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Atmosphere/fusee_cpp/program/source/sdram/fusee_sdram.cpp
Michael Scire 80999988d4 fusee_cpp: skeleton the remaining code flow
2021-09-06 16:26:50 -07:00

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/*
* Copyright (c) 2018-2020 Atmosphère-NX
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope 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, see <http://www.gnu.org/licenses/>.
*/
#include <exosphere.hpp>
#include "fusee_sdram.hpp"
#include "../fusee_uncompress.hpp"
namespace ams::nxboot {
namespace {
template<fuse::SocType SocType>
struct SdramParamsImpl;
template<> struct SdramParamsImpl<fuse::SocType_Erista> { using Type = br::erista::BootSdramParams; };
template<> struct SdramParamsImpl<fuse::SocType_Mariko> { using Type = br::mariko::BootSdramParams; };
template<fuse::SocType SocType>
using BootSdramParams = SdramParamsImpl<SocType>::Type;
constexpr inline const uintptr_t CLKRST = secmon::MemoryRegionPhysicalDeviceClkRst.GetAddress();
constexpr inline const uintptr_t PMC = secmon::MemoryRegionPhysicalDevicePmc.GetAddress();
constexpr inline const uintptr_t APB = secmon::MemoryRegionPhysicalDeviceApbMisc.GetAddress();
constexpr inline const uintptr_t MC = secmon::MemoryRegionPhysicalDeviceMemoryController.GetAddress();
constexpr inline const uintptr_t EMC = EMC_ADDRESS(0);
constexpr inline const uintptr_t AHB = AHB_ARBC(0);
#include "fusee_sdram_params.inc"
#include "fusee_sdram_params_lp0_erista.inc"
#include "fusee_sdram_params_lp0_mariko.inc"
void *GetSdramParams(fuse::SocType soc_type) {
/* Get DRAM Id. */
const auto dram_id = fuse::GetDramId();
/* Extract to work buffer. */
void *sdram_params_work_buffer;
if (soc_type == fuse::SocType_Erista) {
sdram_params_work_buffer = reinterpret_cast<void *>(0x4003E000 - 2 * sizeof(BootSdramParams<fuse::SocType_Erista>));
#define HANDLE_DRAM_CASE(_DRAM_ID_, _INDEX_) \
case _DRAM_ID_: \
Uncompress(sdram_params_work_buffer, 2 * sizeof(BootSdramParams<fuse::SocType_Erista>), SdramParamsErista##_INDEX_, SdramParamsSizeErista##_INDEX_); \
if (_INDEX_ & 1) { \
sdram_params_work_buffer = reinterpret_cast<void *>(reinterpret_cast<uintptr_t>(sdram_params_work_buffer) + sizeof(BootSdramParams<fuse::SocType_Erista>)); \
} \
break;
switch (dram_id) {
HANDLE_DRAM_CASE(0, 0)
HANDLE_DRAM_CASE(1, 1)
HANDLE_DRAM_CASE(2, 2)
HANDLE_DRAM_CASE(3, 3)
HANDLE_DRAM_CASE(4, 4)
HANDLE_DRAM_CASE(5, 5)
HANDLE_DRAM_CASE(6, 6)
default:
AMS_ABORT("Invalid DRAM id");
}
#undef HANDLE_DRAM_CASE
return static_cast<BootSdramParams<fuse::SocType_Erista> *>(sdram_params_work_buffer);
} else /* if (soc_type == fuse::SocType_Mariko) */ {
sdram_params_work_buffer = reinterpret_cast<void *>(0x4003E000 - 2 * sizeof(BootSdramParams<fuse::SocType_Mariko>));
#define HANDLE_DRAM_CASE(_DRAM_ID_, _INDEX_) \
case _DRAM_ID_: \
Uncompress(sdram_params_work_buffer, 2 * sizeof(BootSdramParams<fuse::SocType_Mariko>), SdramParamsMariko##_INDEX_, SdramParamsSizeMariko##_INDEX_); \
if (_INDEX_ & 1) { \
sdram_params_work_buffer = reinterpret_cast<void *>(reinterpret_cast<uintptr_t>(sdram_params_work_buffer) + sizeof(BootSdramParams<fuse::SocType_Mariko>)); \
} \
break;
switch (dram_id) {
HANDLE_DRAM_CASE( 3, 12)
HANDLE_DRAM_CASE( 7, 0)
HANDLE_DRAM_CASE( 8, 1)
HANDLE_DRAM_CASE( 9, 2)
HANDLE_DRAM_CASE(10, 3)
HANDLE_DRAM_CASE(11, 4)
HANDLE_DRAM_CASE(12, 1)
HANDLE_DRAM_CASE(13, 2)
HANDLE_DRAM_CASE(14, 3)
HANDLE_DRAM_CASE(15, 4)
HANDLE_DRAM_CASE(16, 5)
HANDLE_DRAM_CASE(17, 6)
HANDLE_DRAM_CASE(18, 7)
HANDLE_DRAM_CASE(19, 6)
HANDLE_DRAM_CASE(20, 8)
HANDLE_DRAM_CASE(21, 9)
HANDLE_DRAM_CASE(22, 10)
HANDLE_DRAM_CASE(23, 7)
HANDLE_DRAM_CASE(24, 6)
HANDLE_DRAM_CASE(25, 11)
HANDLE_DRAM_CASE(26, 11)
HANDLE_DRAM_CASE(27, 11)
HANDLE_DRAM_CASE(28, 7)
default:
AMS_ABORT("Invalid DRAM id");
}
#undef HANDLE_DRAM_CASE
return static_cast<BootSdramParams<fuse::SocType_Mariko> *>(sdram_params_work_buffer);
}
}
template<fuse::SocType SocType>
void SpareWrite(u32 reg, u32 value) {
if (reg) {
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(reinterpret_cast<volatile u32 *>(reg), value);
} else if constexpr (SocType == fuse::SocType_Mariko) {
/* TODO: Validate the write. */
reg::Write(reinterpret_cast<volatile u32 *>(reg), value);
}
}
}
template<fuse::SocType SocType>
void InitializeSdramImpl(BootSdramParams<SocType> *params) {
/* Perform initial soc-specific setup. */
if constexpr (SocType == fuse::SocType_Erista) {
/* Enable sel_dpd on unused pins. */
reg::Write(PMC + APBDEV_PMC_IO_DPD3_REQ, (((params->EmcPmcScratch1 & 0x3FFFFFFF) | 0x80000000) ^ 0xFFFF) & 0xC000FFFF);
util::WaitMicroSeconds(params->PmcIoDpd3ReqWait);
/* Disable e_dpd_vttgen. */
u32 dpd4 = (params->EmcPmcScratch2 & 0x3FFFFFFF) | 0x80000000;
reg::Write(PMC + APBDEV_PMC_IO_DPD4_REQ, (dpd4 ^ 0x3FFF0000) & 0xFFFF0000);
util::WaitMicroSeconds(params->PmcIoDpd4ReqWait);
/* Disable e_dpd_bg. */
reg::Write(PMC + APBDEV_PMC_IO_DPD4_REQ, (dpd4 ^ 0x0000FFFF) & 0xC000FFFF);
util::WaitMicroSeconds(params->PmcIoDpd4ReqWait);
reg::Write(PMC + APBDEV_PMC_WEAK_BIAS, 0);
util::WaitMicroSeconds(1);
/* Enable memory clock. */
{
/* Initialize pllm. */
{
reg::Write(CLKRST + CLK_RST_CONTROLLER_PLLM_MISC1, params->PllMSetupControl);
reg::Write(CLKRST + CLK_RST_CONTROLLER_PLLM_MISC2, 0);
reg::Write(CLKRST + CLK_RST_CONTROLLER_PLLM_BASE, CLK_RST_REG_BITS_ENUM (PLLM_BASE_PLLM_ENABLE, DISABLE),
CLK_RST_REG_BITS_VALUE(PLLM_BASE_PLLM_DIVP, params->PllMPostDivider),
CLK_RST_REG_BITS_VALUE(PLLM_BASE_PLLM_DIVN, params->PllMFeedbackDivider),
CLK_RST_REG_BITS_VALUE(PLLM_BASE_PLLM_DIVM, params->PllMInputDivider));
reg::Write(CLKRST + CLK_RST_CONTROLLER_PLLM_BASE, CLK_RST_REG_BITS_ENUM (PLLM_BASE_PLLM_ENABLE, ENABLE),
CLK_RST_REG_BITS_VALUE(PLLM_BASE_PLLM_DIVP, params->PllMPostDivider),
CLK_RST_REG_BITS_VALUE(PLLM_BASE_PLLM_DIVN, params->PllMFeedbackDivider),
CLK_RST_REG_BITS_VALUE(PLLM_BASE_PLLM_DIVM, params->PllMInputDivider));
/* Wait 300us for stability. */
const auto stable_time = util::GetMicroSeconds() + 300;
while (true) {
if (reg::HasValue(CLKRST + CLK_RST_CONTROLLER_PLLM_BASE, CLK_RST_REG_BITS_ENUM(PLLM_BASE_PLLM_LOCK, LOCK))) {
util::WaitMicroSeconds(10);
break;
}
if (util::GetMicroSeconds() >= stable_time) {
break;
}
}
}
/* Set CLK_SOURCE_EMC, using McEmcmArbMisc0 as MC_EMC_SAME_FREQ. */
reg::Write(CLKRST + CLK_RST_CONTROLLER_CLK_SOURCE_EMC, (params->EmcClockSource & ~0x10000) | ((params->McEmemArbMisc0 >> 11) & 0x10000));
if (params->EmcClockSourceDll) {
reg::Write(CLKRST + CLK_RST_CONTROLLER_CLK_SOURCE_EMC_DLL, params->EmcClockSourceDll);
}
if (params->ClearClk2Mc1) {
reg::Write(CLKRST + CLK_RST_CONTROLLER_CLK_ENB_W_CLR, CLK_RST_REG_BITS_ENUM(CLK_ENB_W_CLK_ENB_MC1, ENABLE));
}
/* Enable EMC/Mem. */
reg::Write(CLKRST + CLK_RST_CONTROLLER_CLK_ENB_H_SET, CLK_RST_REG_BITS_ENUM(CLK_ENB_H_CLK_ENB_EMC, ENABLE),
CLK_RST_REG_BITS_ENUM(CLK_ENB_H_CLK_ENB_MEM, ENABLE));
/* Enable EMC DLL. */
reg::Write(CLKRST + CLK_RST_CONTROLLER_CLK_ENB_X_SET, CLK_RST_REG_BITS_ENUM(CLK_ENB_X_CLK_ENB_EMC_DLL, ENABLE));
}
/* Clear reset for MEM/EMC. */
reg::Write(CLKRST + CLK_RST_CONTROLLER_RST_DEV_H_CLR, CLK_RST_REG_BITS_ENUM(RST_DEV_H_EMC_RST, ENABLE),
CLK_RST_REG_BITS_ENUM(RST_DEV_H_MEM_RST, ENABLE));
/* Set pad macros. */
reg::Write(EMC + EMC_PMACRO_VTTGEN_CTRL_0, params->EmcPmacroVttgenCtrl0);
reg::Write(EMC + EMC_PMACRO_VTTGEN_CTRL_1, params->EmcPmacroVttgenCtrl1);
reg::Write(EMC + EMC_PMACRO_VTTGEN_CTRL_2, params->EmcPmacroVttgenCtrl2);
reg::Write(EMC + EMC_TIMING_CONTROL, 1);
util::WaitMicroSeconds(1);
/* Select EMC write mux. */
reg::Write(EMC + EMC_DBG, params->EmcDbg | reg::EncodeValue(EMC_REG_BITS_VALUE(DBG_WRITE_MUX, params->EmcDbgWriteMux)));
/* Patch 2. */
SpareWrite<SocType>(params->EmcBctSpare2, params->EmcBctSpare3);
} else if constexpr (SocType == fuse::SocType_Mariko) {
/* Patch 1 */
SpareWrite<SocType>(params->EmcBctSpare0, params->EmcBctSpare1);
if (params->ClkRstControllerPllmMisc2OverrideEnable) {
reg::Write(CLKRST + CLK_RST_CONTROLLER_PLLM_MISC2, params->ClkRstControllerPllmMisc2Override);
}
/* Enable sel_dpd on unused pins. */
{
u32 val = (~params->EmcPmcScratch1 & 0x00000FFF) << 18;
val |= ((~params->EmcPmcScratch1 & 0x00001000) << 19) | ((~params->EmcPmcScratch1 & 0x00008000) << 15);
reg::Write(PMC + APBDEV_PMC_WEAK_BIAS, val);
}
reg::Write(PMC + APBDEV_PMC_IO_DPD3_REQ, 0x80000000 | (~params->EmcPmcScratch1 & 0x00009FFF));
util::WaitMicroSeconds(params->PmcIoDpd3ReqWait);
/* Disable e_dpd_vttgen. */
reg::Write(PMC + APBDEV_PMC_IO_DPD4_REQ, 0x80000000 | (~params->EmcPmcScratch2 & 0x3FFF0000));
util::WaitMicroSeconds(params->PmcIoDpd4ReqWait);
/* Disable e_dpd_bg. */
reg::Write(PMC + APBDEV_PMC_IO_DPD4_REQ, 0x80000000 | (~params->EmcPmcScratch2 & 0x00001FFF));
util::WaitMicroSeconds(1);
}
/* Common phase 1. */
/* Program CMD mapping. */
reg::Write(EMC + EMC_FBIO_CFG7, params->EmcFbioCfg7);
reg::Write(EMC + EMC_CMD_MAPPING_CMD0_0, params->EmcCmdMappingCmd0_0);
reg::Write(EMC + EMC_CMD_MAPPING_CMD0_1, params->EmcCmdMappingCmd0_1);
reg::Write(EMC + EMC_CMD_MAPPING_CMD0_2, params->EmcCmdMappingCmd0_2);
reg::Write(EMC + EMC_CMD_MAPPING_CMD1_0, params->EmcCmdMappingCmd1_0);
reg::Write(EMC + EMC_CMD_MAPPING_CMD1_1, params->EmcCmdMappingCmd1_1);
reg::Write(EMC + EMC_CMD_MAPPING_CMD1_2, params->EmcCmdMappingCmd1_2);
reg::Write(EMC + EMC_CMD_MAPPING_CMD2_0, params->EmcCmdMappingCmd2_0);
reg::Write(EMC + EMC_CMD_MAPPING_CMD2_1, params->EmcCmdMappingCmd2_1);
reg::Write(EMC + EMC_CMD_MAPPING_CMD2_2, params->EmcCmdMappingCmd2_2);
reg::Write(EMC + EMC_CMD_MAPPING_CMD3_0, params->EmcCmdMappingCmd3_0);
reg::Write(EMC + EMC_CMD_MAPPING_CMD3_1, params->EmcCmdMappingCmd3_1);
reg::Write(EMC + EMC_CMD_MAPPING_CMD3_2, params->EmcCmdMappingCmd3_2);
reg::Write(EMC + EMC_CMD_MAPPING_BYTE, params->EmcCmdMappingByte);
/* Program brick mapping. */
reg::Write(EMC + EMC_PMACRO_BRICK_MAPPING_0, params->EmcPmacroBrickMapping0);
reg::Write(EMC + EMC_PMACRO_BRICK_MAPPING_1, params->EmcPmacroBrickMapping1);
reg::Write(EMC + EMC_PMACRO_BRICK_MAPPING_2, params->EmcPmacroBrickMapping2);
/* Specific phase 2. */
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(EMC + EMC_PMACRO_BRICK_CTRL_RFU1, (params->EmcPmacroBrickCtrlRfu1 | ~0x01120112) & 0x1FFF1FFF);
} else if constexpr (SocType == fuse::SocType_Mariko) {
/* Set pad macros. */
reg::Write(EMC + EMC_PMACRO_VTTGEN_CTRL_0, params->EmcPmacroVttgenCtrl0);
reg::Write(EMC + EMC_PMACRO_VTTGEN_CTRL_1, params->EmcPmacroVttgenCtrl1);
reg::Write(EMC + EMC_PMACRO_VTTGEN_CTRL_2, params->EmcPmacroVttgenCtrl2);
/* Set pad macro bias. */
reg::Write(EMC + EMC_PMACRO_BG_BIAS_CTRL_0, params->EmcPmacroBgBiasCtrl0);
SpareWrite<SocType>(params->EmcBctSpareSecure0, params->EmcBctSpareSecure1);
SpareWrite<SocType>(params->EmcBctSpareSecure2, params->EmcBctSpareSecure3);
SpareWrite<SocType>(params->EmcBctSpareSecure4, params->EmcBctSpareSecure5);
/* Trigger timing update. */
reg::Write(EMC + EMC_TIMING_CONTROL, 1);
util::WaitMicroSeconds(params->PmcVddpSelWait + 2);
/* Set clock sources. */
reg::Write(CLKRST + CLK_RST_CONTROLLER_CLK_SOURCE_EMC, params->EmcClockSource);
reg::Write(CLKRST + CLK_RST_CONTROLLER_CLK_SOURCE_EMC_DLL, params->EmcClockSourceDll);
/* Select EMC write mux. */
reg::Write(EMC + EMC_DBG, params->EmcDbg | reg::EncodeValue(EMC_REG_BITS_VALUE(DBG_WRITE_MUX, params->EmcDbgWriteMux)));
/* Patch 2. */
SpareWrite<SocType>(params->EmcBctSpare2, params->EmcBctSpare3);
}
/* Common phase 2. */
reg::Write(EMC + EMC_CONFIG_SAMPLE_DELAY, params->EmcConfigSampleDelay);
reg::Write(EMC + EMC_FBIO_CFG8, params->EmcFbioCfg8);
/* Program swizzle registers. */
reg::Write(EMC + EMC_SWIZZLE_RANK0_BYTE0, params->EmcSwizzleRank0Byte0);
reg::Write(EMC + EMC_SWIZZLE_RANK0_BYTE1, params->EmcSwizzleRank0Byte1);
reg::Write(EMC + EMC_SWIZZLE_RANK0_BYTE2, params->EmcSwizzleRank0Byte2);
reg::Write(EMC + EMC_SWIZZLE_RANK0_BYTE3, params->EmcSwizzleRank0Byte3);
reg::Write(EMC + EMC_SWIZZLE_RANK1_BYTE0, params->EmcSwizzleRank1Byte0);
reg::Write(EMC + EMC_SWIZZLE_RANK1_BYTE1, params->EmcSwizzleRank1Byte1);
reg::Write(EMC + EMC_SWIZZLE_RANK1_BYTE2, params->EmcSwizzleRank1Byte2);
reg::Write(EMC + EMC_SWIZZLE_RANK1_BYTE3, params->EmcSwizzleRank1Byte3);
/* Patch 3. */
SpareWrite<SocType>(params->EmcBctSpare6, params->EmcBctSpare7);
/* Program pad controls. */
reg::Write(EMC + EMC_XM2COMPPADCTRL, params->EmcXm2CompPadCtrl);
reg::Write(EMC + EMC_XM2COMPPADCTRL2, params->EmcXm2CompPadCtrl2);
reg::Write(EMC + EMC_XM2COMPPADCTRL3, params->EmcXm2CompPadCtrl3);
/* Program autocal controls with shadowed register fields. */
reg::Write(EMC + EMC_AUTO_CAL_CONFIG2, params->EmcAutoCalConfig2);
reg::Write(EMC + EMC_AUTO_CAL_CONFIG3, params->EmcAutoCalConfig3);
reg::Write(EMC + EMC_AUTO_CAL_CONFIG4, params->EmcAutoCalConfig4);
reg::Write(EMC + EMC_AUTO_CAL_CONFIG5, params->EmcAutoCalConfig5);
reg::Write(EMC + EMC_AUTO_CAL_CONFIG6, params->EmcAutoCalConfig6);
reg::Write(EMC + EMC_AUTO_CAL_CONFIG7, params->EmcAutoCalConfig7);
reg::Write(EMC + EMC_AUTO_CAL_CONFIG8, params->EmcAutoCalConfig8);
reg::Write(EMC + EMC_PMACRO_RX_TERM, params->EmcPmacroRxTerm);
reg::Write(EMC + EMC_PMACRO_DQ_TX_DRV, params->EmcPmacroDqTxDrv);
reg::Write(EMC + EMC_PMACRO_CA_TX_DRV, params->EmcPmacroCaTxDrv);
reg::Write(EMC + EMC_PMACRO_CMD_TX_DRV, params->EmcPmacroCmdTxDrv);
reg::Write(EMC + EMC_PMACRO_AUTOCAL_CFG_COMMON, params->EmcPmacroAutocalCfgCommon);
reg::Write(EMC + EMC_AUTO_CAL_CHANNEL, params->EmcAutoCalChannel);
reg::Write(EMC + EMC_PMACRO_ZCTRL, params->EmcPmacroZctrl);
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(EMC + EMC_DLL_CFG_0, params->EmcDllCfg0);
reg::Write(EMC + EMC_DLL_CFG_1, params->EmcDllCfg1);
} else if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(EMC + EMC_PMACRO_DLL_CFG_0, params->EmcPmacroDllCfg0);
reg::Write(EMC + EMC_PMACRO_DLL_CFG_1, params->EmcPmacroDllCfg1);
}
reg::Write(EMC + EMC_CFG_DIG_DLL_1, params->EmcCfgDigDll_1);
reg::Write(EMC + EMC_DATA_BRLSHFT_0, params->EmcDataBrlshft0);
reg::Write(EMC + EMC_DATA_BRLSHFT_1, params->EmcDataBrlshft1);
reg::Write(EMC + EMC_DQS_BRLSHFT_0, params->EmcDqsBrlshft0);
reg::Write(EMC + EMC_DQS_BRLSHFT_1, params->EmcDqsBrlshft1);
reg::Write(EMC + EMC_CMD_BRLSHFT_0, params->EmcCmdBrlshft0);
reg::Write(EMC + EMC_CMD_BRLSHFT_1, params->EmcCmdBrlshft1);
reg::Write(EMC + EMC_CMD_BRLSHFT_2, params->EmcCmdBrlshft2);
reg::Write(EMC + EMC_CMD_BRLSHFT_3, params->EmcCmdBrlshft3);
reg::Write(EMC + EMC_QUSE_BRLSHFT_0, params->EmcQuseBrlshft0);
reg::Write(EMC + EMC_QUSE_BRLSHFT_1, params->EmcQuseBrlshft1);
reg::Write(EMC + EMC_QUSE_BRLSHFT_2, params->EmcQuseBrlshft2);
reg::Write(EMC + EMC_QUSE_BRLSHFT_3, params->EmcQuseBrlshft3);
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(EMC + EMC_PMACRO_BRICK_CTRL_RFU1, (params->EmcPmacroBrickCtrlRfu1 | ~0x01BF01BF) & 0x1FFF1FFF);
} else if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(EMC + EMC_PMACRO_BRICK_CTRL_RFU1, params->EmcPmacroBrickCtrlRfu1);
}
reg::Write(EMC + EMC_PMACRO_PAD_CFG_CTRL, params->EmcPmacroPadCfgCtrl);
reg::Write(EMC + EMC_PMACRO_CMD_BRICK_CTRL_FDPD, params->EmcPmacroCmdBrickCtrlFdpd);
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(EMC + EMC_PMACRO_BRICK_CTRL_RFU2, params->EmcPmacroBrickCtrlRfu2 & 0xFF7FFF7F);
} else if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(EMC + EMC_PMACRO_BRICK_CTRL_RFU2, params->EmcPmacroBrickCtrlRfu2);
}
reg::Write(EMC + EMC_PMACRO_DATA_BRICK_CTRL_FDPD, params->EmcPmacroDataBrickCtrlFdpd);
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(EMC + EMC_PMACRO_BG_BIAS_CTRL_0, params->EmcPmacroBgBiasCtrl0);
}
reg::Write(EMC + EMC_PMACRO_DATA_PAD_RX_CTRL, params->EmcPmacroDataPadRxCtrl);
reg::Write(EMC + EMC_PMACRO_CMD_PAD_RX_CTRL, params->EmcPmacroCmdPadRxCtrl);
reg::Write(EMC + EMC_PMACRO_DATA_PAD_TX_CTRL, params->EmcPmacroDataPadTxCtrl);
reg::Write(EMC + EMC_PMACRO_DATA_RX_TERM_MODE, params->EmcPmacroDataRxTermMode);
reg::Write(EMC + EMC_PMACRO_CMD_RX_TERM_MODE, params->EmcPmacroCmdRxTermMode);
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(EMC + EMC_PMACRO_CMD_PAD_TX_CTRL, params->EmcPmacroCmdPadTxCtrl);
} else if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(EMC + EMC_PMACRO_CMD_PAD_TX_CTRL, params->EmcPmacroCmdPadTxCtrl & 0xEFFFFFFF);
}
reg::Write(EMC + EMC_CFG_3, params->EmcCfg3);
reg::Write(EMC + EMC_PMACRO_TX_PWRD_0, params->EmcPmacroTxPwrd0);
reg::Write(EMC + EMC_PMACRO_TX_PWRD_1, params->EmcPmacroTxPwrd1);
reg::Write(EMC + EMC_PMACRO_TX_PWRD_2, params->EmcPmacroTxPwrd2);
reg::Write(EMC + EMC_PMACRO_TX_PWRD_3, params->EmcPmacroTxPwrd3);
reg::Write(EMC + EMC_PMACRO_TX_PWRD_4, params->EmcPmacroTxPwrd4);
reg::Write(EMC + EMC_PMACRO_TX_PWRD_5, params->EmcPmacroTxPwrd5);
reg::Write(EMC + EMC_PMACRO_TX_SEL_CLK_SRC_0, params->EmcPmacroTxSelClkSrc0);
reg::Write(EMC + EMC_PMACRO_TX_SEL_CLK_SRC_1, params->EmcPmacroTxSelClkSrc1);
reg::Write(EMC + EMC_PMACRO_TX_SEL_CLK_SRC_2, params->EmcPmacroTxSelClkSrc2);
reg::Write(EMC + EMC_PMACRO_TX_SEL_CLK_SRC_3, params->EmcPmacroTxSelClkSrc3);
reg::Write(EMC + EMC_PMACRO_TX_SEL_CLK_SRC_4, params->EmcPmacroTxSelClkSrc4);
reg::Write(EMC + EMC_PMACRO_TX_SEL_CLK_SRC_5, params->EmcPmacroTxSelClkSrc5);
if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(EMC + EMC_PMACRO_PERBIT_FGCG_CTRL_0, params->EmcPmacroPerbitFgcgCtrl0);
reg::Write(EMC + EMC_PMACRO_PERBIT_FGCG_CTRL_1, params->EmcPmacroPerbitFgcgCtrl1);
reg::Write(EMC + EMC_PMACRO_PERBIT_FGCG_CTRL_2, params->EmcPmacroPerbitFgcgCtrl2);
reg::Write(EMC + EMC_PMACRO_PERBIT_FGCG_CTRL_3, params->EmcPmacroPerbitFgcgCtrl3);
reg::Write(EMC + EMC_PMACRO_PERBIT_FGCG_CTRL_4, params->EmcPmacroPerbitFgcgCtrl4);
reg::Write(EMC + EMC_PMACRO_PERBIT_FGCG_CTRL_5, params->EmcPmacroPerbitFgcgCtrl5);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU_CTRL_0, params->EmcPmacroPerbitRfuCtrl0);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU_CTRL_1, params->EmcPmacroPerbitRfuCtrl1);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU_CTRL_2, params->EmcPmacroPerbitRfuCtrl2);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU_CTRL_3, params->EmcPmacroPerbitRfuCtrl3);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU_CTRL_4, params->EmcPmacroPerbitRfuCtrl4);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU_CTRL_5, params->EmcPmacroPerbitRfuCtrl5);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU1_CTRL_0, params->EmcPmacroPerbitRfu1Ctrl0);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU1_CTRL_1, params->EmcPmacroPerbitRfu1Ctrl1);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU1_CTRL_2, params->EmcPmacroPerbitRfu1Ctrl2);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU1_CTRL_3, params->EmcPmacroPerbitRfu1Ctrl3);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU1_CTRL_4, params->EmcPmacroPerbitRfu1Ctrl4);
reg::Write(EMC + EMC_PMACRO_PERBIT_RFU1_CTRL_5, params->EmcPmacroPerbitRfu1Ctrl5);
reg::Write(EMC + EMC_PMACRO_DATA_PI_CTRL, params->EmcPmacroDataPiCtrl);
reg::Write(EMC + EMC_PMACRO_CMD_PI_CTRL, params->EmcPmacroCmdPiCtrl);
}
reg::Write(EMC + EMC_PMACRO_DDLL_BYPASS, params->EmcPmacroDdllBypass);
reg::Write(EMC + EMC_PMACRO_DDLL_PWRD_0, params->EmcPmacroDdllPwrd0);
reg::Write(EMC + EMC_PMACRO_DDLL_PWRD_1, params->EmcPmacroDdllPwrd1);
reg::Write(EMC + EMC_PMACRO_DDLL_PWRD_2, params->EmcPmacroDdllPwrd2);
reg::Write(EMC + EMC_PMACRO_CMD_CTRL_0, params->EmcPmacroCmdCtrl0);
reg::Write(EMC + EMC_PMACRO_CMD_CTRL_1, params->EmcPmacroCmdCtrl1);
reg::Write(EMC + EMC_PMACRO_CMD_CTRL_2, params->EmcPmacroCmdCtrl2);
reg::Write(EMC + EMC_PMACRO_IB_VREF_DQ_0, params->EmcPmacroIbVrefDq_0);
reg::Write(EMC + EMC_PMACRO_IB_VREF_DQ_1, params->EmcPmacroIbVrefDq_1);
reg::Write(EMC + EMC_PMACRO_IB_VREF_DQS_0, params->EmcPmacroIbVrefDqs_0);
reg::Write(EMC + EMC_PMACRO_IB_VREF_DQS_1, params->EmcPmacroIbVrefDqs_1);
reg::Write(EMC + EMC_PMACRO_IB_RXRT, params->EmcPmacroIbRxrt);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK0_0, params->EmcPmacroQuseDdllRank0_0);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK0_1, params->EmcPmacroQuseDdllRank0_1);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK0_2, params->EmcPmacroQuseDdllRank0_2);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK0_3, params->EmcPmacroQuseDdllRank0_3);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK0_4, params->EmcPmacroQuseDdllRank0_4);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK0_5, params->EmcPmacroQuseDdllRank0_5);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK1_0, params->EmcPmacroQuseDdllRank1_0);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK1_1, params->EmcPmacroQuseDdllRank1_1);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK1_2, params->EmcPmacroQuseDdllRank1_2);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK1_3, params->EmcPmacroQuseDdllRank1_3);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK1_4, params->EmcPmacroQuseDdllRank1_4);
reg::Write(EMC + EMC_PMACRO_QUSE_DDLL_RANK1_5, params->EmcPmacroQuseDdllRank1_5);
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(EMC + EMC_PMACRO_BRICK_CTRL_RFU1, params->EmcPmacroBrickCtrlRfu1);
}
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_0, params->EmcPmacroObDdllLongDqRank0_0);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_1, params->EmcPmacroObDdllLongDqRank0_1);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_2, params->EmcPmacroObDdllLongDqRank0_2);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_3, params->EmcPmacroObDdllLongDqRank0_3);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_4, params->EmcPmacroObDdllLongDqRank0_4);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK0_5, params->EmcPmacroObDdllLongDqRank0_5);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_0, params->EmcPmacroObDdllLongDqRank1_0);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_1, params->EmcPmacroObDdllLongDqRank1_1);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_2, params->EmcPmacroObDdllLongDqRank1_2);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_3, params->EmcPmacroObDdllLongDqRank1_3);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_4, params->EmcPmacroObDdllLongDqRank1_4);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQ_RANK1_5, params->EmcPmacroObDdllLongDqRank1_5);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK0_0, params->EmcPmacroObDdllLongDqsRank0_0);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK0_1, params->EmcPmacroObDdllLongDqsRank0_1);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK0_2, params->EmcPmacroObDdllLongDqsRank0_2);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK0_3, params->EmcPmacroObDdllLongDqsRank0_3);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK0_4, params->EmcPmacroObDdllLongDqsRank0_4);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK0_5, params->EmcPmacroObDdllLongDqsRank0_5);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK1_0, params->EmcPmacroObDdllLongDqsRank1_0);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK1_1, params->EmcPmacroObDdllLongDqsRank1_1);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK1_2, params->EmcPmacroObDdllLongDqsRank1_2);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK1_3, params->EmcPmacroObDdllLongDqsRank1_3);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK1_4, params->EmcPmacroObDdllLongDqsRank1_4);
reg::Write(EMC + EMC_PMACRO_OB_DDLL_LONG_DQS_RANK1_5, params->EmcPmacroObDdllLongDqsRank1_5);
reg::Write(EMC + EMC_PMACRO_IB_DDLL_LONG_DQS_RANK0_0, params->EmcPmacroIbDdllLongDqsRank0_0);
reg::Write(EMC + EMC_PMACRO_IB_DDLL_LONG_DQS_RANK0_1, params->EmcPmacroIbDdllLongDqsRank0_1);
reg::Write(EMC + EMC_PMACRO_IB_DDLL_LONG_DQS_RANK0_2, params->EmcPmacroIbDdllLongDqsRank0_2);
reg::Write(EMC + EMC_PMACRO_IB_DDLL_LONG_DQS_RANK0_3, params->EmcPmacroIbDdllLongDqsRank0_3);
reg::Write(EMC + EMC_PMACRO_IB_DDLL_LONG_DQS_RANK1_0, params->EmcPmacroIbDdllLongDqsRank1_0);
reg::Write(EMC + EMC_PMACRO_IB_DDLL_LONG_DQS_RANK1_1, params->EmcPmacroIbDdllLongDqsRank1_1);
reg::Write(EMC + EMC_PMACRO_IB_DDLL_LONG_DQS_RANK1_2, params->EmcPmacroIbDdllLongDqsRank1_2);
reg::Write(EMC + EMC_PMACRO_IB_DDLL_LONG_DQS_RANK1_3, params->EmcPmacroIbDdllLongDqsRank1_3);
reg::Write(EMC + EMC_PMACRO_DDLL_LONG_CMD_0, params->EmcPmacroDdllLongCmd_0);
reg::Write(EMC + EMC_PMACRO_DDLL_LONG_CMD_1, params->EmcPmacroDdllLongCmd_1);
reg::Write(EMC + EMC_PMACRO_DDLL_LONG_CMD_2, params->EmcPmacroDdllLongCmd_2);
reg::Write(EMC + EMC_PMACRO_DDLL_LONG_CMD_3, params->EmcPmacroDdllLongCmd_3);
reg::Write(EMC + EMC_PMACRO_DDLL_LONG_CMD_4, params->EmcPmacroDdllLongCmd_4);
reg::Write(EMC + EMC_PMACRO_DDLL_SHORT_CMD_0, params->EmcPmacroDdllShortCmd_0);
reg::Write(EMC + EMC_PMACRO_DDLL_SHORT_CMD_1, params->EmcPmacroDdllShortCmd_1);
reg::Write(EMC + EMC_PMACRO_DDLL_SHORT_CMD_2, params->EmcPmacroDdllShortCmd_2);
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(EMC + EMC_PMACRO_COMMON_PAD_TX_CTRL, (params->EmcPmacroCommonPadTxCtrl | ~0x1) & 0xF);
} else if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(EMC + EMC_PMACRO_DDLL_PERIODIC_OFFSET, params->EmcPmacroDdllPeriodicOffset);
}
if constexpr (SocType == fuse::SocType_Erista) {
SpareWrite<SocType>(params->EmcBctSpare4, params->EmcBctSpare5);
} else if constexpr (SocType == fuse::SocType_Mariko) {
SpareWrite<SocType>(params->EmcBctSpare4, params->EmcBctSpare5);
SpareWrite<SocType>(params->EmcBctSpareSecure6, params->EmcBctSpareSecure7);
SpareWrite<SocType>(params->EmcBctSpareSecure8, params->EmcBctSpareSecure9);
SpareWrite<SocType>(params->EmcBctSpareSecure10, params->EmcBctSpareSecure11);
}
reg::Write(EMC + EMC_TIMING_CONTROL, 1);
/* Initialize MC VPR settings. */
reg::Write(MC + MC_VIDEO_PROTECT_BOM, params->McVideoProtectBom);
reg::Write(MC + MC_VIDEO_PROTECT_BOM_ADR_HI, params->McVideoProtectBomAdrHi);
reg::Write(MC + MC_VIDEO_PROTECT_SIZE_MB, params->McVideoProtectSizeMb);
reg::Write(MC + MC_VIDEO_PROTECT_VPR_OVERRIDE, params->McVideoProtectVprOverride);
reg::Write(MC + MC_VIDEO_PROTECT_VPR_OVERRIDE1, params->McVideoProtectVprOverride1);
reg::Write(MC + MC_VIDEO_PROTECT_GPU_OVERRIDE_0, params->McVideoProtectGpuOverride0);
reg::Write(MC + MC_VIDEO_PROTECT_GPU_OVERRIDE_1, params->McVideoProtectGpuOverride1);
/* Program SDRAM geometry parameters. */
reg::Write(MC + MC_EMEM_ADR_CFG, params->McEmemAdrCfg);
reg::Write(MC + MC_EMEM_ADR_CFG_DEV0, params->McEmemAdrCfgDev0);
reg::Write(MC + MC_EMEM_ADR_CFG_DEV1, params->McEmemAdrCfgDev1);
reg::Write(MC + MC_EMEM_ADR_CFG_CHANNEL_MASK, params->McEmemAdrCfgChannelMask);
/* Program bank swizzling. */
reg::Write(MC + MC_EMEM_ADR_CFG_BANK_MASK_0, params->McEmemAdrCfgBankMask0);
reg::Write(MC + MC_EMEM_ADR_CFG_BANK_MASK_1, params->McEmemAdrCfgBankMask1);
reg::Write(MC + MC_EMEM_ADR_CFG_BANK_MASK_2, params->McEmemAdrCfgBankMask2);
/* Program external memory aperture (base and size). */
reg::Write(MC + MC_EMEM_CFG, params->McEmemCfg);
/* Program SEC carveout (base and size). */
reg::Write(MC + MC_SEC_CARVEOUT_BOM, params->McSecCarveoutBom);
reg::Write(MC + MC_SEC_CARVEOUT_ADR_HI, params->McSecCarveoutAdrHi);
reg::Write(MC + MC_SEC_CARVEOUT_SIZE_MB, params->McSecCarveoutSizeMb);
/* Program MTS carveout (base and size). */
reg::Write(MC + MC_MTS_CARVEOUT_BOM, params->McMtsCarveoutBom);
reg::Write(MC + MC_MTS_CARVEOUT_ADR_HI, params->McMtsCarveoutAdrHi);
reg::Write(MC + MC_MTS_CARVEOUT_SIZE_MB, params->McMtsCarveoutSizeMb);
/* Program the memory arbiter. */
reg::Write(MC + MC_EMEM_ARB_CFG, params->McEmemArbCfg);
reg::Write(MC + MC_EMEM_ARB_OUTSTANDING_REQ, params->McEmemArbOutstandingReq);
reg::Write(MC + MC_EMEM_ARB_REFPB_HP_CTRL, params->McEmemArbRefpbHpCtrl);
reg::Write(MC + MC_EMEM_ARB_REFPB_BANK_CTRL, params->McEmemArbRefpbBankCtrl);
reg::Write(MC + MC_EMEM_ARB_TIMING_RCD, params->McEmemArbTimingRcd);
reg::Write(MC + MC_EMEM_ARB_TIMING_RP, params->McEmemArbTimingRp);
reg::Write(MC + MC_EMEM_ARB_TIMING_RC, params->McEmemArbTimingRc);
reg::Write(MC + MC_EMEM_ARB_TIMING_RAS, params->McEmemArbTimingRas);
reg::Write(MC + MC_EMEM_ARB_TIMING_FAW, params->McEmemArbTimingFaw);
reg::Write(MC + MC_EMEM_ARB_TIMING_RRD, params->McEmemArbTimingRrd);
reg::Write(MC + MC_EMEM_ARB_TIMING_RAP2PRE, params->McEmemArbTimingRap2Pre);
reg::Write(MC + MC_EMEM_ARB_TIMING_WAP2PRE, params->McEmemArbTimingWap2Pre);
reg::Write(MC + MC_EMEM_ARB_TIMING_R2R, params->McEmemArbTimingR2R);
reg::Write(MC + MC_EMEM_ARB_TIMING_W2W, params->McEmemArbTimingW2W);
reg::Write(MC + MC_EMEM_ARB_TIMING_CCDMW, params->McEmemArbTimingCcdmw);
reg::Write(MC + MC_EMEM_ARB_TIMING_R2W, params->McEmemArbTimingR2W);
reg::Write(MC + MC_EMEM_ARB_TIMING_W2R, params->McEmemArbTimingW2R);
reg::Write(MC + MC_EMEM_ARB_TIMING_RFCPB, params->McEmemArbTimingRFCPB);
reg::Write(MC + MC_EMEM_ARB_DA_TURNS, params->McEmemArbDaTurns);
reg::Write(MC + MC_EMEM_ARB_DA_COVERS, params->McEmemArbDaCovers);
reg::Write(MC + MC_EMEM_ARB_MISC0, params->McEmemArbMisc0);
reg::Write(MC + MC_EMEM_ARB_MISC1, params->McEmemArbMisc1);
reg::Write(MC + MC_EMEM_ARB_MISC2, params->McEmemArbMisc2);
reg::Write(MC + MC_EMEM_ARB_RING1_THROTTLE, params->McEmemArbRing1Throttle);
reg::Write(MC + MC_EMEM_ARB_OVERRIDE, params->McEmemArbOverride);
reg::Write(MC + MC_EMEM_ARB_OVERRIDE_1, params->McEmemArbOverride1);
reg::Write(MC + MC_EMEM_ARB_RSV, params->McEmemArbRsv);
reg::Write(MC + MC_DA_CONFIG0, params->McDaCfg0);
/* Trigger MC timing update. */
reg::Write(MC + MC_TIMING_CONTROL, 1);
/* Program second-level clock enable overrides. */
reg::Write(MC + MC_CLKEN_OVERRIDE, params->McClkenOverride);
/* Program statistics gathering. */
reg::Write(MC + MC_STAT_CONTROL, params->McStatControl);
/* Program SDRAM geometry parameters. */
reg::Write(EMC + EMC_ADR_CFG, params->EmcAdrCfg);
/* Program second-level clock enable overrides. */
reg::Write(EMC + EMC_CLKEN_OVERRIDE, params->EmcClkenOverride);
/* Program EMC pad auto calibration. */
reg::Write(EMC + EMC_PMACRO_AUTOCAL_CFG_0, params->EmcPmacroAutocalCfg0);
reg::Write(EMC + EMC_PMACRO_AUTOCAL_CFG_1, params->EmcPmacroAutocalCfg1);
reg::Write(EMC + EMC_PMACRO_AUTOCAL_CFG_2, params->EmcPmacroAutocalCfg2);
reg::Write(EMC + EMC_AUTO_CAL_VREF_SEL_0, params->EmcAutoCalVrefSel0);
reg::Write(EMC + EMC_AUTO_CAL_VREF_SEL_1, params->EmcAutoCalVrefSel1);
reg::Write(EMC + EMC_AUTO_CAL_INTERVAL, params->EmcAutoCalInterval);
reg::Write(EMC + EMC_AUTO_CAL_CONFIG, params->EmcAutoCalConfig);
util::WaitMicroSeconds(params->EmcAutoCalWait);
/* Patch 5. */
if constexpr (SocType == fuse::SocType_Erista) {
SpareWrite<SocType>(params->EmcBctSpare8, params->EmcBctSpare9);
} else if constexpr (SocType == fuse::SocType_Mariko) {
SpareWrite<SocType>(params->EmcBctSpare8, params->EmcBctSpare9);
reg::Write(EMC + EMC_AUTO_CAL_CONFIG9, params->EmcAutoCalConfig9);
}
/* Program EMC timing configuration. */
reg::Write(EMC + EMC_CFG_2, params->EmcCfg2);
reg::Write(EMC + EMC_CFG_PIPE, params->EmcCfgPipe);
reg::Write(EMC + EMC_CFG_PIPE_1, params->EmcCfgPipe1);
reg::Write(EMC + EMC_CFG_PIPE_2, params->EmcCfgPipe2);
reg::Write(EMC + EMC_CMDQ, params->EmcCmdQ);
reg::Write(EMC + EMC_MC2EMCQ, params->EmcMc2EmcQ);
reg::Write(EMC + EMC_MRS_WAIT_CNT, params->EmcMrsWaitCnt);
reg::Write(EMC + EMC_MRS_WAIT_CNT2, params->EmcMrsWaitCnt2);
reg::Write(EMC + EMC_FBIO_CFG5, params->EmcFbioCfg5);
reg::Write(EMC + EMC_RC, params->EmcRc);
reg::Write(EMC + EMC_RFC, params->EmcRfc);
reg::Write(EMC + EMC_RFCPB, params->EmcRfcPb);
reg::Write(EMC + EMC_REFCTRL2, params->EmcRefctrl2);
reg::Write(EMC + EMC_RFC_SLR, params->EmcRfcSlr);
reg::Write(EMC + EMC_RAS, params->EmcRas);
reg::Write(EMC + EMC_RP, params->EmcRp);
reg::Write(EMC + EMC_TPPD, params->EmcTppd);
if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(EMC + EMC_TRTM, params->EmcTrtm);
reg::Write(EMC + EMC_TWTM, params->EmcTwtm);
reg::Write(EMC + EMC_TRATM, params->EmcTratm);
reg::Write(EMC + EMC_TWATM, params->EmcTwatm);
reg::Write(EMC + EMC_TR2REF, params->EmcTr2ref);
}
reg::Write(EMC + EMC_R2R, params->EmcR2r);
reg::Write(EMC + EMC_W2W, params->EmcW2w);
reg::Write(EMC + EMC_R2W, params->EmcR2w);
reg::Write(EMC + EMC_W2R, params->EmcW2r);
reg::Write(EMC + EMC_R2P, params->EmcR2p);
reg::Write(EMC + EMC_W2P, params->EmcW2p);
reg::Write(EMC + EMC_CCDMW, params->EmcCcdmw);
reg::Write(EMC + EMC_RD_RCD, params->EmcRdRcd);
reg::Write(EMC + EMC_WR_RCD, params->EmcWrRcd);
reg::Write(EMC + EMC_RRD, params->EmcRrd);
reg::Write(EMC + EMC_REXT, params->EmcRext);
reg::Write(EMC + EMC_WEXT, params->EmcWext);
reg::Write(EMC + EMC_WDV, params->EmcWdv);
reg::Write(EMC + EMC_WDV_CHK, params->EmcWdvChk);
reg::Write(EMC + EMC_WSV, params->EmcWsv);
reg::Write(EMC + EMC_WEV, params->EmcWev);
reg::Write(EMC + EMC_WDV_MASK, params->EmcWdvMask);
reg::Write(EMC + EMC_WS_DURATION, params->EmcWsDuration);
reg::Write(EMC + EMC_WE_DURATION, params->EmcWeDuration);
reg::Write(EMC + EMC_QUSE, params->EmcQUse);
reg::Write(EMC + EMC_QUSE_WIDTH, params->EmcQuseWidth);
reg::Write(EMC + EMC_IBDLY, params->EmcIbdly);
reg::Write(EMC + EMC_OBDLY, params->EmcObdly);
reg::Write(EMC + EMC_EINPUT, params->EmcEInput);
reg::Write(EMC + EMC_EINPUT_DURATION, params->EmcEInputDuration);
reg::Write(EMC + EMC_PUTERM_EXTRA, params->EmcPutermExtra);
reg::Write(EMC + EMC_PUTERM_WIDTH, params->EmcPutermWidth);
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(EMC + EMC_PMACRO_COMMON_PAD_TX_CTRL, params->EmcPmacroCommonPadTxCtrl);
}
reg::Write(EMC + EMC_DBG, params->EmcDbg);
reg::Write(EMC + EMC_QRST, params->EmcQRst);
reg::Write(EMC + EMC_ISSUE_QRST, 1);
reg::Write(EMC + EMC_ISSUE_QRST, 0);
reg::Write(EMC + EMC_QSAFE, params->EmcQSafe);
reg::Write(EMC + EMC_RDV, params->EmcRdv);
reg::Write(EMC + EMC_RDV_MASK, params->EmcRdvMask);
reg::Write(EMC + EMC_RDV_EARLY, params->EmcRdvEarly);
reg::Write(EMC + EMC_RDV_EARLY_MASK, params->EmcRdvEarlyMask);
reg::Write(EMC + EMC_QPOP, params->EmcQpop);
reg::Write(EMC + EMC_REFRESH, params->EmcRefresh);
reg::Write(EMC + EMC_BURST_REFRESH_NUM, params->EmcBurstRefreshNum);
reg::Write(EMC + EMC_PRE_REFRESH_REQ_CNT, params->EmcPreRefreshReqCnt);
reg::Write(EMC + EMC_PDEX2WR, params->EmcPdEx2Wr);
reg::Write(EMC + EMC_PDEX2RD, params->EmcPdEx2Rd);
reg::Write(EMC + EMC_PCHG2PDEN, params->EmcPChg2Pden);
reg::Write(EMC + EMC_ACT2PDEN, params->EmcAct2Pden);
reg::Write(EMC + EMC_AR2PDEN, params->EmcAr2Pden);
reg::Write(EMC + EMC_RW2PDEN, params->EmcRw2Pden);
reg::Write(EMC + EMC_CKE2PDEN, params->EmcCke2Pden);
reg::Write(EMC + EMC_PDEX2CKE, params->EmcPdex2Cke);
reg::Write(EMC + EMC_PDEX2MRR, params->EmcPdex2Mrr);
reg::Write(EMC + EMC_TXSR, params->EmcTxsr);
reg::Write(EMC + EMC_TXSRDLL, params->EmcTxsrDll);
reg::Write(EMC + EMC_TCKE, params->EmcTcke);
reg::Write(EMC + EMC_TCKESR, params->EmcTckesr);
reg::Write(EMC + EMC_TPD, params->EmcTpd);
reg::Write(EMC + EMC_TFAW, params->EmcTfaw);
reg::Write(EMC + EMC_TRPAB, params->EmcTrpab);
reg::Write(EMC + EMC_TCLKSTABLE, params->EmcTClkStable);
reg::Write(EMC + EMC_TCLKSTOP, params->EmcTClkStop);
reg::Write(EMC + EMC_TREFBW, params->EmcTRefBw);
reg::Write(EMC + EMC_ODT_WRITE, params->EmcOdtWrite);
reg::Write(EMC + EMC_CFG_DIG_DLL, params->EmcCfgDigDll);
reg::Write(EMC + EMC_CFG_DIG_DLL_PERIOD, params->EmcCfgDigDllPeriod);
/* Lock bit written later for CFG_ADR_EN. */
reg::Write(EMC + EMC_FBIO_SPARE, params->EmcFbioSpare & 0xFFFFFFFD);
reg::Write(EMC + EMC_CFG_RSV, params->EmcCfgRsv);
reg::Write(EMC + EMC_PMC_SCRATCH1, params->EmcPmcScratch1);
reg::Write(EMC + EMC_PMC_SCRATCH2, params->EmcPmcScratch2);
reg::Write(EMC + EMC_PMC_SCRATCH3, params->EmcPmcScratch3);
reg::Write(EMC + EMC_ACPD_CONTROL, params->EmcAcpdControl);
reg::Write(EMC + EMC_TXDSRVTTGEN, params->EmcTxdsrvttgen);
if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(EMC + EMC_PMACRO_DSR_VTTGEN_CTRL_0, params->EmcPmacroDsrVttgenCtrl0);
}
/* Set pipe bypass enable bits before sending any DRAM commands. */
reg::Write(EMC + EMC_CFG, (params->EmcCfg * 0xE) | 0x03C00000);
/* Perform bootrom patch. */
if constexpr (SocType == fuse::SocType_Erista) {
if (params->BootRomPatchControl & 0x80000000) {
reg::Write(APB + ((params->BootRomPatchControl & 0x3FFFFFFF) << 2), params->BootRomPatchData);
reg::Write(MC + MC_TIMING_CONTROL, 1);
}
} else if constexpr (SocType == fuse::SocType_Mariko) {
if (params->BootRomPatchControl) {
SpareWrite<SocType>(params->BootRomPatchControl, params->BootRomPatchData);
reg::Write(MC + MC_TIMING_CONTROL, 1);
}
SpareWrite<SocType>(params->EmcBctSpareSecure12, params->EmcBctSpareSecure13);
SpareWrite<SocType>(params->EmcBctSpareSecure14, params->EmcBctSpareSecure15);
SpareWrite<SocType>(params->EmcBctSpareSecure16, params->EmcBctSpareSecure17);
}
/* Release SEL_DPD_CMD. */
reg::Write(PMC + APBDEV_PMC_IO_DPD3_REQ, ((params->EmcPmcScratch1 & 0x3FFFFFFF) | 0x40000000) & 0xCFFF0000);
util::WaitMicroSeconds(params->PmcIoDpd3ReqWait);
if constexpr (SocType == fuse::SocType_Erista) {
if (params->EmcAutoCalInterval == 0) {
reg::Write(EMC + EMC_AUTO_CAL_CONFIG, params->EmcAutoCalConfig | 0x200);
}
reg::Write(EMC + EMC_PMACRO_BRICK_CTRL_RFU2, params->EmcPmacroBrickCtrlRfu2);
} else if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(EMC + EMC_PMACRO_CMD_PAD_TX_CTRL, params->EmcPmacroCmdPadTxCtrl);
}
/* ZQ CAL setup */
if (params->EmcZcalWarmColdBootEnables & 1) {
if (params->MemoryType == br::BootMemoryType_Ddr3) {
reg::Write(EMC + EMC_ZCAL_WAIT_CNT, params->EmcZcalWaitCnt << 3);
} else if (params->MemoryType == br::BootMemoryType_LpDdr4) {
reg::Write(EMC + EMC_ZCAL_WAIT_CNT, params->EmcZcalWaitCnt);
reg::Write(EMC + EMC_ZCAL_MRW_CMD, params->EmcZcalMrwCmd);
}
}
/* Trigger timing update. */
reg::Write(EMC + EMC_TIMING_CONTROL, 1);
util::WaitMicroSeconds(params->EmcTimingControlWait);
/* Deassert HOLD_CKE_LOW. */
if constexpr (SocType == fuse::SocType_Erista) {
reg::ClearBits(PMC + APBDEV_PMC_DDR_CNTRL, ~0xFFF8007F);
} else if constexpr (SocType == fuse::SocType_Mariko) {
reg::ClearBits(PMC + APBDEV_PMC_DDR_CNTRL, ~0xFF78007F);
}
util::WaitMicroSeconds(params->PmcDdrCntrlWait);
/* Set clock enable signal. */
const u32 pin_gpio_cfg = (params->EmcPinGpioEn << 16) | (params->EmcPinGpio << 12);
if (params->MemoryType == br::BootMemoryType_Ddr3 || params->MemoryType == br::BootMemoryType_LpDdr4) {
reg::Write(EMC + EMC_PIN, pin_gpio_cfg);
reg::Read(EMC + EMC_PIN);
util::WaitMicroSeconds(200 + params->EmcPinExtraWait);
reg::Write(EMC + EMC_PIN, pin_gpio_cfg | 0x100);
reg::Read(EMC + EMC_PIN);
const u32 wait = params->MemoryType == br::BootMemoryType_Ddr3 ? 500 : 2000;
util::WaitMicroSeconds(wait + params->EmcPinExtraWait);
}
/* Set clock enable signal. */
reg::Write(EMC + EMC_PIN, pin_gpio_cfg | 0x101);
reg::Read(EMC + EMC_PIN);
util::WaitMicroSeconds(params->EmcPinProgramWait);
/* Send NOP */
if (params->MemoryType != br::BootMemoryType_LpDdr4) {
reg::Write(EMC + EMC_NOP, (params->EmcDevSelect << 30) | 1);
}
/* On coldboot with LPDDR2/3, wait 200us after asserting CKE high. */
if (params->MemoryType != br::BootMemoryType_LpDdr2) {
util::WaitMicroSeconds(200 + params->EmcPinExtraWait);
}
/* Init ZQ calibration. */
if (params->MemoryType == br::BootMemoryType_LpDdr4) {
SpareWrite<SocType>(params->EmcBctSpare10, params->EmcBctSpare11);
reg::Write(EMC + EMC_MRW2, params->EmcMrw2);
reg::Write(EMC + EMC_MRW, params->EmcMrw1);
reg::Write(EMC + EMC_MRW3, params->EmcMrw3);
reg::Write(EMC + EMC_MRW4, params->EmcMrw4);
reg::Write(EMC + EMC_MRW6, params->EmcMrw6);
reg::Write(EMC + EMC_MRW14, params->EmcMrw14);
reg::Write(EMC + EMC_MRW8, params->EmcMrw8);
reg::Write(EMC + EMC_MRW12, params->EmcMrw12);
reg::Write(EMC + EMC_MRW9, params->EmcMrw9);
reg::Write(EMC + EMC_MRW13, params->EmcMrw13);
if (params->EmcZcalWarmColdBootEnables & 1) {
/* Issue ZQCAL start, device 0. */
reg::Write(EMC + EMC_ZQ_CAL, params->EmcZcalInitDev0);
util::WaitMicroSeconds(params->EmcZcalInitWait);
/* Issue ZQCAL latch. */
reg::Write(EMC + EMC_ZQ_CAL, params->EmcZcalInitDev0 ^ 0x3);
/* Do the same for device 1. */
if ((params->EmcDevSelect & 2) == 0) {
reg::Write(EMC + EMC_ZQ_CAL, params->EmcZcalInitDev1);
util::WaitMicroSeconds(params->EmcZcalInitWait);
reg::Write(EMC + EMC_ZQ_CAL, params->EmcZcalInitDev1 ^ 0x3);
}
}
}
/* Patches 10-12. */
if constexpr (SocType == fuse::SocType_Mariko) {
SpareWrite<SocType>(params->EmcBctSpareSecure18, params->EmcBctSpareSecure19);
SpareWrite<SocType>(params->EmcBctSpareSecure20, params->EmcBctSpareSecure21);
SpareWrite<SocType>(params->EmcBctSpareSecure22, params->EmcBctSpareSecure23);
}
/* Set package and DPD pad control. */
reg::Write(PMC + APBDEV_PMC_DDR_CFG, params->PmcDdrCfg);
/* Start periodic ZQ calibration. */
if (params->MemoryType == br::BootMemoryType_LpDdr2 || params->MemoryType == br::BootMemoryType_Ddr3 || params->MemoryType == br::BootMemoryType_LpDdr4) {
reg::Write(EMC + EMC_ZCAL_INTERVAL, params->EmcZcalInterval);
reg::Write(EMC + EMC_ZCAL_WAIT_CNT, params->EmcZcalWaitCnt);
reg::Write(EMC + EMC_ZCAL_MRW_CMD, params->EmcZcalMrwCmd);
}
SpareWrite<SocType>(params->EmcBctSpare12, params->EmcBctSpare13);
/* Trigger timing update. */
reg::Write(EMC + EMC_TIMING_CONTROL, 1);
if (params->EmcExtraRefreshNum) {
reg::Write(EMC + EMC_REF, (params->EmcDevSelect << 30) | (((1 << params->EmcExtraRefreshNum) - 1) << 8) | 3);
}
/* Enable refresh. */
reg::Write(EMC + EMC_REFCTRL, params->EmcDevSelect | 0x80000000);
reg::Write(EMC + EMC_DYN_SELF_REF_CONTROL, params->EmcDynSelfRefControl);
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(EMC + EMC_CFG_UPDATE, params->EmcCfgUpdate);
}
reg::Write(EMC + EMC_CFG, params->EmcCfg);
reg::Write(EMC + EMC_FDPD_CTRL_DQ, params->EmcFdpdCtrlDq);
reg::Write(EMC + EMC_FDPD_CTRL_CMD, params->EmcFdpdCtrlCmd);
reg::Write(EMC + EMC_SEL_DPD_CTRL, params->EmcSelDpdCtrl);
/* Write addr swizzle lock bit. */
reg::Write(EMC + EMC_FBIO_SPARE, params->EmcFbioSpare | 2);
/* Trigger timing update. */
reg::Write(EMC + EMC_TIMING_CONTROL, 1);
if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(EMC + EMC_CFG_UPDATE, params->EmcCfgUpdate);
}
/* Enable EMC pipe clock gating. */
reg::Write(EMC + EMC_CFG_PIPE_CLK, params->EmcCfgPipeClk);
/* Depending on freqency, enable CMD/CLK fdpd. */
reg::Write(EMC + EMC_FDPD_CTRL_CMD_NO_RAMP, params->EmcFdpdCtrlCmdNoRamp);
if constexpr (SocType == fuse::SocType_Erista) {
reg::ReadWrite(AHB + AHB_ARBITRATION_XBAR_CTRL, AHB_REG_BITS_VALUE(ARBITRATION_XBAR_CTRL_MEM_INIT_DONE, params->AhbArbitrationXbarCtrlMemInitDone));
}
if constexpr (SocType == fuse::SocType_Mariko) {
reg::Write(MC + MC_UNTRANSLATED_REGION_CHECK, params->McUntranslatedRegionCheck);
}
/* Lock carveouts. */
reg::Write(MC + MC_VIDEO_PROTECT_REG_CTRL, params->McVideoProtectWriteAccess);
reg::Write(MC + MC_SEC_CARVEOUT_REG_CTRL, params->McSecCarveoutProtectWriteAccess);
reg::Write(MC + MC_MTS_CARVEOUT_REG_CTRL, params->McMtsCarveoutRegCtrl);
reg::Write(MC + MC_EMEM_CFG_ACCESS_CTRL, 1);
if constexpr (SocType == fuse::SocType_Mariko) {
reg::ReadWrite(AHB + AHB_ARBITRATION_XBAR_CTRL, AHB_REG_BITS_VALUE(ARBITRATION_XBAR_CTRL_MEM_INIT_DONE, params->AhbArbitrationXbarCtrlMemInitDone));
}
}
consteval u32 GetBitMask32(u32 range) {
if (range == BITSIZEOF(u32)) {
return 0xFFFFFFFF;
} else {
return (1u << range) - 1;
}
}
template<fuse::SocType SocType>
void SaveSdramParamsToScratch(BootSdramParams<SocType> *params) {
/* Clear the carveout parameters. */
params->McGeneralizedCarveout1Cfg0 = 0;
params->McGeneralizedCarveout2Cfg0 = 0;
params->McGeneralizedCarveout3Cfg0 = 0;
params->McGeneralizedCarveout4Cfg0 = 0;
params->McGeneralizedCarveout5Cfg0 = 0;
/* Patch spare write. */
{
/* TODO: Clean this up? */
u32 t0 = params->EmcSwizzleRank0Byte0 << 5 >> 29 > params->EmcSwizzleRank0Byte0 << 1 >> 29;
u32 t1 = (t0 & 0xFFFFFFEF) | ((params->EmcSwizzleRank1Byte0 << 5 >> 29 > params->EmcSwizzleRank1Byte0 << 1 >> 29) << 4);
u32 t2 = (t1 & 0xFFFFFFFD) | ((params->EmcSwizzleRank0Byte1 << 5 >> 29 > params->EmcSwizzleRank0Byte1 << 1 >> 29) << 1);
u32 t3 = (t2 & 0xFFFFFFDF) | ((params->EmcSwizzleRank1Byte1 << 5 >> 29 > params->EmcSwizzleRank1Byte1 << 1 >> 29) << 5);
u32 t4 = (t3 & 0xFFFFFFFB) | ((params->EmcSwizzleRank0Byte2 << 5 >> 29 > params->EmcSwizzleRank0Byte2 << 1 >> 29) << 2);
u32 t5 = (t4 & 0xFFFFFFBF) | ((params->EmcSwizzleRank1Byte2 << 5 >> 29 > params->EmcSwizzleRank1Byte2 << 1 >> 29) << 6);
u32 t6 = (t5 & 0xFFFFFFF7) | ((params->EmcSwizzleRank0Byte3 << 5 >> 29 > params->EmcSwizzleRank0Byte3 << 1 >> 29) << 3);
u32 t7 = (t6 & 0xFFFFFF7F) | ((params->EmcSwizzleRank1Byte3 << 5 >> 29 > params->EmcSwizzleRank1Byte3 << 1 >> 29) << 7);
params->SwizzleRankByteEncode = t7;
params->EmcBctSpare2 = 0x40000DD8;
params->EmcBctSpare3 = params->SwizzleRankByteEncode;
}
/* Save parameters to scratch. */
{
u32 cur_reg_offset = APBDEV_PMC_SCRATCH6;
u32 cur_reg_value = reg::Read(PMC + cur_reg_offset);
#define RANGE_HIGH(RANGE) (1 ? RANGE)
#define RANGE_LOW(RANGE) (0 ? RANGE)
static_assert(RANGE_HIGH(31:0) - RANGE_LOW(31:0) + 1 == BITSIZEOF(u32));
#define PROCESS_IMPL(PARAM, SCRATCH, SRC_RANGE, DST_RANGE, DO_READ) \
{ \
constexpr u32 RegisterOffset = APBDEV_PMC_##SCRATCH; \
\
if (RegisterOffset != cur_reg_offset) { \
reg::Write(PMC + cur_reg_offset, cur_reg_value); \
cur_reg_offset = RegisterOffset; \
if constexpr (DO_READ) { \
cur_reg_value = reg::Read(PMC + RegisterOffset); \
} else { \
cur_reg_value = 0; \
} \
} \
\
constexpr u32 SrcRange = RANGE_HIGH(SRC_RANGE) - RANGE_LOW(SRC_RANGE) + 1; \
constexpr u32 DstRange = RANGE_HIGH(DST_RANGE) - RANGE_LOW(DST_RANGE) + 1; \
static_assert(SrcRange == DstRange); \
static_assert(SrcRange <= BITSIZEOF(u32)); \
\
const u32 src_value = params->PARAM; \
if constexpr (SrcRange == BITSIZEOF(u32)) { \
cur_reg_value = src_value; \
} else if constexpr (SrcRange < BITSIZEOF(u32)) { \
constexpr u32 Mask = GetBitMask32(SrcRange) << RANGE_LOW(DST_RANGE); \
\
constexpr u32 SrcLow = RANGE_LOW(SRC_RANGE); \
constexpr u32 DstLow = RANGE_LOW(DST_RANGE); \
\
cur_reg_value &= ~Mask; \
if constexpr (SrcLow == DstLow) { \
cur_reg_value |= (src_value & Mask); \
} else if constexpr (SrcLow < DstLow) { \
cur_reg_value |= ((src_value << (DstLow - SrcLow)) & Mask); \
} else { \
cur_reg_value |= ((src_value >> (SrcLow - DstLow)) & Mask); \
} \
} \
}
#define PROCESS_SCRATCH(PARAM, S, SRC_RANGE, DST_RANGE) PROCESS_IMPL(PARAM, SCRATCH##S, SRC_RANGE, DST_RANGE, true)
#define PROCESS_SECURE_SCRATCH(PARAM, S, SRC_RANGE, DST_RANGE) PROCESS_IMPL(PARAM, SECURE_SCRATCH##S, SRC_RANGE, DST_RANGE, true)
#define PROCESS_COMMON_SCRATCH(PARAM, S, SRC_RANGE, DST_RANGE) PROCESS_IMPL(PARAM, SCRATCH##S, SRC_RANGE, DST_RANGE, false)
if constexpr (SocType == fuse::SocType_Erista) {
FOREACH_SDRAM_SCRATCH_REGISTER_ERISTA(PROCESS_SCRATCH);
FOREACH_SDRAM_SECURE_SCRATCH_REGISTER_ERISTA(PROCESS_SECURE_SCRATCH);
} else /* if constexpr (SocType == fuse::SocType_Mariko) */ {
FOREACH_SDRAM_SCRATCH_REGISTER_MARIKO(PROCESS_SCRATCH);
FOREACH_SDRAM_SECURE_SCRATCH_REGISTER_MARIKO(PROCESS_SECURE_SCRATCH);
}
/* Manually process final fields. */
PROCESS_COMMON_SCRATCH(PllMInputDivider, 2, 7:0, 7:0);
PROCESS_COMMON_SCRATCH(PllMFeedbackDivider, 2, 7:0, 15:8);
PROCESS_COMMON_SCRATCH(PllMPostDivider, 2, 4:0, 20:16);
PROCESS_COMMON_SCRATCH(PllMKVCO, 2, 0:0, 17:17);
PROCESS_COMMON_SCRATCH(PllMKCP, 2, 1:0, 19:18);
PROCESS_COMMON_SCRATCH(PllMSetupControl, 35, 15:0, 15:0);
PROCESS_COMMON_SCRATCH(PllMInputDivider, 3, 7:0, 7:0);
cur_reg_value |= 0x3E << 8;
PROCESS_COMMON_SCRATCH(PllMKVCO, 3, 0:0, 21:21);
PROCESS_COMMON_SCRATCH(PllMKCP, 3, 1:0, 23:22);
PROCESS_COMMON_SCRATCH(PllMSetupControl, 36, 23:0, 23:0);
PROCESS_COMMON_SCRATCH(PllMStableTime, 4, 9:0, 9:0);
PROCESS_COMMON_SCRATCH(PllMStableTime, 4, 21:0, 31:10);
/* Write the final field value. */
reg::Write(PMC + cur_reg_offset, cur_reg_value);
#undef PROCESS_COMMON_SCRATCH
#undef PROCESS_SECURE_SCRATCH
#undef PROCESS_SCRATCH
#undef PROCESS_IMPL
#undef RANGE_LOW
#undef RANGE_HIGH
}
}
template<fuse::SocType SocType>
void InitializeSdram(void *generic_params) {
/* Get converted parameters. */
auto *sdram_params = static_cast<BootSdramParams<SocType> *>(generic_params);
/* Enable VDD Memory */
pmic::EnableVddMemory(SocType);
/* Set VDDP select. */
reg::Write(PMC + APBDEV_PMC_VDDP_SEL, sdram_params->PmcVddpSel);
util::WaitMicroSeconds(sdram_params->PmcVddpSelWait);
/* If Erista, Set DDR pad voltage. */
if constexpr (SocType == fuse::SocType_Erista) {
reg::Write(PMC + APBDEV_PMC_DDR_PWR, reg::Read(PMC + APBDEV_PMC_DDR_PWR));
}
/* Turn on MEM IO power. */
reg::Write(PMC + APBDEV_PMC_NO_IOPOWER, sdram_params->PmcNoIoPower);
reg::Write(PMC + APBDEV_PMC_REG_SHORT, sdram_params->PmcRegShort);
reg::Write(PMC + APBDEV_PMC_DDR_CNTRL, sdram_params->PmcDdrCntrl);
/* Apply patch 1. */
*reinterpret_cast<volatile u32 *>(sdram_params->EmcBctSpare0) = sdram_params->EmcBctSpare1;
/* Do main init. */
InitializeSdramImpl<SocType>(sdram_params);
/* Save parameters to scratch. */
SaveSdramParamsToScratch<SocType>(sdram_params);
}
}
void InitializeSdram() {
/* Get soc type. */
const auto soc_type = fuse::GetSocType();
/* Get Sdram params. */
void *sdram_params = GetSdramParams(soc_type);
/* Perform SoC-specific init. */
if (soc_type == fuse::SocType_Erista) {
InitializeSdram<fuse::SocType_Erista>(sdram_params);
} else /* if (soc_type == fuse::SocType_Mariko) */ {
InitializeSdram<fuse::SocType_Mariko>(sdram_params);
}
/* Lock DRAM scratch. */
pmc::LockSecureRegister(pmc::SecureRegister_DramParameters);
}
}
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