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review.coreboot.org / coreboot / b3a8cc54dbaf833c590a56f912209a5632b71f49 / . / src / mainboard / bap / ode_e21XX / BiosCallOuts.c
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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.
*/
#include <AGESA.h>
#include <northbridge/amd/agesa/BiosCallOuts.h>
#include <FchPlatform.h>
#include <cbfs.h>
#include "imc.h"
#include "hudson.h"
#include <stdlib.h>
#include <spd_bin.h>
static AGESA_STATUS Fch_Oem_config(UINT32 Func, UINTN FchData, VOID *ConfigPtr);
static AGESA_STATUS board_ReadSpd_from_cbfs(UINT32 Func, UINTN Data, VOID *ConfigPtr);
const BIOS_CALLOUT_STRUCT BiosCallouts[] =
{
{AGESA_READ_SPD, board_ReadSpd_from_cbfs },
{AGESA_DO_RESET, agesa_Reset },
{AGESA_READ_SPD_RECOVERY, agesa_NoopUnsupported },
{AGESA_RUNFUNC_ONAP, agesa_RunFuncOnAp },
{AGESA_GET_IDS_INIT_DATA, agesa_EmptyIdsInitData },
{AGESA_HOOKBEFORE_DQS_TRAINING, agesa_NoopSuccess },
{AGESA_HOOKBEFORE_EXIT_SELF_REF, agesa_NoopSuccess },
{AGESA_FCH_OEM_CALLOUT, Fch_Oem_config },
{AGESA_GNB_GFX_GET_VBIOS_IMAGE, agesa_GfxGetVbiosImage }
};
const int BiosCalloutsLen = ARRAY_SIZE(BiosCallouts);
/**
* Realtek ALC272 CODEC Verb Table
*/
static const CODEC_ENTRY Alc272_VerbTbl[] = {
{0x11, 0x411111F0}, // - SPDIF_OUT2
{0x12, 0x411111F0}, // - DMIC_1/2
{0x13, 0x411111F0}, // - DMIC_3/4
{0x14, 0x411111F0}, // Port D - LOUT1
{0x15, 0x411111F0}, // Port A - LOUT2
{0x16, 0x411111F0}, //
{0x17, 0x411111F0}, // Port H - MONO
{0x18, 0x01a19840}, // Port B - MIC1
{0x19, 0x411111F0}, // Port F - MIC2
{0x1a, 0x01813030}, // Port C - LINE1
{0x1b, 0x411111F0}, // Port E - LINE2
{0x1d, 0x40251E05}, // - PCBEEP
{0x1e, 0x01441120}, // - SPDIF_OUT1
{0x21, 0x01214010}, // Port I - HPOUT
{0xff, 0xffffffff}
};
static const CODEC_TBL_LIST CodecTableList[] =
{
{0x10ec0272, (CODEC_ENTRY*)&Alc272_VerbTbl[0]},
{(UINT32)0x0FFFFFFFF, (CODEC_ENTRY*)0x0FFFFFFFFUL}
};
#define FAN_INPUT_INTERNAL_DIODE 0
#define FAN_INPUT_TEMP0 1
#define FAN_INPUT_TEMP1 2
#define FAN_INPUT_TEMP2 3
#define FAN_INPUT_TEMP3 4
#define FAN_INPUT_TEMP0_FILTER 5
#define FAN_INPUT_ZERO 6
#define FAN_INPUT_DISABLED 7
#define FAN_AUTOMODE (1 << 0)
#define FAN_LINEARMODE (1 << 1)
#define FAN_STEPMODE ~(1 << 1)
#define FAN_POLARITY_HIGH (1 << 2)
#define FAN_POLARITY_LOW ~(1 << 2)
/* Normally, 4-wire fan runs at 25KHz and 3-wire fan runs at 100Hz */
#define FREQ_28KHZ 0x0
#define FREQ_25KHZ 0x1
#define FREQ_23KHZ 0x2
#define FREQ_21KHZ 0x3
#define FREQ_29KHZ 0x4
#define FREQ_18KHZ 0x5
#define FREQ_100HZ 0xF7
#define FREQ_87HZ 0xF8
#define FREQ_58HZ 0xF9
#define FREQ_44HZ 0xFA
#define FREQ_35HZ 0xFB
#define FREQ_29HZ 0xFC
#define FREQ_22HZ 0xFD
#define FREQ_14HZ 0xFE
#define FREQ_11HZ 0xFF
/*
* Hardware Monitor Fan Control
* Hardware limitation:
* HWM will fail to read the input temperature via I2C if other
* software switches the I2C address. AMD recommends using IMC
* to control fans, instead of HWM.
*/
static void oem_fan_control(FCH_DATA_BLOCK *FchParams)
{
FCH_HWM_FAN_CTR oem_factl[5] = {
/*temperature input, fan mode, frequency, low_duty, med_duty, multiplier, lowtemp, medtemp, hightemp, LinearRange, LinearHoldCount */
/* DB-FT3 FanOUT0 Fan header J32 */
{FAN_INPUT_INTERNAL_DIODE, (FAN_STEPMODE | FAN_POLARITY_HIGH), FREQ_100HZ, 40, 60, 0, 40, 65, 85, 0, 0},
/* DB-FT3 FanOUT1 Fan header J31*/
{FAN_INPUT_INTERNAL_DIODE, (FAN_STEPMODE | FAN_POLARITY_HIGH), FREQ_100HZ, 40, 60, 0, 40, 65, 85, 0, 0},
{FAN_INPUT_INTERNAL_DIODE, (FAN_STEPMODE | FAN_POLARITY_HIGH), FREQ_100HZ, 40, 60, 0, 40, 65, 85, 0, 0},
{FAN_INPUT_INTERNAL_DIODE, (FAN_STEPMODE | FAN_POLARITY_HIGH), FREQ_100HZ, 40, 60, 0, 40, 65, 85, 0, 0},
{FAN_INPUT_INTERNAL_DIODE, (FAN_STEPMODE | FAN_POLARITY_HIGH), FREQ_100HZ, 40, 60, 0, 40, 65, 85, 0, 0},
};
LibAmdMemCopy ((VOID *)(FchParams->Hwm.HwmFanControl), &oem_factl, (sizeof(FCH_HWM_FAN_CTR) * 5), FchParams->StdHeader);
/* Enable IMC fan control. the recommended way */
if (IS_ENABLED(CONFIG_HUDSON_IMC_FWM)) {
/* HwMonitorEnable = TRUE && HwmFchtsiAutoOpll ==FALSE to call FchECfancontrolservice */
FchParams->Hwm.HwMonitorEnable = TRUE;
FchParams->Hwm.HwmFchtsiAutoPoll = FALSE; /* 0 disable, 1 enable TSI Auto Polling */
FchParams->Imc.ImcEnable = TRUE;
FchParams->Hwm.HwmControl = 1; /* 1 IMC, 0 HWM */
FchParams->Imc.ImcEnableOverWrite = 1; /* 2 disable IMC, 1 enable IMC, 0 following hw strap setting */
LibAmdMemFill(&(FchParams->Imc.EcStruct), 0, sizeof(FCH_EC), FchParams->StdHeader);
/* Thermal Zone Parameter */
FchParams->Imc.EcStruct.MsgFun81Zone0MsgReg0 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone0MsgReg1 = 0x00; /* Zone */
FchParams->Imc.EcStruct.MsgFun81Zone0MsgReg2 = 0x3d; //BIT0 | BIT2 | BIT5;
FchParams->Imc.EcStruct.MsgFun81Zone0MsgReg3 = 0x4e; //6 | BIT3;
FchParams->Imc.EcStruct.MsgFun81Zone0MsgReg4 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone0MsgReg5 = 0x04;
FchParams->Imc.EcStruct.MsgFun81Zone0MsgReg6 = 0x9a; /* SMBUS Address for SMBUS based temperature sensor such as SB-TSI and ADM1032 */
FchParams->Imc.EcStruct.MsgFun81Zone0MsgReg7 = 0x01;
FchParams->Imc.EcStruct.MsgFun81Zone0MsgReg8 = 0x01; /* PWM steping rate in unit of PWM level percentage */
FchParams->Imc.EcStruct.MsgFun81Zone0MsgReg9 = 0x00;
/* IMC Fan Policy temperature thresholds */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgReg0 = 0x00;
FchParams->Imc.EcStruct.MsgFun83Zone0MsgReg1 = 0x00; /* Zone */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgReg2 = 0x46; /*AC0 threshold in Celsius */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgReg3 = 0x3c; /*AC1 threshold in Celsius */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgReg4 = 0x32; /*AC2 threshold in Celsius */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgReg5 = 0xff; /*AC3 threshold in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgReg6 = 0xff; /*AC4 threshold in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgReg7 = 0xff; /*AC5 threshold in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgReg8 = 0xff; /*AC6 threshold in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgReg9 = 0xff; /*AC7 lowest threshold in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgRegA = 0x4b; /*critical threshold* in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone0MsgRegB = 0x00;
/* IMC Fan Policy PWM Settings */
FchParams->Imc.EcStruct.MsgFun85Zone0MsgReg0 = 0x00;
FchParams->Imc.EcStruct.MsgFun85Zone0MsgReg1 = 0x00; /* Zone */
FchParams->Imc.EcStruct.MsgFun85Zone0MsgReg2 = 0x5a; /* AL0 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone0MsgReg3 = 0x46; /* AL1 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone0MsgReg4 = 0x28; /* AL2 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone0MsgReg5 = 0xff; /* AL3 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone0MsgReg6 = 0xff; /* AL4 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone0MsgReg7 = 0xff; /* AL5 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone0MsgReg8 = 0xff; /* AL6 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone0MsgReg9 = 0xff; /* AL7 percentage */
FchParams->Imc.EcStruct.MsgFun81Zone1MsgReg0 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone1MsgReg1 = 0x01; /* Zone */
FchParams->Imc.EcStruct.MsgFun81Zone1MsgReg2 = 0x55; //BIT0 | BIT2 | BIT5;
FchParams->Imc.EcStruct.MsgFun81Zone1MsgReg3 = 0x17;
FchParams->Imc.EcStruct.MsgFun81Zone1MsgReg4 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone1MsgReg5 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone1MsgReg6 = 0x90; /* SMBUS Address for SMBUS based temperature sensor such as SB-TSI and ADM1032 */
FchParams->Imc.EcStruct.MsgFun81Zone1MsgReg7 = 0;
FchParams->Imc.EcStruct.MsgFun81Zone1MsgReg8 = 0; /* PWM steping rate in unit of PWM level percentage */
FchParams->Imc.EcStruct.MsgFun81Zone1MsgReg9 = 0;
FchParams->Imc.EcStruct.MsgFun83Zone1MsgReg0 = 0x00;
FchParams->Imc.EcStruct.MsgFun83Zone1MsgReg1 = 0x01; /* zone */
FchParams->Imc.EcStruct.MsgFun83Zone1MsgReg2 = 60; /*AC0 threshold in Celsius */
FchParams->Imc.EcStruct.MsgFun83Zone1MsgReg3 = 40; /*AC1 threshold in Celsius */
FchParams->Imc.EcStruct.MsgFun83Zone1MsgReg4 = 0; /*AC2 threshold in Celsius */
FchParams->Imc.EcStruct.MsgFun83Zone1MsgReg5 = 0; /*AC3 threshold in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone1MsgReg6 = 0; /*AC4 threshold in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone1MsgReg7 = 0; /*AC5 threshold in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone1MsgReg8 = 0; /*AC6 threshold in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone1MsgReg9 = 0; /*AC7 lowest threshold in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone1MsgRegA = 0; /*critical threshold* in Celsius, 0xFF is not define */
FchParams->Imc.EcStruct.MsgFun83Zone1MsgRegB = 0x00;
FchParams->Imc.EcStruct.MsgFun85Zone1MsgReg0 = 0x00;
FchParams->Imc.EcStruct.MsgFun85Zone1MsgReg1 = 0x01; /*Zone */
FchParams->Imc.EcStruct.MsgFun85Zone1MsgReg2 = 0; /* AL0 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone1MsgReg3 = 0; /* AL1 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone1MsgReg4 = 0; /* AL2 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone1MsgReg5 = 0x00; /* AL3 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone1MsgReg6 = 0x00; /* AL4 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone1MsgReg7 = 0x00; /* AL5 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone1MsgReg8 = 0x00; /* AL6 percentage */
FchParams->Imc.EcStruct.MsgFun85Zone1MsgReg9 = 0x00; /* AL7 percentage */
FchParams->Imc.EcStruct.MsgFun81Zone2MsgReg0 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone2MsgReg1 = 0x2; /* Zone */
FchParams->Imc.EcStruct.MsgFun81Zone2MsgReg2 = 0x0; //BIT0 | BIT2 | BIT5;
FchParams->Imc.EcStruct.MsgFun81Zone2MsgReg3 = 0x0;
FchParams->Imc.EcStruct.MsgFun81Zone2MsgReg4 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone2MsgReg5 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone2MsgReg6 = 0x98; /* SMBUS Address for SMBUS based temperature sensor such as SB-TSI and ADM1032 */
FchParams->Imc.EcStruct.MsgFun81Zone2MsgReg7 = 2;
FchParams->Imc.EcStruct.MsgFun81Zone2MsgReg8 = 5; /* PWM steping rate in unit of PWM level percentage */
FchParams->Imc.EcStruct.MsgFun81Zone2MsgReg9 = 0;
FchParams->Imc.EcStruct.MsgFun81Zone3MsgReg0 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone3MsgReg1 = 0x3; /* Zone */
FchParams->Imc.EcStruct.MsgFun81Zone3MsgReg2 = 0x0; //BIT0 | BIT2 | BIT5;
FchParams->Imc.EcStruct.MsgFun81Zone3MsgReg3 = 0x0;
FchParams->Imc.EcStruct.MsgFun81Zone3MsgReg4 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone3MsgReg5 = 0x00;
FchParams->Imc.EcStruct.MsgFun81Zone3MsgReg6 = 0x0; /* SMBUS Address for SMBUS based temperature sensor such as SB-TSI and ADM1032 */
FchParams->Imc.EcStruct.MsgFun81Zone3MsgReg7 = 0;
FchParams->Imc.EcStruct.MsgFun81Zone3MsgReg8 = 0; /* PWM steping rate in unit of PWM level percentage */
FchParams->Imc.EcStruct.MsgFun81Zone3MsgReg9 = 0;
/* IMC Function */
FchParams->Imc.EcStruct.IMCFUNSupportBitMap = 0x333; //BIT0 | BIT4 |BIT8;
/* NOTE:
* FchInitLateHwm will overwrite the EcStruct with EcDefaultMessage,
* AGESA put EcDefaultMessage as global data in ROM, so we can't override it.
* so we remove it from AGESA code. Please See FchInitLateHwm.
*/
} else {
/* HWM fan control, using the alternative method */
FchParams->Imc.ImcEnable = FALSE;
FchParams->Hwm.HwMonitorEnable = TRUE;
FchParams->Hwm.HwmFchtsiAutoPoll = TRUE; /* 1 enable, 0 disable TSI Auto Polling */
}
}
/**
* Fch Oem setting callback
*
* Configure platform specific Hudson device,
* such Azalia, SATA, IMC etc.
*/
static AGESA_STATUS Fch_Oem_config(UINT32 Func, UINTN FchData, VOID *ConfigPtr)
{
AMD_CONFIG_PARAMS *StdHeader = (AMD_CONFIG_PARAMS *)ConfigPtr;
if (StdHeader->Func == AMD_INIT_RESET) {
FCH_RESET_DATA_BLOCK *FchParams = (FCH_RESET_DATA_BLOCK *) FchData;
printk(BIOS_DEBUG, "Fch OEM config in INIT RESET ");
//FchParams_reset->EcChannel0 = TRUE; /* logical devicd 3 */
FchParams->LegacyFree = CONFIG_HUDSON_LEGACY_FREE;
FchParams->FchReset.SataEnable = hudson_sata_enable();
FchParams->FchReset.IdeEnable = hudson_ide_enable();
FchParams->FchReset.Xhci0Enable = IS_ENABLED(CONFIG_HUDSON_XHCI_ENABLE);
FchParams->FchReset.Xhci1Enable = FALSE;
} else if (StdHeader->Func == AMD_INIT_ENV) {
FCH_DATA_BLOCK *FchParams = (FCH_DATA_BLOCK *)FchData;
printk(BIOS_DEBUG, "Fch OEM config in INIT ENV ");
/* Azalia Controller OEM Codec Table Pointer */
FchParams->Azalia.AzaliaOemCodecTablePtr = (CODEC_TBL_LIST *)(&CodecTableList[0]);
/* Azalia Controller Front Panel OEM Table Pointer */
/* Fan Control */
oem_fan_control(FchParams);
/* XHCI configuration */
FchParams->Usb.Xhci0Enable = IS_ENABLED(CONFIG_HUDSON_XHCI_ENABLE);
FchParams->Usb.Xhci1Enable = FALSE;
/* sata configuration */
FchParams->Sata.SataClass = CONFIG_HUDSON_SATA_MODE;
switch ((SATA_CLASS)CONFIG_HUDSON_SATA_MODE) {
case SataRaid:
case SataAhci:
case SataAhci7804:
case SataLegacyIde:
FchParams->Sata.SataIdeMode = FALSE;
break;
case SataIde2Ahci:
case SataIde2Ahci7804:
default: /* SataNativeIde */
FchParams->Sata.SataIdeMode = TRUE;
break;
}
}
printk(BIOS_DEBUG, "Done\n");
return AGESA_SUCCESS;
}
static AGESA_STATUS board_ReadSpd_from_cbfs(UINT32 Func, UINTN Data, VOID *ConfigPtr)
{
AGESA_STATUS Status = AGESA_UNSUPPORTED;
#ifdef __PRE_RAM__
AGESA_READ_SPD_PARAMS *info = ConfigPtr;
u8 index;
if (IS_ENABLED(CONFIG_BAP_E21_DDR3_1066))
index = 1;
else if (IS_ENABLED(CONFIG_BAP_E21_DDR3_1333))
index = 2;
else /* CONFIG_BAP_E21_DDR3_800 */
index = 0;
if (info->MemChannelId > 0)
return AGESA_UNSUPPORTED;
if (info->SocketId != 0)
return AGESA_UNSUPPORTED;
if (info->DimmId != 0)
return AGESA_UNSUPPORTED;
/* Read index 0, first SPD_SIZE bytes of spd.bin file. */
if (read_ddr3_spd_from_cbfs((u8 *)info->Buffer, index) < 0)
die("No SPD data\n");
Status = AGESA_SUCCESS;
#endif
return Status;
}