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/* |
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* Copyright (C) 2005-2006 Anders Gavare. All rights reserved. |
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* |
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* Redistribution and use in source and binary forms, with or without |
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* modification, are permitted provided that the following conditions are met: |
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* |
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* 1. Redistributions of source code must retain the above copyright |
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* notice, this list of conditions and the following disclaimer. |
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* 2. Redistributions in binary form must reproduce the above copyright |
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* notice, this list of conditions and the following disclaimer in the |
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* documentation and/or other materials provided with the distribution. |
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* 3. The name of the author may not be used to endorse or promote products |
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* derived from this software without specific prior written permission. |
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* |
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* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND |
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* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE |
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE |
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* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE |
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* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL |
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* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS |
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* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) |
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* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT |
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* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY |
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* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF |
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* SUCH DAMAGE. |
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* |
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* |
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* $Id: cpu_dyntrans.c,v 1.113 2006/07/21 20:09:15 debug Exp $ |
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* |
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* Common dyntrans routines. Included from cpu_*.c. |
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*/ |
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|
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|
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#ifndef STATIC_STUFF |
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#define STATIC_STUFF |
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/* |
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* gather_statistics(): |
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*/ |
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static void gather_statistics(struct cpu *cpu) |
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{ |
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char ch, buf[60]; |
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struct DYNTRANS_IC *ic = cpu->cd.DYNTRANS_ARCH.next_ic; |
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int i = 0; |
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uint64_t a; |
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int low_pc = ((size_t)cpu->cd.DYNTRANS_ARCH.next_ic - (size_t) |
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cpu->cd.DYNTRANS_ARCH.cur_ic_page) / sizeof(struct DYNTRANS_IC); |
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|
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buf[0] = '\0'; |
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|
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while ((ch = cpu->machine->statistics_fields[i]) != '\0') { |
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if (i != 0) |
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strlcat(buf, " ", sizeof(buf)); |
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|
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switch (ch) { |
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case 'i': |
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snprintf(buf + strlen(buf), sizeof(buf), |
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"%p", (void *)ic->f); |
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break; |
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case 'p': |
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/* Physical program counter address: */ |
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/* (low_pc must be within the page!) */ |
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if (low_pc < 0 || |
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low_pc >= DYNTRANS_IC_ENTRIES_PER_PAGE) |
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strlcat(buf, "-", sizeof(buf)); |
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cpu->cd.DYNTRANS_ARCH.cur_physpage = (void *) |
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cpu->cd.DYNTRANS_ARCH.cur_ic_page; |
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a = cpu->cd.DYNTRANS_ARCH.cur_physpage->physaddr; |
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a &= ~((DYNTRANS_IC_ENTRIES_PER_PAGE-1) << |
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DYNTRANS_INSTR_ALIGNMENT_SHIFT); |
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a += low_pc << DYNTRANS_INSTR_ALIGNMENT_SHIFT; |
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if (cpu->is_32bit) |
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snprintf(buf + strlen(buf), sizeof(buf), |
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"0x%016"PRIx32, (uint32_t)a); |
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else |
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snprintf(buf + strlen(buf), sizeof(buf), |
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"0x%016"PRIx64, (uint64_t)a); |
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break; |
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case 'v': |
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/* Virtual program counter address: */ |
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/* (low_pc inside the page, or in a delay slot) */ |
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if (low_pc < 0 || |
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low_pc >= DYNTRANS_IC_ENTRIES_PER_PAGE + 2) |
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strlcat(buf, "-", sizeof(buf)); |
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a = cpu->pc; |
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a &= ~((DYNTRANS_IC_ENTRIES_PER_PAGE-1) << |
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DYNTRANS_INSTR_ALIGNMENT_SHIFT); |
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a += low_pc << DYNTRANS_INSTR_ALIGNMENT_SHIFT; |
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if (cpu->is_32bit) |
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snprintf(buf + strlen(buf), sizeof(buf), |
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"0x%016"PRIx32, (uint32_t)a); |
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else |
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snprintf(buf + strlen(buf), sizeof(buf), |
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"0x%016"PRIx64, (uint64_t)a); |
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break; |
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} |
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i++; |
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} |
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|
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fprintf(cpu->machine->statistics_file, "%s\n", buf); |
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} |
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|
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|
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#define S gather_statistics(cpu) |
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|
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|
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#ifdef DYNTRANS_VARIABLE_INSTRUCTION_LENGTH |
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#define I ic = cpu->cd.DYNTRANS_ARCH.next_ic; \ |
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cpu->cd.DYNTRANS_ARCH.next_ic += ic->arg[0]; \ |
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ic->f(cpu, ic); |
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#else |
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|
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/* The normal instruction execution core: */ |
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#define I ic = cpu->cd.DYNTRANS_ARCH.next_ic ++; ic->f(cpu, ic); |
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|
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/* For heavy debugging: */ |
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/* #define I ic = cpu->cd.DYNTRANS_ARCH.next_ic ++; \ |
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{ \ |
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int low_pc = ((size_t)cpu->cd.DYNTRANS_ARCH.next_ic - \ |
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(size_t)cpu->cd.DYNTRANS_ARCH.cur_ic_page) / \ |
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sizeof(struct DYNTRANS_IC); \ |
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printf("cur_ic_page=%p ic=%p (low_pc=0x%x)\n", \ |
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cpu->cd.DYNTRANS_ARCH.cur_ic_page, \ |
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ic, low_pc << DYNTRANS_INSTR_ALIGNMENT_SHIFT); \ |
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} \ |
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ic->f(cpu, ic); */ |
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|
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/* static long long nr_of_I_calls = 0; */ |
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|
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/* Temporary hack for finding NULL bugs: */ |
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/* #define I ic = cpu->cd.DYNTRANS_ARCH.next_ic ++; \ |
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nr_of_I_calls ++; \ |
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if (ic->f == NULL) { \ |
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int low_pc = ((size_t)cpu->cd.DYNTRANS_ARCH.next_ic - \ |
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(size_t)cpu->cd.DYNTRANS_ARCH.cur_ic_page) / \ |
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sizeof(struct DYNTRANS_IC); \ |
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cpu->pc &= ~((DYNTRANS_IC_ENTRIES_PER_PAGE-1) << \ |
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DYNTRANS_INSTR_ALIGNMENT_SHIFT); \ |
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cpu->pc += (low_pc << DYNTRANS_INSTR_ALIGNMENT_SHIFT);\ |
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printf("Crash at %016"PRIx64"\n", cpu->pc); \ |
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printf("nr of I calls: %lli\n", nr_of_I_calls); \ |
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printf("Next ic = %p\n", cpu->cd. \ |
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DYNTRANS_ARCH.next_ic); \ |
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printf("cur ic page = %p\n", cpu->cd. \ |
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DYNTRANS_ARCH.cur_ic_page); \ |
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cpu->running = 0; \ |
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return 0; \ |
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} \ |
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ic->f(cpu, ic); */ |
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|
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/* Temporary hack for MIPS, to hunt for 32-bit/64-bit sign-extension bugs: */ |
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/* #define I { int k; for (k=1; k<=31; k++) \ |
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cpu->cd.mips.gpr[k] = (int32_t)cpu->cd.mips.gpr[k];\ |
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if (cpu->cd.mips.gpr[0] != 0) { \ |
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fatal("NOOOOOO\n"); exit(1); \ |
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} \ |
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ic = cpu->cd.DYNTRANS_ARCH.next_ic ++; ic->f(cpu, ic); } |
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*/ |
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#endif |
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#endif /* STATIC STUFF */ |
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|
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|
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|
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#ifdef DYNTRANS_RUN_INSTR |
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/* |
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* XXX_run_instr(): |
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* |
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* Execute one or more instructions on a specific CPU, using dyntrans. |
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* (For dualmode archs, this function is included twice.) |
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* |
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* Return value is the number of instructions executed during this call, |
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* 0 if no instructions were executed. |
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*/ |
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int DYNTRANS_RUN_INSTR(struct cpu *cpu) |
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{ |
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MODE_uint_t cached_pc; |
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int low_pc, n_instrs; |
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|
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/* Ugly... fix this some day. */ |
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#ifdef DYNTRANS_DUALMODE_32 |
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#ifdef MODE32 |
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DYNTRANS_PC_TO_POINTERS32(cpu); |
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#else |
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DYNTRANS_PC_TO_POINTERS(cpu); |
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#endif |
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#else |
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DYNTRANS_PC_TO_POINTERS(cpu); |
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#endif |
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|
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/* |
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* Interrupt assertion? (This is _below_ the initial PC to pointer |
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* conversion; if the conversion caused an exception of some kind |
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* then interrupts are probably disabled, and the exception will get |
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* priority over device interrupts.) |
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* |
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* TODO: Turn this into a family-specific function somewhere... |
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*/ |
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#ifdef DYNTRANS_ARM |
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if (cpu->cd.arm.irq_asserted && !(cpu->cd.arm.cpsr & ARM_FLAG_I)) |
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arm_exception(cpu, ARM_EXCEPTION_IRQ); |
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#endif |
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#ifdef DYNTRANS_MIPS |
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{ |
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int enabled, mask; |
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int status = cpu->cd.mips.coproc[0]->reg[COP0_STATUS]; |
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if (cpu->cd.mips.cpu_type.exc_model == EXC3K) { |
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/* R3000: */ |
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enabled = status & MIPS_SR_INT_IE; |
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} else { |
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/* R4000 and others: */ |
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enabled = (status & STATUS_IE) |
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&& !(status & STATUS_EXL) && !(status & STATUS_ERL); |
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/* Special case for R5900/C790/TX79: */ |
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if (cpu->cd.mips.cpu_type.rev == MIPS_R5900 && |
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!(status & R5900_STATUS_EIE)) |
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enabled = 0; |
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} |
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mask = status & cpu->cd.mips.coproc[0]->reg[COP0_CAUSE] |
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& STATUS_IM_MASK; |
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|
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if (enabled && mask) |
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mips_cpu_exception(cpu, EXCEPTION_INT, 0, 0, 0, 0, 0,0); |
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} |
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#endif |
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#ifdef DYNTRANS_PPC |
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if (cpu->cd.ppc.dec_intr_pending && cpu->cd.ppc.msr & PPC_MSR_EE) { |
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ppc_exception(cpu, PPC_EXCEPTION_DEC); |
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cpu->cd.ppc.dec_intr_pending = 0; |
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} |
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if (cpu->cd.ppc.irq_asserted && cpu->cd.ppc.msr & PPC_MSR_EE) |
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ppc_exception(cpu, PPC_EXCEPTION_EI); |
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#endif |
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|
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cached_pc = cpu->pc; |
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|
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cpu->n_translated_instrs = 0; |
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cpu->running_translated = 1; |
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|
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cpu->cd.DYNTRANS_ARCH.cur_physpage = (void *) |
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cpu->cd.DYNTRANS_ARCH.cur_ic_page; |
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|
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if (single_step || cpu->machine->instruction_trace |
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|| cpu->machine->register_dump) { |
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/* |
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* Single-step: |
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*/ |
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struct DYNTRANS_IC *ic = cpu->cd.DYNTRANS_ARCH.next_ic; |
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if (cpu->machine->register_dump) { |
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debug("\n"); |
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cpu_register_dump(cpu->machine, cpu, 1, 0x1); |
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} |
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if (cpu->machine->instruction_trace) { |
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#ifdef DYNTRANS_X86 |
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unsigned char instr[17]; |
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cpu->cd.x86.cursegment = X86_S_CS; |
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cpu->cd.x86.seg_override = 0; |
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#else |
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#ifdef DYNTRANS_M68K |
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unsigned char instr[16]; /* TODO: 16? */ |
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#else |
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unsigned char instr[4]; /* General case... */ |
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#endif |
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#endif |
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|
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if (!cpu->memory_rw(cpu, cpu->mem, cached_pc, &instr[0], |
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sizeof(instr), MEM_READ, CACHE_INSTRUCTION)) { |
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fatal("XXX_run_instr(): could not read " |
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"the instruction\n"); |
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} else { |
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cpu_disassemble_instr(cpu->machine, cpu, |
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instr, 1, 0); |
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#ifdef DYNTRANS_DELAYSLOT |
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/* Show the instruction in the delay slot, |
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if any: */ |
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if (cpu->instruction_has_delayslot == NULL) |
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fatal("WARNING: ihd func not yet" |
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" implemented?\n"); |
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else if (cpu->instruction_has_delayslot(cpu, |
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instr)) { |
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int saved_delayslot = cpu->delay_slot; |
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cpu->memory_rw(cpu, cpu->mem, cached_pc |
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+ sizeof(instr), &instr[0], |
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sizeof(instr), MEM_READ, |
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CACHE_INSTRUCTION); |
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cpu->delay_slot = DELAYED; |
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cpu->pc += sizeof(instr); |
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cpu_disassemble_instr(cpu->machine, |
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cpu, instr, 1, 0); |
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cpu->delay_slot = saved_delayslot; |
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cpu->pc -= sizeof(instr); |
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} |
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#endif |
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} |
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} |
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|
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/* When single-stepping, multiple instruction calls cannot |
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be combined into one. This clears all translations: */ |
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if (cpu->cd.DYNTRANS_ARCH.cur_physpage->flags & COMBINATIONS) { |
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int i; |
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for (i=0; i<DYNTRANS_IC_ENTRIES_PER_PAGE; i++) { |
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cpu->cd.DYNTRANS_ARCH.cur_physpage->ics[i].f = |
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#ifdef DYNTRANS_DUALMODE_32 |
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cpu->is_32bit? |
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instr32(to_be_translated) : |
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#endif |
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instr(to_be_translated); |
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#ifdef DYNTRANS_VARIABLE_INSTRUCTION_LENGTH |
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cpu->cd.DYNTRANS_ARCH.cur_physpage->ics[i]. |
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arg[0] = 0; |
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#endif |
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} |
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|
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fatal("[ Note: The translation of physical page 0x%" |
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PRIx64" contained combinations of instructions; " |
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"these are now flushed because we are single-" |
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"stepping. ]\n", (long long)cpu->cd.DYNTRANS_ARCH. |
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cur_physpage->physaddr); |
317 |
|
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cpu->cd.DYNTRANS_ARCH.cur_physpage->flags &= |
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~COMBINATIONS; |
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cpu->cd.DYNTRANS_ARCH.cur_physpage->translations = 0; |
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} |
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|
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if (cpu->machine->statistics_enabled) |
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S; |
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|
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/* Execute just one instruction: */ |
327 |
I; |
328 |
|
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n_instrs = 1; |
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} else if (cpu->machine->cycle_accurate) { |
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/* Executing multiple instructions, and call devices' |
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tick functions: */ |
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n_instrs = 0; |
334 |
for (;;) { |
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struct DYNTRANS_IC *ic; |
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/* TODO: continue here */ |
337 |
int64_t cycles = cpu->cd.avr.extra_cycles; |
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I; |
339 |
n_instrs += 1; |
340 |
cycles = cpu->cd.avr.extra_cycles - cycles + 1; |
341 |
/* The instruction took 'cycles' cycles. */ |
342 |
/* printf("A\n"); */ |
343 |
while (cycles-- > 0) |
344 |
cpu->machine->tick_func[1](cpu, cpu->machine->tick_extra[1]); |
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/* printf("B\n"); */ |
346 |
|
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if (!cpu->running_translated || |
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n_instrs + cpu->n_translated_instrs >= |
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N_SAFE_DYNTRANS_LIMIT) |
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break; |
351 |
} |
352 |
} else if (cpu->machine->statistics_enabled) { |
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/* Gather statistics while executing multiple instructions: */ |
354 |
n_instrs = 0; |
355 |
for (;;) { |
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struct DYNTRANS_IC *ic; |
357 |
|
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S; I; S; I; S; I; S; I; S; I; S; I; |
359 |
S; I; S; I; S; I; S; I; S; I; S; I; |
360 |
S; I; S; I; S; I; S; I; S; I; S; I; |
361 |
S; I; S; I; S; I; S; I; S; I; S; I; |
362 |
|
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n_instrs += 24; |
364 |
|
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if (!cpu->running_translated || |
366 |
n_instrs + cpu->n_translated_instrs >= |
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N_SAFE_DYNTRANS_LIMIT) |
368 |
break; |
369 |
} |
370 |
} else { |
371 |
/* Execute multiple instructions: */ |
372 |
n_instrs = 0; |
373 |
for (;;) { |
374 |
struct DYNTRANS_IC *ic; |
375 |
|
376 |
I; I; I; I; I; I; I; I; I; I; |
377 |
I; I; I; I; I; I; I; I; I; I; |
378 |
I; I; I; I; I; I; I; I; I; I; |
379 |
I; I; I; I; I; I; I; I; I; I; |
380 |
I; I; I; I; I; I; I; I; I; I; |
381 |
|
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I; I; I; I; I; I; I; I; I; I; |
383 |
|
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n_instrs += 60; |
385 |
|
386 |
if (!cpu->running_translated || |
387 |
n_instrs + cpu->n_translated_instrs >= |
388 |
N_SAFE_DYNTRANS_LIMIT) |
389 |
break; |
390 |
} |
391 |
} |
392 |
|
393 |
n_instrs += cpu->n_translated_instrs; |
394 |
|
395 |
/* Synchronize the program counter: */ |
396 |
low_pc = ((size_t)cpu->cd.DYNTRANS_ARCH.next_ic - (size_t) |
397 |
cpu->cd.DYNTRANS_ARCH.cur_ic_page) / sizeof(struct DYNTRANS_IC); |
398 |
if (low_pc >= 0 && low_pc < DYNTRANS_IC_ENTRIES_PER_PAGE) { |
399 |
cpu->pc &= ~((DYNTRANS_IC_ENTRIES_PER_PAGE-1) << |
400 |
DYNTRANS_INSTR_ALIGNMENT_SHIFT); |
401 |
cpu->pc += (low_pc << DYNTRANS_INSTR_ALIGNMENT_SHIFT); |
402 |
} else if (low_pc == DYNTRANS_IC_ENTRIES_PER_PAGE) { |
403 |
/* Switch to next page: */ |
404 |
cpu->pc &= ~((DYNTRANS_IC_ENTRIES_PER_PAGE-1) << |
405 |
DYNTRANS_INSTR_ALIGNMENT_SHIFT); |
406 |
cpu->pc += (DYNTRANS_IC_ENTRIES_PER_PAGE << |
407 |
DYNTRANS_INSTR_ALIGNMENT_SHIFT); |
408 |
} else if (low_pc == DYNTRANS_IC_ENTRIES_PER_PAGE + 1) { |
409 |
/* Switch to next page and skip an instruction which was |
410 |
already executed (in a delay slot): */ |
411 |
cpu->pc &= ~((DYNTRANS_IC_ENTRIES_PER_PAGE-1) << |
412 |
DYNTRANS_INSTR_ALIGNMENT_SHIFT); |
413 |
cpu->pc += ((DYNTRANS_IC_ENTRIES_PER_PAGE + 1) << |
414 |
DYNTRANS_INSTR_ALIGNMENT_SHIFT); |
415 |
} |
416 |
|
417 |
#ifdef DYNTRANS_MIPS |
418 |
/* Update the count register (on everything except EXC3K): */ |
419 |
if (cpu->cd.mips.cpu_type.exc_model != EXC3K) { |
420 |
uint32_t old = cpu->cd.mips.coproc[0]->reg[COP0_COUNT]; |
421 |
int32_t diff1 = cpu->cd.mips.coproc[0]->reg[COP0_COMPARE] - old; |
422 |
int32_t diff2; |
423 |
cpu->cd.mips.coproc[0]->reg[COP0_COUNT] = |
424 |
(int32_t) (old + n_instrs); |
425 |
diff2 = cpu->cd.mips.coproc[0]->reg[COP0_COMPARE] - |
426 |
cpu->cd.mips.coproc[0]->reg[COP0_COUNT]; |
427 |
if (cpu->cd.mips.compare_register_set && diff1>0 && diff2<=0) |
428 |
cpu_interrupt(cpu, 7); |
429 |
} |
430 |
#endif |
431 |
#ifdef DYNTRANS_PPC |
432 |
/* Update the Decrementer and Time base registers: */ |
433 |
{ |
434 |
uint32_t old = cpu->cd.ppc.spr[SPR_DEC]; |
435 |
cpu->cd.ppc.spr[SPR_DEC] = (uint32_t) (old - n_instrs); |
436 |
if ((old >> 31) == 0 && (cpu->cd.ppc.spr[SPR_DEC] >> 31) == 1 |
437 |
&& !(cpu->cd.ppc.cpu_type.flags & PPC_NO_DEC)) |
438 |
cpu->cd.ppc.dec_intr_pending = 1; |
439 |
old = cpu->cd.ppc.spr[SPR_TBL]; |
440 |
cpu->cd.ppc.spr[SPR_TBL] += n_instrs; |
441 |
if ((old >> 31) == 1 && (cpu->cd.ppc.spr[SPR_TBL] >> 31) == 0) |
442 |
cpu->cd.ppc.spr[SPR_TBU] ++; |
443 |
} |
444 |
#endif |
445 |
|
446 |
/* Return the nr of instructions executed: */ |
447 |
return n_instrs; |
448 |
} |
449 |
#endif /* DYNTRANS_RUN_INSTR */ |
450 |
|
451 |
|
452 |
|
453 |
#ifdef DYNTRANS_FUNCTION_TRACE |
454 |
/* |
455 |
* XXX_cpu_functioncall_trace(): |
456 |
* |
457 |
* Without this function, the main trace tree function prints something |
458 |
* like <f()> or <0x1234()> on a function call. It is up to this |
459 |
* function to print the arguments passed. |
460 |
*/ |
461 |
void DYNTRANS_FUNCTION_TRACE(struct cpu *cpu, uint64_t f, int n_args) |
462 |
{ |
463 |
char strbuf[50]; |
464 |
char *symbol; |
465 |
uint64_t ot; |
466 |
int x, print_dots = 1, n_args_to_print = |
467 |
#if defined(DYNTRANS_ALPHA) || defined(DYNTRANS_SPARC) |
468 |
6 |
469 |
#else |
470 |
#ifdef DYNTRANS_SH |
471 |
8 |
472 |
#else |
473 |
4 /* Default value for most archs */ |
474 |
#endif |
475 |
#endif |
476 |
; |
477 |
|
478 |
if (n_args >= 0 && n_args <= n_args_to_print) { |
479 |
print_dots = 0; |
480 |
n_args_to_print = n_args; |
481 |
} |
482 |
|
483 |
/* |
484 |
* TODO: The type of each argument should be taken from the symbol |
485 |
* table, in some way. |
486 |
* |
487 |
* The code here does a kind of "heuristic guess" regarding what the |
488 |
* argument values might mean. Sometimes the output looks weird, but |
489 |
* usually it looks good enough. |
490 |
* |
491 |
* Print ".." afterwards to show that there might be more arguments |
492 |
* than were passed in register. |
493 |
*/ |
494 |
for (x=0; x<n_args_to_print; x++) { |
495 |
int64_t d; |
496 |
#if defined(DYNTRANS_X86) || defined(DYNTRANS_TRANSPUTER) |
497 |
d = 0; /* TODO */ |
498 |
#else |
499 |
/* Args in registers: */ |
500 |
d = cpu->cd.DYNTRANS_ARCH. |
501 |
#ifdef DYNTRANS_ALPHA |
502 |
r[ALPHA_A0 |
503 |
#endif |
504 |
#ifdef DYNTRANS_ARM |
505 |
r[0 |
506 |
#endif |
507 |
#ifdef DYNTRANS_AVR |
508 |
/* TODO: 24,25 = first register, but then |
509 |
they go downwards, ie. 22,23 and so on */ |
510 |
r[24 |
511 |
#endif |
512 |
#ifdef DYNTRANS_HPPA |
513 |
r[0 /* TODO */ |
514 |
#endif |
515 |
#ifdef DYNTRANS_I960 |
516 |
r[0 /* TODO */ |
517 |
#endif |
518 |
#ifdef DYNTRANS_IA64 |
519 |
r[0 /* TODO */ |
520 |
#endif |
521 |
#ifdef DYNTRANS_M68K |
522 |
d[0 /* TODO */ |
523 |
#endif |
524 |
#ifdef DYNTRANS_MIPS |
525 |
gpr[MIPS_GPR_A0 |
526 |
#endif |
527 |
#ifdef DYNTRANS_PPC |
528 |
gpr[3 |
529 |
#endif |
530 |
#ifdef DYNTRANS_SH |
531 |
r[2 |
532 |
#endif |
533 |
#ifdef DYNTRANS_SPARC |
534 |
r[24 |
535 |
#endif |
536 |
+ x]; |
537 |
#endif |
538 |
symbol = get_symbol_name(&cpu->machine->symbol_context, d, &ot); |
539 |
|
540 |
if (d > -256 && d < 256) |
541 |
fatal("%i", (int)d); |
542 |
else if (memory_points_to_string(cpu, cpu->mem, d, 1)) |
543 |
fatal("\"%s\"", memory_conv_to_string(cpu, |
544 |
cpu->mem, d, strbuf, sizeof(strbuf))); |
545 |
else if (symbol != NULL && ot == 0) |
546 |
fatal("&%s", symbol); |
547 |
else { |
548 |
if (cpu->is_32bit) |
549 |
fatal("0x%"PRIx32, (uint32_t)d); |
550 |
else |
551 |
fatal("0x%"PRIx64, (uint64_t)d); |
552 |
} |
553 |
|
554 |
if (x < n_args_to_print - 1) |
555 |
fatal(","); |
556 |
} |
557 |
|
558 |
if (print_dots) |
559 |
fatal(",.."); |
560 |
} |
561 |
#endif |
562 |
|
563 |
|
564 |
|
565 |
#ifdef DYNTRANS_TC_ALLOCATE_DEFAULT_PAGE |
566 |
/* |
567 |
* XXX_tc_allocate_default_page(): |
568 |
* |
569 |
* Create a default page (with just pointers to instr(to_be_translated) |
570 |
* at cpu->translation_cache_cur_ofs. |
571 |
*/ |
572 |
static void DYNTRANS_TC_ALLOCATE_DEFAULT_PAGE(struct cpu *cpu, |
573 |
uint64_t physaddr) |
574 |
{ |
575 |
struct DYNTRANS_TC_PHYSPAGE *ppp; |
576 |
|
577 |
ppp = (struct DYNTRANS_TC_PHYSPAGE *)(cpu->translation_cache |
578 |
+ cpu->translation_cache_cur_ofs); |
579 |
|
580 |
/* Copy the entire template page first: */ |
581 |
memcpy(ppp, cpu->cd.DYNTRANS_ARCH.physpage_template, sizeof( |
582 |
struct DYNTRANS_TC_PHYSPAGE)); |
583 |
|
584 |
ppp->physaddr = physaddr & ~(DYNTRANS_PAGESIZE - 1); |
585 |
|
586 |
cpu->translation_cache_cur_ofs += sizeof(struct DYNTRANS_TC_PHYSPAGE); |
587 |
|
588 |
cpu->translation_cache_cur_ofs --; |
589 |
cpu->translation_cache_cur_ofs |= 127; |
590 |
cpu->translation_cache_cur_ofs ++; |
591 |
} |
592 |
#endif /* DYNTRANS_TC_ALLOCATE_DEFAULT_PAGE */ |
593 |
|
594 |
|
595 |
|
596 |
#ifdef DYNTRANS_PC_TO_POINTERS_FUNC |
597 |
/* |
598 |
* XXX_pc_to_pointers_generic(): |
599 |
* |
600 |
* Generic case. See DYNTRANS_PC_TO_POINTERS_FUNC below. |
601 |
*/ |
602 |
void DYNTRANS_PC_TO_POINTERS_GENERIC(struct cpu *cpu) |
603 |
{ |
604 |
#ifdef MODE32 |
605 |
uint32_t |
606 |
#else |
607 |
uint64_t |
608 |
#endif |
609 |
cached_pc = cpu->pc, physaddr = 0; |
610 |
uint32_t physpage_ofs; |
611 |
int ok, pagenr, table_index; |
612 |
uint32_t *physpage_entryp; |
613 |
struct DYNTRANS_TC_PHYSPAGE *ppp; |
614 |
|
615 |
#ifdef MODE32 |
616 |
int index = DYNTRANS_ADDR_TO_PAGENR(cached_pc); |
617 |
#else |
618 |
const uint32_t mask1 = (1 << DYNTRANS_L1N) - 1; |
619 |
const uint32_t mask2 = (1 << DYNTRANS_L2N) - 1; |
620 |
const uint32_t mask3 = (1 << DYNTRANS_L3N) - 1; |
621 |
uint32_t x1, x2, x3; |
622 |
struct DYNTRANS_L2_64_TABLE *l2; |
623 |
struct DYNTRANS_L3_64_TABLE *l3; |
624 |
|
625 |
x1 = (cached_pc >> (64-DYNTRANS_L1N)) & mask1; |
626 |
x2 = (cached_pc >> (64-DYNTRANS_L1N-DYNTRANS_L2N)) & mask2; |
627 |
x3 = (cached_pc >> (64-DYNTRANS_L1N-DYNTRANS_L2N-DYNTRANS_L3N)) & mask3; |
628 |
/* fatal("X3: cached_pc=%016"PRIx64" x1=%x x2=%x x3=%x\n", |
629 |
(uint64_t)cached_pc, (int)x1, (int)x2, (int)x3); */ |
630 |
l2 = cpu->cd.DYNTRANS_ARCH.l1_64[x1]; |
631 |
/* fatal(" l2 = %p\n", l2); */ |
632 |
l3 = l2->l3[x2]; |
633 |
/* fatal(" l3 = %p\n", l3); */ |
634 |
#endif |
635 |
|
636 |
/* Virtual to physical address translation: */ |
637 |
ok = 0; |
638 |
#ifdef MODE32 |
639 |
if (cpu->cd.DYNTRANS_ARCH.host_load[index] != NULL) { |
640 |
physaddr = cpu->cd.DYNTRANS_ARCH.phys_addr[index]; |
641 |
ok = 1; |
642 |
} |
643 |
#else |
644 |
if (l3->host_load[x3] != NULL) { |
645 |
physaddr = l3->phys_addr[x3]; |
646 |
ok = 1; |
647 |
} |
648 |
#endif |
649 |
|
650 |
if (!ok) { |
651 |
uint64_t paddr; |
652 |
if (cpu->translate_v2p != NULL) { |
653 |
ok = cpu->translate_v2p( |
654 |
cpu, cached_pc, &paddr, FLAG_INSTR); |
655 |
} else { |
656 |
paddr = cached_pc; |
657 |
ok = 1; |
658 |
} |
659 |
if (!ok) { |
660 |
/* |
661 |
* The PC is now set to the exception handler. |
662 |
* Try to find the paddr in the translation arrays, |
663 |
* or if that fails, call translate_v2p for the |
664 |
* exception handler. |
665 |
*/ |
666 |
/* fatal("TODO: instruction vaddr=>paddr translation " |
667 |
"failed. vaddr=0x%"PRIx64"\n", (uint64_t)cached_pc); |
668 |
fatal("!! cpu->pc=0x%"PRIx64"\n", (uint64_t)cpu->pc); */ |
669 |
|
670 |
/* If there was an exception, the PC has changed. |
671 |
Update cached_pc: */ |
672 |
cached_pc = cpu->pc; |
673 |
|
674 |
#ifdef MODE32 |
675 |
index = DYNTRANS_ADDR_TO_PAGENR(cached_pc); |
676 |
if (cpu->cd.DYNTRANS_ARCH.host_load[index] != NULL) { |
677 |
paddr = cpu->cd.DYNTRANS_ARCH.phys_addr[index]; |
678 |
ok = 1; |
679 |
} |
680 |
#else |
681 |
x1 = (cached_pc >> (64-DYNTRANS_L1N)) & mask1; |
682 |
x2 = (cached_pc >> (64-DYNTRANS_L1N-DYNTRANS_L2N)) & mask2; |
683 |
x3 = (cached_pc >> (64-DYNTRANS_L1N-DYNTRANS_L2N-DYNTRANS_L3N)) |
684 |
& mask3; |
685 |
l2 = cpu->cd.DYNTRANS_ARCH.l1_64[x1]; |
686 |
l3 = l2->l3[x2]; |
687 |
if (l3->host_load[x3] != NULL) { |
688 |
paddr = l3->phys_addr[x3]; |
689 |
ok = 1; |
690 |
} |
691 |
#endif |
692 |
|
693 |
if (!ok) { |
694 |
ok = cpu->translate_v2p(cpu, cpu->pc, &paddr, |
695 |
FLAG_INSTR); |
696 |
} |
697 |
|
698 |
/* printf("EXCEPTION HANDLER: vaddr = 0x%x ==> " |
699 |
"paddr = 0x%x\n", (int)cpu->pc, (int)paddr); |
700 |
fatal("!? cpu->pc=0x%"PRIx64"\n", (uint64_t)cpu->pc); */ |
701 |
|
702 |
if (!ok) { |
703 |
fatal("FATAL: could not find physical" |
704 |
" address of the exception handler?"); |
705 |
exit(1); |
706 |
} |
707 |
} |
708 |
|
709 |
physaddr = paddr; |
710 |
} |
711 |
|
712 |
physaddr &= ~(DYNTRANS_PAGESIZE - 1); |
713 |
|
714 |
#ifdef MODE32 |
715 |
if (cpu->cd.DYNTRANS_ARCH.host_load[index] == NULL) { |
716 |
#else |
717 |
if (l3->host_load[x3] == NULL) { |
718 |
#endif |
719 |
int q = DYNTRANS_PAGESIZE - 1; |
720 |
unsigned char *host_page = memory_paddr_to_hostaddr(cpu->mem, |
721 |
physaddr, MEM_READ); |
722 |
if (host_page != NULL) { |
723 |
cpu->update_translation_table(cpu, cached_pc & ~q, |
724 |
host_page, 0, physaddr); |
725 |
} |
726 |
} |
727 |
|
728 |
if (cpu->translation_cache_cur_ofs >= DYNTRANS_CACHE_SIZE) { |
729 |
#ifdef UNSTABLE_DEVEL |
730 |
fatal("[ dyntrans: resetting the translation cache ]\n"); |
731 |
#endif |
732 |
cpu_create_or_reset_tc(cpu); |
733 |
} |
734 |
|
735 |
pagenr = DYNTRANS_ADDR_TO_PAGENR(physaddr); |
736 |
table_index = PAGENR_TO_TABLE_INDEX(pagenr); |
737 |
|
738 |
physpage_entryp = &(((uint32_t *)cpu->translation_cache)[table_index]); |
739 |
physpage_ofs = *physpage_entryp; |
740 |
ppp = NULL; |
741 |
|
742 |
/* Traverse the physical page chain: */ |
743 |
while (physpage_ofs != 0) { |
744 |
ppp = (struct DYNTRANS_TC_PHYSPAGE *)(cpu->translation_cache |
745 |
+ physpage_ofs); |
746 |
|
747 |
/* If we found the page in the cache, then we're done: */ |
748 |
if (ppp->physaddr == physaddr) |
749 |
break; |
750 |
|
751 |
/* Try the next page in the chain: */ |
752 |
physpage_ofs = ppp->next_ofs; |
753 |
} |
754 |
|
755 |
/* If the offset is 0 (or ppp is NULL), then we need to create a |
756 |
new "default" empty translation page. */ |
757 |
|
758 |
if (ppp == NULL) { |
759 |
/* fatal("CREATING page %lli (physaddr 0x%"PRIx64"), table " |
760 |
"index %i\n", (long long)pagenr, (uint64_t)physaddr, |
761 |
(int)table_index); */ |
762 |
*physpage_entryp = physpage_ofs = |
763 |
cpu->translation_cache_cur_ofs; |
764 |
|
765 |
/* Allocate a default page, with to_be_translated entries: */ |
766 |
DYNTRANS_TC_ALLOCATE(cpu, physaddr); |
767 |
|
768 |
ppp = (struct DYNTRANS_TC_PHYSPAGE *)(cpu->translation_cache |
769 |
+ physpage_ofs); |
770 |
} |
771 |
|
772 |
#ifdef MODE32 |
773 |
if (cpu->cd.DYNTRANS_ARCH.host_load[index] != NULL) |
774 |
cpu->cd.DYNTRANS_ARCH.phys_page[index] = ppp; |
775 |
#else |
776 |
if (l3->host_load[x3] != NULL) |
777 |
l3->phys_page[x3] = ppp; |
778 |
#endif |
779 |
|
780 |
/* |
781 |
* If there are no translations yet on this page, then mark it |
782 |
* as non-writable. If there are already translations, then it |
783 |
* should already have been marked as non-writable. |
784 |
*/ |
785 |
if (ppp->translations == 0) { |
786 |
cpu->invalidate_translation_caches(cpu, physaddr, |
787 |
JUST_MARK_AS_NON_WRITABLE | INVALIDATE_PADDR); |
788 |
} |
789 |
|
790 |
cpu->cd.DYNTRANS_ARCH.cur_ic_page = &ppp->ics[0]; |
791 |
|
792 |
cpu->cd.DYNTRANS_ARCH.next_ic = cpu->cd.DYNTRANS_ARCH.cur_ic_page + |
793 |
DYNTRANS_PC_TO_IC_ENTRY(cached_pc); |
794 |
|
795 |
/* printf("cached_pc=0x%016"PRIx64" pagenr=%lli table_index=%lli, " |
796 |
"physpage_ofs=0x%016"PRIx64"\n", (uint64_t)cached_pc, (long long) |
797 |
pagenr, (long long)table_index, (uint64_t)physpage_ofs); */ |
798 |
} |
799 |
|
800 |
|
801 |
/* |
802 |
* XXX_pc_to_pointers(): |
803 |
* |
804 |
* This function uses the current program counter (a virtual address) to |
805 |
* find out which physical translation page to use, and then sets the current |
806 |
* translation page pointers to that page. |
807 |
* |
808 |
* If there was no translation page for that physical page, then an empty |
809 |
* one is created. |
810 |
* |
811 |
* NOTE: This is the quick lookup version. See |
812 |
* DYNTRANS_PC_TO_POINTERS_GENERIC above for the generic case. |
813 |
*/ |
814 |
void DYNTRANS_PC_TO_POINTERS_FUNC(struct cpu *cpu) |
815 |
{ |
816 |
#ifdef MODE32 |
817 |
uint32_t |
818 |
#else |
819 |
uint64_t |
820 |
#endif |
821 |
cached_pc = cpu->pc; |
822 |
struct DYNTRANS_TC_PHYSPAGE *ppp; |
823 |
|
824 |
#ifdef MODE32 |
825 |
int index; |
826 |
index = DYNTRANS_ADDR_TO_PAGENR(cached_pc); |
827 |
ppp = cpu->cd.DYNTRANS_ARCH.phys_page[index]; |
828 |
if (ppp != NULL) |
829 |
goto have_it; |
830 |
#else |
831 |
const uint32_t mask1 = (1 << DYNTRANS_L1N) - 1; |
832 |
const uint32_t mask2 = (1 << DYNTRANS_L2N) - 1; |
833 |
const uint32_t mask3 = (1 << DYNTRANS_L3N) - 1; |
834 |
uint32_t x1, x2, x3; |
835 |
struct DYNTRANS_L2_64_TABLE *l2; |
836 |
struct DYNTRANS_L3_64_TABLE *l3; |
837 |
|
838 |
x1 = (cached_pc >> (64-DYNTRANS_L1N)) & mask1; |
839 |
x2 = (cached_pc >> (64-DYNTRANS_L1N-DYNTRANS_L2N)) & mask2; |
840 |
x3 = (cached_pc >> (64-DYNTRANS_L1N-DYNTRANS_L2N-DYNTRANS_L3N)) & mask3; |
841 |
l2 = cpu->cd.DYNTRANS_ARCH.l1_64[x1]; |
842 |
l3 = l2->l3[x2]; |
843 |
ppp = l3->phys_page[x3]; |
844 |
if (ppp != NULL) |
845 |
goto have_it; |
846 |
#endif |
847 |
|
848 |
DYNTRANS_PC_TO_POINTERS_GENERIC(cpu); |
849 |
return; |
850 |
|
851 |
/* Quick return path: */ |
852 |
have_it: |
853 |
cpu->cd.DYNTRANS_ARCH.cur_ic_page = &ppp->ics[0]; |
854 |
cpu->cd.DYNTRANS_ARCH.next_ic = cpu->cd.DYNTRANS_ARCH.cur_ic_page + |
855 |
DYNTRANS_PC_TO_IC_ENTRY(cached_pc); |
856 |
|
857 |
/* printf("cached_pc=0x%016"PRIx64" pagenr=%lli table_index=%lli, " |
858 |
"physpage_ofs=0x%016"PRIx64"\n", (uint64_t)cached_pc, (long long) |
859 |
pagenr, (long long)table_index, (uint64_t)physpage_ofs); */ |
860 |
} |
861 |
#endif /* DYNTRANS_PC_TO_POINTERS_FUNC */ |
862 |
|
863 |
|
864 |
|
865 |
#ifdef DYNTRANS_INIT_TABLES |
866 |
|
867 |
/* forward declaration of to_be_translated and end_of_page: */ |
868 |
static void instr(to_be_translated)(struct cpu *, struct DYNTRANS_IC *); |
869 |
static void instr(end_of_page)(struct cpu *,struct DYNTRANS_IC *); |
870 |
#ifdef DYNTRANS_DUALMODE_32 |
871 |
static void instr32(to_be_translated)(struct cpu *, struct DYNTRANS_IC *); |
872 |
static void instr32(end_of_page)(struct cpu *,struct DYNTRANS_IC *); |
873 |
#endif |
874 |
|
875 |
#ifdef DYNTRANS_DELAYSLOT |
876 |
static void instr(end_of_page2)(struct cpu *,struct DYNTRANS_IC *); |
877 |
#ifdef DYNTRANS_DUALMODE_32 |
878 |
static void instr32(end_of_page2)(struct cpu *,struct DYNTRANS_IC *); |
879 |
#endif |
880 |
#endif |
881 |
|
882 |
/* |
883 |
* XXX_init_tables(): |
884 |
* |
885 |
* Initializes the default translation page (for newly allocated pages), and |
886 |
* for 64-bit emulation it also initializes 64-bit dummy tables and pointers. |
887 |
*/ |
888 |
void DYNTRANS_INIT_TABLES(struct cpu *cpu) |
889 |
{ |
890 |
#ifndef MODE32 |
891 |
struct DYNTRANS_L2_64_TABLE *dummy_l2; |
892 |
struct DYNTRANS_L3_64_TABLE *dummy_l3; |
893 |
int x1, x2; |
894 |
#endif |
895 |
int i; |
896 |
struct DYNTRANS_TC_PHYSPAGE *ppp = malloc(sizeof( |
897 |
struct DYNTRANS_TC_PHYSPAGE)); |
898 |
|
899 |
if (ppp == NULL) { |
900 |
fprintf(stderr, "out of memory\n"); |
901 |
exit(1); |
902 |
} |
903 |
|
904 |
ppp->next_ofs = 0; |
905 |
ppp->flags = 0; |
906 |
ppp->translations = 0; |
907 |
/* ppp->physaddr is filled in by the page allocator */ |
908 |
|
909 |
for (i=0; i<DYNTRANS_IC_ENTRIES_PER_PAGE; i++) { |
910 |
ppp->ics[i].f = |
911 |
#ifdef DYNTRANS_DUALMODE_32 |
912 |
cpu->is_32bit? instr32(to_be_translated) : |
913 |
#endif |
914 |
instr(to_be_translated); |
915 |
#ifdef DYNTRANS_VARIABLE_INSTRUCTION_LENGTH |
916 |
ppp->ics[i].arg[0] = 0; |
917 |
#endif |
918 |
} |
919 |
|
920 |
/* End-of-page: */ |
921 |
ppp->ics[DYNTRANS_IC_ENTRIES_PER_PAGE + 0].f = |
922 |
#ifdef DYNTRANS_DUALMODE_32 |
923 |
cpu->is_32bit? instr32(end_of_page) : |
924 |
#endif |
925 |
instr(end_of_page); |
926 |
|
927 |
#ifdef DYNTRANS_VARIABLE_INSTRUCTION_LENGTH |
928 |
ppp->ics[DYNTRANS_IC_ENTRIES_PER_PAGE + 0].arg[0] = 0; |
929 |
#endif |
930 |
|
931 |
/* End-of-page-2, for delay-slot architectures: */ |
932 |
#ifdef DYNTRANS_DELAYSLOT |
933 |
ppp->ics[DYNTRANS_IC_ENTRIES_PER_PAGE + 1].f = |
934 |
#ifdef DYNTRANS_DUALMODE_32 |
935 |
cpu->is_32bit? instr32(end_of_page2) : |
936 |
#endif |
937 |
instr(end_of_page2); |
938 |
#endif |
939 |
|
940 |
cpu->cd.DYNTRANS_ARCH.physpage_template = ppp; |
941 |
|
942 |
|
943 |
/* Prepare 64-bit virtual address translation tables: */ |
944 |
#ifndef MODE32 |
945 |
if (cpu->is_32bit) |
946 |
return; |
947 |
|
948 |
dummy_l2 = zeroed_alloc(sizeof(struct DYNTRANS_L2_64_TABLE)); |
949 |
dummy_l3 = zeroed_alloc(sizeof(struct DYNTRANS_L3_64_TABLE)); |
950 |
|
951 |
cpu->cd.DYNTRANS_ARCH.l2_64_dummy = dummy_l2; |
952 |
cpu->cd.DYNTRANS_ARCH.l3_64_dummy = dummy_l3; |
953 |
|
954 |
for (x1 = 0; x1 < (1 << DYNTRANS_L1N); x1 ++) |
955 |
cpu->cd.DYNTRANS_ARCH.l1_64[x1] = dummy_l2; |
956 |
|
957 |
for (x2 = 0; x2 < (1 << DYNTRANS_L2N); x2 ++) |
958 |
dummy_l2->l3[x2] = dummy_l3; |
959 |
#endif |
960 |
} |
961 |
#endif /* DYNTRANS_INIT_TABLES */ |
962 |
|
963 |
|
964 |
|
965 |
#ifdef DYNTRANS_INVAL_ENTRY |
966 |
/* |
967 |
* XXX_invalidate_tlb_entry(): |
968 |
* |
969 |
* Invalidate one translation entry (based on virtual address). |
970 |
* |
971 |
* If the JUST_MARK_AS_NON_WRITABLE flag is set, then the translation entry |
972 |
* is just downgraded to non-writable (ie the host store page is set to |
973 |
* NULL). Otherwise, the entire translation is removed. |
974 |
*/ |
975 |
static void DYNTRANS_INVALIDATE_TLB_ENTRY(struct cpu *cpu, |
976 |
#ifdef MODE32 |
977 |
uint32_t |
978 |
#else |
979 |
uint64_t |
980 |
#endif |
981 |
vaddr_page, int flags) |
982 |
{ |
983 |
#ifdef MODE32 |
984 |
uint32_t index = DYNTRANS_ADDR_TO_PAGENR(vaddr_page); |
985 |
|
986 |
#ifdef DYNTRANS_ARM |
987 |
cpu->cd.DYNTRANS_ARCH.is_userpage[index >> 5] &= ~(1 << (index & 31)); |
988 |
#endif |
989 |
|
990 |
if (flags & JUST_MARK_AS_NON_WRITABLE) { |
991 |
/* printf("JUST MARKING NON-W: vaddr 0x%08x\n", |
992 |
(int)vaddr_page); */ |
993 |
cpu->cd.DYNTRANS_ARCH.host_store[index] = NULL; |
994 |
} else { |
995 |
int tlbi = cpu->cd.DYNTRANS_ARCH.vaddr_to_tlbindex[index]; |
996 |
cpu->cd.DYNTRANS_ARCH.host_load[index] = NULL; |
997 |
cpu->cd.DYNTRANS_ARCH.host_store[index] = NULL; |
998 |
cpu->cd.DYNTRANS_ARCH.phys_addr[index] = 0; |
999 |
cpu->cd.DYNTRANS_ARCH.phys_page[index] = NULL; |
1000 |
if (tlbi > 0) |
1001 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[tlbi-1].valid = 0; |
1002 |
cpu->cd.DYNTRANS_ARCH.vaddr_to_tlbindex[index] = 0; |
1003 |
} |
1004 |
#else |
1005 |
const uint32_t mask1 = (1 << DYNTRANS_L1N) - 1; |
1006 |
const uint32_t mask2 = (1 << DYNTRANS_L2N) - 1; |
1007 |
const uint32_t mask3 = (1 << DYNTRANS_L3N) - 1; |
1008 |
uint32_t x1, x2, x3; |
1009 |
struct DYNTRANS_L2_64_TABLE *l2; |
1010 |
struct DYNTRANS_L3_64_TABLE *l3; |
1011 |
|
1012 |
x1 = (vaddr_page >> (64-DYNTRANS_L1N)) & mask1; |
1013 |
x2 = (vaddr_page >> (64-DYNTRANS_L1N-DYNTRANS_L2N)) & mask2; |
1014 |
x3 = (vaddr_page >> (64-DYNTRANS_L1N-DYNTRANS_L2N-DYNTRANS_L3N))& mask3; |
1015 |
|
1016 |
l2 = cpu->cd.DYNTRANS_ARCH.l1_64[x1]; |
1017 |
if (l2 == cpu->cd.DYNTRANS_ARCH.l2_64_dummy) |
1018 |
return; |
1019 |
|
1020 |
l3 = l2->l3[x2]; |
1021 |
if (l3 == cpu->cd.DYNTRANS_ARCH.l3_64_dummy) |
1022 |
return; |
1023 |
|
1024 |
if (flags & JUST_MARK_AS_NON_WRITABLE) { |
1025 |
l3->host_store[x3] = NULL; |
1026 |
return; |
1027 |
} |
1028 |
|
1029 |
#ifdef BUGHUNT |
1030 |
|
1031 |
{ |
1032 |
/* Consistency check, for debugging: */ |
1033 |
int x1, x1b; // x2, x3; |
1034 |
struct DYNTRANS_L2_64_TABLE *l2; |
1035 |
//struct DYNTRANS_L3_64_TABLE *l3; |
1036 |
|
1037 |
for (x1 = 0; x1 <= mask1; x1 ++) { |
1038 |
l2 = cpu->cd.DYNTRANS_ARCH.l1_64[x1]; |
1039 |
if (l2 == cpu->cd.DYNTRANS_ARCH.l2_64_dummy) |
1040 |
continue; |
1041 |
/* Make sure that this l2 isn't used more than 1 time! */ |
1042 |
for (x1b = 0; x1b <= mask1; x1b ++) |
1043 |
if (x1 != x1b && |
1044 |
l2 == cpu->cd.DYNTRANS_ARCH.l1_64[x1b]) { |
1045 |
fatal("L2 reuse: %p\n", l2); |
1046 |
exit(1); |
1047 |
} |
1048 |
} |
1049 |
} |
1050 |
|
1051 |
/* Count how many pages are actually in use: */ |
1052 |
{ |
1053 |
int n=0, i; |
1054 |
for (i=0; i<=mask3; i++) |
1055 |
if (l3->vaddr_to_tlbindex[i]) |
1056 |
n++; |
1057 |
if (n != l3->refcount) { |
1058 |
printf("Z: %i in use, but refcount = %i!\n", n, l3->refcount); |
1059 |
exit(1); |
1060 |
} |
1061 |
|
1062 |
n = 0; |
1063 |
for (i=0; i<=mask3; i++) |
1064 |
if (l3->host_load[i] != NULL) |
1065 |
n++; |
1066 |
if (n != l3->refcount) { |
1067 |
printf("ZHL: %i in use, but refcount = %i!\n", n, l3->refcount); |
1068 |
exit(1); |
1069 |
} |
1070 |
} |
1071 |
#endif |
1072 |
|
1073 |
l3->host_load[x3] = NULL; |
1074 |
l3->host_store[x3] = NULL; |
1075 |
l3->phys_addr[x3] = 0; |
1076 |
l3->phys_page[x3] = NULL; |
1077 |
if (l3->vaddr_to_tlbindex[x3] != 0) { |
1078 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[ |
1079 |
l3->vaddr_to_tlbindex[x3] - 1].valid = 0; |
1080 |
l3->refcount --; |
1081 |
} |
1082 |
l3->vaddr_to_tlbindex[x3] = 0; |
1083 |
|
1084 |
if (l3->refcount < 0) { |
1085 |
fatal("xxx_invalidate_tlb_entry(): huh? Refcount bug.\n"); |
1086 |
exit(1); |
1087 |
} |
1088 |
|
1089 |
if (l3->refcount == 0) { |
1090 |
l3->next = cpu->cd.DYNTRANS_ARCH.next_free_l3; |
1091 |
cpu->cd.DYNTRANS_ARCH.next_free_l3 = l3; |
1092 |
l2->l3[x2] = cpu->cd.DYNTRANS_ARCH.l3_64_dummy; |
1093 |
|
1094 |
#ifdef BUGHUNT |
1095 |
/* Make sure that we're placing a CLEAN page on the |
1096 |
freelist: */ |
1097 |
{ |
1098 |
int i; |
1099 |
for (i=0; i<=mask3; i++) |
1100 |
if (l3->host_load[i] != NULL) { |
1101 |
fatal("TRYING TO RETURN A NON-CLEAN L3 PAGE!\n"); |
1102 |
exit(1); |
1103 |
} |
1104 |
} |
1105 |
#endif |
1106 |
l2->refcount --; |
1107 |
if (l2->refcount < 0) { |
1108 |
fatal("xxx_invalidate_tlb_entry(): Refcount bug L2.\n"); |
1109 |
exit(1); |
1110 |
} |
1111 |
if (l2->refcount == 0) { |
1112 |
l2->next = cpu->cd.DYNTRANS_ARCH.next_free_l2; |
1113 |
cpu->cd.DYNTRANS_ARCH.next_free_l2 = l2; |
1114 |
cpu->cd.DYNTRANS_ARCH.l1_64[x1] = |
1115 |
cpu->cd.DYNTRANS_ARCH.l2_64_dummy; |
1116 |
} |
1117 |
} |
1118 |
#endif |
1119 |
} |
1120 |
#endif |
1121 |
|
1122 |
|
1123 |
#ifdef DYNTRANS_INVALIDATE_TC |
1124 |
/* |
1125 |
* XXX_invalidate_translation_caches(): |
1126 |
* |
1127 |
* Invalidate all entries matching a specific physical address, a specific |
1128 |
* virtual address, or ALL entries. |
1129 |
* |
1130 |
* flags should be one of |
1131 |
* INVALIDATE_PADDR INVALIDATE_VADDR or INVALIDATE_ALL |
1132 |
* |
1133 |
* In addition, for INVALIDATE_ALL, INVALIDATE_VADDR_UPPER4 may be set and |
1134 |
* bit 31..28 of addr are used to select the virtual addresses to invalidate. |
1135 |
* (This is useful for PowerPC emulation, when segment registers are updated.) |
1136 |
* |
1137 |
* In the case when all translations are invalidated, paddr doesn't need |
1138 |
* to be supplied. |
1139 |
* |
1140 |
* NOTE/TODO: When invalidating a virtual address, it is only cleared from |
1141 |
* the quick translation array, not from the linear |
1142 |
* vph_tlb_entry[] array. Hopefully this is enough anyway. |
1143 |
*/ |
1144 |
void DYNTRANS_INVALIDATE_TC(struct cpu *cpu, uint64_t addr, int flags) |
1145 |
{ |
1146 |
int r; |
1147 |
#ifdef MODE32 |
1148 |
uint32_t |
1149 |
#else |
1150 |
uint64_t |
1151 |
#endif |
1152 |
addr_page = addr & ~(DYNTRANS_PAGESIZE - 1); |
1153 |
|
1154 |
/* fatal("invalidate(): "); */ |
1155 |
|
1156 |
/* Quick case for _one_ virtual addresses: see note above. */ |
1157 |
if (flags & INVALIDATE_VADDR) { |
1158 |
/* fatal("vaddr 0x%08x\n", (int)addr_page); */ |
1159 |
DYNTRANS_INVALIDATE_TLB_ENTRY(cpu, addr_page, flags); |
1160 |
return; |
1161 |
} |
1162 |
|
1163 |
/* Invalidate everything: */ |
1164 |
#ifdef DYNTRANS_PPC |
1165 |
if (flags & INVALIDATE_ALL && flags & INVALIDATE_VADDR_UPPER4) { |
1166 |
/* fatal("all, upper4 (PowerPC segment)\n"); */ |
1167 |
for (r=0; r<DYNTRANS_MAX_VPH_TLB_ENTRIES; r++) { |
1168 |
if (cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].valid && |
1169 |
(cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].vaddr_page |
1170 |
& 0xf0000000) == addr_page) { |
1171 |
DYNTRANS_INVALIDATE_TLB_ENTRY(cpu, cpu->cd. |
1172 |
DYNTRANS_ARCH.vph_tlb_entry[r].vaddr_page, |
1173 |
0); |
1174 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].valid=0; |
1175 |
} |
1176 |
} |
1177 |
return; |
1178 |
} |
1179 |
#endif |
1180 |
if (flags & INVALIDATE_ALL) { |
1181 |
/* fatal("all\n"); */ |
1182 |
for (r=0; r<DYNTRANS_MAX_VPH_TLB_ENTRIES; r++) { |
1183 |
if (cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].valid) { |
1184 |
DYNTRANS_INVALIDATE_TLB_ENTRY(cpu, cpu->cd. |
1185 |
DYNTRANS_ARCH.vph_tlb_entry[r].vaddr_page, |
1186 |
0); |
1187 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].valid=0; |
1188 |
} |
1189 |
} |
1190 |
return; |
1191 |
} |
1192 |
|
1193 |
/* Invalidate a physical page: */ |
1194 |
|
1195 |
if (!(flags & INVALIDATE_PADDR)) |
1196 |
fatal("HUH? Invalidate: Not vaddr, all, or paddr?\n"); |
1197 |
|
1198 |
/* fatal("addr 0x%08x\n", (int)addr_page); */ |
1199 |
|
1200 |
for (r=0; r<DYNTRANS_MAX_VPH_TLB_ENTRIES; r++) { |
1201 |
if (cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].valid && addr_page |
1202 |
== cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].paddr_page) { |
1203 |
DYNTRANS_INVALIDATE_TLB_ENTRY(cpu, |
1204 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].vaddr_page, |
1205 |
flags); |
1206 |
if (flags & JUST_MARK_AS_NON_WRITABLE) |
1207 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r] |
1208 |
.writeflag = 0; |
1209 |
else |
1210 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r] |
1211 |
.valid = 0; |
1212 |
} |
1213 |
} |
1214 |
} |
1215 |
#endif /* DYNTRANS_INVALIDATE_TC */ |
1216 |
|
1217 |
|
1218 |
|
1219 |
#ifdef DYNTRANS_INVALIDATE_TC_CODE |
1220 |
/* |
1221 |
* XXX_invalidate_code_translation(): |
1222 |
* |
1223 |
* Invalidate code translations for a specific physical address, a specific |
1224 |
* virtual address, or for all entries in the cache. |
1225 |
*/ |
1226 |
void DYNTRANS_INVALIDATE_TC_CODE(struct cpu *cpu, uint64_t addr, int flags) |
1227 |
{ |
1228 |
int r; |
1229 |
#ifdef MODE32 |
1230 |
uint32_t |
1231 |
#else |
1232 |
uint64_t |
1233 |
#endif |
1234 |
vaddr_page, paddr_page; |
1235 |
|
1236 |
addr &= ~(DYNTRANS_PAGESIZE-1); |
1237 |
|
1238 |
/* printf("DYNTRANS_INVALIDATE_TC_CODE addr=0x%08x flags=%i\n", |
1239 |
(int)addr, flags); */ |
1240 |
|
1241 |
if (flags & INVALIDATE_PADDR) { |
1242 |
int pagenr, table_index; |
1243 |
uint32_t physpage_ofs, *physpage_entryp; |
1244 |
struct DYNTRANS_TC_PHYSPAGE *ppp, *prev_ppp; |
1245 |
|
1246 |
pagenr = DYNTRANS_ADDR_TO_PAGENR(addr); |
1247 |
table_index = PAGENR_TO_TABLE_INDEX(pagenr); |
1248 |
|
1249 |
physpage_entryp = &(((uint32_t *)cpu-> |
1250 |
translation_cache)[table_index]); |
1251 |
physpage_ofs = *physpage_entryp; |
1252 |
prev_ppp = ppp = NULL; |
1253 |
|
1254 |
/* Traverse the physical page chain: */ |
1255 |
while (physpage_ofs != 0) { |
1256 |
prev_ppp = ppp; |
1257 |
ppp = (struct DYNTRANS_TC_PHYSPAGE *) |
1258 |
(cpu->translation_cache + physpage_ofs); |
1259 |
|
1260 |
/* If we found the page in the cache, |
1261 |
then we're done: */ |
1262 |
if (ppp->physaddr == addr) |
1263 |
break; |
1264 |
|
1265 |
/* Try the next page in the chain: */ |
1266 |
physpage_ofs = ppp->next_ofs; |
1267 |
} |
1268 |
|
1269 |
if (physpage_ofs == 0) |
1270 |
ppp = NULL; |
1271 |
|
1272 |
#if 0 |
1273 |
/* |
1274 |
* "Bypass" the page, removing it from the code cache. |
1275 |
* |
1276 |
* NOTE/TODO: This gives _TERRIBLE_ performance with self- |
1277 |
* modifying code, or when a single page is used for both |
1278 |
* code and (writable) data. |
1279 |
*/ |
1280 |
if (ppp != NULL) { |
1281 |
if (prev_ppp != NULL) |
1282 |
prev_ppp->next_ofs = ppp->next_ofs; |
1283 |
else |
1284 |
*physpage_entryp = ppp->next_ofs; |
1285 |
} |
1286 |
#else |
1287 |
/* |
1288 |
* Instead of removing the page from the code cache, each |
1289 |
* entry can be set to "to_be_translated". This is slow in |
1290 |
* the general case, but in the case of self-modifying code, |
1291 |
* it might be faster since we don't risk wasting cache |
1292 |
* memory as quickly (which would force unnecessary Restarts). |
1293 |
*/ |
1294 |
if (ppp != NULL && ppp->translations != 0) { |
1295 |
uint32_t x = ppp->translations; /* TODO: |
1296 |
urk Should be same type as ppp->translations */ |
1297 |
int i, j, n, m; |
1298 |
n = 8 * sizeof(x); |
1299 |
m = DYNTRANS_IC_ENTRIES_PER_PAGE / n; |
1300 |
|
1301 |
for (i=0; i<n; i++) { |
1302 |
if (x & 1) { |
1303 |
for (j=0; j<m; j++) |
1304 |
ppp->ics[i*m + j].f = |
1305 |
#ifdef DYNTRANS_DUALMODE_32 |
1306 |
cpu->is_32bit? |
1307 |
instr32(to_be_translated) : |
1308 |
#endif |
1309 |
instr(to_be_translated); |
1310 |
} |
1311 |
|
1312 |
x >>= 1; |
1313 |
} |
1314 |
|
1315 |
ppp->flags &= ~COMBINATIONS; |
1316 |
ppp->translations = 0; |
1317 |
} |
1318 |
#endif |
1319 |
} |
1320 |
|
1321 |
/* Invalidate entries in the VPH table: */ |
1322 |
for (r = 0; r < DYNTRANS_MAX_VPH_TLB_ENTRIES; r ++) { |
1323 |
if (cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].valid) { |
1324 |
vaddr_page = cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r] |
1325 |
.vaddr_page & ~(DYNTRANS_PAGESIZE-1); |
1326 |
paddr_page = cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r] |
1327 |
.paddr_page & ~(DYNTRANS_PAGESIZE-1); |
1328 |
|
1329 |
if (flags & INVALIDATE_ALL || |
1330 |
(flags & INVALIDATE_PADDR && paddr_page == addr) || |
1331 |
(flags & INVALIDATE_VADDR && vaddr_page == addr)) { |
1332 |
#ifdef MODE32 |
1333 |
uint32_t index = |
1334 |
DYNTRANS_ADDR_TO_PAGENR(vaddr_page); |
1335 |
cpu->cd.DYNTRANS_ARCH.phys_page[index] = NULL; |
1336 |
#else |
1337 |
const uint32_t mask1 = (1 << DYNTRANS_L1N) - 1; |
1338 |
const uint32_t mask2 = (1 << DYNTRANS_L2N) - 1; |
1339 |
const uint32_t mask3 = (1 << DYNTRANS_L3N) - 1; |
1340 |
uint32_t x1, x2, x3; |
1341 |
struct DYNTRANS_L2_64_TABLE *l2; |
1342 |
struct DYNTRANS_L3_64_TABLE *l3; |
1343 |
|
1344 |
x1 = (vaddr_page >> (64-DYNTRANS_L1N)) & mask1; |
1345 |
x2 = (vaddr_page >> (64-DYNTRANS_L1N - |
1346 |
DYNTRANS_L2N)) & mask2; |
1347 |
x3 = (vaddr_page >> (64-DYNTRANS_L1N - |
1348 |
DYNTRANS_L2N - DYNTRANS_L3N)) & mask3; |
1349 |
l2 = cpu->cd.DYNTRANS_ARCH.l1_64[x1]; |
1350 |
l3 = l2->l3[x2]; |
1351 |
l3->phys_page[x3] = NULL; |
1352 |
#endif |
1353 |
} |
1354 |
} |
1355 |
} |
1356 |
} |
1357 |
#endif /* DYNTRANS_INVALIDATE_TC_CODE */ |
1358 |
|
1359 |
|
1360 |
|
1361 |
#ifdef DYNTRANS_UPDATE_TRANSLATION_TABLE |
1362 |
/* |
1363 |
* XXX_update_translation_table(): |
1364 |
* |
1365 |
* Update the virtual memory translation tables. |
1366 |
*/ |
1367 |
void DYNTRANS_UPDATE_TRANSLATION_TABLE(struct cpu *cpu, uint64_t vaddr_page, |
1368 |
unsigned char *host_page, int writeflag, uint64_t paddr_page) |
1369 |
{ |
1370 |
#ifndef MODE32 |
1371 |
int64_t lowest, highest = -1; |
1372 |
#endif |
1373 |
int found, r, lowest_index, useraccess = 0; |
1374 |
|
1375 |
#ifdef MODE32 |
1376 |
uint32_t index; |
1377 |
vaddr_page &= 0xffffffffULL; |
1378 |
paddr_page &= 0xffffffffULL; |
1379 |
/* fatal("update_translation_table(): v=0x%x, h=%p w=%i" |
1380 |
" p=0x%x\n", (int)vaddr_page, host_page, writeflag, |
1381 |
(int)paddr_page); */ |
1382 |
#else /* !MODE32 */ |
1383 |
const uint32_t mask1 = (1 << DYNTRANS_L1N) - 1; |
1384 |
const uint32_t mask2 = (1 << DYNTRANS_L2N) - 1; |
1385 |
const uint32_t mask3 = (1 << DYNTRANS_L3N) - 1; |
1386 |
uint32_t x1, x2, x3; |
1387 |
struct DYNTRANS_L2_64_TABLE *l2; |
1388 |
struct DYNTRANS_L3_64_TABLE *l3; |
1389 |
|
1390 |
/* fatal("update_translation_table(): v=0x%016"PRIx64", h=%p w=%i" |
1391 |
" p=0x%016"PRIx64"\n", (uint64_t)vaddr_page, host_page, writeflag, |
1392 |
(uint64_t)paddr_page); */ |
1393 |
#endif |
1394 |
|
1395 |
assert((vaddr_page & (DYNTRANS_PAGESIZE-1)) == 0); |
1396 |
assert((paddr_page & (DYNTRANS_PAGESIZE-1)) == 0); |
1397 |
|
1398 |
if (writeflag & MEMORY_USER_ACCESS) { |
1399 |
writeflag &= ~MEMORY_USER_ACCESS; |
1400 |
useraccess = 1; |
1401 |
} |
1402 |
|
1403 |
/* Scan the current TLB entries: */ |
1404 |
lowest_index = 0; |
1405 |
|
1406 |
#ifdef MODE32 |
1407 |
/* |
1408 |
* NOTE 1: vaddr_to_tlbindex is one more than the index, so that |
1409 |
* 0 becomes -1, which means a miss. |
1410 |
* |
1411 |
* NOTE 2: When a miss occurs, instead of scanning the entire tlb |
1412 |
* for the entry with the lowest time stamp, just choosing |
1413 |
* one at random will work as well. |
1414 |
*/ |
1415 |
found = (int)cpu->cd.DYNTRANS_ARCH.vaddr_to_tlbindex[ |
1416 |
DYNTRANS_ADDR_TO_PAGENR(vaddr_page)] - 1; |
1417 |
if (found < 0) { |
1418 |
static unsigned int x = 0; |
1419 |
lowest_index = (x++) % DYNTRANS_MAX_VPH_TLB_ENTRIES; |
1420 |
} |
1421 |
#else |
1422 |
lowest = cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[0].timestamp; |
1423 |
found = -1; |
1424 |
for (r=0; r<DYNTRANS_MAX_VPH_TLB_ENTRIES; r++) { |
1425 |
if (cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].timestamp < lowest) { |
1426 |
lowest = cpu->cd.DYNTRANS_ARCH. |
1427 |
vph_tlb_entry[r].timestamp; |
1428 |
lowest_index = r; |
1429 |
} |
1430 |
if (cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].timestamp > highest) |
1431 |
highest = cpu->cd.DYNTRANS_ARCH. |
1432 |
vph_tlb_entry[r].timestamp; |
1433 |
if (cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].valid && |
1434 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].vaddr_page == |
1435 |
vaddr_page) { |
1436 |
found = r; |
1437 |
break; |
1438 |
} |
1439 |
} |
1440 |
#endif |
1441 |
|
1442 |
if (found < 0) { |
1443 |
/* Create the new TLB entry, overwriting the oldest one: */ |
1444 |
r = lowest_index; |
1445 |
if (cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].valid) { |
1446 |
/* This one has to be invalidated first: */ |
1447 |
DYNTRANS_INVALIDATE_TLB_ENTRY(cpu, |
1448 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].vaddr_page, |
1449 |
0); |
1450 |
} |
1451 |
|
1452 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].valid = 1; |
1453 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].host_page = host_page; |
1454 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].paddr_page = paddr_page; |
1455 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].vaddr_page = vaddr_page; |
1456 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].writeflag = |
1457 |
writeflag & MEM_WRITE; |
1458 |
#ifndef MODE32 |
1459 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].timestamp = highest + 1; |
1460 |
#endif |
1461 |
|
1462 |
/* Add the new translation to the table: */ |
1463 |
#ifdef MODE32 |
1464 |
index = DYNTRANS_ADDR_TO_PAGENR(vaddr_page); |
1465 |
cpu->cd.DYNTRANS_ARCH.host_load[index] = host_page; |
1466 |
cpu->cd.DYNTRANS_ARCH.host_store[index] = |
1467 |
writeflag? host_page : NULL; |
1468 |
cpu->cd.DYNTRANS_ARCH.phys_addr[index] = paddr_page; |
1469 |
cpu->cd.DYNTRANS_ARCH.phys_page[index] = NULL; |
1470 |
cpu->cd.DYNTRANS_ARCH.vaddr_to_tlbindex[index] = r + 1; |
1471 |
#ifdef DYNTRANS_ARM |
1472 |
if (useraccess) |
1473 |
cpu->cd.DYNTRANS_ARCH.is_userpage[index >> 5] |
1474 |
|= 1 << (index & 31); |
1475 |
#endif |
1476 |
#else /* !MODE32 */ |
1477 |
x1 = (vaddr_page >> (64-DYNTRANS_L1N)) & mask1; |
1478 |
x2 = (vaddr_page >> (64-DYNTRANS_L1N-DYNTRANS_L2N)) & mask2; |
1479 |
x3 = (vaddr_page >> (64-DYNTRANS_L1N-DYNTRANS_L2N-DYNTRANS_L3N)) |
1480 |
& mask3; |
1481 |
|
1482 |
l2 = cpu->cd.DYNTRANS_ARCH.l1_64[x1]; |
1483 |
if (l2 == cpu->cd.DYNTRANS_ARCH.l2_64_dummy) { |
1484 |
if (cpu->cd.DYNTRANS_ARCH.next_free_l2 != NULL) { |
1485 |
l2 = cpu->cd.DYNTRANS_ARCH.l1_64[x1] = |
1486 |
cpu->cd.DYNTRANS_ARCH.next_free_l2; |
1487 |
cpu->cd.DYNTRANS_ARCH.next_free_l2 = l2->next; |
1488 |
} else { |
1489 |
int i; |
1490 |
l2 = cpu->cd.DYNTRANS_ARCH.l1_64[x1] = |
1491 |
malloc(sizeof(struct DYNTRANS_L2_64_TABLE)); |
1492 |
l2->refcount = 0; |
1493 |
for (i=0; i<(1 << DYNTRANS_L2N); i++) |
1494 |
l2->l3[i] = cpu->cd.DYNTRANS_ARCH. |
1495 |
l3_64_dummy; |
1496 |
} |
1497 |
if (l2->refcount != 0) { |
1498 |
fatal("Huh? l2 Refcount problem.\n"); |
1499 |
exit(1); |
1500 |
} |
1501 |
} |
1502 |
if (l2 == cpu->cd.DYNTRANS_ARCH.l2_64_dummy) { |
1503 |
fatal("INTERNAL ERROR L2 reuse\n"); |
1504 |
exit(1); |
1505 |
} |
1506 |
l3 = l2->l3[x2]; |
1507 |
if (l3 == cpu->cd.DYNTRANS_ARCH.l3_64_dummy) { |
1508 |
if (cpu->cd.DYNTRANS_ARCH.next_free_l3 != NULL) { |
1509 |
l3 = l2->l3[x2] = |
1510 |
cpu->cd.DYNTRANS_ARCH.next_free_l3; |
1511 |
cpu->cd.DYNTRANS_ARCH.next_free_l3 = l3->next; |
1512 |
} else { |
1513 |
l3 = l2->l3[x2] = zeroed_alloc(sizeof( |
1514 |
struct DYNTRANS_L3_64_TABLE)); |
1515 |
} |
1516 |
if (l3->refcount != 0) { |
1517 |
fatal("Huh? l3 Refcount problem.\n"); |
1518 |
exit(1); |
1519 |
} |
1520 |
l2->refcount ++; |
1521 |
} |
1522 |
if (l3 == cpu->cd.DYNTRANS_ARCH.l3_64_dummy) { |
1523 |
fatal("INTERNAL ERROR L3 reuse\n"); |
1524 |
exit(1); |
1525 |
} |
1526 |
|
1527 |
l3->host_load[x3] = host_page; |
1528 |
l3->host_store[x3] = writeflag? host_page : NULL; |
1529 |
l3->phys_addr[x3] = paddr_page; |
1530 |
l3->phys_page[x3] = NULL; |
1531 |
l3->vaddr_to_tlbindex[x3] = r + 1; |
1532 |
l3->refcount ++; |
1533 |
|
1534 |
#ifdef BUGHUNT |
1535 |
/* Count how many pages are actually in use: */ |
1536 |
{ |
1537 |
int n=0, i; |
1538 |
for (i=0; i<=mask3; i++) |
1539 |
if (l3->vaddr_to_tlbindex[i]) |
1540 |
n++; |
1541 |
if (n != l3->refcount) { |
1542 |
printf("X: %i in use, but refcount = %i!\n", n, l3->refcount); |
1543 |
exit(1); |
1544 |
} |
1545 |
|
1546 |
n = 0; |
1547 |
for (i=0; i<=mask3; i++) |
1548 |
if (l3->host_load[i] != NULL) |
1549 |
n++; |
1550 |
if (n != l3->refcount) { |
1551 |
printf("XHL: %i in use, but refcount = %i!\n", n, l3->refcount); |
1552 |
exit(1); |
1553 |
} |
1554 |
} |
1555 |
#endif |
1556 |
|
1557 |
#endif /* !MODE32 */ |
1558 |
} else { |
1559 |
/* |
1560 |
* The translation was already in the TLB. |
1561 |
* Writeflag = 0: Do nothing. |
1562 |
* Writeflag = 1: Make sure the page is writable. |
1563 |
* Writeflag = MEM_DOWNGRADE: Downgrade to readonly. |
1564 |
*/ |
1565 |
r = found; |
1566 |
#ifndef MODE32 |
1567 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].timestamp = highest + 1; |
1568 |
#endif |
1569 |
if (writeflag & MEM_WRITE) |
1570 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].writeflag = 1; |
1571 |
if (writeflag & MEM_DOWNGRADE) |
1572 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].writeflag = 0; |
1573 |
#ifdef MODE32 |
1574 |
index = DYNTRANS_ADDR_TO_PAGENR(vaddr_page); |
1575 |
cpu->cd.DYNTRANS_ARCH.phys_page[index] = NULL; |
1576 |
#ifdef DYNTRANS_ARM |
1577 |
cpu->cd.DYNTRANS_ARCH.is_userpage[index>>5] &= ~(1<<(index&31)); |
1578 |
if (useraccess) |
1579 |
cpu->cd.DYNTRANS_ARCH.is_userpage[index >> 5] |
1580 |
|= 1 << (index & 31); |
1581 |
#endif |
1582 |
if (cpu->cd.DYNTRANS_ARCH.phys_addr[index] == paddr_page) { |
1583 |
if (writeflag & MEM_WRITE) |
1584 |
cpu->cd.DYNTRANS_ARCH.host_store[index] = |
1585 |
host_page; |
1586 |
if (writeflag & MEM_DOWNGRADE) |
1587 |
cpu->cd.DYNTRANS_ARCH.host_store[index] = NULL; |
1588 |
} else { |
1589 |
/* Change the entire physical/host mapping: */ |
1590 |
cpu->cd.DYNTRANS_ARCH.host_load[index] = host_page; |
1591 |
cpu->cd.DYNTRANS_ARCH.host_store[index] = |
1592 |
writeflag? host_page : NULL; |
1593 |
cpu->cd.DYNTRANS_ARCH.phys_addr[index] = paddr_page; |
1594 |
} |
1595 |
#else /* !MODE32 */ |
1596 |
x1 = (vaddr_page >> (64-DYNTRANS_L1N)) & mask1; |
1597 |
x2 = (vaddr_page >> (64-DYNTRANS_L1N-DYNTRANS_L2N)) & mask2; |
1598 |
x3 = (vaddr_page >> (64-DYNTRANS_L1N-DYNTRANS_L2N-DYNTRANS_L3N)) |
1599 |
& mask3; |
1600 |
l2 = cpu->cd.DYNTRANS_ARCH.l1_64[x1]; |
1601 |
l3 = l2->l3[x2]; |
1602 |
if (l3->phys_addr[x3] == paddr_page) { |
1603 |
if (writeflag & MEM_WRITE) |
1604 |
l3->host_store[x3] = host_page; |
1605 |
if (writeflag & MEM_DOWNGRADE) |
1606 |
l3->host_store[x3] = NULL; |
1607 |
} else { |
1608 |
/* Change the entire physical/host mapping: */ |
1609 |
printf("HOST LOAD 2 set to %p\n", host_page); |
1610 |
l3->host_load[x3] = host_page; |
1611 |
l3->host_store[x3] = writeflag? host_page : NULL; |
1612 |
l3->phys_addr[x3] = paddr_page; |
1613 |
} |
1614 |
|
1615 |
#ifdef BUGHUNT |
1616 |
/* Count how many pages are actually in use: */ |
1617 |
{ |
1618 |
int n=0, i; |
1619 |
for (i=0; i<=mask3; i++) |
1620 |
if (l3->vaddr_to_tlbindex[i]) |
1621 |
n++; |
1622 |
if (n != l3->refcount) { |
1623 |
printf("Y: %i in use, but refcount = %i!\n", n, l3->refcount); |
1624 |
exit(1); |
1625 |
} |
1626 |
|
1627 |
n = 0; |
1628 |
for (i=0; i<=mask3; i++) |
1629 |
if (l3->host_load[i] != NULL) |
1630 |
n++; |
1631 |
if (n != l3->refcount) { |
1632 |
printf("YHL: %i in use, but refcount = %i!\n", n, l3->refcount); |
1633 |
printf("Entry r = %i\n", r); |
1634 |
printf("Valid = %i\n", |
1635 |
cpu->cd.DYNTRANS_ARCH.vph_tlb_entry[r].valid); |
1636 |
exit(1); |
1637 |
} |
1638 |
} |
1639 |
#endif |
1640 |
|
1641 |
#endif /* !MODE32 */ |
1642 |
} |
1643 |
} |
1644 |
#endif /* DYNTRANS_UPDATE_TRANSLATION_TABLE */ |
1645 |
|
1646 |
|
1647 |
/*****************************************************************************/ |
1648 |
|
1649 |
|
1650 |
#ifdef DYNTRANS_TO_BE_TRANSLATED_HEAD |
1651 |
/* |
1652 |
* Check for breakpoints. |
1653 |
*/ |
1654 |
if (!single_step_breakpoint) { |
1655 |
MODE_uint_t curpc = cpu->pc; |
1656 |
int i; |
1657 |
for (i=0; i<cpu->machine->n_breakpoints; i++) |
1658 |
if (curpc == (MODE_uint_t) |
1659 |
cpu->machine->breakpoint_addr[i]) { |
1660 |
if (!cpu->machine->instruction_trace) { |
1661 |
int old_quiet_mode = quiet_mode; |
1662 |
quiet_mode = 0; |
1663 |
DISASSEMBLE(cpu, ib, 1, 0); |
1664 |
quiet_mode = old_quiet_mode; |
1665 |
} |
1666 |
fatal("BREAKPOINT: pc = 0x%"PRIx64"\n(The " |
1667 |
"instruction has not yet executed.)\n", |
1668 |
(uint64_t)cpu->pc); |
1669 |
#ifdef DYNTRANS_DELAYSLOT |
1670 |
if (cpu->delay_slot != NOT_DELAYED) |
1671 |
fatal("ERROR! Breakpoint in a delay" |
1672 |
" slot! Not yet supported.\n"); |
1673 |
#endif |
1674 |
single_step_breakpoint = 1; |
1675 |
single_step = ENTER_SINGLE_STEPPING; |
1676 |
goto stop_running_translated; |
1677 |
} |
1678 |
} |
1679 |
#endif /* DYNTRANS_TO_BE_TRANSLATED_HEAD */ |
1680 |
|
1681 |
|
1682 |
/*****************************************************************************/ |
1683 |
|
1684 |
|
1685 |
#ifdef DYNTRANS_TO_BE_TRANSLATED_TAIL |
1686 |
/* |
1687 |
* If we end up here, then an instruction was translated. Let's mark |
1688 |
* the page as containing a translation at this part of the page. |
1689 |
*/ |
1690 |
|
1691 |
/* Make sure cur_physpage is in synch: */ |
1692 |
cpu->cd.DYNTRANS_ARCH.cur_physpage = (void *) |
1693 |
cpu->cd.DYNTRANS_ARCH.cur_ic_page; |
1694 |
|
1695 |
{ |
1696 |
int x = addr & (DYNTRANS_PAGESIZE - 1); |
1697 |
int addr_per_translation_range = DYNTRANS_PAGESIZE / (8 * |
1698 |
sizeof(cpu->cd.DYNTRANS_ARCH.cur_physpage->translations)); |
1699 |
x /= addr_per_translation_range; |
1700 |
|
1701 |
cpu->cd.DYNTRANS_ARCH.cur_physpage->translations |= (1 << x); |
1702 |
} |
1703 |
|
1704 |
/* |
1705 |
* Now it is time to check for combinations of instructions that can |
1706 |
* be converted into a single function call. |
1707 |
* |
1708 |
* Note: Single-stepping or instruction tracing doesn't work with |
1709 |
* instruction combination. For architectures with delay slots, |
1710 |
* we also ignore combinations if the delay slot is across a page |
1711 |
* boundary. |
1712 |
*/ |
1713 |
if (!single_step && !cpu->machine->instruction_trace |
1714 |
#ifdef DYNTRANS_DELAYSLOT |
1715 |
&& !in_crosspage_delayslot |
1716 |
#endif |
1717 |
) { |
1718 |
if (cpu->cd.DYNTRANS_ARCH.combination_check != NULL && |
1719 |
cpu->machine->allow_instruction_combinations) |
1720 |
cpu->cd.DYNTRANS_ARCH.combination_check(cpu, ic, |
1721 |
addr & (DYNTRANS_PAGESIZE - 1)); |
1722 |
} |
1723 |
|
1724 |
cpu->cd.DYNTRANS_ARCH.combination_check = NULL; |
1725 |
|
1726 |
/* An additional check, to catch some bugs: */ |
1727 |
if (ic->f == ( |
1728 |
#ifdef DYNTRANS_DUALMODE_32 |
1729 |
cpu->is_32bit? instr32(to_be_translated) : |
1730 |
#endif |
1731 |
instr(to_be_translated))) { |
1732 |
fatal("INTERNAL ERROR: ic->f not set!\n"); |
1733 |
goto bad; |
1734 |
} |
1735 |
if (ic->f == NULL) { |
1736 |
fatal("INTERNAL ERROR: ic->f == NULL!\n"); |
1737 |
goto bad; |
1738 |
} |
1739 |
|
1740 |
/* ... and finally execute the translated instruction: */ |
1741 |
if ((single_step_breakpoint && cpu->delay_slot == NOT_DELAYED) |
1742 |
#ifdef DYNTRANS_DELAYSLOT |
1743 |
|| in_crosspage_delayslot |
1744 |
#endif |
1745 |
) { |
1746 |
/* |
1747 |
* Special case when single-stepping: Execute the translated |
1748 |
* instruction, but then replace it with a "to be translated" |
1749 |
* directly afterwards. |
1750 |
*/ |
1751 |
single_step_breakpoint = 0; |
1752 |
#ifdef DYNTRANS_VARIABLE_INSTRUCTION_LENGTH |
1753 |
cpu->cd.DYNTRANS_ARCH.next_ic = ic + ic->arg[0]; |
1754 |
#endif |
1755 |
ic->f(cpu, ic); |
1756 |
ic->f = |
1757 |
#ifdef DYNTRANS_DUALMODE_32 |
1758 |
cpu->is_32bit? instr32(to_be_translated) : |
1759 |
#endif |
1760 |
instr(to_be_translated); |
1761 |
#ifdef DYNTRANS_VARIABLE_INSTRUCTION_LENGTH |
1762 |
ic->arg[0] = 0; |
1763 |
#endif |
1764 |
} else { |
1765 |
#ifdef DYNTRANS_VARIABLE_INSTRUCTION_LENGTH |
1766 |
cpu->cd.DYNTRANS_ARCH.next_ic = ic + ic->arg[0]; |
1767 |
|
1768 |
/* Additional check, for variable length ISAs: */ |
1769 |
if (ic->arg[0] == 0) { |
1770 |
fatal("INTERNAL ERROR: instr len = 0!\n"); |
1771 |
goto bad; |
1772 |
} |
1773 |
#endif |
1774 |
|
1775 |
/* Finally finally :-), execute the instruction: */ |
1776 |
ic->f(cpu, ic); |
1777 |
} |
1778 |
|
1779 |
return; |
1780 |
|
1781 |
|
1782 |
bad: /* |
1783 |
* Nothing was translated. (Unimplemented or illegal instruction.) |
1784 |
*/ |
1785 |
|
1786 |
quiet_mode = 0; |
1787 |
fatal("to_be_translated(): TODO: unimplemented instruction"); |
1788 |
|
1789 |
if (cpu->machine->instruction_trace) |
1790 |
#ifdef MODE32 |
1791 |
fatal(" at 0x%"PRIx32"\n", (uint32_t)cpu->pc); |
1792 |
#else |
1793 |
fatal(" at 0x%"PRIx64"\n", (uint64_t)cpu->pc); |
1794 |
#endif |
1795 |
else { |
1796 |
fatal(":\n"); |
1797 |
DISASSEMBLE(cpu, ib, 1, 0); |
1798 |
} |
1799 |
|
1800 |
cpu->running = 0; |
1801 |
cpu->dead = 1; |
1802 |
stop_running_translated: |
1803 |
debugger_n_steps_left_before_interaction = 0; |
1804 |
cpu->running_translated = 0; |
1805 |
ic = cpu->cd.DYNTRANS_ARCH.next_ic = ¬hing_call; |
1806 |
cpu->cd.DYNTRANS_ARCH.next_ic ++; |
1807 |
|
1808 |
/* Execute the "nothing" instruction: */ |
1809 |
ic->f(cpu, ic); |
1810 |
#endif /* DYNTRANS_TO_BE_TRANSLATED_TAIL */ |
1811 |
|