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LUMIERA.clone/tests/core/steam/engine/node-base-test.cpp
Ichthyostega 8923d0f7b5 Invocation: handle default case with disabled ''parameter functor'' 
Some further tweaks to the logic to allow using the `FeedPrototype` in the default setup,
where ''nothing shall be done with parameters...''

Provide the basic constructors and a type constructor in FeedManifold,
so that it is possible to install a ''processing functor'' into the prototype
and then drop off a copy into each new `FeedManifold`

With this additions, can now **demonstrate simple usage**

__Remark__: using the `DiagnosticBufferProvider` developed several years ago;
Seems to work well; however, when creating a new instance in the next test case,
we get a hard failure when the previous test case did not discard all buffers.
Not sure what to think about that
 * for one, it is good to get an alarm, since actually there should not be any leak
 * but on the other hand, `reset()` does imply IMHO „I want a clean slate“
Adding some code thus to clean out memory blocks marked as used.
When a test wants to check that all memory was released, there are tools to do so.
2024-12-20 01:47:40 +01:00

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/*
NodeBase(Test) - unit test to cover the render node base elements
Copyright (C)
2009, Hermann Vosseler <Ichthyostega@web.de>
  **Lumiera** 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. See the file COPYING for further details.
* *****************************************************************/
/** @file node-base-test.cpp
** Unit test \ref NodeBase_test covers elementary components of render nodes.
*/
#include "lib/test/run.hpp"
#include "lib/iter-zip.hpp"
#include "lib/meta/function.hpp"
#include "steam/engine/proc-node.hpp"
#include "steam/engine/turnout.hpp"
#include "steam/engine/turnout-system.hpp"
#include "steam/engine/feed-manifold.hpp"
#include "steam/engine/diagnostic-buffer-provider.hpp"
#include "steam/engine/buffhandle-attach.hpp"
#include "lib/test/test-helper.hpp"
//#include "lib/format-cout.hpp"
#include "lib/test/diagnostic-output.hpp"/////////////////////TODO
#include "lib/format-util.hpp"///////////////////////////////TODO
#include "lib/util.hpp"
//using std::string;
using std::tuple;
using std::array;
using util::isSameAdr;
using lib::test::showType;
using lib::izip;
namespace steam {
namespace engine{
namespace test {
namespace { // Test fixture
/**
*/
}
/***************************************************************//**
* @test basic render node properties and behaviour.
*/
class NodeBase_test : public Test
{
virtual void
run (Arg)
{
seedRand();
verify_TurnoutSystem();
verify_FeedManifold();
verify_FeedPrototype();
UNIMPLEMENTED ("build a simple render node and then activate it");
}
/** @test the TurnoutSystem as transient coordinator for node invocation
*/
void
verify_TurnoutSystem()
{
Time nomTime{rani(10'000),0}; // drive test with a random »nominal Time« <10s with ms granularity
TurnoutSystem invoker{nomTime}; // a time spec is mandatory, all further parameters are optional
}
/** @test the FeedManifold as adapter between Engine and processing library
* - bind local λ with various admissible signatures
* - construct specifically tailored FeedManifold types
* - use the DiagnosticBufferProvider for test buffers
* - create FeedManifold instance, passing the λ and additional parameters
* - connect BuffHandle for these buffers into the FeedManifold instance
* - trigger invocation of the function
* - look into the buffers and verify effect
* @remark within each Render Node, a FeedManifold is used as junction
* to tap into processing functionality provided by external libraries.
* Those will be adapted by a Plug-in, to be loaded by the Lumiera core
* application. The _signature of a functor_ linked to the FeedManifold
* is used as kind of a _low-level-specification_ how to invoke external
* processing functions. Obviously this must be complemented by a more
* high-level descriptor, which is interpreted by the Builder to connect
* a suitable structure of Render Nodes.
* @see feed-manifold.h
* @see NodeLinkage_test
*/
void
verify_FeedManifold()
{
// Prepare setup to build a suitable FeedManifold...
long r1 = rani(100);
using Buffer = long;
//______________________________________________________________
// Example-1: a FeedManifold to adapt a simple generator function
auto fun_singleOut = [&](Buffer* buff) { *buff = r1; };
using M1 = FeedManifold<decltype(fun_singleOut)>;
CHECK (not M1::hasInput());
CHECK (not M1::hasParam());
CHECK (0 == M1::FAN_P);
CHECK (0 == M1::FAN_I);
CHECK (1 == M1::FAN_O);
// instantiate...
M1 m1{fun_singleOut};
CHECK (1 == m1.outBuff.array().size());
CHECK (nullptr == m1.outArgs );
// CHECK (m1.inArgs ); // does not compile because storage field is not provided
// CHECK (m1.param );
BufferProvider& provider = DiagnosticBufferProvider::build();
BuffHandle buff = provider.lockBufferFor<Buffer> (-55);
CHECK (buff.isValid());
CHECK (buff.accessAs<long>() == -55);
m1.outBuff.createAt (0, buff); // plant a copy of the BuffHandle into the output slot
CHECK (m1.outBuff[0].isValid());
CHECK (m1.outBuff[0].accessAs<long>() == -55);
m1.connect(); // instruct the manifold to connect buffers to arguments
CHECK (isSameAdr (m1.outArgs, *buff));
CHECK (*m1.outArgs == -55);
m1.invoke(); // invoke the adapted processing function (fun_singleOut)
CHECK (buff.accessAs<long>() == r1); // result: the random number r1 was written into the buffer.
//_____________________________________________________________
// Example-2: adapt a function to process input -> output buffer
auto fun_singleInOut = [](Buffer* in, Buffer* out) { *out = *in + 1; };
using M2 = FeedManifold<decltype(fun_singleInOut)>;
CHECK ( M2::hasInput());
CHECK (not M2::hasParam());
CHECK (1 == M2::FAN_I);
CHECK (1 == M2::FAN_O);
// instantiate...
M2 m2{fun_singleInOut};
CHECK (1 == m2.inBuff.array().size());
CHECK (1 == m2.outBuff.array().size());
CHECK (nullptr == m2.inArgs );
CHECK (nullptr == m2.outArgs );
// use the result of the preceding Example-1 as input
// and get a new buffer to capture the output
BuffHandle buffOut = provider.lockBufferFor<Buffer> (-99);
CHECK (buff.accessAs<long>() == r1);
CHECK (buffOut.accessAs<long>() == -55); ///////////////////////////////////////OOO should be -99 --> aliasing of buffer meta records due to bug with hash generation
// configure the Manifold-2 with this input and output buffer
m2.inBuff.createAt (0, buff);
m2.outBuff.createAt(0, buffOut);
CHECK (m2.inBuff[0].isValid());
CHECK (m2.inBuff[0].accessAs<long>() == r1 );
CHECK (m2.outBuff[0].isValid());
CHECK (m2.outBuff[0].accessAs<long>() == -55); ////////////////////////////////OOO should be -99
// connect arguments to buffers
m2.connect();
CHECK (isSameAdr (m2.inArgs, *buff));
CHECK (isSameAdr (m2.outArgs, *buffOut));
CHECK (*m2.outArgs == -55); ////////////////////////////////OOO should be -99
m2.invoke();
CHECK (buffOut.accessAs<long>() == r1+1);
//______________________________________
// Example-3: accept complex buffer setup
using Sequence = array<Buffer,3>;
using Channels = array<Buffer*,3>;
using Compound = tuple<Sequence*, Buffer*>;
auto fun_complexInOut = [](Channels in, Compound out)
{
auto [seq,extra] = out;
for (auto [i,b] : izip(in))
{
(*seq)[i] = *b + 1;
*extra += *b;
}
};
using M3 = FeedManifold<decltype(fun_complexInOut)>;
CHECK ( M3::hasInput());
CHECK (not M3::hasParam());
CHECK (3 == M3::FAN_I);
CHECK (2 == M3::FAN_O);
CHECK (showType<M3::ArgI>() == "array<long*, 3ul>"_expect);
CHECK (showType<M3::ArgO>() == "tuple<array<long, 3ul>*, long*>"_expect);
// instantiate...
M3 m3{fun_complexInOut};
CHECK (3 == m3.inBuff.array().size());
CHECK (2 == m3.outBuff.array().size());
// use existing buffers and one additional buffer for input
BuffHandle buffI0 = buff;
BuffHandle buffI1 = buffOut;
BuffHandle buffI2 = provider.lockBufferFor<Buffer> (-22);
CHECK (buffI0.accessAs<long>() == r1 ); // (result from Example-1)
CHECK (buffI1.accessAs<long>() == r1+1); // (result from Example-2)
CHECK (buffI2.accessAs<long>() == -55 ); ///////////////////////////////////////OOO should be -22
// prepare a compound buffer and an extra buffer for output...
BuffHandle buffO0 = provider.lockBufferFor<Sequence> (Sequence{-111,-222,-333});
BuffHandle buffO1 = provider.lockBufferFor<Buffer> (-33);
CHECK ((buffO0.accessAs<Sequence>() == Sequence{-111,-222,-333}));
CHECK (buffO1.accessAs<long>() == -55 ); ///////////////////////////////////////OOO should be -33
// configure the Manifold-3 with these input and output buffers
m3.inBuff.createAt (0, buffI0);
m3.inBuff.createAt (1, buffI1);
m3.inBuff.createAt (2, buffI2);
m3.outBuff.createAt(0, buffO0);
m3.outBuff.createAt(1, buffO1);
m3.connect();
// Verify data exposed prior to invocation....
auto& [ia0,ia1,ia2] = m3.inArgs;
auto& [oa0,oa1] = m3.outArgs;
auto& [o00,o01,o02] = *oa0;
CHECK (*ia0 == r1 );
CHECK (*ia1 == r1+1);
CHECK (*ia2 == -55 ); /////////////////////////////////////////////////////OOO should be -22
CHECK ( o00 == -111);
CHECK ( o01 == -222);
CHECK ( o02 == -333);
CHECK (*oa1 == -55 ); /////////////////////////////////////////////////////OOO should be -33
m3.invoke();
CHECK (*ia0 == r1 ); // Input buffers unchanged
CHECK (*ia1 == r1+1);
CHECK (*ia2 == -55 ); /////////////////////////////////////////////////////OOO should be -22
CHECK ( o00 == *ia0+1); // Output buffers as processed by the function
CHECK ( o01 == *ia1+1);
CHECK ( o02 == *ia2+1);
CHECK (*oa1 == -55 + *ia0+*ia1+*ia2); ///////////////////////////////////////////OOO should be -33
//_________________________________
// Example-4: pass a parameter tuple
using Params = tuple<short,long>;
// Note: demonstrates mix of complex params, an array for input, but just a simple output buffer
auto fun_ParamInOut = [](Params param, Channels in, Buffer* out)
{
auto [s,l] = param;
*out = 0;
for (Buffer* b : in)
*out += (s+l) * (*b);
};
using M4 = FeedManifold<decltype(fun_ParamInOut)>;
CHECK (M4::hasInput());
CHECK (M4::hasParam());
CHECK (2 == M4::FAN_P);
CHECK (3 == M4::FAN_I);
CHECK (1 == M4::FAN_O);
CHECK (showType<M4::ArgI>() == "array<long*, 3ul>"_expect);
CHECK (showType<M4::ArgO>() == "long *"_expect);
CHECK (showType<M4::Param>() == "tuple<short, long>"_expect);
// Note: instantiate passing param values as extra arguments
short r2 = 1+rani(10);
long r3 = rani(1000);
M4 m4{Params{r2,r3}, fun_ParamInOut}; // parameters directly given by-value
auto& [p0,p1] = m4.param;
CHECK (p0 == r2); // parameter values exposed through manifold
CHECK (p1 == r3);
// wire-in existing buffers for this example
m4.inBuff.createAt (0, buffI0);
m4.inBuff.createAt (1, buffI1);
m4.inBuff.createAt (2, buffI2);
m4.outBuff.createAt(0, buffO1);
CHECK (*ia0 == r1 ); // existing values in the buffers....
CHECK (*ia1 == r1+1);
CHECK (*ia2 == -55 ); /////////////////////////////////////////////////////OOO should be -22
CHECK (*oa1 == -55 + *ia0+*ia1+*ia2); ///////////////////////////////////////////OOO should be -33
m4.connect();
m4.invoke(); // processing combines input buffers with parameters
CHECK (*oa1 == (r2+r3) * (r1 + r1+1 -55)); /////////////////////////////////////OOO should be -22
//______________________________________
// Example-5: simple parameter and output
auto fun_singleParamOut = [](short param, Buffer* buff) { *buff = param-1; };
using M5 = FeedManifold<decltype(fun_singleParamOut)>;
CHECK (not M5::hasInput());
CHECK ( M5::hasParam());
CHECK (1 == M5::FAN_P);
CHECK (0 == M5::FAN_I);
CHECK (1 == M5::FAN_O);
CHECK (showType<M5::ArgI>() == "tuple<>"_expect);
CHECK (showType<M5::ArgO>() == "long *"_expect);
CHECK (showType<M5::Param>() == "short"_expect);
// instantiate, directly passing param value
M5 m5{r2, fun_singleParamOut};
// wire with one output buffer
m5.outBuff.createAt(0, buffO1);
m5.connect();
CHECK (m5.param == r2); // the parameter value passed to the ctor
// CHECK (m5.inArgs ); // does not compile because storage field is not provided
CHECK (*m5.outArgs == *oa1); // still previous value sitting in the buffer...
m5.invoke();
CHECK (*oa1 == r2 - 1); // processing has placed result based on param into output buffer
// done with these buffers
buffI0.release();
buffI1.release();
buffI2.release();
buffO0.release();
buffO1.release();
}
/** @test Setup of a FeeManifold to attach parameter-functors
*/
void
verify_FeedPrototype()
{
// Prepare setup to build a suitable FeedManifold...
long r1 = rani(100);
using Buffer = long;
BufferProvider& provider = DiagnosticBufferProvider::build();
BuffHandle buff = provider.lockBufferFor<Buffer> (-55);
auto fun_singleParamOut = [](short param, Buffer* buff) { *buff = param-1; };
using M1 = FeedManifold<decltype(fun_singleParamOut)>;
using P1 = M1::Prototype;
CHECK ( P1::hasParam());
CHECK (not P1::hasParamFun());
CHECK (not P1::canActivate());
P1 p1{move (fun_singleParamOut)};
CHECK (sizeof(p1) <= sizeof(void*));
TurnoutSystem turSys{Time::NEVER};
M1 m1 = p1.createFeed(turSys);
CHECK (m1.param == short{});
m1.outBuff.createAt(0, buff);
CHECK (buff.accessAs<long>() == -55);
m1.connect();
CHECK (*m1.outArgs == -55);
m1.invoke();
CHECK (*m1.outArgs == 0 - 1);
CHECK (buff.accessAs<long>() == 0 - 1);
}
};
/** Register this test class... */
LAUNCHER (NodeBase_test, "unit node");
}}} // namespace steam::engine::test
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