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/* |
/* |
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* Copyright (C) 2005 Anders Gavare. All rights reserved. |
* 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 |
* 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: |
* modification, are permitted provided that the following conditions are met: |
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* SUCH DAMAGE. |
* SUCH DAMAGE. |
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* |
* |
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* |
* |
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* $Id: cpu.c,v 1.292 2005/04/14 21:01:53 debug Exp $ |
* $Id: cpu.c,v 1.348 2006/07/20 21:52:59 debug Exp $ |
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* |
* |
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* Common routines for CPU emulation. (Not specific to any CPU type.) |
* Common routines for CPU emulation. (Not specific to any CPU type.) |
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*/ |
*/ |
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#include <stdio.h> |
#include <stdio.h> |
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#include <stdlib.h> |
#include <stdlib.h> |
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#include <sys/types.h> |
#include <sys/types.h> |
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#include <sys/mman.h> |
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#include <string.h> |
#include <string.h> |
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#include "cpu.h" |
#include "cpu.h" |
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#include "machine.h" |
#include "machine.h" |
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#include "memory.h" |
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#include "misc.h" |
#include "misc.h" |
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extern int quiet_mode; |
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extern int show_opcode_statistics; |
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static struct cpu_family *first_cpu_family = NULL; |
static struct cpu_family *first_cpu_family = NULL; |
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struct cpu *cpu_new(struct memory *mem, struct machine *machine, |
struct cpu *cpu_new(struct memory *mem, struct machine *machine, |
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int cpu_id, char *name) |
int cpu_id, char *name) |
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{ |
{ |
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struct cpu *c; |
struct cpu *cpu; |
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struct cpu_family *fp; |
struct cpu_family *fp; |
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char *cpu_type_name; |
char *cpu_type_name; |
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exit(1); |
exit(1); |
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} |
} |
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cpu = zeroed_alloc(sizeof(struct cpu)); |
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cpu->memory_rw = NULL; |
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cpu->name = cpu_type_name; |
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cpu->mem = mem; |
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cpu->machine = machine; |
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cpu->cpu_id = cpu_id; |
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cpu->byte_order = EMUL_LITTLE_ENDIAN; |
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cpu->bootstrap_cpu_flag = 0; |
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cpu->running = 0; |
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cpu_create_or_reset_tc(cpu); |
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fp = first_cpu_family; |
fp = first_cpu_family; |
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while (fp != NULL) { |
while (fp != NULL) { |
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if (fp->cpu_new != NULL) { |
if (fp->cpu_new != NULL) { |
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c = fp->cpu_new(mem, machine, cpu_id, cpu_type_name); |
if (fp->cpu_new(cpu, mem, machine, cpu_id, |
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if (c != NULL) { |
cpu_type_name)) { |
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/* Some sanity-checks: */ |
/* Sanity check: */ |
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if (c->memory_rw == NULL) { |
if (cpu->memory_rw == NULL) { |
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fatal("No memory_rw?\n"); |
fatal("\ncpu_new(): memory_rw == " |
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"NULL\n"); |
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exit(1); |
exit(1); |
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} |
} |
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break; |
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return c; |
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} |
} |
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} |
} |
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fp = fp->next; |
fp = fp->next; |
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} |
} |
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fprintf(stderr, "cpu_new(): unknown cpu type '%s'\n", cpu_type_name); |
if (fp == NULL) { |
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exit(1); |
fatal("\ncpu_new(): unknown cpu type '%s'\n", cpu_type_name); |
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} |
return NULL; |
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} |
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fp->init_tables(cpu); |
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/* |
return cpu; |
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* cpu_show_full_statistics(): |
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* |
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* Show detailed statistics on opcode usage on each cpu. |
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*/ |
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void cpu_show_full_statistics(struct machine *m) |
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{ |
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if (m->cpu_family == NULL || |
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m->cpu_family->show_full_statistics == NULL) |
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fatal("cpu_show_full_statistics(): NULL\n"); |
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else |
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m->cpu_family->show_full_statistics(m); |
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} |
} |
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* tracing. |
* tracing. |
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*/ |
*/ |
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int cpu_disassemble_instr(struct machine *m, struct cpu *cpu, |
int cpu_disassemble_instr(struct machine *m, struct cpu *cpu, |
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unsigned char *instr, int running, uint64_t addr, int bintrans) |
unsigned char *instr, int running, uint64_t addr) |
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{ |
{ |
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if (m->cpu_family == NULL || m->cpu_family->disassemble_instr == NULL) { |
if (m->cpu_family == NULL || m->cpu_family->disassemble_instr == NULL) { |
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fatal("cpu_disassemble_instr(): NULL\n"); |
fatal("cpu_disassemble_instr(): NULL\n"); |
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return 0; |
return 0; |
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} else |
} else |
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return m->cpu_family->disassemble_instr(cpu, instr, |
return m->cpu_family->disassemble_instr(cpu, instr, |
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running, addr, bintrans); |
running, addr); |
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} |
} |
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* |
* |
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* Dump cpu registers in a relatively readable format. |
* Dump cpu registers in a relatively readable format. |
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* |
* |
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* gprs: set to non-zero to dump GPRs. (CPU dependant.) |
* gprs: set to non-zero to dump GPRs. (CPU dependent.) |
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* coprocs: set bit 0..x to dump registers in coproc 0..x. (CPU dependant.) |
* coprocs: set bit 0..x to dump registers in coproc 0..x. (CPU dependent.) |
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*/ |
*/ |
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void cpu_register_dump(struct machine *m, struct cpu *cpu, |
void cpu_register_dump(struct machine *m, struct cpu *cpu, |
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int gprs, int coprocs) |
int gprs, int coprocs) |
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/* |
/* |
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* cpu_gdb_stub(): |
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* |
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* Execute a "remote GDB" command. Return value is a pointer to a newly |
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* allocated response string, if the command was successfully executed. If |
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* there was an error, NULL is returned. |
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*/ |
192 |
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char *cpu_gdb_stub(struct cpu *cpu, char *cmd) |
193 |
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{ |
194 |
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if (cpu->machine->cpu_family == NULL || |
195 |
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cpu->machine->cpu_family->gdb_stub == NULL) { |
196 |
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fatal("cpu_gdb_stub(): NULL\n"); |
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return NULL; |
198 |
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} else |
199 |
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return cpu->machine->cpu_family->gdb_stub(cpu, cmd); |
200 |
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} |
201 |
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203 |
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/* |
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* cpu_interrupt(): |
* cpu_interrupt(): |
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* |
* |
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* Assert an interrupt. |
* Assert an interrupt. |
235 |
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236 |
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/* |
/* |
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* cpu_run(): |
* cpu_functioncall_trace(): |
239 |
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* |
240 |
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* This function should be called if machine->show_trace_tree is enabled, and |
241 |
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* a function call is being made. f contains the address of the function. |
242 |
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*/ |
243 |
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void cpu_functioncall_trace(struct cpu *cpu, uint64_t f) |
244 |
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{ |
245 |
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int i, n_args = -1; |
246 |
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char *symbol; |
247 |
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uint64_t offset; |
248 |
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249 |
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if (cpu->machine->ncpus > 1) |
250 |
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fatal("cpu%i:\t", cpu->cpu_id); |
251 |
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252 |
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cpu->trace_tree_depth ++; |
253 |
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if (cpu->trace_tree_depth > 100) |
254 |
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cpu->trace_tree_depth = 100; |
255 |
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for (i=0; i<cpu->trace_tree_depth; i++) |
256 |
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fatal(" "); |
257 |
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258 |
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fatal("<"); |
259 |
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symbol = get_symbol_name_and_n_args(&cpu->machine->symbol_context, |
260 |
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f, &offset, &n_args); |
261 |
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if (symbol != NULL) |
262 |
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fatal("%s", symbol); |
263 |
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else { |
264 |
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if (cpu->is_32bit) |
265 |
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fatal("0x%"PRIx32, (uint32_t) f); |
266 |
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else |
267 |
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fatal("0x%"PRIx64, (uint64_t) f); |
268 |
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} |
269 |
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fatal("("); |
270 |
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271 |
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if (cpu->machine->cpu_family->functioncall_trace != NULL) |
272 |
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cpu->machine->cpu_family->functioncall_trace(cpu, f, n_args); |
273 |
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274 |
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fatal(")>\n"); |
275 |
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276 |
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#ifdef PRINT_MEMORY_CHECKSUM |
277 |
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/* Temporary hack for finding bugs: */ |
278 |
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fatal("call chksum=%016"PRIx64"\n", memory_checksum(cpu->mem)); |
279 |
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#endif |
280 |
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} |
281 |
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282 |
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283 |
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/* |
284 |
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* cpu_functioncall_trace_return(): |
285 |
* |
* |
286 |
* Run instructions on all CPUs in this machine, for a "medium duration" |
* This function should be called if machine->show_trace_tree is enabled, and |
287 |
* (or until all CPUs have halted). |
* a function is being returned from. |
288 |
* |
* |
289 |
* Return value is 1 if anything happened, 0 if all CPUs are stopped. |
* TODO: Print return value? This could be implemented similar to the |
290 |
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* cpu->functioncall_trace function call above. |
291 |
*/ |
*/ |
292 |
int cpu_run(struct emul *emul, struct machine *m) |
void cpu_functioncall_trace_return(struct cpu *cpu) |
293 |
{ |
{ |
294 |
if (m->cpu_family == NULL || m->cpu_family->run == NULL) { |
cpu->trace_tree_depth --; |
295 |
fatal("cpu_run(): NULL\n"); |
if (cpu->trace_tree_depth < 0) |
296 |
return 0; |
cpu->trace_tree_depth = 0; |
297 |
} else |
} |
298 |
return m->cpu_family->run(emul, m); |
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299 |
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300 |
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/* |
301 |
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* cpu_create_or_reset_tc(): |
302 |
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* |
303 |
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* Create the translation cache in memory (ie allocate memory for it), if |
304 |
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* necessary, and then reset it to an initial state. |
305 |
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*/ |
306 |
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void cpu_create_or_reset_tc(struct cpu *cpu) |
307 |
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{ |
308 |
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size_t s = DYNTRANS_CACHE_SIZE + DYNTRANS_CACHE_MARGIN; |
309 |
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310 |
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if (cpu->translation_cache == NULL) |
311 |
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cpu->translation_cache = zeroed_alloc(s); |
312 |
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313 |
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/* Create an empty table at the beginning of the translation cache: */ |
314 |
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memset(cpu->translation_cache, 0, sizeof(uint32_t) |
315 |
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* N_BASE_TABLE_ENTRIES); |
316 |
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317 |
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cpu->translation_cache_cur_ofs = |
318 |
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N_BASE_TABLE_ENTRIES * sizeof(uint32_t); |
319 |
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320 |
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/* |
321 |
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* There might be other translation pointers that still point to |
322 |
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* within the translation_cache region. Let's invalidate those too: |
323 |
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*/ |
324 |
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if (cpu->invalidate_code_translation != NULL) |
325 |
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cpu->invalidate_code_translation(cpu, 0, INVALIDATE_ALL); |
326 |
} |
} |
327 |
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328 |
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330 |
* cpu_dumpinfo(): |
* cpu_dumpinfo(): |
331 |
* |
* |
332 |
* Dumps info about a CPU using debug(). "cpu0: CPUNAME, running" (or similar) |
* Dumps info about a CPU using debug(). "cpu0: CPUNAME, running" (or similar) |
333 |
* is outputed, and it is up to CPU dependant code to complete the line. |
* is outputed, and it is up to CPU dependent code to complete the line. |
334 |
*/ |
*/ |
335 |
void cpu_dumpinfo(struct machine *m, struct cpu *cpu) |
void cpu_dumpinfo(struct machine *m, struct cpu *cpu) |
336 |
{ |
{ |
352 |
void cpu_list_available_types(void) |
void cpu_list_available_types(void) |
353 |
{ |
{ |
354 |
struct cpu_family *fp; |
struct cpu_family *fp; |
355 |
int iadd = 4; |
int iadd = DEBUG_INDENTATION; |
356 |
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357 |
fp = first_cpu_family; |
fp = first_cpu_family; |
358 |
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382 |
* Shuts down all CPUs in a machine when ending a simulation. (This function |
* Shuts down all CPUs in a machine when ending a simulation. (This function |
383 |
* should only need to be called once for each machine.) |
* should only need to be called once for each machine.) |
384 |
*/ |
*/ |
385 |
void cpu_run_deinit(struct emul *emul, struct machine *machine) |
void cpu_run_deinit(struct machine *machine) |
386 |
{ |
{ |
387 |
int te; |
int te; |
388 |
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389 |
/* |
/* |
390 |
* Two last ticks of every hardware device. This will allow |
* Two last ticks of every hardware device. This will allow e.g. |
391 |
* framebuffers to draw the last updates to the screen before |
* framebuffers to draw the last updates to the screen before halting. |
392 |
* halting. |
* |
393 |
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* TODO: This should be refactored when redesigning the mainbus |
394 |
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* concepts! |
395 |
*/ |
*/ |
396 |
for (te=0; te<machine->n_tick_entries; te++) { |
for (te=0; te<machine->n_tick_entries; te++) { |
397 |
machine->tick_func[te](machine->cpus[0], |
machine->tick_func[te](machine->cpus[0], |
400 |
machine->tick_extra[te]); |
machine->tick_extra[te]); |
401 |
} |
} |
402 |
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403 |
debug("cpu_run_deinit(): All CPUs halted.\n"); |
if (machine->show_nr_of_instructions) |
404 |
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cpu_show_cycles(machine, 1); |
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if (machine->show_nr_of_instructions || !quiet_mode) |
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cpu_show_cycles(machine, &machine->starttime, |
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machine->ncycles, 1); |
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if (show_opcode_statistics) |
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cpu_show_full_statistics(machine); |
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405 |
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406 |
fflush(stdout); |
fflush(stdout); |
407 |
} |
} |
415 |
* line to stdout about how many instructions/cycles have been executed so |
* line to stdout about how many instructions/cycles have been executed so |
416 |
* far. |
* far. |
417 |
*/ |
*/ |
418 |
void cpu_show_cycles(struct machine *machine, |
void cpu_show_cycles(struct machine *machine, int forced) |
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struct timeval *starttime, int64_t ncycles, int forced) |
|
419 |
{ |
{ |
420 |
uint64_t offset, pc; |
uint64_t offset, pc; |
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int is_32bit = 0, instrs_per_cycle; |
|
421 |
char *symbol; |
char *symbol; |
422 |
int64_t mseconds, ninstrs; |
int64_t mseconds, ninstrs, is, avg; |
423 |
struct timeval tv; |
struct timeval tv; |
424 |
int h, m, s, ms, d; |
int h, m, s, ms, d; |
425 |
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426 |
static int64_t mseconds_last = 0; |
static int64_t mseconds_last = 0; |
427 |
static int64_t ninstrs_last = -1; |
static int64_t ninstrs_last = -1; |
428 |
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if (machine->arch != ARCH_MIPS) { |
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fatal("cpu_show_cycles(): not yet for !MIPS\n"); |
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return; |
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} |
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if (machine->cpus[machine->bootstrap_cpu]->cd.mips.cpu_type.isa_level |
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< 3 || machine->cpus[machine->bootstrap_cpu]->cd.mips.cpu_type. |
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isa_level == 32) |
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is_32bit = 1; |
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429 |
pc = machine->cpus[machine->bootstrap_cpu]->pc; |
pc = machine->cpus[machine->bootstrap_cpu]->pc; |
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instrs_per_cycle = machine->cpus[machine->bootstrap_cpu]-> |
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cd.mips.cpu_type.instrs_per_cycle; |
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430 |
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431 |
gettimeofday(&tv, NULL); |
gettimeofday(&tv, NULL); |
432 |
mseconds = (tv.tv_sec - starttime->tv_sec) * 1000 |
mseconds = (tv.tv_sec - machine->starttime.tv_sec) * 1000 |
433 |
+ (tv.tv_usec - starttime->tv_usec) / 1000; |
+ (tv.tv_usec - machine->starttime.tv_usec) / 1000; |
434 |
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435 |
if (mseconds == 0) |
if (mseconds == 0) |
436 |
mseconds = 1; |
mseconds = 1; |
438 |
if (mseconds - mseconds_last == 0) |
if (mseconds - mseconds_last == 0) |
439 |
mseconds ++; |
mseconds ++; |
440 |
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441 |
ninstrs = ncycles * instrs_per_cycle; |
ninstrs = machine->ninstrs_since_gettimeofday; |
442 |
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443 |
if (machine->automatic_clock_adjustment) { |
if (machine->automatic_clock_adjustment) { |
444 |
static int first_adjustment = 1; |
static int first_adjustment = 1; |
445 |
|
|
446 |
/* Current nr of cycles per second: */ |
/* Current nr of cycles per second: */ |
447 |
int64_t cur_cycles_per_second = 1000 * |
int64_t cur_cycles_per_second = 1000 * |
448 |
(ninstrs-ninstrs_last) / (mseconds-mseconds_last) |
(ninstrs-ninstrs_last) / (mseconds-mseconds_last); |
449 |
/ instrs_per_cycle; |
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450 |
|
/* fatal("[ CYCLES PER SECOND = %"PRIi64" ]\n", |
451 |
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cur_cycles_per_second); */ |
452 |
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|
453 |
if (cur_cycles_per_second < 1000000) |
if (cur_cycles_per_second < 1000000) |
454 |
cur_cycles_per_second = 1000000; |
cur_cycles_per_second = 1000000; |
461 |
cur_cycles_per_second) / 16; |
cur_cycles_per_second) / 16; |
462 |
} |
} |
463 |
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|
464 |
debug("[ updating emulated_hz to %lli Hz ]\n", |
/* fatal("[ updating emulated_hz to %"PRIi64" Hz ]\n", |
465 |
(long long)machine->emulated_hz); |
machine->emulated_hz); */ |
466 |
} |
} |
467 |
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|
468 |
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|
470 |
if (!machine->show_nr_of_instructions && !forced) |
if (!machine->show_nr_of_instructions && !forced) |
471 |
goto do_return; |
goto do_return; |
472 |
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473 |
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printf("[ %"PRIi64" instrs", (int64_t)machine->ninstrs); |
|
printf("[ "); |
|
474 |
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|
475 |
if (!machine->automatic_clock_adjustment) { |
if (!machine->automatic_clock_adjustment) { |
476 |
d = machine->emulated_hz / 1000; |
d = machine->emulated_hz / 1000; |
477 |
if (d < 1) |
if (d < 1) |
478 |
d = 1; |
d = 1; |
479 |
ms = ncycles / d; |
ms = machine->ninstrs / d; |
480 |
h = ms / 3600000; |
h = ms / 3600000; |
481 |
ms -= 3600000 * h; |
ms -= 3600000 * h; |
482 |
m = ms / 60000; |
m = ms / 60000; |
484 |
s = ms / 1000; |
s = ms / 1000; |
485 |
ms -= 1000 * s; |
ms -= 1000 * s; |
486 |
|
|
487 |
printf("emulated time = %02i:%02i:%02i.%03i; ", h, m, s, ms); |
printf(", emulated time = %02i:%02i:%02i.%03i; ", h, m, s, ms); |
488 |
} |
} |
489 |
|
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printf("cycles=%lli", (long long) ncycles); |
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if (instrs_per_cycle > 1) |
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printf(" (%lli instrs)", (long long) ninstrs); |
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|
490 |
/* Instructions per second, and average so far: */ |
/* Instructions per second, and average so far: */ |
491 |
printf("; i/s=%lli avg=%lli", |
is = 1000 * (ninstrs-ninstrs_last) / (mseconds-mseconds_last); |
492 |
(long long) ((long long)1000 * (ninstrs-ninstrs_last) |
avg = (long long)1000 * ninstrs / mseconds; |
493 |
/ (mseconds-mseconds_last)), |
if (is < 0) |
494 |
(long long) ((long long)1000 * ninstrs / mseconds)); |
is = 0; |
495 |
|
if (avg < 0) |
496 |
|
avg = 0; |
497 |
|
printf("; i/s=%"PRIi64" avg=%"PRIi64, is, avg); |
498 |
|
|
499 |
symbol = get_symbol_name(&machine->symbol_context, pc, &offset); |
symbol = get_symbol_name(&machine->symbol_context, pc, &offset); |
500 |
|
|
501 |
if (is_32bit) |
if (machine->ncpus == 1) { |
502 |
printf("; pc=%08x", (int)pc); |
if (machine->cpus[machine->bootstrap_cpu]->is_32bit) |
503 |
else |
printf("; pc=0x%08"PRIx32, (uint32_t) pc); |
504 |
printf("; pc=%016llx", (long long)pc); |
else |
505 |
|
printf("; pc=0x%016"PRIx64, (uint64_t) pc); |
506 |
|
} |
507 |
|
|
508 |
printf(" <%s> ]\n", symbol? symbol : "no symbol"); |
if (symbol != NULL) |
509 |
|
printf(" <%s>", symbol); |
510 |
|
printf(" ]\n"); |
511 |
|
|
512 |
do_return: |
do_return: |
513 |
ninstrs_last = ninstrs; |
ninstrs_last = ninstrs; |
521 |
* Prepare to run instructions on all CPUs in this machine. (This function |
* Prepare to run instructions on all CPUs in this machine. (This function |
522 |
* should only need to be called once for each machine.) |
* should only need to be called once for each machine.) |
523 |
*/ |
*/ |
524 |
void cpu_run_init(struct emul *emul, struct machine *machine) |
void cpu_run_init(struct machine *machine) |
525 |
{ |
{ |
526 |
int ncpus = machine->ncpus; |
machine->ninstrs_flush = 0; |
527 |
int te; |
machine->ninstrs = 0; |
528 |
|
machine->ninstrs_show = 0; |
|
machine->a_few_cycles = 1048576; |
|
|
machine->ncycles_flush = 0; |
|
|
machine->ncycles = 0; |
|
|
machine->ncycles_show = 0; |
|
|
|
|
|
/* |
|
|
* Instead of doing { one cycle, check hardware ticks }, we |
|
|
* can do { n cycles, check hardware ticks }, as long as |
|
|
* n is at most as much as the lowest number of cycles/tick |
|
|
* for any hardware device. |
|
|
*/ |
|
|
for (te=0; te<machine->n_tick_entries; te++) { |
|
|
if (machine->ticks_reset_value[te] < machine->a_few_cycles) |
|
|
machine->a_few_cycles = machine->ticks_reset_value[te]; |
|
|
} |
|
|
|
|
|
machine->a_few_cycles >>= 1; |
|
|
if (machine->a_few_cycles < 1) |
|
|
machine->a_few_cycles = 1; |
|
|
|
|
|
if (ncpus > 1 && machine->max_random_cycles_per_chunk == 0) |
|
|
machine->a_few_cycles = 1; |
|
|
|
|
|
/* debug("cpu_run_init(): a_few_cycles = %i\n", |
|
|
machine->a_few_cycles); */ |
|
529 |
|
|
530 |
/* For performance measurement: */ |
/* For performance measurement: */ |
531 |
gettimeofday(&machine->starttime, NULL); |
gettimeofday(&machine->starttime, NULL); |
532 |
|
machine->ninstrs_since_gettimeofday = 0; |
533 |
} |
} |
534 |
|
|
535 |
|
|
606 |
void cpu_init(void) |
void cpu_init(void) |
607 |
{ |
{ |
608 |
/* Note: These are registered in alphabetic order. */ |
/* Note: These are registered in alphabetic order. */ |
609 |
|
|
610 |
|
#ifdef ENABLE_ALPHA |
611 |
add_cpu_family(alpha_cpu_family_init, ARCH_ALPHA); |
add_cpu_family(alpha_cpu_family_init, ARCH_ALPHA); |
612 |
|
#endif |
613 |
|
|
614 |
|
#ifdef ENABLE_ARM |
615 |
|
add_cpu_family(arm_cpu_family_init, ARCH_ARM); |
616 |
|
#endif |
617 |
|
|
618 |
|
#ifdef ENABLE_AVR |
619 |
|
add_cpu_family(avr_cpu_family_init, ARCH_AVR); |
620 |
|
#endif |
621 |
|
|
622 |
|
#ifdef ENABLE_HPPA |
623 |
add_cpu_family(hppa_cpu_family_init, ARCH_HPPA); |
add_cpu_family(hppa_cpu_family_init, ARCH_HPPA); |
624 |
|
#endif |
625 |
|
|
626 |
|
#ifdef ENABLE_I960 |
627 |
|
add_cpu_family(i960_cpu_family_init, ARCH_I960); |
628 |
|
#endif |
629 |
|
|
630 |
|
#ifdef ENABLE_IA64 |
631 |
|
add_cpu_family(ia64_cpu_family_init, ARCH_IA64); |
632 |
|
#endif |
633 |
|
|
634 |
|
#ifdef ENABLE_M68K |
635 |
|
add_cpu_family(m68k_cpu_family_init, ARCH_M68K); |
636 |
|
#endif |
637 |
|
|
638 |
|
#ifdef ENABLE_MIPS |
639 |
add_cpu_family(mips_cpu_family_init, ARCH_MIPS); |
add_cpu_family(mips_cpu_family_init, ARCH_MIPS); |
640 |
|
#endif |
641 |
|
|
642 |
|
#ifdef ENABLE_PPC |
643 |
add_cpu_family(ppc_cpu_family_init, ARCH_PPC); |
add_cpu_family(ppc_cpu_family_init, ARCH_PPC); |
644 |
|
#endif |
645 |
|
|
646 |
|
#ifdef ENABLE_SH |
647 |
|
add_cpu_family(sh_cpu_family_init, ARCH_SH); |
648 |
|
#endif |
649 |
|
|
650 |
|
#ifdef ENABLE_SPARC |
651 |
add_cpu_family(sparc_cpu_family_init, ARCH_SPARC); |
add_cpu_family(sparc_cpu_family_init, ARCH_SPARC); |
652 |
add_cpu_family(urisc_cpu_family_init, ARCH_URISC); |
#endif |
653 |
|
|
654 |
|
#ifdef ENABLE_TRANSPUTER |
655 |
|
add_cpu_family(transputer_cpu_family_init, ARCH_TRANSPUTER); |
656 |
|
#endif |
657 |
|
|
658 |
|
#ifdef ENABLE_X86 |
659 |
add_cpu_family(x86_cpu_family_init, ARCH_X86); |
add_cpu_family(x86_cpu_family_init, ARCH_X86); |
660 |
|
#endif |
661 |
} |
} |
662 |
|
|