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|
/***********************license start***********************************
* Copyright (c) 2003-2017 Cavium Inc. (support@cavium.com). All rights
* reserved.
*
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided
* with the distribution.
*
* * Neither the name of Cavium Inc. nor the names of
* its contributors may be used to endorse or promote products
* derived from this software without specific prior written
* permission.
*
* This Software, including technical data, may be subject to U.S. export
* control laws, including the U.S. Export Administration Act and its
* associated regulations, and may be subject to export or import
* regulations in other countries.
*
* TO THE MAXIMUM EXTENT PERMITTED BY LAW, THE SOFTWARE IS PROVIDED "AS IS"
* AND WITH ALL FAULTS AND CAVIUM INC. MAKES NO PROMISES, REPRESENTATIONS OR
* WARRANTIES, EITHER EXPRESS, IMPLIED, STATUTORY, OR OTHERWISE, WITH RESPECT
* TO THE SOFTWARE, INCLUDING ITS CONDITION, ITS CONFORMITY TO ANY
* REPRESENTATION OR DESCRIPTION, OR THE EXISTENCE OF ANY LATENT OR PATENT
* DEFECTS, AND CAVIUM SPECIFICALLY DISCLAIMS ALL IMPLIED (IF ANY) WARRANTIES
* OF TITLE, MERCHANTABILITY, NONINFRINGEMENT, FITNESS FOR A PARTICULAR
* PURPOSE, LACK OF VIRUSES, ACCURACY OR COMPLETENESS, QUIET ENJOYMENT,
* QUIET POSSESSION OR CORRESPONDENCE TO DESCRIPTION. THE ENTIRE RISK
* ARISING OUT OF USE OR PERFORMANCE OF THE SOFTWARE LIES WITH YOU.
***********************license end**************************************/
#include <bdk.h>
#include <string.h>
#include "libbdk-arch/bdk-csrs-gti.h"
#include "libbdk-arch/bdk-csrs-ocx.h"
#include <bdk-minimal.h> /* for printf --> printk */
#include <libbdk-dram/bdk-dram-test.h>
#include <libbdk-hal/bdk-atomic.h>
#include <libbdk-hal/bdk-clock.h>
#include <libbdk-hal/bdk-utils.h>
#include <libbdk-os/bdk-init.h>
#include <libbdk-os/bdk-thread.h>
/* This code is an optional part of the BDK. It is only linked in
if BDK_REQUIRE() needs it */
BDK_REQUIRE_DEFINE(DRAM_TEST);
#define MAX_ERRORS_TO_REPORT 50
#define RETRY_LIMIT 1000
typedef struct
{
const char * name; /* Friendly name for the test */
__bdk_dram_test_t test_func; /* Function to call */
int bursts; /* Bursts parameter to pass to the test */
int max_cores; /* Maximum number of cores the test should be run on in parallel. Zero means all */
} dram_test_info_t;
static const dram_test_info_t TEST_INFO[] = {
/* Name, Test function, Bursts, Max Cores */
{ "Data Bus", __bdk_dram_test_mem_data_bus, 8, 1},
{ "Address Bus", __bdk_dram_test_mem_address_bus, 0, 1},
{ "Marching Rows", __bdk_dram_test_mem_rows, 16, 0},
{ "Random Data", __bdk_dram_test_mem_random, 32, 0},
{ "Random XOR (32 Burst)", __bdk_dram_test_mem_xor, 32, 0},
{ "Self Address", __bdk_dram_test_mem_self_addr, 1, 0},
{ "March C- Solid Bits", __bdk_dram_test_mem_solid, 1, 0},
{ "March C- Checkerboard", __bdk_dram_test_mem_checkerboard, 1, 0},
{ "Walking Ones Left", __bdk_dram_test_mem_leftwalk1, 1, 0},
{ "Walking Ones Right", __bdk_dram_test_mem_rightwalk1, 1, 0},
{ "Walking Zeros Left", __bdk_dram_test_mem_leftwalk0, 1, 0},
{ "Walking Zeros Right", __bdk_dram_test_mem_rightwalk0, 1, 0},
{ "Random XOR (224 Burst)", __bdk_dram_test_mem_xor, 224, 0},
{ "Fast Scan", __bdk_dram_test_fast_scan, 0, 0},
{ NULL, NULL, 0, 0}
};
/* These variables count the number of ECC errors. They should only be accessed atomically */
int64_t __bdk_dram_ecc_single_bit_errors[BDK_MAX_MEM_CHANS];
int64_t __bdk_dram_ecc_double_bit_errors[BDK_MAX_MEM_CHANS];
static int64_t dram_test_thread_done;
static int64_t dram_test_thread_errors;
static uint64_t dram_test_thread_start;
static uint64_t dram_test_thread_end;
static uint64_t dram_test_thread_size;
/**
* Force the memory at the pointer location to be written to memory and evicted
* from L2. L1 will be unaffected.
*
* @param address Physical memory location
*/
void __bdk_dram_flush_to_mem(uint64_t address)
{
BDK_MB;
char *ptr = bdk_phys_to_ptr(address);
BDK_CACHE_WBI_L2(ptr);
}
/**
* Force a memory region to be written to DRAM and evicted from L2
*
* @param area Start of the region
* @param max_address
* End of the region (exclusive)
*/
void __bdk_dram_flush_to_mem_range(uint64_t area, uint64_t max_address)
{
char *ptr = bdk_phys_to_ptr(area);
char *end = bdk_phys_to_ptr(max_address);
BDK_MB;
while (ptr < end)
{
BDK_CACHE_WBI_L2(ptr);
ptr += 128;
}
}
/**
* Convert a test enumeration into a string
*
* @param test Test to convert
*
* @return String for display
*/
const char *bdk_dram_get_test_name(int test)
{
if (test < (int)(sizeof(TEST_INFO) / sizeof(TEST_INFO[0])))
return TEST_INFO[test].name;
else
return NULL;
}
static bdk_dram_test_flags_t dram_test_flags; // FIXME: Don't use global
/**
* This function is run as a thread to perform memory tests over multiple cores.
* Each thread gets a section of memory to work on, which is controlled by global
* variables at the beginning of this file.
*
* @param arg Number of the region we should check
* @param arg1 Pointer to the test_info structure
*/
static void dram_test_thread(int arg, void *arg1)
{
const dram_test_info_t *test_info = arg1;
const int bursts = test_info->bursts;
const int range_number = arg;
/* Figure out our work memory range.
*
* Note start_address and end_address just provide the physical offset
* portion of the address and do not have the node bits set. This is
* to simplify address checks and calculations. Later, when about to run
* the memory test, the routines adds in the node bits to form the final
* addresses.
*/
uint64_t start_address = dram_test_thread_start + dram_test_thread_size * range_number;
uint64_t end_address = start_address + dram_test_thread_size;
if (end_address > dram_test_thread_end)
end_address = dram_test_thread_end;
bdk_node_t test_node = bdk_numa_local();
if (dram_test_flags & BDK_DRAM_TEST_USE_CCPI)
test_node ^= 1;
/* Insert the node part of the address */
start_address = bdk_numa_get_address(test_node, start_address);
end_address = bdk_numa_get_address(test_node, end_address);
/* Test the region */
BDK_TRACE(DRAM_TEST, " Node %d, core %d, Testing [0x%011llx:0x%011llx]\n",
bdk_numa_local(), bdk_get_core_num() & 127, start_address, end_address - 1);
test_info->test_func(start_address, end_address, bursts);
/* Report that we're done */
BDK_TRACE(DRAM_TEST, "Thread %d on node %d done with memory test\n", range_number, bdk_numa_local());
bdk_atomic_add64_nosync(&dram_test_thread_done, 1);
}
/**
* Run the memory test.
*
* @param test_info
* @param start_address
* Physical address to start at
* @param length Length of memory block
* @param flags Flags to control memory test options. Zero defaults to testing all
* node with statistics and progress output.
*
* @return Number of errors found. Zero is success. Negative means the test
* did not run due to some other failure.
*/
static int __bdk_dram_run_test(const dram_test_info_t *test_info, uint64_t start_address,
uint64_t length, bdk_dram_test_flags_t flags)
{
/* Figure out the addess of the byte one off the top of memory */
uint64_t max_address = bdk_dram_get_size_mbytes(bdk_numa_local());
BDK_TRACE(DRAM_TEST, "DRAM available per node: %llu MB\n", max_address);
max_address <<= 20;
/* Make sure we have enough */
if (max_address < (16<<20))
{
bdk_error("DRAM size is too small\n");
return -1;
}
/* Make sure the amount is sane */
if (CAVIUM_IS_MODEL(CAVIUM_CN8XXX))
{
if (max_address > (1ull << 40)) /* 40 bits in CN8XXX */
max_address = 1ull << 40;
}
else
{
if (max_address > (1ull << 43)) /* 43 bits in CN9XXX */
max_address = 1ull << 43;
}
BDK_TRACE(DRAM_TEST, "DRAM max address: 0x%011llx\n", max_address-1);
/* Make sure the start address is lower than the top of memory */
if (start_address >= max_address)
{
bdk_error("Start address is larger than the amount of memory: 0x%011llx versus 0x%011llx\n",
start_address, max_address);
return -1;
}
if (length == (uint64_t)-1)
length = max_address - start_address;
/* Final range checks */
uint64_t end_address = start_address + length;
if (end_address > max_address)
{
end_address = max_address;
length = end_address - start_address;
}
if (length == 0)
return 0;
/* Ready to run the test. Figure out how many cores we need */
int max_cores = test_info->max_cores;
int total_cores_all_nodes = max_cores;
/* Figure out the number of cores available in the system */
if (max_cores == 0)
{
max_cores += bdk_get_num_running_cores(bdk_numa_local());
/* Calculate the total number of cores being used. The per node number
is confusing to people */
for (bdk_node_t node = BDK_NODE_0; node < BDK_NUMA_MAX_NODES; node++)
if (flags & (1 << node))
{
if (flags & BDK_DRAM_TEST_USE_CCPI)
total_cores_all_nodes += bdk_get_num_running_cores(node ^ 1);
else
total_cores_all_nodes += bdk_get_num_running_cores(node);
}
}
if (!(flags & BDK_DRAM_TEST_NO_BANNERS))
printf("Starting Test \"%s\" for [0x%011llx:0x%011llx] using %d core(s)\n",
test_info->name, start_address, end_address - 1, total_cores_all_nodes);
/* Remember the LMC perf counters for stats after the test */
uint64_t start_dram_dclk[BDK_NUMA_MAX_NODES][4];
uint64_t start_dram_ops[BDK_NUMA_MAX_NODES][4];
uint64_t stop_dram_dclk[BDK_NUMA_MAX_NODES][4];
uint64_t stop_dram_ops[BDK_NUMA_MAX_NODES][4];
for (bdk_node_t node = BDK_NODE_0; node < BDK_NUMA_MAX_NODES; node++)
{
if (flags & (1 << node))
{
const int num_dram_controllers = __bdk_dram_get_num_lmc(node);
for (int i = 0; i < num_dram_controllers; i++)
{
start_dram_dclk[node][i] = BDK_CSR_READ(node, BDK_LMCX_DCLK_CNT(i));
start_dram_ops[node][i] = BDK_CSR_READ(node, BDK_LMCX_OPS_CNT(i));
}
}
}
/* Remember the CCPI link counters for stats after the test */
uint64_t start_ccpi_data[BDK_NUMA_MAX_NODES][3];
uint64_t start_ccpi_idle[BDK_NUMA_MAX_NODES][3];
uint64_t start_ccpi_err[BDK_NUMA_MAX_NODES][3];
uint64_t stop_ccpi_data[BDK_NUMA_MAX_NODES][3];
uint64_t stop_ccpi_idle[BDK_NUMA_MAX_NODES][3];
uint64_t stop_ccpi_err[BDK_NUMA_MAX_NODES][3];
if (!bdk_numa_is_only_one())
{
for (bdk_node_t node = BDK_NODE_0; node < BDK_NUMA_MAX_NODES; node++)
{
if (flags & (1 << node))
{
for (int link = 0; link < 3; link++)
{
start_ccpi_data[node][link] = BDK_CSR_READ(node, BDK_OCX_TLKX_STAT_DATA_CNT(link));
start_ccpi_idle[node][link] = BDK_CSR_READ(node, BDK_OCX_TLKX_STAT_IDLE_CNT(link));
start_ccpi_err[node][link] = BDK_CSR_READ(node, BDK_OCX_TLKX_STAT_ERR_CNT(link));
}
}
}
}
/* WARNING: This code assumes the same memory range is being tested on
all nodes. The same number of cores are used on each node to test
its local memory */
uint64_t work_address = start_address;
dram_test_flags = flags;
bdk_atomic_set64(&dram_test_thread_errors, 0);
while ((work_address < end_address) && ((dram_test_thread_errors == 0) || (flags & BDK_DRAM_TEST_NO_STOP_ERROR)))
{
/* Check at most MAX_CHUNK_SIZE across each iteration. We only report
progress between chunks, so keep them reasonably small */
const uint64_t MAX_CHUNK_SIZE = 1ull << 28; /* 256MB */
uint64_t size = end_address - work_address;
if (size > MAX_CHUNK_SIZE)
size = MAX_CHUNK_SIZE;
/* Divide memory evenly between the cores. Round the size up so that
all memory is covered. The last core may have slightly less memory to
test */
uint64_t thread_size = (size + (max_cores - 1)) / max_cores;
thread_size += 127;
thread_size &= -128;
dram_test_thread_start = work_address;
dram_test_thread_end = work_address + size;
dram_test_thread_size = thread_size;
BDK_WMB;
/* Poke the watchdog */
BDK_CSR_WRITE(bdk_numa_local(), BDK_GTI_CWD_POKEX(0), 0);
/* disable progress output when batch mode is ON */
if (!(flags & BDK_DRAM_TEST_NO_PROGRESS)) {
/* Report progress percentage */
int percent_x10 = (work_address - start_address) * 1000 / (end_address - start_address);
printf(" %3d.%d%% complete, testing [0x%011llx:0x%011llx]\r",
percent_x10 / 10, percent_x10 % 10, work_address, work_address + size - 1);
fflush(stdout);
}
work_address += size;
/* Start threads for all the cores */
int total_count = 0;
bdk_atomic_set64(&dram_test_thread_done, 0);
for (bdk_node_t node = BDK_NODE_0; node < BDK_NUMA_MAX_NODES; node++)
{
if (flags & (1 << node))
{
const int num_cores = bdk_get_num_cores(node);
int per_node = 0;
for (int core = 0; core < num_cores; core++)
{
if (per_node >= max_cores)
break;
BDK_TRACE(DRAM_TEST, "Starting thread %d on node %d for memory test\n", per_node, node);
dram_test_thread(per_node, (void *)test_info);
}
}
}
#if 0
/* Wait for threads to finish */
while (bdk_atomic_get64(&dram_test_thread_done) < total_count)
bdk_thread_yield();
#else
#define TIMEOUT_SECS 30 // FIXME: long enough so multicore RXOR 224 should not print out
/* Wait for threads to finish, with progress */
int cur_count;
uint64_t cur_time;
uint64_t period = bdk_clock_get_rate(bdk_numa_local(), BDK_CLOCK_TIME) * TIMEOUT_SECS; // FIXME?
uint64_t timeout = bdk_clock_get_count(BDK_CLOCK_TIME) + period;
do {
cur_count = bdk_atomic_get64(&dram_test_thread_done);
cur_time = bdk_clock_get_count(BDK_CLOCK_TIME);
if (cur_time >= timeout) {
BDK_TRACE(DRAM_TEST, "N%d: Waiting for %d cores\n",
bdk_numa_local(), total_count - cur_count);
timeout = cur_time + period;
}
} while (cur_count < total_count);
#endif
}
/* Get the DRAM perf counters */
for (bdk_node_t node = BDK_NODE_0; node < BDK_NUMA_MAX_NODES; node++)
{
if (flags & (1 << node))
{
const int num_dram_controllers = __bdk_dram_get_num_lmc(node);
for (int i = 0; i < num_dram_controllers; i++)
{
stop_dram_dclk[node][i] = BDK_CSR_READ(node, BDK_LMCX_DCLK_CNT(i));
stop_dram_ops[node][i] = BDK_CSR_READ(node, BDK_LMCX_OPS_CNT(i));
}
}
}
/* Get the CCPI link counters */
if (!bdk_numa_is_only_one())
{
for (bdk_node_t node = BDK_NODE_0; node < BDK_NUMA_MAX_NODES; node++)
{
if (flags & (1 << node))
{
for (int link = 0; link < 3; link++)
{
stop_ccpi_data[node][link] = BDK_CSR_READ(node, BDK_OCX_TLKX_STAT_DATA_CNT(link));
stop_ccpi_idle[node][link] = BDK_CSR_READ(node, BDK_OCX_TLKX_STAT_IDLE_CNT(link));
stop_ccpi_err[node][link] = BDK_CSR_READ(node, BDK_OCX_TLKX_STAT_ERR_CNT(link));
}
}
}
}
/* disable progress output when batch mode is ON */
if (!(flags & BDK_DRAM_TEST_NO_PROGRESS)) {
/* Report progress percentage as complete */
printf(" %3d.%d%% complete, testing [0x%011llx:0x%011llx]\n",
100, 0, start_address, end_address - 1);
fflush(stdout);
}
if (!(flags & BDK_DRAM_TEST_NO_STATS))
{
/* Display LMC load */
for (bdk_node_t node = BDK_NODE_0; node < BDK_NUMA_MAX_NODES; node++)
{
if (flags & (1 << node))
{
const int num_dram_controllers = __bdk_dram_get_num_lmc(node);
for (int i = 0; i < num_dram_controllers; i++)
{
uint64_t ops = stop_dram_ops[node][i] - start_dram_ops[node][i];
uint64_t dclk = stop_dram_dclk[node][i] - start_dram_dclk[node][i];
if (dclk == 0)
dclk = 1;
uint64_t percent_x10 = ops * 1000 / dclk;
printf(" Node %d, LMC%d: ops %llu, cycles %llu, used %llu.%llu%%\n",
node, i, ops, dclk, percent_x10 / 10, percent_x10 % 10);
}
}
}
if (flags & BDK_DRAM_TEST_USE_CCPI)
{
/* Display CCPI load */
for (bdk_node_t node = BDK_NODE_0; node < BDK_NUMA_MAX_NODES; node++)
{
if (flags & (1 << node))
{
for (int link = 0; link < 3; link++)
{
uint64_t busy = stop_ccpi_data[node][link] - start_ccpi_data[node][link];
busy += stop_ccpi_err[node][link] - start_ccpi_err[node][link];
uint64_t total = stop_ccpi_idle[node][link] - start_ccpi_idle[node][link];
total += busy;
if (total == 0)
continue;
uint64_t percent_x10 = busy * 1000 / total;
printf(" Node %d, CCPI%d: busy %llu, total %llu, used %llu.%llu%%\n",
node, link, busy, total, percent_x10 / 10, percent_x10 % 10);
}
}
}
}
}
return dram_test_thread_errors;
}
/**
* Perform a memory test.
*
* @param test Test type to run
* @param start_address
* Physical address to start at
* @param length Length of memory block
* @param flags Flags to control memory test options. Zero defaults to testing all
* node with statistics and progress output.
*
* @return Number of errors found. Zero is success. Negative means the test
* did not run due to some other failure.
*/
int bdk_dram_test(int test, uint64_t start_address, uint64_t length, bdk_dram_test_flags_t flags)
{
/* These limits are arbitrary. They just make sure we aren't doing something
silly, like test a non cache line aligned memory region */
if (start_address & 0xffff)
{
bdk_error("DRAM test start address must be aligned on a 64KB boundary\n");
return -1;
}
if (length & 0xffff)
{
bdk_error("DRAM test length must be a multiple of 64KB\n");
return -1;
}
const char *name = bdk_dram_get_test_name(test);
if (name == NULL)
{
bdk_error("Invalid DRAM test number %d\n", test);
return -1;
}
/* If no nodes are selected assume the user meant all nodes */
if ((flags & (BDK_DRAM_TEST_NODE0 | BDK_DRAM_TEST_NODE1 | BDK_DRAM_TEST_NODE2 | BDK_DRAM_TEST_NODE3)) == 0)
flags |= BDK_DRAM_TEST_NODE0 | BDK_DRAM_TEST_NODE1 | BDK_DRAM_TEST_NODE2 | BDK_DRAM_TEST_NODE3;
/* Remove nodes from the flags that don't exist */
for (bdk_node_t node = BDK_NODE_0; node < BDK_NUMA_MAX_NODES; node++)
{
if (flags & BDK_DRAM_TEST_USE_CCPI)
{
if (!bdk_numa_exists(node ^ 1))
flags &= ~(1 << node);
}
else
{
if (!bdk_numa_exists(node))
flags &= ~(1 << node);
}
}
/* Make sure the start address is higher that the BDK's active range */
uint64_t top_of_bdk = bdk_dram_get_top_of_bdk();
if (start_address < top_of_bdk)
start_address = top_of_bdk;
/* Clear ECC error counters before starting the test */
for (int chan = 0; chan < BDK_MAX_MEM_CHANS; chan++) {
bdk_atomic_set64(&__bdk_dram_ecc_single_bit_errors[chan], 0);
bdk_atomic_set64(&__bdk_dram_ecc_double_bit_errors[chan], 0);
}
/* Make sure at least one core from each node is running */
/* FIXME(dhendrix): we only care about core0 on node0 for now */
#if 0
for (bdk_node_t node = BDK_NODE_0; node < BDK_NUMA_MAX_NODES; node++)
{
if (flags & (1<<node))
{
int use_node = (flags & BDK_DRAM_TEST_USE_CCPI) ? node ^ 1 : node;
if (bdk_get_running_coremask(use_node) == 0)
bdk_init_cores(use_node, 1);
}
}
#endif
/* This returns any data compare errors found */
int errors = __bdk_dram_run_test(&TEST_INFO[test], start_address, length, flags);
/* Check ECC error counters after the test */
int64_t ecc_single = 0;
int64_t ecc_double = 0;
int64_t ecc_single_errs[BDK_MAX_MEM_CHANS];
int64_t ecc_double_errs[BDK_MAX_MEM_CHANS];
for (int chan = 0; chan < BDK_MAX_MEM_CHANS; chan++) {
ecc_single += (ecc_single_errs[chan] = bdk_atomic_get64(&__bdk_dram_ecc_single_bit_errors[chan]));
ecc_double += (ecc_double_errs[chan] = bdk_atomic_get64(&__bdk_dram_ecc_double_bit_errors[chan]));
}
/* Always print any ECC errors */
if (ecc_single || ecc_double)
{
printf("Test \"%s\": ECC errors, %lld/%lld/%lld/%lld corrected, %lld/%lld/%lld/%lld uncorrected\n",
name,
ecc_single_errs[0], ecc_single_errs[1], ecc_single_errs[2], ecc_single_errs[3],
ecc_double_errs[0], ecc_double_errs[1], ecc_double_errs[2], ecc_double_errs[3]);
}
if (errors || ecc_double || ecc_single) {
printf("Test \"%s\": FAIL: %lld single, %lld double, %d compare errors\n",
name, ecc_single, ecc_double, errors);
}
else
BDK_TRACE(DRAM_TEST, "Test \"%s\": PASS\n", name);
return (errors + ecc_double + ecc_single);
}
/**
* Report a DRAM address in decoded format.
*
* @param address Physical address the error occurred at
*
*/
static void __bdk_dram_report_address_decode(uint64_t address, char *buffer, int len)
{
int node, lmc, dimm, prank, lrank, bank, row, col;
bdk_dram_address_extract_info(address, &node, &lmc, &dimm, &prank, &lrank, &bank, &row, &col);
snprintf(buffer, len, "[0x%011lx] (N%d,LMC%d,DIMM%d,Rank%d/%d,Bank%02d,Row 0x%05x,Col 0x%04x)",
address, node, lmc, dimm, prank, lrank, bank, row, col);
}
/**
* Report a DRAM address in a new decoded format.
*
* @param address Physical address the error occurred at
* @param xor XOR of data read vs expected data
*
*/
static void __bdk_dram_report_address_decode_new(uint64_t address, uint64_t orig_xor, char *buffer, int len)
{
int node, lmc, dimm, prank, lrank, bank, row, col;
int byte = 8; // means no byte-lanes in error, should not happen
uint64_t bits, print_bits = 0;
uint64_t xor = orig_xor;
// find the byte-lane(s) with errors
for (int i = 0; i < 8; i++) {
bits = xor & 0xffULL;
xor >>= 8;
if (bits) {
if (byte != 8) {
byte = 9; // means more than 1 byte-lane was present
print_bits = orig_xor; // print the full original
break; // quit now
} else {
byte = i; // keep checking
print_bits = bits;
}
}
}
bdk_dram_address_extract_info(address, &node, &lmc, &dimm, &prank, &lrank, &bank, &row, &col);
snprintf(buffer, len, "N%d.LMC%d: CMP byte %d xor 0x%02lx (DIMM%d,Rank%d/%d,Bank%02d,Row 0x%05x,Col 0x%04x)[0x%011lx]",
node, lmc, byte, print_bits, dimm, prank, lrank, bank, row, col, address);
}
/**
* Report a DRAM error. Errors are not shown after MAX_ERRORS_TO_REPORT is
* exceeded. Used when a single address is involved in the failure.
*
* @param address Physical address the error occurred at
* @param data Data read from memory
* @param correct Correct data
* @param burst Which burst this is from, informational only
* @param fails -1 for no retries done, >= 0 number of failures during retries
*
* @return Zero if a message was logged, non-zero if the error limit has been reached
*/
void __bdk_dram_report_error(uint64_t address, uint64_t data, uint64_t correct, int burst, int fails)
{
char buffer[128];
char failbuf[32];
int64_t errors = bdk_atomic_fetch_and_add64(&dram_test_thread_errors, 1);
uint64_t xor = data ^ correct;
if (errors < MAX_ERRORS_TO_REPORT)
{
if (fails < 0) {
snprintf(failbuf, sizeof(failbuf), " ");
} else {
int percent_x10 = fails * 1000 / RETRY_LIMIT;
snprintf(failbuf, sizeof(failbuf), ", retries failed %3d.%d%%",
percent_x10 / 10, percent_x10 % 10);
}
__bdk_dram_report_address_decode_new(address, xor, buffer, sizeof(buffer));
bdk_error("%s%s\n", buffer, failbuf);
if (errors == MAX_ERRORS_TO_REPORT-1)
bdk_error("No further DRAM errors will be reported\n");
}
return;
}
/**
* Report a DRAM error. Errors are not shown after MAX_ERRORS_TO_REPORT is
* exceeded. Used when two addresses might be involved in the failure.
*
* @param address1 First address involved in the failure
* @param data1 Data from the first address
* @param address2 Second address involved in the failure
* @param data2 Data from second address
* @param burst Which burst this is from, informational only
* @param fails -1 for no retries done, >= 0 number of failures during retries
*
* @return Zero if a message was logged, non-zero if the error limit has been reached
*/
void __bdk_dram_report_error2(uint64_t address1, uint64_t data1, uint64_t address2, uint64_t data2,
int burst, int fails)
{
int64_t errors = bdk_atomic_fetch_and_add64(&dram_test_thread_errors, 1);
if (errors < MAX_ERRORS_TO_REPORT)
{
char buffer1[80], buffer2[80];
char failbuf[32];
if (fails < 0) {
snprintf(failbuf, sizeof(failbuf), " ");
} else {
snprintf(failbuf, sizeof(failbuf), ", retried %d failed %d", RETRY_LIMIT, fails);
}
__bdk_dram_report_address_decode(address1, buffer1, sizeof(buffer1));
__bdk_dram_report_address_decode(address2, buffer2, sizeof(buffer2));
bdk_error("compare: data1: 0x%016llx, xor: 0x%016llx%s\n"
" %s\n %s\n",
data1, data1 ^ data2, failbuf,
buffer1, buffer2);
if (errors == MAX_ERRORS_TO_REPORT-1)
bdk_error("No further DRAM errors will be reported\n");
}
return;
}
/* Report the circumstances of a failure and try re-reading the memory
* location to see if the error is transient or permanent.
*
* Note: re-reading requires using evicting addresses
*/
int __bdk_dram_retry_failure(int burst, uint64_t address, uint64_t data, uint64_t expected)
{
int refail = 0;
// bypass the retries if we are already over the limit...
if (bdk_atomic_get64(&dram_test_thread_errors) < MAX_ERRORS_TO_REPORT) {
/* Try re-reading the memory location. A transient error may fail
* on one read and work on another. Keep on retrying even when a
* read succeeds.
*/
for (int i = 0; i < RETRY_LIMIT; i++) {
__bdk_dram_flush_to_mem(address);
BDK_DCACHE_INVALIDATE;
uint64_t new = __bdk_dram_read64(address);
if (new != expected) {
refail++;
}
}
} else
refail = -1;
// this will increment the errors always, but maybe not print...
__bdk_dram_report_error(address, data, expected, burst, refail);
return 1;
}
/**
* retry_failure2
*
* @param burst
* @param address1
* @param address2
*/
int __bdk_dram_retry_failure2(int burst, uint64_t address1, uint64_t data1, uint64_t address2, uint64_t data2)
{
int refail = 0;
// bypass the retries if we are already over the limit...
if (bdk_atomic_get64(&dram_test_thread_errors) < MAX_ERRORS_TO_REPORT) {
for (int i = 0; i < RETRY_LIMIT; i++) {
__bdk_dram_flush_to_mem(address1);
__bdk_dram_flush_to_mem(address2);
BDK_DCACHE_INVALIDATE;
uint64_t d1 = __bdk_dram_read64(address1);
uint64_t d2 = __bdk_dram_read64(address2);
if (d1 != d2) {
refail++;
}
}
} else
refail = -1;
// this will increment the errors always, but maybe not print...
__bdk_dram_report_error2(address1, data1, address2, data2, burst, refail);
return 1;
}
/**
* Inject a DRAM error at a specific address in memory. The injection can either
* be a single bit inside the byte, or a double bit error in the ECC byte. Double
* bit errors may corrupt memory, causing software to crash. The corruption is
* written to memory and will continue to exist until the cache line is written
* again. After a call to this function, the BDK should report a ECC error. Double
* bit errors corrupt bits 0-1.
*
* @param address Physical address to corrupt. Any byte alignment is supported
* @param bit Bit to corrupt in the byte (0-7), or -1 to create a double bit fault in the ECC
* byte.
*/
void bdk_dram_test_inject_error(uint64_t address, int bit)
{
uint64_t aligned_address = address & -16;
int corrupt_bit = -1;
if (bit >= 0)
corrupt_bit = (address & 0xf) * 8 + bit;
/* Extract the DRAM controller information */
int node, lmc, dimm, prank, lrank, bank, row, col;
bdk_dram_address_extract_info(address, &node, &lmc, &dimm, &prank, &lrank, &bank, &row, &col);
/* Read the current data */
uint64_t data = __bdk_dram_read64(aligned_address);
/* Program LMC to inject the error */
if ((corrupt_bit >= 0) && (corrupt_bit < 64))
BDK_CSR_WRITE(node, BDK_LMCX_CHAR_MASK0(lmc), 1ull << corrupt_bit);
else if (bit == -1)
BDK_CSR_WRITE(node, BDK_LMCX_CHAR_MASK0(lmc), 3);
else
BDK_CSR_WRITE(node, BDK_LMCX_CHAR_MASK0(lmc), 0);
if (corrupt_bit >= 64)
BDK_CSR_WRITE(node, BDK_LMCX_CHAR_MASK2(lmc), 1ull << (corrupt_bit - 64));
else
BDK_CSR_WRITE(node, BDK_LMCX_CHAR_MASK2(lmc), 0);
BDK_CSR_MODIFY(c, node, BDK_LMCX_ECC_PARITY_TEST(lmc),
c.s.ecc_corrupt_idx = (address & 0x7f) >> 4;
c.s.ecc_corrupt_ena = 1);
BDK_CSR_READ(node, BDK_LMCX_ECC_PARITY_TEST(lmc));
/* Perform a write and push it to DRAM. This creates the error */
__bdk_dram_write64(aligned_address, data);
__bdk_dram_flush_to_mem(aligned_address);
/* Disable error injection */
BDK_CSR_MODIFY(c, node, BDK_LMCX_ECC_PARITY_TEST(lmc),
c.s.ecc_corrupt_ena = 0);
BDK_CSR_READ(node, BDK_LMCX_ECC_PARITY_TEST(lmc));
BDK_CSR_WRITE(node, BDK_LMCX_CHAR_MASK0(lmc), 0);
BDK_CSR_WRITE(node, BDK_LMCX_CHAR_MASK2(lmc), 0);
/* Read back the data, which should now cause an error */
printf("Loading the injected error address 0x%llx, node=%d, lmc=%d, dimm=%d, rank=%d/%d, bank=%d, row=%d, col=%d\n",
address, node, lmc, dimm, prank, lrank, bank, row, col);
__bdk_dram_read64(aligned_address);
}
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