kernel_samsung_a34x-permissive/drivers/clk/mediatek/clk-mt6768.c
2024-04-28 15:51:13 +02:00

3551 lines
98 KiB
C

/* SPDX-License-Identifier: GPL-2.0 */
/*
* Copyright (c) 2019 MediaTek Inc.
*/
#include <linux/delay.h>
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/slab.h>
#include <linux/mfd/syscon.h>
#include <linux/clk.h>
#include <linux/module.h>
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/of_device.h>
#include <linux/platform_device.h>
#include "clk-mtk.h"
#include "clk-gate.h"
#include "clk-mux.h"
#include "clk-mt6768-pg.h"
#include <dt-bindings/clock/mt6768-clk.h>
#define MT_CCF_BRINGUP 0
#if MT_CCF_BRINGUP
#define MT_MUXPLL_ENABLE 0
#define MT_CG_ENABLE 0
#define MT_MTCMOS_ENABLE 0
#else
#define MT_MUXPLL_ENABLE 1
#define MT_CG_ENABLE 1
#define MT_MTCMOS_ENABLE 1
#endif
#define CHECK_VCORE_FREQ 0
#define LOW_POWER_CLK_PDN 0
/*fmeter div select 4*/
#define _DIV4_ 1
#ifdef CONFIG_ARM64
#define IOMEM(a) ((void __force __iomem *)((a)))
#endif
#define mt_reg_sync_writel(v, a) \
do { \
__raw_writel((v), IOMEM(a)); \
/* insure updates are written */ \
mb(); } \
while (0)
#define clk_readl(addr) __raw_readl(IOMEM(addr))
#define clk_writel(addr, val) \
mt_reg_sync_writel(val, addr)
#define clk_setl(addr, val) \
mt_reg_sync_writel(clk_readl(addr) | (val), addr)
#define clk_clrl(addr, val) \
mt_reg_sync_writel(clk_readl(addr) & ~(val), addr)
#define PLL_EN (0x1 << 0)
#define PLL_PWR_ON (0x1 << 0)
#define PLL_ISO_EN (0x1 << 1)
#define PLL_DIV_RSTB (0x1 << 23)
#define PLL_SDM_PCW_CHG (0x1 << 31)
static bool cg_disable;
static bool mtcmos_disable;
const char *ckgen_array[] = {
"hd_faxi_ck",
"hf_fmem_ck",
"hf_fmm_ck",
"hf_fscp_ck",
"hf_fmfg_ck",
"hf_fatb_ck",
"f_fcamtg_ck",
"f_fcamtg1_ck",
"f_fcamtg2_ck",
"f_fcamtg3_ck",
"f_fuart_ck",
"hf_fspi_ck",
"hf_fmsdc50_0_hclk_ck",
"hf_fmsdc50_0_ck",
"hf_fmsdc30_1_ck",
"hf_faudio_ck",
"hf_faud_intbus_ck",
"hf_faud_1_ck",
"hf_faud_engen1_ck",
"f_fdisp_pwm_ck",
"hf_fsspm_ck",
"hf_fdxcc_ck",
"f_fusb_top_ck",
"hf_fspm_ck",
"hf_fi2c_ck",
"f_fpwm_ck",
"f_fseninf_ck",
"hf_faes_fde_ck",
"f_fpwrap_ulposc_ck",
"f_fcamtm_ck",
"f_fvenc_ck",
"f_cam_ck",
"NA",
"NA",
"NA",
"NA",
"NA",
"NA",
"NA",
"NA",
"NA",
"NA",
"NA",
"NA",
"NA",
"NA",
"NA",
"f_ufs_mp_sap_cfg_ck",
"f_ufs_tick1us_ck",
"hd_faxi_east_ck",
"hd_faxi_west_ck",
"hd_faxi_north_ck",
"hd_faxi_south_ck",
"hg_fmipicfg_tx_ck",
"fmem_ck_bfe_dcm_ch0",
"fmem_ck_aft_dcm_ch0",
"fmem_ck_bfe_dcm_ch1",
"fmem_ck_aft_dcm_ch1",
};
const char *abist_array[] = {
"AD_CSI0_DELAY_TSTCLK",
"AD_CSI1_DELAY_TSTCLK",
"UFS_MP_CLK2FREQ",
"AD_MDBPIPLL_DIV3_CK",
"AD_MDBPIPLL_DIV7_CK",
"AD_MDBRPPLL_DIV6_CK",
"AD_UNIV_624M_CK",
"AD_MAIN_H546_CK",
"AD_MAIN_H364M_CK",
"AD_MAIN_H218P4M_CK",
"AD_MAIN_H156M_CK",
"AD_UNIV_624M_CK",
"AD_UNIV_416M_CK",
"AD_UNIV_249P6M_CK",
"AD_UNIV_178P3M_CK",
"AD_MDPLL_FS26M_CK",
"AD_CSI1A_DPHY_DELAYCAL_CK",
"AD_CSI1B_DPHY_DELAYCAL_CK",
"AD_CSI2A_DPHY_DELAYCAL_CK",
"AD_CSI2B_DPHY_DELAYCAL_CK",
"AD_ARMPLL_L_CK",
"AD_ARMPLL_CK",
"AD_MAINPLL_1092M_CK",
"AD_UNIVPLL_1248M_CK",
"AD_MFGPLL_CK",
"AD_MSDCPLL_416M_CK",
"AD_MMPLL_CK",
"AD_APLL1_196P608M_CK",
"NA",
"AD_APPLLGP_TST_CK",
"AD_USB20_192M_CK",
"NA",
"NA",
"AD_VENCPLL_CK",
"AD_DSI0_MPPLL_TST_CK",
"AD_DSI0_LNTC_DSICLK",
"AD_ULPOSC1_CK",
"AD_ULPOSC2_CK",
"rtc32k_ck_i",
"mcusys_arm_clk_out_all",
"AD_ULPOSC1_SYNC_CK",
"AD_ULPOSC2_SYNC_CK",
"msdc01_in_ck",
"msdc02_in_ck",
"msdc11_in_ck",
"msdc12_in_ck",
"NA",
"NA",
"AD_CCIPLL_CK",
"AD_MPLL_208M_CK",
"AD_WBG_DIG_CK_416M",
"AD_WBG_B_DIG_CK_64M",
"AD_WBG_W_DIG_CK_160M",
"DA_USB20_48M_DIV_CK",
"DA_UNIV_48M_DIV_CK",
"DA_MPLL_104M_DIV_CK",
"DA_MPLL_52M_DIV_CK",
"DA_ARMCPU_MON_CK",
"NA",
"ckmon1_ck",
"ckmon2_ck",
"ckmon3_ck",
"ckmon4_ck",
};
static DEFINE_SPINLOCK(mt6768_clk_lock);
/* Total 12 subsys */
void __iomem *cksys_base;
void __iomem *infracfg_base;
void __iomem *apmixed_base;
void __iomem *audio_base;
void __iomem *cam_base;
void __iomem *img_base;
void __iomem *gce_base;
void __iomem *mfgcfg_base;
void __iomem *mmsys_config_base;
void __iomem *pericfg_base;
void __iomem *mipi_rx_ana_csi0a_base;
void __iomem *mipi_rx_ana_csi0b_base;
void __iomem *mipi_rx_ana_csi1a_base;
void __iomem *mipi_rx_ana_csi1b_base;
void __iomem *mipi_rx_ana_csi2a_base;
void __iomem *mipi_rx_ana_csi2b_base;
void __iomem *venc_gcon_base;
void __iomem *vdec_gcon_base;
/* CKSYS */
/* clk cfg update */
#define CLK_CFG_UPDATE 0x004
#define CLK_CFG_0 0x40
#define CLK_CFG_0_SET 0x44
#define CLK_CFG_0_CLR 0x48
#define CLK_CFG_1 0x50
#define CLK_CFG_1_SET 0x54
#define CLK_CFG_1_CLR 0x58
#define CLK_CFG_2 0x60
#define CLK_CFG_2_SET 0x64
#define CLK_CFG_2_CLR 0x68
#define CLK_CFG_3 0x70
#define CLK_CFG_3_SET 0x74
#define CLK_CFG_3_CLR 0x78
#define CLK_CFG_4 0x80
#define CLK_CFG_4_SET 0x84
#define CLK_CFG_4_CLR 0x88
#define CLK_CFG_5 0x90
#define CLK_CFG_5_SET 0x94
#define CLK_CFG_5_CLR 0x98
#define CLK_CFG_6 0xa0
#define CLK_CFG_6_SET 0xa4
#define CLK_CFG_6_CLR 0xa8
#define CLK_CFG_7 0xb0
#define CLK_CFG_7_SET 0xb4
#define CLK_CFG_7_CLR 0xb8
#define CLK_CFG_8 0xc0
#define CLK_CFG_8_SET 0xc4
#define CLK_CFG_8_CLR 0xc8
#define CLK_CFG_9 0xd0
#define CLK_CFG_9_SET 0xd4
#define CLK_CFG_9_CLR 0xd8
#define CLK_CFG_10 0xe0
#define CLK_CFG_10_SET 0xe4
#define CLK_CFG_10_CLR 0xe8
#define CLK_MISC_CFG_0 (cksys_base + 0x104)
#define CLK_MISC_CFG_1 (cksys_base + 0x108)
#define CLK_DBG_CFG (cksys_base + 0x10C)
#define CLK_SCP_CFG_0 (cksys_base + 0x200)
#define CLK_SCP_CFG_1 (cksys_base + 0x204)
#define CLK26CALI_0 (cksys_base + 0x220)
#define CLK26CALI_1 (cksys_base + 0x224)
/* CG */
#define AP_PLL_CON0 (apmixed_base + 0x00)
#define AP_PLL_CON1 (apmixed_base + 0x04)
#define AP_PLL_CON2 (apmixed_base + 0x08)
#define AP_PLL_CON3 (apmixed_base + 0x0C)
#define AP_PLL_CON4 (apmixed_base + 0x10)
#define AP_PLL_CON5 (apmixed_base + 0x14)
#define CLKSQ_STB_CON0 (apmixed_base + 0x18)
#define PLL_PWR_CON0 (apmixed_base + 0x1C)
#define PLL_PWR_CON1 (apmixed_base + 0x20)
#define PLL_ISO_CON0 (apmixed_base + 0x24)
#define PLL_ISO_CON1 (apmixed_base + 0x28)
#define PLL_STB_CON0 (apmixed_base + 0x2C)
#define DIV_STB_CON0 (apmixed_base + 0x30)
#define PLL_CHG_CON0 (apmixed_base + 0x34)
#define PLL_TEST_CON0 (apmixed_base + 0x38)
#define PLL_TEST_CON1 (apmixed_base + 0x3C)
#define APLL1_TUNER_CON0 (apmixed_base + 0x40)
#define PLLON_CON0 (apmixed_base + 0x44)
#define PLLON_CON1 (apmixed_base + 0x48)
#define ARMPLL_CON0 (apmixed_base + 0x208)
#define ARMPLL_CON1 (apmixed_base + 0x20C)
#define ARMPLL_CON2 (apmixed_base + 0x210)
#define ARMPLL_CON3 (apmixed_base + 0x214)
#define ARMPLL_L_CON0 (apmixed_base + 0x218)
#define ARMPLL_L_CON1 (apmixed_base + 0x21C)
#define ARMPLL_L_CON2 (apmixed_base + 0x220)
#define ARMPLL_L_CON3 (apmixed_base + 0x224)
#define CCIPLL_CON0 (apmixed_base + 0x228)
#define CCIPLL_CON1 (apmixed_base + 0x22C)
#define CCIPLL_CON2 (apmixed_base + 0x230)
#define CCIPLL_CON3 (apmixed_base + 0x234)
#define UNIVPLL_CON0 (apmixed_base + 0x238)
#define UNIVPLL_CON1 (apmixed_base + 0x23C)
#define UNIVPLL_CON2 (apmixed_base + 0x240)
#define UNIVPLL_CON3 (apmixed_base + 0x244)
#define MFGPLL_CON0 (apmixed_base + 0x248)
#define MFGPLL_CON1 (apmixed_base + 0x24C)
#define MFGPLL_CON2 (apmixed_base + 0x250)
#define MFGPLL_CON3 (apmixed_base + 0x254)
#define MAINPLL_CON0 (apmixed_base + 0x258)
#define MAINPLL_CON1 (apmixed_base + 0x25C)
#define MAINPLL_CON2 (apmixed_base + 0x260)
#define MAINPLL_CON3 (apmixed_base + 0x264)
#define APLL1_CON0 (apmixed_base + 0x308)
#define APLL1_CON1 (apmixed_base + 0x30C)
#define APLL1_CON2 (apmixed_base + 0x310)
#define APLL1_CON3 (apmixed_base + 0x314)
#define APLL1_CON4 (apmixed_base + 0x318)
#define MMPLL_CON0 (apmixed_base + 0x31C)
#define MMPLL_CON1 (apmixed_base + 0x320)
#define MMPLL_CON2 (apmixed_base + 0x324)
#define MMPLL_CON3 (apmixed_base + 0x328)
#define MPLL_CON0 (apmixed_base + 0x32C)
#define MPLL_CON1 (apmixed_base + 0x330)
#define MPLL_CON2 (apmixed_base + 0x334)
#define MPLL_CON3 (apmixed_base + 0x338)
#define MSDCPLL_CON0 (apmixed_base + 0x33C)
#define MSDCPLL_CON1 (apmixed_base + 0x340)
#define MSDCPLL_CON2 (apmixed_base + 0x344)
#define MSDCPLL_CON3 (apmixed_base + 0x348)
/* INFRASYS Register */
#define INFRA_GLOBALCON_DCMCTL (infracfg_base + 0x50)
#define INFRA_BUS_DCM_CTRL (infracfg_base + 0x70)
#define PERI_BUS_DCM_CTRL (infracfg_base + 0x74)
#define MODULE_SW_CG_0_SET (infracfg_base + 0x80)
#define MODULE_SW_CG_0_CLR (infracfg_base + 0x84)
#define MODULE_SW_CG_1_SET (infracfg_base + 0x88)
#define MODULE_SW_CG_1_CLR (infracfg_base + 0x8C)
#define MODULE_SW_CG_0_STA (infracfg_base + 0x90)
#define MODULE_SW_CG_1_STA (infracfg_base + 0x94)
#define MODULE_CLK_SEL (infracfg_base + 0x98)
#define MODULE_SW_CG_2_SET (infracfg_base + 0xA4)
#define MODULE_SW_CG_2_CLR (infracfg_base + 0xA8)
#define MODULE_SW_CG_2_STA (infracfg_base + 0xAC)
#define MODULE_SW_CG_3_SET (infracfg_base + 0xC0)
#define MODULE_SW_CG_3_CLR (infracfg_base + 0xC4)
#define MODULE_SW_CG_3_STA (infracfg_base + 0xC8)
#define INFRA_TOPAXI_SI0_CTL (infracfg_base + 0x0200)
#define INFRA_TOPAXI_PROTECTEN (infracfg_base + 0x0220)
#define INFRA_TOPAXI_PROTECTEN_STA1 (infracfg_base + 0x0228)
#define INFRA_TOPAXI_PROTECTEN_1 (infracfg_base + 0x0250)
#define INFRA_TOPAXI_PROTECTEN_STA1_1 (infracfg_base + 0x0258)
#define INFRA_TOPAXI_PROTECTEN_SET (infracfg_base + 0x02A0)
#define INFRA_TOPAXI_PROTECTEN_CLR (infracfg_base + 0x02A4)
#define INFRA_TOPAXI_PROTECTEN_1_SET (infracfg_base + 0x02A8)
#define INFRA_TOPAXI_PROTECTEN_1_CLR (infracfg_base + 0x02AC)
#define INFRA_PLL_ULPOSC_CON0 (infracfg_base + 0x0B00)
#define INFRA_PLL_ULPOSC_CON1 (infracfg_base + 0x0B04)
/* Pericfg Register*/
#define PERIAXI_SI0_CTL (pericfg_base + 0x20C)
/* Audio Register*/
#define AUDIO_TOP_CON0 (audio_base + 0x0000)
#define AUDIO_TOP_CON1 (audio_base + 0x0004)
/* MFGCFG Register*/
#define MFG_CG_CON (mfgcfg_base + 0x000)
#define MFG_CG_SET (mfgcfg_base + 0x004)
#define MFG_CG_CLR (mfgcfg_base + 0x008)
/* MMSYS Register*/
#define MMSYS_CG_CON0 (mmsys_config_base + 0x100)
#define MMSYS_CG_SET0 (mmsys_config_base + 0x104)
#define MMSYS_CG_CLR0 (mmsys_config_base + 0x108)
/* CAMSYS Register */
#define CAMSYS_CG_CON (cam_base + 0x000)
#define CAMSYS_CG_SET (cam_base + 0x004)
#define CAMSYS_CG_CLR (cam_base + 0x008)
/* GCE Register */
#define GCE_CTL_INT0 (gce_base + 0xF0)
/* IMGSYS Register */
#define IMG_CG_CON (img_base + 0x0000)
#define IMG_CG_SET (img_base + 0x0004)
#define IMG_CG_CLR (img_base + 0x0008)
/* MIPI Register */
#define MIPI_RX_WRAPPER80_CSI0A (mipi_rx_ana_csi0a_base + 0x080)
#define MIPI_RX_WRAPPER80_CSI0B (mipi_rx_ana_csi0b_base + 0x080)
#define MIPI_RX_WRAPPER80_CSI1A (mipi_rx_ana_csi1a_base + 0x080)
#define MIPI_RX_WRAPPER80_CSI1B (mipi_rx_ana_csi1b_base + 0x080)
#define MIPI_RX_WRAPPER80_CSI2A (mipi_rx_ana_csi2a_base + 0x080)
#define MIPI_RX_WRAPPER80_CSI2B (mipi_rx_ana_csi2b_base + 0x080)
/* VENC Register*/
#define VENC_CG_CON (venc_gcon_base + 0x0)
#define VENC_CG_SET (venc_gcon_base + 0x4)
#define VENC_CG_CLR (venc_gcon_base + 0x8)
/* VDEC Register*/
#define VDEC_CG_CON (vdec_gcon_base + 0x0)
#define VDEC_CG_SET (vdec_gcon_base + 0x0)
#define VDEC_CG_CLR (vdec_gcon_base + 0x4)
#define VDEC_LARB1_CG_CON (vdec_gcon_base + 0x8)
#define VDEC_LARB1_CG_SET (vdec_gcon_base + 0x8)
#define VDEC_LARB1_CG_CLR (vdec_gcon_base + 0xC)
/* CG default setting */
#if MT_CG_ENABLE
#define INFRA_CG0 0x80000000
#define INFRA_CG1 0x00000004
#define INFRA_CG2 0x983fff00
#define INFRA_CG3 0x86947E16
#define INFRA_CG4 0x2ffc06d9
#define INFRA_CG5 0x00320fe7
#define MM_DISABLE_CG 0x0c840040 /* un-gating in preloader */
#else
#define INFRA_CG0 0x80000000
#define INFRA_CG1 0x00000004
#define INFRA_CG2 0x98ffff7f
#define INFRA_CG3 0x879c7f96 /* DXCC(bit[27,28]) not AO */
#define INFRA_CG4 0x2ffc87dd /* BITS2FPC(bit28) not AO*/
#define INFRA_CG5 0x000387db /* CCIFx(bit[18-21]) not AO*/
#define MM_DISABLE_CG 0xffffffff /* un-gating in preloader */
#endif
#define PERI_CG 0x80000000
#define AUDIO_DISABLE_CG0 0x0f080304
#define AUDIO_DISABLE_CG1 0x000000f0
#define CAMSYS_DISABLE_CG 0x1FC3
#define IMG_DISABLE_CG 0x3D
#define GCE_DISABLE_CG 0x00010000
#define MFG_DISABLE_CG 0x00000001
#define VENC_DISABLE_CG 0x00000111 /* inverse */
#define VDEC_DISABLE_CG 0x00000111 /* inverse */
#define VDEC_LARB1_DISABLE_CG 0x00000001 /* inverse */
#define MIPI_CSI_DISABLE_CG 0x2
enum {
CLK_UNIVPLL = 0,
CLK_CCIPLL = 1,
CLK_ARMPLL_L = 2,
CLK_MPLL = 3,
CLK_MAINPLL = 4,
CLK_ARMPLL = 5,
CLK_NR_PLL_CON0
};
#if CHECK_VCORE_FREQ
/*
* Opp 0 : 0.8v
* Opp 1 : 0.7v
* Opp 2 : 0.7~0.65v
* Opp 3 : 0.65v
*/
static int vf_table[20][4] = {
/* opp0 opp1 opp2 opp3 */
{457000, 320000, 230000, 230000},//mm_sel
{416000, 364000, 273000, 273000},//scp_sel
{26000, 26000, 26000, 26000},//camtg_sel
{26000, 26000, 26000, 26000},//camtg1_sel
{26000, 26000, 26000, 26000},//camtg2_sel
{26000, 26000, 26000, 26000},//camtg3_sel
{109200, 109200, 109200, 109200},//spi_sel
{54600, 54600, 54600, 54600},//audio_sel
{136500, 136500, 136500, 136500},//aud_intbus_sel
{196608, 196608, 196608, 196608},//aud_1_sel
{26000, 26000, 26000, 26000},//aud_engen1_sel
{125000, 125000, 125000, 125000},//disp_pwm_sel
{62400, 62400, 62400, 62400},//usb_top_sel
{208000, 208000, 208000, 208000},//camtm_sel
{457000, 416000, 312000, 312000},//venc_sel
{546000, 320000, 230000, 230000},//cam_sel
};
static const char * const mux_names[] = {
"mm_sel",
"scp_sel",
"camtg_sel",
"camtg1_sel",
"camtg2_sel",
"camtg3_sel",
"spi_sel",
"audio_sel",
"aud_intbus_sel",
"aud_1_sel",
"aud_engen1_sel",
"disp_pwm_sel",
"usb_top_sel",
"camtm_sel",
"venc_sel",
"cam_sel",
};
#endif
#define ARMPLL_HW_CTRL ((0x1 << CLK_ARMPLL) \
| (0x1 << (CLK_ARMPLL + (CLK_NR_PLL_CON0))) \
| (0x1 << (CLK_ARMPLL + 2 * (CLK_NR_PLL_CON0))) \
| (0x1 << (CLK_ARMPLL + 3 * (CLK_NR_PLL_CON0))) \
| (0x1 << (CLK_ARMPLL + 4 * (CLK_NR_PLL_CON0))))
#define ARMPLL_L_HW_CTRL ((0x1 << CLK_ARMPLL_L) \
| (0x1 << (CLK_ARMPLL_L + (CLK_NR_PLL_CON0))) \
| (0x1 << (CLK_ARMPLL_L + 2 * (CLK_NR_PLL_CON0)))\
| (0x1 << (CLK_ARMPLL_L + 3 * (CLK_NR_PLL_CON0)))\
| (0x1 << (CLK_ARMPLL_L + 4 * (CLK_NR_PLL_CON0))))
static const struct mtk_fixed_clk fixed_clks[] = {
FIXED_CLK(CLK_TOP_F_FRTC, "f_frtc_ck", "clk32k", 32768),
FIXED_CLK(CLK_TOP_CLK26M, "clk_26m_ck", "clk26m", 26000000),
FIXED_CLK(CLK_TOP_DMPLL, "dmpll_ck", NULL, 466000000),
};
static const struct mtk_fixed_factor top_divs[] = {
FACTOR(CLK_TOP_SYSPLL, "syspll_ck", "mainpll", 1, 1),
FACTOR(CLK_TOP_SYSPLL_D2, "syspll_d2", "mainpll", 1, 2),
FACTOR(CLK_TOP_SYSPLL1_D2, "syspll1_d2", "syspll_d2", 1, 2),
FACTOR(CLK_TOP_SYSPLL1_D4, "syspll1_d4", "syspll_d2", 1, 4),
FACTOR(CLK_TOP_SYSPLL1_D8, "syspll1_d8", "syspll_d2", 1, 8),
FACTOR(CLK_TOP_SYSPLL1_D16, "syspll1_d16", "syspll_d2", 1, 16),
FACTOR(CLK_TOP_SYSPLL_D3, "syspll_d3", "mainpll", 1, 3),
FACTOR(CLK_TOP_SYSPLL2_D2, "syspll2_d2", "syspll_d3", 1, 2),
FACTOR(CLK_TOP_SYSPLL2_D4, "syspll2_d4", "syspll_d3", 1, 4),
FACTOR(CLK_TOP_SYSPLL2_D8, "syspll2_d8", "syspll_d3", 1, 8),
FACTOR(CLK_TOP_SYSPLL_D5, "syspll_d5", "mainpll", 1, 5),
FACTOR(CLK_TOP_SYSPLL3_D2, "syspll3_d2", "syspll_d5", 1, 2),
FACTOR(CLK_TOP_SYSPLL3_D4, "syspll3_d4", "syspll_d5", 1, 4),
FACTOR(CLK_TOP_SYSPLL_D7, "syspll_d7", "mainpll", 1, 7),
FACTOR(CLK_TOP_SYSPLL4_D2, "syspll4_d2", "syspll_d7", 1, 2),
FACTOR(CLK_TOP_SYSPLL4_D4, "syspll4_d4", "syspll_d7", 1, 4),
FACTOR(CLK_TOP_USB20_192M, "usb20_192m_ck", "univpll", 2, 13),
FACTOR(CLK_TOP_USB20_192M_D4, "usb20_192m_d4", "usb20_192m_ck", 1, 4),
FACTOR(CLK_TOP_USB20_192M_D8, "usb20_192m_d8", "usb20_192m_ck", 1, 8),
FACTOR(CLK_TOP_USB20_192M_D16,
"usb20_192m_d16", "usb20_192m_ck", 1, 16),
FACTOR(CLK_TOP_USB20_192M_D32,
"usb20_192m_d32", "usb20_192m_ck", 1, 32),
FACTOR(CLK_TOP_UNIVPLL, "univpll", "univ2pll", 1, 2),
FACTOR(CLK_TOP_UNIVPLL_D2, "univpll_d2", "univpll", 1, 2),
FACTOR(CLK_TOP_UNIVPLL1_D2, "univpll1_d2", "univpll_d2", 1, 2),
FACTOR(CLK_TOP_UNIVPLL1_D4, "univpll1_d4", "univpll_d2", 1, 4),
FACTOR(CLK_TOP_UNIVPLL_D3, "univpll_d3", "univpll", 1, 3),
FACTOR(CLK_TOP_UNIVPLL2_D2, "univpll2_d2", "univpll_d3", 1, 2),
FACTOR(CLK_TOP_UNIVPLL2_D4, "univpll2_d4", "univpll_d3", 1, 4),
FACTOR(CLK_TOP_UNIVPLL2_D8, "univpll2_d8", "univpll_d3", 1, 8),
FACTOR(CLK_TOP_UNIVPLL2_D32, "univpll2_d32", "univpll_d3", 1, 32),
FACTOR(CLK_TOP_UNIVPLL_D5, "univpll_d5", "univpll", 1, 5),
FACTOR(CLK_TOP_UNIVPLL3_D2, "univpll3_d2", "univpll_d5", 1, 2),
FACTOR(CLK_TOP_UNIVPLL3_D4, "univpll3_d4", "univpll_d5", 1, 4),
FACTOR(CLK_TOP_MMPLL, "mmpll_ck", "mmpll", 1, 1),
FACTOR(CLK_TOP_MMPLL_D2, "mmpll_d2", "mmpll_ck", 1, 2),
FACTOR(CLK_TOP_MPLL, "mpll_ck", "mpll", 1, 1),
FACTOR(CLK_TOP_DA_MPLL_104M_DIV, "mpll_104m_div", "mpll_ck", 1, 2),
FACTOR(CLK_TOP_DA_MPLL_52M_DIV, "mpll_52m_div", "mpll_ck", 1, 4),
FACTOR(CLK_TOP_MFGPLL, "mfgpll_ck", "mfgpll", 1, 1),
FACTOR(CLK_TOP_MSDCPLL, "msdcpll_ck", "msdcpll", 1, 1),
FACTOR(CLK_TOP_MSDCPLL_D2, "msdcpll_d2", "msdcpll_ck", 1, 2),
FACTOR(CLK_TOP_APLL1, "apll1_ck", "apll1", 1, 1),
FACTOR(CLK_TOP_APLL1_D2, "apll1_d2", "apll1_ck", 1, 2),
FACTOR(CLK_TOP_APLL1_D4, "apll1_d4", "apll1_ck", 1, 4),
FACTOR(CLK_TOP_APLL1_D8, "apll1_d8", "apll1_ck", 1, 8),
FACTOR(CLK_TOP_ULPOSC1, "ulposc1_ck", "ulposc1", 1, 1),
FACTOR(CLK_TOP_ULPOSC1_D2, "ulposc1_d2", "ulposc1_ck", 1, 2),
FACTOR(CLK_TOP_ULPOSC1_D4, "ulposc1_d4", "ulposc1_ck", 1, 4),
FACTOR(CLK_TOP_ULPOSC1_D8, "ulposc1_d8", "ulposc1_ck", 1, 8),
FACTOR(CLK_TOP_ULPOSC1_D16, "ulposc1_d16", "ulposc1_ck", 1, 16),
FACTOR(CLK_TOP_ULPOSC1_D32, "ulposc1_d32", "ulposc1_ck", 1, 32),
/* dummy clk define, do not control
*this clock due to it's a ddrphy clock source
*/
/* FACTOR(CLK_TOP_DMPLL, "dmpll_ck", "ulposc1_ck", 1, 32), */
FACTOR(CLK_TOP_F_F26M, "f_f26m_ck", "clk_26m_ck", 1, 1),
FACTOR(CLK_TOP_AXI, "axi_ck", "axi_sel", 1, 1),
FACTOR(CLK_TOP_MM, "mm_ck", "mm_sel", 1, 1),
FACTOR(CLK_TOP_SCP, "scp_ck", "scp_sel", 1, 1),
FACTOR(CLK_TOP_MFG, "mfg_ck", "mfg_sel", 1, 1),
FACTOR(CLK_TOP_F_FUART, "f_fuart_ck", "uart_sel", 1, 1),
FACTOR(CLK_TOP_SPI, "spi_ck", "spi_sel", 1, 1),
FACTOR(CLK_TOP_MSDC50_0_HCLK, "msdc50_0_hclk_ck", "msdc5hclk", 1, 1),
FACTOR(CLK_TOP_MSDC50_0, "msdc50_0_ck", "msdc50_0_sel", 1, 1),
FACTOR(CLK_TOP_MSDC30_1, "msdc30_1_ck", "msdc30_1_sel", 1, 1),
FACTOR(CLK_TOP_AUDIO, "audio_ck", "audio_sel", 1, 1),
FACTOR(CLK_TOP_AUD_1, "aud_1_ck", "aud_1_sel", 1, 1),
FACTOR(CLK_TOP_AUD_ENGEN1, "aud_engen1_ck", "aud_engen1_sel", 1, 1),
FACTOR(CLK_TOP_F_FDISP_PWM, "f_fdisp_pwm_ck", "disp_pwm_sel", 1, 1),
FACTOR(CLK_TOP_SSPM, "sspm_ck", "sspm_sel", 1, 1),
FACTOR(CLK_TOP_DXCC, "dxcc_ck", "dxcc_sel", 1, 1),
FACTOR(CLK_TOP_I2C, "i2c_ck", "i2c_sel", 1, 1),
FACTOR(CLK_TOP_F_FPWM, "f_fpwm_ck", "pwm_sel", 1, 1),
FACTOR(CLK_TOP_F_FSENINF, "f_fseninf_ck", "seninf_sel", 1, 1),
FACTOR(CLK_TOP_AES_FDE, "aes_fde_ck", "aes_fde_sel", 1, 1),
/* MT6768: add for MT6768 */
FACTOR(CLK_TOP_VENC, "venc_ck", "venc_sel", 1, 1),
FACTOR(CLK_TOP_CAM, "cam_ck", "cam_sel", 1, 1),
FACTOR(CLK_TOP_F_BIST2FPC, "f_bist2fpc_ck", "univpll2_d2", 1, 1),
FACTOR(CLK_TOP_CLK13M, "clk13m", "clk_26m_ck", 1, 2),
/* MT6768: remove this temporarily */
/*
* FACTOR(CLK_TOP_ARMPLL_DIVIDER_PLL0, "arm_div_pll0",
* "syspll_d2", 1, 1),
* FACTOR(CLK_TOP_ARMPLL_DIVIDER_PLL1, "arm_div_pll1",
* "syspll_ck", 1, 1),
* FACTOR(CLK_TOP_ARMPLL_DIVIDER_PLL2, "arm_div_pll2",
* "univpll_d2", 1, 1),
* FACTOR(CLK_TOP_DA_USB20_48M_DIV, "usb20_48m_div",
* "usb20_192m_d4", 1, 1),
* FACTOR(CLK_TOP_DA_UNIV_48M_DIV, "univ_48m_div",
* "usb20_192m_d4", 1, 1),
*/
};
static const char * const axi_parents[] = {
"clk26m",
"syspll_d7",
"syspll1_d4",
"syspll3_d2"
};
static const char * const mem_parents[] = {
"clk26m",
"dmpll_ck",
"apll1_ck"
};
static const char * const mm_parents[] = {
"clk26m",
"mmpll_ck",
"syspll1_d2",
"syspll_d5",
"syspll1_d4",
"univpll_d5",
"univpll1_d2",
"mmpll_d2"
};
static const char * const scp_parents[] = {
"clk26m",
"syspll4_d2",
"univpll2_d2",
"syspll1_d2",
"univpll1_d2",
"syspll_d3",
"univpll_d3"
};
static const char * const mfg_parents[] = {
"clk26m",
"mfgpll_ck",
"syspll_d3",
"univpll_d3"
};
static const char * const atb_parents[] = {
"clk26m",
"syspll1_d4",
"syspll1_d2"
};
static const char * const camtg_parents[] = {
"clk26m",
"usb20_192m_d8",
"univpll2_d8",
"usb20_192m_d4",
"univpll2_d32",
"usb20_192m_d16",
"usb20_192m_d32"
};
static const char * const uart_parents[] = {
"clk26m",
"univpll2_d8"
};
static const char * const spi_parents[] = {
"clk26m",
"syspll3_d2",
"syspll4_d2",
"syspll2_d4"
};
static const char * const msdc5hclk_parents[] = {
"clk26m",
"syspll1_d2",
"univpll1_d4",
"syspll2_d2"
};
static const char * const msdc50_0_parents[] = {
"clk26m",
"msdcpll_ck",
"syspll2_d2",
"syspll4_d2",
"univpll1_d2",
"syspll1_d2",
"univpll_d5",
"univpll1_d4"
};
static const char * const msdc30_1_parents[] = {
"clk26m",
"msdcpll_d2",
"univpll2_d2",
"syspll2_d2",
"syspll1_d4",
"univpll1_d4",
"usb20_192m_d4",
"syspll2_d4"
};
static const char * const audio_parents[] = {
"clk26m",
"syspll3_d4",
"syspll4_d4",
"syspll1_d16"
};
static const char * const aud_intbus_parents[] = {
"clk26m",
"syspll1_d4",
"syspll4_d2"
};
static const char * const aud_1_parents[] = {
"clk26m",
"apll1_ck"
};
static const char * const aud_engen1_parents[] = {
"clk26m",
"apll1_d2",
"apll1_d4",
"apll1_d8"
};
static const char * const disp_pwm_parents[] = {
"clk26m",
"univpll2_d4",
"ulposc1_d2",
"ulposc1_d8"
};
static const char * const sspm_parents[] = {
"clk26m",
"syspll1_d2",
"syspll_d3"
};
static const char * const dxcc_parents[] = {
"clk26m",
"syspll1_d2",
"syspll1_d4",
"syspll1_d8"
};
static const char * const usb_top_parents[] = {
"clk26m",
"univpll3_d4"
};
static const char * const spm_parents[] = {
"clk26m",
"syspll1_d8"
};
static const char * const i2c_parents[] = {
"clk26m",
"univpll3_d4",
"univpll3_d2",
"syspll1_d8",
"syspll2_d8"
};
static const char * const pwm_parents[] = {
"clk26m",
"univpll3_d4",
"syspll1_d8"
};
static const char * const seninf_parents[] = {
"clk26m",
"univpll1_d4",
"univpll1_d2",
"univpll2_d2"
};
static const char * const aes_fde_parents[] = {
"clk26m",
"msdcpll_ck",
"univpll_d3",
"univpll2_d2",
"univpll1_d2",
"syspll1_d2"
};
static const char * const ulposc_parents[] = {
"clk26m",
"ulposc1_d4",
"ulposc1_d8",
"ulposc1_d16",
"ulposc1_d32"
};
static const char * const camtm_parents[] = {
"clk26m",
"univpll1_d4",
"univpll1_d2",
"univpll2_d2"
};
/* MT6768: add for MT6768 */
static const char * const venc_parents[] = {
"clk26m",
"mmpll_ck",
"syspll1_d2",
"syspll_d5",
"syspll1_d4",
"syspll_d3",
"univpll_d3",
"univpll1_d2"
};
/* MT6768: add for MT6768 */
static const char * const cam_parents[] = {
"clk26m",
"syspll_d2",
"syspll1_d2",
"syspll_d5",
"mmpll_ck",
"univpll_d5",
"univpll1_d2",
"mmpll_d2"
};
#define INVALID_UPDATE_REG 0xFFFFFFFF
#define INVALID_UPDATE_SHIFT -1
#define INVALID_MUX_GATE -1
static const struct mtk_mux top_muxes[] = {
#if (!MT_MUXPLL_ENABLE)
/* CLK_CFG_0 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_AXI_SEL, "axi_sel", axi_parents,
CLK_CFG_0, CLK_CFG_0_SET, CLK_CFG_0_CLR, 0, 2,
INVALID_MUX_GATE, INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_MEM_SEL, "mem_sel", mem_parents,
CLK_CFG_0, CLK_CFG_0_SET, CLK_CFG_0_CLR, 8, 2,
INVALID_MUX_GATE, INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_MM_SEL, "mm_sel", mm_parents, CLK_CFG_0,
CLK_CFG_0_SET, CLK_CFG_0_CLR, 16, 3, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_SCP_SEL, "scp_sel", scp_parents, CLK_CFG_0,
CLK_CFG_0_SET, CLK_CFG_0_CLR, 24, 3, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
/* CLK_CFG_1 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_MFG_SEL, "mfg_sel", mfg_parents, CLK_CFG_1,
CLK_CFG_1_SET, CLK_CFG_1_CLR, 0, 2, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_ATB_SEL, "atb_sel", atb_parents, CLK_CFG_1,
CLK_CFG_1_SET, CLK_CFG_1_CLR, 8, 2, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAMTG_SEL, "camtg_sel",
camtg_parents, CLK_CFG_1, CLK_CFG_1_SET, CLK_CFG_1_CLR,
16, 3, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAMTG1_SEL, "camtg1_sel",
camtg_parents, CLK_CFG_1, CLK_CFG_1_SET, CLK_CFG_1_CLR,
24, 3, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
/* CLK_CFG_2 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAMTG2_SEL, "camtg2_sel",
camtg_parents, CLK_CFG_2, CLK_CFG_2_SET, CLK_CFG_2_CLR,
0, 3, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAMTG3_SEL, "camtg3_sel",
camtg_parents, CLK_CFG_2, CLK_CFG_2_SET, CLK_CFG_2_CLR,
8, 3, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_UART_SEL, "uart_sel", uart_parents, CLK_CFG_2,
CLK_CFG_2_SET, CLK_CFG_2_CLR, 16, 1, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_SPI_SEL, "spi_sel", spi_parents, CLK_CFG_2,
CLK_CFG_2_SET, CLK_CFG_2_CLR, 24, 2, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
/* CLK_CFG_3 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_MSDC50_0_HCLK_SEL, "msdc5hclk",
msdc5hclk_parents, CLK_CFG_3, CLK_CFG_3_SET, CLK_CFG_3_CLR, 0,
2, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_MSDC50_0_SEL, "msdc50_0_sel",
msdc50_0_parents, CLK_CFG_3, CLK_CFG_3_SET, CLK_CFG_3_CLR,
8, 3, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_MSDC30_1_SEL, "msdc30_1_sel",
msdc30_1_parents, CLK_CFG_3, CLK_CFG_3_SET, CLK_CFG_3_CLR,
16, 3, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_AUDIO_SEL, "audio_sel",
audio_parents, CLK_CFG_3, CLK_CFG_3_SET, CLK_CFG_3_CLR,
24, 2, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
/* CLK_CFG_4 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_AUD_INTBUS_SEL, "aud_intbus_sel",
aud_intbus_parents, CLK_CFG_4, CLK_CFG_4_SET, CLK_CFG_4_CLR,
0, 2, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_AUD_1_SEL, "aud_1_sel",
aud_1_parents, CLK_CFG_4, CLK_CFG_4_SET, CLK_CFG_4_CLR,
8, 1, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_AUD_ENGEN1_SEL, "aud_engen1_sel",
aud_engen1_parents, CLK_CFG_4, CLK_CFG_4_SET, CLK_CFG_4_CLR,
16, 2, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_DISP_PWM_SEL, "disp_pwm_sel",
disp_pwm_parents, CLK_CFG_4, CLK_CFG_4_SET, CLK_CFG_4_CLR,
24, 2, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
/* CLK_CFG_5 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_SSPM_SEL, "sspm_sel", sspm_parents, CLK_CFG_5,
CLK_CFG_5_SET, CLK_CFG_5_CLR, 0, 2, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_DXCC_SEL, "dxcc_sel", dxcc_parents, CLK_CFG_5,
CLK_CFG_5_SET, CLK_CFG_5_CLR, 8, 2, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_USB_TOP_SEL, "usb_top_sel",
usb_top_parents, CLK_CFG_5, CLK_CFG_5_SET, CLK_CFG_5_CLR,
16, 1, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_SPM_SEL, "spm_sel", spm_parents, CLK_CFG_5,
CLK_CFG_5_SET, CLK_CFG_5_CLR, 24, 1, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
/* CLK_CFG_6 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_I2C_SEL, "i2c_sel", i2c_parents, CLK_CFG_6,
CLK_CFG_6_SET, CLK_CFG_6_CLR, 0, 3, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_PWM_SEL, "pwm_sel", pwm_parents, CLK_CFG_6,
CLK_CFG_6_SET, CLK_CFG_6_CLR, 8, 2, INVALID_MUX_GATE,
INVALID_UPDATE_REG, INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_SENINF_SEL, "seninf_sel",
seninf_parents, CLK_CFG_6, CLK_CFG_6_SET, CLK_CFG_6_CLR,
16, 2, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_AES_FDE_SEL, "aes_fde_sel",
aes_fde_parents, CLK_CFG_6, CLK_CFG_6_SET, CLK_CFG_6_CLR,
24, 3, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
/* CLK_CFG_7 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_PWRAP_ULPOSC_SEL, "ulposc_sel",
ulposc_parents, CLK_CFG_7, CLK_CFG_7_SET, CLK_CFG_7_CLR,
0, 3, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAMTM_SEL, "camtm_sel",
camtm_parents, CLK_CFG_7, CLK_CFG_7_SET, CLK_CFG_7_CLR,
8, 2, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
/* MT6768: add for MT6768 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_VENC_SEL, "venc_sel",
venc_parents, CLK_CFG_7, CLK_CFG_7_SET, CLK_CFG_7_CLR,
16, 3, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAM_SEL, "cam_sel",
cam_parents, CLK_CFG_7, CLK_CFG_7_SET, CLK_CFG_7_CLR,
24, 3, INVALID_MUX_GATE, INVALID_UPDATE_REG,
INVALID_UPDATE_SHIFT),
#else
/* CLK_CFG_0 */
MUX_GATE_CLR_SET_UPD_FLAGS(CLK_TOP_AXI_SEL, "axi_sel", axi_parents,
CLK_CFG_0, CLK_CFG_0_SET, CLK_CFG_0_CLR, 0, 2, 7,
CLK_CFG_UPDATE, 0, CLK_IS_CRITICAL),
MUX_GATE_CLR_SET_UPD_FLAGS(CLK_TOP_MEM_SEL, "mem_sel", mem_parents,
CLK_CFG_0, CLK_CFG_0_SET, CLK_CFG_0_CLR, 8, 2, 15,
CLK_CFG_UPDATE, 1, CLK_IS_CRITICAL),
MUX_GATE_CLR_SET_UPD(CLK_TOP_MM_SEL, "mm_sel", mm_parents, CLK_CFG_0,
CLK_CFG_0_SET, CLK_CFG_0_CLR, 16, 3, 23, CLK_CFG_UPDATE, 2),
MUX_GATE_CLR_SET_UPD(CLK_TOP_SCP_SEL, "scp_sel", scp_parents, CLK_CFG_0,
CLK_CFG_0_SET, CLK_CFG_0_CLR, 24, 3, 31, CLK_CFG_UPDATE, 3),
/* CLK_CFG_1 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_MFG_SEL, "mfg_sel", mfg_parents, CLK_CFG_1,
CLK_CFG_1_SET, CLK_CFG_1_CLR, 0, 2, 7, CLK_CFG_UPDATE, 4),
MUX_GATE_CLR_SET_UPD(CLK_TOP_ATB_SEL, "atb_sel", atb_parents, CLK_CFG_1,
CLK_CFG_1_SET, CLK_CFG_1_CLR, 8, 2, 15, CLK_CFG_UPDATE, 5),
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAMTG_SEL, "camtg_sel",
camtg_parents, CLK_CFG_1, CLK_CFG_1_SET, CLK_CFG_1_CLR,
16, 3, 23, CLK_CFG_UPDATE, 6),
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAMTG1_SEL, "camtg1_sel",
camtg_parents, CLK_CFG_1, CLK_CFG_1_SET, CLK_CFG_1_CLR,
24, 3, 31, CLK_CFG_UPDATE, 7),
/* CLK_CFG_2 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAMTG2_SEL, "camtg2_sel",
camtg_parents, CLK_CFG_2, CLK_CFG_2_SET, CLK_CFG_2_CLR,
0, 3, 7, CLK_CFG_UPDATE, 8),
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAMTG3_SEL, "camtg3_sel",
camtg_parents, CLK_CFG_2, CLK_CFG_2_SET, CLK_CFG_2_CLR,
8, 3, 15, CLK_CFG_UPDATE, 9),
MUX_GATE_CLR_SET_UPD(CLK_TOP_UART_SEL, "uart_sel", uart_parents, CLK_CFG_2,
CLK_CFG_2_SET, CLK_CFG_2_CLR, 16, 1, 23, CLK_CFG_UPDATE, 10),
MUX_GATE_CLR_SET_UPD(CLK_TOP_SPI_SEL, "spi_sel", spi_parents, CLK_CFG_2,
CLK_CFG_2_SET, CLK_CFG_2_CLR, 24, 2, 31, CLK_CFG_UPDATE, 11),
/* CLK_CFG_3 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_MSDC50_0_HCLK_SEL, "msdc5hclk",
msdc5hclk_parents, CLK_CFG_3, CLK_CFG_3_SET, CLK_CFG_3_CLR, 0,
2, 7, CLK_CFG_UPDATE, 12),
MUX_GATE_CLR_SET_UPD(CLK_TOP_MSDC50_0_SEL, "msdc50_0_sel",
msdc50_0_parents, CLK_CFG_3, CLK_CFG_3_SET, CLK_CFG_3_CLR,
8, 3, 15, CLK_CFG_UPDATE, 13),
MUX_GATE_CLR_SET_UPD(CLK_TOP_MSDC30_1_SEL, "msdc30_1_sel",
msdc30_1_parents, CLK_CFG_3, CLK_CFG_3_SET, CLK_CFG_3_CLR,
16, 3, 23, CLK_CFG_UPDATE, 14),
MUX_GATE_CLR_SET_UPD(CLK_TOP_AUDIO_SEL, "audio_sel",
audio_parents, CLK_CFG_3, CLK_CFG_3_SET, CLK_CFG_3_CLR,
24, 2, 31, CLK_CFG_UPDATE, 15),
/* CLK_CFG_4 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_AUD_INTBUS_SEL, "aud_intbus_sel",
aud_intbus_parents, CLK_CFG_4, CLK_CFG_4_SET, CLK_CFG_4_CLR,
0, 2, 7, CLK_CFG_UPDATE, 16),
MUX_GATE_CLR_SET_UPD(CLK_TOP_AUD_1_SEL, "aud_1_sel",
aud_1_parents, CLK_CFG_4, CLK_CFG_4_SET, CLK_CFG_4_CLR,
8, 1, 15, CLK_CFG_UPDATE, 17),
MUX_GATE_CLR_SET_UPD(CLK_TOP_AUD_ENGEN1_SEL, "aud_engen1_sel",
aud_engen1_parents, CLK_CFG_4, CLK_CFG_4_SET, CLK_CFG_4_CLR,
16, 2, 23, CLK_CFG_UPDATE, 18),
MUX_GATE_CLR_SET_UPD(CLK_TOP_DISP_PWM_SEL, "disp_pwm_sel",
disp_pwm_parents, CLK_CFG_4, CLK_CFG_4_SET, CLK_CFG_4_CLR,
24, 2, 31, CLK_CFG_UPDATE, 19),
/* CLK_CFG_5 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_SSPM_SEL, "sspm_sel", sspm_parents, CLK_CFG_5,
CLK_CFG_5_SET, CLK_CFG_5_CLR, 0, 2, 7, CLK_CFG_UPDATE, 20),
MUX_GATE_CLR_SET_UPD(CLK_TOP_DXCC_SEL, "dxcc_sel", dxcc_parents, CLK_CFG_5,
CLK_CFG_5_SET, CLK_CFG_5_CLR, 8, 2, 15, CLK_CFG_UPDATE, 21),
MUX_GATE_CLR_SET_UPD(CLK_TOP_USB_TOP_SEL, "usb_top_sel",
usb_top_parents, CLK_CFG_5, CLK_CFG_5_SET, CLK_CFG_5_CLR,
16, 1, 23, CLK_CFG_UPDATE, 22),
MUX_GATE_CLR_SET_UPD(CLK_TOP_SPM_SEL, "spm_sel", spm_parents, CLK_CFG_5,
CLK_CFG_5_SET, CLK_CFG_5_CLR, 24, 1, 31, CLK_CFG_UPDATE, 23),
/* CLK_CFG_6 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_I2C_SEL, "i2c_sel", i2c_parents, CLK_CFG_6,
CLK_CFG_6_SET, CLK_CFG_6_CLR, 0, 3, 7, CLK_CFG_UPDATE, 24),
MUX_GATE_CLR_SET_UPD(CLK_TOP_PWM_SEL, "pwm_sel", pwm_parents, CLK_CFG_6,
CLK_CFG_6_SET, CLK_CFG_6_CLR, 8, 2, 15, CLK_CFG_UPDATE, 25),
MUX_GATE_CLR_SET_UPD(CLK_TOP_SENINF_SEL, "seninf_sel",
seninf_parents, CLK_CFG_6, CLK_CFG_6_SET, CLK_CFG_6_CLR,
16, 2, 23, CLK_CFG_UPDATE, 26),
MUX_GATE_CLR_SET_UPD(CLK_TOP_AES_FDE_SEL, "aes_fde_sel",
aes_fde_parents, CLK_CFG_6, CLK_CFG_6_SET, CLK_CFG_6_CLR,
24, 3, 31, CLK_CFG_UPDATE, 27),
/* CLK_CFG_7 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_PWRAP_ULPOSC_SEL, "ulposc_sel",
ulposc_parents, CLK_CFG_7, CLK_CFG_7_SET, CLK_CFG_7_CLR,
0, 3, 7, CLK_CFG_UPDATE, 28),
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAMTM_SEL, "camtm_sel",
camtm_parents, CLK_CFG_7, CLK_CFG_7_SET, CLK_CFG_7_CLR,
8, 2, 15, CLK_CFG_UPDATE, 29),
/* MT6768: add for MT6768 */
MUX_GATE_CLR_SET_UPD(CLK_TOP_VENC_SEL, "venc_sel",
venc_parents, CLK_CFG_7, CLK_CFG_7_SET, CLK_CFG_7_CLR,
16, 3, 23, CLK_CFG_UPDATE, 30),
MUX_GATE_CLR_SET_UPD(CLK_TOP_CAM_SEL, "cam_sel",
cam_parents, CLK_CFG_7, CLK_CFG_7_SET, CLK_CFG_7_CLR,
24, 3, 31, CLK_CFG_UPDATE, 31),
#endif
};
int __attribute__((weak)) get_sw_req_vcore_opp(void)
{
return -1;
}
/* for debug dummy functions. */
/*
static int mtk_cg_bit_is_cleared(struct clk_hw *hw)
{
struct mtk_clk_gate *cg = to_mtk_clk_gate(hw);
u32 val;
if (mtk_is_cg_enable()) {
regmap_read(cg->regmap, cg->sta_ofs, &val);
val &= BIT(cg->bit);
return val == 0;
}
return 1;
}
static int mtk_cg_bit_is_set(struct clk_hw *hw)
{
struct mtk_clk_gate *cg = to_mtk_clk_gate(hw);
u32 val;
if (mtk_is_cg_enable()) {
regmap_read(cg->regmap, cg->sta_ofs, &val);
val &= BIT(cg->bit);
return val != 0;
}
return 0;
}
static void mtk_cg_set_bit(struct clk_hw *hw)
{
struct mtk_clk_gate *cg = to_mtk_clk_gate(hw);
if (mtk_is_cg_enable())
regmap_write(cg->regmap, cg->set_ofs, BIT(cg->bit));
}
static void mtk_cg_clr_bit(struct clk_hw *hw)
{
struct mtk_clk_gate *cg = to_mtk_clk_gate(hw);
if (mtk_is_cg_enable())
regmap_write(cg->regmap, cg->clr_ofs, BIT(cg->bit));
}
static void mtk_cg_set_bit_no_setclr(struct clk_hw *hw)
{
struct mtk_clk_gate *cg = to_mtk_clk_gate(hw);
u32 cgbit = BIT(cg->bit);
if (mtk_is_cg_enable())
regmap_update_bits(cg->regmap, cg->sta_ofs, cgbit, cgbit);
}
static void mtk_cg_clr_bit_no_setclr(struct clk_hw *hw)
{
struct mtk_clk_gate *cg = to_mtk_clk_gate(hw);
u32 cgbit = BIT(cg->bit);
if (mtk_is_cg_enable())
regmap_update_bits(cg->regmap, cg->sta_ofs, cgbit, 0);
}
static int mtk_cg_enable(struct clk_hw *hw)
{
mtk_cg_clr_bit(hw);
return 0;
}
static int mtk_cg_enable_inv(struct clk_hw *hw)
{
mtk_cg_set_bit(hw);
return 0;
}
static int mtk_cg_enable_no_setclr(struct clk_hw *hw)
{
mtk_cg_clr_bit_no_setclr(hw);
return 0;
}
static int mtk_cg_enable_inv_no_setclr(struct clk_hw *hw)
{
mtk_cg_set_bit_no_setclr(hw);
return 0;
}
disable dummy functions
static void mtk_cg_disable_dummy(struct clk_hw *hw)
{
}
const struct clk_ops mtk_clk_gate_ops_setclr_dummy = {
.is_enabled = mtk_cg_bit_is_cleared,
.enable = mtk_cg_enable,
.disable = mtk_cg_disable_dummy,
};
static void mtk_cg_disable_inv_dummy(struct clk_hw *hw)
{
}
const struct clk_ops mtk_clk_gate_ops_setclr_inv_dummy = {
.is_enabled = mtk_cg_bit_is_set,
.enable = mtk_cg_enable_inv,
.disable = mtk_cg_disable_inv_dummy,
};
static void mtk_cg_disable_no_setclr_dummy(struct clk_hw *hw)
{
}
const struct clk_ops mtk_clk_gate_ops_no_setclr_dummy = {
.is_enabled = mtk_cg_bit_is_cleared,
.enable = mtk_cg_enable_no_setclr,
.disable = mtk_cg_disable_no_setclr_dummy,
};
static void mtk_cg_disable_inv_no_setclr_dummy(struct clk_hw *hw)
{
}
const struct clk_ops mtk_clk_gate_ops_no_setclr_inv_dummy = {
.is_enabled = mtk_cg_bit_is_set,
.enable = mtk_cg_enable_inv_no_setclr,
.disable = mtk_cg_disable_inv_no_setclr_dummy,
};*/
/* for dummy */
static const struct mtk_gate_regs top0_cg_regs = {
.set_ofs = 0x0,
.clr_ofs = 0x0,
.sta_ofs = 0x0,
};
static const struct mtk_gate_regs top1_cg_regs = {
.set_ofs = 0x104,
.clr_ofs = 0x104,
.sta_ofs = 0x104,
};
#define GATE_TOP0(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &top0_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr, \
}
#define GATE_TOP0_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &top0_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_dummy, \
}
#define GATE_TOP1(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &top1_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv, \
}
#define GATE_TOP1_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &top1_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv_dummy, \
}
static const struct mtk_gate top_clks[] = {
/* TOP0 */
GATE_TOP0(CLK_TOP_MD_32K, "md_32k", "f_frtc_ck", 8),
GATE_TOP0(CLK_TOP_MD_26M, "md_26m", "f_f26m_ck", 9),
GATE_TOP0(CLK_TOP_MD2_32K, "md2_32k", "f_frtc_ck", 10),
GATE_TOP0(CLK_TOP_MD2_26M, "md2_26m", "f_f26m_ck", 11),
/* TOP1 */
GATE_TOP1(CLK_TOP_ARMPLL_DIVIDER_PLL0_EN,
"arm_div_pll0_en", "arm_div_pll0", 3),
GATE_TOP1(CLK_TOP_ARMPLL_DIVIDER_PLL1_EN,
"arm_div_pll1_en", "arm_div_pll1", 4),
GATE_TOP1(CLK_TOP_ARMPLL_DIVIDER_PLL2_EN,
"arm_div_pll2_en", "arm_div_pll2", 5),
GATE_TOP1(CLK_TOP_FMEM_OCC_DRC_EN, "drc_en", "univpll2_d2", 6),
GATE_TOP1(CLK_TOP_USB20_48M_EN, "usb20_48m_en", "usb20_48m_div", 8),
GATE_TOP1(CLK_TOP_UNIVPLL_48M_EN, "univpll_48m_en", "univ_48m_div", 9),
GATE_TOP1(CLK_TOP_MPLL_104M_EN, "mpll_104m_en", "mpll_104m_div", 10),
GATE_TOP1(CLK_TOP_MPLL_52M_EN, "mpll_52m_en", "mpll_52m_div", 11),
GATE_TOP1(CLK_TOP_F_UFS_MP_SAP_CFG_EN, "ufs_sap", "f_f26m_ck", 12),
GATE_TOP1(CLK_TOP_F_BIST2FPC_EN, "bist2fpc", "f_bist2fpc_ck", 16),
};
static const struct mtk_gate_regs ifr0_cg_regs = {
.set_ofs = 0x200,
.clr_ofs = 0x200,
.sta_ofs = 0x200,
};
static const struct mtk_gate_regs ifr1_cg_regs = {
.set_ofs = 0x74,
.clr_ofs = 0x74,
.sta_ofs = 0x74,
};
static const struct mtk_gate_regs ifr2_cg_regs = {
.set_ofs = 0x80,
.clr_ofs = 0x84,
.sta_ofs = 0x90,
};
static const struct mtk_gate_regs ifr3_cg_regs = {
.set_ofs = 0x88,
.clr_ofs = 0x8c,
.sta_ofs = 0x94,
};
static const struct mtk_gate_regs ifr4_cg_regs = {
.set_ofs = 0xa4,
.clr_ofs = 0xa8,
.sta_ofs = 0xac,
};
static const struct mtk_gate_regs ifr5_cg_regs = {
.set_ofs = 0xc0,
.clr_ofs = 0xc4,
.sta_ofs = 0xc8,
};
#define GATE_IFR0(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr0_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv, \
}
#define GATE_IFR0_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr0_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv_dummy, \
}
#define GATE_IFR1(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr1_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr, \
}
#define GATE_IFR1_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr1_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_dummy, \
}
#define GATE_IFR2(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr2_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr, \
}
#define GATE_IFR2_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr2_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_dummy, \
}
#define GATE_IFR3(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr3_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr, \
}
#define GATE_IFR3_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr3_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_dummy, \
}
#define GATE_IFR4(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr4_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr, \
}
#define GATE_IFR4_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr4_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_dummy, \
}
#define GATE_IFR5(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr5_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr, \
}
#define GATE_IFR5_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &ifr5_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_dummy, \
}
static const struct mtk_gate ifr_clks[] = {
/* INFRA_TOPAXI */
GATE_IFR0(CLK_IFR_TOPAXI_DISABLE, "ifr_axi_dis", "axi_ck", 31),
/* INFRA PERI */
GATE_IFR1(CLK_IFR_PERI_DCM_RG_FORCE_CLKOFF,
"ifr_dcmforce", "axi_ck", 2),
/* INFRA mode 0 */
GATE_IFR2(CLK_IFR_PMIC_TMR, "ifr_pmic_tmr", "f_f26m_ck", 0),
GATE_IFR2(CLK_IFR_PMIC_AP, "ifr_pmic_ap", "f_f26m_ck", 1),
GATE_IFR2(CLK_IFR_PMIC_MD, "ifr_pmic_md", "f_f26m_ck", 2),
GATE_IFR2(CLK_IFR_PMIC_CONN, "ifr_pmic_conn", "f_f26m_ck", 3),
GATE_IFR2(CLK_IFR_SCP_CORE, "ifr_scp_core", "scp_ck", 4),
GATE_IFR2(CLK_IFR_SEJ, "ifr_sej", "axi_ck", 5),
GATE_IFR2(CLK_IFR_APXGPT, "ifr_apxgpt", "axi_ck", 6),
GATE_IFR2(CLK_IFR_ICUSB, "ifr_icusb", "axi_ck", 8),
GATE_IFR2(CLK_IFR_GCE, "ifr_gce", "axi_ck", 9),
GATE_IFR2(CLK_IFR_THERM, "ifr_therm", "axi_ck", 10),
GATE_IFR2(CLK_IFR_I2C_AP, "ifr_i2c_ap", "i2c_ck", 11),
GATE_IFR2(CLK_IFR_I2C_CCU, "ifr_i2c_ccu", "i2c_ck", 12),
GATE_IFR2(CLK_IFR_I2C_SSPM, "ifr_i2c_sspm", "i2c_ck", 13),
GATE_IFR2(CLK_IFR_I2C_RSV, "ifr_i2c_rsv", "i2c_ck", 14),
GATE_IFR2(CLK_IFR_PWM_HCLK, "ifr_pwm_hclk", "axi_ck", 15),
GATE_IFR2(CLK_IFR_PWM1, "ifr_pwm1", "f_fpwm_ck", 16),
GATE_IFR2(CLK_IFR_PWM2, "ifr_pwm2", "f_fpwm_ck", 17),
GATE_IFR2(CLK_IFR_PWM3, "ifr_pwm3", "f_fpwm_ck", 18),
GATE_IFR2(CLK_IFR_PWM4, "ifr_pwm4", "f_fpwm_ck", 19),
GATE_IFR2(CLK_IFR_PWM5, "ifr_pwm5", "f_fpwm_ck", 20),
GATE_IFR2(CLK_IFR_PWM, "ifr_pwm", "f_fpwm_ck", 21),
GATE_IFR2(CLK_IFR_UART0, "ifr_uart0", "f_fuart_ck", 22),
GATE_IFR2(CLK_IFR_UART1, "ifr_uart1", "f_fuart_ck", 23),
GATE_IFR2(CLK_IFR_GCE_26M, "ifr_gce_26m", "f_f26m_ck", 27),
GATE_IFR2(CLK_IFR_CQ_DMA_FPC, "ifr_dma", "axi_ck", 28),
GATE_IFR2(CLK_IFR_BTIF, "ifr_btif", "axi_ck", 31),
/* INFRA mode 1 */
GATE_IFR3(CLK_IFR_SPI0, "ifr_spi0", "spi_ck", 1),
GATE_IFR3(CLK_IFR_MSDC0, "ifr_msdc0", "msdc50_0_hclk_ck", 2),
GATE_IFR3(CLK_IFR_MSDC1, "ifr_msdc1", "axi_ck", 4),
GATE_IFR3(CLK_IFR_DVFSRC, "ifr_dvfsrc", "f_f26m_ck", 7),
GATE_IFR3(CLK_IFR_GCPU, "ifr_gcpu", "axi_ck", 8),
GATE_IFR3(CLK_IFR_TRNG, "ifr_trng", "axi_ck", 9),
GATE_IFR3(CLK_IFR_AUXADC, "ifr_auxadc", "f_f26m_ck", 10),
GATE_IFR3(CLK_IFR_CPUM, "ifr_cpum", "axi_ck", 11),
GATE_IFR3(CLK_IFR_CCIF1_AP, "ifr_ccif1_ap", "axi_ck", 12),
GATE_IFR3(CLK_IFR_CCIF1_MD, "ifr_ccif1_md", "axi_ck", 13),
GATE_IFR3(CLK_IFR_AUXADC_MD, "ifr_auxadc_md", "f_f26m_ck", 14),
GATE_IFR3(CLK_IFR_AP_DMA, "ifr_ap_dma", "axi_ck", 18),
GATE_IFR3(CLK_IFR_XIU, "ifr_xiu", "axi_ck", 19),
GATE_IFR3(CLK_IFR_DEVICE_APC, "ifr_dapc", "axi_ck", 20),
GATE_IFR3(CLK_IFR_CCIF_AP, "ifr_ccif_ap", "axi_ck", 23),
GATE_IFR3(CLK_IFR_DEBUGTOP, "ifr_debugtop", "axi_ck", 24),
GATE_IFR3(CLK_IFR_AUDIO, "ifr_audio", "axi_ck", 25),
GATE_IFR3(CLK_IFR_CCIF_MD, "ifr_ccif_md", "axi_ck", 26),
GATE_IFR3(CLK_IFR_DXCC_SEC_CORE, "ifr_secore", "dxcc_ck", 27),
GATE_IFR3(CLK_IFR_DXCC_AO, "ifr_dxcc_ao", "dxcc_ck", 28),
GATE_IFR3(CLK_IFR_DRAMC_F26M, "ifr_dramc26", "f_f26m_ck", 31),
/* INFRA mode 2 */
GATE_IFR4(CLK_IFR_RG_PWM_FBCLK6, "ifr_pwmfb", "f_f26m_ck", 0),
GATE_IFR4(CLK_IFR_DISP_PWM, "ifr_disp_pwm", "f_fdisp_pwm_ck", 2),
GATE_IFR4(CLK_IFR_CLDMA_BCLK, "ifr_cldmabclk", "axi_ck", 3),
GATE_IFR4(CLK_IFR_AUDIO_26M_BCLK, "ifr_audio26m", "f_f26m_ck", 4),
GATE_IFR4(CLK_IFR_SPI1, "ifr_spi1", "spi_ck", 6),
GATE_IFR4(CLK_IFR_I2C4, "ifr_i2c4", "i2c_ck", 7),
GATE_IFR4(CLK_IFR_MODEM_TEMP_SHARE, "ifr_mdtemp", "f_f26m_ck", 8),
GATE_IFR4(CLK_IFR_SPI2, "ifr_spi2", "spi_ck", 9),
GATE_IFR4(CLK_IFR_SPI3, "ifr_spi3", "spi_ck", 10),
GATE_IFR4(CLK_IFR_SSPM, "ifr_hf_fsspm", "sspm_ck", 15),
GATE_IFR4(CLK_IFR_I2C5, "ifr_i2c5", "i2c_ck", 18),
GATE_IFR4(CLK_IFR_I2C5_ARBITER, "ifr_i2c5a", "i2c_ck", 19),
GATE_IFR4(CLK_IFR_I2C5_IMM, "ifr_i2c5_imm", "i2c_ck", 20),
GATE_IFR4(CLK_IFR_I2C1_ARBITER, "ifr_i2c1a", "i2c_ck", 21),
GATE_IFR4(CLK_IFR_I2C1_IMM, "ifr_i2c1_imm", "i2c_ck", 22),
GATE_IFR4(CLK_IFR_I2C2_ARBITER, "ifr_i2c2a", "i2c_ck", 23),
GATE_IFR4(CLK_IFR_I2C2_IMM, "ifr_i2c2_imm", "i2c_ck", 24),
GATE_IFR4(CLK_IFR_SPI4, "ifr_spi4", "spi_ck", 25),
GATE_IFR4(CLK_IFR_SPI5, "ifr_spi5", "spi_ck", 26),
GATE_IFR4(CLK_IFR_CQ_DMA, "ifr_cq_dma", "axi_ck", 27),
GATE_IFR4(CLK_IFR_FAES_FDE, "ifr_faes_fde_ck", "aes_fde_ck", 29),
/* INFRA mode 3 */
GATE_IFR5(CLK_IFR_MSDC0_SELF, "ifr_msdc0sf", "msdc50_0_ck", 0),
GATE_IFR5(CLK_IFR_MSDC1_SELF, "ifr_msdc1sf", "msdc50_0_ck", 1),
GATE_IFR5(CLK_IFR_SSPM_26M_SELF, "ifr_sspm_26m", "f_f26m_ck", 3),
GATE_IFR5(CLK_IFR_SSPM_32K_SELF, "ifr_sspm_32k", "f_frtc_ck", 4),
GATE_IFR5(CLK_IFR_I2C6, "ifr_i2c6", "i2c_ck", 6),
GATE_IFR5(CLK_IFR_AP_MSDC0, "ifr_ap_msdc0", "msdc50_0_ck", 7),
GATE_IFR5(CLK_IFR_MD_MSDC0, "ifr_md_msdc0", "msdc50_0_ck", 8),
GATE_IFR5(CLK_IFR_MSDC0_SRC, "ifr_msdc0_clk", "msdc50_0_ck", 9),
GATE_IFR5(CLK_IFR_MSDC1_SRC, "ifr_msdc1_clk", "msdc30_1_ck", 10),
GATE_IFR5(CLK_IFR_SEJ_F13M, "ifr_sej_f13m", "f_f26m_ck", 15),
GATE_IFR5(CLK_IFR_AES_TOP0_BCLK, "ifr_aes", "axi_ck", 16),
GATE_IFR5(CLK_IFR_MCU_PM_BCLK, "ifr_mcu_pm_bclk", "axi_ck", 17),
GATE_IFR5(CLK_IFR_CCIF2_AP, "ifr_ccif2_ap", "axi_ck", 18),
GATE_IFR5(CLK_IFR_CCIF2_MD, "ifr_ccif2_md", "axi_ck", 19),
GATE_IFR5(CLK_IFR_CCIF3_AP, "ifr_ccif3_ap", "axi_ck", 20),
GATE_IFR5(CLK_IFR_CCIF3_MD, "ifr_ccif3_md", "axi_ck", 21),
};
static const struct mtk_gate_regs peri_cg_regs = {
.set_ofs = 0x20C,
.clr_ofs = 0x20C,
.sta_ofs = 0x20C,
};
#define GATE_PERI(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &peri_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv, \
}
#define GATE_PERI_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &peri_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv_dummy, \
}
static const struct mtk_gate peri_clks[] = {
/* PERICFG */
GATE_PERI(CLK_PERIAXI_DISABLE, "periaxi_disable", "axi_ck", 31),
};
static const struct mtk_gate_regs venc_cg_regs = {
.set_ofs = 0x4,
.clr_ofs = 0x8,
.sta_ofs = 0x0,
};
#define GATE_VENC(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &venc_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_inv, \
}
#define GATE_VENC_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &venc_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_inv_dummy, \
}
/* MT6768: change mm_ck to venc_ck */
static const struct mtk_gate venc_clks[] = {
GATE_VENC(CLK_VENC_SET0_LARB, "venc_set0_larb", "venc_ck", 0),
GATE_VENC(CLK_VENC_SET1_VENC, "venc_set1_venc", "venc_ck", 4),
GATE_VENC(CLK_VENC_SET2_JPGENC, "jpgenc", "venc_ck", 8),
/* MT6768: no SET3 CG in MT6768 */
/* GATE_VENC(CLK_VENC_SET3_VDEC, "venc_set3_vdec", "venc_ck", 12), */
};
static const struct mtk_gate_regs vdec1_cg_regs = {
.set_ofs = 0x0,
.clr_ofs = 0x4,
.sta_ofs = 0x0,
};
static const struct mtk_gate_regs vdec2_cg_regs = {
.set_ofs = 0x8,
.clr_ofs = 0xC,
.sta_ofs = 0x8,
};
#define GATE_VDEC1(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &vdec1_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_inv, \
}
#define GATE_VDEC1_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &vdec1_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_inv_dummy, \
}
#define GATE_VDEC2(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &vdec2_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_inv, \
}
#define GATE_VDEC2_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &vdec2_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_inv_dummy, \
}
static const struct mtk_gate vdec_clks[] = {
GATE_VDEC1(CLK_VDEC_CKEN, "vdec_cken", "mm_ck", 0),
GATE_VDEC1(CLK_VDEC_ACTIVE, "vdec_active", "mm_ck", 4),
GATE_VDEC1(CLK_VDEC_CKEN_ENG, "vdec_cken_eng", "mm_ck", 8),
GATE_VDEC2(CLK_VDEC_LARB1_CKEN, "vdec_larb1_cken", "mm_ck", 0),
};
static const struct mtk_gate_regs cam_cg_regs = {
.set_ofs = 0x4,
.clr_ofs = 0x8,
.sta_ofs = 0x0,
};
#define GATE_CAM(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &cam_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr, \
}
#define GATE_CAM_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &cam_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_dummy, \
}
/* MT6768: change mm_ck to cam_ck */
static const struct mtk_gate cam_clks[] = {
GATE_CAM(CLK_CAM_LARB3, "cam_larb3", "cam_ck", 0),/*use dummy*/
GATE_CAM(CLK_CAM_DFP_VAD, "cam_dfp_vad", "cam_ck", 1),
GATE_CAM(CLK_CAM, "cam", "cam_ck", 6),
GATE_CAM(CLK_CAMTG, "camtg", "cam_ck", 7),
GATE_CAM(CLK_CAM_SENINF, "cam_seninf", "cam_ck", 8),
GATE_CAM(CLK_CAMSV0, "camsv0", "cam_ck", 9),
GATE_CAM(CLK_CAMSV1, "camsv1", "cam_ck", 10),
GATE_CAM(CLK_CAMSV2, "camsv2", "cam_ck", 11),
GATE_CAM(CLK_CAM_CCU, "cam_ccu", "cam_ck", 12),
};
static const struct mtk_gate_regs img_cg_regs = {
.set_ofs = 0x4,
.clr_ofs = 0x8,
.sta_ofs = 0x0,
};
#define GATE_IMG(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &img_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr, \
}
#define GATE_IMG_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &img_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_dummy, \
}
static const struct mtk_gate img_clks[] = {
GATE_IMG(CLK_IMG_LARB2, "img_larb2", "mm_ck", 0),/*use dummy*/
GATE_IMG(CLK_IMG_DIP, "img_dip", "mm_ck", 2),
GATE_IMG(CLK_IMG_FDVT, "img_fdvt", "mm_ck", 3),
GATE_IMG(CLK_IMG_DPE, "img_dpe", "mm_ck", 4),
GATE_IMG(CLK_IMG_RSC, "img_rsc", "mm_ck", 5),
};
static const struct mtk_gate_regs audio0_cg_regs = {
.set_ofs = 0x0,
.clr_ofs = 0x0,
.sta_ofs = 0x0,
};
static const struct mtk_gate_regs audio1_cg_regs = {
.set_ofs = 0x4,
.clr_ofs = 0x4,
.sta_ofs = 0x4,
};
#define GATE_AUDIO0(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &audio0_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr, \
}
#define GATE_AUDIO0_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &audio0_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_dummy, \
}
#define GATE_AUDIO1(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &audio1_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr, \
}
#define GATE_AUDIO1_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &audio1_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_dummy, \
}
static const struct mtk_gate audio_clks[] = {
/* AUDIO0 */
GATE_AUDIO0(CLK_AUDIO_AFE, "aud_afe", "audio_ck",
2),
GATE_AUDIO0(CLK_AUDIO_22M, "aud_22m", "aud_engen1_ck",
8),
GATE_AUDIO0(CLK_AUDIO_24M, "aud_24m", "aud_engen1_ck",
9),
GATE_AUDIO0(CLK_AUDIO_APLL_TUNER, "aud_apll_tuner", "aud_engen1_ck",
19),
GATE_AUDIO0(CLK_AUDIO_ADC, "aud_adc", "audio_ck",
24),
GATE_AUDIO0(CLK_AUDIO_DAC, "aud_dac", "audio_ck",
25),
GATE_AUDIO0(CLK_AUDIO_DAC_PREDIS, "aud_dac_predis", "audio_ck",
26),
GATE_AUDIO0(CLK_AUDIO_TML, "aud_tml", "audio_ck",
27),
/* AUDIO1 */
GATE_AUDIO1(CLK_AUDIO_I2S1_BCLK, "aud_i2s1_bclk", "audio_ck",
4),
GATE_AUDIO1(CLK_AUDIO_I2S2_BCLK, "aud_i2s2_bclk", "audio_ck",
5),
GATE_AUDIO1(CLK_AUDIO_I2S3_BCLK, "aud_i2s3_bclk", "audio_ck",
6),
GATE_AUDIO1(CLK_AUDIO_I2S4_BCLK, "aud_i2s4_bclk", "audio_ck",
7),
};
static const struct mtk_gate_regs mm_cg_regs = {
.set_ofs = 0x104,
.clr_ofs = 0x108,
.sta_ofs = 0x100,
};
#define GATE_MM(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mm_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr, \
}
#define GATE_MM_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mm_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_dummy, \
}
static const struct mtk_gate mm_clks[] = {
/* MM */
GATE_MM(CLK_MM_MDP_RDMA0, "mm_mdp_rdma0", "mm_ck", 0),
GATE_MM(CLK_MM_MDP_CCORR0, "mm_mdp_ccorr0", "mm_ck", 1),
GATE_MM(CLK_MM_MDP_RSZ0, "mm_mdp_rsz0", "mm_ck", 2),
GATE_MM(CLK_MM_MDP_RSZ1, "mm_mdp_rsz1", "mm_ck", 3),
GATE_MM(CLK_MM_MDP_TDSHP0, "mm_mdp_tdshp0", "mm_ck", 4),
GATE_MM(CLK_MM_MDP_WROT0, "mm_mdp_wrot0", "mm_ck", 5),
GATE_MM(CLK_MM_MDP_WDMA0, "mm_mdp_wdma0", "mm_ck", 6),
GATE_MM(CLK_MM_DISP_OVL0, "mm_disp_ovl0", "mm_ck", 7),
GATE_MM(CLK_MM_DISP_OVL0_2L, "mm_disp_ovl0_2l", "mm_ck", 8),
GATE_MM(CLK_MM_DISP_RSZ0, "mm_disp_rsz0", "mm_ck", 9),
GATE_MM(CLK_MM_DISP_RDMA0, "mm_disp_rdma0", "mm_ck", 10),
GATE_MM(CLK_MM_DISP_WDMA0, "mm_disp_wdma0", "mm_ck", 11),
GATE_MM(CLK_MM_DISP_COLOR0, "mm_disp_color0", "mm_ck", 12),
GATE_MM(CLK_MM_DISP_CCORR0, "mm_disp_ccorr0", "mm_ck", 13),
GATE_MM(CLK_MM_DISP_AAL0, "mm_disp_aal0", "mm_ck", 14),
GATE_MM(CLK_MM_DISP_GAMMA0, "mm_disp_gamma0", "mm_ck", 15),
GATE_MM(CLK_MM_DISP_DITHER0, "mm_disp_dither0", "mm_ck", 16),
GATE_MM(CLK_MM_DSI0, "mm_dsi0", "mm_ck", 17),
GATE_MM(CLK_MM_FAKE_ENG, "mm_fake_eng", "mm_ck", 18),
GATE_MM(CLK_MM_SMI_COMMON, "mm_smi_common", "mm_ck", 19),
GATE_MM(CLK_MM_SMI_LARB0, "mm_smi_larb0", "mm_ck", 20),
GATE_MM(CLK_MM_SMI_COMM0, "mm_smi_comm0", "mm_ck", 21),
GATE_MM(CLK_MM_SMI_COMM1, "mm_smi_comm1", "mm_ck", 22),
GATE_MM(CLK_MM_CAM_MDP, "mm_cam_mdp_ck", "mm_ck", 23),
GATE_MM(CLK_MM_SMI_IMG, "mm_smi_img_ck", "mm_ck", 24),
GATE_MM(CLK_MM_SMI_CAM, "mm_smi_cam_ck", "mm_ck", 25),
/* MT6768: add for MT6768 */
GATE_MM(CLK_MM_SMI_VENC, "mm_smi_venc_ck", "mm_ck", 26),
GATE_MM(CLK_MM_SMI_VDEC, "mm_smi_vdec_ck", "mm_ck", 27),
GATE_MM(CLK_MM_IMG_DL_RELAY, "mm_img_dl_relay", "mm_ck", 28),
GATE_MM(CLK_MM_IMG_DL_ASYNC_TOP, "mm_imgdl_async", "mm_ck", 29),
GATE_MM(CLK_MM_DIG_DSI, "mm_dig_dsi_ck", "mm_ck", 30),
GATE_MM(CLK_MM_F26M_HRTWT, "mm_hrtwt", "f_f26m_ck", 31),
};
static const struct mtk_gate_regs mipi0a_cg_regs = {
.set_ofs = 0x80,
.clr_ofs = 0x80,
.sta_ofs = 0x80,
};
#define GATE_MIPI0A(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi0a_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv, \
}
#define GATE_MIPI0A_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi0a_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv_dummy, \
}
static const struct mtk_gate mipi0a_clks[] = {
GATE_MIPI0A(CLK_MIPI0A_CSR_CSI_EN_0A,
"mipi0a_csr_0a", "f_fseninf_ck", 1),
};
static const struct mtk_gate_regs mipi0b_cg_regs = {
.set_ofs = 0x80,
.clr_ofs = 0x80,
.sta_ofs = 0x80,
};
#define GATE_MIPI0B(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi0b_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv, \
}
#define GATE_MIPI0B_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi0b_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv_dummy, \
}
static const struct mtk_gate mipi0b_clks[] = {
GATE_MIPI0B(CLK_MIPI0B_CSR_CSI_EN_0B,
"mipi0b_csr_0b", "f_fseninf_ck", 1),
};
static const struct mtk_gate_regs mipi1a_cg_regs = {
.set_ofs = 0x80,
.clr_ofs = 0x80,
.sta_ofs = 0x80,
};
#define GATE_MIPI1A(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi1a_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv, \
}
#define GATE_MIPI1A_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi1a_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv_dummy, \
}
static const struct mtk_gate mipi1a_clks[] = {
GATE_MIPI1A(CLK_MIPI1A_CSR_CSI_EN_1A,
"mipi1a_csr_1a", "f_fseninf_ck", 1),
};
static const struct mtk_gate_regs mipi1b_cg_regs = {
.set_ofs = 0x80,
.clr_ofs = 0x80,
.sta_ofs = 0x80,
};
#define GATE_MIPI1B(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi1b_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv, \
}
#define GATE_MIPI1B_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi1b_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv_dummy, \
}
static const struct mtk_gate mipi1b_clks[] = {
GATE_MIPI1B(CLK_MIPI1B_CSR_CSI_EN_1B,
"mipi1b_csr_1b", "f_fseninf_ck", 1),
};
static const struct mtk_gate_regs mipi2a_cg_regs = {
.set_ofs = 0x80,
.clr_ofs = 0x80,
.sta_ofs = 0x80,
};
#define GATE_MIPI2A(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi2a_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv, \
}
#define GATE_MIPI2A_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi2a_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv_dummy, \
}
static const struct mtk_gate mipi2a_clks[] = {
GATE_MIPI2A(CLK_MIPI2A_CSR_CSI_EN_2A,
"mipi2a_csr_2a", "f_fseninf_ck", 1),
};
static const struct mtk_gate_regs mipi2b_cg_regs = {
.set_ofs = 0x80,
.clr_ofs = 0x80,
.sta_ofs = 0x80,
};
#define GATE_MIPI2B(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi2b_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv, \
}
#define GATE_MIPI2B_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mipi2b_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv_dummy, \
}
static const struct mtk_gate mipi2b_clks[] = {
GATE_MIPI2B(CLK_MIPI2B_CSR_CSI_EN_2B,
"mipi2b_csr_2b", "f_fseninf_ck", 1),
};
static const struct mtk_gate_regs mfgcfg_cg_regs = {
.set_ofs = 0x4,
.clr_ofs = 0x8,
.sta_ofs = 0x0,
};
#define GATE_MFGCFG(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mfgcfg_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr, \
}
#define GATE_MFGCFG_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &mfgcfg_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_setclr_dummy, \
}
static const struct mtk_gate mfgcfg_clks[] = {
/* MT6768: only 1 CG in MFG */
GATE_MFGCFG(CLK_MFGCFG_BG3D, "mfgcfg_bg3d", "mfg_ck", 0),
/*
* GATE_MFGCFG(CLK_MFGCFG_BAXI, "mfgcfg_baxi", "axi_ck", 0),
* GATE_MFGCFG(CLK_MFGCFG_BMEM, "mfgcfg_bmem", "hf_fmem_ck", 1),
* GATE_MFGCFG(CLK_MFGCFG_BG3D, "mfgcfg_bg3d", "f_f26m_ck", 2),
* GATE_MFGCFG(CLK_MFGCFG_B26M, "mfgcfg_b26m", "f_f26m_ck", 3),
*/
};
static const struct mtk_gate_regs gce_cg_regs = {
.set_ofs = 0xf0,
.clr_ofs = 0xf0,
.sta_ofs = 0xf0,
};
#define GATE_GCE(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &gce_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr, \
}
#define GATE_GCE_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &gce_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_dummy, \
}
static const struct mtk_gate gce_clks[] = {
GATE_GCE(CLK_GCE, "gce", "axi_ck", 16),
};
/* additional CCF control for mipi26M race condition(disp/camera) */
static const struct mtk_gate_regs apmixed_cg_regs = {
.set_ofs = 0x14,
.clr_ofs = 0x14,
.sta_ofs = 0x14,
};
#define GATE_APMIXED(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &apmixed_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv, \
}
#define GATE_APMIXED_DUMMY(_id, _name, _parent, _shift) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.regs = &apmixed_cg_regs, \
.shift = _shift, \
.ops = &mtk_clk_gate_ops_no_setclr_inv_dummy, \
}
static const struct mtk_gate apmixed_clks[] = {
/* AUDIO0 */
GATE_APMIXED(CLK_APMIXED_SSUSB26M, "apmixed_ssusb26m", "f_f26m_ck",
4),
GATE_APMIXED(CLK_APMIXED_APPLL26M, "apmixed_appll26m", "f_f26m_ck",
5),
GATE_APMIXED(CLK_APMIXED_MIPIC0_26M, "apmixed_mipic026m", "f_f26m_ck",
6),
GATE_APMIXED(CLK_APMIXED_MDPLLGP26M, "apmixed_mdpll26m", "f_f26m_ck",
7),
GATE_APMIXED(CLK_APMIXED_MMSYS_F26M, "apmixed_mmsys26m", "f_f26m_ck",
8),
GATE_APMIXED(CLK_APMIXED_UFS26M, "apmixed_ufs26m", "f_f26m_ck",
9),
GATE_APMIXED(CLK_APMIXED_MIPIC1_26M, "apmixed_mipic126m", "f_f26m_ck",
11),
GATE_APMIXED(CLK_APMIXED_MEMPLL26M, "apmixed_mempll26m", "f_f26m_ck",
13),
GATE_APMIXED(CLK_APMIXED_CLKSQ_LVPLL_26M, "apmixed_lvpll26m",
"f_f26m_ck", 14),
GATE_APMIXED(CLK_APMIXED_MIPID0_26M, "apmixed_mipid026m", "f_f26m_ck",
16),
/* bit17 no use */
/* GATE_APMIXED(CLK_APMIXED_MIPID1_26M, "apmixed_mipid126m",
* "f_f26m_ck", 17),
*/
};
/* MT6768: add for audio mux in topckgen. */
static const char * const i2s0_m_ck_parents[] = {
"aud_1_sel",
};
static const char * const i2s1_m_ck_parents[] = {
"aud_1_sel",
};
static const char * const i2s2_m_ck_parents[] = {
"aud_1_sel",
};
static const char * const i2s3_m_ck_parents[] = {
"aud_1_sel",
};
static const struct mtk_composite top_audmuxes[] = {
MUX(CLK_TOP_I2S0_M_SEL, "i2s0_m_ck_sel",
i2s0_m_ck_parents, 0x320, 8, 1),
MUX(CLK_TOP_I2S1_M_SEL, "i2s1_m_ck_sel",
i2s1_m_ck_parents, 0x320, 9, 1),
MUX(CLK_TOP_I2S2_M_SEL, "i2s2_m_ck_sel",
i2s2_m_ck_parents, 0x320, 10, 1),
MUX(CLK_TOP_I2S3_M_SEL, "i2s3_m_ck_sel",
i2s3_m_ck_parents, 0x320, 11, 1),
DIV_GATE(CLK_TOP_APLL12_DIV0, "apll12_div0", "i2s0_m_ck_sel",
0x320, 2, 0x324, 8, 0),
DIV_GATE(CLK_TOP_APLL12_DIV1, "apll12_div1", "i2s1_m_ck_sel",
0x320, 3, 0x324, 8, 8),
DIV_GATE(CLK_TOP_APLL12_DIV2, "apll12_div2", "i2s2_m_ck_sel",
0x320, 4, 0x324, 8, 16),
DIV_GATE(CLK_TOP_APLL12_DIV3, "apll12_div3", "i2s3_m_ck_sel",
0x320, 5, 0x324, 8, 24),
};
/* FIXME: modify FMAX/FMIN/RSTBAR */
#define MT6768_PLL_FMAX (3800UL * MHZ)
#define MT6768_PLL_FMIN (1500UL * MHZ)
#define CON0_MT6768_RST_BAR BIT(23)
#define PLL_B(_id, _name, _reg, _pwr_reg, _en_mask, _flags, _pcwbits, \
_pcwibits, _pd_reg, _pd_shift, _tuner_reg, _tuner_en_reg,\
_tuner_en_bit, _pcw_reg, _pcw_shift, _div_table) { \
.id = _id, \
.name = _name, \
.reg = _reg, \
.pwr_reg = _pwr_reg, \
.en_mask = _en_mask, \
.flags = _flags, \
.rst_bar_mask = CON0_MT6768_RST_BAR, \
.fmax = MT6768_PLL_FMAX, \
.fmin = MT6768_PLL_FMIN, \
.pcwbits = _pcwbits, \
.pcwibits = _pcwibits, \
.pd_reg = _pd_reg, \
.pd_shift = _pd_shift, \
.tuner_reg = _tuner_reg, \
.tuner_en_reg = _tuner_en_reg, \
.tuner_en_bit = _tuner_en_bit, \
.pcw_reg = _pcw_reg, \
.pcw_shift = _pcw_shift, \
.div_table = _div_table, \
}
#define PLL(_id, _name, _reg, _pwr_reg, _en_mask, _flags, _pcwbits, \
_pcwibits, _pd_reg, _pd_shift, _tuner_reg, \
_tuner_en_reg, _tuner_en_bit, _pcw_reg, \
_pcw_shift) \
PLL_B(_id, _name, _reg, _pwr_reg, _en_mask, _flags, \
_pcwbits, _pcwibits, _pd_reg, _pd_shift, \
_tuner_reg, _tuner_en_reg, _tuner_en_bit, \
_pcw_reg, _pcw_shift, NULL) \
static const struct mtk_pll_data plls[] = {
PLL(CLK_APMIXED_ARMPLL, "armpll", 0x0208, 0x0214, BIT(0),
PLL_AO, 22, 8, 0x020C, 24, 0, 0, 0, 0x020C, 0),
PLL(CLK_APMIXED_ARMPLL_L, "armpll_l", 0x0218, 0x0224, BIT(0),
PLL_AO, 22, 8, 0x021C, 24, 0, 0, 0, 0x021C, 0),
PLL(CLK_APMIXED_CCIPLL, "ccipll", 0x0228, 0x0234, BIT(0),
PLL_AO, 22, 8, 0x022C, 24, 0, 0, 0, 0x022C, 0),
PLL(CLK_APMIXED_UNIV2PLL, "univ2pll", 0x0238, 0x0244, BIT(0),
HAVE_RST_BAR, 22, 8, 0x023C, 24, 0, 0, 0, 0x023C, 0),
PLL(CLK_APMIXED_MFGPLL, "mfgpll", 0x0248, 0x0254, BIT(0),
0, 22, 8, 0x024C, 24, 0, 0, 0, 0x024C, 0),
PLL(CLK_APMIXED_MAINPLL, "mainpll", 0x0258, 0x0264, BIT(0),
(HAVE_RST_BAR | PLL_AO), 22, 8, 0x025C, 24, 0, 0, 0, 0x025C,
0),
/* APLL pcw is at 0x310, postdiv at 0x30c. Also, it has turner regs.*/
PLL(CLK_APMIXED_APLL1, "apll1", 0x0308, 0x0318, BIT(0),
0, 32, 8, 0x030C, 24, 0x0040, 0x000C, 0, 0x0310, 0),
PLL(CLK_APMIXED_MMPLL, "mmpll", 0x031C, 0x0328, BIT(0),
0, 22, 8, 0x0320, 24, 0, 0, 0, 0x0320, 0),
PLL(CLK_APMIXED_MPLL, "mpll", 0x032C, 0x0338, BIT(0),
PLL_AO, 22, 8, 0x0330, 24, 0, 0, 0, 0x0330, 0),
PLL(CLK_APMIXED_MSDCPLL, "msdcpll", 0x033C, 0x0348, BIT(0),
0, 22, 8, 0x0320, 24, 0, 0, 0, 0x0340, 0),
};
static int mtk_apmixedsys_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
struct device_node *node = pdev->dev.of_node;
int r;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_APMIXED_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_plls(node, plls, ARRAY_SIZE(plls), clk_data);
mtk_clk_register_gates(node, apmixed_clks,
ARRAY_SIZE(apmixed_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
apmixed_base = base;
/* MPLL, ARM/CCIPLLs, MAINPLL set to HW mode, TDCLKSQ, CLKSQ1 */
clk_writel(AP_PLL_CON3, clk_readl(AP_PLL_CON3) & 0xFFFFFFE1);
clk_writel(PLLON_CON0, clk_readl(PLLON_CON0) & 0x01041041);
clk_writel(PLLON_CON1, clk_readl(PLLON_CON1) & 0x01041041);
return r;
}
/* TODO: why disable critical */
static struct clk_onecell_data *mt6768_top_clk_data;
#if 0
static bool timer_ready;
static struct clk_onecell_data *pll_data;
static void mtk_clk_enable_critical(void)
{
if (!timer_ready || !top_data || !pll_data)
return;
#if 0
clk_prepare_enable(top_data->clks[CLK_TOP_AXI_SEL]);
clk_prepare_enable(top_data->clks[CLK_TOP_MEM_SEL]);
clk_prepare_enable(top_data->clks[CLK_TOP_DDRPHYCFG_SEL]);
clk_prepare_enable(top_data->clks[CLK_TOP_RTC_SEL]);
#endif
}
#endif
#if CHECK_VCORE_FREQ
void warn_vcore(int opp, const char *clk_name, int rate, int id)
{
if ((opp >= 0) && (id >= 0) && ((rate/1000) > (vf_table[id][opp]))) {
pr_notice("%s Choose %d FAIL!!!![MAX(%d/%d): %d]\r\n",
clk_name, rate/1000, id, opp, vf_table[id][opp]);
BUG_ON(1);
}
}
static int mtk_mux2id(const char **mux_name)
{
int i = 0;
for (i = 0; i < ARRAY_SIZE(mux_names); i++) {
if (strcmp(*mux_name, mux_names[i]) == 0)
return i;
}
return -2;
}
/* The clocks have a mechanism for synchronizing rate changes. */
static int mtk_clk_rate_change(struct notifier_block *nb,
unsigned long flags, void *data)
{
struct clk_notifier_data *ndata = data;
struct clk_hw *hw = __clk_get_hw(ndata->clk);
const char *clk_name = __clk_get_name(hw->clk);
int vcore_opp = get_sw_req_vcore_opp();
if (flags == PRE_RATE_CHANGE) {
warn_vcore(vcore_opp, clk_name,
ndata->new_rate, mtk_mux2id(&clk_name));
}
return NOTIFY_OK;
}
static struct notifier_block mtk_clk_notifier = {
.notifier_call = mtk_clk_rate_change,
};
int mtk_clk_check_muxes(const struct mtk_mux *muxes,
int num,
struct clk_onecell_data *clk_data)
{
struct clk *clk;
int i;
if (!clk_data)
return -ENOMEM;
for (i = 0; i < num; i++) {
const struct mtk_mux *mux = &muxes[i];
clk = __clk_lookup(mux->name);
clk_notifier_register(clk, &mtk_clk_notifier);
}
return 0;
}
#endif
static int mtk_topckgen_init(struct platform_device *pdev)
{
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
mt6768_top_clk_data = mtk_alloc_clk_data(CLK_TOP_NR_CLK);
mtk_clk_register_fixed_clks(fixed_clks,
ARRAY_SIZE(fixed_clks), mt6768_top_clk_data);
mtk_clk_register_factors(top_divs,
ARRAY_SIZE(top_divs), mt6768_top_clk_data);
/* MT6768: TODO: old style in kernel 4.9
* mtk_clk_register_mux_clr_set_upds(top_muxes,
* ARRAY_SIZE(top_muxes), base,
* &mt6768_clk_lock, mt6768_top_clk_data);
*/
mtk_clk_register_muxes(top_muxes, ARRAY_SIZE(top_muxes), node,
&mt6768_clk_lock, mt6768_top_clk_data);
#if CHECK_VCORE_FREQ
mtk_clk_check_muxes(top_muxes, ARRAY_SIZE(top_muxes),
mt6768_top_clk_data);
#endif
mtk_clk_register_gates(node, top_clks,
ARRAY_SIZE(top_clks), mt6768_top_clk_data);
/* MT6768: add for audio control */
mtk_clk_register_composites(top_audmuxes, ARRAY_SIZE(top_audmuxes),
base, &mt6768_clk_lock, mt6768_top_clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get,
mt6768_top_clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(mt6768_top_clk_data);
}
cksys_base = base;
/* FIX ME: 20171209 SPM CLK Init Flow */
/* [4]:no need */
clk_writel(CLK_SCP_CFG_0, clk_readl(CLK_SCP_CFG_0) | 0x3EF);
/*[1,2,3,8]: no need*/
clk_writel(CLK_SCP_CFG_1, clk_readl(CLK_SCP_CFG_1) | 0x1);
/*mtk_clk_enable_critical();*/
#if LOW_POWER_CLK_PDN /* low power usage */
/* atb : 15, MFG : 7MUX PDN */
clk_writel(cksys_base + CLK_CFG_1_CLR, 0x00008080);
clk_writel(cksys_base + CLK_CFG_1_SET, 0x00008080);
/* msdc50_0_hclk : 7, msdc50_0 : 15 MUX PDN */
clk_writel(cksys_base + CLK_CFG_3_CLR, 0x00008080);
clk_writel(cksys_base + CLK_CFG_3_SET, 0x00008080);
/* usb_top : 23 MUX PDN */
clk_writel(cksys_base + CLK_CFG_5_CLR, 0x00800000);
clk_writel(cksys_base + CLK_CFG_5_SET, 0x00800000);
/* pwm: 15 MUX PDN */
clk_writel(cksys_base + CLK_CFG_6_CLR, 0x00008000);
clk_writel(cksys_base + CLK_CFG_6_SET, 0x00008000);
/* camtm : 15, ssusb_top_xhci 23 MUX PDN */
clk_writel(cksys_base + CLK_CFG_7_CLR, 0x00808000);
clk_writel(cksys_base + CLK_CFG_7_SET, 0x00808000);
#endif
return r;
}
static int mtk_infracfg_ao_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
struct device_node *node = pdev->dev.of_node;
int r;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_IFR_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, ifr_clks,
ARRAY_SIZE(ifr_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
infracfg_base = base;
#if (!MT_CG_ENABLE)
clk_writel(INFRA_TOPAXI_SI0_CTL,
clk_readl(INFRA_TOPAXI_SI0_CTL) | INFRA_CG0);
clk_writel(PERI_BUS_DCM_CTRL,
clk_readl(PERI_BUS_DCM_CTRL) & ~INFRA_CG1);
clk_writel(MODULE_SW_CG_0_CLR, INFRA_CG2);
clk_writel(MODULE_SW_CG_1_CLR, INFRA_CG3);
clk_writel(MODULE_SW_CG_2_CLR, INFRA_CG4);
clk_writel(MODULE_SW_CG_3_CLR, INFRA_CG5);
#else
clk_writel(INFRA_TOPAXI_SI0_CTL,
clk_readl(INFRA_TOPAXI_SI0_CTL) | INFRA_CG0);
clk_writel(PERI_BUS_DCM_CTRL,
clk_readl(PERI_BUS_DCM_CTRL) & ~INFRA_CG1);
clk_writel(MODULE_SW_CG_0_SET, INFRA_CG2);
clk_writel(MODULE_SW_CG_1_SET, INFRA_CG3);
clk_writel(MODULE_SW_CG_2_SET, INFRA_CG4);
clk_writel(MODULE_SW_CG_3_SET, INFRA_CG5);
#endif
return r;
}
static int mtk_pericfg_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
struct device_node *node = pdev->dev.of_node;
int r;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_PERI_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, peri_clks,
ARRAY_SIZE(peri_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
pericfg_base = base;
/* AO */
#if (!MT_CG_ENABLE)
clk_writel(PERIAXI_SI0_CTL, clk_readl(PERIAXI_SI0_CTL) | PERI_CG);
#else
clk_writel(PERIAXI_SI0_CTL, clk_readl(PERIAXI_SI0_CTL) & ~PERI_CG);
#endif
return r;
}
static int mtk_audio_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
struct device_node *node = pdev->dev.of_node;
int r;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_AUDIO_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, audio_clks,
ARRAY_SIZE(audio_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
audio_base = base;
#if (!MT_CG_ENABLE)
clk_writel(AUDIO_TOP_CON0,
clk_readl(AUDIO_TOP_CON0) & ~AUDIO_DISABLE_CG0);
clk_writel(AUDIO_TOP_CON1,
clk_readl(AUDIO_TOP_CON1) & ~AUDIO_DISABLE_CG1);
#endif
return r;
}
static int mtk_camsys_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_CAM_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, cam_clks, ARRAY_SIZE(cam_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
cam_base = base;
#if (!MT_CG_ENABLE)
clk_writel(CAMSYS_CG_CLR, CAMSYS_DISABLE_CG);
#endif
return r;
}
static int mtk_imgsys_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
struct device_node *node = pdev->dev.of_node;
int r;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_IMG_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, img_clks, ARRAY_SIZE(img_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
img_base = base;
#if (!MT_CG_ENABLE)
clk_writel(IMG_CG_CLR, IMG_DISABLE_CG);
#endif
return r;
}
static int mtk_gce_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
struct device_node *node = pdev->dev.of_node;
int r;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_GCE_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, gce_clks, ARRAY_SIZE(gce_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
gce_base = base;
/* default AO, cannot access til infra clk bus on */
#if (!MT_CG_ENABLE)
clk_writel(GCE_CTL_INT0, clk_readl(GCE_CTL_INT0) & ~GCE_DISABLE_CG);
#endif
return r;
}
static int mtk_mmsys_config_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_MM_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, mm_clks, ARRAY_SIZE(mm_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
mmsys_config_base = base;
#if (!MT_CG_ENABLE)
clk_writel(MMSYS_CG_CLR0, MM_DISABLE_CG);
#endif
return r;
}
static int mtk_mfgcfg_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_MFGCFG_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, mfgcfg_clks,
ARRAY_SIZE(mfgcfg_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
mfgcfg_base = base;
/* mfg register would cause hang */
#if (!MT_CG_ENABLE)
clk_writel(MFG_CG_CLR, MFG_DISABLE_CG);
#endif
return r;
}
static int mtk_venc_global_con_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_VENC_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, venc_clks,
ARRAY_SIZE(venc_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
venc_gcon_base = base;
#if (!MT_CG_ENABLE)
clk_writel(VENC_CG_SET, VENC_DISABLE_CG);
#endif
return r;
}
/* add for MT6768 */
static int mtk_vdec_global_con_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_VDEC_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, vdec_clks,
ARRAY_SIZE(vdec_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
vdec_gcon_base = base;
#if (!MT_CG_ENABLE)
clk_writel(VDEC_CG_SET, VDEC_DISABLE_CG);
clk_writel(VDEC_LARB1_CG_SET, VDEC_LARB1_DISABLE_CG);
#endif
return r;
}
static int mtk_mipi0a_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_MIPI0A_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, mipi0a_clks,
ARRAY_SIZE(mipi0a_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
mipi_rx_ana_csi0a_base = base;
#if (!MT_CG_ENABLE)
clk_writel(MIPI_RX_WRAPPER80_CSI0A,
clk_readl(MIPI_RX_WRAPPER80_CSI0A) | MIPI_CSI_DISABLE_CG);
#endif
return r;
}
static int mtk_mipi0b_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_MIPI0B_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, mipi0b_clks,
ARRAY_SIZE(mipi0b_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
mipi_rx_ana_csi0b_base = base;
#if (!MT_CG_ENABLE)
clk_writel(MIPI_RX_WRAPPER80_CSI0B,
clk_readl(MIPI_RX_WRAPPER80_CSI0B) | MIPI_CSI_DISABLE_CG);
#endif
return r;
}
static int mtk_mipi1a_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
struct device_node *node = pdev->dev.of_node;
int r;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_MIPI1A_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, mipi1a_clks,
ARRAY_SIZE(mipi1a_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
mipi_rx_ana_csi1a_base = base;
#if (!MT_CG_ENABLE)
clk_writel(MIPI_RX_WRAPPER80_CSI1A,
clk_readl(MIPI_RX_WRAPPER80_CSI1A) | MIPI_CSI_DISABLE_CG);
#endif
return r;
}
static int mtk_mipi1b_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_MIPI1B_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, mipi1b_clks,
ARRAY_SIZE(mipi1b_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
mipi_rx_ana_csi1b_base = base;
#if (!MT_CG_ENABLE)
clk_writel(MIPI_RX_WRAPPER80_CSI1B,
clk_readl(MIPI_RX_WRAPPER80_CSI1B) | MIPI_CSI_DISABLE_CG);
#endif
return r;
}
static int mtk_mipi2a_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_MIPI2A_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, mipi2a_clks,
ARRAY_SIZE(mipi2a_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
mipi_rx_ana_csi2a_base = base;
#if (!MT_CG_ENABLE)
clk_writel(MIPI_RX_WRAPPER80_CSI2A,
clk_readl(MIPI_RX_WRAPPER80_CSI2A) | MIPI_CSI_DISABLE_CG);
#endif
return r;
}
static int mtk_mipi2b_init(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
void __iomem *base;
int r;
struct device_node *node = pdev->dev.of_node;
base = of_iomap(node, 0);
if (!base) {
pr_notice("%s(): ioremap failed\n", __func__);
return -EINVAL;
}
clk_data = mtk_alloc_clk_data(CLK_MIPI2B_NR_CLK);
if (!clk_data) {
pr_notice("%s(): alloc clk data failed\n", __func__);
return -ENOMEM;
}
mtk_clk_register_gates(node, mipi2b_clks,
ARRAY_SIZE(mipi2b_clks), clk_data);
r = of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
if (r) {
pr_notice("%s(): could not register clock provider: %d\n",
__func__, r);
kfree(clk_data);
}
mipi_rx_ana_csi2b_base = base;
#if (!MT_CG_ENABLE)
clk_writel(MIPI_RX_WRAPPER80_CSI2B,
clk_readl(MIPI_RX_WRAPPER80_CSI2B) | MIPI_CSI_DISABLE_CG);
#endif
return r;
}
unsigned int mt_get_ckgen_freq(unsigned int ID)
{
int output = 0, i = 0;
unsigned int temp, clk26cali_0, clk_dbg_cfg;
unsigned int clk_misc_cfg_0, clk26cali_1;
clk_dbg_cfg = clk_readl(CLK_DBG_CFG);
/*sel ckgen_cksw[22] and enable freq meter
* sel ckgen[21:16], 01:hd_faxi_ck
*/
clk_writel(CLK_DBG_CFG, (clk_dbg_cfg & 0xFFFFC0FC)|(ID << 8)|(0x1));
clk_misc_cfg_0 = clk_readl(CLK_MISC_CFG_0);
/* select divider?dvt set zero */
clk_writel(CLK_MISC_CFG_0, (clk_misc_cfg_0 & 0x00FFFFFF));
clk26cali_0 = clk_readl(CLK26CALI_0);
clk26cali_1 = clk_readl(CLK26CALI_1);
clk_writel(CLK26CALI_0, 0x1000);
clk_writel(CLK26CALI_0, 0x1010);
/* wait frequency meter finish */
while (clk_readl(CLK26CALI_0) & 0x10) {
udelay(10);
i++;
if (i > 10000)
break;
}
temp = clk_readl(CLK26CALI_1) & 0xFFFF;
output = (temp * 26000) / 1024; /* Khz */
clk_writel(CLK_DBG_CFG, clk_dbg_cfg);
clk_writel(CLK_MISC_CFG_0, clk_misc_cfg_0);
clk_writel(CLK26CALI_0, 0x0);
/* print("ckgen meter[%d] = %d Khz\n", ID, output); */
if (i > 10000)
return 0;
else
return output;
}
unsigned int mt_get_abist_freq(unsigned int ID)
{
int output = 0, i = 0;
unsigned int temp, clk26cali_0, clk_dbg_cfg;
unsigned int clk_misc_cfg_0, clk26cali_1;
clk_dbg_cfg = clk_readl(CLK_DBG_CFG);
/* sel abist_cksw and enable freq meter sel abist */
clk_writel(CLK_DBG_CFG, (clk_dbg_cfg & 0xFFC0FFFC)|(ID << 16));
clk_misc_cfg_0 = clk_readl(CLK_MISC_CFG_0);
/* select divider, WAIT CONFIRM */
clk_writel(CLK_MISC_CFG_0, (clk_misc_cfg_0 & 0x00FFFFFF) | (0x3 << 24));
clk26cali_0 = clk_readl(CLK26CALI_0);
clk26cali_1 = clk_readl(CLK26CALI_1);
clk_writel(CLK26CALI_0, 0x1000);
clk_writel(CLK26CALI_0, 0x1010);
/* wait frequency meter finish */
while (clk_readl(CLK26CALI_0) & 0x10) {
udelay(10);
i++;
if (i > 10000)
break;
}
temp = clk_readl(CLK26CALI_1) & 0xFFFF;
output = (temp * 26000) / 1024; /* Khz */
clk_writel(CLK_DBG_CFG, clk_dbg_cfg);
clk_writel(CLK_MISC_CFG_0, clk_misc_cfg_0);
clk_writel(CLK26CALI_0, 0x0);
/*pr_debug("%s = %d Khz\n", abist_array[ID-1], output);*/
if (i > 10000)
return 0;
else
return output * 4;
}
/* Not used anymore in MT6768(armv8.2). Just keep for reference. */
void mp_enter_suspend(int id, int suspend)
{
/* mp0, big core */
if (id == 0) {
if (suspend) {
clk_writel(PLLON_CON0, clk_readl(PLLON_CON0)
& (~ARMPLL_HW_CTRL));
} else {
clk_writel(PLLON_CON0, clk_readl(PLLON_CON0)
| ARMPLL_HW_CTRL);
}
} else if (id == 1) { /* mp1, little cores */
if (suspend) {
clk_writel(PLLON_CON0, clk_readl(PLLON_CON0)
& (~ARMPLL_L_HW_CTRL));
} else {
clk_writel(PLLON_CON0, clk_readl(PLLON_CON0)
| ARMPLL_L_HW_CTRL);
}
}
}
/* Not used anymore in MT6768(armv8.2). Just keep for reference. */
void armpll_control(int id, int on)
{
if (id == 1) { /* big cores */
if (on) {
mt_reg_sync_writel((clk_readl(ARMPLL_CON3))
| (PLL_PWR_ON), ARMPLL_CON3);
udelay(30);
mt_reg_sync_writel((clk_readl(ARMPLL_CON3))
& (~PLL_ISO_EN), ARMPLL_CON3);
udelay(10);
mt_reg_sync_writel((clk_readl(ARMPLL_CON1))
| (PLL_SDM_PCW_CHG), ARMPLL_CON1);
/* seems no rstb for ARMPLL in MT6768.*/
mt_reg_sync_writel((clk_readl(ARMPLL_CON0)
& (~PLL_DIV_RSTB)) | (PLL_EN), ARMPLL_CON0);
udelay(20);
mt_reg_sync_writel((clk_readl(ARMPLL_CON0))
| (PLL_DIV_RSTB), ARMPLL_CON0);
} else {
mt_reg_sync_writel((clk_readl(ARMPLL_CON0))
& (~PLL_EN), ARMPLL_CON0);
mt_reg_sync_writel((clk_readl(ARMPLL_CON3))
| (PLL_ISO_EN), ARMPLL_CON3);
mt_reg_sync_writel((clk_readl(ARMPLL_CON3))
& (~PLL_PWR_ON), ARMPLL_CON3);
}
} else if (id == 2) { /* little cores */
if (on) {
mt_reg_sync_writel((clk_readl(ARMPLL_L_CON3))
| (PLL_PWR_ON), ARMPLL_L_CON3);
udelay(30);
mt_reg_sync_writel((clk_readl(ARMPLL_L_CON3))
& (~PLL_ISO_EN), ARMPLL_L_CON3);
udelay(10);
mt_reg_sync_writel((clk_readl(ARMPLL_L_CON1))
| (PLL_SDM_PCW_CHG), ARMPLL_L_CON1);
/* seems no rstb for ARMPLL in MT6768.*/
mt_reg_sync_writel((clk_readl(ARMPLL_L_CON0)
& (~PLL_DIV_RSTB)) | (PLL_EN), ARMPLL_L_CON0);
udelay(20);
mt_reg_sync_writel((clk_readl(ARMPLL_L_CON0))
| (PLL_DIV_RSTB), ARMPLL_L_CON0);
} else {
mt_reg_sync_writel((clk_readl(ARMPLL_L_CON0))
& (~PLL_EN), ARMPLL_L_CON0);
mt_reg_sync_writel((clk_readl(ARMPLL_L_CON3))
| (PLL_ISO_EN), ARMPLL_L_CON3);
mt_reg_sync_writel((clk_readl(ARMPLL_L_CON3))
& (~PLL_PWR_ON), ARMPLL_L_CON3);
}
}
}
void pll_if_on(void)
{
if (clk_readl(MFGPLL_CON0) & 0x1)
pr_notice("suspend warning: MFGPLL_CON0 is on!!!\n");
if (clk_readl(MMPLL_CON0) & 0x1)
pr_notice("suspend warning: MMPLL is on!!!\n");
if (clk_readl(MSDCPLL_CON0) & 0x1)
pr_notice("suspend warning: MSDCPLL is on!!!\n");
if (clk_readl(APLL1_CON0) & 0x1)
pr_notice("suspend warning: APLL1 is on!!!\n");
if (clk_readl(UNIVPLL_CON0) & 0x1)
pr_notice("suspend warning: UNIVPLL is on!!!\n");
#if 0
if (clk_readl(ARMPLL_CON0) & 0x1)
pr_notice("suspend warning: ARMPLL is on!!!\n");
if (clk_readl(ARMPLL_L_CON0) & 0x1)
pr_notice("suspend warning: ARMPLL_L is on!!!\n");
if (clk_readl(CCIPLL_CON0) & 0x1)
pr_notice("suspend warning: CCIPLL is on!!!\n");
if (clk_readl(MAINPLL_CON0) & 0x1)
pr_notice("suspend warning: MAINPLL is on!!!\n");
if (clk_readl(MPLL_CON0) & 0x1)
pr_notice("suspend warning: MPLL is on!!!\n");
#endif
}
void clock_force_on(void)
{
/* INFRACFG */
clk_writel(MODULE_SW_CG_0_CLR, INFRA_CG2);
clk_writel(MODULE_SW_CG_1_CLR, INFRA_CG3);
clk_writel(MODULE_SW_CG_2_CLR, INFRA_CG4);
clk_writel(MODULE_SW_CG_3_CLR, INFRA_CG5);
/* PERICFG */
clk_writel(PERIAXI_SI0_CTL, clk_readl(PERIAXI_SI0_CTL) | PERI_CG);
/* DISP CG */
clk_writel(MMSYS_CG_CLR0, MM_DISABLE_CG);
/* AUDIO */
clk_writel(AUDIO_TOP_CON0,
clk_readl(AUDIO_TOP_CON0) & ~AUDIO_DISABLE_CG0);
clk_writel(AUDIO_TOP_CON1,
clk_readl(AUDIO_TOP_CON1) & ~AUDIO_DISABLE_CG1);
/* MFG */
clk_writel(MFG_CG_CLR, MFG_DISABLE_CG);
/* ISP */
clk_writel(IMG_CG_CLR, IMG_DISABLE_CG);
/* VENC not inverse */
clk_writel(VENC_CG_SET, VENC_DISABLE_CG);
/* VDEC not inverse */
clk_writel(VDEC_CG_SET, VENC_DISABLE_CG);
clk_writel(VDEC_LARB1_CG_SET, VDEC_LARB1_DISABLE_CG);
/* CAM */
clk_writel(CAMSYS_CG_CLR, CAMSYS_DISABLE_CG);
/* GCE AO */
/* MIPI */
clk_writel(MIPI_RX_WRAPPER80_CSI0A,
clk_readl(MIPI_RX_WRAPPER80_CSI0A) | MIPI_CSI_DISABLE_CG);
clk_writel(MIPI_RX_WRAPPER80_CSI0B,
clk_readl(MIPI_RX_WRAPPER80_CSI0B) | MIPI_CSI_DISABLE_CG);
clk_writel(MIPI_RX_WRAPPER80_CSI1A,
clk_readl(MIPI_RX_WRAPPER80_CSI1A) | MIPI_CSI_DISABLE_CG);
clk_writel(MIPI_RX_WRAPPER80_CSI1B,
clk_readl(MIPI_RX_WRAPPER80_CSI1B) | MIPI_CSI_DISABLE_CG);
clk_writel(MIPI_RX_WRAPPER80_CSI2A,
clk_readl(MIPI_RX_WRAPPER80_CSI2A) | MIPI_CSI_DISABLE_CG);
clk_writel(MIPI_RX_WRAPPER80_CSI2B,
clk_readl(MIPI_RX_WRAPPER80_CSI2B) | MIPI_CSI_DISABLE_CG);
}
void clock_force_off(void)
{
/* DISP CG */
clk_writel(MMSYS_CG_SET0, MM_DISABLE_CG);
/* AUDIO */
clk_writel(AUDIO_TOP_CON0,
clk_readl(AUDIO_TOP_CON0) | AUDIO_DISABLE_CG0);
clk_writel(AUDIO_TOP_CON1,
clk_readl(AUDIO_TOP_CON1) | AUDIO_DISABLE_CG1);
/* MFG AO */
/* ISP */
clk_writel(IMG_CG_SET, IMG_DISABLE_CG);
/* VENC not inverse */
clk_writel(VENC_CG_CLR, VENC_DISABLE_CG);
/* VDEC not inverse */
clk_writel(VDEC_CG_CLR, VENC_DISABLE_CG);
clk_writel(VDEC_LARB1_CG_CLR, VDEC_LARB1_DISABLE_CG);
/* CAM */
clk_writel(CAMSYS_CG_SET, CAMSYS_DISABLE_CG);
/* GCE AO */
/* MIPI */
clk_writel(MIPI_RX_WRAPPER80_CSI0A,
clk_readl(MIPI_RX_WRAPPER80_CSI0A) & ~MIPI_CSI_DISABLE_CG);
clk_writel(MIPI_RX_WRAPPER80_CSI0B,
clk_readl(MIPI_RX_WRAPPER80_CSI0B) & ~MIPI_CSI_DISABLE_CG);
clk_writel(MIPI_RX_WRAPPER80_CSI1A,
clk_readl(MIPI_RX_WRAPPER80_CSI1A) & ~MIPI_CSI_DISABLE_CG);
clk_writel(MIPI_RX_WRAPPER80_CSI1B,
clk_readl(MIPI_RX_WRAPPER80_CSI1B) & ~MIPI_CSI_DISABLE_CG);
clk_writel(MIPI_RX_WRAPPER80_CSI2A,
clk_readl(MIPI_RX_WRAPPER80_CSI2A) & ~MIPI_CSI_DISABLE_CG);
clk_writel(MIPI_RX_WRAPPER80_CSI2B,
clk_readl(MIPI_RX_WRAPPER80_CSI2B) & ~MIPI_CSI_DISABLE_CG);
}
void mmsys_cg_check(void)
{
pr_notice("[MMSYS_CG_CON0]=0x%08x\n", clk_readl(MMSYS_CG_CON0));
}
#if 1
void mfgsys_clk_check(void)
{
pr_notice("CLK_CFG_1 = 0x%08x\n", clk_readl(CLK_CFG_1));
pr_notice("MFGPLL = 0x%08x, 0x%08x, 0x%08x\n",
clk_readl(MFGPLL_CON0), clk_readl(MFGPLL_CON1),
clk_readl(MFGPLL_CON3));
}
void mfgsys_cg_check(void)
{
pr_notice("MFG_CG_CON = 0x%08x\n", clk_readl(MFG_CG_CON));
}
#endif
void pll_force_off(void)
{
/*MFGPLL*/
clk_clrl(MFGPLL_CON0, PLL_EN);
clk_setl(MFGPLL_CON3, PLL_ISO_EN);
clk_clrl(MFGPLL_CON3, PLL_PWR_ON);
/*MPLL Control by dram*/
#if 0
clk_clrl(MPLL_CON0, PLL_EN);
clk_setl(MPLL_CON3, PLL_ISO_EN);
clk_clrl(MPLL_CON3, PLL_PWR_ON);
#endif
/*UNIVPLL*/
clk_clrl(UNIVPLL_CON0, PLL_EN);
clk_setl(UNIVPLL_CON3, PLL_ISO_EN);
clk_clrl(UNIVPLL_CON3, PLL_PWR_ON);
/*MSDCPLL*/
clk_clrl(MSDCPLL_CON0, PLL_EN);
clk_setl(MSDCPLL_CON3, PLL_ISO_EN);
clk_clrl(MSDCPLL_CON3, PLL_PWR_ON);
/*MMPLL*/
clk_clrl(MMPLL_CON0, PLL_EN);
clk_setl(MMPLL_CON3, PLL_ISO_EN);
clk_clrl(MMPLL_CON3, PLL_PWR_ON);
/*APLL1*/
clk_clrl(APLL1_CON0, PLL_EN);
clk_setl(APLL1_CON4, PLL_ISO_EN);
clk_clrl(APLL1_CON4, PLL_PWR_ON);
}
void mtk_set_cg_disable(unsigned int disable)
{
if (disable == 1)
cg_disable = true;
else if (disable == 0)
cg_disable = false;
}
int mtk_is_cg_enable(void)
{
#if MT_CG_ENABLE
if (cg_disable) {
clock_force_on();
pr_debug("%s: skipped for cg control disable\n", __func__);
return 0;
} else {
return 1;
}
#else
return 0;
#endif
}
int mtk_is_pll_enable(void)
{
#if MT_MUXPLL_ENABLE
/* pr_debug("%s: skipped for bring up\n", __func__); */
return 1;
#else
return 0;
#endif
}
void mtk_set_mtcmos_disable(unsigned int disable)
{
if (disable == 1)
mtcmos_disable = true;
else if (disable == 0)
mtcmos_disable = false;
}
int mtk_is_mtcmos_enable(void)
{
#if MT_MTCMOS_ENABLE
if (mtcmos_disable) {
pr_debug("%s: skipped for mtcmos control disable\n", __func__);
return 0;
} else {
return 1;
}
#else
return 0;
#endif
}
void aud_intbus_mux_sel(unsigned int aud_idx)
{
#if 1
clk_writel(cksys_base + CLK_CFG_4_CLR, 0x00000003);/*[1:0]*/
clk_writel(cksys_base + CLK_CFG_4_SET, aud_idx << 0);
clk_writel(cksys_base + CLK_CFG_UPDATE, 0x00010000);/*[16]*/
#endif
}
static const struct of_device_id of_match_clk_mt6768[] = {
{
.compatible = "mediatek,apmixed",
.data = mtk_apmixedsys_init,
}, {
.compatible = "mediatek,topckgen",
.data = mtk_topckgen_init,
}, {
.compatible = "mediatek,infracfg_ao",
.data = mtk_infracfg_ao_init,
}, {
.compatible = "mediatek,pericfg",
.data = mtk_pericfg_init,
},{
.compatible = "mediatek,audio",
.data = mtk_audio_init,
},{
.compatible = "mediatek,mt6768-camsys",
.data = mtk_camsys_init,
},{
.compatible = "mediatek,mt6768-imgsys",
.data = mtk_imgsys_init,
},{
.compatible = "mediatek,gce",
.data = mtk_gce_init,
},{
.compatible = "mediatek,mmsys_config",
.data = mtk_mmsys_config_init,
},{
.compatible = "mediatek,mfgcfg",
.data = mtk_mfgcfg_init,
},{
.compatible = "mediatek,venc_gcon",
.data = mtk_venc_global_con_init,
},{
.compatible = "mediatek,vdec_gcon",
.data = mtk_vdec_global_con_init,
},{
.compatible = "mediatek,mipi_rx_ana_csi0a",
.data = mtk_mipi0a_init,
},{
.compatible = "mediatek,mipi_rx_ana_csi0b",
.data = mtk_mipi0b_init,
},{
.compatible = "mediatek,mipi_rx_ana_csi1a",
.data = mtk_mipi1a_init,
},{
.compatible = "mediatek,mipi_rx_ana_csi1b",
.data = mtk_mipi1b_init,
},{
.compatible = "mediatek,mipi_rx_ana_csi2a",
.data = mtk_mipi2a_init,
},{
.compatible = "mediatek,mipi_rx_ana_csi2b",
.data = mtk_mipi2b_init,
}
};
static int clk_mt6768_probe(struct platform_device *pdev)
{
int (*clk_probe)(struct platform_device *d);
int r;
clk_probe = of_device_get_match_data(&pdev->dev);
if (!clk_probe)
return -EINVAL;
r = clk_probe(pdev);
if (r)
dev_err(&pdev->dev,
"could not register clock provider: %s: %d\n",
pdev->name, r);
return r;
}
static struct platform_driver clk_mt6768_drv = {
.probe = clk_mt6768_probe,
.driver = {
.name = "clk-mt6768",
.owner = THIS_MODULE,
.of_match_table = of_match_clk_mt6768,
},
};
static int __init clk_mt6768_init(void)
{
#if MT_CCF_BRINGUP
cg_disable = true;
mtcmos_disable = true;
#else
#if MT_CG_ENABLE
cg_disable = false;
#endif
#if MT_MTCMOS_ENABLE
mtcmos_disable = false;
#endif
#endif
return platform_driver_register(&clk_mt6768_drv);
}
static void __exit clk_mt6768_exit(void)
{
pr_debug("%s: skipped for mtcmos control disable\n", __func__);
}
arch_initcall(clk_mt6768_init);
module_exit(clk_mt6768_exit);
MODULE_LICENSE("GPL");
MODULE_AUTHOR("MTK");
MODULE_DESCRIPTION("MTK CCF Driverv1.0");