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// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
// vim: ts=8 sw=2 smarttab
/*
* Ceph - scalable distributed file system
*
* Copyright (C) 2004-2006 Sage Weil <sage@newdream.net>
*
* This is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License version 2.1, as published by the Free Software
* Foundation. See file COPYING.
*
*/
#ifndef CEPH_FRAG_H
#define CEPH_FRAG_H
#include <boost/container/small_vector.hpp>
#include <iostream>
#include <stdint.h>
#include <stdio.h>
#include "buffer.h"
#include "compact_map.h"
#include "ceph_frag.h"
#include "include/encoding.h"
#include "include/ceph_assert.h"
#include "common/dout.h"
/*
*
* the goal here is to use a binary split strategy to partition a namespace.
* frag_t represents a particular fragment. bits() tells you the size of the
* fragment, and value() it's name. this is roughly analogous to an ip address
* and netmask.
*
* fragtree_t represents an entire namespace and it's partition. it essentially
* tells you where fragments are split into other fragments, and by how much
* (i.e. by how many bits, resulting in a power of 2 number of child fragments).
*
* this vaguely resembles a btree, in that when a fragment becomes large or small
* we can split or merge, except that there is no guarantee of being balanced.
*
* presumably we are partitioning the output of a (perhaps specialized) hash
* function.
*/
/**
* frag_t
*
* description of an individual fragment. that is, a particular piece
* of the overall namespace.
*
* this is conceptually analogous to an ip address and netmask.
*
* a value v falls "within" fragment f iff (v & f.mask()) == f.value().
*
* we write it as v/b, where v is a value and b is the number of bits.
* 0/0 (bits==0) corresponds to the entire namespace. if we bisect that,
* we get 0/1 and 1/1. quartering gives us 0/2, 1/2, 2/2, 3/2. and so on.
*
* this makes the right most bit of v the "most significant", which is the
* opposite of what we usually see.
*/
/*
* TODO:
* - get_first_child(), next_sibling(int parent_bits) to make (possibly partial)
* iteration efficient (see, e.g., try_assimilate_children()
* - rework frag_t so that we mask the left-most (most significant) bits instead of
* the right-most (least significant) bits. just because it's more intuitive, and
* matches the network/netmask concept.
*/
class frag_t {
/*
* encoding is dictated by frag_* functions in ceph_fs.h. use those
* helpers _exclusively_.
*/
public:
using _frag_t = uint32_t;
frag_t() = default;
frag_t(unsigned v, unsigned b) : _enc(ceph_frag_make(b, v)) { }
frag_t(_frag_t e) : _enc(e) { }
// constructors
void from_unsigned(unsigned e) { _enc = e; }
// accessors
unsigned value() const { return ceph_frag_value(_enc); }
unsigned bits() const { return ceph_frag_bits(_enc); }
unsigned mask() const { return ceph_frag_mask(_enc); }
unsigned mask_shift() const { return ceph_frag_mask_shift(_enc); }
operator _frag_t() const { return _enc; }
// tests
bool contains(unsigned v) const { return ceph_frag_contains_value(_enc, v); }
bool contains(frag_t sub) const { return ceph_frag_contains_frag(_enc, sub._enc); }
bool is_root() const { return bits() == 0; }
frag_t parent() const {
ceph_assert(bits() > 0);
return frag_t(ceph_frag_parent(_enc));
}
// splitting
frag_t make_child(int i, int nb) const {
ceph_assert(i < (1<<nb));
return frag_t(ceph_frag_make_child(_enc, nb, i));
}
template<typename T>
void split(int nb, T& fragments) const {
ceph_assert(nb > 0);
unsigned nway = 1 << nb;
for (unsigned i=0; i<nway; i++)
fragments.push_back(make_child(i, nb));
}
// binary splitting
frag_t left_child() const { return frag_t(ceph_frag_left_child(_enc)); }
frag_t right_child() const { return frag_t(ceph_frag_right_child(_enc)); }
bool is_left() const { return ceph_frag_is_left_child(_enc); }
bool is_right() const { return ceph_frag_is_right_child(_enc); }
frag_t get_sibling() const {
ceph_assert(!is_root());
return frag_t(ceph_frag_sibling(_enc));
}
// sequencing
bool is_leftmost() const { return ceph_frag_is_leftmost(_enc); }
bool is_rightmost() const { return ceph_frag_is_rightmost(_enc); }
frag_t next() const {
ceph_assert(!is_rightmost());
return frag_t(ceph_frag_next(_enc));
}
// parse
bool parse(const char *s) {
int pvalue, pbits;
int r = sscanf(s, "%x/%d", &pvalue, &pbits);
if (r == 2) {
*this = frag_t(pvalue, pbits);
return true;
}
return false;
}
void encode(bufferlist& bl) const {
encode_raw(_enc, bl);
}
void decode(bufferlist::const_iterator& p) {
__u32 v;
decode_raw(v, p);
_enc = v;
}
private:
_frag_t _enc = 0;
};
inline std::ostream& operator<<(std::ostream& out, const frag_t& hb)
{
//out << std::hex << hb.value() << std::dec << "/" << hb.bits() << '=';
unsigned num = hb.bits();
if (num) {
unsigned val = hb.value();
for (unsigned bit = 23; num; num--, bit--)
out << ((val & (1<<bit)) ? '1':'0');
}
return out << '*';
}
inline void encode(const frag_t &f, bufferlist& bl) { f.encode(bl); }
inline void decode(frag_t &f, bufferlist::const_iterator& p) { f.decode(p); }
using frag_vec_t = boost::container::small_vector<frag_t, 4>;
/**
* fragtree_t -- partition an entire namespace into one or more frag_t's.
*/
class fragtree_t {
// pairs <f, b>:
// frag_t f is split by b bits.
// if child frag_t does not appear, it is not split.
public:
compact_map<frag_t,int32_t> _splits;
public:
// -------------
// basics
void swap(fragtree_t& other) {
_splits.swap(other._splits);
}
void clear() {
_splits.clear();
}
// -------------
// accessors
bool empty() const {
return _splits.empty();
}
int get_split(const frag_t hb) const {
compact_map<frag_t,int32_t>::const_iterator p = _splits.find(hb);
if (p == _splits.end())
return 0;
else
return p->second;
}
bool is_leaf(frag_t x) const {
frag_vec_t s;
get_leaves_under(x, s);
//generic_dout(10) << "is_leaf(" << x << ") -> " << ls << dendl;
return s.size() == 1 && s.front() == x;
}
/**
* get_leaves -- list all leaves
*/
template<typename T>
void get_leaves(T& c) const {
return get_leaves_under_split(frag_t(), c);
}
/**
* get_leaves_under_split -- list all leaves under a known split point (or root)
*/
template<typename T>
void get_leaves_under_split(frag_t under, T& c) const {
frag_vec_t s;
s.push_back(under);
while (!s.empty()) {
frag_t t = s.back();
s.pop_back();
int nb = get_split(t);
if (nb)
t.split(nb, s); // queue up children
else
c.push_back(t); // not spit, it's a leaf.
}
}
/**
* get_branch -- get branch point at OR above frag @a x
* - may be @a x itself, if @a x is a split
* - may be root (frag_t())
*/
frag_t get_branch(frag_t x) const {
while (1) {
if (x == frag_t()) return x; // root
if (get_split(x)) return x; // found it!
x = x.parent();
}
}
/**
* get_branch_above -- get a branch point above frag @a x
* - may be root (frag_t())
* - may NOT be @a x, even if @a x is a split.
*/
frag_t get_branch_above(frag_t x) const {
while (1) {
if (x == frag_t()) return x; // root
x = x.parent();
if (get_split(x)) return x; // found it!
}
}
/**
* get_branch_or_leaf -- get branch or leaf point parent for frag @a x
* - may be @a x itself, if @a x is a split or leaf
* - may be root (frag_t())
*/
frag_t get_branch_or_leaf(frag_t x) const {
frag_t branch = get_branch(x);
int nb = get_split(branch);
if (nb > 0 && // if branch is a split, and
branch.bits() + nb <= x.bits()) // one of the children is or contains x
return frag_t(x.value(), branch.bits()+nb); // then return that child (it's a leaf)
else
return branch;
}
/**
* get_leaves_under(x, ls) -- search for any leaves fully contained by x
*/
template<typename T>
void get_leaves_under(frag_t x, T& c) const {
frag_vec_t s;
s.push_back(get_branch_or_leaf(x));
while (!s.empty()) {
frag_t t = s.back();
s.pop_back();
if (t.bits() >= x.bits() && // if t is more specific than x, and
!x.contains(t)) // x does not contain t,
continue; // then skip
int nb = get_split(t);
if (nb)
t.split(nb, s); // queue up children
else if (x.contains(t))
c.push_back(t); // not spit, it's a leaf.
}
}
/**
* contains(fg) -- does fragtree contain the specific frag @a x
*/
bool contains(frag_t x) const {
frag_vec_t s;
s.push_back(get_branch(x));
while (!s.empty()) {
frag_t t = s.back();
s.pop_back();
if (t.bits() >= x.bits() && // if t is more specific than x, and
!x.contains(t)) // x does not contain t,
continue; // then skip
int nb = get_split(t);
if (nb) {
if (t == x) return false; // it's split.
t.split(nb, s); // queue up children
} else {
if (t == x) return true; // it's there.
}
}
return false;
}
/**
* operator[] -- map a (hash?) value to a frag
*/
frag_t operator[](unsigned v) const {
frag_t t;
while (1) {
ceph_assert(t.contains(v));
int nb = get_split(t);
// is this a leaf?
if (nb == 0) return t; // done.
// pick appropriate child fragment.
unsigned nway = 1 << nb;
unsigned i;
for (i=0; i<nway; i++) {
frag_t n = t.make_child(i, nb);
if (n.contains(v)) {
t = n;
break;
}
}
ceph_assert(i < nway);
}
}
// ---------------
// modifiers
void split(frag_t x, int b, bool simplify=true) {
ceph_assert(is_leaf(x));
_splits[x] = b;
if (simplify)
try_assimilate_children(get_branch_above(x));
}
void merge(frag_t x, int b, bool simplify=true) {
ceph_assert(!is_leaf(x));
ceph_assert(_splits[x] == b);
_splits.erase(x);
if (simplify)
try_assimilate_children(get_branch_above(x));
}
/*
* if all of a given split's children are identically split,
* then the children can be assimilated.
*/
void try_assimilate_children(frag_t x) {
int nb = get_split(x);
if (!nb) return;
frag_vec_t children;
x.split(nb, children);
int childbits = 0;
for (auto& frag : children) {
int cb = get_split(frag);
if (!cb) return; // nope.
if (childbits && cb != childbits) return; // not the same
childbits = cb;
}
// all children are split with childbits!
for (auto& frag : children)
_splits.erase(frag);
_splits[x] += childbits;
}
bool force_to_leaf(CephContext *cct, frag_t x) {
if (is_leaf(x))
return false;
lgeneric_dout(cct, 10) << "force_to_leaf " << x << " on " << _splits << dendl;
frag_t parent = get_branch_or_leaf(x);
ceph_assert(parent.bits() <= x.bits());
lgeneric_dout(cct, 10) << "parent is " << parent << dendl;
// do we need to split from parent to x?
if (parent.bits() < x.bits()) {
int spread = x.bits() - parent.bits();
int nb = get_split(parent);
lgeneric_dout(cct, 10) << "spread " << spread << ", parent splits by " << nb << dendl;
if (nb == 0) {
// easy: split parent (a leaf) by the difference
lgeneric_dout(cct, 10) << "splitting parent " << parent << " by spread " << spread << dendl;
split(parent, spread);
ceph_assert(is_leaf(x));
return true;
}
ceph_assert(nb > spread);
// add an intermediary split
merge(parent, nb, false);
split(parent, spread, false);
frag_vec_t subs;
parent.split(spread, subs);
for (auto& frag : subs) {
lgeneric_dout(cct, 10) << "splitting intermediate " << frag << " by " << (nb-spread) << dendl;
split(frag, nb - spread, false);
}
}
// x is now a leaf or split.
// hoover up any children.
frag_vec_t s;
s.push_back(x);
while (!s.empty()) {
frag_t t = s.back();
s.pop_back();
int nb = get_split(t);
if (nb) {
lgeneric_dout(cct, 10) << "merging child " << t << " by " << nb << dendl;
merge(t, nb, false); // merge this point, and
t.split(nb, s); // queue up children
}
}
lgeneric_dout(cct, 10) << "force_to_leaf done" << dendl;
ceph_assert(is_leaf(x));
return true;
}
// encoding
void encode(bufferlist& bl) const {
using ceph::encode;
encode(_splits, bl);
}
void decode(bufferlist::const_iterator& p) {
using ceph::decode;
decode(_splits, p);
}
void encode_nohead(bufferlist& bl) const {
using ceph::encode;
for (compact_map<frag_t,int32_t>::const_iterator p = _splits.begin();
p != _splits.end();
++p) {
encode(p->first, bl);
encode(p->second, bl);
}
}
void decode_nohead(int n, bufferlist::const_iterator& p) {
using ceph::decode;
_splits.clear();
while (n-- > 0) {
frag_t f;
decode(f, p);
decode(_splits[f], p);
}
}
void print(std::ostream& out) {
out << "fragtree_t(";
frag_vec_t s;
s.push_back(frag_t());
while (!s.empty()) {
frag_t t = s.back();
s.pop_back();
// newline + indent?
if (t.bits()) {
out << std::endl;
for (unsigned i=0; i<t.bits(); i++) out << ' ';
}
int nb = get_split(t);
if (nb) {
out << t << " %" << nb;
t.split(nb, s); // queue up children
} else {
out << t;
}
}
out << ")";
}
void dump(Formatter *f) const {
f->open_array_section("splits");
for (compact_map<frag_t,int32_t>::const_iterator p = _splits.begin();
p != _splits.end();
++p) {
f->open_object_section("split");
std::ostringstream frag_str;
frag_str << p->first;
f->dump_string("frag", frag_str.str());
f->dump_int("children", p->second);
f->close_section(); // split
}
f->close_section(); // splits
}
};
WRITE_CLASS_ENCODER(fragtree_t)
inline bool operator==(const fragtree_t& l, const fragtree_t& r) {
return l._splits == r._splits;
}
inline bool operator!=(const fragtree_t& l, const fragtree_t& r) {
return l._splits != r._splits;
}
inline std::ostream& operator<<(std::ostream& out, const fragtree_t& ft)
{
out << "fragtree_t(";
for (compact_map<frag_t,int32_t>::const_iterator p = ft._splits.begin();
p != ft._splits.end();
++p) {
if (p != ft._splits.begin())
out << " ";
out << p->first << "^" << p->second;
}
return out << ")";
}
/**
* fragset_t -- a set of fragments
*/
class fragset_t {
std::set<frag_t> _set;
public:
const std::set<frag_t> &get() const { return _set; }
std::set<frag_t>::iterator begin() { return _set.begin(); }
std::set<frag_t>::iterator end() { return _set.end(); }
bool empty() const { return _set.empty(); }
bool contains(frag_t f) const {
while (1) {
if (_set.count(f)) return true;
if (f.bits() == 0) return false;
f = f.parent();
}
}
void insert(frag_t f) {
_set.insert(f);
simplify();
}
void simplify() {
while (1) {
bool clean = true;
std::set<frag_t>::iterator p = _set.begin();
while (p != _set.end()) {
if (!p->is_root() &&
_set.count(p->get_sibling())) {
_set.erase(p->get_sibling());
_set.insert(p->parent());
_set.erase(p++);
clean = false;
} else {
p++;
}
}
if (clean)
break;
}
}
};
inline std::ostream& operator<<(std::ostream& out, const fragset_t& fs)
{
return out << "fragset_t(" << fs.get() << ")";
}
#endif
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