///////////////////////////////////////////////////////////////////////// // $Id$ ///////////////////////////////////////////////////////////////////////// // // Copyright (c) 2006-2012 Stanislav Shwartsman // Written by Stanislav Shwartsman [sshwarts at sourceforge net] // // 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 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, write to the Free Software // Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA #if BX_INSTRUMENTATION class bxInstruction_c; // define if you want to store instruction opcode bytes in bxInstruction_c #define BX_INSTR_STORE_OPCODE_BYTES void bx_instr_init_env(void); void bx_instr_exit_env(void); void bx_instr_initialize(unsigned cpu); // maximum size of an instruction #define MAX_OPCODE_LENGTH 16 // maximum physical addresses an instruction can generate #define MAX_DATA_ACCESSES 1024 class bxInstrumentation { public: bx_bool ready; // is current instruction ready to be printed bx_bool active; unsigned cpu_id; /* decoding */ unsigned opcode_length; Bit8u opcode[MAX_OPCODE_LENGTH]; bx_bool is32, is64; /* memory accesses */ unsigned num_data_accesses; struct { bx_address laddr; // linear address bx_phy_address paddr; // physical address unsigned rw; // BX_READ, BX_WRITE or BX_RW unsigned size; // 1 .. 32 } data_access[MAX_DATA_ACCESSES]; /* branch resolution and target */ bx_bool is_branch; bx_bool is_taken; bx_address target_linear; public: bxInstrumentation(): ready(0), active(0) {} void set_cpu_id(unsigned cpu) { cpu_id = cpu; } void activate() { active = 1; } void deactivate() { active = 0; } void toggle_active() { active = !active; } bx_bool is_active() const { return active; } void bx_instr_reset(unsigned type); void bx_instr_cnear_branch_taken(bx_address branch_eip, bx_address new_eip); void bx_instr_cnear_branch_not_taken(bx_address branch_eip); void bx_instr_ucnear_branch(unsigned what, bx_address branch_eip, bx_address new_eip); void bx_instr_far_branch(unsigned what, Bit16u new_cs, bx_address new_eip); void bx_instr_before_execution(bxInstruction_c *i); void bx_instr_after_execution(bxInstruction_c *i); void bx_instr_interrupt(unsigned vector); void bx_instr_exception(unsigned vector, unsigned error_code); void bx_instr_hwinterrupt(unsigned vector, Bit16u cs, bx_address eip); void bx_instr_lin_access(bx_address lin, bx_phy_adress phy, unsigned len, unsigned rw); private: void branch_taken(bx_address new_eip); void bx_print_instruction(void); }; void bx_instr_init(unsigned cpu); extern bxInstrumentation *icpu; /* initialization/deinitialization of instrumentalization*/ #define BX_INSTR_INIT_ENV() bx_instr_init_env() #define BX_INSTR_EXIT_ENV() bx_instr_exit_env() /* simulation init, shutdown, reset */ #define BX_INSTR_INITIALIZE(cpu_id) bx_instr_initialize(cpu_id) #define BX_INSTR_EXIT(cpu_id) #define BX_INSTR_RESET(cpu_id, type) icpu[cpu_id].bx_instr_reset(type) #define BX_INSTR_HLT(cpu_id) #define BX_INSTR_MWAIT(cpu_id, addr, len, flags) /* called from command line debugger */ #define BX_INSTR_DEBUG_PROMPT() #define BX_INSTR_DEBUG_CMD(cmd) /* branch resolution */ #define BX_INSTR_CNEAR_BRANCH_TAKEN(cpu_id, branch_eip, new_eip) icpu[cpu_id].bx_instr_cnear_branch_taken(branch_eip, new_eip) #define BX_INSTR_CNEAR_BRANCH_NOT_TAKEN(cpu_id, branch_eip) icpu[cpu_id].bx_instr_cnear_branch_not_taken(branch_eip) #define BX_INSTR_UCNEAR_BRANCH(cpu_id, what, branch_eip, new_eip) icpu[cpu_id].bx_instr_ucnear_branch(what, branch_eip, new_eip) #define BX_INSTR_FAR_BRANCH(cpu_id, what, new_cs, new_eip) icpu[cpu_id].bx_instr_far_branch(what, new_cs, new_eip) /* decoding completed */ #define BX_INSTR_OPCODE(cpu_id, i, opcode, len, is32, is64) /* exceptional case and interrupt */ #define BX_INSTR_EXCEPTION(cpu_id, vector, error_code) \ icpu[cpu_id].bx_instr_exception(vector, error_code) #define BX_INSTR_INTERRUPT(cpu_id, vector) icpu[cpu_id].bx_instr_interrupt(vector) #define BX_INSTR_HWINTERRUPT(cpu_id, vector, cs, eip) icpu[cpu_id].bx_instr_hwinterrupt(vector, cs, eip) /* TLB/CACHE control instruction executed */ #define BX_INSTR_CLFLUSH(cpu_id, laddr, paddr) #define BX_INSTR_CACHE_CNTRL(cpu_id, what) #define BX_INSTR_TLB_CNTRL(cpu_id, what, new_cr3) #define BX_INSTR_PREFETCH_HINT(cpu_id, what, seg, offset) /* execution */ #define BX_INSTR_BEFORE_EXECUTION(cpu_id, i) icpu[cpu_id].bx_instr_before_execution(i) #define BX_INSTR_AFTER_EXECUTION(cpu_id, i) icpu[cpu_id].bx_instr_after_execution(i) #define BX_INSTR_REPEAT_ITERATION(cpu_id, i) /* memory access */ #define BX_INSTR_LIN_ACCESS(cpu_id, lin, phy, len, rw) \ icpu[cpu_id].bx_instr_lin_access(lin, phy, len, rw) #define BX_INSTR_PHY_ACCESS(cpu_id, phy, len, rw) /* feedback from device units */ #define BX_INSTR_INP(addr, len) #define BX_INSTR_INP2(addr, len, val) #define BX_INSTR_OUTP(addr, len, val) /* wrmsr callback */ #define BX_INSTR_WRMSR(cpu_id, addr, value) #else // BX_INSTRUMENTATION /* initialization/deinitialization of instrumentalization */ #define BX_INSTR_INIT_ENV() #define BX_INSTR_EXIT_ENV() /* simulation init, shutdown, reset */ #define BX_INSTR_INITIALIZE(cpu_id) #define BX_INSTR_EXIT(cpu_id) #define BX_INSTR_RESET(cpu_id, type) #define BX_INSTR_HLT(cpu_id) #define BX_INSTR_MWAIT(cpu_id, addr, len, flags) /* called from command line debugger */ #define BX_INSTR_DEBUG_PROMPT() #define BX_INSTR_DEBUG_CMD(cmd) /* branch resolution */ #define BX_INSTR_CNEAR_BRANCH_TAKEN(cpu_id, branch_eip, new_eip) #define BX_INSTR_CNEAR_BRANCH_NOT_TAKEN(cpu_id, branch_eip) #define BX_INSTR_UCNEAR_BRANCH(cpu_id, what, branch_eip, new_eip) #define BX_INSTR_FAR_BRANCH(cpu_id, what, new_cs, new_eip) /* decoding completed */ #define BX_INSTR_OPCODE(cpu_id, i, opcode, len, is32, is64) /* exceptional case and interrupt */ #define BX_INSTR_EXCEPTION(cpu_id, vector, error_code) #define BX_INSTR_INTERRUPT(cpu_id, vector) #define BX_INSTR_HWINTERRUPT(cpu_id, vector, cs, eip) /* TLB/CACHE control instruction executed */ #define BX_INSTR_CLFLUSH(cpu_id, laddr, paddr) #define BX_INSTR_CACHE_CNTRL(cpu_id, what) #define BX_INSTR_TLB_CNTRL(cpu_id, what, new_cr3) #define BX_INSTR_PREFETCH_HINT(cpu_id, what, seg, offset) /* execution */ #define BX_INSTR_BEFORE_EXECUTION(cpu_id, i) #define BX_INSTR_AFTER_EXECUTION(cpu_id, i) #define BX_INSTR_REPEAT_ITERATION(cpu_id, i) /* linear memory access */ #define BX_INSTR_LIN_ACCESS(cpu_id, lin, phy, len, rw) /* physical memory access */ #define BX_INSTR_PHY_ACCESS(cpu_id, phy, len, rw) /* feedback from device units */ #define BX_INSTR_INP(addr, len) #define BX_INSTR_INP2(addr, len, val) #define BX_INSTR_OUTP(addr, len, val) /* wrmsr callback */ #define BX_INSTR_WRMSR(cpu_id, addr, value) #endif // BX_INSTRUMENTATION