/* * Copyright (C) 2002-2009 The DOSBox Team * * This program 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 2 of the License, or * (at your option) any later version. * * This program 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* $Id: core_dynrec.cpp,v 1.12 2009/05/27 09:15:41 qbix79 Exp $ */ #include "dosbox.h" #if (C_DYNREC) #include #include #include #include #include #include #if defined (WIN32) #include #include #endif #if (C_HAVE_MPROTECT) #include #include #ifndef PAGESIZE #define PAGESIZE 4096 #endif #endif /* C_HAVE_MPROTECT */ #include "callback.h" #include "regs.h" #include "mem.h" #include "cpu.h" #include "debug.h" #include "paging.h" #include "inout.h" #include "lazyflags.h" #define CACHE_MAXSIZE (4096*2) #define CACHE_TOTAL (1024*1024*8) #define CACHE_PAGES (512) #define CACHE_BLOCKS (128*1024) #define CACHE_ALIGN (16) #define DYN_HASH_SHIFT (4) #define DYN_PAGE_HASH (4096>>DYN_HASH_SHIFT) #define DYN_LINKS (16) #if 0 #define DYN_LOG LOG_MSG #else #define DYN_LOG #endif #if C_FPU #define CPU_FPU 1 //Enable FPU escape instructions #endif // the emulated x86 registers #define DRC_REG_EAX 0 #define DRC_REG_ECX 1 #define DRC_REG_EDX 2 #define DRC_REG_EBX 3 #define DRC_REG_ESP 4 #define DRC_REG_EBP 5 #define DRC_REG_ESI 6 #define DRC_REG_EDI 7 // the emulated x86 segment registers #define DRC_SEG_ES 0 #define DRC_SEG_CS 1 #define DRC_SEG_SS 2 #define DRC_SEG_DS 3 #define DRC_SEG_FS 4 #define DRC_SEG_GS 5 // access to a general register #define DRCD_REG_VAL(reg) (&cpu_regs.regs[reg].dword) // access to a segment register #define DRCD_SEG_VAL(seg) (&Segs.val[seg]) // access to the physical value of a segment register/selector #define DRCD_SEG_PHYS(seg) (&Segs.phys[seg]) // access to an 8bit general register #define DRCD_REG_BYTE(reg,idx) (&cpu_regs.regs[reg].byte[idx]) // access to 16/32bit general registers #define DRCD_REG_WORD(reg,dwrd) ((dwrd)?((void*)(&cpu_regs.regs[reg].dword)):((void*)(&cpu_regs.regs[reg].word))) enum BlockReturn { BR_Normal=0, BR_Cycles, BR_Link1,BR_Link2, BR_Opcode, #if (C_DEBUG) BR_OpcodeFull, #endif BR_Iret, BR_CallBack, BR_SMCBlock }; // identificator to signal self-modification of the currently executed block #define SMC_CURRENT_BLOCK 0xffff static void IllegalOptionDynrec(const char* msg) { E_Exit("DynrecCore: illegal option in %s",msg); } static struct { BlockReturn (*runcode)(Bit8u*); // points to code that can start a block Bitu callback; // the occurred callback Bitu readdata; // spare space used when reading from memory Bit32u protected_regs[8]; // space to save/restore register values } core_dynrec; #include "core_dynrec/cache.h" #define X86 0x01 #define X86_64 0x02 #define MIPSEL 0x03 #define ARMV4LE 0x04 #if C_TARGETCPU == X86_64 #include "core_dynrec/risc_x64.h" #elif C_TARGETCPU == X86 #include "core_dynrec/risc_x86.h" #elif C_TARGETCPU == MIPSEL #include "core_dynrec/risc_mipsel32.h" #elif C_TARGETCPU == ARMV4LE #include "core_dynrec/risc_armv4le.h" #endif #include "core_dynrec/decoder.h" CacheBlockDynRec * LinkBlocks(BlockReturn ret) { CacheBlockDynRec * block=NULL; // the last instruction was a control flow modifying instruction Bitu temp_ip=SegPhys(cs)+reg_eip; CodePageHandlerDynRec * temp_handler=(CodePageHandlerDynRec *)get_tlb_readhandler(temp_ip); if (temp_handler->flags & PFLAG_HASCODE) { // see if the target is an already translated block block=temp_handler->FindCacheBlock(temp_ip & 4095); if (!block) return NULL; // found it, link the current block to cache.block.running->LinkTo(ret==BR_Link2,block); return block; } return NULL; } /* The core tries to find the block that should be executed next. If such a block is found, it is run, otherwise the instruction stream starting at ip_point is translated (see decoder.h) and makes up a new code block that will be run. When control is returned to CPU_Core_Dynrec_Run (which might be right after the block is run, or somewhen long after that due to the direct cacheblock linking) the returncode decides the next action. This might be continuing the translation and execution process, or returning from the core etc. */ Bits CPU_Core_Dynrec_Run(void) { for (;;) { // Determine the linear address of CS:EIP PhysPt ip_point=SegPhys(cs)+reg_eip; #if C_HEAVY_DEBUG if (DEBUG_HeavyIsBreakpoint()) return debugCallback; #endif CodePageHandlerDynRec * chandler=0; // see if the current page is present and contains code if (GCC_UNLIKELY(MakeCodePage(ip_point,chandler))) { // page not present, throw the exception CPU_Exception(cpu.exception.which,cpu.exception.error); continue; } // page doesn't contain code or is special if (GCC_UNLIKELY(!chandler)) return CPU_Core_Normal_Run(); // find correct Dynamic Block to run CacheBlockDynRec * block=chandler->FindCacheBlock(ip_point&4095); if (!block) { // no block found, thus translate the instruction stream // unless the instruction is known to be modified if (!chandler->invalidation_map || (chandler->invalidation_map[ip_point&4095]<4)) { // translate up to 32 instructions block=CreateCacheBlock(chandler,ip_point,32); } else { // let the normal core handle this instruction to avoid zero-sized blocks Bitu old_cycles=CPU_Cycles; CPU_Cycles=1; Bits nc_retcode=CPU_Core_Normal_Run(); if (!nc_retcode) { CPU_Cycles=old_cycles-1; continue; } CPU_CycleLeft+=old_cycles; return nc_retcode; } } run_block: cache.block.running=0; // now we're ready to run the dynamic code block // BlockReturn ret=((BlockReturn (*)(void))(block->cache.start))(); BlockReturn ret=core_dynrec.runcode(block->cache.start); switch (ret) { case BR_Iret: #if C_HEAVY_DEBUG if (DEBUG_HeavyIsBreakpoint()) return debugCallback; #endif if (!GETFLAG(TF)) break; // trapflag is set, switch to the trap-aware decoder cpudecoder=CPU_Core_Dynrec_Trap_Run; return CBRET_NONE; case BR_Normal: // the block was exited due to a non-predictable control flow // modifying instruction (like ret) or some nontrivial cpu state // changing instruction (for example switch to/from pmode), // or the maximal number of instructions to translate was reached #if C_HEAVY_DEBUG if (DEBUG_HeavyIsBreakpoint()) return debugCallback; #endif break; case BR_Cycles: // cycles went negative, return from the core to handle // external events, schedule the pic... #if C_HEAVY_DEBUG if (DEBUG_HeavyIsBreakpoint()) return debugCallback; #endif return CBRET_NONE; case BR_CallBack: // the callback code is executed in dosbox.conf, return the callback number FillFlags(); return core_dynrec.callback; case BR_SMCBlock: // LOG_MSG("selfmodification of running block at %x:%x",SegValue(cs),reg_eip); cpu.exception.which=0; // fallthrough, let the normal core handle the block-modifying instruction case BR_Opcode: // some instruction has been encountered that could not be translated // (thus it is not part of the code block), the normal core will // handle this instruction CPU_CycleLeft+=CPU_Cycles; CPU_Cycles=1; return CPU_Core_Normal_Run(); #if (C_DEBUG) case BR_OpcodeFull: CPU_CycleLeft+=CPU_Cycles; CPU_Cycles=1; return CPU_Core_Full_Run(); #endif case BR_Link1: case BR_Link2: block=LinkBlocks(ret); if (block) goto run_block; break; default: E_Exit("Invalid return code %d", ret); } } return CBRET_NONE; } Bits CPU_Core_Dynrec_Trap_Run(void) { Bits oldCycles = CPU_Cycles; CPU_Cycles = 1; cpu.trap_skip = false; // let the normal core execute the next (only one!) instruction Bits ret=CPU_Core_Normal_Run(); // trap to int1 unless the last instruction deferred this // (allows hardware interrupts to be served without interaction) if (!cpu.trap_skip) CPU_HW_Interrupt(1); CPU_Cycles = oldCycles-1; // continue (either the trapflag was clear anyways, or the int1 cleared it) cpudecoder = &CPU_Core_Dynrec_Run; return ret; } void CPU_Core_Dynrec_Init(void) { } void CPU_Core_Dynrec_Cache_Init(bool enable_cache) { // Initialize code cache and dynamic blocks cache_init(enable_cache); } void CPU_Core_Dynrec_Cache_Close(void) { cache_close(); } #endif