#include #include #include #define EFLAGS_VM 0x20000 #define V86_VALID_FLAGS 0xDFF // ---- Ugly big static data STATIC_MUTEX(v86_mutex); v86_regs_t v86_regs; bool v86_if; pagedir_t *v86_pagedir = 0; void* v86_alloc_addr; bool v86_retval; thread_t *v86_caller_thread = 0; thread_t *v86_thread = 0; uint32_t v86_int_no; pagedir_t *v86_prev_pagedir = 0; // ---- Setup code void v86_thread_main(void*); void v86_ex_handler(registers_t *regs); void v86_pf_handler(void*, registers_t *regs, void* addr); void v86_asm_enter_v86(v86_regs_t*); bool v86_begin_session() { mutex_lock(&v86_mutex); if (v86_pagedir == 0) { v86_pagedir = create_pagedir(v86_pf_handler, 0); if (v86_pagedir == 0) return false; v86_prev_pagedir = get_current_pagedir(); switch_pagedir(v86_pagedir); for (void* addr = (void*)V86_ALLOC_ADDR; addr < (void*)V86_STACK_TOP; addr += PAGE_SIZE) { pd_map_page(addr, (uint32_t)addr / PAGE_SIZE, true); } for (void* addr = (void*)V86_BIOS_BEGIN; addr < (void*)V86_BIOS_END; addr += PAGE_SIZE) { pd_map_page(addr, (uint32_t)addr / PAGE_SIZE, true); } pd_map_page(0, 0, true); } else { v86_prev_pagedir = get_current_pagedir(); switch_pagedir(v86_pagedir); } if (v86_thread == 0) { v86_thread = new_thread(v86_thread_main, (void*)1); if (v86_thread == 0) return false; v86_thread->user_ex_handler = v86_ex_handler; v86_retval = false; start_thread(v86_thread); while (!v86_retval) yield(); } v86_alloc_addr = (void*)V86_ALLOC_ADDR; memset(&v86_regs, 0, sizeof(v86_regs)); return true; } void v86_end_session() { switch_pagedir(v86_prev_pagedir); v86_prev_pagedir = 0; v86_caller_thread = 0; mutex_unlock(&v86_mutex); } void* v86_alloc(size_t size) { void* addr = v86_alloc_addr; v86_alloc_addr += size; return addr; } bool v86_bios_int(uint8_t int_no) { v86_caller_thread = current_thread; v86_int_no = int_no; int st = enter_critical(CL_NOSWITCH); resume_on(v86_thread); wait_on(current_thread); exit_critical(st); return v86_retval; } void v86_run_bios_int(uint32_t int_no) { switch_pagedir(v86_pagedir); uint16_t *ivt = (uint16_t*)0; v86_regs.cs = ivt[2 * int_no + 1]; v86_regs.ip = ivt[2 * int_no]; v86_regs.ss = ((V86_STACK_TOP - 0x10000) >> 4); v86_regs.sp = 0; v86_if = true; v86_asm_enter_v86(&v86_regs); } void v86_thread_main(void* z) { if (z) v86_retval = true; wait_on(current_thread); v86_run_bios_int(v86_int_no); } void v86_exit_thread(bool status) { v86_retval = status; resume_on(v86_caller_thread); v86_thread_main(0); } bool v86_gpf_handler(registers_t *regs) { uint8_t* ip = (uint8_t*)V86_LIN_OF_SEG_OFF(regs->cs, regs->eip); uint16_t *stack = (uint16_t*)V86_LIN_OF_SEG_OFF(regs->ss, (regs->esp & 0xFFFF)); uint32_t *stack32 = (uint32_t*)stack; bool is_operand32 = false; // bool is_address32 = false; while (true) { switch (ip[0]) { case 0x66: // O32 is_operand32 = true; ip++; regs->eip = (uint16_t)(regs->eip + 1); break; case 0x67: // A32 // is_address32 = true; ip++; regs->eip = (uint16_t)(regs->eip + 1); break; case 0x9C: // PUSHF if (is_operand32) { regs->esp = ((regs->esp & 0xFFFF) - 4) & 0xFFFF; stack32--; *stack32 = regs->eflags & V86_VALID_FLAGS; if (v86_if) *stack32 |= EFLAGS_IF; else *stack32 &= ~EFLAGS_IF; } else { regs->esp = ((regs->esp & 0xFFFF) - 2) & 0xFFFF; stack--; *stack = regs->eflags; if (v86_if) *stack |= EFLAGS_IF; else *stack &= ~EFLAGS_IF; } regs->eip = (uint16_t)(regs->eip + 1); return true; case 0x9D: // POPF if (is_operand32) { regs->eflags = EFLAGS_IF | EFLAGS_VM | (stack32[0] & V86_VALID_FLAGS); v86_if = (stack32[0] & EFLAGS_IF) != 0; regs->esp = ((regs->esp & 0xFFFF) + 4) & 0xFFFF; } else { regs->eflags = EFLAGS_IF | EFLAGS_VM | stack[0]; v86_if = (stack[0] & EFLAGS_IF) != 0; regs->esp = ((regs->esp & 0xFFFF) + 2) & 0xFFFF; } regs->eip = (uint16_t)(regs->eip + 1); return true; case 0xCF: // IRET v86_regs.ax = (uint16_t)regs->eax; v86_regs.bx = (uint16_t)regs->ebx; v86_regs.cx = (uint16_t)regs->ecx; v86_regs.dx = (uint16_t)regs->edx; v86_regs.di = (uint16_t)regs->edi; v86_regs.si = (uint16_t)regs->esi; v86_exit_thread(true); case 0xFA: // CLI v86_if = false; regs->eip = (uint16_t)(regs->eip + 1); return true; case 0xFB: // STI v86_if = true; regs->eip = (uint16_t)(regs->eip + 1); return true; default: return false; } } } void v86_ex_handler(registers_t *regs) { if (regs->int_no == EX_GENERAL_PROTECTION) { if (!v86_gpf_handler(regs)) v86_exit_thread(false); } else { v86_exit_thread(false); } } void v86_pf_handler(void* zero, registers_t *regs, void* addr) { dbg_printf("Unexpected V86 PF at 0x%p\n", addr); if (current_thread == v86_thread) { v86_exit_thread(false); } else { PANIC("V86 memory access exception."); } } /* vim: set ts=4 sw=4 tw=0 noet :*/