kernel-fxtec-pro1x/kernel/trace/tracing_map.c
Steven Rostedt (VMware) 0c81595930 tracing: Have the histogram compare functions convert to u64 first
commit 106f41f5a302cb1f36c7543fae6a05de12e96fa4 upstream.

The compare functions of the histogram code would be specific for the size
of the value being compared (byte, short, int, long long). It would
reference the value from the array via the type of the compare, but the
value was stored in a 64 bit number. This is fine for little endian
machines, but for big endian machines, it would end up comparing zeros or
all ones (depending on the sign) for anything but 64 bit numbers.

To fix this, first derference the value as a u64 then convert it to the type
being compared.

Link: http://lkml.kernel.org/r/20191211103557.7bed6928@gandalf.local.home

Cc: stable@vger.kernel.org
Fixes: 08d43a5fa0 ("tracing: Add lock-free tracing_map")
Acked-by: Tom Zanussi <zanussi@kernel.org>
Reported-by: Sven Schnelle <svens@stackframe.org>
Signed-off-by: Steven Rostedt (VMware) <rostedt@goodmis.org>
Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2020-01-09 10:19:02 +01:00

1125 lines
30 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* tracing_map - lock-free map for tracing
*
* Copyright (C) 2015 Tom Zanussi <tom.zanussi@linux.intel.com>
*
* tracing_map implementation inspired by lock-free map algorithms
* originated by Dr. Cliff Click:
*
* http://www.azulsystems.com/blog/cliff/2007-03-26-non-blocking-hashtable
* http://www.azulsystems.com/events/javaone_2007/2007_LockFreeHash.pdf
*/
#include <linux/vmalloc.h>
#include <linux/jhash.h>
#include <linux/slab.h>
#include <linux/sort.h>
#include "tracing_map.h"
#include "trace.h"
/*
* NOTE: For a detailed description of the data structures used by
* these functions (such as tracing_map_elt) please see the overview
* of tracing_map data structures at the beginning of tracing_map.h.
*/
/**
* tracing_map_update_sum - Add a value to a tracing_map_elt's sum field
* @elt: The tracing_map_elt
* @i: The index of the given sum associated with the tracing_map_elt
* @n: The value to add to the sum
*
* Add n to sum i associated with the specified tracing_map_elt
* instance. The index i is the index returned by the call to
* tracing_map_add_sum_field() when the tracing map was set up.
*/
void tracing_map_update_sum(struct tracing_map_elt *elt, unsigned int i, u64 n)
{
atomic64_add(n, &elt->fields[i].sum);
}
/**
* tracing_map_read_sum - Return the value of a tracing_map_elt's sum field
* @elt: The tracing_map_elt
* @i: The index of the given sum associated with the tracing_map_elt
*
* Retrieve the value of the sum i associated with the specified
* tracing_map_elt instance. The index i is the index returned by the
* call to tracing_map_add_sum_field() when the tracing map was set
* up.
*
* Return: The sum associated with field i for elt.
*/
u64 tracing_map_read_sum(struct tracing_map_elt *elt, unsigned int i)
{
return (u64)atomic64_read(&elt->fields[i].sum);
}
/**
* tracing_map_set_var - Assign a tracing_map_elt's variable field
* @elt: The tracing_map_elt
* @i: The index of the given variable associated with the tracing_map_elt
* @n: The value to assign
*
* Assign n to variable i associated with the specified tracing_map_elt
* instance. The index i is the index returned by the call to
* tracing_map_add_var() when the tracing map was set up.
*/
void tracing_map_set_var(struct tracing_map_elt *elt, unsigned int i, u64 n)
{
atomic64_set(&elt->vars[i], n);
elt->var_set[i] = true;
}
/**
* tracing_map_var_set - Return whether or not a variable has been set
* @elt: The tracing_map_elt
* @i: The index of the given variable associated with the tracing_map_elt
*
* Return true if the variable has been set, false otherwise. The
* index i is the index returned by the call to tracing_map_add_var()
* when the tracing map was set up.
*/
bool tracing_map_var_set(struct tracing_map_elt *elt, unsigned int i)
{
return elt->var_set[i];
}
/**
* tracing_map_read_var - Return the value of a tracing_map_elt's variable field
* @elt: The tracing_map_elt
* @i: The index of the given variable associated with the tracing_map_elt
*
* Retrieve the value of the variable i associated with the specified
* tracing_map_elt instance. The index i is the index returned by the
* call to tracing_map_add_var() when the tracing map was set
* up.
*
* Return: The variable value associated with field i for elt.
*/
u64 tracing_map_read_var(struct tracing_map_elt *elt, unsigned int i)
{
return (u64)atomic64_read(&elt->vars[i]);
}
/**
* tracing_map_read_var_once - Return and reset a tracing_map_elt's variable field
* @elt: The tracing_map_elt
* @i: The index of the given variable associated with the tracing_map_elt
*
* Retrieve the value of the variable i associated with the specified
* tracing_map_elt instance, and reset the variable to the 'not set'
* state. The index i is the index returned by the call to
* tracing_map_add_var() when the tracing map was set up. The reset
* essentially makes the variable a read-once variable if it's only
* accessed using this function.
*
* Return: The variable value associated with field i for elt.
*/
u64 tracing_map_read_var_once(struct tracing_map_elt *elt, unsigned int i)
{
elt->var_set[i] = false;
return (u64)atomic64_read(&elt->vars[i]);
}
int tracing_map_cmp_string(void *val_a, void *val_b)
{
char *a = val_a;
char *b = val_b;
return strcmp(a, b);
}
int tracing_map_cmp_none(void *val_a, void *val_b)
{
return 0;
}
static int tracing_map_cmp_atomic64(void *val_a, void *val_b)
{
u64 a = atomic64_read((atomic64_t *)val_a);
u64 b = atomic64_read((atomic64_t *)val_b);
return (a > b) ? 1 : ((a < b) ? -1 : 0);
}
#define DEFINE_TRACING_MAP_CMP_FN(type) \
static int tracing_map_cmp_##type(void *val_a, void *val_b) \
{ \
type a = (type)(*(u64 *)val_a); \
type b = (type)(*(u64 *)val_b); \
\
return (a > b) ? 1 : ((a < b) ? -1 : 0); \
}
DEFINE_TRACING_MAP_CMP_FN(s64);
DEFINE_TRACING_MAP_CMP_FN(u64);
DEFINE_TRACING_MAP_CMP_FN(s32);
DEFINE_TRACING_MAP_CMP_FN(u32);
DEFINE_TRACING_MAP_CMP_FN(s16);
DEFINE_TRACING_MAP_CMP_FN(u16);
DEFINE_TRACING_MAP_CMP_FN(s8);
DEFINE_TRACING_MAP_CMP_FN(u8);
tracing_map_cmp_fn_t tracing_map_cmp_num(int field_size,
int field_is_signed)
{
tracing_map_cmp_fn_t fn = tracing_map_cmp_none;
switch (field_size) {
case 8:
if (field_is_signed)
fn = tracing_map_cmp_s64;
else
fn = tracing_map_cmp_u64;
break;
case 4:
if (field_is_signed)
fn = tracing_map_cmp_s32;
else
fn = tracing_map_cmp_u32;
break;
case 2:
if (field_is_signed)
fn = tracing_map_cmp_s16;
else
fn = tracing_map_cmp_u16;
break;
case 1:
if (field_is_signed)
fn = tracing_map_cmp_s8;
else
fn = tracing_map_cmp_u8;
break;
}
return fn;
}
static int tracing_map_add_field(struct tracing_map *map,
tracing_map_cmp_fn_t cmp_fn)
{
int ret = -EINVAL;
if (map->n_fields < TRACING_MAP_FIELDS_MAX) {
ret = map->n_fields;
map->fields[map->n_fields++].cmp_fn = cmp_fn;
}
return ret;
}
/**
* tracing_map_add_sum_field - Add a field describing a tracing_map sum
* @map: The tracing_map
*
* Add a sum field to the key and return the index identifying it in
* the map and associated tracing_map_elts. This is the index used
* for instance to update a sum for a particular tracing_map_elt using
* tracing_map_update_sum() or reading it via tracing_map_read_sum().
*
* Return: The index identifying the field in the map and associated
* tracing_map_elts, or -EINVAL on error.
*/
int tracing_map_add_sum_field(struct tracing_map *map)
{
return tracing_map_add_field(map, tracing_map_cmp_atomic64);
}
/**
* tracing_map_add_var - Add a field describing a tracing_map var
* @map: The tracing_map
*
* Add a var to the map and return the index identifying it in the map
* and associated tracing_map_elts. This is the index used for
* instance to update a var for a particular tracing_map_elt using
* tracing_map_update_var() or reading it via tracing_map_read_var().
*
* Return: The index identifying the var in the map and associated
* tracing_map_elts, or -EINVAL on error.
*/
int tracing_map_add_var(struct tracing_map *map)
{
int ret = -EINVAL;
if (map->n_vars < TRACING_MAP_VARS_MAX)
ret = map->n_vars++;
return ret;
}
/**
* tracing_map_add_key_field - Add a field describing a tracing_map key
* @map: The tracing_map
* @offset: The offset within the key
* @cmp_fn: The comparison function that will be used to sort on the key
*
* Let the map know there is a key and that if it's used as a sort key
* to use cmp_fn.
*
* A key can be a subset of a compound key; for that purpose, the
* offset param is used to describe where within the the compound key
* the key referenced by this key field resides.
*
* Return: The index identifying the field in the map and associated
* tracing_map_elts, or -EINVAL on error.
*/
int tracing_map_add_key_field(struct tracing_map *map,
unsigned int offset,
tracing_map_cmp_fn_t cmp_fn)
{
int idx = tracing_map_add_field(map, cmp_fn);
if (idx < 0)
return idx;
map->fields[idx].offset = offset;
map->key_idx[map->n_keys++] = idx;
return idx;
}
void tracing_map_array_clear(struct tracing_map_array *a)
{
unsigned int i;
if (!a->pages)
return;
for (i = 0; i < a->n_pages; i++)
memset(a->pages[i], 0, PAGE_SIZE);
}
void tracing_map_array_free(struct tracing_map_array *a)
{
unsigned int i;
if (!a)
return;
if (!a->pages)
goto free;
for (i = 0; i < a->n_pages; i++) {
if (!a->pages[i])
break;
free_page((unsigned long)a->pages[i]);
}
kfree(a->pages);
free:
kfree(a);
}
struct tracing_map_array *tracing_map_array_alloc(unsigned int n_elts,
unsigned int entry_size)
{
struct tracing_map_array *a;
unsigned int i;
a = kzalloc(sizeof(*a), GFP_KERNEL);
if (!a)
return NULL;
a->entry_size_shift = fls(roundup_pow_of_two(entry_size) - 1);
a->entries_per_page = PAGE_SIZE / (1 << a->entry_size_shift);
a->n_pages = n_elts / a->entries_per_page;
if (!a->n_pages)
a->n_pages = 1;
a->entry_shift = fls(a->entries_per_page) - 1;
a->entry_mask = (1 << a->entry_shift) - 1;
a->pages = kcalloc(a->n_pages, sizeof(void *), GFP_KERNEL);
if (!a->pages)
goto free;
for (i = 0; i < a->n_pages; i++) {
a->pages[i] = (void *)get_zeroed_page(GFP_KERNEL);
if (!a->pages[i])
goto free;
}
out:
return a;
free:
tracing_map_array_free(a);
a = NULL;
goto out;
}
static void tracing_map_elt_clear(struct tracing_map_elt *elt)
{
unsigned i;
for (i = 0; i < elt->map->n_fields; i++)
if (elt->fields[i].cmp_fn == tracing_map_cmp_atomic64)
atomic64_set(&elt->fields[i].sum, 0);
for (i = 0; i < elt->map->n_vars; i++) {
atomic64_set(&elt->vars[i], 0);
elt->var_set[i] = false;
}
if (elt->map->ops && elt->map->ops->elt_clear)
elt->map->ops->elt_clear(elt);
}
static void tracing_map_elt_init_fields(struct tracing_map_elt *elt)
{
unsigned int i;
tracing_map_elt_clear(elt);
for (i = 0; i < elt->map->n_fields; i++) {
elt->fields[i].cmp_fn = elt->map->fields[i].cmp_fn;
if (elt->fields[i].cmp_fn != tracing_map_cmp_atomic64)
elt->fields[i].offset = elt->map->fields[i].offset;
}
}
static void tracing_map_elt_free(struct tracing_map_elt *elt)
{
if (!elt)
return;
if (elt->map->ops && elt->map->ops->elt_free)
elt->map->ops->elt_free(elt);
kfree(elt->fields);
kfree(elt->vars);
kfree(elt->var_set);
kfree(elt->key);
kfree(elt);
}
static struct tracing_map_elt *tracing_map_elt_alloc(struct tracing_map *map)
{
struct tracing_map_elt *elt;
int err = 0;
elt = kzalloc(sizeof(*elt), GFP_KERNEL);
if (!elt)
return ERR_PTR(-ENOMEM);
elt->map = map;
elt->key = kzalloc(map->key_size, GFP_KERNEL);
if (!elt->key) {
err = -ENOMEM;
goto free;
}
elt->fields = kcalloc(map->n_fields, sizeof(*elt->fields), GFP_KERNEL);
if (!elt->fields) {
err = -ENOMEM;
goto free;
}
elt->vars = kcalloc(map->n_vars, sizeof(*elt->vars), GFP_KERNEL);
if (!elt->vars) {
err = -ENOMEM;
goto free;
}
elt->var_set = kcalloc(map->n_vars, sizeof(*elt->var_set), GFP_KERNEL);
if (!elt->var_set) {
err = -ENOMEM;
goto free;
}
tracing_map_elt_init_fields(elt);
if (map->ops && map->ops->elt_alloc) {
err = map->ops->elt_alloc(elt);
if (err)
goto free;
}
return elt;
free:
tracing_map_elt_free(elt);
return ERR_PTR(err);
}
static struct tracing_map_elt *get_free_elt(struct tracing_map *map)
{
struct tracing_map_elt *elt = NULL;
int idx;
idx = atomic_inc_return(&map->next_elt);
if (idx < map->max_elts) {
elt = *(TRACING_MAP_ELT(map->elts, idx));
if (map->ops && map->ops->elt_init)
map->ops->elt_init(elt);
}
return elt;
}
static void tracing_map_free_elts(struct tracing_map *map)
{
unsigned int i;
if (!map->elts)
return;
for (i = 0; i < map->max_elts; i++) {
tracing_map_elt_free(*(TRACING_MAP_ELT(map->elts, i)));
*(TRACING_MAP_ELT(map->elts, i)) = NULL;
}
tracing_map_array_free(map->elts);
map->elts = NULL;
}
static int tracing_map_alloc_elts(struct tracing_map *map)
{
unsigned int i;
map->elts = tracing_map_array_alloc(map->max_elts,
sizeof(struct tracing_map_elt *));
if (!map->elts)
return -ENOMEM;
for (i = 0; i < map->max_elts; i++) {
*(TRACING_MAP_ELT(map->elts, i)) = tracing_map_elt_alloc(map);
if (IS_ERR(*(TRACING_MAP_ELT(map->elts, i)))) {
*(TRACING_MAP_ELT(map->elts, i)) = NULL;
tracing_map_free_elts(map);
return -ENOMEM;
}
}
return 0;
}
static inline bool keys_match(void *key, void *test_key, unsigned key_size)
{
bool match = true;
if (memcmp(key, test_key, key_size))
match = false;
return match;
}
static inline struct tracing_map_elt *
__tracing_map_insert(struct tracing_map *map, void *key, bool lookup_only)
{
u32 idx, key_hash, test_key;
int dup_try = 0;
struct tracing_map_entry *entry;
struct tracing_map_elt *val;
key_hash = jhash(key, map->key_size, 0);
if (key_hash == 0)
key_hash = 1;
idx = key_hash >> (32 - (map->map_bits + 1));
while (1) {
idx &= (map->map_size - 1);
entry = TRACING_MAP_ENTRY(map->map, idx);
test_key = entry->key;
if (test_key && test_key == key_hash) {
val = READ_ONCE(entry->val);
if (val &&
keys_match(key, val->key, map->key_size)) {
if (!lookup_only)
atomic64_inc(&map->hits);
return val;
} else if (unlikely(!val)) {
/*
* The key is present. But, val (pointer to elt
* struct) is still NULL. which means some other
* thread is in the process of inserting an
* element.
*
* On top of that, it's key_hash is same as the
* one being inserted right now. So, it's
* possible that the element has the same
* key as well.
*/
dup_try++;
if (dup_try > map->map_size) {
atomic64_inc(&map->drops);
break;
}
continue;
}
}
if (!test_key) {
if (lookup_only)
break;
if (!cmpxchg(&entry->key, 0, key_hash)) {
struct tracing_map_elt *elt;
elt = get_free_elt(map);
if (!elt) {
atomic64_inc(&map->drops);
entry->key = 0;
break;
}
memcpy(elt->key, key, map->key_size);
entry->val = elt;
atomic64_inc(&map->hits);
return entry->val;
} else {
/*
* cmpxchg() failed. Loop around once
* more to check what key was inserted.
*/
dup_try++;
continue;
}
}
idx++;
}
return NULL;
}
/**
* tracing_map_insert - Insert key and/or retrieve val from a tracing_map
* @map: The tracing_map to insert into
* @key: The key to insert
*
* Inserts a key into a tracing_map and creates and returns a new
* tracing_map_elt for it, or if the key has already been inserted by
* a previous call, returns the tracing_map_elt already associated
* with it. When the map was created, the number of elements to be
* allocated for the map was specified (internally maintained as
* 'max_elts' in struct tracing_map), and that number of
* tracing_map_elts was created by tracing_map_init(). This is the
* pre-allocated pool of tracing_map_elts that tracing_map_insert()
* will allocate from when adding new keys. Once that pool is
* exhausted, tracing_map_insert() is useless and will return NULL to
* signal that state. There are two user-visible tracing_map
* variables, 'hits' and 'drops', which are updated by this function.
* Every time an element is either successfully inserted or retrieved,
* the 'hits' value is incrememented. Every time an element insertion
* fails, the 'drops' value is incremented.
*
* This is a lock-free tracing map insertion function implementing a
* modified form of Cliff Click's basic insertion algorithm. It
* requires the table size be a power of two. To prevent any
* possibility of an infinite loop we always make the internal table
* size double the size of the requested table size (max_elts * 2).
* Likewise, we never reuse a slot or resize or delete elements - when
* we've reached max_elts entries, we simply return NULL once we've
* run out of entries. Readers can at any point in time traverse the
* tracing map and safely access the key/val pairs.
*
* Return: the tracing_map_elt pointer val associated with the key.
* If this was a newly inserted key, the val will be a newly allocated
* and associated tracing_map_elt pointer val. If the key wasn't
* found and the pool of tracing_map_elts has been exhausted, NULL is
* returned and no further insertions will succeed.
*/
struct tracing_map_elt *tracing_map_insert(struct tracing_map *map, void *key)
{
return __tracing_map_insert(map, key, false);
}
/**
* tracing_map_lookup - Retrieve val from a tracing_map
* @map: The tracing_map to perform the lookup on
* @key: The key to look up
*
* Looks up key in tracing_map and if found returns the matching
* tracing_map_elt. This is a lock-free lookup; see
* tracing_map_insert() for details on tracing_map and how it works.
* Every time an element is retrieved, the 'hits' value is
* incrememented. There is one user-visible tracing_map variable,
* 'hits', which is updated by this function. Every time an element
* is successfully retrieved, the 'hits' value is incrememented. The
* 'drops' value is never updated by this function.
*
* Return: the tracing_map_elt pointer val associated with the key.
* If the key wasn't found, NULL is returned.
*/
struct tracing_map_elt *tracing_map_lookup(struct tracing_map *map, void *key)
{
return __tracing_map_insert(map, key, true);
}
/**
* tracing_map_destroy - Destroy a tracing_map
* @map: The tracing_map to destroy
*
* Frees a tracing_map along with its associated array of
* tracing_map_elts.
*
* Callers should make sure there are no readers or writers actively
* reading or inserting into the map before calling this.
*/
void tracing_map_destroy(struct tracing_map *map)
{
if (!map)
return;
tracing_map_free_elts(map);
tracing_map_array_free(map->map);
kfree(map);
}
/**
* tracing_map_clear - Clear a tracing_map
* @map: The tracing_map to clear
*
* Resets the tracing map to a cleared or initial state. The
* tracing_map_elts are all cleared, and the array of struct
* tracing_map_entry is reset to an initialized state.
*
* Callers should make sure there are no writers actively inserting
* into the map before calling this.
*/
void tracing_map_clear(struct tracing_map *map)
{
unsigned int i;
atomic_set(&map->next_elt, -1);
atomic64_set(&map->hits, 0);
atomic64_set(&map->drops, 0);
tracing_map_array_clear(map->map);
for (i = 0; i < map->max_elts; i++)
tracing_map_elt_clear(*(TRACING_MAP_ELT(map->elts, i)));
}
static void set_sort_key(struct tracing_map *map,
struct tracing_map_sort_key *sort_key)
{
map->sort_key = *sort_key;
}
/**
* tracing_map_create - Create a lock-free map and element pool
* @map_bits: The size of the map (2 ** map_bits)
* @key_size: The size of the key for the map in bytes
* @ops: Optional client-defined tracing_map_ops instance
* @private_data: Client data associated with the map
*
* Creates and sets up a map to contain 2 ** map_bits number of
* elements (internally maintained as 'max_elts' in struct
* tracing_map). Before using, map fields should be added to the map
* with tracing_map_add_sum_field() and tracing_map_add_key_field().
* tracing_map_init() should then be called to allocate the array of
* tracing_map_elts, in order to avoid allocating anything in the map
* insertion path. The user-specified map size reflects the maximum
* number of elements that can be contained in the table requested by
* the user - internally we double that in order to keep the table
* sparse and keep collisions manageable.
*
* A tracing_map is a special-purpose map designed to aggregate or
* 'sum' one or more values associated with a specific object of type
* tracing_map_elt, which is attached by the map to a given key.
*
* tracing_map_create() sets up the map itself, and provides
* operations for inserting tracing_map_elts, but doesn't allocate the
* tracing_map_elts themselves, or provide a means for describing the
* keys or sums associated with the tracing_map_elts. All
* tracing_map_elts for a given map have the same set of sums and
* keys, which are defined by the client using the functions
* tracing_map_add_key_field() and tracing_map_add_sum_field(). Once
* the fields are defined, the pool of elements allocated for the map
* can be created, which occurs when the client code calls
* tracing_map_init().
*
* When tracing_map_init() returns, tracing_map_elt elements can be
* inserted into the map using tracing_map_insert(). When called,
* tracing_map_insert() grabs a free tracing_map_elt from the pool, or
* finds an existing match in the map and in either case returns it.
* The client can then use tracing_map_update_sum() and
* tracing_map_read_sum() to update or read a given sum field for the
* tracing_map_elt.
*
* The client can at any point retrieve and traverse the current set
* of inserted tracing_map_elts in a tracing_map, via
* tracing_map_sort_entries(). Sorting can be done on any field,
* including keys.
*
* See tracing_map.h for a description of tracing_map_ops.
*
* Return: the tracing_map pointer if successful, ERR_PTR if not.
*/
struct tracing_map *tracing_map_create(unsigned int map_bits,
unsigned int key_size,
const struct tracing_map_ops *ops,
void *private_data)
{
struct tracing_map *map;
unsigned int i;
if (map_bits < TRACING_MAP_BITS_MIN ||
map_bits > TRACING_MAP_BITS_MAX)
return ERR_PTR(-EINVAL);
map = kzalloc(sizeof(*map), GFP_KERNEL);
if (!map)
return ERR_PTR(-ENOMEM);
map->map_bits = map_bits;
map->max_elts = (1 << map_bits);
atomic_set(&map->next_elt, -1);
map->map_size = (1 << (map_bits + 1));
map->ops = ops;
map->private_data = private_data;
map->map = tracing_map_array_alloc(map->map_size,
sizeof(struct tracing_map_entry));
if (!map->map)
goto free;
map->key_size = key_size;
for (i = 0; i < TRACING_MAP_KEYS_MAX; i++)
map->key_idx[i] = -1;
out:
return map;
free:
tracing_map_destroy(map);
map = ERR_PTR(-ENOMEM);
goto out;
}
/**
* tracing_map_init - Allocate and clear a map's tracing_map_elts
* @map: The tracing_map to initialize
*
* Allocates a clears a pool of tracing_map_elts equal to the
* user-specified size of 2 ** map_bits (internally maintained as
* 'max_elts' in struct tracing_map). Before using, the map fields
* should be added to the map with tracing_map_add_sum_field() and
* tracing_map_add_key_field(). tracing_map_init() should then be
* called to allocate the array of tracing_map_elts, in order to avoid
* allocating anything in the map insertion path. The user-specified
* map size reflects the max number of elements requested by the user
* - internally we double that in order to keep the table sparse and
* keep collisions manageable.
*
* See tracing_map.h for a description of tracing_map_ops.
*
* Return: the tracing_map pointer if successful, ERR_PTR if not.
*/
int tracing_map_init(struct tracing_map *map)
{
int err;
if (map->n_fields < 2)
return -EINVAL; /* need at least 1 key and 1 val */
err = tracing_map_alloc_elts(map);
if (err)
return err;
tracing_map_clear(map);
return err;
}
static int cmp_entries_dup(const struct tracing_map_sort_entry **a,
const struct tracing_map_sort_entry **b)
{
int ret = 0;
if (memcmp((*a)->key, (*b)->key, (*a)->elt->map->key_size))
ret = 1;
return ret;
}
static int cmp_entries_sum(const struct tracing_map_sort_entry **a,
const struct tracing_map_sort_entry **b)
{
const struct tracing_map_elt *elt_a, *elt_b;
struct tracing_map_sort_key *sort_key;
struct tracing_map_field *field;
tracing_map_cmp_fn_t cmp_fn;
void *val_a, *val_b;
int ret = 0;
elt_a = (*a)->elt;
elt_b = (*b)->elt;
sort_key = &elt_a->map->sort_key;
field = &elt_a->fields[sort_key->field_idx];
cmp_fn = field->cmp_fn;
val_a = &elt_a->fields[sort_key->field_idx].sum;
val_b = &elt_b->fields[sort_key->field_idx].sum;
ret = cmp_fn(val_a, val_b);
if (sort_key->descending)
ret = -ret;
return ret;
}
static int cmp_entries_key(const struct tracing_map_sort_entry **a,
const struct tracing_map_sort_entry **b)
{
const struct tracing_map_elt *elt_a, *elt_b;
struct tracing_map_sort_key *sort_key;
struct tracing_map_field *field;
tracing_map_cmp_fn_t cmp_fn;
void *val_a, *val_b;
int ret = 0;
elt_a = (*a)->elt;
elt_b = (*b)->elt;
sort_key = &elt_a->map->sort_key;
field = &elt_a->fields[sort_key->field_idx];
cmp_fn = field->cmp_fn;
val_a = elt_a->key + field->offset;
val_b = elt_b->key + field->offset;
ret = cmp_fn(val_a, val_b);
if (sort_key->descending)
ret = -ret;
return ret;
}
static void destroy_sort_entry(struct tracing_map_sort_entry *entry)
{
if (!entry)
return;
if (entry->elt_copied)
tracing_map_elt_free(entry->elt);
kfree(entry);
}
/**
* tracing_map_destroy_sort_entries - Destroy an array of sort entries
* @entries: The entries to destroy
* @n_entries: The number of entries in the array
*
* Destroy the elements returned by a tracing_map_sort_entries() call.
*/
void tracing_map_destroy_sort_entries(struct tracing_map_sort_entry **entries,
unsigned int n_entries)
{
unsigned int i;
for (i = 0; i < n_entries; i++)
destroy_sort_entry(entries[i]);
vfree(entries);
}
static struct tracing_map_sort_entry *
create_sort_entry(void *key, struct tracing_map_elt *elt)
{
struct tracing_map_sort_entry *sort_entry;
sort_entry = kzalloc(sizeof(*sort_entry), GFP_KERNEL);
if (!sort_entry)
return NULL;
sort_entry->key = key;
sort_entry->elt = elt;
return sort_entry;
}
static void detect_dups(struct tracing_map_sort_entry **sort_entries,
int n_entries, unsigned int key_size)
{
unsigned int dups = 0, total_dups = 0;
int i;
void *key;
if (n_entries < 2)
return;
sort(sort_entries, n_entries, sizeof(struct tracing_map_sort_entry *),
(int (*)(const void *, const void *))cmp_entries_dup, NULL);
key = sort_entries[0]->key;
for (i = 1; i < n_entries; i++) {
if (!memcmp(sort_entries[i]->key, key, key_size)) {
dups++; total_dups++;
continue;
}
key = sort_entries[i]->key;
dups = 0;
}
WARN_ONCE(total_dups > 0,
"Duplicates detected: %d\n", total_dups);
}
static bool is_key(struct tracing_map *map, unsigned int field_idx)
{
unsigned int i;
for (i = 0; i < map->n_keys; i++)
if (map->key_idx[i] == field_idx)
return true;
return false;
}
static void sort_secondary(struct tracing_map *map,
const struct tracing_map_sort_entry **entries,
unsigned int n_entries,
struct tracing_map_sort_key *primary_key,
struct tracing_map_sort_key *secondary_key)
{
int (*primary_fn)(const struct tracing_map_sort_entry **,
const struct tracing_map_sort_entry **);
int (*secondary_fn)(const struct tracing_map_sort_entry **,
const struct tracing_map_sort_entry **);
unsigned i, start = 0, n_sub = 1;
if (is_key(map, primary_key->field_idx))
primary_fn = cmp_entries_key;
else
primary_fn = cmp_entries_sum;
if (is_key(map, secondary_key->field_idx))
secondary_fn = cmp_entries_key;
else
secondary_fn = cmp_entries_sum;
for (i = 0; i < n_entries - 1; i++) {
const struct tracing_map_sort_entry **a = &entries[i];
const struct tracing_map_sort_entry **b = &entries[i + 1];
if (primary_fn(a, b) == 0) {
n_sub++;
if (i < n_entries - 2)
continue;
}
if (n_sub < 2) {
start = i + 1;
n_sub = 1;
continue;
}
set_sort_key(map, secondary_key);
sort(&entries[start], n_sub,
sizeof(struct tracing_map_sort_entry *),
(int (*)(const void *, const void *))secondary_fn, NULL);
set_sort_key(map, primary_key);
start = i + 1;
n_sub = 1;
}
}
/**
* tracing_map_sort_entries - Sort the current set of tracing_map_elts in a map
* @map: The tracing_map
* @sort_key: The sort key to use for sorting
* @sort_entries: outval: pointer to allocated and sorted array of entries
*
* tracing_map_sort_entries() sorts the current set of entries in the
* map and returns the list of tracing_map_sort_entries containing
* them to the client in the sort_entries param. The client can
* access the struct tracing_map_elt element of interest directly as
* the 'elt' field of a returned struct tracing_map_sort_entry object.
*
* The sort_key has only two fields: idx and descending. 'idx' refers
* to the index of the field added via tracing_map_add_sum_field() or
* tracing_map_add_key_field() when the tracing_map was initialized.
* 'descending' is a flag that if set reverses the sort order, which
* by default is ascending.
*
* The client should not hold on to the returned array but should use
* it and call tracing_map_destroy_sort_entries() when done.
*
* Return: the number of sort_entries in the struct tracing_map_sort_entry
* array, negative on error
*/
int tracing_map_sort_entries(struct tracing_map *map,
struct tracing_map_sort_key *sort_keys,
unsigned int n_sort_keys,
struct tracing_map_sort_entry ***sort_entries)
{
int (*cmp_entries_fn)(const struct tracing_map_sort_entry **,
const struct tracing_map_sort_entry **);
struct tracing_map_sort_entry *sort_entry, **entries;
int i, n_entries, ret;
entries = vmalloc(array_size(sizeof(sort_entry), map->max_elts));
if (!entries)
return -ENOMEM;
for (i = 0, n_entries = 0; i < map->map_size; i++) {
struct tracing_map_entry *entry;
entry = TRACING_MAP_ENTRY(map->map, i);
if (!entry->key || !entry->val)
continue;
entries[n_entries] = create_sort_entry(entry->val->key,
entry->val);
if (!entries[n_entries++]) {
ret = -ENOMEM;
goto free;
}
}
if (n_entries == 0) {
ret = 0;
goto free;
}
if (n_entries == 1) {
*sort_entries = entries;
return 1;
}
detect_dups(entries, n_entries, map->key_size);
if (is_key(map, sort_keys[0].field_idx))
cmp_entries_fn = cmp_entries_key;
else
cmp_entries_fn = cmp_entries_sum;
set_sort_key(map, &sort_keys[0]);
sort(entries, n_entries, sizeof(struct tracing_map_sort_entry *),
(int (*)(const void *, const void *))cmp_entries_fn, NULL);
if (n_sort_keys > 1)
sort_secondary(map,
(const struct tracing_map_sort_entry **)entries,
n_entries,
&sort_keys[0],
&sort_keys[1]);
*sort_entries = entries;
return n_entries;
free:
tracing_map_destroy_sort_entries(entries, n_entries);
return ret;
}