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[/] [openrisc/] [trunk/] [gnu-stable/] [gdb-7.2/] [sim/] [lm32/] [cpu.h] - Rev 866
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/* CPU family header for lm32bf. THIS FILE IS MACHINE GENERATED WITH CGEN. Copyright 1996-2010 Free Software Foundation, Inc. This file is part of the GNU simulators. This file is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. It 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA. */ #ifndef CPU_LM32BF_H #define CPU_LM32BF_H /* Maximum number of instructions that are fetched at a time. This is for LIW type instructions sets (e.g. m32r). */ #define MAX_LIW_INSNS 1 /* Maximum number of instructions that can be executed in parallel. */ #define MAX_PARALLEL_INSNS 1 /* The size of an "int" needed to hold an instruction word. This is usually 32 bits, but some architectures needs 64 bits. */ typedef CGEN_INSN_INT CGEN_INSN_WORD; #include "cgen-engine.h" /* CPU state information. */ typedef struct { /* Hardware elements. */ struct { /* Program counter */ USI h_pc; #define GET_H_PC() CPU (h_pc) #define SET_H_PC(x) (CPU (h_pc) = (x)) /* General purpose registers */ SI h_gr[32]; #define GET_H_GR(a1) CPU (h_gr)[a1] #define SET_H_GR(a1, x) (CPU (h_gr)[a1] = (x)) /* Control and status registers */ SI h_csr[32]; #define GET_H_CSR(a1) CPU (h_csr)[a1] #define SET_H_CSR(a1, x) (CPU (h_csr)[a1] = (x)) } hardware; #define CPU_CGEN_HW(cpu) (& (cpu)->cpu_data.hardware) } LM32BF_CPU_DATA; /* Cover fns for register access. */ USI lm32bf_h_pc_get (SIM_CPU *); void lm32bf_h_pc_set (SIM_CPU *, USI); SI lm32bf_h_gr_get (SIM_CPU *, UINT); void lm32bf_h_gr_set (SIM_CPU *, UINT, SI); SI lm32bf_h_csr_get (SIM_CPU *, UINT); void lm32bf_h_csr_set (SIM_CPU *, UINT, SI); /* These must be hand-written. */ extern CPUREG_FETCH_FN lm32bf_fetch_register; extern CPUREG_STORE_FN lm32bf_store_register; typedef struct { int empty; } MODEL_LM32_DATA; /* Instruction argument buffer. */ union sem_fields { struct { /* no operands */ int empty; } sfmt_empty; struct { /* */ IADDR i_call; } sfmt_bi; struct { /* */ UINT f_csr; UINT f_r1; } sfmt_wcsr; struct { /* */ UINT f_csr; UINT f_r2; } sfmt_rcsr; struct { /* */ IADDR i_branch; UINT f_r0; UINT f_r1; } sfmt_be; struct { /* */ UINT f_r0; UINT f_r1; UINT f_uimm; } sfmt_andi; struct { /* */ INT f_imm; UINT f_r0; UINT f_r1; } sfmt_addi; struct { /* */ UINT f_r0; UINT f_r1; UINT f_r2; UINT f_user; } sfmt_user; #if WITH_SCACHE_PBB /* Writeback handler. */ struct { /* Pointer to argbuf entry for insn whose results need writing back. */ const struct argbuf *abuf; } write; /* x-before handler */ struct { /*const SCACHE *insns[MAX_PARALLEL_INSNS];*/ int first_p; } before; /* x-after handler */ struct { int empty; } after; /* This entry is used to terminate each pbb. */ struct { /* Number of insns in pbb. */ int insn_count; /* Next pbb to execute. */ SCACHE *next; SCACHE *branch_target; } chain; #endif }; /* The ARGBUF struct. */ struct argbuf { /* These are the baseclass definitions. */ IADDR addr; const IDESC *idesc; char trace_p; char profile_p; /* ??? Temporary hack for skip insns. */ char skip_count; char unused; /* cpu specific data follows */ union sem semantic; int written; union sem_fields fields; }; /* A cached insn. ??? SCACHE used to contain more than just argbuf. We could delete the type entirely and always just use ARGBUF, but for future concerns and as a level of abstraction it is left in. */ struct scache { struct argbuf argbuf; }; /* Macros to simplify extraction, reading and semantic code. These define and assign the local vars that contain the insn's fields. */ #define EXTRACT_IFMT_EMPTY_VARS \ unsigned int length; #define EXTRACT_IFMT_EMPTY_CODE \ length = 0; \ #define EXTRACT_IFMT_ADD_VARS \ UINT f_opcode; \ UINT f_r0; \ UINT f_r1; \ UINT f_r2; \ UINT f_resv0; \ unsigned int length; #define EXTRACT_IFMT_ADD_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_r0 = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_r2 = EXTRACT_LSB0_UINT (insn, 32, 15, 5); \ f_resv0 = EXTRACT_LSB0_UINT (insn, 32, 10, 11); \ #define EXTRACT_IFMT_ADDI_VARS \ UINT f_opcode; \ UINT f_r0; \ UINT f_r1; \ INT f_imm; \ unsigned int length; #define EXTRACT_IFMT_ADDI_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_r0 = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_imm = EXTRACT_LSB0_SINT (insn, 32, 15, 16); \ #define EXTRACT_IFMT_ANDI_VARS \ UINT f_opcode; \ UINT f_r0; \ UINT f_r1; \ UINT f_uimm; \ unsigned int length; #define EXTRACT_IFMT_ANDI_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_r0 = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_uimm = EXTRACT_LSB0_UINT (insn, 32, 15, 16); \ #define EXTRACT_IFMT_ANDHII_VARS \ UINT f_opcode; \ UINT f_r0; \ UINT f_r1; \ UINT f_uimm; \ unsigned int length; #define EXTRACT_IFMT_ANDHII_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_r0 = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_uimm = EXTRACT_LSB0_UINT (insn, 32, 15, 16); \ #define EXTRACT_IFMT_B_VARS \ UINT f_opcode; \ UINT f_r0; \ UINT f_r1; \ UINT f_r2; \ UINT f_resv0; \ unsigned int length; #define EXTRACT_IFMT_B_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_r0 = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_r2 = EXTRACT_LSB0_UINT (insn, 32, 15, 5); \ f_resv0 = EXTRACT_LSB0_UINT (insn, 32, 10, 11); \ #define EXTRACT_IFMT_BI_VARS \ UINT f_opcode; \ SI f_call; \ unsigned int length; #define EXTRACT_IFMT_BI_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_call = ((pc) + (((SI) (((EXTRACT_LSB0_SINT (insn, 32, 25, 26)) << (6))) >> (4)))); \ #define EXTRACT_IFMT_BE_VARS \ UINT f_opcode; \ UINT f_r0; \ UINT f_r1; \ SI f_branch; \ unsigned int length; #define EXTRACT_IFMT_BE_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_r0 = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_branch = ((pc) + (((SI) (((EXTRACT_LSB0_SINT (insn, 32, 15, 16)) << (16))) >> (14)))); \ #define EXTRACT_IFMT_ORI_VARS \ UINT f_opcode; \ UINT f_r0; \ UINT f_r1; \ UINT f_uimm; \ unsigned int length; #define EXTRACT_IFMT_ORI_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_r0 = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_uimm = EXTRACT_LSB0_UINT (insn, 32, 15, 16); \ #define EXTRACT_IFMT_RCSR_VARS \ UINT f_opcode; \ UINT f_csr; \ UINT f_r1; \ UINT f_r2; \ UINT f_resv0; \ unsigned int length; #define EXTRACT_IFMT_RCSR_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_csr = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_r2 = EXTRACT_LSB0_UINT (insn, 32, 15, 5); \ f_resv0 = EXTRACT_LSB0_UINT (insn, 32, 10, 11); \ #define EXTRACT_IFMT_SEXTB_VARS \ UINT f_opcode; \ UINT f_r0; \ UINT f_r1; \ UINT f_r2; \ UINT f_resv0; \ unsigned int length; #define EXTRACT_IFMT_SEXTB_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_r0 = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_r2 = EXTRACT_LSB0_UINT (insn, 32, 15, 5); \ f_resv0 = EXTRACT_LSB0_UINT (insn, 32, 10, 11); \ #define EXTRACT_IFMT_USER_VARS \ UINT f_opcode; \ UINT f_r0; \ UINT f_r1; \ UINT f_r2; \ UINT f_user; \ unsigned int length; #define EXTRACT_IFMT_USER_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_r0 = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_r2 = EXTRACT_LSB0_UINT (insn, 32, 15, 5); \ f_user = EXTRACT_LSB0_UINT (insn, 32, 10, 11); \ #define EXTRACT_IFMT_WCSR_VARS \ UINT f_opcode; \ UINT f_csr; \ UINT f_r1; \ UINT f_r2; \ UINT f_resv0; \ unsigned int length; #define EXTRACT_IFMT_WCSR_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_csr = EXTRACT_LSB0_UINT (insn, 32, 25, 5); \ f_r1 = EXTRACT_LSB0_UINT (insn, 32, 20, 5); \ f_r2 = EXTRACT_LSB0_UINT (insn, 32, 15, 5); \ f_resv0 = EXTRACT_LSB0_UINT (insn, 32, 10, 11); \ #define EXTRACT_IFMT_BREAK_VARS \ UINT f_opcode; \ UINT f_exception; \ unsigned int length; #define EXTRACT_IFMT_BREAK_CODE \ length = 4; \ f_opcode = EXTRACT_LSB0_UINT (insn, 32, 31, 6); \ f_exception = EXTRACT_LSB0_UINT (insn, 32, 25, 26); \ /* Collection of various things for the trace handler to use. */ typedef struct trace_record { IADDR pc; /* FIXME:wip */ } TRACE_RECORD; #endif /* CPU_LM32BF_H */
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