WSL2-Linux-Kernel/drivers/clk/tegra/clk-tegra210.c

3766 строки
122 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (c) 2012-2014 NVIDIA CORPORATION. All rights reserved.
*/
#include <linux/io.h>
#include <linux/clk.h>
#include <linux/clk-provider.h>
#include <linux/clkdev.h>
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/syscore_ops.h>
#include <linux/delay.h>
#include <linux/export.h>
#include <linux/mutex.h>
#include <linux/clk/tegra.h>
#include <dt-bindings/clock/tegra210-car.h>
#include <dt-bindings/reset/tegra210-car.h>
#include <linux/sizes.h>
#include <soc/tegra/pmc.h>
#include "clk.h"
#include "clk-id.h"
/*
* TEGRA210_CAR_BANK_COUNT: the number of peripheral clock register
* banks present in the Tegra210 CAR IP block. The banks are
* identified by single letters, e.g.: L, H, U, V, W, X, Y. See
* periph_regs[] in drivers/clk/tegra/clk.c
*/
#define TEGRA210_CAR_BANK_COUNT 7
#define CLK_SOURCE_CSITE 0x1d4
#define CLK_SOURCE_EMC 0x19c
#define CLK_SOURCE_SOR1 0x410
#define CLK_SOURCE_SOR0 0x414
#define CLK_SOURCE_LA 0x1f8
#define CLK_SOURCE_SDMMC2 0x154
#define CLK_SOURCE_SDMMC4 0x164
#define CLK_SOURCE_EMC_DLL 0x664
#define PLLC_BASE 0x80
#define PLLC_OUT 0x84
#define PLLC_MISC0 0x88
#define PLLC_MISC1 0x8c
#define PLLC_MISC2 0x5d0
#define PLLC_MISC3 0x5d4
#define PLLC2_BASE 0x4e8
#define PLLC2_MISC0 0x4ec
#define PLLC2_MISC1 0x4f0
#define PLLC2_MISC2 0x4f4
#define PLLC2_MISC3 0x4f8
#define PLLC3_BASE 0x4fc
#define PLLC3_MISC0 0x500
#define PLLC3_MISC1 0x504
#define PLLC3_MISC2 0x508
#define PLLC3_MISC3 0x50c
#define PLLM_BASE 0x90
#define PLLM_MISC1 0x98
#define PLLM_MISC2 0x9c
#define PLLP_BASE 0xa0
#define PLLP_MISC0 0xac
#define PLLP_MISC1 0x680
#define PLLA_BASE 0xb0
#define PLLA_MISC0 0xbc
#define PLLA_MISC1 0xb8
#define PLLA_MISC2 0x5d8
#define PLLD_BASE 0xd0
#define PLLD_MISC0 0xdc
#define PLLD_MISC1 0xd8
#define PLLU_BASE 0xc0
#define PLLU_OUTA 0xc4
#define PLLU_MISC0 0xcc
#define PLLU_MISC1 0xc8
#define PLLX_BASE 0xe0
#define PLLX_MISC0 0xe4
#define PLLX_MISC1 0x510
#define PLLX_MISC2 0x514
#define PLLX_MISC3 0x518
#define PLLX_MISC4 0x5f0
#define PLLX_MISC5 0x5f4
#define PLLE_BASE 0xe8
#define PLLE_MISC0 0xec
#define PLLD2_BASE 0x4b8
#define PLLD2_MISC0 0x4bc
#define PLLD2_MISC1 0x570
#define PLLD2_MISC2 0x574
#define PLLD2_MISC3 0x578
#define PLLE_AUX 0x48c
#define PLLRE_BASE 0x4c4
#define PLLRE_MISC0 0x4c8
#define PLLRE_OUT1 0x4cc
#define PLLDP_BASE 0x590
#define PLLDP_MISC 0x594
#define PLLC4_BASE 0x5a4
#define PLLC4_MISC0 0x5a8
#define PLLC4_OUT 0x5e4
#define PLLMB_BASE 0x5e8
#define PLLMB_MISC1 0x5ec
#define PLLA1_BASE 0x6a4
#define PLLA1_MISC0 0x6a8
#define PLLA1_MISC1 0x6ac
#define PLLA1_MISC2 0x6b0
#define PLLA1_MISC3 0x6b4
#define PLLU_IDDQ_BIT 31
#define PLLCX_IDDQ_BIT 27
#define PLLRE_IDDQ_BIT 24
#define PLLA_IDDQ_BIT 25
#define PLLD_IDDQ_BIT 20
#define PLLSS_IDDQ_BIT 18
#define PLLM_IDDQ_BIT 5
#define PLLMB_IDDQ_BIT 17
#define PLLXP_IDDQ_BIT 3
#define PLLCX_RESET_BIT 30
#define PLL_BASE_LOCK BIT(27)
#define PLLCX_BASE_LOCK BIT(26)
#define PLLE_MISC_LOCK BIT(11)
#define PLLRE_MISC_LOCK BIT(27)
#define PLL_MISC_LOCK_ENABLE 18
#define PLLC_MISC_LOCK_ENABLE 24
#define PLLDU_MISC_LOCK_ENABLE 22
#define PLLU_MISC_LOCK_ENABLE 29
#define PLLE_MISC_LOCK_ENABLE 9
#define PLLRE_MISC_LOCK_ENABLE 30
#define PLLSS_MISC_LOCK_ENABLE 30
#define PLLP_MISC_LOCK_ENABLE 18
#define PLLM_MISC_LOCK_ENABLE 4
#define PLLMB_MISC_LOCK_ENABLE 16
#define PLLA_MISC_LOCK_ENABLE 28
#define PLLU_MISC_LOCK_ENABLE 29
#define PLLD_MISC_LOCK_ENABLE 18
#define PLLA_SDM_DIN_MASK 0xffff
#define PLLA_SDM_EN_MASK BIT(26)
#define PLLD_SDM_EN_MASK BIT(16)
#define PLLD2_SDM_EN_MASK BIT(31)
#define PLLD2_SSC_EN_MASK 0
#define PLLDP_SS_CFG 0x598
#define PLLDP_SDM_EN_MASK BIT(31)
#define PLLDP_SSC_EN_MASK BIT(30)
#define PLLDP_SS_CTRL1 0x59c
#define PLLDP_SS_CTRL2 0x5a0
#define PMC_PLLM_WB0_OVERRIDE 0x1dc
#define PMC_PLLM_WB0_OVERRIDE_2 0x2b0
#define UTMIP_PLL_CFG2 0x488
#define UTMIP_PLL_CFG2_STABLE_COUNT(x) (((x) & 0xfff) << 6)
#define UTMIP_PLL_CFG2_ACTIVE_DLY_COUNT(x) (((x) & 0x3f) << 18)
#define UTMIP_PLL_CFG2_FORCE_PD_SAMP_A_POWERDOWN BIT(0)
#define UTMIP_PLL_CFG2_FORCE_PD_SAMP_A_POWERUP BIT(1)
#define UTMIP_PLL_CFG2_FORCE_PD_SAMP_B_POWERDOWN BIT(2)
#define UTMIP_PLL_CFG2_FORCE_PD_SAMP_B_POWERUP BIT(3)
#define UTMIP_PLL_CFG2_FORCE_PD_SAMP_C_POWERDOWN BIT(4)
#define UTMIP_PLL_CFG2_FORCE_PD_SAMP_C_POWERUP BIT(5)
#define UTMIP_PLL_CFG2_FORCE_PD_SAMP_D_POWERDOWN BIT(24)
#define UTMIP_PLL_CFG2_FORCE_PD_SAMP_D_POWERUP BIT(25)
#define UTMIP_PLL_CFG1 0x484
#define UTMIP_PLL_CFG1_ENABLE_DLY_COUNT(x) (((x) & 0x1f) << 27)
#define UTMIP_PLL_CFG1_XTAL_FREQ_COUNT(x) (((x) & 0xfff) << 0)
#define UTMIP_PLL_CFG1_FORCE_PLLU_POWERUP BIT(17)
#define UTMIP_PLL_CFG1_FORCE_PLLU_POWERDOWN BIT(16)
#define UTMIP_PLL_CFG1_FORCE_PLL_ENABLE_POWERUP BIT(15)
#define UTMIP_PLL_CFG1_FORCE_PLL_ENABLE_POWERDOWN BIT(14)
#define UTMIP_PLL_CFG1_FORCE_PLL_ACTIVE_POWERDOWN BIT(12)
#define SATA_PLL_CFG0 0x490
#define SATA_PLL_CFG0_PADPLL_RESET_SWCTL BIT(0)
#define SATA_PLL_CFG0_PADPLL_USE_LOCKDET BIT(2)
#define SATA_PLL_CFG0_SATA_SEQ_IN_SWCTL BIT(4)
#define SATA_PLL_CFG0_SATA_SEQ_RESET_INPUT_VALUE BIT(5)
#define SATA_PLL_CFG0_SATA_SEQ_LANE_PD_INPUT_VALUE BIT(6)
#define SATA_PLL_CFG0_SATA_SEQ_PADPLL_PD_INPUT_VALUE BIT(7)
#define SATA_PLL_CFG0_PADPLL_SLEEP_IDDQ BIT(13)
#define SATA_PLL_CFG0_SEQ_ENABLE BIT(24)
#define XUSBIO_PLL_CFG0 0x51c
#define XUSBIO_PLL_CFG0_PADPLL_RESET_SWCTL BIT(0)
#define XUSBIO_PLL_CFG0_CLK_ENABLE_SWCTL BIT(2)
#define XUSBIO_PLL_CFG0_PADPLL_USE_LOCKDET BIT(6)
#define XUSBIO_PLL_CFG0_PADPLL_SLEEP_IDDQ BIT(13)
#define XUSBIO_PLL_CFG0_SEQ_ENABLE BIT(24)
#define UTMIPLL_HW_PWRDN_CFG0 0x52c
#define UTMIPLL_HW_PWRDN_CFG0_UTMIPLL_LOCK BIT(31)
#define UTMIPLL_HW_PWRDN_CFG0_SEQ_START_STATE BIT(25)
#define UTMIPLL_HW_PWRDN_CFG0_SEQ_ENABLE BIT(24)
#define UTMIPLL_HW_PWRDN_CFG0_IDDQ_PD_INCLUDE BIT(7)
#define UTMIPLL_HW_PWRDN_CFG0_USE_LOCKDET BIT(6)
#define UTMIPLL_HW_PWRDN_CFG0_SEQ_RESET_INPUT_VALUE BIT(5)
#define UTMIPLL_HW_PWRDN_CFG0_SEQ_IN_SWCTL BIT(4)
#define UTMIPLL_HW_PWRDN_CFG0_CLK_ENABLE_SWCTL BIT(2)
#define UTMIPLL_HW_PWRDN_CFG0_IDDQ_OVERRIDE BIT(1)
#define UTMIPLL_HW_PWRDN_CFG0_IDDQ_SWCTL BIT(0)
#define PLLU_HW_PWRDN_CFG0 0x530
#define PLLU_HW_PWRDN_CFG0_IDDQ_PD_INCLUDE BIT(28)
#define PLLU_HW_PWRDN_CFG0_SEQ_ENABLE BIT(24)
#define PLLU_HW_PWRDN_CFG0_USE_SWITCH_DETECT BIT(7)
#define PLLU_HW_PWRDN_CFG0_USE_LOCKDET BIT(6)
#define PLLU_HW_PWRDN_CFG0_CLK_ENABLE_SWCTL BIT(2)
#define PLLU_HW_PWRDN_CFG0_CLK_SWITCH_SWCTL BIT(0)
#define XUSB_PLL_CFG0 0x534
#define XUSB_PLL_CFG0_UTMIPLL_LOCK_DLY 0x3ff
#define XUSB_PLL_CFG0_PLLU_LOCK_DLY_MASK (0x3ff << 14)
#define SPARE_REG0 0x55c
#define CLK_M_DIVISOR_SHIFT 2
#define CLK_M_DIVISOR_MASK 0x3
#define CLK_MASK_ARM 0x44
#define MISC_CLK_ENB 0x48
#define RST_DFLL_DVCO 0x2f4
#define DVFS_DFLL_RESET_SHIFT 0
#define CLK_RST_CONTROLLER_CLK_OUT_ENB_X_SET 0x284
#define CLK_RST_CONTROLLER_CLK_OUT_ENB_X_CLR 0x288
#define CLK_OUT_ENB_X_CLK_ENB_EMC_DLL BIT(14)
#define CLK_RST_CONTROLLER_RST_DEV_Y_SET 0x2a8
#define CLK_RST_CONTROLLER_RST_DEV_Y_CLR 0x2ac
#define CPU_SOFTRST_CTRL 0x380
#define LVL2_CLK_GATE_OVRA 0xf8
#define LVL2_CLK_GATE_OVRC 0x3a0
#define LVL2_CLK_GATE_OVRD 0x3a4
#define LVL2_CLK_GATE_OVRE 0x554
/* I2S registers to handle during APE MBIST WAR */
#define TEGRA210_I2S_BASE 0x1000
#define TEGRA210_I2S_SIZE 0x100
#define TEGRA210_I2S_CTRLS 5
#define TEGRA210_I2S_CG 0x88
#define TEGRA210_I2S_CTRL 0xa0
/* DISPA registers to handle during MBIST WAR */
#define DC_CMD_DISPLAY_COMMAND 0xc8
#define DC_COM_DSC_TOP_CTL 0xcf8
/* VIC register to handle during MBIST WAR */
#define NV_PVIC_THI_SLCG_OVERRIDE_LOW 0x8c
/* APE, DISPA and VIC base addesses needed for MBIST WAR */
#define TEGRA210_AHUB_BASE 0x702d0000
#define TEGRA210_DISPA_BASE 0x54200000
#define TEGRA210_VIC_BASE 0x54340000
/*
* SDM fractional divisor is 16-bit 2's complement signed number within
* (-2^12 ... 2^12-1) range. Represented in PLL data structure as unsigned
* 16-bit value, with "0" divisor mapped to 0xFFFF. Data "0" is used to
* indicate that SDM is disabled.
*
* Effective ndiv value when SDM is enabled: ndiv + 1/2 + sdm_din/2^13
*/
#define PLL_SDM_COEFF BIT(13)
#define sdin_din_to_data(din) ((u16)((din) ? : 0xFFFFU))
#define sdin_data_to_din(dat) (((dat) == 0xFFFFU) ? 0 : (s16)dat)
/* This macro returns ndiv effective scaled to SDM range */
#define sdin_get_n_eff(cfg) ((cfg)->n * PLL_SDM_COEFF + ((cfg)->sdm_data ? \
(PLL_SDM_COEFF/2 + sdin_data_to_din((cfg)->sdm_data)) : 0))
/* Tegra CPU clock and reset control regs */
#define CLK_RST_CONTROLLER_CPU_CMPLX_STATUS 0x470
#ifdef CONFIG_PM_SLEEP
static struct cpu_clk_suspend_context {
u32 clk_csite_src;
} tegra210_cpu_clk_sctx;
#endif
struct tegra210_domain_mbist_war {
void (*handle_lvl2_ovr)(struct tegra210_domain_mbist_war *mbist);
const u32 lvl2_offset;
const u32 lvl2_mask;
const unsigned int num_clks;
const unsigned int *clk_init_data;
struct clk_bulk_data *clks;
};
static struct clk **clks;
static void __iomem *clk_base;
static void __iomem *pmc_base;
static void __iomem *ahub_base;
static void __iomem *dispa_base;
static void __iomem *vic_base;
static unsigned long osc_freq;
static unsigned long pll_ref_freq;
static DEFINE_SPINLOCK(pll_d_lock);
static DEFINE_SPINLOCK(pll_e_lock);
static DEFINE_SPINLOCK(pll_re_lock);
static DEFINE_SPINLOCK(pll_u_lock);
static DEFINE_SPINLOCK(sor0_lock);
static DEFINE_SPINLOCK(sor1_lock);
static DEFINE_SPINLOCK(emc_lock);
static DEFINE_MUTEX(lvl2_ovr_lock);
/* possible OSC frequencies in Hz */
static unsigned long tegra210_input_freq[] = {
[5] = 38400000,
[8] = 12000000,
};
#define PLL_ENABLE (1 << 30)
#define PLLCX_MISC1_IDDQ (1 << 27)
#define PLLCX_MISC0_RESET (1 << 30)
#define PLLCX_MISC0_DEFAULT_VALUE 0x40080000
#define PLLCX_MISC0_WRITE_MASK 0x400ffffb
#define PLLCX_MISC1_DEFAULT_VALUE 0x08000000
#define PLLCX_MISC1_WRITE_MASK 0x08003cff
#define PLLCX_MISC2_DEFAULT_VALUE 0x1f720f05
#define PLLCX_MISC2_WRITE_MASK 0xffffff17
#define PLLCX_MISC3_DEFAULT_VALUE 0x000000c4
#define PLLCX_MISC3_WRITE_MASK 0x00ffffff
/* PLLA */
#define PLLA_BASE_IDDQ (1 << 25)
#define PLLA_BASE_LOCK (1 << 27)
#define PLLA_MISC0_LOCK_ENABLE (1 << 28)
#define PLLA_MISC0_LOCK_OVERRIDE (1 << 27)
#define PLLA_MISC2_EN_SDM (1 << 26)
#define PLLA_MISC2_EN_DYNRAMP (1 << 25)
#define PLLA_MISC0_DEFAULT_VALUE 0x12000020
#define PLLA_MISC0_WRITE_MASK 0x7fffffff
#define PLLA_MISC2_DEFAULT_VALUE 0x0
#define PLLA_MISC2_WRITE_MASK 0x06ffffff
/* PLLD */
#define PLLD_BASE_CSI_CLKSOURCE (1 << 23)
#define PLLD_MISC0_EN_SDM (1 << 16)
#define PLLD_MISC0_LOCK_OVERRIDE (1 << 17)
#define PLLD_MISC0_LOCK_ENABLE (1 << 18)
#define PLLD_MISC0_IDDQ (1 << 20)
#define PLLD_MISC0_DSI_CLKENABLE (1 << 21)
#define PLLD_MISC0_DEFAULT_VALUE 0x00140000
#define PLLD_MISC0_WRITE_MASK 0x3ff7ffff
#define PLLD_MISC1_DEFAULT_VALUE 0x20
#define PLLD_MISC1_WRITE_MASK 0x00ffffff
/* PLLD2 and PLLDP and PLLC4 */
#define PLLDSS_BASE_LOCK (1 << 27)
#define PLLDSS_BASE_LOCK_OVERRIDE (1 << 24)
#define PLLDSS_BASE_IDDQ (1 << 18)
#define PLLDSS_BASE_REF_SEL_SHIFT 25
#define PLLDSS_BASE_REF_SEL_MASK (0x3 << PLLDSS_BASE_REF_SEL_SHIFT)
#define PLLDSS_MISC0_LOCK_ENABLE (1 << 30)
#define PLLDSS_MISC1_CFG_EN_SDM (1 << 31)
#define PLLDSS_MISC1_CFG_EN_SSC (1 << 30)
#define PLLD2_MISC0_DEFAULT_VALUE 0x40000020
#define PLLD2_MISC1_CFG_DEFAULT_VALUE 0x10000000
#define PLLD2_MISC2_CTRL1_DEFAULT_VALUE 0x0
#define PLLD2_MISC3_CTRL2_DEFAULT_VALUE 0x0
#define PLLDP_MISC0_DEFAULT_VALUE 0x40000020
#define PLLDP_MISC1_CFG_DEFAULT_VALUE 0xc0000000
#define PLLDP_MISC2_CTRL1_DEFAULT_VALUE 0xf400f0da
#define PLLDP_MISC3_CTRL2_DEFAULT_VALUE 0x2004f400
#define PLLDSS_MISC0_WRITE_MASK 0x47ffffff
#define PLLDSS_MISC1_CFG_WRITE_MASK 0xf8000000
#define PLLDSS_MISC2_CTRL1_WRITE_MASK 0xffffffff
#define PLLDSS_MISC3_CTRL2_WRITE_MASK 0xffffffff
#define PLLC4_MISC0_DEFAULT_VALUE 0x40000000
/* PLLRE */
#define PLLRE_MISC0_LOCK_ENABLE (1 << 30)
#define PLLRE_MISC0_LOCK_OVERRIDE (1 << 29)
#define PLLRE_MISC0_LOCK (1 << 27)
#define PLLRE_MISC0_IDDQ (1 << 24)
#define PLLRE_BASE_DEFAULT_VALUE 0x0
#define PLLRE_MISC0_DEFAULT_VALUE 0x41000000
#define PLLRE_BASE_DEFAULT_MASK 0x1c000000
#define PLLRE_MISC0_WRITE_MASK 0x67ffffff
/* PLLX */
#define PLLX_USE_DYN_RAMP 1
#define PLLX_BASE_LOCK (1 << 27)
#define PLLX_MISC0_FO_G_DISABLE (0x1 << 28)
#define PLLX_MISC0_LOCK_ENABLE (0x1 << 18)
#define PLLX_MISC2_DYNRAMP_STEPB_SHIFT 24
#define PLLX_MISC2_DYNRAMP_STEPB_MASK (0xFF << PLLX_MISC2_DYNRAMP_STEPB_SHIFT)
#define PLLX_MISC2_DYNRAMP_STEPA_SHIFT 16
#define PLLX_MISC2_DYNRAMP_STEPA_MASK (0xFF << PLLX_MISC2_DYNRAMP_STEPA_SHIFT)
#define PLLX_MISC2_NDIV_NEW_SHIFT 8
#define PLLX_MISC2_NDIV_NEW_MASK (0xFF << PLLX_MISC2_NDIV_NEW_SHIFT)
#define PLLX_MISC2_LOCK_OVERRIDE (0x1 << 4)
#define PLLX_MISC2_DYNRAMP_DONE (0x1 << 2)
#define PLLX_MISC2_EN_DYNRAMP (0x1 << 0)
#define PLLX_MISC3_IDDQ (0x1 << 3)
#define PLLX_MISC0_DEFAULT_VALUE PLLX_MISC0_LOCK_ENABLE
#define PLLX_MISC0_WRITE_MASK 0x10c40000
#define PLLX_MISC1_DEFAULT_VALUE 0x20
#define PLLX_MISC1_WRITE_MASK 0x00ffffff
#define PLLX_MISC2_DEFAULT_VALUE 0x0
#define PLLX_MISC2_WRITE_MASK 0xffffff11
#define PLLX_MISC3_DEFAULT_VALUE PLLX_MISC3_IDDQ
#define PLLX_MISC3_WRITE_MASK 0x01ff0f0f
#define PLLX_MISC4_DEFAULT_VALUE 0x0
#define PLLX_MISC4_WRITE_MASK 0x8000ffff
#define PLLX_MISC5_DEFAULT_VALUE 0x0
#define PLLX_MISC5_WRITE_MASK 0x0000ffff
#define PLLX_HW_CTRL_CFG 0x548
#define PLLX_HW_CTRL_CFG_SWCTRL (0x1 << 0)
/* PLLMB */
#define PLLMB_BASE_LOCK (1 << 27)
#define PLLMB_MISC1_LOCK_OVERRIDE (1 << 18)
#define PLLMB_MISC1_IDDQ (1 << 17)
#define PLLMB_MISC1_LOCK_ENABLE (1 << 16)
#define PLLMB_MISC1_DEFAULT_VALUE 0x00030000
#define PLLMB_MISC1_WRITE_MASK 0x0007ffff
/* PLLP */
#define PLLP_BASE_OVERRIDE (1 << 28)
#define PLLP_BASE_LOCK (1 << 27)
#define PLLP_MISC0_LOCK_ENABLE (1 << 18)
#define PLLP_MISC0_LOCK_OVERRIDE (1 << 17)
#define PLLP_MISC0_IDDQ (1 << 3)
#define PLLP_MISC1_HSIO_EN_SHIFT 29
#define PLLP_MISC1_HSIO_EN (1 << PLLP_MISC1_HSIO_EN_SHIFT)
#define PLLP_MISC1_XUSB_EN_SHIFT 28
#define PLLP_MISC1_XUSB_EN (1 << PLLP_MISC1_XUSB_EN_SHIFT)
#define PLLP_MISC0_DEFAULT_VALUE 0x00040008
#define PLLP_MISC1_DEFAULT_VALUE 0x0
#define PLLP_MISC0_WRITE_MASK 0xdc6000f
#define PLLP_MISC1_WRITE_MASK 0x70ffffff
/* PLLU */
#define PLLU_BASE_LOCK (1 << 27)
#define PLLU_BASE_OVERRIDE (1 << 24)
#define PLLU_BASE_CLKENABLE_USB (1 << 21)
#define PLLU_BASE_CLKENABLE_HSIC (1 << 22)
#define PLLU_BASE_CLKENABLE_ICUSB (1 << 23)
#define PLLU_BASE_CLKENABLE_48M (1 << 25)
#define PLLU_BASE_CLKENABLE_ALL (PLLU_BASE_CLKENABLE_USB |\
PLLU_BASE_CLKENABLE_HSIC |\
PLLU_BASE_CLKENABLE_ICUSB |\
PLLU_BASE_CLKENABLE_48M)
#define PLLU_MISC0_IDDQ (1 << 31)
#define PLLU_MISC0_LOCK_ENABLE (1 << 29)
#define PLLU_MISC1_LOCK_OVERRIDE (1 << 0)
#define PLLU_MISC0_DEFAULT_VALUE 0xa0000000
#define PLLU_MISC1_DEFAULT_VALUE 0x0
#define PLLU_MISC0_WRITE_MASK 0xbfffffff
#define PLLU_MISC1_WRITE_MASK 0x00000007
void tegra210_xusb_pll_hw_control_enable(void)
{
u32 val;
val = readl_relaxed(clk_base + XUSBIO_PLL_CFG0);
val &= ~(XUSBIO_PLL_CFG0_CLK_ENABLE_SWCTL |
XUSBIO_PLL_CFG0_PADPLL_RESET_SWCTL);
val |= XUSBIO_PLL_CFG0_PADPLL_USE_LOCKDET |
XUSBIO_PLL_CFG0_PADPLL_SLEEP_IDDQ;
writel_relaxed(val, clk_base + XUSBIO_PLL_CFG0);
}
EXPORT_SYMBOL_GPL(tegra210_xusb_pll_hw_control_enable);
void tegra210_xusb_pll_hw_sequence_start(void)
{
u32 val;
val = readl_relaxed(clk_base + XUSBIO_PLL_CFG0);
val |= XUSBIO_PLL_CFG0_SEQ_ENABLE;
writel_relaxed(val, clk_base + XUSBIO_PLL_CFG0);
}
EXPORT_SYMBOL_GPL(tegra210_xusb_pll_hw_sequence_start);
void tegra210_sata_pll_hw_control_enable(void)
{
u32 val;
val = readl_relaxed(clk_base + SATA_PLL_CFG0);
val &= ~SATA_PLL_CFG0_PADPLL_RESET_SWCTL;
val |= SATA_PLL_CFG0_PADPLL_USE_LOCKDET |
SATA_PLL_CFG0_PADPLL_SLEEP_IDDQ;
writel_relaxed(val, clk_base + SATA_PLL_CFG0);
}
EXPORT_SYMBOL_GPL(tegra210_sata_pll_hw_control_enable);
void tegra210_sata_pll_hw_sequence_start(void)
{
u32 val;
val = readl_relaxed(clk_base + SATA_PLL_CFG0);
val |= SATA_PLL_CFG0_SEQ_ENABLE;
writel_relaxed(val, clk_base + SATA_PLL_CFG0);
}
EXPORT_SYMBOL_GPL(tegra210_sata_pll_hw_sequence_start);
void tegra210_set_sata_pll_seq_sw(bool state)
{
u32 val;
val = readl_relaxed(clk_base + SATA_PLL_CFG0);
if (state) {
val |= SATA_PLL_CFG0_SATA_SEQ_IN_SWCTL;
val |= SATA_PLL_CFG0_SATA_SEQ_RESET_INPUT_VALUE;
val |= SATA_PLL_CFG0_SATA_SEQ_LANE_PD_INPUT_VALUE;
val |= SATA_PLL_CFG0_SATA_SEQ_PADPLL_PD_INPUT_VALUE;
} else {
val &= ~SATA_PLL_CFG0_SATA_SEQ_IN_SWCTL;
val &= ~SATA_PLL_CFG0_SATA_SEQ_RESET_INPUT_VALUE;
val &= ~SATA_PLL_CFG0_SATA_SEQ_LANE_PD_INPUT_VALUE;
val &= ~SATA_PLL_CFG0_SATA_SEQ_PADPLL_PD_INPUT_VALUE;
}
writel_relaxed(val, clk_base + SATA_PLL_CFG0);
}
EXPORT_SYMBOL_GPL(tegra210_set_sata_pll_seq_sw);
void tegra210_clk_emc_dll_enable(bool flag)
{
u32 offset = flag ? CLK_RST_CONTROLLER_CLK_OUT_ENB_X_SET :
CLK_RST_CONTROLLER_CLK_OUT_ENB_X_CLR;
writel_relaxed(CLK_OUT_ENB_X_CLK_ENB_EMC_DLL, clk_base + offset);
}
EXPORT_SYMBOL_GPL(tegra210_clk_emc_dll_enable);
void tegra210_clk_emc_dll_update_setting(u32 emc_dll_src_value)
{
writel_relaxed(emc_dll_src_value, clk_base + CLK_SOURCE_EMC_DLL);
}
EXPORT_SYMBOL_GPL(tegra210_clk_emc_dll_update_setting);
void tegra210_clk_emc_update_setting(u32 emc_src_value)
{
writel_relaxed(emc_src_value, clk_base + CLK_SOURCE_EMC);
}
EXPORT_SYMBOL_GPL(tegra210_clk_emc_update_setting);
static void tegra210_generic_mbist_war(struct tegra210_domain_mbist_war *mbist)
{
u32 val;
val = readl_relaxed(clk_base + mbist->lvl2_offset);
writel_relaxed(val | mbist->lvl2_mask, clk_base + mbist->lvl2_offset);
fence_udelay(1, clk_base);
writel_relaxed(val, clk_base + mbist->lvl2_offset);
fence_udelay(1, clk_base);
}
static void tegra210_venc_mbist_war(struct tegra210_domain_mbist_war *mbist)
{
u32 csi_src, ovra, ovre;
unsigned long flags = 0;
spin_lock_irqsave(&pll_d_lock, flags);
csi_src = readl_relaxed(clk_base + PLLD_BASE);
writel_relaxed(csi_src | PLLD_BASE_CSI_CLKSOURCE, clk_base + PLLD_BASE);
fence_udelay(1, clk_base);
ovra = readl_relaxed(clk_base + LVL2_CLK_GATE_OVRA);
writel_relaxed(ovra | BIT(15), clk_base + LVL2_CLK_GATE_OVRA);
ovre = readl_relaxed(clk_base + LVL2_CLK_GATE_OVRE);
writel_relaxed(ovre | BIT(3), clk_base + LVL2_CLK_GATE_OVRE);
fence_udelay(1, clk_base);
writel_relaxed(ovra, clk_base + LVL2_CLK_GATE_OVRA);
writel_relaxed(ovre, clk_base + LVL2_CLK_GATE_OVRE);
writel_relaxed(csi_src, clk_base + PLLD_BASE);
fence_udelay(1, clk_base);
spin_unlock_irqrestore(&pll_d_lock, flags);
}
static void tegra210_disp_mbist_war(struct tegra210_domain_mbist_war *mbist)
{
u32 ovra, dsc_top_ctrl;
ovra = readl_relaxed(clk_base + LVL2_CLK_GATE_OVRA);
writel_relaxed(ovra | BIT(1), clk_base + LVL2_CLK_GATE_OVRA);
fence_udelay(1, clk_base);
dsc_top_ctrl = readl_relaxed(dispa_base + DC_COM_DSC_TOP_CTL);
writel_relaxed(dsc_top_ctrl | BIT(2), dispa_base + DC_COM_DSC_TOP_CTL);
readl_relaxed(dispa_base + DC_CMD_DISPLAY_COMMAND);
writel_relaxed(dsc_top_ctrl, dispa_base + DC_COM_DSC_TOP_CTL);
readl_relaxed(dispa_base + DC_CMD_DISPLAY_COMMAND);
writel_relaxed(ovra, clk_base + LVL2_CLK_GATE_OVRA);
fence_udelay(1, clk_base);
}
static void tegra210_vic_mbist_war(struct tegra210_domain_mbist_war *mbist)
{
u32 ovre, val;
ovre = readl_relaxed(clk_base + LVL2_CLK_GATE_OVRE);
writel_relaxed(ovre | BIT(5), clk_base + LVL2_CLK_GATE_OVRE);
fence_udelay(1, clk_base);
val = readl_relaxed(vic_base + NV_PVIC_THI_SLCG_OVERRIDE_LOW);
writel_relaxed(val | BIT(0) | GENMASK(7, 2) | BIT(24),
vic_base + NV_PVIC_THI_SLCG_OVERRIDE_LOW);
fence_udelay(1, vic_base + NV_PVIC_THI_SLCG_OVERRIDE_LOW);
writel_relaxed(val, vic_base + NV_PVIC_THI_SLCG_OVERRIDE_LOW);
readl(vic_base + NV_PVIC_THI_SLCG_OVERRIDE_LOW);
writel_relaxed(ovre, clk_base + LVL2_CLK_GATE_OVRE);
fence_udelay(1, clk_base);
}
static void tegra210_ape_mbist_war(struct tegra210_domain_mbist_war *mbist)
{
void __iomem *i2s_base;
unsigned int i;
u32 ovrc, ovre;
ovrc = readl_relaxed(clk_base + LVL2_CLK_GATE_OVRC);
ovre = readl_relaxed(clk_base + LVL2_CLK_GATE_OVRE);
writel_relaxed(ovrc | BIT(1), clk_base + LVL2_CLK_GATE_OVRC);
writel_relaxed(ovre | BIT(10) | BIT(11),
clk_base + LVL2_CLK_GATE_OVRE);
fence_udelay(1, clk_base);
i2s_base = ahub_base + TEGRA210_I2S_BASE;
for (i = 0; i < TEGRA210_I2S_CTRLS; i++) {
u32 i2s_ctrl;
i2s_ctrl = readl_relaxed(i2s_base + TEGRA210_I2S_CTRL);
writel_relaxed(i2s_ctrl | BIT(10),
i2s_base + TEGRA210_I2S_CTRL);
writel_relaxed(0, i2s_base + TEGRA210_I2S_CG);
readl(i2s_base + TEGRA210_I2S_CG);
writel_relaxed(1, i2s_base + TEGRA210_I2S_CG);
writel_relaxed(i2s_ctrl, i2s_base + TEGRA210_I2S_CTRL);
readl(i2s_base + TEGRA210_I2S_CTRL);
i2s_base += TEGRA210_I2S_SIZE;
}
writel_relaxed(ovrc, clk_base + LVL2_CLK_GATE_OVRC);
writel_relaxed(ovre, clk_base + LVL2_CLK_GATE_OVRE);
fence_udelay(1, clk_base);
}
static inline void _pll_misc_chk_default(void __iomem *base,
struct tegra_clk_pll_params *params,
u8 misc_num, u32 default_val, u32 mask)
{
u32 boot_val = readl_relaxed(base + params->ext_misc_reg[misc_num]);
boot_val &= mask;
default_val &= mask;
if (boot_val != default_val) {
pr_warn("boot misc%d 0x%x: expected 0x%x\n",
misc_num, boot_val, default_val);
pr_warn(" (comparison mask = 0x%x)\n", mask);
params->defaults_set = false;
}
}
/*
* PLLCX: PLLC, PLLC2, PLLC3, PLLA1
* Hybrid PLLs with dynamic ramp. Dynamic ramp is allowed for any transition
* that changes NDIV only, while PLL is already locked.
*/
static void pllcx_check_defaults(struct tegra_clk_pll_params *params)
{
u32 default_val;
default_val = PLLCX_MISC0_DEFAULT_VALUE & (~PLLCX_MISC0_RESET);
_pll_misc_chk_default(clk_base, params, 0, default_val,
PLLCX_MISC0_WRITE_MASK);
default_val = PLLCX_MISC1_DEFAULT_VALUE & (~PLLCX_MISC1_IDDQ);
_pll_misc_chk_default(clk_base, params, 1, default_val,
PLLCX_MISC1_WRITE_MASK);
default_val = PLLCX_MISC2_DEFAULT_VALUE;
_pll_misc_chk_default(clk_base, params, 2, default_val,
PLLCX_MISC2_WRITE_MASK);
default_val = PLLCX_MISC3_DEFAULT_VALUE;
_pll_misc_chk_default(clk_base, params, 3, default_val,
PLLCX_MISC3_WRITE_MASK);
}
static void tegra210_pllcx_set_defaults(const char *name,
struct tegra_clk_pll *pllcx)
{
pllcx->params->defaults_set = true;
if (readl_relaxed(clk_base + pllcx->params->base_reg) & PLL_ENABLE) {
/* PLL is ON: only check if defaults already set */
pllcx_check_defaults(pllcx->params);
if (!pllcx->params->defaults_set)
pr_warn("%s already enabled. Postponing set full defaults\n",
name);
return;
}
/* Defaults assert PLL reset, and set IDDQ */
writel_relaxed(PLLCX_MISC0_DEFAULT_VALUE,
clk_base + pllcx->params->ext_misc_reg[0]);
writel_relaxed(PLLCX_MISC1_DEFAULT_VALUE,
clk_base + pllcx->params->ext_misc_reg[1]);
writel_relaxed(PLLCX_MISC2_DEFAULT_VALUE,
clk_base + pllcx->params->ext_misc_reg[2]);
writel_relaxed(PLLCX_MISC3_DEFAULT_VALUE,
clk_base + pllcx->params->ext_misc_reg[3]);
udelay(1);
}
static void _pllc_set_defaults(struct tegra_clk_pll *pllcx)
{
tegra210_pllcx_set_defaults("PLL_C", pllcx);
}
static void _pllc2_set_defaults(struct tegra_clk_pll *pllcx)
{
tegra210_pllcx_set_defaults("PLL_C2", pllcx);
}
static void _pllc3_set_defaults(struct tegra_clk_pll *pllcx)
{
tegra210_pllcx_set_defaults("PLL_C3", pllcx);
}
static void _plla1_set_defaults(struct tegra_clk_pll *pllcx)
{
tegra210_pllcx_set_defaults("PLL_A1", pllcx);
}
/*
* PLLA
* PLL with dynamic ramp and fractional SDM. Dynamic ramp is not used.
* Fractional SDM is allowed to provide exact audio rates.
*/
static void tegra210_plla_set_defaults(struct tegra_clk_pll *plla)
{
u32 mask;
u32 val = readl_relaxed(clk_base + plla->params->base_reg);
plla->params->defaults_set = true;
if (val & PLL_ENABLE) {
/*
* PLL is ON: check if defaults already set, then set those
* that can be updated in flight.
*/
if (val & PLLA_BASE_IDDQ) {
pr_warn("PLL_A boot enabled with IDDQ set\n");
plla->params->defaults_set = false;
}
pr_warn("PLL_A already enabled. Postponing set full defaults\n");
val = PLLA_MISC0_DEFAULT_VALUE; /* ignore lock enable */
mask = PLLA_MISC0_LOCK_ENABLE | PLLA_MISC0_LOCK_OVERRIDE;
_pll_misc_chk_default(clk_base, plla->params, 0, val,
~mask & PLLA_MISC0_WRITE_MASK);
val = PLLA_MISC2_DEFAULT_VALUE; /* ignore all but control bit */
_pll_misc_chk_default(clk_base, plla->params, 2, val,
PLLA_MISC2_EN_DYNRAMP);
/* Enable lock detect */
val = readl_relaxed(clk_base + plla->params->ext_misc_reg[0]);
val &= ~mask;
val |= PLLA_MISC0_DEFAULT_VALUE & mask;
writel_relaxed(val, clk_base + plla->params->ext_misc_reg[0]);
udelay(1);
return;
}
/* set IDDQ, enable lock detect, disable dynamic ramp and SDM */
val |= PLLA_BASE_IDDQ;
writel_relaxed(val, clk_base + plla->params->base_reg);
writel_relaxed(PLLA_MISC0_DEFAULT_VALUE,
clk_base + plla->params->ext_misc_reg[0]);
writel_relaxed(PLLA_MISC2_DEFAULT_VALUE,
clk_base + plla->params->ext_misc_reg[2]);
udelay(1);
}
/*
* PLLD
* PLL with fractional SDM.
*/
static void tegra210_plld_set_defaults(struct tegra_clk_pll *plld)
{
u32 val;
u32 mask = 0xffff;
plld->params->defaults_set = true;
if (readl_relaxed(clk_base + plld->params->base_reg) &
PLL_ENABLE) {
/*
* PLL is ON: check if defaults already set, then set those
* that can be updated in flight.
*/
val = PLLD_MISC1_DEFAULT_VALUE;
_pll_misc_chk_default(clk_base, plld->params, 1,
val, PLLD_MISC1_WRITE_MASK);
/* ignore lock, DSI and SDM controls, make sure IDDQ not set */
val = PLLD_MISC0_DEFAULT_VALUE & (~PLLD_MISC0_IDDQ);
mask |= PLLD_MISC0_DSI_CLKENABLE | PLLD_MISC0_LOCK_ENABLE |
PLLD_MISC0_LOCK_OVERRIDE | PLLD_MISC0_EN_SDM;
_pll_misc_chk_default(clk_base, plld->params, 0, val,
~mask & PLLD_MISC0_WRITE_MASK);
if (!plld->params->defaults_set)
pr_warn("PLL_D already enabled. Postponing set full defaults\n");
/* Enable lock detect */
mask = PLLD_MISC0_LOCK_ENABLE | PLLD_MISC0_LOCK_OVERRIDE;
val = readl_relaxed(clk_base + plld->params->ext_misc_reg[0]);
val &= ~mask;
val |= PLLD_MISC0_DEFAULT_VALUE & mask;
writel_relaxed(val, clk_base + plld->params->ext_misc_reg[0]);
udelay(1);
return;
}
val = readl_relaxed(clk_base + plld->params->ext_misc_reg[0]);
val &= PLLD_MISC0_DSI_CLKENABLE;
val |= PLLD_MISC0_DEFAULT_VALUE;
/* set IDDQ, enable lock detect, disable SDM */
writel_relaxed(val, clk_base + plld->params->ext_misc_reg[0]);
writel_relaxed(PLLD_MISC1_DEFAULT_VALUE, clk_base +
plld->params->ext_misc_reg[1]);
udelay(1);
}
/*
* PLLD2, PLLDP
* PLL with fractional SDM and Spread Spectrum (SDM is a must if SSC is used).
*/
static void plldss_defaults(const char *pll_name, struct tegra_clk_pll *plldss,
u32 misc0_val, u32 misc1_val, u32 misc2_val, u32 misc3_val)
{
u32 default_val;
u32 val = readl_relaxed(clk_base + plldss->params->base_reg);
plldss->params->defaults_set = true;
if (val & PLL_ENABLE) {
/*
* PLL is ON: check if defaults already set, then set those
* that can be updated in flight.
*/
if (val & PLLDSS_BASE_IDDQ) {
pr_warn("plldss boot enabled with IDDQ set\n");
plldss->params->defaults_set = false;
}
/* ignore lock enable */
default_val = misc0_val;
_pll_misc_chk_default(clk_base, plldss->params, 0, default_val,
PLLDSS_MISC0_WRITE_MASK &
(~PLLDSS_MISC0_LOCK_ENABLE));
/*
* If SSC is used, check all settings, otherwise just confirm
* that SSC is not used on boot as well. Do nothing when using
* this function for PLLC4 that has only MISC0.
*/
if (plldss->params->ssc_ctrl_en_mask) {
default_val = misc1_val;
_pll_misc_chk_default(clk_base, plldss->params, 1,
default_val, PLLDSS_MISC1_CFG_WRITE_MASK);
default_val = misc2_val;
_pll_misc_chk_default(clk_base, plldss->params, 2,
default_val, PLLDSS_MISC2_CTRL1_WRITE_MASK);
default_val = misc3_val;
_pll_misc_chk_default(clk_base, plldss->params, 3,
default_val, PLLDSS_MISC3_CTRL2_WRITE_MASK);
} else if (plldss->params->ext_misc_reg[1]) {
default_val = misc1_val;
_pll_misc_chk_default(clk_base, plldss->params, 1,
default_val, PLLDSS_MISC1_CFG_WRITE_MASK &
(~PLLDSS_MISC1_CFG_EN_SDM));
}
if (!plldss->params->defaults_set)
pr_warn("%s already enabled. Postponing set full defaults\n",
pll_name);
/* Enable lock detect */
if (val & PLLDSS_BASE_LOCK_OVERRIDE) {
val &= ~PLLDSS_BASE_LOCK_OVERRIDE;
writel_relaxed(val, clk_base +
plldss->params->base_reg);
}
val = readl_relaxed(clk_base + plldss->params->ext_misc_reg[0]);
val &= ~PLLDSS_MISC0_LOCK_ENABLE;
val |= misc0_val & PLLDSS_MISC0_LOCK_ENABLE;
writel_relaxed(val, clk_base + plldss->params->ext_misc_reg[0]);
udelay(1);
return;
}
/* set IDDQ, enable lock detect, configure SDM/SSC */
val |= PLLDSS_BASE_IDDQ;
val &= ~PLLDSS_BASE_LOCK_OVERRIDE;
writel_relaxed(val, clk_base + plldss->params->base_reg);
/* When using this function for PLLC4 exit here */
if (!plldss->params->ext_misc_reg[1]) {
writel_relaxed(misc0_val, clk_base +
plldss->params->ext_misc_reg[0]);
udelay(1);
return;
}
writel_relaxed(misc0_val, clk_base +
plldss->params->ext_misc_reg[0]);
/* if SSC used set by 1st enable */
writel_relaxed(misc1_val & (~PLLDSS_MISC1_CFG_EN_SSC),
clk_base + plldss->params->ext_misc_reg[1]);
writel_relaxed(misc2_val, clk_base + plldss->params->ext_misc_reg[2]);
writel_relaxed(misc3_val, clk_base + plldss->params->ext_misc_reg[3]);
udelay(1);
}
static void tegra210_plld2_set_defaults(struct tegra_clk_pll *plld2)
{
plldss_defaults("PLL_D2", plld2, PLLD2_MISC0_DEFAULT_VALUE,
PLLD2_MISC1_CFG_DEFAULT_VALUE,
PLLD2_MISC2_CTRL1_DEFAULT_VALUE,
PLLD2_MISC3_CTRL2_DEFAULT_VALUE);
}
static void tegra210_plldp_set_defaults(struct tegra_clk_pll *plldp)
{
plldss_defaults("PLL_DP", plldp, PLLDP_MISC0_DEFAULT_VALUE,
PLLDP_MISC1_CFG_DEFAULT_VALUE,
PLLDP_MISC2_CTRL1_DEFAULT_VALUE,
PLLDP_MISC3_CTRL2_DEFAULT_VALUE);
}
/*
* PLLC4
* Base and misc0 layout is the same as PLLD2/PLLDP, but no SDM/SSC support.
* VCO is exposed to the clock tree via fixed 1/3 and 1/5 dividers.
*/
static void tegra210_pllc4_set_defaults(struct tegra_clk_pll *pllc4)
{
plldss_defaults("PLL_C4", pllc4, PLLC4_MISC0_DEFAULT_VALUE, 0, 0, 0);
}
/*
* PLLRE
* VCO is exposed to the clock tree directly along with post-divider output
*/
static void tegra210_pllre_set_defaults(struct tegra_clk_pll *pllre)
{
u32 mask;
u32 val = readl_relaxed(clk_base + pllre->params->base_reg);
pllre->params->defaults_set = true;
if (val & PLL_ENABLE) {
/*
* PLL is ON: check if defaults already set, then set those
* that can be updated in flight.
*/
val &= PLLRE_BASE_DEFAULT_MASK;
if (val != PLLRE_BASE_DEFAULT_VALUE) {
pr_warn("pllre boot base 0x%x : expected 0x%x\n",
val, PLLRE_BASE_DEFAULT_VALUE);
pr_warn("(comparison mask = 0x%x)\n",
PLLRE_BASE_DEFAULT_MASK);
pllre->params->defaults_set = false;
}
/* Ignore lock enable */
val = PLLRE_MISC0_DEFAULT_VALUE & (~PLLRE_MISC0_IDDQ);
mask = PLLRE_MISC0_LOCK_ENABLE | PLLRE_MISC0_LOCK_OVERRIDE;
_pll_misc_chk_default(clk_base, pllre->params, 0, val,
~mask & PLLRE_MISC0_WRITE_MASK);
/* The PLL doesn't work if it's in IDDQ. */
val = readl_relaxed(clk_base + pllre->params->ext_misc_reg[0]);
if (val & PLLRE_MISC0_IDDQ)
pr_warn("unexpected IDDQ bit set for enabled clock\n");
/* Enable lock detect */
val &= ~mask;
val |= PLLRE_MISC0_DEFAULT_VALUE & mask;
writel_relaxed(val, clk_base + pllre->params->ext_misc_reg[0]);
udelay(1);
if (!pllre->params->defaults_set)
pr_warn("PLL_RE already enabled. Postponing set full defaults\n");
return;
}
/* set IDDQ, enable lock detect */
val &= ~PLLRE_BASE_DEFAULT_MASK;
val |= PLLRE_BASE_DEFAULT_VALUE & PLLRE_BASE_DEFAULT_MASK;
writel_relaxed(val, clk_base + pllre->params->base_reg);
writel_relaxed(PLLRE_MISC0_DEFAULT_VALUE,
clk_base + pllre->params->ext_misc_reg[0]);
udelay(1);
}
static void pllx_get_dyn_steps(struct clk_hw *hw, u32 *step_a, u32 *step_b)
{
unsigned long input_rate;
/* cf rate */
if (!IS_ERR_OR_NULL(hw->clk))
input_rate = clk_hw_get_rate(clk_hw_get_parent(hw));
else
input_rate = 38400000;
input_rate /= tegra_pll_get_fixed_mdiv(hw, input_rate);
switch (input_rate) {
case 12000000:
case 12800000:
case 13000000:
*step_a = 0x2B;
*step_b = 0x0B;
return;
case 19200000:
*step_a = 0x12;
*step_b = 0x08;
return;
case 38400000:
*step_a = 0x04;
*step_b = 0x05;
return;
default:
pr_err("%s: Unexpected reference rate %lu\n",
__func__, input_rate);
BUG();
}
}
static void pllx_check_defaults(struct tegra_clk_pll *pll)
{
u32 default_val;
default_val = PLLX_MISC0_DEFAULT_VALUE;
/* ignore lock enable */
_pll_misc_chk_default(clk_base, pll->params, 0, default_val,
PLLX_MISC0_WRITE_MASK & (~PLLX_MISC0_LOCK_ENABLE));
default_val = PLLX_MISC1_DEFAULT_VALUE;
_pll_misc_chk_default(clk_base, pll->params, 1, default_val,
PLLX_MISC1_WRITE_MASK);
/* ignore all but control bit */
default_val = PLLX_MISC2_DEFAULT_VALUE;
_pll_misc_chk_default(clk_base, pll->params, 2,
default_val, PLLX_MISC2_EN_DYNRAMP);
default_val = PLLX_MISC3_DEFAULT_VALUE & (~PLLX_MISC3_IDDQ);
_pll_misc_chk_default(clk_base, pll->params, 3, default_val,
PLLX_MISC3_WRITE_MASK);
default_val = PLLX_MISC4_DEFAULT_VALUE;
_pll_misc_chk_default(clk_base, pll->params, 4, default_val,
PLLX_MISC4_WRITE_MASK);
default_val = PLLX_MISC5_DEFAULT_VALUE;
_pll_misc_chk_default(clk_base, pll->params, 5, default_val,
PLLX_MISC5_WRITE_MASK);
}
static void tegra210_pllx_set_defaults(struct tegra_clk_pll *pllx)
{
u32 val;
u32 step_a, step_b;
pllx->params->defaults_set = true;
/* Get ready dyn ramp state machine settings */
pllx_get_dyn_steps(&pllx->hw, &step_a, &step_b);
val = PLLX_MISC2_DEFAULT_VALUE & (~PLLX_MISC2_DYNRAMP_STEPA_MASK) &
(~PLLX_MISC2_DYNRAMP_STEPB_MASK);
val |= step_a << PLLX_MISC2_DYNRAMP_STEPA_SHIFT;
val |= step_b << PLLX_MISC2_DYNRAMP_STEPB_SHIFT;
if (readl_relaxed(clk_base + pllx->params->base_reg) & PLL_ENABLE) {
/*
* PLL is ON: check if defaults already set, then set those
* that can be updated in flight.
*/
pllx_check_defaults(pllx);
if (!pllx->params->defaults_set)
pr_warn("PLL_X already enabled. Postponing set full defaults\n");
/* Configure dyn ramp, disable lock override */
writel_relaxed(val, clk_base + pllx->params->ext_misc_reg[2]);
/* Enable lock detect */
val = readl_relaxed(clk_base + pllx->params->ext_misc_reg[0]);
val &= ~PLLX_MISC0_LOCK_ENABLE;
val |= PLLX_MISC0_DEFAULT_VALUE & PLLX_MISC0_LOCK_ENABLE;
writel_relaxed(val, clk_base + pllx->params->ext_misc_reg[0]);
udelay(1);
return;
}
/* Enable lock detect and CPU output */
writel_relaxed(PLLX_MISC0_DEFAULT_VALUE, clk_base +
pllx->params->ext_misc_reg[0]);
/* Setup */
writel_relaxed(PLLX_MISC1_DEFAULT_VALUE, clk_base +
pllx->params->ext_misc_reg[1]);
/* Configure dyn ramp state machine, disable lock override */
writel_relaxed(val, clk_base + pllx->params->ext_misc_reg[2]);
/* Set IDDQ */
writel_relaxed(PLLX_MISC3_DEFAULT_VALUE, clk_base +
pllx->params->ext_misc_reg[3]);
/* Disable SDM */
writel_relaxed(PLLX_MISC4_DEFAULT_VALUE, clk_base +
pllx->params->ext_misc_reg[4]);
writel_relaxed(PLLX_MISC5_DEFAULT_VALUE, clk_base +
pllx->params->ext_misc_reg[5]);
udelay(1);
}
/* PLLMB */
static void tegra210_pllmb_set_defaults(struct tegra_clk_pll *pllmb)
{
u32 mask, val = readl_relaxed(clk_base + pllmb->params->base_reg);
pllmb->params->defaults_set = true;
if (val & PLL_ENABLE) {
/*
* PLL is ON: check if defaults already set, then set those
* that can be updated in flight.
*/
val = PLLMB_MISC1_DEFAULT_VALUE & (~PLLMB_MISC1_IDDQ);
mask = PLLMB_MISC1_LOCK_ENABLE | PLLMB_MISC1_LOCK_OVERRIDE;
_pll_misc_chk_default(clk_base, pllmb->params, 0, val,
~mask & PLLMB_MISC1_WRITE_MASK);
if (!pllmb->params->defaults_set)
pr_warn("PLL_MB already enabled. Postponing set full defaults\n");
/* Enable lock detect */
val = readl_relaxed(clk_base + pllmb->params->ext_misc_reg[0]);
val &= ~mask;
val |= PLLMB_MISC1_DEFAULT_VALUE & mask;
writel_relaxed(val, clk_base + pllmb->params->ext_misc_reg[0]);
udelay(1);
return;
}
/* set IDDQ, enable lock detect */
writel_relaxed(PLLMB_MISC1_DEFAULT_VALUE,
clk_base + pllmb->params->ext_misc_reg[0]);
udelay(1);
}
/*
* PLLP
* VCO is exposed to the clock tree directly along with post-divider output.
* Both VCO and post-divider output rates are fixed at 408MHz and 204MHz,
* respectively.
*/
static void pllp_check_defaults(struct tegra_clk_pll *pll, bool enabled)
{
u32 val, mask;
/* Ignore lock enable (will be set), make sure not in IDDQ if enabled */
val = PLLP_MISC0_DEFAULT_VALUE & (~PLLP_MISC0_IDDQ);
mask = PLLP_MISC0_LOCK_ENABLE | PLLP_MISC0_LOCK_OVERRIDE;
if (!enabled)
mask |= PLLP_MISC0_IDDQ;
_pll_misc_chk_default(clk_base, pll->params, 0, val,
~mask & PLLP_MISC0_WRITE_MASK);
/* Ignore branch controls */
val = PLLP_MISC1_DEFAULT_VALUE;
mask = PLLP_MISC1_HSIO_EN | PLLP_MISC1_XUSB_EN;
_pll_misc_chk_default(clk_base, pll->params, 1, val,
~mask & PLLP_MISC1_WRITE_MASK);
}
static void tegra210_pllp_set_defaults(struct tegra_clk_pll *pllp)
{
u32 mask;
u32 val = readl_relaxed(clk_base + pllp->params->base_reg);
pllp->params->defaults_set = true;
if (val & PLL_ENABLE) {
/*
* PLL is ON: check if defaults already set, then set those
* that can be updated in flight.
*/
pllp_check_defaults(pllp, true);
if (!pllp->params->defaults_set)
pr_warn("PLL_P already enabled. Postponing set full defaults\n");
/* Enable lock detect */
val = readl_relaxed(clk_base + pllp->params->ext_misc_reg[0]);
mask = PLLP_MISC0_LOCK_ENABLE | PLLP_MISC0_LOCK_OVERRIDE;
val &= ~mask;
val |= PLLP_MISC0_DEFAULT_VALUE & mask;
writel_relaxed(val, clk_base + pllp->params->ext_misc_reg[0]);
udelay(1);
return;
}
/* set IDDQ, enable lock detect */
writel_relaxed(PLLP_MISC0_DEFAULT_VALUE,
clk_base + pllp->params->ext_misc_reg[0]);
/* Preserve branch control */
val = readl_relaxed(clk_base + pllp->params->ext_misc_reg[1]);
mask = PLLP_MISC1_HSIO_EN | PLLP_MISC1_XUSB_EN;
val &= mask;
val |= ~mask & PLLP_MISC1_DEFAULT_VALUE;
writel_relaxed(val, clk_base + pllp->params->ext_misc_reg[1]);
udelay(1);
}
/*
* PLLU
* VCO is exposed to the clock tree directly along with post-divider output.
* Both VCO and post-divider output rates are fixed at 480MHz and 240MHz,
* respectively.
*/
static void pllu_check_defaults(struct tegra_clk_pll_params *params,
bool hw_control)
{
u32 val, mask;
/* Ignore lock enable (will be set) and IDDQ if under h/w control */
val = PLLU_MISC0_DEFAULT_VALUE & (~PLLU_MISC0_IDDQ);
mask = PLLU_MISC0_LOCK_ENABLE | (hw_control ? PLLU_MISC0_IDDQ : 0);
_pll_misc_chk_default(clk_base, params, 0, val,
~mask & PLLU_MISC0_WRITE_MASK);
val = PLLU_MISC1_DEFAULT_VALUE;
mask = PLLU_MISC1_LOCK_OVERRIDE;
_pll_misc_chk_default(clk_base, params, 1, val,
~mask & PLLU_MISC1_WRITE_MASK);
}
static void tegra210_pllu_set_defaults(struct tegra_clk_pll_params *pllu)
{
u32 val = readl_relaxed(clk_base + pllu->base_reg);
pllu->defaults_set = true;
if (val & PLL_ENABLE) {
/*
* PLL is ON: check if defaults already set, then set those
* that can be updated in flight.
*/
pllu_check_defaults(pllu, false);
if (!pllu->defaults_set)
pr_warn("PLL_U already enabled. Postponing set full defaults\n");
/* Enable lock detect */
val = readl_relaxed(clk_base + pllu->ext_misc_reg[0]);
val &= ~PLLU_MISC0_LOCK_ENABLE;
val |= PLLU_MISC0_DEFAULT_VALUE & PLLU_MISC0_LOCK_ENABLE;
writel_relaxed(val, clk_base + pllu->ext_misc_reg[0]);
val = readl_relaxed(clk_base + pllu->ext_misc_reg[1]);
val &= ~PLLU_MISC1_LOCK_OVERRIDE;
val |= PLLU_MISC1_DEFAULT_VALUE & PLLU_MISC1_LOCK_OVERRIDE;
writel_relaxed(val, clk_base + pllu->ext_misc_reg[1]);
udelay(1);
return;
}
/* set IDDQ, enable lock detect */
writel_relaxed(PLLU_MISC0_DEFAULT_VALUE,
clk_base + pllu->ext_misc_reg[0]);
writel_relaxed(PLLU_MISC1_DEFAULT_VALUE,
clk_base + pllu->ext_misc_reg[1]);
udelay(1);
}
#define mask(w) ((1 << (w)) - 1)
#define divm_mask(p) mask(p->params->div_nmp->divm_width)
#define divn_mask(p) mask(p->params->div_nmp->divn_width)
#define divp_mask(p) (p->params->flags & TEGRA_PLLU ? PLLU_POST_DIVP_MASK :\
mask(p->params->div_nmp->divp_width))
#define divm_shift(p) ((p)->params->div_nmp->divm_shift)
#define divn_shift(p) ((p)->params->div_nmp->divn_shift)
#define divp_shift(p) ((p)->params->div_nmp->divp_shift)
#define divm_mask_shifted(p) (divm_mask(p) << divm_shift(p))
#define divn_mask_shifted(p) (divn_mask(p) << divn_shift(p))
#define divp_mask_shifted(p) (divp_mask(p) << divp_shift(p))
#define PLL_LOCKDET_DELAY 2 /* Lock detection safety delays */
static int tegra210_wait_for_mask(struct tegra_clk_pll *pll,
u32 reg, u32 mask)
{
int i;
u32 val = 0;
for (i = 0; i < pll->params->lock_delay / PLL_LOCKDET_DELAY + 1; i++) {
udelay(PLL_LOCKDET_DELAY);
val = readl_relaxed(clk_base + reg);
if ((val & mask) == mask) {
udelay(PLL_LOCKDET_DELAY);
return 0;
}
}
return -ETIMEDOUT;
}
static int tegra210_pllx_dyn_ramp(struct tegra_clk_pll *pllx,
struct tegra_clk_pll_freq_table *cfg)
{
u32 val, base, ndiv_new_mask;
ndiv_new_mask = (divn_mask(pllx) >> pllx->params->div_nmp->divn_shift)
<< PLLX_MISC2_NDIV_NEW_SHIFT;
val = readl_relaxed(clk_base + pllx->params->ext_misc_reg[2]);
val &= (~ndiv_new_mask);
val |= cfg->n << PLLX_MISC2_NDIV_NEW_SHIFT;
writel_relaxed(val, clk_base + pllx->params->ext_misc_reg[2]);
udelay(1);
val = readl_relaxed(clk_base + pllx->params->ext_misc_reg[2]);
val |= PLLX_MISC2_EN_DYNRAMP;
writel_relaxed(val, clk_base + pllx->params->ext_misc_reg[2]);
udelay(1);
tegra210_wait_for_mask(pllx, pllx->params->ext_misc_reg[2],
PLLX_MISC2_DYNRAMP_DONE);
base = readl_relaxed(clk_base + pllx->params->base_reg) &
(~divn_mask_shifted(pllx));
base |= cfg->n << pllx->params->div_nmp->divn_shift;
writel_relaxed(base, clk_base + pllx->params->base_reg);
udelay(1);
val &= ~PLLX_MISC2_EN_DYNRAMP;
writel_relaxed(val, clk_base + pllx->params->ext_misc_reg[2]);
udelay(1);
pr_debug("%s: dynamic ramp to m = %u n = %u p = %u, Fout = %lu kHz\n",
__clk_get_name(pllx->hw.clk), cfg->m, cfg->n, cfg->p,
cfg->input_rate / cfg->m * cfg->n /
pllx->params->pdiv_tohw[cfg->p].pdiv / 1000);
return 0;
}
/*
* Common configuration for PLLs with fixed input divider policy:
* - always set fixed M-value based on the reference rate
* - always set P-value value 1:1 for output rates above VCO minimum, and
* choose minimum necessary P-value for output rates below VCO maximum
* - calculate N-value based on selected M and P
* - calculate SDM_DIN fractional part
*/
static int tegra210_pll_fixed_mdiv_cfg(struct clk_hw *hw,
struct tegra_clk_pll_freq_table *cfg,
unsigned long rate, unsigned long input_rate)
{
struct tegra_clk_pll *pll = to_clk_pll(hw);
struct tegra_clk_pll_params *params = pll->params;
int p;
unsigned long cf, p_rate;
u32 pdiv;
if (!rate)
return -EINVAL;
if (!(params->flags & TEGRA_PLL_VCO_OUT)) {
p = DIV_ROUND_UP(params->vco_min, rate);
p = params->round_p_to_pdiv(p, &pdiv);
} else {
p = rate >= params->vco_min ? 1 : -EINVAL;
}
if (p < 0)
return -EINVAL;
cfg->m = tegra_pll_get_fixed_mdiv(hw, input_rate);
cfg->p = p;
/* Store P as HW value, as that is what is expected */
cfg->p = tegra_pll_p_div_to_hw(pll, cfg->p);
p_rate = rate * p;
if (p_rate > params->vco_max)
p_rate = params->vco_max;
cf = input_rate / cfg->m;
cfg->n = p_rate / cf;
cfg->sdm_data = 0;
cfg->output_rate = input_rate;
if (params->sdm_ctrl_reg) {
unsigned long rem = p_rate - cf * cfg->n;
/* If ssc is enabled SDM enabled as well, even for integer n */
if (rem || params->ssc_ctrl_reg) {
u64 s = rem * PLL_SDM_COEFF;
do_div(s, cf);
s -= PLL_SDM_COEFF / 2;
cfg->sdm_data = sdin_din_to_data(s);
}
cfg->output_rate *= sdin_get_n_eff(cfg);
cfg->output_rate /= p * cfg->m * PLL_SDM_COEFF;
} else {
cfg->output_rate *= cfg->n;
cfg->output_rate /= p * cfg->m;
}
cfg->input_rate = input_rate;
return 0;
}
/*
* clk_pll_set_gain - set gain to m, n to calculate correct VCO rate
*
* @cfg: struct tegra_clk_pll_freq_table * cfg
*
* For Normal mode:
* Fvco = Fref * NDIV / MDIV
*
* For fractional mode:
* Fvco = Fref * (NDIV + 0.5 + SDM_DIN / PLL_SDM_COEFF) / MDIV
*/
static void tegra210_clk_pll_set_gain(struct tegra_clk_pll_freq_table *cfg)
{
cfg->n = sdin_get_n_eff(cfg);
cfg->m *= PLL_SDM_COEFF;
}
static unsigned long
tegra210_clk_adjust_vco_min(struct tegra_clk_pll_params *params,
unsigned long parent_rate)
{
unsigned long vco_min = params->vco_min;
params->vco_min += DIV_ROUND_UP(parent_rate, PLL_SDM_COEFF);
vco_min = min(vco_min, params->vco_min);
return vco_min;
}
static struct div_nmp pllx_nmp = {
.divm_shift = 0,
.divm_width = 8,
.divn_shift = 8,
.divn_width = 8,
.divp_shift = 20,
.divp_width = 5,
};
/*
* PLL post divider maps - two types: quasi-linear and exponential
* post divider.
*/
#define PLL_QLIN_PDIV_MAX 16
static const struct pdiv_map pll_qlin_pdiv_to_hw[] = {
{ .pdiv = 1, .hw_val = 0 },
{ .pdiv = 2, .hw_val = 1 },
{ .pdiv = 3, .hw_val = 2 },
{ .pdiv = 4, .hw_val = 3 },
{ .pdiv = 5, .hw_val = 4 },
{ .pdiv = 6, .hw_val = 5 },
{ .pdiv = 8, .hw_val = 6 },
{ .pdiv = 9, .hw_val = 7 },
{ .pdiv = 10, .hw_val = 8 },
{ .pdiv = 12, .hw_val = 9 },
{ .pdiv = 15, .hw_val = 10 },
{ .pdiv = 16, .hw_val = 11 },
{ .pdiv = 18, .hw_val = 12 },
{ .pdiv = 20, .hw_val = 13 },
{ .pdiv = 24, .hw_val = 14 },
{ .pdiv = 30, .hw_val = 15 },
{ .pdiv = 32, .hw_val = 16 },
};
static u32 pll_qlin_p_to_pdiv(u32 p, u32 *pdiv)
{
int i;
if (p) {
for (i = 0; i <= PLL_QLIN_PDIV_MAX; i++) {
if (p <= pll_qlin_pdiv_to_hw[i].pdiv) {
if (pdiv)
*pdiv = i;
return pll_qlin_pdiv_to_hw[i].pdiv;
}
}
}
return -EINVAL;
}
#define PLL_EXPO_PDIV_MAX 7
static const struct pdiv_map pll_expo_pdiv_to_hw[] = {
{ .pdiv = 1, .hw_val = 0 },
{ .pdiv = 2, .hw_val = 1 },
{ .pdiv = 4, .hw_val = 2 },
{ .pdiv = 8, .hw_val = 3 },
{ .pdiv = 16, .hw_val = 4 },
{ .pdiv = 32, .hw_val = 5 },
{ .pdiv = 64, .hw_val = 6 },
{ .pdiv = 128, .hw_val = 7 },
};
static u32 pll_expo_p_to_pdiv(u32 p, u32 *pdiv)
{
if (p) {
u32 i = fls(p);
if (i == ffs(p))
i--;
if (i <= PLL_EXPO_PDIV_MAX) {
if (pdiv)
*pdiv = i;
return 1 << i;
}
}
return -EINVAL;
}
static struct tegra_clk_pll_freq_table pll_x_freq_table[] = {
/* 1 GHz */
{ 12000000, 1000000000, 166, 1, 2, 0 }, /* actual: 996.0 MHz */
{ 13000000, 1000000000, 153, 1, 2, 0 }, /* actual: 994.0 MHz */
{ 38400000, 1000000000, 156, 3, 2, 0 }, /* actual: 998.4 MHz */
{ 0, 0, 0, 0, 0, 0 },
};
static struct tegra_clk_pll_params pll_x_params = {
.input_min = 12000000,
.input_max = 800000000,
.cf_min = 12000000,
.cf_max = 38400000,
.vco_min = 1350000000,
.vco_max = 3000000000UL,
.base_reg = PLLX_BASE,
.misc_reg = PLLX_MISC0,
.lock_mask = PLL_BASE_LOCK,
.lock_enable_bit_idx = PLL_MISC_LOCK_ENABLE,
.lock_delay = 300,
.ext_misc_reg[0] = PLLX_MISC0,
.ext_misc_reg[1] = PLLX_MISC1,
.ext_misc_reg[2] = PLLX_MISC2,
.ext_misc_reg[3] = PLLX_MISC3,
.ext_misc_reg[4] = PLLX_MISC4,
.ext_misc_reg[5] = PLLX_MISC5,
.iddq_reg = PLLX_MISC3,
.iddq_bit_idx = PLLXP_IDDQ_BIT,
.max_p = PLL_QLIN_PDIV_MAX,
.mdiv_default = 2,
.dyn_ramp_reg = PLLX_MISC2,
.stepa_shift = 16,
.stepb_shift = 24,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.div_nmp = &pllx_nmp,
.freq_table = pll_x_freq_table,
.flags = TEGRA_PLL_USE_LOCK | TEGRA_PLL_HAS_LOCK_ENABLE,
.dyn_ramp = tegra210_pllx_dyn_ramp,
.set_defaults = tegra210_pllx_set_defaults,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct div_nmp pllc_nmp = {
.divm_shift = 0,
.divm_width = 8,
.divn_shift = 10,
.divn_width = 8,
.divp_shift = 20,
.divp_width = 5,
};
static struct tegra_clk_pll_freq_table pll_cx_freq_table[] = {
{ 12000000, 510000000, 85, 1, 2, 0 },
{ 13000000, 510000000, 78, 1, 2, 0 }, /* actual: 507.0 MHz */
{ 38400000, 510000000, 79, 3, 2, 0 }, /* actual: 505.6 MHz */
{ 0, 0, 0, 0, 0, 0 },
};
static struct tegra_clk_pll_params pll_c_params = {
.input_min = 12000000,
.input_max = 700000000,
.cf_min = 12000000,
.cf_max = 50000000,
.vco_min = 600000000,
.vco_max = 1200000000,
.base_reg = PLLC_BASE,
.misc_reg = PLLC_MISC0,
.lock_mask = PLL_BASE_LOCK,
.lock_delay = 300,
.iddq_reg = PLLC_MISC1,
.iddq_bit_idx = PLLCX_IDDQ_BIT,
.reset_reg = PLLC_MISC0,
.reset_bit_idx = PLLCX_RESET_BIT,
.max_p = PLL_QLIN_PDIV_MAX,
.ext_misc_reg[0] = PLLC_MISC0,
.ext_misc_reg[1] = PLLC_MISC1,
.ext_misc_reg[2] = PLLC_MISC2,
.ext_misc_reg[3] = PLLC_MISC3,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.mdiv_default = 3,
.div_nmp = &pllc_nmp,
.freq_table = pll_cx_freq_table,
.flags = TEGRA_PLL_USE_LOCK,
.set_defaults = _pllc_set_defaults,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct div_nmp pllcx_nmp = {
.divm_shift = 0,
.divm_width = 8,
.divn_shift = 10,
.divn_width = 8,
.divp_shift = 20,
.divp_width = 5,
};
static struct tegra_clk_pll_params pll_c2_params = {
.input_min = 12000000,
.input_max = 700000000,
.cf_min = 12000000,
.cf_max = 50000000,
.vco_min = 600000000,
.vco_max = 1200000000,
.base_reg = PLLC2_BASE,
.misc_reg = PLLC2_MISC0,
.iddq_reg = PLLC2_MISC1,
.iddq_bit_idx = PLLCX_IDDQ_BIT,
.reset_reg = PLLC2_MISC0,
.reset_bit_idx = PLLCX_RESET_BIT,
.lock_mask = PLLCX_BASE_LOCK,
.lock_delay = 300,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.mdiv_default = 3,
.div_nmp = &pllcx_nmp,
.max_p = PLL_QLIN_PDIV_MAX,
.ext_misc_reg[0] = PLLC2_MISC0,
.ext_misc_reg[1] = PLLC2_MISC1,
.ext_misc_reg[2] = PLLC2_MISC2,
.ext_misc_reg[3] = PLLC2_MISC3,
.freq_table = pll_cx_freq_table,
.flags = TEGRA_PLL_USE_LOCK,
.set_defaults = _pllc2_set_defaults,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct tegra_clk_pll_params pll_c3_params = {
.input_min = 12000000,
.input_max = 700000000,
.cf_min = 12000000,
.cf_max = 50000000,
.vco_min = 600000000,
.vco_max = 1200000000,
.base_reg = PLLC3_BASE,
.misc_reg = PLLC3_MISC0,
.lock_mask = PLLCX_BASE_LOCK,
.lock_delay = 300,
.iddq_reg = PLLC3_MISC1,
.iddq_bit_idx = PLLCX_IDDQ_BIT,
.reset_reg = PLLC3_MISC0,
.reset_bit_idx = PLLCX_RESET_BIT,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.mdiv_default = 3,
.div_nmp = &pllcx_nmp,
.max_p = PLL_QLIN_PDIV_MAX,
.ext_misc_reg[0] = PLLC3_MISC0,
.ext_misc_reg[1] = PLLC3_MISC1,
.ext_misc_reg[2] = PLLC3_MISC2,
.ext_misc_reg[3] = PLLC3_MISC3,
.freq_table = pll_cx_freq_table,
.flags = TEGRA_PLL_USE_LOCK,
.set_defaults = _pllc3_set_defaults,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct div_nmp pllss_nmp = {
.divm_shift = 0,
.divm_width = 8,
.divn_shift = 8,
.divn_width = 8,
.divp_shift = 19,
.divp_width = 5,
};
static struct tegra_clk_pll_freq_table pll_c4_vco_freq_table[] = {
{ 12000000, 600000000, 50, 1, 1, 0 },
{ 13000000, 600000000, 46, 1, 1, 0 }, /* actual: 598.0 MHz */
{ 38400000, 600000000, 62, 4, 1, 0 }, /* actual: 595.2 MHz */
{ 0, 0, 0, 0, 0, 0 },
};
static const struct clk_div_table pll_vco_post_div_table[] = {
{ .val = 0, .div = 1 },
{ .val = 1, .div = 2 },
{ .val = 2, .div = 3 },
{ .val = 3, .div = 4 },
{ .val = 4, .div = 5 },
{ .val = 5, .div = 6 },
{ .val = 6, .div = 8 },
{ .val = 7, .div = 10 },
{ .val = 8, .div = 12 },
{ .val = 9, .div = 16 },
{ .val = 10, .div = 12 },
{ .val = 11, .div = 16 },
{ .val = 12, .div = 20 },
{ .val = 13, .div = 24 },
{ .val = 14, .div = 32 },
{ .val = 0, .div = 0 },
};
static struct tegra_clk_pll_params pll_c4_vco_params = {
.input_min = 9600000,
.input_max = 800000000,
.cf_min = 9600000,
.cf_max = 19200000,
.vco_min = 500000000,
.vco_max = 1080000000,
.base_reg = PLLC4_BASE,
.misc_reg = PLLC4_MISC0,
.lock_mask = PLL_BASE_LOCK,
.lock_delay = 300,
.max_p = PLL_QLIN_PDIV_MAX,
.ext_misc_reg[0] = PLLC4_MISC0,
.iddq_reg = PLLC4_BASE,
.iddq_bit_idx = PLLSS_IDDQ_BIT,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.mdiv_default = 3,
.div_nmp = &pllss_nmp,
.freq_table = pll_c4_vco_freq_table,
.set_defaults = tegra210_pllc4_set_defaults,
.flags = TEGRA_PLL_USE_LOCK | TEGRA_PLL_VCO_OUT,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct tegra_clk_pll_freq_table pll_m_freq_table[] = {
{ 12000000, 800000000, 66, 1, 1, 0 }, /* actual: 792.0 MHz */
{ 13000000, 800000000, 61, 1, 1, 0 }, /* actual: 793.0 MHz */
{ 38400000, 297600000, 93, 4, 3, 0 },
{ 38400000, 400000000, 125, 4, 3, 0 },
{ 38400000, 532800000, 111, 4, 2, 0 },
{ 38400000, 665600000, 104, 3, 2, 0 },
{ 38400000, 800000000, 125, 3, 2, 0 },
{ 38400000, 931200000, 97, 4, 1, 0 },
{ 38400000, 1065600000, 111, 4, 1, 0 },
{ 38400000, 1200000000, 125, 4, 1, 0 },
{ 38400000, 1331200000, 104, 3, 1, 0 },
{ 38400000, 1459200000, 76, 2, 1, 0 },
{ 38400000, 1600000000, 125, 3, 1, 0 },
{ 0, 0, 0, 0, 0, 0 },
};
static struct div_nmp pllm_nmp = {
.divm_shift = 0,
.divm_width = 8,
.override_divm_shift = 0,
.divn_shift = 8,
.divn_width = 8,
.override_divn_shift = 8,
.divp_shift = 20,
.divp_width = 5,
.override_divp_shift = 27,
};
static struct tegra_clk_pll_params pll_m_params = {
.input_min = 9600000,
.input_max = 500000000,
.cf_min = 9600000,
.cf_max = 19200000,
.vco_min = 800000000,
.vco_max = 1866000000,
.base_reg = PLLM_BASE,
.misc_reg = PLLM_MISC2,
.lock_mask = PLL_BASE_LOCK,
.lock_enable_bit_idx = PLLM_MISC_LOCK_ENABLE,
.lock_delay = 300,
.iddq_reg = PLLM_MISC2,
.iddq_bit_idx = PLLM_IDDQ_BIT,
.max_p = PLL_QLIN_PDIV_MAX,
.ext_misc_reg[0] = PLLM_MISC2,
.ext_misc_reg[1] = PLLM_MISC1,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.div_nmp = &pllm_nmp,
.pmc_divnm_reg = PMC_PLLM_WB0_OVERRIDE,
.pmc_divp_reg = PMC_PLLM_WB0_OVERRIDE_2,
.freq_table = pll_m_freq_table,
.flags = TEGRA_PLL_USE_LOCK | TEGRA_PLL_HAS_LOCK_ENABLE,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct tegra_clk_pll_params pll_mb_params = {
.input_min = 9600000,
.input_max = 500000000,
.cf_min = 9600000,
.cf_max = 19200000,
.vco_min = 800000000,
.vco_max = 1866000000,
.base_reg = PLLMB_BASE,
.misc_reg = PLLMB_MISC1,
.lock_mask = PLL_BASE_LOCK,
.lock_delay = 300,
.iddq_reg = PLLMB_MISC1,
.iddq_bit_idx = PLLMB_IDDQ_BIT,
.max_p = PLL_QLIN_PDIV_MAX,
.ext_misc_reg[0] = PLLMB_MISC1,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.div_nmp = &pllm_nmp,
.freq_table = pll_m_freq_table,
.flags = TEGRA_PLL_USE_LOCK,
.set_defaults = tegra210_pllmb_set_defaults,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct tegra_clk_pll_freq_table pll_e_freq_table[] = {
/* PLLE special case: use cpcon field to store cml divider value */
{ 672000000, 100000000, 125, 42, 0, 13 },
{ 624000000, 100000000, 125, 39, 0, 13 },
{ 336000000, 100000000, 125, 21, 0, 13 },
{ 312000000, 100000000, 200, 26, 0, 14 },
{ 38400000, 100000000, 125, 2, 0, 14 },
{ 12000000, 100000000, 200, 1, 0, 14 },
{ 0, 0, 0, 0, 0, 0 },
};
static struct div_nmp plle_nmp = {
.divm_shift = 0,
.divm_width = 8,
.divn_shift = 8,
.divn_width = 8,
.divp_shift = 24,
.divp_width = 5,
};
static struct tegra_clk_pll_params pll_e_params = {
.input_min = 12000000,
.input_max = 800000000,
.cf_min = 12000000,
.cf_max = 38400000,
.vco_min = 1600000000,
.vco_max = 2500000000U,
.base_reg = PLLE_BASE,
.misc_reg = PLLE_MISC0,
.aux_reg = PLLE_AUX,
.lock_mask = PLLE_MISC_LOCK,
.lock_enable_bit_idx = PLLE_MISC_LOCK_ENABLE,
.lock_delay = 300,
.div_nmp = &plle_nmp,
.freq_table = pll_e_freq_table,
.flags = TEGRA_PLL_FIXED | TEGRA_PLL_LOCK_MISC | TEGRA_PLL_USE_LOCK |
TEGRA_PLL_HAS_LOCK_ENABLE,
.fixed_rate = 100000000,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct tegra_clk_pll_freq_table pll_re_vco_freq_table[] = {
{ 12000000, 672000000, 56, 1, 1, 0 },
{ 13000000, 672000000, 51, 1, 1, 0 }, /* actual: 663.0 MHz */
{ 38400000, 672000000, 70, 4, 1, 0 },
{ 0, 0, 0, 0, 0, 0 },
};
static struct div_nmp pllre_nmp = {
.divm_shift = 0,
.divm_width = 8,
.divn_shift = 8,
.divn_width = 8,
.divp_shift = 16,
.divp_width = 5,
};
static struct tegra_clk_pll_params pll_re_vco_params = {
.input_min = 9600000,
.input_max = 800000000,
.cf_min = 9600000,
.cf_max = 19200000,
.vco_min = 350000000,
.vco_max = 700000000,
.base_reg = PLLRE_BASE,
.misc_reg = PLLRE_MISC0,
.lock_mask = PLLRE_MISC_LOCK,
.lock_delay = 300,
.max_p = PLL_QLIN_PDIV_MAX,
.ext_misc_reg[0] = PLLRE_MISC0,
.iddq_reg = PLLRE_MISC0,
.iddq_bit_idx = PLLRE_IDDQ_BIT,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.div_nmp = &pllre_nmp,
.freq_table = pll_re_vco_freq_table,
.flags = TEGRA_PLL_USE_LOCK | TEGRA_PLL_LOCK_MISC | TEGRA_PLL_VCO_OUT,
.set_defaults = tegra210_pllre_set_defaults,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct div_nmp pllp_nmp = {
.divm_shift = 0,
.divm_width = 8,
.divn_shift = 10,
.divn_width = 8,
.divp_shift = 20,
.divp_width = 5,
};
static struct tegra_clk_pll_freq_table pll_p_freq_table[] = {
{ 12000000, 408000000, 34, 1, 1, 0 },
{ 38400000, 408000000, 85, 8, 1, 0 }, /* cf = 4.8MHz, allowed exception */
{ 0, 0, 0, 0, 0, 0 },
};
static struct tegra_clk_pll_params pll_p_params = {
.input_min = 9600000,
.input_max = 800000000,
.cf_min = 9600000,
.cf_max = 19200000,
.vco_min = 350000000,
.vco_max = 700000000,
.base_reg = PLLP_BASE,
.misc_reg = PLLP_MISC0,
.lock_mask = PLL_BASE_LOCK,
.lock_delay = 300,
.iddq_reg = PLLP_MISC0,
.iddq_bit_idx = PLLXP_IDDQ_BIT,
.ext_misc_reg[0] = PLLP_MISC0,
.ext_misc_reg[1] = PLLP_MISC1,
.div_nmp = &pllp_nmp,
.freq_table = pll_p_freq_table,
.fixed_rate = 408000000,
.flags = TEGRA_PLL_FIXED | TEGRA_PLL_USE_LOCK | TEGRA_PLL_VCO_OUT,
.set_defaults = tegra210_pllp_set_defaults,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct tegra_clk_pll_params pll_a1_params = {
.input_min = 12000000,
.input_max = 700000000,
.cf_min = 12000000,
.cf_max = 50000000,
.vco_min = 600000000,
.vco_max = 1200000000,
.base_reg = PLLA1_BASE,
.misc_reg = PLLA1_MISC0,
.lock_mask = PLLCX_BASE_LOCK,
.lock_delay = 300,
.iddq_reg = PLLA1_MISC1,
.iddq_bit_idx = PLLCX_IDDQ_BIT,
.reset_reg = PLLA1_MISC0,
.reset_bit_idx = PLLCX_RESET_BIT,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.div_nmp = &pllc_nmp,
.ext_misc_reg[0] = PLLA1_MISC0,
.ext_misc_reg[1] = PLLA1_MISC1,
.ext_misc_reg[2] = PLLA1_MISC2,
.ext_misc_reg[3] = PLLA1_MISC3,
.freq_table = pll_cx_freq_table,
.flags = TEGRA_PLL_USE_LOCK,
.set_defaults = _plla1_set_defaults,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
};
static struct div_nmp plla_nmp = {
.divm_shift = 0,
.divm_width = 8,
.divn_shift = 8,
.divn_width = 8,
.divp_shift = 20,
.divp_width = 5,
};
static struct tegra_clk_pll_freq_table pll_a_freq_table[] = {
{ 12000000, 282240000, 47, 1, 2, 1, 0xf148 }, /* actual: 282240234 */
{ 12000000, 368640000, 61, 1, 2, 1, 0xfe15 }, /* actual: 368640381 */
{ 12000000, 240000000, 60, 1, 3, 1, 0 },
{ 13000000, 282240000, 43, 1, 2, 1, 0xfd7d }, /* actual: 282239807 */
{ 13000000, 368640000, 56, 1, 2, 1, 0x06d8 }, /* actual: 368640137 */
{ 13000000, 240000000, 55, 1, 3, 1, 0 }, /* actual: 238.3 MHz */
{ 38400000, 282240000, 44, 3, 2, 1, 0xf333 }, /* actual: 282239844 */
{ 38400000, 368640000, 57, 3, 2, 1, 0x0333 }, /* actual: 368639844 */
{ 38400000, 240000000, 75, 3, 3, 1, 0 },
{ 0, 0, 0, 0, 0, 0, 0 },
};
static struct tegra_clk_pll_params pll_a_params = {
.input_min = 12000000,
.input_max = 800000000,
.cf_min = 12000000,
.cf_max = 19200000,
.vco_min = 500000000,
.vco_max = 1000000000,
.base_reg = PLLA_BASE,
.misc_reg = PLLA_MISC0,
.lock_mask = PLL_BASE_LOCK,
.lock_delay = 300,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.iddq_reg = PLLA_BASE,
.iddq_bit_idx = PLLA_IDDQ_BIT,
.div_nmp = &plla_nmp,
.sdm_din_reg = PLLA_MISC1,
.sdm_din_mask = PLLA_SDM_DIN_MASK,
.sdm_ctrl_reg = PLLA_MISC2,
.sdm_ctrl_en_mask = PLLA_SDM_EN_MASK,
.ext_misc_reg[0] = PLLA_MISC0,
.ext_misc_reg[1] = PLLA_MISC1,
.ext_misc_reg[2] = PLLA_MISC2,
.freq_table = pll_a_freq_table,
.flags = TEGRA_PLL_USE_LOCK | TEGRA_MDIV_NEW,
.set_defaults = tegra210_plla_set_defaults,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
.set_gain = tegra210_clk_pll_set_gain,
.adjust_vco = tegra210_clk_adjust_vco_min,
};
static struct div_nmp plld_nmp = {
.divm_shift = 0,
.divm_width = 8,
.divn_shift = 11,
.divn_width = 8,
.divp_shift = 20,
.divp_width = 3,
};
static struct tegra_clk_pll_freq_table pll_d_freq_table[] = {
{ 12000000, 594000000, 99, 1, 2, 0, 0 },
{ 13000000, 594000000, 91, 1, 2, 0, 0xfc4f }, /* actual: 594000183 */
{ 38400000, 594000000, 30, 1, 2, 0, 0x0e00 },
{ 0, 0, 0, 0, 0, 0, 0 },
};
static struct tegra_clk_pll_params pll_d_params = {
.input_min = 12000000,
.input_max = 800000000,
.cf_min = 12000000,
.cf_max = 38400000,
.vco_min = 750000000,
.vco_max = 1500000000,
.base_reg = PLLD_BASE,
.misc_reg = PLLD_MISC0,
.lock_mask = PLL_BASE_LOCK,
.lock_delay = 1000,
.iddq_reg = PLLD_MISC0,
.iddq_bit_idx = PLLD_IDDQ_BIT,
.round_p_to_pdiv = pll_expo_p_to_pdiv,
.pdiv_tohw = pll_expo_pdiv_to_hw,
.div_nmp = &plld_nmp,
.sdm_din_reg = PLLD_MISC0,
.sdm_din_mask = PLLA_SDM_DIN_MASK,
.sdm_ctrl_reg = PLLD_MISC0,
.sdm_ctrl_en_mask = PLLD_SDM_EN_MASK,
.ext_misc_reg[0] = PLLD_MISC0,
.ext_misc_reg[1] = PLLD_MISC1,
.freq_table = pll_d_freq_table,
.flags = TEGRA_PLL_USE_LOCK,
.mdiv_default = 1,
.set_defaults = tegra210_plld_set_defaults,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
.set_gain = tegra210_clk_pll_set_gain,
.adjust_vco = tegra210_clk_adjust_vco_min,
};
static struct tegra_clk_pll_freq_table tegra210_pll_d2_freq_table[] = {
{ 12000000, 594000000, 99, 1, 2, 0, 0xf000 },
{ 13000000, 594000000, 91, 1, 2, 0, 0xfc4f }, /* actual: 594000183 */
{ 38400000, 594000000, 30, 1, 2, 0, 0x0e00 },
{ 0, 0, 0, 0, 0, 0, 0 },
};
/* s/w policy, always tegra_pll_ref */
static struct tegra_clk_pll_params pll_d2_params = {
.input_min = 12000000,
.input_max = 800000000,
.cf_min = 12000000,
.cf_max = 38400000,
.vco_min = 750000000,
.vco_max = 1500000000,
.base_reg = PLLD2_BASE,
.misc_reg = PLLD2_MISC0,
.lock_mask = PLL_BASE_LOCK,
.lock_delay = 300,
.iddq_reg = PLLD2_BASE,
.iddq_bit_idx = PLLSS_IDDQ_BIT,
.sdm_din_reg = PLLD2_MISC3,
.sdm_din_mask = PLLA_SDM_DIN_MASK,
.sdm_ctrl_reg = PLLD2_MISC1,
.sdm_ctrl_en_mask = PLLD2_SDM_EN_MASK,
/* disable spread-spectrum for pll_d2 */
.ssc_ctrl_reg = 0,
.ssc_ctrl_en_mask = 0,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.div_nmp = &pllss_nmp,
.ext_misc_reg[0] = PLLD2_MISC0,
.ext_misc_reg[1] = PLLD2_MISC1,
.ext_misc_reg[2] = PLLD2_MISC2,
.ext_misc_reg[3] = PLLD2_MISC3,
.max_p = PLL_QLIN_PDIV_MAX,
.mdiv_default = 1,
.freq_table = tegra210_pll_d2_freq_table,
.set_defaults = tegra210_plld2_set_defaults,
.flags = TEGRA_PLL_USE_LOCK,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
.set_gain = tegra210_clk_pll_set_gain,
.adjust_vco = tegra210_clk_adjust_vco_min,
};
static struct tegra_clk_pll_freq_table pll_dp_freq_table[] = {
{ 12000000, 270000000, 90, 1, 4, 0, 0xf000 },
{ 13000000, 270000000, 83, 1, 4, 0, 0xf000 }, /* actual: 269.8 MHz */
{ 38400000, 270000000, 28, 1, 4, 0, 0xf400 },
{ 0, 0, 0, 0, 0, 0, 0 },
};
static struct tegra_clk_pll_params pll_dp_params = {
.input_min = 12000000,
.input_max = 800000000,
.cf_min = 12000000,
.cf_max = 38400000,
.vco_min = 750000000,
.vco_max = 1500000000,
.base_reg = PLLDP_BASE,
.misc_reg = PLLDP_MISC,
.lock_mask = PLL_BASE_LOCK,
.lock_delay = 300,
.iddq_reg = PLLDP_BASE,
.iddq_bit_idx = PLLSS_IDDQ_BIT,
.sdm_din_reg = PLLDP_SS_CTRL2,
.sdm_din_mask = PLLA_SDM_DIN_MASK,
.sdm_ctrl_reg = PLLDP_SS_CFG,
.sdm_ctrl_en_mask = PLLDP_SDM_EN_MASK,
.ssc_ctrl_reg = PLLDP_SS_CFG,
.ssc_ctrl_en_mask = PLLDP_SSC_EN_MASK,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.div_nmp = &pllss_nmp,
.ext_misc_reg[0] = PLLDP_MISC,
.ext_misc_reg[1] = PLLDP_SS_CFG,
.ext_misc_reg[2] = PLLDP_SS_CTRL1,
.ext_misc_reg[3] = PLLDP_SS_CTRL2,
.max_p = PLL_QLIN_PDIV_MAX,
.mdiv_default = 1,
.freq_table = pll_dp_freq_table,
.set_defaults = tegra210_plldp_set_defaults,
.flags = TEGRA_PLL_USE_LOCK,
.calc_rate = tegra210_pll_fixed_mdiv_cfg,
.set_gain = tegra210_clk_pll_set_gain,
.adjust_vco = tegra210_clk_adjust_vco_min,
};
static struct div_nmp pllu_nmp = {
.divm_shift = 0,
.divm_width = 8,
.divn_shift = 8,
.divn_width = 8,
.divp_shift = 16,
.divp_width = 5,
};
static struct tegra_clk_pll_freq_table pll_u_freq_table[] = {
{ 12000000, 480000000, 40, 1, 1, 0 },
{ 13000000, 480000000, 36, 1, 1, 0 }, /* actual: 468.0 MHz */
{ 38400000, 480000000, 25, 2, 1, 0 },
{ 0, 0, 0, 0, 0, 0 },
};
static struct tegra_clk_pll_params pll_u_vco_params = {
.input_min = 9600000,
.input_max = 800000000,
.cf_min = 9600000,
.cf_max = 19200000,
.vco_min = 350000000,
.vco_max = 700000000,
.base_reg = PLLU_BASE,
.misc_reg = PLLU_MISC0,
.lock_mask = PLL_BASE_LOCK,
.lock_delay = 1000,
.iddq_reg = PLLU_MISC0,
.iddq_bit_idx = PLLU_IDDQ_BIT,
.ext_misc_reg[0] = PLLU_MISC0,
.ext_misc_reg[1] = PLLU_MISC1,
.round_p_to_pdiv = pll_qlin_p_to_pdiv,
.pdiv_tohw = pll_qlin_pdiv_to_hw,
.div_nmp = &pllu_nmp,
.freq_table = pll_u_freq_table,
.flags = TEGRA_PLLU | TEGRA_PLL_USE_LOCK | TEGRA_PLL_VCO_OUT,
};
struct utmi_clk_param {
/* Oscillator Frequency in KHz */
u32 osc_frequency;
/* UTMIP PLL Enable Delay Count */
u8 enable_delay_count;
/* UTMIP PLL Stable count */
u16 stable_count;
/* UTMIP PLL Active delay count */
u8 active_delay_count;
/* UTMIP PLL Xtal frequency count */
u16 xtal_freq_count;
};
static const struct utmi_clk_param utmi_parameters[] = {
{
.osc_frequency = 38400000, .enable_delay_count = 0x0,
.stable_count = 0x0, .active_delay_count = 0x6,
.xtal_freq_count = 0x80
}, {
.osc_frequency = 13000000, .enable_delay_count = 0x02,
.stable_count = 0x33, .active_delay_count = 0x05,
.xtal_freq_count = 0x7f
}, {
.osc_frequency = 19200000, .enable_delay_count = 0x03,
.stable_count = 0x4b, .active_delay_count = 0x06,
.xtal_freq_count = 0xbb
}, {
.osc_frequency = 12000000, .enable_delay_count = 0x02,
.stable_count = 0x2f, .active_delay_count = 0x08,
.xtal_freq_count = 0x76
}, {
.osc_frequency = 26000000, .enable_delay_count = 0x04,
.stable_count = 0x66, .active_delay_count = 0x09,
.xtal_freq_count = 0xfe
}, {
.osc_frequency = 16800000, .enable_delay_count = 0x03,
.stable_count = 0x41, .active_delay_count = 0x0a,
.xtal_freq_count = 0xa4
},
};
static struct tegra_clk tegra210_clks[tegra_clk_max] __initdata = {
[tegra_clk_ispb] = { .dt_id = TEGRA210_CLK_ISPB, .present = true },
[tegra_clk_rtc] = { .dt_id = TEGRA210_CLK_RTC, .present = true },
[tegra_clk_timer] = { .dt_id = TEGRA210_CLK_TIMER, .present = true },
[tegra_clk_uarta_8] = { .dt_id = TEGRA210_CLK_UARTA, .present = true },
[tegra_clk_i2s1] = { .dt_id = TEGRA210_CLK_I2S1, .present = true },
[tegra_clk_i2c1] = { .dt_id = TEGRA210_CLK_I2C1, .present = true },
[tegra_clk_sdmmc1_9] = { .dt_id = TEGRA210_CLK_SDMMC1, .present = true },
[tegra_clk_pwm] = { .dt_id = TEGRA210_CLK_PWM, .present = true },
[tegra_clk_i2s2] = { .dt_id = TEGRA210_CLK_I2S2, .present = true },
[tegra_clk_usbd] = { .dt_id = TEGRA210_CLK_USBD, .present = true },
[tegra_clk_isp_9] = { .dt_id = TEGRA210_CLK_ISP, .present = true },
[tegra_clk_disp2_8] = { .dt_id = TEGRA210_CLK_DISP2, .present = true },
[tegra_clk_disp1_8] = { .dt_id = TEGRA210_CLK_DISP1, .present = true },
[tegra_clk_host1x_9] = { .dt_id = TEGRA210_CLK_HOST1X, .present = true },
[tegra_clk_i2s0] = { .dt_id = TEGRA210_CLK_I2S0, .present = true },
[tegra_clk_apbdma] = { .dt_id = TEGRA210_CLK_APBDMA, .present = true },
[tegra_clk_kfuse] = { .dt_id = TEGRA210_CLK_KFUSE, .present = true },
[tegra_clk_sbc1_9] = { .dt_id = TEGRA210_CLK_SBC1, .present = true },
[tegra_clk_sbc2_9] = { .dt_id = TEGRA210_CLK_SBC2, .present = true },
[tegra_clk_sbc3_9] = { .dt_id = TEGRA210_CLK_SBC3, .present = true },
[tegra_clk_i2c5] = { .dt_id = TEGRA210_CLK_I2C5, .present = true },
[tegra_clk_csi] = { .dt_id = TEGRA210_CLK_CSI, .present = true },
[tegra_clk_i2c2] = { .dt_id = TEGRA210_CLK_I2C2, .present = true },
[tegra_clk_uartc_8] = { .dt_id = TEGRA210_CLK_UARTC, .present = true },
[tegra_clk_mipi_cal] = { .dt_id = TEGRA210_CLK_MIPI_CAL, .present = true },
[tegra_clk_usb2] = { .dt_id = TEGRA210_CLK_USB2, .present = true },
[tegra_clk_bsev] = { .dt_id = TEGRA210_CLK_BSEV, .present = true },
[tegra_clk_uartd_8] = { .dt_id = TEGRA210_CLK_UARTD, .present = true },
[tegra_clk_i2c3] = { .dt_id = TEGRA210_CLK_I2C3, .present = true },
[tegra_clk_sbc4_9] = { .dt_id = TEGRA210_CLK_SBC4, .present = true },
[tegra_clk_sdmmc3_9] = { .dt_id = TEGRA210_CLK_SDMMC3, .present = true },
[tegra_clk_pcie] = { .dt_id = TEGRA210_CLK_PCIE, .present = true },
[tegra_clk_owr_8] = { .dt_id = TEGRA210_CLK_OWR, .present = true },
[tegra_clk_afi] = { .dt_id = TEGRA210_CLK_AFI, .present = true },
[tegra_clk_csite_8] = { .dt_id = TEGRA210_CLK_CSITE, .present = true },
[tegra_clk_soc_therm_8] = { .dt_id = TEGRA210_CLK_SOC_THERM, .present = true },
[tegra_clk_dtv] = { .dt_id = TEGRA210_CLK_DTV, .present = true },
[tegra_clk_i2cslow] = { .dt_id = TEGRA210_CLK_I2CSLOW, .present = true },
[tegra_clk_tsec_8] = { .dt_id = TEGRA210_CLK_TSEC, .present = true },
[tegra_clk_xusb_host] = { .dt_id = TEGRA210_CLK_XUSB_HOST, .present = true },
[tegra_clk_csus] = { .dt_id = TEGRA210_CLK_CSUS, .present = true },
[tegra_clk_mselect] = { .dt_id = TEGRA210_CLK_MSELECT, .present = true },
[tegra_clk_tsensor] = { .dt_id = TEGRA210_CLK_TSENSOR, .present = true },
[tegra_clk_i2s3] = { .dt_id = TEGRA210_CLK_I2S3, .present = true },
[tegra_clk_i2s4] = { .dt_id = TEGRA210_CLK_I2S4, .present = true },
[tegra_clk_i2c4] = { .dt_id = TEGRA210_CLK_I2C4, .present = true },
[tegra_clk_d_audio] = { .dt_id = TEGRA210_CLK_D_AUDIO, .present = true },
[tegra_clk_hda2codec_2x_8] = { .dt_id = TEGRA210_CLK_HDA2CODEC_2X, .present = true },
[tegra_clk_spdif_2x] = { .dt_id = TEGRA210_CLK_SPDIF_2X, .present = true },
[tegra_clk_actmon] = { .dt_id = TEGRA210_CLK_ACTMON, .present = true },
[tegra_clk_extern1] = { .dt_id = TEGRA210_CLK_EXTERN1, .present = true },
[tegra_clk_extern2] = { .dt_id = TEGRA210_CLK_EXTERN2, .present = true },
[tegra_clk_extern3] = { .dt_id = TEGRA210_CLK_EXTERN3, .present = true },
[tegra_clk_sata_oob_8] = { .dt_id = TEGRA210_CLK_SATA_OOB, .present = true },
[tegra_clk_sata_8] = { .dt_id = TEGRA210_CLK_SATA, .present = true },
[tegra_clk_hda_8] = { .dt_id = TEGRA210_CLK_HDA, .present = true },
[tegra_clk_hda2hdmi] = { .dt_id = TEGRA210_CLK_HDA2HDMI, .present = true },
[tegra_clk_cilab] = { .dt_id = TEGRA210_CLK_CILAB, .present = true },
[tegra_clk_cilcd] = { .dt_id = TEGRA210_CLK_CILCD, .present = true },
[tegra_clk_cile] = { .dt_id = TEGRA210_CLK_CILE, .present = true },
[tegra_clk_dsialp] = { .dt_id = TEGRA210_CLK_DSIALP, .present = true },
[tegra_clk_dsiblp] = { .dt_id = TEGRA210_CLK_DSIBLP, .present = true },
[tegra_clk_entropy_8] = { .dt_id = TEGRA210_CLK_ENTROPY, .present = true },
[tegra_clk_xusb_ss] = { .dt_id = TEGRA210_CLK_XUSB_SS, .present = true },
[tegra_clk_i2c6] = { .dt_id = TEGRA210_CLK_I2C6, .present = true },
[tegra_clk_vim2_clk] = { .dt_id = TEGRA210_CLK_VIM2_CLK, .present = true },
[tegra_clk_clk72Mhz_8] = { .dt_id = TEGRA210_CLK_CLK72MHZ, .present = true },
[tegra_clk_vic03_8] = { .dt_id = TEGRA210_CLK_VIC03, .present = true },
[tegra_clk_dpaux] = { .dt_id = TEGRA210_CLK_DPAUX, .present = true },
[tegra_clk_dpaux1] = { .dt_id = TEGRA210_CLK_DPAUX1, .present = true },
[tegra_clk_sor0] = { .dt_id = TEGRA210_CLK_SOR0, .present = true },
[tegra_clk_sor0_out] = { .dt_id = TEGRA210_CLK_SOR0_OUT, .present = true },
[tegra_clk_sor1] = { .dt_id = TEGRA210_CLK_SOR1, .present = true },
[tegra_clk_sor1_out] = { .dt_id = TEGRA210_CLK_SOR1_OUT, .present = true },
[tegra_clk_gpu] = { .dt_id = TEGRA210_CLK_GPU, .present = true },
[tegra_clk_pll_g_ref] = { .dt_id = TEGRA210_CLK_PLL_G_REF, .present = true, },
[tegra_clk_uartb_8] = { .dt_id = TEGRA210_CLK_UARTB, .present = true },
[tegra_clk_spdif_in_8] = { .dt_id = TEGRA210_CLK_SPDIF_IN, .present = true },
[tegra_clk_spdif_out] = { .dt_id = TEGRA210_CLK_SPDIF_OUT, .present = true },
[tegra_clk_vi_10] = { .dt_id = TEGRA210_CLK_VI, .present = true },
[tegra_clk_vi_sensor_8] = { .dt_id = TEGRA210_CLK_VI_SENSOR, .present = true },
[tegra_clk_fuse] = { .dt_id = TEGRA210_CLK_FUSE, .present = true },
[tegra_clk_fuse_burn] = { .dt_id = TEGRA210_CLK_FUSE_BURN, .present = true },
[tegra_clk_clk_32k] = { .dt_id = TEGRA210_CLK_CLK_32K, .present = true },
[tegra_clk_clk_m] = { .dt_id = TEGRA210_CLK_CLK_M, .present = true },
[tegra_clk_osc] = { .dt_id = TEGRA210_CLK_OSC, .present = true },
[tegra_clk_osc_div2] = { .dt_id = TEGRA210_CLK_OSC_DIV2, .present = true },
[tegra_clk_osc_div4] = { .dt_id = TEGRA210_CLK_OSC_DIV4, .present = true },
[tegra_clk_pll_ref] = { .dt_id = TEGRA210_CLK_PLL_REF, .present = true },
[tegra_clk_pll_c] = { .dt_id = TEGRA210_CLK_PLL_C, .present = true },
[tegra_clk_pll_c_out1] = { .dt_id = TEGRA210_CLK_PLL_C_OUT1, .present = true },
[tegra_clk_pll_c2] = { .dt_id = TEGRA210_CLK_PLL_C2, .present = true },
[tegra_clk_pll_c3] = { .dt_id = TEGRA210_CLK_PLL_C3, .present = true },
[tegra_clk_pll_m] = { .dt_id = TEGRA210_CLK_PLL_M, .present = true },
[tegra_clk_pll_p] = { .dt_id = TEGRA210_CLK_PLL_P, .present = true },
[tegra_clk_pll_p_out1] = { .dt_id = TEGRA210_CLK_PLL_P_OUT1, .present = true },
[tegra_clk_pll_p_out3] = { .dt_id = TEGRA210_CLK_PLL_P_OUT3, .present = true },
[tegra_clk_pll_p_out4_cpu] = { .dt_id = TEGRA210_CLK_PLL_P_OUT4, .present = true },
[tegra_clk_pll_p_out_hsio] = { .dt_id = TEGRA210_CLK_PLL_P_OUT_HSIO, .present = true },
[tegra_clk_pll_p_out_xusb] = { .dt_id = TEGRA210_CLK_PLL_P_OUT_XUSB, .present = true },
[tegra_clk_pll_p_out_cpu] = { .dt_id = TEGRA210_CLK_PLL_P_OUT_CPU, .present = true },
[tegra_clk_pll_p_out_adsp] = { .dt_id = TEGRA210_CLK_PLL_P_OUT_ADSP, .present = true },
[tegra_clk_pll_a] = { .dt_id = TEGRA210_CLK_PLL_A, .present = true },
[tegra_clk_pll_a_out0] = { .dt_id = TEGRA210_CLK_PLL_A_OUT0, .present = true },
[tegra_clk_pll_d] = { .dt_id = TEGRA210_CLK_PLL_D, .present = true },
[tegra_clk_pll_d_out0] = { .dt_id = TEGRA210_CLK_PLL_D_OUT0, .present = true },
[tegra_clk_pll_d2] = { .dt_id = TEGRA210_CLK_PLL_D2, .present = true },
[tegra_clk_pll_d2_out0] = { .dt_id = TEGRA210_CLK_PLL_D2_OUT0, .present = true },
[tegra_clk_pll_u] = { .dt_id = TEGRA210_CLK_PLL_U, .present = true },
[tegra_clk_pll_u_out] = { .dt_id = TEGRA210_CLK_PLL_U_OUT, .present = true },
[tegra_clk_pll_u_out1] = { .dt_id = TEGRA210_CLK_PLL_U_OUT1, .present = true },
[tegra_clk_pll_u_out2] = { .dt_id = TEGRA210_CLK_PLL_U_OUT2, .present = true },
[tegra_clk_pll_u_480m] = { .dt_id = TEGRA210_CLK_PLL_U_480M, .present = true },
[tegra_clk_pll_u_60m] = { .dt_id = TEGRA210_CLK_PLL_U_60M, .present = true },
[tegra_clk_pll_u_48m] = { .dt_id = TEGRA210_CLK_PLL_U_48M, .present = true },
[tegra_clk_pll_x] = { .dt_id = TEGRA210_CLK_PLL_X, .present = true },
[tegra_clk_pll_x_out0] = { .dt_id = TEGRA210_CLK_PLL_X_OUT0, .present = true },
[tegra_clk_pll_re_vco] = { .dt_id = TEGRA210_CLK_PLL_RE_VCO, .present = true },
[tegra_clk_pll_re_out] = { .dt_id = TEGRA210_CLK_PLL_RE_OUT, .present = true },
[tegra_clk_spdif_in_sync] = { .dt_id = TEGRA210_CLK_SPDIF_IN_SYNC, .present = true },
[tegra_clk_i2s0_sync] = { .dt_id = TEGRA210_CLK_I2S0_SYNC, .present = true },
[tegra_clk_i2s1_sync] = { .dt_id = TEGRA210_CLK_I2S1_SYNC, .present = true },
[tegra_clk_i2s2_sync] = { .dt_id = TEGRA210_CLK_I2S2_SYNC, .present = true },
[tegra_clk_i2s3_sync] = { .dt_id = TEGRA210_CLK_I2S3_SYNC, .present = true },
[tegra_clk_i2s4_sync] = { .dt_id = TEGRA210_CLK_I2S4_SYNC, .present = true },
[tegra_clk_vimclk_sync] = { .dt_id = TEGRA210_CLK_VIMCLK_SYNC, .present = true },
[tegra_clk_audio0] = { .dt_id = TEGRA210_CLK_AUDIO0, .present = true },
[tegra_clk_audio1] = { .dt_id = TEGRA210_CLK_AUDIO1, .present = true },
[tegra_clk_audio2] = { .dt_id = TEGRA210_CLK_AUDIO2, .present = true },
[tegra_clk_audio3] = { .dt_id = TEGRA210_CLK_AUDIO3, .present = true },
[tegra_clk_audio4] = { .dt_id = TEGRA210_CLK_AUDIO4, .present = true },
[tegra_clk_spdif] = { .dt_id = TEGRA210_CLK_SPDIF, .present = true },
[tegra_clk_xusb_gate] = { .dt_id = TEGRA210_CLK_XUSB_GATE, .present = true },
[tegra_clk_xusb_host_src_8] = { .dt_id = TEGRA210_CLK_XUSB_HOST_SRC, .present = true },
[tegra_clk_xusb_falcon_src_8] = { .dt_id = TEGRA210_CLK_XUSB_FALCON_SRC, .present = true },
[tegra_clk_xusb_fs_src] = { .dt_id = TEGRA210_CLK_XUSB_FS_SRC, .present = true },
[tegra_clk_xusb_ss_src_8] = { .dt_id = TEGRA210_CLK_XUSB_SS_SRC, .present = true },
[tegra_clk_xusb_ss_div2] = { .dt_id = TEGRA210_CLK_XUSB_SS_DIV2, .present = true },
[tegra_clk_xusb_dev_src_8] = { .dt_id = TEGRA210_CLK_XUSB_DEV_SRC, .present = true },
[tegra_clk_xusb_dev] = { .dt_id = TEGRA210_CLK_XUSB_DEV, .present = true },
[tegra_clk_xusb_hs_src_4] = { .dt_id = TEGRA210_CLK_XUSB_HS_SRC, .present = true },
[tegra_clk_xusb_ssp_src] = { .dt_id = TEGRA210_CLK_XUSB_SSP_SRC, .present = true },
[tegra_clk_usb2_hsic_trk] = { .dt_id = TEGRA210_CLK_USB2_HSIC_TRK, .present = true },
[tegra_clk_hsic_trk] = { .dt_id = TEGRA210_CLK_HSIC_TRK, .present = true },
[tegra_clk_usb2_trk] = { .dt_id = TEGRA210_CLK_USB2_TRK, .present = true },
[tegra_clk_sclk] = { .dt_id = TEGRA210_CLK_SCLK, .present = true },
[tegra_clk_sclk_mux] = { .dt_id = TEGRA210_CLK_SCLK_MUX, .present = true },
[tegra_clk_hclk] = { .dt_id = TEGRA210_CLK_HCLK, .present = true },
[tegra_clk_pclk] = { .dt_id = TEGRA210_CLK_PCLK, .present = true },
[tegra_clk_cclk_g] = { .dt_id = TEGRA210_CLK_CCLK_G, .present = true },
[tegra_clk_cclk_lp] = { .dt_id = TEGRA210_CLK_CCLK_LP, .present = true },
[tegra_clk_dfll_ref] = { .dt_id = TEGRA210_CLK_DFLL_REF, .present = true },
[tegra_clk_dfll_soc] = { .dt_id = TEGRA210_CLK_DFLL_SOC, .present = true },
[tegra_clk_vi_sensor2_8] = { .dt_id = TEGRA210_CLK_VI_SENSOR2, .present = true },
[tegra_clk_pll_p_out5] = { .dt_id = TEGRA210_CLK_PLL_P_OUT5, .present = true },
[tegra_clk_pll_c4] = { .dt_id = TEGRA210_CLK_PLL_C4, .present = true },
[tegra_clk_pll_dp] = { .dt_id = TEGRA210_CLK_PLL_DP, .present = true },
[tegra_clk_audio0_mux] = { .dt_id = TEGRA210_CLK_AUDIO0_MUX, .present = true },
[tegra_clk_audio1_mux] = { .dt_id = TEGRA210_CLK_AUDIO1_MUX, .present = true },
[tegra_clk_audio2_mux] = { .dt_id = TEGRA210_CLK_AUDIO2_MUX, .present = true },
[tegra_clk_audio3_mux] = { .dt_id = TEGRA210_CLK_AUDIO3_MUX, .present = true },
[tegra_clk_audio4_mux] = { .dt_id = TEGRA210_CLK_AUDIO4_MUX, .present = true },
[tegra_clk_spdif_mux] = { .dt_id = TEGRA210_CLK_SPDIF_MUX, .present = true },
[tegra_clk_maud] = { .dt_id = TEGRA210_CLK_MAUD, .present = true },
[tegra_clk_mipibif] = { .dt_id = TEGRA210_CLK_MIPIBIF, .present = true },
[tegra_clk_qspi] = { .dt_id = TEGRA210_CLK_QSPI, .present = true },
[tegra_clk_sdmmc_legacy] = { .dt_id = TEGRA210_CLK_SDMMC_LEGACY, .present = true },
[tegra_clk_tsecb] = { .dt_id = TEGRA210_CLK_TSECB, .present = true },
[tegra_clk_uartape] = { .dt_id = TEGRA210_CLK_UARTAPE, .present = true },
[tegra_clk_vi_i2c] = { .dt_id = TEGRA210_CLK_VI_I2C, .present = true },
[tegra_clk_ape] = { .dt_id = TEGRA210_CLK_APE, .present = true },
[tegra_clk_dbgapb] = { .dt_id = TEGRA210_CLK_DBGAPB, .present = true },
[tegra_clk_nvdec] = { .dt_id = TEGRA210_CLK_NVDEC, .present = true },
[tegra_clk_nvenc] = { .dt_id = TEGRA210_CLK_NVENC, .present = true },
[tegra_clk_nvjpg] = { .dt_id = TEGRA210_CLK_NVJPG, .present = true },
[tegra_clk_pll_c4_out0] = { .dt_id = TEGRA210_CLK_PLL_C4_OUT0, .present = true },
[tegra_clk_pll_c4_out1] = { .dt_id = TEGRA210_CLK_PLL_C4_OUT1, .present = true },
[tegra_clk_pll_c4_out2] = { .dt_id = TEGRA210_CLK_PLL_C4_OUT2, .present = true },
[tegra_clk_pll_c4_out3] = { .dt_id = TEGRA210_CLK_PLL_C4_OUT3, .present = true },
[tegra_clk_apb2ape] = { .dt_id = TEGRA210_CLK_APB2APE, .present = true },
[tegra_clk_pll_a1] = { .dt_id = TEGRA210_CLK_PLL_A1, .present = true },
[tegra_clk_ispa] = { .dt_id = TEGRA210_CLK_ISPA, .present = true },
[tegra_clk_cec] = { .dt_id = TEGRA210_CLK_CEC, .present = true },
[tegra_clk_dmic1] = { .dt_id = TEGRA210_CLK_DMIC1, .present = true },
[tegra_clk_dmic2] = { .dt_id = TEGRA210_CLK_DMIC2, .present = true },
[tegra_clk_dmic3] = { .dt_id = TEGRA210_CLK_DMIC3, .present = true },
[tegra_clk_dmic1_sync_clk] = { .dt_id = TEGRA210_CLK_DMIC1_SYNC_CLK, .present = true },
[tegra_clk_dmic2_sync_clk] = { .dt_id = TEGRA210_CLK_DMIC2_SYNC_CLK, .present = true },
[tegra_clk_dmic3_sync_clk] = { .dt_id = TEGRA210_CLK_DMIC3_SYNC_CLK, .present = true },
[tegra_clk_dmic1_sync_clk_mux] = { .dt_id = TEGRA210_CLK_DMIC1_SYNC_CLK_MUX, .present = true },
[tegra_clk_dmic2_sync_clk_mux] = { .dt_id = TEGRA210_CLK_DMIC2_SYNC_CLK_MUX, .present = true },
[tegra_clk_dmic3_sync_clk_mux] = { .dt_id = TEGRA210_CLK_DMIC3_SYNC_CLK_MUX, .present = true },
[tegra_clk_dp2] = { .dt_id = TEGRA210_CLK_DP2, .present = true },
[tegra_clk_iqc1] = { .dt_id = TEGRA210_CLK_IQC1, .present = true },
[tegra_clk_iqc2] = { .dt_id = TEGRA210_CLK_IQC2, .present = true },
[tegra_clk_pll_a_out_adsp] = { .dt_id = TEGRA210_CLK_PLL_A_OUT_ADSP, .present = true },
[tegra_clk_pll_a_out0_out_adsp] = { .dt_id = TEGRA210_CLK_PLL_A_OUT0_OUT_ADSP, .present = true },
[tegra_clk_adsp] = { .dt_id = TEGRA210_CLK_ADSP, .present = true },
[tegra_clk_adsp_neon] = { .dt_id = TEGRA210_CLK_ADSP_NEON, .present = true },
};
static struct tegra_devclk devclks[] __initdata = {
{ .con_id = "clk_m", .dt_id = TEGRA210_CLK_CLK_M },
{ .con_id = "pll_ref", .dt_id = TEGRA210_CLK_PLL_REF },
{ .con_id = "clk_32k", .dt_id = TEGRA210_CLK_CLK_32K },
{ .con_id = "osc", .dt_id = TEGRA210_CLK_OSC },
{ .con_id = "osc_div2", .dt_id = TEGRA210_CLK_OSC_DIV2 },
{ .con_id = "osc_div4", .dt_id = TEGRA210_CLK_OSC_DIV4 },
{ .con_id = "pll_c", .dt_id = TEGRA210_CLK_PLL_C },
{ .con_id = "pll_c_out1", .dt_id = TEGRA210_CLK_PLL_C_OUT1 },
{ .con_id = "pll_c2", .dt_id = TEGRA210_CLK_PLL_C2 },
{ .con_id = "pll_c3", .dt_id = TEGRA210_CLK_PLL_C3 },
{ .con_id = "pll_p", .dt_id = TEGRA210_CLK_PLL_P },
{ .con_id = "pll_p_out1", .dt_id = TEGRA210_CLK_PLL_P_OUT1 },
{ .con_id = "pll_p_out2", .dt_id = TEGRA210_CLK_PLL_P_OUT2 },
{ .con_id = "pll_p_out3", .dt_id = TEGRA210_CLK_PLL_P_OUT3 },
{ .con_id = "pll_p_out4", .dt_id = TEGRA210_CLK_PLL_P_OUT4 },
{ .con_id = "pll_m", .dt_id = TEGRA210_CLK_PLL_M },
{ .con_id = "pll_x", .dt_id = TEGRA210_CLK_PLL_X },
{ .con_id = "pll_x_out0", .dt_id = TEGRA210_CLK_PLL_X_OUT0 },
{ .con_id = "pll_u", .dt_id = TEGRA210_CLK_PLL_U },
{ .con_id = "pll_u_out", .dt_id = TEGRA210_CLK_PLL_U_OUT },
{ .con_id = "pll_u_out1", .dt_id = TEGRA210_CLK_PLL_U_OUT1 },
{ .con_id = "pll_u_out2", .dt_id = TEGRA210_CLK_PLL_U_OUT2 },
{ .con_id = "pll_u_480M", .dt_id = TEGRA210_CLK_PLL_U_480M },
{ .con_id = "pll_u_60M", .dt_id = TEGRA210_CLK_PLL_U_60M },
{ .con_id = "pll_u_48M", .dt_id = TEGRA210_CLK_PLL_U_48M },
{ .con_id = "pll_d", .dt_id = TEGRA210_CLK_PLL_D },
{ .con_id = "pll_d_out0", .dt_id = TEGRA210_CLK_PLL_D_OUT0 },
{ .con_id = "pll_d2", .dt_id = TEGRA210_CLK_PLL_D2 },
{ .con_id = "pll_d2_out0", .dt_id = TEGRA210_CLK_PLL_D2_OUT0 },
{ .con_id = "pll_a", .dt_id = TEGRA210_CLK_PLL_A },
{ .con_id = "pll_a_out0", .dt_id = TEGRA210_CLK_PLL_A_OUT0 },
{ .con_id = "pll_re_vco", .dt_id = TEGRA210_CLK_PLL_RE_VCO },
{ .con_id = "pll_re_out", .dt_id = TEGRA210_CLK_PLL_RE_OUT },
{ .con_id = "spdif_in_sync", .dt_id = TEGRA210_CLK_SPDIF_IN_SYNC },
{ .con_id = "i2s0_sync", .dt_id = TEGRA210_CLK_I2S0_SYNC },
{ .con_id = "i2s1_sync", .dt_id = TEGRA210_CLK_I2S1_SYNC },
{ .con_id = "i2s2_sync", .dt_id = TEGRA210_CLK_I2S2_SYNC },
{ .con_id = "i2s3_sync", .dt_id = TEGRA210_CLK_I2S3_SYNC },
{ .con_id = "i2s4_sync", .dt_id = TEGRA210_CLK_I2S4_SYNC },
{ .con_id = "vimclk_sync", .dt_id = TEGRA210_CLK_VIMCLK_SYNC },
{ .con_id = "audio0", .dt_id = TEGRA210_CLK_AUDIO0 },
{ .con_id = "audio1", .dt_id = TEGRA210_CLK_AUDIO1 },
{ .con_id = "audio2", .dt_id = TEGRA210_CLK_AUDIO2 },
{ .con_id = "audio3", .dt_id = TEGRA210_CLK_AUDIO3 },
{ .con_id = "audio4", .dt_id = TEGRA210_CLK_AUDIO4 },
{ .con_id = "spdif", .dt_id = TEGRA210_CLK_SPDIF },
{ .con_id = "spdif_2x", .dt_id = TEGRA210_CLK_SPDIF_2X },
{ .con_id = "extern1", .dt_id = TEGRA210_CLK_EXTERN1 },
{ .con_id = "extern2", .dt_id = TEGRA210_CLK_EXTERN2 },
{ .con_id = "extern3", .dt_id = TEGRA210_CLK_EXTERN3 },
{ .con_id = "cclk_g", .dt_id = TEGRA210_CLK_CCLK_G },
{ .con_id = "cclk_lp", .dt_id = TEGRA210_CLK_CCLK_LP },
{ .con_id = "sclk", .dt_id = TEGRA210_CLK_SCLK },
{ .con_id = "hclk", .dt_id = TEGRA210_CLK_HCLK },
{ .con_id = "pclk", .dt_id = TEGRA210_CLK_PCLK },
{ .con_id = "fuse", .dt_id = TEGRA210_CLK_FUSE },
{ .dev_id = "rtc-tegra", .dt_id = TEGRA210_CLK_RTC },
{ .dev_id = "timer", .dt_id = TEGRA210_CLK_TIMER },
{ .con_id = "pll_c4_out0", .dt_id = TEGRA210_CLK_PLL_C4_OUT0 },
{ .con_id = "pll_c4_out1", .dt_id = TEGRA210_CLK_PLL_C4_OUT1 },
{ .con_id = "pll_c4_out2", .dt_id = TEGRA210_CLK_PLL_C4_OUT2 },
{ .con_id = "pll_c4_out3", .dt_id = TEGRA210_CLK_PLL_C4_OUT3 },
{ .con_id = "dpaux", .dt_id = TEGRA210_CLK_DPAUX },
};
static struct tegra_audio_clk_info tegra210_audio_plls[] = {
{ "pll_a", &pll_a_params, tegra_clk_pll_a, "pll_ref" },
{ "pll_a1", &pll_a1_params, tegra_clk_pll_a1, "pll_ref" },
};
static const char * const aclk_parents[] = {
"pll_a1", "pll_c", "pll_p", "pll_a_out0", "pll_c2", "pll_c3",
"clk_m"
};
static const unsigned int nvjpg_slcg_clkids[] = { TEGRA210_CLK_NVDEC };
static const unsigned int nvdec_slcg_clkids[] = { TEGRA210_CLK_NVJPG };
static const unsigned int sor_slcg_clkids[] = { TEGRA210_CLK_HDA2CODEC_2X,
TEGRA210_CLK_HDA2HDMI, TEGRA210_CLK_DISP1, TEGRA210_CLK_DISP2 };
static const unsigned int disp_slcg_clkids[] = { TEGRA210_CLK_LA,
TEGRA210_CLK_HOST1X};
static const unsigned int xusba_slcg_clkids[] = { TEGRA210_CLK_XUSB_HOST,
TEGRA210_CLK_XUSB_DEV };
static const unsigned int xusbb_slcg_clkids[] = { TEGRA210_CLK_XUSB_HOST,
TEGRA210_CLK_XUSB_SS };
static const unsigned int xusbc_slcg_clkids[] = { TEGRA210_CLK_XUSB_DEV,
TEGRA210_CLK_XUSB_SS };
static const unsigned int venc_slcg_clkids[] = { TEGRA210_CLK_HOST1X,
TEGRA210_CLK_PLL_D };
static const unsigned int ape_slcg_clkids[] = { TEGRA210_CLK_ACLK,
TEGRA210_CLK_I2S0, TEGRA210_CLK_I2S1, TEGRA210_CLK_I2S2,
TEGRA210_CLK_I2S3, TEGRA210_CLK_I2S4, TEGRA210_CLK_SPDIF_OUT,
TEGRA210_CLK_D_AUDIO };
static const unsigned int vic_slcg_clkids[] = { TEGRA210_CLK_HOST1X };
static struct tegra210_domain_mbist_war tegra210_pg_mbist_war[] = {
[TEGRA_POWERGATE_VENC] = {
.handle_lvl2_ovr = tegra210_venc_mbist_war,
.num_clks = ARRAY_SIZE(venc_slcg_clkids),
.clk_init_data = venc_slcg_clkids,
},
[TEGRA_POWERGATE_SATA] = {
.handle_lvl2_ovr = tegra210_generic_mbist_war,
.lvl2_offset = LVL2_CLK_GATE_OVRC,
.lvl2_mask = BIT(0) | BIT(17) | BIT(19),
},
[TEGRA_POWERGATE_MPE] = {
.handle_lvl2_ovr = tegra210_generic_mbist_war,
.lvl2_offset = LVL2_CLK_GATE_OVRE,
.lvl2_mask = BIT(29),
},
[TEGRA_POWERGATE_SOR] = {
.handle_lvl2_ovr = tegra210_generic_mbist_war,
.num_clks = ARRAY_SIZE(sor_slcg_clkids),
.clk_init_data = sor_slcg_clkids,
.lvl2_offset = LVL2_CLK_GATE_OVRA,
.lvl2_mask = BIT(1) | BIT(2),
},
[TEGRA_POWERGATE_DIS] = {
.handle_lvl2_ovr = tegra210_disp_mbist_war,
.num_clks = ARRAY_SIZE(disp_slcg_clkids),
.clk_init_data = disp_slcg_clkids,
},
[TEGRA_POWERGATE_DISB] = {
.num_clks = ARRAY_SIZE(disp_slcg_clkids),
.clk_init_data = disp_slcg_clkids,
.handle_lvl2_ovr = tegra210_generic_mbist_war,
.lvl2_offset = LVL2_CLK_GATE_OVRA,
.lvl2_mask = BIT(2),
},
[TEGRA_POWERGATE_XUSBA] = {
.num_clks = ARRAY_SIZE(xusba_slcg_clkids),
.clk_init_data = xusba_slcg_clkids,
.handle_lvl2_ovr = tegra210_generic_mbist_war,
.lvl2_offset = LVL2_CLK_GATE_OVRC,
.lvl2_mask = BIT(30) | BIT(31),
},
[TEGRA_POWERGATE_XUSBB] = {
.num_clks = ARRAY_SIZE(xusbb_slcg_clkids),
.clk_init_data = xusbb_slcg_clkids,
.handle_lvl2_ovr = tegra210_generic_mbist_war,
.lvl2_offset = LVL2_CLK_GATE_OVRC,
.lvl2_mask = BIT(30) | BIT(31),
},
[TEGRA_POWERGATE_XUSBC] = {
.num_clks = ARRAY_SIZE(xusbc_slcg_clkids),
.clk_init_data = xusbc_slcg_clkids,
.handle_lvl2_ovr = tegra210_generic_mbist_war,
.lvl2_offset = LVL2_CLK_GATE_OVRC,
.lvl2_mask = BIT(30) | BIT(31),
},
[TEGRA_POWERGATE_VIC] = {
.num_clks = ARRAY_SIZE(vic_slcg_clkids),
.clk_init_data = vic_slcg_clkids,
.handle_lvl2_ovr = tegra210_vic_mbist_war,
},
[TEGRA_POWERGATE_NVDEC] = {
.num_clks = ARRAY_SIZE(nvdec_slcg_clkids),
.clk_init_data = nvdec_slcg_clkids,
.handle_lvl2_ovr = tegra210_generic_mbist_war,
.lvl2_offset = LVL2_CLK_GATE_OVRE,
.lvl2_mask = BIT(9) | BIT(31),
},
[TEGRA_POWERGATE_NVJPG] = {
.num_clks = ARRAY_SIZE(nvjpg_slcg_clkids),
.clk_init_data = nvjpg_slcg_clkids,
.handle_lvl2_ovr = tegra210_generic_mbist_war,
.lvl2_offset = LVL2_CLK_GATE_OVRE,
.lvl2_mask = BIT(9) | BIT(31),
},
[TEGRA_POWERGATE_AUD] = {
.num_clks = ARRAY_SIZE(ape_slcg_clkids),
.clk_init_data = ape_slcg_clkids,
.handle_lvl2_ovr = tegra210_ape_mbist_war,
},
[TEGRA_POWERGATE_VE2] = {
.handle_lvl2_ovr = tegra210_generic_mbist_war,
.lvl2_offset = LVL2_CLK_GATE_OVRD,
.lvl2_mask = BIT(22),
},
};
int tegra210_clk_handle_mbist_war(unsigned int id)
{
int err;
struct tegra210_domain_mbist_war *mbist_war;
if (id >= ARRAY_SIZE(tegra210_pg_mbist_war)) {
WARN(1, "unknown domain id in MBIST WAR handler\n");
return -EINVAL;
}
mbist_war = &tegra210_pg_mbist_war[id];
if (!mbist_war->handle_lvl2_ovr)
return 0;
if (mbist_war->num_clks && !mbist_war->clks)
return -ENODEV;
err = clk_bulk_prepare_enable(mbist_war->num_clks, mbist_war->clks);
if (err < 0)
return err;
mutex_lock(&lvl2_ovr_lock);
mbist_war->handle_lvl2_ovr(mbist_war);
mutex_unlock(&lvl2_ovr_lock);
clk_bulk_disable_unprepare(mbist_war->num_clks, mbist_war->clks);
return 0;
}
void tegra210_put_utmipll_in_iddq(void)
{
u32 reg;
reg = readl_relaxed(clk_base + UTMIPLL_HW_PWRDN_CFG0);
if (reg & UTMIPLL_HW_PWRDN_CFG0_UTMIPLL_LOCK) {
pr_err("trying to assert IDDQ while UTMIPLL is locked\n");
return;
}
reg |= UTMIPLL_HW_PWRDN_CFG0_IDDQ_OVERRIDE;
writel_relaxed(reg, clk_base + UTMIPLL_HW_PWRDN_CFG0);
}
EXPORT_SYMBOL_GPL(tegra210_put_utmipll_in_iddq);
void tegra210_put_utmipll_out_iddq(void)
{
u32 reg;
reg = readl_relaxed(clk_base + UTMIPLL_HW_PWRDN_CFG0);
reg &= ~UTMIPLL_HW_PWRDN_CFG0_IDDQ_OVERRIDE;
writel_relaxed(reg, clk_base + UTMIPLL_HW_PWRDN_CFG0);
}
EXPORT_SYMBOL_GPL(tegra210_put_utmipll_out_iddq);
static void tegra210_utmi_param_configure(void)
{
u32 reg;
int i;
for (i = 0; i < ARRAY_SIZE(utmi_parameters); i++) {
if (osc_freq == utmi_parameters[i].osc_frequency)
break;
}
if (i >= ARRAY_SIZE(utmi_parameters)) {
pr_err("%s: Unexpected oscillator freq %lu\n", __func__,
osc_freq);
return;
}
reg = readl_relaxed(clk_base + UTMIPLL_HW_PWRDN_CFG0);
reg &= ~UTMIPLL_HW_PWRDN_CFG0_IDDQ_OVERRIDE;
writel_relaxed(reg, clk_base + UTMIPLL_HW_PWRDN_CFG0);
udelay(10);
reg = readl_relaxed(clk_base + UTMIP_PLL_CFG2);
/* Program UTMIP PLL stable and active counts */
/* [FIXME] arclk_rst.h says WRONG! This should be 1ms -> 0x50 Check! */
reg &= ~UTMIP_PLL_CFG2_STABLE_COUNT(~0);
reg |= UTMIP_PLL_CFG2_STABLE_COUNT(utmi_parameters[i].stable_count);
reg &= ~UTMIP_PLL_CFG2_ACTIVE_DLY_COUNT(~0);
reg |=
UTMIP_PLL_CFG2_ACTIVE_DLY_COUNT(utmi_parameters[i].active_delay_count);
writel_relaxed(reg, clk_base + UTMIP_PLL_CFG2);
/* Program UTMIP PLL delay and oscillator frequency counts */
reg = readl_relaxed(clk_base + UTMIP_PLL_CFG1);
reg &= ~UTMIP_PLL_CFG1_ENABLE_DLY_COUNT(~0);
reg |=
UTMIP_PLL_CFG1_ENABLE_DLY_COUNT(utmi_parameters[i].enable_delay_count);
reg &= ~UTMIP_PLL_CFG1_XTAL_FREQ_COUNT(~0);
reg |=
UTMIP_PLL_CFG1_XTAL_FREQ_COUNT(utmi_parameters[i].xtal_freq_count);
reg |= UTMIP_PLL_CFG1_FORCE_PLLU_POWERDOWN;
writel_relaxed(reg, clk_base + UTMIP_PLL_CFG1);
/* Remove power downs from UTMIP PLL control bits */
reg = readl_relaxed(clk_base + UTMIP_PLL_CFG1);
reg &= ~UTMIP_PLL_CFG1_FORCE_PLL_ENABLE_POWERDOWN;
reg |= UTMIP_PLL_CFG1_FORCE_PLL_ENABLE_POWERUP;
writel_relaxed(reg, clk_base + UTMIP_PLL_CFG1);
udelay(20);
/* Enable samplers for SNPS, XUSB_HOST, XUSB_DEV */
reg = readl_relaxed(clk_base + UTMIP_PLL_CFG2);
reg |= UTMIP_PLL_CFG2_FORCE_PD_SAMP_A_POWERUP;
reg |= UTMIP_PLL_CFG2_FORCE_PD_SAMP_B_POWERUP;
reg |= UTMIP_PLL_CFG2_FORCE_PD_SAMP_D_POWERUP;
reg &= ~UTMIP_PLL_CFG2_FORCE_PD_SAMP_A_POWERDOWN;
reg &= ~UTMIP_PLL_CFG2_FORCE_PD_SAMP_B_POWERDOWN;
reg &= ~UTMIP_PLL_CFG2_FORCE_PD_SAMP_D_POWERDOWN;
writel_relaxed(reg, clk_base + UTMIP_PLL_CFG2);
/* Setup HW control of UTMIPLL */
reg = readl_relaxed(clk_base + UTMIP_PLL_CFG1);
reg &= ~UTMIP_PLL_CFG1_FORCE_PLL_ENABLE_POWERDOWN;
reg &= ~UTMIP_PLL_CFG1_FORCE_PLL_ENABLE_POWERUP;
writel_relaxed(reg, clk_base + UTMIP_PLL_CFG1);
reg = readl_relaxed(clk_base + UTMIPLL_HW_PWRDN_CFG0);
reg |= UTMIPLL_HW_PWRDN_CFG0_USE_LOCKDET;
reg &= ~UTMIPLL_HW_PWRDN_CFG0_CLK_ENABLE_SWCTL;
writel_relaxed(reg, clk_base + UTMIPLL_HW_PWRDN_CFG0);
udelay(1);
reg = readl_relaxed(clk_base + XUSB_PLL_CFG0);
reg &= ~XUSB_PLL_CFG0_UTMIPLL_LOCK_DLY;
writel_relaxed(reg, clk_base + XUSB_PLL_CFG0);
udelay(1);
/* Enable HW control UTMIPLL */
reg = readl_relaxed(clk_base + UTMIPLL_HW_PWRDN_CFG0);
reg |= UTMIPLL_HW_PWRDN_CFG0_SEQ_ENABLE;
writel_relaxed(reg, clk_base + UTMIPLL_HW_PWRDN_CFG0);
}
static int tegra210_enable_pllu(void)
{
struct tegra_clk_pll_freq_table *fentry;
struct tegra_clk_pll pllu;
u32 reg;
int ret;
for (fentry = pll_u_freq_table; fentry->input_rate; fentry++) {
if (fentry->input_rate == pll_ref_freq)
break;
}
if (!fentry->input_rate) {
pr_err("Unknown PLL_U reference frequency %lu\n", pll_ref_freq);
return -EINVAL;
}
/* clear IDDQ bit */
pllu.params = &pll_u_vco_params;
reg = readl_relaxed(clk_base + pllu.params->ext_misc_reg[0]);
reg &= ~BIT(pllu.params->iddq_bit_idx);
writel_relaxed(reg, clk_base + pllu.params->ext_misc_reg[0]);
fence_udelay(5, clk_base);
reg = readl_relaxed(clk_base + PLLU_BASE);
reg &= ~GENMASK(20, 0);
reg |= fentry->m;
reg |= fentry->n << 8;
reg |= fentry->p << 16;
writel(reg, clk_base + PLLU_BASE);
fence_udelay(1, clk_base);
reg |= PLL_ENABLE;
writel(reg, clk_base + PLLU_BASE);
/*
* During clocks resume, same PLLU init and enable sequence get
* executed. So, readx_poll_timeout_atomic can't be used here as it
* uses ktime_get() and timekeeping resume doesn't happen by that
* time. So, using tegra210_wait_for_mask for PLL LOCK.
*/
ret = tegra210_wait_for_mask(&pllu, PLLU_BASE, PLL_BASE_LOCK);
if (ret) {
pr_err("Timed out waiting for PLL_U to lock\n");
return -ETIMEDOUT;
}
return 0;
}
static int tegra210_init_pllu(void)
{
u32 reg;
int err;
tegra210_pllu_set_defaults(&pll_u_vco_params);
/* skip initialization when pllu is in hw controlled mode */
reg = readl_relaxed(clk_base + PLLU_BASE);
if (reg & PLLU_BASE_OVERRIDE) {
if (!(reg & PLL_ENABLE)) {
err = tegra210_enable_pllu();
if (err < 0) {
WARN_ON(1);
return err;
}
}
/* enable hw controlled mode */
reg = readl_relaxed(clk_base + PLLU_BASE);
reg &= ~PLLU_BASE_OVERRIDE;
writel(reg, clk_base + PLLU_BASE);
reg = readl_relaxed(clk_base + PLLU_HW_PWRDN_CFG0);
reg |= PLLU_HW_PWRDN_CFG0_IDDQ_PD_INCLUDE |
PLLU_HW_PWRDN_CFG0_USE_SWITCH_DETECT |
PLLU_HW_PWRDN_CFG0_USE_LOCKDET;
reg &= ~(PLLU_HW_PWRDN_CFG0_CLK_ENABLE_SWCTL |
PLLU_HW_PWRDN_CFG0_CLK_SWITCH_SWCTL);
writel_relaxed(reg, clk_base + PLLU_HW_PWRDN_CFG0);
reg = readl_relaxed(clk_base + XUSB_PLL_CFG0);
reg &= ~XUSB_PLL_CFG0_PLLU_LOCK_DLY_MASK;
writel_relaxed(reg, clk_base + XUSB_PLL_CFG0);
fence_udelay(1, clk_base);
reg = readl_relaxed(clk_base + PLLU_HW_PWRDN_CFG0);
reg |= PLLU_HW_PWRDN_CFG0_SEQ_ENABLE;
writel_relaxed(reg, clk_base + PLLU_HW_PWRDN_CFG0);
fence_udelay(1, clk_base);
reg = readl_relaxed(clk_base + PLLU_BASE);
reg &= ~PLLU_BASE_CLKENABLE_USB;
writel_relaxed(reg, clk_base + PLLU_BASE);
}
/* enable UTMIPLL hw control if not yet done by the bootloader */
reg = readl_relaxed(clk_base + UTMIPLL_HW_PWRDN_CFG0);
if (!(reg & UTMIPLL_HW_PWRDN_CFG0_SEQ_ENABLE))
tegra210_utmi_param_configure();
return 0;
}
/*
* The SOR hardware blocks are driven by two clocks: a module clock that is
* used to access registers and a pixel clock that is sourced from the same
* pixel clock that also drives the head attached to the SOR. The module
* clock is typically called sorX (with X being the SOR instance) and the
* pixel clock is called sorX_out. The source for the SOR pixel clock is
* referred to as the "parent" clock.
*
* On Tegra186 and newer, clocks are provided by the BPMP. Unfortunately the
* BPMP implementation for the SOR clocks doesn't exactly match the above in
* some aspects. For example, the SOR module is really clocked by the pad or
* sor_safe clocks, but BPMP models the sorX clock as being sourced by the
* pixel clocks. Conversely the sorX_out clock is sourced by the sor_safe or
* pad clocks on BPMP.
*
* In order to allow the display driver to deal with all SoC generations in
* a unified way, implement the BPMP semantics in this driver.
*/
static const char * const sor0_parents[] = {
"pll_d_out0",
};
static const char * const sor0_out_parents[] = {
"sor_safe", "sor0_pad_clkout",
};
static const char * const sor1_parents[] = {
"pll_p", "pll_d_out0", "pll_d2_out0", "clk_m",
};
static u32 sor1_parents_idx[] = { 0, 2, 5, 6 };
static const struct clk_div_table mc_div_table_tegra210[] = {
{ .val = 0, .div = 2 },
{ .val = 1, .div = 4 },
{ .val = 2, .div = 1 },
{ .val = 3, .div = 2 },
{ .val = 0, .div = 0 },
};
static void tegra210_clk_register_mc(const char *name,
const char *parent_name)
{
struct clk *clk;
clk = clk_register_divider_table(NULL, name, parent_name,
CLK_IS_CRITICAL,
clk_base + CLK_SOURCE_EMC,
15, 2, CLK_DIVIDER_READ_ONLY,
mc_div_table_tegra210, &emc_lock);
clks[TEGRA210_CLK_MC] = clk;
}
static const char * const sor1_out_parents[] = {
/*
* Bit 0 of the mux selects sor1_pad_clkout, irrespective of bit 1, so
* the sor1_pad_clkout parent appears twice in the list below. This is
* merely to support clk_get_parent() if firmware happened to set
* these bits to 0b11. While not an invalid setting, code should
* always set the bits to 0b01 to select sor1_pad_clkout.
*/
"sor_safe", "sor1_pad_clkout", "sor1_out", "sor1_pad_clkout",
};
static struct tegra_periph_init_data tegra210_periph[] = {
/*
* On Tegra210, the sor0 clock doesn't have a mux it bitfield 31:29,
* but it is hardwired to the pll_d_out0 clock.
*/
TEGRA_INIT_DATA_TABLE("sor0", NULL, NULL, sor0_parents,
CLK_SOURCE_SOR0, 29, 0x0, 0, 0, 0, 0,
0, 182, 0, tegra_clk_sor0, NULL, 0,
&sor0_lock),
TEGRA_INIT_DATA_TABLE("sor0_out", NULL, NULL, sor0_out_parents,
CLK_SOURCE_SOR0, 14, 0x1, 0, 0, 0, 0,
0, 0, TEGRA_PERIPH_NO_GATE, tegra_clk_sor0_out,
NULL, 0, &sor0_lock),
TEGRA_INIT_DATA_TABLE("sor1", NULL, NULL, sor1_parents,
CLK_SOURCE_SOR1, 29, 0x7, 0, 0, 8, 1,
TEGRA_DIVIDER_ROUND_UP, 183, 0,
tegra_clk_sor1, sor1_parents_idx, 0,
&sor1_lock),
TEGRA_INIT_DATA_TABLE("sor1_out", NULL, NULL, sor1_out_parents,
CLK_SOURCE_SOR1, 14, 0x3, 0, 0, 0, 0,
0, 0, TEGRA_PERIPH_NO_GATE,
tegra_clk_sor1_out, NULL, 0, &sor1_lock),
};
static const char * const la_parents[] = {
"pll_p", "pll_c2", "pll_c", "pll_c3", "pll_re_out1", "pll_a1", "clk_m", "pll_c4_out0"
};
static struct tegra_clk_periph tegra210_la =
TEGRA_CLK_PERIPH(29, 7, 9, 0, 8, 1, TEGRA_DIVIDER_ROUND_UP, 76, 0, NULL, NULL);
static __init void tegra210_periph_clk_init(struct device_node *np,
void __iomem *clk_base,
void __iomem *pmc_base)
{
struct clk *clk;
unsigned int i;
/* xusb_ss_div2 */
clk = clk_register_fixed_factor(NULL, "xusb_ss_div2", "xusb_ss_src", 0,
1, 2);
clks[TEGRA210_CLK_XUSB_SS_DIV2] = clk;
clk = tegra_clk_register_periph_fixed("sor_safe", "pll_p", 0, clk_base,
1, 17, 222);
clks[TEGRA210_CLK_SOR_SAFE] = clk;
clk = tegra_clk_register_periph_fixed("dpaux", "sor_safe", 0, clk_base,
1, 17, 181);
clks[TEGRA210_CLK_DPAUX] = clk;
clk = tegra_clk_register_periph_fixed("dpaux1", "sor_safe", 0, clk_base,
1, 17, 207);
clks[TEGRA210_CLK_DPAUX1] = clk;
/* pll_d_dsi_out */
clk = clk_register_gate(NULL, "pll_d_dsi_out", "pll_d_out0", 0,
clk_base + PLLD_MISC0, 21, 0, &pll_d_lock);
clks[TEGRA210_CLK_PLL_D_DSI_OUT] = clk;
/* dsia */
clk = tegra_clk_register_periph_gate("dsia", "pll_d_dsi_out", 0,
clk_base, 0, 48,
periph_clk_enb_refcnt);
clks[TEGRA210_CLK_DSIA] = clk;
/* dsib */
clk = tegra_clk_register_periph_gate("dsib", "pll_d_dsi_out", 0,
clk_base, 0, 82,
periph_clk_enb_refcnt);
clks[TEGRA210_CLK_DSIB] = clk;
/* csi_tpg */
clk = clk_register_gate(NULL, "csi_tpg", "pll_d",
CLK_SET_RATE_PARENT, clk_base + PLLD_BASE,
23, 0, &pll_d_lock);
clk_register_clkdev(clk, "csi_tpg", NULL);
clks[TEGRA210_CLK_CSI_TPG] = clk;
/* la */
clk = tegra_clk_register_periph("la", la_parents,
ARRAY_SIZE(la_parents), &tegra210_la, clk_base,
CLK_SOURCE_LA, 0);
clks[TEGRA210_CLK_LA] = clk;
/* cml0 */
clk = clk_register_gate(NULL, "cml0", "pll_e", 0, clk_base + PLLE_AUX,
0, 0, &pll_e_lock);
clk_register_clkdev(clk, "cml0", NULL);
clks[TEGRA210_CLK_CML0] = clk;
/* cml1 */
clk = clk_register_gate(NULL, "cml1", "pll_e", 0, clk_base + PLLE_AUX,
1, 0, &pll_e_lock);
clk_register_clkdev(clk, "cml1", NULL);
clks[TEGRA210_CLK_CML1] = clk;
clk = tegra_clk_register_super_clk("aclk", aclk_parents,
ARRAY_SIZE(aclk_parents), 0, clk_base + 0x6e0,
0, NULL);
clks[TEGRA210_CLK_ACLK] = clk;
clk = tegra_clk_register_sdmmc_mux_div("sdmmc2", clk_base,
CLK_SOURCE_SDMMC2, 9,
TEGRA_DIVIDER_ROUND_UP, 0, NULL);
clks[TEGRA210_CLK_SDMMC2] = clk;
clk = tegra_clk_register_sdmmc_mux_div("sdmmc4", clk_base,
CLK_SOURCE_SDMMC4, 15,
TEGRA_DIVIDER_ROUND_UP, 0, NULL);
clks[TEGRA210_CLK_SDMMC4] = clk;
for (i = 0; i < ARRAY_SIZE(tegra210_periph); i++) {
struct tegra_periph_init_data *init = &tegra210_periph[i];
struct clk **clkp;
clkp = tegra_lookup_dt_id(init->clk_id, tegra210_clks);
if (!clkp) {
pr_warn("clock %u not found\n", init->clk_id);
continue;
}
clk = tegra_clk_register_periph_data(clk_base, init);
*clkp = clk;
}
tegra_periph_clk_init(clk_base, pmc_base, tegra210_clks, &pll_p_params);
/* emc */
clk = tegra210_clk_register_emc(np, clk_base);
clks[TEGRA210_CLK_EMC] = clk;
/* mc */
tegra210_clk_register_mc("mc", "emc");
}
static void __init tegra210_pll_init(void __iomem *clk_base,
void __iomem *pmc)
{
struct clk *clk;
/* PLLC */
clk = tegra_clk_register_pllc_tegra210("pll_c", "pll_ref", clk_base,
pmc, 0, &pll_c_params, NULL);
if (!WARN_ON(IS_ERR(clk)))
clk_register_clkdev(clk, "pll_c", NULL);
clks[TEGRA210_CLK_PLL_C] = clk;
/* PLLC_OUT1 */
clk = tegra_clk_register_divider("pll_c_out1_div", "pll_c",
clk_base + PLLC_OUT, 0, TEGRA_DIVIDER_ROUND_UP,
8, 8, 1, NULL);
clk = tegra_clk_register_pll_out("pll_c_out1", "pll_c_out1_div",
clk_base + PLLC_OUT, 1, 0,
CLK_SET_RATE_PARENT, 0, NULL);
clk_register_clkdev(clk, "pll_c_out1", NULL);
clks[TEGRA210_CLK_PLL_C_OUT1] = clk;
/* PLLC_UD */
clk = clk_register_fixed_factor(NULL, "pll_c_ud", "pll_c",
CLK_SET_RATE_PARENT, 1, 1);
clk_register_clkdev(clk, "pll_c_ud", NULL);
clks[TEGRA210_CLK_PLL_C_UD] = clk;
/* PLLC2 */
clk = tegra_clk_register_pllc_tegra210("pll_c2", "pll_ref", clk_base,
pmc, 0, &pll_c2_params, NULL);
clk_register_clkdev(clk, "pll_c2", NULL);
clks[TEGRA210_CLK_PLL_C2] = clk;
/* PLLC3 */
clk = tegra_clk_register_pllc_tegra210("pll_c3", "pll_ref", clk_base,
pmc, 0, &pll_c3_params, NULL);
clk_register_clkdev(clk, "pll_c3", NULL);
clks[TEGRA210_CLK_PLL_C3] = clk;
/* PLLM */
clk = tegra_clk_register_pllm("pll_m", "osc", clk_base, pmc,
CLK_SET_RATE_GATE, &pll_m_params, NULL);
clk_register_clkdev(clk, "pll_m", NULL);
clks[TEGRA210_CLK_PLL_M] = clk;
/* PLLMB */
clk = tegra_clk_register_pllmb("pll_mb", "osc", clk_base, pmc,
CLK_SET_RATE_GATE, &pll_mb_params, NULL);
clk_register_clkdev(clk, "pll_mb", NULL);
clks[TEGRA210_CLK_PLL_MB] = clk;
/* PLLM_UD */
clk = clk_register_fixed_factor(NULL, "pll_m_ud", "pll_m",
CLK_SET_RATE_PARENT, 1, 1);
clk_register_clkdev(clk, "pll_m_ud", NULL);
clks[TEGRA210_CLK_PLL_M_UD] = clk;
/* PLLMB_UD */
clk = clk_register_fixed_factor(NULL, "pll_mb_ud", "pll_mb",
CLK_SET_RATE_PARENT, 1, 1);
clk_register_clkdev(clk, "pll_mb_ud", NULL);
clks[TEGRA210_CLK_PLL_MB_UD] = clk;
/* PLLP_UD */
clk = clk_register_fixed_factor(NULL, "pll_p_ud", "pll_p",
0, 1, 1);
clks[TEGRA210_CLK_PLL_P_UD] = clk;
/* PLLU_VCO */
if (!tegra210_init_pllu()) {
clk = clk_register_fixed_rate(NULL, "pll_u_vco", "pll_ref", 0,
480*1000*1000);
clk_register_clkdev(clk, "pll_u_vco", NULL);
clks[TEGRA210_CLK_PLL_U] = clk;
}
/* PLLU_OUT */
clk = clk_register_divider_table(NULL, "pll_u_out", "pll_u_vco", 0,
clk_base + PLLU_BASE, 16, 4, 0,
pll_vco_post_div_table, NULL);
clk_register_clkdev(clk, "pll_u_out", NULL);
clks[TEGRA210_CLK_PLL_U_OUT] = clk;
/* PLLU_OUT1 */
clk = tegra_clk_register_divider("pll_u_out1_div", "pll_u_out",
clk_base + PLLU_OUTA, 0,
TEGRA_DIVIDER_ROUND_UP,
8, 8, 1, &pll_u_lock);
clk = tegra_clk_register_pll_out("pll_u_out1", "pll_u_out1_div",
clk_base + PLLU_OUTA, 1, 0,
CLK_SET_RATE_PARENT, 0, &pll_u_lock);
clk_register_clkdev(clk, "pll_u_out1", NULL);
clks[TEGRA210_CLK_PLL_U_OUT1] = clk;
/* PLLU_OUT2 */
clk = tegra_clk_register_divider("pll_u_out2_div", "pll_u_out",
clk_base + PLLU_OUTA, 0,
TEGRA_DIVIDER_ROUND_UP,
24, 8, 1, &pll_u_lock);
clk = tegra_clk_register_pll_out("pll_u_out2", "pll_u_out2_div",
clk_base + PLLU_OUTA, 17, 16,
CLK_SET_RATE_PARENT, 0, &pll_u_lock);
clk_register_clkdev(clk, "pll_u_out2", NULL);
clks[TEGRA210_CLK_PLL_U_OUT2] = clk;
/* PLLU_480M */
clk = clk_register_gate(NULL, "pll_u_480M", "pll_u_vco",
CLK_SET_RATE_PARENT, clk_base + PLLU_BASE,
22, 0, &pll_u_lock);
clk_register_clkdev(clk, "pll_u_480M", NULL);
clks[TEGRA210_CLK_PLL_U_480M] = clk;
/* PLLU_60M */
clk = clk_register_gate(NULL, "pll_u_60M", "pll_u_out2",
CLK_SET_RATE_PARENT, clk_base + PLLU_BASE,
23, 0, &pll_u_lock);
clk_register_clkdev(clk, "pll_u_60M", NULL);
clks[TEGRA210_CLK_PLL_U_60M] = clk;
/* PLLU_48M */
clk = clk_register_gate(NULL, "pll_u_48M", "pll_u_out1",
CLK_SET_RATE_PARENT, clk_base + PLLU_BASE,
25, 0, &pll_u_lock);
clk_register_clkdev(clk, "pll_u_48M", NULL);
clks[TEGRA210_CLK_PLL_U_48M] = clk;
/* PLLD */
clk = tegra_clk_register_pll("pll_d", "pll_ref", clk_base, pmc, 0,
&pll_d_params, &pll_d_lock);
clk_register_clkdev(clk, "pll_d", NULL);
clks[TEGRA210_CLK_PLL_D] = clk;
/* PLLD_OUT0 */
clk = clk_register_fixed_factor(NULL, "pll_d_out0", "pll_d",
CLK_SET_RATE_PARENT, 1, 2);
clk_register_clkdev(clk, "pll_d_out0", NULL);
clks[TEGRA210_CLK_PLL_D_OUT0] = clk;
/* PLLRE */
clk = tegra_clk_register_pllre_tegra210("pll_re_vco", "pll_ref",
clk_base, pmc, 0,
&pll_re_vco_params,
&pll_re_lock, pll_ref_freq);
clk_register_clkdev(clk, "pll_re_vco", NULL);
clks[TEGRA210_CLK_PLL_RE_VCO] = clk;
clk = clk_register_divider_table(NULL, "pll_re_out", "pll_re_vco", 0,
clk_base + PLLRE_BASE, 16, 5, 0,
pll_vco_post_div_table, &pll_re_lock);
clk_register_clkdev(clk, "pll_re_out", NULL);
clks[TEGRA210_CLK_PLL_RE_OUT] = clk;
clk = tegra_clk_register_divider("pll_re_out1_div", "pll_re_vco",
clk_base + PLLRE_OUT1, 0,
TEGRA_DIVIDER_ROUND_UP,
8, 8, 1, NULL);
clk = tegra_clk_register_pll_out("pll_re_out1", "pll_re_out1_div",
clk_base + PLLRE_OUT1, 1, 0,
CLK_SET_RATE_PARENT, 0, NULL);
clks[TEGRA210_CLK_PLL_RE_OUT1] = clk;
/* PLLE */
clk = tegra_clk_register_plle_tegra210("pll_e", "pll_ref",
clk_base, 0, &pll_e_params, NULL);
clk_register_clkdev(clk, "pll_e", NULL);
clks[TEGRA210_CLK_PLL_E] = clk;
/* PLLC4 */
clk = tegra_clk_register_pllre("pll_c4_vco", "pll_ref", clk_base, pmc,
0, &pll_c4_vco_params, NULL, pll_ref_freq);
clk_register_clkdev(clk, "pll_c4_vco", NULL);
clks[TEGRA210_CLK_PLL_C4] = clk;
/* PLLC4_OUT0 */
clk = clk_register_divider_table(NULL, "pll_c4_out0", "pll_c4_vco", 0,
clk_base + PLLC4_BASE, 19, 4, 0,
pll_vco_post_div_table, NULL);
clk_register_clkdev(clk, "pll_c4_out0", NULL);
clks[TEGRA210_CLK_PLL_C4_OUT0] = clk;
/* PLLC4_OUT1 */
clk = clk_register_fixed_factor(NULL, "pll_c4_out1", "pll_c4_vco",
CLK_SET_RATE_PARENT, 1, 3);
clk_register_clkdev(clk, "pll_c4_out1", NULL);
clks[TEGRA210_CLK_PLL_C4_OUT1] = clk;
/* PLLC4_OUT2 */
clk = clk_register_fixed_factor(NULL, "pll_c4_out2", "pll_c4_vco",
CLK_SET_RATE_PARENT, 1, 5);
clk_register_clkdev(clk, "pll_c4_out2", NULL);
clks[TEGRA210_CLK_PLL_C4_OUT2] = clk;
/* PLLC4_OUT3 */
clk = tegra_clk_register_divider("pll_c4_out3_div", "pll_c4_out0",
clk_base + PLLC4_OUT, 0, TEGRA_DIVIDER_ROUND_UP,
8, 8, 1, NULL);
clk = tegra_clk_register_pll_out("pll_c4_out3", "pll_c4_out3_div",
clk_base + PLLC4_OUT, 1, 0,
CLK_SET_RATE_PARENT, 0, NULL);
clk_register_clkdev(clk, "pll_c4_out3", NULL);
clks[TEGRA210_CLK_PLL_C4_OUT3] = clk;
/* PLLDP */
clk = tegra_clk_register_pllss_tegra210("pll_dp", "pll_ref", clk_base,
0, &pll_dp_params, NULL);
clk_register_clkdev(clk, "pll_dp", NULL);
clks[TEGRA210_CLK_PLL_DP] = clk;
/* PLLD2 */
clk = tegra_clk_register_pllss_tegra210("pll_d2", "pll_ref", clk_base,
0, &pll_d2_params, NULL);
clk_register_clkdev(clk, "pll_d2", NULL);
clks[TEGRA210_CLK_PLL_D2] = clk;
/* PLLD2_OUT0 */
clk = clk_register_fixed_factor(NULL, "pll_d2_out0", "pll_d2",
CLK_SET_RATE_PARENT, 1, 1);
clk_register_clkdev(clk, "pll_d2_out0", NULL);
clks[TEGRA210_CLK_PLL_D2_OUT0] = clk;
/* PLLP_OUT2 */
clk = clk_register_fixed_factor(NULL, "pll_p_out2", "pll_p",
CLK_SET_RATE_PARENT, 1, 2);
clk_register_clkdev(clk, "pll_p_out2", NULL);
clks[TEGRA210_CLK_PLL_P_OUT2] = clk;
}
/* Tegra210 CPU clock and reset control functions */
static void tegra210_wait_cpu_in_reset(u32 cpu)
{
unsigned int reg;
do {
reg = readl(clk_base + CLK_RST_CONTROLLER_CPU_CMPLX_STATUS);
cpu_relax();
} while (!(reg & (1 << cpu))); /* check CPU been reset or not */
}
static void tegra210_disable_cpu_clock(u32 cpu)
{
/* flow controller would take care in the power sequence. */
}
#ifdef CONFIG_PM_SLEEP
#define car_readl(_base, _off) readl_relaxed(clk_base + (_base) + ((_off) * 4))
#define car_writel(_val, _base, _off) \
writel_relaxed(_val, clk_base + (_base) + ((_off) * 4))
static u32 spare_reg_ctx, misc_clk_enb_ctx, clk_msk_arm_ctx;
static u32 cpu_softrst_ctx[3];
static int tegra210_clk_suspend(void)
{
unsigned int i;
clk_save_context();
/*
* Save the bootloader configured clock registers SPARE_REG0,
* MISC_CLK_ENB, CLK_MASK_ARM, CPU_SOFTRST_CTRL.
*/
spare_reg_ctx = readl_relaxed(clk_base + SPARE_REG0);
misc_clk_enb_ctx = readl_relaxed(clk_base + MISC_CLK_ENB);
clk_msk_arm_ctx = readl_relaxed(clk_base + CLK_MASK_ARM);
for (i = 0; i < ARRAY_SIZE(cpu_softrst_ctx); i++)
cpu_softrst_ctx[i] = car_readl(CPU_SOFTRST_CTRL, i);
tegra_clk_periph_suspend();
return 0;
}
static void tegra210_clk_resume(void)
{
unsigned int i;
tegra_clk_osc_resume(clk_base);
/*
* Restore the bootloader configured clock registers SPARE_REG0,
* MISC_CLK_ENB, CLK_MASK_ARM, CPU_SOFTRST_CTRL from saved context.
*/
writel_relaxed(spare_reg_ctx, clk_base + SPARE_REG0);
writel_relaxed(misc_clk_enb_ctx, clk_base + MISC_CLK_ENB);
writel_relaxed(clk_msk_arm_ctx, clk_base + CLK_MASK_ARM);
for (i = 0; i < ARRAY_SIZE(cpu_softrst_ctx); i++)
car_writel(cpu_softrst_ctx[i], CPU_SOFTRST_CTRL, i);
/*
* Tegra clock programming sequence recommends peripheral clock to
* be enabled prior to changing its clock source and divider to
* prevent glitchless frequency switch.
* So, enable all peripheral clocks before restoring their source
* and dividers.
*/
writel_relaxed(TEGRA210_CLK_ENB_VLD_MSK_L, clk_base + CLK_OUT_ENB_L);
writel_relaxed(TEGRA210_CLK_ENB_VLD_MSK_H, clk_base + CLK_OUT_ENB_H);
writel_relaxed(TEGRA210_CLK_ENB_VLD_MSK_U, clk_base + CLK_OUT_ENB_U);
writel_relaxed(TEGRA210_CLK_ENB_VLD_MSK_V, clk_base + CLK_OUT_ENB_V);
writel_relaxed(TEGRA210_CLK_ENB_VLD_MSK_W, clk_base + CLK_OUT_ENB_W);
writel_relaxed(TEGRA210_CLK_ENB_VLD_MSK_X, clk_base + CLK_OUT_ENB_X);
writel_relaxed(TEGRA210_CLK_ENB_VLD_MSK_Y, clk_base + CLK_OUT_ENB_Y);
/* wait for all writes to happen to have all the clocks enabled */
fence_udelay(2, clk_base);
/* restore PLLs and all peripheral clock rates */
tegra210_init_pllu();
clk_restore_context();
/* restore saved context of peripheral clocks and reset state */
tegra_clk_periph_resume();
}
static void tegra210_cpu_clock_suspend(void)
{
/* switch coresite to clk_m, save off original source */
tegra210_cpu_clk_sctx.clk_csite_src =
readl(clk_base + CLK_SOURCE_CSITE);
writel(3 << 30, clk_base + CLK_SOURCE_CSITE);
}
static void tegra210_cpu_clock_resume(void)
{
writel(tegra210_cpu_clk_sctx.clk_csite_src,
clk_base + CLK_SOURCE_CSITE);
}
#endif
static struct syscore_ops tegra_clk_syscore_ops = {
#ifdef CONFIG_PM_SLEEP
.suspend = tegra210_clk_suspend,
.resume = tegra210_clk_resume,
#endif
};
static struct tegra_cpu_car_ops tegra210_cpu_car_ops = {
.wait_for_reset = tegra210_wait_cpu_in_reset,
.disable_clock = tegra210_disable_cpu_clock,
#ifdef CONFIG_PM_SLEEP
.suspend = tegra210_cpu_clock_suspend,
.resume = tegra210_cpu_clock_resume,
#endif
};
static const struct of_device_id pmc_match[] __initconst = {
{ .compatible = "nvidia,tegra210-pmc" },
{ },
};
static struct tegra_clk_init_table init_table[] __initdata = {
{ TEGRA210_CLK_UARTA, TEGRA210_CLK_PLL_P, 408000000, 0 },
{ TEGRA210_CLK_UARTB, TEGRA210_CLK_PLL_P, 408000000, 0 },
{ TEGRA210_CLK_UARTC, TEGRA210_CLK_PLL_P, 408000000, 0 },
{ TEGRA210_CLK_UARTD, TEGRA210_CLK_PLL_P, 408000000, 0 },
{ TEGRA210_CLK_PLL_A, TEGRA210_CLK_CLK_MAX, 564480000, 0 },
{ TEGRA210_CLK_PLL_A_OUT0, TEGRA210_CLK_CLK_MAX, 11289600, 0 },
{ TEGRA210_CLK_I2S0, TEGRA210_CLK_PLL_A_OUT0, 11289600, 0 },
{ TEGRA210_CLK_I2S1, TEGRA210_CLK_PLL_A_OUT0, 11289600, 0 },
{ TEGRA210_CLK_I2S2, TEGRA210_CLK_PLL_A_OUT0, 11289600, 0 },
{ TEGRA210_CLK_I2S3, TEGRA210_CLK_PLL_A_OUT0, 11289600, 0 },
{ TEGRA210_CLK_I2S4, TEGRA210_CLK_PLL_A_OUT0, 11289600, 0 },
{ TEGRA210_CLK_HOST1X, TEGRA210_CLK_PLL_P, 136000000, 1 },
{ TEGRA210_CLK_SCLK_MUX, TEGRA210_CLK_PLL_P, 0, 1 },
{ TEGRA210_CLK_SCLK, TEGRA210_CLK_CLK_MAX, 102000000, 0 },
{ TEGRA210_CLK_DFLL_SOC, TEGRA210_CLK_PLL_P, 51000000, 1 },
{ TEGRA210_CLK_DFLL_REF, TEGRA210_CLK_PLL_P, 51000000, 1 },
{ TEGRA210_CLK_SBC4, TEGRA210_CLK_PLL_P, 12000000, 1 },
{ TEGRA210_CLK_PLL_U_OUT1, TEGRA210_CLK_CLK_MAX, 48000000, 1 },
{ TEGRA210_CLK_XUSB_GATE, TEGRA210_CLK_CLK_MAX, 0, 1 },
{ TEGRA210_CLK_XUSB_SS_SRC, TEGRA210_CLK_PLL_U_480M, 120000000, 0 },
{ TEGRA210_CLK_XUSB_FS_SRC, TEGRA210_CLK_PLL_U_48M, 48000000, 0 },
{ TEGRA210_CLK_XUSB_HS_SRC, TEGRA210_CLK_XUSB_SS_SRC, 120000000, 0 },
{ TEGRA210_CLK_XUSB_SSP_SRC, TEGRA210_CLK_XUSB_SS_SRC, 120000000, 0 },
{ TEGRA210_CLK_XUSB_FALCON_SRC, TEGRA210_CLK_PLL_P_OUT_XUSB, 204000000, 0 },
{ TEGRA210_CLK_XUSB_HOST_SRC, TEGRA210_CLK_PLL_P_OUT_XUSB, 102000000, 0 },
{ TEGRA210_CLK_XUSB_DEV_SRC, TEGRA210_CLK_PLL_P_OUT_XUSB, 102000000, 0 },
{ TEGRA210_CLK_SATA, TEGRA210_CLK_PLL_P, 104000000, 0 },
{ TEGRA210_CLK_SATA_OOB, TEGRA210_CLK_PLL_P, 204000000, 0 },
{ TEGRA210_CLK_MSELECT, TEGRA210_CLK_CLK_MAX, 0, 1 },
{ TEGRA210_CLK_CSITE, TEGRA210_CLK_CLK_MAX, 0, 1 },
/* TODO find a way to enable this on-demand */
{ TEGRA210_CLK_DBGAPB, TEGRA210_CLK_CLK_MAX, 0, 1 },
{ TEGRA210_CLK_TSENSOR, TEGRA210_CLK_CLK_M, 400000, 0 },
{ TEGRA210_CLK_I2C1, TEGRA210_CLK_PLL_P, 0, 0 },
{ TEGRA210_CLK_I2C2, TEGRA210_CLK_PLL_P, 0, 0 },
{ TEGRA210_CLK_I2C3, TEGRA210_CLK_PLL_P, 0, 0 },
{ TEGRA210_CLK_I2C4, TEGRA210_CLK_PLL_P, 0, 0 },
{ TEGRA210_CLK_I2C5, TEGRA210_CLK_PLL_P, 0, 0 },
{ TEGRA210_CLK_I2C6, TEGRA210_CLK_PLL_P, 0, 0 },
{ TEGRA210_CLK_PLL_DP, TEGRA210_CLK_CLK_MAX, 270000000, 0 },
{ TEGRA210_CLK_SOC_THERM, TEGRA210_CLK_PLL_P, 51000000, 0 },
{ TEGRA210_CLK_CCLK_G, TEGRA210_CLK_CLK_MAX, 0, 1 },
{ TEGRA210_CLK_PLL_U_OUT2, TEGRA210_CLK_CLK_MAX, 60000000, 1 },
{ TEGRA210_CLK_SPDIF_IN_SYNC, TEGRA210_CLK_CLK_MAX, 24576000, 0 },
{ TEGRA210_CLK_I2S0_SYNC, TEGRA210_CLK_CLK_MAX, 24576000, 0 },
{ TEGRA210_CLK_I2S1_SYNC, TEGRA210_CLK_CLK_MAX, 24576000, 0 },
{ TEGRA210_CLK_I2S2_SYNC, TEGRA210_CLK_CLK_MAX, 24576000, 0 },
{ TEGRA210_CLK_I2S3_SYNC, TEGRA210_CLK_CLK_MAX, 24576000, 0 },
{ TEGRA210_CLK_I2S4_SYNC, TEGRA210_CLK_CLK_MAX, 24576000, 0 },
{ TEGRA210_CLK_VIMCLK_SYNC, TEGRA210_CLK_CLK_MAX, 24576000, 0 },
{ TEGRA210_CLK_HDA, TEGRA210_CLK_PLL_P, 51000000, 0 },
{ TEGRA210_CLK_HDA2CODEC_2X, TEGRA210_CLK_PLL_P, 48000000, 0 },
/* This MUST be the last entry. */
{ TEGRA210_CLK_CLK_MAX, TEGRA210_CLK_CLK_MAX, 0, 0 },
};
/**
* tegra210_clock_apply_init_table - initialize clocks on Tegra210 SoCs
*
* Program an initial clock rate and enable or disable clocks needed
* by the rest of the kernel, for Tegra210 SoCs. It is intended to be
* called by assigning a pointer to it to tegra_clk_apply_init_table -
* this will be called as an arch_initcall. No return value.
*/
static void __init tegra210_clock_apply_init_table(void)
{
tegra_init_from_table(init_table, clks, TEGRA210_CLK_CLK_MAX);
}
/**
* tegra210_car_barrier - wait for pending writes to the CAR to complete
*
* Wait for any outstanding writes to the CAR MMIO space from this CPU
* to complete before continuing execution. No return value.
*/
static void tegra210_car_barrier(void)
{
readl_relaxed(clk_base + RST_DFLL_DVCO);
}
/**
* tegra210_clock_assert_dfll_dvco_reset - assert the DFLL's DVCO reset
*
* Assert the reset line of the DFLL's DVCO. No return value.
*/
static void tegra210_clock_assert_dfll_dvco_reset(void)
{
u32 v;
v = readl_relaxed(clk_base + RST_DFLL_DVCO);
v |= (1 << DVFS_DFLL_RESET_SHIFT);
writel_relaxed(v, clk_base + RST_DFLL_DVCO);
tegra210_car_barrier();
}
/**
* tegra210_clock_deassert_dfll_dvco_reset - deassert the DFLL's DVCO reset
*
* Deassert the reset line of the DFLL's DVCO, allowing the DVCO to
* operate. No return value.
*/
static void tegra210_clock_deassert_dfll_dvco_reset(void)
{
u32 v;
v = readl_relaxed(clk_base + RST_DFLL_DVCO);
v &= ~(1 << DVFS_DFLL_RESET_SHIFT);
writel_relaxed(v, clk_base + RST_DFLL_DVCO);
tegra210_car_barrier();
}
static int tegra210_reset_assert(unsigned long id)
{
if (id == TEGRA210_RST_DFLL_DVCO)
tegra210_clock_assert_dfll_dvco_reset();
else if (id == TEGRA210_RST_ADSP)
writel(GENMASK(26, 21) | BIT(7),
clk_base + CLK_RST_CONTROLLER_RST_DEV_Y_SET);
else
return -EINVAL;
return 0;
}
static int tegra210_reset_deassert(unsigned long id)
{
if (id == TEGRA210_RST_DFLL_DVCO)
tegra210_clock_deassert_dfll_dvco_reset();
else if (id == TEGRA210_RST_ADSP) {
writel(BIT(21), clk_base + CLK_RST_CONTROLLER_RST_DEV_Y_CLR);
/*
* Considering adsp cpu clock (min: 12.5MHZ, max: 1GHz)
* a delay of 5us ensures that it's at least
* 6 * adsp_cpu_cycle_period long.
*/
udelay(5);
writel(GENMASK(26, 22) | BIT(7),
clk_base + CLK_RST_CONTROLLER_RST_DEV_Y_CLR);
} else
return -EINVAL;
return 0;
}
static void tegra210_mbist_clk_init(void)
{
unsigned int i, j;
for (i = 0; i < ARRAY_SIZE(tegra210_pg_mbist_war); i++) {
unsigned int num_clks = tegra210_pg_mbist_war[i].num_clks;
struct clk_bulk_data *clk_data;
if (!num_clks)
continue;
clk_data = kmalloc_array(num_clks, sizeof(*clk_data),
GFP_KERNEL);
if (WARN_ON(!clk_data))
return;
tegra210_pg_mbist_war[i].clks = clk_data;
for (j = 0; j < num_clks; j++) {
int clk_id = tegra210_pg_mbist_war[i].clk_init_data[j];
struct clk *clk = clks[clk_id];
if (WARN(IS_ERR(clk), "clk_id: %d\n", clk_id)) {
kfree(clk_data);
tegra210_pg_mbist_war[i].clks = NULL;
break;
}
clk_data[j].clk = clk;
}
}
}
/**
* tegra210_clock_init - Tegra210-specific clock initialization
* @np: struct device_node * of the DT node for the SoC CAR IP block
*
* Register most SoC clocks for the Tegra210 system-on-chip. Intended
* to be called by the OF init code when a DT node with the
* "nvidia,tegra210-car" string is encountered, and declared with
* CLK_OF_DECLARE. No return value.
*/
static void __init tegra210_clock_init(struct device_node *np)
{
struct device_node *node;
u32 value, clk_m_div;
clk_base = of_iomap(np, 0);
if (!clk_base) {
pr_err("ioremap tegra210 CAR failed\n");
return;
}
node = of_find_matching_node(NULL, pmc_match);
if (!node) {
pr_err("Failed to find pmc node\n");
WARN_ON(1);
return;
}
pmc_base = of_iomap(node, 0);
if (!pmc_base) {
pr_err("Can't map pmc registers\n");
WARN_ON(1);
return;
}
ahub_base = ioremap(TEGRA210_AHUB_BASE, SZ_64K);
if (!ahub_base) {
pr_err("ioremap tegra210 APE failed\n");
return;
}
dispa_base = ioremap(TEGRA210_DISPA_BASE, SZ_256K);
if (!dispa_base) {
pr_err("ioremap tegra210 DISPA failed\n");
return;
}
vic_base = ioremap(TEGRA210_VIC_BASE, SZ_256K);
if (!vic_base) {
pr_err("ioremap tegra210 VIC failed\n");
return;
}
clks = tegra_clk_init(clk_base, TEGRA210_CLK_CLK_MAX,
TEGRA210_CAR_BANK_COUNT);
if (!clks)
return;
value = readl(clk_base + SPARE_REG0) >> CLK_M_DIVISOR_SHIFT;
clk_m_div = (value & CLK_M_DIVISOR_MASK) + 1;
if (tegra_osc_clk_init(clk_base, tegra210_clks, tegra210_input_freq,
ARRAY_SIZE(tegra210_input_freq), clk_m_div,
&osc_freq, &pll_ref_freq) < 0)
return;
tegra_fixed_clk_init(tegra210_clks);
tegra210_pll_init(clk_base, pmc_base);
tegra210_periph_clk_init(np, clk_base, pmc_base);
tegra_audio_clk_init(clk_base, pmc_base, tegra210_clks,
tegra210_audio_plls,
ARRAY_SIZE(tegra210_audio_plls), 24576000);
/* For Tegra210, PLLD is the only source for DSIA & DSIB */
value = readl(clk_base + PLLD_BASE);
value &= ~BIT(25);
writel(value, clk_base + PLLD_BASE);
tegra_clk_apply_init_table = tegra210_clock_apply_init_table;
tegra_super_clk_gen5_init(clk_base, pmc_base, tegra210_clks,
&pll_x_params);
tegra_init_special_resets(2, tegra210_reset_assert,
tegra210_reset_deassert);
tegra_add_of_provider(np, of_clk_src_onecell_get);
tegra_register_devclks(devclks, ARRAY_SIZE(devclks));
tegra210_mbist_clk_init();
tegra_cpu_car_ops = &tegra210_cpu_car_ops;
register_syscore_ops(&tegra_clk_syscore_ops);
}
CLK_OF_DECLARE(tegra210, "nvidia,tegra210-car", tegra210_clock_init);