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|
/*
* This file is part of the coreboot project.
*
* Copyright (C) 2012 Advanced Micro Devices, Inc.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; version 2 of the License.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
/*----------------------------------------------------------------------------------------
* M O D U L E S U S E D
*----------------------------------------------------------------------------------------
*/
#include <stdint.h>
#include <string.h>
#include <cpu/x86/mtrr.h>
#include "agesawrapper.h"
#include "BiosCallOuts.h"
#include "cpuRegisters.h"
#include "cpuCacheInit.h"
#include "cpuApicUtilities.h"
#include "cpuEarlyInit.h"
#include "cpuLateInit.h"
#include "Dispatcher.h"
#include "cpuCacheInit.h"
#include "amdlib.h"
#include "heapManager.h"
#include "Filecode.h"
#include <arch/io.h>
#define FILECODE UNASSIGNED_FILE_FILECODE
/*----------------------------------------------------------------------------------------
* D E F I N I T I O N S A N D M A C R O S
*----------------------------------------------------------------------------------------
*/
/* ACPI table pointers returned by AmdInitLate */
VOID *DmiTable = NULL;
VOID *AcpiPstate = NULL;
VOID *AcpiSrat = NULL;
VOID *AcpiSlit = NULL;
VOID *AcpiWheaMce = NULL;
VOID *AcpiWheaCmc = NULL;
VOID *AcpiAlib = NULL;
/*----------------------------------------------------------------------------------------
* T Y P E D E F S A N D S T R U C T U R E S
*----------------------------------------------------------------------------------------
*/
/*----------------------------------------------------------------------------------------
* P R O T O T Y P E S O F L O C A L F U N C T I O N S
*----------------------------------------------------------------------------------------
*/
/*----------------------------------------------------------------------------------------
* E X P O R T E D F U N C T I O N S
*----------------------------------------------------------------------------------------
*/
/*---------------------------------------------------------------------------------------
* L O C A L F U N C T I O N S
*---------------------------------------------------------------------------------------
*/
extern VOID OemCustomizeInitEarly(IN OUT AMD_EARLY_PARAMS *InitEarly);
extern VOID OemCustomizeInitPost(IN AMD_POST_PARAMS *InitPost);
/*Get the Bus Number from CONFIG_MMCONF_BUS_NUMBER, Please reference AMD BIOS BKDG docuemt about it*/
/*
BusRange: bus range identifier. Read-write. Reset: X. This specifies the number of buses in the
MMIO configuration space range. The size of the MMIO configuration space range varies with this
field as follows: the size is 1 Mbyte times the number of buses. This field is encoded as follows:
Bits Buses Bits Buses
0h 1 5h 32
1h 2 6h 64
2h 4 7h 128
3h 8 8h 256
4h 16 Fh-9h Reserved
*/
STATIC
UINT8
GetEndBusNum (
VOID
)
{
UINT64 BusNum;
UINT8 Index;
for (Index = 1; Index <= 8; Index ++ ) {
BusNum = CONFIG_MMCONF_BUS_NUMBER >> Index;
if (BusNum == 1 ) {
break;
}
}
return Index;
}
static UINT32 amdinitcpuio(VOID)
{
AGESA_STATUS Status;
UINT64 MsrReg;
UINT32 PciData;
PCI_ADDR PciAddress;
AMD_CONFIG_PARAMS StdHeader;
UINT32 TopMem;
UINT32 NodeCnt;
UINT32 Node;
UINT32 SbLink;
UINT32 Index;
/* get the number of coherent nodes in the system */
PciAddress.AddressValue = MAKE_SBDFO(0, 0, 0x18, 0, 0x60);
LibAmdPciRead(AccessWidth32, PciAddress, &PciData, &StdHeader);
NodeCnt = ((PciData >> 4) & 7) + 1; //NodeCnt[6:4]
/* Find out the Link ID of Node0 that connects to the
* Southbridge (system IO hub). e.g. family10 MCM Processor,
* SbLink is Processor0 Link2, internal Node0 Link3
*/
PciAddress.AddressValue = MAKE_SBDFO(0, 0, 0x18, 0, 0x64);
LibAmdPciRead(AccessWidth32, PciAddress, &PciData, &StdHeader);
SbLink = (PciData >> 8) & 3; //assume ganged
/* Enable MMIO on AMD CPU Address Map Controller for all nodes */
for (Node = 0; Node < NodeCnt; Node ++) {
/* clear all MMIO Mapped Base/Limit Registers */
for (Index = 0; Index < 8; Index ++) {
PciData = 0x00000000;
PciAddress.AddressValue = MAKE_SBDFO(0, 0, 0x18 + Node, 1, 0x80 + Index * 8);
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
PciAddress.AddressValue = MAKE_SBDFO(0, 0, 0x18 + Node, 1, 0x84 + Index * 8);
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
}
/* clear all IO Space Base/Limit Registers */
for (Index = 0; Index < 4; Index ++) {
PciData = 0x00000000;
PciAddress.AddressValue = MAKE_SBDFO(0, 0, 0x18 + Node, 1, 0xC0 + Index * 8);
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
PciAddress.AddressValue = MAKE_SBDFO(0, 0, 0x18 + Node, 1, 0xC4 + Index * 8);
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
}
/* Enable MMIO on AMD CPU Address Map Controller */
/* Set VGA Ram MMIO 0000A0000-0000BFFFF to Node0 sbLink */
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0x80);
PciData = (0xA0000 >> 8) |3;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0x84);
PciData = 0xB0000 >> 8;
PciData &= (~0xFF);
PciData |= SbLink << 4;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
/* Set UMA MMIO. */
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0x88);
LibAmdMsrRead (0xC001001A, &MsrReg, &StdHeader);
TopMem = (UINT32)MsrReg;
MsrReg = (MsrReg >> 8) | 3;
PciData = (UINT32)MsrReg;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0x8c);
if (TopMem <= CONFIG_MMCONF_BASE_ADDRESS) {
PciData = (CONFIG_MMCONF_BASE_ADDRESS - 1) >> 8;
}
else {
PciData = (0x100000000ull - 1) >> 8;
}
PciData &= (~0xFF);
PciData |= SbLink << 4;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
/* Set PCIE MMIO. */
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0x90);
PciData = (CONFIG_MMCONF_BASE_ADDRESS >> 8) |3;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0x94);
PciData = (( CONFIG_MMCONF_BASE_ADDRESS + CONFIG_MMCONF_BUS_NUMBER * 4096 *256 - 1) >> 8) & (~0xFF);
PciData &= (~0xFF);
PciData |= MMIO_NP_BIT;
PciData |= SbLink << 4;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
/* Set XAPIC MMIO. 24K */
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0x98);
PciData = (0xFEC00000 >> 8) |3;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0x9c);
PciData = ((0xFEC00000 + 6 * 4096 - 1) >> 8);
PciData &= (~0xFF);
PciData |= MMIO_NP_BIT;
PciData |= SbLink << 4;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
/* Set Local APIC MMIO. 4K*4= 16K, Llano CPU are 4 cores */
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0xA0);
PciData = (0xFEE00000 >> 8) |3;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0xA8);
PciData = (0xFEE00000 + 4 * 4096 - 1) >> 8;
PciData &= (~0xFF);
PciData |= MMIO_NP_BIT;
PciData |= SbLink << 4;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
/* Set PCIO: 0x0 - 0xFFF000 and enabled VGA IO*/
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0xC0);
PciData = 0x13;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18 + Node, 1, 0xC4);
PciData = 0x00FFF000;
PciData &= (~0x7F);
PciData |= SbLink << 4;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
}
Status = AGESA_SUCCESS;
return (UINT32)Status;
}
UINT32
agesawrapper_amdinitmmio (
VOID
)
{
AGESA_STATUS Status;
UINT64 MsrReg;
UINT32 PciData;
PCI_ADDR PciAddress;
AMD_CONFIG_PARAMS StdHeader;
/*
Set the MMIO Configuration Base Address and Bus Range onto MMIO configuration base
Address MSR register.
*/
MsrReg = CONFIG_MMCONF_BASE_ADDRESS | (GetEndBusNum () << 2) | 1;
LibAmdMsrWrite (0xC0010058, &MsrReg, &StdHeader);
/*
Set the NB_CFG MSR register. Enable CF8 extended configuration cycles.
*/
LibAmdMsrRead (0xC001001F, &MsrReg, &StdHeader);
MsrReg = MsrReg | BIT46;
LibAmdMsrWrite (0xC001001F, &MsrReg, &StdHeader);
/* Set PCIE MMIO. */
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18, 1, 0x90);
PciData = (CONFIG_MMCONF_BASE_ADDRESS >> 8) |3;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0x18, 1, 0x94);
PciData = (( CONFIG_MMCONF_BASE_ADDRESS + CONFIG_MMCONF_BUS_NUMBER * 4096 *256 - 1) >> 8) | MMIO_NP_BIT;
LibAmdPciWrite(AccessWidth32, PciAddress, &PciData, &StdHeader);
/* Enable memory access */
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0, 0, 0x04);
LibAmdPciRead(AccessWidth8, PciAddress, &PciData, &StdHeader);
PciData |= BIT1;
PciAddress.AddressValue = MAKE_SBDFO (0, 0, 0, 0, 0x04);
LibAmdPciWrite(AccessWidth8, PciAddress, &PciData, &StdHeader);
/* Set ROM cache onto WP to decrease post time */
MsrReg = (0x0100000000 - CACHE_ROM_SIZE) | 5;
LibAmdMsrWrite (0x20E, &MsrReg, &StdHeader);
MsrReg = ((1ULL << CONFIG_CPU_ADDR_BITS) - CACHE_ROM_SIZE) | 0x800ull;
LibAmdMsrWrite (0x20F, &MsrReg, &StdHeader);
Status = AGESA_SUCCESS;
return (UINT32)Status;
}
UINT32
agesawrapper_amdinitreset (
VOID
)
{
AGESA_STATUS status;
#if (defined AGESA_ENTRY_INIT_RESET) && (AGESA_ENTRY_INIT_RESET == TRUE)
AMD_INTERFACE_PARAMS AmdParamStruct;
AMD_RESET_PARAMS AmdResetParams;
#endif
#if (defined AGESA_ENTRY_INIT_RESET) && (AGESA_ENTRY_INIT_RESET == TRUE)
LibAmdMemFill (&AmdParamStruct,
0,
sizeof (AMD_INTERFACE_PARAMS),
&(AmdParamStruct.StdHeader));
LibAmdMemFill (&AmdResetParams,
0,
sizeof (AMD_RESET_PARAMS),
&(AmdResetParams.StdHeader));
AmdParamStruct.AgesaFunctionName = AMD_INIT_RESET;
AmdParamStruct.AllocationMethod = ByHost;
AmdParamStruct.NewStructSize = sizeof(AMD_RESET_PARAMS);
AmdParamStruct.NewStructPtr = &AmdResetParams;
AmdParamStruct.StdHeader.AltImageBasePtr = 0;
AmdParamStruct.StdHeader.CalloutPtr = NULL;
AmdParamStruct.StdHeader.Func = 0;
AmdParamStruct.StdHeader.ImageBasePtr = 0;
AmdCreateStruct (&AmdParamStruct);
AmdResetParams.HtConfig.Depth = 0;
status = AmdInitReset ((AMD_RESET_PARAMS *)AmdParamStruct.NewStructPtr);
if (status != AGESA_SUCCESS) agesawrapper_amdreadeventlog();
AmdReleaseStruct (&AmdParamStruct);
#else
status = AGESA_SUCCESS;
#endif
return (UINT32)status;
}
UINT32
agesawrapper_amdinitearly (
VOID
)
{
AGESA_STATUS status;
AMD_INTERFACE_PARAMS AmdParamStruct;
AMD_EARLY_PARAMS *AmdEarlyParamsPtr;
LibAmdMemFill (&AmdParamStruct,
0,
sizeof (AMD_INTERFACE_PARAMS),
&(AmdParamStruct.StdHeader));
AmdParamStruct.AgesaFunctionName = AMD_INIT_EARLY;
AmdParamStruct.AllocationMethod = PreMemHeap;
AmdParamStruct.StdHeader.AltImageBasePtr = 0;
AmdParamStruct.StdHeader.CalloutPtr = (CALLOUT_ENTRY) &GetBiosCallout;
AmdParamStruct.StdHeader.Func = 0;
AmdParamStruct.StdHeader.ImageBasePtr = 0;
AmdCreateStruct (&AmdParamStruct);
AmdEarlyParamsPtr = (AMD_EARLY_PARAMS *)AmdParamStruct.NewStructPtr;
OemCustomizeInitEarly (AmdEarlyParamsPtr);
status = AmdInitEarly ((AMD_EARLY_PARAMS *)AmdParamStruct.NewStructPtr);
if (status != AGESA_SUCCESS) agesawrapper_amdreadeventlog();
AmdReleaseStruct (&AmdParamStruct);
return (UINT32)status;
}
/*---------------------------------------------------------------------------------------*/
/**
* OemCustomizeInitEarly
*
* Description:
* This stub function will call the host environment through the binary block
* interface (call-out port) to provide a user hook opportunity
*
* Parameters:
* @param[in] **PeiServices
* @param[in] *InitEarly
*
* @retval VOID
*
**/
/*---------------------------------------------------------------------------------------*/
VOID OemCustomizeInitEarly(IN OUT AMD_EARLY_PARAMS *InitEarly)
{
//InitEarly->PlatformConfig.CoreLevelingMode = CORE_LEVEL_TWO;
}
VOID
OemCustomizeInitPost (
IN AMD_POST_PARAMS *InitPost
)
{
InitPost->MemConfig.UmaMode = UMA_AUTO;
InitPost->MemConfig.BottomIo = 0xE0;
InitPost->MemConfig.UmaSize = 0xE0-0xC0;
}
UINT32
agesawrapper_amdinitpost (
VOID
)
{
AGESA_STATUS status;
AMD_INTERFACE_PARAMS AmdParamStruct;
LibAmdMemFill (&AmdParamStruct,
0,
sizeof (AMD_INTERFACE_PARAMS),
&(AmdParamStruct.StdHeader));
AmdParamStruct.AgesaFunctionName = AMD_INIT_POST;
AmdParamStruct.AllocationMethod = PreMemHeap;
AmdParamStruct.StdHeader.AltImageBasePtr = 0;
AmdParamStruct.StdHeader.CalloutPtr = (CALLOUT_ENTRY) &GetBiosCallout;
AmdParamStruct.StdHeader.Func = 0;
AmdParamStruct.StdHeader.ImageBasePtr = 0;
AmdCreateStruct (&AmdParamStruct);
/* OEM Should Customize the defaults through this hook */
OemCustomizeInitPost ((AMD_POST_PARAMS *)AmdParamStruct.NewStructPtr);
status = AmdInitPost ((AMD_POST_PARAMS *)AmdParamStruct.NewStructPtr);
if (status != AGESA_SUCCESS) agesawrapper_amdreadeventlog();
AmdReleaseStruct (&AmdParamStruct);
/* Initialize heap space */
EmptyHeap();
return (UINT32)status;
}
UINT32
agesawrapper_amdinitenv (
VOID
)
{
AGESA_STATUS status;
AMD_INTERFACE_PARAMS AmdParamStruct;
LibAmdMemFill (&AmdParamStruct,
0,
sizeof (AMD_INTERFACE_PARAMS),
&(AmdParamStruct.StdHeader));
AmdParamStruct.AgesaFunctionName = AMD_INIT_ENV;
AmdParamStruct.AllocationMethod = PostMemDram;
AmdParamStruct.StdHeader.AltImageBasePtr = 0;
AmdParamStruct.StdHeader.CalloutPtr = (CALLOUT_ENTRY) &GetBiosCallout;
AmdParamStruct.StdHeader.Func = 0;
AmdParamStruct.StdHeader.ImageBasePtr = 0;
AmdCreateStruct (&AmdParamStruct);
status = AmdInitEnv ((AMD_ENV_PARAMS *)AmdParamStruct.NewStructPtr);
if (status != AGESA_SUCCESS) agesawrapper_amdreadeventlog();
AmdReleaseStruct (&AmdParamStruct);
return (UINT32)status;
}
VOID *
agesawrapper_getlateinitptr (
int pick
)
{
switch (pick) {
case PICK_DMI:
return DmiTable;
case PICK_PSTATE:
return AcpiPstate;
case PICK_SRAT:
return AcpiSrat;
case PICK_SLIT:
return AcpiSlit;
case PICK_WHEA_MCE:
return AcpiWheaMce;
case PICK_WHEA_CMC:
return AcpiWheaCmc;
case PICK_ALIB:
return AcpiAlib;
default:
return NULL;
}
}
UINT32
agesawrapper_amdinitmid (
VOID
)
{
AGESA_STATUS status;
AMD_INTERFACE_PARAMS AmdParamStruct;
printk(BIOS_DEBUG, "file '%s',line %d, %s()\n", __FILE__, __LINE__, __func__);
/* Enable MMIO on AMD CPU Address Map Controller */
amdinitcpuio ();
LibAmdMemFill (&AmdParamStruct,
0,
sizeof (AMD_INTERFACE_PARAMS),
&(AmdParamStruct.StdHeader));
AmdParamStruct.AgesaFunctionName = AMD_INIT_MID;
AmdParamStruct.AllocationMethod = PostMemDram;
AmdParamStruct.StdHeader.AltImageBasePtr = 0;
AmdParamStruct.StdHeader.CalloutPtr = (CALLOUT_ENTRY) &GetBiosCallout;
AmdParamStruct.StdHeader.Func = 0;
AmdParamStruct.StdHeader.ImageBasePtr = 0;
AmdCreateStruct (&AmdParamStruct);
status = AmdInitMid ((AMD_MID_PARAMS *)AmdParamStruct.NewStructPtr);
if (status != AGESA_SUCCESS) agesawrapper_amdreadeventlog();
AmdReleaseStruct (&AmdParamStruct);
return (UINT32)status;
}
UINT32
agesawrapper_amdinitlate(VOID)
{
AGESA_STATUS Status;
AMD_INTERFACE_PARAMS AmdParamStruct;
AMD_LATE_PARAMS *AmdLateParamsPtr;
LibAmdMemFill(&AmdParamStruct,
0,
sizeof (AMD_INTERFACE_PARAMS),
&(AmdParamStruct.StdHeader));
AmdParamStruct.AgesaFunctionName = AMD_INIT_LATE;
AmdParamStruct.AllocationMethod = PostMemDram;
AmdParamStruct.StdHeader.AltImageBasePtr = 0;
AmdParamStruct.StdHeader.CalloutPtr = (CALLOUT_ENTRY) &GetBiosCallout;
AmdParamStruct.StdHeader.Func = 0;
AmdParamStruct.StdHeader.ImageBasePtr = 0;
AmdParamStruct.StdHeader.HeapStatus = HEAP_SYSTEM_MEM;
AmdCreateStruct (&AmdParamStruct);
AmdLateParamsPtr = (AMD_LATE_PARAMS *) AmdParamStruct.NewStructPtr;
printk(BIOS_DEBUG, "agesawrapper_amdinitlate: AmdLateParamsPtr = %X\n", (u32)AmdLateParamsPtr);
Status = AmdInitLate(AmdLateParamsPtr);
if (Status != AGESA_SUCCESS) {
//agesawrapper_amdreadeventlog(AmdLateParamsPtr->StdHeader.HeapStatus);
agesawrapper_amdreadeventlog();
ASSERT(Status == AGESA_SUCCESS);
}
DmiTable = AmdLateParamsPtr->DmiTable;
AcpiPstate = AmdLateParamsPtr->AcpiPState;
AcpiSrat = AmdLateParamsPtr->AcpiSrat;
AcpiSlit = AmdLateParamsPtr->AcpiSlit;
AcpiWheaMce = AmdLateParamsPtr->AcpiWheaMce;
AcpiWheaCmc = AmdLateParamsPtr->AcpiWheaCmc;
AcpiAlib = AmdLateParamsPtr->AcpiAlib;
printk(BIOS_DEBUG, "In %s, AGESA generated ACPI tables:\n"
" DmiTable:%p\n AcpiPstate: %p\n AcpiSrat:%p\n AcpiSlit:%p\n"
" Mce:%p\n Cmc:%p\n Alib:%p\n",
__func__, DmiTable, AcpiPstate, AcpiSrat, AcpiSlit,
AcpiWheaMce, AcpiWheaCmc, AcpiAlib);
/* Don't release the structure until coreboot has copied the ACPI tables.
* AmdReleaseStruct (&AmdLateParams);
*/
return (UINT32)Status;
}
UINT32 agesawrapper_amdlaterunaptask (UINT32 Func, UINT32 Data, VOID *ConfigPtr)
{
AGESA_STATUS Status;
AP_EXE_PARAMS AmdLateParams;
LibAmdMemFill (&AmdLateParams,
0,
sizeof (AP_EXE_PARAMS),
&(AmdLateParams.StdHeader));
AmdLateParams.StdHeader.AltImageBasePtr = 0;
AmdLateParams.StdHeader.CalloutPtr = (CALLOUT_ENTRY) &GetBiosCallout;
AmdLateParams.StdHeader.Func = 0;
AmdLateParams.StdHeader.ImageBasePtr = 0;
Status = AmdLateRunApTask (&AmdLateParams);
if (Status != AGESA_SUCCESS) {
agesawrapper_amdreadeventlog();
ASSERT(Status == AGESA_SUCCESS);
}
return (UINT32)Status;
}
UINT32
agesawrapper_amdreadeventlog (
VOID
)
{
AGESA_STATUS Status;
EVENT_PARAMS AmdEventParams;
LibAmdMemFill (&AmdEventParams,
0,
sizeof (EVENT_PARAMS),
&(AmdEventParams.StdHeader));
AmdEventParams.StdHeader.AltImageBasePtr = 0;
AmdEventParams.StdHeader.CalloutPtr = NULL;
AmdEventParams.StdHeader.Func = 0;
AmdEventParams.StdHeader.ImageBasePtr = 0;
Status = AmdReadEventLog (&AmdEventParams);
while (AmdEventParams.EventClass != 0) {
printk(BIOS_DEBUG,"\nEventLog: EventClass = %x, EventInfo = %x.\n",AmdEventParams.EventClass,AmdEventParams.EventInfo);
printk(BIOS_DEBUG," Param1 = %x, Param2 = %x.\n",AmdEventParams.DataParam1,AmdEventParams.DataParam2);
printk(BIOS_DEBUG," Param3 = %x, Param4 = %x.\n",AmdEventParams.DataParam3,AmdEventParams.DataParam4);
Status = AmdReadEventLog (&AmdEventParams);
}
return (UINT32)Status;
}
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