1 /** 2 * Describes high level functions for converting an entire CPER log, and functions for parsing 3 * CPER headers and section descriptions into an intermediate JSON format. 4 * 5 * Author: Lawrence.Tang@arm.com 6 **/ 7 8 #include <stdio.h> 9 #include "json.h" 10 #include "edk/Cper.h" 11 #include "cper-parse.h" 12 #include "cper-utils.h" 13 #include "sections/cper-section-generic.h" 14 #include "sections/cper-section-ia32x64.h" 15 #include "sections/cper-section-arm.h" 16 #include "sections/cper-section-memory.h" 17 #include "sections/cper-section-pcie.h" 18 #include "sections/cper-section-pci-bus.h" 19 #include "sections/cper-section-pci-dev.h" 20 #include "sections/cper-section-firmware.h" 21 #include "sections/cper-section-dmar-generic.h" 22 #include "sections/cper-section-dmar-vtd.h" 23 #include "sections/cper-section-dmar-iommu.h" 24 #include "sections/cper-section-ccix-per.h" 25 #include "sections/cper-section-cxl-protocol.h" 26 27 //Private pre-definitions. 28 json_object* cper_header_to_ir(EFI_COMMON_ERROR_RECORD_HEADER* header); 29 json_object* cper_section_descriptor_to_ir(EFI_ERROR_SECTION_DESCRIPTOR* section_descriptor); 30 json_object* cper_section_to_ir(FILE* handle, EFI_ERROR_SECTION_DESCRIPTOR* descriptor); 31 32 //Reads a CPER log file at the given file location, and returns an intermediate 33 //JSON representation of this CPER record. 34 json_object* cper_to_ir(const char* filename) 35 { 36 //Get a handle for the log file. 37 FILE* cper_file = fopen(filename, "r"); 38 if (cper_file == NULL) { 39 printf("Could not open CPER record, file handle returned null."); 40 return NULL; 41 } 42 43 //Ensure this is really a CPER log. 44 EFI_COMMON_ERROR_RECORD_HEADER header; 45 fseek(cper_file, 0, SEEK_SET); 46 if (fread(&header, sizeof(EFI_COMMON_ERROR_RECORD_HEADER), 1, cper_file) != 1) 47 { 48 printf("Invalid CPER file: Invalid length (log too short)."); 49 return NULL; 50 } 51 52 //Check if the header contains the magic bytes ("CPER"). 53 if (header.SignatureStart != EFI_ERROR_RECORD_SIGNATURE_START) { 54 printf("Invalid CPER file: Invalid header (incorrect signature)."); 55 return NULL; 56 } 57 58 // //Print struct contents (debug). 59 // fpos_t file_pos; 60 // fgetpos(cper_file, &file_pos); 61 // printf("Stream is at position %d.\n", file_pos); 62 // printf("SignatureStart: %s\n", (char*)&header.SignatureStart); 63 // printf("Revision: %u\n", header.Revision); 64 // printf("SectionCount: %u\n", header.SectionCount); 65 // printf("Severity: %d\n", header.ErrorSeverity); 66 // printf("RecordLength: %d\n", header.RecordLength); 67 68 //Create the header JSON object from the read bytes. 69 json_object* header_ir = cper_header_to_ir(&header); 70 71 //Read the appropriate number of section descriptors & sections, and convert them into IR format. 72 json_object* section_descriptors_ir = json_object_new_array(); 73 json_object* sections_ir = json_object_new_array(); 74 for (int i=0; i<header.SectionCount; i++) 75 { 76 //Create the section descriptor. 77 EFI_ERROR_SECTION_DESCRIPTOR section_descriptor; 78 if (fread(§ion_descriptor, sizeof(EFI_ERROR_SECTION_DESCRIPTOR), 1, cper_file) != 1) 79 { 80 printf("Invalid number of section headers: Header states %d sections, could not read section %d.", header.SectionCount, i+1); 81 return NULL; 82 } 83 json_object_array_add(section_descriptors_ir, cper_section_descriptor_to_ir(§ion_descriptor)); 84 85 //Read the section itself. 86 json_object_array_add(sections_ir, cper_section_to_ir(cper_file, §ion_descriptor)); 87 } 88 89 //Add the header, section descriptors, and sections to a parent object. 90 json_object* parent = json_object_new_object(); 91 json_object_object_add(parent, "header", header_ir); 92 json_object_object_add(parent, "sectionDescriptors", section_descriptors_ir); 93 json_object_object_add(parent, "sections", sections_ir); 94 95 //... 96 return parent; 97 } 98 99 //Converts a parsed CPER record header into intermediate JSON object format. 100 json_object* cper_header_to_ir(EFI_COMMON_ERROR_RECORD_HEADER* header) 101 { 102 json_object* header_ir = json_object_new_object(); 103 104 //Revision/version information. 105 json_object_object_add(header_ir, "revision", revision_to_ir(header->Revision)); 106 107 //Section count. 108 json_object_object_add(header_ir, "sectionCount", json_object_new_int(header->SectionCount)); 109 110 //Error severity (with interpreted string version). 111 json_object* error_severity = json_object_new_object(); 112 json_object_object_add(error_severity, "code", json_object_new_int(header->ErrorSeverity)); 113 json_object_object_add(error_severity, "name", json_object_new_string(severity_to_string(header->ErrorSeverity))); 114 json_object_object_add(header_ir, "severity", error_severity); 115 116 //The validation bits for each section. 117 json_object* validation_bits = bitfield_to_ir(header->ValidationBits, 3, CPER_HEADER_VALID_BITFIELD_NAMES); 118 json_object_object_add(header_ir, "validationBits", validation_bits); 119 120 //Total length of the record (including headers) in bytes. 121 json_object_object_add(header_ir, "recordLength", json_object_new_int(header->RecordLength)); 122 123 //If a timestamp exists according to validation bits, then add it. 124 if (header->ValidationBits & 0b10) 125 { 126 char timestamp_string[TIMESTAMP_LENGTH]; 127 sprintf(timestamp_string, "%02d%02d-%02d-%02dT%02d:%02d:%02d.000", 128 header->TimeStamp.Century, 129 header->TimeStamp.Year, 130 header->TimeStamp.Month, 131 header->TimeStamp.Day, 132 header->TimeStamp.Hours, 133 header->TimeStamp.Minutes, 134 header->TimeStamp.Seconds); 135 136 json_object_object_add(header_ir, "timestamp", json_object_new_string(timestamp_string)); 137 json_object_object_add(header_ir, "timestampIsPrecise", json_object_new_boolean(header->TimeStamp.Flag)); 138 } 139 140 //If a platform ID exists according to the validation bits, then add it. 141 if (header->ValidationBits & 0b1) 142 { 143 char platform_string[GUID_STRING_LENGTH]; 144 guid_to_string(platform_string, &header->PlatformID); 145 json_object_object_add(header_ir, "platformID", json_object_new_string(platform_string)); 146 } 147 148 //If a partition ID exists according to the validation bits, then add it. 149 if (header->ValidationBits & 0b100) 150 { 151 char partition_string[GUID_STRING_LENGTH]; 152 guid_to_string(partition_string, &header->PartitionID); 153 json_object_object_add(header_ir, "partitionID", json_object_new_string(partition_string)); 154 } 155 156 //Creator ID of the header. 157 char creator_string[GUID_STRING_LENGTH]; 158 guid_to_string(creator_string, &header->CreatorID); 159 json_object_object_add(header_ir, "creatorID", json_object_new_string(creator_string)); 160 161 //Notification type for the header. Some defined types are available. 162 json_object* notification_type = json_object_new_object(); 163 char notification_type_string[GUID_STRING_LENGTH]; 164 guid_to_string(notification_type_string, &header->NotificationType); 165 json_object_object_add(notification_type, "guid", json_object_new_string(notification_type_string)); 166 167 //Add the human readable notification type if possible. 168 char* notification_type_readable = "Unknown"; 169 if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypeCmcGuid)) 170 notification_type_readable = "CMC"; 171 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypeCpeGuid)) 172 notification_type_readable = "CPE"; 173 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypeMceGuid)) 174 notification_type_readable = "MCE"; 175 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypePcieGuid)) 176 notification_type_readable = "PCIe"; 177 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypeInitGuid)) 178 notification_type_readable = "INIT"; 179 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypeNmiGuid)) 180 notification_type_readable = "NMI"; 181 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypeBootGuid)) 182 notification_type_readable = "Boot"; 183 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypeDmarGuid)) 184 notification_type_readable = "DMAr"; 185 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypeSeaGuid)) 186 notification_type_readable = "SEA"; 187 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypeSeiGuid)) 188 notification_type_readable = "SEI"; 189 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypePeiGuid)) 190 notification_type_readable = "PEI"; 191 else if (guid_equal(&header->NotificationType, &gEfiEventNotificationTypeCxlGuid)) 192 notification_type_readable = "CXL Component"; 193 json_object_object_add(notification_type, "type", json_object_new_string(notification_type_readable)); 194 json_object_object_add(header_ir, "notificationType", notification_type); 195 196 //The record ID for this record, unique on a given system. 197 json_object_object_add(header_ir, "recordID", json_object_new_uint64(header->RecordID)); 198 199 //Flag for the record, and a human readable form. 200 json_object* flags = integer_to_readable_pair(header->Flags, 201 sizeof(CPER_HEADER_FLAG_TYPES_KEYS) / sizeof(int), 202 CPER_HEADER_FLAG_TYPES_KEYS, 203 CPER_HEADER_FLAG_TYPES_VALUES, 204 "Unknown"); 205 json_object_object_add(header_ir, "flags", flags); 206 207 //Persistence information. Outside the scope of specification, so just a uint32 here. 208 json_object_object_add(header_ir, "persistenceInformation", json_object_new_uint64(header->PersistenceInfo)); 209 return header_ir; 210 } 211 212 //Converts the given EFI section descriptor into JSON IR format. 213 json_object* cper_section_descriptor_to_ir(EFI_ERROR_SECTION_DESCRIPTOR* section_descriptor) 214 { 215 json_object* section_descriptor_ir = json_object_new_object(); 216 217 //The offset of the section from the base of the record header, length. 218 json_object_object_add(section_descriptor_ir, "sectionOffset", json_object_new_int(section_descriptor->SectionOffset)); 219 json_object_object_add(section_descriptor_ir, "sectionLength", json_object_new_int(section_descriptor->SectionLength)); 220 221 //Revision. 222 json_object_object_add(section_descriptor_ir, "revision", revision_to_ir(section_descriptor->Revision)); 223 224 //Validation bits. 225 json_object* validation_bits = json_object_new_object(); 226 json_object_object_add(validation_bits, "fruID", json_object_new_boolean(section_descriptor->SecValidMask & 0b1)); 227 json_object_object_add(validation_bits, "fruString", json_object_new_boolean((section_descriptor->SecValidMask & 0b10) >> 1)); 228 json_object_object_add(section_descriptor_ir, "validationBits", validation_bits); 229 230 //Flag bits. 231 json_object* flags = bitfield_to_ir(section_descriptor->SectionFlags, 8, CPER_SECTION_DESCRIPTOR_FLAGS_BITFIELD_NAMES); 232 json_object_object_add(section_descriptor_ir, "flags", flags); 233 234 //Section type (GUID). 235 json_object* section_type = json_object_new_object(); 236 char section_type_string[GUID_STRING_LENGTH]; 237 guid_to_string(section_type_string, §ion_descriptor->SectionType); 238 json_object_object_add(section_type, "data", json_object_new_string(section_type_string)); 239 240 //Readable section type, if possible. 241 char* section_type_readable = "Unknown"; 242 if (guid_equal(§ion_descriptor->SectionType, &gEfiProcessorGenericErrorSectionGuid)) 243 section_type_readable = "Processor Generic"; 244 else if (guid_equal(§ion_descriptor->SectionType, &gEfiIa32X64ProcessorErrorSectionGuid)) 245 section_type_readable = "IA32/X64"; 246 //todo: Why does IPF have an overly long GUID? 247 // if (guid_equal(§ion_descriptor->SectionType, &gEfiIpfProcessorErrorSectionGuid)) 248 // section_type_readable = "IPF"; 249 else if (guid_equal(§ion_descriptor->SectionType, &gEfiArmProcessorErrorSectionGuid)) 250 section_type_readable = "ARM"; 251 else if (guid_equal(§ion_descriptor->SectionType, &gEfiPlatformMemoryErrorSectionGuid)) 252 section_type_readable = "Platform Memory"; 253 else if (guid_equal(§ion_descriptor->SectionType, &gEfiPcieErrorSectionGuid)) 254 section_type_readable = "PCIe"; 255 else if (guid_equal(§ion_descriptor->SectionType, &gEfiFirmwareErrorSectionGuid)) 256 section_type_readable = "Firmware Error Record Reference"; 257 else if (guid_equal(§ion_descriptor->SectionType, &gEfiPciBusErrorSectionGuid)) 258 section_type_readable = "PCI/PCI-X Bus"; 259 else if (guid_equal(§ion_descriptor->SectionType, &gEfiPciDevErrorSectionGuid)) 260 section_type_readable = "PCI Component/Device"; 261 else if (guid_equal(§ion_descriptor->SectionType, &gEfiDMArGenericErrorSectionGuid)) 262 section_type_readable = "DMAr Generic"; 263 else if (guid_equal(§ion_descriptor->SectionType, &gEfiDirectedIoDMArErrorSectionGuid)) 264 section_type_readable = "Intel VT for Directed I/O specific DMAr section"; 265 else if (guid_equal(§ion_descriptor->SectionType, &gEfiIommuDMArErrorSectionGuid)) 266 section_type_readable = "IOMMU specific DMAr section"; 267 else if (guid_equal(§ion_descriptor->SectionType, &gEfiCcixPerLogErrorSectionGuid)) 268 section_type_readable = "CCIX PER Log Error"; 269 else if (guid_equal(§ion_descriptor->SectionType, &gEfiCxlProtocolErrorSectionGuid)) 270 section_type_readable = "CXL Protocol Error"; 271 272 //todo: How do you determine if this is a CXL component event? 273 //perhaps refer to CXL Specification, Rev 2.0 274 // if (guid_equal(§ion_descriptor->SectionType, &gEfiProcessorGenericErrorSectionGuid)) 275 // section_type_readable = "CXL Component Event"; 276 277 json_object_object_add(section_type, "type", json_object_new_string(section_type_readable)); 278 json_object_object_add(section_descriptor_ir, "sectionType", section_type); 279 280 //If validation bits indicate it exists, add FRU ID. 281 if (section_descriptor->SecValidMask & 0b1) 282 { 283 char fru_id_string[GUID_STRING_LENGTH]; 284 guid_to_string(fru_id_string, §ion_descriptor->FruId); 285 json_object_object_add(section_descriptor_ir, "fruID", json_object_new_string(fru_id_string)); 286 } 287 288 //If validation bits indicate it exists, add FRU text. 289 if ((section_descriptor->SecValidMask & 0b10) >> 1) 290 json_object_object_add(section_descriptor_ir, "fruText", json_object_new_string(section_descriptor->FruString)); 291 292 //Section severity. 293 json_object* section_severity = json_object_new_object(); 294 json_object_object_add(section_severity, "code", json_object_new_int(section_descriptor->Severity)); 295 json_object_object_add(section_severity, "name", json_object_new_string(severity_to_string(section_descriptor->Severity))); 296 json_object_object_add(section_descriptor_ir, "severity", section_severity); 297 298 return section_descriptor_ir; 299 } 300 301 302 //Converts the section described by a single given section descriptor. 303 json_object* cper_section_to_ir(FILE* handle, EFI_ERROR_SECTION_DESCRIPTOR* descriptor) 304 { 305 //Read section as described by the section descriptor. 306 fseek(handle, descriptor->SectionOffset, SEEK_SET); 307 void* section = calloc(1, descriptor->SectionLength); 308 if (fread(section, descriptor->SectionLength, 1, handle) != 1) 309 { 310 printf("Section read failed: Could not read %d bytes from global offset %d.", 311 descriptor->SectionLength, 312 descriptor->SectionOffset); 313 } 314 315 //Parse section to IR based on GUID. 316 json_object* result = NULL; 317 if (guid_equal(&descriptor->SectionType, &gEfiProcessorGenericErrorSectionGuid)) 318 result = cper_section_generic_to_ir(section, descriptor); 319 else if (guid_equal(&descriptor->SectionType, &gEfiIa32X64ProcessorErrorSectionGuid)) 320 result = cper_section_ia32x64_to_ir(section, descriptor); 321 // //todo: Why does IPF have an overly long GUID? 322 // // if (guid_equal(&descriptor->SectionType, &gEfiIpfProcessorErrorSectionGuid)) 323 else if (guid_equal(&descriptor->SectionType, &gEfiArmProcessorErrorSectionGuid)) 324 result = cper_section_arm_to_ir(section, descriptor); 325 else if (guid_equal(&descriptor->SectionType, &gEfiPlatformMemoryErrorSectionGuid)) 326 result = cper_section_platform_memory_to_ir(section, descriptor); 327 else if (guid_equal(&descriptor->SectionType, &gEfiPlatformMemoryError2SectionGuid)) 328 result = cper_section_platform_memory2_to_ir(section, descriptor); 329 else if (guid_equal(&descriptor->SectionType, &gEfiPcieErrorSectionGuid)) 330 result = cper_section_pcie_to_ir(section, descriptor); 331 else if (guid_equal(&descriptor->SectionType, &gEfiFirmwareErrorSectionGuid)) 332 result = cper_section_firmware_to_ir(section, descriptor); 333 else if (guid_equal(&descriptor->SectionType, &gEfiPciBusErrorSectionGuid)) 334 result = cper_section_pci_bus_to_ir(section, descriptor); 335 else if (guid_equal(&descriptor->SectionType, &gEfiPciDevErrorSectionGuid)) 336 result = cper_section_pci_dev_to_ir(section, descriptor); 337 else if (guid_equal(&descriptor->SectionType, &gEfiDMArGenericErrorSectionGuid)) 338 result = cper_section_dmar_generic_to_ir(section, descriptor); 339 else if (guid_equal(&descriptor->SectionType, &gEfiDirectedIoDMArErrorSectionGuid)) 340 result = cper_section_dmar_vtd_to_ir(section, descriptor); 341 else if (guid_equal(&descriptor->SectionType, &gEfiIommuDMArErrorSectionGuid)) 342 result = cper_section_dmar_iommu_to_ir(section, descriptor); 343 else if (guid_equal(&descriptor->SectionType, &gEfiCcixPerLogErrorSectionGuid)) 344 result = cper_section_ccix_per_to_ir(section, descriptor); 345 else if (guid_equal(&descriptor->SectionType, &gEfiCxlProtocolErrorSectionGuid)) 346 result = cper_section_cxl_protocol_to_ir(section, descriptor); 347 else 348 { 349 //Failed read, unknown GUID. 350 //todo: dump the binary data out to b64. 351 } 352 353 //Free section memory, return result. 354 free(section); 355 return result; 356 }