hekate/bdk/soc/bpmp.c

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/*
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* BPMP-Lite Cache/MMU and Frequency driver for Tegra X1
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*
* Copyright (c) 2019-2024 CTCaer
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*
* 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 <soc/bpmp.h>
#include <soc/clock.h>
#include <soc/timer.h>
#include <soc/t210.h>
#include <memory_map.h>
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#define BPMP_MMU_CACHE_LINE_SIZE 0x20
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#define BPMP_CACHE_CONFIG 0x0
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#define CFG_ENABLE_CACHE BIT(0)
#define CFG_ENABLE_SKEW_ASSOC BIT(1)
#define CFG_DISABLE_RANDOM_ALLOC BIT(2)
#define CFG_FORCE_WRITE_THROUGH BIT(3)
#define CFG_NEVER_ALLOCATE BIT(6)
#define CFG_ENABLE_INTERRUPT BIT(7)
#define CFG_MMU_TAG_MODE(x) ((x) << 8)
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#define TAG_MODE_PARALLEL 0
#define TAG_MODE_TAG_FIRST 1
#define TAG_MODE_MMU_FIRST 2
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#define CFG_DISABLE_WRITE_BUFFER BIT(10)
#define CFG_DISABLE_READ_BUFFER BIT(11)
#define CFG_ENABLE_HANG_DETECT BIT(12)
#define CFG_FULL_LINE_DIRTY BIT(13)
#define CFG_TAG_CHK_ABRT_ON_ERR BIT(14)
#define CFG_TAG_CHK_CLR_ERR BIT(15)
#define CFG_DISABLE_SAMELINE BIT(16)
#define CFG_OBS_BUS_EN BIT(31)
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#define BPMP_CACHE_LOCK 0x4
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#define LOCK_LINE(x) BIT((x))
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#define BPMP_CACHE_SIZE 0xC
#define BPMP_CACHE_LFSR 0x10
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#define BPMP_CACHE_TAG_STATUS 0x14
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#define TAG_STATUS_TAG_CHECK_ERROR BIT(0)
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#define TAG_STATUS_CONFLICT_ADDR_MASK 0xFFFFFFE0
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#define BPMP_CACHE_CLKEN_OVERRIDE 0x18
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#define CLKEN_OVERRIDE_WR_MCCIF_CLKEN BIT(0)
#define CLKEN_OVERRIDE_RD_MCCIF_CLKEN BIT(1)
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#define BPMP_CACHE_MAINT_ADDR 0x20
#define BPMP_CACHE_MAINT_DATA 0x24
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#define BPMP_CACHE_MAINT_REQ 0x28
#define MAINT_REQ_WAY_BITMAP(x) ((x) << 8)
#define BPMP_CACHE_INT_MASK 0x40
#define BPMP_CACHE_INT_CLEAR 0x44
#define BPMP_CACHE_INT_RAW_EVENT 0x48
#define BPMP_CACHE_INT_STATUS 0x4C
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#define INT_MAINT_DONE BIT(0)
#define INT_MAINT_ERROR BIT(1)
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#define BPMP_CACHE_RB_CFG 0x80
#define BPMP_CACHE_WB_CFG 0x84
#define BPMP_CACHE_MMU_FALLBACK_ENTRY 0xA0
#define BPMP_CACHE_MMU_SHADOW_COPY_MASK 0xA4
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#define BPMP_CACHE_MMU_CFG 0xAC
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#define MMU_CFG_BLOCK_MAIN_ENTRY_WR BIT(0)
#define MMU_CFG_SEQ_EN BIT(1)
#define MMU_CFG_TLB_EN BIT(2)
#define MMU_CFG_SEG_CHECK_ALL_ENTRIES BIT(3)
#define MMU_CFG_ABORT_STORE_LAST BIT(4)
#define MMU_CFG_CLR_ABORT BIT(5)
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#define BPMP_CACHE_MMU_CMD 0xB0
#define MMU_CMD_NOP 0
#define MMU_CMD_INIT 1
#define MMU_CMD_COPY_SHADOW 2
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#define BPMP_CACHE_MMU_ABORT_STAT 0xB4
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#define ABORT_STAT_UNIT_MASK 0x7
#define ABORT_STAT_UNIT_NONE 0
#define ABORT_STAT_UNIT_CACHE 1
#define ABORT_STAT_UNIT_SEQ 2
#define ABORT_STAT_UNIT_TLB 3
#define ABORT_STAT_UNIT_SEG 4
#define ABORT_STAT_UNIT_FALLBACK 5
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#define ABORT_STAT_OVERLAP BIT(3)
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#define ABORT_STAT_ENTRY (0x1F << 4)
#define ABORT_STAT_TYPE_MASK (3 << 16)
#define ABORT_STAT_TYPE_EXE (0 << 16)
#define ABORT_STAT_TYPE_RD (1 << 16)
#define ABORT_STAT_TYPE_WR (2 << 16)
#define ABORT_STAT_SIZE (3 << 18)
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#define ABORT_STAT_SEQ BIT(20)
#define ABORT_STAT_PROT BIT(21)
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#define BPMP_CACHE_MMU_ABORT_ADDR 0xB8
#define BPMP_CACHE_MMU_ACTIVE_ENTRIES 0xBC
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#define BPMP_MMU_SHADOW_ENTRY_BASE (BPMP_CACHE_BASE + 0x400)
#define BPMP_MMU_MAIN_ENTRY_BASE (BPMP_CACHE_BASE + 0x800)
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#define MMU_EN_CACHED BIT(0)
#define MMU_EN_EXEC BIT(1)
#define MMU_EN_READ BIT(2)
#define MMU_EN_WRITE BIT(3)
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static const bpmp_mmu_entry_t mmu_entries[] =
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{
{ DRAM_START, 0xFFFFFFFF, MMU_EN_READ | MMU_EN_WRITE | MMU_EN_EXEC | MMU_EN_CACHED, true },
{ IRAM_BASE, 0x4003FFFF, MMU_EN_READ | MMU_EN_WRITE | MMU_EN_EXEC | MMU_EN_CACHED, true }
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};
void bpmp_mmu_maintenance(u32 op, bool force)
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{
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if (!force && !(BPMP_CACHE_CTRL(BPMP_CACHE_CONFIG) & CFG_ENABLE_CACHE))
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return;
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BPMP_CACHE_CTRL(BPMP_CACHE_INT_CLEAR) = INT_MAINT_DONE;
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// This is a blocking operation.
BPMP_CACHE_CTRL(BPMP_CACHE_MAINT_REQ) = MAINT_REQ_WAY_BITMAP(0xF) | op;
while (!(BPMP_CACHE_CTRL(BPMP_CACHE_INT_RAW_EVENT) & INT_MAINT_DONE))
;
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BPMP_CACHE_CTRL(BPMP_CACHE_INT_CLEAR) = BPMP_CACHE_CTRL(BPMP_CACHE_INT_RAW_EVENT);
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}
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void bpmp_mmu_set_entry(int idx, const bpmp_mmu_entry_t *entry, bool apply)
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{
if (idx > 31)
return;
volatile bpmp_mmu_entry_t *mmu_entry = (bpmp_mmu_entry_t *)(BPMP_MMU_SHADOW_ENTRY_BASE + sizeof(bpmp_mmu_entry_t) * idx);
if (entry->enable)
{
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mmu_entry->start_addr = ALIGN(entry->start_addr, BPMP_MMU_CACHE_LINE_SIZE);
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mmu_entry->end_addr = ALIGN_DOWN(entry->end_addr, BPMP_MMU_CACHE_LINE_SIZE);
mmu_entry->attr = entry->attr;
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BPMP_CACHE_CTRL(BPMP_CACHE_MMU_SHADOW_COPY_MASK) |= BIT(idx);
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if (apply)
BPMP_CACHE_CTRL(BPMP_CACHE_MMU_CMD) = MMU_CMD_COPY_SHADOW;
}
}
void bpmp_mmu_enable()
{
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if (BPMP_CACHE_CTRL(BPMP_CACHE_CONFIG) & CFG_ENABLE_CACHE)
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return;
// Init BPMP MMU.
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BPMP_CACHE_CTRL(BPMP_CACHE_MMU_CMD) = MMU_CMD_INIT;
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BPMP_CACHE_CTRL(BPMP_CACHE_MMU_FALLBACK_ENTRY) = MMU_EN_READ | MMU_EN_WRITE | MMU_EN_EXEC; // RWX for non-defined regions.
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BPMP_CACHE_CTRL(BPMP_CACHE_MMU_CFG) = MMU_CFG_SEQ_EN | MMU_CFG_TLB_EN | MMU_CFG_ABORT_STORE_LAST;
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// Init BPMP MMU entries.
BPMP_CACHE_CTRL(BPMP_CACHE_MMU_SHADOW_COPY_MASK) = 0;
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for (u32 idx = 0; idx < ARRAY_SIZE(mmu_entries); idx++)
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bpmp_mmu_set_entry(idx, &mmu_entries[idx], false);
BPMP_CACHE_CTRL(BPMP_CACHE_MMU_CMD) = MMU_CMD_COPY_SHADOW;
// Invalidate cache.
bpmp_mmu_maintenance(BPMP_MMU_MAINT_INVALID_WAY, true);
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// Enable cache.
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BPMP_CACHE_CTRL(BPMP_CACHE_CONFIG) = CFG_ENABLE_CACHE | CFG_FORCE_WRITE_THROUGH |
CFG_MMU_TAG_MODE(TAG_MODE_PARALLEL) | CFG_TAG_CHK_ABRT_ON_ERR;
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// HW bug. Invalidate cache again.
bpmp_mmu_maintenance(BPMP_MMU_MAINT_INVALID_WAY, false);
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}
void bpmp_mmu_disable()
{
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if (!(BPMP_CACHE_CTRL(BPMP_CACHE_CONFIG) & CFG_ENABLE_CACHE))
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return;
// Clean and invalidate cache.
bpmp_mmu_maintenance(BPMP_MMU_MAINT_CLN_INV_WAY, false);
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// Disable cache.
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BPMP_CACHE_CTRL(BPMP_CACHE_CONFIG) = 0;
}
/*
* CLK_RST_CONTROLLER_SCLK_BURST_POLICY:
* 0 = CLKM
* 1 = PLLC_OUT1
* 2 = PLLC4_OUT3
* 3 = PLLP_OUT0
* 4 = PLLP_OUT2
* 5 = PLLC4_OUT1
* 6 = CLK_S
* 7 = PLLC4_OUT2
*/
bpmp_freq_t bpmp_fid_current = BPMP_CLK_NORMAL;
void bpmp_clk_rate_relaxed(bool enable)
{
// This is a glitch-free way to reduce the SCLK timings.
if (enable)
{
// Restore to PLLP source during PLLC configuration.
CLOCK(CLK_RST_CONTROLLER_SCLK_BURST_POLICY) = 0x20003330; // PLLP_OUT.
usleep(100); // Wait a bit for clock source change.
CLOCK(CLK_RST_CONTROLLER_CLK_SYSTEM_RATE) = 2; // PCLK = HCLK / (2 + 1). HCLK == SCLK.
}
else if (bpmp_fid_current)
{
// Restore to PLLC_OUT1.
CLOCK(CLK_RST_CONTROLLER_CLK_SYSTEM_RATE) = 3; // PCLK = HCLK / (3 + 1). HCLK == SCLK.
CLOCK(CLK_RST_CONTROLLER_SCLK_BURST_POLICY) = 0x20003310; // PLLC_OUT1 and CLKM for idle.
usleep(100); // Wait a bit for clock source change.
}
}
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// APB clock affects RTC, PWM, MEMFETCH, APE, USB, SOR PWM,
// I2C host, DC/DSI/DISP. UART gives extra stress.
// 92: 100% success ratio. 93-94: 595-602MHz has 99% success ratio. 95: 608MHz less.
// APB clock max is supposed to be 204 MHz though.
static const u8 pll_divn[] = {
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0, // BPMP_CLK_NORMAL: 408MHz 0% - 136MHz APB.
85, // BPMP_CLK_HIGH_BOOST: 544MHz 33% - 136MHz APB.
88, // BPMP_CLK_HIGH2_BOOST: 563MHz 38% - 141MHz APB.
90, // BPMP_CLK_SUPER_BOOST: 576MHz 41% - 144MHz APB.
92 // BPMP_CLK_HYPER_BOOST: 589MHz 44% - 147MHz APB.
// Do not use for public releases!
//95 // BPMP_CLK_DEV_BOOST: 608MHz 49% - 152MHz APB.
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};
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void bpmp_clk_rate_get()
{
bool clk_src_is_pllp = ((CLOCK(CLK_RST_CONTROLLER_SCLK_BURST_POLICY) >> 4) & 7) == 3;
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if (clk_src_is_pllp)
bpmp_fid_current = BPMP_CLK_NORMAL;
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else
{
bpmp_fid_current = BPMP_CLK_HIGH_BOOST;
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u8 pll_divn_curr = (CLOCK(CLK_RST_CONTROLLER_PLLC_BASE) >> 10) & 0xFF;
for (u32 i = 1; i < sizeof(pll_divn); i++)
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{
if (pll_divn[i] == pll_divn_curr)
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{
bpmp_fid_current = i;
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break;
}
}
}
}
void bpmp_clk_rate_set(bpmp_freq_t fid)
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{
if (fid > (BPMP_CLK_MAX - 1))
fid = BPMP_CLK_MAX - 1;
if (bpmp_fid_current == fid)
return;
bpmp_fid_current = fid;
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if (fid)
{
// Use default SCLK / HCLK / PCLK clocks.
bpmp_clk_rate_relaxed(true);
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// Configure and enable PLLC.
clock_enable_pllc(pll_divn[fid]);
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// Set new source and SCLK / HCLK / PCLK dividers.
bpmp_clk_rate_relaxed(false);
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}
else
{
// Use default SCLK / HCLK / PCLK clocks.
bpmp_clk_rate_relaxed(true);
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// Disable PLLC to save power.
clock_disable_pllc();
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}
}
// State is reset to RUN on any clock or source set via SW.
void bpmp_state_set(bpmp_state_t state)
{
u32 cfg = CLOCK(CLK_RST_CONTROLLER_SCLK_BURST_POLICY) & ~0xF0000000u;
CLOCK(CLK_RST_CONTROLLER_SCLK_BURST_POLICY) = cfg | (state << 28u);
}
// The following functions halt BPMP to reduce power while sleeping.
// They are not as accurate as RTC at big values but they guarantee time+ delay.
void bpmp_usleep(u32 us)
{
u32 delay;
// Each iteration takes 1us.
while (us)
{
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delay = (us > HALT_MAX_CNT) ? HALT_MAX_CNT : us;
us -= delay;
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FLOW_CTLR(FLOW_CTLR_HALT_COP_EVENTS) = HALT_MODE_WAITEVENT | HALT_USEC | delay;
}
}
void bpmp_msleep(u32 ms)
{
u32 delay;
// Iteration time is variable. ~200 - 1000us.
while (ms)
{
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delay = (ms > HALT_MAX_CNT) ? HALT_MAX_CNT : ms;
ms -= delay;
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FLOW_CTLR(FLOW_CTLR_HALT_COP_EVENTS) = HALT_MODE_WAITEVENT | HALT_MSEC | delay;
}
}
void bpmp_halt()
{
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FLOW_CTLR(FLOW_CTLR_HALT_COP_EVENTS) = HALT_MODE_WAITEVENT | HALT_JTAG;
}