/* * PowerPC internal definitions for qemu. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, see . */ #ifndef PPC_INTERNAL_H #define PPC_INTERNAL_H #define FUNC_MASK(name, ret_type, size, max_val) \ static inline ret_type name(uint##size##_t start, \ uint##size##_t end) \ { \ ret_type ret, max_bit = size - 1; \ \ if (likely(start == 0)) { \ ret = max_val << (max_bit - end); \ } else if (likely(end == max_bit)) { \ ret = max_val >> start; \ } else { \ ret = (((uint##size##_t)(-1ULL)) >> (start)) ^ \ (((uint##size##_t)(-1ULL) >> (end)) >> 1); \ if (unlikely(start > end)) { \ return ~ret; \ } \ } \ \ return ret; \ } #if defined(TARGET_PPC64) FUNC_MASK(MASK, target_ulong, 64, UINT64_MAX); #else FUNC_MASK(MASK, target_ulong, 32, UINT32_MAX); #endif FUNC_MASK(mask_u32, uint32_t, 32, UINT32_MAX); FUNC_MASK(mask_u64, uint64_t, 64, UINT64_MAX); /*****************************************************************************/ /*** Instruction decoding ***/ #define EXTRACT_HELPER(name, shift, nb) \ static inline uint32_t name(uint32_t opcode) \ { \ return extract32(opcode, shift, nb); \ } #define EXTRACT_SHELPER(name, shift, nb) \ static inline int32_t name(uint32_t opcode) \ { \ return sextract32(opcode, shift, nb); \ } #define EXTRACT_HELPER_SPLIT(name, shift1, nb1, shift2, nb2) \ static inline uint32_t name(uint32_t opcode) \ { \ return extract32(opcode, shift1, nb1) << nb2 | \ extract32(opcode, shift2, nb2); \ } #define EXTRACT_HELPER_SPLIT_3(name, \ d0_bits, shift_op_d0, shift_d0, \ d1_bits, shift_op_d1, shift_d1, \ d2_bits, shift_op_d2, shift_d2) \ static inline int16_t name(uint32_t opcode) \ { \ return \ (((opcode >> (shift_op_d0)) & ((1 << (d0_bits)) - 1)) << (shift_d0)) | \ (((opcode >> (shift_op_d1)) & ((1 << (d1_bits)) - 1)) << (shift_d1)) | \ (((opcode >> (shift_op_d2)) & ((1 << (d2_bits)) - 1)) << (shift_d2)); \ } /* Opcode part 1 */ EXTRACT_HELPER(opc1, 26, 6); /* Opcode part 2 */ EXTRACT_HELPER(opc2, 1, 5); /* Opcode part 3 */ EXTRACT_HELPER(opc3, 6, 5); /* Opcode part 4 */ EXTRACT_HELPER(opc4, 16, 5); /* Update Cr0 flags */ EXTRACT_HELPER(Rc, 0, 1); /* Update Cr6 flags (Altivec) */ EXTRACT_HELPER(Rc21, 10, 1); /* Destination */ EXTRACT_HELPER(rD, 21, 5); /* Source */ EXTRACT_HELPER(rS, 21, 5); /* First operand */ EXTRACT_HELPER(rA, 16, 5); /* Second operand */ EXTRACT_HELPER(rB, 11, 5); /* Third operand */ EXTRACT_HELPER(rC, 6, 5); /*** Get CRn ***/ EXTRACT_HELPER(crfD, 23, 3); EXTRACT_HELPER(BF, 23, 3); EXTRACT_HELPER(crfS, 18, 3); EXTRACT_HELPER(crbD, 21, 5); EXTRACT_HELPER(crbA, 16, 5); EXTRACT_HELPER(crbB, 11, 5); /* SPR / TBL */ EXTRACT_HELPER(_SPR, 11, 10); static inline uint32_t SPR(uint32_t opcode) { uint32_t sprn = _SPR(opcode); return ((sprn >> 5) & 0x1F) | ((sprn & 0x1F) << 5); } /*** Get constants ***/ /* 16 bits signed immediate value */ EXTRACT_SHELPER(SIMM, 0, 16); /* 16 bits unsigned immediate value */ EXTRACT_HELPER(UIMM, 0, 16); /* 5 bits signed immediate value */ EXTRACT_SHELPER(SIMM5, 16, 5); /* 5 bits signed immediate value */ EXTRACT_HELPER(UIMM5, 16, 5); /* 4 bits unsigned immediate value */ EXTRACT_HELPER(UIMM4, 16, 4); /* Bit count */ EXTRACT_HELPER(NB, 11, 5); /* Shift count */ EXTRACT_HELPER(SH, 11, 5); /* lwat/stwat/ldat/lwat */ EXTRACT_HELPER(FC, 11, 5); /* Vector shift count */ EXTRACT_HELPER(VSH, 6, 4); /* Mask start */ EXTRACT_HELPER(MB, 6, 5); /* Mask end */ EXTRACT_HELPER(ME, 1, 5); /* Trap operand */ EXTRACT_HELPER(TO, 21, 5); EXTRACT_HELPER(CRM, 12, 8); #ifndef CONFIG_USER_ONLY EXTRACT_HELPER(SR, 16, 4); #endif /* mtfsf/mtfsfi */ EXTRACT_HELPER(FPBF, 23, 3); EXTRACT_HELPER(FPIMM, 12, 4); EXTRACT_HELPER(FPL, 25, 1); EXTRACT_HELPER(FPFLM, 17, 8); EXTRACT_HELPER(FPW, 16, 1); /* mffscrni */ EXTRACT_HELPER(RM, 11, 2); /* addpcis */ EXTRACT_HELPER_SPLIT_3(DX, 10, 6, 6, 5, 16, 1, 1, 0, 0) #if defined(TARGET_PPC64) /* darn */ EXTRACT_HELPER(L, 16, 2); #endif /*** Jump target decoding ***/ /* Immediate address */ static inline target_ulong LI(uint32_t opcode) { return (opcode >> 0) & 0x03FFFFFC; } static inline uint32_t BD(uint32_t opcode) { return (opcode >> 0) & 0xFFFC; } EXTRACT_HELPER(BO, 21, 5); EXTRACT_HELPER(BI, 16, 5); /* Absolute/relative address */ EXTRACT_HELPER(AA, 1, 1); /* Link */ EXTRACT_HELPER(LK, 0, 1); /* DFP Z22-form */ EXTRACT_HELPER(DCM, 10, 6) /* DFP Z23-form */ EXTRACT_HELPER(RMC, 9, 2) EXTRACT_HELPER(Rrm, 16, 1) EXTRACT_HELPER_SPLIT(DQxT, 3, 1, 21, 5); EXTRACT_HELPER_SPLIT(xT, 0, 1, 21, 5); EXTRACT_HELPER_SPLIT(xS, 0, 1, 21, 5); EXTRACT_HELPER_SPLIT(xA, 2, 1, 16, 5); EXTRACT_HELPER_SPLIT(xB, 1, 1, 11, 5); EXTRACT_HELPER_SPLIT(xC, 3, 1, 6, 5); EXTRACT_HELPER(DM, 8, 2); EXTRACT_HELPER(UIM, 16, 2); EXTRACT_HELPER(SHW, 8, 2); EXTRACT_HELPER(SP, 19, 2); EXTRACT_HELPER(IMM8, 11, 8); EXTRACT_HELPER(DCMX, 16, 7); EXTRACT_HELPER_SPLIT_3(DCMX_XV, 5, 16, 0, 1, 2, 5, 1, 6, 6); void helper_compute_fprf_float16(CPUPPCState *env, float16 arg); void helper_compute_fprf_float32(CPUPPCState *env, float32 arg); void helper_compute_fprf_float128(CPUPPCState *env, float128 arg); /* Raise a data fault alignment exception for the specified virtual address */ void ppc_cpu_do_unaligned_access(CPUState *cs, vaddr addr, MMUAccessType access_type, int mmu_idx, uintptr_t retaddr); /* translate.c */ int ppc_fixup_cpu(PowerPCCPU *cpu); void create_ppc_opcodes(PowerPCCPU *cpu, Error **errp); void destroy_ppc_opcodes(PowerPCCPU *cpu); /* gdbstub.c */ void ppc_gdb_init(CPUState *cs, PowerPCCPUClass *ppc); gchar *ppc_gdb_arch_name(CPUState *cs); /** * prot_for_access_type: * @access_type: Access type * * Return the protection bit required for the given access type. */ static inline int prot_for_access_type(MMUAccessType access_type) { switch (access_type) { case MMU_INST_FETCH: return PAGE_EXEC; case MMU_DATA_LOAD: return PAGE_READ; case MMU_DATA_STORE: return PAGE_WRITE; } g_assert_not_reached(); } /* PowerPC MMU emulation */ typedef struct mmu_ctx_t mmu_ctx_t; bool ppc_xlate(PowerPCCPU *cpu, vaddr eaddr, MMUAccessType access_type, hwaddr *raddrp, int *psizep, int *protp, int mmu_idx, bool guest_visible); int get_physical_address_wtlb(CPUPPCState *env, mmu_ctx_t *ctx, target_ulong eaddr, MMUAccessType access_type, int type, int mmu_idx); /* Software driven TLB helpers */ int ppc6xx_tlb_getnum(CPUPPCState *env, target_ulong eaddr, int way, int is_code); /* Context used internally during MMU translations */ struct mmu_ctx_t { hwaddr raddr; /* Real address */ hwaddr eaddr; /* Effective address */ int prot; /* Protection bits */ hwaddr hash[2]; /* Pagetable hash values */ target_ulong ptem; /* Virtual segment ID | API */ int key; /* Access key */ int nx; /* Non-execute area */ }; /* Common routines used by software and hardware TLBs emulation */ static inline int pte_is_valid(target_ulong pte0) { return pte0 & 0x80000000 ? 1 : 0; } static inline void pte_invalidate(target_ulong *pte0) { *pte0 &= ~0x80000000; } #define PTE_PTEM_MASK 0x7FFFFFBF #define PTE_CHECK_MASK (TARGET_PAGE_MASK | 0x7B) #endif /* PPC_INTERNAL_H */