kernel_samsung_a34x-permissive/drivers/misc/mediatek/m4u/2.0/m4u_pgtable.h

/* SPDX-License-Identifier: GPL-2.0 */
/*
 * Copyright (c) 2019 MediaTek Inc.
 */

#ifndef __M4U_PGTABLE_H__
#define __M4U_PGTABLE_H__

#include "m4u_reg.h"

/* ================================================================= */
/* 2 level pagetable: pgd -> pte */

#define F_PTE_TYPE_MSK                     F_MSK(1, 0)
#define F_PTE_TYPE_SET(val)                F_VAL(val, 1, 0)
#define F_PTE_TYPE_GET(regval)             F_MSK_SHIFT(regval, 1, 0)
#define F_PTE_TYPE_LARGE                   (0x1)
#define F_PTE_TYPE_SMALL                   (0x2)
#define F_PTE_B_BIT                        F_BIT_SET(2)
#define F_PTE_C_BIT                        F_BIT_SET(3)
#define F_PTE_BIT33_BIT                    F_BIT_SET(4)
#define F_PTE_TEX_MSK                      F_MSK(8, 6)
#define F_PTE_TEX_SET(val)                 F_VAL(val, 8, 6)
#define F_PTE_TEX_GET(regval)              F_MSK_SHIFT(regval, 8, 6)
#define F_PTE_BIT32_BIT                    F_BIT_SET(9)
#define F_PTE_S_BIT                        F_BIT_SET(10)
#define F_PTE_NG_BIT                       F_BIT_SET(11)

#define F_PTE_PA_LARGE_MSK                 F_MSK(31, 16)
#define F_PTE_PA_LARGE_SET(val)            F_VAL(val, 31, 16)
#define F_PTE_PA_LARGE_GET(regval)         F_MSK_SHIFT(regval, 31, 16)
#define F_PTE_PA_SMALL_MSK                 F_MSK(31, 12)
#define F_PTE_PA_SMALL_SET(val)            F_VAL(val, 31, 12)
#define F_PTE_PA_SMALL_GET(regval)         F_MSK_SHIFT(regval, 31, 12)

#define F_PTE_TYPE_IS_LARGE_PAGE(pte) \
	((imu_pte_val(pte)&0x3) == F_PTE_TYPE_LARGE)
#define F_PTE_TYPE_IS_SMALL_PAGE(pte) \
	((imu_pte_val(pte)&0x3) == F_PTE_TYPE_SMALL)


#define F_PGD_TYPE_PAGE                    (0x1)
#define F_PGD_TYPE_PAGE_MSK                (0x3)
#define F_PGD_TYPE_SECTION                 (0x2)
#define F_PGD_TYPE_SUPERSECTION            (0x2|(1<<18))
#define F_PGD_TYPE_SECTION_MSK             (0x3|(1<<18))
#define F_PGD_TYPE_IS_PAGE(pgd)            ((imu_pgd_val(pgd)&3) == 1)
#define F_PGD_TYPE_IS_SECTION(pgd) \
	(F_PGD_TYPE_IS_PAGE(pgd) ? 0 : \
	 ((imu_pgd_val(pgd)&F_PGD_TYPE_SECTION_MSK) == F_PGD_TYPE_SECTION))
#define F_PGD_TYPE_IS_SUPERSECTION(pgd) \
	(F_PGD_TYPE_IS_PAGE(pgd) ? 0 : \
	 ((imu_pgd_val(pgd)&F_PGD_TYPE_SECTION_MSK) == \
	 F_PGD_TYPE_SUPERSECTION))

#define F_PGD_B_BIT                        F_BIT_SET(2)
#define F_PGD_C_BIT                        F_BIT_SET(3)
#define F_PGD_BIT33_BIT                    F_BIT_SET(4)
#define F_PGD_AP_MSK                       F_MSK(11, 10)
#define F_PGD_AP_SET(val)                  F_VAL(val, 11, 10)
#define F_PGD_AP_GET(regval)               F_MSK_SHIFT(regval, 11, 10)
#define F_PGD_TEX_MSK                      F_MSK(14, 12)
#define F_PGD_TEX_SET(val)                 F_VAL(val, 14, 12)
#define F_PGD_TEX_GET(regval)              F_MSK_SHIFT(regval, 14, 12)
#define F_PGD_BIT32_BIT                    F_BIT_SET(9)
#define F_PGD_S_BIT                        F_BIT_SET(16)
#define F_PGD_NG_BIT                       F_BIT_SET(17)
#define F_PGD_NS_BIT_PAGE(ns)              F_BIT_VAL(ns, 3)
#define F_PGD_NS_BIT_SECTION(ns)           F_BIT_VAL(ns, 19)
#define F_PGD_NS_BIT_SUPERSECTION(ns)      F_BIT_VAL(ns, 19)

#define F_PGD_PA_PAGETABLE_MSK             F_MSK(31, 10)
#define F_PGD_PA_PAGETABLE_SET(val)        F_VAL(val, 31, 10)
#define F_PGD_PA_SECTION_MSK               F_MSK(31, 20)
#define F_PGD_PA_SECTION_SET(val)          F_VAL(val, 31, 20)
#define F_PGD_PA_SUPERSECTION_MSK          F_MSK(31, 24)
#define F_PGD_PA_SUPERSECTION_SET(val)     F_VAL(val, 31, 24)

/* pagetable walk */
#define IMU_PGDIR_SHIFT                    20
#define IMU_PAGE_SHIFT                     12
#define IMU_PTRS_PER_PGD                   4096
#define IMU_PTRS_PER_PTE                   256
#define IMU_BYTES_PER_PTE \
	(IMU_PTRS_PER_PTE*sizeof(imu_pteval_t))

#define MMU_PT_TYPE_SUPERSECTION           (1<<4)
#define MMU_PT_TYPE_SECTION                (1<<3)
#define MMU_PT_TYPE_LARGE_PAGE             (1<<2)
#define MMU_PT_TYPE_SMALL_PAGE             (1<<1)

#define MMU_SMALL_PAGE_SIZE                (SZ_4K)
#define MMU_LARGE_PAGE_SIZE                (SZ_64K)
#define MMU_SECTION_SIZE                   (SZ_1M)
#define MMU_SUPERSECTION_SIZE              (SZ_16M)

struct m4u_pte_info {
	struct imu_pgd *pgd;
	struct imu_pte *pte;
	unsigned int mva;
	unsigned long pa;
	unsigned int size;
	int valid;
};

typedef unsigned int imu_pteval_t;

struct imu_pte {
	imu_pteval_t imu_pte;
};

struct imu_pgd {
	imu_pteval_t imu_pgd;
};

#define imu_pte_val(x)                     ((x).imu_pte)
#define imu_pgd_val(x)                     ((x).imu_pgd)

//#define __imu_pte(x)                       ((imu_pte_t){(x)})
//#define __imu_pgd(x)                       ((struct imu_pgd){(x)})

#define imu_pte_none(pte)                  (!imu_pte_val(pte))
#define imu_pte_type(pte)                  (imu_pte_val(pte)&0x3)

#define imu_pgd_index(addr)                ((addr) >> IMU_PGDIR_SHIFT)
#define imu_pgd_offset(domain, addr) \
	((domain)->pgd + imu_pgd_index(addr))

#define imu_pte_index(addr) \
	(((addr)>>IMU_PAGE_SHIFT)&(IMU_PTRS_PER_PTE - 1))
#define imu_pte_offset_map(pgd, addr) \
	(imu_pte_map(pgd) + imu_pte_index(addr))

extern int gM4U_4G_DRAM_Mode;

static inline struct imu_pte *imu_pte_map(struct imu_pgd *pgd)
{
	imu_pteval_t pte_pa = imu_pgd_val(*pgd);

	if (gM4U_4G_DRAM_Mode) {
		if (pte_pa < 0x40000000)
			return (struct imu_pte *)
				(__va((pte_pa & F_PGD_PA_PAGETABLE_MSK) +
				 0x100000000L));
		else
			return (struct imu_pte *)
				(__va(pte_pa & F_PGD_PA_PAGETABLE_MSK));
	} else {
		phys_addr_t pte_pa_new = pte_pa & F_PGD_PA_PAGETABLE_MSK;

		if (pte_pa & F_PGD_BIT32_BIT)
			pte_pa_new |= 0x100000000L;
		if (pte_pa & F_PGD_BIT33_BIT)
			pte_pa_new |= 0x200000000L;
		return (struct imu_pte *)(__va(pte_pa_new));
	}
}

static inline int imu_pte_unmap(struct imu_pte *pte)
{
	return 0;
}

static inline unsigned int imu_pgd_entry_pa(struct imu_pgd pgd)
{
	if (F_PGD_TYPE_IS_PAGE(pgd))
		return imu_pgd_val(pgd) & F_PGD_PA_PAGETABLE_MSK;
	else if (F_PGD_TYPE_IS_SECTION(pgd))
		return imu_pgd_val(pgd) & F_PGD_PA_SECTION_MSK;
	else if (F_PGD_TYPE_IS_SUPERSECTION(pgd))
		return imu_pgd_val(pgd) & F_PGD_PA_SUPERSECTION_MSK;
	else
		return 0;
}

static inline struct imu_pgd *imu_supersection_start(struct imu_pgd *pgd)
{
	return (struct imu_pgd *) (round_down((unsigned long)pgd, (16 * 4)));
}
static inline struct imu_pte *imu_largepage_start(struct imu_pte *pte)
{
	return (struct imu_pte *) (round_down((unsigned long)pte, (16 * 4)));
}

static inline unsigned long long
m4u_calc_next_mva(unsigned long long addr,
	unsigned long long end, unsigned int size)
{
	/* addr + size may equal 0x100000000*/
	unsigned long long __boundary = (addr + (unsigned long long)size) &
					(~((unsigned long long)size-1));
	unsigned long long min = min_t(unsigned long long, __boundary, end);

	return min;
}

#endif
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.`
			`*/`

			`#ifndef __M4U_PGTABLE_H__`
			`#define __M4U_PGTABLE_H__`

			`#include "m4u_reg.h"`

			`/* ================================================================= */`
			`/* 2 level pagetable: pgd -> pte */`

			`#define F_PTE_TYPE_MSK F_MSK(1, 0)`
			`#define F_PTE_TYPE_SET(val) F_VAL(val, 1, 0)`
			`#define F_PTE_TYPE_GET(regval) F_MSK_SHIFT(regval, 1, 0)`
			`#define F_PTE_TYPE_LARGE (0x1)`
			`#define F_PTE_TYPE_SMALL (0x2)`
			`#define F_PTE_B_BIT F_BIT_SET(2)`
			`#define F_PTE_C_BIT F_BIT_SET(3)`
			`#define F_PTE_BIT33_BIT F_BIT_SET(4)`
			`#define F_PTE_TEX_MSK F_MSK(8, 6)`
			`#define F_PTE_TEX_SET(val) F_VAL(val, 8, 6)`
			`#define F_PTE_TEX_GET(regval) F_MSK_SHIFT(regval, 8, 6)`
			`#define F_PTE_BIT32_BIT F_BIT_SET(9)`
			`#define F_PTE_S_BIT F_BIT_SET(10)`
			`#define F_PTE_NG_BIT F_BIT_SET(11)`

			`#define F_PTE_PA_LARGE_MSK F_MSK(31, 16)`
			`#define F_PTE_PA_LARGE_SET(val) F_VAL(val, 31, 16)`
			`#define F_PTE_PA_LARGE_GET(regval) F_MSK_SHIFT(regval, 31, 16)`
			`#define F_PTE_PA_SMALL_MSK F_MSK(31, 12)`
			`#define F_PTE_PA_SMALL_SET(val) F_VAL(val, 31, 12)`
			`#define F_PTE_PA_SMALL_GET(regval) F_MSK_SHIFT(regval, 31, 12)`

			`#define F_PTE_TYPE_IS_LARGE_PAGE(pte) \`
			`((imu_pte_val(pte)&0x3) == F_PTE_TYPE_LARGE)`
			`#define F_PTE_TYPE_IS_SMALL_PAGE(pte) \`
			`((imu_pte_val(pte)&0x3) == F_PTE_TYPE_SMALL)`


			`#define F_PGD_TYPE_PAGE (0x1)`
			`#define F_PGD_TYPE_PAGE_MSK (0x3)`
			`#define F_PGD_TYPE_SECTION (0x2)`
			`#define F_PGD_TYPE_SUPERSECTION (0x2\|(1<<18))`
			`#define F_PGD_TYPE_SECTION_MSK (0x3\|(1<<18))`
			`#define F_PGD_TYPE_IS_PAGE(pgd) ((imu_pgd_val(pgd)&3) == 1)`
			`#define F_PGD_TYPE_IS_SECTION(pgd) \`
			`(F_PGD_TYPE_IS_PAGE(pgd) ? 0 : \`
			`((imu_pgd_val(pgd)&F_PGD_TYPE_SECTION_MSK) == F_PGD_TYPE_SECTION))`
			`#define F_PGD_TYPE_IS_SUPERSECTION(pgd) \`
			`(F_PGD_TYPE_IS_PAGE(pgd) ? 0 : \`
			`((imu_pgd_val(pgd)&F_PGD_TYPE_SECTION_MSK) == \`
			`F_PGD_TYPE_SUPERSECTION))`

			`#define F_PGD_B_BIT F_BIT_SET(2)`
			`#define F_PGD_C_BIT F_BIT_SET(3)`
			`#define F_PGD_BIT33_BIT F_BIT_SET(4)`
			`#define F_PGD_AP_MSK F_MSK(11, 10)`
			`#define F_PGD_AP_SET(val) F_VAL(val, 11, 10)`
			`#define F_PGD_AP_GET(regval) F_MSK_SHIFT(regval, 11, 10)`
			`#define F_PGD_TEX_MSK F_MSK(14, 12)`
			`#define F_PGD_TEX_SET(val) F_VAL(val, 14, 12)`
			`#define F_PGD_TEX_GET(regval) F_MSK_SHIFT(regval, 14, 12)`
			`#define F_PGD_BIT32_BIT F_BIT_SET(9)`
			`#define F_PGD_S_BIT F_BIT_SET(16)`
			`#define F_PGD_NG_BIT F_BIT_SET(17)`
			`#define F_PGD_NS_BIT_PAGE(ns) F_BIT_VAL(ns, 3)`
			`#define F_PGD_NS_BIT_SECTION(ns) F_BIT_VAL(ns, 19)`
			`#define F_PGD_NS_BIT_SUPERSECTION(ns) F_BIT_VAL(ns, 19)`

			`#define F_PGD_PA_PAGETABLE_MSK F_MSK(31, 10)`
			`#define F_PGD_PA_PAGETABLE_SET(val) F_VAL(val, 31, 10)`
			`#define F_PGD_PA_SECTION_MSK F_MSK(31, 20)`
			`#define F_PGD_PA_SECTION_SET(val) F_VAL(val, 31, 20)`
			`#define F_PGD_PA_SUPERSECTION_MSK F_MSK(31, 24)`
			`#define F_PGD_PA_SUPERSECTION_SET(val) F_VAL(val, 31, 24)`

			`/* pagetable walk */`
			`#define IMU_PGDIR_SHIFT 20`
			`#define IMU_PAGE_SHIFT 12`
			`#define IMU_PTRS_PER_PGD 4096`
			`#define IMU_PTRS_PER_PTE 256`
			`#define IMU_BYTES_PER_PTE \`
			`(IMU_PTRS_PER_PTE*sizeof(imu_pteval_t))`

			`#define MMU_PT_TYPE_SUPERSECTION (1<<4)`
			`#define MMU_PT_TYPE_SECTION (1<<3)`
			`#define MMU_PT_TYPE_LARGE_PAGE (1<<2)`
			`#define MMU_PT_TYPE_SMALL_PAGE (1<<1)`

			`#define MMU_SMALL_PAGE_SIZE (SZ_4K)`
			`#define MMU_LARGE_PAGE_SIZE (SZ_64K)`
			`#define MMU_SECTION_SIZE (SZ_1M)`
			`#define MMU_SUPERSECTION_SIZE (SZ_16M)`

			`struct m4u_pte_info {`
			`struct imu_pgd *pgd;`
			`struct imu_pte *pte;`
			`unsigned int mva;`
			`unsigned long pa;`
			`unsigned int size;`
			`int valid;`
			`};`

			`typedef unsigned int imu_pteval_t;`

			`struct imu_pte {`
			`imu_pteval_t imu_pte;`
			`};`

			`struct imu_pgd {`
			`imu_pteval_t imu_pgd;`
			`};`

			`#define imu_pte_val(x) ((x).imu_pte)`
			`#define imu_pgd_val(x) ((x).imu_pgd)`

			`//#define __imu_pte(x) ((imu_pte_t){(x)})`
			`//#define __imu_pgd(x) ((struct imu_pgd){(x)})`

			`#define imu_pte_none(pte) (!imu_pte_val(pte))`
			`#define imu_pte_type(pte) (imu_pte_val(pte)&0x3)`

			`#define imu_pgd_index(addr) ((addr) >> IMU_PGDIR_SHIFT)`
			`#define imu_pgd_offset(domain, addr) \`
			`((domain)->pgd + imu_pgd_index(addr))`

			`#define imu_pte_index(addr) \`
			`(((addr)>>IMU_PAGE_SHIFT)&(IMU_PTRS_PER_PTE - 1))`
			`#define imu_pte_offset_map(pgd, addr) \`
			`(imu_pte_map(pgd) + imu_pte_index(addr))`

			`extern int gM4U_4G_DRAM_Mode;`

			`static inline struct imu_pte imu_pte_map(struct imu_pgd pgd)`
			`{`
			`imu_pteval_t pte_pa = imu_pgd_val(*pgd);`

			`if (gM4U_4G_DRAM_Mode) {`
			`if (pte_pa < 0x40000000)`
			`return (struct imu_pte *)`
			`(__va((pte_pa & F_PGD_PA_PAGETABLE_MSK) +`
			`0x100000000L));`
			`else`
			`return (struct imu_pte *)`
			`(__va(pte_pa & F_PGD_PA_PAGETABLE_MSK));`
			`} else {`
			`phys_addr_t pte_pa_new = pte_pa & F_PGD_PA_PAGETABLE_MSK;`

			`if (pte_pa & F_PGD_BIT32_BIT)`
			`pte_pa_new \|= 0x100000000L;`
			`if (pte_pa & F_PGD_BIT33_BIT)`
			`pte_pa_new \|= 0x200000000L;`
			`return (struct imu_pte *)(__va(pte_pa_new));`
			`}`
			`}`

			`static inline int imu_pte_unmap(struct imu_pte *pte)`
			`{`
			`return 0;`
			`}`

			`static inline unsigned int imu_pgd_entry_pa(struct imu_pgd pgd)`
			`{`
			`if (F_PGD_TYPE_IS_PAGE(pgd))`
			`return imu_pgd_val(pgd) & F_PGD_PA_PAGETABLE_MSK;`
			`else if (F_PGD_TYPE_IS_SECTION(pgd))`
			`return imu_pgd_val(pgd) & F_PGD_PA_SECTION_MSK;`
			`else if (F_PGD_TYPE_IS_SUPERSECTION(pgd))`
			`return imu_pgd_val(pgd) & F_PGD_PA_SUPERSECTION_MSK;`
			`else`
			`return 0;`
			`}`

			`static inline struct imu_pgd imu_supersection_start(struct imu_pgd pgd)`
			`{`
			`return (struct imu_pgd ) (round_down((unsigned long)pgd, (16 4)));`
			`}`
			`static inline struct imu_pte imu_largepage_start(struct imu_pte pte)`
			`{`
			`return (struct imu_pte ) (round_down((unsigned long)pte, (16 4)));`
			`}`

			`static inline unsigned long long`
			`m4u_calc_next_mva(unsigned long long addr,`
			`unsigned long long end, unsigned int size)`
			`{`
			`/* addr + size may equal 0x100000000*/`
			`unsigned long long __boundary = (addr + (unsigned long long)size) &`
			`(~((unsigned long long)size-1));`
			`unsigned long long min = min_t(unsigned long long, __boundary, end);`

			`return min;`
			`}`

			`#endif`