memtest86plus/tests/own_addr.c

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// SPDX-License-Identifier: GPL-2.0
// Copyright (C) 2020-2022 Martin Whitaker.
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//
// Derived from an extract of memtest86+ test.c:
//
// MemTest86+ V5 Specific code (GPL V2.0)
// By Samuel DEMEULEMEESTER, sdemeule@memtest.org
// http://www.canardpc.com - http://www.memtest.org
// Thanks to Passmark for calculate_chunk() and various comments !
// ----------------------------------------------------
// test.c - MemTest-86 Version 3.4
//
// Released under version 2 of the Gnu Public License.
// By Chris Brady
#include <stdbool.h>
#include <stdint.h>
#include "vmem.h"
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#include "display.h"
#include "error.h"
#include "test.h"
#include "test_funcs.h"
#include "test_helper.h"
//------------------------------------------------------------------------------
// Private Functions
//------------------------------------------------------------------------------
static int pattern_fill(int my_cpu, testword_t offset)
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{
int ticks = 0;
if (my_cpu == master_cpu) {
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display_test_pattern_name("own address");
}
// Write each address with it's own address.
for (int i = 0; i < vm_map_size; i++) {
testword_t *start = vm_map[i].start;
testword_t *end = vm_map[i].end;
testword_t *p = start;
testword_t *pe = start;
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bool at_end = false;
do {
// take care to avoid pointer overflow
if ((end - pe) >= SPIN_SIZE) {
pe += SPIN_SIZE - 1;
} else {
at_end = true;
pe = end;
}
ticks++;
if (my_cpu < 0) {
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continue;
}
test_addr[my_cpu] = (uintptr_t)p;
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do {
write_word(p, (testword_t)p + offset);
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} while (p++ < pe); // test before increment in case pointer overflows
do_tick(my_cpu);
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BAILOUT;
} while (!at_end && ++pe); // advance pe to next start point
}
flush_caches(my_cpu);
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return ticks;
}
static int pattern_check(int my_cpu, testword_t offset)
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{
int ticks = 0;
// Check each address has its own address.
for (int i = 0; i < vm_map_size; i++) {
testword_t *start = vm_map[i].start;
testword_t *end = vm_map[i].end;
testword_t *p = start;
testword_t *pe = start;
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bool at_end = false;
do {
// take care to avoid pointer overflow
if ((end - pe) >= SPIN_SIZE) {
pe += SPIN_SIZE - 1;
} else {
at_end = true;
pe = end;
}
ticks++;
if (my_cpu < 0) {
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continue;
}
test_addr[my_cpu] = (uintptr_t)p;
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do {
testword_t expect = (testword_t)p + offset;
testword_t actual = read_word(p);
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if (unlikely(actual != expect)) {
data_error(p, expect, actual, true);
}
} while (p++ < pe); // test before increment in case pointer overflows
do_tick(my_cpu);
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BAILOUT;
} while (!at_end && ++pe); // advance pe to next start point
}
return ticks;
}
//------------------------------------------------------------------------------
// Public Functions
//------------------------------------------------------------------------------
int test_own_addr1(int my_cpu)
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{
int ticks = 0;
ticks += pattern_fill(my_cpu, 0);
ticks += pattern_check(my_cpu, 0);
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return ticks;
}
int test_own_addr2(int my_cpu, int stage)
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{
int ticks = 0;
testword_t offset;
// Calculate the offset (in pages) between the virtual address and the physical address.
offset = (vm_map[0].pm_base_addr / VM_WINDOW_SIZE) * VM_WINDOW_SIZE;
offset = (offset >= VM_PINNED_SIZE) ? offset - VM_PINNED_SIZE : 0;
#ifdef __x86_64__
// Convert to a byte address offset. This will translate the virtual address into a physical address.
offset *= PAGE_SIZE;
#else
// Convert to a VM window offset. This will get added into the LSBs of the virtual address.
offset /= VM_WINDOW_SIZE;
#endif
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switch (stage) {
case 0:
ticks = pattern_fill(my_cpu, offset);
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break;
case 1:
ticks = pattern_check(my_cpu, offset);
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break;
default:
break;
}
return ticks;
}