lumiera_/tests/core/proc/engine/buffer-metadata-key-test.cpp

/*
  BufferMetadataKey(Test)  -  calculation of (internal) buffer metadata type keys

  Copyright (C)         Lumiera.org
    2011,               Hermann Vosseler <Ichthyostega@web.de>

  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., 675 Mass Ave, Cambridge, MA 02139, USA.

* *****************************************************/


#include "lib/error.hpp"
#include "lib/test/run.hpp"
#include "lib/test/test-helper.hpp"
#include "proc/engine/buffer-metadata.hpp"

#include <boost/scoped_ptr.hpp>
#include <cstdlib>
#include <cstring>
#include <limits>

using boost::scoped_ptr;
using util::isnil;
using util::isSameObject;


namespace proc {
namespace engine{
namespace metadata{
namespace test  {
  
  
  using lumiera::error::LUMIERA_ERROR_INVALID;
  using lumiera::error::LUMIERA_ERROR_LIFECYCLE;
  
  
  namespace { // Test fixture
    
    const size_t TEST_MAX_SIZE = 1024 * 1024;
    
    const size_t SIZE_A = 1 + rand() % TEST_MAX_SIZE;
    const size_t SIZE_B = 1 + rand() % TEST_MAX_SIZE;
    
    
    /**
     * Test Mock to verify the attachment of objects to the buffer.
     * An instance of this class overwrites the occupied storage
     * with an ascending sequence of numbers on construction,
     * and clears the memory area on destruction.
     * 
     * This allows to verify that an instance of this class
     * has actually been placed into the buffer, and will be
     * cleaned up properly
     */
    template<size_t siz>
    struct PlacedNumbers
      {
        typedef char Pattern[siz];
        
        Pattern pattern_;
        
        PlacedNumbers()
          {
            for (size_t i=0; i<siz; ++i)
              pattern_[i] = i % CHAR_MAX;
          }
        
       ~PlacedNumbers()
          {
            for (size_t i=0; i<siz; ++i)
              pattern_[i] = 0;
          }
        
        
        /* === diagnostics === */
        
        static bool
        verifyFilled (const void* buff)
          {
            REQUIRE (buff);
            const Pattern& patt = *reinterpret_cast<const Pattern*> (buff);
            
            for (size_t i=0; i<siz; ++i)
              if (patt[i] != char(i % CHAR_MAX))
                return false;
            
            return true;
          }
        
        static bool
        verifyCleared (const void* buff)
          {
            REQUIRE (buff);
            const Pattern& patt = *reinterpret_cast<const Pattern*> (buff);
            
            for (size_t i=0; i<siz; ++i)
              if (patt[i])
                return false;
            
            return true;
          }
      };
    
    
    /**
     * Helper to investigate the settings stored in Metadata Key elements.
     * Since these are protected, we use an derived class as adapter
     */
    struct KeyTypeSpecialisationDiagnostics
      : Key
      {
        size_t const& investigateSize()         const { return this->storageSize_; }
        TypeHandler const& investigateHandler() const { return this->instanceFunc_; }
        LocalKey const& investigateSpecifics()  const { return this->specifics_; }
        
        KeyTypeSpecialisationDiagnostics (Key const& toInvestigate)
          : Key(toInvestigate)
          { }
      };
    
    
    inline size_t
    verifySize (Key const& subject)
    {
      return KeyTypeSpecialisationDiagnostics(subject).investigateSize();
    }
    
    inline const TypeHandler
    verifyHandler (Key const& subject)
    {
      return KeyTypeSpecialisationDiagnostics(subject).investigateHandler();
    }
    
    inline const LocalKey
    verifySpecifics (Key const& subject)
    {
      return KeyTypeSpecialisationDiagnostics(subject).investigateSpecifics();
    }
    
  }//(End) Test helpers
  
  
  
  
  
  /***********************************************************************
   * @test verify calculation and relations of Buffer metadata type keys.
   *       These are used internally within the standard implementation
   *       of BufferProvider to keep track of various kinds of buffers,
   *       to provide a service for attaching metadata, e.g. a state flag.
   *       These metadata key entries are based on chained hash values,
   *       thus forming sort-of a "type" hierarchy.
   *       - the actual BufferProvider instance-ID is the top level
   *       - second level is the size of the buffer required
   *       - optionally, custom ctor/dtor functions can be registered
   *       - also optionally, implementation might attach an private-ID
   */
  class BufferMetadataKey_test : public Test
    {
      
      virtual void
      run (Arg) 
        {
          CHECK (ensure_proper_fixture());
          buildSimpleKeys();
          verifyChainedHashes();
          verifyTypeHandler<500>();
          verifyTypeSpecialisation();
        }
      
      
      bool
      ensure_proper_fixture() 
        {
          return (SIZE_A != SIZE_B);
        }
      
      
      void
      buildSimpleKeys()
        {
          HashVal family(123);
          Key k1(family, SIZE_A);
          Key k12(k1, SIZE_B);
          Key k123(k12, LocalKey(56));
          
          CHECK (HashVal (k1));
          CHECK (HashVal (k12));
          CHECK (HashVal (k123));
        }
      
      
      void
      verifyChainedHashes()
        {
          HashVal family(123);
          HashVal otherFamily(456);
          
          Key k1(family, SIZE_A);
          Key k1o(otherFamily, SIZE_A);
          CHECK (HashVal(k1) != HashVal(k1o));
          
          // hash is reproducible
          CHECK (HashVal(k1) == HashVal(Key(family, SIZE_A)));
          
          // differentiate on buffer size
          Key k12(k1, SIZE_B);
          Key k121(k12, SIZE_A);
          Key k2(family, SIZE_B);
          
          CHECK (HashVal(k1) != HashVal(k121));
          CHECK (HashVal(k12) != HashVal(k2));
          
          // so the specialisation path really matters, but this is reproducible...
          CHECK (HashVal(k121) == HashVal(Key(Key(Key(family,SIZE_A),SIZE_B),SIZE_A)));
        }
      
      
      template<size_t SIZ>
      void
      verifyTypeHandler()
        {
          char buff[SIZ];
          memset (buff, '\0', SIZ);
          
          typedef PlacedNumbers<SIZ> Pattern;
          
          TypeHandler attachPattern = TypeHandler::create<Pattern>();
          
          CHECK (attachPattern.isValid());
          CHECK (0 != hash_value(attachPattern));
          
          CHECK (Pattern::verifyCleared (buff));
          attachPattern.createAttached  (buff);         // invoke the ctor-functor to place an instance of PlacedNumbers
          CHECK (Pattern::verifyFilled  (buff));
          attachPattern.destroyAttached (buff);         // invoke the dtor-functor to clear the attached instance
          CHECK (Pattern::verifyCleared (buff));
        }
      
      
      void
      verifyTypeSpecialisation()
        {
          HashVal family(123);
          Key kb (family, SIZE_A);       // "root" key
          
          typedef PlacedNumbers<45> Marker;
          TypeHandler placeMarker = TypeHandler::create<Marker>();
          TypeHandler noHandler;
          
          LocalKey opaque1 (rand() % 1000);
          LocalKey opaque2 (1000 + rand() % 1000);
          
          Key k_siz (kb, SIZE_B);        // sub-key to "root": use a different buffer size
          Key k_han0(kb, noHandler);     // sub-key to "root": use a locally defined type functor
          Key k_han1(kb, placeMarker);   // sub-key to "root": use yet another type functor
          Key k_loc1(kb, opaque1);       // sub-key to "root": attach an private opaque ID
          Key k_loc2(kb, opaque2);       // sub-key to "root": attach another opaque ID
          
          CHECK (kb     != k_siz );
          CHECK (kb     != k_han0);
          CHECK (kb     != k_han1);
          CHECK (kb     != k_loc1);
          CHECK (kb     != k_loc2);
          CHECK (k_siz  != k_han0);
          CHECK (k_siz  != k_han1);
          CHECK (k_siz  != k_loc1);
          CHECK (k_siz  != k_loc2);
          CHECK (k_han0 != k_han1);
          CHECK (k_han0 != k_loc1);
          CHECK (k_han0 != k_loc2);
          CHECK (k_han1 != k_loc1);
          CHECK (k_han1 != k_loc2);
          CHECK (k_loc1 != k_loc2);
          
          CHECK (HashVal(kb    ) != HashVal(k_siz ));
          CHECK (HashVal(kb    ) != HashVal(k_han0));
          CHECK (HashVal(kb    ) != HashVal(k_han1));
          CHECK (HashVal(kb    ) != HashVal(k_loc1));
          CHECK (HashVal(kb    ) != HashVal(k_loc2));
          CHECK (HashVal(k_siz ) != HashVal(k_han0));
          CHECK (HashVal(k_siz ) != HashVal(k_han1));
          CHECK (HashVal(k_siz ) != HashVal(k_loc1));
          CHECK (HashVal(k_siz ) != HashVal(k_loc2));
          CHECK (HashVal(k_han0) != HashVal(k_han1));
          CHECK (HashVal(k_han0) != HashVal(k_loc1));
          CHECK (HashVal(k_han0) != HashVal(k_loc2));
          CHECK (HashVal(k_han1) != HashVal(k_loc1));
          CHECK (HashVal(k_han1) != HashVal(k_loc2));
          CHECK (HashVal(k_loc1) != HashVal(k_loc2));
          
          CHECK (SIZE_A == verifySize(kb    ));
          CHECK (SIZE_B == verifySize(k_siz ));
          CHECK (SIZE_A == verifySize(k_han0));
          CHECK (SIZE_A == verifySize(k_han1));
          CHECK (SIZE_A == verifySize(k_loc1));
          CHECK (SIZE_A == verifySize(k_loc2));
          
          CHECK (RAW_BUFFER  == verifyHandler(kb    ));
          CHECK (RAW_BUFFER  == verifyHandler(k_siz ));
          CHECK (noHandler   == verifyHandler(k_han0));
          CHECK (placeMarker == verifyHandler(k_han1));
          CHECK (RAW_BUFFER  == verifyHandler(k_loc1));
          CHECK (RAW_BUFFER  == verifyHandler(k_loc2));
          
          CHECK (UNSPECIFIC == verifySpecifics(kb    ));
          CHECK (UNSPECIFIC == verifySpecifics(k_siz ));
          CHECK (UNSPECIFIC == verifySpecifics(k_han0));
          CHECK (UNSPECIFIC == verifySpecifics(k_han1));
          CHECK (opaque1    == verifySpecifics(k_loc1));
          CHECK (opaque2    == verifySpecifics(k_loc2));
          
          
          // Verify 2nd level specialisation (some examples)
          Key k_han1_siz (k_han1, SIZE_B);           // sub-key deriving from k_han1, but differing buffer size 
          Key k_siz_han1 (k_siz,  placeMarker);      // sub-key deriving from k_siz, but using another type functor
          
          // Verify some 3rd level specialisations
          Key k_han1_siz_loc2 (k_han1_siz, opaque2);
          Key k_loc2_han1_siz (Key(k_loc2,placeMarker), SIZE_B);
          
          CHECK (SIZE_B == verifySize(k_han1_siz     ));
          CHECK (SIZE_B == verifySize(k_siz_han1     ));
          CHECK (SIZE_B == verifySize(k_han1_siz_loc2));
          CHECK (SIZE_B == verifySize(k_loc2_han1_siz));
          
          CHECK (placeMarker == verifyHandler(k_han1_siz     ));
          CHECK (placeMarker == verifyHandler(k_siz_han1     ));
          CHECK (placeMarker == verifyHandler(k_han1_siz_loc2));
          CHECK (placeMarker == verifyHandler(k_loc2_han1_siz));
          
          CHECK (UNSPECIFIC  == verifySpecifics(k_han1_siz     ));
          CHECK (UNSPECIFIC  == verifySpecifics(k_siz_han1     ));
          CHECK (opaque2     == verifySpecifics(k_han1_siz_loc2));
          CHECK (opaque2     == verifySpecifics(k_loc2_han1_siz));
          
          // for equality, also the order of specialisation matters
          CHECK (k_han1_siz      != k_siz_han1     );
          CHECK (k_han1_siz_loc2 != k_loc2_han1_siz);
          
          CHECK (HashVal(k_han1_siz     ) != HashVal(k_siz_han1     ));
          CHECK (HashVal(k_han1_siz_loc2) != HashVal(k_loc2_han1_siz));
          
          // yet this *is* an semantic equality test
          Key k_again (Key(k_han1,SIZE_B), opaque2);
          CHECK (k_again == k_han1_siz_loc2);
          CHECK (HashVal(k_again) == HashVal(k_han1_siz_loc2));
          
          // pick just some combinations for cross verification...
          CHECK (kb     != k_han1_siz     );
          CHECK (kb     != k_siz_han1     );
          CHECK (kb     != k_han1_siz_loc2);
          CHECK (kb     != k_loc2_han1_siz);
          CHECK (k_han1 != k_han1_siz     );
          CHECK (k_han1 != k_siz_han1     );
          CHECK (k_han1 != k_han1_siz_loc2);
          CHECK (k_han1 != k_loc2_han1_siz);
          CHECK (k_siz  != k_han1_siz     );
          CHECK (k_siz  != k_siz_han1     );
          CHECK (k_siz  != k_han1_siz_loc2);
          CHECK (k_siz  != k_loc2_han1_siz);
          CHECK (k_loc2 != k_han1_siz     );
          CHECK (k_loc2 != k_siz_han1     );
          CHECK (k_loc2 != k_han1_siz_loc2);
          CHECK (k_loc2 != k_loc2_han1_siz);
          
          CHECK (HashVal(kb    ) != HashVal(k_han1_siz     ));
          CHECK (HashVal(kb    ) != HashVal(k_siz_han1     ));
          CHECK (HashVal(kb    ) != HashVal(k_han1_siz_loc2));
          CHECK (HashVal(kb    ) != HashVal(k_loc2_han1_siz));
          CHECK (HashVal(k_han1) != HashVal(k_han1_siz     ));
          CHECK (HashVal(k_han1) != HashVal(k_siz_han1     ));
          CHECK (HashVal(k_han1) != HashVal(k_han1_siz_loc2));
          CHECK (HashVal(k_han1) != HashVal(k_loc2_han1_siz));
          CHECK (HashVal(k_siz ) != HashVal(k_han1_siz     ));
          CHECK (HashVal(k_siz ) != HashVal(k_siz_han1     ));
          CHECK (HashVal(k_siz ) != HashVal(k_han1_siz_loc2));
          CHECK (HashVal(k_siz ) != HashVal(k_loc2_han1_siz));
          CHECK (HashVal(k_loc2) != HashVal(k_han1_siz     ));
          CHECK (HashVal(k_loc2) != HashVal(k_siz_han1     ));
          CHECK (HashVal(k_loc2) != HashVal(k_han1_siz_loc2));
          CHECK (HashVal(k_loc2) != HashVal(k_loc2_han1_siz));
        }
    };
  
  
  /** Register this test class... */
  LAUNCHER (BufferMetadataKey_test, "unit player");
  
  
  
}}}} // namespace proc::engine::metadata::test