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hekate/bdk/soc/clock.c
CTCaer d258c82d52 bdk: sdmmc: add UHS DDR200 support
The bdk flag BDK_SDMMC_UHS_DDR200_SUPPORT can be used to enable it.

SD Card DDR200 (DDR208) support

Proper procedure:
1. Check that Vendor Specific Command System is supported.
   Used as Enable DDR200 Bus.
2. Enable DDR200 bus mode via setting 14 to Group 2 via CMD6.
   Access Mode group is left to default 0 (SDR12).
3. Setup clock to 200 or 208 MHz.
4. Set host to DDR bus mode that supports such high clocks.
   Some hosts have special mode, others use DDR50 and others HS400.
5. Execute Tuning.

The true validation that this value in Group 2 activates it, is that DDR50 bus
and clocks/timings work fully after that point.

On Tegra X1, that can be done with DDR50 host mode.
Tuning though can't be done automatically on any DDR mode.
So it needs to be done manually and selected tap will be applied from the
biggest sampling window.

Finally, all that simply works, because the marketing materials for DDR200 are
basically overstatements to sell the feature. DDR200 is simply SDR104 in DDR mode,
so sampling on rising and falling edge and with variable output data window.
It can be supported by any host that is fast enough to support DDR at 200/208MHz
and can do hw/sw tuning for finding the proper sampling window in that mode.

Using a SDMMC controller on DDR200 mode at 400MHz, has latency allowance implications. The MC/EMC must be clocked enough to be able to serve the requests in time (512B in 1.28 ns).
2023-03-31 08:54:13 +03:00

980 lines
26 KiB
C

/*
* Copyright (c) 2018 naehrwert
* Copyright (c) 2018-2023 CTCaer
*
* 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/clock.h>
#include <soc/hw_init.h>
#include <soc/pmc.h>
#include <soc/timer.h>
#include <soc/t210.h>
#include <storage/sdmmc.h>
typedef struct _clock_osc_t
{
u32 freq;
u16 min;
u16 max;
} clock_osc_t;
static const clock_osc_t _clock_osc_cnt[] = {
{ 12000, 706, 757 },
{ 13000, 766, 820 },
{ 16800, 991, 1059 },
{ 19200, 1133, 1210 },
{ 26000, 1535, 1638 },
{ 38400, 2268, 2418 },
{ 48000, 2836, 3023 }
};
/* clk_rst_t: reset, enable, source, index, clk_src, clk_div */
static const clk_rst_t _clock_uart[] = {
{ CLK_RST_CONTROLLER_RST_DEVICES_L, CLK_RST_CONTROLLER_CLK_OUT_ENB_L, CLK_RST_CONTROLLER_CLK_SOURCE_UARTA, CLK_L_UARTA, 0, 2 },
{ CLK_RST_CONTROLLER_RST_DEVICES_L, CLK_RST_CONTROLLER_CLK_OUT_ENB_L, CLK_RST_CONTROLLER_CLK_SOURCE_UARTB, CLK_L_UARTB, 0, 2 },
{ CLK_RST_CONTROLLER_RST_DEVICES_H, CLK_RST_CONTROLLER_CLK_OUT_ENB_H, CLK_RST_CONTROLLER_CLK_SOURCE_UARTC, CLK_H_UARTC, 0, 2 },
{ CLK_RST_CONTROLLER_RST_DEVICES_U, CLK_RST_CONTROLLER_CLK_OUT_ENB_U, CLK_RST_CONTROLLER_CLK_SOURCE_UARTD, CLK_U_UARTD, 0, 2 },
{ CLK_RST_CONTROLLER_RST_DEVICES_Y, CLK_RST_CONTROLLER_CLK_OUT_ENB_Y, CLK_RST_CONTROLLER_CLK_SOURCE_UARTAPE, CLK_Y_UARTAPE, 0, 2 }
};
//I2C default parameters - TLOW: 4, THIGH: 2, DEBOUNCE: 0, FM_DIV: 26.
static const clk_rst_t _clock_i2c[] = {
{ CLK_RST_CONTROLLER_RST_DEVICES_L, CLK_RST_CONTROLLER_CLK_OUT_ENB_L, CLK_RST_CONTROLLER_CLK_SOURCE_I2C1, CLK_L_I2C1, 0, 19 }, //20.4MHz -> 100KHz
{ CLK_RST_CONTROLLER_RST_DEVICES_H, CLK_RST_CONTROLLER_CLK_OUT_ENB_H, CLK_RST_CONTROLLER_CLK_SOURCE_I2C2, CLK_H_I2C2, 0, 4 }, //81.6MHz -> 400KHz
{ CLK_RST_CONTROLLER_RST_DEVICES_U, CLK_RST_CONTROLLER_CLK_OUT_ENB_U, CLK_RST_CONTROLLER_CLK_SOURCE_I2C3, CLK_U_I2C3, 0, 4 }, //81.6MHz -> 400KHz
{ CLK_RST_CONTROLLER_RST_DEVICES_V, CLK_RST_CONTROLLER_CLK_OUT_ENB_V, CLK_RST_CONTROLLER_CLK_SOURCE_I2C4, CLK_V_I2C4, 0, 19 }, //20.4MHz -> 100KHz
{ CLK_RST_CONTROLLER_RST_DEVICES_H, CLK_RST_CONTROLLER_CLK_OUT_ENB_H, CLK_RST_CONTROLLER_CLK_SOURCE_I2C5, CLK_H_I2C5, 0, 4 }, //81.6MHz -> 400KHz
{ CLK_RST_CONTROLLER_RST_DEVICES_X, CLK_RST_CONTROLLER_CLK_OUT_ENB_X, CLK_RST_CONTROLLER_CLK_SOURCE_I2C6, CLK_X_I2C6, 0, 19 } //20.4MHz -> 100KHz
};
static clk_rst_t _clock_se = {
CLK_RST_CONTROLLER_RST_DEVICES_V, CLK_RST_CONTROLLER_CLK_OUT_ENB_V, CLK_RST_CONTROLLER_CLK_SOURCE_SE, CLK_V_SE, 0, 0 // 408MHz. Default: 408MHz. Max: 627.2 MHz.
};
static clk_rst_t _clock_tzram = {
CLK_RST_CONTROLLER_RST_DEVICES_V, CLK_RST_CONTROLLER_CLK_OUT_ENB_V, CLK_NO_SOURCE, CLK_V_TZRAM, 0, 0
};
static clk_rst_t _clock_host1x = {
CLK_RST_CONTROLLER_RST_DEVICES_L, CLK_RST_CONTROLLER_CLK_OUT_ENB_L, CLK_RST_CONTROLLER_CLK_SOURCE_HOST1X, CLK_L_HOST1X, 4, 3 // 163.2MHz. Max: 408MHz.
};
static clk_rst_t _clock_tsec = {
CLK_RST_CONTROLLER_RST_DEVICES_U, CLK_RST_CONTROLLER_CLK_OUT_ENB_U, CLK_RST_CONTROLLER_CLK_SOURCE_TSEC, CLK_U_TSEC, 0, 2 // 204MHz. Max: 408MHz.
};
static clk_rst_t _clock_nvdec = {
CLK_RST_CONTROLLER_RST_DEVICES_Y, CLK_RST_CONTROLLER_CLK_OUT_ENB_Y, CLK_RST_CONTROLLER_CLK_SOURCE_NVDEC, CLK_Y_NVDEC, 4, 0 // 408 MHz. Max: 716.8/979.2MHz.
};
static clk_rst_t _clock_nvjpg = {
CLK_RST_CONTROLLER_RST_DEVICES_Y, CLK_RST_CONTROLLER_CLK_OUT_ENB_Y, CLK_RST_CONTROLLER_CLK_SOURCE_NVJPG, CLK_Y_NVJPG, 4, 0 // 408 MHz. Max: 627.2/652.8MHz.
};
static clk_rst_t _clock_vic = {
CLK_RST_CONTROLLER_RST_DEVICES_X, CLK_RST_CONTROLLER_CLK_OUT_ENB_X, CLK_RST_CONTROLLER_CLK_SOURCE_VIC, CLK_X_VIC, 2, 0 // 408 MHz. Max: 627.2/652.8MHz.
};
static clk_rst_t _clock_sor_safe = {
CLK_RST_CONTROLLER_RST_DEVICES_Y, CLK_RST_CONTROLLER_CLK_OUT_ENB_Y, CLK_NO_SOURCE, CLK_Y_SOR_SAFE, 0, 0
};
static clk_rst_t _clock_sor0 = {
CLK_RST_CONTROLLER_RST_DEVICES_X, CLK_RST_CONTROLLER_CLK_OUT_ENB_X, CLK_NOT_USED, CLK_X_SOR0, 0, 0
};
static clk_rst_t _clock_sor1 = {
CLK_RST_CONTROLLER_RST_DEVICES_X, CLK_RST_CONTROLLER_CLK_OUT_ENB_X, CLK_RST_CONTROLLER_CLK_SOURCE_SOR1, CLK_X_SOR1, 0, 2 // 204MHz.
};
static clk_rst_t _clock_kfuse = {
CLK_RST_CONTROLLER_RST_DEVICES_H, CLK_RST_CONTROLLER_CLK_OUT_ENB_H, CLK_NO_SOURCE, CLK_H_KFUSE, 0, 0
};
static clk_rst_t _clock_cl_dvfs = {
CLK_RST_CONTROLLER_RST_DEVICES_W, CLK_RST_CONTROLLER_CLK_OUT_ENB_W, CLK_NO_SOURCE, CLK_W_DVFS, 0, 0
};
static clk_rst_t _clock_coresight = {
CLK_RST_CONTROLLER_RST_DEVICES_U, CLK_RST_CONTROLLER_CLK_OUT_ENB_U, CLK_RST_CONTROLLER_CLK_SOURCE_CSITE, CLK_U_CSITE, 0, 4 // 136MHz.
};
static clk_rst_t _clock_pwm = {
CLK_RST_CONTROLLER_RST_DEVICES_L, CLK_RST_CONTROLLER_CLK_OUT_ENB_L, CLK_RST_CONTROLLER_CLK_SOURCE_PWM, CLK_L_PWM, 6, 4 // Fref: 6.4MHz. HOS: PLLP / 54 = 7.55MHz.
};
static clk_rst_t _clock_sdmmc_legacy_tm = {
CLK_RST_CONTROLLER_RST_DEVICES_Y, CLK_RST_CONTROLLER_CLK_OUT_ENB_Y, CLK_RST_CONTROLLER_CLK_SOURCE_SDMMC_LEGACY_TM, CLK_Y_SDMMC_LEGACY_TM, 4, 66
};
static clk_rst_t _clock_apbdma = {
CLK_RST_CONTROLLER_RST_DEVICES_H, CLK_RST_CONTROLLER_CLK_OUT_ENB_H, CLK_NO_SOURCE, CLK_H_APBDMA, 0, 0 // Max: 204MHz.
};
static clk_rst_t _clock_ahbdma = {
CLK_RST_CONTROLLER_RST_DEVICES_H, CLK_RST_CONTROLLER_CLK_OUT_ENB_H, CLK_NO_SOURCE, CLK_H_AHBDMA, 0, 0
};
static clk_rst_t _clock_actmon = {
CLK_RST_CONTROLLER_RST_DEVICES_V, CLK_RST_CONTROLLER_CLK_OUT_ENB_V, CLK_RST_CONTROLLER_CLK_SOURCE_ACTMON, CLK_V_ACTMON, 6, 0 // 19.2MHz.
};
static clk_rst_t _clock_extperiph1 = {
CLK_RST_CONTROLLER_RST_DEVICES_V, CLK_RST_CONTROLLER_CLK_OUT_ENB_V, CLK_RST_CONTROLLER_CLK_SOURCE_EXTPERIPH1, CLK_V_EXTPERIPH1, 0, 0
};
static clk_rst_t _clock_extperiph2 = {
CLK_RST_CONTROLLER_RST_DEVICES_V, CLK_RST_CONTROLLER_CLK_OUT_ENB_V, CLK_RST_CONTROLLER_CLK_SOURCE_EXTPERIPH2, CLK_V_EXTPERIPH2, 2, 202 // 4.0MHz
};
void clock_enable(const clk_rst_t *clk)
{
// Put clock into reset.
CLOCK(clk->reset) = (CLOCK(clk->reset) & ~BIT(clk->index)) | BIT(clk->index);
// Disable.
CLOCK(clk->enable) &= ~BIT(clk->index);
// Configure clock source if required.
if (clk->source)
CLOCK(clk->source) = clk->clk_div | (clk->clk_src << 29);
// Enable.
CLOCK(clk->enable) = (CLOCK(clk->enable) & ~BIT(clk->index)) | BIT(clk->index);
usleep(2);
// Take clock off reset.
CLOCK(clk->reset) &= ~BIT(clk->index);
}
void clock_disable(const clk_rst_t *clk)
{
// Put clock into reset.
CLOCK(clk->reset) = (CLOCK(clk->reset) & ~BIT(clk->index)) | BIT(clk->index);
// Disable.
CLOCK(clk->enable) &= ~BIT(clk->index);
}
void clock_enable_fuse(bool enable)
{
// Enable Fuse registers visibility.
CLOCK(CLK_RST_CONTROLLER_MISC_CLK_ENB) = (CLOCK(CLK_RST_CONTROLLER_MISC_CLK_ENB) & 0xEFFFFFFF) | ((enable & 1) << 28);
}
void clock_enable_uart(u32 idx)
{
clock_enable(&_clock_uart[idx]);
}
void clock_disable_uart(u32 idx)
{
clock_disable(&_clock_uart[idx]);
}
#define UART_SRC_CLK_DIV_EN BIT(24)
int clock_uart_use_src_div(u32 idx, u32 baud)
{
u32 clk_src_div = CLOCK(_clock_uart[idx].source) & 0xE0000000;
if (baud == 3000000)
CLOCK(_clock_uart[idx].source) = clk_src_div | UART_SRC_CLK_DIV_EN | 15;
else if (baud == 1000000)
CLOCK(_clock_uart[idx].source) = clk_src_div | UART_SRC_CLK_DIV_EN | 49;
else
{
CLOCK(_clock_uart[idx].source) = clk_src_div | 2;
return 1;
}
return 0;
}
void clock_enable_i2c(u32 idx)
{
clock_enable(&_clock_i2c[idx]);
}
void clock_disable_i2c(u32 idx)
{
clock_disable(&_clock_i2c[idx]);
}
void clock_enable_se()
{
clock_enable(&_clock_se);
// Lock clock to always enabled if T210B01.
if (hw_get_chip_id() == GP_HIDREV_MAJOR_T210B01)
CLOCK(CLK_RST_CONTROLLER_CLK_SOURCE_SE) |= 0x100;
}
void clock_enable_tzram()
{
clock_enable(&_clock_tzram);
}
void clock_enable_host1x()
{
clock_enable(&_clock_host1x);
}
void clock_disable_host1x()
{
clock_disable(&_clock_host1x);
}
void clock_enable_tsec()
{
clock_enable(&_clock_tsec);
}
void clock_disable_tsec()
{
clock_disable(&_clock_tsec);
}
void clock_enable_nvdec()
{
clock_enable(&_clock_nvdec);
}
void clock_disable_nvdec()
{
clock_disable(&_clock_nvdec);
}
void clock_enable_nvjpg()
{
clock_enable(&_clock_nvjpg);
}
void clock_disable_nvjpg()
{
clock_disable(&_clock_nvjpg);
}
void clock_enable_vic()
{
clock_enable(&_clock_vic);
}
void clock_disable_vic()
{
clock_disable(&_clock_vic);
}
void clock_enable_sor_safe()
{
clock_enable(&_clock_sor_safe);
}
void clock_disable_sor_safe()
{
clock_disable(&_clock_sor_safe);
}
void clock_enable_sor0()
{
clock_enable(&_clock_sor0);
}
void clock_disable_sor0()
{
clock_disable(&_clock_sor0);
}
void clock_enable_sor1()
{
clock_enable(&_clock_sor1);
}
void clock_disable_sor1()
{
clock_disable(&_clock_sor1);
}
void clock_enable_kfuse()
{
CLOCK(CLK_RST_CONTROLLER_RST_DEV_H_SET) = BIT(CLK_H_KFUSE);
CLOCK(CLK_RST_CONTROLLER_CLK_ENB_H_CLR) = BIT(CLK_H_KFUSE);
CLOCK(CLK_RST_CONTROLLER_CLK_ENB_H_SET) = BIT(CLK_H_KFUSE);
usleep(10); // Wait 10s to prevent glitching.
CLOCK(CLK_RST_CONTROLLER_RST_DEV_H_CLR) = BIT(CLK_H_KFUSE);
usleep(20); // Wait 20s fo kfuse hw to init.
}
void clock_disable_kfuse()
{
clock_disable(&_clock_kfuse);
}
void clock_enable_cl_dvfs()
{
clock_enable(&_clock_cl_dvfs);
}
void clock_disable_cl_dvfs()
{
clock_disable(&_clock_cl_dvfs);
}
void clock_enable_coresight()
{
clock_enable(&_clock_coresight);
}
void clock_disable_coresight()
{
clock_disable(&_clock_coresight);
}
void clock_enable_pwm()
{
clock_enable(&_clock_pwm);
}
void clock_disable_pwm()
{
clock_disable(&_clock_pwm);
}
void clock_enable_apbdma()
{
clock_enable(&_clock_apbdma);
}
void clock_disable_apbdma()
{
clock_disable(&_clock_apbdma);
}
void clock_enable_ahbdma()
{
clock_enable(&_clock_ahbdma);
}
void clock_disable_ahbdma()
{
clock_disable(&_clock_ahbdma);
}
void clock_enable_actmon()
{
clock_enable(&_clock_actmon);
}
void clock_disable_actmon()
{
clock_disable(&_clock_actmon);
}
void clock_enable_extperiph1()
{
clock_enable(&_clock_extperiph1);
PMC(APBDEV_PMC_CLK_OUT_CNTRL) |= PMC_CLK_OUT_CNTRL_CLK1_SRC_SEL(OSC_CAR) | PMC_CLK_OUT_CNTRL_CLK1_FORCE_EN;
usleep(5);
}
void clock_disable_extperiph1()
{
PMC(APBDEV_PMC_CLK_OUT_CNTRL) &= ~((PMC_CLK_OUT_CNTRL_CLK1_SRC_SEL(OSC_CAR)) | PMC_CLK_OUT_CNTRL_CLK1_FORCE_EN);
clock_disable(&_clock_extperiph1);
}
void clock_enable_extperiph2()
{
clock_enable(&_clock_extperiph2);
PMC(APBDEV_PMC_CLK_OUT_CNTRL) |= PMC_CLK_OUT_CNTRL_CLK2_SRC_SEL(OSC_CAR) | PMC_CLK_OUT_CNTRL_CLK2_FORCE_EN;
usleep(5);
}
void clock_disable_extperiph2()
{
PMC(APBDEV_PMC_CLK_OUT_CNTRL) &= ~((PMC_CLK_OUT_CNTRL_CLK2_SRC_SEL(OSC_CAR)) | PMC_CLK_OUT_CNTRL_CLK2_FORCE_EN);
clock_disable(&_clock_extperiph2);
}
void clock_enable_plld(u32 divp, u32 divn, bool lowpower, bool tegra_t210)
{
u32 plld_div = (divp << 20) | (divn << 11) | 1;
// N divider is fractional, so N = DIVN + 1/2 + PLLD_SDM_DIN/8192.
u32 misc = 0x2D0000 | 0xFC00; // Clock enable and PLLD_SDM_DIN: -1024 -> DIVN + 0.375.
if (lowpower && tegra_t210)
misc = 0x2D0000 | 0x0AAA; // Clock enable and PLLD_SDM_DIN: 2730 -> DIVN + 0.833.
// Set DISP1 clock source and parent clock.
if (lowpower)
CLOCK(CLK_RST_CONTROLLER_CLK_SOURCE_DISP1) = 0x40000000; // PLLD_OUT0.
// Set dividers and enable PLLD.
CLOCK(CLK_RST_CONTROLLER_PLLD_BASE) = PLLCX_BASE_ENABLE | PLLCX_BASE_LOCK | plld_div;
CLOCK(CLK_RST_CONTROLLER_PLLD_MISC1) = tegra_t210 ? 0x20 : 0; // Keep default PLLD_SETUP.
// Set PLLD_SDM_DIN and enable PLLD to DSI pads.
CLOCK(CLK_RST_CONTROLLER_PLLD_MISC) = misc;
}
void clock_enable_pllx()
{
// Configure and enable PLLX if disabled.
if (!(CLOCK(CLK_RST_CONTROLLER_PLLX_BASE) & PLLX_BASE_ENABLE)) // PLLX_ENABLE.
{
CLOCK(CLK_RST_CONTROLLER_PLLX_MISC_3) &= ~PLLX_MISC3_IDDQ; // Disable IDDQ.
usleep(2);
// Set div configuration.
const u32 pllx_div_cfg = (2 << 20) | (156 << 8) | 2; // P div: 2 (3), N div: 156, M div: 2. 998.4 MHz.
// Bypass dividers.
CLOCK(CLK_RST_CONTROLLER_PLLX_BASE) = PLLX_BASE_BYPASS | pllx_div_cfg;
// Disable bypass
CLOCK(CLK_RST_CONTROLLER_PLLX_BASE) = pllx_div_cfg;
// Set PLLX_LOCK_ENABLE.
CLOCK(CLK_RST_CONTROLLER_PLLX_MISC) |= PLLX_MISC_LOCK_EN;
// Enable PLLX.
CLOCK(CLK_RST_CONTROLLER_PLLX_BASE) = PLLX_BASE_ENABLE | pllx_div_cfg;
}
// Wait for PLL to stabilize.
while (!(CLOCK(CLK_RST_CONTROLLER_PLLX_BASE) & PLLX_BASE_LOCK))
;
}
void clock_enable_pllc(u32 divn)
{
u8 pll_divn_curr = (CLOCK(CLK_RST_CONTROLLER_PLLC_BASE) >> 10) & 0xFF;
// Check if already enabled and configured.
if ((CLOCK(CLK_RST_CONTROLLER_PLLC_BASE) & PLLCX_BASE_ENABLE) && (pll_divn_curr == divn))
return;
// Take PLLC out of reset and set basic misc parameters.
CLOCK(CLK_RST_CONTROLLER_PLLC_MISC) =
((CLOCK(CLK_RST_CONTROLLER_PLLC_MISC) & 0xFFF0000F) & ~PLLC_MISC_RESET) | (0x8000 << 4); // PLLC_EXT_FRU.
CLOCK(CLK_RST_CONTROLLER_PLLC_MISC_2) |= 0xF0 << 8; // PLLC_FLL_LD_MEM.
// Disable PLL and IDDQ in case they are on.
CLOCK(CLK_RST_CONTROLLER_PLLC_BASE) &= ~PLLCX_BASE_ENABLE;
CLOCK(CLK_RST_CONTROLLER_PLLC_MISC_1) &= ~PLLC_MISC1_IDDQ;
usleep(10);
// Set PLLC dividers.
CLOCK(CLK_RST_CONTROLLER_PLLC_BASE) = (divn << 10) | 4; // DIVM: 4, DIVP: 1.
// Enable PLLC and wait for Phase and Frequency lock.
CLOCK(CLK_RST_CONTROLLER_PLLC_BASE) |= PLLCX_BASE_ENABLE;
while (!(CLOCK(CLK_RST_CONTROLLER_PLLC_BASE) & PLLCX_BASE_LOCK))
;
// Disable PLLC_OUT1, enable reset and set div to 1.5.
CLOCK(CLK_RST_CONTROLLER_PLLC_OUT) = BIT(8);
// Enable PLLC_OUT1 and bring it out of reset.
CLOCK(CLK_RST_CONTROLLER_PLLC_OUT) |= (PLLC_OUT1_CLKEN | PLLC_OUT1_RSTN_CLR);
msleep(1); // Wait a bit for PLL to stabilize.
}
void clock_disable_pllc()
{
// Disable PLLC and PLLC_OUT1.
CLOCK(CLK_RST_CONTROLLER_PLLC_OUT) &= ~PLLC_OUT1_RSTN_CLR;
CLOCK(CLK_RST_CONTROLLER_PLLC_MISC) = PLLC_MISC_RESET;
CLOCK(CLK_RST_CONTROLLER_PLLC_BASE) &= ~PLLCX_BASE_ENABLE;
CLOCK(CLK_RST_CONTROLLER_PLLC_MISC_1) |= PLLC_MISC1_IDDQ;
CLOCK(CLK_RST_CONTROLLER_PLLC_MISC_2) &= ~(0xFF << 8); // PLLC_FLL_LD_MEM.
usleep(10);
}
#define PLLC4_ENABLED BIT(31)
#define PLLC4_IN_USE (~PLLC4_ENABLED)
u32 pllc4_enabled = 0;
static void _clock_enable_pllc4(u32 mask)
{
pllc4_enabled |= mask;
if (pllc4_enabled & PLLC4_ENABLED)
return;
// Enable Phase and Frequency lock detection.
//CLOCK(CLK_RST_CONTROLLER_PLLC4_MISC) = PLLC4_MISC_EN_LCKDET;
// Disable PLL and IDDQ in case they are on.
CLOCK(CLK_RST_CONTROLLER_PLLC4_BASE) &= ~PLLCX_BASE_ENABLE;
CLOCK(CLK_RST_CONTROLLER_PLLC4_BASE) &= ~PLLC4_BASE_IDDQ;
usleep(10);
// Set PLLC4 dividers.
CLOCK(CLK_RST_CONTROLLER_PLLC4_BASE) = (0 << 19) | (104 << 8) | 4; // DIVP: 1, DIVN: 104, DIVM: 4. 998MHz OUT0, 199MHz OUT2.
// Enable PLLC4 and wait for Phase and Frequency lock.
CLOCK(CLK_RST_CONTROLLER_PLLC4_BASE) |= PLLCX_BASE_ENABLE;
while (!(CLOCK(CLK_RST_CONTROLLER_PLLC4_BASE) & PLLCX_BASE_LOCK))
;
msleep(1); // Wait a bit for PLL to stabilize.
pllc4_enabled |= PLLC4_ENABLED;
}
static void _clock_disable_pllc4(u32 mask)
{
pllc4_enabled &= ~mask;
// Check if currently in use or disabled.
if ((pllc4_enabled & PLLC4_IN_USE) || !(pllc4_enabled & PLLC4_ENABLED))
return;
// Disable PLLC4.
msleep(1); // Wait at least 1ms to prevent glitching.
CLOCK(CLK_RST_CONTROLLER_PLLC4_BASE) &= ~PLLCX_BASE_ENABLE;
CLOCK(CLK_RST_CONTROLLER_PLLC4_BASE) |= PLLC4_BASE_IDDQ;
usleep(10);
pllc4_enabled = 0;
}
void clock_enable_pllu()
{
// Configure PLLU.
CLOCK(CLK_RST_CONTROLLER_PLLU_MISC) |= BIT(29); // Disable reference clock.
u32 pllu_cfg = (CLOCK(CLK_RST_CONTROLLER_PLLU_BASE) & 0xFFE00000) | BIT(24) | (1 << 16) | (0x19 << 8) | 2;
CLOCK(CLK_RST_CONTROLLER_PLLU_BASE) = pllu_cfg;
CLOCK(CLK_RST_CONTROLLER_PLLU_BASE) = pllu_cfg | PLLCX_BASE_ENABLE; // Enable.
// Wait for PLL to stabilize.
u32 timeout = get_tmr_us() + 1300;
while (!(CLOCK(CLK_RST_CONTROLLER_PLLU_BASE) & PLLCX_BASE_LOCK)) // PLL_LOCK.
if (get_tmr_us() > timeout)
break;
usleep(10);
// Enable PLLU USB/HSIC/ICUSB/48M.
CLOCK(CLK_RST_CONTROLLER_PLLU_BASE) |= 0x2E00000;
}
void clock_disable_pllu()
{
CLOCK(CLK_RST_CONTROLLER_PLLU_BASE) &= ~0x2E00000; // Disable PLLU USB/HSIC/ICUSB/48M.
CLOCK(CLK_RST_CONTROLLER_PLLU_BASE) &= ~BIT(30); // Disable PLLU.
CLOCK(CLK_RST_CONTROLLER_PLLU_MISC) &= ~BIT(29); // Enable reference clock.
}
void clock_enable_utmipll()
{
// Set UTMIPLL dividers and config based on OSC and enable it to 960 MHz.
CLOCK(CLK_RST_CONTROLLER_UTMIP_PLL_CFG0) = (CLOCK(CLK_RST_CONTROLLER_UTMIP_PLL_CFG0) & 0xFF0000FF) | (25 << 16) | (1 << 8); // 38.4Mhz * (25 / 1) = 960 MHz.
CLOCK(CLK_RST_CONTROLLER_UTMIP_PLL_CFG2) = (CLOCK(CLK_RST_CONTROLLER_UTMIP_PLL_CFG2) & 0xFF00003F) | (24 << 18); // Set delay count for 38.4Mhz osc crystal.
CLOCK(CLK_RST_CONTROLLER_UTMIP_PLL_CFG1) = (CLOCK(CLK_RST_CONTROLLER_UTMIP_PLL_CFG1) & 0x7FFA000) | (1 << 15) | 375;
// Wait for UTMIPLL to stabilize.
u32 retries = 10; // Wait 20us
while (!(CLOCK(CLK_RST_CONTROLLER_UTMIPLL_HW_PWRDN_CFG0) & UTMIPLL_LOCK) && retries)
{
usleep(1);
retries--;
}
}
static int _clock_sdmmc_is_reset(u32 id)
{
switch (id)
{
case SDMMC_1:
return CLOCK(CLK_RST_CONTROLLER_RST_DEVICES_L) & BIT(CLK_L_SDMMC1);
case SDMMC_2:
return CLOCK(CLK_RST_CONTROLLER_RST_DEVICES_L) & BIT(CLK_L_SDMMC2);
case SDMMC_3:
return CLOCK(CLK_RST_CONTROLLER_RST_DEVICES_U) & BIT(CLK_U_SDMMC3);
case SDMMC_4:
return CLOCK(CLK_RST_CONTROLLER_RST_DEVICES_L) & BIT(CLK_L_SDMMC4);
}
return 0;
}
static void _clock_sdmmc_set_reset(u32 id)
{
switch (id)
{
case SDMMC_1:
CLOCK(CLK_RST_CONTROLLER_RST_DEV_L_SET) = BIT(CLK_L_SDMMC1);
break;
case SDMMC_2:
CLOCK(CLK_RST_CONTROLLER_RST_DEV_L_SET) = BIT(CLK_L_SDMMC2);
break;
case SDMMC_3:
CLOCK(CLK_RST_CONTROLLER_RST_DEV_U_SET) = BIT(CLK_U_SDMMC3);
break;
case SDMMC_4:
CLOCK(CLK_RST_CONTROLLER_RST_DEV_L_SET) = BIT(CLK_L_SDMMC4);
break;
}
}
static void _clock_sdmmc_clear_reset(u32 id)
{
switch (id)
{
case SDMMC_1:
CLOCK(CLK_RST_CONTROLLER_RST_DEV_L_CLR) = BIT(CLK_L_SDMMC1);
break;
case SDMMC_2:
CLOCK(CLK_RST_CONTROLLER_RST_DEV_L_CLR) = BIT(CLK_L_SDMMC2);
break;
case SDMMC_3:
CLOCK(CLK_RST_CONTROLLER_RST_DEV_U_CLR) = BIT(CLK_U_SDMMC3);
break;
case SDMMC_4:
CLOCK(CLK_RST_CONTROLLER_RST_DEV_L_CLR) = BIT(CLK_L_SDMMC4);
break;
}
}
static int _clock_sdmmc_is_enabled(u32 id)
{
switch (id)
{
case SDMMC_1:
return CLOCK(CLK_RST_CONTROLLER_CLK_OUT_ENB_L) & BIT(CLK_L_SDMMC1);
case SDMMC_2:
return CLOCK(CLK_RST_CONTROLLER_CLK_OUT_ENB_L) & BIT(CLK_L_SDMMC2);
case SDMMC_3:
return CLOCK(CLK_RST_CONTROLLER_CLK_OUT_ENB_U) & BIT(CLK_U_SDMMC3);
case SDMMC_4:
return CLOCK(CLK_RST_CONTROLLER_CLK_OUT_ENB_L) & BIT(CLK_L_SDMMC4);
}
return 0;
}
static void _clock_sdmmc_set_enable(u32 id)
{
switch (id)
{
case SDMMC_1:
CLOCK(CLK_RST_CONTROLLER_CLK_ENB_L_SET) = BIT(CLK_L_SDMMC1);
break;
case SDMMC_2:
CLOCK(CLK_RST_CONTROLLER_CLK_ENB_L_SET) = BIT(CLK_L_SDMMC2);
break;
case SDMMC_3:
CLOCK(CLK_RST_CONTROLLER_CLK_ENB_U_SET) = BIT(CLK_U_SDMMC3);
break;
case SDMMC_4:
CLOCK(CLK_RST_CONTROLLER_CLK_ENB_L_SET) = BIT(CLK_L_SDMMC4);
break;
}
}
static void _clock_sdmmc_clear_enable(u32 id)
{
switch (id)
{
case SDMMC_1:
CLOCK(CLK_RST_CONTROLLER_CLK_ENB_L_CLR) = BIT(CLK_L_SDMMC1);
break;
case SDMMC_2:
CLOCK(CLK_RST_CONTROLLER_CLK_ENB_L_CLR) = BIT(CLK_L_SDMMC2);
break;
case SDMMC_3:
CLOCK(CLK_RST_CONTROLLER_CLK_ENB_U_CLR) = BIT(CLK_U_SDMMC3);
break;
case SDMMC_4:
CLOCK(CLK_RST_CONTROLLER_CLK_ENB_L_CLR) = BIT(CLK_L_SDMMC4);
break;
}
}
static void _clock_sdmmc_config_legacy_tm()
{
clk_rst_t *clk = &_clock_sdmmc_legacy_tm;
if (!(CLOCK(clk->enable) & BIT(clk->index)))
clock_enable(clk);
}
typedef struct _clock_sdmmc_t
{
u32 clock;
u32 real_clock;
} clock_sdmmc_t;
static clock_sdmmc_t _clock_sdmmc_table[4] = { 0 };
#define SDMMC_CLOCK_SRC_PLLP_OUT0 0x0
#define SDMMC_CLOCK_SRC_PLLC4_OUT2 0x3
#define SDMMC_CLOCK_SRC_PLLC4_OUT0 0x7
#define SDMMC4_CLOCK_SRC_PLLC4_OUT2_LJ 0x1
static int _clock_sdmmc_config_clock_host(u32 *pclock, u32 id, u32 val)
{
u32 divisor = 0;
u32 source = SDMMC_CLOCK_SRC_PLLP_OUT0;
if (id > SDMMC_4)
return 0;
// Get IO clock divisor.
switch (val)
{
case 25000:
*pclock = 24728;
divisor = 31; // 16.5 div.
break;
case 26000:
*pclock = 25500;
divisor = 30; // 16 div.
break;
case 50000:
*pclock = 48000;
divisor = 15; // 8.5 div.
break;
case 52000:
*pclock = 51000;
divisor = 14; // 8 div.
break;
case 82000:
*pclock = 81600;
divisor = 8; // 5 div.
break;
case 100000:
source = SDMMC_CLOCK_SRC_PLLC4_OUT2;
*pclock = 99840;
divisor = 2; // 2 div.
break;
case 164000:
*pclock = 163200;
divisor = 3; // 2.5 div.
break;
case 200000:
switch (id)
{
case SDMMC_1:
case SDMMC_3:
source = SDMMC_CLOCK_SRC_PLLC4_OUT2;
break;
case SDMMC_2:
case SDMMC_4:
source = SDMMC4_CLOCK_SRC_PLLC4_OUT2_LJ; // div is ignored.
break;
}
*pclock = 199680;
divisor = 0; // 1 div.
break;
#ifdef BDK_SDMMC_UHS_DDR200_SUPPORT
case 400000:
source = SDMMC_CLOCK_SRC_PLLC4_OUT0;
*pclock = 399360;
divisor = 3; // 2.5 div
break;
#endif
}
_clock_sdmmc_table[id].clock = val;
_clock_sdmmc_table[id].real_clock = *pclock;
// Enable PLLC4 if in use by any SDMMC.
if (source != SDMMC_CLOCK_SRC_PLLP_OUT0)
_clock_enable_pllc4(BIT(id));
// Set SDMMC legacy timeout clock.
_clock_sdmmc_config_legacy_tm();
// Set SDMMC clock.
u32 src_div = (source << 29) | divisor;
switch (id)
{
case SDMMC_1:
CLOCK(CLK_RST_CONTROLLER_CLK_SOURCE_SDMMC1) = src_div;
break;
case SDMMC_2:
CLOCK(CLK_RST_CONTROLLER_CLK_SOURCE_SDMMC2) = src_div;
break;
case SDMMC_3:
CLOCK(CLK_RST_CONTROLLER_CLK_SOURCE_SDMMC3) = src_div;
break;
case SDMMC_4:
CLOCK(CLK_RST_CONTROLLER_CLK_SOURCE_SDMMC4) = src_div;
break;
}
return 1;
}
void clock_sdmmc_config_clock_source(u32 *pclock, u32 id, u32 val)
{
if (_clock_sdmmc_table[id].clock == val)
{
*pclock = _clock_sdmmc_table[id].real_clock;
}
else
{
int is_enabled = _clock_sdmmc_is_enabled(id);
if (is_enabled)
_clock_sdmmc_clear_enable(id);
_clock_sdmmc_config_clock_host(pclock, id, val);
if (is_enabled)
_clock_sdmmc_set_enable(id);
_clock_sdmmc_is_reset(id);
}
}
void clock_sdmmc_get_card_clock_div(u32 *pclock, u16 *pdivisor, u32 type)
{
// Get Card clock divisor.
switch (type)
{
case SDHCI_TIMING_MMC_ID: // Actual card clock: 386.36 KHz.
*pclock = 26000;
*pdivisor = 66;
break;
case SDHCI_TIMING_MMC_LS26:
*pclock = 26000;
*pdivisor = 1;
break;
case SDHCI_TIMING_MMC_HS52:
*pclock = 52000;
*pdivisor = 1;
break;
case SDHCI_TIMING_MMC_HS200:
case SDHCI_TIMING_MMC_HS400:
case SDHCI_TIMING_UHS_SDR104:
*pclock = 200000;
*pdivisor = 1;
break;
case SDHCI_TIMING_SD_ID: // Actual card clock: 386.38 KHz.
*pclock = 25000;
*pdivisor = 64;
break;
case SDHCI_TIMING_SD_DS12:
case SDHCI_TIMING_UHS_SDR12:
*pclock = 25000;
*pdivisor = 1;
break;
case SDHCI_TIMING_SD_HS25:
case SDHCI_TIMING_UHS_SDR25:
*pclock = 50000;
*pdivisor = 1;
break;
case SDHCI_TIMING_UHS_SDR50:
*pclock = 100000;
*pdivisor = 1;
break;
case SDHCI_TIMING_UHS_SDR82:
*pclock = 164000;
*pdivisor = 1;
break;
case SDHCI_TIMING_UHS_DDR50: // Actual card clock: 40.80 MHz.
*pclock = 82000;
*pdivisor = 2;
break;
case SDHCI_TIMING_MMC_HS100: // Actual card clock: 99.84 MHz.
*pclock = 200000;
*pdivisor = 2;
break;
#ifdef BDK_SDMMC_UHS_DDR200_SUPPORT
case SDHCI_TIMING_UHS_DDR200: // Actual card clock: 199.68 KHz.
*pclock = 400000;
*pdivisor = 2;
break;
#endif
}
}
int clock_sdmmc_is_not_reset_and_enabled(u32 id)
{
return !_clock_sdmmc_is_reset(id) && _clock_sdmmc_is_enabled(id);
}
void clock_sdmmc_enable(u32 id, u32 val)
{
u32 clock = 0;
if (_clock_sdmmc_is_enabled(id))
_clock_sdmmc_clear_enable(id);
_clock_sdmmc_set_reset(id);
_clock_sdmmc_config_clock_host(&clock, id, val);
_clock_sdmmc_set_enable(id);
_clock_sdmmc_is_reset(id);
// Wait 100 cycles for reset and for clocks to stabilize.
usleep((100 * 1000 + clock - 1) / clock);
_clock_sdmmc_clear_reset(id);
_clock_sdmmc_is_reset(id);
}
void clock_sdmmc_disable(u32 id)
{
_clock_sdmmc_set_reset(id);
_clock_sdmmc_clear_enable(id);
_clock_sdmmc_is_reset(id);
_clock_disable_pllc4(BIT(id));
}
u32 clock_get_osc_freq()
{
CLOCK(CLK_RST_CONTROLLER_OSC_FREQ_DET) = OSC_FREQ_DET_TRIG | (2 - 1); // 2 periods of 32.76KHz window.
while (CLOCK(CLK_RST_CONTROLLER_OSC_FREQ_DET_STATUS) & OSC_FREQ_DET_BUSY)
;
u32 cnt = (CLOCK(CLK_RST_CONTROLLER_OSC_FREQ_DET_STATUS) & OSC_FREQ_DET_CNT);
CLOCK(CLK_RST_CONTROLLER_OSC_FREQ_DET) = 0;
// Return frequency in KHz.
for (u32 i = 0; i < ARRAY_SIZE(_clock_osc_cnt); i++)
if (cnt >= _clock_osc_cnt[i].min && cnt <= _clock_osc_cnt[i].max)
return _clock_osc_cnt[i].freq;
return 0;
}
u32 clock_get_dev_freq(clock_pto_id_t id)
{
const u32 pto_win = 16;
const u32 pto_osc = 32768;
u32 val = ((id & PTO_SRC_SEL_MASK) << PTO_SRC_SEL_SHIFT) | PTO_DIV_SEL_DIV1 | PTO_CLK_ENABLE | (pto_win - 1);
CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_CNTL) = val;
(void)CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_CNTL);
usleep(2);
CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_CNTL) = val | PTO_CNT_RST;
(void)CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_CNTL);
usleep(2);
CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_CNTL) = val;
(void)CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_CNTL);
usleep(2);
CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_CNTL) = val | PTO_CNT_EN;
(void)CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_CNTL);
usleep((1000000 * pto_win / pto_osc) + 12 + 2);
while (CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_STATUS) & PTO_CLK_CNT_BUSY)
;
u32 cnt = CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_STATUS) & PTO_CLK_CNT;
CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_CNTL) = 0;
(void)CLOCK(CLK_RST_CONTROLLER_PTO_CLK_CNT_CNTL);
usleep(2);
u32 freq_khz = (u64)cnt * pto_osc / pto_win / 1000;
return freq_khz;
}