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Add AUTO_ADJ for erista

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This commit is contained in:
Lightos1
2025-09-30 22:30:27 +02:00
parent e5f4a19a4a
commit ad212a15c0
4 changed files with 101 additions and 214 deletions
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1
Source/Atmosphere/stratosphere/loader/source/oc/customize.cpp
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@@ -91,7 +91,6 @@ volatile CustomizeTable C = {
.marikoGpuUV = 0,
.eristaCpuUV = 0,
.eristaGpuUV = 0,

6
Source/Atmosphere/stratosphere/loader/source/oc/customize.hpp
View File

@@ -30,11 +30,7 @@
#include "mtc_timing_table.hpp"
enum MtcConfig: u32 {
AUTO_ADJ_ALL = 0,
CUSTOM_ADJ_ALL = 1,
NO_ADJ_ALL = 2,
CUSTOMIZED_ALL = 4,
AUTO_ADJ = 0,
};
using CustomizeCpuDvfsTable = pcv::cvb_entry_t[pcv::DvfsTableEntryLimit];

150
Source/Atmosphere/stratosphere/loader/source/oc/mtc_timing_value.hpp
View File

@@ -21,35 +21,35 @@
#pragma once
#include "oc_common.hpp"
namespace ams::ldr::oc {
#define MAX(A, B) std::max(A, B)
#define MIN(A, B) std::min(A, B)
#define CEIL(A) std::ceil(A)
#define FLOOR(A) std::floor(A)
//Preset One
const std::array<u32, 8> tRCD_values = {18, 17, 16, 15, 14, 13, 12, 11};
const std::array<u32, 8> tRP_values = {18, 17, 16, 15, 14, 13, 12, 11};
const std::array<u32, 10> tRAS_values = {42, 36, 34, 32, 30, 28, 26, 24, 22, 20};
// Preset Two
const std::array<double, 8> tRRD_values = {10, 7.5, 6, 5, 4, 3, 2, 1};
const std::array<double, 5> tFAW_values = {40, 30, 24, 16, 12};
// Preset Three
const std::array<u32, 6> tWR_values = {18, 15, 15, 12, 12, 8}; // TODO: identify what exactly eos tRTW even is (is it even real?)
const std::array<double, 6> tRTP_values = {7.5, 7.5, 6, 6, 4, 4};
// Preset Four
const std::array<u32, 6> tRFC_values = {140, 120, 100, 80, 70, 60};
// Preset Five
const std::array<u32, 10> tWTR_values = {10, 9, 8, 7, 6, 5, 4, 3, 2, 1};
// Preset Six
const std::array<u32, 6> tREFpb_values = {488, 976, 1952, 3256, 9999, 9999};
// const u32 TIMING_PRESET_ONE = C.ramTimingPresetOne;
// const u32 TIMING_PRESET_TWO = C.ramTimingPresetTwo;
const u32 TIMING_PRESET_THREE = 0;
@@ -57,138 +57,137 @@
// const u32 TIMING_PRESET_FIVE = C.ramTimingPresetFive;
// const u32 TIMING_PRESET_SIX = C.ramTimingPresetSix;
// const u32 TIMING_PRESET_SEVEN = C.ramTimingPresetSeven;
// Burst Length
const u32 BL = 16;
// tRFCpb (refresh cycle time per bank) in ns for 8Gb density
const u32 tRFCpb = !C.t5_tRFC ? 140 : tRFC_values[C.t5_tRFC-1];
// tRFCab (refresh cycle time all banks) in ns for 8Gb density
const u32 tRFCab = !C.t5_tRFC ? 280 : 2*tRFCpb;
// tRAS (row active time) in ns
const u32 tRAS = !C.t3_tRAS ? 42 : tRAS_values[C.t3_tRAS-1];
// tRPpb (row precharge time per bank) in ns
const u32 tRPpb = !C.t2_tRP ? 18 : tRP_values[C.t2_tRP-1];
// tRPab (row precharge time all banks) in ns
const u32 tRPab = !C.t2_tRP ? 21 : tRPpb + 3;
// tRC (ACTIVATE-ACTIVATE command period same bank) in ns
const u32 tRC = tRPpb + tRAS;
const u32 tRTW = !C.t6_tRTW ? 10 : tWTR_values[C.t6_tRTW-1];
// DQS output access time from CK_t/CK_c
const double tDQSCK_min = 1.5;
const double tDQSCK_min = 1.5; // TODO: Fix/remove for mariko if needed
// DQS output access time from CK_t/CK_c
const double tDQSCK_max = 3.5;
const double tDQSCK_max = 3.5; // TODO: Fix/remove for mariko if needed
// Write preamble (tCK)
const double tWPRE = 1.8;
const double tWPRE = 1.8; // TODO: Fix/remove for mariko if needed
// Read postamble (tCK)
const double tRPST = 0.4;
const double tRPST = 0.4; // TODO: Fix/remove for mariko if needed
// WRITE command to first DQS transition(max) (tCK)
const double tDQSS_max = 1.25;
const double tDQSS_max = 1.25; // TODO: Fix/remove for mariko if needed
// DQ-to-DQS offset(max) (ns)
const double tDQS2DQ_max = 0.8;
const double tDQS2DQ_max = 0.8; // TODO: Fix/remove for mariko if needed
// DQS_t, DQS_c to DQ skew total, per group, per access (DBI Disabled)
const double tDQSQ = 0.18;
const double tDQSQ = 0.18; // TODO: Fix/remove for mariko if needed
// Write-to-Read delay
const u32 tWTR = !C.t7_tWTR ? 10 : tWTR_values[C.t7_tWTR-1];
// Internal READ-to-PRE-CHARGE command delay in ns
const double tRTP = !TIMING_PRESET_THREE ? 7.5 : tRTP_values[TIMING_PRESET_THREE-1];
// write recovery time
const u32 tWR = !TIMING_PRESET_THREE ? 18 : tWR_values[TIMING_PRESET_THREE-1];
// Read to refresh delay
const u32 tR2REF = tRTP + tRPpb;
// tRCD (RAS-CAS delay) in ns
const u32 tRCD = !C.t1_tRCD ? 18 : tRCD_values[C.t1_tRCD-1];
// tRRD (Active bank-A to Active bank-B) in ns
const double tRRD = !C.t4_tRRD ? 10. : tRRD_values[C.t4_tRRD-1];
// tREFpb (average refresh interval per bank) in ns for 8Gb density
const u32 tREFpb = !C.t8_tREFI ? 488 : tREFpb_values[C.t8_tREFI-1];
// tREFab (average refresh interval all 8 banks) in ns for 8Gb density
// const u32 tREFab = tREFpb * 8;
// tPDEX2WR, tPDEX2RD (timing delay from exiting powerdown mode to a write/read command) in ns
// const u32 tPDEX2 = 10;
// Exit power-down to next valid command delay
const double tXP = 10;
// Delay from valid command to CKE input LOW in ns
const double tCMDCKE = 1.75;
const double tCMDCKE = 1.75; // TODO: Fix/remove for mariko if needed
// tACT2PDEN (timing delay from an activate, MRS or EMRS command to power-down entry) in ns
// Valid clock and CS requirement after CKE input LOW after MRW command
const u32 tMRWCKEL = 14;
const u32 tMRWCKEL = 14; // TODO: Fix/remove for mariko if needed
// Valid CS requirement after CKE input LOW
const double tCKELCS = 5;
const double tCKELCS = 5; // TODO: Fix/remove for mariko if needed
// Valid CS requirement before CKE input HIGH
const double tCSCKEH = 1.75;
const double tCSCKEH = 1.75; // TODO: Fix/remove for mariko if needed
// tXSR (SELF REFRESH exit to next valid command delay) in ns
const double tXSR = tRFCab + 7.5;
// tCKE (minimum pulse width(HIGH and LOW pulse width)) in ns
const double tCKE = 7.5;
const double tCKE = 7.5; // TODO: Fix/remove for mariko if needed
// Minimum self refresh time (entry to exit)
const u32 tSR = 15;
// tFAW (Four-bank Activate Window) in ns
const u32 tFAW = 40;// !TIMING_PRESET_TWO ? 40 : tFAW_values[TIMING_PRESET_TWO-1]; TOGO
// Valid Clock requirement before CKE Input HIGH in ns
const double tCKCKEH = 1.75;
const double tCKCKEH = 1.75; // TODO: Fix/remove for mariko if needed
// p78 The first valid data is available RL × t CK + t DQSCK + t DQSQ
//const u32 QUSE = RL + CEIL(tDQSCK_min/tCK_avg + tDQSQ);
namespace pcv::erista {
// tCK_avg (average clock period) in ns
const double tCK_avg = 1000'000. / C.eristaEmcMaxClock;
// Write Latency
const u32 WL = 14 + C.mem_burst_latency;
// Read Latency
const u32 RL = 32 - C.mem_burst_latency;
// minimum number of cycles from any read command to any write command, irrespective of bank
const u32 R2W = CEIL (RL + CEIL(tDQSCK_max/tCK_avg) + BL/2 - WL + tWPRE + FLOOR(tRPST)) + 6;
// const u32 R2W = CEIL (RL + CEIL(tDQSCK_max/tCK_avg) + BL/2 - WL + tWPRE + FLOOR(tRPST)) + 6;
// Delay Time From WRITE-to-READ
const u32 W2R = WL + BL/2 + 1 + CEIL(tWTR/tCK_avg) - 6;
// const u32 W2R = WL + BL/2 + 1 + CEIL(tWTR/tCK_avg) - 6;
// write-to-precharge time for commands to the same bank in cycles
const u32 WTP = WL + BL/2 + 1 + CEIL(tWR/tCK_avg) - 8;
// #_of_rows per die for 8Gb density
const u32 numOfRows = 65536;
// const u32 WTP = WL + BL/2 + 1 + CEIL(tWR/tCK_avg) - 8;
// #_of_rows per die for 16Gb density
const u32 numOfRows = 131072;
// {REFRESH, REFRESH_LO} = max[(tREF/#_of_rows) / (emc_clk_period) - 64, (tREF/#_of_rows) / (emc_clk_period) * 97%]
// emc_clk_period = dram_clk / 2;
// 1600 MHz: 5894, but N' set to 6176 (~4.8% margin)
const u32 REFRESH = MIN((u32)65472, u32(std::ceil((double(tREFpb) * C.eristaEmcMaxClock / numOfRows * 1.048 / 2 - 64))) / 4 * 4);
const u32 REFBW = MIN((u32)65536, REFRESH+64);
// Write With Auto Precharge to to Power-Down Entry
const u32 WTPDEN = WTP + 1 + CEIL(tDQSS_max/tCK_avg) + CEIL(tDQS2DQ_max/tCK_avg) + 6;
// const u32 WTPDEN = WTP + 1 + CEIL(tDQSS_max/tCK_avg) + CEIL(tDQS2DQ_max/tCK_avg) + 6;
// Additional time after t XP hasexpired until the MRR commandmay be issued
const double tMRRI = tRCD + 3 * tCK_avg;
// const double tMRRI = tRCD + 3 * tCK_avg;
// tPDEX2MRR (timing delay from exiting powerdown mode to MRR command) in ns
const double tPDEX2MRR = tXP + tMRRI;
// const double tPDEX2MRR = tXP + tMRRI;
}
namespace pcv::mariko {
// tCK_avg (average clock period) in ns
@@ -197,28 +196,28 @@
const u32 WL = 14 + C.mem_burst_latency;
// Read Latency
const u32 RL = 32 - C.mem_burst_latency;
// minimum number of cycles from any read command to any write command, irrespective of bank
const u32 R2W = WL + BL/2 + 1 + CEIL(tRTW/tCK_avg);
// Delay Time From WRITE-to-READ
const u32 W2R = WL + BL/2 + 1 + CEIL(tWTR/tCK_avg);
// write-to-precharge time for commands to the same bank in cycles
const u32 WTP = WL + BL/2 + 1 + CEIL(tWR/tCK_avg);
// Read-To-MRW delay
const u32 RTM = RL + BL/2 + CEIL(tDQSCK_max/tCK_avg) + FLOOR(tRPST) + CEIL(7.5/tCK_avg);
// Write-To-MRW/MRR delay
const u32 WTM = WL + 1 + BL/2 + CEIL(7.5/tCK_avg);
// Read With AP-To-MRW/MRR delay
const u32 RATM = RTM + CEIL(tRTP/tCK_avg) - 8;
// Write With AP-To-MRW/MRR delay
const u32 WATM = WTM + CEIL(tWR/tCK_avg);
// #_of_rows per die for 8Gb density
const u32 numOfRows = 65536;
// {REFRESH, REFRESH_LO} = max[(tREF/#_of_rows) / (emc_clk_period) - 64, (tREF/#_of_rows) / (emc_clk_period) * 97%]
@@ -226,15 +225,14 @@
// 1600 MHz: 5894, but N' set to 6176 (~4.8% margin)
const u32 REFRESH = MIN((u32)65472, u32(std::ceil((double(tREFpb) * C.marikoEmcMaxClock / numOfRows * 1.048 / 2 - 64))) / 4 * 4);
const u32 REFBW = MIN((u32)65536, REFRESH+64);
// Write With Auto Precharge to to Power-Down Entry
const u32 WTPDEN = WTP + 1 + CEIL(tDQSS_max/tCK_avg) + CEIL(tDQS2DQ_max/tCK_avg) + 6;
// Additional time after t XP hasexpired until the MRR commandmay be issued
const double tMRRI = tRCD + 3 * tCK_avg;
// tPDEX2MRR (timing delay from exiting powerdown mode to MRR command) in ns
const double tPDEX2MRR = tXP + tMRRI;
}
}

158
Source/Atmosphere/stratosphere/loader/source/oc/pcv/pcv_erista.cpp
View File

@@ -21,8 +21,7 @@
#include "pcv.hpp"
#include "../mtc_timing_value.hpp"
namespace ams::ldr::oc::pcv::erista
{
namespace ams::ldr::oc::pcv::erista {
Result CpuFreqVdd(u32* ptr) {
dvfs_rail* entry = reinterpret_cast<dvfs_rail *>(reinterpret_cast<u8 *>(ptr) - offsetof(dvfs_rail, freq));
@@ -43,18 +42,15 @@
R_SUCCEED();
}
Result GpuVmin(u32 *ptr)
{
Result GpuVmin(u32 *ptr) {
if (!C.eristaGpuVmin)
R_SKIP();
PATCH_OFFSET(ptr, (int)C.eristaGpuVmin);
R_SUCCEED();
}
Result CpuVoltRange(u32 *ptr)
{
Result CpuVoltRange(u32 *ptr) {
u32 min_volt_got = *(ptr - 1);
for (const auto &mv : CpuMinVolts)
{
for (const auto &mv : CpuMinVolts) {
if (min_volt_got != mv)
continue;
@@ -107,8 +103,7 @@
R_SUCCEED();
}
Result GpuFreqMaxAsm(u32 *ptr32)
{
Result GpuFreqMaxAsm(u32 *ptr32) {
// Check if both two instructions match the pattern
u32 ins1 = *ptr32, ins2 = *(ptr32 + 1);
if (!(asm_compare_no_rd(ins1, asm_pattern[0]) && asm_compare_no_rd(ins2, asm_pattern[1])))
@@ -120,8 +115,7 @@
R_THROW(ldr::ResultInvalidGpuFreqMaxPattern());
u32 max_clock;
switch (C.eristaGpuUV)
{
switch (C.eristaGpuUV) {
case 0:
max_clock = GetDvfsTableLastEntry(C.eristaGpuDvfsTable)->freq;
break;
@@ -132,12 +126,9 @@
max_clock = GetDvfsTableLastEntry(C.eristaGpuDvfsTableHigh)->freq;
break;
case 3:
if(C.enableEristaGpuUnsafeFreqs)
{
if(C.enableEristaGpuUnsafeFreqs) {
max_clock = GetDvfsTableLastEntry(C.eristaGpuDvfsTableUv3UnsafeFreqs)->freq;
}
else
{
} else {
max_clock = GetDvfsTableLastEntry(C.eristaGpuDvfsTable)->freq;
}
break;
@@ -154,13 +145,11 @@
R_SUCCEED();
}
Result GpuFreqPllLimit(u32 *ptr)
{
Result GpuFreqPllLimit(u32 *ptr) {
clk_pll_param *entry = reinterpret_cast<clk_pll_param *>(ptr);
// All zero except for freq
for (size_t i = 1; i < sizeof(clk_pll_param) / sizeof(u32); i++)
{
for (size_t i = 1; i < sizeof(clk_pll_param) / sizeof(u32); i++) {
R_UNLESS(*(ptr + i) == 0, ldr::ResultInvalidGpuPllEntry());
}
@@ -170,9 +159,8 @@
R_SUCCEED();
}
void MemMtcTableAutoAdjust(EristaMtcTable *table)
{
if (C.mtcConf != AUTO_ADJ_ALL)
void MemMtcTableAutoAdjust(EristaMtcTable *table) {
if (C.mtcConf != AUTO_ADJ)
return;
#define WRITE_PARAM_ALL_REG(TABLE, PARAM, VALUE) \
@@ -188,10 +176,7 @@
WRITE_PARAM_ALL_REG(table, emc_rfcpb, GET_CYCLE_CEIL(tRFCpb));
WRITE_PARAM_ALL_REG(table, emc_ras, GET_CYCLE_CEIL(tRAS));
WRITE_PARAM_ALL_REG(table, emc_rp, GET_CYCLE_CEIL(tRPpb));
WRITE_PARAM_ALL_REG(table, emc_r2w, R2W);
WRITE_PARAM_ALL_REG(table, emc_w2r, W2R);
WRITE_PARAM_ALL_REG(table, emc_r2p, GET_CYCLE_CEIL(tRTP));
WRITE_PARAM_ALL_REG(table, emc_w2p, WTP);
WRITE_PARAM_ALL_REG(table, emc_rd_rcd, GET_CYCLE_CEIL(tRCD));
WRITE_PARAM_ALL_REG(table, emc_wr_rcd, GET_CYCLE_CEIL(tRCD));
WRITE_PARAM_ALL_REG(table, emc_rrd, GET_CYCLE_CEIL(tRRD));
@@ -199,22 +184,11 @@
WRITE_PARAM_ALL_REG(table, emc_pre_refresh_req_cnt, REFRESH / 4);
WRITE_PARAM_ALL_REG(table, emc_pdex2wr, GET_CYCLE_CEIL(tXP));
WRITE_PARAM_ALL_REG(table, emc_pdex2rd, GET_CYCLE_CEIL(tXP));
WRITE_PARAM_ALL_REG(table, emc_pchg2pden, GET_CYCLE_CEIL(tCMDCKE));
WRITE_PARAM_ALL_REG(table, emc_act2pden, GET_CYCLE_CEIL(tMRWCKEL));
WRITE_PARAM_ALL_REG(table, emc_ar2pden, GET_CYCLE_CEIL(tCMDCKE));
WRITE_PARAM_ALL_REG(table, emc_rw2pden, WTPDEN);
WRITE_PARAM_ALL_REG(table, emc_cke2pden, GET_CYCLE_CEIL(tCKELCS));
WRITE_PARAM_ALL_REG(table, emc_pdex2cke, GET_CYCLE_CEIL(tCSCKEH));
WRITE_PARAM_ALL_REG(table, emc_pdex2mrr, GET_CYCLE_CEIL(tPDEX2MRR));
WRITE_PARAM_ALL_REG(table, emc_txsr, MIN(GET_CYCLE_CEIL(tXSR), (u32)0x3fe));
WRITE_PARAM_ALL_REG(table, emc_txsrdll, MIN(GET_CYCLE_CEIL(tXSR), (u32)0x3fe));
WRITE_PARAM_ALL_REG(table, emc_tcke, GET_CYCLE_CEIL(tCKE));
WRITE_PARAM_ALL_REG(table, emc_tckesr, GET_CYCLE_CEIL(tSR));
WRITE_PARAM_ALL_REG(table, emc_tpd, GET_CYCLE_CEIL(tCKE));
WRITE_PARAM_ALL_REG(table, emc_tfaw, GET_CYCLE_CEIL(tFAW));
WRITE_PARAM_ALL_REG(table, emc_trpab, GET_CYCLE_CEIL(tRPab));
WRITE_PARAM_ALL_REG(table, emc_tclkstable, GET_CYCLE_CEIL(tCKCKEH));
WRITE_PARAM_ALL_REG(table, emc_tclkstop, GET_CYCLE_CEIL(tCKE) + 8);
WRITE_PARAM_ALL_REG(table, emc_trefbw, REFBW);
#define WRITE_PARAM_BURST_MC_REG(TABLE, PARAM, VALUE) TABLE->burst_mc_regs.PARAM = VALUE;
@@ -227,98 +201,23 @@
table->burst_mc_regs.mc_emem_arb_timing_ras = CEIL(GET_CYCLE_CEIL(tRAS) / MC_ARB_DIV) - 2;
table->burst_mc_regs.mc_emem_arb_timing_faw = CEIL(GET_CYCLE_CEIL(tFAW) / MC_ARB_DIV) - 1;
table->burst_mc_regs.mc_emem_arb_timing_rrd = CEIL(GET_CYCLE_CEIL(tRRD) / MC_ARB_DIV) - 1;
table->burst_mc_regs.mc_emem_arb_timing_rap2pre = CEIL(GET_CYCLE_CEIL(tRTP) / MC_ARB_DIV);
table->burst_mc_regs.mc_emem_arb_timing_wap2pre = CEIL(WTP / MC_ARB_DIV);
//table->burst_mc_regs.mc_emem_arb_timing_rap2pre = CEIL(GET_CYCLE_CEIL(tRTP) / MC_ARB_DIV);
//table->burst_mc_regs.mc_emem_arb_timing_wap2pre = CEIL(WTP / MC_ARB_DIV);
// table->burst_mc_regs.mc_emem_arb_timing_r2r = CEIL(table->burst_regs.emc_rext / MC_ARB_DIV) - 1 + MC_ARB_SFA;
// table->burst_mc_regs.mc_emem_arb_timing_w2w = CEIL(table->burst_regs.emc_wext / MC_ARB_DIV) - 1 + MC_ARB_SFA;
table->burst_mc_regs.mc_emem_arb_timing_r2w = CEIL(R2W / MC_ARB_DIV) - 1 + MC_ARB_SFA;
table->burst_mc_regs.mc_emem_arb_timing_w2r = CEIL(W2R / MC_ARB_DIV) - 1 + MC_ARB_SFA;
// table->burst_mc_regs.mc_emem_arb_timing_r2w = CEIL(R2W / MC_ARB_DIV) - 1 + MC_ARB_SFA;
// table->burst_mc_regs.mc_emem_arb_timing_w2r = CEIL(W2R / MC_ARB_DIV) - 1 + MC_ARB_SFA;
table->burst_mc_regs.mc_emem_arb_timing_rfcpb = CEIL(GET_CYCLE_CEIL(tRFCpb) / MC_ARB_DIV);
// table->burst_mc_regs.mc_emem_arb_timing_ccdmw = CEIL(tCCDMW / MC_ARB_DIV) -1 + MC_ARB_SFA;
}
void MemMtcTableCustomAdjust(EristaMtcTable *table)
{
if (C.mtcConf != CUSTOM_ADJ_ALL)
return;
constexpr u32 MC_ARB_DIV = 4;
constexpr u32 MC_ARB_SFA = 2;
WRITE_PARAM_ALL_REG(table, emc_rc, GET_CYCLE_CEIL(tRC));
WRITE_PARAM_ALL_REG(table, emc_ras, GET_CYCLE_CEIL(tRAS));
WRITE_PARAM_ALL_REG(table, emc_rp, GET_CYCLE_CEIL(tRPpb));
WRITE_PARAM_ALL_REG(table, emc_trpab, GET_CYCLE_CEIL(tRPab));
WRITE_PARAM_ALL_REG(table, emc_rd_rcd, GET_CYCLE_CEIL(tRCD));
WRITE_PARAM_ALL_REG(table, emc_wr_rcd, GET_CYCLE_CEIL(tRCD));
WRITE_PARAM_ALL_REG(table, emc_pdex2mrr, GET_CYCLE_CEIL(tPDEX2MRR));
table->burst_mc_regs.mc_emem_arb_timing_rcd = CEIL(GET_CYCLE_CEIL(tRCD) / MC_ARB_DIV - 2);
table->burst_mc_regs.mc_emem_arb_timing_rc = CEIL(GET_CYCLE_CEIL(tRC) / MC_ARB_DIV - 1);
table->burst_mc_regs.mc_emem_arb_timing_rp = CEIL(GET_CYCLE_CEIL(tRPpb) / MC_ARB_DIV - 1 + MC_ARB_SFA);
table->burst_mc_regs.mc_emem_arb_timing_ras = CEIL(GET_CYCLE_CEIL(tRAS) / MC_ARB_DIV - 2);
WRITE_PARAM_ALL_REG(table, emc_tfaw, GET_CYCLE_CEIL(tFAW));
WRITE_PARAM_ALL_REG(table, emc_rrd, GET_CYCLE_CEIL(tRRD));
table->burst_mc_regs.mc_emem_arb_timing_faw = CEIL(GET_CYCLE_CEIL(tFAW) / MC_ARB_DIV) - 1;
table->burst_mc_regs.mc_emem_arb_timing_rrd = CEIL(GET_CYCLE_CEIL(tRRD) / MC_ARB_DIV) - 1;
WRITE_PARAM_ALL_REG(table, emc_r2p, GET_CYCLE_CEIL(tRTP));
WRITE_PARAM_ALL_REG(table, emc_w2p, WTP);
WRITE_PARAM_ALL_REG(table, emc_rw2pden, WTPDEN);
table->burst_mc_regs.mc_emem_arb_timing_rap2pre = CEIL(GET_CYCLE_CEIL(tRTP) / MC_ARB_DIV);
table->burst_mc_regs.mc_emem_arb_timing_wap2pre = CEIL(WTP / MC_ARB_DIV);
WRITE_PARAM_ALL_REG(table, emc_rfc, GET_CYCLE_CEIL(tRFCab));
WRITE_PARAM_ALL_REG(table, emc_rfcpb, GET_CYCLE_CEIL(tRFCpb));
WRITE_PARAM_ALL_REG(table, emc_txsr, MIN(GET_CYCLE_CEIL(tXSR), (u32)0x3fe));
WRITE_PARAM_ALL_REG(table, emc_txsrdll, MIN(GET_CYCLE_CEIL(tXSR), (u32)0x3fe));
table->burst_mc_regs.mc_emem_arb_timing_rfcpb = CEIL(GET_CYCLE_CEIL(tRFCpb) / MC_ARB_DIV);
WRITE_PARAM_ALL_REG(table, emc_w2r, W2R);
table->burst_mc_regs.mc_emem_arb_timing_w2r = CEIL(W2R / MC_ARB_DIV) - 1 + MC_ARB_SFA;
WRITE_PARAM_ALL_REG(table, emc_refresh, REFRESH);
WRITE_PARAM_ALL_REG(table, emc_pre_refresh_req_cnt, REFRESH / 4);
WRITE_PARAM_ALL_REG(table, emc_trefbw, REFBW);
WRITE_PARAM_ALL_REG(table, emc_r2w, R2W);
WRITE_PARAM_ALL_REG(table, emc_w2r, W2R);
WRITE_PARAM_ALL_REG(table, emc_w2p, WTP);
WRITE_PARAM_ALL_REG(table, emc_rw2pden, WTPDEN);
table->burst_mc_regs.mc_emem_arb_timing_wap2pre = CEIL(WTP / MC_ARB_DIV);
table->burst_mc_regs.mc_emem_arb_timing_r2w = CEIL(R2W / MC_ARB_DIV) - 1 + MC_ARB_SFA;
table->burst_mc_regs.mc_emem_arb_timing_w2r = CEIL(W2R / MC_ARB_DIV) - 1 + MC_ARB_SFA;
u32 DA_TURNS = 0;
DA_TURNS |= u8(table->burst_mc_regs.mc_emem_arb_timing_r2w / 2) << 16; // R2W TURN
DA_TURNS |= u8(table->burst_mc_regs.mc_emem_arb_timing_w2r / 2) << 24; // W2R TURN
WRITE_PARAM_BURST_MC_REG(table, mc_emem_arb_da_turns, DA_TURNS);
u32 DA_COVERS = 0;
u8 R_COVER = (table->burst_mc_regs.mc_emem_arb_timing_rap2pre + table->burst_mc_regs.mc_emem_arb_timing_rp + table->burst_mc_regs.mc_emem_arb_timing_rcd) / 2;
u8 W_COVER = (table->burst_mc_regs.mc_emem_arb_timing_wap2pre + table->burst_mc_regs.mc_emem_arb_timing_rp + table->burst_mc_regs.mc_emem_arb_timing_rcd) / 2;
DA_COVERS |= (u8)(table->burst_mc_regs.mc_emem_arb_timing_rc / 2); // RC COVER
DA_COVERS |= (R_COVER << 8); // RCD_R COVER
DA_COVERS |= (W_COVER << 16); // RCD_W COVER
WRITE_PARAM_BURST_MC_REG(table, mc_emem_arb_da_covers, DA_COVERS);
}
Result MemFreqMtcTable(u32 *ptr)
{
Result MemFreqMtcTable(u32 *ptr) {
u32 khz_list[] = {1600000, 1331200, 1065600, 800000, 665600, 408000, 204000, 102000, 68000, 40800};
u32 khz_list_size = sizeof(khz_list) / sizeof(u32);
// Generate list for mtc table pointers
EristaMtcTable *table_list[khz_list_size];
for (u32 i = 0; i < khz_list_size; i++)
{
for (u32 i = 0; i < khz_list_size; i++) {
u8 *table = reinterpret_cast<u8 *>(ptr) - offsetof(EristaMtcTable, rate_khz) - i * sizeof(EristaMtcTable);
table_list[i] = reinterpret_cast<EristaMtcTable *>(table);
R_UNLESS(table_list[i]->rate_khz == khz_list[i], ldr::ResultInvalidMtcTable());
@@ -344,8 +243,7 @@
R_SUCCEED();
}
Result MemFreqMax(u32 *ptr)
{
Result MemFreqMax(u32 *ptr) {
if (C.eristaEmcMaxClock <= EmcClkOSLimit)
R_SKIP();
@@ -354,16 +252,15 @@
R_SUCCEED();
}
void Patch(uintptr_t mapped_nso, size_t nso_size)
{
void Patch(uintptr_t mapped_nso, size_t nso_size) {
u32 CpuCvbDefaultMaxFreq = static_cast<u32>(GetDvfsTableLastEntry(CpuCvbTableDefault)->freq);
u32 GpuCvbDefaultMaxFreq = static_cast<u32>(GetDvfsTableLastEntry(GpuCvbTableDefault)->freq);
PatcherEntry<u32> patches[] = {
{ "CPU Freq Vdd", &CpuFreqVdd, 1, nullptr, CpuClkOSLimit },
{"CPU Freq Vdd", &CpuFreqVdd, 1, nullptr, CpuClkOSLimit },
{"CPU Freq Table", CpuFreqCvbTable<false>, 1, nullptr, CpuCvbDefaultMaxFreq},
{ "CPU Volt Limit", &CpuVoltRange, 13, nullptr, CpuVoltOfficial },
{ "CPU Volt Dfll", &CpuVoltDfll, 1, nullptr, 0xFFEAD0FF },
{"CPU Volt Limit", &CpuVoltRange, 13, nullptr, CpuVoltOfficial },
{"CPU Volt Dfll", &CpuVoltDfll, 1, nullptr, 0xFFEAD0FF },
{"GPU Freq Table", GpuFreqCvbTable<false>, 1, nullptr, GpuCvbDefaultMaxFreq},
{"GPU Freq Asm", &GpuFreqMaxAsm, 2, &GpuMaxClockPatternFn},
{"GPU Freq PLL", &GpuFreqPllLimit, 1, nullptr, GpuClkPllLimit},
@@ -376,18 +273,15 @@
for (uintptr_t ptr = mapped_nso;
ptr <= mapped_nso + nso_size - sizeof(EristaMtcTable);
ptr += sizeof(u32))
{
ptr += sizeof(u32)) {
u32 *ptr32 = reinterpret_cast<u32 *>(ptr);
for (auto &entry : patches)
{
for (auto &entry : patches) {
if (R_SUCCEEDED(entry.SearchAndApply(ptr32)))
break;
}
}
for (auto &entry : patches)
{
for (auto &entry : patches) {
LOGGING("%s Count: %zu", entry.description, entry.patched_count);
if (R_FAILED(entry.CheckResult()))
CRASH(entry.description);