src/register/hei_hardware_register.cpp - openbmc/openpower-libhei - Gitiles

 #include <hei_includes.hpp>
 #include <hei_user_interface.hpp>
 #include <register/hei_hardware_register.hpp>
 #include <util/hei_bit_string.hpp>

 namespace libhei
 {

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

 HardwareRegister::~HardwareRegister() {}

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

 #if 0
 void HardwareRegister::setBitString(const BitString *bs)
 {
     BitString& l_string  = accessBitString();
     l_string.setString(*bs);
 }
 #endif

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

 const BitString* HardwareRegister::getBitString(const Chip& i_chip) const
 {
     // Verify this register belongs on i_chip.
     verifyAccessorChip(i_chip);

     // Calling read() will ensure that an entry exists in the cache and the
     // entry has at been synched with hardware at least once. Note that we
     // cannot read hardware for write-only registers. In this case, an entry
     // will be created in the cache, if it does not exist, when the cache is
     // accessed below.

     if ((REG_ACCESS_NONE != getAccessLevel()) &&
         (REG_ACCESS_WO   != getAccessLevel()))
     {
         read(i_chip);
     }

     return &(accessCache(i_chip));
 }

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

 BitString& HardwareRegister::accessBitString(const Chip& i_chip)
 {
     // Verify this register belongs on i_chip.
     verifyAccessorChip(i_chip);

     // Calling read() will ensure that an entry exists in the cache and the
     // entry has at been synched with hardware at least once. Note that we
     // cannot read hardware for write-only registers. In this case, an entry
     // will be created in the cache, if it does not exist, when the cache is
     // accessed below.

     if ((REG_ACCESS_NONE != getAccessLevel()) &&
         (REG_ACCESS_WO   != getAccessLevel()))
     {
         read(i_chip);
     }

     return accessCache(i_chip);
 }

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

 ReturnCode HardwareRegister::read(const Chip& i_chip, bool i_force) const
 {
     ReturnCode rc;

     // Verify this register belongs on i_chip.
     verifyAccessorChip(i_chip);

     // Read from hardware only if the read is forced or the entry for this
     // instance does not exist in the cache.
     if (i_force || !queryCache(i_chip))
     {
         // This register must be readable.
         HEI_ASSERT((REG_ACCESS_NONE != getAccessLevel()) &&
                    (REG_ACCESS_WO   != getAccessLevel()));

         // Get the buffer from the register cache.
         BitString& bs = accessCache(i_chip);

         // Get the byte size of the buffer.
         size_t sz_buffer = BitString::getMinBytes(bs.getBitLen());

         // Read this register from hardware.
         rc = registerRead(i_chip.getChip(), bs.getBufAddr(), sz_buffer,
                           getRegisterType(), getAddress());
         if (RC_SUCCESS != rc)
         {
             // The read failed and we can't trust what was put in the register
             // cache. So remove this instance's entry from the cache.
             flush(i_chip);
         }
         else
         {
             // Sanity check. The returned size of the data written to the buffer
             // should match the register size.
             HEI_ASSERT(getSize() == sz_buffer);
         }
     }

     return rc;
 }

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

 #ifndef __HEI_READ_ONLY

 ReturnCode HardwareRegister::write(const Chip& i_chip) const
 {
     ReturnCode rc;

     // Verify this register belongs on i_chip.
     verifyAccessorChip(i_chip);

     // This register must be writable.
     HEI_ASSERT((REG_ACCESS_NONE != getAccessLevel()) &&
                (REG_ACCESS_RO   != getAccessLevel()));

     // An entry for this register must exist in the cache.
     HEI_ASSERT(queryCache(i_chip));

     // Get the buffer from the register cache.
     BitString& bs = accessCache(i_chip);

     // Get the byte size of the buffer.
     size_t sz_buffer = BitString::getMinBytes(bs.getBitLen());

     // Write to this register to hardware.
     rc = registerWrite(i_chip.getChip(), bs.getBufAddr(), sz_buffer,
                        getRegisterType(), getAddress());

     if (RC_SUCCESS == rc)
     {
         // Sanity check. The returned size of the data written to the buffer
         // should match the register size.
         HEI_ASSERT(getSize() == sz_buffer);
     }

     return rc;
 }

 #endif // __HEI_READ_ONLY

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

 HardwareRegister::Cache HardwareRegister::cv_cache {};

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

 bool HardwareRegister::Cache::query(const Chip& i_chip,
                                     const HardwareRegister* i_hwReg) const
 {
     // Does i_chip exist in the cache?
     auto chipPairItr = iv_cache.find(i_chip);
     if (iv_cache.end() != chipPairItr)
     {
         auto& hwRegMap = chipPairItr->second; // for ease of use

         // Does i_hwReg exist in the cache?
         auto hwRegPairItr = hwRegMap.find(i_hwReg);
         if (hwRegMap.end() != hwRegPairItr)
         {
             return true;
         }
     }

     return false;
 }

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

 BitString& HardwareRegister::Cache::access(const Chip& i_chip,
                                            const HardwareRegister * i_hwReg)
 {
     // If the entry does not exist, create a new entry.
     if (!query(i_chip, i_hwReg))
     {
         BitString* bs = new BitStringBuffer { i_hwReg->getSize() * 8 };
         iv_cache[i_chip][i_hwReg] = bs;
     }

     // Return a reference to the target entry.
     return *(iv_cache[i_chip][i_hwReg]);
 }

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

 void HardwareRegister::Cache::flush()
 {
     // Delete all of the BitStrings.
     for (auto& chipPair : iv_cache)
     {
         for (auto& hwRegPair : chipPair.second)
         {
             delete hwRegPair.second;
         }
     }

     // !!! Do not delete the HardwareRegisters !!!
     // Those are deleted when the main uninitialize() API is called.

     // Flush the rest of the cache.
     iv_cache.clear();
 }

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

 void HardwareRegister::Cache::flush(const Chip& i_chip,
                                     const HardwareRegister* i_hwReg)
 {
     // Does i_chip exist in the cache?
     auto chipPairItr = iv_cache.find(i_chip);
     if (iv_cache.end() != chipPairItr)
     {
         auto& hwRegMap = chipPairItr->second; // for ease of use

         // Does i_hwReg exist in the cache?
         auto hwRegPairItr = hwRegMap.find(i_hwReg);
         if (hwRegMap.end() != hwRegPairItr)
         {
             delete hwRegPairItr->second; // delete the BitString
             hwRegMap.erase(i_hwReg);     // remove the entry for this register
         }

         // If i_hwReg was the only entry for i_chip, we can remove i_chip from
         // the cache.
         if (hwRegMap.empty())
         {
             iv_cache.erase(i_chip);
         }
     }
 }

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

 } // end namespace libhei
	#include <hei_includes.hpp>
	#include <hei_user_interface.hpp>
	#include <register/hei_hardware_register.hpp>
	#include <util/hei_bit_string.hpp>

	namespace libhei
	{

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

	HardwareRegister::~HardwareRegister() {}

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

	#if 0
	void HardwareRegister::setBitString(const BitString *bs)
	{
	BitString& l_string = accessBitString();
	l_string.setString(*bs);
	}
	#endif

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

	const BitString* HardwareRegister::getBitString(const Chip& i_chip) const
	{
	// Verify this register belongs on i_chip.
	verifyAccessorChip(i_chip);

	// Calling read() will ensure that an entry exists in the cache and the
	// entry has at been synched with hardware at least once. Note that we
	// cannot read hardware for write-only registers. In this case, an entry
	// will be created in the cache, if it does not exist, when the cache is
	// accessed below.

	if ((REG_ACCESS_NONE != getAccessLevel()) &&
	(REG_ACCESS_WO != getAccessLevel()))
	{
	read(i_chip);
	}

	return &(accessCache(i_chip));
	}

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

	BitString& HardwareRegister::accessBitString(const Chip& i_chip)
	{
	// Verify this register belongs on i_chip.
	verifyAccessorChip(i_chip);

	// Calling read() will ensure that an entry exists in the cache and the
	// entry has at been synched with hardware at least once. Note that we
	// cannot read hardware for write-only registers. In this case, an entry
	// will be created in the cache, if it does not exist, when the cache is
	// accessed below.

	if ((REG_ACCESS_NONE != getAccessLevel()) &&
	(REG_ACCESS_WO != getAccessLevel()))
	{
	read(i_chip);
	}

	return accessCache(i_chip);
	}

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

	ReturnCode HardwareRegister::read(const Chip& i_chip, bool i_force) const
	{
	ReturnCode rc;

	// Verify this register belongs on i_chip.
	verifyAccessorChip(i_chip);

	// Read from hardware only if the read is forced or the entry for this
	// instance does not exist in the cache.
	if (i_force \|\| !queryCache(i_chip))
	{
	// This register must be readable.
	HEI_ASSERT((REG_ACCESS_NONE != getAccessLevel()) &&
	(REG_ACCESS_WO != getAccessLevel()));

	// Get the buffer from the register cache.
	BitString& bs = accessCache(i_chip);

	// Get the byte size of the buffer.
	size_t sz_buffer = BitString::getMinBytes(bs.getBitLen());

	// Read this register from hardware.
	rc = registerRead(i_chip.getChip(), bs.getBufAddr(), sz_buffer,
	getRegisterType(), getAddress());
	if (RC_SUCCESS != rc)
	{
	// The read failed and we can't trust what was put in the register
	// cache. So remove this instance's entry from the cache.
	flush(i_chip);
	}
	else
	{
	// Sanity check. The returned size of the data written to the buffer
	// should match the register size.
	HEI_ASSERT(getSize() == sz_buffer);
	}
	}

	return rc;
	}

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

	#ifndef __HEI_READ_ONLY

	ReturnCode HardwareRegister::write(const Chip& i_chip) const
	{
	ReturnCode rc;

	// Verify this register belongs on i_chip.
	verifyAccessorChip(i_chip);

	// This register must be writable.
	HEI_ASSERT((REG_ACCESS_NONE != getAccessLevel()) &&
	(REG_ACCESS_RO != getAccessLevel()));

	// An entry for this register must exist in the cache.
	HEI_ASSERT(queryCache(i_chip));

	// Get the buffer from the register cache.
	BitString& bs = accessCache(i_chip);

	// Get the byte size of the buffer.
	size_t sz_buffer = BitString::getMinBytes(bs.getBitLen());

	// Write to this register to hardware.
	rc = registerWrite(i_chip.getChip(), bs.getBufAddr(), sz_buffer,
	getRegisterType(), getAddress());

	if (RC_SUCCESS == rc)
	{
	// Sanity check. The returned size of the data written to the buffer
	// should match the register size.
	HEI_ASSERT(getSize() == sz_buffer);
	}

	return rc;
	}

	#endif // __HEI_READ_ONLY

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

	HardwareRegister::Cache HardwareRegister::cv_cache {};

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

	bool HardwareRegister::Cache::query(const Chip& i_chip,
	const HardwareRegister* i_hwReg) const
	{
	// Does i_chip exist in the cache?
	auto chipPairItr = iv_cache.find(i_chip);
	if (iv_cache.end() != chipPairItr)
	{
	auto& hwRegMap = chipPairItr->second; // for ease of use

	// Does i_hwReg exist in the cache?
	auto hwRegPairItr = hwRegMap.find(i_hwReg);
	if (hwRegMap.end() != hwRegPairItr)
	{
	return true;
	}
	}

	return false;
	}

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

	BitString& HardwareRegister::Cache::access(const Chip& i_chip,
	const HardwareRegister * i_hwReg)
	{
	// If the entry does not exist, create a new entry.
	if (!query(i_chip, i_hwReg))
	{
	BitString* bs = new BitStringBuffer { i_hwReg->getSize() * 8 };
	iv_cache[i_chip][i_hwReg] = bs;
	}

	// Return a reference to the target entry.
	return *(iv_cache[i_chip][i_hwReg]);
	}

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

	void HardwareRegister::Cache::flush()
	{
	// Delete all of the BitStrings.
	for (auto& chipPair : iv_cache)
	{
	for (auto& hwRegPair : chipPair.second)
	{
	delete hwRegPair.second;
	}
	}

	// !!! Do not delete the HardwareRegisters !!!
	// Those are deleted when the main uninitialize() API is called.

	// Flush the rest of the cache.
	iv_cache.clear();
	}

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

	void HardwareRegister::Cache::flush(const Chip& i_chip,
	const HardwareRegister* i_hwReg)
	{
	// Does i_chip exist in the cache?
	auto chipPairItr = iv_cache.find(i_chip);
	if (iv_cache.end() != chipPairItr)
	{
	auto& hwRegMap = chipPairItr->second; // for ease of use

	// Does i_hwReg exist in the cache?
	auto hwRegPairItr = hwRegMap.find(i_hwReg);
	if (hwRegMap.end() != hwRegPairItr)
	{
	delete hwRegPairItr->second; // delete the BitString
	hwRegMap.erase(i_hwReg); // remove the entry for this register
	}

	// If i_hwReg was the only entry for i_chip, we can remove i_chip from
	// the cache.
	if (hwRegMap.empty())
	{
	iv_cache.erase(i_chip);
	}
	}
	}

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

	} // end namespace libhei