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|
// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
// vim: ts=8 sw=2 smarttab
#ifndef CEPH_CRUSH_WRAPPER_H
#define CEPH_CRUSH_WRAPPER_H
#include <stdlib.h>
#include <map>
#include <set>
#include <string>
#include <iosfwd>
#include "include/types.h"
extern "C" {
#include "crush.h"
#include "hash.h"
#include "mapper.h"
#include "builder.h"
}
#include "include/ceph_assert.h"
#include "include/err.h"
#include "include/encoding.h"
#include "include/mempool.h"
namespace ceph {
class Formatter;
}
namespace CrushTreeDumper {
typedef mempool::osdmap::map<int64_t,std::string> name_map_t;
}
WRITE_RAW_ENCODER(crush_rule_mask) // it's all u8's
inline void encode(const crush_rule_step &s, ceph::buffer::list &bl)
{
using ceph::encode;
encode(s.op, bl);
encode(s.arg1, bl);
encode(s.arg2, bl);
}
inline void decode(crush_rule_step &s, ceph::buffer::list::const_iterator &p)
{
using ceph::decode;
decode(s.op, p);
decode(s.arg1, p);
decode(s.arg2, p);
}
class CrushWrapper {
public:
// magic value used by OSDMap for a "default" fallback choose_args, used if
// the choose_arg_map passed to do_rule does not exist. if this also
// doesn't exist, fall back to canonical weights.
enum {
DEFAULT_CHOOSE_ARGS = -1
};
std::map<int32_t, std::string> type_map; // item(bucket/device) type id ==> item type name
std::map<int32_t, std::string> name_map; // item id ==> item name
std::map<int32_t, std::string> rule_name_map;
std::map<int32_t, int32_t> class_map; /* item id -> class id */
std::map<int32_t, std::string> class_name; /* class id -> class name */
std::map<std::string, int32_t> class_rname; /* class name -> class id */
std::map<int32_t, std::map<int32_t, int32_t> > class_bucket; /* bucket[id][class] == id */
std::map<int64_t, crush_choose_arg_map> choose_args;
private:
struct crush_map *crush = nullptr;
bool have_uniform_rules = false;
/* reverse maps */
mutable bool have_rmaps = false;
mutable std::map<std::string, int> type_rmap, name_rmap, rule_name_rmap;
void build_rmaps() const {
if (have_rmaps) return;
build_rmap(type_map, type_rmap);
build_rmap(name_map, name_rmap);
build_rmap(rule_name_map, rule_name_rmap);
have_rmaps = true;
}
void build_rmap(const std::map<int, std::string> &f, std::map<std::string, int> &r) const {
r.clear();
for (auto p = f.begin(); p != f.end(); ++p)
r[p->second] = p->first;
}
public:
CrushWrapper(const CrushWrapper& other);
const CrushWrapper& operator=(const CrushWrapper& other);
CrushWrapper() {
create();
}
~CrushWrapper() {
if (crush)
crush_destroy(crush);
choose_args_clear();
}
crush_map *get_crush_map() { return crush; }
/* building */
void create() {
if (crush)
crush_destroy(crush);
crush = crush_create();
choose_args_clear();
ceph_assert(crush);
have_rmaps = false;
set_tunables_default();
}
/**
* true if any rule has a rule id != its position in the array
*
* These indicate "ruleset" IDs that were created by older versions
* of Ceph. They are cleaned up in renumber_rules so that eventually
* we can remove the code for handling them.
*/
bool has_legacy_rule_ids() const;
/**
* fix rules whose ruleid != ruleset
*
* These rules were created in older versions of Ceph. The concept
* of a ruleset no longer exists.
*
* Return a map of old ID -> new ID. Caller must update OSDMap
* to use new IDs.
*/
std::map<int, int> renumber_rules();
/// true if any buckets that aren't straw2
bool has_non_straw2_buckets() const;
// tunables
void set_tunables_argonaut() {
crush->choose_local_tries = 2;
crush->choose_local_fallback_tries = 5;
crush->choose_total_tries = 19;
crush->chooseleaf_descend_once = 0;
crush->chooseleaf_vary_r = 0;
crush->chooseleaf_stable = 0;
crush->allowed_bucket_algs = CRUSH_LEGACY_ALLOWED_BUCKET_ALGS;
}
void set_tunables_bobtail() {
crush->choose_local_tries = 0;
crush->choose_local_fallback_tries = 0;
crush->choose_total_tries = 50;
crush->chooseleaf_descend_once = 1;
crush->chooseleaf_vary_r = 0;
crush->chooseleaf_stable = 0;
crush->allowed_bucket_algs = CRUSH_LEGACY_ALLOWED_BUCKET_ALGS;
}
void set_tunables_firefly() {
crush->choose_local_tries = 0;
crush->choose_local_fallback_tries = 0;
crush->choose_total_tries = 50;
crush->chooseleaf_descend_once = 1;
crush->chooseleaf_vary_r = 1;
crush->chooseleaf_stable = 0;
crush->allowed_bucket_algs = CRUSH_LEGACY_ALLOWED_BUCKET_ALGS;
}
void set_tunables_hammer() {
crush->choose_local_tries = 0;
crush->choose_local_fallback_tries = 0;
crush->choose_total_tries = 50;
crush->chooseleaf_descend_once = 1;
crush->chooseleaf_vary_r = 1;
crush->chooseleaf_stable = 0;
crush->allowed_bucket_algs =
(1 << CRUSH_BUCKET_UNIFORM) |
(1 << CRUSH_BUCKET_LIST) |
(1 << CRUSH_BUCKET_STRAW) |
(1 << CRUSH_BUCKET_STRAW2);
}
void set_tunables_jewel() {
crush->choose_local_tries = 0;
crush->choose_local_fallback_tries = 0;
crush->choose_total_tries = 50;
crush->chooseleaf_descend_once = 1;
crush->chooseleaf_vary_r = 1;
crush->chooseleaf_stable = 1;
crush->allowed_bucket_algs =
(1 << CRUSH_BUCKET_UNIFORM) |
(1 << CRUSH_BUCKET_LIST) |
(1 << CRUSH_BUCKET_STRAW) |
(1 << CRUSH_BUCKET_STRAW2);
}
void set_tunables_legacy() {
set_tunables_argonaut();
crush->straw_calc_version = 0;
}
void set_tunables_optimal() {
set_tunables_jewel();
crush->straw_calc_version = 1;
}
void set_tunables_default() {
set_tunables_jewel();
crush->straw_calc_version = 1;
}
int get_choose_local_tries() const {
return crush->choose_local_tries;
}
void set_choose_local_tries(int n) {
crush->choose_local_tries = n;
}
int get_choose_local_fallback_tries() const {
return crush->choose_local_fallback_tries;
}
void set_choose_local_fallback_tries(int n) {
crush->choose_local_fallback_tries = n;
}
int get_choose_total_tries() const {
return crush->choose_total_tries;
}
void set_choose_total_tries(int n) {
crush->choose_total_tries = n;
}
int get_chooseleaf_descend_once() const {
return crush->chooseleaf_descend_once;
}
void set_chooseleaf_descend_once(int n) {
crush->chooseleaf_descend_once = !!n;
}
int get_chooseleaf_vary_r() const {
return crush->chooseleaf_vary_r;
}
void set_chooseleaf_vary_r(int n) {
crush->chooseleaf_vary_r = n;
}
int get_chooseleaf_stable() const {
return crush->chooseleaf_stable;
}
void set_chooseleaf_stable(int n) {
crush->chooseleaf_stable = n;
}
int get_straw_calc_version() const {
return crush->straw_calc_version;
}
void set_straw_calc_version(int n) {
crush->straw_calc_version = n;
}
unsigned get_allowed_bucket_algs() const {
return crush->allowed_bucket_algs;
}
void set_allowed_bucket_algs(unsigned n) {
crush->allowed_bucket_algs = n;
}
bool has_argonaut_tunables() const {
return
crush->choose_local_tries == 2 &&
crush->choose_local_fallback_tries == 5 &&
crush->choose_total_tries == 19 &&
crush->chooseleaf_descend_once == 0 &&
crush->chooseleaf_vary_r == 0 &&
crush->chooseleaf_stable == 0 &&
crush->allowed_bucket_algs == CRUSH_LEGACY_ALLOWED_BUCKET_ALGS;
}
bool has_bobtail_tunables() const {
return
crush->choose_local_tries == 0 &&
crush->choose_local_fallback_tries == 0 &&
crush->choose_total_tries == 50 &&
crush->chooseleaf_descend_once == 1 &&
crush->chooseleaf_vary_r == 0 &&
crush->chooseleaf_stable == 0 &&
crush->allowed_bucket_algs == CRUSH_LEGACY_ALLOWED_BUCKET_ALGS;
}
bool has_firefly_tunables() const {
return
crush->choose_local_tries == 0 &&
crush->choose_local_fallback_tries == 0 &&
crush->choose_total_tries == 50 &&
crush->chooseleaf_descend_once == 1 &&
crush->chooseleaf_vary_r == 1 &&
crush->chooseleaf_stable == 0 &&
crush->allowed_bucket_algs == CRUSH_LEGACY_ALLOWED_BUCKET_ALGS;
}
bool has_hammer_tunables() const {
return
crush->choose_local_tries == 0 &&
crush->choose_local_fallback_tries == 0 &&
crush->choose_total_tries == 50 &&
crush->chooseleaf_descend_once == 1 &&
crush->chooseleaf_vary_r == 1 &&
crush->chooseleaf_stable == 0 &&
crush->allowed_bucket_algs == ((1 << CRUSH_BUCKET_UNIFORM) |
(1 << CRUSH_BUCKET_LIST) |
(1 << CRUSH_BUCKET_STRAW) |
(1 << CRUSH_BUCKET_STRAW2));
}
bool has_jewel_tunables() const {
return
crush->choose_local_tries == 0 &&
crush->choose_local_fallback_tries == 0 &&
crush->choose_total_tries == 50 &&
crush->chooseleaf_descend_once == 1 &&
crush->chooseleaf_vary_r == 1 &&
crush->chooseleaf_stable == 1 &&
crush->allowed_bucket_algs == ((1 << CRUSH_BUCKET_UNIFORM) |
(1 << CRUSH_BUCKET_LIST) |
(1 << CRUSH_BUCKET_STRAW) |
(1 << CRUSH_BUCKET_STRAW2));
}
bool has_optimal_tunables() const {
return has_jewel_tunables();
}
bool has_legacy_tunables() const {
return has_argonaut_tunables();
}
bool has_nondefault_tunables() const {
return
(crush->choose_local_tries != 2 ||
crush->choose_local_fallback_tries != 5 ||
crush->choose_total_tries != 19);
}
bool has_nondefault_tunables2() const {
return
crush->chooseleaf_descend_once != 0;
}
bool has_nondefault_tunables3() const {
return
crush->chooseleaf_vary_r != 0;
}
bool has_nondefault_tunables5() const {
return
crush->chooseleaf_stable != 0;
}
bool has_v2_rules() const;
bool has_v3_rules() const;
bool has_v4_buckets() const;
bool has_v5_rules() const;
bool has_choose_args() const; // any choose_args
bool has_incompat_choose_args() const; // choose_args that can't be made compat
bool is_v2_rule(unsigned ruleid) const;
bool is_v3_rule(unsigned ruleid) const;
bool is_v5_rule(unsigned ruleid) const;
std::string get_min_required_version() const {
if (has_v5_rules() || has_nondefault_tunables5())
return "jewel";
else if (has_v4_buckets())
return "hammer";
else if (has_nondefault_tunables3())
return "firefly";
else if (has_nondefault_tunables2() || has_nondefault_tunables())
return "bobtail";
else
return "argonaut";
}
// default bucket types
unsigned get_default_bucket_alg() const {
// in order of preference
if (crush->allowed_bucket_algs & (1 << CRUSH_BUCKET_STRAW2))
return CRUSH_BUCKET_STRAW2;
if (crush->allowed_bucket_algs & (1 << CRUSH_BUCKET_STRAW))
return CRUSH_BUCKET_STRAW;
if (crush->allowed_bucket_algs & (1 << CRUSH_BUCKET_TREE))
return CRUSH_BUCKET_TREE;
if (crush->allowed_bucket_algs & (1 << CRUSH_BUCKET_LIST))
return CRUSH_BUCKET_LIST;
if (crush->allowed_bucket_algs & (1 << CRUSH_BUCKET_UNIFORM))
return CRUSH_BUCKET_UNIFORM;
return 0;
}
// bucket types
int get_num_type_names() const {
return type_map.size();
}
int get_max_type_id() const {
if (type_map.empty())
return 0;
return type_map.rbegin()->first;
}
int get_type_id(const std::string& name) const {
build_rmaps();
if (type_rmap.count(name))
return type_rmap[name];
return -1;
}
int get_validated_type_id(const std::string& name, int *id) const {
int retval = get_type_id(name);
if (retval == -1 && !type_rmap.count(name)) {
return -1;
}
*id = retval;
return 0;
}
const char *get_type_name(int t) const {
auto p = type_map.find(t);
if (p != type_map.end())
return p->second.c_str();
return 0;
}
void set_type_name(int i, const std::string& name) {
type_map[i] = name;
if (have_rmaps)
type_rmap[name] = i;
}
// item/bucket names
bool name_exists(const std::string& name) const {
build_rmaps();
return name_rmap.count(name);
}
bool item_exists(int i) const {
return name_map.count(i);
}
int get_item_id(const std::string& name) const {
build_rmaps();
if (name_rmap.count(name))
return name_rmap[name];
return 0; /* hrm */
}
const char *get_item_name(int t) const {
std::map<int,std::string>::const_iterator p = name_map.find(t);
if (p != name_map.end())
return p->second.c_str();
return 0;
}
int set_item_name(int i, const std::string& name) {
if (!is_valid_crush_name(name))
return -EINVAL;
name_map[i] = name;
if (have_rmaps)
name_rmap[name] = i;
return 0;
}
void swap_names(int a, int b) {
std::string an = name_map[a];
std::string bn = name_map[b];
name_map[a] = bn;
name_map[b] = an;
if (have_rmaps) {
name_rmap[an] = b;
name_rmap[bn] = a;
}
}
int split_id_class(int i, int *idout, int *classout) const;
bool class_exists(const std::string& name) const {
return class_rname.count(name);
}
const char *get_class_name(int i) const {
auto p = class_name.find(i);
if (p != class_name.end())
return p->second.c_str();
return 0;
}
int get_class_id(const std::string& name) const {
auto p = class_rname.find(name);
if (p != class_rname.end())
return p->second;
else
return -EINVAL;
}
int remove_class_name(const std::string& name) {
auto p = class_rname.find(name);
if (p == class_rname.end())
return -ENOENT;
int class_id = p->second;
auto q = class_name.find(class_id);
if (q == class_name.end())
return -ENOENT;
class_rname.erase(name);
class_name.erase(class_id);
return 0;
}
int32_t _alloc_class_id() const;
int get_or_create_class_id(const std::string& name) {
int c = get_class_id(name);
if (c < 0) {
int i = _alloc_class_id();
class_name[i] = name;
class_rname[name] = i;
return i;
} else {
return c;
}
}
const char *get_item_class(int t) const {
std::map<int,int>::const_iterator p = class_map.find(t);
if (p == class_map.end())
return 0;
return get_class_name(p->second);
}
int get_item_class_id(int t) const {
auto p = class_map.find(t);
if (p == class_map.end())
return -ENOENT;
return p->second;
}
int set_item_class(int i, const std::string& name) {
if (!is_valid_crush_name(name))
return -EINVAL;
class_map[i] = get_or_create_class_id(name);
return 0;
}
int set_item_class(int i, int c) {
class_map[i] = c;
return c;
}
void get_devices_by_class(const std::string &name,
std::set<int> *devices) const {
ceph_assert(devices);
devices->clear();
if (!class_exists(name)) {
return;
}
auto cid = get_class_id(name);
for (auto& p : class_map) {
if (p.first >= 0 && p.second == cid) {
devices->insert(p.first);
}
}
}
void class_remove_item(int i) {
auto it = class_map.find(i);
if (it == class_map.end()) {
return;
}
class_map.erase(it);
}
int can_rename_item(const std::string& srcname,
const std::string& dstname,
std::ostream *ss) const;
int rename_item(const std::string& srcname,
const std::string& dstname,
std::ostream *ss);
int can_rename_bucket(const std::string& srcname,
const std::string& dstname,
std::ostream *ss) const;
int rename_bucket(const std::string& srcname,
const std::string& dstname,
std::ostream *ss);
// rule names
int rename_rule(const std::string& srcname,
const std::string& dstname,
std::ostream *ss);
bool rule_exists(std::string name) const {
build_rmaps();
return rule_name_rmap.count(name);
}
int get_rule_id(std::string name) const {
build_rmaps();
if (rule_name_rmap.count(name))
return rule_name_rmap[name];
return -ENOENT;
}
const char *get_rule_name(int t) const {
auto p = rule_name_map.find(t);
if (p != rule_name_map.end())
return p->second.c_str();
return 0;
}
void set_rule_name(int i, const std::string& name) {
rule_name_map[i] = name;
if (have_rmaps)
rule_name_rmap[name] = i;
}
bool is_shadow_item(int id) const {
const char *name = get_item_name(id);
return name && !is_valid_crush_name(name);
}
/**
* find tree nodes referenced by rules by a 'take' command
*
* Note that these may not be parentless roots.
*/
void find_takes(std::set<int> *roots) const;
void find_takes_by_rule(int rule, std::set<int> *roots) const;
/**
* find tree roots
*
* These are parentless nodes in the map.
*/
void find_roots(std::set<int> *roots) const;
/**
* find tree roots that contain shadow (device class) items only
*/
void find_shadow_roots(std::set<int> *roots) const {
std::set<int> all;
find_roots(&all);
for (auto& p: all) {
if (is_shadow_item(p)) {
roots->insert(p);
}
}
}
/**
* find tree roots that are not shadow (device class) items
*
* These are parentless nodes in the map that are not shadow
* items for device classes.
*/
void find_nonshadow_roots(std::set<int> *roots) const {
std::set<int> all;
find_roots(&all);
for (auto& p: all) {
if (!is_shadow_item(p)) {
roots->insert(p);
}
}
}
/**
* see if an item is contained within a subtree
*
* @param root haystack
* @param item needle
* @return true if the item is located beneath the given node
*/
bool subtree_contains(int root, int item) const;
private:
/**
* search for an item in any bucket
*
* @param i item
* @return true if present
*/
bool _search_item_exists(int i) const;
bool is_parent_of(int child, int p) const;
public:
/**
* see if item is located where we think it is
*
* This verifies that the given item is located at a particular
* location in the hierarchy. However, that check is imprecise; we
* are actually verifying that the most specific location key/value
* is correct. For example, if loc specifies that rack=foo and
* host=bar, it will verify that host=bar is correct; any placement
* above that level in the hierarchy is ignored. This matches the
* semantics for insert_item().
*
* @param cct cct
* @param item item id
* @param loc location to check (map of type to bucket names)
* @param weight optional pointer to weight of item at that location
* @return true if item is at specified location
*/
bool check_item_loc(CephContext *cct, int item,
const std::map<std::string,std::string>& loc,
int *iweight);
bool check_item_loc(CephContext *cct, int item,
const std::map<std::string,std::string>& loc,
float *weight) {
int iweight;
bool ret = check_item_loc(cct, item, loc, &iweight);
if (weight)
*weight = (float)iweight / (float)0x10000;
return ret;
}
/**
* returns the (type, name) of the parent bucket of id
*
* FIXME: ambiguous for items that occur multiple times in the map
*/
std::pair<std::string,std::string> get_immediate_parent(int id, int *ret = NULL) const;
int get_immediate_parent_id(int id, int *parent) const;
/**
* return ancestor of the given type, or 0 if none
* can pass in a specific crush **rule** to return ancestor from that rule only
* (parent is always a bucket and thus <0)
*/
int get_parent_of_type(int id, int type, int rule = -1) const;
/**
* get the fully qualified location of a device by successively finding
* parents beginning at ID and ending at highest type number specified in
* the CRUSH map which assumes that if device foo is under device bar, the
* type_id of foo < bar where type_id is the integer specified in the CRUSH map
*
* returns the location in the form of (type=foo) where type is a type of bucket
* specified in the CRUSH map and foo is a name specified in the CRUSH map
*/
std::map<std::string, std::string> get_full_location(int id) const;
/**
* return location map for a item, by name
*/
int get_full_location(
const std::string& name,
std::map<std::string,std::string> *ploc);
/*
* identical to get_full_location(int id) although it returns the type/name
* pairs in the order they occur in the hierarchy.
*
* returns -ENOENT if id is not found.
*/
int get_full_location_ordered(
int id,
std::vector<std::pair<std::string, std::string> >& path) const;
/*
* identical to get_full_location_ordered(int id, vector<pair<string, string> >& path),
* although it returns a concatenated string with the type/name pairs in descending
* hierarchical order with format key1=val1,key2=val2.
*
* returns the location in descending hierarchy as a string.
*/
std::string get_full_location_ordered_string(int id) const;
/**
* returns (type_id, type) of all parent buckets between id and
* default, can be used to check for anomalous CRUSH maps
*/
std::map<int, std::string> get_parent_hierarchy(int id) const;
/**
* enumerate immediate children of given node
*
* @param id parent bucket or device id
* @return number of items, or error
*/
int get_children(int id, std::list<int> *children) const;
/**
* enumerate all children of given node
*
* @param id parent bucket or device id
* @return number of items, or error
*/
int get_all_children(int id, std::set<int> *children) const;
void get_children_of_type(int id,
int type,
std::vector<int> *children,
bool exclude_shadow = true) const;
/**
* enumerate all subtrees by type
*/
void get_subtree_of_type(int type, std::vector<int> *subtrees);
/**
* verify upmapping results.
* return 0 on success or a negative errno on error.
*/
int verify_upmap(CephContext *cct,
int rule_id,
int pool_size,
const std::vector<int>& up);
/**
* enumerate leaves(devices) of given node
*
* @param name parent bucket name
* @return 0 on success or a negative errno on error.
*/
int get_leaves(const std::string &name, std::set<int> *leaves) const;
private:
int _get_leaves(int id, std::list<int> *leaves) const; // worker
public:
/**
* insert an item into the map at a specific position
*
* Add an item at a specific location of the hierarchy.
* Specifically, we look for the most specific location constraint
* for which a bucket already exists, and then create intervening
* buckets beneath that in order to place the item.
*
* Note that any location specifiers *above* the most specific match
* are ignored. For example, if we specify that osd.12 goes in
* host=foo, rack=bar, and row=baz, and rack=bar is the most
* specific match, we will create host=foo beneath that point and
* put osd.12 inside it. However, we will not verify that rack=bar
* is beneath row=baz or move it.
*
* In short, we will build out a hierarchy, and move leaves around,
* but not adjust the hierarchy's internal structure. Yet.
*
* If the item is already present in the map, we will return EEXIST.
* If the location key/value pairs are nonsensical
* (rack=nameofdevice), or location specifies that do not attach us
* to any existing part of the hierarchy, we will return EINVAL.
*
* @param cct cct
* @param id item id
* @param weight item weight
* @param name item name
* @param loc location (map of type to bucket names)
* @param init_weight_sets initialize weight-set weights to weight (vs 0)
* @return 0 for success, negative on error
*/
int insert_item(CephContext *cct, int id, float weight, std::string name,
const std::map<std::string,std::string>& loc,
bool init_weight_sets=true);
/**
* move a bucket in the hierarchy to the given location
*
* This has the same location and ancestor creation behavior as
* insert_item(), but will relocate the specified existing bucket.
*
* @param cct cct
* @param id bucket id
* @param loc location (map of type to bucket names)
* @return 0 for success, negative on error
*/
int move_bucket(CephContext *cct, int id, const std::map<std::string,std::string>& loc);
/**
* swap bucket contents of two buckets without touching bucket ids
*
* @param cct cct
* @param src bucket a
* @param dst bucket b
* @return 0 for success, negative on error
*/
int swap_bucket(CephContext *cct, int src, int dst);
/**
* add a link to an existing bucket in the hierarchy to the new location
*
* This has the same location and ancestor creation behavior as
* insert_item(), but will add a new link to the specified existing
* bucket.
*
* @param cct cct
* @param id bucket id
* @param loc location (map of type to bucket names)
* @return 0 for success, negative on error
*/
int link_bucket(CephContext *cct, int id,
const std::map<std::string,std::string>& loc);
/**
* add or update an item's position in the map
*
* This is analogous to insert_item, except we will move an item if
* it is already present.
*
* @param cct cct
* @param id item id
* @param weight item weight
* @param name item name
* @param loc location (map of type to bucket names)
* @return 0 for no change, 1 for successful change, negative on error
*/
int update_item(CephContext *cct, int id, float weight, std::string name,
const std::map<std::string, std::string>& loc);
/**
* create or move an item, but do not adjust its weight if it already exists
*
* @param cct cct
* @param item item id
* @param weight initial item weight (if we need to create it)
* @param name item name
* @param loc location (map of type to bucket names)
* @param init_weight_sets initialize weight-set values to weight (vs 0)
* @return 0 for no change, 1 for successful change, negative on error
*/
int create_or_move_item(CephContext *cct, int item, float weight,
std::string name,
const std::map<std::string,std::string>& loc,
bool init_weight_sets=true);
/**
* remove all instances of an item from the map
*
* @param cct cct
* @param id item id to remove
* @param unlink_only unlink but do not remove bucket (useful if multiple links or not empty)
* @return 0 on success, negative on error
*/
int remove_item(CephContext *cct, int id, bool unlink_only);
/**
* recursively remove buckets starting at item and stop removing
* when a bucket is in use.
*
* @param item id to remove
* @return 0 on success, negative on error
*/
int remove_root(CephContext *cct, int item);
/**
* remove all instances of an item nested beneath a certain point from the map
*
* @param cct cct
* @param id item id to remove
* @param ancestor ancestor item id under which to search for id
* @param unlink_only unlink but do not remove bucket (useful if bucket has multiple links or is not empty)
* @return 0 on success, negative on error
*/
private:
bool _maybe_remove_last_instance(CephContext *cct, int id, bool unlink_only);
int _remove_item_under(CephContext *cct, int id, int ancestor, bool unlink_only);
bool _bucket_is_in_use(int id);
public:
int remove_item_under(CephContext *cct, int id, int ancestor, bool unlink_only);
/**
* calculate the locality/distance from a given id to a crush location map
*
* Specifically, we look for the lowest-valued type for which the
* location of id matches that described in loc.
*
* @param cct cct
* @param id the existing id in the map
* @param loc a set of key=value pairs describing a location in the hierarchy
*/
int get_common_ancestor_distance(CephContext *cct, int id,
const std::multimap<std::string,std::string>& loc) const;
/**
* parse a set of key/value pairs out of a string vector
*
* These are used to describe a location in the CRUSH hierarchy.
*
* @param args list of strings (each key= or key=value)
* @param ploc pointer to a resulting location map or multimap
*/
static int parse_loc_map(const std::vector<std::string>& args,
std::map<std::string,std::string> *ploc);
static int parse_loc_multimap(const std::vector<std::string>& args,
std::multimap<std::string,std::string> *ploc);
/**
* get an item's weight
*
* Will return the weight for the first instance it finds.
*
* @param id item id to check
* @return weight of item
*/
int get_item_weight(int id) const;
float get_item_weightf(int id) const {
return (float)get_item_weight(id) / (float)0x10000;
}
int get_item_weight_in_loc(int id,
const std::map<std::string, std::string> &loc);
float get_item_weightf_in_loc(int id,
const std::map<std::string, std::string> &loc) {
return (float)get_item_weight_in_loc(id, loc) / (float)0x10000;
}
int validate_weightf(float weight) {
uint64_t iweight = weight * 0x10000;
if (iweight > static_cast<uint64_t>(std::numeric_limits<int>::max())) {
return -EOVERFLOW;
}
return 0;
}
int adjust_item_weight(CephContext *cct, int id, int weight,
bool update_weight_sets=true);
int adjust_item_weightf(CephContext *cct, int id, float weight,
bool update_weight_sets=true) {
int r = validate_weightf(weight);
if (r < 0) {
return r;
}
return adjust_item_weight(cct, id, (int)(weight * (float)0x10000),
update_weight_sets);
}
int adjust_item_weight_in_bucket(CephContext *cct, int id, int weight,
int bucket_id,
bool update_weight_sets);
int adjust_item_weight_in_loc(CephContext *cct, int id, int weight,
const std::map<std::string,std::string>& loc,
bool update_weight_sets=true);
int adjust_item_weightf_in_loc(CephContext *cct, int id, float weight,
const std::map<std::string,std::string>& loc,
bool update_weight_sets=true) {
int r = validate_weightf(weight);
if (r < 0) {
return r;
}
return adjust_item_weight_in_loc(cct, id, (int)(weight * (float)0x10000),
loc, update_weight_sets);
}
void reweight(CephContext *cct);
void reweight_bucket(crush_bucket *b,
crush_choose_arg_map& arg_map,
std::vector<uint32_t> *weightv);
int adjust_subtree_weight(CephContext *cct, int id, int weight,
bool update_weight_sets=true);
int adjust_subtree_weightf(CephContext *cct, int id, float weight,
bool update_weight_sets=true) {
int r = validate_weightf(weight);
if (r < 0) {
return r;
}
return adjust_subtree_weight(cct, id, (int)(weight * (float)0x10000),
update_weight_sets);
}
/// check if item id is present in the map hierarchy
bool check_item_present(int id) const;
/*** devices ***/
int get_max_devices() const {
if (!crush) return 0;
return crush->max_devices;
}
/*** rules ***/
private:
crush_rule *get_rule(unsigned ruleno) const {
if (!crush) return (crush_rule *)(-ENOENT);
if (ruleno >= crush->max_rules)
return 0;
return crush->rules[ruleno];
}
crush_rule_step *get_rule_step(unsigned ruleno, unsigned step) const {
crush_rule *n = get_rule(ruleno);
if (IS_ERR(n)) return (crush_rule_step *)(-EINVAL);
if (step >= n->len) return (crush_rule_step *)(-EINVAL);
return &n->steps[step];
}
public:
/* accessors */
int get_max_rules() const {
if (!crush) return 0;
return crush->max_rules;
}
bool rule_exists(unsigned ruleno) const {
if (!crush) return false;
if (ruleno < crush->max_rules &&
crush->rules[ruleno] != NULL)
return true;
return false;
}
bool rule_has_take(unsigned ruleno, int take) const {
if (!crush) return false;
crush_rule *rule = get_rule(ruleno);
for (unsigned i = 0; i < rule->len; ++i) {
if (rule->steps[i].op == CRUSH_RULE_TAKE &&
rule->steps[i].arg1 == take) {
return true;
}
}
return false;
}
int get_rule_len(unsigned ruleno) const {
crush_rule *r = get_rule(ruleno);
if (IS_ERR(r)) return PTR_ERR(r);
return r->len;
}
int get_rule_mask_ruleset(unsigned ruleno) const {
crush_rule *r = get_rule(ruleno);
if (IS_ERR(r)) return -1;
return r->mask.ruleset;
}
int get_rule_mask_type(unsigned ruleno) const {
crush_rule *r = get_rule(ruleno);
if (IS_ERR(r)) return -1;
return r->mask.type;
}
int get_rule_mask_min_size(unsigned ruleno) const {
crush_rule *r = get_rule(ruleno);
if (IS_ERR(r)) return -1;
return r->mask.min_size;
}
int get_rule_mask_max_size(unsigned ruleno) const {
crush_rule *r = get_rule(ruleno);
if (IS_ERR(r)) return -1;
return r->mask.max_size;
}
int get_rule_op(unsigned ruleno, unsigned step) const {
crush_rule_step *s = get_rule_step(ruleno, step);
if (IS_ERR(s)) return PTR_ERR(s);
return s->op;
}
int get_rule_arg1(unsigned ruleno, unsigned step) const {
crush_rule_step *s = get_rule_step(ruleno, step);
if (IS_ERR(s)) return PTR_ERR(s);
return s->arg1;
}
int get_rule_arg2(unsigned ruleno, unsigned step) const {
crush_rule_step *s = get_rule_step(ruleno, step);
if (IS_ERR(s)) return PTR_ERR(s);
return s->arg2;
}
private:
float _get_take_weight_osd_map(int root, std::map<int,float> *pmap) const;
void _normalize_weight_map(float sum, const std::map<int,float>& m,
std::map<int,float> *pmap) const;
public:
/**
* calculate a map of osds to weights for a given rule
*
* Generate a map of which OSDs get how much relative weight for a
* given rule.
*
* @param ruleno [in] rule id
* @param pmap [out] map of osd to weight
* @return 0 for success, or negative error code
*/
int get_rule_weight_osd_map(unsigned ruleno, std::map<int,float> *pmap) const;
/**
* calculate a map of osds to weights for a given starting root
*
* Generate a map of which OSDs get how much relative weight for a
* given starting root
*
* @param root node
* @param pmap [out] map of osd to weight
* @return 0 for success, or negative error code
*/
int get_take_weight_osd_map(int root, std::map<int,float> *pmap) const;
/* modifiers */
int add_rule(int ruleno, int len, int type, int minsize, int maxsize) {
if (!crush) return -ENOENT;
crush_rule *n = crush_make_rule(len, ruleno, type, minsize, maxsize);
ceph_assert(n);
ruleno = crush_add_rule(crush, n, ruleno);
return ruleno;
}
int set_rule_mask_max_size(unsigned ruleno, int max_size) {
crush_rule *r = get_rule(ruleno);
if (IS_ERR(r)) return -1;
return r->mask.max_size = max_size;
}
int set_rule_step(unsigned ruleno, unsigned step, int op, int arg1, int arg2) {
if (!crush) return -ENOENT;
crush_rule *n = get_rule(ruleno);
if (!n) return -1;
crush_rule_set_step(n, step, op, arg1, arg2);
return 0;
}
int set_rule_step_take(unsigned ruleno, unsigned step, int val) {
return set_rule_step(ruleno, step, CRUSH_RULE_TAKE, val, 0);
}
int set_rule_step_set_choose_tries(unsigned ruleno, unsigned step, int val) {
return set_rule_step(ruleno, step, CRUSH_RULE_SET_CHOOSE_TRIES, val, 0);
}
int set_rule_step_set_choose_local_tries(unsigned ruleno, unsigned step, int val) {
return set_rule_step(ruleno, step, CRUSH_RULE_SET_CHOOSE_LOCAL_TRIES, val, 0);
}
int set_rule_step_set_choose_local_fallback_tries(unsigned ruleno, unsigned step, int val) {
return set_rule_step(ruleno, step, CRUSH_RULE_SET_CHOOSE_LOCAL_FALLBACK_TRIES, val, 0);
}
int set_rule_step_set_chooseleaf_tries(unsigned ruleno, unsigned step, int val) {
return set_rule_step(ruleno, step, CRUSH_RULE_SET_CHOOSELEAF_TRIES, val, 0);
}
int set_rule_step_set_chooseleaf_vary_r(unsigned ruleno, unsigned step, int val) {
return set_rule_step(ruleno, step, CRUSH_RULE_SET_CHOOSELEAF_VARY_R, val, 0);
}
int set_rule_step_set_chooseleaf_stable(unsigned ruleno, unsigned step, int val) {
return set_rule_step(ruleno, step, CRUSH_RULE_SET_CHOOSELEAF_STABLE, val, 0);
}
int set_rule_step_choose_firstn(unsigned ruleno, unsigned step, int val, int type) {
return set_rule_step(ruleno, step, CRUSH_RULE_CHOOSE_FIRSTN, val, type);
}
int set_rule_step_choose_indep(unsigned ruleno, unsigned step, int val, int type) {
return set_rule_step(ruleno, step, CRUSH_RULE_CHOOSE_INDEP, val, type);
}
int set_rule_step_choose_leaf_firstn(unsigned ruleno, unsigned step, int val, int type) {
return set_rule_step(ruleno, step, CRUSH_RULE_CHOOSELEAF_FIRSTN, val, type);
}
int set_rule_step_choose_leaf_indep(unsigned ruleno, unsigned step, int val, int type) {
return set_rule_step(ruleno, step, CRUSH_RULE_CHOOSELEAF_INDEP, val, type);
}
int set_rule_step_emit(unsigned ruleno, unsigned step) {
return set_rule_step(ruleno, step, CRUSH_RULE_EMIT, 0, 0);
}
int add_simple_rule(
std::string name, std::string root_name, std::string failure_domain_type,
std::string device_class, std::string mode, int rule_type,
std::ostream *err = 0);
/**
* @param rno rule[set] id to use, -1 to pick the lowest available
*/
int add_simple_rule_at(
std::string name, std::string root_name,
std::string failure_domain_type, std::string device_class, std::string mode,
int rule_type, int rno, std::ostream *err = 0);
int remove_rule(int ruleno);
/** buckets **/
const crush_bucket *get_bucket(int id) const {
if (!crush)
return (crush_bucket *)(-EINVAL);
unsigned int pos = (unsigned int)(-1 - id);
unsigned int max_buckets = crush->max_buckets;
if (pos >= max_buckets)
return (crush_bucket *)(-ENOENT);
crush_bucket *ret = crush->buckets[pos];
if (ret == NULL)
return (crush_bucket *)(-ENOENT);
return ret;
}
private:
crush_bucket *get_bucket(int id) {
if (!crush)
return (crush_bucket *)(-EINVAL);
unsigned int pos = (unsigned int)(-1 - id);
unsigned int max_buckets = crush->max_buckets;
if (pos >= max_buckets)
return (crush_bucket *)(-ENOENT);
crush_bucket *ret = crush->buckets[pos];
if (ret == NULL)
return (crush_bucket *)(-ENOENT);
return ret;
}
/**
* detach a bucket from its parent and adjust the parent weight
*
* returns the weight of the detached bucket
**/
int detach_bucket(CephContext *cct, int item);
int get_new_bucket_id();
public:
int get_max_buckets() const {
if (!crush) return -EINVAL;
return crush->max_buckets;
}
int get_next_bucket_id() const {
if (!crush) return -EINVAL;
return crush_get_next_bucket_id(crush);
}
bool bucket_exists(int id) const {
const crush_bucket *b = get_bucket(id);
if (IS_ERR(b))
return false;
return true;
}
int get_bucket_weight(int id) const {
const crush_bucket *b = get_bucket(id);
if (IS_ERR(b)) return PTR_ERR(b);
return b->weight;
}
float get_bucket_weightf(int id) const {
const crush_bucket *b = get_bucket(id);
if (IS_ERR(b)) return 0;
return b->weight / (float)0x10000;
}
int get_bucket_type(int id) const {
const crush_bucket *b = get_bucket(id);
if (IS_ERR(b)) return PTR_ERR(b);
return b->type;
}
int get_bucket_alg(int id) const {
const crush_bucket *b = get_bucket(id);
if (IS_ERR(b)) return PTR_ERR(b);
return b->alg;
}
int get_bucket_hash(int id) const {
const crush_bucket *b = get_bucket(id);
if (IS_ERR(b)) return PTR_ERR(b);
return b->hash;
}
int get_bucket_size(int id) const {
const crush_bucket *b = get_bucket(id);
if (IS_ERR(b)) return PTR_ERR(b);
return b->size;
}
int get_bucket_item(int id, int pos) const {
const crush_bucket *b = get_bucket(id);
if (IS_ERR(b)) return PTR_ERR(b);
if ((__u32)pos >= b->size)
return PTR_ERR(b);
return b->items[pos];
}
int get_bucket_item_weight(int id, int pos) const {
const crush_bucket *b = get_bucket(id);
if (IS_ERR(b)) return PTR_ERR(b);
return crush_get_bucket_item_weight(b, pos);
}
float get_bucket_item_weightf(int id, int pos) const {
const crush_bucket *b = get_bucket(id);
if (IS_ERR(b)) return 0;
return (float)crush_get_bucket_item_weight(b, pos) / (float)0x10000;
}
/* modifiers */
int add_bucket(int bucketno, int alg, int hash, int type, int size,
int *items, int *weights, int *idout);
int bucket_add_item(crush_bucket *bucket, int item, int weight);
int bucket_remove_item(struct crush_bucket *bucket, int item);
int bucket_adjust_item_weight(
CephContext *cct, struct crush_bucket *bucket, int item, int weight,
bool adjust_weight_sets);
void finalize() {
ceph_assert(crush);
crush_finalize(crush);
if (!name_map.empty() &&
name_map.rbegin()->first >= crush->max_devices) {
crush->max_devices = name_map.rbegin()->first + 1;
}
have_uniform_rules = !has_legacy_rule_ids();
build_rmaps();
}
int bucket_set_alg(int id, int alg);
int update_device_class(int id, const std::string& class_name,
const std::string& name, std::ostream *ss);
int remove_device_class(CephContext *cct, int id, std::ostream *ss);
int device_class_clone(
int original, int device_class,
const std::map<int32_t, std::map<int32_t, int32_t>>& old_class_bucket,
const std::set<int32_t>& used_ids,
int *clone,
std::map<int, std::map<int,std::vector<int>>> *cmap_item_weight);
bool class_is_in_use(int class_id, std::ostream *ss = nullptr);
int rename_class(const std::string& srcname, const std::string& dstname);
int populate_classes(
const std::map<int32_t, std::map<int32_t, int32_t>>& old_class_bucket);
int get_rules_by_class(const std::string &class_name, std::set<int> *rules);
int get_rules_by_osd(int osd, std::set<int> *rules);
bool _class_is_dead(int class_id);
void cleanup_dead_classes();
int rebuild_roots_with_classes(CephContext *cct);
/* remove unused roots generated for class devices */
int trim_roots_with_class(CephContext *cct);
int reclassify(
CephContext *cct,
std::ostream& out,
const std::map<std::string,std::string>& classify_root,
const std::map<std::string,std::pair<std::string,std::string>>& classify_bucket
);
int set_subtree_class(const std::string& name, const std::string& class_name);
void start_choose_profile() {
free(crush->choose_tries);
/*
* the original choose_total_tries value was off by one (it
* counted "retries" and not "tries"). add one to alloc.
*/
crush->choose_tries = (__u32 *)calloc(sizeof(*crush->choose_tries),
(crush->choose_total_tries + 1));
memset(crush->choose_tries, 0,
sizeof(*crush->choose_tries) * (crush->choose_total_tries + 1));
}
void stop_choose_profile() {
free(crush->choose_tries);
crush->choose_tries = 0;
}
int get_choose_profile(__u32 **vec) {
if (crush->choose_tries) {
*vec = crush->choose_tries;
return crush->choose_total_tries;
}
return 0;
}
void set_max_devices(int m) {
crush->max_devices = m;
}
int find_rule(int ruleset, int type, int size) const {
if (!crush) return -1;
if (have_uniform_rules &&
ruleset < (int)crush->max_rules &&
crush->rules[ruleset] &&
crush->rules[ruleset]->mask.type == type &&
crush->rules[ruleset]->mask.min_size <= size &&
crush->rules[ruleset]->mask.max_size >= size) {
return ruleset;
}
return crush_find_rule(crush, ruleset, type, size);
}
bool ruleset_exists(const int ruleset) const {
for (size_t i = 0; i < crush->max_rules; ++i) {
if (rule_exists(i) && crush->rules[i]->mask.ruleset == ruleset) {
return true;
}
}
return false;
}
/**
* Return the lowest numbered ruleset of type `type`
*
* @returns a ruleset ID, or -1 if no matching rules found.
*/
int find_first_ruleset(int type) const {
int result = -1;
for (size_t i = 0; i < crush->max_rules; ++i) {
if (crush->rules[i]
&& crush->rules[i]->mask.type == type
&& (crush->rules[i]->mask.ruleset < result || result == -1)) {
result = crush->rules[i]->mask.ruleset;
}
}
return result;
}
bool have_choose_args(int64_t choose_args_index) const {
return choose_args.count(choose_args_index);
}
crush_choose_arg_map choose_args_get_with_fallback(
int64_t choose_args_index) const {
auto i = choose_args.find(choose_args_index);
if (i == choose_args.end()) {
i = choose_args.find(DEFAULT_CHOOSE_ARGS);
}
if (i == choose_args.end()) {
crush_choose_arg_map arg_map;
arg_map.args = NULL;
arg_map.size = 0;
return arg_map;
} else {
return i->second;
}
}
crush_choose_arg_map choose_args_get(int64_t choose_args_index) const {
auto i = choose_args.find(choose_args_index);
if (i == choose_args.end()) {
crush_choose_arg_map arg_map;
arg_map.args = NULL;
arg_map.size = 0;
return arg_map;
} else {
return i->second;
}
}
void destroy_choose_args(crush_choose_arg_map arg_map) {
for (__u32 i = 0; i < arg_map.size; i++) {
crush_choose_arg *arg = &arg_map.args[i];
for (__u32 j = 0; j < arg->weight_set_positions; j++) {
crush_weight_set *weight_set = &arg->weight_set[j];
free(weight_set->weights);
}
if (arg->weight_set)
free(arg->weight_set);
if (arg->ids)
free(arg->ids);
}
free(arg_map.args);
}
bool create_choose_args(int64_t id, int positions) {
if (choose_args.count(id))
return false;
ceph_assert(positions);
auto &cmap = choose_args[id];
cmap.args = static_cast<crush_choose_arg*>(calloc(sizeof(crush_choose_arg),
crush->max_buckets));
cmap.size = crush->max_buckets;
for (int bidx=0; bidx < crush->max_buckets; ++bidx) {
crush_bucket *b = crush->buckets[bidx];
auto &carg = cmap.args[bidx];
carg.ids = NULL;
carg.ids_size = 0;
if (b && b->alg == CRUSH_BUCKET_STRAW2) {
crush_bucket_straw2 *sb = reinterpret_cast<crush_bucket_straw2*>(b);
carg.weight_set_positions = positions;
carg.weight_set = static_cast<crush_weight_set*>(calloc(sizeof(crush_weight_set),
carg.weight_set_positions));
// initialize with canonical weights
for (int pos = 0; pos < positions; ++pos) {
carg.weight_set[pos].size = b->size;
carg.weight_set[pos].weights = (__u32*)calloc(4, b->size);
for (unsigned i = 0; i < b->size; ++i) {
carg.weight_set[pos].weights[i] = sb->item_weights[i];
}
}
} else {
carg.weight_set = NULL;
carg.weight_set_positions = 0;
}
}
return true;
}
void rm_choose_args(int64_t id) {
auto p = choose_args.find(id);
if (p != choose_args.end()) {
destroy_choose_args(p->second);
choose_args.erase(p);
}
}
void choose_args_clear() {
for (auto w : choose_args)
destroy_choose_args(w.second);
choose_args.clear();
}
// remove choose_args for buckets that no longer exist, create them for new buckets
void update_choose_args(CephContext *cct);
// adjust choose_args_map weight, preserving the hierarchical summation
// property. used by callers optimizing layouts by tweaking weights.
int _choose_args_adjust_item_weight_in_bucket(
CephContext *cct,
crush_choose_arg_map cmap,
int bucketid,
int id,
const std::vector<int>& weight,
std::ostream *ss);
int choose_args_adjust_item_weight(
CephContext *cct,
crush_choose_arg_map cmap,
int id, const std::vector<int>& weight,
std::ostream *ss);
int choose_args_adjust_item_weightf(
CephContext *cct,
crush_choose_arg_map cmap,
int id, const std::vector<double>& weightf,
std::ostream *ss) {
std::vector<int> weight(weightf.size());
for (unsigned i = 0; i < weightf.size(); ++i) {
weight[i] = (int)(weightf[i] * (double)0x10000);
}
return choose_args_adjust_item_weight(cct, cmap, id, weight, ss);
}
int get_choose_args_positions(crush_choose_arg_map cmap) {
// infer positions from other buckets
for (unsigned j = 0; j < cmap.size; ++j) {
if (cmap.args[j].weight_set_positions) {
return cmap.args[j].weight_set_positions;
}
}
return 1;
}
template<typename WeightVector>
void do_rule(int rule, int x, std::vector<int>& out, int maxout,
const WeightVector& weight,
uint64_t choose_args_index) const {
int rawout[maxout];
char work[crush_work_size(crush, maxout)];
crush_init_workspace(crush, work);
crush_choose_arg_map arg_map = choose_args_get_with_fallback(
choose_args_index);
int numrep = crush_do_rule(crush, rule, x, rawout, maxout,
std::data(weight), std::size(weight),
work, arg_map.args);
if (numrep < 0)
numrep = 0;
out.resize(numrep);
for (int i=0; i<numrep; i++)
out[i] = rawout[i];
}
int _choose_type_stack(
CephContext *cct,
const std::vector<std::pair<int,int>>& stack,
const std::set<int>& overfull,
const std::vector<int>& underfull,
const std::vector<int>& more_underfull,
const std::vector<int>& orig,
std::vector<int>::const_iterator& i,
std::set<int>& used,
std::vector<int> *pw,
int root_bucket,
int rule) const;
int try_remap_rule(
CephContext *cct,
int rule,
int maxout,
const std::set<int>& overfull,
const std::vector<int>& underfull,
const std::vector<int>& more_underfull,
const std::vector<int>& orig,
std::vector<int> *out) const;
bool check_crush_rule(int ruleset, int type, int size, std::ostream& ss) {
ceph_assert(crush);
__u32 i;
for (i = 0; i < crush->max_rules; i++) {
if (crush->rules[i] &&
crush->rules[i]->mask.ruleset == ruleset &&
crush->rules[i]->mask.type == type) {
if (crush->rules[i]->mask.min_size <= size &&
crush->rules[i]->mask.max_size >= size) {
return true;
} else if (size < crush->rules[i]->mask.min_size) {
ss << "pool size is smaller than the crush rule min size";
return false;
} else {
ss << "pool size is bigger than the crush rule max size";
return false;
}
}
}
return false;
}
void encode(ceph::buffer::list &bl, uint64_t features) const;
void decode(ceph::buffer::list::const_iterator &blp);
void decode_crush_bucket(crush_bucket** bptr,
ceph::buffer::list::const_iterator &blp);
void dump(ceph::Formatter *f) const;
void dump_rules(ceph::Formatter *f) const;
void dump_rule(int ruleset, ceph::Formatter *f) const;
void dump_tunables(ceph::Formatter *f) const;
void dump_choose_args(ceph::Formatter *f) const;
void list_rules(ceph::Formatter *f) const;
void list_rules(std::ostream *ss) const;
void dump_tree(std::ostream *out,
ceph::Formatter *f,
const CrushTreeDumper::name_map_t& ws,
bool show_shadow = false) const;
void dump_tree(std::ostream *out, ceph::Formatter *f) {
dump_tree(out, f, CrushTreeDumper::name_map_t());
}
void dump_tree(ceph::Formatter *f,
const CrushTreeDumper::name_map_t& ws) const;
static void generate_test_instances(std::list<CrushWrapper*>& o);
int get_osd_pool_default_crush_replicated_ruleset(CephContext *cct);
static bool is_valid_crush_name(const std::string& s);
static bool is_valid_crush_loc(CephContext *cct,
const std::map<std::string,std::string>& loc);
};
WRITE_CLASS_ENCODER_FEATURES(CrushWrapper)
#endif
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