analyzer/analyzer_main.cpp - openbmc/openpower-hw-diags - Gitiles

 #include <assert.h>
 #include <libpdbg.h>
 #include <unistd.h>

 #include <hei_main.hpp>
 #include <phosphor-logging/log.hpp>
 #include <util/pdbg.hpp>
 #include <util/trace.hpp>

 #include <algorithm>
 #include <fstream>
 #include <iostream>
 #include <map>
 #include <string>

 namespace analyzer
 {

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

 // Forward references for externally defined functions.

 /**
  * @brief Will get the list of active chip and initialize the isolator.
  * @param o_chips The returned list of active chips.
  */
 void initializeIsolator(std::vector<libhei::Chip>& o_chips);

 /**
  * @brief Will create and submit a PEL using the given data.
  * @param i_rootCause A signature defining the attention root cause.
  * @param i_isoData   The data gathered during isolation (for FFDC).
  */
 void createPel(const libhei::Signature& i_rootCause,
                const libhei::IsolationData& i_isoData);

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

 const char* __attn(libhei::AttentionType_t i_attnType)
 {
     const char* str = "";
     switch (i_attnType)
     {
         case libhei::ATTN_TYPE_CHECKSTOP:
             str = "CHECKSTOP";
             break;
         case libhei::ATTN_TYPE_UNIT_CS:
             str = "UNIT_CS";
             break;
         case libhei::ATTN_TYPE_RECOVERABLE:
             str = "RECOVERABLE";
             break;
         case libhei::ATTN_TYPE_SP_ATTN:
             str = "SP_ATTN";
             break;
         case libhei::ATTN_TYPE_HOST_ATTN:
             str = "HOST_ATTN";
             break;
         default:
             trace::err("Unsupported attention type: %u", i_attnType);
             assert(0);
     }
     return str;
 }

 uint32_t __trgt(const libhei::Signature& i_sig)
 {
     uint8_t type = util::pdbg::getTrgtType(i_sig.getChip());
     uint32_t pos = util::pdbg::getChipPos(i_sig.getChip());

     // Technically, the FapiPos attribute is 32-bit, but not likely to ever go
     // over 24-bit.

     return type << 24 | (pos & 0xffffff);
 }

 uint32_t __sig(const libhei::Signature& i_sig)
 {
     return i_sig.getId() << 16 | i_sig.getInstance() << 8 | i_sig.getBit();
 }

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

 // Takes a signature list that will be filtered and sorted. The first entry in
 // the returned list will be the root cause. If the returned list is empty,
 // analysis failed.
 void __filterRootCause(std::vector<libhei::Signature>& io_list)
 {
     // For debug, trace out the original list of signatures before filtering.
     for (const auto& sig : io_list)
     {
         trace::inf("Signature: %s 0x%0" PRIx32 " %s",
                    util::pdbg::getPath(sig.getChip()), __sig(sig),
                    __attn(sig.getAttnType()));
     }

     // Special and host attentions are not supported by this user application.
     auto newEndItr =
         std::remove_if(io_list.begin(), io_list.end(), [&](const auto& t) {
             return (libhei::ATTN_TYPE_SP_ATTN == t.getAttnType() ||
                     libhei::ATTN_TYPE_HOST_ATTN == t.getAttnType());
         });

     // Shrink the vector, if needed.
     io_list.resize(std::distance(io_list.begin(), newEndItr));

     // START WORKAROUND
     // TODO: Filtering should be determined by the RAS Data Files provided by
     //       the host firmware via the PNOR (similar to the Chip Data Files).
     //       Until that support is available, use a rudimentary filter that
     //       first looks for any recoverable attention, then any unit checkstop,
     //       and then any system checkstop. This is built on the premise that
     //       recoverable errors could be the root cause of an system checkstop
     //       attentions. Fortunately, we just need to sort the list by the
     //       greater attention type value.
     std::sort(io_list.begin(), io_list.end(),
               [&](const auto& a, const auto& b) {
                   return a.getAttnType() > b.getAttnType();
               });
     // END WORKAROUND
 }

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

 bool __logError(const std::vector<libhei::Signature>& i_sigList,
                 const libhei::IsolationData& i_isoData)
 {
     bool attnFound = false;

     if (i_sigList.empty())
     {
         trace::inf("No active attentions found");
     }
     else
     {
         attnFound = true;

         // The root cause attention is the first in the filtered list.
         libhei::Signature root = i_sigList.front();

         trace::inf("Root cause attention: %s 0x%0" PRIx32 " %s",
                    util::pdbg::getPath(root.getChip()), root.toUint32(),
                    __attn(root.getAttnType()));

         // Create and commit a PEL.
         createPel(root, i_isoData);
     }

     return attnFound;
 }

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

 bool analyzeHardware()
 {
     bool attnFound = false;

     trace::inf(">>> enter analyzeHardware()");

     if (util::pdbg::queryHardwareAnalysisSupported())
     {
         // Initialize the isolator and get all of the chips to be analyzed.
         trace::inf("Initializing the isolator...");
         std::vector<libhei::Chip> chips;
         initializeIsolator(chips);

         // Isolate attentions.
         trace::inf("Isolating errors: # of chips=%u", chips.size());
         libhei::IsolationData isoData{};
         libhei::isolate(chips, isoData);

         // Filter signatures to determine root cause. We'll need to make a copy
         // of the list so that the original list is maintained for the log.
         std::vector<libhei::Signature> sigList{isoData.getSignatureList()};
         __filterRootCause(sigList);

         // Create and commit a log.
         attnFound = __logError(sigList, isoData);

         // All done, clean up the isolator.
         trace::inf("Uninitializing isolator...");
         libhei::uninitialize();
     }
     else
     {
         trace::err("Hardware error analysis is not supported on this system");
     }

     trace::inf("<<< exit analyzeHardware()");

     return attnFound;
 }

 } // namespace analyzer
	#include <assert.h>
	#include <libpdbg.h>
	#include <unistd.h>

	#include <hei_main.hpp>
	#include <phosphor-logging/log.hpp>
	#include <util/pdbg.hpp>
	#include <util/trace.hpp>

	#include <algorithm>
	#include <fstream>
	#include <iostream>
	#include <map>
	#include <string>

	namespace analyzer
	{

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

	// Forward references for externally defined functions.

	/**
	* @brief Will get the list of active chip and initialize the isolator.
	* @param o_chips The returned list of active chips.
	*/
	void initializeIsolator(std::vector<libhei::Chip>& o_chips);

	/**
	* @brief Will create and submit a PEL using the given data.
	* @param i_rootCause A signature defining the attention root cause.
	* @param i_isoData The data gathered during isolation (for FFDC).
	*/
	void createPel(const libhei::Signature& i_rootCause,
	const libhei::IsolationData& i_isoData);

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

	const char* __attn(libhei::AttentionType_t i_attnType)
	{
	const char* str = "";
	switch (i_attnType)
	{
	case libhei::ATTN_TYPE_CHECKSTOP:
	str = "CHECKSTOP";
	break;
	case libhei::ATTN_TYPE_UNIT_CS:
	str = "UNIT_CS";
	break;
	case libhei::ATTN_TYPE_RECOVERABLE:
	str = "RECOVERABLE";
	break;
	case libhei::ATTN_TYPE_SP_ATTN:
	str = "SP_ATTN";
	break;
	case libhei::ATTN_TYPE_HOST_ATTN:
	str = "HOST_ATTN";
	break;
	default:
	trace::err("Unsupported attention type: %u", i_attnType);
	assert(0);
	}
	return str;
	}

	uint32_t __trgt(const libhei::Signature& i_sig)
	{
	uint8_t type = util::pdbg::getTrgtType(i_sig.getChip());
	uint32_t pos = util::pdbg::getChipPos(i_sig.getChip());

	// Technically, the FapiPos attribute is 32-bit, but not likely to ever go
	// over 24-bit.

	return type << 24 \| (pos & 0xffffff);
	}

	uint32_t __sig(const libhei::Signature& i_sig)
	{
	return i_sig.getId() << 16 \| i_sig.getInstance() << 8 \| i_sig.getBit();
	}

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

	// Takes a signature list that will be filtered and sorted. The first entry in
	// the returned list will be the root cause. If the returned list is empty,
	// analysis failed.
	void __filterRootCause(std::vector<libhei::Signature>& io_list)
	{
	// For debug, trace out the original list of signatures before filtering.
	for (const auto& sig : io_list)
	{
	trace::inf("Signature: %s 0x%0" PRIx32 " %s",
	util::pdbg::getPath(sig.getChip()), __sig(sig),
	__attn(sig.getAttnType()));
	}

	// Special and host attentions are not supported by this user application.
	auto newEndItr =
	std::remove_if(io_list.begin(), io_list.end(), [&](const auto& t) {
	return (libhei::ATTN_TYPE_SP_ATTN == t.getAttnType() \|\|
	libhei::ATTN_TYPE_HOST_ATTN == t.getAttnType());
	});

	// Shrink the vector, if needed.
	io_list.resize(std::distance(io_list.begin(), newEndItr));

	// START WORKAROUND
	// TODO: Filtering should be determined by the RAS Data Files provided by
	// the host firmware via the PNOR (similar to the Chip Data Files).
	// Until that support is available, use a rudimentary filter that
	// first looks for any recoverable attention, then any unit checkstop,
	// and then any system checkstop. This is built on the premise that
	// recoverable errors could be the root cause of an system checkstop
	// attentions. Fortunately, we just need to sort the list by the
	// greater attention type value.
	std::sort(io_list.begin(), io_list.end(),
	[&](const auto& a, const auto& b) {
	return a.getAttnType() > b.getAttnType();
	});
	// END WORKAROUND
	}

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

	bool __logError(const std::vector<libhei::Signature>& i_sigList,
	const libhei::IsolationData& i_isoData)
	{
	bool attnFound = false;

	if (i_sigList.empty())
	{
	trace::inf("No active attentions found");
	}
	else
	{
	attnFound = true;

	// The root cause attention is the first in the filtered list.
	libhei::Signature root = i_sigList.front();

	trace::inf("Root cause attention: %s 0x%0" PRIx32 " %s",
	util::pdbg::getPath(root.getChip()), root.toUint32(),
	__attn(root.getAttnType()));

	// Create and commit a PEL.
	createPel(root, i_isoData);
	}

	return attnFound;
	}

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

	bool analyzeHardware()
	{
	bool attnFound = false;

	trace::inf(">>> enter analyzeHardware()");

	if (util::pdbg::queryHardwareAnalysisSupported())
	{
	// Initialize the isolator and get all of the chips to be analyzed.
	trace::inf("Initializing the isolator...");
	std::vector<libhei::Chip> chips;
	initializeIsolator(chips);

	// Isolate attentions.
	trace::inf("Isolating errors: # of chips=%u", chips.size());
	libhei::IsolationData isoData{};
	libhei::isolate(chips, isoData);

	// Filter signatures to determine root cause. We'll need to make a copy
	// of the list so that the original list is maintained for the log.
	std::vector<libhei::Signature> sigList{isoData.getSignatureList()};
	__filterRootCause(sigList);

	// Create and commit a log.
	attnFound = __logError(sigList, isoData);

	// All done, clean up the isolator.
	trace::inf("Uninitializing isolator...");
	libhei::uninitialize();
	}
	else
	{
	trace::err("Hardware error analysis is not supported on this system");
	}

	trace::inf("<<< exit analyzeHardware()");

	return attnFound;
	}

	} // namespace analyzer