431 lines
12 KiB
C
431 lines
12 KiB
C
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/*++
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Copyright (c) 2000 Intel Corporation
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Module Name:
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guidgen.c
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Abstract:
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Add the GUID generator logic for the EFI 1.0 Disk Utilities.
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Revision History
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** Intel 2000 Update for EFI 1.0
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** Copyright (c) 1990- 1993, 1996 Open Software Foundation, Inc.
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** Copyright (c) 1989 by Hewlett-Packard Company, Palo Alto, Ca. &
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** Digital Equipment Corporation, Maynard, Mass.
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** To anyone who acknowledges that this file is provided <EFBFBD>AS IS<EFBFBD>
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** without any express or implied warranty: permission to use, copy,
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** modify, and distribute this file for any purpose is hereby
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** granted without fee, provided that the above copyright notices and
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** this notice appears in all source code copies, and that none of
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** the names of Open Software Foundation, Inc., Hewlett-Packard
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** Company, or Digital Equipment Corporation be used in advertising
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** or publicity pertaining to distribution of the software without
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** specific, written prior permission. Neither Open Software
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** Foundation, Inc., Hewlett-Packard Company, nor Digital Equipment
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** Corporation makes any representations about the suitability of
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** this software for any purpose.
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*/
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#include "efi.h"
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#include "efilib.h"
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#include "md5.h"
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//#define NONVOLATILE_CLOCK
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extern EFI_HANDLE SavedImageHandle;
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extern EFI_HANDLE *DiskHandleList;
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extern INTN DiskHandleCount;
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#define CLOCK_SEQ_LAST 0x3FFF
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#define RAND_MASK CLOCK_SEQ_LAST
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typedef struct _uuid_t {
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UINT32 time_low;
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UINT16 time_mid;
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UINT16 time_hi_and_version;
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UINT8 clock_seq_hi_and_reserved;
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UINT8 clock_seq_low;
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UINT8 node[6];
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} uuid_t;
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typedef struct {
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UINT32 lo;
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UINT32 hi;
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} unsigned64_t;
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/*
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** Add two unsigned 64-bit long integers.
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*/
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#define ADD_64b_2_64b(A, B, sum) \
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{ \
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if (!(((A)->lo & 0x80000000UL) ^ ((B)->lo & 0x80000000UL))) { \
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if (((A)->lo&0x80000000UL)) { \
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(sum)->lo = (A)->lo + (B)->lo; \
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(sum)->hi = (A)->hi + (B)->hi + 1; \
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} \
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else { \
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(sum)->lo = (A)->lo + (B)->lo; \
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(sum)->hi = (A)->hi + (B)->hi; \
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} \
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} \
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else { \
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(sum)->lo = (A)->lo + (B)->lo; \
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(sum)->hi = (A)->hi + (B)->hi; \
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if (!((sum)->lo&0x80000000UL)) (sum)->hi++; \
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} \
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}
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/*
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** Add a 16-bit unsigned integer to a 64-bit unsigned integer.
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*/
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#define ADD_16b_2_64b(A, B, sum) \
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{ \
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(sum)->hi = (B)->hi; \
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if ((B)->lo & 0x80000000UL) { \
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(sum)->lo = (*A) + (B)->lo; \
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if (!((sum)->lo & 0x80000000UL)) (sum)->hi++; \
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} \
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else \
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(sum)->lo = (*A) + (B)->lo; \
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}
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/*
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** Global variables.
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*/
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static unsigned64_t time_last;
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static UINT16 clock_seq;
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VOID
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GetIeeeNodeIdentifier(
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UINT8 MacAddress[]
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)
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// Use the Device Path for the NIC to provide a MAC address
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{
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UINTN NoHandles, Index;
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EFI_HANDLE *Handles;
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EFI_HANDLE Handle;
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EFI_DEVICE_PATH *DevPathNode, *DevicePath;
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MAC_ADDR_DEVICE_PATH *SourceMacAddress;
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UINT8 *Anchor;
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EFI_MEMORY_DESCRIPTOR *Desc, *MemMap;
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UINTN DescriptorSize;
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UINT32 DescriptorVersion;
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UINTN NoDesc, MapKey;
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UINT8 *pDataBuf;
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UINT32 cData;
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EFI_TIME Time;
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EFI_STATUS Status;
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Status = EFI_SUCCESS;
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//
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// Find all Device Paths
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//
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LibLocateHandle (ByProtocol, &DevicePathProtocol, NULL, &NoHandles, &Handles);
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for (Index=0; Index < NoHandles; Index++) {
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Handle = Handles[Index];
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DevicePath = DevicePathFromHandle (Handle);
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//
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// Process each device path node
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//
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DevPathNode = DevicePath;
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while (!IsDevicePathEnd(DevPathNode)) {
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//
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// Find the handler to dump this device path node
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//
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if (DevicePathType(DevPathNode) == MESSAGING_DEVICE_PATH &&
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DevicePathSubType(DevPathNode) == MSG_MAC_ADDR_DP) {
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SourceMacAddress = (MAC_ADDR_DEVICE_PATH *) DevPathNode;
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if (SourceMacAddress->IfType == 0x01 || SourceMacAddress->IfType == 0x00) {
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CopyMem(&MacAddress[0], &SourceMacAddress->MacAddress, sizeof(UINT8) * 6);
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return;
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}
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}
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DevPathNode = NextDevicePathNode(DevPathNode);
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}
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}
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//
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// Arriving here means that there is not an SNP-compliant
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// device in the system. Use the MD5 1-way hash function to
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// generate the node address
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//
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MemMap = LibMemoryMap (&NoDesc, &MapKey, &DescriptorSize, &DescriptorVersion);
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if (!MemMap) {
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Print (L"Memory map was not returned\n");
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} else {
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pDataBuf = AllocatePool (NoDesc * DescriptorSize +
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DiskHandleCount * sizeof(EFI_HANDLE) + sizeof(EFI_TIME));
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ASSERT (pDataBuf != NULL);
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Anchor = pDataBuf;
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Desc = MemMap;
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cData = 0;
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if (NoDesc != 0) {
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while (NoDesc --) {
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CopyMem(pDataBuf, Desc, DescriptorSize);
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Desc ++;
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pDataBuf += DescriptorSize;
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cData += (UINT32)DescriptorSize;
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}
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}
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//
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// Also copy in the handles of the Disks
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//
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if (DiskHandleCount != 0) {
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Index = DiskHandleCount;
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while (Index --) {
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CopyMem(pDataBuf, &DiskHandleList [Index], sizeof (EFI_HANDLE));
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pDataBuf += sizeof(EFI_HANDLE);
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cData += sizeof(EFI_HANDLE);
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}
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}
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Status = RT->GetTime(&Time,NULL);
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if (!EFI_ERROR(Status)) {
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CopyMem(pDataBuf, &Time, sizeof(EFI_TIME));
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pDataBuf += sizeof(EFI_TIME);
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cData += sizeof (EFI_TIME);
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}
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GenNodeID(Anchor, cData, &MacAddress[0]);
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FreePool(Anchor);
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FreePool(MemMap);
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return;
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}
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// Just case fall through
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ZeroMem(MacAddress, 6 * sizeof (UINT8));
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return;
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}
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static VOID
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mult32(UINT32 u, UINT32 v, unsigned64_t *result)
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{
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/* Following the notation in Knuth, Vol. 2. */
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UINT32 uuid1, uuid2, v1, v2, temp;
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uuid1 = u >> 16;
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uuid2 = u & 0xFFFF;
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v1 = v >> 16;
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v2 = v & 0xFFFF;
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temp = uuid2 * v2;
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result->lo = temp & 0xFFFF;
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temp = uuid1 * v2 + (temp >> 16);
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result->hi = temp >> 16;
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temp = uuid2 * v1 + (temp & 0xFFFF);
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result->lo += (temp & 0xFFFF) << 16;
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result->hi += uuid1 * v1 + (temp >> 16);
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}
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static VOID
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GetSystemTime(unsigned64_t *uuid_time)
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{
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// struct timeval tp;
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EFI_TIME Time;
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EFI_STATUS Status;
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unsigned64_t utc, usecs, os_basetime_diff;
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EFI_TIME_CAPABILITIES TimeCapabilities;
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UINTN DeadCount;
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UINT8 Second;
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DeadCount = 0;
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// gettimeofday(&tp, (struct timezone *)0);
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Status = RT->GetTime(&Time,&TimeCapabilities);
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Second = Time.Second;
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//
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// If the time resolution is 1Hz, then spin until a
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// second transition. This will at least make the
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// "0 nanoseconds" value appear correct inasmuch as
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// multiple reads within 1 second are prohibited and
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// the exit on roll-over really implies that the
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// nanoseconds field "would have" rolled to zero in
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// a more robust time keeper.
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//
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//
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if (TimeCapabilities.Resolution == 1) {
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while (Time.Second == Second) {
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Second = Time.Second;
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Status = RT->GetTime(&Time, NULL);
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if (DeadCount++ == 0x1000000) {
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break;
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}
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}
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}
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mult32(Time.Second, 10000000, &utc);
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mult32(Time.Nanosecond, 10, &usecs);
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ADD_64b_2_64b(&usecs, &utc, &utc);
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/* Offset between UUID formatted times and Unix formatted times.
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* UUID UTC base time is October 15, 1582.
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* Unix base time is January 1, 1970. */
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os_basetime_diff.lo = 0x13814000;
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os_basetime_diff.hi = 0x01B21DD2;
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ADD_64b_2_64b(&utc, &os_basetime_diff, uuid_time);
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}
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UINT32
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getpid() {
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UINT64 FakePidValue;
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BS->GetNextMonotonicCount(&FakePidValue);
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//FakePidValue = 0; //(UINT32) ((UINT32)FakePidValue + (UINT32) SavedImageHandle);
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FakePidValue = (UINT32) ((UINT32)FakePidValue + (UINT32) (UINT64) SavedImageHandle);
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return ((UINT32)FakePidValue);
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}
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/*
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** See <EFBFBD>The Multiple Prime Random Number Generator<EFBFBD> by Alexander
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** Hass pp. 368-381, ACM Transactions on Mathematical Software,
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** 12/87.
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*/
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static UINT32 rand_m;
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static UINT32 rand_ia;
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static UINT32 rand_ib;
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static UINT32 rand_irand;
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static VOID
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TrueRandomInit(VOID)
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{
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unsigned64_t t;
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EFI_TIME Time;
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EFI_STATUS Status;
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UINT16 seed;
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/* Generating our 'seed' value Start with the current time, but,
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* since the resolution of clocks is system hardware dependent
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and
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* most likely coarser than our resolution (10 usec) we 'mixup'
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the
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* bits by xor'ing all the bits together. This will have the
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effect
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* of involving all of the bits in the determination of the seed
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* value while remaining system independent. Then for good
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measure
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* to ensure a unique seed when there are multiple processes
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* creating UUIDs on a system, we add in the PID.
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*/
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rand_m = 971;
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rand_ia = 11113;
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rand_ib = 104322;
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rand_irand = 4181;
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// GetSystemTime(&t);
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Status = RT->GetTime(&Time,NULL);
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t.lo = Time.Nanosecond;
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t.hi = (Time.Hour << 16) | Time.Second;
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seed = (UINT16) (t.lo & 0xFFFF);
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seed ^= (t.lo >> 16) & 0xFFFF;
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seed ^= t.hi & 0xFFFF;
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seed ^= (t.hi >> 16) & 0xFFFF;
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rand_irand += seed + getpid();
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}
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static UINT16
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true_random(VOID)
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{
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if ((rand_m += 7) >= 9973)
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rand_m -= 9871;
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if ((rand_ia += 1907) >= 99991)
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rand_ia -= 89989;
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if ((rand_ib += 73939) >= 224729)
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rand_ib -= 96233;
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rand_irand = (rand_irand * rand_m) + rand_ia + rand_ib;
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return (UINT16) ((rand_irand >> 16) ^ (rand_irand & RAND_MASK));
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}
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/*
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** Startup initialization routine for the UUID module.
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*/
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VOID
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InitGuid(VOID)
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{
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TrueRandomInit();
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GetSystemTime(&time_last);
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#ifdef NONVOLATILE_CLOCK
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clock_seq = read_clock();
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#else
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clock_seq = true_random();
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#endif
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}
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static INTN
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time_cmp(unsigned64_t *time1, unsigned64_t *time2)
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{
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if (time1->hi < time2->hi) return -1;
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if (time1->hi > time2->hi) return 1;
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if (time1->lo < time2->lo) return -1;
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if (time1->lo > time2->lo) return 1;
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return 0;
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}
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static VOID new_clock_seq(VOID)
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{
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clock_seq = (clock_seq + 1) % (CLOCK_SEQ_LAST + 1);
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if (clock_seq == 0) clock_seq = 1;
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#ifdef NONVOLATILE_CLOCK
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write_clock(clock_seq);
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#endif
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}
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VOID CreateGuid(uuid_t *guid)
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{
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static unsigned64_t time_now;
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static UINT16 time_adjust;
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UINT8 eaddr[6];
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INTN got_no_time = 0;
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GetIeeeNodeIdentifier(&eaddr[0]); /* TO BE PROVIDED by EFI device path */
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do {
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GetSystemTime(&time_now);
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switch (time_cmp(&time_now, &time_last)) {
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case -1:
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/* Time went backwards. */
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new_clock_seq();
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time_adjust = 0;
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break;
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case 1:
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time_adjust = 0;
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break;
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default:
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if (time_adjust == 0x7FFF)
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/* We're going too fast for our clock; spin. */
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got_no_time = 1;
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else
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time_adjust++;
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break;
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}
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} while (got_no_time);
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time_last.lo = time_now.lo;
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time_last.hi = time_now.hi;
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if (time_adjust != 0) {
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ADD_16b_2_64b(&time_adjust, &time_now, &time_now);
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}
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/* Construct a guid with the information we've gathered
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* plus a few constants. */
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guid->time_low = time_now.lo;
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guid->time_mid = (UINT16) (time_now.hi & 0x0000FFFF);
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guid->time_hi_and_version = (UINT16) (time_now.hi & 0x0FFF0000) >> 16;
|
|||
|
guid->time_hi_and_version |= (1 << 12);
|
|||
|
guid->clock_seq_low = clock_seq & 0xFF;
|
|||
|
guid->clock_seq_hi_and_reserved = (clock_seq & 0x3F00) >> 8;
|
|||
|
guid->clock_seq_hi_and_reserved |= 0x80;
|
|||
|
CopyMem (guid->node, &eaddr, sizeof guid->node);
|
|||
|
}
|
|||
|
|