blob: c05cc033f344994db12dabe87d844ee05a6fd3c3 [file] [log] [blame]
// This file was extracted from the TCG Published
// Trusted Platform Module Library
// Part 4: Supporting Routines
// Family "2.0"
// Level 00 Revision 01.16
// October 30, 2014
#include "InternalRoutines.h"
//
//
// Functions
//
// PCRGetProperty()
//
// This function accepts a property selection and, if so, sets value to the value of the property.
// All the fixed values are vendor dependent or determined by a platform-specific specification. The values
// in the table below are examples and should be changed by the vendor.
//
// Return Value 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 = (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
{
TPMA_MEMORY attributes = {0};
attributes.sharedNV = SET;
attributes.objectCopiedToRam = SET;
// Note: Different compilers may require a different method to cast
// a bit field structure to a UINT32.
memcpy(value, &attributes, sizeof(UINT32));
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:
// 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) +
CryptGetHashDigestSize(CONTEXT_INTEGRITY_HASH_ALG);
// Add fingerprint size, which is the same as sequence size
*value += sizeof(UINT64);
// Add OBJECT structure size
*value += sizeof(OBJECT);
break;
case TPM_PT_MAX_SESSION_CONTEXT:
// 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) +
CryptGetHashDigestSize(CONTEXT_INTEGRITY_HASH_ALG);
// Add fingerprint size, which is the same as sequence size
*value += sizeof(UINT64);
// Add SESSION structure size
*value += sizeof(SESSION);
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 = 0;
break;
case TPM_PT_PS_LEVEL:
// level of the platform-specific specification
*value = 0;
break;
case TPM_PT_PS_REVISION:
// specification Revision times 100 for the platform-specific
// specification
*value = 0;
break;
case TPM_PT_PS_DAY_OF_YEAR:
// platform-specific specification day of year using TCG calendar
*value = 0;
break;
case TPM_PT_PS_YEAR:
// platform-specific specification year using the CE
*value = 0;
break;
case TPM_PT_SPLIT_MAX:
// number of split signing operations supported by the TPM
*value = 0;
#ifdef TPM_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.
{
UINT32 i;
*value = 0;
// calculate implemented command numbers
for(i = TPM_CC_FIRST; i <= TPM_CC_LAST; i++)
{
if(CommandIsImplemented(i)) (*value)++;
}
break;
}
case TPM_PT_LIBRARY_COMMANDS:
// number of commands from the TPM library that are implemented
{
UINT32 i;
*value = 0;
// calculate implemented command numbers
for(i = TPM_CC_FIRST; i <= TPM_CC_LAST; i++)
{
if(CommandIsImplemented(i)) (*value)++;
}
break;
}
case TPM_PT_VENDOR_COMMANDS:
// number of vendor commands that are implemented
*value = 0;
break;
case TPM_PT_PERMANENT:
// TPMA_PERMANENT
{
TPMA_PERMANENT flags = {0};
if(gp.ownerAuth.t.size != 0)
flags.ownerAuthSet = SET;
if(gp.endorsementAuth.t.size != 0)
flags.endorsementAuthSet = SET;
if(gp.lockoutAuth.t.size != 0)
flags.lockoutAuthSet = SET;
if(gp.disableClear)
flags.disableClear = SET;
if(gp.failedTries >= gp.maxTries)
flags.inLockout = SET;
// In this implementation, EPS is always generated by TPM
flags.tpmGeneratedEPS = SET;
// Note: Different compilers may require a different method to cast
// a bit field structure to a UINT32.
memcpy(value, &flags, sizeof(UINT32));
break;
}
case TPM_PT_STARTUP_CLEAR:
// TPMA_STARTUP_CLEAR
{
TPMA_STARTUP_CLEAR flags = {0};
if(g_phEnable)
flags.phEnable = SET;
if(gc.shEnable)
flags.shEnable = SET;
if(gc.ehEnable)
flags.ehEnable = SET;
if(gc.phEnableNV)
flags.phEnableNV = SET;
if(g_prevOrderlyState != SHUTDOWN_NONE)
flags.orderly = SET;
// Note: Different compilers may require a different method to cast
// a bit field structure to a UINT32.
memcpy(value, &flags, sizeof(UINT32));
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:
#ifdef TPM_ALG_ECC
// number of loaded ECC curves
*value = CryptCapGetEccCurveNumber();
#else // TPM_ALG_ECC
*value = 0;
#endif // TPM_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_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;
}
//
//
// 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 Value 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
// propertie
TPML_TAGGED_TPM_PROPERTY *propertyList // OUT: property list
)
{
TPMI_YES_NO more = NO;
UINT32 i;
// 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;
// Scan through the TPM properties of the requested group.
// The size of TPM property group is PT_GROUP * 2 for fix and
// variable groups.
for(i = property; i <= PT_FIXED + PT_GROUP * 2; i++)
{
UINT32 value;
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;
}