/* SPDX-License-Identifier: GPL-2.0 */ /* * Copyright (c) 2019 MediaTek Inc. */ #ifndef _MT_M4U_REG_H__ #define _MT_M4U_REG_H__ /* mau related */ #define MAU_NR_PER_M4U_SLAVE 1 /* #include "mach/mt_reg_base.h" */ /* ================================================= */ /* common macro definitions */ #define F_VAL(val, msb, lsb) (((val)&((1<<(msb-lsb+1))-1))<>lsb) /* ===================================================== */ /* M4U register definition */ /* ===================================================== */ #define REG_MMUg_PT_BASE (0x0) #define F_MMUg_PT_VA_MSK 0xffffff80 #define REG_MMUg_PT_BASE_SEC (0x4) #define F_MMUg_PT_VA_MSK_SEC 0xffffff80 #define F_PGD_REG_BIT32 F_BIT_SET(0) #define F_PGD_REG_BIT33 F_BIT_SET(1) #define REG_MMU_PROG_EN 0x10 #define F_MMU0_PROG_EN 0x1 #define F_MMU1_PROG_EN 0x2 #define REG_MMU_PROG_VA (0x14) #define F_PROG_VA_LOCK_BIT (1<<11) #define F_PROG_VA_LAYER_BIT F_BIT_SET(9) #define F_PROG_VA_SIZE16X_BIT F_BIT_SET(8) #define F_PROG_VA_SECURE_BIT (1<<7) #define F_PROG_VA_MASK 0xfffff000 #define REG_MMU_PROG_DSC (0x18) #define REG_MMU_INVLD (0x20) #define F_MMU_INV_ALL (0x2) #define F_MMU_INV_RANGE (0x1) #define REG_MMU_INVLD_SA (0x24) #define REG_MMU_INVLD_EA (0x28) #define REG_MMU_INVLD_SEC (0x2c) #define F_MMU_INV_SEC_RANGE (0x1) #define REG_MMU_INVLD_SA_SEC (0x30) #define REG_MMU_INVLD_EA_SEC (0x34) #define REG_INVLID_SEL (0x38) #define F_MMU_INV_EN_L2 (1<<1) #define F_MMU_INV_EN_L1 (1<<0) #define REG_INVLID_SEL_SEC (0x3c) #define F_MMU_INV_SEC_ABORT_WR (1<<18) #define F_MMU_INV_SEC_ABORT_ADDR (0x3ffc0) #define F_MMU_INV_SEC_DBG (1<<5) #define F_MMU_INV_SEC_INV_INT_EN (1<<4) #define F_MMU_INV_SEC_INV_INT_CLR (1<<3) #define F_MMU_INV_SEC_INV_DONE (1<<2) #define F_MMU_INV_SEC_EN_L2 (1<<1) #define F_MMU_INV_SEC_EN_L1 (1<<0) #define REG_MMU_SEC_ABORT_INFO (0x40) #define F_MMU_M4U_DOMAIN_ABORT F_BIT_VAL(en, 31) #define F_MMU_SEC_ABORT_DOMAIN F_MSK_SHIFT(regval, 20, 16) #define F_MMU_SEC_ABORT_ID F_MSK_SHIFT(regval, 15, 0) #define REG_MMU_DUMMY (0x44) #define F_REG_MMU_IDLE_ENABLE F_BIT_SET(0) #define REG_MMU_STANDARD_AXI_MODE (0x48) #define REG_MMU_PRIORITY (0x4c) #define F_MMU1_COMMAND_GROUPING_EN F_BIT_SET(4) #define F_MMU0_COMMAND_GROUPING_EN F_BIT_SET(3) #define F_MMU_RS_FULL_ULTRA_EN F_BIT_SET(2) #define F_MMU_AUTO_PF_ULTRA_BIT F_BIT_SET(1) #define F_MMU_TABLE_WALK_ULTRA_BIT F_BIT_SET(0) #define REG_MMU_DCM_DIS (0x50) #define F_MMU_MTLB_LOGIC_STALL_DUMMY F_BIT_SET(15) #define F_MMU_MTLB_LOGIC_STALL_DCM F_BIT_SET(14) #define F_MMU_RS_ENTRY_STALL_DCM F_BIT_SET(13) #define F_MMU_FIFO_ENTRY_STALL_DCM F_BIT_SET(12) #define F_MMU_SLICE_ENTRY_STALL_DCM F_BIT_SET(11) #define F_MMU_ULTRA_SLICE_STALL_ENTRY_DCM F_BIT_SET(10) #define F_MMU_L2_LOGIC_STALL_DCM F_BIT_SET(9) #define F_MMU_TOP_STALL_DCM F_BIT_SET(8) #define F_MMU_APB_DCM F_BIT_SET(7) #define F_MMU_MTLB_LOGIC_DCM F_BIT_SET(6) #define F_MMU_RS_ENTRY_DCM F_BIT_SET(5) #define F_MMU_FIFO_ENTRY_DCM F_BIT_SET(4) #define F_MMU_SLICE_ENTRY_DCM F_BIT_SET(3) #define F_MMU_ULTRA_SLICE_ENTRY_DCM F_BIT_SET(2) #define F_MMU_L2_LOGIC_DCM F_BIT_SET(1) #define F_MMU_TOP_DCM F_BIT_SET(0) #define REG_MMU_WR_LEN (0x54) #define F_MMU_WR_THROT_DIS(sel) F_VAL(sel, 11, 10) #define F_MMU_MMU1_WRITE_LEN F_MSK(9, 5) #define F_MMU_MMU0_WRITE_LEN F_MSK(4, 0) #define REG_MMU_HW_DEBUG (0x58) #define F_MMU_HW_DBG_L2_SCAN_ALL F_BIT_SET(1) #define F_MMU_HW_DBG_PFQ_BRDCST F_BIT_SET(0) #define REG_MMU_NON_BLOCKING_DIS 0x5C #define F_MMU_MMU1_HALF_ENTRY_MODE F_BIT_SET(3) #define F_MMU_MMU0_HALF_ENTRY_MODE F_BIT_SET(2) #define F_MMU_MMU1_BLOCKING_MODE F_BIT_SET(1) #define F_MMU_MMU0_BLOCKING_MODE F_BIT_SET(0) #define REG_MMU_LEGACY_4KB_MODE (0x60) #define REG_MMU_DBG0 (0X64) #define REG_MMU_DBG1 (0x68) #define REG_MMU_DBG2 (0x6c) #define REG_MMU_SMI_COMMON_DBG0 (0x78) #define REG_MMU_SMI_COMMON_DBG1 (0x7c) #define REG_MMU_MMU_COHERENCE_EN (0x80) #define REG_MMU_IN_ORDER_WR_EN (0x84) #define REG_MMU_MMU_TABLE_WALK_DIS (0x88) #define REG_MMU_MMU_MTLB_RESERVE_MODE_DIS (0x8c) #define REG_MMU_READ_ENTRY 0x100 #define F_READ_ENTRY_EN F_BIT_SET(31) #define F_READ_ENTRY_VICT_TLB_SEL F_BIT_SET(30) #define F_READ_ENTRY_MM0_MAIN F_BIT_SET(27) #define F_READ_ENTRY_MMx_MAIN(id) F_BIT_SET(27+id) #define F_READ_ENTRY_PFH F_BIT_SET(26) #define F_READ_ENTRY_MMU1_IDX(idx) F_VAL(idx, 24, 19) #define F_READ_ENTRY_MAIN_IDX(idx) F_VAL(idx, 16, 12) #define F_READ_ENTRY_PFH_IDX(idx) F_VAL(idx, 10, 5) #define F_READ_ENTRY_PFH_HI_LO(high) F_VAL(high, 4, 4) #define F_READ_ENTRY_PFH_PAGE_IDX(idx) F_VAL(idx, 3, 2) #define F_READ_ENTRY_PFH_WAY(way) F_VAL(way, 1, 0) #define REG_MMU_DES_RDATA (0x104) #define REG_MMU_PFH_TAG_RDATA (0x108) #define F_PFH_TAG_VA_GET(mmu, tag) \ ((mmu == 0)?F_MMU0_PFH_TAG_VA_GET(tag) : F_MMU1_PFH_TAG_VA_GET(tag)) #define F_MMU0_PFH_TAG_VA_GET(tag) \ (F_MSK_SHIFT(tag, 14, 4)<<(MMU_SET_MSB_OFFSET(0)+1)) #define F_MMU1_PFH_TAG_VA_GET(tag) \ (F_MSK_SHIFT(tag, 14, 4)<<(MMU_SET_MSB_OFFSET(1)+1)) #define F_MMU_PFH_TAG_VA_LAYER0_MSK(mmu) \ ((mmu == 0)?F_MSK(31, 28):F_MSK(31, 28)) #define F_PFH_TAG_LAYER_BIT F_BIT_SET(3) /* this bit is always 0 -- cost down. */ #define F_PFH_TAG_16X_BIT F_BIT_SET(2) #define F_PFH_TAG_SEC_BIT F_BIT_SET(1) #define F_PFH_TAG_AUTO_PFH F_BIT_SET(0) #define REG_MMU_VICT_VLD 0x10c #define F_MMU_VICT_VLD_BIT(way) F_BIT_SET((way)&0xf) /* tag related macro */ #define MMU0_SET_ORDER (6) #define MMU1_SET_ORDER (6) #define MMU_SET_ORDER(mmu) ((mmu == 0) ? MMU0_SET_ORDER : MMU1_SET_ORDER) #define MMU_SET_NR(mmu) (1<> 32) & F_MSK(1, 0))) #define F_RP_PA_REG_BIT32 F_BIT_SET(0) #define F_RP_PA_REG_BIT33 F_BIT_SET(1) #define REG_MMU_INT_L2_CONTROL (0x120) #define F_INT_L2_CLR_BIT (1<<12) #define F_INT_L2_MULTI_HIT_FAULT F_BIT_SET(0) #define F_INT_L2_TABLE_WALK_FAULT F_BIT_SET(1) #define F_INT_L2_PFH_DMA_FIFO_OVERFLOW F_BIT_SET(2) #define F_INT_L2_MISS_DMA_FIFO_OVERFLOW F_BIT_SET(3) #define F_INT_L2_INVALID_DONE F_BIT_SET(4) #define F_INT_L2_PFH_FIFO_ERROR F_BIT_SET(5) #define F_INT_L2_MISS_FIFO_ERR F_BIT_SET(6) #define REG_MMU_INT_MAIN_CONTROL (0x124) #define F_INT_TRANSLATION_FAULT(MMU) F_BIT_SET(0+(MMU)*7) #define F_INT_MAIN_MULTI_HIT_FAULT(MMU) F_BIT_SET(1+(MMU)*7) #define F_INT_INVALID_PHYSICAL_ADDRESS_FAULT(MMU) F_BIT_SET(2+(MMU)*7) #define F_INT_ENTRY_REPLACEMENT_FAULT(MMU) F_BIT_SET(3+(MMU)*7) #define F_INT_TLB_MISS_FAULT(MMU) F_BIT_SET(4+(MMU)*7) #define F_INT_MISS_FIFO_ERR(MMU) F_BIT_SET(5+(MMU)*7) #define F_INT_PFH_FIFO_ERR(MMU) F_BIT_SET(6+(MMU)*7) #define F_INT_MAU(mmu, set) F_BIT_SET(14+(set)+(mmu*4)) #define F_INT_MMU0_MAIN_MSK F_MSK(6, 0) #define F_INT_MMU1_MAIN_MSK F_MSK(13, 7) #define F_INT_MMU0_MAU_MSK F_MSK((14 + MAU_NR_PER_M4U_SLAVE - 1), 14) #define F_INT_MMU1_MAU_MSK \ F_MSK((14 + MAU_NR_PER_M4U_SLAVE * 2 - 1), (14 + MAU_NR_PER_M4U_SLAVE)) #define REG_MMU_CPE_DONE_SEC (0x128) #define REG_MMU_CPE_DONE (0x12C) #define REG_MMU_L2_FAULT_ST (0x130) #define F_INT_L2_MISS_IN_FIFO_ERR F_BIT_SET(8) #define F_INT_L2_MISS_OUT_FIFO_ERROR F_BIT_SET(7) #define F_INT_L2_PFH_IN_FIFO_ERROR F_BIT_SET(6) #define F_INT_L2_PFH_OUT_FIFO_ERROR F_BIT_SET(5) #define REG_MMU_MAIN_FAULT_ST (0x134) #define REG_MMU_TBWALK_FAULT_VA (0x138) #define F_MMU_TBWALK_FAULT_VA_MSK F_MSK(31, 12) #define F_MMU_TBWALK_FAULT_LAYER(regval) F_MSK_SHIFT(regval, 0, 0) #define REG_MMU_FAULT_VA(mmu) (0x13c+((mmu)<<3)) #define F_MMU_FAULT_VA_MSK F_MSK(31, 12) #define F_MMU_FAULT_CATCH_INVPA F_BIT_SET(11) #define F_MMU_FAULT_CATCH_TF F_BIT_SET(10) #define F_MMU_FAULT_PA_B33_32 F_MSK(9, 8) #define F_MMU_FAULT_VA_WRITE_BIT F_BIT_SET(1) #define F_MMU_FAULT_VA_LAYER_BIT F_BIT_SET(0) #define REG_MMU_INVLD_PA(mmu) (0x140+((mmu)<<3)) #define REG_MMU_INT_ID(mmu) (0x150+((mmu)<<2)) #define F_MMU0_INT_ID_TF_MSK (~0x3) /* only for MM iommu. */ #define REG_MMU_PF_MSCNT (0x160) #define REG_MMU_PF_CNT (0x164) #define REG_MMU_ACC_CNT(mmu) \ (0x168+(((mmu)<<3)|((mmu)<<2))) /* (0x168+((mmu)*12) */ #define REG_MMU_MAIN_MSCNT(mmu) (0x16c+(((mmu)<<3)|((mmu)<<2))) #define REG_MMU_RS_PERF_CNT(mmu) (0x170+(((mmu)<<3)|((mmu)<<2))) #define REG_MMU_PFH_VLD_0 (0x180) #define REG_MMU_PFH_VLD(mmu, set, way) \ (REG_MMU_PFH_VLD_0+(((set)>>5)<<2)+\ ((way)<<((mmu == 0)?(MMU0_SET_ORDER - 3):(MMU1_SET_ORDER - 3)))) #define F_MMU_PFH_VLD_BIT(set, way) F_BIT_SET((set%32)&0x1f) #define MMU01_SQ_OFFSET (0x600-0x300) #define REG_MMU_SQ_START(mmu, x) \ (0x300+((x)<<3)+((mmu)*MMU01_SQ_OFFSET)) #define F_SQ_VA_MASK F_MSK(31, 20) #define F_SQ_EN_BIT (1<<19) /* #define F_SQ_MULTI_ENTRY_VAL(x) (((x)&0xf)<<13) */ #define REG_MMU_SQ_END(mmu, x) (0x304+((x)<<3)+((mmu)*MMU01_SQ_OFFSET)) #define MMU_TOTAL_RS_NR (8) #define REG_MMU_RSx_VA(mmu, x) (0x380+((x)<<4)+((mmu)*MMU01_SQ_OFFSET)) #define F_MMU_RSx_VA_GET(regval) ((regval)&F_MSK(31, 12)) #define F_MMU_RSx_VA_VALID(regval) F_MSK_SHIFT(regval, 11, 11) #define REG_MMU_RSx_PA(mmu, x) (0x384+((x)<<4)+((mmu)*MMU01_SQ_OFFSET)) #define F_MMU_RSx_PA_GET(regval) ((regval)&F_MSK(31, 12)) #define REG_MMU_RSx_2ND_BASE(mmu, x) (0x388+((x)<<4)+((mmu)*MMU01_SQ_OFFSET)) #define REG_MMU_RSx_ST(mmu, x) (0x38c+((x)<<4)+((mmu)*MMU01_SQ_OFFSET)) #define F_MMU_RSx_ST_LARB(regval) F_MSK_SHIFT(regval, 25, 23) #define F_MMU_RSx_ST_PORT(regval) F_MSK_SHIFT(regval, 22, 16) #define F_MMU_RSx_ST_WRT(regval) F_MSK_SHIFT(regval, 12, 12) #define F_MMU_RSx_ST_OTHER(regval) F_MSK_SHIFT(regval, 8, 0) #define REG_MMU_MAIN_TAG(mmu, x) (0x500+((x)<<2)+((mmu)*MMU01_SQ_OFFSET)) #define F_MAIN_TLB_VA_MSK F_MSK(31, 12) #define F_MAIN_TLB_LOCK_BIT (1<<11) #define F_MAIN_TLB_VALID_BIT (1<<10) #define F_MAIN_TLB_LAYER_BIT F_BIT_SET(9) #define F_MAIN_TLB_16X_BIT F_BIT_SET(8) #define F_MAIN_TLB_SEC_BIT F_BIT_SET(7) #define F_MAIN_TLB_INV_DES_BIT (1<<6) #define F_MAIN_TLB_SQ_EN_BIT (1<<5) #define F_MAIN_TLB_SQ_INDEX_MSK F_MSK(4, 1) #define F_MAIN_TLB_SQ_INDEX_GET(regval) F_MSK_SHIFT(regval, 4, 1) #define REG_MMU_MAU_START(mmu, mau) (0x900+((mau)*0x20)+((mmu)*0xa4)) #define REG_MMU_MAU_START_BIT32(mmu, mau) \ (0x904+((mau)*0x20)+((mmu)*0xa4)) #define REG_MMU_MAU_END(mmu, mau) \ (0x908+((mau)*0x20)+((mmu)*0xa4)) #define REG_MMU_MAU_END_BIT32(mmu, mau) (0x90C+((mau)*0x20)+((mmu)*0xa4)) #define REG_MMU_MAU_LARB_EN(mmu) (0x910+((mmu)*0xa4)) #define F_MAU_LARB_VAL(mau, larb) ((larb)<<(mau*8)) #define F_MAU_LARB_MSK(mau) (0xff<<(mau*8)) #define REG_MMU_MAU_PORT_EN(mmu, mau) (0x914+((mau)*0x20)+((mmu)*0xa4)) #define REG_MMU_MAU_ASSERT_ID(mmu, mau) (0x918+((mau)*0x20)+((mmu)*0xa4)) #define F_MMU_MAU_ASSERT_ID_LARB(regval) F_MSK_SHIFT(regval, 7, 5) #define F_MMU_MAU_ASSERT_ID_PORT(regval) F_MSK_SHIFT(regval, 4, 0) #define REG_MMU_MAU_ADDR(mmu, mau) (0x91C+((mau)*0x20)+((mmu)*0xa4)) #define REG_MMU_MAU_ADDR_BIT32(mmu, mau) \ (0x920+((mau)*0x20)+((mmu)*0xa4)) #define REG_MMU_MAU_CLR(mmu) (0x924+((mmu)*0xa4)) #define REG_MMU_MAU_IO(mmu) (0x928+((mmu)*0xa4)) #define F_MAU_BIT_VAL(val, mau) F_BIT_VAL(val, mau) #define REG_MMU_MAU_RW(mmu) (0x92c+((mmu)*0xa4)) #define REG_MMU_MAU_VA(mmu) (0x930+((mmu)*0xa4)) #define REG_MMU_MAU_ASSERT_ST(mmu) (0x934+((mmu)*0xa4)) #define MMU_TOTAL_PROG_DIST_NR (2) #define REG_MMU_PROG_DIST(dist, slave) (0xb00 + 0x100*slave + ((dist)<<2)) #define F_PF_ID_COMP_SEL(sel) F_BIT_VAL(sel, 16) #define F_PF_DIR(dir) F_BIT_VAL(dir, 15) #define F_PF_DIST_MSB (14) #define F_PF_DIST_LSB (11) #define F_PF_ID(larb, port, mm_id) ((larb) << 7 | ((port) << 2) | mm_id) #define F_PF_ID_MSB (10) #define F_PF_ID_LSB (1) #define F_PF_EN(en) F_BIT_VAL(en, 0) #define REG_MMU_SMI_ASYNC_CFG (0xb80) /* ================================================================ */ /* SMI larb */ /* ================================================================ */ #define SMI_LARB_NON_SEC_CONx(larb_port) (0x380 + ((larb_port)<<2)) #define F_SMI_NON_SEC_MMU_EN(en) F_BIT_VAL(en, 0) #define F_SMI_MMU_EN F_BIT_SET(0) #define F_SMI_DOMN(domain) F_VAL(domain, 8, 4) #define F_SMI_BIT32 F_MSK(15, 8) #define SMI_COMMON_LARB_BUS_SEL (0x220) #define F_SMI_LARB_BUS(larb, bus) F_VAL(bus, (larb * 2 + 1), (larb * 2)) /* ========================================================================= */ /* peripheral system */ /* ========================================================================= */ #define REG_PERIAXI_BUS_CTL3 (0x208) #define F_PERI_MMU_EN(port, en) ((en)<<((port))) #include static inline unsigned int COM_ReadReg32(unsigned long addr) { return ioread32((void *)addr); } static inline void COM_WriteReg32(unsigned long addr, unsigned int Val) { mt_reg_sync_writel(Val, (void *)addr); } static inline unsigned int M4U_ReadReg32( unsigned long M4uBase, unsigned int Offset) { unsigned int val; val = COM_ReadReg32((M4uBase + Offset)); return val; } static inline void M4U_WriteReg32(unsigned long M4uBase, unsigned int Offset, unsigned int Val) { COM_WriteReg32((M4uBase + Offset), Val); } static inline unsigned int m4uHw_set_field(unsigned long M4UBase, unsigned int Reg, unsigned int bit_width, unsigned int shift, unsigned int value) { unsigned int mask = ((1 << bit_width) - 1) << shift; unsigned int old; value = (value << shift) & mask; old = M4U_ReadReg32(M4UBase, Reg); M4U_WriteReg32(M4UBase, Reg, (old & (~mask)) | value); return (old & mask) >> shift; } static inline void m4uHw_set_field_by_mask( unsigned long M4UBase, unsigned int reg, unsigned long mask, unsigned int val) { unsigned int regval; regval = M4U_ReadReg32(M4UBase, reg); regval = (regval & (~mask)) | val; M4U_WriteReg32(M4UBase, reg, regval); } static inline unsigned int m4uHw_get_field_by_mask( unsigned long M4UBase, unsigned int reg, unsigned int mask) { return M4U_ReadReg32(M4UBase, reg) & mask; } #endif