Google Git
Sign in
cos / mirrors / cros / chromiumos / third_party / coreboot / 796af17f18554380a49d69d7768ac18ee039d711 / . / src / vendorcode / amd / cimx / sb800 / SBCMN.c
blob: ea1c029d1fced17d44db2f884ca3eb5fc306f7d0 [file] [log] [blame]
/**
* @file
*
* Southbridge Initial routine
*
*
*
* @xrefitem bom "File Content Label" "Release Content"
* @e project: CIMx-SB
* @e sub-project:
* @e \$Revision:$ @e \$Date:$
*
*/
/*
*****************************************************************************
*
* Copyright (c) 2011, Advanced Micro Devices, Inc.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of Advanced Micro Devices, Inc. nor the names of
* its contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL ADVANCED MICRO DEVICES, INC. BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* ***************************************************************************
*
*/
#include "SBPLATFORM.h"
#include "cbtypes.h"
//
// Declaration of local functions
//
VOID abcfgTbl (IN ABTBLENTRY* pABTbl);
/**
* sbUsbPhySetting - USB Phy Calibration Adjustment
*
*
* @param[in] Value Controller PCI config address (bus# + device# + function#)
*
*/
VOID sbUsbPhySetting (IN UINT32 Value);
/*--------------------------- Documentation Pages ---------------------------*/
/**
* @page LegacyInterfaceCalls Legacy Interface Calls
* <TD>@subpage SB_POWERON_INIT_Page "SB_POWERON_INIT"</TD><TD></TD>
* <TD>@subpage SB_BEFORE_PCI_INIT_Page "SB_BEFORE_PCI_INIT"</TD><TD></TD>
* <TD>@subpage SB_AFTER_PCI_INIT_Page "SB_AFTER_PCI_INIT"</TD><TD></TD>
* <TD>@subpage SB_LATE_POST_INIT_Page "SB_LATE_POST_INIT"</TD><TD></TD>
* <TD>@subpage SB_BEFORE_PCI_RESTORE_INIT_Page "SB_BEFORE_PCI_RESTORE_INIT"</TD><TD></TD>
* <TD>@subpage SB_AFTER_PCI_RESTORE_INIT_Page "SB_AFTER_PCI_RESTORE_INIT"</TD><TD></TD>
* <TD>@subpage SB_SMM_SERVICE_Page "SB_SMM_SERVICE"</TD><TD></TD>
* <TD>@subpage SB_SMM_ACPION_Page "SB_SMM_ACPION"</TD><TD></TD>
*
* @page LegacyInterfaceCallOuts Legacy Interface CallOuts
* <TD>@subpage CB_SBGPP_RESET_ASSERT_Page CB_SBGPP_RESET_ASSERT
* <TD>@subpage CB_SBGPP_RESET_DEASSERT_Page CB_SBGPP_RESET_DEASSERT
*
*/
/**
* sbEarlyPostByteInitTable - PCI device registers initial during early POST.
*
*/
const static REG8MASK sbEarlyPostByteInitTable[] =
{
// SMBUS Device (Bus 0, Dev 20, Func 0)
{0x00, SMBUS_BUS_DEV_FUN, 0},
{SB_CFG_REG10, 0X00, (SBCIMx_Version & 0xFF)}, //Program the version information
{SB_CFG_REG11, 0X00, (SBCIMx_Version >> 8)},
{0xFF, 0xFF, 0xFF},
// IDE Device (Bus 0, Dev 20, Func 1)
{0x00, IDE_BUS_DEV_FUN, 0},
{SB_IDE_REG62 + 1, ~BIT0, BIT5}, // Enabling IDE Explicit Pre-Fetch IDE PCI Config 0x62[8]=0
// Allow MSI capability of IDE controller to be visible. IDE PCI Config 0x62[13]=1
{0xFF, 0xFF, 0xFF},
// Azalia Device (Bus 0, Dev 20, Func 2)
{0x00, AZALIA_BUS_DEV_FUN, 0},
{SB_AZ_REG4C, ~BIT0, BIT0},
{0xFF, 0xFF, 0xFF},
// LPC Device (Bus 0, Dev 20, Func 3)
{0x00, LPC_BUS_DEV_FUN, 0},
{SB_LPC_REG40, ~BIT2, BIT2}, // RPR 1.1 Enabling LPC DMA Function 0x40[2]=1b 0x78[0]=0b
{SB_LPC_REG78, ~BIT0, 00}, // RPR 1.1 Enabling LPC DMA Function 0x40[2]=1b 0x78[0]=0b
{SB_LPC_REG78, ~BIT1, 00}, // Disables MSI capability
{SB_LPC_REGBB, ~BIT0, BIT0 + BIT3 + BIT4 + BIT5}, // Enabled SPI Prefetch from HOST.
{0xFF, 0xFF, 0xFF},
// PCIB Bridge (Bus 0, Dev 20, Func 4)
{0x00, PCIB_BUS_DEV_FUN, 0},
{SB_PCIB_REG40, 0xFF, BIT5}, // RPR PCI-bridge Subtractive Decode
{SB_PCIB_REG4B, 0xFF, BIT7}, //
{SB_PCIB_REG66, 0xFF, BIT4}, // RPR Enabling One-Prefetch-Channel Mode, PCIB_PCI_config 0x64 [20]
{SB_PCIB_REG65, 0xFF, BIT7}, // RPR proper operation of CLKRUN#.
{SB_PCIB_REG0D, 0x00, 0x40}, // Setting Latency Timers to 0x40, Enables the PCIB to retain ownership
{SB_PCIB_REG1B, 0x00, 0x40}, // of the bus on the Primary side and on the Secondary side when GNT# is deasserted.
{SB_PCIB_REG66 + 1, 0xFF, BIT1}, // RPR Enable PCI bus GNT3#..
{0xFF, 0xFF, 0xFF},
// SATA Device (Bus 0, Dev 17, Func 0)
{0x00, SATA_BUS_DEV_FUN, 0},
{SB_SATA_REG44, 0xff, BIT0}, // Enables the SATA watchdog timer register prior to the SATA BIOS post
{SB_SATA_REG44 + 2, 0, 0x20}, // RPR 8.12 SATA PCI Watchdog timer setting
// [SB01923] Set timer out to 0x20 to fix IDE to SATA Bridge dropping drive issue.
{0xFF, 0xFF, 0xFF},
};
/**
* sbPmioEPostInitTable - Southbridge ACPI MMIO initial during POST.
*
*/
const static AcpiRegWrite sbPmioEPostInitTable[] =
{
// HPET workaround
{PMIO_BASE >> 8, SB_PMIOA_REG54 + 3, 0xFC, BIT0 + BIT1},
{PMIO_BASE >> 8, SB_PMIOA_REG54 + 2, 0x7F, BIT7},
{PMIO_BASE >> 8, SB_PMIOA_REG54 + 2, 0x7F, 0x00},
// End of HPET workaround
// Enable SB800 A12 ACPI bits at PMIO 0xC0 [30,10:3]
// ClrAllStsInThermalEvent 3 Set to 1 to allow ASF remote power down/power cycle, Thermal event, Fan slow event to clear all the Gevent status and enabled bits. The bit should be set to 1 all the time.
// UsbGoodClkDlyEn 4 Set to 1 to delay de-assertion of Usb clk by 6 Osc clk. The bit should be set to 1 all the time.
// ForceNBCPUPwr 5 Set to 1 to force CPU pwrGood to be toggled along with NB pwrGood.
// MergeUsbPerReq 6 Set to 1 to merge usb perdical traffic into usb request as one of break event.
// IMCWatchDogRstEn 7 Set to 1 to allow IMC watchdog timer to reset entire acpi block. The bit should be set to 1 when IMC is enabled.
// GeventStsFixEn 8 1: Gevent status is not reset by its enable bit. 0: Gevent status is reset by its enable bit.
// PmeTimerFixEn 9 Set to 1 to reset Pme Timer when going to sleep state.
// UserRst2EcEn 10 Set to 1 to route user reset event to Ec. The bit should be set to 1 when IMC is enabled.
// Smbus0ClkSEn 30 Set to 1 to enable SMBus0 controller clock stretch support.
{PMIO_BASE >> 8, SB_PMIOA_REGC4, ~(BIT2 + BIT4), BIT2 + BIT4},
{PMIO_BASE >> 8, SB_PMIOA_REGC0, 0, 0xF9},
// PM_reg xC1 [3] = 1b, per RPR 2.7 CPU PwrGood Setting
{PMIO_BASE >> 8, SB_PMIOA_REGC0 + 1, 0x04, 0x0B},
// RtcSts 19-17 RTC_STS set only in Sleep State.
// GppPme 20 Set to 1 to enable PME request from SB GPP.
// Pcireset 22 Set to 1 to allow SW to reset PCIe.
{PMIO_BASE >> 8, SB_PMIOA_REGC2, 0x20, 0x58},
{PMIO_BASE >> 8, SB_PMIOA_REGC2 + 1, 0, 0x40},
//Item Id: SB02037: RTC_STS should be set in S state
//set PMIO 0xC0 [19:16] Set to 1110 to allow RTC_STS to be set only in non_G0 state.
//{PMIO_BASE >> 8, SB_PMIOA_REGC2, (UINT8)~(0x0F), 0x0E},
//Item Id: SB02034
//Title: SB GPP NIC auto wake at second time sleep
//set PMIO 0xC4 bit 2 to 1 then set PMIO 0xC0 bit 20 to 1 to enable fix for SB02034
{PMIO_BASE >> 8, SB_PMIOA_REGC2, ~(BIT4), BIT4},
//{GPIO_BASE >> 8, SB_GPIO_REG62 , 0x00, 0x4E},
{PMIO_BASE >> 8, SB_PMIOA_REG74, 0x00, BIT0 + BIT1 + BIT2 + BIT4},
{PMIO_BASE >> 8, SB_PMIOA_REGDE + 1, ~(BIT0 + BIT1), BIT0 + BIT1},
{PMIO_BASE >> 8, SB_PMIOA_REGDE, ~BIT4, BIT4},
{PMIO_BASE >> 8, SB_PMIOA_REGBA, ~BIT3, BIT3},
{PMIO_BASE >> 8, SB_PMIOA_REGBA + 1, ~BIT6, BIT6},
{PMIO_BASE >> 8, SB_PMIOA_REGBC, ~BIT1, BIT1},
{PMIO_BASE >> 8, SB_PMIOA_REGED, ~(BIT0 + BIT1), 0},
//RPR Hiding Flash Controller PM_IO 0xDC[7] = 0x0 & PM_IO 0xDC [1:0]=0x01
{PMIO_BASE >> 8, SB_PMIOA_REGDC, 0x7C, BIT0},
// RPR Turning off FC clock
{MISC_BASE >> 8, SB_MISC_REG40 + 1, ~(BIT3 + BIT2), BIT3 + BIT2},
{MISC_BASE >> 8, SB_MISC_REG40 + 2, ~BIT0, BIT0},
{SMI_BASE >> 8, SB_SMI_Gevent0, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent1, 0, 1},
{SMI_BASE >> 8, SB_SMI_Gevent2, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent3, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent4, 0, 4},
{SMI_BASE >> 8, SB_SMI_Gevent5, 0, 5},
{SMI_BASE >> 8, SB_SMI_Gevent6, 0, 6},
{SMI_BASE >> 8, SB_SMI_Gevent7, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent9, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent10, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent11, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent12, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent13, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent14, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent15, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent16, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent17, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent18, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent19, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent20, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent21, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent22, 0, 29},
{SMI_BASE >> 8, SB_SMI_Gevent23, 0, 29},
//
{SMI_BASE >> 8, SB_SMI_Usbwakup0, 0, 11},
{SMI_BASE >> 8, SB_SMI_Usbwakup1, 0, 11},
{SMI_BASE >> 8, SB_SMI_Usbwakup2, 0, 11},
{SMI_BASE >> 8, SB_SMI_Usbwakup3, 0, 11},
{SMI_BASE >> 8, SB_SMI_IMCGevent0, 0, 12},
{SMI_BASE >> 8, SB_SMI_IMCGevent1, 0, 29},
{SMI_BASE >> 8, SB_SMI_FanThGevent, 0, 13},
{SMI_BASE >> 8, SB_SMI_SBGppPme0, 0, 15},
{SMI_BASE >> 8, SB_SMI_SBGppPme1, 0, 16},
{SMI_BASE >> 8, SB_SMI_SBGppPme2, 0, 17},
{SMI_BASE >> 8, SB_SMI_SBGppPme3, 0, 18},
{SMI_BASE >> 8, SB_SMI_SBGppHp0, 0, 29},
{SMI_BASE >> 8, SB_SMI_SBGppHp1, 0, 29},
{SMI_BASE >> 8, SB_SMI_SBGppHp2, 0, 29},
{SMI_BASE >> 8, SB_SMI_SBGppHp3, 0, 29},
{SMI_BASE >> 8, SB_SMI_GecPme, 0, 19},
{SMI_BASE >> 8, SB_SMI_CIRPme, 0, 23},
{SMI_BASE >> 8, SB_SMI_Gevent8, 0, 26},
{SMI_BASE >> 8, SB_SMI_AzaliaPme, 0, 27},
{SMI_BASE >> 8, SB_SMI_SataGevent0, 0, 30},
{SMI_BASE >> 8, SB_SMI_SataGevent1, 0, 31},
{SMI_BASE >> 8, SB_SMI_WakePinGevent, 0, 29},
{SMI_BASE >> 8, SB_SMI_ASFMasterIntr, 0, 29},
{SMI_BASE >> 8, SB_SMI_ASFSlaveIntr, 0, 29},
// {SMI_BASE >> 8, SB_SMI_REG04, ~BIT4, BIT4},
// {SMI_BASE >> 8, SB_SMI_REG04 + 1, ~BIT0, BIT0},
// {SMI_BASE >> 8, SB_SMI_REG04 + 2, ~BIT3, BIT3},
{SMI_BASE >> 8, SB_SMI_REG08, ~BIT4, 0},
{SMI_BASE >> 8, SB_SMI_REG08+3, ~BIT2, 0},
// {SMI_BASE >> 8, SB_SMI_REG0C, ~BIT4, BIT4},
{SMI_BASE >> 8, SB_SMI_REG0C + 2, ~BIT3, BIT3},
{SMI_BASE >> 8, SB_SMI_TWARN, 0, 9},
{SMI_BASE >> 8, SB_SMI_TMI, 0, 29},
{0xFF, 0xFF, 0xFF, 0xFF},
};
/**
* abTblEntry800 - AB-Link Configuration Table for SB800
*
*/
const static ABTBLENTRY abTblEntry800[] =
{
// RPR Enable downstream posted transactions to pass non-posted transactions.
{ABCFG, SB_ABCFG_REG10090, BIT8 + BIT16, BIT8 + BIT16},
// RPR Enable SB800 to issue memory read/write requests in the upstream direction.
{AXCFG, SB_AB_REG04, BIT2, BIT2},
// RPR Enabling IDE/PCIB Prefetch for Performance Enhancement
// PCIB prefetch ABCFG 0x10060 [20] = 1 ABCFG 0x10064 [20] = 1
{ABCFG, SB_ABCFG_REG10060, BIT20, BIT20}, // PCIB prefetch enable
{ABCFG, SB_ABCFG_REG10064, BIT20, BIT20}, // PCIB prefetch enable
// RPR Controls the USB OHCI controller prefetch used for enhancing performance of ISO out devices.
// RPR Setting B-Link Prefetch Mode (ABCFG 0x80 [18:17] = 11)
{ABCFG, SB_ABCFG_REG80, BIT0 + BIT17 + BIT18, BIT0 + BIT17 + BIT18},
// RPR Enabled SMI ordering enhancement. ABCFG 0x90[21]
// RPR USB Delay A-Link Express L1 State. ABCFG 0x90[17]
{ABCFG, SB_ABCFG_REG90, BIT21 + BIT17, BIT21 + BIT17},
// RPR Disable the credit variable in the downstream arbitration equation
// RPR Register bit to qualify additional address bits into downstream register programming. (A12 BIT1 default is set)
{ABCFG, SB_ABCFG_REG9C, BIT0, BIT0},
// RPR Enabling Detection of Upstream Interrupts ABCFG 0x94 [20] = 1
// ABCFG 0x94 [19:0] = cpu interrupt delivery address [39:20]
{ABCFG, SB_ABCFG_REG94, BIT20, BIT20 + 0x00FEE},
// RPR Programming cycle delay for AB and BIF clock gating
// RPR Enable the AB and BIF clock-gating logic.
// RPR Enable the A-Link int_arbiter enhancement to allow the A-Link bandwidth to be used more efficiently
// RPR Enable the requester ID for upstream traffic. [16]: SB/NB link [17]: GPP
{ABCFG, SB_ABCFG_REG10054, 0x00FFFFFF, 0x010407FF},
{ABCFG, SB_ABCFG_REG98, 0xFFFF00FF, 0x00034700},
{ABCFG, SB_ABCFG_REG54, 0x00FF0000, 0x00040000},
// RPR Non-Posted Memory Write Support
{AX_INDXC, SB_AX_INDXC_REG10, BIT9, BIT9},
{ABCFG, 0, 0, (UINT8) 0xFF}, // This dummy entry is to clear ab index
{ (UINT8)0xFF, (UINT8)0xFF, (UINT8)0xFF, (UINT8)0xFF},
};
/**
* SbPcieOrderRule - AB-Link Configuration Table for ablink Post Pass Np Downstream/Upstream Feature
*
*/
const static ABTBLENTRY SbPcieOrderRule[] =
{
// abPostPassNpDownStreamTbl
{ABCFG, SB_ABCFG_REG10060, BIT31, BIT31},
{ABCFG, SB_ABCFG_REG1009C, BIT4 + BIT5, BIT4 + BIT5},
{ABCFG, SB_ABCFG_REG9C, BIT2 + BIT3 + BIT4 + BIT5 + BIT6 + BIT7, BIT2 + BIT3 + BIT4 + BIT5 + BIT6 + BIT7},
{ABCFG, SB_ABCFG_REG90, BIT21 + BIT22 + BIT23, BIT21 + BIT22 + BIT23},
{ABCFG, SB_ABCFG_REGF0, BIT6 + BIT5, BIT6 + BIT5},
{AXINDC, SB_AX_INDXC_REG02, BIT9, BIT9},
{ABCFG, SB_ABCFG_REG10090, BIT9 + BIT10 + BIT11 + BIT12, BIT9 + BIT10 + BIT11 + BIT12},
// abPostPassNpUpStreamTbl
{ABCFG, SB_ABCFG_REG58, BIT10, BIT10},
{ABCFG, SB_ABCFG_REGF0, BIT3 + BIT4, BIT3 + BIT4},
{ABCFG, SB_ABCFG_REG54, BIT1, BIT1},
{ (UINT8)0xFF, (UINT8)0xFF, (UINT8)0xFF, (UINT8)0xFF},
};
/**
* commonInitEarlyBoot - Config Southbridge SMBUS/ACPI/IDE/LPC/PCIB.
*
* This settings should be done during S3 resume also
*
* @param[in] pConfig Southbridge configuration structure pointer.
*
*/
VOID
commonInitEarlyBoot (
IN AMDSBCFG* pConfig
)
{
UINT32 abValue;
UINT16 dwTempVar;
CPUID_DATA CpuId;
UINT8 cimNativepciesupport;
UINT8 cimIrConfig;
UINT8 Data;
cimNativepciesupport = (UINT8) pConfig->NativePcieSupport;
cimIrConfig = (UINT8) pConfig->IrConfig;
#if SB_CIMx_PARAMETER == 0
cimNativepciesupport = cimNativepciesupportDefault;
cimIrConfig = cimIrConfigDefault;
#endif
//IR init Logical device 0x05
if ( cimIrConfig ) {
// Enable EC_PortActive
RWPCI (((LPC_BUS_DEV_FUN << 16) + SB_LPC_REGA4), AccWidthUint16 | S3_SAVE, 0xFFFE, BIT0);
EnterEcConfig ();
RWEC8 (0x07, 0x00, 0x05); //Select logical device 05, IR controller
RWEC8 (0x60, 0x00, 0x05); //Set Base Address to 550h
RWEC8 (0x61, 0x00, 0x50);
RWEC8 (0x70, 0xF0, 0x05); //Set IRQ to 05h
RWEC8 (0x30, 0x00, 0x01); //Enable logical device 5, IR controller
Data = 0xAB;
WriteIO (0x550, AccWidthUint8, &Data);
ReadIO (0x551, AccWidthUint8, &Data);
Data = ((Data & 0xFC ) | cimIrConfig);
WriteIO (0x551, AccWidthUint8, &Data);
ExitEcConfig ();
Data = 0xA0; // EC APIC index
WriteIO (SB_IOMAP_REGC00, AccWidthUint8, &Data);
Data = 0x05; // IRQ5
WriteIO (SB_IOMAP_REGC01, AccWidthUint8, &Data);
} else {
EnterEcConfig ();
RWEC8 (0x07, 0x00, 0x05); //Select logical device 05, IR controller
RWEC8 (0x30, 0x00, 0x00); //Disable logical device 5, IR controller
ExitEcConfig ();
}
CpuidRead (0x01, &CpuId);
//
// SB CFG programming
//
//Make BAR registers of smbus visible.
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGC8 + 1, AccWidthUint8, ~BIT6, 0);
//Early post initialization of pci config space
programPciByteTable ((REG8MASK*) FIXUP_PTR (&sbEarlyPostByteInitTable[0]), sizeof (sbEarlyPostByteInitTable) / sizeof (REG8MASK) );
if ( pConfig->BuildParameters.SmbusSsid != NULL ) {
RWPCI ((SMBUS_BUS_DEV_FUN << 16) + SB_CFG_REG2C, AccWidthUint32 | S3_SAVE, 0x00, pConfig->BuildParameters.SmbusSsid);
}
//Make BAR registers of smbus invisible.
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGC8 + 1, AccWidthUint8, ~BIT6, BIT6);
//
// LPC CFG programming
//
// SSID for LPC Controller
if (pConfig->BuildParameters.LpcSsid != NULL ) {
RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REG2C, AccWidthUint32 | S3_SAVE, 0x00, pConfig->BuildParameters.LpcSsid);
}
// LPC MSI
if ( pConfig->BuildParameters.LpcMsi) {
RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REG78, AccWidthUint32 | S3_SAVE, ~BIT1, BIT1);
}
//
// PCIB CFG programming
//
//Disable or Enable PCI Clks based on input
RWPCI ((PCIB_BUS_DEV_FUN << 16) + SB_PCIB_REG42, AccWidthUint8 | S3_SAVE, ~(BIT5 + BIT4 + BIT3 + BIT2), ((pConfig->PciClks) & 0x0F) << 2 );
RWPCI ((PCIB_BUS_DEV_FUN << 16) + SB_PCIB_REG4A, AccWidthUint8 | S3_SAVE, ~(BIT1 + BIT0), (pConfig->PciClks) >> 4 );
// PCIB MSI
if ( pConfig->BuildParameters.PcibMsi) {
RWPCI ((PCIB_BUS_DEV_FUN << 16) + SB_PCIB_REG40, AccWidthUint8 | S3_SAVE, ~BIT3, BIT3);
}
//
// AB CFG programming
//
// Read Arbiter address, Arbiter address is in PMIO 6Ch
ReadMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG6C, AccWidthUint16, &dwTempVar);
RWIO (dwTempVar, AccWidthUint8, 0, 0); // Write 0 to enable the arbiter
abLinkInitBeforePciEnum (pConfig); // Set ABCFG registers
// AB MSI
if ( pConfig->BuildParameters.AbMsi) {
abValue = readAlink (SB_ABCFG_REG94 | (UINT32) (ABCFG << 29));
abValue = abValue | BIT20;
writeAlink (SB_ABCFG_REG94 | (UINT32) (ABCFG << 29), abValue);
}
//
// SB Specific Function programming
//
// PCIE Native setting
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGBA + 1, AccWidthUint8, ~BIT14, 0);
if ( pConfig->NativePcieSupport == 1) {
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG74 + 3, AccWidthUint8, ~(BIT3 + BIT1 + BIT0), BIT2 + BIT0);
} else {
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG74 + 3, AccWidthUint8, ~(BIT3 + BIT1 + BIT0), BIT2);
}
#ifdef ACPI_SLEEP_TRAP
// Set SLP_TYPE as SMI event
RWMEM (ACPI_MMIO_BASE + SMI_BASE + SB_SMI_REGB0, AccWidthUint8, ~(BIT2 + BIT3), BIT2);
// Disabled SLP function for S1/S3/S4/S5
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGBE, AccWidthUint8, ~BIT5, 0x00);
// Set S state transition disabled (BIT0) force ACPI to send SMI message when writing to SLP_TYP Acpi register. (BIT1)
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG08 + 3, AccWidthUint8, ~(BIT0 + BIT1), BIT1);
// Enabled Global Smi ( BIT7 clear as 0 to enable )
RWMEM (ACPI_MMIO_BASE + SMI_BASE + SB_SMI_REG98 + 3 , AccWidthUint8, ~BIT7, 0x00);
#endif
if ( pConfig->SbUsbPll == 0) {
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGF3, AccWidthUint8, 0, 0x20);
}
// Set Stutter timer settings
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG80 + 1, AccWidthUint8, ~(BIT3 + BIT4), BIT3 + BIT4);
// Set LDTSTP# duration to 10us for HydraD CPU, or when HT link is 200MHz
if ((pConfig->AnyHT200MhzLink) || ((CpuId.EAX_Reg & 0x00ff00f0) == 0x100080) || ((CpuId.EAX_Reg & 0x00ff00f0) == 0x100090) || ((CpuId.EAX_Reg & 0x00ff00f0) == 0x1000A0)) {
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG94, AccWidthUint8, 0, 0x0A);
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG80 + 3, AccWidthUint8 | S3_SAVE, 0xFE, 0x28);
} else {
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG94, AccWidthUint8, 0, 0x01);
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG80 + 3, AccWidthUint8 | S3_SAVE, 0xFE, 0x20);
}
//PM_Reg 0x7A[15] (CountHaltMsgEn) should be set when C1e option is enabled
//PM_Reg 0x7A[3:0] (NumOfCpu) should be set to 1h when C1e option is enabled
//PM_Reg 0x80[13] has to set to 1 to enable Message C scheme.
if (pConfig->MTC1e) {
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG7A, AccWidthUint16 | S3_SAVE, 0x7FF0, BIT15 + 1);
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG80 + 1, AccWidthUint8 | S3_SAVE, ~BIT5, BIT5);
}
programSbAcpiMmioTbl ((AcpiRegWrite *) (pConfig->OEMPROGTBL.OemProgrammingTablePtr_Ptr));
}
/**
* abSpecialSetBeforePciEnum - Special setting ABCFG registers before PCI emulation.
*
*
* @param[in] pConfig Southbridge configuration structure pointer.
*
*/
VOID
abSpecialSetBeforePciEnum (
IN AMDSBCFG* pConfig
)
{
UINT32 abValue;
abValue = readAlink (SB_ABCFG_REGC0 | (UINT32) (ABCFG << 29));
abValue &= 0xf0;
if ( pConfig->SbPcieOrderRule && abValue ) {
abValue = readAlink (SB_RCINDXC_REG02 | (UINT32) (RCINDXC << 29));
abValue = abValue | BIT9;
writeAlink (SB_RCINDXC_REG02 | (UINT32) (RCINDXC << 29), abValue);
}
}
VOID
usbDesertPll (
IN AMDSBCFG* pConfig
)
{
if ( pConfig->SbUsbPll == 0) {
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGF3, AccWidthUint8, 0, 0x00);
}
}
/**
* commonInitEarlyPost - Config Southbridge SMBUS/ACPI/IDE/LPC/PCIB.
*
* This settings might not program during S3 resume
*
* @param[in] pConfig Southbridge configuration structure pointer.
*
*/
VOID
commonInitEarlyPost (
IN AMDSBCFG* pConfig
)
{
UINT8 dbPortStatus;
UINT8 cimSpreadSpectrum;
UINT32 cimSpreadSpectrumType;
AMDSBCFG* pTmp;
pTmp = pConfig;
cimSpreadSpectrum = pConfig->SpreadSpectrum;
cimSpreadSpectrumType = pConfig->BuildParameters.SpreadSpectrumType;
#if SB_CIMx_PARAMETER == 0
cimSpreadSpectrum = cimSpreadSpectrumDefault;
cimSpreadSpectrumType = cimSpreadSpectrumTypeDefault;
#endif
programSbAcpiMmioTbl ((AcpiRegWrite*) FIXUP_PTR (&sbPmioEPostInitTable[0]));
// CallBackToOEM (PULL_UP_PULL_DOWN_SETTINGS, NULL, pConfig);
if ( cimSpreadSpectrum ) {
// Misc_Reg_40[25]=1 -> allow to change spread profile
// Misc_Reg19=83 -> new spread profile
// Misc_Reg[12:10]=9975be
// Misc_Reg0B=91
// Misc_Reg09=21
// Misc_Misc_Reg_08[0]=1 -> enable spread
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x43, AccWidthUint8, ~BIT1, BIT1);
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x19, AccWidthUint8, 0, 0x83);
getChipSysMode (&dbPortStatus);
if ( ((dbPortStatus & ChipSysIntClkGen) != ChipSysIntClkGen) ) {
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x1A, AccWidthUint8, ~(BIT5 + BIT6 + BIT7), 0x80);
}
if ( cimSpreadSpectrumType == 0 ) {
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x12, AccWidthUint8, 0, 0x99);
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x11, AccWidthUint8, 0, 0x75);
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x10, AccWidthUint8, 0, 0xBE);
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x0B, AccWidthUint8, 0, 0x91);
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x09, AccWidthUint8, 0, 0x21);
} else { // Spread profile for Ontario CPU related platform
// This spread profile setting is for Ontario HDMI & DVI output from DP with -0.425%
// Misc_Reg[12:10]=828FA8
// Misc_Reg0B=11
// Misc_Reg09=21
// Misc_Reg10[25:24]=01b
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x12, AccWidthUint8, 0, 0x82);
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x11, AccWidthUint8, 0, 0x8F);
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x10, AccWidthUint8, 0, 0xA8);
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x0B, AccWidthUint8, 0, 0x11);
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x09, AccWidthUint8, 0, 0x21);
RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x13, AccWidthUint8, 0xFC, 0x1);
}
RWMEM (ACPI_MMIO_BASE + MISC_BASE + SB_MISC_REG08, AccWidthUint8, 0xFE, 0x01);
} else {
RWMEM (ACPI_MMIO_BASE + MISC_BASE + SB_MISC_REG08, AccWidthUint8, 0xFE, 0x00);
}
// RPR PLL 100Mhz Reference Clock Buffer setting for internal clock generator mode
getChipSysMode (&dbPortStatus);
if ( ((dbPortStatus & ChipSysIntClkGen) == ChipSysIntClkGen) ) {
RWMEM (ACPI_MMIO_BASE + MISC_BASE + SB_MISC_REG04 + 1, AccWidthUint8, ~BIT5, BIT5);
}
// Set ASF SMBUS master function enabled here (temporary)
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG28, AccWidthUint16 | S3_SAVE, ~(BIT0 + BIT2), BIT0 + BIT2);
programSbAcpiMmioTbl ((AcpiRegWrite *) (pConfig->OEMPROGTBL.OemProgrammingTablePtr_Ptr));
#ifndef NO_EC_SUPPORT
// Software IMC enable
if (((pConfig->BuildParameters.ImcEnableOverWrite == 1) && ((dbPortStatus & ChipSysEcEnable) == 0)) || ((pConfig->BuildParameters.ImcEnableOverWrite == 2) && ((dbPortStatus & ChipSysEcEnable) == ChipSysEcEnable))) {
if (validateImcFirmware (pConfig)) {
softwareToggleImcStrapping (pConfig);
} else {
CallBackToOEM (IMC_FIRMWARE_FAIL, 0, pConfig);
}
}
#endif
}
/**
* abLinkInitBeforePciEnum - Set ABCFG registers before PCI emulation.
*
*
* @param[in] pConfig Southbridge configuration structure pointer.
*
*/
VOID
abLinkInitBeforePciEnum (
IN AMDSBCFG* pConfig
)
{
UINT32 cimResetCpuOnSyncFlood;
ABTBLENTRY *pAbTblPtr;
AMDSBCFG* Temp;
cimResetCpuOnSyncFlood = pConfig->ResetCpuOnSyncFlood;
#if SB_CIMx_PARAMETER == 0
cimResetCpuOnSyncFlood = cimResetCpuOnSyncFloodDefault;
#endif
Temp = pConfig;
if ( pConfig->SbPcieOrderRule ) {
pAbTblPtr = (ABTBLENTRY *) FIXUP_PTR (&SbPcieOrderRule[0]);
abcfgTbl (pAbTblPtr);
}
pAbTblPtr = (ABTBLENTRY *) FIXUP_PTR (&abTblEntry800[0]);
abcfgTbl (pAbTblPtr);
if ( cimResetCpuOnSyncFlood ) {
rwAlink (SB_ABCFG_REG10050 | (UINT32) (ABCFG << 29), ~BIT2, BIT2);
}
}
/**
* abcfgTbl - Program ABCFG by input table.
*
*
* @param[in] pABTbl ABCFG config table.
*
*/
VOID
abcfgTbl (
IN ABTBLENTRY* pABTbl
)
{
UINT32 ddValue;
while ( (pABTbl->regType) != 0xFF ) {
if ( pABTbl->regType > AXINDC ) {
ddValue = pABTbl->regIndex | (pABTbl->regType << 29);
writeAlink (ddValue, ((readAlink (ddValue)) & (0xFFFFFFFF^ (pABTbl->regMask))) | pABTbl->regData);
} else {
ddValue = 0x30 | (pABTbl->regType << 29);
writeAlink (ddValue, pABTbl->regIndex);
ddValue = 0x34 | (pABTbl->regType << 29);
writeAlink (ddValue, ((readAlink (ddValue)) & (0xFFFFFFFF^ (pABTbl->regMask))) | pABTbl->regData);
}
++pABTbl;
}
//Clear ALink Access Index
ddValue = 0;
WriteIO (ALINK_ACCESS_INDEX, AccWidthUint32 | S3_SAVE, &ddValue);
}
/**
* commonInitLateBoot - Prepare Southbridge register setting to boot to OS.
*
*
* @param[in] pConfig Southbridge configuration structure pointer.
*
*/
VOID
commonInitLateBoot (
IN AMDSBCFG* pConfig
)
{
UINT8 dbValue;
UINT32 ddVar;
// We need to do the following setting in late post also because some bios core pci enumeration changes these values
// programmed during early post.
// RPR 4.5 Master Latency Timer
dbValue = 0x40;
WritePCI ((PCIB_BUS_DEV_FUN << 16) + SB_PCIB_REG0D, AccWidthUint8, &dbValue);
WritePCI ((PCIB_BUS_DEV_FUN << 16) + SB_PCIB_REG1B, AccWidthUint8, &dbValue);
//SB P2P AutoClock control settings.
ddVar = (pConfig->PcibAutoClkCtrlHigh << 16) | (pConfig->PcibAutoClkCtrlLow);
WritePCI ((PCIB_BUS_DEV_FUN << 16) + SB_PCIB_REG4C, AccWidthUint32, &ddVar);
ddVar = (pConfig->PcibClkStopOverride);
RWPCI ((PCIB_BUS_DEV_FUN << 16) + SB_PCIB_REG50, AccWidthUint16, 0x3F, (UINT16) (ddVar << 6));
RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REGBB, AccWidthUint8, 0xBF | S3_SAVE, BIT3 + BIT4 + BIT5);
// USB Phy Calibration Adjustment
ddVar = (USB1_EHCI_BUS_DEV_FUN << 16);
sbUsbPhySetting (ddVar);
ddVar = (USB2_EHCI_BUS_DEV_FUN << 16);
sbUsbPhySetting (ddVar);
ddVar = (USB3_EHCI_BUS_DEV_FUN << 16);
sbUsbPhySetting (ddVar);
c3PopupSetting (pConfig);
FusionRelatedSetting (pConfig);
}
/**
* sbUsbPhySetting - USB Phy Calibration Adjustment
*
*
* @param[in] Value Controller PCI config address (bus# + device# + function#)
*
*/
VOID
sbUsbPhySetting (
IN UINT32 Value
)
{
UINT32 ddBarAddress;
UINT32 ddPhyStatus03;
UINT32 ddPhyStatus4;
UINT8 dbRevId;
//Get BAR address
ReadPCI ((UINT32) Value + SB_EHCI_REG10, AccWidthUint32, &ddBarAddress);
if ( (ddBarAddress != - 1) && (ddBarAddress != 0) ) {
ReadMEM ( ddBarAddress + SB_EHCI_BAR_REGA8, AccWidthUint32, &ddPhyStatus03);
ReadMEM ( ddBarAddress + SB_EHCI_BAR_REGAC, AccWidthUint32, &ddPhyStatus4);
ddPhyStatus03 &= 0x07070707;
ddPhyStatus4 &= 0x00000007;
if ( (ddPhyStatus03 != 0x00) | (ddPhyStatus4 != 0x00) ) {
// RPR 7.7 USB 2.0 Ports Driving Strength step 1
//Make BAR registers of smbus visible.
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGC8 + 1, AccWidthUint8, ~BIT6, 0);
ReadPCI ((SMBUS_BUS_DEV_FUN << 16) + SB_CFG_REG08, AccWidthUint8, &dbRevId);
//Make BAR registers of smbus invisible.
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGC8 + 1, AccWidthUint8, ~BIT6, BIT6);
if (dbRevId == 0x41) { // A12
RWMEM (ddBarAddress + SB_EHCI_BAR_REGC0, AccWidthUint32, 0xFFFF00FF, 0x1500);
RWMEM (ddBarAddress + SB_EHCI_BAR_REGC4, AccWidthUint32, 0xFFFFF0FF, 0);
} else if (dbRevId == 0x42) { // A13
RWMEM (ddBarAddress + SB_EHCI_BAR_REGC0, AccWidthUint32, 0xFFFF00FF, 0x0F00);
RWMEM (ddBarAddress + SB_EHCI_BAR_REGC4, AccWidthUint32, 0xFFFFF0FF, 0x0100);
}
}
}
}
/**
* hpetInit - Program Southbridge HPET function
*
*
*
* @param[in] pConfig Southbridge configuration structure pointer.
* @param[in] pStaticOptions Platform build configuration table.
*
*/
VOID
hpetInit (
IN AMDSBCFG* pConfig,
IN BUILDPARAM *pStaticOptions
)
{
DESCRIPTION_HEADER* pHpetTable;
UINT8 cimHpetTimer;
UINT8 cimHpetMsiDis;
cimHpetTimer = (UINT8) pConfig->HpetTimer;
cimHpetMsiDis = (UINT8) pConfig->HpetMsiDis;
#if SB_CIMx_PARAMETER == 0
cimHpetTimer = cimHpetTimerDefault;
cimHpetMsiDis = cimHpetMsiDisDefault;
#endif
pHpetTable = NULL;
if ( cimHpetTimer == TRUE ) {
//Program the HPET BAR address
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG50, AccWidthUint32 | S3_SAVE, 0xFFFFF800, pStaticOptions->HpetBase);
//Enabling decoding of HPET MMIO
//Enable HPET MSI support
//Enable High Precision Event Timer (also called Multimedia Timer) interrupt
if ( cimHpetMsiDis == FALSE ) {
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG50, AccWidthUint32 | S3_SAVE, 0xFFFFF800, BIT0 + BIT1 + BIT2 + BIT3 + BIT4);
} else {
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG50, AccWidthUint32 | S3_SAVE, 0xFFFFF800, BIT0 + BIT1);
}
} else {
if ( ! (pConfig->S3Resume) ) {
pHpetTable = (DESCRIPTION_HEADER*) ACPI_LocateTable (Int32FromChar('H', 'P', 'E', 'T'));
}
if ( pHpetTable != NULL ) {
pHpetTable->Signature = Int32FromChar('T', 'E', 'P', 'H');
}
}
}
/**
* c3PopupSetting - Program Southbridge C state function
*
*
*
* @param[in] pConfig Southbridge configuration structure pointer.
*
*/
VOID
c3PopupSetting (
IN AMDSBCFG* pConfig
)
{
AMDSBCFG* Temp;
UINT8 dbValue;
Temp = pConfig;
//RPR C-State and VID/FID Change
dbValue = getNumberOfCpuCores ();
if (dbValue > 1) {
//PM 0x80[2]=1, For system with dual core CPU, set this bit to 1 to automatically clear BM_STS when the C3 state is being initiated.
//PM 0x80[1]=1, For system with dual core CPU, set this bit to 1 and BM_STS will cause C3 to wakeup regardless of BM_RLD
//PM 0x7E[6]=1, Enable pop-up for C3. For internal bus mastering or BmReq# from the NB, the SB will de-assert
//LDTSTP# (pop-up) to allow DMA traffic, then assert LDTSTP# again after some idle time.
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG80, AccWidthUint8 | S3_SAVE, ~(BIT1 + BIT2), (BIT1 + BIT2));
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG7E, AccWidthUint8 | S3_SAVE, ~BIT6, BIT6);
}
//SB800 needs to changed for RD790 support
//PM 0x80 [8] = 0 for system with RS780
//Note: RS690 north bridge has AllowLdtStop built for both display and PCIE traffic to wake up the HT link.
//BmReq# needs to be ignored otherwise may cause LDTSTP# not to toggle.
//PM_IO 0x80[3]=1, Ignore BM_STS_SET message from NB
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG80, AccWidthUint16 | S3_SAVE, ~(BIT9 + BIT8 + BIT7 + BIT4 + BIT3 + BIT2 + BIT1 + BIT0), 0x21F);
//LdtStartTime = 10h for minimum LDTSTP# de-assertion duration of 16us in StutterMode. This is to guarantee that
//the HT link has been safely reconnected before it can be disconnected again. If C3 pop-up is enabled, the 16us also
//serves as the minimum idle time before LDTSTP# can be asserted again. This allows DMA to finish before the HT
//link is disconnected.
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG94 + 2, AccWidthUint8, 0, 0x10);
//This setting provides 16us delay before the assertion of LDTSTOP# when C3 is entered. The
//delay will allow USB DMA to go on in a continuous manner
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG98 + 1, AccWidthUint8, 0, 0x10);
// Not in the RPR so far, it's hand writing from ASIC
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG7C, AccWidthUint8 | S3_SAVE, 0, 0x85);
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG7C + 1, AccWidthUint8 | S3_SAVE, 0, 0x01);
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG7E + 1, AccWidthUint8 | S3_SAVE, ~(BIT7 + BIT5), BIT7 + BIT5);
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG88 + 1, AccWidthUint8 | S3_SAVE, ~BIT4, BIT4);
// RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG94, AccWidthUint8, 0, 0x10);
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG98 + 3, AccWidthUint8, 0, 0x10);
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGB4 + 1, AccWidthUint8, 0, 0x0B);
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG88, AccWidthUint8 | S3_SAVE, 0xFF, BIT4);
if (pConfig->LdtStpDisable) {
RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG88, AccWidthUint8 | S3_SAVE, ~BIT5, 0);
}
}
/**
* FusionRelatedSetting - Program Fusion C related function
*
*
*
* @param[in] pConfig Southbridge configuration structure pointer.
*
*/
VOID
FusionRelatedSetting (
IN AMDSBCFG* pConfig
)
{
UINT8 cimAcDcMsg;
UINT8 cimTimerTickTrack;
UINT8 cimClockInterruptTag;
UINT8 cimOhciTrafficHanding;
UINT8 cimEhciTrafficHanding;
UINT8 cimFusionMsgCMultiCore;
UINT8 cimFusionMsgCStage;
UINT32 ddValue;
cimAcDcMsg = (UINT8) pConfig->AcDcMsg;
cimTimerTickTrack = (UINT8) pConfig->TimerTickTrack;
cimClockInterruptTag = (UINT8) pConfig->ClockInterruptTag;
cimOhciTrafficHanding = (UINT8) pConfig->OhciTrafficHanding;
cimEhciTrafficHanding = (UINT8) pConfig->EhciTrafficHanding;
cimFusionMsgCMultiCore = (UINT8) pConfig->FusionMsgCMultiCore;
cimFusionMsgCStage = (UINT8) pConfig->FusionMsgCStage;
#if SB_CIMx_PARAMETER == 0
cimAcDcMsg = cimAcDcMsgDefault;
cimTimerTickTrack = cimTimerTickTrackDefault;
cimClockInterruptTag = cimClockInterruptTagDefault;
cimOhciTrafficHanding = cimOhciTrafficHandingDefault;
cimEhciTrafficHanding = cimEhciTrafficHandingDefault;
cimFusionMsgCMultiCore = cimFusionMsgCMultiCoreDefault;
cimFusionMsgCStage = cimFusionMsgCStageDefault;
#endif
ReadMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGA0, AccWidthUint32 | S3_SAVE, &ddValue);
ddValue = ddValue & 0xC07F00A0;
if ( cimAcDcMsg ) {
ddValue = ddValue | BIT0;
}
if ( cimTimerTickTrack ) {
ddValue = ddValue | BIT1;
}
if ( cimClockInterruptTag ) {
ddValue = ddValue | BIT10;
}
if ( cimOhciTrafficHanding ) {
ddValue = ddValue | BIT13;
}
if ( cimEhciTrafficHanding ) {
ddValue = ddValue | BIT15;
}
if ( cimFusionMsgCMultiCore ) {
ddValue = ddValue | BIT23;
}
if ( cimFusionMsgCStage ) {
ddValue = (ddValue | (BIT6 + BIT4 + BIT3 + BIT2));
}
WriteMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGA0, AccWidthUint32 | S3_SAVE, &ddValue);
}
#ifndef NO_EC_SUPPORT
/**
* validateImcFirmware - Validate IMC Firmware.
*
*
* @param[in] pConfig Southbridge configuration structure pointer.
*
* @retval TRUE Pass
* @retval FALSE Failed
*/
BOOLEAN
validateImcFirmware (
IN AMDSBCFG* pConfig
)
{
UINT32 ImcSig;
UINT32 ImcSigAddr;
UINT32 ImcAddr;
UINT32 CurAddr;
UINT32 ImcBinSig0;
UINT32 ImcBinSig1;
UINT16 ImcBinSig2;
UINT8 dbIMCChecksume;
UINT8 dbIMC;
ImcAddr = 0;
// Software IMC enable
ImcSigAddr = 0x80000; // start from 512k to 64M
ImcSig = 0x0; //
while ( ( ImcSig != 0x55aa55aa ) && ( ImcSigAddr <= 0x4000000 ) ) {
CurAddr = 0xffffffff - ImcSigAddr + 0x20001;
ReadMEM (CurAddr, AccWidthUint32, &ImcSig);
ReadMEM ((CurAddr + 4), AccWidthUint32, &ImcAddr);
ImcSigAddr <<= 1;
}
dbIMCChecksume = 0xff;
if ( ImcSig == 0x55aa55aa ) {
// "_AMD_IMC_C" at offset 0x2000 of the binary
ReadMEM ((ImcAddr + 0x2000), AccWidthUint32, &ImcBinSig0);
ReadMEM ((ImcAddr + 0x2004), AccWidthUint32, &ImcBinSig1);
ReadMEM ((ImcAddr + 0x2008), AccWidthUint16, &ImcBinSig2);
if ((ImcBinSig0 == 0x444D415F) && (ImcBinSig1 == 0x434D495F) && (ImcBinSig2 == 0x435F) ) {
dbIMCChecksume = 0;
for ( CurAddr = ImcAddr; CurAddr < ImcAddr + 0x10000; CurAddr++ ) {
ReadMEM (CurAddr, AccWidthUint8, &dbIMC);
dbIMCChecksume = dbIMCChecksume + dbIMC;
}
}
}
if ( dbIMCChecksume ) {
return FALSE;
} else {
return TRUE;
}
}
/**
* softwareToggleImcStrapping - Software Toggle IMC Firmware Strapping.
*
*
* @param[in] pConfig Southbridge configuration structure pointer.
*
*/
VOID
softwareToggleImcStrapping (
IN AMDSBCFG* pConfig
)
{
UINT8 dbValue;
UINT8 dbPortStatus;
UINT32 abValue;
UINT32 abValue1;
getChipSysMode (&dbPortStatus);
ReadPMIO (SB_PMIOA_REGBF, AccWidthUint8, &dbValue);
//if ( (dbValue & (BIT6 + BIT7)) != 0xC0 ) { // PwrGoodOut =1, PwrGoodEnB=1
//The strapStatus register is not mapped into StrapOveride not in the same bit position. The following is difference.
//StrapStatus StrapOverride
// bit4 bit17
// bit6 bit12
// bit12 bit15
// bit15 bit16
// bit16 bit18
ReadMEM ((ACPI_MMIO_BASE + MISC_BASE + SB_MISC_REG80), AccWidthUint32, &abValue);
abValue1 = abValue;
if (abValue & BIT4) {
abValue1 = (abValue1 & ~BIT4) | BIT17;
}
if (abValue & BIT6) {
abValue1 = (abValue1 & ~BIT6) | BIT12;
}
if (abValue & BIT12) {
abValue1 = (abValue1 & ~BIT12) | BIT15;
}
if (abValue & BIT15) {
abValue1 = (abValue1 & ~BIT15) | BIT16;
}
if (abValue & BIT16) {
abValue1 = (abValue1 & ~BIT16) | BIT18;
}
abValue1 |= BIT31; // Overwrite enable
if ((dbPortStatus & ChipSysEcEnable) == 0) {
abValue1 |= BIT2; // bit2- EcEnableStrap
} else {
abValue1 &= ~BIT2; // bit2=0 EcEnableStrap
}
WriteMEM ((ACPI_MMIO_BASE + MISC_BASE + SB_MISC_REG84), AccWidthUint32, &abValue1);
dbValue |= BIT6; // PwrGoodOut =1
dbValue &= ~BIT7; // PwrGoodEnB =0
WritePMIO (SB_PMIOA_REGBF, AccWidthUint8, &dbValue);
dbValue = 06;
WriteIO (0xcf9, AccWidthUint8, &dbValue);
SbStall (0xffffffff);
}
#endif
#ifndef NO_HWM_SUPPORT
/**
* validateImcFirmware - Validate IMC Firmware.
*
*
* @param[in] pConfig Southbridge configuration structure pointer.
*
*/
VOID
hwmInit (
IN AMDSBCFG* pConfig
)
{
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0xB2, AccWidthUint8 | S3_SAVE, 0, 0x55);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0xB3, AccWidthUint8 | S3_SAVE, 0, 0x55);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x91, AccWidthUint8 | S3_SAVE, 0, 0x55);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x92, AccWidthUint8 | S3_SAVE, 0, 0x55);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x00, AccWidthUint8 | S3_SAVE, 0, 0x06);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x10, AccWidthUint8 | S3_SAVE, 0, 0x06);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x20, AccWidthUint8 | S3_SAVE, 0, 0x06);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x30, AccWidthUint8 | S3_SAVE, 0, 0x06);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x40, AccWidthUint8 | S3_SAVE, 0, 0x06);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x66, AccWidthUint8 | S3_SAVE, 0, 0x01);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x6B, AccWidthUint8 | S3_SAVE, 0, 0x01);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x70, AccWidthUint8 | S3_SAVE, 0, 0x01);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x75, AccWidthUint8 | S3_SAVE, 0, 0x01);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0x7A, AccWidthUint8 | S3_SAVE, 0, 0x01);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0xF8, AccWidthUint8 | S3_SAVE, 0, 0x05);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0xF9, AccWidthUint8 | S3_SAVE, 0, 0x06);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0xFF, AccWidthUint8 | S3_SAVE, 0, 0x42);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0xE9, AccWidthUint8 | S3_SAVE, 0, 0xFF);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0xEB, AccWidthUint8 | S3_SAVE, 0, 0x1F);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0xEF, AccWidthUint8 | S3_SAVE, 0, 0x04);
RWMEM (ACPI_MMIO_BASE + PMIO2_BASE + 0xFB, AccWidthUint8 | S3_SAVE, 0, 0x00);
}
#endif