/********************************************************************************/ /* */ /* For accessing the TPM_CAP_TPM_PROPERTY values */ /* Written by Ken Goldman */ /* IBM Thomas J. Watson Research Center */ /* $Id: PropertyCap.c 1519 2019-11-15 20:43:51Z kgoldman $ */ /* */ /* Licenses and Notices */ /* */ /* 1. 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The values in the table below are examples and should be changed by the vendor. */ /* Return Values Meaning */ /* TRUE referenced property exists and value set */ /* FALSE referenced property does not exist */ static BOOL TPMPropertyIsDefined( TPM_PT property, // IN: property UINT32 *value // OUT: property value ) { switch(property) { case TPM_PT_FAMILY_INDICATOR: // from the title page of the specification // For this specification, the value is "2.0". *value = TPM_SPEC_FAMILY; break; case TPM_PT_LEVEL: // from the title page of the specification *value = TPM_SPEC_LEVEL; break; case TPM_PT_REVISION: // from the title page of the specification *value = TPM_SPEC_VERSION; break; case TPM_PT_DAY_OF_YEAR: // computed from the date value on the title page of the specification *value = TPM_SPEC_DAY_OF_YEAR; break; case TPM_PT_YEAR: // from the title page of the specification *value = TPM_SPEC_YEAR; break; case TPM_PT_MANUFACTURER: // vendor ID unique to each TPM manufacturer *value = BYTE_ARRAY_TO_UINT32(MANUFACTURER); break; case TPM_PT_VENDOR_STRING_1: // first four characters of the vendor ID string *value = BYTE_ARRAY_TO_UINT32(VENDOR_STRING_1); break; case TPM_PT_VENDOR_STRING_2: // second four characters of the vendor ID string #ifdef VENDOR_STRING_2 *value = BYTE_ARRAY_TO_UINT32(VENDOR_STRING_2); #else *value = 0; #endif break; case TPM_PT_VENDOR_STRING_3: // third four characters of the vendor ID string #ifdef VENDOR_STRING_3 *value = BYTE_ARRAY_TO_UINT32(VENDOR_STRING_3); #else *value = 0; #endif break; case TPM_PT_VENDOR_STRING_4: // fourth four characters of the vendor ID string #ifdef VENDOR_STRING_4 *value = BYTE_ARRAY_TO_UINT32(VENDOR_STRING_4); #else *value = 0; #endif break; case TPM_PT_VENDOR_TPM_TYPE: // vendor-defined value indicating the TPM model *value = 1; break; case TPM_PT_FIRMWARE_VERSION_1: // more significant 32-bits of a vendor-specific value *value = gp.firmwareV1; break; case TPM_PT_FIRMWARE_VERSION_2: // less significant 32-bits of a vendor-specific value *value = gp.firmwareV2; break; case TPM_PT_INPUT_BUFFER: // maximum size of TPM2B_MAX_BUFFER *value = MAX_DIGEST_BUFFER; break; case TPM_PT_HR_TRANSIENT_MIN: // minimum number of transient objects that can be held in TPM // RAM *value = MAX_LOADED_OBJECTS; break; case TPM_PT_HR_PERSISTENT_MIN: // minimum number of persistent objects that can be held in // TPM NV memory // In this implementation, there is no minimum number of // persistent objects. *value = MIN_EVICT_OBJECTS; break; case TPM_PT_HR_LOADED_MIN: // minimum number of authorization sessions that can be held in // TPM RAM *value = MAX_LOADED_SESSIONS; break; case TPM_PT_ACTIVE_SESSIONS_MAX: // number of authorization sessions that may be active at a time *value = MAX_ACTIVE_SESSIONS; break; case TPM_PT_PCR_COUNT: // number of PCR implemented *value = IMPLEMENTATION_PCR; break; case TPM_PT_PCR_SELECT_MIN: // minimum number of bytes in a TPMS_PCR_SELECT.sizeOfSelect *value = PCR_SELECT_MIN; break; case TPM_PT_CONTEXT_GAP_MAX: // maximum allowed difference (unsigned) between the contextID // values of two saved session contexts *value = ((UINT32)1 << (sizeof(CONTEXT_SLOT) * 8)) - 1; break; case TPM_PT_NV_COUNTERS_MAX: // maximum number of NV indexes that are allowed to have the // TPMA_NV_COUNTER attribute SET // In this implementation, there is no limitation on the number // of counters, except for the size of the NV Index memory. *value = 0; break; case TPM_PT_NV_INDEX_MAX: // maximum size of an NV index data area *value = MAX_NV_INDEX_SIZE; break; case TPM_PT_MEMORY: // a TPMA_MEMORY indicating the memory management method for the TPM { union { TPMA_MEMORY att; UINT32 u32; } attributes = { TPMA_ZERO_INITIALIZER() }; SET_ATTRIBUTE(attributes.att, TPMA_MEMORY, sharedNV); SET_ATTRIBUTE(attributes.att, TPMA_MEMORY, objectCopiedToRam); // Note: For a LSb0 machine, the bits in a bit field are in the correct // order even if the machine is MSB0. For a MSb0 machine, a TPMA will // be an integer manipulated by masking (USE_BIT_FIELD_STRUCTURES will // NO) so the bits are manipulated correctly. *value = attributes.u32; break; } case TPM_PT_CLOCK_UPDATE: // interval, in seconds, between updates to the copy of // TPMS_TIME_INFO .clock in NV *value = (1 << NV_CLOCK_UPDATE_INTERVAL); break; case TPM_PT_CONTEXT_HASH: // algorithm used for the integrity hash on saved contexts and // for digesting the fuData of TPM2_FirmwareRead() *value = CONTEXT_INTEGRITY_HASH_ALG; break; case TPM_PT_CONTEXT_SYM: // algorithm used for encryption of saved contexts *value = CONTEXT_ENCRYPT_ALG; break; case TPM_PT_CONTEXT_SYM_SIZE: // size of the key used for encryption of saved contexts *value = CONTEXT_ENCRYPT_KEY_BITS; break; case TPM_PT_ORDERLY_COUNT: // maximum difference between the volatile and non-volatile // versions of TPMA_NV_COUNTER that have TPMA_NV_ORDERLY SET *value = MAX_ORDERLY_COUNT; break; case TPM_PT_MAX_COMMAND_SIZE: // maximum value for 'commandSize' *value = MAX_COMMAND_SIZE; break; case TPM_PT_MAX_RESPONSE_SIZE: // maximum value for 'responseSize' *value = MAX_RESPONSE_SIZE; break; case TPM_PT_MAX_DIGEST: // maximum size of a digest that can be produced by the TPM *value = sizeof(TPMU_HA); break; case TPM_PT_MAX_OBJECT_CONTEXT: // Header has 'sequence', 'handle' and 'hierarchy' #define SIZE_OF_CONTEXT_HEADER \ sizeof(UINT64) + sizeof(TPMI_DH_CONTEXT) + sizeof(TPMI_RH_HIERARCHY) #define SIZE_OF_CONTEXT_INTEGRITY (sizeof(UINT16) + CONTEXT_INTEGRITY_HASH_SIZE) #define SIZE_OF_FINGERPRINT sizeof(UINT64) #define SIZE_OF_CONTEXT_BLOB_OVERHEAD \ (sizeof(UINT16) + SIZE_OF_CONTEXT_INTEGRITY + SIZE_OF_FINGERPRINT) #define SIZE_OF_CONTEXT_OVERHEAD \ (SIZE_OF_CONTEXT_HEADER + SIZE_OF_CONTEXT_BLOB_OVERHEAD) #if 0 // maximum size of a TPMS_CONTEXT that will be returned by // TPM2_ContextSave for object context *value = 0; // adding sequence, saved handle and hierarchy *value += sizeof(UINT64) + sizeof(TPMI_DH_CONTEXT) + sizeof(TPMI_RH_HIERARCHY); // add size field in TPM2B_CONTEXT *value += sizeof(UINT16); // add integrity hash size *value += sizeof(UINT16) + CryptHashGetDigestSize(CONTEXT_INTEGRITY_HASH_ALG); // Add fingerprint size, which is the same as sequence size *value += sizeof(UINT64); // Add OBJECT structure size *value += sizeof(OBJECT); #else // the maximum size of a TPMS_CONTEXT that will be returned by // TPM2_ContextSave for object context *value = SIZE_OF_CONTEXT_OVERHEAD + sizeof(OBJECT); #endif break; case TPM_PT_MAX_SESSION_CONTEXT: #if 0 // the maximum size of a TPMS_CONTEXT that will be returned by // TPM2_ContextSave for object context *value = 0; // adding sequence, saved handle and hierarchy *value += sizeof(UINT64) + sizeof(TPMI_DH_CONTEXT) + sizeof(TPMI_RH_HIERARCHY); // Add size field in TPM2B_CONTEXT *value += sizeof(UINT16); // Add integrity hash size *value += sizeof(UINT16) + CryptHashGetDigestSize(CONTEXT_INTEGRITY_HASH_ALG); // Add fingerprint size, which is the same as sequence size *value += sizeof(UINT64); // Add SESSION structure size *value += sizeof(SESSION); #else // the maximum size of a TPMS_CONTEXT that will be returned by // TPM2_ContextSave for object context *value = SIZE_OF_CONTEXT_OVERHEAD + sizeof(SESSION); #endif break; case TPM_PT_PS_FAMILY_INDICATOR: // platform specific values for the TPM_PT_PS parameters from // the relevant platform-specific specification // In this reference implementation, all of these values are 0. *value = PLATFORM_FAMILY; break; case TPM_PT_PS_LEVEL: // level of the platform-specific specification *value = PLATFORM_LEVEL; break; case TPM_PT_PS_REVISION: // specification Revision times 100 for the platform-specific // specification *value = PLATFORM_VERSION; break; case TPM_PT_PS_DAY_OF_YEAR: // platform-specific specification day of year using TCG calendar *value = PLATFORM_DAY_OF_YEAR; break; case TPM_PT_PS_YEAR: // platform-specific specification year using the CE *value = PLATFORM_YEAR; break; case TPM_PT_SPLIT_MAX: // number of split signing operations supported by the TPM *value = 0; #if ALG_ECC *value = sizeof(gr.commitArray) * 8; #endif break; case TPM_PT_TOTAL_COMMANDS: // total number of commands implemented in the TPM // Since the reference implementation does not have any // vendor-defined commands, this will be the same as the // number of library commands. { #if COMPRESSED_LISTS (*value) = COMMAND_COUNT; #else COMMAND_INDEX commandIndex; *value = 0; // scan all implemented commands for(commandIndex = GetClosestCommandIndex(0); commandIndex != UNIMPLEMENTED_COMMAND_INDEX; commandIndex = GetNextCommandIndex(commandIndex)) { (*value)++; // count of all implemented } #endif break; } case TPM_PT_LIBRARY_COMMANDS: // number of commands from the TPM library that are implemented { #if COMPRESSED_LISTS *value = LIBRARY_COMMAND_ARRAY_SIZE; #else COMMAND_INDEX commandIndex; *value = 0; // scan all implemented commands for(commandIndex = GetClosestCommandIndex(0); commandIndex < LIBRARY_COMMAND_ARRAY_SIZE; commandIndex = GetNextCommandIndex(commandIndex)) { (*value)++; } #endif break; } case TPM_PT_VENDOR_COMMANDS: // number of vendor commands that are implemented *value = VENDOR_COMMAND_ARRAY_SIZE; break; case TPM_PT_NV_BUFFER_MAX: // Maximum data size in an NV write command *value = MAX_NV_BUFFER_SIZE; break; case TPM_PT_MODES: #if FIPS_COMPLIANT *value = 1; #else *value = 0; #endif break; case TPM_PT_MAX_CAP_BUFFER: *value = MAX_CAP_BUFFER; break; // Start of variable commands case TPM_PT_PERMANENT: // TPMA_PERMANENT { union { TPMA_PERMANENT attr; UINT32 u32; } flags = { TPMA_ZERO_INITIALIZER() }; if(gp.ownerAuth.t.size != 0) SET_ATTRIBUTE(flags.attr, TPMA_PERMANENT, ownerAuthSet); if(gp.endorsementAuth.t.size != 0) SET_ATTRIBUTE(flags.attr, TPMA_PERMANENT, endorsementAuthSet); if(gp.lockoutAuth.t.size != 0) SET_ATTRIBUTE(flags.attr, TPMA_PERMANENT, lockoutAuthSet); if(gp.disableClear) SET_ATTRIBUTE(flags.attr, TPMA_PERMANENT, disableClear); if(gp.failedTries >= gp.maxTries) SET_ATTRIBUTE(flags.attr, TPMA_PERMANENT, inLockout); // In this implementation, EPS is always generated by TPM SET_ATTRIBUTE(flags.attr, TPMA_PERMANENT, tpmGeneratedEPS); // Note: For a LSb0 machine, the bits in a bit field are in the correct // order even if the machine is MSB0. For a MSb0 machine, a TPMA will // be an integer manipulated by masking (USE_BIT_FIELD_STRUCTURES will // be NO ) so the bits are manipulate correctly. *value = flags.u32; break; } case TPM_PT_STARTUP_CLEAR: // TPMA_STARTUP_CLEAR { union { TPMA_STARTUP_CLEAR attr; UINT32 u32; } flags = { TPMA_ZERO_INITIALIZER() }; // if(g_phEnable) SET_ATTRIBUTE(flags.attr, TPMA_STARTUP_CLEAR, phEnable); if(gc.shEnable) SET_ATTRIBUTE(flags.attr, TPMA_STARTUP_CLEAR, shEnable); if(gc.ehEnable) SET_ATTRIBUTE(flags.attr, TPMA_STARTUP_CLEAR, ehEnable); if(gc.phEnableNV) SET_ATTRIBUTE(flags.attr, TPMA_STARTUP_CLEAR, phEnableNV); if(g_prevOrderlyState != SU_NONE_VALUE) SET_ATTRIBUTE(flags.attr, TPMA_STARTUP_CLEAR, orderly); // Note: For a LSb0 machine, the bits in a bit field are in the correct // order even if the machine is MSB0. For a MSb0 machine, a TPMA will // be an integer manipulated by masking (USE_BIT_FIELD_STRUCTURES will // be NO) so the bits are manipulate correctly. *value = flags.u32; break; } case TPM_PT_HR_NV_INDEX: // number of NV indexes currently defined *value = NvCapGetIndexNumber(); break; case TPM_PT_HR_LOADED: // number of authorization sessions currently loaded into TPM // RAM *value = SessionCapGetLoadedNumber(); break; case TPM_PT_HR_LOADED_AVAIL: // number of additional authorization sessions, of any type, // that could be loaded into TPM RAM *value = SessionCapGetLoadedAvail(); break; case TPM_PT_HR_ACTIVE: // number of active authorization sessions currently being // tracked by the TPM *value = SessionCapGetActiveNumber(); break; case TPM_PT_HR_ACTIVE_AVAIL: // number of additional authorization sessions, of any type, // that could be created *value = SessionCapGetActiveAvail(); break; case TPM_PT_HR_TRANSIENT_AVAIL: // estimate of the number of additional transient objects that // could be loaded into TPM RAM *value = ObjectCapGetTransientAvail(); break; case TPM_PT_HR_PERSISTENT: // number of persistent objects currently loaded into TPM // NV memory *value = NvCapGetPersistentNumber(); break; case TPM_PT_HR_PERSISTENT_AVAIL: // number of additional persistent objects that could be loaded // into NV memory *value = NvCapGetPersistentAvail(); break; case TPM_PT_NV_COUNTERS: // number of defined NV indexes that have NV TPMA_NV_COUNTER // attribute SET *value = NvCapGetCounterNumber(); break; case TPM_PT_NV_COUNTERS_AVAIL: // number of additional NV indexes that can be defined with their // TPMA_NV_COUNTER attribute SET *value = NvCapGetCounterAvail(); break; case TPM_PT_ALGORITHM_SET: // region code for the TPM *value = gp.algorithmSet; break; case TPM_PT_LOADED_CURVES: #if ALG_ECC // number of loaded ECC curves *value = ECC_CURVE_COUNT; #else // ALG_ECC *value = 0; #endif // ALG_ECC break; case TPM_PT_LOCKOUT_COUNTER: // current value of the lockout counter *value = gp.failedTries; break; case TPM_PT_MAX_AUTH_FAIL: // number of authorization failures before DA lockout is invoked *value = gp.maxTries; break; case TPM_PT_LOCKOUT_INTERVAL: // number of seconds before the value reported by // TPM_PT_LOCKOUT_COUNTER is decremented *value = gp.recoveryTime; break; case TPM_PT_LOCKOUT_RECOVERY: // number of seconds after a lockoutAuth failure before use of // lockoutAuth may be attempted again *value = gp.lockoutRecovery; break; case TPM_PT_NV_WRITE_RECOVERY: // number of milliseconds before the TPM will accept another command // that will modify NV. // This should make a call to the platform code that is doing rate // limiting of NV. Rate limiting is not implemented in the reference // code so no call is made. *value = 0; break; case TPM_PT_AUDIT_COUNTER_0: // high-order 32 bits of the command audit counter *value = (UINT32)(gp.auditCounter >> 32); break; case TPM_PT_AUDIT_COUNTER_1: // low-order 32 bits of the command audit counter *value = (UINT32)(gp.auditCounter); break; default: // property is not defined return FALSE; break; } return TRUE; } /* 9.14.3.2 TPMCapGetProperties() */ /* This function is used to get the TPM_PT values. The search of properties will start at property and continue until propertyList has as many values as will fit, or the last property has been reported, or the list has as many values as requested in count. */ /* Return Values Meaning */ /* YES more properties are available */ /* NO no more properties to be reported */ TPMI_YES_NO TPMCapGetProperties( TPM_PT property, // IN: the starting TPM property UINT32 count, // IN: maximum number of returned // properties TPML_TAGGED_TPM_PROPERTY *propertyList // OUT: property list ) { TPMI_YES_NO more = NO; UINT32 i; UINT32 nextGroup; // initialize output property list propertyList->count = 0; // maximum count of properties we may return is MAX_PCR_PROPERTIES if(count > MAX_TPM_PROPERTIES) count = MAX_TPM_PROPERTIES; // if property is less than PT_FIXED, start from PT_FIXED if(property < PT_FIXED) property = PT_FIXED; // There is only the fixed and variable groups with the variable group coming // last if(property >= (PT_VAR + PT_GROUP)) return more; // Don't read past the end of the selected group nextGroup = ((property / PT_GROUP) * PT_GROUP) + PT_GROUP; // Scan through the TPM properties of the requested group. for(i = property; i < nextGroup; i++) { UINT32 value; // if we have hit the end of the group, quit if(i != property && ((i % PT_GROUP) == 0)) break; if(TPMPropertyIsDefined((TPM_PT)i, &value)) { if(propertyList->count < count) { // If the list is not full, add this property propertyList->tpmProperty[propertyList->count].property = (TPM_PT)i; propertyList->tpmProperty[propertyList->count].value = value; propertyList->count++; } else { // If the return list is full but there are more properties // available, set the indication and exit the loop. more = YES; break; } } } return more; }