open-gpu-kernel-modules/kernel-open/nvidia-uvm/uvm_perf_utils_test.c
2022-05-09 13:18:59 -07:00

748 lines
29 KiB
C

/*******************************************************************************
Copyright (c) 2015 NVIDIA Corporation
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to
deal in the Software without restriction, including without limitation the
rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
sell copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be
included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
DEALINGS IN THE SOFTWARE.
*******************************************************************************/
#include "uvm_perf_utils.h"
#include "uvm_va_block.h"
#include "uvm_test.h"
static NV_STATUS test_saturating_counter_basic(void)
{
NvU8 counter8;
NvU16 counter16;
NvU32 counter32;
NvU64 counter64;
NvU8 max8 = -1;
NvU16 max16 = -1;
NvU32 max32 = -1;
NvU64 max64 = -1;
counter8 = 0;
UVM_PERF_SATURATING_INC(counter8);
TEST_CHECK_RET(counter8 == 1);
UVM_PERF_SATURATING_INC(counter8);
TEST_CHECK_RET(counter8 == 2);
UVM_PERF_SATURATING_ADD(counter8, 5);
TEST_CHECK_RET(counter8 == 7);
// Counter saturating at maximum unsigned char value
UVM_PERF_SATURATING_ADD(counter8, max8);
TEST_CHECK_RET(counter8 == max8);
counter16 = 0;
UVM_PERF_SATURATING_INC(counter16);
TEST_CHECK_RET(counter16 == 1);
UVM_PERF_SATURATING_INC(counter16);
TEST_CHECK_RET(counter16 == 2);
UVM_PERF_SATURATING_ADD(counter16, 5);
TEST_CHECK_RET(counter16 == 7);
// Counter saturating at maximum unsigned short value
UVM_PERF_SATURATING_ADD(counter16, max16);
TEST_CHECK_RET(counter16 == max16);
counter32 = 0;
UVM_PERF_SATURATING_INC(counter32);
TEST_CHECK_RET(counter32 == 1);
UVM_PERF_SATURATING_INC(counter32);
TEST_CHECK_RET(counter32 == 2);
UVM_PERF_SATURATING_ADD(counter32, 5);
TEST_CHECK_RET(counter32 == 7);
// Counter saturating at maximum unsigned long int value
UVM_PERF_SATURATING_ADD(counter32, max32);
TEST_CHECK_RET(counter32 == max32);
counter64 = 0;
UVM_PERF_SATURATING_INC(counter64);
TEST_CHECK_RET(counter64 == 1);
UVM_PERF_SATURATING_INC(counter64);
TEST_CHECK_RET(counter64 == 2);
UVM_PERF_SATURATING_ADD(counter64, 5);
TEST_CHECK_RET(counter64 == 7);
// Counter saturating at maximum unsigned long long int value
UVM_PERF_SATURATING_ADD(counter64, max64);
TEST_CHECK_RET(counter64 == max64);
return NV_OK;
}
struct region
{
unsigned char read_faults : 4;
unsigned char write_faults : 4;
unsigned char atomic_faults : 4;
unsigned char upgrades : 4;
};
static NV_STATUS test_saturating_counter_bitfields(void)
{
struct region r;
memset(&r, 0, sizeof(r));
UVM_PERF_SATURATING_INC(r.read_faults);
TEST_CHECK_RET(r.read_faults == 1);
UVM_PERF_SATURATING_INC(r.write_faults);
TEST_CHECK_RET(r.write_faults == 1);
UVM_PERF_SATURATING_ADD(r.atomic_faults, 18);
TEST_CHECK_RET(r.atomic_faults == 15);
return NV_OK;
}
static NV_STATUS test_saturating_counter(void)
{
NV_STATUS status;
status = test_saturating_counter_basic();
if (status != NV_OK)
goto fail;
status = test_saturating_counter_bitfields();
fail:
return status;
}
static NV_STATUS test_tree_pow2(void)
{
NV_STATUS status;
uvm_perf_tree_t my_int_tree;
uvm_perf_tree_iter_t iter;
int *node;
status = uvm_perf_tree_init(&my_int_tree, sizeof(int), 8);
MEM_NV_CHECK_RET(status, NV_OK);
TEST_CHECK_GOTO(my_int_tree.node_count == 8 * 2 - 1, fail);
TEST_CHECK_GOTO(my_int_tree.level_count == 4, fail);
uvm_perf_tree_traverse_leaf_to_root(&my_int_tree, 3, node, &iter) {
++*node;
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 0, fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 1] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 3] == 0, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[12 + 0] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[12 + 1] == 0, fail);
// Level 3 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 1, fail);
TEST_CHECK_GOTO(*UVM_PERF_TREE_ROOT(&my_int_tree, int) == 1, fail);
uvm_perf_tree_traverse_leaf_to_root(&my_int_tree, 6, node, &iter) {
++*node;
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 0, fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 1] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 3] == 1, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[12 + 0] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[12 + 1] == 1, fail);
// Level 3 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 2, fail);
TEST_CHECK_GOTO(*UVM_PERF_TREE_ROOT(&my_int_tree, int) == 2, fail);
uvm_perf_tree_traverse_root_to_leaf(&my_int_tree, 7, node, &iter) {
++*node;
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 1, fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 0) == &((int *)my_int_tree.nodes)[0], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 1) == &((int *)my_int_tree.nodes)[1], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 2) == &((int *)my_int_tree.nodes)[2], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 3) == &((int *)my_int_tree.nodes)[3], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 4) == &((int *)my_int_tree.nodes)[4], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 5) == &((int *)my_int_tree.nodes)[5], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 6) == &((int *)my_int_tree.nodes)[6], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 7) == &((int *)my_int_tree.nodes)[7], fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 1] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 3] == 2, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[12 + 0] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[12 + 1] == 2, fail);
// Level 3 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 3, fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_ROOT(&my_int_tree, int) == &((int *)my_int_tree.nodes)[14 + 0], fail);
uvm_perf_tree_clear(&my_int_tree, sizeof(int));
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 0, fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8 + 3] == 0, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[12 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[12 + 1] == 0, fail);
// Level 3 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 0, fail);
uvm_perf_tree_destroy(&my_int_tree);
return NV_OK;
fail:
uvm_perf_tree_destroy(&my_int_tree);
return NV_ERR_INVALID_STATE;
}
static NV_STATUS test_tree_non_pow2(void)
{
NV_STATUS status;
uvm_perf_tree_t my_int_tree;
uvm_perf_tree_iter_t iter;
int *node;
status = uvm_perf_tree_init(&my_int_tree, sizeof(int), 7);
MEM_NV_CHECK_RET(status, NV_OK);
TEST_CHECK_GOTO(my_int_tree.node_count == 7 + 4 + 2 + 1, fail);
TEST_CHECK_GOTO(my_int_tree.level_count == 4, fail);
uvm_perf_tree_destroy(&my_int_tree);
status = uvm_perf_tree_init(&my_int_tree, sizeof(int), 9);
MEM_NV_CHECK_RET(status, NV_OK);
TEST_CHECK_GOTO(my_int_tree.node_count == 9 + 5 + 3 + 2 + 1, fail);
TEST_CHECK_GOTO(my_int_tree.level_count == 5, fail);
uvm_perf_tree_destroy(&my_int_tree);
status = uvm_perf_tree_init(&my_int_tree, sizeof(int), 13);
MEM_NV_CHECK_RET(status, NV_OK);
TEST_CHECK_GOTO(my_int_tree.node_count == 13 + 7 + 4 + 2 + 1, fail);
TEST_CHECK_GOTO(my_int_tree.level_count == 5, fail);
uvm_perf_tree_destroy(&my_int_tree);
status = uvm_perf_tree_init(&my_int_tree, sizeof(int), 15);
MEM_NV_CHECK_RET(status, NV_OK);
TEST_CHECK_GOTO(my_int_tree.node_count == 15 + 8 + 4 + 2 + 1, fail);
TEST_CHECK_GOTO(my_int_tree.level_count == 5, fail);
uvm_perf_tree_destroy(&my_int_tree);
status = uvm_perf_tree_init(&my_int_tree, sizeof(int), 9);
MEM_NV_CHECK_RET(status, NV_OK);
uvm_perf_tree_traverse_leaf_to_root(&my_int_tree, 6, node, &iter) {
++*node;
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8] == 0, fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 3] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 4] == 0, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 1] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 2] == 0, fail);
// Level 3
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 0] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 1] == 0, fail);
// Level 4 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[19 + 0] == 1, fail);
TEST_CHECK_GOTO(*UVM_PERF_TREE_ROOT(&my_int_tree, int) == 1, fail);
uvm_perf_tree_traverse_root_to_leaf(&my_int_tree, 2, node, &iter) {
++*node;
}
uvm_perf_tree_traverse_root_to_leaf(&my_int_tree, 8, node, &iter) {
++*node;
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8] == 1, fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 0) == &((int *)my_int_tree.nodes)[0], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 1) == &((int *)my_int_tree.nodes)[1], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 2) == &((int *)my_int_tree.nodes)[2], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 3) == &((int *)my_int_tree.nodes)[3], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 4) == &((int *)my_int_tree.nodes)[4], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 5) == &((int *)my_int_tree.nodes)[5], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 6) == &((int *)my_int_tree.nodes)[6], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 7) == &((int *)my_int_tree.nodes)[7], fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_LEAF(&my_int_tree, int, 8) == &((int *)my_int_tree.nodes)[8], fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 1] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 3] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 4] == 1, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 1] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 2] == 1, fail);
// Level 3
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 0] == 2, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 1] == 1, fail);
// Level 4 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[19 + 0] == 3, fail);
TEST_CHECK_GOTO(UVM_PERF_TREE_ROOT(&my_int_tree, int) == &((int *)my_int_tree.nodes)[19 + 0], fail);
uvm_perf_tree_destroy(&my_int_tree);
return NV_OK;
fail:
uvm_perf_tree_destroy(&my_int_tree);
return NV_ERR_INVALID_STATE;
}
static NV_STATUS test_branch_traversal(void)
{
NV_STATUS status;
uvm_perf_tree_t my_int_tree;
uvm_perf_tree_iter_t iter;
int *node;
int value;
status = uvm_perf_tree_init(&my_int_tree, sizeof(int), 9);
MEM_NV_CHECK_RET(status, NV_OK);
value = 1;
/*
* Level idx
* =========
* 0 0
* _______/ \______
* 1 0 1
* __/ \__ __/
* 2 0 1 2
* / \ / \ /
* 3 0 1 2 3 4
* / \ / \ / \ / \ / \
* 4 0 1 2 3 4 5 6 7 8 9
*/
uvm_perf_tree_traverse_leaf_to_root(&my_int_tree, 6, node, &iter) {
if (iter.level_idx == 4) {
TEST_CHECK_GOTO(uvm_perf_tree_iter_max_leaves(&my_int_tree, &iter) == 1, fail);
TEST_CHECK_GOTO(uvm_perf_tree_iter_leaf_range(&my_int_tree, &iter) == 1, fail);
TEST_CHECK_GOTO(uvm_perf_tree_iter_leaf_range_start(&my_int_tree, &iter) == 6, fail);
}
else if (iter.level_idx == 3) {
TEST_CHECK_GOTO(uvm_perf_tree_iter_max_leaves(&my_int_tree, &iter) == 2, fail);
TEST_CHECK_GOTO(uvm_perf_tree_iter_leaf_range(&my_int_tree, &iter) == 2, fail);
TEST_CHECK_GOTO(uvm_perf_tree_iter_leaf_range_start(&my_int_tree, &iter) == 6, fail);
}
else if (iter.level_idx == 2) {
TEST_CHECK_GOTO(uvm_perf_tree_iter_max_leaves(&my_int_tree, &iter) == 4, fail);
TEST_CHECK_GOTO(uvm_perf_tree_iter_leaf_range(&my_int_tree, &iter) == 4, fail);
TEST_CHECK_GOTO(uvm_perf_tree_iter_leaf_range_start(&my_int_tree, &iter) == 4, fail);
}
else if (iter.level_idx == 1) {
TEST_CHECK_GOTO(uvm_perf_tree_iter_max_leaves(&my_int_tree, &iter) == 8, fail);
TEST_CHECK_GOTO(uvm_perf_tree_iter_leaf_range(&my_int_tree, &iter) == 8, fail);
TEST_CHECK_GOTO(uvm_perf_tree_iter_leaf_range_start(&my_int_tree, &iter) == 0, fail);
}
else if (iter.level_idx == 0) {
TEST_CHECK_GOTO(uvm_perf_tree_iter_max_leaves(&my_int_tree, &iter) == 16, fail);
TEST_CHECK_GOTO(uvm_perf_tree_iter_leaf_range(&my_int_tree, &iter) == 9, fail);
TEST_CHECK_GOTO(uvm_perf_tree_iter_leaf_range_start(&my_int_tree, &iter) == 0, fail);
}
*node += value++;
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8] == 0, fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 3] == 2, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 4] == 0, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 1] == 3, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 2] == 0, fail);
// Level 3
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 0] == 4, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 1] == 0, fail);
// Level 4 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[19 + 0] == 5, fail);
TEST_CHECK_GOTO(*UVM_PERF_TREE_ROOT(&my_int_tree, int) == 5, fail);
uvm_perf_tree_traverse_root_to_leaf(&my_int_tree, 6, node, &iter) {
*node -= --value;
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8] == 0, fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 2] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 3] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 4] == 0, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 1] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 2] == 0, fail);
// Level 3
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 0] == 0, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 1] == 0, fail);
// Level 4 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[19 + 0] == 0, fail);
uvm_perf_tree_destroy(&my_int_tree);
return NV_OK;
fail:
uvm_perf_tree_destroy(&my_int_tree);
return NV_ERR_INVALID_STATE;
}
static NV_STATUS test_tree_traversal(void)
{
NV_STATUS status;
uvm_perf_tree_t my_int_tree;
uvm_perf_tree_iter_t iter;
int *node;
int value;
status = uvm_perf_tree_init(&my_int_tree, sizeof(int), 9);
MEM_NV_CHECK_RET(status, NV_OK);
value = 1;
uvm_perf_tree_for_each_level_down(&my_int_tree, &iter) {
uvm_perf_tree_level_for_each_node(&my_int_tree, node, &iter) {
*node = value++;
}
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 12, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 13, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 14, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 15, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 16, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 17, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 18, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 19, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8] == 20, fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 0] == 7, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 1] == 8, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 2] == 9, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 3] == 10, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 4] == 11, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 4, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 1] == 5, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 2] == 6, fail);
// Level 3
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 0] == 2, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 1] == 3, fail);
// Level 4 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[19 + 0] == 1, fail);
value = 1;
uvm_perf_tree_for_each_level_up(&my_int_tree, &iter) {
// Traverse nodes left to right in each level
uvm_perf_tree_level_for_each_node(&my_int_tree, node, &iter) {
*node = value++;
}
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 1, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 2, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 3, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 4, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 5, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 6, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 7, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 8, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8] == 9, fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 0] == 10, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 1] == 11, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 2] == 12, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 3] == 13, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 4] == 14, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 15, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 1] == 16, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 2] == 17, fail);
// Level 3
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 0] == 18, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 1] == 19, fail);
// Level 4 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[19 + 0] == 20, fail);
value = 1;
uvm_perf_tree_for_each_level_down(&my_int_tree, &iter) {
uvm_perf_tree_level_for_each_node_reverse(&my_int_tree, node, &iter) {
*node = value++;
}
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 20, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 19, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 18, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 17, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 16, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 15, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 14, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 13, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8] == 12, fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 0] == 11, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 1] == 10, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 2] == 9, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 3] == 8, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 4] == 7, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 6, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 1] == 5, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 2] == 4, fail);
// Level 3
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 0] == 3, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 1] == 2, fail);
// Level 4 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[19 + 0] == 1, fail);
value = 1;
uvm_perf_tree_for_each_level_up(&my_int_tree, &iter) {
// Traverse nodes right to left in each level
uvm_perf_tree_level_for_each_node_reverse(&my_int_tree, node, &iter) {
*node = value++;
}
}
// Level 0 (leafs)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[0] == 9, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[1] == 8, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[2] == 7, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[3] == 6, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[4] == 5, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[5] == 4, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[6] == 3, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[7] == 2, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[8] == 1, fail);
// Level 1
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 0] == 14, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 1] == 13, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 2] == 12, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 3] == 11, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[9 + 4] == 10, fail);
// Level 2
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 0] == 17, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 1] == 16, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[14 + 2] == 15, fail);
// Level 3
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 0] == 19, fail);
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[17 + 1] == 18, fail);
// Level 4 (root)
TEST_CHECK_GOTO(((int *)my_int_tree.nodes)[19 + 0] == 20, fail);
uvm_perf_tree_destroy(&my_int_tree);
return NV_OK;
fail:
uvm_perf_tree_destroy(&my_int_tree);
return NV_ERR_INVALID_STATE;
}
static NV_STATUS test_bitmap_tree_traversal(void)
{
int value;
uvm_va_block_bitmap_tree_t tree;
uvm_va_block_bitmap_tree_iter_t iter;
uvm_va_block_bitmap_tree_init_from_page_count(&tree, 9);
TEST_CHECK_RET(tree.level_count == 5);
TEST_CHECK_RET(tree.leaf_count == 9);
uvm_page_mask_set(&tree.pages, 1);
uvm_page_mask_set(&tree.pages, 2);
uvm_page_mask_set(&tree.pages, 4);
uvm_page_mask_set(&tree.pages, 7);
uvm_page_mask_set(&tree.pages, 8);
uvm_va_block_bitmap_tree_traverse_counters(value, &tree, 6, &iter) {
if (iter.level_idx == 4)
TEST_CHECK_RET(value == 0);
else if (iter.level_idx == 3)
TEST_CHECK_RET(value == 1);
else if (iter.level_idx == 2)
TEST_CHECK_RET(value == 2);
else if (iter.level_idx == 1)
TEST_CHECK_RET(value == 4);
else if (iter.level_idx == 0)
TEST_CHECK_RET(value == 5);
}
return NV_OK;
}
static NV_STATUS test_trees(void)
{
NV_STATUS status;
status = test_tree_pow2();
if (status != NV_OK)
goto fail;
status = test_tree_non_pow2();
if (status != NV_OK)
goto fail;
status = test_branch_traversal();
if (status != NV_OK)
goto fail;
status = test_tree_traversal();
if (status != NV_OK)
goto fail;
status = test_bitmap_tree_traversal();
fail:
return status;
}
NV_STATUS uvm_test_perf_utils_sanity(UVM_TEST_PERF_UTILS_SANITY_PARAMS *params, struct file *filp)
{
NV_STATUS status;
status = test_saturating_counter();
if (status != NV_OK)
goto fail;
status = test_trees();
fail:
return status;
}