd(4,vRealD::Nsimd()))<<std::endl;
std::cout<<GridLogMessage<<"\tvComplexF : "<<sizeof(vComplexF)*8 <<"bits ; " <<GridCmdVectorIntToString(GridDefaultSimd(4,vComplexF::Nsimd()))<<std::endl;
std::cout<<GridLogMessage<<"\tvComplexD : "<<sizeof(vComplexD)*8 <<"bits ; " <<GridCmdVectorIntToString(GridDefaultSimd(4,vComplexD::Nsimd()))<<std::endl;
}
////////////////////////////////////
// Banner
////////////////////////////////////
std::string COL_RED = GridLogColours.colour["RED"];
std::string COL_PURPLE = GridLogColours.colour["PURPLE"];
@ -241,20 +281,19 @@ void Grid_init(int *argc,char ***argv)
std::string COL_BLUE = GridLogColours.colour["BLUE"];
std::string COL_YELLOW = GridLogColours.colour["YELLOW"];
std::string COL_BACKGROUND = GridLogColours.colour["NORMAL"];
std::cout <<std::endl;
std::cout <<COL_RED << "__|__|__|__|__"<< "|__|__|_"<<COL_PURPLE<<"_|__|__|"<< "__|__|__|__|__"<<std::endl;
std::cout <<COL_RED << "__|__|__|__|__"<< "|__|__|_"<<COL_PURPLE<<"_|__|__|"<< "__|__|__|__|__"<<std::endl;
std::cout <<COL_RED << "__|__| | | "<< "| | | "<<COL_PURPLE<<" | | |"<< " | | | _|__"<<std::endl;
std::cout <<COL_RED << "__|__ "<< " "<<COL_PURPLE<<" "<< " _|__"<<std::endl;
std::cout <<COL_RED << "__|_ | | | "<< "| | | "<<COL_PURPLE<<" | | |"<< " | | | _|__"<<std::endl;
std::cout <<COL_RED << "__|_ "<< " "<<COL_PURPLE<<" "<< " _|__"<<std::endl;
std::cout <<COL_RED << "__|_ "<<COL_GREEN<<" GGGG "<<COL_RED<<" RRRR "<<COL_BLUE <<" III "<<COL_PURPLE<<"DDDD "<<COL_PURPLE<<" _|__"<<std::endl;
std::cout <<COL_RED << "__|_ "<<COL_GREEN<<"G "<<COL_RED<<" R R "<<COL_BLUE <<" I "<<COL_PURPLE<<"D D "<<COL_PURPLE<<" _|__"<<std::endl;
std::cout <<COL_RED << "__|_ "<<COL_GREEN<<"G "<<COL_RED<<" R R "<<COL_BLUE <<" I "<<COL_PURPLE<<"D D"<<COL_PURPLE<<" _|__"<<std::endl;
std::cout <<COL_BLUE << "__|_ "<<COL_GREEN<<"G GG "<<COL_RED<<" RRRR "<<COL_BLUE <<" I "<<COL_PURPLE<<"D D"<<COL_GREEN <<" _|__"<<std::endl;
std::cout <<COL_BLUE << "__|_ "<<COL_GREEN<<"G G "<<COL_RED<<" R R "<<COL_BLUE <<" I "<<COL_PURPLE<<"D D "<<COL_GREEN <<" _|__"<<std::endl;
std::cout <<COL_BLUE << "__|_ "<<COL_GREEN<<" GGGG "<<COL_RED<<" R R "<<COL_BLUE <<" III "<<COL_PURPLE<<"DDDD "<<COL_GREEN <<" _|__"<<std::endl;
std::cout <<COL_BLUE << "__|__ "<< " "<<COL_GREEN <<" "<< " _|__"<<std::endl;
std::cout <<COL_BLUE << "__|_ "<< " "<<COL_GREEN <<" "<< " _|__"<<std::endl;
std::cout <<COL_BLUE << "__|__|__|__|__"<< "|__|__|_"<<COL_GREEN <<"_|__|__|"<< "__|__|__|__|__"<<std::endl;
std::cout <<COL_BLUE << "__|__|__|__|__"<< "|__|__|_"<<COL_GREEN <<"_|__|__|"<< "__|__|__|__|__"<<std::endl;
std::cout <<COL_BLUE << " | | | | "<< "| | | "<<COL_GREEN <<" | | |"<< " | | | | "<<std::endl;
@ -274,12 +313,63 @@ void Grid_init(int *argc,char ***argv)
std::cout << "GNU General Public License for more details."<<std::endl;
std::cout << COL_BACKGROUND <<std::endl;
std::cout << std::endl;
////////////////////////////////////
// Debug and performance options
////////////////////////////////////
if( GridCmdOptionExists(*argv,*argv+*argc,"--debug-signals") ){
Grid_debug_handler_init();
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--dslash-unroll") ){
QCD::WilsonKernelsStatic::Opt=QCD::WilsonKernelsStatic::OptHandUnroll;
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--dslash-asm") ){
QCD::WilsonKernelsStatic::Opt=QCD::WilsonKernelsStatic::OptInlineAsm;
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--dslash-generic") ){
QCD::WilsonKernelsStatic::Opt=QCD::WilsonKernelsStatic::OptGeneric;
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--lebesgue") ){
LebesgueOrder::UseLebesgueOrder=1;
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--cacheblocking") ){
arg= GridCmdOptionPayload(*argv,*argv+*argc,"--cacheblocking");
GridCmdOptionIntVector(arg,LebesgueOrder::Block);
}
if( GridCmdOptionExists(*argv,*argv+*argc,"--notimestamp") ){
GridLogTimestamp(0);
} else {
GridLogTimestamp(1);
}
GridParseLayout(*argv,*argc,
Grid_default_latt,
Grid_default_mpi);
std::cout << GridLogMessage << "Requesting "<< CartesianCommunicator::MAX_MPI_SHM_BYTES <<" byte stencil comms buffers "<<std::endl;
if( GridCmdOptionExists(*argv,*argv+*argc,"--decomposition") ){
std::cout<<GridLogMessage<<"Grid Decomposition\n";
std::cout<<GridLogMessage<<"\tOpenMP threads : "<<GridThread::GetThreads()<<std::endl;
std::cout<<GridLogMessage<<"\tMPI tasks : "<<GridCmdVectorIntToString(GridDefaultMpi())<<std::endl;
std::cout<<GridLogMessage<<"\tvRealF : "<<sizeof(vRealF)*8 <<"bits ; " <<GridCmdVectorIntToString(GridDefaultSimd(4,vRealF::Nsimd()))<<std::endl;
std::cout<<GridLogMessage<<"\tvRealD : "<<sizeof(vRealD)*8 <<"bits ; " <<GridCmdVectorIntToString(GridDefaultSimd(4,vRealD::Nsimd()))<<std::endl;
std::cout<<GridLogMessage<<"\tvComplexF : "<<sizeof(vComplexF)*8 <<"bits ; " <<GridCmdVectorIntToString(GridDefaultSimd(4,vComplexF::Nsimd()))<<std::endl;
std::cout<<GridLogMessage<<"\tvComplexD : "<<sizeof(vComplexD)*8 <<"bits ; " <<GridCmdVectorIntToString(GridDefaultSimd(4,vComplexD::Nsimd()))<<std::endl;
}
Grid_is_initialised = 1;
}
void Grid_finalize(void)
{
#ifdef GRID_COMMS_MPI
#if defined (GRID_COMMS_MPI) || defined (GRID_COMMS_MPI3)
MPI_Finalize();
Grid_unquiesce_nodes();
#endif
@ -326,10 +416,7 @@ void Grid_sa_signal_handler(int sig,siginfo_t *si,void * ptr)
exit(0);
return;
};
#ifdef GRID_FPE
#define _GNU_SOURCE
#include <fenv.h>
#endif
void Grid_debug_handler_init(void)
{
struct sigaction sa,osa;
@ -338,9 +425,9 @@ void Grid_debug_handler_init(void)
sa.sa_flags = SA_SIGINFO;
sigaction(SIGSEGV,&sa,NULL);
sigaction(SIGTRAP,&sa,NULL);
#ifdef GRID_FPE
feenableexcept( FE_INVALID|FE_OVERFLOW|FE_DIVBYZERO);
sigaction(SIGFPE,&sa,NULL);
#endif
}
}

3
lib/Init.h
View File

@ -33,6 +33,7 @@ namespace Grid {
void Grid_init(int *argc,char ***argv);
void Grid_finalize(void);
// internal, controled with --handle
void Grid_sa_signal_handler(int sig,siginfo_t *si,void * ptr);
void Grid_debug_handler_init(void);
@ -44,6 +45,7 @@ namespace Grid {
const std::vector<int> &GridDefaultMpi(void);
const int &GridThreads(void) ;
void GridSetThreads(int t) ;
void GridLogTimestamp(int);
// Common parsing chores
std::string GridCmdOptionPayload(char ** begin, char ** end, const std::string & option);
@ -52,6 +54,7 @@ namespace Grid {
void GridCmdOptionCSL(std::string str,std::vector<std::string> & vec);
void GridCmdOptionIntVector(std::string &str,std::vector<int> & vec);
void GridParseLayout(char **argv,int argc,
std::vector<int> &latt,
std::vector<int> &simd,

22
lib/Log.cc
View File

@ -31,11 +31,31 @@ directory
/* END LEGAL */
#include <Grid.h>
#include <cxxabi.h>
namespace Grid {
std::string demangle(const char* name) {
int status = -4; // some arbitrary value to eliminate the compiler warning
// enable c++11 by passing the flag -std=c++11 to g++
std::unique_ptr<char, void(*)(void*)> res {
abi::__cxa_demangle(name, NULL, NULL, &status),
std::free
};
return (status==0) ? res.get() : name ;
}
GridStopWatch Logger::StopWatch;
int Logger::timestamp;
std::ostream Logger::devnull(0);
void GridLogTimestamp(int on){
Logger::Timestamp(on);
}
Colours GridLogColours(0);
GridLogger GridLogError(1, "Error", GridLogColours, "RED");
GridLogger GridLogWarning(1, "Warning", GridLogColours, "YELLOW");
@ -73,7 +93,7 @@ void GridLogConfigure(std::vector<std::string> &logstreams) {
////////////////////////////////////////////////////////////
void Grid_quiesce_nodes(void) {
int me = 0;
#ifdef GRID_COMMS_MPI
#if defined(GRID_COMMS_MPI) || defined(GRID_COMMS_MPI3) || defined(GRID_COMMS_MPI3L)
MPI_Comm_rank(MPI_COMM_WORLD, &me);
#endif
#ifdef GRID_COMMS_SHMEM

62
lib/Log.h
View File

@ -37,10 +37,11 @@
#include <execinfo.h>
#endif
namespace Grid {
namespace Grid {
//////////////////////////////////////////////////////////////////////////////////////////////////
// Dress the output; use std::chrono for time stamping via the StopWatch class
int Rank(void); // used for early stage debug before library init
//////////////////////////////////////////////////////////////////////////////////////////////////
class Colours{
@ -55,7 +56,6 @@ public:
void Active(bool activate){
is_active=activate;
if (is_active){
colour["BLACK"] ="\033[30m";
colour["RED"] ="\033[31m";
@ -66,21 +66,18 @@ public:
colour["CYAN"] ="\033[36m";
colour["WHITE"] ="\033[37m";
colour["NORMAL"] ="\033[0;39m";
} else {
colour["BLACK"] ="";
colour["RED"] ="";
colour["GREEN"] ="";
colour["YELLOW"]="";
colour["BLUE"] ="";
colour["PURPLE"]="";
colour["CYAN"] ="";
colour["WHITE"] ="";
colour["NORMAL"]="";
}
};
} else {
colour["BLACK"] ="";
colour["RED"] ="";
colour["GREEN"] ="";
colour["YELLOW"]="";
colour["BLUE"] ="";
colour["PURPLE"]="";
colour["CYAN"] ="";
colour["WHITE"] ="";
colour["NORMAL"]="";
}
};
};
@ -88,6 +85,7 @@ class Logger {
protected:
Colours &Painter;
int active;
static int timestamp;
std::string name, topName;
std::string COLOUR;
@ -99,25 +97,28 @@ public:
std::string evidence() {return Painter.colour["YELLOW"];}
std::string colour() {return Painter.colour[COLOUR];}
Logger(std::string topNm, int on, std::string nm, Colours& col_class, std::string col)
: active(on),
name(nm),
topName(topNm),
Painter(col_class),
COLOUR(col){} ;
Logger(std::string topNm, int on, std::string nm, Colours& col_class, std::string col) : active(on),
name(nm),
topName(topNm),
Painter(col_class),
COLOUR(col) {} ;
void Active(int on) {active = on;};
int isActive(void) {return active;};
static void Timestamp(int on) {timestamp = on;};
friend std::ostream& operator<< (std::ostream& stream, Logger& log){
if ( log.active ) {
StopWatch.Stop();
GridTime now = StopWatch.Elapsed();
StopWatch.Start();
stream << log.background()<< log.topName << log.background()<< " : ";
stream << log.colour() <<std::setw(14) << std::left << log.name << log.background() << " : ";
stream << log.evidence()<< now << log.background() << " : " << log.colour();
if ( log.timestamp ) {
StopWatch.Stop();
GridTime now = StopWatch.Elapsed();
StopWatch.Start();
stream << log.evidence()<< now << log.background() << " : " ;
}
stream << log.colour();
return stream;
} else {
return devnull;
@ -143,13 +144,14 @@ extern GridLogger GridLogIterative ;
extern GridLogger GridLogIntegrator ;
extern Colours GridLogColours;
std::string demangle(const char* name) ;
#define _NBACKTRACE (256)
extern void * Grid_backtrace_buffer[_NBACKTRACE];
#define BACKTRACEFILE() {\
char string[20]; \
std::sprintf(string,"backtrace.%d",Rank()); \
std::sprintf(string,"backtrace.%d",CartesianCommunicator::RankWorld()); \
std::FILE * fp = std::fopen(string,"w"); \
BACKTRACEFP(fp)\
std::fclose(fp); \
@ -161,7 +163,7 @@ std::fclose(fp); \
int symbols = backtrace (Grid_backtrace_buffer,_NBACKTRACE);\
char **strings = backtrace_symbols(Grid_backtrace_buffer,symbols);\
for (int i = 0; i < symbols; i++){\
std::fprintf (fp,"BackTrace Strings: %d %s\n",i, strings[i]); std::fflush(fp); \
std::fprintf (fp,"BackTrace Strings: %d %s\n",i, demangle(strings[i]).c_str()); std::fflush(fp); \
}\
}
#else

13
lib/Makefile.am
View File

@ -1,14 +1,27 @@
extra_sources=
if BUILD_COMMS_MPI
extra_sources+=communicator/Communicator_mpi.cc
extra_sources+=communicator/Communicator_base.cc
endif
if BUILD_COMMS_MPI3
extra_sources+=communicator/Communicator_mpi3.cc
extra_sources+=communicator/Communicator_base.cc
endif
if BUILD_COMMS_MPI3L
extra_sources+=communicator/Communicator_mpi3_leader.cc
extra_sources+=communicator/Communicator_base.cc
endif
if BUILD_COMMS_SHMEM
extra_sources+=communicator/Communicator_shmem.cc
extra_sources+=communicator/Communicator_base.cc
endif
if BUILD_COMMS_NONE
extra_sources+=communicator/Communicator_none.cc
extra_sources+=communicator/Communicator_base.cc
endif
#

4
lib/PerfCount.h
View File

@ -43,6 +43,9 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
#else
#include <sys/syscall.h>
#endif
#ifdef __x86_64__
#include <x86intrin.h>
#endif
namespace Grid {
@ -86,7 +89,6 @@ inline uint64_t cyclecount(void){
return tmp;
}
#elif defined __x86_64__
#include <x86intrin.h>
inline uint64_t cyclecount(void){
return __rdtsc();
// unsigned int dummy;

12
lib/Simd.h
View File

@ -237,6 +237,18 @@ namespace Grid {
stream<<">";
return stream;
}
inline std::ostream& operator<< (std::ostream& stream, const vInteger &o){
int nn=vInteger::Nsimd();
std::vector<Integer,alignedAllocator<Integer> > buf(nn);
vstore(o,&buf[0]);
stream<<"<";
for(int i=0;i<nn;i++){
stream<<buf[i];
if(i<nn-1) stream<<",";
}
stream<<">";
return stream;
}
}

247
lib/Stat.cc Normal file
View File

@ -0,0 +1,247 @@
#include <Grid.h>
#include <PerfCount.h>
#include <Stat.h>
namespace Grid {
bool PmuStat::pmu_initialized=false;
void PmuStat::init(const char *regname)
{
#ifdef __x86_64__
name = regname;
if (!pmu_initialized)
{
std::cout<<"initialising pmu"<<std::endl;
pmu_initialized = true;
pmu_init();
}
clear();
#endif
}
void PmuStat::clear(void)
{
#ifdef __x86_64__
count = 0;
tregion = 0;
pmc0 = 0;
pmc1 = 0;
inst = 0;
cyc = 0;
ref = 0;
tcycles = 0;
reads = 0;
writes = 0;
#endif
}
void PmuStat::print(void)
{
#ifdef __x86_64__
std::cout <<"Reg "<<std::string(name)<<":\n";
std::cout <<" region "<<tregion<<std::endl;
std::cout <<" cycles "<<tcycles<<std::endl;
std::cout <<" inst "<<inst <<std::endl;
std::cout <<" cyc "<<cyc <<std::endl;
std::cout <<" ref "<<ref <<std::endl;
std::cout <<" pmc0 "<<pmc0 <<std::endl;
std::cout <<" pmc1 "<<pmc1 <<std::endl;
std::cout <<" count "<<count <<std::endl;
std::cout <<" reads "<<reads <<std::endl;
std::cout <<" writes "<<writes <<std::endl;
#endif
}
void PmuStat::start(void)
{
#ifdef __x86_64__
pmu_start();
++count;
xmemctrs(&mrstart, &mwstart);
tstart = __rdtsc();
#endif
}
void PmuStat::enter(int t)
{
#ifdef __x86_64__
counters[0][t] = __rdpmc(0);
counters[1][t] = __rdpmc(1);
counters[2][t] = __rdpmc((1<<30)|0);
counters[3][t] = __rdpmc((1<<30)|1);
counters[4][t] = __rdpmc((1<<30)|2);
counters[5][t] = __rdtsc();
#endif
}
void PmuStat::exit(int t)
{
#ifdef __x86_64__
counters[0][t] = __rdpmc(0) - counters[0][t];
counters[1][t] = __rdpmc(1) - counters[1][t];
counters[2][t] = __rdpmc((1<<30)|0) - counters[2][t];
counters[3][t] = __rdpmc((1<<30)|1) - counters[3][t];
counters[4][t] = __rdpmc((1<<30)|2) - counters[4][t];
counters[5][t] = __rdtsc() - counters[5][t];
#endif
}
void PmuStat::accum(int nthreads)
{
#ifdef __x86_64__
tend = __rdtsc();
xmemctrs(&mrend, &mwend);
pmu_stop();
for (int t = 0; t < nthreads; ++t) {
pmc0 += counters[0][t];
pmc1 += counters[1][t];
inst += counters[2][t];
cyc += counters[3][t];
ref += counters[4][t];
tcycles += counters[5][t];
}
uint64_t region = tend - tstart;
tregion += region;
uint64_t mreads = mrend - mrstart;
reads += mreads;
uint64_t mwrites = mwend - mwstart;
writes += mwrites;
#endif
}
void PmuStat::pmu_fini(void) {}
void PmuStat::pmu_start(void) {};
void PmuStat::pmu_stop(void) {};
void PmuStat::pmu_init(void)
{
#ifdef _KNIGHTS_LANDING_
KNLsetup();
#endif
}
void PmuStat::xmemctrs(uint64_t *mr, uint64_t *mw)
{
#ifdef _KNIGHTS_LANDING_
ctrs c;
KNLreadctrs(c);
uint64_t emr = 0, emw = 0;
for (int i = 0; i < NEDC; ++i)
{
emr += c.edcrd[i];
emw += c.edcwr[i];
}
*mr = emr;
*mw = emw;
#else
*mr = *mw = 0;
#endif
}
#ifdef _KNIGHTS_LANDING_
struct knl_gbl_ PmuStat::gbl;
#define PMU_MEM
void PmuStat::KNLevsetup(const char *ename, int &fd, int event, int umask)
{
char fname[1024];
snprintf(fname, sizeof(fname), "%s/type", ename);
FILE *fp = fopen(fname, "r");
if (fp == 0) {
::printf("open %s", fname);
::exit(0);
}
int type;
int ret = fscanf(fp, "%d", &type);
assert(ret == 1);
fclose(fp);
// std::cout << "Using PMU type "<<type<<" from " << std::string(ename) <<std::endl;
struct perf_event_attr hw = {};
hw.size = sizeof(hw);
hw.type = type;
// see /sys/devices/uncore_*/format/*
// All of the events we are interested in are configured the same way, but
// that isn't always true. Proper code would parse the format files
hw.config = event | (umask << 8);
//hw.read_format = PERF_FORMAT_GROUP;
// unfortunately the above only works within a single PMU; might
// as well just read them one at a time
int cpu = 0;
fd = perf_event_open(&hw, -1, cpu, -1, 0);
if (fd == -1) {
::printf("CPU %d, box %s, event 0x%lx", cpu, ename, hw.config);
::exit(0);
} else {
// std::cout << "event "<<std::string(ename)<<" set up for fd "<<fd<<" hw.config "<<hw.config <<std::endl;
}
}
void PmuStat::KNLsetup(void){
int ret;
char fname[1024];
// MC RPQ inserts and WPQ inserts (reads & writes)
for (int mc = 0; mc < NMC; ++mc)
{
::snprintf(fname, sizeof(fname), "/sys/devices/uncore_imc_%d",mc);
// RPQ Inserts
KNLevsetup(fname, gbl.mc_rd[mc], 0x1, 0x1);
// WPQ Inserts
KNLevsetup(fname, gbl.mc_wr[mc], 0x2, 0x1);
}
// EDC RPQ inserts and WPQ inserts
for (int edc=0; edc < NEDC; ++edc)
{
::snprintf(fname, sizeof(fname), "/sys/devices/uncore_edc_eclk_%d",edc);
// RPQ inserts
KNLevsetup(fname, gbl.edc_rd[edc], 0x1, 0x1);
// WPQ inserts
KNLevsetup(fname, gbl.edc_wr[edc], 0x2, 0x1);
}
// EDC HitE, HitM, MissE, MissM
for (int edc=0; edc < NEDC; ++edc)
{
::snprintf(fname, sizeof(fname), "/sys/devices/uncore_edc_uclk_%d", edc);
KNLevsetup(fname, gbl.edc_hite[edc], 0x2, 0x1);
KNLevsetup(fname, gbl.edc_hitm[edc], 0x2, 0x2);
KNLevsetup(fname, gbl.edc_misse[edc], 0x2, 0x4);
KNLevsetup(fname, gbl.edc_missm[edc], 0x2, 0x8);
}
}
uint64_t PmuStat::KNLreadctr(int fd)
{
uint64_t data;
size_t s = ::read(fd, &data, sizeof(data));
if (s != sizeof(uint64_t)){
::printf("read counter %lu", s);
::exit(0);
}
return data;
}
void PmuStat::KNLreadctrs(ctrs &c)
{
for (int i = 0; i < NMC; ++i)
{
c.mcrd[i] = KNLreadctr(gbl.mc_rd[i]);
c.mcwr[i] = KNLreadctr(gbl.mc_wr[i]);
}
for (int i = 0; i < NEDC; ++i)
{
c.edcrd[i] = KNLreadctr(gbl.edc_rd[i]);
c.edcwr[i] = KNLreadctr(gbl.edc_wr[i]);
}
for (int i = 0; i < NEDC; ++i)
{
c.edchite[i] = KNLreadctr(gbl.edc_hite[i]);
c.edchitm[i] = KNLreadctr(gbl.edc_hitm[i]);
c.edcmisse[i] = KNLreadctr(gbl.edc_misse[i]);
c.edcmissm[i] = KNLreadctr(gbl.edc_missm[i]);
}
}
#endif
}

104
lib/Stat.h Normal file
View File

@ -0,0 +1,104 @@
#ifndef _GRID_STAT_H
#define _GRID_STAT_H
#ifdef AVX512
#define _KNIGHTS_LANDING_ROOTONLY
#endif
namespace Grid {
///////////////////////////////////////////////////////////////////////////////
// Extra KNL counters from MCDRAM
///////////////////////////////////////////////////////////////////////////////
#ifdef _KNIGHTS_LANDING_
#define NMC 6
#define NEDC 8
struct ctrs
{
uint64_t mcrd[NMC];
uint64_t mcwr[NMC];
uint64_t edcrd[NEDC];
uint64_t edcwr[NEDC];
uint64_t edchite[NEDC];
uint64_t edchitm[NEDC];
uint64_t edcmisse[NEDC];
uint64_t edcmissm[NEDC];
};
// Peter/Azusa:
// Our modification of a code provided by Larry Meadows from Intel
// Verified by email exchange non-NDA, ok for github. Should be as uses /sys/devices/ FS
// so is already public and in the linux kernel for KNL.
struct knl_gbl_
{
int mc_rd[NMC];
int mc_wr[NMC];
int edc_rd[NEDC];
int edc_wr[NEDC];
int edc_hite[NEDC];
int edc_hitm[NEDC];
int edc_misse[NEDC];
int edc_missm[NEDC];
};
#endif
///////////////////////////////////////////////////////////////////////////////
class PmuStat
{
uint64_t counters[8][256];
#ifdef _KNIGHTS_LANDING_
static struct knl_gbl_ gbl;
#endif
const char *name;
uint64_t reads; // memory reads
uint64_t writes; // memory writes
uint64_t mrstart; // memory read counter at start of parallel region
uint64_t mrend; // memory read counter at end of parallel region
uint64_t mwstart; // memory write counter at start of parallel region
uint64_t mwend; // memory write counter at end of parallel region
// cumulative counters
uint64_t count; // number of invocations
uint64_t tregion; // total time in parallel region (from thread 0)
uint64_t tcycles; // total cycles inside parallel region
uint64_t inst, ref, cyc; // fixed counters
uint64_t pmc0, pmc1;// pmu
// add memory counters here
// temp variables
uint64_t tstart; // tsc at start of parallel region
uint64_t tend; // tsc at end of parallel region
// map for ctrs values
// 0 pmc0 start
// 1 pmc0 end
// 2 pmc1 start
// 3 pmc1 end
// 4 tsc start
// 5 tsc end
static bool pmu_initialized;
public:
static bool is_init(void){ return pmu_initialized;}
static void pmu_init(void);
static void pmu_fini(void);
static void pmu_start(void);
static void pmu_stop(void);
void accum(int nthreads);
static void xmemctrs(uint64_t *mr, uint64_t *mw);
void start(void);
void enter(int t);
void exit(int t);
void print(void);
void init(const char *regname);
void clear(void);
#ifdef _KNIGHTS_LANDING_
static void KNLsetup(void);
static uint64_t KNLreadctr(int fd);
static void KNLreadctrs(ctrs &c);
static void KNLevsetup(const char *ename, int &fd, int event, int umask);
#endif
};
}
#endif

1694
lib/Stencil.h
View File

File diff suppressed because it is too large Load Diff

31
lib/Threads.h
View File

@ -37,11 +37,20 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
#ifdef GRID_OMP
#include <omp.h>
#define PARALLEL_FOR_LOOP _Pragma("omp parallel for ")
#define PARALLEL_NESTED_LOOP2 _Pragma("omp parallel for collapse(2)")
#ifdef GRID_NUMA
#define PARALLEL_FOR_LOOP _Pragma("omp parallel for schedule(static)")
#define PARALLEL_FOR_LOOP_INTERN _Pragma("omp for schedule(static)")
#else
#define PARALLEL_FOR_LOOP
#define PARALLEL_FOR_LOOP _Pragma("omp parallel for schedule(runtime)")
#define PARALLEL_FOR_LOOP_INTERN _Pragma("omp for schedule(runtime)")
#endif
#define PARALLEL_NESTED_LOOP2 _Pragma("omp parallel for collapse(2)")
#define PARALLEL_REGION _Pragma("omp parallel")
#else
#define PARALLEL_FOR_LOOP
#define PARALLEL_FOR_LOOP_INTERN
#define PARALLEL_NESTED_LOOP2
#define PARALLEL_REGION
#endif
namespace Grid {
@ -123,6 +132,22 @@ class GridThread {
ThreadBarrier();
};
static void bcopy(const void *src, void *dst, size_t len) {
#ifdef GRID_OMP
#pragma omp parallel
{
const char *c_src =(char *) src;
char *c_dest=(char *) dst;
int me,mywork,myoff;
GridThread::GetWorkBarrier(len,me, mywork,myoff);
bcopy(&c_src[myoff],&c_dest[myoff],mywork);
}
#else
bcopy(src,dst,len);
#endif
}
};
}

2
lib/algorithms/CoarsenedMatrix.h
View File

@ -282,7 +282,7 @@ PARALLEL_FOR_LOOP
} else if(SE->_is_local) {
nbr = in._odata[SE->_offset];
} else {
nbr = Stencil.comm_buf[SE->_offset];
nbr = Stencil.CommBuf()[SE->_offset];
}
res = res + A[point]._odata[ss]*nbr;
}

2
lib/algorithms/iterative/ConjugateGradient.h
View File

@ -154,7 +154,7 @@ class ConjugateGradient : public OperatorFunction<Field> {
<< LinalgTimer.Elapsed();
std::cout << std::endl;
if (ErrorOnNoConverge) assert(true_residual / Tolerance < 1000.0);
if (ErrorOnNoConverge) assert(true_residual / Tolerance < 10000.0);
return;
}

6
lib/algorithms/iterative/ImplicitlyRestartedLanczos.h
View File

@ -31,7 +31,11 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
#include <string.h> //memset
#ifdef USE_LAPACK
#include <lapacke.h>
void LAPACK_dstegr(char *jobz, char *range, int *n, double *d, double *e,
double *vl, double *vu, int *il, int *iu, double *abstol,
int *m, double *w, double *z, int *ldz, int *isuppz,
double *work, int *lwork, int *iwork, int *liwork,
int *info);
#endif
#include "DenseMatrix.h"
#include "EigenSort.h"

9
lib/cartesian/Cartesian_base.h
View File

@ -77,15 +77,12 @@ public:
// GridCartesian / GridRedBlackCartesian
////////////////////////////////////////////////////////////////
virtual int CheckerBoarded(int dim)=0;
virtual int CheckerBoard(std::vector<int> site)=0;
virtual int CheckerBoard(std::vector<int> &site)=0;
virtual int CheckerBoardDestination(int source_cb,int shift,int dim)=0;
virtual int CheckerBoardShift(int source_cb,int dim,int shift,int osite)=0;
virtual int CheckerBoardShiftForCB(int source_cb,int dim,int shift,int cb)=0;
int CheckerBoardFromOindex (int Oindex){
std::vector<int> ocoor;
oCoorFromOindex(ocoor,Oindex);
return CheckerBoard(ocoor);
}
virtual int CheckerBoardFromOindex (int Oindex)=0;
virtual int CheckerBoardFromOindexTable (int Oindex)=0;
//////////////////////////////////////////////////////////////////////////////////////////////
// Local layout calculations

9
lib/cartesian/Cartesian_full.h
View File

@ -39,10 +39,17 @@ class GridCartesian: public GridBase {
public:
virtual int CheckerBoardFromOindexTable (int Oindex) {
return 0;
}
virtual int CheckerBoardFromOindex (int Oindex)
{
return 0;
}
virtual int CheckerBoarded(int dim){
return 0;
}
virtual int CheckerBoard(std::vector<int> site){
virtual int CheckerBoard(std::vector<int> &site){
return 0;
}
virtual int CheckerBoardDestination(int cb,int shift,int dim){

29
lib/cartesian/Cartesian_red_black.h
View File

@ -43,12 +43,13 @@ class GridRedBlackCartesian : public GridBase
public:
std::vector<int> _checker_dim_mask;
int _checker_dim;
std::vector<int> _checker_board;
virtual int CheckerBoarded(int dim){
if( dim==_checker_dim) return 1;
else return 0;
}
virtual int CheckerBoard(std::vector<int> site){
virtual int CheckerBoard(std::vector<int> &site){
int linear=0;
assert(site.size()==_ndimension);
for(int d=0;d<_ndimension;d++){
@ -72,12 +73,20 @@ public:
// or by looping over x,y,z and multiply rather than computing checkerboard.
if ( (source_cb+ocb)&1 ) {
return (shift)/2;
} else {
return (shift+1)/2;
}
}
virtual int CheckerBoardFromOindexTable (int Oindex) {
return _checker_board[Oindex];
}
virtual int CheckerBoardFromOindex (int Oindex)
{
std::vector<int> ocoor;
oCoorFromOindex(ocoor,Oindex);
return CheckerBoard(ocoor);
}
virtual int CheckerBoardShift(int source_cb,int dim,int shift,int osite){
if(dim != _checker_dim) return shift;
@ -169,7 +178,7 @@ public:
// all elements of a simd vector must have same checkerboard.
// If Ls vectorised, this must still be the case; e.g. dwf rb5d
if ( _simd_layout[d]>1 ) {
if ( d != _checker_dim ) {
if ( checker_dim_mask[d] ) {
assert( (_rdimensions[d]&0x1) == 0 );
}
}
@ -185,6 +194,8 @@ public:
_ostride[d] = _ostride[d-1]*_rdimensions[d-1];
_istride[d] = _istride[d-1]*_simd_layout[d-1];
}
}
////////////////////////////////////////////////////////////////////////////////////////////
@ -205,6 +216,18 @@ public:
_slice_nblock[d]=nblock;
block = block*_rdimensions[d];
}
////////////////////////////////////////////////
// Create a checkerboard lookup table
////////////////////////////////////////////////
int rvol = 1;
for(int d=0;d<_ndimension;d++){
rvol=rvol * _rdimensions[d];
}
_checker_board.resize(rvol);
for(int osite=0;osite<_osites;osite++){
_checker_board[osite] = CheckerBoardFromOindex (osite);
}
};
protected:

124
lib/communicator/Communicator_base.cc Normal file
View File

@ -0,0 +1,124 @@
/*************************************************************************************
Grid physics library, www.github.com/paboyle/Grid
Source file: ./lib/communicator/Communicator_none.cc
Copyright (C) 2015
Author: Peter Boyle <paboyle@ph.ed.ac.uk>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
See the full license in the file "LICENSE" in the top level distribution directory
*************************************************************************************/
/* END LEGAL */
#include "Grid.h"
namespace Grid {
///////////////////////////////////////////////////////////////
// Info that is setup once and indept of cartesian layout
///////////////////////////////////////////////////////////////
void * CartesianCommunicator::ShmCommBuf;
uint64_t CartesianCommunicator::MAX_MPI_SHM_BYTES = 128*1024*1024;
/////////////////////////////////
// Alloc, free shmem region
/////////////////////////////////
void *CartesianCommunicator::ShmBufferMalloc(size_t bytes){
// bytes = (bytes+sizeof(vRealD))&(~(sizeof(vRealD)-1));// align up bytes
void *ptr = (void *)heap_top;
heap_top += bytes;
heap_bytes+= bytes;
if (heap_bytes >= MAX_MPI_SHM_BYTES) {
std::cout<< " ShmBufferMalloc exceeded shared heap size -- try increasing with --shm <MB> flag" <<std::endl;
std::cout<< " Parameter specified in units of MB (megabytes) " <<std::endl;
std::cout<< " Current value is " << (MAX_MPI_SHM_BYTES/(1024*1024)) <<std::endl;
assert(heap_bytes<MAX_MPI_SHM_BYTES);
}
return ptr;
}
void CartesianCommunicator::ShmBufferFreeAll(void) {
heap_top =(size_t)ShmBufferSelf();
heap_bytes=0;
}
/////////////////////////////////
// Grid information queries
/////////////////////////////////
int CartesianCommunicator::IsBoss(void) { return _processor==0; };
int CartesianCommunicator::BossRank(void) { return 0; };
int CartesianCommunicator::ThisRank(void) { return _processor; };
const std::vector<int> & CartesianCommunicator::ThisProcessorCoor(void) { return _processor_coor; };
const std::vector<int> & CartesianCommunicator::ProcessorGrid(void) { return _processors; };
int CartesianCommunicator::ProcessorCount(void) { return _Nprocessors; };
////////////////////////////////////////////////////////////////////////////////
// very VERY rarely (Log, serial RNG) we need world without a grid
////////////////////////////////////////////////////////////////////////////////
void CartesianCommunicator::GlobalSum(ComplexF &c)
{
GlobalSumVector((float *)&c,2);
}
void CartesianCommunicator::GlobalSumVector(ComplexF *c,int N)
{
GlobalSumVector((float *)c,2*N);
}
void CartesianCommunicator::GlobalSum(ComplexD &c)
{
GlobalSumVector((double *)&c,2);
}
void CartesianCommunicator::GlobalSumVector(ComplexD *c,int N)
{
GlobalSumVector((double *)c,2*N);
}
#if !defined( GRID_COMMS_MPI3) && !defined (GRID_COMMS_MPI3L)
void CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsRequest_t> &list,
void *xmit,
int xmit_to_rank,
void *recv,
int recv_from_rank,
int bytes)
{
SendToRecvFromBegin(list,xmit,xmit_to_rank,recv,recv_from_rank,bytes);
}
void CartesianCommunicator::StencilSendToRecvFromComplete(std::vector<CommsRequest_t> &waitall)
{
SendToRecvFromComplete(waitall);
}
void CartesianCommunicator::StencilBarrier(void){};
commVector<uint8_t> CartesianCommunicator::ShmBufStorageVector;
void *CartesianCommunicator::ShmBufferSelf(void) { return ShmCommBuf; }
void *CartesianCommunicator::ShmBuffer(int rank) {
return NULL;
}
void *CartesianCommunicator::ShmBufferTranslate(int rank,void * local_p) {
return NULL;
}
void CartesianCommunicator::ShmInitGeneric(void){
ShmBufStorageVector.resize(MAX_MPI_SHM_BYTES);
ShmCommBuf=(void *)&ShmBufStorageVector[0];
}
#endif
}

258
lib/communicator/Communicator_base.h
View File

@ -1,3 +1,4 @@
/*************************************************************************************
Grid physics library, www.github.com/paboyle/Grid
@ -34,123 +35,196 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
#ifdef GRID_COMMS_MPI
#include <mpi.h>
#endif
#ifdef GRID_COMMS_MPI3
#include <mpi.h>
#endif
#ifdef GRID_COMMS_MPI3L
#include <mpi.h>
#endif
#ifdef GRID_COMMS_SHMEM
#include <mpp/shmem.h>
#endif
namespace Grid {
class CartesianCommunicator {
public:
// 65536 ranks per node adequate for now
// 128MB shared memory for comms enought for 48^4 local vol comms
// Give external control (command line override?) of this
static const int MAXLOG2RANKSPERNODE = 16;
static uint64_t MAX_MPI_SHM_BYTES;
// Communicator should know nothing of the physics grid, only processor grid.
int _Nprocessors; // How many in all
std::vector<int> _processors; // Which dimensions get relayed out over processors lanes.
int _processor; // linear processor rank
std::vector<int> _processor_coor; // linear processor coordinate
unsigned long _ndimension;
int _Nprocessors; // How many in all
std::vector<int> _processors; // Which dimensions get relayed out over processors lanes.
int _processor; // linear processor rank
std::vector<int> _processor_coor; // linear processor coordinate
unsigned long _ndimension;
#ifdef GRID_COMMS_MPI
MPI_Comm communicator;
typedef MPI_Request CommsRequest_t;
#if defined (GRID_COMMS_MPI) || defined (GRID_COMMS_MPI3) || defined (GRID_COMMS_MPI3L)
static MPI_Comm communicator_world;
MPI_Comm communicator;
typedef MPI_Request CommsRequest_t;
#else
typedef int CommsRequest_t;
typedef int CommsRequest_t;
#endif
static void Init(int *argc, char ***argv);
////////////////////////////////////////////////////////////////////
// Helper functionality for SHM Windows common to all other impls
////////////////////////////////////////////////////////////////////
// Longer term; drop this in favour of a master / slave model with
// cartesian communicator on a subset of ranks, slave ranks controlled
// by group leader with data xfer via shared memory
////////////////////////////////////////////////////////////////////
#ifdef GRID_COMMS_MPI3
// Constructor
CartesianCommunicator(const std::vector<int> &pdimensions_in);
static int ShmRank;
static int ShmSize;
static int GroupRank;
static int GroupSize;
static int WorldRank;
static int WorldSize;
// Wraps MPI_Cart routines
void ShiftedRanks(int dim,int shift,int & source, int & dest);
int RankFromProcessorCoor(std::vector<int> &coor);
void ProcessorCoorFromRank(int rank,std::vector<int> &coor);
std::vector<int> WorldDims;
std::vector<int> GroupDims;
std::vector<int> ShmDims;
std::vector<int> GroupCoor;
std::vector<int> ShmCoor;
std::vector<int> WorldCoor;
/////////////////////////////////
// Grid information queries
/////////////////////////////////
int IsBoss(void) { return _processor==0; };
int BossRank(void) { return 0; };
int ThisRank(void) { return _processor; };
const std::vector<int> & ThisProcessorCoor(void) { return _processor_coor; };
const std::vector<int> & ProcessorGrid(void) { return _processors; };
int ProcessorCount(void) { return _Nprocessors; };
static std::vector<int> GroupRanks;
static std::vector<int> MyGroup;
static int ShmSetup;
static MPI_Win ShmWindow;
static MPI_Comm ShmComm;
std::vector<int> LexicographicToWorldRank;
static std::vector<void *> ShmCommBufs;
////////////////////////////////////////////////////////////
// Reduction
////////////////////////////////////////////////////////////
void GlobalSum(RealF &);
void GlobalSumVector(RealF *,int N);
#else
static void ShmInitGeneric(void);
static commVector<uint8_t> ShmBufStorageVector;
#endif
void GlobalSum(RealD &);
void GlobalSumVector(RealD *,int N);
/////////////////////////////////
// Grid information and queries
// Implemented in Communicator_base.C
/////////////////////////////////
static void * ShmCommBuf;
size_t heap_top;
size_t heap_bytes;
void GlobalSum(uint32_t &);
void GlobalSum(uint64_t &);
void *ShmBufferSelf(void);
void *ShmBuffer(int rank);
void *ShmBufferTranslate(int rank,void * local_p);
void *ShmBufferMalloc(size_t bytes);
void ShmBufferFreeAll(void) ;
////////////////////////////////////////////////
// Must call in Grid startup
////////////////////////////////////////////////
static void Init(int *argc, char ***argv);
////////////////////////////////////////////////
// Constructor of any given grid
////////////////////////////////////////////////
CartesianCommunicator(const std::vector<int> &pdimensions_in);
////////////////////////////////////////////////////////////////////////////////////////
// Wraps MPI_Cart routines, or implements equivalent on other impls
////////////////////////////////////////////////////////////////////////////////////////
void ShiftedRanks(int dim,int shift,int & source, int & dest);
int RankFromProcessorCoor(std::vector<int> &coor);
void ProcessorCoorFromRank(int rank,std::vector<int> &coor);
int IsBoss(void) ;
int BossRank(void) ;
int ThisRank(void) ;
const std::vector<int> & ThisProcessorCoor(void) ;
const std::vector<int> & ProcessorGrid(void) ;
int ProcessorCount(void) ;
void GlobalSum(ComplexF &c)
{
GlobalSumVector((float *)&c,2);
}
void GlobalSumVector(ComplexF *c,int N)
{
GlobalSumVector((float *)c,2*N);
}
////////////////////////////////////////////////////////////////////////////////
// very VERY rarely (Log, serial RNG) we need world without a grid
////////////////////////////////////////////////////////////////////////////////
static int RankWorld(void) ;
static void BroadcastWorld(int root,void* data, int bytes);
////////////////////////////////////////////////////////////
// Reduction
////////////////////////////////////////////////////////////
void GlobalSum(RealF &);
void GlobalSumVector(RealF *,int N);
void GlobalSum(RealD &);
void GlobalSumVector(RealD *,int N);
void GlobalSum(uint32_t &);
void GlobalSum(uint64_t &);
void GlobalSum(ComplexF &c);
void GlobalSumVector(ComplexF *c,int N);
void GlobalSum(ComplexD &c);
void GlobalSumVector(ComplexD *c,int N);
template<class obj> void GlobalSum(obj &o){
typedef typename obj::scalar_type scalar_type;
int words = sizeof(obj)/sizeof(scalar_type);
scalar_type * ptr = (scalar_type *)& o;
GlobalSumVector(ptr,words);
}
////////////////////////////////////////////////////////////
// Face exchange, buffer swap in translational invariant way
////////////////////////////////////////////////////////////
void SendToRecvFrom(void *xmit,
int xmit_to_rank,
void *recv,
int recv_from_rank,
int bytes);
void SendRecvPacket(void *xmit,
void *recv,
int xmit_to_rank,
int recv_from_rank,
int bytes);
void SendToRecvFromBegin(std::vector<CommsRequest_t> &list,
void *xmit,
int xmit_to_rank,
void *recv,
int recv_from_rank,
int bytes);
void SendToRecvFromComplete(std::vector<CommsRequest_t> &waitall);
void GlobalSum(ComplexD &c)
{
GlobalSumVector((double *)&c,2);
}
void GlobalSumVector(ComplexD *c,int N)
{
GlobalSumVector((double *)c,2*N);
}
template<class obj> void GlobalSum(obj &o){
typedef typename obj::scalar_type scalar_type;
int words = sizeof(obj)/sizeof(scalar_type);
scalar_type * ptr = (scalar_type *)& o;
GlobalSumVector(ptr,words);
}
////////////////////////////////////////////////////////////
// Face exchange, buffer swap in translational invariant way
////////////////////////////////////////////////////////////
void SendToRecvFrom(void *xmit,
int xmit_to_rank,
void *recv,
int recv_from_rank,
int bytes);
void StencilSendToRecvFromBegin(std::vector<CommsRequest_t> &list,
void *xmit,
int xmit_to_rank,
void *recv,
int recv_from_rank,
int bytes);
void StencilSendToRecvFromComplete(std::vector<CommsRequest_t> &waitall);
void StencilBarrier(void);
void SendRecvPacket(void *xmit,
void *recv,
int xmit_to_rank,
int recv_from_rank,
int bytes);
void SendToRecvFromBegin(std::vector<CommsRequest_t> &list,
void *xmit,
int xmit_to_rank,
void *recv,
int recv_from_rank,
int bytes);
void SendToRecvFromComplete(std::vector<CommsRequest_t> &waitall);
////////////////////////////////////////////////////////////
// Barrier
////////////////////////////////////////////////////////////
void Barrier(void);
////////////////////////////////////////////////////////////
// Broadcast a buffer and composite larger
////////////////////////////////////////////////////////////
void Broadcast(int root,void* data, int bytes);
template<class obj> void Broadcast(int root,obj &data)
////////////////////////////////////////////////////////////
// Barrier
////////////////////////////////////////////////////////////
void Barrier(void);
////////////////////////////////////////////////////////////
// Broadcast a buffer and composite larger
////////////////////////////////////////////////////////////
void Broadcast(int root,void* data, int bytes);
template<class obj> void Broadcast(int root,obj &data)
{
Broadcast(root,(void *)&data,sizeof(data));
};
static void BroadcastWorld(int root,void* data, int bytes);
};
}

32
lib/communicator/Communicator_mpi.cc
View File

@ -30,21 +30,23 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
namespace Grid {
// Should error check all MPI calls.
///////////////////////////////////////////////////////////////////////////////////////////////////
// Info that is setup once and indept of cartesian layout
///////////////////////////////////////////////////////////////////////////////////////////////////
MPI_Comm CartesianCommunicator::communicator_world;
// Should error check all MPI calls.
void CartesianCommunicator::Init(int *argc, char ***argv) {
int flag;
MPI_Initialized(&flag); // needed to coexist with other libs apparently
if ( !flag ) {
MPI_Init(argc,argv);
}
MPI_Comm_dup (MPI_COMM_WORLD,&communicator_world);
ShmInitGeneric();
}
int Rank(void) {
int pe;
MPI_Comm_rank(MPI_COMM_WORLD,&pe);
return pe;
}
CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors)
{
_ndimension = processors.size();
@ -54,7 +56,7 @@ CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors)
_processors = processors;
_processor_coor.resize(_ndimension);
MPI_Cart_create(MPI_COMM_WORLD, _ndimension,&_processors[0],&periodic[0],1,&communicator);
MPI_Cart_create(communicator_world, _ndimension,&_processors[0],&periodic[0],1,&communicator);
MPI_Comm_rank(communicator,&_processor);
MPI_Cart_coords(communicator,_processor,_ndimension,&_processor_coor[0]);
@ -67,7 +69,6 @@ CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors)
assert(Size==_Nprocessors);
}
void CartesianCommunicator::GlobalSum(uint32_t &u){
int ierr=MPI_Allreduce(MPI_IN_PLACE,&u,1,MPI_UINT32_T,MPI_SUM,communicator);
assert(ierr==0);
@ -168,7 +169,6 @@ void CartesianCommunicator::SendToRecvFromComplete(std::vector<CommsRequest_t> &
int nreq=list.size();
std::vector<MPI_Status> status(nreq);
int ierr = MPI_Waitall(nreq,&list[0],&status[0]);
assert(ierr==0);
}
@ -187,14 +187,22 @@ void CartesianCommunicator::Broadcast(int root,void* data, int bytes)
communicator);
assert(ierr==0);
}
///////////////////////////////////////////////////////
// Should only be used prior to Grid Init finished.
// Check for this?
///////////////////////////////////////////////////////
int CartesianCommunicator::RankWorld(void){
int r;
MPI_Comm_rank(communicator_world,&r);
return r;
}
void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes)
{
int ierr= MPI_Bcast(data,
bytes,
MPI_BYTE,
root,
MPI_COMM_WORLD);
communicator_world);
assert(ierr==0);
}

580
lib/communicator/Communicator_mpi3.cc Normal file
View File

@ -0,0 +1,580 @@
/*************************************************************************************
Grid physics library, www.github.com/paboyle/Grid
Source file: ./lib/communicator/Communicator_mpi.cc
Copyright (C) 2015
Author: Peter Boyle <paboyle@ph.ed.ac.uk>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
See the full license in the file "LICENSE" in the top level distribution directory
*************************************************************************************/
/* END LEGAL */
#include "Grid.h"
#include <mpi.h>
namespace Grid {
///////////////////////////////////////////////////////////////////////////////////////////////////
// Info that is setup once and indept of cartesian layout
///////////////////////////////////////////////////////////////////////////////////////////////////
int CartesianCommunicator::ShmSetup = 0;
int CartesianCommunicator::ShmRank;
int CartesianCommunicator::ShmSize;
int CartesianCommunicator::GroupRank;
int CartesianCommunicator::GroupSize;
int CartesianCommunicator::WorldRank;
int CartesianCommunicator::WorldSize;
MPI_Comm CartesianCommunicator::communicator_world;
MPI_Comm CartesianCommunicator::ShmComm;
MPI_Win CartesianCommunicator::ShmWindow;
std::vector<int> CartesianCommunicator::GroupRanks;
std::vector<int> CartesianCommunicator::MyGroup;
std::vector<void *> CartesianCommunicator::ShmCommBufs;
void *CartesianCommunicator::ShmBufferSelf(void)
{
return ShmCommBufs[ShmRank];
}
void *CartesianCommunicator::ShmBuffer(int rank)
{
int gpeer = GroupRanks[rank];
if (gpeer == MPI_UNDEFINED){
return NULL;
} else {
return ShmCommBufs[gpeer];
}
}
void *CartesianCommunicator::ShmBufferTranslate(int rank,void * local_p)
{
int gpeer = GroupRanks[rank];
if (gpeer == MPI_UNDEFINED){
return NULL;
} else {
uint64_t offset = (uint64_t)local_p - (uint64_t)ShmCommBufs[ShmRank];
uint64_t remote = (uint64_t)ShmCommBufs[gpeer]+offset;
return (void *) remote;
}
}
void CartesianCommunicator::Init(int *argc, char ***argv) {
int flag;
MPI_Initialized(&flag); // needed to coexist with other libs apparently
if ( !flag ) {
MPI_Init(argc,argv);
}
MPI_Comm_dup (MPI_COMM_WORLD,&communicator_world);
MPI_Comm_rank(communicator_world,&WorldRank);
MPI_Comm_size(communicator_world,&WorldSize);
/////////////////////////////////////////////////////////////////////
// Split into groups that can share memory
/////////////////////////////////////////////////////////////////////
MPI_Comm_split_type(communicator_world, MPI_COMM_TYPE_SHARED, 0, MPI_INFO_NULL,&ShmComm);
MPI_Comm_rank(ShmComm ,&ShmRank);
MPI_Comm_size(ShmComm ,&ShmSize);
GroupSize = WorldSize/ShmSize;
/////////////////////////////////////////////////////////////////////
// find world ranks in our SHM group (i.e. which ranks are on our node)
/////////////////////////////////////////////////////////////////////
MPI_Group WorldGroup, ShmGroup;
MPI_Comm_group (communicator_world, &WorldGroup);
MPI_Comm_group (ShmComm, &ShmGroup);
std::vector<int> world_ranks(WorldSize);
GroupRanks.resize(WorldSize);
for(int r=0;r<WorldSize;r++) world_ranks[r]=r;
MPI_Group_translate_ranks (WorldGroup,WorldSize,&world_ranks[0],ShmGroup, &GroupRanks[0]);
///////////////////////////////////////////////////////////////////
// Identify who is in my group and noninate the leader
///////////////////////////////////////////////////////////////////
int g=0;
MyGroup.resize(ShmSize);
for(int rank=0;rank<WorldSize;rank++){
if(GroupRanks[rank]!=MPI_UNDEFINED){
assert(g<ShmSize);
MyGroup[g++] = rank;
}
}
std::sort(MyGroup.begin(),MyGroup.end(),std::less<int>());
int myleader = MyGroup[0];
std::vector<int> leaders_1hot(WorldSize,0);
std::vector<int> leaders_group(GroupSize,0);
leaders_1hot [ myleader ] = 1;
///////////////////////////////////////////////////////////////////
// global sum leaders over comm world
///////////////////////////////////////////////////////////////////
int ierr=MPI_Allreduce(MPI_IN_PLACE,&leaders_1hot[0],WorldSize,MPI_INT,MPI_SUM,communicator_world);
assert(ierr==0);
///////////////////////////////////////////////////////////////////
// find the group leaders world rank
///////////////////////////////////////////////////////////////////
int group=0;
for(int l=0;l<WorldSize;l++){
if(leaders_1hot[l]){
leaders_group[group++] = l;
}
}
///////////////////////////////////////////////////////////////////
// Identify the rank of the group in which I (and my leader) live
///////////////////////////////////////////////////////////////////
GroupRank=-1;
for(int g=0;g<GroupSize;g++){
if (myleader == leaders_group[g]){
GroupRank=g;
}
}
assert(GroupRank!=-1);
//////////////////////////////////////////////////////////////////////////////////////////////////////////
// allocate the shared window for our group
//////////////////////////////////////////////////////////////////////////////////////////////////////////
ShmCommBuf = 0;
ierr = MPI_Win_allocate_shared(MAX_MPI_SHM_BYTES,1,MPI_INFO_NULL,ShmComm,&ShmCommBuf,&ShmWindow);
assert(ierr==0);
// KNL hack -- force to numa-domain 1 in flat
#if 0
//#include <numaif.h>
for(uint64_t page=0;page<MAX_MPI_SHM_BYTES;page+=4096){
void *pages = (void *) ( page + ShmCommBuf );
int status;
int flags=MPOL_MF_MOVE_ALL;
int nodes=1; // numa domain == MCDRAM
unsigned long count=1;
ierr= move_pages(0,count, &pages,&nodes,&status,flags);
if (ierr && (page==0)) perror("numa relocate command failed");
}
#endif
MPI_Win_lock_all (MPI_MODE_NOCHECK, ShmWindow);
/////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Plan: allocate a fixed SHM region. Scratch that is just used via some scheme during stencil comms, with no allocate free.
/////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
ShmCommBufs.resize(ShmSize);
for(int r=0;r<ShmSize;r++){
MPI_Aint sz;
int dsp_unit;
MPI_Win_shared_query (ShmWindow, r, &sz, &dsp_unit, &ShmCommBufs[r]);
}
//////////////////////////////////////////////////////////////////////////////////////////////////////////
// Verbose for now
//////////////////////////////////////////////////////////////////////////////////////////////////////////
if (WorldRank == 0){
std::cout<<GridLogMessage<< "Grid MPI-3 configuration: detected ";
std::cout<< WorldSize << " Ranks " ;
std::cout<< GroupSize << " Nodes " ;
std::cout<< ShmSize << " with ranks-per-node "<<std::endl;
std::cout<<GridLogMessage <<"Grid MPI-3 configuration: allocated shared memory region of size ";
std::cout<<std::hex << MAX_MPI_SHM_BYTES <<" ShmCommBuf address = "<<ShmCommBuf << std::dec<<std::endl;
for(int g=0;g<GroupSize;g++){
std::cout<<GridLogMessage<<" Node "<<g<<" led by MPI rank "<<leaders_group[g]<<std::endl;
}
std::cout<<GridLogMessage<<" Boss Node Shm Pointers are {";
for(int g=0;g<ShmSize;g++){
std::cout<<std::hex<<ShmCommBufs[g]<<std::dec;
if(g!=ShmSize-1) std::cout<<",";
else std::cout<<"}"<<std::endl;
}
}
for(int g=0;g<GroupSize;g++){
if ( (ShmRank == 0) && (GroupRank==g) ) std::cout<<GridLogMessage<<"["<<g<<"] Node Group "<<g<<" is ranks {";
for(int r=0;r<ShmSize;r++){
if ( (ShmRank == 0) && (GroupRank==g) ) {
std::cout<<MyGroup[r];
if(r<ShmSize-1) std::cout<<",";
else std::cout<<"}"<<std::endl;
}
MPI_Barrier(communicator_world);
}
}
assert(ShmSetup==0); ShmSetup=1;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Want to implement some magic ... Group sub-cubes into those on same node
////////////////////////////////////////////////////////////////////////////////////////////////////////////
void CartesianCommunicator::ShiftedRanks(int dim,int shift,int &source,int &dest)
{
std::vector<int> coor = _processor_coor;
assert(std::abs(shift) <_processors[dim]);
coor[dim] = (_processor_coor[dim] + shift + _processors[dim])%_processors[dim];
Lexicographic::IndexFromCoor(coor,source,_processors);
source = LexicographicToWorldRank[source];
coor[dim] = (_processor_coor[dim] - shift + _processors[dim])%_processors[dim];
Lexicographic::IndexFromCoor(coor,dest,_processors);
dest = LexicographicToWorldRank[dest];
}
int CartesianCommunicator::RankFromProcessorCoor(std::vector<int> &coor)
{
int rank;
Lexicographic::IndexFromCoor(coor,rank,_processors);
rank = LexicographicToWorldRank[rank];
return rank;
}
void CartesianCommunicator::ProcessorCoorFromRank(int rank, std::vector<int> &coor)
{
Lexicographic::CoorFromIndex(coor,rank,_processors);
rank = LexicographicToWorldRank[rank];
}
CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors)
{
int ierr;
communicator=communicator_world;
_ndimension = processors.size();
////////////////////////////////////////////////////////////////
// Assert power of two shm_size.
////////////////////////////////////////////////////////////////
int log2size = -1;
for(int i=0;i<=MAXLOG2RANKSPERNODE;i++){
if ( (0x1<<i) == ShmSize ) {
log2size = i;
break;
}
}
assert(log2size != -1);
////////////////////////////////////////////////////////////////
// Identify subblock of ranks on node spreading across dims
// in a maximally symmetrical way
////////////////////////////////////////////////////////////////
int dim = 0;
std::vector<int> WorldDims = processors;
ShmDims.resize(_ndimension,1);
GroupDims.resize(_ndimension);
ShmCoor.resize(_ndimension);
GroupCoor.resize(_ndimension);
WorldCoor.resize(_ndimension);
for(int l2=0;l2<log2size;l2++){
while ( WorldDims[dim] / ShmDims[dim] <= 1 ) dim=(dim+1)%_ndimension;
ShmDims[dim]*=2;
dim=(dim+1)%_ndimension;
}
////////////////////////////////////////////////////////////////
// Establish torus of processes and nodes with sub-blockings
////////////////////////////////////////////////////////////////
for(int d=0;d<_ndimension;d++){
GroupDims[d] = WorldDims[d]/ShmDims[d];
}
////////////////////////////////////////////////////////////////
// Check processor counts match
////////////////////////////////////////////////////////////////
_Nprocessors=1;
_processors = processors;
_processor_coor.resize(_ndimension);
for(int i=0;i<_ndimension;i++){
_Nprocessors*=_processors[i];
}
assert(WorldSize==_Nprocessors);
////////////////////////////////////////////////////////////////
// Establish mapping between lexico physics coord and WorldRank
//
////////////////////////////////////////////////////////////////
LexicographicToWorldRank.resize(WorldSize,0);
Lexicographic::CoorFromIndex(GroupCoor,GroupRank,GroupDims);
Lexicographic::CoorFromIndex(ShmCoor,ShmRank,ShmDims);
for(int d=0;d<_ndimension;d++){
WorldCoor[d] = GroupCoor[d]*ShmDims[d]+ShmCoor[d];
}
_processor_coor = WorldCoor;
int lexico;
Lexicographic::IndexFromCoor(WorldCoor,lexico,WorldDims);
LexicographicToWorldRank[lexico]=WorldRank;
_processor = lexico;
///////////////////////////////////////////////////////////////////
// global sum Lexico to World mapping
///////////////////////////////////////////////////////////////////
ierr=MPI_Allreduce(MPI_IN_PLACE,&LexicographicToWorldRank[0],WorldSize,MPI_INT,MPI_SUM,communicator);
assert(ierr==0);
};
void CartesianCommunicator::GlobalSum(uint32_t &u){
int ierr=MPI_Allreduce(MPI_IN_PLACE,&u,1,MPI_UINT32_T,MPI_SUM,communicator);
assert(ierr==0);
}
void CartesianCommunicator::GlobalSum(uint64_t &u){
int ierr=MPI_Allreduce(MPI_IN_PLACE,&u,1,MPI_UINT64_T,MPI_SUM,communicator);
assert(ierr==0);
}
void CartesianCommunicator::GlobalSum(float &f){
int ierr=MPI_Allreduce(MPI_IN_PLACE,&f,1,MPI_FLOAT,MPI_SUM,communicator);
assert(ierr==0);
}
void CartesianCommunicator::GlobalSumVector(float *f,int N)
{
int ierr=MPI_Allreduce(MPI_IN_PLACE,f,N,MPI_FLOAT,MPI_SUM,communicator);
assert(ierr==0);
}
void CartesianCommunicator::GlobalSum(double &d)
{
int ierr = MPI_Allreduce(MPI_IN_PLACE,&d,1,MPI_DOUBLE,MPI_SUM,communicator);
assert(ierr==0);
}
void CartesianCommunicator::GlobalSumVector(double *d,int N)
{
int ierr = MPI_Allreduce(MPI_IN_PLACE,d,N,MPI_DOUBLE,MPI_SUM,communicator);
assert(ierr==0);
}
// Basic Halo comms primitive
void CartesianCommunicator::SendToRecvFrom(void *xmit,
int dest,
void *recv,
int from,
int bytes)
{
std::vector<CommsRequest_t> reqs(0);
SendToRecvFromBegin(reqs,xmit,dest,recv,from,bytes);
SendToRecvFromComplete(reqs);
}
void CartesianCommunicator::SendRecvPacket(void *xmit,
void *recv,
int sender,
int receiver,
int bytes)
{
MPI_Status stat;
assert(sender != receiver);
int tag = sender;
if ( _processor == sender ) {
MPI_Send(xmit, bytes, MPI_CHAR,receiver,tag,communicator);
}
if ( _processor == receiver ) {
MPI_Recv(recv, bytes, MPI_CHAR,sender,tag,communicator,&stat);
}
}
// Basic Halo comms primitive
void CartesianCommunicator::SendToRecvFromBegin(std::vector<CommsRequest_t> &list,
void *xmit,
int dest,
void *recv,
int from,
int bytes)
{
#if 0
this->StencilBarrier();
MPI_Request xrq;
MPI_Request rrq;
static int sequence;
int ierr;
int tag;
int check;
assert(dest != _processor);
assert(from != _processor);
int gdest = GroupRanks[dest];
int gfrom = GroupRanks[from];
int gme = GroupRanks[_processor];
sequence++;
char *from_ptr = (char *)ShmCommBufs[ShmRank];
int small = (bytes<MAX_MPI_SHM_BYTES);
typedef uint64_t T;
int words = bytes/sizeof(T);
assert(((size_t)bytes &(sizeof(T)-1))==0);
assert(gme == ShmRank);
if ( small && (gdest !=MPI_UNDEFINED) ) {
char *to_ptr = (char *)ShmCommBufs[gdest];
assert(gme != gdest);
T *ip = (T *)xmit;
T *op = (T *)to_ptr;
PARALLEL_FOR_LOOP
for(int w=0;w<words;w++) {
op[w]=ip[w];
}
bcopy(&_processor,&to_ptr[bytes],sizeof(_processor));
bcopy(& sequence,&to_ptr[bytes+4],sizeof(sequence));
} else {
ierr =MPI_Isend(xmit, bytes, MPI_CHAR,dest,_processor,communicator,&xrq);
assert(ierr==0);
list.push_back(xrq);
}
this->StencilBarrier();
if (small && (gfrom !=MPI_UNDEFINED) ) {
T *ip = (T *)from_ptr;
T *op = (T *)recv;
PARALLEL_FOR_LOOP
for(int w=0;w<words;w++) {
op[w]=ip[w];
}
bcopy(&from_ptr[bytes] ,&tag ,sizeof(tag));
bcopy(&from_ptr[bytes+4],&check,sizeof(check));
assert(check==sequence);
assert(tag==from);
} else {
ierr=MPI_Irecv(recv, bytes, MPI_CHAR,from,from,communicator,&rrq);
assert(ierr==0);
list.push_back(rrq);
}
this->StencilBarrier();
#else
MPI_Request xrq;
MPI_Request rrq;
int rank = _processor;
int ierr;
ierr =MPI_Isend(xmit, bytes, MPI_CHAR,dest,_processor,communicator,&xrq);
ierr|=MPI_Irecv(recv, bytes, MPI_CHAR,from,from,communicator,&rrq);
assert(ierr==0);
list.push_back(xrq);
list.push_back(rrq);
#endif
}
void CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsRequest_t> &list,
void *xmit,
int dest,
void *recv,
int from,
int bytes)
{
MPI_Request xrq;
MPI_Request rrq;
int ierr;
assert(dest != _processor);
assert(from != _processor);
int gdest = GroupRanks[dest];
int gfrom = GroupRanks[from];
int gme = GroupRanks[_processor];
assert(gme == ShmRank);
if ( gdest == MPI_UNDEFINED ) {
ierr =MPI_Isend(xmit, bytes, MPI_CHAR,dest,_processor,communicator,&xrq);
assert(ierr==0);
list.push_back(xrq);
}
if ( gfrom ==MPI_UNDEFINED) {
ierr=MPI_Irecv(recv, bytes, MPI_CHAR,from,from,communicator,&rrq);
assert(ierr==0);
list.push_back(rrq);
}
}
void CartesianCommunicator::StencilSendToRecvFromComplete(std::vector<CommsRequest_t> &list)
{
SendToRecvFromComplete(list);
}
void CartesianCommunicator::StencilBarrier(void)
{
MPI_Win_sync (ShmWindow);
MPI_Barrier (ShmComm);
MPI_Win_sync (ShmWindow);
}
void CartesianCommunicator::SendToRecvFromComplete(std::vector<CommsRequest_t> &list)
{
int nreq=list.size();
std::vector<MPI_Status> status(nreq);
int ierr = MPI_Waitall(nreq,&list[0],&status[0]);
assert(ierr==0);
}
void CartesianCommunicator::Barrier(void)
{
int ierr = MPI_Barrier(communicator);
assert(ierr==0);
}
void CartesianCommunicator::Broadcast(int root,void* data, int bytes)
{
int ierr=MPI_Bcast(data,
bytes,
MPI_BYTE,
root,
communicator);
assert(ierr==0);
}
void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes)
{
int ierr= MPI_Bcast(data,
bytes,
MPI_BYTE,
root,
communicator_world);
assert(ierr==0);
}
}

874
lib/communicator/Communicator_mpi3_leader.cc Normal file
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@ -0,0 +1,874 @@
/*************************************************************************************
Grid physics library, www.github.com/paboyle/Grid
Source file: ./lib/communicator/Communicator_mpi.cc
Copyright (C) 2015
Author: Peter Boyle <paboyle@ph.ed.ac.uk>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
See the full license in the file "LICENSE" in the top level distribution directory
*************************************************************************************/
/* END LEGAL */
#include "Grid.h"
#include <mpi.h>
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
/// Workarounds:
/// i) bloody mac os doesn't implement unnamed semaphores since it is "optional" posix.
/// darwin dispatch semaphores don't seem to be multiprocess.
///
/// ii) openmpi under --mca shmem posix works with two squadrons per node;
/// openmpi under default mca settings (I think --mca shmem mmap) on MacOS makes two squadrons map the SAME
/// memory as each other, despite their living on different communicators. This appears to be a bug in OpenMPI.
///
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
#include <semaphore.h>
#include <fcntl.h>
#include <unistd.h>
#include <limits.h>
typedef sem_t *Grid_semaphore;
#define SEM_INIT(S) S = sem_open(sem_name,0,0600,0); assert ( S != SEM_FAILED );
#define SEM_INIT_EXCL(S) sem_unlink(sem_name); S = sem_open(sem_name,O_CREAT|O_EXCL,0600,0); assert ( S != SEM_FAILED );
#define SEM_POST(S) assert ( sem_post(S) == 0 );
#define SEM_WAIT(S) assert ( sem_wait(S) == 0 );
#include <sys/mman.h>
namespace Grid {
enum { COMMAND_ISEND, COMMAND_IRECV, COMMAND_WAITALL };
struct Descriptor {
uint64_t buf;
size_t bytes;
int rank;
int tag;
int command;
MPI_Request request;
};
const int pool = 48;
class SlaveState {
public:
volatile int head;
volatile int start;
volatile int tail;
volatile Descriptor Descrs[pool];
};
class Slave {
public:
Grid_semaphore sem_head;
Grid_semaphore sem_tail;
SlaveState *state;
MPI_Comm squadron;
uint64_t base;
int universe_rank;
int vertical_rank;
char sem_name [NAME_MAX];
////////////////////////////////////////////////////////////
// Descriptor circular pointers
////////////////////////////////////////////////////////////
Slave() {};
void Init(SlaveState * _state,MPI_Comm _squadron,int _universe_rank,int _vertical_rank);
void SemInit(void) {
sprintf(sem_name,"/Grid_mpi3_sem_head_%d",universe_rank);
// printf("SEM_NAME: %s \n",sem_name);
SEM_INIT(sem_head);
sprintf(sem_name,"/Grid_mpi3_sem_tail_%d",universe_rank);
// printf("SEM_NAME: %s \n",sem_name);
SEM_INIT(sem_tail);
}
void SemInitExcl(void) {
sprintf(sem_name,"/Grid_mpi3_sem_head_%d",universe_rank);
// printf("SEM_INIT_EXCL: %s \n",sem_name);
SEM_INIT_EXCL(sem_head);
sprintf(sem_name,"/Grid_mpi3_sem_tail_%d",universe_rank);
// printf("SEM_INIT_EXCL: %s \n",sem_name);
SEM_INIT_EXCL(sem_tail);
}
void WakeUpDMA(void) {
SEM_POST(sem_head);
};
void WakeUpCompute(void) {
SEM_POST(sem_tail);
};
void WaitForCommand(void) {
SEM_WAIT(sem_head);
};
void WaitForComplete(void) {
SEM_WAIT(sem_tail);
};
void EventLoop (void) {
// std::cout<< " Entering event loop "<<std::endl;
while(1){
WaitForCommand();
// std::cout << "Getting command "<<std::endl;
Event();
}
}
int Event (void) ;
uint64_t QueueCommand(int command,void *buf, int bytes, int hashtag, MPI_Comm comm,int u_rank) ;
void WaitAll() {
// std::cout << "Queueing WAIT command "<<std::endl;
QueueCommand(COMMAND_WAITALL,0,0,0,squadron,0);
// std::cout << "Waking up DMA "<<std::endl;
WakeUpDMA();
// std::cout << "Waiting from semaphore "<<std::endl;
WaitForComplete();
// std::cout << "Checking FIFO is empty "<<std::endl;
assert ( state->tail == state->head );
}
};
////////////////////////////////////////////////////////////////////////
// One instance of a data mover.
// Master and Slave must agree on location in shared memory
////////////////////////////////////////////////////////////////////////
class MPIoffloadEngine {
public:
static std::vector<Slave> Slaves;
static int ShmSetup;
static int UniverseRank;
static int UniverseSize;
static MPI_Comm communicator_universe;
static MPI_Comm communicator_cached;
static MPI_Comm HorizontalComm;
static int HorizontalRank;
static int HorizontalSize;
static MPI_Comm VerticalComm;
static MPI_Win VerticalWindow;
static int VerticalSize;
static int VerticalRank;
static std::vector<void *> VerticalShmBufs;
static std::vector<std::vector<int> > UniverseRanks;
static std::vector<int> UserCommunicatorToWorldRanks;
static MPI_Group WorldGroup, CachedGroup;
static void CommunicatorInit (MPI_Comm &communicator_world,
MPI_Comm &ShmComm,
void * &ShmCommBuf);
static void MapCommRankToWorldRank(int &hashtag, int & comm_world_peer,int tag, MPI_Comm comm,int commrank);
/////////////////////////////////////////////////////////
// routines for master proc must handle any communicator
/////////////////////////////////////////////////////////
static void QueueSend(int slave,void *buf, int bytes, int tag, MPI_Comm comm,int rank) {
// std::cout<< " Queueing send "<< bytes<< " slave "<< slave << " to comm "<<rank <<std::endl;
Slaves[slave].QueueCommand(COMMAND_ISEND,buf,bytes,tag,comm,rank);
// std::cout << "Queued send command to rank "<< rank<< " via "<<slave <<std::endl;
Slaves[slave].WakeUpDMA();
// std::cout << "Waking up DMA "<< slave<<std::endl;
};
static void QueueRecv(int slave, void *buf, int bytes, int tag, MPI_Comm comm,int rank) {
// std::cout<< " Queueing recv "<< bytes<< " slave "<< slave << " from comm "<<rank <<std::endl;
Slaves[slave].QueueCommand(COMMAND_IRECV,buf,bytes,tag,comm,rank);
// std::cout << "Queued recv command from rank "<< rank<< " via "<<slave <<std::endl;
Slaves[slave].WakeUpDMA();
// std::cout << "Waking up DMA "<< slave<<std::endl;
};
static void WaitAll() {
for(int s=1;s<VerticalSize;s++) {
// std::cout << "Waiting for slave "<< s<<std::endl;
Slaves[s].WaitAll();
}
// std::cout << " Wait all Complete "<<std::endl;
};
static void GetWork(int nwork, int me, int & mywork, int & myoff,int units){
int basework = nwork/units;
int backfill = units-(nwork%units);
if ( me >= units ) {
mywork = myoff = 0;
} else {
mywork = (nwork+me)/units;
myoff = basework * me;
if ( me > backfill )
myoff+= (me-backfill);
}
return;
};
static void QueueMultiplexedSend(void *buf, int bytes, int tag, MPI_Comm comm,int rank) {
uint8_t * cbuf = (uint8_t *) buf;
int mywork, myoff, procs;
procs = VerticalSize-1;
for(int s=0;s<procs;s++) {
GetWork(bytes,s,mywork,myoff,procs);
QueueSend(s+1,&cbuf[myoff],mywork,tag,comm,rank);
}
};
static void QueueMultiplexedRecv(void *buf, int bytes, int tag, MPI_Comm comm,int rank) {
uint8_t * cbuf = (uint8_t *) buf;
int mywork, myoff, procs;
procs = VerticalSize-1;
for(int s=0;s<procs;s++) {
GetWork(bytes,s,mywork,myoff,procs);
QueueRecv(s+1,&cbuf[myoff],mywork,tag,comm,rank);
}
};
};
///////////////////////////////////////////////////////////////////////////////////////////////////
// Info that is setup once and indept of cartesian layout
///////////////////////////////////////////////////////////////////////////////////////////////////
std::vector<Slave> MPIoffloadEngine::Slaves;
int MPIoffloadEngine::UniverseRank;
int MPIoffloadEngine::UniverseSize;
MPI_Comm MPIoffloadEngine::communicator_universe;
MPI_Comm MPIoffloadEngine::communicator_cached;
MPI_Group MPIoffloadEngine::WorldGroup;
MPI_Group MPIoffloadEngine::CachedGroup;
MPI_Comm MPIoffloadEngine::HorizontalComm;
int MPIoffloadEngine::HorizontalRank;
int MPIoffloadEngine::HorizontalSize;
MPI_Comm MPIoffloadEngine::VerticalComm;
int MPIoffloadEngine::VerticalSize;
int MPIoffloadEngine::VerticalRank;
MPI_Win MPIoffloadEngine::VerticalWindow;
std::vector<void *> MPIoffloadEngine::VerticalShmBufs;
std::vector<std::vector<int> > MPIoffloadEngine::UniverseRanks;
std::vector<int> MPIoffloadEngine::UserCommunicatorToWorldRanks;
int MPIoffloadEngine::ShmSetup = 0;
void MPIoffloadEngine::CommunicatorInit (MPI_Comm &communicator_world,
MPI_Comm &ShmComm,
void * &ShmCommBuf)
{
int flag;
assert(ShmSetup==0);
//////////////////////////////////////////////////////////////////////
// Universe is all nodes prior to squadron grouping
//////////////////////////////////////////////////////////////////////
MPI_Comm_dup (MPI_COMM_WORLD,&communicator_universe);
MPI_Comm_rank(communicator_universe,&UniverseRank);
MPI_Comm_size(communicator_universe,&UniverseSize);
/////////////////////////////////////////////////////////////////////
// Split into groups that can share memory (Verticals)
/////////////////////////////////////////////////////////////////////
#undef MPI_SHARED_MEM_DEBUG
#ifdef MPI_SHARED_MEM_DEBUG
MPI_Comm_split(communicator_universe,(UniverseRank/4),UniverseRank,&VerticalComm);
#else
MPI_Comm_split_type(communicator_universe, MPI_COMM_TYPE_SHARED, 0, MPI_INFO_NULL,&VerticalComm);
#endif
MPI_Comm_rank(VerticalComm ,&VerticalRank);
MPI_Comm_size(VerticalComm ,&VerticalSize);
//////////////////////////////////////////////////////////////////////
// Split into horizontal groups by rank in squadron
//////////////////////////////////////////////////////////////////////
MPI_Comm_split(communicator_universe,VerticalRank,UniverseRank,&HorizontalComm);
MPI_Comm_rank(HorizontalComm,&HorizontalRank);
MPI_Comm_size(HorizontalComm,&HorizontalSize);
assert(HorizontalSize*VerticalSize==UniverseSize);
////////////////////////////////////////////////////////////////////////////////
// What is my place in the world
////////////////////////////////////////////////////////////////////////////////
int WorldRank=0;
if(VerticalRank==0) WorldRank = HorizontalRank;
int ierr=MPI_Allreduce(MPI_IN_PLACE,&WorldRank,1,MPI_INT,MPI_SUM,VerticalComm);
assert(ierr==0);
////////////////////////////////////////////////////////////////////////////////
// Where is the world in the universe?
////////////////////////////////////////////////////////////////////////////////
UniverseRanks = std::vector<std::vector<int> >(HorizontalSize,std::vector<int>(VerticalSize,0));
UniverseRanks[WorldRank][VerticalRank] = UniverseRank;
for(int w=0;w<HorizontalSize;w++){
ierr=MPI_Allreduce(MPI_IN_PLACE,&UniverseRanks[w][0],VerticalSize,MPI_INT,MPI_SUM,communicator_universe);
assert(ierr==0);
}
//////////////////////////////////////////////////////////////////////////////////////////////////////////
// allocate the shared window for our group, pass back Shm info to CartesianCommunicator
//////////////////////////////////////////////////////////////////////////////////////////////////////////
VerticalShmBufs.resize(VerticalSize);
#undef MPI_SHARED_MEM
#ifdef MPI_SHARED_MEM
ierr = MPI_Win_allocate_shared(CartesianCommunicator::MAX_MPI_SHM_BYTES,1,MPI_INFO_NULL,VerticalComm,&ShmCommBuf,&VerticalWindow);
ierr|= MPI_Win_lock_all (MPI_MODE_NOCHECK, VerticalWindow);
assert(ierr==0);
// std::cout<<"SHM "<<ShmCommBuf<<std::endl;
for(int r=0;r<VerticalSize;r++){
MPI_Aint sz;
int dsp_unit;
MPI_Win_shared_query (VerticalWindow, r, &sz, &dsp_unit, &VerticalShmBufs[r]);
// std::cout<<"SHM "<<r<<" " <<VerticalShmBufs[r]<<std::endl;
}
#else
char shm_name [NAME_MAX];
MPI_Barrier(VerticalComm);
if ( VerticalRank == 0 ) {
for(int r=0;r<VerticalSize;r++){
size_t size = CartesianCommunicator::MAX_MPI_SHM_BYTES;
if ( r>0 ) size = sizeof(SlaveState);
sprintf(shm_name,"/Grid_mpi3_shm_%d_%d",WorldRank,r);
shm_unlink(shm_name);
int fd=shm_open(shm_name,O_RDWR|O_CREAT,0600);
if ( fd < 0 ) {
perror("failed shm_open");
assert(0);
}
ftruncate(fd, size);
VerticalShmBufs[r] = mmap(NULL,size, PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0);
if ( VerticalShmBufs[r] == MAP_FAILED ) {
perror("failed mmap");
assert(0);
}
uint64_t * check = (uint64_t *) VerticalShmBufs[r];
check[0] = WorldRank;
check[1] = r;
// std::cout<<"SHM "<<r<<" " <<VerticalShmBufs[r]<<std::endl;
}
}
MPI_Barrier(VerticalComm);
if ( VerticalRank != 0 ) {
for(int r=0;r<VerticalSize;r++){
size_t size = CartesianCommunicator::MAX_MPI_SHM_BYTES ;
if ( r>0 ) size = sizeof(SlaveState);
sprintf(shm_name,"/Grid_mpi3_shm_%d_%d",WorldRank,r);
int fd=shm_open(shm_name,O_RDWR|O_CREAT,0600);
if ( fd<0 ) {
perror("failed shm_open");
assert(0);
}
VerticalShmBufs[r] = mmap(NULL,size, PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0);
uint64_t * check = (uint64_t *) VerticalShmBufs[r];
assert(check[0]== WorldRank);
assert(check[1]== r);
std::cerr<<"SHM "<<r<<" " <<VerticalShmBufs[r]<<std::endl;
}
}
#endif
MPI_Barrier(VerticalComm);
//////////////////////////////////////////////////////////////////////
// Map rank of leader on node in their in new world, to the
// rank in this vertical plane's horizontal communicator
//////////////////////////////////////////////////////////////////////
communicator_world = HorizontalComm;
ShmComm = VerticalComm;
ShmCommBuf = VerticalShmBufs[0];
MPI_Comm_group (communicator_world, &WorldGroup);
///////////////////////////////////////////////////////////
// Start the slave data movers
///////////////////////////////////////////////////////////
if ( VerticalRank != 0 ) {
Slave indentured;
indentured.Init( (SlaveState *) VerticalShmBufs[VerticalRank], VerticalComm, UniverseRank,VerticalRank);
indentured.SemInitExcl();// init semaphore in shared memory
MPI_Barrier(VerticalComm);
MPI_Barrier(VerticalComm);
indentured.EventLoop();
assert(0);
} else {
Slaves.resize(VerticalSize);
for(int i=1;i<VerticalSize;i++){
Slaves[i].Init((SlaveState *)VerticalShmBufs[i],VerticalComm, UniverseRanks[HorizontalRank][i],i);
}
MPI_Barrier(VerticalComm);
for(int i=1;i<VerticalSize;i++){
Slaves[i].SemInit();// init semaphore in shared memory
}
MPI_Barrier(VerticalComm);
}
///////////////////////////////////////////////////////////
// Verbose for now
///////////////////////////////////////////////////////////
ShmSetup=1;
if (UniverseRank == 0){
std::cout<<GridLogMessage << "Grid MPI-3 configuration: detected ";
std::cout<<UniverseSize << " Ranks " ;
std::cout<<HorizontalSize << " Nodes " ;
std::cout<<VerticalSize << " with ranks-per-node "<<std::endl;
std::cout<<GridLogMessage << "Grid MPI-3 configuration: using one lead process per node " << std::endl;
std::cout<<GridLogMessage << "Grid MPI-3 configuration: reduced communicator has size " << HorizontalSize << std::endl;
for(int g=0;g<HorizontalSize;g++){
std::cout<<GridLogMessage<<" Node "<<g<<" led by MPI rank "<< UniverseRanks[g][0]<<std::endl;
}
for(int g=0;g<HorizontalSize;g++){
std::cout<<GridLogMessage<<" { ";
for(int s=0;s<VerticalSize;s++){
std::cout<< UniverseRanks[g][s];
if ( s<VerticalSize-1 ) {
std::cout<<",";
}
}
std::cout<<" } "<<std::endl;
}
}
};
///////////////////////////////////////////////////////////////////////////////////////////////
// Map the communicator into communicator_world, and find the neighbour.
// Cache the mappings; cache size is 1.
///////////////////////////////////////////////////////////////////////////////////////////////
void MPIoffloadEngine::MapCommRankToWorldRank(int &hashtag, int & comm_world_peer,int tag, MPI_Comm comm,int rank) {
if ( comm == HorizontalComm ) {
comm_world_peer = rank;
// std::cout << " MapCommRankToWorldRank horiz " <<rank<<"->"<<comm_world_peer<<std::endl;
} else if ( comm == communicator_cached ) {
comm_world_peer = UserCommunicatorToWorldRanks[rank];
// std::cout << " MapCommRankToWorldRank cached " <<rank<<"->"<<comm_world_peer<<std::endl;
} else {
int size;
MPI_Comm_size(comm,&size);
UserCommunicatorToWorldRanks.resize(size);
std::vector<int> cached_ranks(size);
for(int r=0;r<size;r++) {
cached_ranks[r]=r;
}
communicator_cached=comm;
MPI_Comm_group(communicator_cached, &CachedGroup);
MPI_Group_translate_ranks(CachedGroup,size,&cached_ranks[0],WorldGroup, &UserCommunicatorToWorldRanks[0]);
comm_world_peer = UserCommunicatorToWorldRanks[rank];
// std::cout << " MapCommRankToWorldRank cache miss " <<rank<<"->"<<comm_world_peer<<std::endl;
assert(comm_world_peer != MPI_UNDEFINED);
}
assert( (tag & (~0xFFFFL)) ==0);
uint64_t icomm = (uint64_t)comm;
int comm_hash = ((icomm>>0 )&0xFFFF)^((icomm>>16)&0xFFFF)
^ ((icomm>>32)&0xFFFF)^((icomm>>48)&0xFFFF);
// hashtag = (comm_hash<<15) | tag;
hashtag = tag;
};
void Slave::Init(SlaveState * _state,MPI_Comm _squadron,int _universe_rank,int _vertical_rank)
{
squadron=_squadron;
universe_rank=_universe_rank;
vertical_rank=_vertical_rank;
state =_state;
// std::cout << "state "<<_state<<" comm "<<_squadron<<" universe_rank"<<universe_rank <<std::endl;
state->head = state->tail = state->start = 0;
base = (uint64_t)MPIoffloadEngine::VerticalShmBufs[0];
int rank; MPI_Comm_rank(_squadron,&rank);
}
#define PERI_PLUS(A) ( (A+1)%pool )
int Slave::Event (void) {
static int tail_last;
static int head_last;
static int start_last;
int ierr;
////////////////////////////////////////////////////
// Try to advance the start pointers
////////////////////////////////////////////////////
int s=state->start;
if ( s != state->head ) {
switch ( state->Descrs[s].command ) {
case COMMAND_ISEND:
/*
std::cout<< " Send "<<s << " ptr "<< state<<" "<< state->Descrs[s].buf<< "["<<state->Descrs[s].bytes<<"]"
<< " to " << state->Descrs[s].rank<< " tag" << state->Descrs[s].tag
<< " Comm " << MPIoffloadEngine::communicator_universe<< " me " <<universe_rank<< std::endl;
*/
ierr = MPI_Isend((void *)(state->Descrs[s].buf+base),
state->Descrs[s].bytes,
MPI_CHAR,
state->Descrs[s].rank,
state->Descrs[s].tag,
MPIoffloadEngine::communicator_universe,
(MPI_Request *)&state->Descrs[s].request);
assert(ierr==0);
state->start = PERI_PLUS(s);
return 1;
break;
case COMMAND_IRECV:
/*
std::cout<< " Recv "<<s << " ptr "<< state<<" "<< state->Descrs[s].buf<< "["<<state->Descrs[s].bytes<<"]"
<< " from " << state->Descrs[s].rank<< " tag" << state->Descrs[s].tag
<< " Comm " << MPIoffloadEngine::communicator_universe<< " me "<< universe_rank<< std::endl;
*/
ierr=MPI_Irecv((void *)(state->Descrs[s].buf+base),
state->Descrs[s].bytes,
MPI_CHAR,
state->Descrs[s].rank,
state->Descrs[s].tag,
MPIoffloadEngine::communicator_universe,
(MPI_Request *)&state->Descrs[s].request);
// std::cout<< " Request is "<<state->Descrs[s].request<<std::endl;
// std::cout<< " Request0 is "<<state->Descrs[0].request<<std::endl;
assert(ierr==0);
state->start = PERI_PLUS(s);
return 1;
break;
case COMMAND_WAITALL:
for(int t=state->tail;t!=s; t=PERI_PLUS(t) ){
MPI_Wait((MPI_Request *)&state->Descrs[t].request,MPI_STATUS_IGNORE);
};
s=PERI_PLUS(s);
state->start = s;
state->tail = s;
WakeUpCompute();
return 1;
break;
default:
assert(0);
break;
}
}
return 0;
}
//////////////////////////////////////////////////////////////////////////////
// External interaction with the queue
//////////////////////////////////////////////////////////////////////////////
uint64_t Slave::QueueCommand(int command,void *buf, int bytes, int tag, MPI_Comm comm,int commrank)
{
/////////////////////////////////////////
// Spin; if FIFO is full until not full
/////////////////////////////////////////
int head =state->head;
int next = PERI_PLUS(head);
// Set up descriptor
int worldrank;
int hashtag;
MPI_Comm communicator;
MPI_Request request;
MPIoffloadEngine::MapCommRankToWorldRank(hashtag,worldrank,tag,comm,commrank);
uint64_t relative= (uint64_t)buf - base;
state->Descrs[head].buf = relative;
state->Descrs[head].bytes = bytes;
state->Descrs[head].rank = MPIoffloadEngine::UniverseRanks[worldrank][vertical_rank];
state->Descrs[head].tag = hashtag;
state->Descrs[head].command= command;
/*
if ( command == COMMAND_ISEND ) {
std::cout << "QueueSend from "<< universe_rank <<" to commrank " << commrank
<< " to worldrank " << worldrank <<std::endl;
std::cout << " via VerticalRank "<< vertical_rank <<" to universerank " << MPIoffloadEngine::UniverseRanks[worldrank][vertical_rank]<<std::endl;
std::cout << " QueueCommand "<<buf<<"["<<bytes<<"]" << std::endl;
}
if ( command == COMMAND_IRECV ) {
std::cout << "QueueRecv on "<< universe_rank <<" from commrank " << commrank
<< " from worldrank " << worldrank <<std::endl;
std::cout << " via VerticalRank "<< vertical_rank <<" from universerank " << MPIoffloadEngine::UniverseRanks[worldrank][vertical_rank]<<std::endl;
std::cout << " QueueSend "<<buf<<"["<<bytes<<"]" << std::endl;
}
*/
// Block until FIFO has space
while( state->tail==next );
// Msync on weak order architectures
// Advance pointer
state->head = next;
return 0;
}
///////////////////////////////////////////////////////////////////////////////////////////////////
// Info that is setup once and indept of cartesian layout
///////////////////////////////////////////////////////////////////////////////////////////////////
MPI_Comm CartesianCommunicator::communicator_world;
void CartesianCommunicator::Init(int *argc, char ***argv)
{
int flag;
MPI_Initialized(&flag); // needed to coexist with other libs apparently
if ( !flag ) {
MPI_Init(argc,argv);
}
communicator_world = MPI_COMM_WORLD;
MPI_Comm ShmComm;
MPIoffloadEngine::CommunicatorInit (communicator_world,ShmComm,ShmCommBuf);
}
void CartesianCommunicator::ShiftedRanks(int dim,int shift,int &source,int &dest)
{
int ierr=MPI_Cart_shift(communicator,dim,shift,&source,&dest);
assert(ierr==0);
}
int CartesianCommunicator::RankFromProcessorCoor(std::vector<int> &coor)
{
int rank;
int ierr=MPI_Cart_rank (communicator, &coor[0], &rank);
assert(ierr==0);
return rank;
}
void CartesianCommunicator::ProcessorCoorFromRank(int rank, std::vector<int> &coor)
{
coor.resize(_ndimension);
int ierr=MPI_Cart_coords (communicator, rank, _ndimension,&coor[0]);
assert(ierr==0);
}
CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors)
{
_ndimension = processors.size();
std::vector<int> periodic(_ndimension,1);
_Nprocessors=1;
_processors = processors;
for(int i=0;i<_ndimension;i++){
_Nprocessors*=_processors[i];
}
int Size;
MPI_Comm_size(communicator_world,&Size);
assert(Size==_Nprocessors);
_processor_coor.resize(_ndimension);
MPI_Cart_create(communicator_world, _ndimension,&_processors[0],&periodic[0],1,&communicator);
MPI_Comm_rank (communicator,&_processor);
MPI_Cart_coords(communicator,_processor,_ndimension,&_processor_coor[0]);
};
void CartesianCommunicator::GlobalSum(uint32_t &u){
int ierr=MPI_Allreduce(MPI_IN_PLACE,&u,1,MPI_UINT32_T,MPI_SUM,communicator);
assert(ierr==0);
}
void CartesianCommunicator::GlobalSum(uint64_t &u){
int ierr=MPI_Allreduce(MPI_IN_PLACE,&u,1,MPI_UINT64_T,MPI_SUM,communicator);
assert(ierr==0);
}
void CartesianCommunicator::GlobalSum(float &f){
int ierr=MPI_Allreduce(MPI_IN_PLACE,&f,1,MPI_FLOAT,MPI_SUM,communicator);
assert(ierr==0);
}
void CartesianCommunicator::GlobalSumVector(float *f,int N)
{
int ierr=MPI_Allreduce(MPI_IN_PLACE,f,N,MPI_FLOAT,MPI_SUM,communicator);
assert(ierr==0);
}
void CartesianCommunicator::GlobalSum(double &d)
{
int ierr = MPI_Allreduce(MPI_IN_PLACE,&d,1,MPI_DOUBLE,MPI_SUM,communicator);
assert(ierr==0);
}
void CartesianCommunicator::GlobalSumVector(double *d,int N)
{
int ierr = MPI_Allreduce(MPI_IN_PLACE,d,N,MPI_DOUBLE,MPI_SUM,communicator);
assert(ierr==0);
}
// Basic Halo comms primitive
void CartesianCommunicator::SendToRecvFrom(void *xmit,
int dest,
void *recv,
int from,
int bytes)
{
std::vector<CommsRequest_t> reqs(0);
SendToRecvFromBegin(reqs,xmit,dest,recv,from,bytes);
SendToRecvFromComplete(reqs);
}
void CartesianCommunicator::SendRecvPacket(void *xmit,
void *recv,
int sender,
int receiver,
int bytes)
{
MPI_Status stat;
assert(sender != receiver);
int tag = sender;
if ( _processor == sender ) {
MPI_Send(xmit, bytes, MPI_CHAR,receiver,tag,communicator);
}
if ( _processor == receiver ) {
MPI_Recv(recv, bytes, MPI_CHAR,sender,tag,communicator,&stat);
}
}
// Basic Halo comms primitive
void CartesianCommunicator::SendToRecvFromBegin(std::vector<CommsRequest_t> &list,
void *xmit,
int dest,
void *recv,
int from,
int bytes)
{
MPI_Request xrq;
MPI_Request rrq;
int rank = _processor;
int ierr;
ierr =MPI_Isend(xmit, bytes, MPI_CHAR,dest,_processor,communicator,&xrq);
ierr|=MPI_Irecv(recv, bytes, MPI_CHAR,from,from,communicator,&rrq);
assert(ierr==0);
list.push_back(xrq);
list.push_back(rrq);
}
void CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsRequest_t> &list,
void *xmit,
int dest,
void *recv,
int from,
int bytes)
{
uint64_t xmit_i = (uint64_t) xmit;
uint64_t recv_i = (uint64_t) recv;
uint64_t shm = (uint64_t) ShmCommBuf;
// assert xmit and recv lie in shared memory region
assert( (xmit_i >= shm) && (xmit_i+bytes <= shm+MAX_MPI_SHM_BYTES) );
assert( (recv_i >= shm) && (recv_i+bytes <= shm+MAX_MPI_SHM_BYTES) );
assert(from!=_processor);
assert(dest!=_processor);
MPIoffloadEngine::QueueMultiplexedSend(xmit,bytes,_processor,communicator,dest);
MPIoffloadEngine::QueueMultiplexedRecv(recv,bytes,from,communicator,from);
}
void CartesianCommunicator::StencilSendToRecvFromComplete(std::vector<CommsRequest_t> &list)
{
MPIoffloadEngine::WaitAll();
}
void CartesianCommunicator::StencilBarrier(void)
{
}
void CartesianCommunicator::SendToRecvFromComplete(std::vector<CommsRequest_t> &list)
{
int nreq=list.size();
std::vector<MPI_Status> status(nreq);
int ierr = MPI_Waitall(nreq,&list[0],&status[0]);
assert(ierr==0);
}
void CartesianCommunicator::Barrier(void)
{
int ierr = MPI_Barrier(communicator);
assert(ierr==0);
}
void CartesianCommunicator::Broadcast(int root,void* data, int bytes)
{
int ierr=MPI_Bcast(data,
bytes,
MPI_BYTE,
root,
communicator);
assert(ierr==0);
}
void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes)
{
int ierr= MPI_Bcast(data,
bytes,
MPI_BYTE,
root,
communicator_world);
assert(ierr==0);
}
void *CartesianCommunicator::ShmBufferSelf(void) { return ShmCommBuf; }
void *CartesianCommunicator::ShmBuffer(int rank) {
return NULL;
}
void *CartesianCommunicator::ShmBufferTranslate(int rank,void * local_p) {
return NULL;
}
};

32
lib/communicator/Communicator_none.cc
View File

@ -28,12 +28,15 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
#include "Grid.h"
namespace Grid {
///////////////////////////////////////////////////////////////////////////////////////////////////
// Info that is setup once and indept of cartesian layout
///////////////////////////////////////////////////////////////////////////////////////////////////
void CartesianCommunicator::Init(int *argc, char *** arv)
{
ShmInitGeneric();
}
int Rank(void ){ return 0; };
CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors)
{
_processors = processors;
@ -89,30 +92,17 @@ void CartesianCommunicator::SendToRecvFromComplete(std::vector<CommsRequest_t> &
assert(0);
}
void CartesianCommunicator::Barrier(void)
{
}
void CartesianCommunicator::Broadcast(int root,void* data, int bytes)
{
}
void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes)
{
}
int CartesianCommunicator::RankWorld(void){return 0;}
void CartesianCommunicator::Barrier(void){}
void CartesianCommunicator::Broadcast(int root,void* data, int bytes) {}
void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes) { }
int CartesianCommunicator::RankFromProcessorCoor(std::vector<int> &coor) { return 0;}
void CartesianCommunicator::ProcessorCoorFromRank(int rank, std::vector<int> &coor){ coor = _processor_coor ;}
void CartesianCommunicator::ShiftedRanks(int dim,int shift,int &source,int &dest)
{
source =0;
dest=0;
}
int CartesianCommunicator::RankFromProcessorCoor(std::vector<int> &coor)
{
return 0;
}
void CartesianCommunicator::ProcessorCoorFromRank(int rank, std::vector<int> &coor)
{
}
}

45
lib/communicator/Communicator_shmem.cc
View File

@ -39,14 +39,24 @@ namespace Grid {
BACKTRACEFILE(); \
}\
}
int Rank(void) {
return shmem_my_pe();
}
///////////////////////////////////////////////////////////////////////////////////////////////////
// Info that is setup once and indept of cartesian layout
///////////////////////////////////////////////////////////////////////////////////////////////////
typedef struct HandShake_t {
uint64_t seq_local;
uint64_t seq_remote;
} HandShake;
std::array<long,_SHMEM_REDUCE_SYNC_SIZE> make_psync_init(void) {
array<long,_SHMEM_REDUCE_SYNC_SIZE> ret;
ret.fill(SHMEM_SYNC_VALUE);
return ret;
}
static std::array<long,_SHMEM_REDUCE_SYNC_SIZE> psync_init = make_psync_init();
static Vector< HandShake > XConnections;
static Vector< HandShake > RConnections;
@ -61,7 +71,9 @@ void CartesianCommunicator::Init(int *argc, char ***argv) {
RConnections[pe].seq_remote= 0;
}
shmem_barrier_all();
ShmInitGeneric();
}
CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors)
{
_ndimension = processors.size();
@ -89,7 +101,7 @@ void CartesianCommunicator::GlobalSum(uint32_t &u){
static long long source ;
static long long dest ;
static long long llwrk[_SHMEM_REDUCE_MIN_WRKDATA_SIZE];
static long psync[_SHMEM_REDUCE_SYNC_SIZE];
static std::array<long,_SHMEM_REDUCE_SYNC_SIZE> psync = psync_init;
// int nreduce=1;
// int pestart=0;
@ -105,7 +117,7 @@ void CartesianCommunicator::GlobalSum(uint64_t &u){
static long long source ;
static long long dest ;
static long long llwrk[_SHMEM_REDUCE_MIN_WRKDATA_SIZE];
static long psync[_SHMEM_REDUCE_SYNC_SIZE];
static std::array<long,_SHMEM_REDUCE_SYNC_SIZE> psync = psync_init;
// int nreduce=1;
// int pestart=0;
@ -121,7 +133,7 @@ void CartesianCommunicator::GlobalSum(float &f){
static float source ;
static float dest ;
static float llwrk[_SHMEM_REDUCE_MIN_WRKDATA_SIZE];
static long psync[_SHMEM_REDUCE_SYNC_SIZE];
static std::array<long,_SHMEM_REDUCE_SYNC_SIZE> psync = psync_init;
source = f;
dest =0.0;
@ -133,7 +145,7 @@ void CartesianCommunicator::GlobalSumVector(float *f,int N)
static float source ;
static float dest = 0 ;
static float llwrk[_SHMEM_REDUCE_MIN_WRKDATA_SIZE];
static long psync[_SHMEM_REDUCE_SYNC_SIZE];
static std::array<long,_SHMEM_REDUCE_SYNC_SIZE> psync = psync_init;
if ( shmem_addr_accessible(f,_processor) ){
shmem_float_sum_to_all(f,f,N,0,0,_Nprocessors,llwrk,psync);
@ -152,7 +164,7 @@ void CartesianCommunicator::GlobalSum(double &d)
static double source;
static double dest ;
static double llwrk[_SHMEM_REDUCE_MIN_WRKDATA_SIZE];
static long psync[_SHMEM_REDUCE_SYNC_SIZE];
static std::array<long,_SHMEM_REDUCE_SYNC_SIZE> psync = psync_init;
source = d;
dest = 0;
@ -164,7 +176,8 @@ void CartesianCommunicator::GlobalSumVector(double *d,int N)
static double source ;
static double dest ;
static double llwrk[_SHMEM_REDUCE_MIN_WRKDATA_SIZE];
static long psync[_SHMEM_REDUCE_SYNC_SIZE];
static std::array<long,_SHMEM_REDUCE_SYNC_SIZE> psync = psync_init;
if ( shmem_addr_accessible(d,_processor) ){
shmem_double_sum_to_all(d,d,N,0,0,_Nprocessors,llwrk,psync);
@ -230,12 +243,9 @@ void CartesianCommunicator::SendRecvPacket(void *xmit,
if ( _processor == sender ) {
printf("Sender SHMEM pt2pt %d -> %d\n",sender,receiver);
// Check he has posted a receive
while(SendSeq->seq_remote == SendSeq->seq_local);
printf("Sender receive %d posted\n",sender,receiver);
// Advance our send count
seq = ++(SendSeq->seq_local);
@ -244,26 +254,19 @@ void CartesianCommunicator::SendRecvPacket(void *xmit,
shmem_putmem(recv,xmit,bytes,receiver);
shmem_fence();
printf("Sender sent payload %d\n",seq);
//Notify him we're done
shmem_putmem((void *)&(RecvSeq->seq_remote),&seq,sizeof(seq),receiver);
shmem_fence();
printf("Sender ringing door bell %d\n",seq);
}
if ( _processor == receiver ) {
printf("Receiver SHMEM pt2pt %d->%d\n",sender,receiver);
// Post a receive
seq = ++(RecvSeq->seq_local);
shmem_putmem((void *)&(SendSeq->seq_remote),&seq,sizeof(seq),sender);
printf("Receiver Opening letter box %d\n",seq);
// Now wait until he has advanced our reception counter
while(RecvSeq->seq_remote != RecvSeq->seq_local);
printf("Receiver Got the mail %d\n",seq);
}
}
@ -291,7 +294,7 @@ void CartesianCommunicator::Barrier(void)
}
void CartesianCommunicator::Broadcast(int root,void* data, int bytes)
{
static long psync[_SHMEM_REDUCE_SYNC_SIZE];
static std::array<long,_SHMEM_REDUCE_SYNC_SIZE> psync = psync_init;
static uint32_t word;
uint32_t *array = (uint32_t *) data;
assert( (bytes % 4)==0);
@ -314,7 +317,7 @@ void CartesianCommunicator::Broadcast(int root,void* data, int bytes)
}
void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes)
{
static long psync[_SHMEM_REDUCE_SYNC_SIZE];
static std::array<long,_SHMEM_REDUCE_SYNC_SIZE> psync = psync_init;
static uint32_t word;
uint32_t *array = (uint32_t *) data;
assert( (bytes % 4)==0);

19
lib/cshift/Cshift_common.h
View File

@ -1,3 +1,4 @@
/*************************************************************************************
Grid physics library, www.github.com/paboyle/Grid
@ -44,7 +45,7 @@ public:
// Gather for when there is no need to SIMD split with compression
///////////////////////////////////////////////////////////////////
template<class vobj,class cobj,class compressor> void
Gather_plane_simple (const Lattice<vobj> &rhs,std::vector<cobj,alignedAllocator<cobj> > &buffer,int dimension,int plane,int cbmask,compressor &compress, int off=0)
Gather_plane_simple (const Lattice<vobj> &rhs,commVector<cobj> &buffer,int dimension,int plane,int cbmask,compressor &compress, int off=0)
{
int rd = rhs._grid->_rdimensions[dimension];
@ -56,6 +57,7 @@ Gather_plane_simple (const Lattice<vobj> &rhs,std::vector<cobj,alignedAllocator<
int e1=rhs._grid->_slice_nblock[dimension];
int e2=rhs._grid->_slice_block[dimension];
int stride=rhs._grid->_slice_stride[dimension];
if ( cbmask == 0x3 ) {
PARALLEL_NESTED_LOOP2
@ -68,15 +70,20 @@ PARALLEL_NESTED_LOOP2
}
} else {
int bo=0;
std::vector<std::pair<int,int> > table;
for(int n=0;n<e1;n++){
for(int b=0;b<e2;b++){
int o = n*stride;
int ocb=1<<rhs._grid->CheckerBoardFromOindex(o+b);// Could easily be a table lookup
int ocb=1<<rhs._grid->CheckerBoardFromOindexTable(o+b);
if ( ocb &cbmask ) {
buffer[off+bo++]=compress(rhs._odata[so+o+b]);
table.push_back(std::pair<int,int> (bo++,o+b));
}
}
}
PARALLEL_FOR_LOOP
for(int i=0;i<table.size();i++){
buffer[off+table[i].first]=compress(rhs._odata[so+table[i].second]);
}
}
}
@ -107,6 +114,7 @@ PARALLEL_NESTED_LOOP2
int o = n*n1;
int offset = b+n*n2;
cobj temp =compress(rhs._odata[so+o+b]);
extract<cobj>(temp,pointers,offset);
}
@ -114,6 +122,7 @@ PARALLEL_NESTED_LOOP2
} else {
assert(0); //Fixme think this is buggy
for(int n=0;n<e1;n++){
for(int b=0;b<e2;b++){
int o=n*rhs._grid->_slice_stride[dimension];
@ -132,7 +141,7 @@ PARALLEL_NESTED_LOOP2
//////////////////////////////////////////////////////
// Gather for when there is no need to SIMD split
//////////////////////////////////////////////////////
template<class vobj> void Gather_plane_simple (const Lattice<vobj> &rhs,std::vector<vobj,alignedAllocator<vobj> > &buffer, int dimension,int plane,int cbmask)
template<class vobj> void Gather_plane_simple (const Lattice<vobj> &rhs,commVector<vobj> &buffer, int dimension,int plane,int cbmask)
{
SimpleCompressor<vobj> dontcompress;
Gather_plane_simple (rhs,buffer,dimension,plane,cbmask,dontcompress);
@ -150,7 +159,7 @@ template<class vobj> void Gather_plane_extract(const Lattice<vobj> &rhs,std::vec
//////////////////////////////////////////////////////
// Scatter for when there is no need to SIMD split
//////////////////////////////////////////////////////
template<class vobj> void Scatter_plane_simple (Lattice<vobj> &rhs,std::vector<vobj,alignedAllocator<vobj> > &buffer, int dimension,int plane,int cbmask)
template<class vobj> void Scatter_plane_simple (Lattice<vobj> &rhs,commVector<vobj> &buffer, int dimension,int plane,int cbmask)
{
int rd = rhs._grid->_rdimensions[dimension];

8
lib/cshift/Cshift_mpi.h
View File

@ -119,8 +119,8 @@ template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &r
assert(shift<fd);
int buffer_size = rhs._grid->_slice_nblock[dimension]*rhs._grid->_slice_block[dimension];
std::vector<vobj,alignedAllocator<vobj> > send_buf(buffer_size);
std::vector<vobj,alignedAllocator<vobj> > recv_buf(buffer_size);
commVector<vobj> send_buf(buffer_size);
commVector<vobj> recv_buf(buffer_size);
int cb= (cbmask==0x2)? Odd : Even;
int sshift= rhs._grid->CheckerBoardShiftForCB(rhs.checkerboard,dimension,shift,cb);
@ -191,8 +191,8 @@ template<class vobj> void Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
int buffer_size = grid->_slice_nblock[dimension]*grid->_slice_block[dimension];
int words = sizeof(vobj)/sizeof(vector_type);
std::vector<Vector<scalar_object> > send_buf_extract(Nsimd,Vector<scalar_object>(buffer_size) );
std::vector<Vector<scalar_object> > recv_buf_extract(Nsimd,Vector<scalar_object>(buffer_size) );
std::vector<commVector<scalar_object> > send_buf_extract(Nsimd,commVector<scalar_object>(buffer_size) );
std::vector<commVector<scalar_object> > recv_buf_extract(Nsimd,commVector<scalar_object>(buffer_size) );
int bytes = buffer_size*sizeof(scalar_object);

412
lib/fftw/fftw3.h
View File

@ -1,412 +0,0 @@
/*
* Copyright (c) 2003, 2007-14 Matteo Frigo
* Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology
*
* The following statement of license applies *only* to this header file,
* and *not* to the other files distributed with FFTW or derived therefrom:
*
* 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 ``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 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.
*/
/***************************** NOTE TO USERS *********************************
*
* THIS IS A HEADER FILE, NOT A MANUAL
*
* If you want to know how to use FFTW, please read the manual,
* online at http://www.fftw.org/doc/ and also included with FFTW.
* For a quick start, see the manual's tutorial section.
*
* (Reading header files to learn how to use a library is a habit
* stemming from code lacking a proper manual. Arguably, it's a
* *bad* habit in most cases, because header files can contain
* interfaces that are not part of the public, stable API.)
*
****************************************************************************/
#ifndef FFTW3_H
#define FFTW3_H
#include <stdio.h>
#ifdef __cplusplus
extern "C"
{
#endif /* __cplusplus */
/* If <complex.h> is included, use the C99 complex type. Otherwise
define a type bit-compatible with C99 complex */
#if !defined(FFTW_NO_Complex) && defined(_Complex_I) && defined(complex) && defined(I)
# define FFTW_DEFINE_COMPLEX(R, C) typedef R _Complex C
#else
# define FFTW_DEFINE_COMPLEX(R, C) typedef R C[2]
#endif
#define FFTW_CONCAT(prefix, name) prefix ## name
#define FFTW_MANGLE_DOUBLE(name) FFTW_CONCAT(fftw_, name)
#define FFTW_MANGLE_FLOAT(name) FFTW_CONCAT(fftwf_, name)
#define FFTW_MANGLE_LONG_DOUBLE(name) FFTW_CONCAT(fftwl_, name)
#define FFTW_MANGLE_QUAD(name) FFTW_CONCAT(fftwq_, name)
/* IMPORTANT: for Windows compilers, you should add a line
#define FFTW_DLL
here and in kernel/ifftw.h if you are compiling/using FFTW as a
DLL, in order to do the proper importing/exporting, or
alternatively compile with -DFFTW_DLL or the equivalent
command-line flag. This is not necessary under MinGW/Cygwin, where
libtool does the imports/exports automatically. */
#if defined(FFTW_DLL) && (defined(_WIN32) || defined(__WIN32__))
/* annoying Windows syntax for shared-library declarations */
# if defined(COMPILING_FFTW) /* defined in api.h when compiling FFTW */
# define FFTW_EXTERN extern __declspec(dllexport)
# else /* user is calling FFTW; import symbol */
# define FFTW_EXTERN extern __declspec(dllimport)
# endif
#else
# define FFTW_EXTERN extern
#endif
enum fftw_r2r_kind_do_not_use_me {
FFTW_R2HC=0, FFTW_HC2R=1, FFTW_DHT=2,
FFTW_REDFT00=3, FFTW_REDFT01=4, FFTW_REDFT10=5, FFTW_REDFT11=6,
FFTW_RODFT00=7, FFTW_RODFT01=8, FFTW_RODFT10=9, FFTW_RODFT11=10
};
struct fftw_iodim_do_not_use_me {
int n; /* dimension size */
int is; /* input stride */
int os; /* output stride */
};
#include <stddef.h> /* for ptrdiff_t */
struct fftw_iodim64_do_not_use_me {
ptrdiff_t n; /* dimension size */
ptrdiff_t is; /* input stride */
ptrdiff_t os; /* output stride */
};
typedef void (*fftw_write_char_func_do_not_use_me)(char c, void *);
typedef int (*fftw_read_char_func_do_not_use_me)(void *);
/*
huge second-order macro that defines prototypes for all API
functions. We expand this macro for each supported precision
X: name-mangling macro
R: real data type
C: complex data type
*/
#define FFTW_DEFINE_API(X, R, C) \
\
FFTW_DEFINE_COMPLEX(R, C); \
\
typedef struct X(plan_s) *X(plan); \
\
typedef struct fftw_iodim_do_not_use_me X(iodim); \
typedef struct fftw_iodim64_do_not_use_me X(iodim64); \
\
typedef enum fftw_r2r_kind_do_not_use_me X(r2r_kind); \
\
typedef fftw_write_char_func_do_not_use_me X(write_char_func); \
typedef fftw_read_char_func_do_not_use_me X(read_char_func); \
\
FFTW_EXTERN void X(execute)(const X(plan) p); \
\
FFTW_EXTERN X(plan) X(plan_dft)(int rank, const int *n, \
C *in, C *out, int sign, unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_dft_1d)(int n, C *in, C *out, int sign, \
unsigned flags); \
FFTW_EXTERN X(plan) X(plan_dft_2d)(int n0, int n1, \
C *in, C *out, int sign, unsigned flags); \
FFTW_EXTERN X(plan) X(plan_dft_3d)(int n0, int n1, int n2, \
C *in, C *out, int sign, unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_many_dft)(int rank, const int *n, \
int howmany, \
C *in, const int *inembed, \
int istride, int idist, \
C *out, const int *onembed, \
int ostride, int odist, \
int sign, unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_guru_dft)(int rank, const X(iodim) *dims, \
int howmany_rank, \
const X(iodim) *howmany_dims, \
C *in, C *out, \
int sign, unsigned flags); \
FFTW_EXTERN X(plan) X(plan_guru_split_dft)(int rank, const X(iodim) *dims, \
int howmany_rank, \
const X(iodim) *howmany_dims, \
R *ri, R *ii, R *ro, R *io, \
unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_guru64_dft)(int rank, \
const X(iodim64) *dims, \
int howmany_rank, \
const X(iodim64) *howmany_dims, \
C *in, C *out, \
int sign, unsigned flags); \
FFTW_EXTERN X(plan) X(plan_guru64_split_dft)(int rank, \
const X(iodim64) *dims, \
int howmany_rank, \
const X(iodim64) *howmany_dims, \
R *ri, R *ii, R *ro, R *io, \
unsigned flags); \
\
FFTW_EXTERN void X(execute_dft)(const X(plan) p, C *in, C *out); \
FFTW_EXTERN void X(execute_split_dft)(const X(plan) p, R *ri, R *ii, \
R *ro, R *io); \
\
FFTW_EXTERN X(plan) X(plan_many_dft_r2c)(int rank, const int *n, \
int howmany, \
R *in, const int *inembed, \
int istride, int idist, \
C *out, const int *onembed, \
int ostride, int odist, \
unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_dft_r2c)(int rank, const int *n, \
R *in, C *out, unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_dft_r2c_1d)(int n,R *in,C *out,unsigned flags); \
FFTW_EXTERN X(plan) X(plan_dft_r2c_2d)(int n0, int n1, \
R *in, C *out, unsigned flags); \
FFTW_EXTERN X(plan) X(plan_dft_r2c_3d)(int n0, int n1, \
int n2, \
R *in, C *out, unsigned flags); \
\
\
FFTW_EXTERN X(plan) X(plan_many_dft_c2r)(int rank, const int *n, \
int howmany, \
C *in, const int *inembed, \
int istride, int idist, \
R *out, const int *onembed, \
int ostride, int odist, \
unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_dft_c2r)(int rank, const int *n, \
C *in, R *out, unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_dft_c2r_1d)(int n,C *in,R *out,unsigned flags); \
FFTW_EXTERN X(plan) X(plan_dft_c2r_2d)(int n0, int n1, \
C *in, R *out, unsigned flags); \
FFTW_EXTERN X(plan) X(plan_dft_c2r_3d)(int n0, int n1, \
int n2, \
C *in, R *out, unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_guru_dft_r2c)(int rank, const X(iodim) *dims, \
int howmany_rank, \
const X(iodim) *howmany_dims, \
R *in, C *out, \
unsigned flags); \
FFTW_EXTERN X(plan) X(plan_guru_dft_c2r)(int rank, const X(iodim) *dims, \
int howmany_rank, \
const X(iodim) *howmany_dims, \
C *in, R *out, \
unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_guru_split_dft_r2c)( \
int rank, const X(iodim) *dims, \
int howmany_rank, \
const X(iodim) *howmany_dims, \
R *in, R *ro, R *io, \
unsigned flags); \
FFTW_EXTERN X(plan) X(plan_guru_split_dft_c2r)( \
int rank, const X(iodim) *dims, \
int howmany_rank, \
const X(iodim) *howmany_dims, \
R *ri, R *ii, R *out, \
unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_guru64_dft_r2c)(int rank, \
const X(iodim64) *dims, \
int howmany_rank, \
const X(iodim64) *howmany_dims, \
R *in, C *out, \
unsigned flags); \
FFTW_EXTERN X(plan) X(plan_guru64_dft_c2r)(int rank, \
const X(iodim64) *dims, \
int howmany_rank, \
const X(iodim64) *howmany_dims, \
C *in, R *out, \
unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_guru64_split_dft_r2c)( \
int rank, const X(iodim64) *dims, \
int howmany_rank, \
const X(iodim64) *howmany_dims, \
R *in, R *ro, R *io, \
unsigned flags); \
FFTW_EXTERN X(plan) X(plan_guru64_split_dft_c2r)( \
int rank, const X(iodim64) *dims, \
int howmany_rank, \
const X(iodim64) *howmany_dims, \
R *ri, R *ii, R *out, \
unsigned flags); \
\
FFTW_EXTERN void X(execute_dft_r2c)(const X(plan) p, R *in, C *out); \
FFTW_EXTERN void X(execute_dft_c2r)(const X(plan) p, C *in, R *out); \
\
FFTW_EXTERN void X(execute_split_dft_r2c)(const X(plan) p, \
R *in, R *ro, R *io); \
FFTW_EXTERN void X(execute_split_dft_c2r)(const X(plan) p, \
R *ri, R *ii, R *out); \
\
FFTW_EXTERN X(plan) X(plan_many_r2r)(int rank, const int *n, \
int howmany, \
R *in, const int *inembed, \
int istride, int idist, \
R *out, const int *onembed, \
int ostride, int odist, \
const X(r2r_kind) *kind, unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_r2r)(int rank, const int *n, R *in, R *out, \
const X(r2r_kind) *kind, unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_r2r_1d)(int n, R *in, R *out, \
X(r2r_kind) kind, unsigned flags); \
FFTW_EXTERN X(plan) X(plan_r2r_2d)(int n0, int n1, R *in, R *out, \
X(r2r_kind) kind0, X(r2r_kind) kind1, \
unsigned flags); \
FFTW_EXTERN X(plan) X(plan_r2r_3d)(int n0, int n1, int n2, \
R *in, R *out, X(r2r_kind) kind0, \
X(r2r_kind) kind1, X(r2r_kind) kind2, \
unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_guru_r2r)(int rank, const X(iodim) *dims, \
int howmany_rank, \
const X(iodim) *howmany_dims, \
R *in, R *out, \
const X(r2r_kind) *kind, unsigned flags); \
\
FFTW_EXTERN X(plan) X(plan_guru64_r2r)(int rank, const X(iodim64) *dims, \
int howmany_rank, \
const X(iodim64) *howmany_dims, \
R *in, R *out, \
const X(r2r_kind) *kind, unsigned flags); \
\
FFTW_EXTERN void X(execute_r2r)(const X(plan) p, R *in, R *out); \
\
FFTW_EXTERN void X(destroy_plan)(X(plan) p); \
FFTW_EXTERN void X(forget_wisdom)(void); \
FFTW_EXTERN void X(cleanup)(void); \
\
FFTW_EXTERN void X(set_timelimit)(double t); \
\
FFTW_EXTERN void X(plan_with_nthreads)(int nthreads); \
FFTW_EXTERN int X(init_threads)(void); \
FFTW_EXTERN void X(cleanup_threads)(void); \
\
FFTW_EXTERN int X(export_wisdom_to_filename)(const char *filename); \
FFTW_EXTERN void X(export_wisdom_to_file)(FILE *output_file); \
FFTW_EXTERN char *X(export_wisdom_to_string)(void); \
FFTW_EXTERN void X(export_wisdom)(X(write_char_func) write_char, \
void *data); \
FFTW_EXTERN int X(import_system_wisdom)(void); \
FFTW_EXTERN int X(import_wisdom_from_filename)(const char *filename); \
FFTW_EXTERN int X(import_wisdom_from_file)(FILE *input_file); \
FFTW_EXTERN int X(import_wisdom_from_string)(const char *input_string); \
FFTW_EXTERN int X(import_wisdom)(X(read_char_func) read_char, void *data); \
\
FFTW_EXTERN void X(fprint_plan)(const X(plan) p, FILE *output_file); \
FFTW_EXTERN void X(print_plan)(const X(plan) p); \
FFTW_EXTERN char *X(sprint_plan)(const X(plan) p); \
\
FFTW_EXTERN void *X(malloc)(size_t n); \
FFTW_EXTERN R *X(alloc_real)(size_t n); \
FFTW_EXTERN C *X(alloc_complex)(size_t n); \
FFTW_EXTERN void X(free)(void *p); \
\
FFTW_EXTERN void X(flops)(const X(plan) p, \
double *add, double *mul, double *fmas); \
FFTW_EXTERN double X(estimate_cost)(const X(plan) p); \
FFTW_EXTERN double X(cost)(const X(plan) p); \
\
FFTW_EXTERN int X(alignment_of)(R *p); \
FFTW_EXTERN const char X(version)[]; \
FFTW_EXTERN const char X(cc)[]; \
FFTW_EXTERN const char X(codelet_optim)[];
/* end of FFTW_DEFINE_API macro */
FFTW_DEFINE_API(FFTW_MANGLE_DOUBLE, double, fftw_complex)
FFTW_DEFINE_API(FFTW_MANGLE_FLOAT, float, fftwf_complex)
FFTW_DEFINE_API(FFTW_MANGLE_LONG_DOUBLE, long double, fftwl_complex)
/* __float128 (quad precision) is a gcc extension on i386, x86_64, and ia64
for gcc >= 4.6 (compiled in FFTW with --enable-quad-precision) */
#if (__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 6)) \
&& !(defined(__ICC) || defined(__INTEL_COMPILER)) \
&& (defined(__i386__) || defined(__x86_64__) || defined(__ia64__))
# if !defined(FFTW_NO_Complex) && defined(_Complex_I) && defined(complex) && defined(I)
/* note: __float128 is a typedef, which is not supported with the _Complex
keyword in gcc, so instead we use this ugly __attribute__ version.
However, we can't simply pass the __attribute__ version to
FFTW_DEFINE_API because the __attribute__ confuses gcc in pointer
types. Hence redefining FFTW_DEFINE_COMPLEX. Ugh. */
# undef FFTW_DEFINE_COMPLEX
# define FFTW_DEFINE_COMPLEX(R, C) typedef _Complex float __attribute__((mode(TC))) C
# endif
FFTW_DEFINE_API(FFTW_MANGLE_QUAD, __float128, fftwq_complex)
#endif
#define FFTW_FORWARD (-1)
#define FFTW_BACKWARD (+1)
#define FFTW_NO_TIMELIMIT (-1.0)
/* documented flags */
#define FFTW_MEASURE (0U)
#define FFTW_DESTROY_INPUT (1U << 0)
#define FFTW_UNALIGNED (1U << 1)
#define FFTW_CONSERVE_MEMORY (1U << 2)
#define FFTW_EXHAUSTIVE (1U << 3) /* NO_EXHAUSTIVE is default */
#define FFTW_PRESERVE_INPUT (1U << 4) /* cancels FFTW_DESTROY_INPUT */
#define FFTW_PATIENT (1U << 5) /* IMPATIENT is default */
#define FFTW_ESTIMATE (1U << 6)
#define FFTW_WISDOM_ONLY (1U << 21)
/* undocumented beyond-guru flags */
#define FFTW_ESTIMATE_PATIENT (1U << 7)
#define FFTW_BELIEVE_PCOST (1U << 8)
#define FFTW_NO_DFT_R2HC (1U << 9)
#define FFTW_NO_NONTHREADED (1U << 10)
#define FFTW_NO_BUFFERING (1U << 11)
#define FFTW_NO_INDIRECT_OP (1U << 12)
#define FFTW_ALLOW_LARGE_GENERIC (1U << 13) /* NO_LARGE_GENERIC is default */
#define FFTW_NO_RANK_SPLITS (1U << 14)
#define FFTW_NO_VRANK_SPLITS (1U << 15)
#define FFTW_NO_VRECURSE (1U << 16)
#define FFTW_NO_SIMD (1U << 17)
#define FFTW_NO_SLOW (1U << 18)
#define FFTW_NO_FIXED_RADIX_LARGE_N (1U << 19)
#define FFTW_ALLOW_PRUNING (1U << 20)
#ifdef __cplusplus
} /* extern "C" */
#endif /* __cplusplus */
#endif /* FFTW3_H */

2
lib/lattice/Lattice_ET.h
View File

@ -261,6 +261,7 @@ GridUnopClass(UnaryExp, exp(a));
GridBinOpClass(BinaryAdd, lhs + rhs);
GridBinOpClass(BinarySub, lhs - rhs);
GridBinOpClass(BinaryMul, lhs *rhs);
GridBinOpClass(BinaryDiv, lhs /rhs);
GridBinOpClass(BinaryAnd, lhs &rhs);
GridBinOpClass(BinaryOr, lhs | rhs);
@ -385,6 +386,7 @@ GRID_DEF_UNOP(exp, UnaryExp);
GRID_DEF_BINOP(operator+, BinaryAdd);
GRID_DEF_BINOP(operator-, BinarySub);
GRID_DEF_BINOP(operator*, BinaryMul);
GRID_DEF_BINOP(operator/, BinaryDiv);
GRID_DEF_BINOP(operator&, BinaryAnd);
GRID_DEF_BINOP(operator|, BinaryOr);

14
lib/lattice/Lattice_base.h
View File

@ -65,9 +65,6 @@ public:
class LatticeExpressionBase {};
template<class T> using Vector = std::vector<T,alignedAllocator<T> >; // Aligned allocator??
template<class T> using Matrix = std::vector<std::vector<T,alignedAllocator<T> > >; // Aligned allocator??
template <typename Op, typename T1>
class LatticeUnaryExpression : public std::pair<Op,std::tuple<T1> > , public LatticeExpressionBase {
public:
@ -303,17 +300,6 @@ PARALLEL_FOR_LOOP
*this = (*this)+r;
return *this;
}
strong_inline friend Lattice<vobj> operator / (const Lattice<vobj> &lhs,const Lattice<vobj> &rhs){
conformable(lhs,rhs);
Lattice<vobj> ret(lhs._grid);
PARALLEL_FOR_LOOP
for(int ss=0;ss<lhs._grid->oSites();ss++){
ret._odata[ss] = lhs._odata[ss]*pow(rhs._odata[ss],-1.0);
}
return ret;
};
}; // class Lattice
template<class vobj> std::ostream& operator<< (std::ostream& stream, const Lattice<vobj> &o){

27
lib/lattice/Lattice_peekpoke.h
View File

@ -154,7 +154,7 @@ PARALLEL_FOR_LOOP
template<class vobj,class sobj>
void peekLocalSite(sobj &s,const Lattice<vobj> &l,std::vector<int> &site){
GridBase *grid=l._grid;
GridBase *grid = l._grid;
typedef typename vobj::scalar_type scalar_type;
typedef typename vobj::vector_type vector_type;
@ -164,16 +164,18 @@ PARALLEL_FOR_LOOP
assert( l.checkerboard== l._grid->CheckerBoard(site));
assert( sizeof(sobj)*Nsimd == sizeof(vobj));
static const int words=sizeof(vobj)/sizeof(vector_type);
int odx,idx;
idx= grid->iIndex(site);
odx= grid->oIndex(site);
std::vector<sobj> buf(Nsimd);
extract(l._odata[odx],buf);
scalar_type * vp = (scalar_type *)&l._odata[odx];
scalar_type * pt = (scalar_type *)&s;
for(int w=0;w<words;w++){
pt[w] = vp[idx+w*Nsimd];
}
s = buf[idx];
return;
};
@ -190,18 +192,17 @@ PARALLEL_FOR_LOOP
assert( l.checkerboard== l._grid->CheckerBoard(site));
assert( sizeof(sobj)*Nsimd == sizeof(vobj));
static const int words=sizeof(vobj)/sizeof(vector_type);
int odx,idx;
idx= grid->iIndex(site);
odx= grid->oIndex(site);
std::vector<sobj> buf(Nsimd);
// extract-modify-merge cycle is easiest way and this is not perf critical
extract(l._odata[odx],buf);
scalar_type * vp = (scalar_type *)&l._odata[odx];
scalar_type * pt = (scalar_type *)&s;
buf[idx] = s;
merge(l._odata[odx],buf);
for(int w=0;w<words;w++){
vp[idx+w*Nsimd] = pt[w];
}
return;
};

9
lib/lattice/Lattice_rng.h
View File

@ -294,11 +294,12 @@ namespace Grid {
int rank,o_idx,i_idx;
_grid->GlobalIndexToGlobalCoor(gidx,gcoor);
_grid->GlobalCoorToRankIndex(rank,o_idx,i_idx,gcoor);
int l_idx=generator_idx(o_idx,i_idx);
std::vector<int> site_seeds(4);
for(int i=0;i<4;i++){
const int num_rand_seed=16;
std::vector<int> site_seeds(num_rand_seed);
for(int i=0;i<site_seeds.size();i++){
site_seeds[i]= ui(pseeder);
}

2
lib/parallelIO/BinaryIO.h
View File

@ -457,7 +457,7 @@ class BinaryIO {
// available (how short sighted is that?)
//////////////////////////////////////////////////////////
Umu = zero;
static uint32_t csum=0;
static uint32_t csum; csum=0;
fobj fileObj;
static sobj siteObj; // Static to place in symmetric region for SHMEM

24
lib/qcd/action/fermion/CayleyFermion5D.cc
View File

@ -50,6 +50,30 @@ namespace QCD {
mass(_mass)
{ }
template<class Impl>
void CayleyFermion5D<Impl>::Dminus(const FermionField &psi, FermionField &chi)
{
int Ls=this->Ls;
FermionField tmp(psi._grid);
this->DW(psi,tmp,DaggerNo);
for(int s=0;s<Ls;s++){
axpby_ssp(chi,Coeff_t(1.0),psi,-cs[s],tmp,s,s);// chi = (1-c[s] D_W) psi
}
}
template<class Impl>
void CayleyFermion5D<Impl>::DminusDag(const FermionField &psi, FermionField &chi)
{
int Ls=this->Ls;
FermionField tmp(psi._grid);
this->DW(psi,tmp,DaggerYes);
for(int s=0;s<Ls;s++){
axpby_ssp(chi,Coeff_t(1.0),psi,-cs[s],tmp,s,s);// chi = (1-c[s] D_W) psi
}
}
template<class Impl>
void CayleyFermion5D<Impl>::M5D (const FermionField &psi, FermionField &chi)
{

4
lib/qcd/action/fermion/CayleyFermion5D.h
View File

@ -56,6 +56,9 @@ namespace Grid {
virtual void M5D (const FermionField &psi, FermionField &chi);
virtual void M5Ddag(const FermionField &psi, FermionField &chi);
virtual void Dminus(const FermionField &psi, FermionField &chi);
virtual void DminusDag(const FermionField &psi, FermionField &chi);
/////////////////////////////////////////////////////
// Instantiate different versions depending on Impl
/////////////////////////////////////////////////////
@ -117,6 +120,7 @@ namespace Grid {
GridRedBlackCartesian &FourDimRedBlackGrid,
RealD _mass,RealD _M5,const ImplParams &p= ImplParams());
protected:
void SetCoefficientsZolotarev(RealD zolohi,Approx::zolotarev_data *zdata,RealD b,RealD c);
void SetCoefficientsTanh(Approx::zolotarev_data *zdata,RealD b,RealD c);

5
lib/qcd/action/fermion/DomainWallFermion.h
View File

@ -42,6 +42,10 @@ namespace Grid {
INHERIT_IMPL_TYPES(Impl);
public:
void MomentumSpacePropagator(FermionField &out,const FermionField &in,RealD _m) {
this->MomentumSpacePropagatorHt(out,in,_m);
};
virtual void Instantiatable(void) {};
// Constructors
DomainWallFermion(GaugeField &_Umu,
@ -51,6 +55,7 @@ namespace Grid {
GridRedBlackCartesian &FourDimRedBlackGrid,
RealD _mass,RealD _M5,const ImplParams &p= ImplParams()) :
CayleyFermion5D<Impl>(_Umu,
FiveDimGrid,
FiveDimRedBlackGrid,

14
lib/qcd/action/fermion/FermionOperator.h
View File

@ -91,6 +91,20 @@ namespace Grid {
virtual void Mdiag (const FermionField &in, FermionField &out) { Mooee(in,out);}; // Same as Mooee applied to both CB's
virtual void Mdir (const FermionField &in, FermionField &out,int dir,int disp)=0; // case by case Wilson, Clover, Cayley, ContFrac, PartFrac
virtual void MomentumSpacePropagator(FermionField &out,const FermionField &in,RealD _m) { assert(0);};
virtual void FreePropagator(const FermionField &in,FermionField &out,RealD mass) {
FFT theFFT((GridCartesian *) in._grid);
FermionField in_k(in._grid);
FermionField prop_k(in._grid);
theFFT.FFT_all_dim(in_k,in,FFT::forward);
this->MomentumSpacePropagator(prop_k,in_k,mass);
theFFT.FFT_all_dim(out,prop_k,FFT::backward);
};
///////////////////////////////////////////////
// Updates gauge field during HMC
///////////////////////////////////////////////

863
lib/qcd/action/fermion/FermionOperatorImpl.h
View File

@ -33,511 +33,500 @@ directory
#define GRID_QCD_FERMION_OPERATOR_IMPL_H
namespace Grid {
namespace QCD {
namespace QCD {
//////////////////////////////////////////////
// Template parameter class constructs to package
// externally control Fermion implementations
// in orthogonal directions
//
// Ultimately need Impl to always define types where XXX is opaque
//
// typedef typename XXX Simd;
// typedef typename XXX GaugeLinkField;
// typedef typename XXX GaugeField;
// typedef typename XXX GaugeActField;
// typedef typename XXX FermionField;
// typedef typename XXX DoubledGaugeField;
// typedef typename XXX SiteSpinor;
// typedef typename XXX SiteHalfSpinor;
// typedef typename XXX Compressor;
//
// and Methods:
// void ImportGauge(GridBase *GaugeGrid,DoubledGaugeField &Uds,const GaugeField &Umu)
// void DoubleStore(GridBase *GaugeGrid,DoubledGaugeField &Uds,const GaugeField &Umu)
// void multLink(SiteHalfSpinor &phi,const SiteDoubledGaugeField &U,const SiteHalfSpinor &chi,int mu,StencilEntry *SE,StencilImpl &St)
// void InsertForce4D(GaugeField &mat,const FermionField &Btilde,const FermionField &A,int mu)
// void InsertForce5D(GaugeField &mat,const FermionField &Btilde,const FermionField &A,int mu)
//
//
// To acquire the typedefs from "Base" (either a base class or template param) use:
//
// INHERIT_GIMPL_TYPES(Base)
// INHERIT_FIMPL_TYPES(Base)
// INHERIT_IMPL_TYPES(Base)
//
// The Fermion operators will do the following:
//
// struct MyOpParams {
// RealD mass;
// };
//
//
// template<class Impl>
// class MyOp : public<Impl> {
// public:
//
// INHERIT_ALL_IMPL_TYPES(Impl);
//
// MyOp(MyOpParams Myparm, ImplParams &ImplParam) : Impl(ImplParam)
// {
//
// };
//
// }
//////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
// Implementation dependent fermion types
////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////
// Template parameter class constructs to package
// externally control Fermion implementations
// in orthogonal directions
//
// Ultimately need Impl to always define types where XXX is opaque
//
// typedef typename XXX Simd;
// typedef typename XXX GaugeLinkField;
// typedef typename XXX GaugeField;
// typedef typename XXX GaugeActField;
// typedef typename XXX FermionField;
// typedef typename XXX DoubledGaugeField;
// typedef typename XXX SiteSpinor;
// typedef typename XXX SiteHalfSpinor;
// typedef typename XXX Compressor;
//
// and Methods:
// void ImportGauge(GridBase *GaugeGrid,DoubledGaugeField &Uds,const GaugeField &Umu)
// void DoubleStore(GridBase *GaugeGrid,DoubledGaugeField &Uds,const GaugeField &Umu)
// void multLink(SiteHalfSpinor &phi,const SiteDoubledGaugeField &U,const SiteHalfSpinor &chi,int mu,StencilEntry *SE,StencilImpl &St)
// void InsertForce4D(GaugeField &mat,const FermionField &Btilde,const FermionField &A,int mu)
// void InsertForce5D(GaugeField &mat,const FermionField &Btilde,const FermionField &A,int mu)
//
//
// To acquire the typedefs from "Base" (either a base class or template param) use:
//
// INHERIT_GIMPL_TYPES(Base)
// INHERIT_FIMPL_TYPES(Base)
// INHERIT_IMPL_TYPES(Base)
//
// The Fermion operators will do the following:
//
// struct MyOpParams {
// RealD mass;
// };
//
//
// template<class Impl>
// class MyOp : public<Impl> {
// public:
//
// INHERIT_ALL_IMPL_TYPES(Impl);
//
// MyOp(MyOpParams Myparm, ImplParams &ImplParam) : Impl(ImplParam)
// {
//
// };
//
// }
//////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
// Implementation dependent fermion types
////////////////////////////////////////////////////////////////////////
#define INHERIT_FIMPL_TYPES(Impl)\
typedef typename Impl::FermionField FermionField; \
typedef typename Impl::DoubledGaugeField DoubledGaugeField; \
typedef typename Impl::SiteSpinor SiteSpinor; \
typedef typename Impl::SiteHalfSpinor SiteHalfSpinor; \
typedef typename Impl::Compressor Compressor; \
typedef typename Impl::StencilImpl StencilImpl; \
typedef typename Impl::ImplParams ImplParams; \
typedef typename Impl::Coeff_t Coeff_t;
typedef typename Impl::FermionField FermionField; \
typedef typename Impl::DoubledGaugeField DoubledGaugeField; \
typedef typename Impl::SiteSpinor SiteSpinor; \
typedef typename Impl::SiteHalfSpinor SiteHalfSpinor; \
typedef typename Impl::Compressor Compressor; \
typedef typename Impl::StencilImpl StencilImpl; \
typedef typename Impl::ImplParams ImplParams; \
typedef typename Impl::Coeff_t Coeff_t;
#define INHERIT_IMPL_TYPES(Base) \
INHERIT_GIMPL_TYPES(Base) \
INHERIT_FIMPL_TYPES(Base)
INHERIT_GIMPL_TYPES(Base) \
INHERIT_FIMPL_TYPES(Base)
/////////////////////////////////////////////////////////////////////////////
// Single flavour four spinors with colour index
/////////////////////////////////////////////////////////////////////////////
template <class S, class Representation = FundamentalRepresentation,class _Coeff_t = RealD >
class WilsonImpl : public PeriodicGaugeImpl<GaugeImplTypes<S, Representation::Dimension > > {
public:
static const int Dimension = Representation::Dimension;
typedef PeriodicGaugeImpl<GaugeImplTypes<S, Dimension > > Gimpl;
//Necessary?
constexpr bool is_fundamental() const{return Dimension == Nc ? 1 : 0;}
///////
// Single flavour four spinors with colour index
///////
template <class S, class Representation = FundamentalRepresentation,class _Coeff_t = RealD >
class WilsonImpl
: public PeriodicGaugeImpl<GaugeImplTypes<S, Representation::Dimension > > {
public:
static const int Dimension = Representation::Dimension;
typedef PeriodicGaugeImpl<GaugeImplTypes<S, Dimension > > Gimpl;
//Necessary?
constexpr bool is_fundamental() const{return Dimension == Nc ? 1 : 0;}
const bool LsVectorised=false;
typedef _Coeff_t Coeff_t;
const bool LsVectorised=false;
typedef _Coeff_t Coeff_t;
INHERIT_GIMPL_TYPES(Gimpl);
INHERIT_GIMPL_TYPES(Gimpl);
template <typename vtype> using iImplSpinor = iScalar<iVector<iVector<vtype, Dimension>, Ns> >;
template <typename vtype> using iImplHalfSpinor = iScalar<iVector<iVector<vtype, Dimension>, Nhs> >;
template <typename vtype> using iImplDoubledGaugeField = iVector<iScalar<iMatrix<vtype, Dimension> >, Nds>;
template <typename vtype> using iImplSpinor = iScalar<iVector<iVector<vtype, Dimension>, Ns> >;
template <typename vtype> using iImplHalfSpinor = iScalar<iVector<iVector<vtype, Dimension>, Nhs> >;
template <typename vtype> using iImplDoubledGaugeField = iVector<iScalar<iMatrix<vtype, Dimension> >, Nds>;
typedef iImplSpinor<Simd> SiteSpinor;
typedef iImplHalfSpinor<Simd> SiteHalfSpinor;
typedef iImplDoubledGaugeField<Simd> SiteDoubledGaugeField;
typedef Lattice<SiteSpinor> FermionField;
typedef Lattice<SiteDoubledGaugeField> DoubledGaugeField;
typedef WilsonCompressor<SiteHalfSpinor, SiteSpinor> Compressor;
typedef WilsonImplParams ImplParams;
typedef WilsonStencil<SiteSpinor, SiteHalfSpinor> StencilImpl;
ImplParams Params;
WilsonImpl(const ImplParams &p = ImplParams()) : Params(p){};
typedef iImplSpinor<Simd> SiteSpinor;
typedef iImplHalfSpinor<Simd> SiteHalfSpinor;
typedef iImplDoubledGaugeField<Simd> SiteDoubledGaugeField;
bool overlapCommsCompute(void) { return Params.overlapCommsCompute; };
typedef Lattice<SiteSpinor> FermionField;
typedef Lattice<SiteDoubledGaugeField> DoubledGaugeField;
inline void multLink(SiteHalfSpinor &phi,
const SiteDoubledGaugeField &U,
const SiteHalfSpinor &chi,
int mu,
StencilEntry *SE,
StencilImpl &St) {
mult(&phi(), &U(mu), &chi());
}
typedef WilsonCompressor<SiteHalfSpinor, SiteSpinor> Compressor;
typedef WilsonImplParams ImplParams;
typedef WilsonStencil<SiteSpinor, SiteHalfSpinor> StencilImpl;
template <class ref>
inline void loadLinkElement(Simd &reg, ref &memory) {
reg = memory;
}
ImplParams Params;
WilsonImpl(const ImplParams &p = ImplParams()) : Params(p){};
bool overlapCommsCompute(void) { return Params.overlapCommsCompute; };
inline void multLink(SiteHalfSpinor &phi,
const SiteDoubledGaugeField &U,
const SiteHalfSpinor &chi,
int mu,
StencilEntry *SE,
StencilImpl &St) {
mult(&phi(), &U(mu), &chi());
inline void DoubleStore(GridBase *GaugeGrid,
DoubledGaugeField &Uds,
const GaugeField &Umu) {
conformable(Uds._grid, GaugeGrid);
conformable(Umu._grid, GaugeGrid);
GaugeLinkField U(GaugeGrid);
for (int mu = 0; mu < Nd; mu++) {
U = PeekIndex<LorentzIndex>(Umu, mu);
PokeIndex<LorentzIndex>(Uds, U, mu);
U = adj(Cshift(U, mu, -1));
PokeIndex<LorentzIndex>(Uds, U, mu + 4);
}
}
inline void InsertForce4D(GaugeField &mat, FermionField &Btilde, FermionField &A,int mu){
GaugeLinkField link(mat._grid);
link = TraceIndex<SpinIndex>(outerProduct(Btilde,A));
PokeIndex<LorentzIndex>(mat,link,mu);
}
template <class ref>
inline void loadLinkElement(Simd &reg,
ref &memory) {
reg = memory;
}
inline void InsertForce5D(GaugeField &mat, FermionField &Btilde, FermionField &Atilde,int mu){
inline void DoubleStore(GridBase *GaugeGrid,
DoubledGaugeField &Uds,
const GaugeField &Umu) {
conformable(Uds._grid, GaugeGrid);
conformable(Umu._grid, GaugeGrid);
GaugeLinkField U(GaugeGrid);
for (int mu = 0; mu < Nd; mu++) {
U = PeekIndex<LorentzIndex>(Umu, mu);
PokeIndex<LorentzIndex>(Uds, U, mu);
U = adj(Cshift(U, mu, -1));
PokeIndex<LorentzIndex>(Uds, U, mu + 4);
int Ls=Btilde._grid->_fdimensions[0];
GaugeLinkField tmp(mat._grid);
tmp = zero;
PARALLEL_FOR_LOOP
for(int sss=0;sss<tmp._grid->oSites();sss++){
int sU=sss;
for(int s=0;s<Ls;s++){
int sF = s+Ls*sU;
tmp[sU] = tmp[sU]+ traceIndex<SpinIndex>(outerProduct(Btilde[sF],Atilde[sF])); // ordering here
}
}
PokeIndex<LorentzIndex>(mat,tmp,mu);
}
};
inline void InsertForce4D(GaugeField &mat, FermionField &Btilde, FermionField &A,int mu){
GaugeLinkField link(mat._grid);
link = TraceIndex<SpinIndex>(outerProduct(Btilde,A));
PokeIndex<LorentzIndex>(mat,link,mu);
}
inline void InsertForce5D(GaugeField &mat, FermionField &Btilde, FermionField &Atilde,int mu){
int Ls=Btilde._grid->_fdimensions[0];
GaugeLinkField tmp(mat._grid);
tmp = zero;
PARALLEL_FOR_LOOP
for(int sss=0;sss<tmp._grid->oSites();sss++){
int sU=sss;
for(int s=0;s<Ls;s++){
int sF = s+Ls*sU;
tmp[sU] = tmp[sU]+ traceIndex<SpinIndex>(outerProduct(Btilde[sF],Atilde[sF])); // ordering here
}
}
PokeIndex<LorentzIndex>(mat,tmp,mu);
}
};
////////////////////////////////////////////////////////////////////////////////////
// Single flavour four spinors with colour index, 5d redblack
////////////////////////////////////////////////////////////////////////////////////
///////
// Single flavour four spinors with colour index, 5d redblack
///////
template<class S,int Nrepresentation=Nc,class _Coeff_t = RealD>
class DomainWallVec5dImpl : public PeriodicGaugeImpl< GaugeImplTypes< S,Nrepresentation> > {
public:
template<class S,int Nrepresentation=Nc,class _Coeff_t = RealD>
class DomainWallVec5dImpl : public PeriodicGaugeImpl< GaugeImplTypes< S,Nrepresentation> > {
public:
static const int Dimension = Nrepresentation;
const bool LsVectorised=true;
typedef _Coeff_t Coeff_t;
typedef PeriodicGaugeImpl<GaugeImplTypes<S, Nrepresentation> > Gimpl;
static const int Dimension = Nrepresentation;
const bool LsVectorised=true;
typedef _Coeff_t Coeff_t;
typedef PeriodicGaugeImpl<GaugeImplTypes<S, Nrepresentation> > Gimpl;
INHERIT_GIMPL_TYPES(Gimpl);
template <typename vtype> using iImplSpinor = iScalar<iVector<iVector<vtype, Nrepresentation>, Ns> >;
template <typename vtype> using iImplHalfSpinor = iScalar<iVector<iVector<vtype, Nrepresentation>, Nhs> >;
template <typename vtype> using iImplDoubledGaugeField = iVector<iScalar<iMatrix<vtype, Nrepresentation> >, Nds>;
template <typename vtype> using iImplGaugeField = iVector<iScalar<iMatrix<vtype, Nrepresentation> >, Nd>;
template <typename vtype> using iImplGaugeLink = iScalar<iScalar<iMatrix<vtype, Nrepresentation> > >;
typedef iImplSpinor<Simd> SiteSpinor;
typedef iImplHalfSpinor<Simd> SiteHalfSpinor;
typedef Lattice<SiteSpinor> FermionField;
// Make the doubled gauge field a *scalar*
typedef iImplDoubledGaugeField<typename Simd::scalar_type> SiteDoubledGaugeField; // This is a scalar
typedef iImplGaugeField<typename Simd::scalar_type> SiteScalarGaugeField; // scalar
typedef iImplGaugeLink<typename Simd::scalar_type> SiteScalarGaugeLink; // scalar
typedef Lattice<SiteDoubledGaugeField> DoubledGaugeField;
typedef WilsonCompressor<SiteHalfSpinor, SiteSpinor> Compressor;
typedef WilsonImplParams ImplParams;
typedef WilsonStencil<SiteSpinor, SiteHalfSpinor> StencilImpl;
ImplParams Params;
DomainWallVec5dImpl(const ImplParams &p = ImplParams()) : Params(p){};
bool overlapCommsCompute(void) { return false; };
template <class ref>
inline void loadLinkElement(Simd &reg, ref &memory) {
vsplat(reg, memory);
}
INHERIT_GIMPL_TYPES(Gimpl);
template <typename vtype> using iImplSpinor = iScalar<iVector<iVector<vtype, Nrepresentation>, Ns> >;
template <typename vtype> using iImplHalfSpinor = iScalar<iVector<iVector<vtype, Nrepresentation>, Nhs> >;
template <typename vtype> using iImplDoubledGaugeField = iVector<iScalar<iMatrix<vtype, Nrepresentation> >, Nds>;
template <typename vtype> using iImplGaugeField = iVector<iScalar<iMatrix<vtype, Nrepresentation> >, Nd>;
template <typename vtype> using iImplGaugeLink = iScalar<iScalar<iMatrix<vtype, Nrepresentation> > >;
typedef iImplSpinor<Simd> SiteSpinor;
typedef iImplHalfSpinor<Simd> SiteHalfSpinor;
typedef Lattice<SiteSpinor> FermionField;
// Make the doubled gauge field a *scalar*
typedef iImplDoubledGaugeField<typename Simd::scalar_type>
SiteDoubledGaugeField; // This is a scalar
typedef iImplGaugeField<typename Simd::scalar_type>
SiteScalarGaugeField; // scalar
typedef iImplGaugeLink<typename Simd::scalar_type>
SiteScalarGaugeLink; // scalar
typedef Lattice<SiteDoubledGaugeField> DoubledGaugeField;
typedef WilsonCompressor<SiteHalfSpinor, SiteSpinor> Compressor;
typedef WilsonImplParams ImplParams;
typedef WilsonStencil<SiteSpinor, SiteHalfSpinor> StencilImpl;
ImplParams Params;
DomainWallVec5dImpl(const ImplParams &p = ImplParams()) : Params(p){};
bool overlapCommsCompute(void) { return false; };
template <class ref>
inline void loadLinkElement(Simd &reg, ref &memory) {
vsplat(reg, memory);
}
inline void multLink(SiteHalfSpinor &phi, const SiteDoubledGaugeField &U,
const SiteHalfSpinor &chi, int mu, StencilEntry *SE,
StencilImpl &St) {
SiteGaugeLink UU;
for (int i = 0; i < Nrepresentation; i++) {
for (int j = 0; j < Nrepresentation; j++) {
vsplat(UU()()(i, j), U(mu)()(i, j));
}
}
mult(&phi(), &UU(), &chi());
inline void multLink(SiteHalfSpinor &phi, const SiteDoubledGaugeField &U,
const SiteHalfSpinor &chi, int mu, StencilEntry *SE,
StencilImpl &St) {
SiteGaugeLink UU;
for (int i = 0; i < Nrepresentation; i++) {
for (int j = 0; j < Nrepresentation; j++) {
vsplat(UU()()(i, j), U(mu)()(i, j));
}
}
mult(&phi(), &UU(), &chi());
}
inline void DoubleStore(GridBase *GaugeGrid, DoubledGaugeField &Uds,
const GaugeField &Umu) {
SiteScalarGaugeField ScalarUmu;
SiteDoubledGaugeField ScalarUds;
GaugeLinkField U(Umu._grid);
GaugeField Uadj(Umu._grid);
for (int mu = 0; mu < Nd; mu++) {
U = PeekIndex<LorentzIndex>(Umu, mu);
U = adj(Cshift(U, mu, -1));
PokeIndex<LorentzIndex>(Uadj, U, mu);
}
for (int lidx = 0; lidx < GaugeGrid->lSites(); lidx++) {
std::vector<int> lcoor;
GaugeGrid->LocalIndexToLocalCoor(lidx, lcoor);
peekLocalSite(ScalarUmu, Umu, lcoor);
for (int mu = 0; mu < 4; mu++) ScalarUds(mu) = ScalarUmu(mu);
peekLocalSite(ScalarUmu, Uadj, lcoor);
for (int mu = 0; mu < 4; mu++) ScalarUds(mu + 4) = ScalarUmu(mu);
pokeLocalSite(ScalarUds, Uds, lcoor);
}
}
inline void DoubleStore(GridBase *GaugeGrid, DoubledGaugeField &Uds,const GaugeField &Umu)
{
SiteScalarGaugeField ScalarUmu;
SiteDoubledGaugeField ScalarUds;
GaugeLinkField U(Umu._grid);
GaugeField Uadj(Umu._grid);
for (int mu = 0; mu < Nd; mu++) {
U = PeekIndex<LorentzIndex>(Umu, mu);
U = adj(Cshift(U, mu, -1));
PokeIndex<LorentzIndex>(Uadj, U, mu);
}
for (int lidx = 0; lidx < GaugeGrid->lSites(); lidx++) {
std::vector<int> lcoor;
GaugeGrid->LocalIndexToLocalCoor(lidx, lcoor);
inline void InsertForce4D(GaugeField &mat, FermionField &Btilde,
FermionField &A, int mu) {
peekLocalSite(ScalarUmu, Umu, lcoor);
for (int mu = 0; mu < 4; mu++) ScalarUds(mu) = ScalarUmu(mu);
peekLocalSite(ScalarUmu, Uadj, lcoor);
for (int mu = 0; mu < 4; mu++) ScalarUds(mu + 4) = ScalarUmu(mu);
pokeLocalSite(ScalarUds, Uds, lcoor);
}
}
inline void InsertForce4D(GaugeField &mat, FermionField &Btilde,FermionField &A, int mu)
{
assert(0);
}
inline void InsertForce5D(GaugeField &mat, FermionField &Btilde,FermionField &Atilde, int mu)
{
assert(0);
}
inline void InsertForce5D(GaugeField &mat, FermionField &Btilde,
FermionField &Atilde, int mu) {
assert(0);
}
};
}
};
////////////////////////////////////////////////////////////////////////////////////////
// Flavour doubled spinors; is Gparity the only? what about C*?
////////////////////////////////////////////////////////////////////////////////////////
template <class S, int Nrepresentation,class _Coeff_t = RealD>
class GparityWilsonImpl
: public ConjugateGaugeImpl<GaugeImplTypes<S, Nrepresentation> > {
public:
static const int Dimension = Nrepresentation;
template <class S, int Nrepresentation,class _Coeff_t = RealD>
class GparityWilsonImpl : public ConjugateGaugeImpl<GaugeImplTypes<S, Nrepresentation> > {
public:
const bool LsVectorised=false;
static const int Dimension = Nrepresentation;
typedef _Coeff_t Coeff_t;
typedef ConjugateGaugeImpl< GaugeImplTypes<S,Nrepresentation> > Gimpl;
const bool LsVectorised=false;
typedef _Coeff_t Coeff_t;
typedef ConjugateGaugeImpl< GaugeImplTypes<S,Nrepresentation> > Gimpl;
INHERIT_GIMPL_TYPES(Gimpl);
INHERIT_GIMPL_TYPES(Gimpl);
template <typename vtype> using iImplSpinor = iVector<iVector<iVector<vtype, Nrepresentation>, Ns>, Ngp>;
template <typename vtype> using iImplHalfSpinor = iVector<iVector<iVector<vtype, Nrepresentation>, Nhs>, Ngp>;
template <typename vtype> using iImplDoubledGaugeField = iVector<iVector<iScalar<iMatrix<vtype, Nrepresentation> >, Nds>, Ngp>;
template <typename vtype>
using iImplSpinor =
iVector<iVector<iVector<vtype, Nrepresentation>, Ns>, Ngp>;
template <typename vtype>
using iImplHalfSpinor =
iVector<iVector<iVector<vtype, Nrepresentation>, Nhs>, Ngp>;
template <typename vtype>
using iImplDoubledGaugeField =
iVector<iVector<iScalar<iMatrix<vtype, Nrepresentation> >, Nds>, Ngp>;
typedef iImplSpinor<Simd> SiteSpinor;
typedef iImplHalfSpinor<Simd> SiteHalfSpinor;
typedef iImplDoubledGaugeField<Simd> SiteDoubledGaugeField;
typedef Lattice<SiteSpinor> FermionField;
typedef Lattice<SiteDoubledGaugeField> DoubledGaugeField;
typedef WilsonCompressor<SiteHalfSpinor, SiteSpinor> Compressor;
typedef WilsonStencil<SiteSpinor, SiteHalfSpinor> StencilImpl;
typedef GparityWilsonImplParams ImplParams;
typedef iImplSpinor<Simd> SiteSpinor;
typedef iImplHalfSpinor<Simd> SiteHalfSpinor;
typedef iImplDoubledGaugeField<Simd> SiteDoubledGaugeField;
typedef Lattice<SiteSpinor> FermionField;
typedef Lattice<SiteDoubledGaugeField> DoubledGaugeField;
typedef WilsonCompressor<SiteHalfSpinor, SiteSpinor> Compressor;
typedef WilsonStencil<SiteSpinor, SiteHalfSpinor> StencilImpl;
ImplParams Params;
typedef GparityWilsonImplParams ImplParams;
ImplParams Params;
GparityWilsonImpl(const ImplParams &p = ImplParams()) : Params(p){};
bool overlapCommsCompute(void) { return Params.overlapCommsCompute; };
GparityWilsonImpl(const ImplParams &p = ImplParams()) : Params(p){};
// provide the multiply by link that is differentiated between Gparity (with
// flavour index) and non-Gparity
inline void multLink(SiteHalfSpinor &phi, const SiteDoubledGaugeField &U,
const SiteHalfSpinor &chi, int mu, StencilEntry *SE,
StencilImpl &St) {
bool overlapCommsCompute(void) { return Params.overlapCommsCompute; };
// provide the multiply by link that is differentiated between Gparity (with
// flavour index) and non-Gparity
inline void multLink(SiteHalfSpinor &phi, const SiteDoubledGaugeField &U,
const SiteHalfSpinor &chi, int mu, StencilEntry *SE,
StencilImpl &St) {
typedef SiteHalfSpinor vobj;
typedef typename SiteHalfSpinor::scalar_object sobj;
typedef SiteHalfSpinor vobj;
typedef typename SiteHalfSpinor::scalar_object sobj;
vobj vtmp;
sobj stmp;
vobj vtmp;
sobj stmp;
GridBase *grid = St._grid;
GridBase *grid = St._grid;
const int Nsimd = grid->Nsimd();
const int Nsimd = grid->Nsimd();
int direction = St._directions[mu];
int distance = St._distances[mu];
int ptype = St._permute_type[mu];
int sl = St._grid->_simd_layout[direction];
int direction = St._directions[mu];
int distance = St._distances[mu];
int ptype = St._permute_type[mu];
int sl = St._grid->_simd_layout[direction];
// Fixme X.Y.Z.T hardcode in stencil
int mmu = mu % Nd;
// Fixme X.Y.Z.T hardcode in stencil
int mmu = mu % Nd;
// assert our assumptions
assert((distance == 1) || (distance == -1)); // nearest neighbour stencil hard code
assert((sl == 1) || (sl == 2));
std::vector<int> icoor;
// assert our assumptions
assert((distance == 1) || (distance == -1)); // nearest neighbour stencil hard code
assert((sl == 1) || (sl == 2));
std::vector<int> icoor;
if ( SE->_around_the_world && Params.twists[mmu] ) {
if ( SE->_around_the_world && Params.twists[mmu] ) {
if ( sl == 2 ) {
if ( sl == 2 ) {
std::vector<sobj> vals(Nsimd);
std::vector<sobj> vals(Nsimd);
extract(chi,vals);
for(int s=0;s<Nsimd;s++){
extract(chi,vals);
for(int s=0;s<Nsimd;s++){
grid->iCoorFromIindex(icoor,s);
grid->iCoorFromIindex(icoor,s);
assert((icoor[direction]==0)||(icoor[direction]==1));
assert((icoor[direction]==0)||(icoor[direction]==1));
int permute_lane;
if ( distance == 1) {
permute_lane = icoor[direction]?1:0;
} else {
permute_lane = icoor[direction]?0:1;
int permute_lane;
if ( distance == 1) {
permute_lane = icoor[direction]?1:0;
} else {
permute_lane = icoor[direction]?0:1;
}
if ( permute_lane ) {
stmp(0) = vals[s](1);
stmp(1) = vals[s](0);
vals[s] = stmp;
}
if ( permute_lane ) {
stmp(0) = vals[s](1);
stmp(1) = vals[s](0);
vals[s] = stmp;
}
}
merge(vtmp,vals);
}
merge(vtmp,vals);
} else {
vtmp(0) = chi(1);
vtmp(1) = chi(0);
}
mult(&phi(0),&U(0)(mu),&vtmp(0));
mult(&phi(1),&U(1)(mu),&vtmp(1));
} else {
mult(&phi(0),&U(0)(mu),&chi(0));
mult(&phi(1),&U(1)(mu),&chi(1));
}
}
} else {
vtmp(0) = chi(1);
vtmp(1) = chi(0);
}
mult(&phi(0),&U(0)(mu),&vtmp(0));
mult(&phi(1),&U(1)(mu),&vtmp(1));
} else {
mult(&phi(0),&U(0)(mu),&chi(0));
mult(&phi(1),&U(1)(mu),&chi(1));
}
inline void DoubleStore(GridBase *GaugeGrid,DoubledGaugeField &Uds,const GaugeField &Umu)
{
conformable(Uds._grid,GaugeGrid);
conformable(Umu._grid,GaugeGrid);
GaugeLinkField Utmp (GaugeGrid);
GaugeLinkField U (GaugeGrid);
GaugeLinkField Uconj(GaugeGrid);
Lattice<iScalar<vInteger> > coor(GaugeGrid);
}
inline void DoubleStore(GridBase *GaugeGrid,DoubledGaugeField &Uds,const GaugeField &Umu)
{
conformable(Uds._grid,GaugeGrid);
conformable(Umu._grid,GaugeGrid);
GaugeLinkField Utmp (GaugeGrid);
GaugeLinkField U (GaugeGrid);
GaugeLinkField Uconj(GaugeGrid);
Lattice<iScalar<vInteger> > coor(GaugeGrid);
for(int mu=0;mu<Nd;mu++){
for(int mu=0;mu<Nd;mu++){
LatticeCoordinate(coor,mu);
LatticeCoordinate(coor,mu);
U = PeekIndex<LorentzIndex>(Umu,mu);
Uconj = conjugate(U);
U = PeekIndex<LorentzIndex>(Umu,mu);
Uconj = conjugate(U);
// This phase could come from a simple bc 1,1,-1,1 ..
int neglink = GaugeGrid->GlobalDimensions()[mu]-1;
if ( Params.twists[mu] ) {
Uconj = where(coor==neglink,-Uconj,Uconj);
}
// This phase could come from a simple bc 1,1,-1,1 ..
int neglink = GaugeGrid->GlobalDimensions()[mu]-1;
if ( Params.twists[mu] ) {
Uconj = where(coor==neglink,-Uconj,Uconj);
}
PARALLEL_FOR_LOOP
for(auto ss=U.begin();ss<U.end();ss++){
Uds[ss](0)(mu) = U[ss]();
Uds[ss](1)(mu) = Uconj[ss]();
}
U = adj(Cshift(U ,mu,-1)); // correct except for spanning the boundary
Uconj = adj(Cshift(Uconj,mu,-1));
Utmp = U;
if ( Params.twists[mu] ) {
Utmp = where(coor==0,Uconj,Utmp);
}
PARALLEL_FOR_LOOP
for(auto ss=U.begin();ss<U.end();ss++){
Uds[ss](0)(mu) = U[ss]();
Uds[ss](1)(mu) = Uconj[ss]();
}
PARALLEL_FOR_LOOP
for(auto ss=U.begin();ss<U.end();ss++){
Uds[ss](0)(mu+4) = Utmp[ss]();
}
U = adj(Cshift(U ,mu,-1)); // correct except for spanning the boundary
Uconj = adj(Cshift(Uconj,mu,-1));
Utmp = Uconj;
if ( Params.twists[mu] ) {
Utmp = where(coor==0,U,Utmp);
}
Utmp = U;
if ( Params.twists[mu] ) {
Utmp = where(coor==0,Uconj,Utmp);
}
PARALLEL_FOR_LOOP
for(auto ss=U.begin();ss<U.end();ss++){
Uds[ss](1)(mu+4) = Utmp[ss]();
}
PARALLEL_FOR_LOOP
for(auto ss=U.begin();ss<U.end();ss++){
Uds[ss](0)(mu+4) = Utmp[ss]();
}
Utmp = Uconj;
if ( Params.twists[mu] ) {
Utmp = where(coor==0,U,Utmp);
}
PARALLEL_FOR_LOOP
for(auto ss=U.begin();ss<U.end();ss++){
Uds[ss](1)(mu+4) = Utmp[ss]();
}
}
}
}
}
inline void InsertForce4D(GaugeField &mat, FermionField &Btilde,
FermionField &A, int mu) {
// DhopDir provides U or Uconj depending on coor/flavour.
GaugeLinkField link(mat._grid);
// use lorentz for flavour as hack.
auto tmp = TraceIndex<SpinIndex>(outerProduct(Btilde, A));
PARALLEL_FOR_LOOP
for (auto ss = tmp.begin(); ss < tmp.end(); ss++) {
link[ss]() = tmp[ss](0, 0) - conjugate(tmp[ss](1, 1));
}
PokeIndex<LorentzIndex>(mat, link, mu);
return;
}
inline void InsertForce4D(GaugeField &mat, FermionField &Btilde, FermionField &A, int mu) {
// DhopDir provides U or Uconj depending on coor/flavour.
GaugeLinkField link(mat._grid);
// use lorentz for flavour as hack.
auto tmp = TraceIndex<SpinIndex>(outerProduct(Btilde, A));
PARALLEL_FOR_LOOP
for (auto ss = tmp.begin(); ss < tmp.end(); ss++) {
link[ss]() = tmp[ss](0, 0) - conjugate(tmp[ss](1, 1));
}
PokeIndex<LorentzIndex>(mat, link, mu);
return;
}
inline void InsertForce5D(GaugeField &mat, FermionField &Btilde,
FermionField &Atilde, int mu) {
int Ls = Btilde._grid->_fdimensions[0];
inline void InsertForce5D(GaugeField &mat, FermionField &Btilde, FermionField &Atilde, int mu) {
int Ls = Btilde._grid->_fdimensions[0];
GaugeLinkField tmp(mat._grid);
tmp = zero;
PARALLEL_FOR_LOOP
for (int ss = 0; ss < tmp._grid->oSites(); ss++) {
for (int s = 0; s < Ls; s++) {
int sF = s + Ls * ss;
auto ttmp = traceIndex<SpinIndex>(outerProduct(Btilde[sF], Atilde[sF]));
tmp[ss]() = tmp[ss]() + ttmp(0, 0) + conjugate(ttmp(1, 1));
}
}
PokeIndex<LorentzIndex>(mat, tmp, mu);
return;
}
};
GaugeLinkField tmp(mat._grid);
tmp = zero;
PARALLEL_FOR_LOOP
for (int ss = 0; ss < tmp._grid->oSites(); ss++) {
for (int s = 0; s < Ls; s++) {
int sF = s + Ls * ss;
auto ttmp = traceIndex<SpinIndex>(outerProduct(Btilde[sF], Atilde[sF]));
tmp[ss]() = tmp[ss]() + ttmp(0, 0) + conjugate(ttmp(1, 1));
}
}
PokeIndex<LorentzIndex>(mat, tmp, mu);
return;
}
typedef WilsonImpl<vComplex, FundamentalRepresentation > WilsonImplR; // Real.. whichever prec
typedef WilsonImpl<vComplexF, FundamentalRepresentation > WilsonImplF; // Float
typedef WilsonImpl<vComplexD, FundamentalRepresentation > WilsonImplD; // Double
};
typedef WilsonImpl<vComplex, FundamentalRepresentation > WilsonImplR; // Real.. whichever prec
typedef WilsonImpl<vComplexF, FundamentalRepresentation > WilsonImplF; // Float
typedef WilsonImpl<vComplexD, FundamentalRepresentation > WilsonImplD; // Double
typedef WilsonImpl<vComplex, FundamentalRepresentation, ComplexD > ZWilsonImplR; // Real.. whichever prec
typedef WilsonImpl<vComplexF, FundamentalRepresentation, ComplexD > ZWilsonImplF; // Float
typedef WilsonImpl<vComplexD, FundamentalRepresentation, ComplexD > ZWilsonImplD; // Double
typedef WilsonImpl<vComplex, FundamentalRepresentation, ComplexD > ZWilsonImplR; // Real.. whichever prec
typedef WilsonImpl<vComplexF, FundamentalRepresentation, ComplexD > ZWilsonImplF; // Float
typedef WilsonImpl<vComplexD, FundamentalRepresentation, ComplexD > ZWilsonImplD; // Double
typedef WilsonImpl<vComplex, AdjointRepresentation > WilsonAdjImplR; // Real.. whichever prec
typedef WilsonImpl<vComplexF, AdjointRepresentation > WilsonAdjImplF; // Float
typedef WilsonImpl<vComplexD, AdjointRepresentation > WilsonAdjImplD; // Double
typedef WilsonImpl<vComplex, TwoIndexSymmetricRepresentation > WilsonTwoIndexSymmetricImplR; // Real.. whichever prec
typedef WilsonImpl<vComplexF, TwoIndexSymmetricRepresentation > WilsonTwoIndexSymmetricImplF; // Float
typedef WilsonImpl<vComplexD, TwoIndexSymmetricRepresentation > WilsonTwoIndexSymmetricImplD; // Double
typedef DomainWallVec5dImpl<vComplex ,Nc> DomainWallVec5dImplR; // Real.. whichever prec
typedef DomainWallVec5dImpl<vComplexF,Nc> DomainWallVec5dImplF; // Float
typedef DomainWallVec5dImpl<vComplexD,Nc> DomainWallVec5dImplD; // Double
typedef DomainWallVec5dImpl<vComplex ,Nc,ComplexD> ZDomainWallVec5dImplR; // Real.. whichever prec
typedef DomainWallVec5dImpl<vComplexF,Nc,ComplexD> ZDomainWallVec5dImplF; // Float
typedef DomainWallVec5dImpl<vComplexD,Nc,ComplexD> ZDomainWallVec5dImplD; // Double
typedef GparityWilsonImpl<vComplex , Nc> GparityWilsonImplR; // Real.. whichever prec
typedef GparityWilsonImpl<vComplexF, Nc> GparityWilsonImplF; // Float
typedef GparityWilsonImpl<vComplexD, Nc> GparityWilsonImplD; // Double
typedef WilsonImpl<vComplex, AdjointRepresentation > WilsonAdjImplR; // Real.. whichever prec
typedef WilsonImpl<vComplexF, AdjointRepresentation > WilsonAdjImplF; // Float
typedef WilsonImpl<vComplexD, AdjointRepresentation > WilsonAdjImplD; // Double
}}
typedef WilsonImpl<vComplex, TwoIndexSymmetricRepresentation > WilsonTwoIndexSymmetricImplR; // Real.. whichever prec
typedef WilsonImpl<vComplexF, TwoIndexSymmetricRepresentation > WilsonTwoIndexSymmetricImplF; // Float
typedef WilsonImpl<vComplexD, TwoIndexSymmetricRepresentation > WilsonTwoIndexSymmetricImplD; // Double
typedef DomainWallVec5dImpl<vComplex ,Nc> DomainWallVec5dImplR; // Real.. whichever prec
typedef DomainWallVec5dImpl<vComplexF,Nc> DomainWallVec5dImplF; // Float
typedef DomainWallVec5dImpl<vComplexD,Nc> DomainWallVec5dImplD; // Double
typedef DomainWallVec5dImpl<vComplex ,Nc,ComplexD> ZDomainWallVec5dImplR; // Real.. whichever prec
typedef DomainWallVec5dImpl<vComplexF,Nc,ComplexD> ZDomainWallVec5dImplF; // Float
typedef DomainWallVec5dImpl<vComplexD,Nc,ComplexD> ZDomainWallVec5dImplD; // Double
typedef GparityWilsonImpl<vComplex, Nc> GparityWilsonImplR; // Real.. whichever prec
typedef GparityWilsonImpl<vComplexF, Nc> GparityWilsonImplF; // Float
typedef GparityWilsonImpl<vComplexD, Nc> GparityWilsonImplD; // Double
}
}
#endif

6
lib/qcd/action/fermion/OverlapWilsonCayleyTanhFermion.h
View File

@ -42,7 +42,11 @@ namespace Grid {
INHERIT_IMPL_TYPES(Impl);
public:
// Constructors
void MomentumSpacePropagator(FermionField &out,const FermionField &in,RealD _m) {
this->MomentumSpacePropagatorHw(out,in,_m);
};
// Constructors
OverlapWilsonCayleyTanhFermion(GaugeField &_Umu,
GridCartesian &FiveDimGrid,
GridRedBlackCartesian &FiveDimRedBlackGrid,

108
lib/qcd/action/fermion/WilsonFermion.cc
View File

@ -101,6 +101,7 @@ void WilsonFermion<Impl>::Meooe(const FermionField &in, FermionField &out) {
DhopOE(in, out, DaggerNo);
}
}
template <class Impl>
void WilsonFermion<Impl>::MeooeDag(const FermionField &in, FermionField &out) {
if (in.checkerboard == Odd) {
@ -109,32 +110,87 @@ void WilsonFermion<Impl>::MeooeDag(const FermionField &in, FermionField &out) {
DhopOE(in, out, DaggerYes);
}
}
template <class Impl>
void WilsonFermion<Impl>::Mooee(const FermionField &in, FermionField &out) {
out.checkerboard = in.checkerboard;
typename FermionField::scalar_type scal(4.0 + mass);
out = scal * in;
}
template <class Impl>
void WilsonFermion<Impl>::Mooee(const FermionField &in, FermionField &out) {
out.checkerboard = in.checkerboard;
typename FermionField::scalar_type scal(4.0 + mass);
out = scal * in;
}
template <class Impl>
void WilsonFermion<Impl>::MooeeDag(const FermionField &in, FermionField &out) {
out.checkerboard = in.checkerboard;
Mooee(in, out);
}
template <class Impl>
void WilsonFermion<Impl>::MooeeDag(const FermionField &in, FermionField &out) {
out.checkerboard = in.checkerboard;
Mooee(in, out);
}
template<class Impl>
void WilsonFermion<Impl>::MooeeInv(const FermionField &in, FermionField &out) {
out.checkerboard = in.checkerboard;
out = (1.0/(4.0+mass))*in;
}
template<class Impl>
void WilsonFermion<Impl>::MooeeInvDag(const FermionField &in, FermionField &out) {
out.checkerboard = in.checkerboard;
MooeeInv(in,out);
}
template <class Impl>
void WilsonFermion<Impl>::MooeeInv(const FermionField &in, FermionField &out) {
out.checkerboard = in.checkerboard;
out = (1.0 / (4.0 + mass)) * in;
}
template<class Impl>
void WilsonFermion<Impl>::MomentumSpacePropagator(FermionField &out, const FermionField &in,RealD _m) {
template <class Impl>
void WilsonFermion<Impl>::MooeeInvDag(const FermionField &in,
FermionField &out) {
out.checkerboard = in.checkerboard;
MooeeInv(in, out);
}
// what type LatticeComplex
conformable(_grid,out._grid);
typedef typename FermionField::vector_type vector_type;
typedef typename FermionField::scalar_type ScalComplex;
typedef Lattice<iSinglet<vector_type> > LatComplex;
Gamma::GammaMatrix Gmu [] = {
Gamma::GammaX,
Gamma::GammaY,
Gamma::GammaZ,
Gamma::GammaT
};
std::vector<int> latt_size = _grid->_fdimensions;
FermionField num (_grid); num = zero;
LatComplex wilson(_grid); wilson= zero;
LatComplex one (_grid); one = ScalComplex(1.0,0.0);
LatComplex denom(_grid); denom= zero;
LatComplex kmu(_grid);
ScalComplex ci(0.0,1.0);
// momphase = n * 2pi / L
for(int mu=0;mu<Nd;mu++) {
LatticeCoordinate(kmu,mu);
RealD TwoPiL = M_PI * 2.0/ latt_size[mu];
kmu = TwoPiL * kmu;
wilson = wilson + 2.0*sin(kmu*0.5)*sin(kmu*0.5); // Wilson term
num = num - sin(kmu)*ci*(Gamma(Gmu[mu])*in); // derivative term
denom=denom + sin(kmu)*sin(kmu);
}
wilson = wilson + _m; // 2 sin^2 k/2 + m
num = num + wilson*in; // -i gmu sin k + 2 sin^2 k/2 + m
denom= denom+wilson*wilson; // sin^2 k + (2 sin^2 k/2 + m)^2
denom= one/denom;
out = num*denom; // [ -i gmu sin k + 2 sin^2 k/2 + m] / [ sin^2 k + (2 sin^2 k/2 + m)^2 ]
}
///////////////////////////////////
// Internal
@ -166,7 +222,7 @@ void WilsonFermion<Impl>::DerivInternal(StencilImpl &st, DoubledGaugeField &U,
////////////////////////
PARALLEL_FOR_LOOP
for (int sss = 0; sss < B._grid->oSites(); sss++) {
Kernels::DiracOptDhopDir(st, U, st.comm_buf, sss, sss, B, Btilde, mu,
Kernels::DiracOptDhopDir(st, U, st.CommBuf(), sss, sss, B, Btilde, mu,
gamma);
}
@ -277,7 +333,7 @@ void WilsonFermion<Impl>::DhopDirDisp(const FermionField &in, FermionField &out,
PARALLEL_FOR_LOOP
for (int sss = 0; sss < in._grid->oSites(); sss++) {
Kernels::DiracOptDhopDir(Stencil, Umu, Stencil.comm_buf, sss, sss, in, out,
Kernels::DiracOptDhopDir(Stencil, Umu, Stencil.CommBuf(), sss, sss, in, out,
dirdisp, gamma);
}
};
@ -295,13 +351,13 @@ void WilsonFermion<Impl>::DhopInternal(StencilImpl &st, LebesgueOrder &lo,
if (dag == DaggerYes) {
PARALLEL_FOR_LOOP
for (int sss = 0; sss < in._grid->oSites(); sss++) {
Kernels::DiracOptDhopSiteDag(st, lo, U, st.comm_buf, sss, sss, 1, 1, in,
Kernels::DiracOptDhopSiteDag(st, lo, U, st.CommBuf(), sss, sss, 1, 1, in,
out);
}
} else {
PARALLEL_FOR_LOOP
for (int sss = 0; sss < in._grid->oSites(); sss++) {
Kernels::DiracOptDhopSite(st, lo, U, st.comm_buf, sss, sss, 1, 1, in,
Kernels::DiracOptDhopSite(st, lo, U, st.CommBuf(), sss, sss, 1, 1, in,
out);
}
}

11
lib/qcd/action/fermion/WilsonFermion.h
View File

@ -78,16 +78,15 @@ class WilsonFermion : public WilsonKernels<Impl>, public WilsonFermionStatic {
virtual void MooeeInv(const FermionField &in, FermionField &out);
virtual void MooeeInvDag(const FermionField &in, FermionField &out);
virtual void MomentumSpacePropagator(FermionField &out,const FermionField &in,RealD _mass) ;
////////////////////////
// Derivative interface
////////////////////////
// Interface calls an internal routine
void DhopDeriv(GaugeField &mat, const FermionField &U, const FermionField &V,
int dag);
void DhopDerivOE(GaugeField &mat, const FermionField &U,
const FermionField &V, int dag);
void DhopDerivEO(GaugeField &mat, const FermionField &U,
const FermionField &V, int dag);
void DhopDeriv(GaugeField &mat,const FermionField &U,const FermionField &V,int dag);
void DhopDerivOE(GaugeField &mat,const FermionField &U,const FermionField &V,int dag);
void DhopDerivEO(GaugeField &mat,const FermionField &U,const FermionField &V,int dag);
///////////////////////////////////////////////////////////////
// non-hermitian hopping term; half cb or both

253
lib/qcd/action/fermion/WilsonFermion5D.cc
View File

@ -184,44 +184,37 @@ void WilsonFermion5D<Impl>::Report(void)
if ( DhopCalls > 0 ) {
std::cout << GridLogMessage << "#### Dhop calls report " << std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Number of Dhop Calls : " << DhopCalls << std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Total Communication time : " << DhopCommTime
<< " us" << std::endl;
std::cout << GridLogMessage << "WilsonFermion5D CommTime/Calls : "
<< DhopCommTime / DhopCalls << " us" << std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Total Compute time : "
<< DhopComputeTime << " us" << std::endl;
std::cout << GridLogMessage << "WilsonFermion5D ComputeTime/Calls : "
<< DhopComputeTime / DhopCalls << " us" << std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Number of Dhop Calls : " << DhopCalls << std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Total Communication time : " << DhopCommTime<< " us" << std::endl;
std::cout << GridLogMessage << "WilsonFermion5D CommTime/Calls : " << DhopCommTime / DhopCalls << " us" << std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Total Compute time : " << DhopComputeTime << " us" << std::endl;
std::cout << GridLogMessage << "WilsonFermion5D ComputeTime/Calls : " << DhopComputeTime / DhopCalls << " us" << std::endl;
RealD mflops = 1344*volume*DhopCalls/DhopComputeTime;
RealD mflops = 1344*volume*DhopCalls/DhopComputeTime/2; // 2 for red black counting
std::cout << GridLogMessage << "Average mflops/s per call : " << mflops << std::endl;
std::cout << GridLogMessage << "Average mflops/s per call per node : " << mflops/NP << std::endl;
std::cout << GridLogMessage << "Average mflops/s per call per rank : " << mflops/NP << std::endl;
}
if ( DerivCalls > 0 ) {
std::cout << GridLogMessage << "#### Deriv calls report "<< std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Number of Deriv Calls : " <<DerivCalls <<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Total Communication time : " <<DerivCommTime <<" us"<<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D CommTime/Calls : " <<DerivCommTime/DerivCalls<<" us" <<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Total Compute time : " <<DerivComputeTime <<" us"<<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D ComputeTime/Calls : " <<DerivComputeTime/DerivCalls<<" us" <<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Total Dhop Compute time : " <<DerivDhopComputeTime <<" us"<<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Dhop ComputeTime/Calls : " <<DerivDhopComputeTime/DerivCalls<<" us" <<std::endl;
RealD mflops = 144*volume*DerivCalls/DerivDhopComputeTime;
std::cout << GridLogMessage << "Average mflops/s per call : " << mflops << std::endl;
std::cout << GridLogMessage << "Average mflops/s per call per node : " << mflops/NP << std::endl;
std::cout << GridLogMessage << "#### Deriv calls report "<< std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Number of Deriv Calls : " <<DerivCalls <<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Total Communication time : " <<DerivCommTime <<" us"<<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D CommTime/Calls : " <<DerivCommTime/DerivCalls<<" us" <<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Total Compute time : " <<DerivComputeTime <<" us"<<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D ComputeTime/Calls : " <<DerivComputeTime/DerivCalls<<" us" <<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Total Dhop Compute time : " <<DerivDhopComputeTime <<" us"<<std::endl;
std::cout << GridLogMessage << "WilsonFermion5D Dhop ComputeTime/Calls : " <<DerivDhopComputeTime/DerivCalls<<" us" <<std::endl;
RealD mflops = 144*volume*DerivCalls/DerivDhopComputeTime;
std::cout << GridLogMessage << "Average mflops/s per call : " << mflops << std::endl;
std::cout << GridLogMessage << "Average mflops/s per call per node : " << mflops/NP << std::endl;
}
if (DerivCalls > 0 || DhopCalls > 0){
std::cout << GridLogMessage << "WilsonFermion5D Stencil"<<std::endl; Stencil.Report();
std::cout << GridLogMessage << "WilsonFermion5D StencilEven"<<std::endl; StencilEven.Report();
std::cout << GridLogMessage << "WilsonFermion5D StencilOdd"<<std::endl; StencilOdd.Report();
std::cout << GridLogMessage << "WilsonFermion5D Stencil"<<std::endl; Stencil.Report();
std::cout << GridLogMessage << "WilsonFermion5D StencilEven"<<std::endl; StencilEven.Report();
std::cout << GridLogMessage << "WilsonFermion5D StencilOdd"<<std::endl; StencilOdd.Report();
}
}
@ -275,7 +268,7 @@ PARALLEL_FOR_LOOP
for(int s=0;s<Ls;s++){
int sU=ss;
int sF = s+Ls*sU;
Kernels::DiracOptDhopDir(Stencil,Umu,Stencil.comm_buf,sF,sU,in,out,dirdisp,gamma);
Kernels::DiracOptDhopDir(Stencil,Umu,Stencil.CommBuf(),sF,sU,in,out,dirdisp,gamma);
}
}
};
@ -327,8 +320,7 @@ void WilsonFermion5D<Impl>::DerivInternal(StencilImpl & st,
assert(sF < B._grid->oSites());
assert(sU < U._grid->oSites());
Kernels::DiracOptDhopDir(st, U, st.comm_buf, sF, sU, B, Btilde, mu,
gamma);
Kernels::DiracOptDhopDir(st, U, st.CommBuf(), sF, sU, B, Btilde, mu, gamma);
////////////////////////////
// spin trace outer product
@ -342,10 +334,10 @@ void WilsonFermion5D<Impl>::DerivInternal(StencilImpl & st,
}
template<class Impl>
void WilsonFermion5D<Impl>::DhopDeriv( GaugeField &mat,
const FermionField &A,
const FermionField &B,
int dag)
void WilsonFermion5D<Impl>::DhopDeriv(GaugeField &mat,
const FermionField &A,
const FermionField &B,
int dag)
{
conformable(A._grid,FermionGrid());
conformable(A._grid,B._grid);
@ -358,9 +350,9 @@ void WilsonFermion5D<Impl>::DhopDeriv( GaugeField &mat,
template<class Impl>
void WilsonFermion5D<Impl>::DhopDerivEO(GaugeField &mat,
const FermionField &A,
const FermionField &B,
int dag)
const FermionField &A,
const FermionField &B,
int dag)
{
conformable(A._grid,FermionRedBlackGrid());
conformable(GaugeRedBlackGrid(),mat._grid);
@ -376,9 +368,9 @@ void WilsonFermion5D<Impl>::DhopDerivEO(GaugeField &mat,
template<class Impl>
void WilsonFermion5D<Impl>::DhopDerivOE(GaugeField &mat,
const FermionField &A,
const FermionField &B,
int dag)
const FermionField &A,
const FermionField &B,
int dag)
{
conformable(A._grid,FermionRedBlackGrid());
conformable(GaugeRedBlackGrid(),mat._grid);
@ -393,10 +385,9 @@ void WilsonFermion5D<Impl>::DhopDerivOE(GaugeField &mat,
template<class Impl>
void WilsonFermion5D<Impl>::DhopInternal(StencilImpl & st, LebesgueOrder &lo,
DoubledGaugeField & U,
const FermionField &in, FermionField &out,int dag)
DoubledGaugeField & U,
const FermionField &in, FermionField &out,int dag)
{
DhopCalls++;
// assert((dag==DaggerNo) ||(dag==DaggerYes));
Compressor compressor(dag);
@ -413,16 +404,35 @@ void WilsonFermion5D<Impl>::DhopInternal(StencilImpl & st, LebesgueOrder &lo,
for (int ss = 0; ss < U._grid->oSites(); ss++) {
int sU = ss;
int sF = LLs * sU;
Kernels::DiracOptDhopSiteDag(st, lo, U, st.comm_buf, sF, sU, LLs, 1, in,
out);
Kernels::DiracOptDhopSiteDag(st, lo, U, st.CommBuf(), sF, sU, LLs, 1, in, out);
}
#ifdef AVX512
} else if (stat.is_init() ) {
int nthreads;
stat.start();
#pragma omp parallel
{
#pragma omp master
nthreads = omp_get_num_threads();
int mythread = omp_get_thread_num();
stat.enter(mythread);
#pragma omp for nowait
for(int ss=0;ss<U._grid->oSites();ss++) {
int sU=ss;
int sF=LLs*sU;
Kernels::DiracOptDhopSite(st,lo,U,st.CommBuf(),sF,sU,LLs,1,in,out);
}
stat.exit(mythread);
}
stat.accum(nthreads);
#endif
} else {
PARALLEL_FOR_LOOP
for (int ss = 0; ss < U._grid->oSites(); ss++) {
int sU = ss;
int sF = LLs * sU;
Kernels::DiracOptDhopSite(st, lo, U, st.comm_buf, sF, sU, LLs, 1, in,
out);
Kernels::DiracOptDhopSite(st,lo,U,st.CommBuf(),sF,sU,LLs,1,in,out);
}
}
DhopComputeTime+=usecond();
@ -432,6 +442,7 @@ void WilsonFermion5D<Impl>::DhopInternal(StencilImpl & st, LebesgueOrder &lo,
template<class Impl>
void WilsonFermion5D<Impl>::DhopOE(const FermionField &in, FermionField &out,int dag)
{
DhopCalls++;
conformable(in._grid,FermionRedBlackGrid()); // verifies half grid
conformable(in._grid,out._grid); // drops the cb check
@ -443,6 +454,7 @@ void WilsonFermion5D<Impl>::DhopOE(const FermionField &in, FermionField &out,int
template<class Impl>
void WilsonFermion5D<Impl>::DhopEO(const FermionField &in, FermionField &out,int dag)
{
DhopCalls++;
conformable(in._grid,FermionRedBlackGrid()); // verifies half grid
conformable(in._grid,out._grid); // drops the cb check
@ -454,6 +466,7 @@ void WilsonFermion5D<Impl>::DhopEO(const FermionField &in, FermionField &out,int
template<class Impl>
void WilsonFermion5D<Impl>::Dhop(const FermionField &in, FermionField &out,int dag)
{
DhopCalls+=2;
conformable(in._grid,FermionGrid()); // verifies full grid
conformable(in._grid,out._grid);
@ -469,6 +482,148 @@ void WilsonFermion5D<Impl>::DW(const FermionField &in, FermionField &out,int dag
axpy(out,4.0-M5,in,out);
}
template<class Impl>
void WilsonFermion5D<Impl>::MomentumSpacePropagatorHt(FermionField &out,const FermionField &in, RealD mass)
{
// what type LatticeComplex
GridBase *_grid = _FourDimGrid;
conformable(_grid,out._grid);
typedef typename FermionField::vector_type vector_type;
typedef typename FermionField::scalar_type ScalComplex;
typedef iSinglet<ScalComplex> Tcomplex;
typedef Lattice<iSinglet<vector_type> > LatComplex;
Gamma::GammaMatrix Gmu [] = {
Gamma::GammaX,
Gamma::GammaY,
Gamma::GammaZ,
Gamma::GammaT
};
std::vector<int> latt_size = _grid->_fdimensions;
FermionField num (_grid); num = zero;
LatComplex sk(_grid); sk = zero;
LatComplex sk2(_grid); sk2= zero;
LatComplex W(_grid); W= zero;
LatComplex a(_grid); a= zero;
LatComplex one (_grid); one = ScalComplex(1.0,0.0);
LatComplex denom(_grid); denom= zero;
LatComplex cosha(_grid);
LatComplex kmu(_grid);
LatComplex Wea(_grid);
LatComplex Wema(_grid);
ScalComplex ci(0.0,1.0);
for(int mu=0;mu<Nd;mu++) {
LatticeCoordinate(kmu,mu);
RealD TwoPiL = M_PI * 2.0/ latt_size[mu];
kmu = TwoPiL * kmu;
sk2 = sk2 + 2.0*sin(kmu*0.5)*sin(kmu*0.5);
sk = sk + sin(kmu) *sin(kmu);
num = num - sin(kmu)*ci*(Gamma(Gmu[mu])*in);
}
W = one - M5 + sk2;
////////////////////////////////////////////
// Cosh alpha -> alpha
////////////////////////////////////////////
cosha = (one + W*W + sk) / (W*2.0);
// FIXME Need a Lattice acosh
for(int idx=0;idx<_grid->lSites();idx++){
std::vector<int> lcoor(Nd);
Tcomplex cc;
RealD sgn;
_grid->LocalIndexToLocalCoor(idx,lcoor);
peekLocalSite(cc,cosha,lcoor);
assert((double)real(cc)>=1.0);
assert(fabs((double)imag(cc))<=1.0e-15);
cc = ScalComplex(::acosh(real(cc)),0.0);
pokeLocalSite(cc,a,lcoor);
}
Wea = ( exp( a) * W );
Wema= ( exp(-a) * W );
num = num + ( one - Wema ) * mass * in;
denom= ( Wea - one ) + mass*mass * (one - Wema);
out = num/denom;
}
template<class Impl>
void WilsonFermion5D<Impl>::MomentumSpacePropagatorHw(FermionField &out,const FermionField &in,RealD mass)
{
Gamma::GammaMatrix Gmu [] = {
Gamma::GammaX,
Gamma::GammaY,
Gamma::GammaZ,
Gamma::GammaT
};
GridBase *_grid = _FourDimGrid;
conformable(_grid,out._grid);
typedef typename FermionField::vector_type vector_type;
typedef typename FermionField::scalar_type ScalComplex;
typedef Lattice<iSinglet<vector_type> > LatComplex;
std::vector<int> latt_size = _grid->_fdimensions;
LatComplex sk(_grid); sk = zero;
LatComplex sk2(_grid); sk2= zero;
LatComplex w_k(_grid); w_k= zero;
LatComplex b_k(_grid); b_k= zero;
LatComplex one (_grid); one = ScalComplex(1.0,0.0);
FermionField num (_grid); num = zero;
LatComplex denom(_grid); denom= zero;
LatComplex kmu(_grid);
ScalComplex ci(0.0,1.0);
for(int mu=0;mu<Nd;mu++) {
LatticeCoordinate(kmu,mu);
RealD TwoPiL = M_PI * 2.0/ latt_size[mu];
kmu = TwoPiL * kmu;
sk2 = sk2 + 2.0*sin(kmu*0.5)*sin(kmu*0.5);
sk = sk + sin(kmu)*sin(kmu);
num = num - sin(kmu)*ci*(Gamma(Gmu[mu])*in);
}
num = num + mass * in ;
b_k = sk2 - M5;
w_k = sqrt(sk + b_k*b_k);
denom= ( w_k + b_k + mass*mass) ;
denom= one/denom;
out = num*denom;
}
FermOpTemplateInstantiate(WilsonFermion5D);
GparityFermOpTemplateInstantiate(WilsonFermion5D);

162
lib/qcd/action/fermion/WilsonFermion5D.h
View File

@ -31,9 +31,21 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
#ifndef GRID_QCD_WILSON_FERMION_5D_H
#define GRID_QCD_WILSON_FERMION_5D_H
namespace Grid {
#include <Grid/Stat.h>
namespace QCD {
namespace Grid {
namespace QCD {
////////////////////////////////////////////////////////////////////////////////
// This is the 4d red black case appropriate to support
//
// parity = (x+y+z+t)|2;
// generalised five dim fermions like mobius, zolotarev etc..
//
// i.e. even even contains fifth dim hopping term.
//
// [DIFFERS from original CPS red black implementation parity = (x+y+z+t+s)|2 ]
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// This is the 4d red black case appropriate to support
@ -60,6 +72,7 @@ namespace Grid {
public:
INHERIT_IMPL_TYPES(Impl);
typedef WilsonKernels<Impl> Kernels;
PmuStat stat;
void Report(void);
void ZeroCounters(void);
@ -99,6 +112,9 @@ namespace Grid {
virtual void DhopDerivEO(GaugeField &mat,const FermionField &U,const FermionField &V,int dag);
virtual void DhopDerivOE(GaugeField &mat,const FermionField &U,const FermionField &V,int dag);
void MomentumSpacePropagatorHt(FermionField &out,const FermionField &in,RealD mass) ;
void MomentumSpacePropagatorHw(FermionField &out,const FermionField &in,RealD mass) ;
// Implement hopping term non-hermitian hopping term; half cb or both
// Implement s-diagonal DW
void DW (const FermionField &in, FermionField &out,int dag);
@ -108,78 +124,78 @@ namespace Grid {
// add a DhopComm
// -- suboptimal interface will presently trigger multiple comms.
void DhopDir(const FermionField &in, FermionField &out,int dir,int disp);
///////////////////////////////////////////////////////////////
// New methods added
///////////////////////////////////////////////////////////////
void DerivInternal(StencilImpl & st,
DoubledGaugeField & U,
GaugeField &mat,
const FermionField &A,
const FermionField &B,
int dag);
void DhopInternal(StencilImpl & st,
LebesgueOrder &lo,
DoubledGaugeField &U,
const FermionField &in,
FermionField &out,
int dag);
// Constructors
WilsonFermion5D(GaugeField &_Umu,
GridCartesian &FiveDimGrid,
GridRedBlackCartesian &FiveDimRedBlackGrid,
GridCartesian &FourDimGrid,
GridRedBlackCartesian &FourDimRedBlackGrid,
double _M5,const ImplParams &p= ImplParams());
// Constructors
/*
void DhopDir(const FermionField &in, FermionField &out,int dir,int disp);
///////////////////////////////////////////////////////////////
// New methods added
///////////////////////////////////////////////////////////////
void DerivInternal(StencilImpl & st,
DoubledGaugeField & U,
GaugeField &mat,
const FermionField &A,
const FermionField &B,
int dag);
void DhopInternal(StencilImpl & st,
LebesgueOrder &lo,
DoubledGaugeField &U,
const FermionField &in,
FermionField &out,
int dag);
// Constructors
WilsonFermion5D(GaugeField &_Umu,
GridCartesian &FiveDimGrid,
GridRedBlackCartesian &FiveDimRedBlackGrid,
GridCartesian &FourDimGrid,
GridRedBlackCartesian &FourDimRedBlackGrid,
double _M5,const ImplParams &p= ImplParams());
// Constructors
/*
WilsonFermion5D(int simd,
GaugeField &_Umu,
GridCartesian &FiveDimGrid,
GridRedBlackCartesian &FiveDimRedBlackGrid,
GridCartesian &FourDimGrid,
double _M5,const ImplParams &p= ImplParams());
*/
GaugeField &_Umu,
GridCartesian &FiveDimGrid,
GridRedBlackCartesian &FiveDimRedBlackGrid,
GridCartesian &FourDimGrid,
double _M5,const ImplParams &p= ImplParams());
*/
// DoubleStore
void ImportGauge(const GaugeField &_Umu);
///////////////////////////////////////////////////////////////
// Data members require to support the functionality
///////////////////////////////////////////////////////////////
public:
// Add these to the support from Wilson
GridBase *_FourDimGrid;
GridBase *_FourDimRedBlackGrid;
GridBase *_FiveDimGrid;
GridBase *_FiveDimRedBlackGrid;
double M5;
int Ls;
//Defines the stencils for even and odd
StencilImpl Stencil;
StencilImpl StencilEven;
StencilImpl StencilOdd;
// Copy of the gauge field , with even and odd subsets
DoubledGaugeField Umu;
DoubledGaugeField UmuEven;
DoubledGaugeField UmuOdd;
LebesgueOrder Lebesgue;
LebesgueOrder LebesgueEvenOdd;
// Comms buffer
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > comm_buf;
};
// DoubleStore
void ImportGauge(const GaugeField &_Umu);
///////////////////////////////////////////////////////////////
// Data members require to support the functionality
///////////////////////////////////////////////////////////////
public:
// Add these to the support from Wilson
GridBase *_FourDimGrid;
GridBase *_FourDimRedBlackGrid;
GridBase *_FiveDimGrid;
GridBase *_FiveDimRedBlackGrid;
double M5;
int Ls;
//Defines the stencils for even and odd
StencilImpl Stencil;
StencilImpl StencilEven;
StencilImpl StencilOdd;
// Copy of the gauge field , with even and odd subsets
DoubledGaugeField Umu;
DoubledGaugeField UmuEven;
DoubledGaugeField UmuOdd;
LebesgueOrder Lebesgue;
LebesgueOrder LebesgueEvenOdd;
// Comms buffer
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > comm_buf;
};
}
}
}}
#endif

24
lib/qcd/action/fermion/WilsonKernels.cc
View File

@ -32,8 +32,7 @@ directory
namespace Grid {
namespace QCD {
int WilsonKernelsStatic::HandOpt;
int WilsonKernelsStatic::AsmOpt;
int WilsonKernelsStatic::Opt;
template <class Impl>
WilsonKernels<Impl>::WilsonKernels(const ImplParams &p) : Base(p){};
@ -43,10 +42,9 @@ WilsonKernels<Impl>::WilsonKernels(const ImplParams &p) : Base(p){};
////////////////////////////////////////////
template <class Impl>
void WilsonKernels<Impl>::DiracOptGenericDhopSiteDag(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf, int sF,
int sU, const FermionField &in, FermionField &out) {
void WilsonKernels<Impl>::DiracOptGenericDhopSiteDag(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
SiteHalfSpinor *buf, int sF,
int sU, const FermionField &in, FermionField &out) {
SiteHalfSpinor tmp;
SiteHalfSpinor chi;
SiteHalfSpinor *chi_p;
@ -220,10 +218,9 @@ void WilsonKernels<Impl>::DiracOptGenericDhopSiteDag(
// Need controls to do interior, exterior, or both
template <class Impl>
void WilsonKernels<Impl>::DiracOptGenericDhopSite(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf, int sF,
int sU, const FermionField &in, FermionField &out) {
void WilsonKernels<Impl>::DiracOptGenericDhopSite(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
SiteHalfSpinor *buf, int sF,
int sU, const FermionField &in, FermionField &out) {
SiteHalfSpinor tmp;
SiteHalfSpinor chi;
SiteHalfSpinor *chi_p;
@ -396,10 +393,9 @@ void WilsonKernels<Impl>::DiracOptGenericDhopSite(
};
template <class Impl>
void WilsonKernels<Impl>::DiracOptDhopDir(
StencilImpl &st, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf, int sF,
int sU, const FermionField &in, FermionField &out, int dir, int gamma) {
void WilsonKernels<Impl>::DiracOptDhopDir( StencilImpl &st, DoubledGaugeField &U,SiteHalfSpinor *buf, int sF,
int sU, const FermionField &in, FermionField &out, int dir, int gamma) {
SiteHalfSpinor tmp;
SiteHalfSpinor chi;
SiteSpinor result;

297
lib/qcd/action/fermion/WilsonKernels.h
View File

@ -32,175 +32,152 @@ directory
#define GRID_QCD_DHOP_H
namespace Grid {
namespace QCD {
namespace QCD {
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Helper routines that implement Wilson stencil for a single site.
// Common to both the WilsonFermion and WilsonFermion5D
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
class WilsonKernelsStatic {
public:
// S-direction is INNERMOST and takes no part in the parity.
static int AsmOpt; // these are a temporary hack
static int HandOpt; // these are a temporary hack
};
template<class Impl> class WilsonKernels : public FermionOperator<Impl> , public WilsonKernelsStatic {
public:
INHERIT_IMPL_TYPES(Impl);
typedef FermionOperator<Impl> Base;
public:
template <bool EnableBool = true>
typename std::enable_if<Impl::Dimension == 3 && Nc == 3 &&EnableBool, void>::type
DiracOptDhopSite(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, int Ls, int Ns, const FermionField &in,
FermionField &out) {
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Helper routines that implement Wilson stencil for a single site.
// Common to both the WilsonFermion and WilsonFermion5D
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
class WilsonKernelsStatic {
public:
enum { OptGeneric, OptHandUnroll, OptInlineAsm };
// S-direction is INNERMOST and takes no part in the parity.
static int Opt; // these are a temporary hack
};
template<class Impl> class WilsonKernels : public FermionOperator<Impl> , public WilsonKernelsStatic {
public:
INHERIT_IMPL_TYPES(Impl);
typedef FermionOperator<Impl> Base;
public:
template <bool EnableBool = true>
typename std::enable_if<Impl::Dimension == 3 && Nc == 3 &&EnableBool, void>::type
DiracOptDhopSite(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U, SiteHalfSpinor * buf,
int sF, int sU, int Ls, int Ns, const FermionField &in, FermionField &out)
{
switch(Opt) {
#ifdef AVX512
if (AsmOpt) {
WilsonKernels<Impl>::DiracOptAsmDhopSite(st, lo, U, buf, sF, sU, Ls, Ns,
in, out);
} else {
#else
{
case OptInlineAsm:
WilsonKernels<Impl>::DiracOptAsmDhopSite(st,lo,U,buf,sF,sU,Ls,Ns,in,out);
break;
#endif
for (int site = 0; site < Ns; site++) {
for (int s = 0; s < Ls; s++) {
if (HandOpt)
WilsonKernels<Impl>::DiracOptHandDhopSite(st, lo, U, buf, sF, sU,
in, out);
else
WilsonKernels<Impl>::DiracOptGenericDhopSite(st, lo, U, buf, sF, sU,
in, out);
sF++;
}
sU++;
}
}
case OptHandUnroll:
for (int site = 0; site < Ns; site++) {
for (int s = 0; s < Ls; s++) {
WilsonKernels<Impl>::DiracOptHandDhopSite(st,lo,U,buf,sF,sU,in,out);
sF++;
}
template <bool EnableBool = true>
typename std::enable_if<(Impl::Dimension != 3 || (Impl::Dimension == 3 && Nc != 3)) && EnableBool, void>::type
DiracOptDhopSite(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, int Ls, int Ns, const FermionField &in,
FermionField &out) {
for (int site = 0; site < Ns; site++) {
for (int s = 0; s < Ls; s++) {
WilsonKernels<Impl>::DiracOptGenericDhopSite(st, lo, U, buf, sF, sU, in,
out);
sF++;
}
sU++;
}
}
template <bool EnableBool = true>
typename std::enable_if<Impl::Dimension == 3 && Nc == 3 && EnableBool,
void>::type
DiracOptDhopSiteDag(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, int Ls, int Ns, const FermionField &in,
FermionField &out) {
#ifdef AVX512
if (AsmOpt) {
WilsonKernels<Impl>::DiracOptAsmDhopSiteDag(st, lo, U, buf, sF, sU, Ls,
Ns, in, out);
} else {
#else
{
#endif
for (int site = 0; site < Ns; site++) {
for (int s = 0; s < Ls; s++) {
if (HandOpt)
WilsonKernels<Impl>::DiracOptHandDhopSiteDag(st, lo, U, buf, sF, sU,
in, out);
else
WilsonKernels<Impl>::DiracOptGenericDhopSiteDag(st, lo, U, buf, sF,
sU, in, out);
sF++;
}
sU++;
}
}
}
template <bool EnableBool = true>
typename std::enable_if<
(Impl::Dimension != 3 || (Impl::Dimension == 3 && Nc != 3)) && EnableBool,
void>::type
DiracOptDhopSiteDag(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, int Ls, int Ns, const FermionField &in,
FermionField &out) {
for (int site = 0; site < Ns; site++) {
for (int s = 0; s < Ls; s++) {
WilsonKernels<Impl>::DiracOptGenericDhopSiteDag(st, lo, U, buf, sF, sU,
in, out);
sF++;
}
sU++;
}
}
void DiracOptDhopDir(
StencilImpl &st, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, const FermionField &in, FermionField &out, int dirdisp,
int gamma);
private:
// Specialised variants
void DiracOptGenericDhopSite(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, const FermionField &in, FermionField &out);
void DiracOptGenericDhopSiteDag(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, const FermionField &in, FermionField &out);
void DiracOptAsmDhopSite(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, int Ls, int Ns, const FermionField &in,
FermionField &out);
void DiracOptAsmDhopSiteDag(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, int Ls, int Ns, const FermionField &in,
FermionField &out);
void DiracOptHandDhopSite(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, const FermionField &in, FermionField &out);
void DiracOptHandDhopSiteDag(
StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,
std::vector<SiteHalfSpinor, alignedAllocator<SiteHalfSpinor> > &buf,
int sF, int sU, const FermionField &in, FermionField &out);
public:
WilsonKernels(const ImplParams &p = ImplParams());
};
sU++;
}
break;
case OptGeneric:
for (int site = 0; site < Ns; site++) {
for (int s = 0; s < Ls; s++) {
WilsonKernels<Impl>::DiracOptGenericDhopSite(st,lo,U,buf,sF,sU,in,out);
sF++;
}
sU++;
}
break;
default:
assert(0);
}
}
template <bool EnableBool = true>
typename std::enable_if<(Impl::Dimension != 3 || (Impl::Dimension == 3 && Nc != 3)) && EnableBool, void>::type
DiracOptDhopSite(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U, SiteHalfSpinor * buf,
int sF, int sU, int Ls, int Ns, const FermionField &in, FermionField &out) {
// no kernel choice
for (int site = 0; site < Ns; site++) {
for (int s = 0; s < Ls; s++) {
WilsonKernels<Impl>::DiracOptGenericDhopSite(st, lo, U, buf, sF, sU, in, out);
sF++;
}
sU++;
}
}
template <bool EnableBool = true>
typename std::enable_if<Impl::Dimension == 3 && Nc == 3 && EnableBool,void>::type
DiracOptDhopSiteDag(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U, SiteHalfSpinor * buf,
int sF, int sU, int Ls, int Ns, const FermionField &in, FermionField &out) {
switch(Opt) {
#ifdef AVX512
case OptInlineAsm:
WilsonKernels<Impl>::DiracOptAsmDhopSiteDag(st,lo,U,buf,sF,sU,Ls,Ns,in,out);
break;
#endif
case OptHandUnroll:
for (int site = 0; site < Ns; site++) {
for (int s = 0; s < Ls; s++) {
WilsonKernels<Impl>::DiracOptHandDhopSiteDag(st,lo,U,buf,sF,sU,in,out);
sF++;
}
sU++;
}
break;
case OptGeneric:
for (int site = 0; site < Ns; site++) {
for (int s = 0; s < Ls; s++) {
WilsonKernels<Impl>::DiracOptGenericDhopSiteDag(st,lo,U,buf,sF,sU,in,out);
sF++;
}
sU++;
}
break;
default:
assert(0);
}
}
template <bool EnableBool = true>
typename std::enable_if<(Impl::Dimension != 3 || (Impl::Dimension == 3 && Nc != 3)) && EnableBool,void>::type
DiracOptDhopSiteDag(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U,SiteHalfSpinor * buf,
int sF, int sU, int Ls, int Ns, const FermionField &in, FermionField &out) {
for (int site = 0; site < Ns; site++) {
for (int s = 0; s < Ls; s++) {
WilsonKernels<Impl>::DiracOptGenericDhopSiteDag(st,lo,U,buf,sF,sU,in,out);
sF++;
}
sU++;
}
}
void DiracOptDhopDir(StencilImpl &st, DoubledGaugeField &U,SiteHalfSpinor * buf,
int sF, int sU, const FermionField &in, FermionField &out, int dirdisp, int gamma);
private:
// Specialised variants
void DiracOptGenericDhopSite(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U, SiteHalfSpinor * buf,
int sF, int sU, const FermionField &in, FermionField &out);
void DiracOptGenericDhopSiteDag(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U, SiteHalfSpinor * buf,
int sF, int sU, const FermionField &in, FermionField &out);
void DiracOptAsmDhopSite(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U, SiteHalfSpinor * buf,
int sF, int sU, int Ls, int Ns, const FermionField &in,FermionField &out);
void DiracOptAsmDhopSiteDag(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U, SiteHalfSpinor * buf,
int sF, int sU, int Ls, int Ns, const FermionField &in, FermionField &out);
void DiracOptHandDhopSite(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U, SiteHalfSpinor * buf,
int sF, int sU, const FermionField &in, FermionField &out);
void DiracOptHandDhopSiteDag(StencilImpl &st, LebesgueOrder &lo, DoubledGaugeField &U, SiteHalfSpinor * buf,
int sF, int sU, const FermionField &in, FermionField &out);
public:
WilsonKernels(const ImplParams &p = ImplParams());
};
}}
#endif

175
lib/qcd/action/fermion/WilsonKernelsAsm.cc
View File

@ -10,6 +10,7 @@
Author: Peter Boyle <paboyle@ph.ed.ac.uk>
Author: paboyle <paboyle@ph.ed.ac.uk>
Author: Guido Cossu <guido.cossu@ed.ac.uk>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
@ -33,48 +34,46 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
namespace Grid {
namespace QCD {
namespace QCD {
///////////////////////////////////////////////////////////
// Default to no assembler implementation
///////////////////////////////////////////////////////////
template<class Impl>
void WilsonKernels<Impl >::DiracOptAsmDhopSite(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
{
assert(0);
}
template<class Impl>
void WilsonKernels<Impl >::DiracOptAsmDhopSiteDag(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
{
assert(0);
}
///////////////////////////////////////////////////////////
// Default to no assembler implementation
///////////////////////////////////////////////////////////
template<class Impl> void
WilsonKernels<Impl >::DiracOptAsmDhopSite(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,SiteHalfSpinor *buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
{
assert(0);
}
template<class Impl> void
WilsonKernels<Impl >::DiracOptAsmDhopSiteDag(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,SiteHalfSpinor *buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
{
assert(0);
}
#if defined(AVX512)
#include <simd/Intel512wilson.h>
///////////////////////////////////////////////////////////
// If we are AVX512 specialise the single precision routine
///////////////////////////////////////////////////////////
#include <simd/Intel512wilson.h>
#include <simd/Intel512single.h>
static Vector<vComplexF> signs;
int setupSigns(void ){
Vector<vComplexF> bother(2);
signs = bother;
vrsign(signs[0]);
visign(signs[1]);
return 1;
}
static int signInit = setupSigns();
static Vector<vComplexF> signsF;
template<typename vtype>
int setupSigns(Vector<vtype>& signs ){
Vector<vtype> bother(2);
signs = bother;
vrsign(signs[0]);
visign(signs[1]);
return 1;
}
static int signInitF = setupSigns(signsF);
#define label(A) ilabel(A)
#define ilabel(A) ".globl\n" #A ":\n"
@ -82,19 +81,19 @@ namespace Grid {
#define MAYBEPERM(A,perm) if (perm) { A ; }
#define MULT_2SPIN(ptr,pf) MULT_ADDSUB_2SPIN(ptr,pf)
#define FX(A) WILSONASM_ ##A
#define COMPLEX_TYPE vComplexF
#define signs signsF
#undef KERNEL_DAG
template<>
void WilsonKernels<WilsonImplF>::DiracOptAsmDhopSite(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
template<> void
WilsonKernels<WilsonImplF>::DiracOptAsmDhopSite(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U, SiteHalfSpinor *buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
#include <qcd/action/fermion/WilsonKernelsAsmBody.h>
#define KERNEL_DAG
template<>
void WilsonKernels<WilsonImplF>::DiracOptAsmDhopSiteDag(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
template<> void
WilsonKernels<WilsonImplF>::DiracOptAsmDhopSiteDag(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,SiteHalfSpinor *buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
#include <qcd/action/fermion/WilsonKernelsAsmBody.h>
#undef VMOVIDUP
@ -104,36 +103,94 @@ namespace Grid {
#undef FX
#define FX(A) DWFASM_ ## A
#define MAYBEPERM(A,B)
#define VMOVIDUP(A,B,C) VBCASTIDUPf(A,B,C)
#define VMOVRDUP(A,B,C) VBCASTRDUPf(A,B,C)
//#define VMOVIDUP(A,B,C) VBCASTIDUPf(A,B,C)
//#define VMOVRDUP(A,B,C) VBCASTRDUPf(A,B,C)
#define MULT_2SPIN(ptr,pf) MULT_ADDSUB_2SPIN_LS(ptr,pf)
#undef KERNEL_DAG
template<>
void WilsonKernels<DomainWallVec5dImplF>::DiracOptAsmDhopSite(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
template<> void
WilsonKernels<DomainWallVec5dImplF>::DiracOptAsmDhopSite(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U, SiteHalfSpinor *buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
#include <qcd/action/fermion/WilsonKernelsAsmBody.h>
#define KERNEL_DAG
template<>
void WilsonKernels<DomainWallVec5dImplF>::DiracOptAsmDhopSiteDag(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
template<> void
WilsonKernels<DomainWallVec5dImplF>::DiracOptAsmDhopSiteDag(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,SiteHalfSpinor *buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
#include <qcd/action/fermion/WilsonKernelsAsmBody.h>
#undef COMPLEX_TYPE
#undef signs
#undef VMOVRDUP
#undef MAYBEPERM
#undef MULT_2SPIN
#undef FX
///////////////////////////////////////////////////////////
// If we are AVX512 specialise the double precision routine
///////////////////////////////////////////////////////////
#include <simd/Intel512double.h>
static Vector<vComplexD> signsD;
#define signs signsD
static int signInitD = setupSigns(signsD);
#define MAYBEPERM(A,perm) if (perm) { A ; }
#define MULT_2SPIN(ptr,pf) MULT_ADDSUB_2SPIN(ptr,pf)
#define FX(A) WILSONASM_ ##A
#define COMPLEX_TYPE vComplexD
#undef KERNEL_DAG
template<> void
WilsonKernels<WilsonImplD>::DiracOptAsmDhopSite(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U, SiteHalfSpinor *buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
#include <qcd/action/fermion/WilsonKernelsAsmBody.h>
#define KERNEL_DAG
template<> void
WilsonKernels<WilsonImplD>::DiracOptAsmDhopSiteDag(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,SiteHalfSpinor *buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
#include <qcd/action/fermion/WilsonKernelsAsmBody.h>
#endif
#undef VMOVIDUP
#undef VMOVRDUP
#undef MAYBEPERM
#undef MULT_2SPIN
#undef FX
#define FX(A) DWFASM_ ## A
#define MAYBEPERM(A,B)
//#define VMOVIDUP(A,B,C) VBCASTIDUPd(A,B,C)
//#define VMOVRDUP(A,B,C) VBCASTRDUPd(A,B,C)
#define MULT_2SPIN(ptr,pf) MULT_ADDSUB_2SPIN_LS(ptr,pf)
#undef KERNEL_DAG
template<> void
WilsonKernels<DomainWallVec5dImplD>::DiracOptAsmDhopSite(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U, SiteHalfSpinor *buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
#include <qcd/action/fermion/WilsonKernelsAsmBody.h>
#define KERNEL_DAG
template<> void
WilsonKernels<DomainWallVec5dImplD>::DiracOptAsmDhopSiteDag(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,SiteHalfSpinor *buf,
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out)
#include <qcd/action/fermion/WilsonKernelsAsmBody.h>
#undef COMPLEX_TYPE
#undef signs
#undef VMOVRDUP
#undef MAYBEPERM
#undef MULT_2SPIN
#undef FX
#endif //AVX512
#define INSTANTIATE_ASM(A)\
template void WilsonKernels<A>::DiracOptAsmDhopSite(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,\
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,\
template void WilsonKernels<A>::DiracOptAsmDhopSite(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U, SiteHalfSpinor *buf,\
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out);\
template void WilsonKernels<A>::DiracOptAsmDhopSiteDag(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U,\
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,\
\
template void WilsonKernels<A>::DiracOptAsmDhopSiteDag(StencilImpl &st,LebesgueOrder & lo,DoubledGaugeField &U, SiteHalfSpinor *buf,\
int ss,int ssU,int Ls,int Ns,const FermionField &in, FermionField &out);\
INSTANTIATE_ASM(WilsonImplF);
INSTANTIATE_ASM(WilsonImplD);
INSTANTIATE_ASM(ZWilsonImplF);
@ -144,6 +201,6 @@ INSTANTIATE_ASM(DomainWallVec5dImplF);
INSTANTIATE_ASM(DomainWallVec5dImplD);
INSTANTIATE_ASM(ZDomainWallVec5dImplF);
INSTANTIATE_ASM(ZDomainWallVec5dImplD);
}
}
}}

8
lib/qcd/action/fermion/WilsonKernelsAsmBody.h
View File

@ -5,7 +5,9 @@
const uint64_t plocal =(uint64_t) & in._odata[0];
// vComplexF isigns[2] = { signs[0], signs[1] };
vComplexF *isigns = &signs[0];
//COMPLEX_TYPE is vComplexF of vComplexD depending
//on the chosen precision
COMPLEX_TYPE *isigns = &signs[0];
MASK_REGS;
int nmax=U._grid->oSites();
@ -134,7 +136,9 @@
////////////////////////////////
// Xm
////////////////////////////////
#ifndef STREAM_STORE
basep= (uint64_t) &out._odata[ss];
#endif
// basep= st.GetPFInfo(nent,plocal); nent++;
if ( local ) {
LOAD64(%r10,isigns); // times i => shuffle and xor the real part sign bit
@ -229,7 +233,9 @@
LOAD_CHI(base);
}
base= (uint64_t) &out._odata[ss];
#ifndef STREAM_STORE
PREFETCH_CHIMU(base);
#endif
{
MULT_2SPIN_DIR_PFTM(Tm,basep);
}

55
lib/qcd/action/fermion/WilsonKernelsHand.cc
View File

@ -311,10 +311,9 @@ namespace Grid {
namespace QCD {
template<class Impl>
void WilsonKernels<Impl>::DiracOptHandDhopSite(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int ss,int sU,const FermionField &in, FermionField &out)
template<class Impl> void
WilsonKernels<Impl>::DiracOptHandDhopSite(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,SiteHalfSpinor *buf,
int ss,int sU,const FermionField &in, FermionField &out)
{
typedef typename Simd::scalar_type S;
typedef typename Simd::vector_type V;
@ -554,10 +553,9 @@ namespace QCD {
}
}
template<class Impl>
void WilsonKernels<Impl>::DiracOptHandDhopSiteDag(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int ss,int sU,const FermionField &in, FermionField &out)
template<class Impl>
void WilsonKernels<Impl>::DiracOptHandDhopSiteDag(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,SiteHalfSpinor *buf,
int ss,int sU,const FermionField &in, FermionField &out)
{
// std::cout << "Hand op Dhop "<<std::endl;
typedef typename Simd::scalar_type S;
@ -798,38 +796,35 @@ namespace QCD {
}
}
////////////////////////////////////////////////
// Specialise Gparity to simple implementation
////////////////////////////////////////////////
template<>
void WilsonKernels<GparityWilsonImplF>::DiracOptHandDhopSite(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int sF,int sU,const FermionField &in, FermionField &out)
template<> void
WilsonKernels<GparityWilsonImplF>::DiracOptHandDhopSite(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,
SiteHalfSpinor *buf,
int sF,int sU,const FermionField &in, FermionField &out)
{
assert(0);
}
template<>
void WilsonKernels<GparityWilsonImplF>::DiracOptHandDhopSiteDag(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int sF,int sU,const FermionField &in, FermionField &out)
template<> void
WilsonKernels<GparityWilsonImplF>::DiracOptHandDhopSiteDag(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,
SiteHalfSpinor *buf,
int sF,int sU,const FermionField &in, FermionField &out)
{
assert(0);
}
template<>
void WilsonKernels<GparityWilsonImplD>::DiracOptHandDhopSite(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int sF,int sU,const FermionField &in, FermionField &out)
template<> void
WilsonKernels<GparityWilsonImplD>::DiracOptHandDhopSite(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,SiteHalfSpinor *buf,
int sF,int sU,const FermionField &in, FermionField &out)
{
assert(0);
}
template<>
void WilsonKernels<GparityWilsonImplD>::DiracOptHandDhopSiteDag(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,
int sF,int sU,const FermionField &in, FermionField &out)
template<> void
WilsonKernels<GparityWilsonImplD>::DiracOptHandDhopSiteDag(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,SiteHalfSpinor *buf,
int sF,int sU,const FermionField &in, FermionField &out)
{
assert(0);
}
@ -840,12 +835,10 @@ void WilsonKernels<GparityWilsonImplD>::DiracOptHandDhopSiteDag(StencilImpl &st,
// Need Nc=3 though //
#define INSTANTIATE_THEM(A) \
template void WilsonKernels<A>::DiracOptHandDhopSite(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,\
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,\
int ss,int sU,const FermionField &in, FermionField &out);\
template void WilsonKernels<A>::DiracOptHandDhopSiteDag(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,\
std::vector<SiteHalfSpinor,alignedAllocator<SiteHalfSpinor> > &buf,\
int ss,int sU,const FermionField &in, FermionField &out);
template void WilsonKernels<A>::DiracOptHandDhopSite(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,SiteHalfSpinor *buf,\
int ss,int sU,const FermionField &in, FermionField &out); \
template void WilsonKernels<A>::DiracOptHandDhopSiteDag(StencilImpl &st,LebesgueOrder &lo,DoubledGaugeField &U,SiteHalfSpinor *buf,\
int ss,int sU,const FermionField &in, FermionField &out);
INSTANTIATE_THEM(WilsonImplF);
INSTANTIATE_THEM(WilsonImplD);

2
lib/qcd/hmc/HmcRunner.h
View File

@ -116,7 +116,7 @@ class NerscHmcRunnerTemplate {
NoSmearing<Gimpl> SmearingPolicy;
typedef MinimumNorm2<GaugeField, NoSmearing<Gimpl>, RepresentationsPolicy >
IntegratorType; // change here to change the algorithm
IntegratorParameters MDpar(20, 1.0);
IntegratorParameters MDpar(40, 1.0);
IntegratorType MDynamics(UGrid, MDpar, TheAction, SmearingPolicy);
// Checkpoint strategy

28
lib/qcd/utils/LinalgUtils.h
View File

@ -39,8 +39,8 @@ namespace QCD{
//on the 5d (rb4d) checkerboarded lattices
////////////////////////////////////////////////////////////////////////
template<class vobj>
void axpibg5x(Lattice<vobj> &z,const Lattice<vobj> &x,RealD a,RealD b)
template<class vobj,class Coeff>
void axpibg5x(Lattice<vobj> &z,const Lattice<vobj> &x,Coeff a,Coeff b)
{
z.checkerboard = x.checkerboard;
conformable(x,z);
@ -57,8 +57,8 @@ PARALLEL_FOR_LOOP
}
}
template<class vobj>
void axpby_ssp(Lattice<vobj> &z, RealD a,const Lattice<vobj> &x,RealD b,const Lattice<vobj> &y,int s,int sp)
template<class vobj,class Coeff>
void axpby_ssp(Lattice<vobj> &z, Coeff a,const Lattice<vobj> &x,Coeff b,const Lattice<vobj> &y,int s,int sp)
{
z.checkerboard = x.checkerboard;
conformable(x,y);
@ -72,8 +72,8 @@ PARALLEL_FOR_LOOP
}
}
template<class vobj>
void ag5xpby_ssp(Lattice<vobj> &z,RealD a,const Lattice<vobj> &x,RealD b,const Lattice<vobj> &y,int s,int sp)
template<class vobj,class Coeff>
void ag5xpby_ssp(Lattice<vobj> &z,Coeff a,const Lattice<vobj> &x,Coeff b,const Lattice<vobj> &y,int s,int sp)
{
z.checkerboard = x.checkerboard;
conformable(x,y);
@ -90,8 +90,8 @@ PARALLEL_FOR_LOOP
}
}
template<class vobj>
void axpbg5y_ssp(Lattice<vobj> &z,RealD a,const Lattice<vobj> &x,RealD b,const Lattice<vobj> &y,int s,int sp)
template<class vobj,class Coeff>
void axpbg5y_ssp(Lattice<vobj> &z,Coeff a,const Lattice<vobj> &x,Coeff b,const Lattice<vobj> &y,int s,int sp)
{
z.checkerboard = x.checkerboard;
conformable(x,y);
@ -108,8 +108,8 @@ PARALLEL_FOR_LOOP
}
}
template<class vobj>
void ag5xpbg5y_ssp(Lattice<vobj> &z,RealD a,const Lattice<vobj> &x,RealD b,const Lattice<vobj> &y,int s,int sp)
template<class vobj,class Coeff>
void ag5xpbg5y_ssp(Lattice<vobj> &z,Coeff a,const Lattice<vobj> &x,Coeff b,const Lattice<vobj> &y,int s,int sp)
{
z.checkerboard = x.checkerboard;
conformable(x,y);
@ -127,8 +127,8 @@ PARALLEL_FOR_LOOP
}
}
template<class vobj>
void axpby_ssp_pminus(Lattice<vobj> &z,RealD a,const Lattice<vobj> &x,RealD b,const Lattice<vobj> &y,int s,int sp)
template<class vobj,class Coeff>
void axpby_ssp_pminus(Lattice<vobj> &z,Coeff a,const Lattice<vobj> &x,Coeff b,const Lattice<vobj> &y,int s,int sp)
{
z.checkerboard = x.checkerboard;
conformable(x,y);
@ -144,8 +144,8 @@ PARALLEL_FOR_LOOP
}
}
template<class vobj>
void axpby_ssp_pplus(Lattice<vobj> &z,RealD a,const Lattice<vobj> &x,RealD b,const Lattice<vobj> &y,int s,int sp)
template<class vobj,class Coeff>
void axpby_ssp_pplus(Lattice<vobj> &z,Coeff a,const Lattice<vobj> &x,Coeff b,const Lattice<vobj> &y,int s,int sp)
{
z.checkerboard = x.checkerboard;
conformable(x,y);

65
lib/qcd/utils/SUn.h
View File

@ -674,6 +674,37 @@ class SU {
out += la;
}
}
/*
add GaugeTrans
*/
template<typename GaugeField,typename GaugeMat>
static void GaugeTransform( GaugeField &Umu, GaugeMat &g){
GridBase *grid = Umu._grid;
conformable(grid,g._grid);
GaugeMat U(grid);
GaugeMat ag(grid); ag = adj(g);
for(int mu=0;mu<Nd;mu++){
U= PeekIndex<LorentzIndex>(Umu,mu);
U = g*U*Cshift(ag, mu, 1);
PokeIndex<LorentzIndex>(Umu,U,mu);
}
}
template<typename GaugeMat>
static void GaugeTransform( std::vector<GaugeMat> &U, GaugeMat &g){
GridBase *grid = g._grid;
GaugeMat ag(grid); ag = adj(g);
for(int mu=0;mu<Nd;mu++){
U[mu] = g*U[mu]*Cshift(ag, mu, 1);
}
}
template<typename GaugeField,typename GaugeMat>
static void RandomGaugeTransform(GridParallelRNG &pRNG, GaugeField &Umu, GaugeMat &g){
LieRandomize(pRNG,g,1.0);
GaugeTransform(Umu,g);
}
// Projects the algebra components a lattice matrix (of dimension ncol*ncol -1 )
// inverse operation: FundamentalLieAlgebraMatrix
@ -702,23 +733,33 @@ class SU {
PokeIndex<LorentzIndex>(out, Umu, mu);
}
}
static void TepidConfiguration(GridParallelRNG &pRNG,
LatticeGaugeField &out) {
LatticeMatrix Umu(out._grid);
for (int mu = 0; mu < Nd; mu++) {
LieRandomize(pRNG, Umu, 0.01);
PokeIndex<LorentzIndex>(out, Umu, mu);
template<typename GaugeField>
static void TepidConfiguration(GridParallelRNG &pRNG,GaugeField &out){
typedef typename GaugeField::vector_type vector_type;
typedef iSUnMatrix<vector_type> vMatrixType;
typedef Lattice<vMatrixType> LatticeMatrixType;
LatticeMatrixType Umu(out._grid);
for(int mu=0;mu<Nd;mu++){
LieRandomize(pRNG,Umu,0.01);
PokeIndex<LorentzIndex>(out,Umu,mu);
}
}
static void ColdConfiguration(GridParallelRNG &pRNG, LatticeGaugeField &out) {
LatticeMatrix Umu(out._grid);
Umu = 1.0;
for (int mu = 0; mu < Nd; mu++) {
PokeIndex<LorentzIndex>(out, Umu, mu);
template<typename GaugeField>
static void ColdConfiguration(GridParallelRNG &pRNG,GaugeField &out){
typedef typename GaugeField::vector_type vector_type;
typedef iSUnMatrix<vector_type> vMatrixType;
typedef Lattice<vMatrixType> LatticeMatrixType;
LatticeMatrixType Umu(out._grid);
Umu=1.0;
for(int mu=0;mu<Nd;mu++){
PokeIndex<LorentzIndex>(out,Umu,mu);
}
}
static void taProj(const LatticeMatrix &in, LatticeMatrix &out) {
template<typename LatticeMatrixType>
static void taProj( const LatticeMatrixType &in, LatticeMatrixType &out){
out = Ta(in);
}
template <typename LatticeMatrixType>

2
lib/qcd/utils/WilsonLoops.h
View File

@ -522,4 +522,4 @@ typedef WilsonLoops<PeriodicGimplR> SU3WilsonLoops;
}
}
#endif
#endif

51
lib/simd/Grid_avx.h
View File

@ -365,6 +365,18 @@ namespace Optimization {
}
};
struct Div{
// Real float
inline __m256 operator()(__m256 a, __m256 b){
return _mm256_div_ps(a,b);
}
// Real double
inline __m256d operator()(__m256d a, __m256d b){
return _mm256_div_pd(a,b);
}
};
struct Conj{
// Complex single
inline __m256 operator()(__m256 in){
@ -437,14 +449,13 @@ namespace Optimization {
};
#if defined (AVX2) || defined (AVXFMA4)
#define _mm256_alignr_epi32(ret,a,b,n) ret=(__m256) _mm256_alignr_epi8((__m256i)a,(__m256i)b,(n*4)%16)
#define _mm256_alignr_epi64(ret,a,b,n) ret=(__m256d) _mm256_alignr_epi8((__m256i)a,(__m256i)b,(n*8)%16)
#if defined (AVX2)
#define _mm256_alignr_epi32_grid(ret,a,b,n) ret=(__m256) _mm256_alignr_epi8((__m256i)a,(__m256i)b,(n*4)%16)
#define _mm256_alignr_epi64_grid(ret,a,b,n) ret=(__m256d) _mm256_alignr_epi8((__m256i)a,(__m256i)b,(n*8)%16)
#endif
#if defined (AVX1)
#define _mm256_alignr_epi32(ret,a,b,n) { \
#if defined (AVX1) || defined (AVXFMA)
#define _mm256_alignr_epi32_grid(ret,a,b,n) { \
__m128 aa, bb; \
\
aa = _mm256_extractf128_ps(a,1); \
@ -458,7 +469,7 @@ namespace Optimization {
ret = _mm256_insertf128_ps(ret,aa,0); \
}
#define _mm256_alignr_epi64(ret,a,b,n) { \
#define _mm256_alignr_epi64_grid(ret,a,b,n) { \
__m128d aa, bb; \
\
aa = _mm256_extractf128_pd(a,1); \
@ -474,19 +485,6 @@ namespace Optimization {
#endif
inline std::ostream & operator << (std::ostream& stream, const __m256 a)
{
const float *p=(const float *)&a;
stream<< "{"<<p[0]<<","<<p[1]<<","<<p[2]<<","<<p[3]<<","<<p[4]<<","<<p[5]<<","<<p[6]<<","<<p[7]<<"}";
return stream;
};
inline std::ostream & operator<< (std::ostream& stream, const __m256d a)
{
const double *p=(const double *)&a;
stream<< "{"<<p[0]<<","<<p[1]<<","<<p[2]<<","<<p[3]<<"}";
return stream;
};
struct Rotate{
static inline __m256 rotate(__m256 in,int n){
@ -518,11 +516,10 @@ namespace Optimization {
__m256 tmp = Permute::Permute0(in);
__m256 ret;
if ( n > 3 ) {
_mm256_alignr_epi32(ret,in,tmp,n);
_mm256_alignr_epi32_grid(ret,in,tmp,n);
} else {
_mm256_alignr_epi32(ret,tmp,in,n);
_mm256_alignr_epi32_grid(ret,tmp,in,n);
}
// std::cout << " align epi32 n=" <<n<<" in "<<tmp<<in<<" -> "<< ret <<std::endl;
return ret;
};
@ -531,18 +528,15 @@ namespace Optimization {
__m256d tmp = Permute::Permute0(in);
__m256d ret;
if ( n > 1 ) {
_mm256_alignr_epi64(ret,in,tmp,n);
_mm256_alignr_epi64_grid(ret,in,tmp,n);
} else {
_mm256_alignr_epi64(ret,tmp,in,n);
_mm256_alignr_epi64_grid(ret,tmp,in,n);
}
// std::cout << " align epi64 n=" <<n<<" in "<<tmp<<in<<" -> "<< ret <<std::endl;
return ret;
};
};
//Complex float Reduce
template<>
inline Grid::ComplexF Reduce<Grid::ComplexF, __m256>::operator()(__m256 in){
@ -631,6 +625,7 @@ namespace Optimization {
// Arithmetic operations
typedef Optimization::Sum SumSIMD;
typedef Optimization::Sub SubSIMD;
typedef Optimization::Div DivSIMD;
typedef Optimization::Mult MultSIMD;
typedef Optimization::MultComplex MultComplexSIMD;
typedef Optimization::Conj ConjSIMD;

84
lib/simd/Grid_avx512.h
View File

@ -32,6 +32,16 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
namespace Grid{
namespace Optimization {
union u512f {
__m512 v;
float f[16];
};
union u512d {
__m512d v;
double f[8];
};
struct Vsplat{
//Complex float
@ -221,6 +231,17 @@ namespace Optimization {
}
};
struct Div{
// Real float
inline __m512 operator()(__m512 a, __m512 b){
return _mm512_div_ps(a,b);
}
// Real double
inline __m512d operator()(__m512d a, __m512d b){
return _mm512_div_pd(a,b);
}
};
struct Conj{
// Complex single
@ -350,7 +371,67 @@ namespace Optimization {
//////////////////////////////////////////////
// Some Template specialization
// Hack for CLANG until mm512_reduce_add_ps etc... are implemented in GCC and Clang releases
#ifndef __INTEL_COMPILER
#warning "Slow reduction due to incomplete reduce intrinsics"
//Complex float Reduce
template<>
inline Grid::ComplexF Reduce<Grid::ComplexF, __m512>::operator()(__m512 in){
__m512 v1,v2;
v1=Optimization::Permute::Permute0(in); // avx 512; quad complex single
v1= _mm512_add_ps(v1,in);
v2=Optimization::Permute::Permute1(v1);
v1 = _mm512_add_ps(v1,v2);
v2=Optimization::Permute::Permute2(v1);
v1 = _mm512_add_ps(v1,v2);
u512f conv; conv.v = v1;
return Grid::ComplexF(conv.f[0],conv.f[1]);
}
//Real float Reduce
template<>
inline Grid::RealF Reduce<Grid::RealF, __m512>::operator()(__m512 in){
__m512 v1,v2;
v1 = Optimization::Permute::Permute0(in); // avx 512; octo-double
v1 = _mm512_add_ps(v1,in);
v2 = Optimization::Permute::Permute1(v1);
v1 = _mm512_add_ps(v1,v2);
v2 = Optimization::Permute::Permute2(v1);
v1 = _mm512_add_ps(v1,v2);
v2 = Optimization::Permute::Permute3(v1);
v1 = _mm512_add_ps(v1,v2);
u512f conv; conv.v=v1;
return conv.f[0];
}
//Complex double Reduce
template<>
inline Grid::ComplexD Reduce<Grid::ComplexD, __m512d>::operator()(__m512d in){
__m512d v1;
v1 = Optimization::Permute::Permute0(in); // sse 128; paired complex single
v1 = _mm512_add_pd(v1,in);
v1 = Optimization::Permute::Permute1(in); // sse 128; paired complex single
v1 = _mm512_add_pd(v1,in);
u512d conv; conv.v = v1;
return Grid::ComplexD(conv.f[0],conv.f[1]);
}
//Real double Reduce
template<>
inline Grid::RealD Reduce<Grid::RealD, __m512d>::operator()(__m512d in){
__m512d v1,v2;
v1 = Optimization::Permute::Permute0(in); // avx 512; quad double
v1 = _mm512_add_pd(v1,in);
v2 = Optimization::Permute::Permute1(v1);
v1 = _mm512_add_pd(v1,v2);
v2 = Optimization::Permute::Permute2(v1);
v1 = _mm512_add_pd(v1,v2);
u512d conv; conv.v = v1;
return conv.f[0];
}
#else
//Complex float Reduce
template<>
inline Grid::ComplexF Reduce<Grid::ComplexF, __m512>::operator()(__m512 in){
@ -362,7 +443,6 @@ namespace Optimization {
return _mm512_reduce_add_ps(in);
}
//Complex double Reduce
template<>
inline Grid::ComplexD Reduce<Grid::ComplexD, __m512d>::operator()(__m512d in){
@ -382,6 +462,7 @@ namespace Optimization {
printf("Reduce : Missing integer implementation -> FIX\n");
assert(0);
}
#endif
}
@ -418,6 +499,7 @@ namespace Optimization {
typedef Optimization::Sum SumSIMD;
typedef Optimization::Sub SubSIMD;
typedef Optimization::Mult MultSIMD;
typedef Optimization::Div DivSIMD;
typedef Optimization::MultComplex MultComplexSIMD;
typedef Optimization::Conj ConjSIMD;
typedef Optimization::TimesMinusI TimesMinusISIMD;

718
lib/simd/Grid_generic.h
View File

@ -6,8 +6,7 @@
Copyright (C) 2015
Author: Peter Boyle <paboyle@ph.ed.ac.uk>
Author: neo <cossu@post.kek.jp>
Author: Antonin Portelli <antonin.portelli@me.com>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
@ -27,133 +26,352 @@ Author: neo <cossu@post.kek.jp>
*************************************************************************************/
/* END LEGAL */
static_assert(GEN_SIMD_WIDTH % 16u == 0, "SIMD vector size is not an integer multiple of 16 bytes");
//#define VECTOR_LOOPS
// playing with compiler pragmas
#ifdef VECTOR_LOOPS
#ifdef __clang__
#define VECTOR_FOR(i, w, inc)\
_Pragma("clang loop unroll(full) vectorize(enable) interleave(enable) vectorize_width(w)")\
for (unsigned int i = 0; i < w; i += inc)
#elif defined __INTEL_COMPILER
#define VECTOR_FOR(i, w, inc)\
_Pragma("simd vectorlength(w*8)")\
for (unsigned int i = 0; i < w; i += inc)
#else
#define VECTOR_FOR(i, w, inc)\
for (unsigned int i = 0; i < w; i += inc)
#endif
#else
#define VECTOR_FOR(i, w, inc)\
for (unsigned int i = 0; i < w; i += inc)
#endif
namespace Grid {
namespace Optimization {
template<class vtype>
union uconv {
float f;
vtype v;
// type traits giving the number of elements for each vector type
template <typename T> struct W;
template <> struct W<double> {
constexpr static unsigned int c = GEN_SIMD_WIDTH/16u;
constexpr static unsigned int r = GEN_SIMD_WIDTH/8u;
};
union u128f {
float v;
float f[4];
};
union u128d {
double v;
double f[2];
template <> struct W<float> {
constexpr static unsigned int c = GEN_SIMD_WIDTH/8u;
constexpr static unsigned int r = GEN_SIMD_WIDTH/4u;
};
// SIMD vector types
template <typename T>
struct vec {
alignas(GEN_SIMD_WIDTH) T v[W<T>::r];
};
typedef vec<float> vecf;
typedef vec<double> vecd;
struct Vsplat{
//Complex float
inline u128f operator()(float a, float b){
u128f out;
out.f[0] = a;
out.f[1] = b;
out.f[2] = a;
out.f[3] = b;
// Complex
template <typename T>
inline vec<T> operator()(T a, T b){
vec<T> out;
VECTOR_FOR(i, W<T>::r, 2)
{
out.v[i] = a;
out.v[i+1] = b;
}
return out;
}
// Real float
inline u128f operator()(float a){
u128f out;
out.f[0] = a;
out.f[1] = a;
out.f[2] = a;
out.f[3] = a;
// Real
template <typename T>
inline vec<T> operator()(T a){
vec<T> out;
VECTOR_FOR(i, W<T>::r, 1)
{
out.v[i] = a;
}
return out;
}
//Complex double
inline u128d operator()(double a, double b){
u128d out;
out.f[0] = a;
out.f[1] = b;
return out;
}
//Real double
inline u128d operator()(double a){
u128d out;
out.f[0] = a;
out.f[1] = a;
return out;
}
//Integer
// Integer
inline int operator()(Integer a){
return a;
}
};
struct Vstore{
//Float
inline void operator()(u128f a, float* F){
memcpy(F,a.f,4*sizeof(float));
}
//Double
inline void operator()(u128d a, double* D){
memcpy(D,a.f,2*sizeof(double));
// Real
template <typename T>
inline void operator()(vec<T> a, T *D){
*((vec<T> *)D) = a;
}
//Integer
inline void operator()(int a, Integer* I){
I[0] = a;
inline void operator()(int a, Integer *I){
*I = a;
}
};
struct Vstream{
//Float
inline void operator()(float * a, u128f b){
memcpy(a,b.f,4*sizeof(float));
// Real
template <typename T>
inline void operator()(T * a, vec<T> b){
*((vec<T> *)a) = b;
}
//Double
inline void operator()(double * a, u128d b){
memcpy(a,b.f,2*sizeof(double));
}
};
struct Vset{
// Complex float
inline u128f operator()(Grid::ComplexF *a){
u128f out;
out.f[0] = a[0].real();
out.f[1] = a[0].imag();
out.f[2] = a[1].real();
out.f[3] = a[1].imag();
// Complex
template <typename T>
inline vec<T> operator()(std::complex<T> *a){
vec<T> out;
VECTOR_FOR(i, W<T>::c, 1)
{
out.v[2*i] = a[i].real();
out.v[2*i+1] = a[i].imag();
}
return out;
}
// Complex double
inline u128d operator()(Grid::ComplexD *a){
u128d out;
out.f[0] = a[0].real();
out.f[1] = a[0].imag();
return out;
}
// Real float
inline u128f operator()(float *a){
u128f out;
out.f[0] = a[0];
out.f[1] = a[1];
out.f[2] = a[2];
out.f[3] = a[3];
return out;
}
// Real double
inline u128d operator()(double *a){
u128d out;
out.f[0] = a[0];
out.f[1] = a[1];
// Real
template <typename T>
inline vec<T> operator()(T *a){
vec<T> out;
out = *((vec<T> *)a);
return out;
}
// Integer
inline int operator()(Integer *a){
return a[0];
return *a;
}
};
/////////////////////////////////////////////////////
// Arithmetic operations
/////////////////////////////////////////////////////
struct Sum{
// Complex/Real
template <typename T>
inline vec<T> operator()(vec<T> a, vec<T> b){
vec<T> out;
VECTOR_FOR(i, W<T>::r, 1)
{
out.v[i] = a.v[i] + b.v[i];
}
return out;
}
//I nteger
inline int operator()(int a, int b){
return a + b;
}
};
struct Sub{
// Complex/Real
template <typename T>
inline vec<T> operator()(vec<T> a, vec<T> b){
vec<T> out;
VECTOR_FOR(i, W<T>::r, 1)
{
out.v[i] = a.v[i] - b.v[i];
}
return out;
}
//Integer
inline int operator()(int a, int b){
return a-b;
}
};
struct Mult{
// Real
template <typename T>
inline vec<T> operator()(vec<T> a, vec<T> b){
vec<T> out;
VECTOR_FOR(i, W<T>::r, 1)
{
out.v[i] = a.v[i]*b.v[i];
}
return out;
}
// Integer
inline int operator()(int a, int b){
return a*b;
}
};
#define cmul(a, b, c, i)\
c[i] = a[i]*b[i] - a[i+1]*b[i+1];\
c[i+1] = a[i]*b[i+1] + a[i+1]*b[i];
struct MultComplex{
// Complex
template <typename T>
inline vec<T> operator()(vec<T> a, vec<T> b){
vec<T> out;
VECTOR_FOR(i, W<T>::c, 1)
{
cmul(a.v, b.v, out.v, 2*i);
}
return out;
}
};
#undef cmul
struct Div{
// Real
template <typename T>
inline vec<T> operator()(vec<T> a, vec<T> b){
vec<T> out;
VECTOR_FOR(i, W<T>::r, 1)
{
out.v[i] = a.v[i]/b.v[i];
}
return out;
}
};
#define conj(a, b, i)\
b[i] = a[i];\
b[i+1] = -a[i+1];
struct Conj{
// Complex
template <typename T>
inline vec<T> operator()(vec<T> a){
vec<T> out;
VECTOR_FOR(i, W<T>::c, 1)
{
conj(a.v, out.v, 2*i);
}
return out;
}
};
#undef conj
#define timesmi(a, b, i)\
b[i] = a[i+1];\
b[i+1] = -a[i];
struct TimesMinusI{
// Complex
template <typename T>
inline vec<T> operator()(vec<T> a, vec<T> b){
vec<T> out;
VECTOR_FOR(i, W<T>::c, 1)
{
timesmi(a.v, out.v, 2*i);
}
return out;
}
};
#undef timesmi
#define timesi(a, b, i)\
b[i] = -a[i+1];\
b[i+1] = a[i];
struct TimesI{
// Complex
template <typename T>
inline vec<T> operator()(vec<T> a, vec<T> b){
vec<T> out;
VECTOR_FOR(i, W<T>::c, 1)
{
timesi(a.v, out.v, 2*i);
}
return out;
}
};
#undef timesi
//////////////////////////////////////////////
// Some Template specialization
#define perm(a, b, n, w)\
unsigned int _mask = w >> (n + 1);\
VECTOR_FOR(i, w, 1)\
{\
b[i] = a[i^_mask];\
}
#define DECL_PERMUTE_N(n)\
template <typename T>\
static inline vec<T> Permute##n(vec<T> in) {\
vec<T> out;\
perm(in.v, out.v, n, W<T>::r);\
return out;\
}
struct Permute{
DECL_PERMUTE_N(0);
DECL_PERMUTE_N(1);
DECL_PERMUTE_N(2);
DECL_PERMUTE_N(3);
};
#undef perm
#undef DECL_PERMUTE_N
#define rot(a, b, n, w)\
VECTOR_FOR(i, w, 1)\
{\
b[i] = a[(i + n)%w];\
}
struct Rotate{
template <typename T>
static inline vec<T> rotate(vec<T> in, int n){
vec<T> out;
rot(in.v, out.v, n, W<T>::r);
return out;
}
};
#undef rot
#define acc(v, a, off, step, n)\
for (unsigned int i = off; i < n; i += step)\
{\
a += v[i];\
}
template <typename Out_type, typename In_type>
struct Reduce{
//Need templated class to overload output type
@ -164,316 +382,67 @@ namespace Optimization {
return 0;
}
};
/////////////////////////////////////////////////////
// Arithmetic operations
/////////////////////////////////////////////////////
struct Sum{
//Complex/Real float
inline u128f operator()(u128f a, u128f b){
u128f out;
out.f[0] = a.f[0] + b.f[0];
out.f[1] = a.f[1] + b.f[1];
out.f[2] = a.f[2] + b.f[2];
out.f[3] = a.f[3] + b.f[3];
return out;
}
//Complex/Real double
inline u128d operator()(u128d a, u128d b){
u128d out;
out.f[0] = a.f[0] + b.f[0];
out.f[1] = a.f[1] + b.f[1];
return out;
}
//Integer
inline int operator()(int a, int b){
return a + b;
}
};
struct Sub{
//Complex/Real float
inline u128f operator()(u128f a, u128f b){
u128f out;
out.f[0] = a.f[0] - b.f[0];
out.f[1] = a.f[1] - b.f[1];
out.f[2] = a.f[2] - b.f[2];
out.f[3] = a.f[3] - b.f[3];
return out;
}
//Complex/Real double
inline u128d operator()(u128d a, u128d b){
u128d out;
out.f[0] = a.f[0] - b.f[0];
out.f[1] = a.f[1] - b.f[1];
return out;
}
//Integer
inline int operator()(int a, int b){
return a-b;
}
};
struct MultComplex{
// Complex float
inline u128f operator()(u128f a, u128f b){
u128f out;
out.f[0] = a.f[0]*b.f[0] - a.f[1]*b.f[1];
out.f[1] = a.f[0]*b.f[1] + a.f[1]*b.f[0];
out.f[2] = a.f[2]*b.f[2] - a.f[3]*b.f[3];
out.f[3] = a.f[2]*b.f[3] + a.f[3]*b.f[2];
return out;
}
// Complex double
inline u128d operator()(u128d a, u128d b){
u128d out;
out.f[0] = a.f[0]*b.f[0] - a.f[1]*b.f[1];
out.f[1] = a.f[0]*b.f[1] + a.f[1]*b.f[0];
return out;
}
};
struct Mult{
//CK: Appear unneeded
// inline float mac(float a, float b,double c){
// return 0;
// }
// inline double mac(double a, double b,double c){
// return 0;
// }
// Real float
inline u128f operator()(u128f a, u128f b){
u128f out;
out.f[0] = a.f[0]*b.f[0];
out.f[1] = a.f[1]*b.f[1];
out.f[2] = a.f[2]*b.f[2];
out.f[3] = a.f[3]*b.f[3];
return out;
}
// Real double
inline u128d operator()(u128d a, u128d b){
u128d out;
out.f[0] = a.f[0]*b.f[0];
out.f[1] = a.f[1]*b.f[1];
return out;
}
// Integer
inline int operator()(int a, int b){
return a*b;
}
};
struct Conj{
// Complex single
inline u128f operator()(u128f in){
u128f out;
out.f[0] = in.f[0];
out.f[1] = -in.f[1];
out.f[2] = in.f[2];
out.f[3] = -in.f[3];
return out;
}
// Complex double
inline u128d operator()(u128d in){
u128d out;
out.f[0] = in.f[0];
out.f[1] = -in.f[1];
return out;
}
// do not define for integer input
};
struct TimesMinusI{
//Complex single
inline u128f operator()(u128f in, u128f ret){ //note ret is ignored
u128f out;
out.f[0] = in.f[1];
out.f[1] = -in.f[0];
out.f[2] = in.f[3];
out.f[3] = -in.f[2];
return out;
}
//Complex double
inline u128d operator()(u128d in, u128d ret){
u128d out;
out.f[0] = in.f[1];
out.f[1] = -in.f[0];
return out;
}
};
struct TimesI{
//Complex single
inline u128f operator()(u128f in, u128f ret){ //note ret is ignored
u128f out;
out.f[0] = -in.f[1];
out.f[1] = in.f[0];
out.f[2] = -in.f[3];
out.f[3] = in.f[2];
return out;
}
//Complex double
inline u128d operator()(u128d in, u128d ret){
u128d out;
out.f[0] = -in.f[1];
out.f[1] = in.f[0];
return out;
}
};
//////////////////////////////////////////////
// Some Template specialization
struct Permute{
//We just have to mirror the permutes of Grid_sse4.h
static inline u128f Permute0(u128f in){ //AB CD -> CD AB
u128f out;
out.f[0] = in.f[2];
out.f[1] = in.f[3];
out.f[2] = in.f[0];
out.f[3] = in.f[1];
return out;
};
static inline u128f Permute1(u128f in){ //AB CD -> BA DC
u128f out;
out.f[0] = in.f[1];
out.f[1] = in.f[0];
out.f[2] = in.f[3];
out.f[3] = in.f[2];
return out;
};
static inline u128f Permute2(u128f in){
return in;
};
static inline u128f Permute3(u128f in){
return in;
};
static inline u128d Permute0(u128d in){ //AB -> BA
u128d out;
out.f[0] = in.f[1];
out.f[1] = in.f[0];
return out;
};
static inline u128d Permute1(u128d in){
return in;
};
static inline u128d Permute2(u128d in){
return in;
};
static inline u128d Permute3(u128d in){
return in;
};
};
template < typename vtype >
void permute(vtype &a, vtype b, int perm) {
};
struct Rotate{
static inline u128f rotate(u128f in,int n){
u128f out;
switch(n){
case 0:
out.f[0] = in.f[0];
out.f[1] = in.f[1];
out.f[2] = in.f[2];
out.f[3] = in.f[3];
break;
case 1:
out.f[0] = in.f[1];
out.f[1] = in.f[2];
out.f[2] = in.f[3];
out.f[3] = in.f[0];
break;
case 2:
out.f[0] = in.f[2];
out.f[1] = in.f[3];
out.f[2] = in.f[0];
out.f[3] = in.f[1];
break;
case 3:
out.f[0] = in.f[3];
out.f[1] = in.f[0];
out.f[2] = in.f[1];
out.f[3] = in.f[2];
break;
default: assert(0);
}
return out;
}
static inline u128d rotate(u128d in,int n){
u128d out;
switch(n){
case 0:
out.f[0] = in.f[0];
out.f[1] = in.f[1];
break;
case 1:
out.f[0] = in.f[1];
out.f[1] = in.f[0];
break;
default: assert(0);
}
return out;
}
};
//Complex float Reduce
template<>
inline Grid::ComplexF Reduce<Grid::ComplexF, u128f>::operator()(u128f in){ //2 complex
return Grid::ComplexF(in.f[0] + in.f[2], in.f[1] + in.f[3]);
template <>
inline Grid::ComplexF Reduce<Grid::ComplexF, vecf>::operator()(vecf in){
float a = 0.f, b = 0.f;
acc(in.v, a, 0, 2, W<float>::r);
acc(in.v, b, 1, 2, W<float>::r);
return Grid::ComplexF(a, b);
}
//Real float Reduce
template<>
inline Grid::RealF Reduce<Grid::RealF, u128f>::operator()(u128f in){ //4 floats
return in.f[0] + in.f[1] + in.f[2] + in.f[3];
inline Grid::RealF Reduce<Grid::RealF, vecf>::operator()(vecf in){
float a = 0.;
acc(in.v, a, 0, 1, W<float>::r);
return a;
}
//Complex double Reduce
template<>
inline Grid::ComplexD Reduce<Grid::ComplexD, u128d>::operator()(u128d in){ //1 complex
return Grid::ComplexD(in.f[0],in.f[1]);
inline Grid::ComplexD Reduce<Grid::ComplexD, vecd>::operator()(vecd in){
double a = 0., b = 0.;
acc(in.v, a, 0, 2, W<double>::r);
acc(in.v, b, 1, 2, W<double>::r);
return Grid::ComplexD(a, b);
}
//Real double Reduce
template<>
inline Grid::RealD Reduce<Grid::RealD, u128d>::operator()(u128d in){ //2 doubles
return in.f[0] + in.f[1];
inline Grid::RealD Reduce<Grid::RealD, vecd>::operator()(vecd in){
double a = 0.f;
acc(in.v, a, 0, 1, W<double>::r);
return a;
}
//Integer Reduce
template<>
inline Integer Reduce<Integer, int>::operator()(int in){
// FIXME unimplemented
printf("Reduce : Missing integer implementation -> FIX\n");
assert(0);
return in;
}
}
//////////////////////////////////////////////////////////////////////////////////////
// Here assign types
typedef Optimization::u128f SIMD_Ftype; // Single precision type
typedef Optimization::u128d SIMD_Dtype; // Double precision type
typedef Optimization::vecf SIMD_Ftype; // Single precision type
typedef Optimization::vecd SIMD_Dtype; // Double precision type
typedef int SIMD_Itype; // Integer type
// prefetch utilities
inline void v_prefetch0(int size, const char *ptr){};
inline void prefetch_HINT_T0(const char *ptr){};
// Gpermute function
template < typename VectorSIMD >
inline void Gpermute(VectorSIMD &y,const VectorSIMD &b, int perm ) {
Optimization::permute(y.v,b.v,perm);
}
// Function name aliases
typedef Optimization::Vsplat VsplatSIMD;
typedef Optimization::Vstore VstoreSIMD;
@ -481,16 +450,13 @@ namespace Optimization {
typedef Optimization::Vstream VstreamSIMD;
template <typename S, typename T> using ReduceSIMD = Optimization::Reduce<S,T>;
// Arithmetic operations
typedef Optimization::Sum SumSIMD;
typedef Optimization::Sub SubSIMD;
typedef Optimization::Div DivSIMD;
typedef Optimization::Mult MultSIMD;
typedef Optimization::MultComplex MultComplexSIMD;
typedef Optimization::Conj ConjSIMD;
typedef Optimization::TimesMinusI TimesMinusISIMD;
typedef Optimization::TimesI TimesISIMD;
}

12
lib/simd/Grid_imci.h
View File

@ -236,6 +236,17 @@ namespace Optimization {
}
};
struct Div{
// Real float
inline __m512 operator()(__m512 a, __m512 b){
return _mm512_div_ps(a,b);
}
// Real double
inline __m512d operator()(__m512d a, __m512d b){
return _mm512_div_pd(a,b);
}
};
struct Conj{
// Complex single
@ -429,6 +440,7 @@ namespace Optimization {
// Arithmetic operations
typedef Optimization::Sum SumSIMD;
typedef Optimization::Sub SubSIMD;
typedef Optimization::Div DivSIMD;
typedef Optimization::Mult MultSIMD;
typedef Optimization::MultComplex MultComplexSIMD;
typedef Optimization::Conj ConjSIMD;

15
lib/simd/Grid_sse4.h
View File

@ -224,6 +224,18 @@ namespace Optimization {
}
};
struct Div{
// Real float
inline __m128 operator()(__m128 a, __m128 b){
return _mm_div_ps(a,b);
}
// Real double
inline __m128d operator()(__m128d a, __m128d b){
return _mm_div_pd(a,b);
}
};
struct Conj{
// Complex single
inline __m128 operator()(__m128 in){
@ -372,6 +384,8 @@ namespace Optimization {
}
}
//////////////////////////////////////////////////////////////////////////////////////
// Here assign types
@ -398,6 +412,7 @@ namespace Optimization {
// Arithmetic operations
typedef Optimization::Sum SumSIMD;
typedef Optimization::Sub SubSIMD;
typedef Optimization::Div DivSIMD;
typedef Optimization::Mult MultSIMD;
typedef Optimization::MultComplex MultComplexSIMD;
typedef Optimization::Conj ConjSIMD;

90
lib/simd/Grid_vector_types.h
View File

@ -38,7 +38,7 @@ directory
#ifndef GRID_VECTOR_TYPES
#define GRID_VECTOR_TYPES
#ifdef GENERIC_VEC
#ifdef GEN
#include "Grid_generic.h"
#endif
#ifdef SSE4
@ -77,38 +77,24 @@ struct RealPart<std::complex<T> > {
//////////////////////////////////////
// demote a vector to real type
//////////////////////////////////////
// type alias used to simplify the syntax of std::enable_if
template <typename T>
using Invoke = typename T::type;
template <typename Condition, typename ReturnType>
using EnableIf = Invoke<std::enable_if<Condition::value, ReturnType> >;
template <typename Condition, typename ReturnType>
using NotEnableIf = Invoke<std::enable_if<!Condition::value, ReturnType> >;
template <typename T> using Invoke = typename T::type;
template <typename Condition, typename ReturnType> using EnableIf = Invoke<std::enable_if<Condition::value, ReturnType> >;
template <typename Condition, typename ReturnType> using NotEnableIf = Invoke<std::enable_if<!Condition::value, ReturnType> >;
////////////////////////////////////////////////////////
// Check for complexity with type traits
template <typename T>
struct is_complex : public std::false_type {};
template <>
struct is_complex<std::complex<double> > : public std::true_type {};
template <>
struct is_complex<std::complex<float> > : public std::true_type {};
template <typename T> struct is_complex : public std::false_type {};
template <> struct is_complex<std::complex<double> > : public std::true_type {};
template <> struct is_complex<std::complex<float> > : public std::true_type {};
template <typename T>
using IfReal = Invoke<std::enable_if<std::is_floating_point<T>::value, int> >;
template <typename T>
using IfComplex = Invoke<std::enable_if<is_complex<T>::value, int> >;
template <typename T>
using IfInteger = Invoke<std::enable_if<std::is_integral<T>::value, int> >;
template <typename T> using IfReal = Invoke<std::enable_if<std::is_floating_point<T>::value, int> >;
template <typename T> using IfComplex = Invoke<std::enable_if<is_complex<T>::value, int> >;
template <typename T> using IfInteger = Invoke<std::enable_if<std::is_integral<T>::value, int> >;
template <typename T>
using IfNotReal =
Invoke<std::enable_if<!std::is_floating_point<T>::value, int> >;
template <typename T>
using IfNotComplex = Invoke<std::enable_if<!is_complex<T>::value, int> >;
template <typename T>
using IfNotInteger = Invoke<std::enable_if<!std::is_integral<T>::value, int> >;
template <typename T> using IfNotReal = Invoke<std::enable_if<!std::is_floating_point<T>::value, int> >;
template <typename T> using IfNotComplex = Invoke<std::enable_if<!is_complex<T>::value, int> >;
template <typename T> using IfNotInteger = Invoke<std::enable_if<!std::is_integral<T>::value, int> >;
////////////////////////////////////////////////////////
// Define the operation templates functors
@ -285,6 +271,20 @@ class Grid_simd {
return a * b;
}
//////////////////////////////////
// Divides
//////////////////////////////////
friend inline Grid_simd operator/(const Scalar_type &a, Grid_simd b) {
Grid_simd va;
vsplat(va, a);
return va / b;
}
friend inline Grid_simd operator/(Grid_simd b, const Scalar_type &a) {
Grid_simd va;
vsplat(va, a);
return b / a;
}
///////////////////////
// Unary negation
///////////////////////
@ -428,7 +428,6 @@ inline void rotate(Grid_simd<S,V> &ret,Grid_simd<S,V> b,int nrot)
ret.v = Optimization::Rotate::rotate(b.v,2*nrot);
}
template <class S, class V>
inline void vbroadcast(Grid_simd<S,V> &ret,const Grid_simd<S,V> &src,int lane){
S* typepun =(S*) &src;
@ -512,7 +511,6 @@ template <class S, class V, IfInteger<S> = 0>
inline void vfalse(Grid_simd<S, V> &ret) {
vsplat(ret, 0);
}
template <class S, class V>
inline void zeroit(Grid_simd<S, V> &z) {
vzero(z);
@ -530,7 +528,6 @@ inline void vstream(Grid_simd<S, V> &out, const Grid_simd<S, V> &in) {
typedef typename S::value_type T;
binary<void>((T *)&out.v, in.v, VstreamSIMD());
}
template <class S, class V, IfInteger<S> = 0>
inline void vstream(Grid_simd<S, V> &out, const Grid_simd<S, V> &in) {
out = in;
@ -569,6 +566,34 @@ inline Grid_simd<S, V> operator*(Grid_simd<S, V> a, Grid_simd<S, V> b) {
return ret;
};
// Distinguish between complex types and others
template <class S, class V, IfComplex<S> = 0>
inline Grid_simd<S, V> operator/(Grid_simd<S, V> a, Grid_simd<S, V> b) {
typedef Grid_simd<S, V> simd;
simd ret;
simd den;
typename simd::conv_t conv;
ret = a * conjugate(b) ;
den = b * conjugate(b) ;
auto real_den = toReal(den);
ret.v=binary<V>(ret.v, real_den.v, DivSIMD());
return ret;
};
// Real/Integer types
template <class S, class V, IfNotComplex<S> = 0>
inline Grid_simd<S, V> operator/(Grid_simd<S, V> a, Grid_simd<S, V> b) {
Grid_simd<S, V> ret;
ret.v = binary<V>(a.v, b.v, DivSIMD());
return ret;
};
///////////////////////
// Conjugate
///////////////////////
@ -582,7 +607,6 @@ template <class S, class V, IfNotComplex<S> = 0>
inline Grid_simd<S, V> conjugate(const Grid_simd<S, V> &in) {
return in; // for real objects
}
// Suppress adj for integer types... // odd; why conjugate above but not adj??
template <class S, class V, IfNotInteger<S> = 0>
inline Grid_simd<S, V> adj(const Grid_simd<S, V> &in) {
@ -596,14 +620,12 @@ template <class S, class V, IfComplex<S> = 0>
inline void timesMinusI(Grid_simd<S, V> &ret, const Grid_simd<S, V> &in) {
ret.v = binary<V>(in.v, ret.v, TimesMinusISIMD());
}
template <class S, class V, IfComplex<S> = 0>
inline Grid_simd<S, V> timesMinusI(const Grid_simd<S, V> &in) {
Grid_simd<S, V> ret;
timesMinusI(ret, in);
return ret;
}
template <class S, class V, IfNotComplex<S> = 0>
inline Grid_simd<S, V> timesMinusI(const Grid_simd<S, V> &in) {
return in;
@ -616,14 +638,12 @@ template <class S, class V, IfComplex<S> = 0>
inline void timesI(Grid_simd<S, V> &ret, const Grid_simd<S, V> &in) {
ret.v = binary<V>(in.v, ret.v, TimesISIMD());
}
template <class S, class V, IfComplex<S> = 0>
inline Grid_simd<S, V> timesI(const Grid_simd<S, V> &in) {
Grid_simd<S, V> ret;
timesI(ret, in);
return ret;
}
template <class S, class V, IfNotComplex<S> = 0>
inline Grid_simd<S, V> timesI(const Grid_simd<S, V> &in) {
return in;

2
lib/simd/Intel512avx.h
View File

@ -53,7 +53,7 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
#define ZMULMEM2SPd(O,P,tmp,B,C,Briir,Biirr,Criir,Ciirr)\
VSHUFMEMd(O,P,tmp) \
VMULMEMd(O,P,B,Biirr) \
VMULMEMd(O,P,B,Biirr) \
VMULMEMd(O,P,C,Ciirr) \
VMULd(tmp,B,Briir) \
VMULd(tmp,C,Criir)

9
lib/simd/Intel512common.h
View File

@ -37,7 +37,7 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
// Opcodes common
////////////////////////////////////////////////////////////////////////////////////////////////////
#define MASK_REGS \
__asm__ ("mov $0xAAAA, %%eax \n"\
__asm__ ("mov $0xAAAA, %%eax \n"\
"kmovw %%eax, %%k6 \n"\
"mov $0x5555, %%eax \n"\
"kmovw %%eax, %%k7 \n" : : : "%eax");
@ -138,9 +138,14 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
#define ZLOADf(OFF,PTR,ri,ir) VLOADf(OFF,PTR,ir) VSHUFf(ir,ri)
#define ZLOADd(OFF,PTR,ri,ir) VLOADd(OFF,PTR,ir) VSHUFd(ir,ri)
#define STREAM_STORE
#ifdef STREAM_STORE
#define VSTOREf(OFF,PTR,SRC) "vmovntps " #SRC "," #OFF "*64(" #PTR ")" ";\n"
#define VSTOREd(OFF,PTR,SRC) "vmovntpd " #SRC "," #OFF "*64(" #PTR ")" ";\n"
#else
#define VSTOREf(OFF,PTR,SRC) "vmovaps " #SRC "," #OFF "*64(" #PTR ")" ";\n"
#define VSTOREd(OFF,PTR,SRC) "vmovapd " #SRC "," #OFF "*64(" #PTR ")" ";\n"
#endif
// Swaps Re/Im ; could unify this with IMCI
#define VSHUFd(A,DEST) "vpshufd $0x4e," #A "," #DEST ";\n"

2
lib/stencil/Lebesgue.cc
View File

@ -32,7 +32,7 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
namespace Grid {
int LebesgueOrder::UseLebesgueOrder;
std::vector<int> LebesgueOrder::Block({2,2,2,2});
std::vector<int> LebesgueOrder::Block({8,2,2,2});
LebesgueOrder::IndexInteger LebesgueOrder::alignup(IndexInteger n){
n--; // 1000 0011 --> 1000 0010

30
lib/tensors/Tensor_arith_mul.h
View File

@ -126,6 +126,36 @@ iVector<rtype,N> operator * (const iVector<mtype,N>& lhs,const iScalar<vtype>& r
mult(&ret,&lhs,&rhs);
return ret;
}
//////////////////////////////////////////////////////////////////
// Divide by scalar
//////////////////////////////////////////////////////////////////
template<class rtype,class vtype> strong_inline
iScalar<rtype> operator / (const iScalar<rtype>& lhs,const iScalar<vtype>& rhs)
{
iScalar<rtype> ret;
ret._internal = lhs._internal/rhs._internal;
return ret;
}
template<class rtype,class vtype,int N> strong_inline
iVector<rtype,N> operator / (const iVector<rtype,N>& lhs,const iScalar<vtype>& rhs)
{
iVector<rtype,N> ret;
for(int i=0;i<N;i++){
ret._internal[i] = lhs._internal[i]/rhs._internal;
}
return ret;
}
template<class rtype,class vtype,int N> strong_inline
iMatrix<rtype,N> operator / (const iMatrix<rtype,N>& lhs,const iScalar<vtype>& rhs)
{
iMatrix<rtype,N> ret;
for(int i=0;i<N;i++){
for(int j=0;j<N;j++){
ret._internal[i][j] = lhs._internal[i][j]/rhs._internal;
}}
return ret;
}
//////////////////////////////////////////////////////////////////
// Glue operators to mult routines. Must resolve return type cleverly from typeof(internal)

6
lib/tensors/Tensor_extract_merge.h
View File

@ -250,8 +250,7 @@ void merge(vobj &vec,std::vector<typename vobj::scalar_object *> &extracted,int
}
}
template<class vobj> inline
void merge1(vobj &vec,std::vector<typename vobj::scalar_object *> &extracted,int offset)
template<class vobj> inline void merge1(vobj &vec,std::vector<typename vobj::scalar_object *> &extracted,int offset)
{
typedef typename vobj::scalar_type scalar_type ;
typedef typename vobj::vector_type vector_type ;
@ -269,8 +268,7 @@ void merge1(vobj &vec,std::vector<typename vobj::scalar_object *> &extracted,int
}}
}
template<class vobj> inline
void merge2(vobj &vec,std::vector<typename vobj::scalar_object *> &extracted,int offset)
template<class vobj> inline void merge2(vobj &vec,std::vector<typename vobj::scalar_object *> &extracted,int offset)
{
typedef typename vobj::scalar_type scalar_type ;
typedef typename vobj::vector_type vector_type ;

1
scripts/arm_configure.experimental
View File

@ -1 +0,0 @@
./configure --host=arm-linux-gnueabihf CXX=clang++-3.5 CXXFLAGS='-std=c++11 -O3 -target arm-linux-gnueabihf -I/usr/arm-linux-gnueabihf/include/ -I/home/neo/Codes/gmp6.0/gmp-arm/include/ -I/usr/arm-linux-gnueabihf/include/c++/4.8.2/arm-linux-gnueabihf/ -L/home/neo/Codes/gmp6.0/gmp-arm/lib/ -I/home/neo/Codes/mpfr3.1.2/mpfr-arm/include/ -L/home/neo/Codes/mpfr3.1.2/mpfr-arm/lib/ -static -mcpu=cortex-a7' --enable-simd=NEONv7

3
scripts/arm_configure.experimental_cortex57
View File

@ -1,3 +0,0 @@
#./configure --host=arm-linux-gnueabihf CXX=clang++-3.5 CXXFLAGS='-std=c++11 -O3 -target arm-linux-gnueabihf -I/usr/arm-linux-gnueabihf/include/ -I/home/neo/Codes/gmp6.0/gmp-arm/include/ -I/usr/lib/llvm-3.5/lib/clang/3.5.0/include/ -L/home/neo/Codes/gmp6.0/gmp-arm/lib/ -I/home/neo/Codes/mpfr3.1.2/mpfr-arm/include/ -L/home/neo/Codes/mpfr3.1.2/mpfr-arm/lib/ -static -mcpu=cortex-a57' --enable-simd=NEONv7
./configure --host=aarch64-linux-gnu CXX=clang++-3.5 CXXFLAGS='-std=c++11 -O3 -target aarch64-linux-gnu -static -I/home/neo/Codes/gmp6.0/gmp-armv8/include/ -L/home/neo/Codes/gmp6.0/gmp-armv8/lib/ -I/home/neo/Codes/mpfr3.1.2/mpfr-armv8/include/ -L/home/neo/Codes/mpfr3.1.2/mpfr-armv8/lib/ -I/usr/aarch64-linux-gnu/include/ -I/usr/aarch64-linux-gnu/include/c++/4.8.2/aarch64-linux-gnu/' --enable-simd=NEONv7

9
scripts/bench_wilson.sh
View File

@ -1,9 +0,0 @@
for omp in 1 2 4
do
echo > wilson.t$omp
for vol in 4.4.4.4 4.4.4.8 4.4.8.8 4.8.8.8 8.8.8.8 8.8.8.16 8.8.16.16 8.16.16.16
do
perf=` ./benchmarks/Grid_wilson --grid $vol --omp $omp | grep mflop | awk '{print $3}'`
echo $vol $perf >> wilson.t$omp
done
done

46
scripts/build-all
View File

@ -1,46 +0,0 @@
#!/bin/bash -e
DIRS="clang-avx clang-avx-openmp clang-avx-openmp-mpi clang-avx-mpi clang-avx2 clang-avx2-openmp clang-avx2-openmp-mpi clang-avx2-mpi clang-sse"
EXTRADIRS="g++-avx g++-sse4 icpc-avx icpc-avx2 icpc-avx512"
BLACK="\033[30m"
RED="\033[31m"
GREEN="\033[32m"
YELLOW="\033[33m"
BLUE="\033[34m"
PINK="\033[35m"
CYAN="\033[36m"
WHITE="\033[37m"
NORMAL="\033[0;39m"
for D in $DIRS
do
echo
echo -e $RED ==============================
echo -e $GREEN $D
echo -e $RED ==============================
echo -e $BLUE
cd builds/$D
make clean all -j 8
cd ../../
echo -e $NORMAL
done
if [ "X$1" == "Xextra" ]
then
for D in $EXTRADIRS
do
echo
echo -e $RED ==============================
echo -e $RED $D
echo -e $RED ==============================
echo -e $BLUE
cd builds/$D
make clean all -j 8
cd ../../
echo -e $NORMAL
done
fi

11
scripts/configure-all
View File

@ -1,11 +0,0 @@
#!/bin/bash
DIRS="clang-avx clang-avx-openmp clang-avx-openmp-mpi clang-avx-mpi clang-avx2 clang-avx2-openmp clang-avx2-openmp-mpi clang-avx2-mpi icpc-avx icpc-avx2 icpc-avx512 g++-sse4 g++-avx clang-sse icpc-avx-openmp-mpi icpc-avx-openmp"
for D in $DIRS
do
mkdir -p builds/$D
cd builds/$D
../../scripts/configure-commands $D
cd ../..
done

89
scripts/configure-commands
View File

@ -1,89 +0,0 @@
#!/bin/bash
WD=$1
BLACK="\033[30m"
RED="\033[31m"
GREEN="\033[32m"
YELLOW="\033[33m"
BLUE="\033[34m"
PINK="\033[35m"
CYAN="\033[36m"
WHITE="\033[37m"
NORMAL="\033[0;39m"
echo
echo -e $RED ==============================
echo -e $GREEN $WD
echo -e $RED ==============================
echo -e $YELLOW
case $WD in
g++-avx)
CXX=g++ ../../configure --enable-simd=AVX CXXFLAGS="-mavx -O3 -std=c++11" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
g++-avx-openmp)
CXX=g++ ../../configure --enable-simd=AVX CXXFLAGS="-mavx -fopenmp -O3 -std=c++11" LIBS="-fopenmp -lgmp -lmpfr" --enable-comms=none
;;
g++5-sse4)
CXX=g++-5 ../../configure --enable-simd=SSE4 CXXFLAGS="-msse4 -O3 -std=c++11" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
g++5-avx)
CXX=g++-5 ../../configure --enable-simd=AVX CXXFLAGS="-mavx -O3 -std=c++11" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
icpc-avx)
CXX=icpc ../../configure --enable-simd=AVX CXXFLAGS="-mavx -O3 -std=c++11" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
icpc-avx-openmp-mpi)
CXX=icpc ../../configure --enable-simd=AVX CXXFLAGS="-mavx -fopenmp -O3 -I/opt/local/include/openmpi-mp/ -std=c++11" LDFLAGS=-L/opt/local/lib/openmpi-mp/ LIBS="-lmpi -lmpi_cxx -fopenmp -lgmp -lmpfr" --enable-comms=mpi
;;
icpc-avx-openmp)
CXX=icpc ../../configure --enable-precision=single --enable-simd=AVX CXXFLAGS="-mavx -fopenmp -O3 -std=c++11" LIBS="-fopenmp -lgmp -lmpfr" --enable-comms=mpi
;;
icpc-avx2)
CXX=icpc ../../configure --enable-simd=AVX2 CXXFLAGS="-march=core-avx2 -O3 -std=c++11" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
icpc-avx512)
CXX=icpc ../../configure --enable-simd=AVX512 CXXFLAGS="-xCOMMON-AVX512 -O3 -std=c++11" --host=none LIBS="-lgmp -lmpfr" --enable-comms=none
;;
icpc-mic)
CXX=icpc ../../configure --host=none --enable-simd=IMCI CXXFLAGS="-mmic -O3 -std=c++11" LDFLAGS=-mmic LIBS="-lgmp -lmpfr" --enable-comms=none
;;
icpc-mic-avx512)
CXX=icpc ../../configure --host=none --enable-simd=IMCI CXXFLAGS="-xCOMMON_AVX512 -O3 -std=c++11" LDFLAGS=-xCOMMON_AVX512 LIBS="-lgmp -lmpfr" --enable-comms=none
;;
clang-sse)
CXX=clang++ ../../configure --enable-precision=single --enable-simd=SSE4 CXXFLAGS="-msse4 -O3 -std=c++11" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
clang-avx)
CXX=clang++ ../../configure --enable-simd=AVX CXXFLAGS="-mavx -O3 -std=c++11" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
clang-avx2)
CXX=clang++ ../../configure --enable-simd=AVX2 CXXFLAGS="-mavx2 -mfma -O3 -std=c++11" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
clang-avx-openmp)
CXX=clang-omp++ ../../configure --enable-precision=double --enable-simd=AVX CXXFLAGS="-mavx -fopenmp -O3 -std=c++11" LDFLAGS="-fopenmp" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
clang-xc30)
CXX=$HOME/Clang/install/bin/clang++ ../../configure --enable-simd=AVX CXXFLAGS="-mavx -O3 -std=c++11 -I/opt/gcc/4.9.2/snos/include/g++/x86_64-suse-linux/ -I/opt/gcc/4.9.2/snos/include/g++/ " LDFLAGS="" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
clang-xc30-openmp)
CXX=$HOME/Clang/install/bin/clang++ ../../configure --enable-simd=AVX CXXFLAGS="-mavx -fopenmp -O3 -std=c++11 -I/opt/gcc/4.9.2/snos/include/g++/x86_64-suse-linux/ -I/opt/gcc/4.9.2/snos/include/g++/ " LDFLAGS="-fopenmp" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
clang-avx2-openmp)
CXX=clang-omp++ ../../configure --enable-simd=AVX2 CXXFLAGS="-mavx2 -mfma -fopenmp -O3 -std=c++11" LDFLAGS="-fopenmp" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
clang-avx-openmp-mpi)
CXX=clang-omp++ ../../configure --enable-simd=AVX CXXFLAGS="-mavx -fopenmp -O3 -I/opt/local/include/openmpi-mp/ -std=c++11" LDFLAGS=-L/opt/local/lib/openmpi-mp/ LIBS="-lmpi -lmpi_cxx -fopenmp -lgmp -lmpfr" --enable-comms=mpi
;;
clang-avx2-openmp-mpi)
CXX=clang-omp++ ../../configure --enable-simd=AVX2 CXXFLAGS="-mavx2 -mfma -fopenmp -O3 -I/opt/local/include/openmpi-mp/ -std=c++11" LDFLAGS=-L/opt/local/lib/openmpi-mp/ LIBS="-lmpi -lmpi_cxx -fopenmp -lgmp -lmpfr" --enable-comms=mpi
;;
clang-avx-mpi)
CXX=clang++ ../../configure --enable-simd=AVX CXXFLAGS="-mavx -O3 -I/opt/local/include/openmpi-mp/ -std=c++11" LDFLAGS=-L/opt/local/lib/openmpi-mp/ LIBS="-lmpi -lmpi_cxx -lgmp -lmpfr" --enable-comms=mpi
;;
clang-avx2-mpi)
CXX=clang++ ../../configure --enable-simd=AVX2 CXXFLAGS="-mavx2 -mfma -O3 -I/opt/local/include/openmpi-mp/ -std=c++11" LDFLAGS=-L/opt/local/lib/openmpi-mp/ LIBS="-lmpi -lmpi_cxx -lgmp -lmpfr" --enable-comms=mpi
;;
clang-avx2)
CXX=clang++ ../../configure --enable-simd=AVX2 CXXFLAGS="-mavx2 -mfma -O3 -std=c++11" LDFLAGS="-L/usr/local/lib/" LIBS="-lgmp -lmpfr" --enable-comms=none
;;
esac
echo -e $NORMAL

10
scripts/configure-cray
View File

@ -1,10 +0,0 @@
#!/bin/bash
DIRS="g++-avx-openmp g++-avx clang-xc30 clang-xc30-openmp"
for D in $DIRS
do
mkdir -p builds/$D
cd builds/$D
../../scripts/configure-commands $D
cd ../..
done

10
scripts/configure-mic
View File

@ -1,10 +0,0 @@
#!/bin/bash
DIRS="build-icpc-mic"
for D in $DIRS
do
mkdir -p $D
cd $D
../configure-commands
cd ..
done

16
scripts/copyright
View File

@ -12,6 +12,7 @@ Grid physics library, www.github.com/paboyle/Grid
Source file: $1
Copyright (C) 2015
Copyright (C) 2016
EOF
@ -38,8 +39,21 @@ See the full license in the file "LICENSE" in the top level distribution directo
/* END LEGAL */
EOF
cat message > tmp.fil
cat $1 >> tmp.fil
NOTICE=`grep -n "END LEGAL" $1 | awk '{ print $1 }' `
if [ "X$NOTICE" != "X" ]
then
echo "found notice ending on line $NOTICE"
awk 'BEGIN { P=0 } { if ( P ) print } /END LEGAL/{P=1} ' $1 >> tmp.fil
else
cat $1 >> tmp.fil
fi
cp tmp.fil $1
shift

2
scripts/cray-modules
View File

@ -1,2 +0,0 @@
module swap PrgEnv-cray PrgEnv-intel
module swap intel/14.0.4.211 intel/15.0.2.164

15
scripts/filelist
View File

@ -20,15 +20,20 @@ for subdir in $dirs; do
TESTS=`ls T*.cc`
TESTLIST=`echo ${TESTS} | sed s/.cc//g `
PREF=`[ $subdir = '.' ] && echo noinst || echo EXTRA`
echo "tests: ${TESTLIST}" > Make.inc
SUB=`[ $subdir = '.' ] && echo subtests`
echo "tests: ${TESTLIST} ${SUB}" > Make.inc
echo ${PREF}_PROGRAMS = ${TESTLIST} >> Make.inc
echo >> Make.inc
for f in $TESTS; do
BNAME=`basename $f .cc`
echo ${BNAME}_SOURCES=$f >> Make.inc
echo ${BNAME}_LDADD=-lGrid>> Make.inc
echo >> Make.inc
BNAME=`basename $f .cc`
echo ${BNAME}_SOURCES=$f >> Make.inc
echo ${BNAME}_LDADD=-lGrid>> Make.inc
echo >> Make.inc
done
if [ $subdir != '.' ]; then
echo CLEANFILES = ${TESTLIST} >> Make.inc
echo >> Make.inc
fi
done
# benchmarks Make.inc

4
scripts/reconfigure_script
View File

@ -1,4 +0,0 @@
aclocal -I m4
autoheader -f
automake -f --add-missing
autoconf -f

18
scripts/update_fftw.sh
View File

@ -1,18 +0,0 @@
#!/usr/bin/env bash
if (( $# != 1 )); then
echo "usage: `basename $0` <archive>" 1>&2
exit 1
fi
ARC=$1
INITDIR=`pwd`
rm -rf lib/fftw
mkdir lib/fftw
ARCDIR=`tar -tf ${ARC} | head -n1 | sed -e 's@/.*@@'`
tar -xf ${ARC}
cp ${ARCDIR}/api/fftw3.h lib/fftw/
cd ${INITDIR}
rm -rf ${ARCDIR}

7
scripts/wilson.gnu
View File

@ -1,7 +0,0 @@
plot 'wilson.t1' u 2 w l t "AVX1-OMP=1"
replot 'wilson.t2' u 2 w l t "AVX1-OMP=2"
replot 'wilson.t4' u 2 w l t "AVX1-OMP=4"
set terminal 'pdf'
set output 'wilson_clang.pdf'
replot
quit

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