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kernel_samsung_a34x-permissive/drivers/clk/mediatek/clk-mt6768-pg.c

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Import A346BXXU1AWB9 kernel source Android 13
2024-04-28 06:49:01 -07:00
/* SPDX-License-Identifier: GPL-2.0 */
/*
* Copyright (c) 2019 MediaTek Inc.
*/
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/io.h>
#include <linux/slab.h>
#include <linux/delay.h>
#include <linux/clkdev.h>
#include <linux/clk-provider.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-v1.h"
#include "clk-mt6768-pg.h"
#include <dt-bindings/clock/mt6768-clk.h>
/* bring up control */
#define MT_CCF_DEBUG 0
#define CONTROL_LIMIT 1
#define CLK_DEBUG 0
#define DUMMY_REG_TEST 0
#ifdef CONFIG_FPGA_EARLY_PORTING
#define IGNORE_MTCMOS_CHECK
#endif
#if !defined(MT_CCF_DEBUG) || !defined(CLK_DEBUG) || !defined(DUMMY_REG_TEST)
#define MT_CCF_DEBUG 0
#define CONTROL_LIMIT 0
#define CLK_DEBUG 0
#define DUMMY_REG_TEST 0
#endif
#define CHECK_PWR_ST 1
#define CONN_TIMEOUT_RECOVERY 5
#define CONN_TIMEOUT_STEP1 4
#ifndef GENMASK
#define GENMASK(h, l) (((U32_C(1) << ((h) - (l) + 1)) - 1) << (l))
#endif
#ifdef CONFIG_ARM64
#define IOMEM(a) ((void __force __iomem *)((a)))
#endif
#define mt_reg_sync_writel(v, a) \
do { \
__raw_writel((v), IOMEM(a)); \
/* sync up */ \
mb(); } \
while (0)
#define spm_read(addr) __raw_readl(IOMEM(addr))
#define spm_write(addr, val) mt_reg_sync_writel(val, addr)
#define clk_readl(addr) __raw_readl(IOMEM(addr))
#define clk_writel(addr, val) mt_reg_sync_writel(val, addr)
/*MM Bus*/
#ifdef CONFIG_OF
void __iomem *clk_mmsys_config_base;
void __iomem *clk_imgsys_base;
void __iomem *clk_venc_gcon_base;
void __iomem *clk_camsys_base;
#endif
/*
* MTCMOS
*/
#define STA_POWER_DOWN 0
#define STA_POWER_ON 1
#define SUBSYS_PWR_DOWN 0
#define SUBSYS_PWR_ON 1
struct subsys;
struct subsys_ops {
int (*prepare)(struct subsys *sys);
int (*unprepare)(struct subsys *sys);
int (*enable)(struct subsys *sys);
int (*disable)(struct subsys *sys);
int (*get_state)(struct subsys *sys);
};
struct subsys {
const char *name;
uint32_t sta_mask;
void __iomem *ctl_addr;
uint32_t sram_pdn_bits;
uint32_t sram_pdn_ack_bits;
uint32_t bus_prot_mask;
struct subsys_ops *ops;
};
/*static struct subsys_ops general_sys_ops;*/
static struct subsys_ops MD1_sys_ops;
static struct subsys_ops CONN_sys_ops;
static struct subsys_ops DPY_sys_ops;
static struct subsys_ops DIS_sys_ops;
static struct subsys_ops MFG_sys_ops;
static struct subsys_ops ISP_sys_ops;
static struct subsys_ops IFR_sys_ops;
static struct subsys_ops MFG_CORE0_sys_ops;
static struct subsys_ops MFG_CORE1_sys_ops;
static struct subsys_ops MFG_ASYNC_sys_ops;
static struct subsys_ops CAM_sys_ops;
static struct subsys_ops VENC_sys_ops;
static struct subsys_ops VDEC_sys_ops;
static void __iomem *infracfg_base; /* infracfg_ao */
static void __iomem *spm_base; /* spm */
static void __iomem *infra_base; /* infra */
static void __iomem *smi_common_base; /* smi_common */
static void __iomem *conn_base; /* connsys*/
static void __iomem *conn_mcu_base; /* connsys MCU */
static void __iomem *cksys_base; /* topckgen */
static void __iomem *vdec_gcon_base; /* vdec gcon */
static void __iomem *vdec_base; /* vdec */
#define INFRACFG_REG(offset) (infracfg_base + offset)
#define SPM_REG(offset) (spm_base + offset)
#define INFRA_REG(offset) (infra_base + offset)
#define SMI_COMMON_REG(offset) (smi_common_base + offset)
#define CONN_HIF_REG(offset) (conn_base + offset)
#define CONN_MCU_REG(offset) (conn_mcu_base + offset)
#define CK_REG_0 (cksys_base + 0x40)
#define CK_REG_7 (cksys_base + 0xB0)
#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)
#define VDEC_REG0 (vdec_base + 0x110)
#define VDEC_REG1 (vdec_base + 0x114)
#define VDEC_REG2 (vdec_base + 0x118)
#define VDEC_REG3 (vdec_base + 0x11C)
#define VDEC_REG4 (vdec_base + 0x120)
#define VDEC_REG5 (vdec_base + 0x124)
#define VDEC_REG6 (vdec_base + 0x128)
#define VDEC_REG7 (vdec_base + 0x12C)
#define VDEC_REG8 (vdec_base + 0x130)
#define VDEC_REG9 (vdec_base + 0x134)
#define VDEC_REG10 (vdec_base + 0x138)
#define VDEC_REG11 (vdec_base + 0x13C)
/* Define MTCMOS power control */
#define PWR_RST_B (0x1 << 0)
#define PWR_ISO (0x1 << 1)
#define PWR_ON (0x1 << 2)
#define PWR_ON_2ND (0x1 << 3)
#define PWR_CLK_DIS (0x1 << 4)
#define SRAM_CKISO (0x1 << 5)
#define SRAM_ISOINT_B (0x1 << 6)
/**************************************
* for non-CPU MTCMOS
**************************************/
#define POWERON_CONFIG_EN SPM_REG(0x0000)
#define SPM_POWER_ON_VAL0 SPM_REG(0x0004)
#define SPM_POWER_ON_VAL1 SPM_REG(0x0008)
#define PWR_STATUS SPM_REG(0x0180)
#define PWR_STATUS_2ND SPM_REG(0x0184)
#define VCODEC_PWR_CON SPM_REG(0x0300)
#define VEN_PWR_CON SPM_REG(0x0304)
#define ISP_PWR_CON SPM_REG(0x0308)
#define DIS_PWR_CON SPM_REG(0x030C)
#define MFG_CORE1_PWR_CON SPM_REG(0x0310)
#define AUDIO_PWR_CON SPM_REG(0x0314)
#define IFR_PWR_CON SPM_REG(0x0318)
#define DPY_PWR_CON SPM_REG(0x031C)
#define MD1_PWR_CON SPM_REG(0x0320)
#define VPU_TOP_PWR_CON SPM_REG(0x0324)
#define CONN_PWR_CON SPM_REG(0x032C)
#define VPU_CORE2_PWR_CON SPM_REG(0x0330)
#define MFG_ASYNC_PWR_CON SPM_REG(0x0334)
#define MFG_PWR_CON SPM_REG(0x0338)
#define VPU_CORE0_PWR_CON SPM_REG(0x033C)
#define VPU_CORE1_PWR_CON SPM_REG(0x0340)
#define CAM_PWR_CON SPM_REG(0x0344)
#define MFG_2D_PWR_CON SPM_REG(0x0348)
#define MFG_CORE0_PWR_CON SPM_REG(0x034C)
#define VDE_PWR_CON SPM_REG(0x0370)
#define MD_SRAM_ISO_CON SPM_REG(0x0394)
#define MD_EXTRA_PWR_CON SPM_REG(0x0398)
#define SPM_PROJECT_CODE 0xB16
#define INFRA_TOPAXI_PROTECTEN INFRACFG_REG(0x0220)
#define INFRA_TOPAXI_PROTECTEN_STA0 INFRACFG_REG(0x0224)
#define INFRA_TOPAXI_PROTECTEN_STA1 INFRACFG_REG(0x0228)
#define INFRA_TOPAXI_PROTECTEN_1 INFRACFG_REG(0x0250)
#define INFRA_TOPAXI_PROTECTEN_STA0_1 INFRACFG_REG(0x0254)
#define INFRA_TOPAXI_PROTECTEN_STA1_1 INFRACFG_REG(0x0258)
#define INFRA_TOPAXI_PROTECTEN_SET INFRACFG_REG(0x02A0)
#define INFRA_TOPAXI_PROTECTEN_CLR INFRACFG_REG(0x02A4)
#define INFRA_TOPAXI_PROTECTEN_1_SET INFRACFG_REG(0x02A8)
#define INFRA_TOPAXI_PROTECTEN_1_CLR INFRACFG_REG(0x02AC)
/* fix with infra config address */
#define INFRA_TOPAXI_SI0_STA INFRA_REG(0x0000)
#define INFRA_TOPAXI_SI1_STA INFRA_REG(0x0004)
#define INFRA_TOPAXI_SI2_STA INFRA_REG(0x0028)
#define INFRA_TOPAXI_SI3_STA INFRA_REG(0x002C)
#define INFRA_TOPAXI_SI4_STA INFRA_REG(0x0030)
#define INFRA_TOPAXI_MI_STA INFRA_REG(0x0008)
#define INFRA_MCI_SI0_STA INFRA_REG(0x0010)
#define INFRA_MCI_SI2_STA INFRA_REG(0x0018)
#define INFRA_BUS_IDLE_STA4 INFRA_REG(0x018C)
/* SMI COMMON */
#define SMI_COMMON_SMI_CLAMP SMI_COMMON_REG(0x03C0)
#define SMI_COMMON_SMI_CLAMP_SET SMI_COMMON_REG(0x03C4)
#define SMI_COMMON_SMI_CLAMP_CLR SMI_COMMON_REG(0x03C8)
/* Define MTCMOS Bus Protect Mask */
#define MD1_PROT_STEP1_0_MASK ((0x1 << 7))
#define MD1_PROT_STEP1_0_ACK_MASK ((0x1 << 7))
#define MD1_PROT_STEP2_0_MASK ((0x1 << 3) \
|(0x1 << 4))
#define MD1_PROT_STEP2_0_ACK_MASK ((0x1 << 3) \
|(0x1 << 4))
#define MD1_PROT_STEP2_1_MASK ((0x1 << 6))
#define MD1_PROT_STEP2_1_ACK_MASK ((0x1 << 6))
#define CONN_PROT_STEP1_0_MASK ((0x1 << 13))
#define CONN_PROT_STEP1_0_ACK_MASK ((0x1 << 13))
#define CONN_PROT_STEP1_1_MASK ((0x1 << 18))
#define CONN_PROT_STEP1_1_ACK_MASK ((0x1 << 18))
#define CONN_PROT_STEP2_0_MASK ((0x1 << 14) \
|(0x1 << 16))
#define CONN_PROT_STEP2_0_ACK_MASK ((0x1 << 14) \
|(0x1 << 16))
#define DPY_PROT_STEP1_0_MASK ((0x1 << 0) \
|(0x1 << 5) \
|(0x1 << 23) \
|(0x1 << 26))
#define DPY_PROT_STEP1_0_ACK_MASK ((0x1 << 0) \
|(0x1 << 5) \
|(0x1 << 23) \
|(0x1 << 26))
#define DPY_PROT_STEP1_1_MASK ((0x1 << 10) \
|(0x1 << 11) \
|(0x1 << 12) \
|(0x1 << 13) \
|(0x1 << 14) \
|(0x1 << 15) \
|(0x1 << 16) \
|(0x1 << 17))
#define DPY_PROT_STEP1_1_ACK_MASK ((0x1 << 10) \
|(0x1 << 11) \
|(0x1 << 12) \
|(0x1 << 13) \
|(0x1 << 14) \
|(0x1 << 15) \
|(0x1 << 16) \
|(0x1 << 17))
#define DPY_PROT_STEP2_0_MASK ((0x1 << 1) \
|(0x1 << 2) \
|(0x1 << 3) \
|(0x1 << 4) \
|(0x1 << 10) \
|(0x1 << 11) \
|(0x1 << 21) \
|(0x1 << 22))
#define DPY_PROT_STEP2_0_ACK_MASK ((0x1 << 1) \
|(0x1 << 2) \
|(0x1 << 3) \
|(0x1 << 4) \
|(0x1 << 10) \
|(0x1 << 11) \
|(0x1 << 21) \
|(0x1 << 22))
#define DIS_PROT_STEP1_0_MASK ((0x1 << 19) \
|(0x1 << 20) \
|(0x1 << 30) \
|(0x1 << 31))
#define DIS_PROT_STEP1_0_ACK_MASK ((0x1 << 19) \
|(0x1 << 20) \
|(0x1 << 30) \
|(0x1 << 31))
#define DIS_PROT_STEP2_0_MASK ((0x1 << 16) \
|(0x1 << 17))
#define DIS_PROT_STEP2_0_ACK_MASK ((0x1 << 16) \
|(0x1 << 17))
#define DIS_PROT_STEP3_0_MASK ((0x1 << 10) \
|(0x1 << 11))
#define DIS_PROT_STEP3_0_ACK_MASK ((0x1 << 10) \
|(0x1 << 11))
#define DIS_PROT_STEP4_0_MASK ((0x1 << 1) \
|(0x1 << 2))
#define DIS_PROT_STEP4_0_ACK_MASK ((0x1 << 1) \
|(0x1 << 2))
#define ISP_PROT_STEP1_0_MASK ((0x1 << 20))
#define ISP_PROT_STEP1_0_ACK_MASK ((0x1 << 20))
#define ISP_PROT_STEP2_0_MASK ((0x1 << 2))
#define ISP_PROT_STEP2_0_ACK_MASK ((0x1 << 2))
#define CAM_PROT_STEP1_0_MASK ((0x1 << 19) \
|(0x1 << 21))
#define CAM_PROT_STEP1_0_ACK_MASK ((0x1 << 19) \
|(0x1 << 21))
#define CAM_PROT_STEP2_0_MASK ((0x1 << 20))
#define CAM_PROT_STEP2_0_ACK_MASK ((0x1 << 20))
#define CAM_PROT_STEP2_1_MASK ((0x1 << 3))
#define CAM_PROT_STEP2_1_ACK_MASK ((0x1 << 3))
#define VDE_PROT_STEP1_0_MASK ((0x1 << 30))
#define VDE_PROT_STEP1_0_ACK_MASK ((0x1 << 30))
#define VDE_PROT_STEP2_0_MASK ((0x1 << 1))
#define VDE_PROT_STEP2_0_ACK_MASK ((0x1 << 1))
#define VEN_PROT_STEP1_0_MASK ((0x1 << 31))
#define VEN_PROT_STEP1_0_ACK_MASK ((0x1 << 31))
#define VEN_PROT_STEP2_0_MASK ((0x1 << 4))
#define VEN_PROT_STEP2_0_ACK_MASK ((0x1 << 4))
#define MFG_PROT_STEP1_0_MASK ((0x1 << 25))
#define MFG_PROT_STEP1_0_ACK_MASK ((0x1 << 25))
#define MFG_PROT_STEP2_0_MASK ((0x1 << 21) \
|(0x1 << 22))
#define MFG_PROT_STEP2_0_ACK_MASK ((0x1 << 21) \
|(0x1 << 22))
#define MCU_PROT_STEP1_0_MASK ((0x1 << 0) \
|(0x1 << 5) \
|(0x1 << 9))
#define MCU_PROT_STEP1_0_ACK_MASK ((0x1 << 0) \
|(0x1 << 5) \
|(0x1 << 9))
#define MCU_PROT_STEP2_0_MASK ((0x1 << 12))
#define MCU_PROT_STEP2_0_ACK_MASK ((0x1 << 12))
/* Define MTCMOS Power Status Mask */
#define MD1_PWR_STA_MASK (0x1 << 0)
#define CONN_PWR_STA_MASK (0x1 << 1)
#define DPY_PWR_STA_MASK (0x1 << 2)
#define IFR_PWR_STA_MASK (0x1 << 3)
#define DIS_PWR_STA_MASK (0x1 << 5)
#define ISP_PWR_STA_MASK (0x1 << 6)
#define CAM_PWR_STA_MASK (0x1 << 7)
#define VDE_PWR_STA_MASK (0x1 << 8)
#define VEN_PWR_STA_MASK (0x1 << 9)
#define MFG_PWR_STA_MASK (0x1 << 11)
#define MFG_CORE0_PWR_STA_MASK (0x1 << 12)
#define MFG_CORE1_PWR_STA_MASK (0x1 << 13)
#define MFG_ASYNC_PWR_STA_MASK (0x1 << 14)
#define MP0_CPU0_PWR_STA_MASK (0x1 << 16)
#define MP0_CPU1_PWR_STA_MASK (0x1 << 17)
#define MP0_CPU2_PWR_STA_MASK (0x1 << 18)
#define MP0_CPU3_PWR_STA_MASK (0x1 << 19)
#define MP0_CPU4_PWR_STA_MASK (0x1 << 20)
#define MP0_CPU5_PWR_STA_MASK (0x1 << 21)
#define MP0_CPU6_PWR_STA_MASK (0x1 << 22)
#define MP0_CPU7_PWR_STA_MASK (0x1 << 23)
#define MP0_CPUTOP_PWR_STA_MASK (0x1 << 25)
#define MCU_PWR_STA_MASK (0x1 << 26)
/* Define CPU SRAM Mask */
/* Define Non-CPU SRAM Mask */
#define MD1_SRAM_PDN (0x1 << 8)
#define MD1_SRAM_PDN_ACK (0x1 << 12)
#define MD1_SRAM_PDN_ACK_BIT0 (0x1 << 12)
#define DPY_SRAM_PDN (0xF << 8)
#define DPY_SRAM_PDN_ACK (0xF << 12)
#define DPY_SRAM_PDN_ACK_BIT0 (0x1 << 12)
#define DPY_SRAM_PDN_ACK_BIT1 (0x1 << 13)
#define DPY_SRAM_PDN_ACK_BIT2 (0x1 << 14)
#define DPY_SRAM_PDN_ACK_BIT3 (0x1 << 15)
#define IFR_SRAM_PDN (0x1 << 8)
#define IFR_SRAM_PDN_ACK (0x1 << 12)
#define IFR_SRAM_PDN_ACK_BIT0 (0x1 << 12)
#define DIS_SRAM_PDN (0x1 << 8)
#define DIS_SRAM_PDN_ACK (0x1 << 12)
#define DIS_SRAM_PDN_ACK_BIT0 (0x1 << 12)
#define ISP_SRAM_PDN (0x1 << 8)
#define ISP_SRAM_PDN_ACK (0x1 << 12)
#define ISP_SRAM_PDN_ACK_BIT0 (0x1 << 12)
#define CAM_SRAM_PDN (0x3 << 8)
#define CAM_SRAM_PDN_ACK (0x3 << 12)
#define CAM_SRAM_PDN_ACK_BIT0 (0x1 << 12)
#define CAM_SRAM_PDN_ACK_BIT1 (0x1 << 13)
#define VDE_SRAM_PDN (0x1 << 8)
#define VDE_SRAM_PDN_ACK (0x1 << 12)
#define VDE_SRAM_PDN_ACK_BIT0 (0x1 << 12)
#define VEN_SRAM_PDN (0x1 << 8)
#define VEN_SRAM_PDN_ACK (0x1 << 12)
#define VEN_SRAM_PDN_ACK_BIT0 (0x1 << 12)
#define MFG_SRAM_PDN (0x1 << 8)
#define MFG_SRAM_PDN_ACK (0x1 << 12)
#define MFG_SRAM_PDN_ACK_BIT0 (0x1 << 12)
#define MFG_CORE0_SRAM_PDN (0x1 << 8)
#define MFG_CORE0_SRAM_PDN_ACK (0x1 << 12)
#define MFG_CORE0_SRAM_PDN_ACK_BIT0 (0x1 << 12)
#define MFG_CORE1_SRAM_PDN (0x1 << 8)
#define MFG_CORE1_SRAM_PDN_ACK (0x1 << 12)
#define MFG_CORE1_SRAM_PDN_ACK_BIT0 (0x1 << 12)
static struct subsys syss[] = /* NR_SYSS *//* FIXME: set correct value */
{
[SYS_MD1] = {
.name = __stringify(SYS_MD1),
.sta_mask = MD1_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &MD1_sys_ops,
},
[SYS_CONN] = {
.name = __stringify(SYS_CONN),
.sta_mask = CONN_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &CONN_sys_ops,
},
[SYS_DPY] = {
.name = __stringify(SYS_DPY),
.sta_mask = DPY_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &DPY_sys_ops,
},
[SYS_DIS] = {
.name = __stringify(SYS_DIS),
.sta_mask = DIS_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &DIS_sys_ops,
},
[SYS_MFG] = {
.name = __stringify(SYS_MFG),
.sta_mask = MFG_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &MFG_sys_ops,
},
[SYS_ISP] = {
.name = __stringify(SYS_ISP),
.sta_mask = ISP_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &ISP_sys_ops,
},
[SYS_IFR] = {
.name = __stringify(SYS_IFR),
.sta_mask = IFR_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &IFR_sys_ops,
},
[SYS_MFG_CORE0] = {
.name = __stringify(SYS_MFG_CORE0),
.sta_mask = MFG_CORE0_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &MFG_CORE0_sys_ops,
},
[SYS_MFG_CORE1] = {
.name = __stringify(SYS_MFG_CORE1),
.sta_mask = MFG_CORE1_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &MFG_CORE1_sys_ops,
},
[SYS_MFG_ASYNC] = {
.name = __stringify(SYS_MFG_ASYNC),
.sta_mask = MFG_ASYNC_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &MFG_ASYNC_sys_ops,
},
[SYS_CAM] = {
.name = __stringify(SYS_CAM),
.sta_mask = CAM_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &CAM_sys_ops,
},
[SYS_VENC] = {
.name = __stringify(SYS_VENC),
.sta_mask = VEN_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &VENC_sys_ops,
},
[SYS_VDEC] = {
.name = __stringify(SYS_VDEC),
.sta_mask = VDE_PWR_STA_MASK,
/* .ctl_addr = NULL, */
.sram_pdn_bits = 0,
.sram_pdn_ack_bits = 0,
.bus_prot_mask = 0,
.ops = &VDEC_sys_ops,
},
};
spinlock_t pgcb_lock;
LIST_HEAD(pgcb_list);
struct pg_callbacks *register_pg_callback(struct pg_callbacks *pgcb)
{
unsigned long spinlock_save_flags;
spin_lock_irqsave(&pgcb_lock, spinlock_save_flags);
INIT_LIST_HEAD(&pgcb->list);
list_add(&pgcb->list, &pgcb_list);
spin_unlock_irqrestore(&pgcb_lock, spinlock_save_flags);
return pgcb;
}
static struct subsys *id_to_sys(unsigned int id)
{
return id < NR_SYSS ? &syss[id] : NULL;
}
/* TODO: remove this once it is done.*/
void __attribute__((weak)) print_enabled_clks_once(void)
{
}
u32 data_latched[16];
static void vdec_pre_busprotect(void)
{
data_latched[0] = clk_readl(CK_REG_0);
data_latched[1] = clk_readl(CK_REG_7);
data_latched[2] = clk_readl(VDEC_CG_CON);
data_latched[3] = clk_readl(VDEC_LARB1_CG_CON);
data_latched[4] = clk_readl(VDEC_REG0);
data_latched[5] = clk_readl(VDEC_REG1);
data_latched[6] = clk_readl(VDEC_REG2);
data_latched[7] = clk_readl(VDEC_REG3);
data_latched[8] = clk_readl(VDEC_REG4);
data_latched[9] = clk_readl(VDEC_REG5);
data_latched[10] = clk_readl(VDEC_REG6);
data_latched[11] = clk_readl(VDEC_REG7);
data_latched[12] = clk_readl(VDEC_REG8);
data_latched[13] = clk_readl(VDEC_REG9);
data_latched[14] = clk_readl(VDEC_REG10);
data_latched[15] = clk_readl(VDEC_REG11);
}
#ifdef CONFIG_MTK_RAM_CONSOLE
static void vdec_dump_regs(void)
{
int i;
void __iomem *GCON, *MISC, *VLD, *VLD_TOP, *MC, *HEVC_VLD, *HEVC_MV;
void __iomem *PP, *UFO;
/* HWT soon, so that no need to free them */
GCON = ioremap(0x16000000, PAGE_SIZE);
VLD = ioremap(0x16020000, PAGE_SIZE);
VLD_TOP = ioremap(0x16020800, PAGE_SIZE);
MC = ioremap(0x16021000, PAGE_SIZE);
HEVC_MV = ioremap(0x16023000, PAGE_SIZE);
PP = ioremap(0x16024000, PAGE_SIZE);
MISC = ioremap(0x16025000, PAGE_SIZE);
HEVC_VLD = ioremap(0x16028000, PAGE_SIZE);
UFO = ioremap(0x16000800, PAGE_SIZE);
pr_notice("===GCON===\n");
for (i = 0; i < 64; i += 4)
pr_notice("GCON[%d]:0x%x 0x%x 0x%x 0x%x\n", i,
clk_readl(GCON+i*4), clk_readl(GCON+(i+1)*4),
clk_readl(GCON+(i+2)*4), clk_readl(GCON+(i+3)*4));
pr_notice("===VLD===\n");
pr_notice("VLD[34]:0x%x\n", clk_readl(VLD+34*4));
pr_notice("VLD[35]:0x%x\n", clk_readl(VLD+35*4));
for (i = 36; i < 256; i += 4)
pr_notice("VLD[%d]:0x%x 0x%x 0x%x 0x%x\n", i,
clk_readl(VLD+i*4), clk_readl(VLD+(i+1)*4),
clk_readl(VLD+(i+2)*4), clk_readl(VLD+(i+3)*4));
pr_notice("===VLD_TOP===\n");
pr_notice("VLD_T[34]:0x%x\n", clk_readl(VLD_TOP+34*4));
pr_notice("VLD_T[35]:0x%x\n", clk_readl(VLD_TOP+35*4));
for (i = 36; i < 230; i += 4)
pr_notice("VLD_T[%d]:0x%x 0x%x 0x%x 0x%x\n", i,
clk_readl(VLD_TOP+i*4), clk_readl(VLD_TOP+(i+1)*4),
clk_readl(VLD_TOP+(i+2)*4),
clk_readl(VLD_TOP+(i+3)*4));
pr_notice("===MC===\n");
for (i = 0; i < 880; i += 4)
pr_notice("MC[%d]:0x%x 0x%x 0x%x 0x%x\n", i, clk_readl(MC+i*4),
clk_readl(MC+(i+1)*4), clk_readl(MC+(i+2)*4),
clk_readl(MC+(i+3)*4));
pr_notice("===HEVC_MV===\n");
for (i = 0; i < 256; i += 4)
pr_notice("HEVC_MV[%d]:0x%x 0x%x 0x%x 0x%x\n", i,
clk_readl(HEVC_MV+i*4), clk_readl(HEVC_MV+(i+1)*4),
clk_readl(HEVC_MV+(i+2)*4),
clk_readl(HEVC_MV+(i+3)*4));
pr_notice("===PP===\n");
for (i = 0; i < 1024; i += 4)
pr_notice("PP[%d]:0x%x 0x%x 0x%x 0x%x\n", i, clk_readl(PP+i*4),
clk_readl(PP+(i+1)*4), clk_readl(PP+(i+2)*4),
clk_readl(PP+(i+3)*4));
pr_notice("===MISC===\n");
for (i = 0; i < 104; i += 4)
pr_notice("MISC[%d]:0x%x 0x%x 0x%x 0x%x\n", i,
clk_readl(MISC+i*4), clk_readl(MISC+(i+1)*4),
clk_readl(MISC+(i+2)*4), clk_readl(MISC+(i+3)*4));
pr_notice("===HEVC_VLD===\n");
pr_notice("HEVC_VLD[0]:0x%x\n", clk_readl(HEVC_VLD+0*4));
pr_notice("HEVC_VLD[33]:0x%x\n", clk_readl(HEVC_VLD+33*4));
pr_notice("HEVC_VLD[34]:0x%x\n", clk_readl(HEVC_VLD+34*4));
pr_notice("HEVC_VLD[35]:0x%x\n", clk_readl(HEVC_VLD+35*4));
pr_notice("HEVC_VLD[36]:0x%x\n", clk_readl(HEVC_VLD+36*4));
pr_notice("HEVC_VLD[37]:0x%x\n", clk_readl(HEVC_VLD+37*4));
for (i = 40; i < 256; i += 4)
pr_notice("HEVC_VLD[%d]:0x%x 0x%x 0x%x 0x%x\n", i,
clk_readl(HEVC_VLD+i*4), clk_readl(HEVC_VLD+(i+1)*4),
clk_readl(HEVC_VLD+(i+2)*4),
clk_readl(HEVC_VLD+(i+3)*4));
pr_notice("===UFO===\n");
for (i = 0; i < 64; i += 4)
pr_notice("UFO[%d]:0x%x 0x%x 0x%x 0x%x\n", i,
clk_readl(UFO+i*4), clk_readl(UFO+(i+1)*4),
clk_readl(UFO+(i+2)*4), clk_readl(UFO+(i+3)*4));
}
#endif
enum dbg_id {
DBG_ID_MD1_BUS = 0,
DBG_ID_CONN_BUS,
DBG_ID_DPY_BUS,
DBG_ID_DIS_BUS,
DBG_ID_MFG_BUS,
DBG_ID_ISP_BUS,
DBG_ID_IFR_BUS,
DBG_ID_MFG_CORE0_BUS,
DBG_ID_MFG_CORE1_BUS,
DBG_ID_MFG_ASYNC_BUS,
DBG_ID_CAM_BUS,
DBG_ID_VENC_BUS,
DBG_ID_VDEC_BUS = 12,
DBG_ID_MD1_PWR = 13,
DBG_ID_CONN_PWR,
DBG_ID_DPY_PWR,
DBG_ID_DIS_PWR,
DBG_ID_MFG_PWR,
DBG_ID_ISP_PWR,
DBG_ID_IFR_PWR,
DBG_ID_MFG_CORE0_PWR,
DBG_ID_MFG_CORE1_PWR,
DBG_ID_MFG_ASYNC_PWR,
DBG_ID_CAM_PWR,
DBG_ID_VENC_PWR,
DBG_ID_VDEC_PWR,
DBG_ID_NUM = 26,
};
#define ID_MADK 0xFF000000
#define STA_MASK 0x00F00000
#define STEP_MASK 0x000000FF
#define INCREASE_STEPS \
do { DBG_STEP++; } while (0)
static int DBG_ID;
static int DBG_STA;
static int DBG_STEP;
/*
* ram console data0 define
* [31:24] : DBG_ID
* [23:20] : DBG_STA
* [7:0] : DBG_STEP
*/
static void ram_console_update(void)
{
#ifdef CONFIG_MTK_RAM_CONSOLE
struct pg_callbacks *pgcb;
unsigned long spinlock_save_flags;
u32 data[8] = {0x0};
u32 i = 0, j = 0;
static u32 pre_data;
static int k;
static bool print_once = true;
if (DBG_ID < 0 || DBG_ID >= DBG_ID_NUM)
return;
data[i] = ((DBG_ID << 24) & ID_MADK)
| ((DBG_STA << 20) & STA_MASK)
| (DBG_STEP & STEP_MASK);
data[++i] = clk_readl(INFRA_TOPAXI_PROTECTEN);
data[++i] = clk_readl(INFRA_TOPAXI_PROTECTEN_1);
data[++i] = clk_readl(INFRA_TOPAXI_PROTECTEN_STA1);
data[++i] = clk_readl(INFRA_TOPAXI_PROTECTEN_STA1_1);
data[++i] = clk_readl(PWR_STATUS);
data[++i] = clk_readl(PWR_STATUS_2ND);
data[++i] = clk_readl(INFRA_TOPAXI_SI3_STA);
if (pre_data == data[0])
k++;
else if (pre_data != data[0]) {
k = 0;
pre_data = data[0];
print_once = true;
}
if (k > 5000 && print_once) {
enum subsys_id id =
(enum subsys_id)(DBG_ID % (DBG_ID_NUM / 2));
print_once = false;
k = 0;
print_enabled_clks_once();
/* Release bus prot for connsys specifically */
if (DBG_ID == DBG_ID_CONN_BUS) {
if (DBG_STEP == 1 && DBG_STA == STA_POWER_DOWN) {
/* TINFO="Release bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR,
CONN_PROT_STEP1_0_MASK);
}
}
/* callback func in every subsys */
spin_lock_irqsave(&pgcb_lock, spinlock_save_flags);
list_for_each_entry_reverse(pgcb, &pgcb_list, list) {
if (pgcb->debug_dump)
pgcb->debug_dump(id);
}
spin_unlock_irqrestore(&pgcb_lock, spinlock_save_flags);
/* Restore(set) bus prot for connsys specifically */
if (DBG_ID == DBG_ID_CONN_BUS) {
if (DBG_STEP == 1 && DBG_STA == STA_POWER_DOWN) {
/* TINFO="Set bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET,
CONN_PROT_STEP1_0_MASK);
j = 0;
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& CONN_PROT_STEP1_0_ACK_MASK)
!= CONN_PROT_STEP1_0_ACK_MASK) {
udelay(1);
if (j > 1000)
break;
j++;
}
if (j > 1000)
DBG_STEP = CONN_TIMEOUT_STEP1;
else
DBG_STEP = CONN_TIMEOUT_RECOVERY;
data[0] = ((DBG_ID << 24) & ID_MADK)
| ((DBG_STA << 20) & STA_MASK)
| (DBG_STEP & STEP_MASK);
pre_data = data[0];
}
}
if (DBG_ID >= (DBG_ID_NUM / 2))
pr_notice("%s %s MTCMOS PWR hang at %s flow step %d\n",
"[clkmgr]",
syss[(DBG_ID - (DBG_ID_NUM / 2))].name,
DBG_STA ? "pwron":"pdn",
DBG_STEP);
else
pr_notice("%s %s MTCMOS BUS hang at %s flow step %d\n",
"[clkmgr]",
syss[DBG_ID].name,
DBG_STA ? "pwron":"pdn",
DBG_STEP);
for (j = 1; j <= i; j++)
pr_notice("%s: clk[%d] = 0x%x\n", __func__, j, data[j]);
pr_notice("INFRA_TOPAXI_SI0_STA =0x%x\n",
spm_read(INFRA_TOPAXI_SI0_STA));
pr_notice("INFRA_TOPAXI_SI1_STA =0x%x\n",
spm_read(INFRA_TOPAXI_SI1_STA));
pr_notice("INFRA_TOPAXI_SI2_STA =0x%x\n",
spm_read(INFRA_TOPAXI_SI2_STA));
pr_notice("INFRA_TOPAXI_SI3_STA =0x%x\n",
spm_read(INFRA_TOPAXI_SI3_STA));
pr_notice("INFRA_TOPAXI_SI4_STA =0x%x\n",
spm_read(INFRA_TOPAXI_SI4_STA));
pr_notice("INFRA_TOPAXI_MI_STA =0x%x\n",
spm_read(INFRA_TOPAXI_MI_STA));
pr_notice("INFRA_MCI_SI0_STA =0x%x\n",
spm_read(INFRA_MCI_SI0_STA));
pr_notice("INFRA_MCI_SI2_STA =0x%x\n",
spm_read(INFRA_MCI_SI2_STA));
for (j = 0; j < sizeof(data_latched)/sizeof(u32); j++)
pr_notice("datalatch[%d]=0x%x\n", j, data_latched[j]);
if (DBG_ID == DBG_ID_VDEC_BUS) {
pr_notice("CK_REG_0=0x%x\n", spm_read(CK_REG_0));
pr_notice("CK_REG_7=0x%x\n", spm_read(CK_REG_7));
pr_notice("VDEC_CG_CON=0x%x\n", spm_read(VDEC_CG_CON));
pr_notice("VDEC_LARB1_CG_CON=0x%x\n",
spm_read(VDEC_LARB1_CG_CON));
pr_notice("VENC_110=0x%x\n", spm_read(VDEC_REG0));
pr_notice("VENC_114=0x%x\n", spm_read(VDEC_REG1));
pr_notice("VENC_118=0x%x\n", spm_read(VDEC_REG2));
pr_notice("VENC_11C=0x%x\n", spm_read(VDEC_REG3));
pr_notice("VENC_120=0x%x\n", spm_read(VDEC_REG4));
pr_notice("VENC_124=0x%x\n", spm_read(VDEC_REG5));
pr_notice("VENC_128=0x%x\n", spm_read(VDEC_REG6));
pr_notice("VENC_12C=0x%x\n", spm_read(VDEC_REG7));
pr_notice("VENC_130=0x%x\n", spm_read(VDEC_REG8));
pr_notice("VENC_134=0x%x\n", spm_read(VDEC_REG9));
pr_notice("VENC_138=0x%x\n", spm_read(VDEC_REG10));
pr_notice("VENC_13C=0x%x\n", spm_read(VDEC_REG11));
vdec_dump_regs();
}
}
for (j = 0; j <= i; j++)
aee_rr_rec_clk(j, data[j]);
/*todo: add each domain's debug register to ram console*/
#endif
}
/* auto-gen begin*/
int spm_mtcmos_ctrl_md1_bus_prot(int state)
{
int err = 0;
DBG_ID = DBG_ID_MD1_BUS;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off MD1" */
/* TINFO="Set bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, MD1_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& MD1_PROT_STEP1_0_ACK_MASK)
!= MD1_PROT_STEP1_0_ACK_MASK)
ram_console_update();
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, MD1_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& MD1_PROT_STEP2_0_ACK_MASK)
!= MD1_PROT_STEP2_0_ACK_MASK)
ram_console_update();
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 1" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_SET, MD1_PROT_STEP2_1_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1_1)
& MD1_PROT_STEP2_1_ACK_MASK)
!= MD1_PROT_STEP2_1_ACK_MASK)
ram_console_update();
#endif
} else { /* STA_POWER_ON */
/* TINFO="Release bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR, MD1_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step2 : 1" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_CLR, MD1_PROT_STEP2_1_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
*releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR, MD1_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Finish to turn on MD1" */
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_md1_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_MD1_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="MD_EXTRA_PWR_CON[0]=1"*/
spm_write(MD_EXTRA_PWR_CON,
spm_read(MD_EXTRA_PWR_CON) | (0x1 << 0));
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(MD1_PWR_CON,
spm_read(MD1_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 1" */
spm_write(MD1_PWR_CON,
spm_read(MD1_PWR_CON) | PWR_ISO);
/* TINFO="MD_SRAM_ISO_CON[0]=0"*/
spm_write(MD_SRAM_ISO_CON,
spm_read(MD_SRAM_ISO_CON) & ~(0x1 << 0));
/* TINFO="Set SRAM_PDN = 1" */
spm_write(MD1_PWR_CON, spm_read(MD1_PWR_CON) | MD1_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
#endif
/* TINFO="Set PWR_ON = 0" */
spm_write(MD1_PWR_CON, spm_read(MD1_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(MD1_PWR_CON, spm_read(MD1_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & MD1_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & MD1_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Finish to turn off MD1" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on MD1" */
/* TINFO="Set PWR_RST_B = 0" */
spm_write(MD1_PWR_CON, spm_read(MD1_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 1" */
spm_write(MD1_PWR_CON, spm_read(MD1_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(MD1_PWR_CON, spm_read(MD1_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & MD1_PWR_STA_MASK)
!= MD1_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & MD1_PWR_STA_MASK)
!= MD1_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set SRAM_PDN = 0" */
spm_write(MD1_PWR_CON, spm_read(MD1_PWR_CON) & ~(0x1 << 8));
/* TINFO="MD_SRAM_ISO_CON[0]=1"*/
spm_write(MD_SRAM_ISO_CON,
spm_read(MD_SRAM_ISO_CON) | (0x1 << 0));
/* TINFO="Set PWR_ISO = 0" */
spm_write(MD1_PWR_CON, spm_read(MD1_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(MD1_PWR_CON, spm_read(MD1_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(MD1_PWR_CON, spm_read(MD1_PWR_CON) | PWR_RST_B);
/* TINFO="MD_EXTRA_PWR_CON[0]=0"*/
spm_write(MD_EXTRA_PWR_CON,
spm_read(MD_EXTRA_PWR_CON) & ~(0x1 << 0));
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_conn_bus_prot(int state)
{
int err = 0;
DBG_ID = DBG_ID_CONN_BUS;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off CONN" */
/* TINFO="Set bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, CONN_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& CONN_PROT_STEP1_0_ACK_MASK)
!= CONN_PROT_STEP1_0_ACK_MASK)
ram_console_update();
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step1 : 1" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_SET,
CONN_PROT_STEP1_1_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1_1)
& CONN_PROT_STEP1_1_ACK_MASK)
!= CONN_PROT_STEP1_1_ACK_MASK) {
ram_console_update();
if (DBG_STEP == CONN_TIMEOUT_RECOVERY)
break;
}
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, CONN_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& CONN_PROT_STEP2_0_ACK_MASK)
!= CONN_PROT_STEP2_0_ACK_MASK)
ram_console_update();
#endif
} else { /* STA_POWER_ON */
/* TINFO="Release bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR,
CONN_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR,
CONN_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step1 : 1" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_CLR,
CONN_PROT_STEP1_1_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Finish to turn on CONN" */
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_conn_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_CONN_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Set PWR_ISO = 1" */
spm_write(CONN_PWR_CON, spm_read(CONN_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(CONN_PWR_CON,
spm_read(CONN_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(CONN_PWR_CON,
spm_read(CONN_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(CONN_PWR_CON,
spm_read(CONN_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(CONN_PWR_CON,
spm_read(CONN_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & CONN_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & CONN_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
#endif
/* TINFO="Finish to turn off CONN" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on CONN" */
/* TINFO="Set PWR_ON = 1" */
spm_write(CONN_PWR_CON, spm_read(CONN_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(CONN_PWR_CON,
spm_read(CONN_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & CONN_PWR_STA_MASK)
!= CONN_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & CONN_PWR_STA_MASK)
!= CONN_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(CONN_PWR_CON,
spm_read(CONN_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(CONN_PWR_CON, spm_read(CONN_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(CONN_PWR_CON, spm_read(CONN_PWR_CON) | PWR_RST_B);
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_dpy_bus_prot(int state)
{
int err = 0;
DBG_ID = DBG_ID_DPY_BUS;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off DPY" */
/* TINFO="Set bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, DPY_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& DPY_PROT_STEP1_0_ACK_MASK)
!= DPY_PROT_STEP1_0_ACK_MASK)
ram_console_update();
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step1 : 1" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_SET, DPY_PROT_STEP1_1_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1_1)
& DPY_PROT_STEP1_1_ACK_MASK)
!= DPY_PROT_STEP1_1_ACK_MASK)
ram_console_update();
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, DPY_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& DPY_PROT_STEP2_0_ACK_MASK)
!= DPY_PROT_STEP2_0_ACK_MASK)
ram_console_update();
INCREASE_STEPS;
#endif
} else { /* STA_POWER_ON */
/* TINFO="Release bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR, DPY_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR, DPY_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step1 : 1" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_CLR, DPY_PROT_STEP1_1_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Finish to turn on DPY" */
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_dpy_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_DPY_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Set SRAM_PDN = 1" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) | DPY_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until DPY_SRAM_PDN_ACK = 1" */
while ((spm_read(DPY_PWR_CON) & DPY_SRAM_PDN_ACK)
!= DPY_SRAM_PDN_ACK)
ram_console_update();
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_ISO = 1" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & DPY_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & DPY_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Finish to turn off DPY" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on DPY" */
/* TINFO="Set PWR_ON = 1" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & DPY_PWR_STA_MASK)
!= DPY_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & DPY_PWR_STA_MASK)
!= DPY_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) | PWR_RST_B);
/* TINFO="Set SRAM_PDN = 0" */
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) & ~(0x1 << 8));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until DPY_SRAM_PDN_ACK_BIT0 = 0" */
while (spm_read(DPY_PWR_CON) & DPY_SRAM_PDN_ACK_BIT0)
ram_console_update();
INCREASE_STEPS;
#endif
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) & ~(0x1 << 9));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until DPY_SRAM_PDN_ACK_BIT1 = 0" */
while (spm_read(DPY_PWR_CON) & DPY_SRAM_PDN_ACK_BIT1)
ram_console_update();
INCREASE_STEPS;
#endif
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) & ~(0x1 << 10));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until DPY_SRAM_PDN_ACK_BIT2 = 0" */
while (spm_read(DPY_PWR_CON) & DPY_SRAM_PDN_ACK_BIT2)
ram_console_update();
INCREASE_STEPS;
#endif
spm_write(DPY_PWR_CON, spm_read(DPY_PWR_CON) & ~(0x1 << 11));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until DPY_SRAM_PDN_ACK_BIT3 = 0" */
while (spm_read(DPY_PWR_CON) & DPY_SRAM_PDN_ACK_BIT3)
ram_console_update();
INCREASE_STEPS;
#endif
}
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_dis_bus_prot(int state)
{
int err = 0;
DBG_ID = DBG_ID_DIS_BUS;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off DIS" */
/* TINFO="Set bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_SET, DIS_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1_1)
& DIS_PROT_STEP1_0_ACK_MASK)
!= DIS_PROT_STEP1_0_ACK_MASK) {
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_SET, DIS_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1_1)
& DIS_PROT_STEP2_0_ACK_MASK)
!= DIS_PROT_STEP2_0_ACK_MASK) {
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step3 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, DIS_PROT_STEP3_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& DIS_PROT_STEP3_0_ACK_MASK)
!= DIS_PROT_STEP3_0_ACK_MASK) {
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step4 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, DIS_PROT_STEP4_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& DIS_PROT_STEP4_0_ACK_MASK)
!= DIS_PROT_STEP4_0_ACK_MASK) {
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set SRAM_PDN = 1" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) | DIS_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until DIS_SRAM_PDN_ACK = 1" */
while ((spm_read(DIS_PWR_CON) & DIS_SRAM_PDN_ACK)
!= DIS_SRAM_PDN_ACK)
ram_console_update();
/* Need hf_fmm_ck for SRAM PDN delay IP. */
INCREASE_STEPS;
#endif
} else { /* STA_POWER_ON */
/* TINFO="Set SRAM_PDN = 0" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) & ~(0x1 << 8));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until DIS_SRAM_PDN_ACK_BIT0 = 0" */
while (spm_read(DIS_PWR_CON) & DIS_SRAM_PDN_ACK_BIT0)
ram_console_update();
/* Need hf_fmm_ck for SRAM PDN delay IP. */
INCREASE_STEPS;
#endif
/* TINFO="Release bus protect - step4 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR, DIS_PROT_STEP4_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step3 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR, DIS_PROT_STEP3_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_CLR, DIS_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_CLR, DIS_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Finish to turn on DIS" */
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_dis_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_DIS_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Set PWR_ISO = 1" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & DIS_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & DIS_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Finish to turn off DIS" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on DIS" */
/* TINFO="Set PWR_ON = 1" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & DIS_PWR_STA_MASK)
!= DIS_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & DIS_PWR_STA_MASK)
!= DIS_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(DIS_PWR_CON, spm_read(DIS_PWR_CON) | PWR_RST_B);
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_mfg_bus_prot(int state)
{
int err = 0;
DBG_ID = DBG_ID_MFG_BUS;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off MFG" */
/* TINFO="Set bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, MFG_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& MFG_PROT_STEP1_0_ACK_MASK)
!= MFG_PROT_STEP1_0_ACK_MASK) {
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, MFG_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& MFG_PROT_STEP2_0_ACK_MASK)
!= MFG_PROT_STEP2_0_ACK_MASK) {
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set SRAM_PDN = 1" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) | MFG_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until MFG_SRAM_PDN_ACK = 1" */
while ((spm_read(MFG_PWR_CON) & MFG_SRAM_PDN_ACK)
!= MFG_SRAM_PDN_ACK)
ram_console_update();
/* Need f_fmfg_core_ck for SRAM PDN delay IP. */
#endif
} else { /* STA_POWER_ON */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) & ~(0x1 << 8));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until MFG_SRAM_PDN_ACK_BIT0 = 0" */
while (spm_read(MFG_PWR_CON) & MFG_SRAM_PDN_ACK_BIT0)
ram_console_update();
/* Need f_fmfg_core_ck for SRAM PDN delay IP. */
INCREASE_STEPS;
#endif
/* TINFO="Release bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR, MFG_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR, MFG_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Finish to turn on MFG" */
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_mfg_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_MFG_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Set PWR_ISO = 1" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & MFG_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & MFG_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
#endif
/* TINFO="Finish to turn off MFG" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on MFG" */
/* TINFO="Set PWR_ON = 1" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & MFG_PWR_STA_MASK)
!= MFG_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & MFG_PWR_STA_MASK)
!= MFG_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(MFG_PWR_CON, spm_read(MFG_PWR_CON) | PWR_RST_B);
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_isp_bus_prot(int state)
{
int err = 0;
DBG_ID = DBG_ID_ISP_BUS;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off ISP" */
/* TINFO="Set bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_SET, ISP_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1_1)
& ISP_PROT_STEP1_0_ACK_MASK)
!= ISP_PROT_STEP1_0_ACK_MASK) {
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 0" */
spm_write(SMI_COMMON_SMI_CLAMP_SET, ISP_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(SMI_COMMON_SMI_CLAMP)
& ISP_PROT_STEP2_0_ACK_MASK)
!= ISP_PROT_STEP2_0_ACK_MASK) {
ram_console_update();
}
#endif
/* TINFO="Set SRAM_PDN = 1" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) | ISP_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until ISP_SRAM_PDN_ACK = 1" */
while ((spm_read(ISP_PWR_CON) & ISP_SRAM_PDN_ACK)
!= ISP_SRAM_PDN_ACK)
ram_console_update();
/* Need hf_fmm_ck for SRAM PDN delay IP. */
INCREASE_STEPS;
#endif
} else { /* STA_POWER_ON */
/* TINFO="Set SRAM_PDN = 0" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) & ~(0x1 << 8));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until ISP_SRAM_PDN_ACK_BIT0 = 0" */
while (spm_read(ISP_PWR_CON) & ISP_SRAM_PDN_ACK_BIT0)
ram_console_update();
/* Need hf_fmm_ck for SRAM PDN delay IP. */
INCREASE_STEPS;
#endif
/* TINFO="Release bus protect - step2 : 0" */
spm_write(SMI_COMMON_SMI_CLAMP_CLR, ISP_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_CLR, ISP_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Finish to turn on ISP" */
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_isp_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_ISP_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Set PWR_ISO = 1" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & ISP_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & ISP_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
#endif
/* TINFO="Finish to turn off ISP" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on ISP" */
/* TINFO="Set PWR_ON = 1" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & ISP_PWR_STA_MASK)
!= ISP_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & ISP_PWR_STA_MASK)
!= ISP_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(ISP_PWR_CON, spm_read(ISP_PWR_CON) | PWR_RST_B);
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_ifr_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_IFR_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off IFR" */
/* TINFO="Set SRAM_PDN = 1" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) | IFR_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until IFR_SRAM_PDN_ACK = 1" */
while ((spm_read(IFR_PWR_CON) & IFR_SRAM_PDN_ACK)
!= IFR_SRAM_PDN_ACK) {
/* SRAM PDN delay IP clock is 26MHz.
* Print SRAM control and ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_ISO = 1" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & IFR_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & IFR_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Finish to turn off IFR" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on IFR" */
/* TINFO="Set PWR_ON = 1" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & IFR_PWR_STA_MASK)
!= IFR_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & IFR_PWR_STA_MASK)
!= IFR_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) | PWR_RST_B);
/* TINFO="Set SRAM_PDN = 0" */
spm_write(IFR_PWR_CON, spm_read(IFR_PWR_CON) & ~(0x1 << 8));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until IFR_SRAM_PDN_ACK_BIT0 = 0" */
while (spm_read(IFR_PWR_CON) & IFR_SRAM_PDN_ACK_BIT0) {
/* SRAM PDN delay IP clock is 26MHz.
* Print SRAM control and ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Finish to turn on IFR" */
}
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_mfg_core0_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_MFG_CORE0_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off MFG_CORE0" */
/* TINFO="Set SRAM_PDN = 1" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) | MFG_CORE0_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until MFG_CORE0_SRAM_PDN_ACK = 1" */
while ((spm_read(MFG_CORE0_PWR_CON)
& MFG_CORE0_SRAM_PDN_ACK)
!= MFG_CORE0_SRAM_PDN_ACK) {
ram_console_update();/* n/a */
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_ISO = 1" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & MFG_CORE0_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & MFG_CORE0_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Finish to turn off MFG_CORE0" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on MFG_CORE0" */
/* TINFO="Set PWR_ON = 1" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & MFG_CORE0_PWR_STA_MASK)
!= MFG_CORE0_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & MFG_CORE0_PWR_STA_MASK)
!= MFG_CORE0_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) | PWR_RST_B);
/* TINFO="Set SRAM_PDN = 0" */
spm_write(MFG_CORE0_PWR_CON,
spm_read(MFG_CORE0_PWR_CON) & ~(0x1 << 8));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until MFG_CORE0_SRAM_PDN_ACK_BIT0 = 0" */
while (spm_read(MFG_CORE0_PWR_CON)
& MFG_CORE0_SRAM_PDN_ACK_BIT0)
ram_console_update();
INCREASE_STEPS;
#endif
/* TINFO="Finish to turn on MFG_CORE0" */
}
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_mfg_core1_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_MFG_CORE1_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off MFG_CORE1" */
/* TINFO="Set SRAM_PDN = 1" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) | MFG_CORE1_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until MFG_CORE1_SRAM_PDN_ACK = 1" */
while ((spm_read(MFG_CORE1_PWR_CON)
& MFG_CORE1_SRAM_PDN_ACK)
!= MFG_CORE1_SRAM_PDN_ACK) {
ram_console_update();/* n/a */
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_ISO = 1" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & MFG_CORE1_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & MFG_CORE1_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Finish to turn off MFG_CORE1" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on MFG_CORE1" */
/* TINFO="Set PWR_ON = 1" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & MFG_CORE1_PWR_STA_MASK)
!= MFG_CORE1_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & MFG_CORE1_PWR_STA_MASK)
!= MFG_CORE1_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) | PWR_RST_B);
/* TINFO="Set SRAM_PDN = 0" */
spm_write(MFG_CORE1_PWR_CON,
spm_read(MFG_CORE1_PWR_CON) & ~(0x1 << 8));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until MFG_CORE1_SRAM_PDN_ACK_BIT0 = 0" */
while (spm_read(MFG_CORE1_PWR_CON)
& MFG_CORE1_SRAM_PDN_ACK_BIT0)
ram_console_update();
INCREASE_STEPS;
#endif
/* TINFO="Finish to turn on MFG_CORE1" */
}
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_mfg_async_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_MFG_ASYNC_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off MFG_ASYNC" */
#ifndef IGNORE_MTCMOS_CHECK
#endif
/* TINFO="Set PWR_ISO = 1" */
spm_write(MFG_ASYNC_PWR_CON,
spm_read(MFG_ASYNC_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(MFG_ASYNC_PWR_CON,
spm_read(MFG_ASYNC_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(MFG_ASYNC_PWR_CON,
spm_read(MFG_ASYNC_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(MFG_ASYNC_PWR_CON,
spm_read(MFG_ASYNC_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(MFG_ASYNC_PWR_CON,
spm_read(MFG_ASYNC_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & MFG_ASYNC_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & MFG_ASYNC_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Finish to turn off MFG_ASYNC" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on MFG_ASYNC" */
/* TINFO="Set PWR_ON = 1" */
spm_write(MFG_ASYNC_PWR_CON,
spm_read(MFG_ASYNC_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(MFG_ASYNC_PWR_CON,
spm_read(MFG_ASYNC_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & MFG_ASYNC_PWR_STA_MASK)
!= MFG_ASYNC_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & MFG_ASYNC_PWR_STA_MASK)
!= MFG_ASYNC_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(MFG_ASYNC_PWR_CON,
spm_read(MFG_ASYNC_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(MFG_ASYNC_PWR_CON,
spm_read(MFG_ASYNC_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(MFG_ASYNC_PWR_CON,
spm_read(MFG_ASYNC_PWR_CON) | PWR_RST_B);
#ifndef IGNORE_MTCMOS_CHECK
#endif
/* TINFO="Finish to turn on MFG_ASYNC" */
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_cam_bus_prot(int state)
{
int err = 0;
DBG_ID = DBG_ID_CAM_BUS;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off CAM" */
/* TINFO="Set bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_SET, CAM_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1_1)
& CAM_PROT_STEP1_0_ACK_MASK)
!= CAM_PROT_STEP1_0_ACK_MASK) {
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_SET, CAM_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1)
& CAM_PROT_STEP2_0_ACK_MASK)
!= CAM_PROT_STEP2_0_ACK_MASK) {
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 1" */
spm_write(SMI_COMMON_SMI_CLAMP_SET, CAM_PROT_STEP2_1_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(SMI_COMMON_SMI_CLAMP)
& CAM_PROT_STEP2_1_ACK_MASK)
!= CAM_PROT_STEP2_1_ACK_MASK) {
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set SRAM_PDN = 1" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) | CAM_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until CAM_SRAM_PDN_ACK = 1" */
while ((spm_read(CAM_PWR_CON) & CAM_SRAM_PDN_ACK)
!= CAM_SRAM_PDN_ACK)
ram_console_update();
#endif
} else { /* STA_POWER_ON */
/* TINFO="Set SRAM_PDN = 0" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) & ~(0x1 << 8));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until CAM_SRAM_PDN_ACK_BIT0 = 0" */
while (spm_read(CAM_PWR_CON) & CAM_SRAM_PDN_ACK_BIT0)
ram_console_update();
INCREASE_STEPS;
#endif
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) & ~(0x1 << 9));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until CAM_SRAM_PDN_ACK_BIT1 = 0" */
while (spm_read(CAM_PWR_CON) & CAM_SRAM_PDN_ACK_BIT1)
ram_console_update();
INCREASE_STEPS;
#endif
/* TINFO="Release bus protect - step2 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_CLR, CAM_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step2 : 1" */
spm_write(SMI_COMMON_SMI_CLAMP_CLR, CAM_PROT_STEP2_1_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_CLR, CAM_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Finish to turn on CAM" */
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_cam_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_CAM_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Set PWR_ISO = 1" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & CAM_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & CAM_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
#endif
/* TINFO="Finish to turn off CAM" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on CAM" */
/* TINFO="Set PWR_ON = 1" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & CAM_PWR_STA_MASK)
!= CAM_PWR_STA_MASK)
|| ((spm_read(PWR_STATUS_2ND) & CAM_PWR_STA_MASK)
!= CAM_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack.
* Print SRAM / MTCMOS control and
* PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(CAM_PWR_CON, spm_read(CAM_PWR_CON) | PWR_RST_B);
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_ven_bus_prot(int state)
{
int err = 0;
DBG_ID = DBG_ID_VENC_BUS;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Start to turn off VEN" */
/* TINFO="Set bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_SET, VEN_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1_1) &
VEN_PROT_STEP1_0_ACK_MASK) !=
VEN_PROT_STEP1_0_ACK_MASK) {
/* avoid warning */
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 0" */
spm_write(SMI_COMMON_SMI_CLAMP_SET, VEN_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(SMI_COMMON_SMI_CLAMP) &
VEN_PROT_STEP2_0_ACK_MASK) !=
VEN_PROT_STEP2_0_ACK_MASK) {
/* avoid warning */
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set SRAM_PDN = 1" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) | VEN_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until VEN_SRAM_PDN_ACK = 1" */
while ((spm_read(VEN_PWR_CON) & VEN_SRAM_PDN_ACK)
!= VEN_SRAM_PDN_ACK) {
/* Need hf_fmm_ck for SRAM PDN delay IP. */
ram_console_update();
}
#endif
//////// CUT
} else { /* STA_POWER_ON */
//////// CUT
/* TINFO="Set SRAM_PDN = 0" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) & ~(0x1 << 8));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until VEN_SRAM_PDN_ACK_BIT0 = 0" */
while (spm_read(VEN_PWR_CON) & VEN_SRAM_PDN_ACK_BIT0) {
/* Need hf_fmm_ck for SRAM PDN delay IP. */
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Release bus protect - step2 : 0" */
spm_write(SMI_COMMON_SMI_CLAMP_CLR, VEN_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Release bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_CLR, VEN_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after
* releasing protect has been ignored
*/
#endif
/* TINFO="Finish to turn on VEN" */
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_ven_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_VENC_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
//////// CUT
/* TINFO="Set PWR_ISO = 1" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & VEN_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & VEN_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack. Print
* SRAM / MTCMOS control and PWR_ACK for debug.
*/
ram_console_update();
}
#endif
/* TINFO="Finish to turn off VEN" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on VEN" */
/* TINFO="Set PWR_ON = 1" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & VEN_PWR_STA_MASK) !=
VEN_PWR_STA_MASK) || ((spm_read(PWR_STATUS_2ND) &
VEN_PWR_STA_MASK) != VEN_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack. Print
* SRAM/MTCMOS control and PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(VEN_PWR_CON, spm_read(VEN_PWR_CON) | PWR_RST_B);
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_vde_bus_prot(int state)
{
int err = 0;
DBG_ID = DBG_ID_VDEC_BUS;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
vdec_pre_busprotect();
/* TINFO="Start to turn off VDE" */
/* TINFO="Set bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_SET, VDE_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(INFRA_TOPAXI_PROTECTEN_STA1_1) &
VDE_PROT_STEP1_0_ACK_MASK) !=
VDE_PROT_STEP1_0_ACK_MASK) {
/* avoid warning */
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set bus protect - step2 : 0" */
spm_write(SMI_COMMON_SMI_CLAMP_SET, VDE_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
while ((spm_read(SMI_COMMON_SMI_CLAMP) &
VDE_PROT_STEP2_0_ACK_MASK) !=
VDE_PROT_STEP2_0_ACK_MASK) {
/* avoid warning */
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set SRAM_PDN = 1" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) | VDE_SRAM_PDN);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until VDE_SRAM_PDN_ACK = 1" */
while ((spm_read(VDE_PWR_CON) & VDE_SRAM_PDN_ACK) !=
VDE_SRAM_PDN_ACK) {
/* avoid warning */
ram_console_update();
}
#endif
} else { /* STA_POWER_ON */
/* TINFO="Set SRAM_PDN = 0" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) & ~(0x1 << 8));
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until VDE_SRAM_PDN_ACK_BIT0 = 0" */
while (spm_read(VDE_PWR_CON) & VDE_SRAM_PDN_ACK_BIT0) {
/* */
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Release bus protect - step2 : 0" */
spm_write(SMI_COMMON_SMI_CLAMP_CLR, VDE_PROT_STEP2_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after releasing protect
* has been ignored.
*/
#endif
/* TINFO="Release bus protect - step1 : 0" */
spm_write(INFRA_TOPAXI_PROTECTEN_1_CLR, VDE_PROT_STEP1_0_MASK);
#ifndef IGNORE_MTCMOS_CHECK
/* Note that this protect ack check after releasing protect
* has been ignored
*/
#endif
/* TINFO="Finish to turn on VDE" */
}
INCREASE_STEPS;
ram_console_update();
return err;
}
int spm_mtcmos_ctrl_vde_pwr(int state)
{
int err = 0;
DBG_ID = DBG_ID_VDEC_PWR;
DBG_STA = state;
DBG_STEP = 0;
/* TINFO="enable SPM register control" */
if (state == STA_POWER_DOWN) {
/* TINFO="Set PWR_ISO = 1" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) | PWR_ISO);
/* TINFO="Set PWR_CLK_DIS = 1" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) | PWR_CLK_DIS);
/* TINFO="Set PWR_RST_B = 0" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) & ~PWR_RST_B);
/* TINFO="Set PWR_ON = 0" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) & ~PWR_ON);
/* TINFO="Set PWR_ON_2ND = 0" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) & ~PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 0 and PWR_STATUS_2ND = 0" */
while ((spm_read(PWR_STATUS) & VDE_PWR_STA_MASK)
|| (spm_read(PWR_STATUS_2ND) & VDE_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack. Print
* SRAM / MTCMOS control and PWR_ACK for debug.
*/
ram_console_update();
}
#endif
/* TINFO="Finish to turn off VDE" */
} else { /* STA_POWER_ON */
/* TINFO="Start to turn on VDE" */
/* TINFO="Set PWR_ON = 1" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) | PWR_ON);
/* TINFO="Set PWR_ON_2ND = 1" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) | PWR_ON_2ND);
#ifndef IGNORE_MTCMOS_CHECK
/* TINFO="Wait until PWR_STATUS = 1 and PWR_STATUS_2ND = 1" */
while (((spm_read(PWR_STATUS) & VDE_PWR_STA_MASK) !=
VDE_PWR_STA_MASK) || ((spm_read(PWR_STATUS_2ND) &
VDE_PWR_STA_MASK) != VDE_PWR_STA_MASK)) {
/* No logic between pwr_on and pwr_ack. Print
* SRAM / MTCMOS control and PWR_ACK for debug.
*/
ram_console_update();
}
INCREASE_STEPS;
#endif
/* TINFO="Set PWR_CLK_DIS = 0" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) & ~PWR_CLK_DIS);
/* TINFO="Set PWR_ISO = 0" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) & ~PWR_ISO);
/* TINFO="Set PWR_RST_B = 1" */
spm_write(VDE_PWR_CON, spm_read(VDE_PWR_CON) | PWR_RST_B);
}
INCREASE_STEPS;
ram_console_update();
return err;
}
/* auto-gen end*/
static int MD1_sys_prepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_md1_bus_prot(STA_POWER_ON);
}
static int MD1_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_md1_pwr(STA_POWER_ON);
}
static int CONN_sys_prepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_conn_bus_prot(STA_POWER_ON);
}
static int CONN_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_conn_pwr(STA_POWER_ON);
}
static int DPY_sys_prepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_dpy_bus_prot(STA_POWER_ON);
}
static int DPY_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_dpy_pwr(STA_POWER_ON);
}
static int DIS_sys_prepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_dis_bus_prot(STA_POWER_ON);
}
static int DIS_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_dis_pwr(STA_POWER_ON);
}
static int MFG_sys_prepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_mfg_bus_prot(STA_POWER_ON);
}
static int MFG_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_mfg_pwr(STA_POWER_ON);
}
static int ISP_sys_prepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_isp_bus_prot(STA_POWER_ON);
}
static int ISP_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_isp_pwr(STA_POWER_ON);
}
static int IFR_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_ifr_pwr(STA_POWER_ON);
}
static int MFG_CORE0_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_mfg_core0_pwr(STA_POWER_ON);
}
static int MFG_CORE1_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_mfg_core1_pwr(STA_POWER_ON);
}
static int MFG_ASYNC_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_mfg_async_pwr(STA_POWER_ON);
}
static int CAM_sys_prepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_cam_bus_prot(STA_POWER_ON);
}
static int CAM_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_cam_pwr(STA_POWER_ON);
}
static int VENC_sys_prepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_ven_bus_prot(STA_POWER_ON);
}
static int VENC_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_ven_pwr(STA_POWER_ON);
}
static int VDEC_sys_prepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_vde_bus_prot(STA_POWER_ON);
}
static int VDEC_sys_enable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_vde_pwr(STA_POWER_ON);
}
static int MD1_sys_unprepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_md1_bus_prot(STA_POWER_DOWN);
}
static int MD1_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_md1_pwr(STA_POWER_DOWN);
}
static int CONN_sys_unprepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_conn_bus_prot(STA_POWER_DOWN);
}
static int CONN_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_conn_pwr(STA_POWER_DOWN);
}
static int DPY_sys_unprepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_dpy_bus_prot(STA_POWER_DOWN);
}
static int DPY_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_dpy_pwr(STA_POWER_DOWN);
}
static int DIS_sys_unprepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_dis_bus_prot(STA_POWER_DOWN);
}
static int DIS_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_dis_pwr(STA_POWER_DOWN);
}
static int MFG_sys_unprepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_mfg_bus_prot(STA_POWER_DOWN);
}
static int MFG_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_mfg_pwr(STA_POWER_DOWN);
}
static int ISP_sys_unprepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_isp_bus_prot(STA_POWER_DOWN);
}
static int ISP_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_isp_pwr(STA_POWER_DOWN);
}
static int IFR_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_ifr_pwr(STA_POWER_DOWN);
}
static int MFG_CORE0_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_mfg_core0_pwr(STA_POWER_DOWN);
}
static int MFG_CORE1_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_mfg_core1_pwr(STA_POWER_DOWN);
}
static int MFG_ASYNC_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_mfg_async_pwr(STA_POWER_DOWN);
}
static int CAM_sys_unprepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_cam_bus_prot(STA_POWER_DOWN);
}
static int CAM_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_cam_pwr(STA_POWER_DOWN);
}
static int VENC_sys_unprepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_ven_bus_prot(STA_POWER_DOWN);
}
static int VENC_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_ven_pwr(STA_POWER_DOWN);
}
static int VDEC_sys_unprepare_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_vde_bus_prot(STA_POWER_DOWN);
}
static int VDEC_sys_disable_op(struct subsys *sys)
{
/*pr_debug("[CCF] %s\r\n", __func__); */
return spm_mtcmos_ctrl_vde_pwr(STA_POWER_DOWN);
}
static int sys_get_state_op(struct subsys *sys)
{
unsigned int sta = clk_readl(PWR_STATUS);
unsigned int sta_s = clk_readl(PWR_STATUS_2ND);
return (sta & sys->sta_mask) && (sta_s & sys->sta_mask);
}
#if 0
static int mfg_get_state_op(struct subsys *sys)
{
if ((spm_read(MFG_PWR_CON) & PWR_ON) &&
(spm_read(MFG_PWR_CON) & PWR_ON_2ND))
return 1;
else
return 0;
}
#endif
static struct subsys_ops MD1_sys_ops = {
.prepare = MD1_sys_prepare_op,
.unprepare = MD1_sys_unprepare_op,
.enable = MD1_sys_enable_op,
.disable = MD1_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops CONN_sys_ops = {
.prepare = CONN_sys_prepare_op,
.unprepare = CONN_sys_unprepare_op,
.enable = CONN_sys_enable_op,
.disable = CONN_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops DPY_sys_ops = {
.prepare = DPY_sys_prepare_op,
.unprepare = DPY_sys_unprepare_op,
.enable = DPY_sys_enable_op,
.disable = DPY_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops DIS_sys_ops = {
.prepare = DIS_sys_prepare_op,
.unprepare = DIS_sys_unprepare_op,
.enable = DIS_sys_enable_op,
.disable = DIS_sys_disable_op,
/*.get_state = sys_get_state_op,*/
.get_state = sys_get_state_op,
};
static struct subsys_ops MFG_sys_ops = {
.prepare = MFG_sys_prepare_op,
.unprepare = MFG_sys_unprepare_op,
.enable = MFG_sys_enable_op,
.disable = MFG_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops ISP_sys_ops = {
.prepare = ISP_sys_prepare_op,
.unprepare = ISP_sys_unprepare_op,
.enable = ISP_sys_enable_op,
.disable = ISP_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops IFR_sys_ops = {
.prepare = NULL,
.unprepare = NULL,
.enable = IFR_sys_enable_op,
.disable = IFR_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops MFG_CORE0_sys_ops = {
.prepare = NULL,
.unprepare = NULL,
.enable = MFG_CORE0_sys_enable_op,
.disable = MFG_CORE0_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops MFG_CORE1_sys_ops = {
.prepare = NULL,
.unprepare = NULL,
.enable = MFG_CORE1_sys_enable_op,
.disable = MFG_CORE1_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops MFG_ASYNC_sys_ops = {
.prepare = NULL,
.unprepare = NULL,
.enable = MFG_ASYNC_sys_enable_op,
.disable = MFG_ASYNC_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops CAM_sys_ops = {
.prepare = CAM_sys_prepare_op,
.unprepare = CAM_sys_unprepare_op,
.enable = CAM_sys_enable_op,
.disable = CAM_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops VENC_sys_ops = {
.prepare = VENC_sys_prepare_op,
.unprepare = VENC_sys_unprepare_op,
.enable = VENC_sys_enable_op,
.disable = VENC_sys_disable_op,
.get_state = sys_get_state_op,
};
static struct subsys_ops VDEC_sys_ops = {
.prepare = VDEC_sys_prepare_op,
.unprepare = VDEC_sys_unprepare_op,
.enable = VDEC_sys_enable_op,
.disable = VDEC_sys_disable_op,
.get_state = sys_get_state_op,
};
static int subsys_is_on(enum subsys_id id)
{
int r;
struct subsys *sys = id_to_sys(id);
WARN_ON(!sys);
r = sys->ops->get_state(sys);
#if MT_CCF_DEBUG
pr_debug("[CCF] %s:%d, sys=%s, id=%d\n", __func__, r, sys->name, id);
#endif /* MT_CCF_DEBUG */
return r;
}
#if CONTROL_LIMIT
int allow[NR_SYSS] = {
1, /*SYS_MD1*/
1, /*SYS_CONN*/
1, /*SYS_DPY*/
1, /*SYS_DIS*/
1, /*SYS_MFG*/
1, /*SYS_ISP*/
1, /*SYS_IFR*/
1, /*SYS_MFG_CORE0*/
1, /*SYS_MFG_CORE1*/
1, /*SYS_MFG_ASYNC*/
1, /*SYS_CAM*/
1, /*SYS_VENC*/
1, /*SYS_VDEC*/
};
#endif
static int enable_subsys(enum subsys_id id, enum mtcmos_op action)
{
int r = 0;
unsigned long flags;
struct subsys *sys = id_to_sys(id);
struct pg_callbacks *pgcb;
unsigned long spinlock_save_flags;
WARN_ON(!sys);
if (!mtk_is_mtcmos_enable()) {
#if MT_CCF_DEBUG
pr_notice("[CCF] skip %s: sys=%s, id=%d\n",
__func__, sys->name, id);
#endif
switch (id) {
case SYS_MD1:
spm_mtcmos_ctrl_md1_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_md1_bus_prot(STA_POWER_ON);
break;
case SYS_CONN:
spm_mtcmos_ctrl_conn_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_conn_bus_prot(STA_POWER_ON);
break;
default:
break;
}
return 0;
}
#if CONTROL_LIMIT
#if MT_CCF_DEBUG
pr_notice("[CCF] %s: sys=%s, id=%d, action = %s\n",
__func__, sys->name, id, action?"PWN":"BUS_PROT");
#endif
if (allow[id] == 0) {
#if MT_CCF_DEBUG
pr_debug("[CCF] %s: do nothing return\n", __func__);
#endif
return 0;
}
#endif
mtk_clk_lock(flags);
if (action == MTCMOS_BUS_PROT)
r = sys->ops->prepare(sys);
else if (action == MTCMOS_PWR)
r = sys->ops->enable(sys);
WARN_ON(r);
mtk_clk_unlock(flags);
if (action == MTCMOS_BUS_PROT) {
spin_lock_irqsave(&pgcb_lock, spinlock_save_flags);
list_for_each_entry(pgcb, &pgcb_list, list) {
if (pgcb->after_on)
pgcb->after_on(id);
}
spin_unlock_irqrestore(&pgcb_lock, spinlock_save_flags);
}
return r;
}
static int disable_subsys(enum subsys_id id, enum mtcmos_op action)
{
int r = 0;
unsigned long flags;
struct subsys *sys = id_to_sys(id);
struct pg_callbacks *pgcb;
unsigned long spinlock_save_flags;
WARN_ON(!sys);
if (!mtk_is_mtcmos_enable()) {
#if MT_CCF_DEBUG
pr_notice("[CCF] skip %s: sys=%s, id=%d\n",
__func__, sys->name, id);
#endif
switch (id) {
case SYS_MD1:
spm_mtcmos_ctrl_md1_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_md1_pwr(STA_POWER_DOWN);
break;
case SYS_CONN:
spm_mtcmos_ctrl_conn_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_conn_pwr(STA_POWER_DOWN);
break;
default:
break;
}
return 0;
}
#if CONTROL_LIMIT
#if MT_CCF_DEBUG
pr_notice("[CCF] %s: sys=%s, id=%d, action = %s\n",
__func__, sys->name, id, action?"PWN":"BUS_PROT");
#endif
if (allow[id] == 0) {
#if MT_CCF_DEBUG
pr_debug("[CCF] %s: do nothing return\n", __func__);
#endif
return 0;
}
#endif
/* TODO: check all clocks related to this subsys are off */
/* could be power off or not */
if (action == MTCMOS_BUS_PROT) {
spin_lock_irqsave(&pgcb_lock, spinlock_save_flags);
list_for_each_entry_reverse(pgcb, &pgcb_list, list) {
if (pgcb->before_off)
pgcb->before_off(id);
}
spin_unlock_irqrestore(&pgcb_lock, spinlock_save_flags);
}
mtk_clk_lock(flags);
if (action == MTCMOS_BUS_PROT)
r = sys->ops->unprepare(sys);
else if (action == MTCMOS_PWR)
r = sys->ops->disable(sys);
WARN_ON(r);
mtk_clk_unlock(flags);
return r;
}
/*
* power_gate
*/
#define CLK_NUM 10
struct mt_power_gate {
struct clk_hw hw;
struct cg_list *pre_clk1_list;
struct cg_list *pre_clk2_list;
enum subsys_id pd_id;
};
#define to_power_gate(_hw) container_of(_hw, struct mt_power_gate, hw)
struct cg_list {
const char *cg[CLK_NUM];
};
static int pg_is_enabled(struct clk_hw *hw)
{
struct mt_power_gate *pg = to_power_gate(hw);
if (!mtk_is_mtcmos_enable())
return 1;
else
return subsys_is_on(pg->pd_id);
}
int pg_prepare(struct clk_hw *hw)
{
int ret1 = 0, ret2 = 0, ret3 = 0, ret4 = 0;
int i = 0;
int skip_pg = 0;
struct clk *clk;
struct mt_power_gate *pg = to_power_gate(hw);
struct subsys *sys = id_to_sys(pg->pd_id);
#if CHECK_PWR_ST
if (sys->ops->get_state(sys) == SUBSYS_PWR_ON)
skip_pg = 1;
#endif /* CHECK_PWR_ST */
do {
if (pg->pre_clk1_list == NULL)
break;
clk = pg->pre_clk1_list->cg[i] ?
__clk_lookup(pg->pre_clk1_list->cg[i]) : NULL;
if (clk)
ret1 = clk_prepare_enable(clk);
else
break;
if (ret1)
break;
#if MT_CCF_DEBUG
pr_notice("[CCF] %s 1: sys=%s, pre_clk=%s\n", __func__,
__clk_get_name(hw->clk),
pg->pre_clk1_list->cg[i] ?
pg->pre_clk1_list->cg[i]:NULL);
#endif /* MT_CCF_DEBUG */
i++;
} while (i < CLK_NUM);
if (!skip_pg)
ret2 = enable_subsys(pg->pd_id, MTCMOS_PWR);
i = 0;
do {
if (pg->pre_clk2_list == NULL)
break;
clk = pg->pre_clk2_list->cg[i] ?
__clk_lookup(pg->pre_clk2_list->cg[i]) : NULL;
if (clk)
ret3 = clk_prepare_enable(clk);
else
break;
if (ret3)
break;
#if MT_CCF_DEBUG
pr_notice("[CCF] %s 2: sys=%s, pre_clk=%s\n", __func__,
__clk_get_name(hw->clk),
pg->pre_clk2_list->cg[i] ?
pg->pre_clk2_list->cg[i]:NULL);
#endif /* MT_CCF_DEBUG */
i++;
} while (i < CLK_NUM);
if (!skip_pg && sys->ops->prepare)
ret4 = enable_subsys(pg->pd_id, MTCMOS_BUS_PROT);
if (ret2)
return ret2;
if (ret3)
return ret3;
if (ret4)
return ret4;
return ret1;
}
void pg_unprepare(struct clk_hw *hw)
{
int i = 0;
int skip_pg = 0;
struct clk *clk;
struct mt_power_gate *pg = to_power_gate(hw);
struct subsys *sys = id_to_sys(pg->pd_id);
#if CHECK_PWR_ST
if (sys->ops->get_state(sys) == SUBSYS_PWR_DOWN)
skip_pg = 1;
#endif /* CHECK_PWR_ST */
if (!skip_pg && sys->ops->unprepare)
disable_subsys(pg->pd_id, MTCMOS_BUS_PROT);
do {
if (pg->pre_clk2_list == NULL)
break;
clk = pg->pre_clk2_list->cg[i] ?
__clk_lookup(pg->pre_clk2_list->cg[i]) : NULL;
if (clk)
clk_disable_unprepare(clk);
else
break;
#if MT_CCF_DEBUG
pr_notice("[CCF] %s: sys=%s, pre_clk=%s\n", __func__,
__clk_get_name(hw->clk),
pg->pre_clk2_list->cg[i] ?
pg->pre_clk2_list->cg[i]:NULL);
#endif /* MT_CCF_DEBUG */
i++;
} while (i < CLK_NUM);
if (!skip_pg)
disable_subsys(pg->pd_id, MTCMOS_PWR);
i = 0;
do {
if (pg->pre_clk1_list == NULL)
break;
clk = pg->pre_clk1_list->cg[i] ?
__clk_lookup(pg->pre_clk1_list->cg[i]) : NULL;
if (clk)
clk_disable_unprepare(clk);
else
break;
#if MT_CCF_DEBUG
pr_notice("[CCF] %s: sys=%s, pre_clk=%s\n", __func__,
__clk_get_name(hw->clk),
pg->pre_clk1_list->cg[i] ?
pg->pre_clk1_list->cg[i]:NULL);
#endif /* MT_CCF_DEBUG */
i++;
} while (i < CLK_NUM);
}
static const struct clk_ops mt_power_gate_ops = {
.prepare = pg_prepare,
.unprepare = pg_unprepare,
.is_enabled = pg_is_enabled,
};
struct clk *mt_clk_register_power_gate(const char *name,
const char *parent_name,
struct cg_list *pre_clk1_list,
struct cg_list *pre_clk2_list,
enum subsys_id pd_id)
{
struct mt_power_gate *pg;
struct clk *clk;
struct clk_init_data init = {};
pg = kzalloc(sizeof(*pg), GFP_KERNEL);
if (!pg)
return ERR_PTR(-ENOMEM);
init.name = name;
init.flags = CLK_IGNORE_UNUSED;
init.parent_names = parent_name ? &parent_name : NULL;
init.num_parents = parent_name ? 1 : 0;
init.ops = &mt_power_gate_ops;
pg->pre_clk1_list = pre_clk1_list;
pg->pre_clk2_list = pre_clk2_list;
pg->pd_id = pd_id;
pg->hw.init = &init;
clk = clk_register(NULL, &pg->hw);
if (IS_ERR(clk))
kfree(pg);
return clk;
}
#define pg_md1 "pg_md1"
#define pg_conn "pg_conn"
#define pg_dpy "pg_dpy"
#define pg_dis "pg_dis"
#define pg_mfg "pg_mfg"
#define pg_isp "pg_isp"
#define pg_ifr "pg_ifr"
#define pg_mfg_core0 "pg_mfg_core0"
#define pg_mfg_core1 "pg_mfg_core1"
#define pg_mfg_async "pg_mfg_async"
#define pg_cam "pg_cam"
#define pg_venc "pg_venc"
#define pg_vdec "pg_vdec"
struct cg_list mm_cg1 = {.cg = {"mm_sel"},};
struct cg_list mm_cg2 = {
.cg = {
"mm_smi_common",
"mm_smi_comm0",
"mm_smi_comm1",
"mm_smi_larb0",
"mm_cam_mdp_ck", /* add for MT6768 */
},
};
struct cg_list mfg_cg = {.cg = {"mfg_sel"},};
struct cg_list isp_cg = {
.cg = {
"img_larb2",
"mm_smi_img_ck",
"img_dip",
"img_fdvt",
"img_dpe",
},
};
struct cg_list cam_cg = {
.cg = {
"cam_larb3",
"cam_dfp_vad",
"cam",
"cam_ccu",
"mm_smi_cam_ck"
},
};
struct cg_list venc_cg = {
.cg = {
"venc_set1_venc"
},
};
struct cg_list vdec_cg = {
.cg = {
"vdec_cken",
"vdec_active",
"vdec_cken_eng",
"vdec_larb1_cken",
},
};
struct mtk_power_gate {
int id;
const char *name;
const char *parent_name;
enum subsys_id pd_id;
struct cg_list *pre_clk1_names;
struct cg_list *pre_clk2_names;
};
#define PGATE(_id, _name, _parent, _pre_clk, _pd_id) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.pre_clk_name = _pre_clk, \
.pd_id = _pd_id, \
}
#define PGATE2(_id, _name, _parent, _pre_clks1, _pre_clks2, _pd_id) { \
.id = _id, \
.name = _name, \
.parent_name = _parent, \
.pd_id = _pd_id, \
.pre_clk1_names = _pre_clks1, \
.pre_clk2_names = _pre_clks2, \
}
/* FIXME: all values needed to be verified */
struct mtk_power_gate scp_clks[] __initdata = {
PGATE2(SCP_SYS_MD1, pg_md1, NULL, NULL, NULL, SYS_MD1),
PGATE2(SCP_SYS_CONN, pg_conn, NULL, NULL, NULL, SYS_CONN),
PGATE2(SCP_SYS_DPY, pg_dpy, NULL, NULL, NULL, SYS_DPY),
PGATE2(SCP_SYS_DIS, pg_dis, NULL, &mm_cg1, &mm_cg2, SYS_DIS),
PGATE2(SCP_SYS_MFG, pg_mfg, pg_mfg_async, NULL, NULL, SYS_MFG),
PGATE2(SCP_SYS_ISP, pg_isp, pg_dis, NULL, &isp_cg, SYS_ISP),
PGATE2(SCP_SYS_IFR, pg_ifr, NULL, NULL, NULL, SYS_IFR),
PGATE2(SCP_SYS_MFG_CORE0, pg_mfg_core0, pg_mfg,
NULL, NULL, SYS_MFG_CORE0),
PGATE2(SCP_SYS_MFG_CORE1, pg_mfg_core1, pg_mfg,
NULL, NULL, SYS_MFG_CORE1),
PGATE2(SCP_SYS_MFG_ASYNC, pg_mfg_async, NULL,
&mfg_cg, NULL, SYS_MFG_ASYNC),
PGATE2(SCP_SYS_CAM, pg_cam, pg_dis, NULL, &cam_cg, SYS_CAM),
PGATE2(SCP_SYS_VENC, pg_venc, pg_dis, NULL, &venc_cg, SYS_VENC),
PGATE2(SCP_SYS_VDEC, pg_vdec, pg_dis, NULL, &vdec_cg, SYS_VDEC),
};
static int init_clk_scpsys(struct platform_device *pdev, struct clk_onecell_data *clk_data)
{
int i;
struct clk *clk;
syss[SYS_MD1].ctl_addr = MD1_PWR_CON;
syss[SYS_CONN].ctl_addr = CONN_PWR_CON;
syss[SYS_DPY].ctl_addr = DPY_PWR_CON;
syss[SYS_DIS].ctl_addr = DIS_PWR_CON;
syss[SYS_MFG].ctl_addr = MFG_PWR_CON;
syss[SYS_ISP].ctl_addr = ISP_PWR_CON;
syss[SYS_IFR].ctl_addr = IFR_PWR_CON;
syss[SYS_MFG_CORE0].ctl_addr = MFG_CORE0_PWR_CON;
syss[SYS_MFG_CORE1].ctl_addr = MFG_CORE1_PWR_CON;
syss[SYS_MFG_ASYNC].ctl_addr = MFG_ASYNC_PWR_CON;
syss[SYS_CAM].ctl_addr = CAM_PWR_CON;
syss[SYS_VENC].ctl_addr = VEN_PWR_CON;
syss[SYS_VDEC].ctl_addr = VDE_PWR_CON;
for (i = 0; i < ARRAY_SIZE(scp_clks); i++) {
struct mtk_power_gate *pg = &scp_clks[i];
if (mtk_is_mtcmos_enable())
clk = mt_clk_register_power_gate(pg->name,
pg->parent_name, pg->pre_clk1_names,
pg->pre_clk2_names, pg->pd_id);
else
clk = mt_clk_register_power_gate(pg->name,
pg->parent_name, NULL,
NULL, pg->pd_id);
if (IS_ERR(clk)) {
pr_debug("[CCF] %s: Failed to register clk %s: %ld\n",
__func__, pg->name, PTR_ERR(clk));
continue;
}
if (clk_data)
clk_data->clks[pg->id] = clk;
#if MT_CCF_DEBUG
pr_notice("[CCF] %s: pgate %3d: %s\n", __func__, i, pg->name);
#endif /* MT_CCF_DEBUG */
}
return 0;
}
/*
* device tree support
*/
/* TODO: remove this function */
static struct clk_onecell_data *alloc_clk_data(unsigned int clk_num)
{
int i;
struct clk_onecell_data *clk_data;
clk_data = kzalloc(sizeof(*clk_data), GFP_KERNEL);
if (!clk_data)
return NULL;
clk_data->clks = kcalloc(clk_num, sizeof(struct clk *), GFP_KERNEL);
if (!clk_data->clks) {
kfree(clk_data);
return NULL;
}
clk_data->clk_num = clk_num;
for (i = 0; i < clk_num; ++i)
clk_data->clks[i] = ERR_PTR(-ENOENT);
return clk_data;
}
/* TODO: remove this function */
static void __iomem *get_reg(struct device_node *np, int index)
{
#if DUMMY_REG_TEST
return kzalloc(PAGE_SIZE, GFP_KERNEL);
#else
return of_iomap(np, index);
#endif
}
static int clk_mt6768_scpsys_probe(struct platform_device *pdev)
{
struct clk_onecell_data *clk_data;
int r;
struct device_node *node = pdev->dev.of_node;
if(!node) {
pr_err("%s node is null\n", __func__);
return -EINVAL;
}
infracfg_base = get_reg(node, 0);
spm_base = get_reg(node, 1);
smi_common_base = get_reg(node, 2);
infra_base = get_reg(node, 3);
conn_base = get_reg(node, 4);
conn_mcu_base = get_reg(node, 5);
cksys_base = get_reg(node, 6);
vdec_gcon_base = get_reg(node, 7);
vdec_base = get_reg(node, 8);
if (!infracfg_base || !spm_base || !smi_common_base || !infra_base ||
!conn_base || !conn_mcu_base) {
pr_debug("clk-pg-mt6758: missing reg\n");
return -EINVAL;
}
clk_data = alloc_clk_data(SCP_NR_SYSS);
if (!clk_data) {
pr_err("%s clk_data is null\n", __func__);
return -ENOMEM;
}
init_clk_scpsys(pdev, 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);
}
spin_lock_init(&pgcb_lock);
if (mtk_is_mtcmos_enable()) {
/* subsys init: per modem owner request,
*disable modem power first
*/
disable_subsys(SYS_MD1, MTCMOS_PWR);
} else { /*power on all subsys for bring up */
#ifndef CONFIG_FPGA_EARLY_PORTING
pr_notice("[CCF] %s: MT6768: S/B bringup mtcmos start\n",
__func__);
/* md1 and conn power down first */
spm_mtcmos_ctrl_md1_bus_prot(STA_POWER_DOWN);/*do after ccif*/
spm_mtcmos_ctrl_md1_pwr(STA_POWER_DOWN);/*do after ccif*/
spm_mtcmos_ctrl_conn_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_conn_pwr(STA_POWER_DOWN);
spm_mtcmos_ctrl_dpy_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_dpy_bus_prot(STA_POWER_ON);
spm_mtcmos_ctrl_dis_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_dis_bus_prot(STA_POWER_ON);
spm_mtcmos_ctrl_isp_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_isp_bus_prot(STA_POWER_ON);
spm_mtcmos_ctrl_ifr_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_mfg_async_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_mfg_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_mfg_bus_prot(STA_POWER_ON);
spm_mtcmos_ctrl_mfg_core0_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_mfg_core1_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_cam_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_cam_bus_prot(STA_POWER_ON);
spm_mtcmos_ctrl_ven_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_ven_bus_prot(STA_POWER_ON);
spm_mtcmos_ctrl_vde_pwr(STA_POWER_ON);
spm_mtcmos_ctrl_vde_bus_prot(STA_POWER_ON);
pr_notice("[CCF] %s: MT6768: S/B bringup done\n",
__func__);
#endif
}
return r;
}
void subsys_if_on(void)
{
unsigned int sta = spm_read(PWR_STATUS);
unsigned int sta_s = spm_read(PWR_STATUS_2ND);
int ret = 0;
if ((sta & (1U << 0)) && (sta_s & (1U << 0)))
pr_debug("suspend warning: SYS_MD1 is on!!!\n");
if ((sta & (1U << 1)) && (sta_s & (1U << 1))) {
pr_notice("suspend warning: SYS_CONN is on!!!\n");
ret++;
}
#if 0
if ((sta & (1U << 2)) && (sta_s & (1U << 2)))
pr_debug("suspend warning: SYS_DPY is on!!!\n");
if ((sta & (1U << 3)) && (sta_s & (1U << 3)))
pr_debug("suspend warning: SYS_IFR is on!!!\n");
#endif
if ((sta & (1U << 5)) && (sta_s & (1U << 5))) {
pr_notice("suspend warning: SYS_DIS is on!!!\n");
ret++;
}
if ((sta & (1U << 6)) && (sta_s & (1U << 6))) {
pr_notice("suspend warning: SYS_ISP is on!!!\n");
ret++;
}
if ((sta & (1U << 7)) && (sta_s & (1U << 7))) {
pr_notice("suspend warning: SYS_CAM is on!!!\n");
ret++;
}
if ((sta & (1U << 8)) && (sta_s & (1U << 8))) {
pr_notice("suspend warning: SYS_VDEC is on!!!\n");
ret++;
}
if ((sta & (1U << 9)) && (sta_s & (1U << 9))) {
pr_notice("suspend warning: SYS_VENC is on!!!\n");
ret++;
}
if ((sta & (1U << 11)) && (sta_s & (1U << 11))) {
pr_notice("suspend warning: SYS_MFG is on!!!\n");
ret++;
}
if ((sta & (1U << 12)) && (sta_s & (1U << 12))) {
pr_notice("suspend warning: SYS_MFG_CORE0 is on!!!\n");
ret++;
}
if ((sta & (1U << 13)) && (sta_s & (1U << 13))) {
pr_notice("suspend warning: SYS_MFG_CORE1 is on!!!\n");
ret++;
}
if ((sta & (1U << 14)) && (sta_s & (1U << 14))) {
pr_notice("suspend warning: SYS_MFG_ASYNC is on!!!\n");
ret++;
}
/*
*if (ret > 0)
* WARN_ON(1);
*/
}
#if 1 /*only use for suspend test*/
void mtcmos_force_off(void)
{
spm_mtcmos_ctrl_md1_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_md1_pwr(STA_POWER_DOWN);/*do after ccif*/
spm_mtcmos_ctrl_conn_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_conn_pwr(STA_POWER_DOWN);
/* spm_mtcmos_ctrl_dpy(STA_POWER_DOWN); */
spm_mtcmos_ctrl_isp_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_isp_pwr(STA_POWER_DOWN);
/* spm_mtcmos_ctrl_ifr(STA_POWER_DOWN); */
spm_mtcmos_ctrl_mfg_core0_pwr(STA_POWER_DOWN);
spm_mtcmos_ctrl_mfg_core1_pwr(STA_POWER_DOWN);
spm_mtcmos_ctrl_mfg_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_mfg_pwr(STA_POWER_DOWN);
spm_mtcmos_ctrl_mfg_async_pwr(STA_POWER_DOWN);
spm_mtcmos_ctrl_cam_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_cam_pwr(STA_POWER_DOWN);
spm_mtcmos_ctrl_ven_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_ven_pwr(STA_POWER_DOWN);
spm_mtcmos_ctrl_vde_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_vde_pwr(STA_POWER_DOWN);
spm_mtcmos_ctrl_dis_bus_prot(STA_POWER_DOWN);
spm_mtcmos_ctrl_dis_pwr(STA_POWER_DOWN);
}
#endif
static const struct of_device_id of_match_clk_mt6768_scpsys[] = {
{ .compatible = "mediatek,scpsys", },
{}
};
static struct platform_driver clk_mt6768_scpsys_drv = {
.probe = clk_mt6768_scpsys_probe,
.driver = {
.name = "clk-mt6768-scpsys",
.owner = THIS_MODULE,
.of_match_table = of_match_clk_mt6768_scpsys,
},
};
/*
* Workaround for mm dvfs: Poll mm rdma before clkmux switching.
*/
void polling_rdma_output_line_is_not_zero(void);
void mm_polling(struct clk_hw *hw)
{
const char *clk_name = __clk_get_name(hw->clk);
if (clk_name) {
if (!strcmp(clk_name, "mm_sel") && subsys_is_on(SYS_DIS))
polling_rdma_output_line_is_not_zero();
}
}
#if CLK_DEBUG
/*
* debug / unit test
*/
#include <linux/proc_fs.h>
#include <linux/fs.h>
#include <linux/seq_file.h>
#include <linux/uaccess.h>
#include <linux/module.h>
static char last_cmd[128] = "null";
static int test_pg_dump_regs(struct seq_file *s, void *v)
{
int i;
for (i = 0; i < NR_SYSS; i++) {
if (!syss[i].ctl_addr)
continue;
seq_printf(s, "%10s: [0x%p]: 0x%08x\n", syss[i].name,
syss[i].ctl_addr, clk_readl(syss[i].ctl_addr));
}
return 0;
}
static void dump_pg_state(const char *clkname, struct seq_file *s)
{
struct clk *c = __clk_lookup(clkname);
struct clk *p = IS_ERR_OR_NULL(c) ? NULL : clk_get_parent(c);
if (IS_ERR_OR_NULL(c)) {
seq_printf(s, "[%17s: NULL]\n", clkname);
return;
}
seq_printf(s, "[%17s: %3s, %3d, %10lu, %7s]\n",
__clk_get_name(c),
__clk_is_enabled(c) ? "ON" : "off",
__clk_get_enable_count(c), clk_get_rate(c),
p ? __clk_get_name(p) : "");
clk_put(c);
}
static int test_pg_dump_state_all(struct seq_file *s, void *v)
{
static const char *const clks[] = {
pg_md1,
pg_conn,
pg_dpy,
pg_dis,
pg_mfg,
pg_isp,
pg_ifr,
pg_mfg_core0,
pg_mfg_core1,
pg_mfg_async,
pg_cam,
pg_venc,
pg_vdec,
};
int i;
/* pr_debug("\n");*/
for (i = 0; i < ARRAY_SIZE(clks); i++)
dump_pg_state(clks[i], s);
return 0;
}
static struct {
const char *name;
struct clk *clk;
} g_clks[] = {
{
.name = pg_md1}, {
.name = pg_venc}, {
.name = pg_vdec}, {
.name = pg_mfg},};
static int test_pg_1(struct seq_file *s, void *v)
{
int i;
/* pr_debug("\n");*/
for (i = 0; i < ARRAY_SIZE(g_clks); i++) {
g_clks[i].clk = __clk_lookup(g_clks[i].name);
if (IS_ERR_OR_NULL(g_clks[i].clk)) {
seq_printf(s, "clk_get(%s): NULL\n", g_clks[i].name);
continue;
}
clk_prepare_enable(g_clks[i].clk);
seq_printf(s, "clk_prepare_enable(%s)\n",
__clk_get_name(g_clks[i].clk));
}
return 0;
}
static int test_pg_2(struct seq_file *s, void *v)
{
int i;
/* pr_debug("\n");*/
for (i = 0; i < ARRAY_SIZE(g_clks); i++) {
if (IS_ERR_OR_NULL(g_clks[i].clk)) {
seq_printf(s, "(%s).clk: NULL\n", g_clks[i].name);
continue;
}
seq_printf(s, "clk_disable_unprepare(%s)\n",
__clk_get_name(g_clks[i].clk));
clk_disable_unprepare(g_clks[i].clk);
clk_put(g_clks[i].clk);
}
return 0;
}
static int test_pg_show(struct seq_file *s, void *v)
{
static const struct {
int (*fn)(struct seq_file *s, void *p);
const char *cmd;
} cmds[] = {
{
.cmd = "dump_regs", .fn = test_pg_dump_regs}, {
.cmd = "dump_state", .fn = test_pg_dump_state_all}, {
.cmd = "1", .fn = test_pg_1}, {
.cmd = "2", .fn = test_pg_2},};
int i;
/* pr_debug("last_cmd: %s\n", last_cmd);*/
for (i = 0; i < ARRAY_SIZE(cmds); i++) {
if (strcmp(cmds[i].cmd, last_cmd) == 0)
return cmds[i].fn(s, v);
}
return 0;
}
static int test_pg_open(struct inode *inode, struct file *file)
{
return single_open(file, test_pg_show, NULL);
}
static ssize_t test_pg_write(struct file *file,
const char __user *buffer, size_t count, loff_t *data)
{
char desc[sizeof(last_cmd)];
int len = 0;
/* pr_debug("count: %zu\n", count);*/
len = (count < (sizeof(desc) - 1)) ? count : (sizeof(desc) - 1);
if (copy_from_user(desc, buffer, len))
return 0;
desc[len] = '\0';
strcpy(last_cmd, desc);
if (last_cmd[len - 1] == '\n')
last_cmd[len - 1] = 0;
return count;
}
static const struct file_operations test_pg_fops = {
.owner = THIS_MODULE,
.open = test_pg_open,
.read = seq_read,
.write = test_pg_write,
.llseek = seq_lseek,
.release = single_release,
};
static int __init debug_init(void)
{
static int init;
struct proc_dir_entry *entry;
/* pr_debug("init: %d\n", init);*/
if (init)
return 0;
++init;
entry = proc_create("test_pg", 0000, 0000, &test_pg_fops);
if (!entry)
return -ENOMEM;
++init;
return 0;
}
static void __exit debug_exit(void)
{
remove_proc_entry("test_pg", NULL);
}
module_init(debug_init);
module_exit(debug_exit);
#endif /* CLK_DEBUG */
static int __init clk_mt6768_scpsys_init(void)
{
return platform_driver_register(&clk_mt6768_scpsys_drv);
}
static void __exit clk_mt6768_scpsys_exit(void)
{
pr_notice("%s: clk_mt6768_scpsys exit!\n", __func__);
}
arch_initcall(clk_mt6768_scpsys_init);
module_exit(clk_mt6768_scpsys_exit);
MODULE_LICENSE("GPL");
MODULE_AUTHOR("MTK");
MODULE_DESCRIPTION("MTK CCF Driver");
Reference in a new issue Copy permalink