test/simulator/simulator.hpp - openbmc/openpower-libhei - Gitiles

 #pragma once

 #include <hei_main.hpp>

 #include <algorithm>
 #include <map>
 #include <vector>

 #include "gtest/gtest.h"

 namespace libhei
 {

 /**
  * @brief Contains simulated chip objects and register contents used during
  *        isolation. Also contains the expected signatures to compare after
  *        isolation.
  */
 class SimulatorData
 {
   private: // This class cannot be instantiated. Use getSingleton() instead.
     /** @brief Default constructor. */
     SimulatorData() = default;

     /** @brief Destructor. */
     ~SimulatorData() = default;

     /** @brief Copy constructor. */
     SimulatorData(const SimulatorData&) = delete;

     /** @brief Assignment operator. */
     SimulatorData& operator=(const SimulatorData&) = delete;

   public:
     /** @brief Provides access to a singleton instance of this object. */
     static SimulatorData& getSingleton()
     {
         static SimulatorData theSimData{};
         return theSimData;
     }

   public:
     /** The list of supported chip types for the simulator. */
     enum SimChipType
     {
         SAMPLE = 0xdeadbeef,
     };

   private:
     /** The Chip Data file paths for each support chip type. */
     static const std::map<SimChipType, const char*> cv_chipPath;

     /** The list of configured chips used throughout a test case. */
     std::vector<Chip> iv_chipList;

     /** The list of configured chip types used throughout a test case. */
     std::vector<ChipType_t> iv_typeList;

     /** The contents of all the SCOM registers used for an iteration of
      *  isolation. */
     std::map<Chip, std::map<uint32_t, uint64_t>> iv_scomRegData;

     /** The contents of all the Indirect SCOM registers used for an iteration of
      *  isolation. */
     std::map<Chip, std::map<uint64_t, uint64_t>> iv_idScomRegData;

     /** The list of expected signatures during an iteration of isolation. */
     std::vector<Signature> iv_expSigList;

   public:
     /**
      * @brief Adds a chip to the list of configured chips. Also, calls the main
      *        initialize() API which will initialize the isolator with the Chip
      *        Data File associated with this chip.
      */
     void addChip(const Chip& i_chip);

     /** @brief Retrieve ScomReg from map and return its value */
     uint64_t getScomReg(const Chip& i_chip, uint32_t i_address)
     {
         return iv_scomRegData[i_chip][i_address];
     }

     /** @breif Retrieve idScomReg from map and return its value */
     uint64_t getIdScomReg(const Chip& i_chip, uint64_t i_address)
     {
         return iv_idScomRegData[i_chip][i_address];
     }

     /** @brief Adds a SCOM register to iv_scomRegData. */
     void addScomReg(const Chip& i_chip, uint32_t i_address, uint64_t i_value)
     {
         // First check if this entry already exists.
         auto chip_itr = iv_scomRegData.find(i_chip);
         if (iv_scomRegData.end() != chip_itr)
         {
             auto addr_itr = chip_itr->second.find(i_address);
             ASSERT_EQ(chip_itr->second.end(), addr_itr);
         }

         // Add the new entry.
         iv_scomRegData[i_chip][i_address] = i_value;
     }

     /** @brief Adds a SCOM register to iv_idScomRegData. */
     void addIdScomReg(const Chip& i_chip, uint64_t i_address, uint64_t i_value)
     {
         // First check if this entry already exists.
         auto chip_itr = iv_idScomRegData.find(i_chip);
         if (iv_idScomRegData.end() != chip_itr)
         {
             auto addr_itr = chip_itr->second.find(i_address);
             ASSERT_EQ(chip_itr->second.end(), addr_itr);
         }

         // Add the new entry.
         iv_idScomRegData[i_chip][i_address] = i_value;
     }

     /** @brief Adds a Signature to iv_expSigList. */
     void addSignature(const Signature& i_signature)
     {
         // First check if this entry already exists.
         auto itr =
             std::find(iv_expSigList.begin(), iv_expSigList.end(), i_signature);
         ASSERT_EQ(iv_expSigList.end(), itr);

         // Add the new entry.
         iv_expSigList.push_back(i_signature);
     }

     /**
      * @brief Flushes register and expected signature lists used for a single
      *        isolation.
      */
     void flushIterationData()
     {
         iv_scomRegData.clear();
         iv_idScomRegData.clear();
         iv_expSigList.clear();
     }

     /** @brief Flushes all simulation data. */
     void flushAll()
     {
         flushIterationData();
         iv_chipList.clear();
     }

     /**
      * @brief After an iteration is set up with registers and expected
      *        signatures, this is called to run the simulation and verify the
      *        expected signatures.
      */
     void endIteration();
 };

 } // end namespace libhei

 //------------------------------------------------------------------------------

 // clang-format off

 // The following macros can be used to simplify commonly used function for
 // simulation test cases. At the core of each test case is a Google Test (i.e.
 // gtest), which will do most of the error checking. Just like in gtest, a test
 // case file can contain more than one test. Also, remember that this is all C++
 // code. While it not likely to be used much, you can combine these macros with
 // C++ code to do more advanced test cases. For example, you can put the
 // iteration macros in a loop to walk through each bit of a register.

 /**
  * This is the beginning of a test case. The NAME parameter must be valid C++
  * identifier and must not contain any underscores (per gtest requirement). To
  * end the test case use END_TEST_CASE. All contents of the test case must be
  * contain in between these two macros.
  */
 #define START_TEST_CASE(NAME)                                                  \
     TEST(Simulator, NAME)                                                      \
     {                                                                          \
         libhei::SimulatorData& simData =                                       \
             libhei::SimulatorData::getSingleton();                             \
         simData.flushAll();                                                    \
         libhei::ChipType_t chipType;

 /**
  * Use this to configure a chip object for the test case. There should be an
  * instance of this macro for each chip required for the test case. Note that
  * this will also call libhei::initialize() for each new chip type. The CHIP
  * parameter must be valid C++ identifier because it will be used as the name of
  * the chip variable. This same identifier will be re-used in several other
  * macros.
  */
 #define CHIP(CHIP, TYPE)                                                       \
     chipType = static_cast<libhei::ChipType_t>(libhei::SimulatorData::TYPE);   \
     libhei::Chip CHIP{#CHIP, chipType};                                        \
     simData.addChip(CHIP);

 /**
  * Once all of the chips have been configured, there can be one or more
  * iterations defined in the test case. Use END_ITERATION to end the iteration.
  * Note that register and signature information will be reset for each
  * iteration, however, the same set of configure chips will be used for all
  * iterations within the test case.
  */
 #define START_ITERATION                                                        \
     {                                                                          \
         simData.flushIterationData();

 /** This will add a SCOM register to the current iteration. */
 #define REG_SCOM(CHIP, ADDR, VAL)                                              \
     simData.addScomReg(CHIP, static_cast<uint32_t>(ADDR),                      \
                        static_cast<uint64_t>(VAL));

 /** This will add an Indirect SCOM register to the current iteration. */
 #define REG_IDSCOM(CHIP, ADDR, VAL)                                            \
     simData.addIdScomReg(CHIP, static_cast<uint64_t>(ADDR),                    \
                          static_cast<uint64_t>(VAL));

 /** This will add an expected signature to the current iteration. */
 #define EXP_SIG(CHIP, ID, INST, BIT, TYPE)                                     \
     simData.addSignature(libhei::Signature{                                    \
         CHIP, static_cast<libhei::RegisterId_t>(ID),                           \
         static_cast<libhei::Instance_t>(INST),                                 \
         static_cast<libhei::BitPosition_t>(BIT), libhei::ATTN_TYPE_##TYPE});

 /**
  * This is the end of an iteration that began with START_ITERATION. All of the
  * register contents and expected signatures will have been stored in the
  * simulation data. So, this will call libhei::isolate() with the list of
  * configured chips. Using the register contents in the simulation data,
  * libhei::isolate() will return a list of signatures (active attentions). That
  * list will be compared against the expected list of signatures stored in the
  * simulation data for test case verification.
  *
  * You will see that there are two gtest checks for failures:
  *  - The first check will look to see if any of the previous functions to add
  *    chips, registers, or signatures to the simulation data failed.
  *  - The second check will determine if isolation completed successfully and if
  *    all expected signatures have been verified.
  * If either check fails, the test case will be aborted regardless if there are
  * additional iterations in that test case. Note that failure in a test case
  * will not have any impact on subsequent test cases. Therefore, all test cases
  * in a file will at least be attempted even if there is a failure.
  */
 #define END_ITERATION                                                          \
         if (HasFailure()) { simData.flushAll(); return; }                      \
         simData.endIteration();                                                \
         if (HasFailure()) { simData.flushAll(); return; }                      \
     }

 /**
  * This is the end of the test case that started with START_TEST_CASE. It will
  * call libhei::uninitialize() and clean up the simulation data.
  */
 #define END_TEST_CASE                                                          \
         libhei::uninitialize();                                                \
         simData.flushAll();                                                    \
     }

 // clang-format on
	#pragma once

	#include <hei_main.hpp>

	#include <algorithm>
	#include <map>
	#include <vector>

	#include "gtest/gtest.h"

	namespace libhei
	{

	/**
	* @brief Contains simulated chip objects and register contents used during
	* isolation. Also contains the expected signatures to compare after
	* isolation.
	*/
	class SimulatorData
	{
	private: // This class cannot be instantiated. Use getSingleton() instead.
	/** @brief Default constructor. */
	SimulatorData() = default;

	/** @brief Destructor. */
	~SimulatorData() = default;

	/** @brief Copy constructor. */
	SimulatorData(const SimulatorData&) = delete;

	/** @brief Assignment operator. */
	SimulatorData& operator=(const SimulatorData&) = delete;

	public:
	/** @brief Provides access to a singleton instance of this object. */
	static SimulatorData& getSingleton()
	{
	static SimulatorData theSimData{};
	return theSimData;
	}

	public:
	/** The list of supported chip types for the simulator. */
	enum SimChipType
	{
	SAMPLE = 0xdeadbeef,
	};

	private:
	/** The Chip Data file paths for each support chip type. */
	static const std::map<SimChipType, const char*> cv_chipPath;

	/** The list of configured chips used throughout a test case. */
	std::vector<Chip> iv_chipList;

	/** The list of configured chip types used throughout a test case. */
	std::vector<ChipType_t> iv_typeList;

	/** The contents of all the SCOM registers used for an iteration of
	* isolation. */
	std::map<Chip, std::map<uint32_t, uint64_t>> iv_scomRegData;

	/** The contents of all the Indirect SCOM registers used for an iteration of
	* isolation. */
	std::map<Chip, std::map<uint64_t, uint64_t>> iv_idScomRegData;

	/** The list of expected signatures during an iteration of isolation. */
	std::vector<Signature> iv_expSigList;

	public:
	/**
	* @brief Adds a chip to the list of configured chips. Also, calls the main
	* initialize() API which will initialize the isolator with the Chip
	* Data File associated with this chip.
	*/
	void addChip(const Chip& i_chip);

	/** @brief Retrieve ScomReg from map and return its value */
	uint64_t getScomReg(const Chip& i_chip, uint32_t i_address)
	{
	return iv_scomRegData[i_chip][i_address];
	}

	/** @breif Retrieve idScomReg from map and return its value */
	uint64_t getIdScomReg(const Chip& i_chip, uint64_t i_address)
	{
	return iv_idScomRegData[i_chip][i_address];
	}

	/** @brief Adds a SCOM register to iv_scomRegData. */
	void addScomReg(const Chip& i_chip, uint32_t i_address, uint64_t i_value)
	{
	// First check if this entry already exists.
	auto chip_itr = iv_scomRegData.find(i_chip);
	if (iv_scomRegData.end() != chip_itr)
	{
	auto addr_itr = chip_itr->second.find(i_address);
	ASSERT_EQ(chip_itr->second.end(), addr_itr);
	}

	// Add the new entry.
	iv_scomRegData[i_chip][i_address] = i_value;
	}

	/** @brief Adds a SCOM register to iv_idScomRegData. */
	void addIdScomReg(const Chip& i_chip, uint64_t i_address, uint64_t i_value)
	{
	// First check if this entry already exists.
	auto chip_itr = iv_idScomRegData.find(i_chip);
	if (iv_idScomRegData.end() != chip_itr)
	{
	auto addr_itr = chip_itr->second.find(i_address);
	ASSERT_EQ(chip_itr->second.end(), addr_itr);
	}

	// Add the new entry.
	iv_idScomRegData[i_chip][i_address] = i_value;
	}

	/** @brief Adds a Signature to iv_expSigList. */
	void addSignature(const Signature& i_signature)
	{
	// First check if this entry already exists.
	auto itr =
	std::find(iv_expSigList.begin(), iv_expSigList.end(), i_signature);
	ASSERT_EQ(iv_expSigList.end(), itr);

	// Add the new entry.
	iv_expSigList.push_back(i_signature);
	}

	/**
	* @brief Flushes register and expected signature lists used for a single
	* isolation.
	*/
	void flushIterationData()
	{
	iv_scomRegData.clear();
	iv_idScomRegData.clear();
	iv_expSigList.clear();
	}

	/** @brief Flushes all simulation data. */
	void flushAll()
	{
	flushIterationData();
	iv_chipList.clear();
	}

	/**
	* @brief After an iteration is set up with registers and expected
	* signatures, this is called to run the simulation and verify the
	* expected signatures.
	*/
	void endIteration();
	};

	} // end namespace libhei

	//------------------------------------------------------------------------------

	// clang-format off

	// The following macros can be used to simplify commonly used function for
	// simulation test cases. At the core of each test case is a Google Test (i.e.
	// gtest), which will do most of the error checking. Just like in gtest, a test
	// case file can contain more than one test. Also, remember that this is all C++
	// code. While it not likely to be used much, you can combine these macros with
	// C++ code to do more advanced test cases. For example, you can put the
	// iteration macros in a loop to walk through each bit of a register.

	/**
	* This is the beginning of a test case. The NAME parameter must be valid C++
	* identifier and must not contain any underscores (per gtest requirement). To
	* end the test case use END_TEST_CASE. All contents of the test case must be
	* contain in between these two macros.
	*/
	#define START_TEST_CASE(NAME) \
	TEST(Simulator, NAME) \
	{ \
	libhei::SimulatorData& simData = \
	libhei::SimulatorData::getSingleton(); \
	simData.flushAll(); \
	libhei::ChipType_t chipType;

	/**
	* Use this to configure a chip object for the test case. There should be an
	* instance of this macro for each chip required for the test case. Note that
	* this will also call libhei::initialize() for each new chip type. The CHIP
	* parameter must be valid C++ identifier because it will be used as the name of
	* the chip variable. This same identifier will be re-used in several other
	* macros.
	*/
	#define CHIP(CHIP, TYPE) \
	chipType = static_cast<libhei::ChipType_t>(libhei::SimulatorData::TYPE); \
	libhei::Chip CHIP{#CHIP, chipType}; \
	simData.addChip(CHIP);

	/**
	* Once all of the chips have been configured, there can be one or more
	* iterations defined in the test case. Use END_ITERATION to end the iteration.
	* Note that register and signature information will be reset for each
	* iteration, however, the same set of configure chips will be used for all
	* iterations within the test case.
	*/
	#define START_ITERATION \
	{ \
	simData.flushIterationData();

	/** This will add a SCOM register to the current iteration. */
	#define REG_SCOM(CHIP, ADDR, VAL) \
	simData.addScomReg(CHIP, static_cast<uint32_t>(ADDR), \
	static_cast<uint64_t>(VAL));

	/** This will add an Indirect SCOM register to the current iteration. */
	#define REG_IDSCOM(CHIP, ADDR, VAL) \
	simData.addIdScomReg(CHIP, static_cast<uint64_t>(ADDR), \
	static_cast<uint64_t>(VAL));

	/** This will add an expected signature to the current iteration. */
	#define EXP_SIG(CHIP, ID, INST, BIT, TYPE) \
	simData.addSignature(libhei::Signature{ \
	CHIP, static_cast<libhei::RegisterId_t>(ID), \
	static_cast<libhei::Instance_t>(INST), \
	static_cast<libhei::BitPosition_t>(BIT), libhei::ATTN_TYPE_##TYPE});

	/**
	* This is the end of an iteration that began with START_ITERATION. All of the
	* register contents and expected signatures will have been stored in the
	* simulation data. So, this will call libhei::isolate() with the list of
	* configured chips. Using the register contents in the simulation data,
	* libhei::isolate() will return a list of signatures (active attentions). That
	* list will be compared against the expected list of signatures stored in the
	* simulation data for test case verification.
	*
	* You will see that there are two gtest checks for failures:
	* - The first check will look to see if any of the previous functions to add
	* chips, registers, or signatures to the simulation data failed.
	* - The second check will determine if isolation completed successfully and if
	* all expected signatures have been verified.
	* If either check fails, the test case will be aborted regardless if there are
	* additional iterations in that test case. Note that failure in a test case
	* will not have any impact on subsequent test cases. Therefore, all test cases
	* in a file will at least be attempted even if there is a failure.
	*/
	#define END_ITERATION \
	if (HasFailure()) { simData.flushAll(); return; } \
	simData.endIteration(); \
	if (HasFailure()) { simData.flushAll(); return; } \
	}

	/**
	* This is the end of the test case that started with START_TEST_CASE. It will
	* call libhei::uninitialize() and clean up the simulation data.
	*/
	#define END_TEST_CASE \
	libhei::uninitialize(); \
	simData.flushAll(); \
	}

	// clang-format on