tracing: Create a sparse bitmask for pid filtering

When the trace_pid_list was created, the default pid max was 32768.
Creating a bitmask that can hold one bit for all 32768 took up 4096 (one
page). Having a one page bitmask was not much of a problem, and that was
used for mapping pids. But today, systems are bigger and can run more
tasks, and now the default pid_max is usually set to 4194304. Which means
to handle that many pids requires 524288 bytes. Worse yet, the pid_max can
be set to 2^30 (1073741824 or 1G) which would take 134217728 (128M) of
memory to store this array.

Since the pid_list array is very sparsely populated, it is a huge waste of
memory to store all possible bits for each pid when most will not be set.

Instead, use a page table scheme to store the array, and allow this to
handle up to 30 bit pids.

The pid_mask will start out with 256 entries for the first 8 MSB bits.
This will cost 1K for 32 bit architectures and 2K for 64 bit. Each of
these will have a 256 array to store the next 8 bits of the pid (another
1 or 2K). These will hold an 2K byte bitmask (which will cover the LSB
14 bits or 16384 pids).

When the trace_pid_list is allocated, it will have the 1/2K upper bits
allocated, and then it will allocate a cache for the next upper chunks and
the lower chunks (default 6 of each). Then when a bit is "set", these
chunks will be pulled from the free list and added to the array. If the
free list gets down to a lever (default 2), it will trigger an irqwork
that will refill the cache back up.

On clearing a bit, if the clear causes the bitmask to be zero, that chunk
will then be placed back into the free cache for later use, keeping the
need to allocate more down to a minimum.
Signed-off-by: default avatarSteven Rostedt (VMware) <rostedt@goodmis.org>
parent 6954e415
......@@ -2,10 +2,119 @@
/*
* Copyright (C) 2021 VMware Inc, Steven Rostedt <rostedt@goodmis.org>
*/
#include <linux/vmalloc.h>
#include <linux/spinlock.h>
#include <linux/irq_work.h>
#include <linux/slab.h>
#include "trace.h"
/* See pid_list.h for details */
static inline union lower_chunk *get_lower_chunk(struct trace_pid_list *pid_list)
{
union lower_chunk *chunk;
lockdep_assert_held(&pid_list->lock);
if (!pid_list->lower_list)
return NULL;
chunk = pid_list->lower_list;
pid_list->lower_list = chunk->next;
pid_list->free_lower_chunks--;
WARN_ON_ONCE(pid_list->free_lower_chunks < 0);
chunk->next = NULL;
/*
* If a refill needs to happen, it can not happen here
* as the scheduler run queue locks are held.
*/
if (pid_list->free_lower_chunks <= CHUNK_REALLOC)
irq_work_queue(&pid_list->refill_irqwork);
return chunk;
}
static inline union upper_chunk *get_upper_chunk(struct trace_pid_list *pid_list)
{
union upper_chunk *chunk;
lockdep_assert_held(&pid_list->lock);
if (!pid_list->upper_list)
return NULL;
chunk = pid_list->upper_list;
pid_list->upper_list = chunk->next;
pid_list->free_upper_chunks--;
WARN_ON_ONCE(pid_list->free_upper_chunks < 0);
chunk->next = NULL;
/*
* If a refill needs to happen, it can not happen here
* as the scheduler run queue locks are held.
*/
if (pid_list->free_upper_chunks <= CHUNK_REALLOC)
irq_work_queue(&pid_list->refill_irqwork);
return chunk;
}
static inline void put_lower_chunk(struct trace_pid_list *pid_list,
union lower_chunk *chunk)
{
lockdep_assert_held(&pid_list->lock);
chunk->next = pid_list->lower_list;
pid_list->lower_list = chunk;
pid_list->free_lower_chunks++;
}
static inline void put_upper_chunk(struct trace_pid_list *pid_list,
union upper_chunk *chunk)
{
lockdep_assert_held(&pid_list->lock);
chunk->next = pid_list->upper_list;
pid_list->upper_list = chunk;
pid_list->free_upper_chunks++;
}
static inline bool upper_empty(union upper_chunk *chunk)
{
/*
* If chunk->data has no lower chunks, it will be the same
* as a zeroed bitmask. Use find_first_bit() to test it
* and if it doesn't find any bits set, then the array
* is empty.
*/
int bit = find_first_bit((unsigned long *)chunk->data,
sizeof(chunk->data) * 8);
return bit >= sizeof(chunk->data) * 8;
}
static inline int pid_split(unsigned int pid, unsigned int *upper1,
unsigned int *upper2, unsigned int *lower)
{
/* MAX_PID should cover all pids */
BUILD_BUG_ON(MAX_PID < PID_MAX_LIMIT);
/* In case a bad pid is passed in, then fail */
if (unlikely(pid >= MAX_PID))
return -1;
*upper1 = (pid >> UPPER1_SHIFT) & UPPER_MASK;
*upper2 = (pid >> UPPER2_SHIFT) & UPPER_MASK;
*lower = pid & LOWER_MASK;
return 0;
}
static inline unsigned int pid_join(unsigned int upper1,
unsigned int upper2, unsigned int lower)
{
return ((upper1 & UPPER_MASK) << UPPER1_SHIFT) |
((upper2 & UPPER_MASK) << UPPER2_SHIFT) |
(lower & LOWER_MASK);
}
/**
* trace_pid_list_is_set - test if the pid is set in the list
* @pid_list: The pid list to test
......@@ -19,14 +128,30 @@
*/
bool trace_pid_list_is_set(struct trace_pid_list *pid_list, unsigned int pid)
{
/*
* If pid_max changed after filtered_pids was created, we
* by default ignore all pids greater than the previous pid_max.
*/
if (pid >= pid_list->pid_max)
union upper_chunk *upper_chunk;
union lower_chunk *lower_chunk;
unsigned long flags;
unsigned int upper1;
unsigned int upper2;
unsigned int lower;
bool ret = false;
if (!pid_list)
return false;
if (pid_split(pid, &upper1, &upper2, &lower) < 0)
return false;
return test_bit(pid, pid_list->pids);
raw_spin_lock_irqsave(&pid_list->lock, flags);
upper_chunk = pid_list->upper[upper1];
if (upper_chunk) {
lower_chunk = upper_chunk->data[upper2];
if (lower_chunk)
ret = test_bit(lower, lower_chunk->data);
}
raw_spin_unlock_irqrestore(&pid_list->lock, flags);
return ret;
}
/**
......@@ -42,13 +167,44 @@ bool trace_pid_list_is_set(struct trace_pid_list *pid_list, unsigned int pid)
*/
int trace_pid_list_set(struct trace_pid_list *pid_list, unsigned int pid)
{
/* Sorry, but we don't support pid_max changing after setting */
if (pid >= pid_list->pid_max)
return -EINVAL;
union upper_chunk *upper_chunk;
union lower_chunk *lower_chunk;
unsigned long flags;
unsigned int upper1;
unsigned int upper2;
unsigned int lower;
int ret;
set_bit(pid, pid_list->pids);
if (!pid_list)
return -ENODEV;
return 0;
if (pid_split(pid, &upper1, &upper2, &lower) < 0)
return -EINVAL;
raw_spin_lock_irqsave(&pid_list->lock, flags);
upper_chunk = pid_list->upper[upper1];
if (!upper_chunk) {
upper_chunk = get_upper_chunk(pid_list);
if (!upper_chunk) {
ret = -ENOMEM;
goto out;
}
pid_list->upper[upper1] = upper_chunk;
}
lower_chunk = upper_chunk->data[upper2];
if (!lower_chunk) {
lower_chunk = get_lower_chunk(pid_list);
if (!lower_chunk) {
ret = -ENOMEM;
goto out;
}
upper_chunk->data[upper2] = lower_chunk;
}
set_bit(lower, lower_chunk->data);
ret = 0;
out:
raw_spin_unlock_irqrestore(&pid_list->lock, flags);
return ret;
}
/**
......@@ -64,12 +220,41 @@ int trace_pid_list_set(struct trace_pid_list *pid_list, unsigned int pid)
*/
int trace_pid_list_clear(struct trace_pid_list *pid_list, unsigned int pid)
{
/* Sorry, but we don't support pid_max changing after setting */
if (pid >= pid_list->pid_max)
union upper_chunk *upper_chunk;
union lower_chunk *lower_chunk;
unsigned long flags;
unsigned int upper1;
unsigned int upper2;
unsigned int lower;
if (!pid_list)
return -ENODEV;
if (pid_split(pid, &upper1, &upper2, &lower) < 0)
return -EINVAL;
clear_bit(pid, pid_list->pids);
raw_spin_lock_irqsave(&pid_list->lock, flags);
upper_chunk = pid_list->upper[upper1];
if (!upper_chunk)
goto out;
lower_chunk = upper_chunk->data[upper2];
if (!lower_chunk)
goto out;
clear_bit(lower, lower_chunk->data);
/* if there's no more bits set, add it to the free list */
if (find_first_bit(lower_chunk->data, LOWER_MAX) >= LOWER_MAX) {
put_lower_chunk(pid_list, lower_chunk);
upper_chunk->data[upper2] = NULL;
if (upper_empty(upper_chunk)) {
put_upper_chunk(pid_list, upper_chunk);
pid_list->upper[upper1] = NULL;
}
}
out:
raw_spin_unlock_irqrestore(&pid_list->lock, flags);
return 0;
}
......@@ -88,13 +273,45 @@ int trace_pid_list_clear(struct trace_pid_list *pid_list, unsigned int pid)
int trace_pid_list_next(struct trace_pid_list *pid_list, unsigned int pid,
unsigned int *next)
{
pid = find_next_bit(pid_list->pids, pid_list->pid_max, pid);
union upper_chunk *upper_chunk;
union lower_chunk *lower_chunk;
unsigned long flags;
unsigned int upper1;
unsigned int upper2;
unsigned int lower;
if (pid < pid_list->pid_max) {
*next = pid;
return 0;
if (!pid_list)
return -ENODEV;
if (pid_split(pid, &upper1, &upper2, &lower) < 0)
return -EINVAL;
raw_spin_lock_irqsave(&pid_list->lock, flags);
for (; upper1 <= UPPER_MASK; upper1++, upper2 = 0) {
upper_chunk = pid_list->upper[upper1];
if (!upper_chunk)
continue;
for (; upper2 <= UPPER_MASK; upper2++, lower = 0) {
lower_chunk = upper_chunk->data[upper2];
if (!lower_chunk)
continue;
lower = find_next_bit(lower_chunk->data, LOWER_MAX,
lower);
if (lower < LOWER_MAX)
goto found;
}
}
found:
raw_spin_unlock_irqrestore(&pid_list->lock, flags);
if (upper1 > UPPER_MASK)
return -1;
*next = pid_join(upper1, upper2, lower);
return 0;
}
/**
......@@ -109,15 +326,79 @@ int trace_pid_list_next(struct trace_pid_list *pid_list, unsigned int pid,
*/
int trace_pid_list_first(struct trace_pid_list *pid_list, unsigned int *pid)
{
unsigned int first;
return trace_pid_list_next(pid_list, 0, pid);
}
first = find_first_bit(pid_list->pids, pid_list->pid_max);
static void pid_list_refill_irq(struct irq_work *iwork)
{
struct trace_pid_list *pid_list = container_of(iwork, struct trace_pid_list,
refill_irqwork);
union upper_chunk *upper;
union lower_chunk *lower;
union upper_chunk **upper_next = &upper;
union lower_chunk **lower_next = &lower;
int upper_count;
int lower_count;
int ucnt = 0;
int lcnt = 0;
if (first < pid_list->pid_max) {
*pid = first;
return 0;
again:
raw_spin_lock(&pid_list->lock);
upper_count = CHUNK_ALLOC - pid_list->free_upper_chunks;
lower_count = CHUNK_ALLOC - pid_list->free_lower_chunks;
raw_spin_unlock(&pid_list->lock);
if (upper_count <= 0 && lower_count <= 0)
return;
while (upper_count-- > 0) {
union upper_chunk *chunk;
chunk = kzalloc(sizeof(*chunk), GFP_KERNEL);
if (!chunk)
break;
*upper_next = chunk;
upper_next = &chunk->next;
ucnt++;
}
return -1;
while (lower_count-- > 0) {
union lower_chunk *chunk;
chunk = kzalloc(sizeof(*chunk), GFP_KERNEL);
if (!chunk)
break;
*lower_next = chunk;
lower_next = &chunk->next;
lcnt++;
}
raw_spin_lock(&pid_list->lock);
if (upper) {
*upper_next = pid_list->upper_list;
pid_list->upper_list = upper;
pid_list->free_upper_chunks += ucnt;
}
if (lower) {
*lower_next = pid_list->lower_list;
pid_list->lower_list = lower;
pid_list->free_lower_chunks += lcnt;
}
raw_spin_unlock(&pid_list->lock);
/*
* On success of allocating all the chunks, both counters
* will be less than zero. If they are not, then an allocation
* failed, and we should not try again.
*/
if (upper_count >= 0 || lower_count >= 0)
return;
/*
* When the locks were released, free chunks could have
* been used and allocation needs to be done again. Might as
* well allocate it now.
*/
goto again;
}
/**
......@@ -130,18 +411,41 @@ int trace_pid_list_first(struct trace_pid_list *pid_list, unsigned int *pid)
struct trace_pid_list *trace_pid_list_alloc(void)
{
struct trace_pid_list *pid_list;
int i;
pid_list = kmalloc(sizeof(*pid_list), GFP_KERNEL);
/* According to linux/thread.h, pids can be no bigger that 30 bits */
WARN_ON_ONCE(pid_max > (1 << 30));
pid_list = kzalloc(sizeof(*pid_list), GFP_KERNEL);
if (!pid_list)
return NULL;
pid_list->pid_max = READ_ONCE(pid_max);
init_irq_work(&pid_list->refill_irqwork, pid_list_refill_irq);
pid_list->pids = vzalloc((pid_list->pid_max + 7) >> 3);
if (!pid_list->pids) {
kfree(pid_list);
return NULL;
raw_spin_lock_init(&pid_list->lock);
for (i = 0; i < CHUNK_ALLOC; i++) {
union upper_chunk *chunk;
chunk = kzalloc(sizeof(*chunk), GFP_KERNEL);
if (!chunk)
break;
chunk->next = pid_list->upper_list;
pid_list->upper_list = chunk;
pid_list->free_upper_chunks++;
}
for (i = 0; i < CHUNK_ALLOC; i++) {
union lower_chunk *chunk;
chunk = kzalloc(sizeof(*chunk), GFP_KERNEL);
if (!chunk)
break;
chunk->next = pid_list->lower_list;
pid_list->lower_list = chunk;
pid_list->free_lower_chunks++;
}
return pid_list;
}
......@@ -152,9 +456,40 @@ struct trace_pid_list *trace_pid_list_alloc(void)
*/
void trace_pid_list_free(struct trace_pid_list *pid_list)
{
union upper_chunk *upper;
union lower_chunk *lower;
int i, j;
if (!pid_list)
return;
vfree(pid_list->pids);
irq_work_sync(&pid_list->refill_irqwork);
while (pid_list->lower_list) {
union lower_chunk *chunk;
chunk = pid_list->lower_list;
pid_list->lower_list = pid_list->lower_list->next;
kfree(chunk);
}
while (pid_list->upper_list) {
union upper_chunk *chunk;
chunk = pid_list->upper_list;
pid_list->upper_list = pid_list->upper_list->next;
kfree(chunk);
}
for (i = 0; i < UPPER1_SIZE; i++) {
upper = pid_list->upper[i];
if (upper) {
for (j = 0; j < UPPER2_SIZE; j++) {
lower = upper->data[j];
kfree(lower);
}
kfree(upper);
}
}
kfree(pid_list);
}
......@@ -5,9 +5,84 @@
#ifndef _TRACE_INTERNAL_PID_LIST_H
#define _TRACE_INTERNAL_PID_LIST_H
/*
* In order to keep track of what pids to trace, a tree is created much
* like page tables are used. This creates a sparse bit map, where
* the tree is filled in when needed. A PID is at most 30 bits (see
* linux/thread.h), and is broken up into 3 sections based on the bit map
* of the bits. The 8 MSB is the "upper1" section. The next 8 MSB is the
* "upper2" section and the 14 LSB is the "lower" section.
*
* A trace_pid_list structure holds the "upper1" section, in an
* array of 256 pointers (1 or 2K in size) to "upper_chunk" unions, where
* each has an array of 256 pointers (1 or 2K in size) to the "lower_chunk"
* structures, where each has an array of size 2K bytes representing a bitmask
* of the 14 LSB of the PID (256 * 8 = 2048)
*
* When a trace_pid_list is allocated, it includes the 256 pointer array
* of the upper1 unions. Then a "cache" of upper and lower is allocated
* where these will be assigned as needed.
*
* When a bit is set in the pid_list bitmask, the pid to use has
* the 8 MSB masked, and this is used to index the array in the
* pid_list to find the next upper union. If the element is NULL,
* then one is retrieved from the upper_list cache. If none is
* available, then -ENOMEM is returned.
*
* The next 8 MSB is used to index into the "upper2" section. If this
* element is NULL, then it is retrieved from the lower_list cache.
* Again, if one is not available -ENOMEM is returned.
*
* Finally the 14 LSB of the PID is used to set the bit in the 16384
* bitmask (made up of 2K bytes).
*
* When the second upper section or the lower section has their last
* bit cleared, they are added back to the free list to be reused
* when needed.
*/
#define UPPER_BITS 8
#define UPPER_MAX (1 << UPPER_BITS)
#define UPPER1_SIZE (1 << UPPER_BITS)
#define UPPER2_SIZE (1 << UPPER_BITS)
#define LOWER_BITS 14
#define LOWER_MAX (1 << LOWER_BITS)
#define LOWER_SIZE (LOWER_MAX / BITS_PER_LONG)
#define UPPER1_SHIFT (LOWER_BITS + UPPER_BITS)
#define UPPER2_SHIFT LOWER_BITS
#define LOWER_MASK (LOWER_MAX - 1)
#define UPPER_MASK (UPPER_MAX - 1)
/* According to linux/thread.h pids can not be bigger than or equal to 1 << 30 */
#define MAX_PID (1 << 30)
/* Just keep 6 chunks of both upper and lower in the cache on alloc */
#define CHUNK_ALLOC 6
/* Have 2 chunks free, trigger a refill of the cache */
#define CHUNK_REALLOC 2
union lower_chunk {
union lower_chunk *next;
unsigned long data[LOWER_SIZE]; // 2K in size
};
union upper_chunk {
union upper_chunk *next;
union lower_chunk *data[UPPER2_SIZE]; // 1 or 2K in size
};
struct trace_pid_list {
int pid_max;
unsigned long *pids;
raw_spinlock_t lock;
struct irq_work refill_irqwork;
union upper_chunk *upper[UPPER1_SIZE]; // 1 or 2K in size
union upper_chunk *upper_list;
union lower_chunk *lower_list;
int free_upper_chunks;
int free_lower_chunks;
};
#endif /* _TRACE_INTERNAL_PID_LIST_H */
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