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Merge pull request #134 from Shopify/c_cursor 

C cursor
pull/34/head
Ben Johnson 2014-04-21 07:24:48 -06:00
parent 4b0c7e3d42 1bead4401c
commit afe8123d91
6 changed files with 631 additions and 5 deletions
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10
bucket.go
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@ -63,6 +63,16 @@ func newBucket(tx *Tx) Bucket {
return b
}
// Tx returns the tx of the bucket.
func (b *Bucket) Tx() *Tx {
return b.tx
}
// Root returns the root of the bucket.
func (b *Bucket) Root() pgid {
return b.root
}
// Writable returns whether the bucket is writable.
func (b *Bucket) Writable() bool {
return b.tx.writable

381
c/cursor.go Normal file
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@ -0,0 +1,381 @@
package c
/*
#include <stdint.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <inttypes.h>
//------------------------------------------------------------------------------
// Constants
//------------------------------------------------------------------------------
// This represents the maximum number of levels that a cursor can traverse.
#define MAX_DEPTH 100
// These flags mark the type of page and are set in the page.flags.
#define PAGE_BRANCH 0x01
#define PAGE_LEAF 0x02
#define PAGE_META 0x04
#define PAGE_FREELIST 0x10
//------------------------------------------------------------------------------
// Typedefs
//------------------------------------------------------------------------------
// These types MUST have the same layout as their corresponding Go types
typedef int64_t pgid;
// Page represents a header struct of a block in the mmap.
typedef struct page {
pgid id;
uint16_t flags;
uint16_t count;
uint32_t overflow;
} page;
// The branch element represents an a item in a branch page
// that points to a child page.
typedef struct branch_element {
uint32_t pos;
uint32_t ksize;
pgid pgid;
} branch_element;
// The leaf element represents an a item in a leaf page
// that points to a key/value pair.
typedef struct leaf_element {
uint32_t flags;
uint32_t pos;
uint32_t ksize;
uint32_t vsize;
} leaf_element;
// elem_ref represents a pointer to an element inside of a page.
// It is used by the cursor stack to track the position at each level.
typedef struct elem_ref {
page *page;
uint16_t index;
} elem_ref;
// bolt_val represents a pointer to a fixed-length series of bytes.
// It is used to represent keys and values returned by the cursor.
typedef struct bolt_val {
uint32_t size;
void *data;
} bolt_val;
// bolt_cursor represents a cursor attached to a bucket.
typedef struct bolt_cursor {
void *data;
pgid root;
size_t pgsz;
int top;
elem_ref stack[MAX_DEPTH];
} bolt_cursor;
//------------------------------------------------------------------------------
// Forward Declarations
//------------------------------------------------------------------------------
elem_ref *cursor_push(bolt_cursor *c, pgid id);
elem_ref *cursor_current(bolt_cursor *c);
elem_ref *cursor_pop(bolt_cursor *c);
void cursor_first_leaf(bolt_cursor *c);
void cursor_key_value(bolt_cursor *c, bolt_val *key, bolt_val *value, uint32_t *flags);
void cursor_search(bolt_cursor *c, bolt_val key, pgid id);
void cursor_search_branch(bolt_cursor *c, bolt_val key);
void cursor_search_leaf(bolt_cursor *c, bolt_val key);
//------------------------------------------------------------------------------
// Public Functions
//------------------------------------------------------------------------------
// Initializes a cursor.
void bolt_cursor_init(bolt_cursor *c, void *data, size_t pgsz, pgid root) {
c->data = data;
c->root = root;
c->pgsz = pgsz;
c->top = -1;
}
// Positions the cursor to the first leaf element and returns the key/value pair.
void bolt_cursor_first(bolt_cursor *c, bolt_val *key, bolt_val *value, uint32_t *flags) {
// reset stack to initial state
elem_ref *ref = cursor_push(c, c->root);
// Find first leaf and return key/value.
cursor_first_leaf(c);
cursor_key_value(c, key, value, flags);
}
// Positions the cursor to the next leaf element and returns the key/value pair.
void bolt_cursor_next(bolt_cursor *c, bolt_val *key, bolt_val *value, uint32_t *flags) {
int i;
elem_ref *ref;
// Attempt to move over one element until we're successful.
// Move up the stack as we hit the end of each page in our stack.
for (ref = cursor_current(c); ref != NULL; ref = cursor_current(c)) {
ref->index++;
if (ref->index < ref->page->count) break;
cursor_pop(c);
};
// If we are at the top of the stack then return a blank key/value pair.
if (ref == NULL) {
key->size = value->size = 0;
key->data = value->data = NULL;
*flags = 0;
return;
};
// Find first leaf and return key/value.
cursor_first_leaf(c);
cursor_key_value(c, key, value, flags);
}
// Positions the cursor first leaf element starting from a given key.
// If there is a matching key then the cursor will be place on that key.
// If there not a match then the cursor will be placed on the next key, if available.
void bolt_cursor_seek(bolt_cursor *c, bolt_val seek, bolt_val *key, bolt_val *value, uint32_t *flags) {
// Start from root page/node and traverse to correct page.
cursor_push(c, c->root);
if (seek.size > 0) cursor_search(c, seek, c->root);
elem_ref *ref = cursor_current(c);
// If the cursor is pointing to the end of page then return nil.
if (ref == NULL) {
key->size = value->size = 0;
key->data = value->data = NULL;
*flags = 0;
return;
};
// Find first leaf and return key/value.
cursor_first_leaf(c);
cursor_key_value(c, key, value, flags);
}
//------------------------------------------------------------------------------
// Private Functions
//------------------------------------------------------------------------------
// Push ref to the first element of the page onto the cursor stack
// If the page is the root page reset the stack to initial state
elem_ref *cursor_push(bolt_cursor *c, pgid id) {
elem_ref *ref;
if (id == c->root)
c->top = 0;
else
c->top++;
ref = &(c->stack[c->top]);
ref->page = (page *)(c->data + (c->pgsz * id));
ref->index = 0;
return ref;
}
// Return current element ref from the cursor stack
// If stack is empty return null
elem_ref *cursor_current(bolt_cursor *c) {
if (c->top < 0) return NULL;
return &c->stack[c->top];
}
// Pop current element ref off the cursor stack
elem_ref *cursor_pop(bolt_cursor *c) {
elem_ref *ref = cursor_current(c);
if (ref != NULL) c->top--;
return ref;
}
// Returns the branch element at a given index on a given page.
branch_element *page_branch_element(page *p, uint16_t index) {
branch_element *elements = (branch_element*)((void*)(p) + sizeof(page));
return &elements[index];
}
// Returns the leaf element at a given index on a given page.
leaf_element *page_leaf_element(page *p, uint16_t index) {
leaf_element *elements = (leaf_element*)((void*)(p) + sizeof(page));
return &elements[index];
}
// Returns the key/value pair for the current position of the cursor.
void cursor_key_value(bolt_cursor *c, bolt_val *key, bolt_val *value, uint32_t *flags) {
elem_ref *ref = cursor_current(c);
leaf_element *elem = page_leaf_element(ref->page,ref->index);
// Assign key pointer.
key->size = elem->ksize;
key->data = ((void*)elem) + elem->pos;
// Assign value pointer.
value->size = elem->vsize;
value->data = key->data + key->size;
// Return the element flags.
*flags = elem->flags;
}
// Traverses from the current stack position down to the first leaf element.
void cursor_first_leaf(bolt_cursor *c) {
elem_ref *ref = cursor_current(c);
while (ref->page->flags & PAGE_BRANCH) {
branch_element *elem = page_branch_element(ref->page,ref->index);
ref = cursor_push(c, elem->pgid);
};
}
// Recursively performs a binary search against a given page/node until it finds a given key.
void cursor_search(bolt_cursor *c, bolt_val key, pgid id) {
// Push page onto the cursor stack.
elem_ref *ref = cursor_push(c, id);
// If we're on a leaf page/node then find the specific node.
if (ref->page->flags & PAGE_LEAF) {
cursor_search_leaf(c, key);
return;
}
// Otherwise search the branch page.
cursor_search_branch(c, key);
}
// Recursively search over a leaf page for a key.
void cursor_search_leaf(bolt_cursor *c, bolt_val key) {
elem_ref *ref = cursor_current(c);
int i;
// HACK: Simply loop over elements to find the right one. Replace with a binary search.
leaf_element *elems = (leaf_element*)((void*)(ref->page) + sizeof(page));
for (i=0; i<ref->page->count; i++) {
leaf_element *elem = &elems[i];
int rc = memcmp(key.data, ((void*)elem) + elem->pos, (elem->ksize < key.size ? elem->ksize : key.size));
// printf("? %.*s | %.*s\n", key.size, key.data, elem->ksize, ((void*)elem) + elem->pos);
// printf("rc=%d; key.size(%d) >= elem->ksize(%d)\n", rc, key.size, elem->ksize);
if ((rc == 0 && key.size >= elem->ksize) || rc < 0) {
ref->index = i;
return;
}
}
// If nothing was greater than the key then pop the current page off the stack.
cursor_pop(c);
}
// Recursively search over a branch page for a key.
void cursor_search_branch(bolt_cursor *c, bolt_val key) {
elem_ref *ref = cursor_current(c);
int i;
// HACK: Simply loop over elements to find the right one. Replace with a binary search.
branch_element *elems = (branch_element*)((void*)(ref->page) + sizeof(page));
for (i=0; i<ref->page->count; i++) {
branch_element *elem = &elems[i];
int rc = memcmp(key.data, ((void*)elem) + elem->pos, (elem->ksize < key.size ? elem->ksize : key.size));
if (rc == 0 && key.size == elem->ksize) {
// exact match, done
ref->index = i;
return;
} else if ((rc == 0 && key.size < elem->ksize) || rc < 0) {
// if key is less than anything in this subtree we are done
if (i == 0) return;
// otherwise search the previous subtree
cursor_search(c, key, elems[i-1].pgid);
// didn't find anything greater than key?
if (cursor_current(c) == ref)
ref->index = i;
else
ref->index = i-1;
return;
}
}
// If nothing was greater than the key then pop the current page off the stack.
cursor_pop(c);
}
*/
import "C"
import (
"fmt"
"os"
"unsafe"
"github.com/boltdb/bolt"
)
// Cursor represents a wrapper around a Bolt C cursor.
type Cursor struct {
C *C.bolt_cursor
}
// NewCursor creates a C cursor from a Bucket.
func NewCursor(b *bolt.Bucket) *Cursor {
info := b.Tx().DB().Info()
root := b.Root()
c := &Cursor{C: new(C.bolt_cursor)}
C.bolt_cursor_init(c.C, unsafe.Pointer(&info.Data[0]), C.size_t(info.PageSize), C.pgid(root))
return c
}
// Next moves the cursor to the first element and returns the key and value.
// Returns a nil key if there are no elements.
func (c *Cursor) First() (key, value []byte) {
var k, v C.bolt_val
var flags C.uint32_t
C.bolt_cursor_first(c.C, &k, &v, &flags)
return C.GoBytes(k.data, C.int(k.size)), C.GoBytes(v.data, C.int(v.size))
}
// Next moves the cursor to the next element and returns the key and value.
// Returns a nil key if there are no more key/value pairs.
func (c *Cursor) Next() (key, value []byte) {
var k, v C.bolt_val
var flags C.uint32_t
C.bolt_cursor_next(c.C, &k, &v, &flags)
return C.GoBytes(k.data, C.int(k.size)), C.GoBytes(v.data, C.int(v.size))
}
// Seek moves the cursor to a given key and returns it.
// If the key does not exist then the next key is used. If no keys
// follow, an empty value is returned.
func (c *Cursor) Seek(seek []byte) (key, value []byte, flags int) {
var _flags C.uint32_t
var _seek, k, v C.bolt_val
if len(seek) > 0 {
_seek.size = C.uint32_t(len(seek))
_seek.data = unsafe.Pointer(&seek[0])
}
C.bolt_cursor_seek(c.C, _seek, &k, &v, &_flags)
//fmt.Printf("Key %v [%v]\n", k.data, k.size)
//fmt.Printf("Value %v [%v]\n", k.data, k.size)
if k.data == nil {
return nil, nil, 0
}
return C.GoBytes(k.data, C.int(k.size)), C.GoBytes(v.data, C.int(v.size)), int(_flags)
}
func warn(v ...interface{}) {
fmt.Fprintln(os.Stderr, v...)
}
func warnf(msg string, v ...interface{}) {
fmt.Fprintf(os.Stderr, msg+"\n", v...)
}

220
c/cursor_test.go Normal file
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@ -0,0 +1,220 @@
package c_test
import (
"fmt"
"io/ioutil"
"os"
"testing"
"github.com/boltdb/bolt"
. "github.com/boltdb/bolt/c"
"github.com/stretchr/testify/assert"
)
// Ensure that the C cursor can
func TestCursor_First(t *testing.T) {
withDB(func(db *bolt.DB) {
db.Update(func(tx *bolt.Tx) error {
b, _ := tx.CreateBucket([]byte("widgets"))
return b.Put([]byte("foo"), []byte("barz"))
})
db.View(func(tx *bolt.Tx) error {
c := NewCursor(tx.Bucket([]byte("widgets")))
key, value := c.First()
assert.Equal(t, []byte("foo"), key)
assert.Equal(t, []byte("barz"), value)
return nil
})
})
}
// Ensure that a C cursor can seek to the appropriate keys.
func TestCursor_Seek(t *testing.T) {
withDB(func(db *bolt.DB) {
db.Update(func(tx *bolt.Tx) error {
b, err := tx.CreateBucket([]byte("widgets"))
assert.NoError(t, err)
assert.NoError(t, b.Put([]byte("foo"), []byte("0001")))
assert.NoError(t, b.Put([]byte("bar"), []byte("0002")))
assert.NoError(t, b.Put([]byte("baz"), []byte("0003")))
_, err = b.CreateBucket([]byte("bkt"))
assert.NoError(t, err)
return nil
})
db.View(func(tx *bolt.Tx) error {
c := NewCursor(tx.Bucket([]byte("widgets")))
// Exact match should go to the key.
k, v, flags := c.Seek([]byte("bar"))
assert.Equal(t, "bar", string(k))
assert.Equal(t, "0002", string(v))
assert.Equal(t, 0, flags)
// Inexact match should go to the next key.
k, v, flags = c.Seek([]byte("bas"))
assert.Equal(t, "baz", string(k))
assert.Equal(t, "0003", string(v))
assert.Equal(t, 0, flags)
// Low key should go to the first key.
k, v, flags = c.Seek([]byte(""))
assert.Equal(t, "bar", string(k))
assert.Equal(t, "0002", string(v))
assert.Equal(t, 0, flags)
// High key should return no key.
k, v, flags = c.Seek([]byte("zzz"))
assert.Equal(t, "", string(k))
assert.Equal(t, "", string(v))
assert.Equal(t, 0, flags)
// Buckets should return their key but no value.
k, v, flags = c.Seek([]byte("bkt"))
assert.Equal(t, []byte("bkt"), k)
assert.True(t, len(v) > 0)
assert.Equal(t, 1, flags) // bucketLeafFlag
return nil
})
})
}
// Ensure that a C cursor can iterate over a single root with a couple elements.
func TestCursor_Iterate_Leaf(t *testing.T) {
withDB(func(db *bolt.DB) {
db.Update(func(tx *bolt.Tx) error {
tx.CreateBucket([]byte("widgets"))
tx.Bucket([]byte("widgets")).Put([]byte("baz"), []byte{})
tx.Bucket([]byte("widgets")).Put([]byte("foo"), []byte{0})
tx.Bucket([]byte("widgets")).Put([]byte("bar"), []byte{1})
return nil
})
db.View(func(tx *bolt.Tx) error {
c := NewCursor(tx.Bucket([]byte("widgets")))
k, v := c.First()
assert.Equal(t, string(k), "bar")
assert.Equal(t, []byte{1}, v)
k, v = c.Next()
assert.Equal(t, string(k), "baz")
assert.Equal(t, []byte{}, v)
k, v = c.Next()
assert.Equal(t, string(k), "foo")
assert.Equal(t, []byte{0}, v)
k, v = c.Next()
assert.Equal(t, []byte{}, k)
assert.Equal(t, []byte{}, v)
k, v = c.Next()
assert.Equal(t, []byte{}, k)
assert.Equal(t, []byte{}, v)
return nil
})
})
}
// Ensure that a C cursor can iterate over branches and leafs.
func TestCursor_Iterate_Large(t *testing.T) {
withDB(func(db *bolt.DB) {
db.Update(func(tx *bolt.Tx) error {
b, _ := tx.CreateBucket([]byte("widgets"))
for i := 0; i < 1000; i++ {
b.Put([]byte(fmt.Sprintf("%05d", i)), []byte(fmt.Sprintf("%020d", i)))
}
return nil
})
db.View(func(tx *bolt.Tx) error {
var index int
c := NewCursor(tx.Bucket([]byte("widgets")))
for k, v := c.First(); len(k) > 0; k, v = c.Next() {
assert.Equal(t, fmt.Sprintf("%05d", index), string(k))
assert.Equal(t, fmt.Sprintf("%020d", index), string(v))
index++
}
assert.Equal(t, 1000, index)
return nil
})
})
}
// Ensure that a C cursor can seek over branches and leafs.
func TestCursor_Seek_Large(t *testing.T) {
withDB(func(db *bolt.DB) {
db.Update(func(tx *bolt.Tx) error {
b, _ := tx.CreateBucket([]byte("widgets"))
for i := 1; i < 1000; i++ {
b.Put([]byte(fmt.Sprintf("%05d\000", i*10)), []byte(fmt.Sprintf("%020d", i*10)))
}
return nil
})
db.View(func(tx *bolt.Tx) error {
c := NewCursor(tx.Bucket([]byte("widgets")))
// Exact match should go to the key.
k, v, _ := c.Seek([]byte("05000\000"))
assert.Equal(t, "05000\000", string(k))
assert.Equal(t, fmt.Sprintf("%020d", 5000), string(v))
// Inexact match should go to the next key.
k, v, _ = c.Seek([]byte("07495\000"))
assert.Equal(t, "07500\000", string(k))
assert.Equal(t, fmt.Sprintf("%020d", 7500), string(v))
// Low key should go to the first key.
k, v, _ = c.Seek([]byte("00000\000"))
assert.Equal(t, "00010\000", string(k))
assert.Equal(t, fmt.Sprintf("%020d", 10), string(v))
// High key should return no key.
k, v, _ = c.Seek([]byte("40000\000"))
assert.Equal(t, "", string(k))
assert.Equal(t, "", string(v))
return nil
})
})
}
// tempfile returns a temporary path.
func tempfile() string {
f, _ := ioutil.TempFile("", "bolt-c-")
f.Close()
os.Remove(f.Name())
return f.Name()
}
// withDB executes a function with an already opened database.
func withDB(fn func(*bolt.DB)) {
path := tempfile()
db, err := bolt.Open(path, 0666)
if err != nil {
panic("cannot open db: " + err.Error())
}
defer os.Remove(path)
defer db.Close()
fn(db)
// Check database consistency after every test.
mustCheck(db)
}
// mustCheck runs a consistency check on the database and panics if any errors are found.
func mustCheck(db *bolt.DB) {
if err := db.Check(); err != nil {
// Copy db off first.
var path = tempfile()
db.CopyFile(path, 0600)
if errors, ok := err.(bolt.ErrorList); ok {
for _, err := range errors {
fmt.Println(err)
}
}
fmt.Println(err)
panic("check failure: " + path)
}
}

4
c/doc.go Normal file
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@ -0,0 +1,4 @@
/*
Package c provides a C interface to Bolt.
*/
package c

10
cursor_test.go
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@ -101,7 +101,7 @@ func TestCursor_EmptyBucketReverse(t *testing.T) {
}
// Ensure that a Tx cursor can iterate over a single root with a couple elements.
func TestCursor_LeafRoot(t *testing.T) {
func TestCursor_Iterate_Leaf(t *testing.T) {
withOpenDB(func(db *DB, path string) {
db.Update(func(tx *Tx) error {
tx.CreateBucket([]byte("widgets"))
@ -204,7 +204,7 @@ func TestCursor_Restart(t *testing.T) {
}
// Ensure that a Tx can iterate over all elements in a bucket.
func TestCursor_Iterate(t *testing.T) {
func TestCursor_QuickCheck(t *testing.T) {
f := func(items testdata) bool {
withOpenDB(func(db *DB, path string) {
// Bulk insert all values.
@ -239,7 +239,7 @@ func TestCursor_Iterate(t *testing.T) {
}
// Ensure that a transaction can iterate over all elements in a bucket in reverse.
func TestCursor_Iterate_Reverse(t *testing.T) {
func TestCursor_QuickCheck_Reverse(t *testing.T) {
f := func(items testdata) bool {
withOpenDB(func(db *DB, path string) {
// Bulk insert all values.
@ -274,7 +274,7 @@ func TestCursor_Iterate_Reverse(t *testing.T) {
}
// Ensure that a Tx cursor can iterate over subbuckets.
func TestCursor_Iterate_BucketsOnly(t *testing.T) {
func TestCursor_QuickCheck_BucketsOnly(t *testing.T) {
withOpenDB(func(db *DB, path string) {
db.Update(func(tx *Tx) error {
b, err := tx.CreateBucket([]byte("widgets"))
@ -301,7 +301,7 @@ func TestCursor_Iterate_BucketsOnly(t *testing.T) {
}
// Ensure that a Tx cursor can reverse iterate over subbuckets.
func TestCursor_Iterate_BucketsOnly_Reverse(t *testing.T) {
func TestCursor_QuickCheck_BucketsOnly_Reverse(t *testing.T) {
withOpenDB(func(db *DB, path string) {
db.Update(func(tx *Tx) error {
b, err := tx.CreateBucket([]byte("widgets"))

11
db.go
View File

@ -578,6 +578,12 @@ func (db *DB) checkBucket(b *Bucket, reachable map[pgid]*page, errors *ErrorList
})
}
// This is for internal access to the raw data bytes from the C cursor, use
// carefully, or not at all.
func (db *DB) Info() *Info {
return &Info{db.data, db.pageSize}
}
// page retrieves a page reference from the mmap based on the current page size.
func (db *DB) page(id pgid) *page {
pos := id * pgid(db.pageSize)
@ -641,3 +647,8 @@ func (s *Stats) Sub(other *Stats) Stats {
func (s *Stats) add(other *Stats) {
s.TxStats.add(&other.TxStats)
}
type Info struct {
Data []byte
PageSize int
}