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/* |
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* Copyright (C) 2005 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_arm.c,v 1.19 2005/06/27 16:44:54 debug Exp $ |
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* |
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* ARM CPU emulation. |
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* |
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* Whenever there is a reference to "(1)", that means |
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* "http://www.pinknoise.demon.co.uk/ARMinstrs/ARMinstrs.html". |
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*/ |
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|
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#include <stdio.h> |
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#include <stdlib.h> |
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#include <string.h> |
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#include <ctype.h> |
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|
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#include "misc.h" |
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|
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|
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#ifndef ENABLE_ARM |
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|
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|
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#include "cpu_arm.h" |
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|
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|
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/* |
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* arm_cpu_family_init(): |
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* |
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* Bogus, when ENABLE_ARM isn't defined. |
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*/ |
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int arm_cpu_family_init(struct cpu_family *fp) |
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{ |
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return 0; |
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} |
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|
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|
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#else /* ENABLE_ARM */ |
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|
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|
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#include "cpu.h" |
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#include "cpu_arm.h" |
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#include "machine.h" |
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#include "memory.h" |
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#include "symbol.h" |
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|
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|
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/* instr uses the same names as in cpu_arm_instr.c */ |
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#define instr(n) arm_instr_ ## n |
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|
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static char *arm_condition_string[16] = { |
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"eq", "ne", "cs", "cc", "mi", "pl", "vs", "vc", |
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"hi", "ls", "ge", "lt", "gt", "le", ""/*Always*/, "(INVALID)" }; |
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|
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/* ARM symbolic register names: */ |
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static char *arm_regname[N_ARM_REGS] = { |
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"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", |
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"r8", "r9", "sl", "fp", "ip", "sp", "lr", "pc" }; |
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|
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/* Data processing instructions: */ |
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static char *arm_dpiname[16] = { |
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"and", "eor", "sub", "rsb", "add", "adc", "sbc", "rsc", |
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"tst", "teq", "cmp", "cmn", "orr", "mov", "bic", "mvn" }; |
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static int arm_dpi_uses_d[16] = { |
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1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 1, 1, 1, 1 }; |
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static int arm_dpi_uses_n[16] = { |
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1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 0 }; |
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|
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extern volatile int single_step; |
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extern int old_show_trace_tree; |
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extern int old_instruction_trace; |
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extern int old_quiet_mode; |
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extern int quiet_mode; |
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|
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|
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/* |
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* arm_cpu_new(): |
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* |
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* Create a new ARM cpu object by filling in the CPU struct. |
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* Return 1 on success, 0 if cpu_type_name isn't a valid ARM processor. |
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*/ |
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int arm_cpu_new(struct cpu *cpu, struct memory *mem, |
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struct machine *machine, int cpu_id, char *cpu_type_name) |
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{ |
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if (strcmp(cpu_type_name, "ARM") != 0) |
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return 0; |
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|
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cpu->memory_rw = arm_memory_rw; |
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|
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cpu->cd.arm.flags = ARM_FLAG_I | ARM_FLAG_F | ARM_MODE_USR32; |
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|
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/* Only show name and caches etc for CPU nr 0: */ |
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if (cpu_id == 0) { |
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debug("%s", cpu->name); |
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} |
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|
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return 1; |
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} |
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|
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|
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/* |
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* arm_cpu_dumpinfo(): |
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*/ |
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void arm_cpu_dumpinfo(struct cpu *cpu) |
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{ |
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debug(" (%i MB translation cache)\n", |
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(int)(ARM_TRANSLATION_CACHE_SIZE / 1048576)); |
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} |
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|
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|
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/* |
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* arm_cpu_list_available_types(): |
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* |
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* Print a list of available ARM CPU types. |
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*/ |
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void arm_cpu_list_available_types(void) |
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{ |
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/* TODO */ |
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|
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debug("ARM\n"); |
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} |
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|
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|
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/* |
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* arm_cpu_register_match(): |
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*/ |
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void arm_cpu_register_match(struct machine *m, char *name, |
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int writeflag, uint64_t *valuep, int *match_register) |
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{ |
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int i, cpunr = 0; |
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|
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/* CPU number: */ |
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|
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/* TODO */ |
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|
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/* Register names: */ |
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for (i=0; i<N_ARM_REGS; i++) { |
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if (strcasecmp(name, arm_regname[i]) == 0) { |
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if (writeflag) { |
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m->cpus[cpunr]->cd.arm.r[i] = *valuep; |
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if (i == ARM_PC) |
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m->cpus[cpunr]->pc = *valuep; |
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} else |
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*valuep = m->cpus[cpunr]->cd.arm.r[i]; |
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*match_register = 1; |
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} |
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} |
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} |
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|
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|
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/* |
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* arm_cpu_register_dump(): |
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* |
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* Dump cpu registers in a relatively readable format. |
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* |
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* gprs: set to non-zero to dump GPRs and some special-purpose registers. |
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* coprocs: set bit 0..3 to dump registers in coproc 0..3. |
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*/ |
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void arm_cpu_register_dump(struct cpu *cpu, int gprs, int coprocs) |
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{ |
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char *symbol; |
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uint64_t offset; |
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int i, x = cpu->cpu_id; |
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|
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if (gprs) { |
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symbol = get_symbol_name(&cpu->machine->symbol_context, |
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cpu->cd.arm.r[ARM_PC], &offset); |
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debug("cpu%i: flags = ", x); |
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debug("%s%s%s%s%s%s", |
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(cpu->cd.arm.flags & ARM_FLAG_N)? "N" : "n", |
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(cpu->cd.arm.flags & ARM_FLAG_Z)? "Z" : "z", |
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(cpu->cd.arm.flags & ARM_FLAG_C)? "C" : "c", |
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(cpu->cd.arm.flags & ARM_FLAG_V)? "V" : "v", |
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(cpu->cd.arm.flags & ARM_FLAG_I)? "I" : "i", |
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(cpu->cd.arm.flags & ARM_FLAG_F)? "F" : "f"); |
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debug(" pc = 0x%08x", (int)cpu->cd.arm.r[ARM_PC]); |
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|
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/* TODO: Flags */ |
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|
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debug(" <%s>\n", symbol != NULL? symbol : " no symbol "); |
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|
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for (i=0; i<N_ARM_REGS; i++) { |
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if ((i % 4) == 0) |
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debug("cpu%i:", x); |
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if (i != ARM_PC) |
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debug(" %s = 0x%08x", arm_regname[i], |
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(int)cpu->cd.arm.r[i]); |
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if ((i % 4) == 3) |
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debug("\n"); |
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} |
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} |
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} |
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|
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|
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/* |
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* arm_cpu_disassemble_instr(): |
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* |
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* Convert an instruction word into human readable format, for instruction |
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* tracing. |
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* |
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* If running is 1, cpu->pc should be the address of the instruction. |
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* |
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* If running is 0, things that depend on the runtime environment (eg. |
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* register contents) will not be shown, and addr will be used instead of |
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* cpu->pc for relative addresses. |
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*/ |
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int arm_cpu_disassemble_instr(struct cpu *cpu, unsigned char *ib, |
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int running, uint64_t dumpaddr, int bintrans) |
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{ |
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uint32_t iw, tmp; |
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int main_opcode, secondary_opcode, s_bit, r16, r12, r8; |
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int p_bit, u_bit, b_bit, w_bit, l_bit; |
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char *symbol, *condition; |
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uint64_t offset; |
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|
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if (running) |
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dumpaddr = cpu->pc; |
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|
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symbol = get_symbol_name(&cpu->machine->symbol_context, |
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dumpaddr, &offset); |
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if (symbol != NULL && offset == 0) |
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debug("<%s>\n", symbol); |
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|
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if (cpu->machine->ncpus > 1 && running) |
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debug("cpu%i:\t", cpu->cpu_id); |
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|
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debug("%08x: ", (int)dumpaddr); |
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|
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if (cpu->byte_order == EMUL_LITTLE_ENDIAN) |
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iw = ib[0] + (ib[1]<<8) + (ib[2]<<16) + (ib[3]<<24); |
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else |
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iw = ib[3] + (ib[2]<<8) + (ib[1]<<16) + (ib[0]<<24); |
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debug("%08x\t", (int)iw); |
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|
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condition = arm_condition_string[iw >> 28]; |
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main_opcode = (iw >> 24) & 15; |
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secondary_opcode = (iw >> 21) & 15; |
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u_bit = (iw >> 23) & 1; |
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b_bit = (iw >> 22) & 1; |
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w_bit = (iw >> 21) & 1; |
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s_bit = l_bit = (iw >> 20) & 1; |
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r16 = (iw >> 16) & 15; |
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r12 = (iw >> 12) & 15; |
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r8 = (iw >> 8) & 15; |
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|
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switch (main_opcode) { |
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case 0x0: |
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case 0x1: |
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case 0x2: |
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case 0x3: |
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/* |
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* See (1): |
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* xxxx000a aaaSnnnn ddddcccc ctttmmmm Register form |
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* xxxx001a aaaSnnnn ddddrrrr bbbbbbbb Immediate form |
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*/ |
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if (iw & 0x80 && !(main_opcode & 2)) { |
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debug("UNIMPLEMENTED reg (c!=0)\n"); |
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break; |
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} |
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|
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debug("%s%s%s\t", arm_dpiname[secondary_opcode], |
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condition, s_bit? "s" : ""); |
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if (arm_dpi_uses_d[secondary_opcode]) |
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debug("%s,", arm_regname[r12]); |
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if (arm_dpi_uses_n[secondary_opcode]) |
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debug("%s,", arm_regname[r16]); |
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|
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if (main_opcode & 2) { |
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/* Immediate form: */ |
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int r = (iw >> 7) & 30; |
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uint32_t b = iw & 0xff; |
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while (r-- > 0) |
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b = (b >> 1) | ((b & 1) << 31); |
297 |
if (b < 15) |
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debug("#%i", b); |
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else |
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debug("#0x%x", b); |
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} else { |
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/* Register form: */ |
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int t = (iw >> 4) & 7; |
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int c = (iw >> 7) & 31; |
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debug("%s", arm_regname[iw & 15]); |
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switch (t) { |
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case 0: if (c != 0) |
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debug(" LSL #%i", c); |
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break; |
310 |
case 1: debug(" LSL %s", arm_regname[c >> 1]); |
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break; |
312 |
case 2: debug(" LSR #%i", c? c : 32); |
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break; |
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case 3: debug(" LSR %s", arm_regname[c >> 1]); |
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break; |
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case 4: debug(" ASR #%i", c? c : 32); |
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break; |
318 |
case 5: debug(" ASR %s", arm_regname[c >> 1]); |
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break; |
320 |
case 6: if (c != 0) |
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debug(" ROR #%i", c); |
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else |
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debug(" RRX"); |
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break; |
325 |
case 7: debug(" ROR %s", arm_regname[c >> 1]); |
326 |
break; |
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} |
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} |
329 |
debug("\n"); |
330 |
break; |
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case 0x4: /* Single Data Transfer */ |
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case 0x5: |
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case 0x6: |
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case 0x7: |
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/* |
336 |
* See (1): |
337 |
* xxxx010P UBWLnnnn ddddoooo oooooooo Immediate form |
338 |
* xxxx011P UBWLnnnn ddddcccc ctt0mmmm Register form |
339 |
*/ |
340 |
p_bit = main_opcode & 1; |
341 |
if (main_opcode >= 6 && iw & 0x10) { |
342 |
debug("TODO: single data transf. but 0x10\n"); |
343 |
break; |
344 |
} |
345 |
debug("%s%s%s", l_bit? "ldr" : "str", |
346 |
condition, b_bit? "b" : ""); |
347 |
if (!p_bit && w_bit) |
348 |
debug("t"); |
349 |
debug("\t%s,[%s", arm_regname[r12], arm_regname[r16]); |
350 |
if (main_opcode < 6) { |
351 |
/* Immediate form: */ |
352 |
uint32_t imm = iw & 0xfff; |
353 |
if (!p_bit) |
354 |
debug("]"); |
355 |
if (imm != 0) |
356 |
debug(",#%s%i", u_bit? "" : "-", imm); |
357 |
if (p_bit) |
358 |
debug("]"); |
359 |
} else { |
360 |
debug(" TODO: REG-form]"); |
361 |
} |
362 |
debug("%s\n", (p_bit && w_bit)? "!" : ""); |
363 |
break; |
364 |
case 0x8: /* Block Data Transfer */ |
365 |
case 0x9: |
366 |
debug("TODO: block data transfer\n"); |
367 |
break; |
368 |
case 0xa: /* B: branch */ |
369 |
case 0xb: /* BL: branch and link */ |
370 |
debug("b%s%s\t", main_opcode == 0xa? "" : "l", condition); |
371 |
tmp = (iw & 0x00ffffff) << 2; |
372 |
if (tmp & 0x02000000) |
373 |
tmp |= 0xfc000000; |
374 |
tmp = (int32_t)(dumpaddr + tmp + 8); |
375 |
debug("0x%x", (int)tmp); |
376 |
symbol = get_symbol_name(&cpu->machine->symbol_context, |
377 |
tmp, &offset); |
378 |
if (symbol != NULL) |
379 |
debug("\t\t<%s>", symbol); |
380 |
debug("\n"); |
381 |
break; |
382 |
case 0xc: /* Coprocessor */ |
383 |
case 0xd: /* LDC/STC */ |
384 |
/* xxxx110P UNWLnnnn DDDDpppp oooooooo LDC/STC */ |
385 |
debug("TODO: coprocessor LDC/STC\n"); |
386 |
break; |
387 |
case 0xe: /* CDP (Coprocessor Op) */ |
388 |
/* or MRC/MCR! |
389 |
* According to (1): |
390 |
* xxxx1110 oooonnnn ddddpppp qqq0mmmm CDP |
391 |
* xxxx1110 oooLNNNN ddddpppp qqq1MMMM MRC/MCR |
392 |
*/ |
393 |
if (iw & 0x10) { |
394 |
debug("%s%s\t", |
395 |
(iw & 0x00100000)? "mrc" : "mcr", condition); |
396 |
debug("%i,%i,r%i,cr%i,cr%i,%i", |
397 |
(int)((iw >> 8) & 15), (int)((iw >>21) & 7), |
398 |
(int)((iw >>12) & 15), (int)((iw >>16) & 15), |
399 |
(int)((iw >> 0) & 15), (int)((iw >> 5) & 7)); |
400 |
} else { |
401 |
debug("cdp%s\t", condition); |
402 |
debug("%i,%i,cr%i,cr%i,cr%i", |
403 |
(int)((iw >> 8) & 15), |
404 |
(int)((iw >>20) & 15), |
405 |
(int)((iw >>12) & 15), |
406 |
(int)((iw >>16) & 15), |
407 |
(int)((iw >> 0) & 15)); |
408 |
if ((iw >> 5) & 7) |
409 |
debug(",0x%x", (int)((iw >> 5) & 7)); |
410 |
} |
411 |
debug("\n"); |
412 |
break; |
413 |
case 0xf: /* SWI */ |
414 |
debug("swi%s\t", condition); |
415 |
debug("0x%x\n", (int)(iw & 0x00ffffff)); |
416 |
break; |
417 |
default:debug("UNIMPLEMENTED\n"); |
418 |
} |
419 |
|
420 |
return sizeof(uint32_t); |
421 |
} |
422 |
|
423 |
|
424 |
/* |
425 |
* arm_create_or_reset_tc(): |
426 |
* |
427 |
* Create the translation cache in memory (ie allocate memory for it), if |
428 |
* necessary, and then reset it to an initial state. |
429 |
*/ |
430 |
static void arm_create_or_reset_tc(struct cpu *cpu) |
431 |
{ |
432 |
if (cpu->cd.arm.translation_cache == NULL) { |
433 |
cpu->cd.arm.translation_cache = malloc( |
434 |
ARM_TRANSLATION_CACHE_SIZE + ARM_TRANSLATION_CACHE_MARGIN); |
435 |
if (cpu->cd.arm.translation_cache == NULL) { |
436 |
fprintf(stderr, "arm_create_or_reset_tc(): out of " |
437 |
"memory when allocating the translation cache\n"); |
438 |
exit(1); |
439 |
} |
440 |
} |
441 |
|
442 |
/* Create an empty table at the beginning of the translation cache: */ |
443 |
memset(cpu->cd.arm.translation_cache, 0, sizeof(uint32_t) * |
444 |
N_BASE_TABLE_ENTRIES); |
445 |
|
446 |
cpu->cd.arm.translation_cache_cur_ofs = |
447 |
N_BASE_TABLE_ENTRIES * sizeof(uint32_t); |
448 |
} |
449 |
|
450 |
|
451 |
/* |
452 |
* arm_tc_allocate_default_page(): |
453 |
* |
454 |
* Create a default page (with just pointers to instr(to_be_translated) |
455 |
* at cpu->cd.arm.translation_cache_cur_ofs. |
456 |
*/ |
457 |
/* forward declaration of to_be_translated and end_of_page: */ |
458 |
static void instr(to_be_translated)(struct cpu *,struct arm_instr_call *); |
459 |
static void instr(end_of_page)(struct cpu *,struct arm_instr_call *); |
460 |
static void arm_tc_allocate_default_page(struct cpu *cpu, uint32_t physaddr) |
461 |
{ |
462 |
struct arm_tc_physpage *ppp; |
463 |
int i; |
464 |
|
465 |
/* Create the physpage header: */ |
466 |
ppp = (struct arm_tc_physpage *)(cpu->cd.arm.translation_cache |
467 |
+ cpu->cd.arm.translation_cache_cur_ofs); |
468 |
ppp->next_ofs = 0; |
469 |
ppp->physaddr = physaddr; |
470 |
|
471 |
for (i=0; i<IC_ENTRIES_PER_PAGE; i++) |
472 |
ppp->ics[i].f = instr(to_be_translated); |
473 |
|
474 |
ppp->ics[IC_ENTRIES_PER_PAGE].f = instr(end_of_page); |
475 |
|
476 |
cpu->cd.arm.translation_cache_cur_ofs += |
477 |
sizeof(struct arm_tc_physpage); |
478 |
} |
479 |
|
480 |
|
481 |
#define MEMORY_RW arm_memory_rw |
482 |
#define MEM_ARM |
483 |
#include "memory_rw.c" |
484 |
#undef MEM_ARM |
485 |
#undef MEMORY_RW |
486 |
|
487 |
|
488 |
#include "cpu_arm_instr.c" |
489 |
|
490 |
|
491 |
/* |
492 |
* arm_cpu_run_instr(): |
493 |
* |
494 |
* Execute one or more instructions on a specific CPU. |
495 |
* |
496 |
* Return value is the number of instructions executed during this call, |
497 |
* 0 if no instructions were executed. |
498 |
*/ |
499 |
int arm_cpu_run_instr(struct emul *emul, struct cpu *cpu) |
500 |
{ |
501 |
/* |
502 |
* Find the correct translated page in the translation cache, |
503 |
* and start running code on that page. |
504 |
*/ |
505 |
|
506 |
uint32_t cached_pc, physaddr, physpage_ofs; |
507 |
int pagenr, table_index, n_instrs, low_pc; |
508 |
uint32_t *physpage_entryp; |
509 |
struct arm_tc_physpage *ppp; |
510 |
|
511 |
if (cpu->cd.arm.translation_cache == NULL || cpu->cd. |
512 |
arm.translation_cache_cur_ofs >= ARM_TRANSLATION_CACHE_SIZE) |
513 |
arm_create_or_reset_tc(cpu); |
514 |
|
515 |
cached_pc = cpu->cd.arm.r[ARM_PC]; |
516 |
|
517 |
physaddr = cached_pc & ~(((IC_ENTRIES_PER_PAGE-1) << 2) | 3); |
518 |
/* TODO: virtual to physical */ |
519 |
|
520 |
pagenr = ADDR_TO_PAGENR(physaddr); |
521 |
table_index = PAGENR_TO_TABLE_INDEX(pagenr); |
522 |
|
523 |
physpage_entryp = &(((uint32_t *) |
524 |
cpu->cd.arm.translation_cache)[table_index]); |
525 |
physpage_ofs = *physpage_entryp; |
526 |
ppp = NULL; |
527 |
|
528 |
/* Traverse the physical page chain: */ |
529 |
while (physpage_ofs != 0) { |
530 |
ppp = (struct arm_tc_physpage *)(cpu->cd.arm.translation_cache |
531 |
+ physpage_ofs); |
532 |
/* If we found the page in the cache, then we're done: */ |
533 |
if (ppp->physaddr == physaddr) |
534 |
break; |
535 |
/* Try the next page in the chain: */ |
536 |
physpage_ofs = ppp->next_ofs; |
537 |
} |
538 |
|
539 |
/* If the offset is 0 (or ppp is NULL), then we need to create a |
540 |
new "default" empty translation page. */ |
541 |
|
542 |
if (ppp == NULL) { |
543 |
fatal("CREATING page %i (physaddr 0x%08x), table index = %i\n", |
544 |
pagenr, physaddr, table_index); |
545 |
*physpage_entryp = physpage_ofs = |
546 |
cpu->cd.arm.translation_cache_cur_ofs; |
547 |
|
548 |
arm_tc_allocate_default_page(cpu, physaddr); |
549 |
|
550 |
ppp = (struct arm_tc_physpage *)(cpu->cd.arm.translation_cache |
551 |
+ physpage_ofs); |
552 |
} |
553 |
|
554 |
cpu->cd.arm.cur_physpage = ppp; |
555 |
cpu->cd.arm.cur_ic_page = &ppp->ics[0]; |
556 |
cpu->cd.arm.next_ic = cpu->cd.arm.cur_ic_page + |
557 |
PC_TO_IC_ENTRY(cached_pc); |
558 |
|
559 |
/* printf("cached_pc = 0x%08x pagenr = %i table_index = %i, " |
560 |
"physpage_ofs = 0x%08x\n", (int)cached_pc, (int)pagenr, |
561 |
(int)table_index, (int)physpage_ofs); */ |
562 |
|
563 |
cpu->cd.arm.n_translated_instrs = 0; |
564 |
cpu->cd.arm.running_translated = 1; |
565 |
|
566 |
if (single_step || cpu->machine->instruction_trace) { |
567 |
/* |
568 |
* Single-step: |
569 |
*/ |
570 |
struct arm_instr_call *ic = cpu->cd.arm.next_ic ++; |
571 |
if (cpu->machine->instruction_trace) { |
572 |
unsigned char instr[4]; |
573 |
if (!cpu->memory_rw(cpu, cpu->mem, cpu->pc, &instr[0], |
574 |
sizeof(instr), MEM_READ, CACHE_INSTRUCTION)) { |
575 |
fatal("arm_cpu_run_instr(): could not read " |
576 |
"the instruction\n"); |
577 |
} else |
578 |
arm_cpu_disassemble_instr(cpu, instr, 1, 0, 0); |
579 |
} |
580 |
|
581 |
/* When single-stepping, multiple instruction calls cannot |
582 |
be combined into one. This clears all translations: */ |
583 |
if (ppp->flags & ARM_COMBINATIONS) { |
584 |
int i; |
585 |
for (i=0; i<IC_ENTRIES_PER_PAGE; i++) |
586 |
ppp->ics[i].f = instr(to_be_translated); |
587 |
debug("[ Note: The translation of physical page 0x%08x" |
588 |
" contained combinations of instructions; these " |
589 |
"are now flushed because we are single-stepping." |
590 |
" ]\n", ppp->physaddr); |
591 |
ppp->flags &= ~ARM_COMBINATIONS; |
592 |
} |
593 |
|
594 |
/* Execute just one instruction: */ |
595 |
ic->f(cpu, ic); |
596 |
n_instrs = 1; |
597 |
} else { |
598 |
/* Execute multiple instructions: */ |
599 |
n_instrs = 0; |
600 |
for (;;) { |
601 |
struct arm_instr_call *ic; |
602 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
603 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
604 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
605 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
606 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
607 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
608 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
609 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
610 |
|
611 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
612 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
613 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
614 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
615 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
616 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
617 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
618 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
619 |
|
620 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
621 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
622 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
623 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
624 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
625 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
626 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
627 |
ic = cpu->cd.arm.next_ic ++; ic->f(cpu, ic); |
628 |
|
629 |
n_instrs += 24; |
630 |
if (!cpu->cd.arm.running_translated || single_step || |
631 |
n_instrs + cpu->cd.arm.n_translated_instrs >= 8192) |
632 |
break; |
633 |
} |
634 |
} |
635 |
|
636 |
|
637 |
/* |
638 |
* Update the program counter and return the correct number of |
639 |
* executed instructions: |
640 |
*/ |
641 |
low_pc = ((size_t)cpu->cd.arm.next_ic - (size_t) |
642 |
cpu->cd.arm.cur_ic_page) / sizeof(struct arm_instr_call); |
643 |
|
644 |
if (low_pc >= 0 && low_pc < IC_ENTRIES_PER_PAGE) { |
645 |
cpu->cd.arm.r[ARM_PC] &= ~((IC_ENTRIES_PER_PAGE-1) << 2); |
646 |
cpu->cd.arm.r[ARM_PC] += (low_pc << 2); |
647 |
cpu->pc = cpu->cd.arm.r[ARM_PC]; |
648 |
} else { |
649 |
fatal("Outside a page (This is actually ok)\n"); |
650 |
} |
651 |
|
652 |
return n_instrs + cpu->cd.arm.n_translated_instrs; |
653 |
} |
654 |
|
655 |
|
656 |
#define CPU_RUN arm_cpu_run |
657 |
#define CPU_RINSTR arm_cpu_run_instr |
658 |
#define CPU_RUN_ARM |
659 |
#include "cpu_run.c" |
660 |
#undef CPU_RINSTR |
661 |
#undef CPU_RUN_ARM |
662 |
#undef CPU_RUN |
663 |
|
664 |
|
665 |
/* |
666 |
* arm_cpu_family_init(): |
667 |
* |
668 |
* This function fills the cpu_family struct with valid data. |
669 |
*/ |
670 |
int arm_cpu_family_init(struct cpu_family *fp) |
671 |
{ |
672 |
fp->name = "ARM"; |
673 |
fp->cpu_new = arm_cpu_new; |
674 |
fp->list_available_types = arm_cpu_list_available_types; |
675 |
fp->register_match = arm_cpu_register_match; |
676 |
fp->disassemble_instr = arm_cpu_disassemble_instr; |
677 |
fp->register_dump = arm_cpu_register_dump; |
678 |
fp->run = arm_cpu_run; |
679 |
fp->dumpinfo = arm_cpu_dumpinfo; |
680 |
/* fp->show_full_statistics = arm_cpu_show_full_statistics; */ |
681 |
/* fp->tlbdump = arm_cpu_tlbdump; */ |
682 |
/* fp->interrupt = arm_cpu_interrupt; */ |
683 |
/* fp->interrupt_ack = arm_cpu_interrupt_ack; */ |
684 |
return 1; |
685 |
} |
686 |
|
687 |
#endif /* ENABLE_ARM */ |