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include/FluidSCWrapper.hpp
include/SCBufferAdaptor.hpp
nix
Owen Green 7 years ago
parent 337b3e6e25
commit 6d19889ba5
2 changed files with 188 additions and 260 deletions
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375
include/FluidSCWrapper.hpp
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@ -1,4 +1,4 @@
#pragma once
#pragma once
#include "SCBufferAdaptor.hpp"
#include <clients/common/FluidBaseClient.hpp>
@ -16,130 +16,142 @@
namespace fluid {
namespace client {
template <typename Client, typename Params> class FluidSCWrapper;
template <typename Client, typename Params>
class FluidSCWrapper;
namespace impl {
template <typename Client, typename T, size_t N> struct Setter;
template <size_t N, typename T> struct ArgumentGetter;
template <size_t N, typename T> struct ControlGetter;
template <typename T> using msg_iter_method = T (sc_msg_iter::*)(T);
template <typename Client, typename T, size_t N>
struct Setter;
template <size_t N, typename T>
struct ArgumentGetter;
template <size_t N, typename T>
struct ControlGetter;
template <typename T>
using msg_iter_method = T (sc_msg_iter::*)(T);
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//Iterate over kr/ir inputs via callbacks from params object
// Iterate over kr/ir inputs via callbacks from params object
struct FloatControlsIter
{
FloatControlsIter(float** vals, size_t N):mValues(vals), mSize(N) {}
float next()
{
return mCount >= mSize ? 0 : *mValues[mCount++];
}
FloatControlsIter(float **vals, size_t N)
: mValues(vals)
, mSize(N)
{}
void reset(float** vals)
float next() { return mCount >= mSize ? 0 : *mValues[mCount++]; }
void reset(float **vals)
{
mValues = vals;
mCount = 0;
mCount = 0;
}
size_t size() const noexcept { return mSize; }
private:
float** mValues;
size_t mSize;
size_t mCount{0};
private:
float **mValues;
size_t mSize;
size_t mCount{0};
};
//General case
template <size_t N, typename T> struct GetControl
// General case
template <size_t N, typename T>
struct GetControl
{
T operator()(World*, FloatControlsIter& controls) { return controls.next(); }
T operator()(World *, FloatControlsIter &controls) { return controls.next(); }
};
template <size_t N, typename T> struct ControlGetter : public GetControl<N, typename T::type>
template <size_t N, typename T>
struct ControlGetter : public GetControl<N, typename T::type>
{};
//Specializations
template <size_t N> struct ControlGetter<N, BufferT>
// Specializations
template <size_t N>
struct ControlGetter<N, BufferT>
{
auto operator() (World* w, FloatControlsIter& iter)
auto operator()(World *w, FloatControlsIter &iter)
{
typename LongT::type bufnum = iter.next();
return std::unique_ptr<BufferAdaptor>(bufnum >= 0 ? new SCBufferAdaptor(bufnum,w): nullptr);
return std::unique_ptr<BufferAdaptor>(bufnum >= 0 ? new SCBufferAdaptor(bufnum, w) : nullptr);
}
};
template<size_t N>
struct ControlGetter<N,FloatPairsArrayT>
template <size_t N>
struct ControlGetter<N, FloatPairsArrayT>
{
typename FloatPairsArrayT::type operator()(World*, FloatControlsIter& iter)
typename FloatPairsArrayT::type operator()(World *, FloatControlsIter &iter)
{
return {{iter.next(),iter.next()},{iter.next(),iter.next()}};
return {{iter.next(), iter.next()}, {iter.next(), iter.next()}};
}
};
template<size_t N>
struct ControlGetter<N,FFTParamsT>
template <size_t N>
struct ControlGetter<N, FFTParamsT>
{
typename FFTParamsT::type operator()(World*, FloatControlsIter& iter)
typename FFTParamsT::type operator()(World *, FloatControlsIter &iter)
{
return {static_cast<long>(iter.next()),static_cast<long>(iter.next()),static_cast<long>(iter.next())};
return {static_cast<long>(iter.next()), static_cast<long>(iter.next()), static_cast<long>(iter.next())};
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
/// Iterate over arguments in sc_msg_iter, via callbacks from params object
template <size_t N, typename T, msg_iter_method<T> Method> struct GetArgument
template <size_t N, typename T, msg_iter_method<T> Method>
struct GetArgument
{
T operator()(World* w, sc_msg_iter *args)
T operator()(World *w, sc_msg_iter *args)
{
T r = (args->*Method)(T{0});
return r;
}
};
//General cases
template <size_t N> struct ArgumentGetter<N, FloatT> : public GetArgument<N, float, &sc_msg_iter::getf>
// General cases
template <size_t N>
struct ArgumentGetter<N, FloatT> : public GetArgument<N, float, &sc_msg_iter::getf>
{};
template <size_t N> struct ArgumentGetter<N, LongT> : public GetArgument<N, int32, &sc_msg_iter::geti>
template <size_t N>
struct ArgumentGetter<N, LongT> : public GetArgument<N, int32, &sc_msg_iter::geti>
{};
template <size_t N> struct ArgumentGetter<N, EnumT> : public GetArgument<N, int32, &sc_msg_iter::geti>
template <size_t N>
struct ArgumentGetter<N, EnumT> : public GetArgument<N, int32, &sc_msg_iter::geti>
{};
//Specializations
template <size_t N> struct ArgumentGetter<N, BufferT>
// Specializations
template <size_t N>
struct ArgumentGetter<N, BufferT>
{
auto operator() (World* w, sc_msg_iter *args)
auto operator()(World *w, sc_msg_iter *args)
{
typename LongT::type bufnum = args->geti(-1);
return std::unique_ptr<BufferAdaptor>(bufnum >= 0 ? new SCBufferAdaptor(bufnum,w) : nullptr);
return std::unique_ptr<BufferAdaptor>(bufnum >= 0 ? new SCBufferAdaptor(bufnum, w) : nullptr);
}
};
template <size_t N> struct ArgumentGetter<N, FloatPairsArrayT>
template <size_t N>
struct ArgumentGetter<N, FloatPairsArrayT>
{
typename FloatPairsArrayT::type operator()(World* w, sc_msg_iter *args)
typename FloatPairsArrayT::type operator()(World *w, sc_msg_iter *args)
{
return {{args->getf(),args->getf()},{args->getf(),args->getf()}};
return {{args->getf(), args->getf()}, {args->getf(), args->getf()}};
}
};
template <size_t N> struct ArgumentGetter<N, FFTParamsT>
template <size_t N>
struct ArgumentGetter<N, FFTParamsT>
{
typename FFTParamsT::type operator()(World* w, sc_msg_iter *args)
{
return {args->geti(),args->geti(),args->geti()};
}
typename FFTParamsT::type operator()(World *w, sc_msg_iter *args) { return {args->geti(), args->geti(), args->geti()}; }
};
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//Real Time Processor
// Real Time Processor
template <typename Client,class Wrapper, class Params> class RealTime : public SCUnit
template <typename Client, class Wrapper, class Params>
class RealTime : public SCUnit
{
using HostVector = FluidTensorView<float, 1>;
// using Client = typename Wrapper::ClientType;
@ -148,46 +160,47 @@ public:
static void setup(InterfaceTable *ft, const char *name)
{
registerUnit<Wrapper>(ft, name);
ft->fDefineUnitCmd(name,"latency",doLatency);
ft->fDefineUnitCmd(name, "latency", doLatency);
}
static void doLatency(Unit *unit, sc_msg_iter *args)
{
float l[] {static_cast<float>(static_cast<Wrapper*>(unit)->mClient.latency())};
auto ft = Wrapper::getInterfaceTable();
float l[]{static_cast<float>(static_cast<Wrapper *>(unit)->mClient.latency())};
auto ft = Wrapper::getInterfaceTable();
std::stringstream ss;
ss << '/' << Wrapper::getName() << "_latency";
std::cout << ss.str() << '\n';
ft->fSendNodeReply(&unit->mParent->mNode,-1,ss.str().c_str() , 1, l);
ft->fSendNodeReply(&unit->mParent->mNode, -1, ss.str().c_str(), 1, l);
}
RealTime():
mControlsIterator{mInBuf + mSpecialIndex + 1,mNumInputs - mSpecialIndex - 1},
mParams{*Wrapper::getParamDescriptors()},
mClient{Wrapper::setParams(mParams,mWorld->mVerbosity > 0, mWorld, mControlsIterator)}
RealTime()
: mControlsIterator{mInBuf + mSpecialIndex + 1, mNumInputs - mSpecialIndex - 1}
, mParams{*Wrapper::getParamDescriptors()}
, mClient{Wrapper::setParams(mParams, mWorld->mVerbosity > 0, mWorld, mControlsIterator)}
{}
void init()
{
assert(!(mClient.audioChannelsOut() > 0 && mClient.controlChannelsOut() > 0) && "Client can't have both audio and control outputs");
assert(!(mClient.audioChannelsOut() > 0 && mClient.controlChannelsOut() > 0) &&
"Client can't have both audio and control outputs");
//If we don't the number of arguments we expect, the language side code is probably the wrong version
//set plugin to no-op, squawk, and bail;
if(mControlsIterator.size() != Wrapper::getParamDescriptors()->count())
// If we don't the number of arguments we expect, the language side code is probably the wrong version
// set plugin to no-op, squawk, and bail;
if (mControlsIterator.size() != Wrapper::getParamDescriptors()->count())
{
mCalcFunc = Wrapper::getInterfaceTable()->fClearUnitOutputs;
std::cout << "ERROR: " << Wrapper::getName() <<
" wrong number of arguments. Expected " << Wrapper::getParamDescriptors()->count() <<
", got " << mControlsIterator.size() << ". Your .sc file and binary plugin might be different versions." << std::endl;
std::cout << "ERROR: " << Wrapper::getName() << " wrong number of arguments. Expected "
<< Wrapper::getParamDescriptors()->count() << ", got " << mControlsIterator.size()
<< ". Your .sc file and binary plugin might be different versions." << std::endl;
return;
}
mInputConnections.reserve(mClient.audioChannelsIn());
mOutputConnections.reserve(mClient.audioChannelsOut());
mAudioInputs.reserve(mClient.audioChannelsIn());
mOutputs.reserve(std::max(mClient.audioChannelsOut(),mClient.controlChannelsOut()));
mOutputs.reserve(std::max(mClient.audioChannelsOut(), mClient.controlChannelsOut()));
for (int i = 0; i < mClient.audioChannelsIn(); ++i)
{
mInputConnections.emplace_back(isAudioRateIn(i));
@ -200,10 +213,7 @@ public:
mOutputs.emplace_back(nullptr, 0, 0);
}
for (int i = 0; i < mClient.controlChannelsOut(); ++i)
{
mOutputs.emplace_back(nullptr, 0, 0);
}
for (int i = 0; i < mClient.controlChannelsOut(); ++i) { mOutputs.emplace_back(nullptr, 0, 0); }
set_calc_function<RealTime, &RealTime::next>();
Wrapper::getInterfaceTable()->fClearUnitOutputs(this, 1);
@ -211,8 +221,9 @@ public:
void next(int n)
{
mControlsIterator.reset(mInBuf + 1); //mClient.audioChannelsIn());
Wrapper::setParams(mParams,mWorld->mVerbosity > 0, mWorld,mControlsIterator); // forward on inputs N + audio inputs as params
mControlsIterator.reset(mInBuf + 1); // mClient.audioChannelsIn());
Wrapper::setParams(mParams, mWorld->mVerbosity > 0, mWorld,
mControlsIterator); // forward on inputs N + audio inputs as params
const Unit *unit = this;
for (int i = 0; i < mClient.audioChannelsIn(); ++i)
{
@ -222,33 +233,33 @@ public:
{
if (mOutputConnections[i]) mOutputs[i].reset(out(i), 0, fullBufferSize());
}
for(int i = 0; i < mClient.controlChannelsOut();++i)
{
mOutputs[i].reset(out(i),0,1);
}
for (int i = 0; i < mClient.controlChannelsOut(); ++i) { mOutputs[i].reset(out(i), 0, 1); }
mClient.process(mAudioInputs, mOutputs);
}
private:
std::vector<bool> mInputConnections;
std::vector<bool> mOutputConnections;
std::vector<HostVector> mAudioInputs;
std::vector<HostVector> mOutputs;
FloatControlsIter mControlsIterator;
protected:
ParameterSet<Params> mParams;
Client mClient;
Client mClient;
};
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
/// Non Real Time Processor
template <typename Client, typename Wrapper, typename Params> class NonRealTime
template <typename Client, typename Wrapper, typename Params>
class NonRealTime
{
public:
static void setup(InterfaceTable *ft, const char *name) { DefinePlugInCmd(name, launch, nullptr); }
NonRealTime(World *world,sc_msg_iter *args):
mParams{*Wrapper::getParamDescriptors()},
mClient{mParams}
NonRealTime(World *world, sc_msg_iter *args)
: mParams{*Wrapper::getParamDescriptors()}
, mClient{mParams}
{}
void init(){};
@ -256,20 +267,20 @@ public:
static void launch(World *world, void *inUserData, struct sc_msg_iter *args, void *replyAddr)
{
if(args->tags && ((std::string{args->tags}.size() - 1) != Wrapper::getParamDescriptors()->count()))
if (args->tags && ((std::string{args->tags}.size() - 1) != Wrapper::getParamDescriptors()->count()))
{
std::cout << "ERROR: " << Wrapper::getName() <<
" wrong number of arguments. Expected " << Wrapper::getParamDescriptors()->count() <<
", got " << (std::string{args->tags}.size() - 1) << ". Your .sc file and binary plugin might be different versions." << std::endl;
std::cout << "ERROR: " << Wrapper::getName() << " wrong number of arguments. Expected "
<< Wrapper::getParamDescriptors()->count() << ", got " << (std::string{args->tags}.size() - 1)
<< ". Your .sc file and binary plugin might be different versions." << std::endl;
return;
}
Wrapper *w = new Wrapper(world,args); //this has to be on the heap, because it doesn't get destoryed until the async command is done
int argsPosition = args->count;
auto argsRdPos = args->rdpos;
Result result = validateParameters(w, world, args);
Wrapper *w = new Wrapper(
world, args); // this has to be on the heap, because it doesn't get destoryed until the async command is done
int argsPosition = args->count;
auto argsRdPos = args->rdpos;
Result result = validateParameters(w, world, args);
if (!result.ok())
{
std::cout << "ERROR: " << Wrapper::getName() << ": " << result.message().c_str() << std::endl;
@ -278,37 +289,30 @@ public:
}
args->count = argsPosition;
args->rdpos = argsRdPos;
Wrapper::setParams(w->mParams,false, world, args);
size_t msgSize = args->getbsize();
Wrapper::setParams(w->mParams, false, world, args);
size_t msgSize = args->getbsize();
std::vector<char> completionMessage(msgSize);
// char * completionMsgData = 0;
if (msgSize)
{
args->getb(completionMessage.data(), msgSize);
}
// char * completionMsgData = 0;
if (msgSize) { args->getb(completionMessage.data(), msgSize); }
world->ft->fDoAsynchronousCommand(world, replyAddr, Wrapper::getName(), w, process, exchangeBuffers, tidyUp, destroy,msgSize, completionMessage.data());
world->ft->fDoAsynchronousCommand(world, replyAddr, Wrapper::getName(), w, process, exchangeBuffers, tidyUp, destroy,
msgSize, completionMessage.data());
}
static bool process(World *world, void *data) { return static_cast<Wrapper *>(data)->process(world); }
static bool exchangeBuffers(World *world, void *data) { return static_cast<Wrapper *>(data)->exchangeBuffers(world); }
static bool tidyUp(World *world, void *data) { return static_cast<Wrapper *>(data)->tidyUp(world); }
static void destroy(World *world, void *data)
{
// void* c = static_cast<Wrapper *>(data)->mCompletionMessage;
// if(c) world->ft->fRTFree(world,c);
delete static_cast<Wrapper *>(data);
}
static void destroy(World *world, void *data) { delete static_cast<Wrapper *>(data); }
protected:
ParameterSet<Params> mParams;
Client mClient;
Client mClient;
private:
static Result validateParameters(NonRealTime *w, World* world, sc_msg_iter *args)
static Result validateParameters(NonRealTime *w, World *world, sc_msg_iter *args)
{
auto results = w->mParams.template checkParameterValues<ArgumentGetter>(world, args);
auto results = w->mParams.template checkParameterValues<ArgumentGetter>(world, args);
for (auto &r : results)
{
if (!r.ok()) return r;
@ -318,118 +322,121 @@ private:
bool process(World *world)
{
Result r = mClient.process();///mInputs, mOutputs);
if(!r.ok())
Result r = mClient.process();
if (!r.ok())
{
std::cout << "ERROR: " << Wrapper::getName() << ": " << r.message().c_str();
return false;
return false;
}
return true;
}
bool exchangeBuffers(World *world)
{
mParams.template forEachParamType<BufferT,AssignBuffer>(world);
// for (auto &b : mBuffersOut) b.assignToRT(world);
mParams.template forEachParamType<BufferT, AssignBuffer>(world);
return true;
}
bool tidyUp(World *world)
{
// for (auto &b : mBuffersIn) b.cleanUp();
// for (auto &b : mBuffersOut) b.cleanUp()
mParams.template forEachParamType<BufferT,CleanUpBuffer>();
mParams.template forEachParamType<BufferT, CleanUpBuffer>();
return true;
}
template<size_t N,typename T>
template <size_t N, typename T>
struct AssignBuffer
{
void operator()(typename BufferT::type& p, World* w)
void operator()(typename BufferT::type &p, World *w)
{
if(auto b = static_cast<SCBufferAdaptor*>(p.get()))
b->assignToRT(w);
if (auto b = static_cast<SCBufferAdaptor *>(p.get())) b->assignToRT(w);
}
};
template<size_t N,typename T>
template <size_t N, typename T>
struct CleanUpBuffer
{
void operator()(typename BufferT::type& p)
void operator()(typename BufferT::type &p)
{
if(auto b = static_cast<SCBufferAdaptor*>(p.get()))
b->cleanUp();
if (auto b = static_cast<SCBufferAdaptor *>(p.get())) b->cleanUp();
}
};
// std::vector<SCBufferAdaptor> mBuffersIn;
// std::vector<SCBufferAdaptor> mBuffersOut;
// std::vector<BufferProcessSpec> mInputs;
// std::vector<BufferProcessSpec> mOutputs;
char * mCompletionMessage = nullptr;
void * mReplyAddr = nullptr;
const char * mName = nullptr;
char * mCompletionMessage = nullptr;
void * mReplyAddr = nullptr;
const char *mName = nullptr;
};
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
/// An impossible monstrosty
template <typename Client, typename Wrapper, typename Params> class NonRealTimeAndRealTime : public RealTime<Client,Wrapper, Params>, public NonRealTime<Client,Wrapper, Params>
template <typename Client, typename Wrapper, typename Params>
class NonRealTimeAndRealTime : public RealTime<Client, Wrapper, Params>, public NonRealTime<Client, Wrapper, Params>
{
static void setup(InterfaceTable *ft, const char *name)
{
RealTime<Client,Wrapper,Params >::setup(ft, name);
NonRealTime<Client,Wrapper, Params>::setup(ft, name);
RealTime<Client, Wrapper, Params>::setup(ft, name);
NonRealTime<Client, Wrapper, Params>::setup(ft, name);
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Template Specialisations for NRT/RT
template <typename Client, typename Wrapper, typename Params, typename NRT, typename RT> class FluidSCWrapperImpl;
template <typename Client, typename Wrapper, typename Params, typename NRT, typename RT>
class FluidSCWrapperImpl;
template <typename Client, typename Wrapper, typename Params> class FluidSCWrapperImpl<Client, Wrapper, Params, std::true_type, std::false_type> : public NonRealTime<Client, Wrapper, Params>
template <typename Client, typename Wrapper, typename Params>
class FluidSCWrapperImpl<Client, Wrapper, Params, std::true_type, std::false_type>
: public NonRealTime<Client, Wrapper, Params>
{
public:
FluidSCWrapperImpl(World* w, sc_msg_iter *args): NonRealTime<Client, Wrapper, Params>(w,args){};
FluidSCWrapperImpl(World *w, sc_msg_iter *args)
: NonRealTime<Client, Wrapper, Params>(w, args){};
};
template <typename Client, typename Wrapper, typename Params> class FluidSCWrapperImpl<Client, Wrapper,Params, std::false_type, std::true_type> : public RealTime<Client, Wrapper, Params>
template <typename Client, typename Wrapper, typename Params>
class FluidSCWrapperImpl<Client, Wrapper, Params, std::false_type, std::true_type> : public RealTime<Client, Wrapper, Params>
{};
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Make base class(es), full of CRTP mixin goodness
template <typename Client,typename Params>
using FluidSCWrapperBase = FluidSCWrapperImpl<Client, FluidSCWrapper<Client, Params>,Params, isNonRealTime<Client>, isRealTime<Client>>;
template <typename Client, typename Params>
using FluidSCWrapperBase =
FluidSCWrapperImpl<Client, FluidSCWrapper<Client, Params>, Params, isNonRealTime<Client>, isRealTime<Client>>;
} // namespace impl
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
///The main wrapper
template <typename C, typename P> class FluidSCWrapper : public impl::FluidSCWrapperBase<C,P>
/// The main wrapper
template <typename C, typename P>
class FluidSCWrapper : public impl::FluidSCWrapperBase<C, P>
{
public:
using Client = C;
using Params = P;
FluidSCWrapper() //mParams{*getParamDescriptors()}, //impl::FluidSCWrapperBase<Client,Params>()
{ impl::FluidSCWrapperBase<Client,Params>::init(); }
FluidSCWrapper(World* w, sc_msg_iter *args): impl::FluidSCWrapperBase<Client, Params>(w,args)
{ impl::FluidSCWrapperBase<Client, Params>::init(); }
FluidSCWrapper() // mParams{*getParamDescriptors()}, //impl::FluidSCWrapperBase<Client,Params>()
{
impl::FluidSCWrapperBase<Client, Params>::init();
}
FluidSCWrapper(World *w, sc_msg_iter *args)
: impl::FluidSCWrapperBase<Client, Params>(w, args)
{
impl::FluidSCWrapperBase<Client, Params>::init();
}
static const char *getName(const char *setName = nullptr)
{
static const char *name = nullptr;
return (name = setName ? setName : name);
}
static Params *getParamDescriptors(Params *setParams = nullptr)
{
static Params* descriptors = nullptr;
static Params *descriptors = nullptr;
return (descriptors = setParams ? setParams : descriptors);
}
@ -439,7 +446,7 @@ public:
return (ft = setTable ? setTable : ft);
}
static void setup(Params& p, InterfaceTable *ft, const char *name)
static void setup(Params &p, InterfaceTable *ft, const char *name)
{
getName(name);
getInterfaceTable(ft);
@ -447,35 +454,29 @@ public:
impl::FluidSCWrapperBase<Client, Params>::setup(ft, name);
}
template<typename ParameterSet>
static auto& setParams(ParameterSet& p, bool verbose, World* world, impl::FloatControlsIter& inputs)
template <typename ParameterSet>
static auto &setParams(ParameterSet &p, bool verbose, World *world, impl::FloatControlsIter &inputs)
{
//We won't even try and set params if the arguments don't match
if(inputs.size() == getParamDescriptors()->count())
// We won't even try and set params if the arguments don't match
if (inputs.size() == getParamDescriptors()->count())
p.template setParameterValues<impl::ControlGetter>(verbose, world, inputs);
return p;
}
template<typename ParameterSet>
static auto& setParams(ParameterSet& p, bool verbose, World* world, sc_msg_iter *args)
template <typename ParameterSet>
static auto &setParams(ParameterSet &p, bool verbose, World *world, sc_msg_iter *args)
{
p.template setParameterValues<impl::ArgumentGetter>(verbose,world, args);
return p;
p.template setParameterValues<impl::ArgumentGetter>(verbose, world, args);
return p;
}
// impl::ParameterSet<Params> mParams;
// Client &client() { return mClient; }
//
//private:
// Client mClient;
};
template <template <typename...> class Client,typename...Rest,typename Params>
void makeSCWrapper(const char *name, Params& params, InterfaceTable *ft)
template <template <typename...> class Client, typename... Rest, typename Params>
void makeSCWrapper(const char *name, Params &params, InterfaceTable *ft)
{
FluidSCWrapper<Client<ParameterSet<Params>,Rest...>, Params>::setup(params, ft, name);
FluidSCWrapper<Client<ParameterSet<Params>, Rest...>, Params>::setup(params, ft, name);
}
} // namespace client
} // namespace fluid

73
include/SCBufferAdaptor.hpp
Unescape Escape View File

@ -3,7 +3,6 @@
#include <SC_PlugIn.h>
#include <boost/align/aligned_alloc.hpp>
#include <cctype>
//#include <clients/common/FluidParams.hpp>
#include <data/FluidTensor.hpp>
#include <clients/common/BufferAdaptor.hpp>
#include <fstream>
@ -12,7 +11,6 @@
#include <string>
#include <vector>
// static InterfaceTable *ft;
namespace fluid
{
@ -169,77 +167,6 @@ protected:
size_t mRank{1};
};
class RTBufferView : public client::BufferAdaptor
{
public:
RTBufferView(World *world, int bufnum)
: mWorld(world)
, mBufnum(bufnum)
{
}
void acquire() override { mBuffer = World_GetBuf(mWorld, mBufnum); }
void release() override {}
// Validity is based on whether this buffer is within the range the server
// knows about
bool valid() const override
{
return (mBuffer && mBufnum >= 0 && mBufnum < mWorld->mNumSndBufs);
}
FluidTensorView<float, 1> samps(size_t channel, size_t rankIdx = 0) override
{
FluidTensorView<float, 2> v{mBuffer->data, 0,
static_cast<size_t>(mBuffer->frames),
static_cast<size_t>(mBuffer->channels)};
return v.col(rankIdx + channel * mRank);
}
FluidTensorView<float, 1> samps(size_t offset, size_t nframes,
size_t chanoffset) override
{
FluidTensorView<float, 2> v{mBuffer->data, 0,
static_cast<size_t>(mBuffer->frames),
static_cast<size_t>(mBuffer->channels)};
return v(fluid::Slice(offset, nframes), fluid::Slice(chanoffset, 1)).col(0);
}
size_t numFrames() const override
{
return valid() ? this->mBuffer->frames : 0;
}
size_t numChans() const override
{
return valid() ? this->mBuffer->channels / mRank : 0;
}
size_t rank() const override { return valid() ? mRank : 0; }
void resize(size_t frames, size_t channels, size_t rank) override
{
assert(false && "Don't try and resize real-time buffers");
}
int bufnum() { return mBufnum; }
private:
bool equal(BufferAdaptor *rhs) const override
{
RTBufferView *x = dynamic_cast<RTBufferView *>(rhs);
if (x) { return mBufnum == x->mBufnum; }
return false;
}
size_t mRank = 1;
World * mWorld;
int mBufnum = -1;
SndBuf *mBuffer = nullptr;
};
std::ostream& operator <<(std::ostream& os, SCBufferAdaptor& b)
{
return os << b.bufnum();

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