git/refs/iterator.c

/*
 * Generic reference iterator infrastructure. See refs-internal.h for
 * documentation about the design and use of reference iterators.
 */

#include "cache.h"
#include "refs.h"
#include "refs/refs-internal.h"
#include "iterator.h"

int ref_iterator_advance(struct ref_iterator *ref_iterator)
{
	return ref_iterator->vtable->advance(ref_iterator);
}

int ref_iterator_peel(struct ref_iterator *ref_iterator,
		      struct object_id *peeled)
{
	return ref_iterator->vtable->peel(ref_iterator, peeled);
}

int ref_iterator_abort(struct ref_iterator *ref_iterator)
{
	return ref_iterator->vtable->abort(ref_iterator);
}

void base_ref_iterator_init(struct ref_iterator *iter,
			    struct ref_iterator_vtable *vtable)
{
	iter->vtable = vtable;
	iter->refname = NULL;
	iter->oid = NULL;
	iter->flags = 0;
}

void base_ref_iterator_free(struct ref_iterator *iter)
{
	/* Help make use-after-free bugs fail quickly: */
	iter->vtable = NULL;
	free(iter);
}

struct empty_ref_iterator {
	struct ref_iterator base;
};

static int empty_ref_iterator_advance(struct ref_iterator *ref_iterator)
{
	return ref_iterator_abort(ref_iterator);
}

static int empty_ref_iterator_peel(struct ref_iterator *ref_iterator,
				   struct object_id *peeled)
{
	die("BUG: peel called for empty iterator");
}

static int empty_ref_iterator_abort(struct ref_iterator *ref_iterator)
{
	base_ref_iterator_free(ref_iterator);
	return ITER_DONE;
}

static struct ref_iterator_vtable empty_ref_iterator_vtable = {
	empty_ref_iterator_advance,
	empty_ref_iterator_peel,
	empty_ref_iterator_abort
};

struct ref_iterator *empty_ref_iterator_begin(void)
{
	struct empty_ref_iterator *iter = xcalloc(1, sizeof(*iter));
	struct ref_iterator *ref_iterator = &iter->base;

	base_ref_iterator_init(ref_iterator, &empty_ref_iterator_vtable);
	return ref_iterator;
}

int is_empty_ref_iterator(struct ref_iterator *ref_iterator)
{
	return ref_iterator->vtable == &empty_ref_iterator_vtable;
}

struct merge_ref_iterator {
	struct ref_iterator base;

	struct ref_iterator *iter0, *iter1;

	ref_iterator_select_fn *select;
	void *cb_data;

	/*
	 * A pointer to iter0 or iter1 (whichever is supplying the
	 * current value), or NULL if advance has not yet been called.
	 */
	struct ref_iterator **current;
};

static int merge_ref_iterator_advance(struct ref_iterator *ref_iterator)
{
	struct merge_ref_iterator *iter =
		(struct merge_ref_iterator *)ref_iterator;
	int ok;

	if (!iter->current) {
		/* Initialize: advance both iterators to their first entries */
		if ((ok = ref_iterator_advance(iter->iter0)) != ITER_OK) {
			iter->iter0 = NULL;
			if (ok == ITER_ERROR)
				goto error;
		}
		if ((ok = ref_iterator_advance(iter->iter1)) != ITER_OK) {
			iter->iter1 = NULL;
			if (ok == ITER_ERROR)
				goto error;
		}
	} else {
		/*
		 * Advance the current iterator past the just-used
		 * entry:
		 */
		if ((ok = ref_iterator_advance(*iter->current)) != ITER_OK) {
			*iter->current = NULL;
			if (ok == ITER_ERROR)
				goto error;
		}
	}

	/* Loop until we find an entry that we can yield. */
	while (1) {
		struct ref_iterator **secondary;
		enum iterator_selection selection =
			iter->select(iter->iter0, iter->iter1, iter->cb_data);

		if (selection == ITER_SELECT_DONE) {
			return ref_iterator_abort(ref_iterator);
		} else if (selection == ITER_SELECT_ERROR) {
			ref_iterator_abort(ref_iterator);
			return ITER_ERROR;
		}

		if ((selection & ITER_CURRENT_SELECTION_MASK) == 0) {
			iter->current = &iter->iter0;
			secondary = &iter->iter1;
		} else {
			iter->current = &iter->iter1;
			secondary = &iter->iter0;
		}

		if (selection & ITER_SKIP_SECONDARY) {
			if ((ok = ref_iterator_advance(*secondary)) != ITER_OK) {
				*secondary = NULL;
				if (ok == ITER_ERROR)
					goto error;
			}
		}

		if (selection & ITER_YIELD_CURRENT) {
			iter->base.refname = (*iter->current)->refname;
			iter->base.oid = (*iter->current)->oid;
			iter->base.flags = (*iter->current)->flags;
			return ITER_OK;
		}
	}

error:
	ref_iterator_abort(ref_iterator);
	return ITER_ERROR;
}

static int merge_ref_iterator_peel(struct ref_iterator *ref_iterator,
				   struct object_id *peeled)
{
	struct merge_ref_iterator *iter =
		(struct merge_ref_iterator *)ref_iterator;

	if (!iter->current) {
		die("BUG: peel called before advance for merge iterator");
	}
	return ref_iterator_peel(*iter->current, peeled);
}

static int merge_ref_iterator_abort(struct ref_iterator *ref_iterator)
{
	struct merge_ref_iterator *iter =
		(struct merge_ref_iterator *)ref_iterator;
	int ok = ITER_DONE;

	if (iter->iter0) {
		if (ref_iterator_abort(iter->iter0) != ITER_DONE)
			ok = ITER_ERROR;
	}
	if (iter->iter1) {
		if (ref_iterator_abort(iter->iter1) != ITER_DONE)
			ok = ITER_ERROR;
	}
	base_ref_iterator_free(ref_iterator);
	return ok;
}

static struct ref_iterator_vtable merge_ref_iterator_vtable = {
	merge_ref_iterator_advance,
	merge_ref_iterator_peel,
	merge_ref_iterator_abort
};

struct ref_iterator *merge_ref_iterator_begin(
		struct ref_iterator *iter0, struct ref_iterator *iter1,
		ref_iterator_select_fn *select, void *cb_data)
{
	struct merge_ref_iterator *iter = xcalloc(1, sizeof(*iter));
	struct ref_iterator *ref_iterator = &iter->base;

	/*
	 * We can't do the same kind of is_empty_ref_iterator()-style
	 * optimization here as overlay_ref_iterator_begin() does,
	 * because we don't know the semantics of the select function.
	 * It might, for example, implement "intersect" by passing
	 * references through only if they exist in both iterators.
	 */

	base_ref_iterator_init(ref_iterator, &merge_ref_iterator_vtable);
	iter->iter0 = iter0;
	iter->iter1 = iter1;
	iter->select = select;
	iter->cb_data = cb_data;
	iter->current = NULL;
	return ref_iterator;
}

/*
 * A ref_iterator_select_fn that overlays the items from front on top
 * of those from back (like loose refs over packed refs). See
 * overlay_ref_iterator_begin().
 */
static enum iterator_selection overlay_iterator_select(
		struct ref_iterator *front, struct ref_iterator *back,
		void *cb_data)
{
	int cmp;

	if (!back)
		return front ? ITER_SELECT_0 : ITER_SELECT_DONE;
	else if (!front)
		return ITER_SELECT_1;

	cmp = strcmp(front->refname, back->refname);

	if (cmp < 0)
		return ITER_SELECT_0;
	else if (cmp > 0)
		return ITER_SELECT_1;
	else
		return ITER_SELECT_0_SKIP_1;
}

struct ref_iterator *overlay_ref_iterator_begin(
		struct ref_iterator *front, struct ref_iterator *back)
{
	/*
	 * Optimization: if one of the iterators is empty, return the
	 * other one rather than incurring the overhead of wrapping
	 * them.
	 */
	if (is_empty_ref_iterator(front)) {
		ref_iterator_abort(front);
		return back;
	} else if (is_empty_ref_iterator(back)) {
		ref_iterator_abort(back);
		return front;
	}

	return merge_ref_iterator_begin(front, back,
					overlay_iterator_select, NULL);
}

struct prefix_ref_iterator {
	struct ref_iterator base;

	struct ref_iterator *iter0;
	char *prefix;
	int trim;
};

static int prefix_ref_iterator_advance(struct ref_iterator *ref_iterator)
{
	struct prefix_ref_iterator *iter =
		(struct prefix_ref_iterator *)ref_iterator;
	int ok;

	while ((ok = ref_iterator_advance(iter->iter0)) == ITER_OK) {
		if (!starts_with(iter->iter0->refname, iter->prefix))
			continue;

		iter->base.refname = iter->iter0->refname + iter->trim;
		iter->base.oid = iter->iter0->oid;
		iter->base.flags = iter->iter0->flags;
		return ITER_OK;
	}

	iter->iter0 = NULL;
	if (ref_iterator_abort(ref_iterator) != ITER_DONE)
		return ITER_ERROR;
	return ok;
}

static int prefix_ref_iterator_peel(struct ref_iterator *ref_iterator,
				    struct object_id *peeled)
{
	struct prefix_ref_iterator *iter =
		(struct prefix_ref_iterator *)ref_iterator;

	return ref_iterator_peel(iter->iter0, peeled);
}

static int prefix_ref_iterator_abort(struct ref_iterator *ref_iterator)
{
	struct prefix_ref_iterator *iter =
		(struct prefix_ref_iterator *)ref_iterator;
	int ok = ITER_DONE;

	if (iter->iter0)
		ok = ref_iterator_abort(iter->iter0);
	free(iter->prefix);
	base_ref_iterator_free(ref_iterator);
	return ok;
}

static struct ref_iterator_vtable prefix_ref_iterator_vtable = {
	prefix_ref_iterator_advance,
	prefix_ref_iterator_peel,
	prefix_ref_iterator_abort
};

struct ref_iterator *prefix_ref_iterator_begin(struct ref_iterator *iter0,
					       const char *prefix,
					       int trim)
{
	struct prefix_ref_iterator *iter;
	struct ref_iterator *ref_iterator;

	if (!*prefix && !trim)
		return iter0; /* optimization: no need to wrap iterator */

	iter = xcalloc(1, sizeof(*iter));
	ref_iterator = &iter->base;

	base_ref_iterator_init(ref_iterator, &prefix_ref_iterator_vtable);

	iter->iter0 = iter0;
	iter->prefix = xstrdup(prefix);
	iter->trim = trim;

	return ref_iterator;
}
refs: introduce an iterator interface Currently, the API for iterating over references is via a family of for_each_ref()-type functions that invoke a callback function for each selected reference. All of these eventually call do_for_each_ref(), which knows how to do one thing: iterate in parallel through two ref_caches, one for loose and one for packed refs, giving loose references precedence over packed refs. This is rather complicated code, and is quite specialized to the files backend. It also requires callers to encapsulate their work into a callback function, which often means that they have to define and use a "cb_data" struct to manage their context. The current design is already bursting at the seams, and will become even more awkward in the upcoming world of multiple reference storage backends: * Per-worktree vs. shared references are currently handled via a kludge in git_path() rather than iterating over each part of the reference namespace separately and merging the results. This kludge will cease to work when we have multiple reference storage backends. * The current scheme is inflexible. What if we sometimes want to bypass the ref_cache, or use it only for packed or only for loose refs? What if we want to store symbolic refs in one type of storage backend and non-symbolic ones in another? In the future, each reference backend will need to define its own way of iterating over references. The crux of the problem with the current design is that it is impossible to compose for_each_ref()-style iterations, because the flow of control is owned by the for_each_ref() function. There is nothing that a caller can do but iterate through all references in a single burst, so there is no way for it to interleave references from multiple backends and present the result to the rest of the world as a single compound backend. This commit introduces a new iteration primitive for references: a ref_iterator. A ref_iterator is a polymorphic object that a reference storage backend can be asked to instantiate. There are three functions that can be applied to a ref_iterator: * ref_iterator_advance(): move to the next reference in the iteration * ref_iterator_abort(): end the iteration before it is exhausted * ref_iterator_peel(): peel the reference currently being looked at Iterating using a ref_iterator leaves the flow of control in the hands of the caller, which means that ref_iterators from multiple sources (e.g., loose and packed refs) can be composed and presented to the world as a single compound ref_iterator. It also means that the backend code for implementing reference iteration will sometimes be more complicated. For example, the cache_ref_iterator (which iterates over a ref_cache) can't use the C stack to recurse; instead, it must manage its own stack internally as explicit data structures. There is also a lot of boilerplate connected with object-oriented programming in C. Eventually, end-user callers will be able to be written in a more natural way—managing their own flow of control rather than having to work via callbacks. Since there will only be a few reference backends but there are many consumers of this API, this is a good tradeoff. More importantly, we gain composability, and especially the possibility of writing interchangeable parts that can work with any ref_iterator. For example, merge_ref_iterator implements a generic way of merging the contents of any two ref_iterators. It is used to merge loose + packed refs as part of the implementation of the files_ref_iterator. But it will also be possible to use it to merge other pairs of reference sources (e.g., per-worktree vs. shared refs). Another example is prefix_ref_iterator, which can be used to trim a prefix off the front of reference names before presenting them to the caller (e.g., "refs/heads/master" -> "master"). In this patch, we introduce the iterator abstraction and many utilities, and implement a reference iterator for the files ref storage backend. (I've written several other obvious utilities, for example a generic way to filter references being iterated over. These will probably be useful in the future. But they are not needed for this patch series, so I am not including them at this time.) In a moment we will rewrite do_for_each_ref() to work via reference iterators (allowing some special-purpose code to be discarded), and do something similar for reflogs. In future patch series, we will expose the ref_iterator abstraction in the public refs API so that callers can use it directly. Implementation note: I tried abstracting this a layer further to allow generic iterators (over arbitrary types of objects) and generic utilities like a generic merge_iterator. But the implementation in C was very cumbersome, involving (in my opinion) too much boilerplate and too much unsafe casting, some of which would have had to be done on the caller side. However, I did put a few iterator-related constants in a top-level header file, iterator.h, as they will be useful in a moment to implement iteration over directory trees and possibly other types of iterators in the future. Signed-off-by: Ramsay Jones <ramsay@ramsayjones.plus.com> Signed-off-by: Michael Haggerty <mhagger@alum.mit.edu> Signed-off-by: Junio C Hamano <gitster@pobox.com> 2016-06-18 06:15:15 +02:00			`/*`
			`* Generic reference iterator infrastructure. See refs-internal.h for`
			`* documentation about the design and use of reference iterators.`
			`*/`

			`#include "cache.h"`
			`#include "refs.h"`
			`#include "refs/refs-internal.h"`
			`#include "iterator.h"`

			`int ref_iterator_advance(struct ref_iterator *ref_iterator)`
			`{`
			`return ref_iterator->vtable->advance(ref_iterator);`
			`}`

			`int ref_iterator_peel(struct ref_iterator *ref_iterator,`
			`struct object_id *peeled)`
			`{`
			`return ref_iterator->vtable->peel(ref_iterator, peeled);`
			`}`

			`int ref_iterator_abort(struct ref_iterator *ref_iterator)`
			`{`
			`return ref_iterator->vtable->abort(ref_iterator);`
			`}`

			`void base_ref_iterator_init(struct ref_iterator *iter,`
			`struct ref_iterator_vtable *vtable)`
			`{`
			`iter->vtable = vtable;`
			`iter->refname = NULL;`
			`iter->oid = NULL;`
			`iter->flags = 0;`
			`}`

			`void base_ref_iterator_free(struct ref_iterator *iter)`
			`{`
			`/* Help make use-after-free bugs fail quickly: */`
			`iter->vtable = NULL;`
			`free(iter);`
			`}`

			`struct empty_ref_iterator {`
			`struct ref_iterator base;`
			`};`

			`static int empty_ref_iterator_advance(struct ref_iterator *ref_iterator)`
			`{`
			`return ref_iterator_abort(ref_iterator);`
			`}`

			`static int empty_ref_iterator_peel(struct ref_iterator *ref_iterator,`
			`struct object_id *peeled)`
			`{`
			`die("BUG: peel called for empty iterator");`
			`}`

			`static int empty_ref_iterator_abort(struct ref_iterator *ref_iterator)`
			`{`
			`base_ref_iterator_free(ref_iterator);`
			`return ITER_DONE;`
			`}`

			`static struct ref_iterator_vtable empty_ref_iterator_vtable = {`
			`empty_ref_iterator_advance,`
			`empty_ref_iterator_peel,`
			`empty_ref_iterator_abort`
			`};`

			`struct ref_iterator *empty_ref_iterator_begin(void)`
			`{`
			`struct empty_ref_iterator iter = xcalloc(1, sizeof(iter));`
			`struct ref_iterator *ref_iterator = &iter->base;`

			`base_ref_iterator_init(ref_iterator, &empty_ref_iterator_vtable);`
			`return ref_iterator;`
			`}`

			`int is_empty_ref_iterator(struct ref_iterator *ref_iterator)`
			`{`
			`return ref_iterator->vtable == &empty_ref_iterator_vtable;`
			`}`

			`struct merge_ref_iterator {`
			`struct ref_iterator base;`

			`struct ref_iterator iter0, iter1;`

			`ref_iterator_select_fn *select;`
			`void *cb_data;`

			`/*`
			`* A pointer to iter0 or iter1 (whichever is supplying the`
			`* current value), or NULL if advance has not yet been called.`
			`*/`
			`struct ref_iterator **current;`
			`};`

			`static int merge_ref_iterator_advance(struct ref_iterator *ref_iterator)`
			`{`
			`struct merge_ref_iterator *iter =`
			`(struct merge_ref_iterator *)ref_iterator;`
			`int ok;`

			`if (!iter->current) {`
			`/* Initialize: advance both iterators to their first entries */`
			`if ((ok = ref_iterator_advance(iter->iter0)) != ITER_OK) {`
			`iter->iter0 = NULL;`
			`if (ok == ITER_ERROR)`
			`goto error;`
			`}`
			`if ((ok = ref_iterator_advance(iter->iter1)) != ITER_OK) {`
			`iter->iter1 = NULL;`
			`if (ok == ITER_ERROR)`
			`goto error;`
			`}`
			`} else {`
			`/*`
			`* Advance the current iterator past the just-used`
			`* entry:`
			`*/`
			`if ((ok = ref_iterator_advance(*iter->current)) != ITER_OK) {`
			`*iter->current = NULL;`
			`if (ok == ITER_ERROR)`
			`goto error;`
			`}`
			`}`

			`/* Loop until we find an entry that we can yield. */`
			`while (1) {`
			`struct ref_iterator **secondary;`
			`enum iterator_selection selection =`
			`iter->select(iter->iter0, iter->iter1, iter->cb_data);`

			`if (selection == ITER_SELECT_DONE) {`
			`return ref_iterator_abort(ref_iterator);`
			`} else if (selection == ITER_SELECT_ERROR) {`
			`ref_iterator_abort(ref_iterator);`
			`return ITER_ERROR;`
			`}`

			`if ((selection & ITER_CURRENT_SELECTION_MASK) == 0) {`
			`iter->current = &iter->iter0;`
			`secondary = &iter->iter1;`
			`} else {`
			`iter->current = &iter->iter1;`
			`secondary = &iter->iter0;`
			`}`

			`if (selection & ITER_SKIP_SECONDARY) {`
			`if ((ok = ref_iterator_advance(*secondary)) != ITER_OK) {`
			`*secondary = NULL;`
			`if (ok == ITER_ERROR)`
			`goto error;`
			`}`
			`}`

			`if (selection & ITER_YIELD_CURRENT) {`
			`iter->base.refname = (*iter->current)->refname;`
			`iter->base.oid = (*iter->current)->oid;`
			`iter->base.flags = (*iter->current)->flags;`
			`return ITER_OK;`
			`}`
			`}`

			`error:`
			`ref_iterator_abort(ref_iterator);`
			`return ITER_ERROR;`
			`}`

			`static int merge_ref_iterator_peel(struct ref_iterator *ref_iterator,`
			`struct object_id *peeled)`
			`{`
			`struct merge_ref_iterator *iter =`
			`(struct merge_ref_iterator *)ref_iterator;`

			`if (!iter->current) {`
			`die("BUG: peel called before advance for merge iterator");`
			`}`
			`return ref_iterator_peel(*iter->current, peeled);`
			`}`

			`static int merge_ref_iterator_abort(struct ref_iterator *ref_iterator)`
			`{`
			`struct merge_ref_iterator *iter =`
			`(struct merge_ref_iterator *)ref_iterator;`
			`int ok = ITER_DONE;`

			`if (iter->iter0) {`
			`if (ref_iterator_abort(iter->iter0) != ITER_DONE)`
			`ok = ITER_ERROR;`
			`}`
			`if (iter->iter1) {`
			`if (ref_iterator_abort(iter->iter1) != ITER_DONE)`
			`ok = ITER_ERROR;`
			`}`
			`base_ref_iterator_free(ref_iterator);`
			`return ok;`
			`}`

			`static struct ref_iterator_vtable merge_ref_iterator_vtable = {`
			`merge_ref_iterator_advance,`
			`merge_ref_iterator_peel,`
			`merge_ref_iterator_abort`
			`};`

			`struct ref_iterator *merge_ref_iterator_begin(`
			`struct ref_iterator iter0, struct ref_iterator iter1,`
			`ref_iterator_select_fn select, void cb_data)`
			`{`
			`struct merge_ref_iterator iter = xcalloc(1, sizeof(iter));`
			`struct ref_iterator *ref_iterator = &iter->base;`

			`/*`
			`* We can't do the same kind of is_empty_ref_iterator()-style`
			`* optimization here as overlay_ref_iterator_begin() does,`
			`* because we don't know the semantics of the select function.`
			`* It might, for example, implement "intersect" by passing`
			`* references through only if they exist in both iterators.`
			`*/`

			`base_ref_iterator_init(ref_iterator, &merge_ref_iterator_vtable);`
			`iter->iter0 = iter0;`
			`iter->iter1 = iter1;`
			`iter->select = select;`
			`iter->cb_data = cb_data;`
			`iter->current = NULL;`
			`return ref_iterator;`
			`}`

			`/*`
			`* A ref_iterator_select_fn that overlays the items from front on top`
			`* of those from back (like loose refs over packed refs). See`
			`* overlay_ref_iterator_begin().`
			`*/`
			`static enum iterator_selection overlay_iterator_select(`
			`struct ref_iterator front, struct ref_iterator back,`
			`void *cb_data)`
			`{`
			`int cmp;`

			`if (!back)`
			`return front ? ITER_SELECT_0 : ITER_SELECT_DONE;`
			`else if (!front)`
			`return ITER_SELECT_1;`

			`cmp = strcmp(front->refname, back->refname);`

			`if (cmp < 0)`
			`return ITER_SELECT_0;`
			`else if (cmp > 0)`
			`return ITER_SELECT_1;`
			`else`
			`return ITER_SELECT_0_SKIP_1;`
			`}`

			`struct ref_iterator *overlay_ref_iterator_begin(`
			`struct ref_iterator front, struct ref_iterator back)`
			`{`
			`/*`
			`* Optimization: if one of the iterators is empty, return the`
			`* other one rather than incurring the overhead of wrapping`
			`* them.`
			`*/`
			`if (is_empty_ref_iterator(front)) {`
			`ref_iterator_abort(front);`
			`return back;`
			`} else if (is_empty_ref_iterator(back)) {`
			`ref_iterator_abort(back);`
			`return front;`
			`}`

			`return merge_ref_iterator_begin(front, back,`
			`overlay_iterator_select, NULL);`
			`}`

			`struct prefix_ref_iterator {`
			`struct ref_iterator base;`

			`struct ref_iterator *iter0;`
			`char *prefix;`
			`int trim;`
			`};`

			`static int prefix_ref_iterator_advance(struct ref_iterator *ref_iterator)`
			`{`
			`struct prefix_ref_iterator *iter =`
			`(struct prefix_ref_iterator *)ref_iterator;`
			`int ok;`

			`while ((ok = ref_iterator_advance(iter->iter0)) == ITER_OK) {`
			`if (!starts_with(iter->iter0->refname, iter->prefix))`
			`continue;`

			`iter->base.refname = iter->iter0->refname + iter->trim;`
			`iter->base.oid = iter->iter0->oid;`
			`iter->base.flags = iter->iter0->flags;`
			`return ITER_OK;`
			`}`

			`iter->iter0 = NULL;`
			`if (ref_iterator_abort(ref_iterator) != ITER_DONE)`
			`return ITER_ERROR;`
			`return ok;`
			`}`

			`static int prefix_ref_iterator_peel(struct ref_iterator *ref_iterator,`
			`struct object_id *peeled)`
			`{`
			`struct prefix_ref_iterator *iter =`
			`(struct prefix_ref_iterator *)ref_iterator;`

			`return ref_iterator_peel(iter->iter0, peeled);`
			`}`

			`static int prefix_ref_iterator_abort(struct ref_iterator *ref_iterator)`
			`{`
			`struct prefix_ref_iterator *iter =`
			`(struct prefix_ref_iterator *)ref_iterator;`
			`int ok = ITER_DONE;`

			`if (iter->iter0)`
			`ok = ref_iterator_abort(iter->iter0);`
			`free(iter->prefix);`
			`base_ref_iterator_free(ref_iterator);`
			`return ok;`
			`}`

			`static struct ref_iterator_vtable prefix_ref_iterator_vtable = {`
			`prefix_ref_iterator_advance,`
			`prefix_ref_iterator_peel,`
			`prefix_ref_iterator_abort`
			`};`

			`struct ref_iterator prefix_ref_iterator_begin(struct ref_iterator iter0,`
			`const char *prefix,`
			`int trim)`
			`{`
			`struct prefix_ref_iterator *iter;`
			`struct ref_iterator *ref_iterator;`

			`if (!*prefix && !trim)`
			`return iter0; /* optimization: no need to wrap iterator */`

			`iter = xcalloc(1, sizeof(*iter));`
			`ref_iterator = &iter->base;`

			`base_ref_iterator_init(ref_iterator, &prefix_ref_iterator_vtable);`

			`iter->iter0 = iter0;`
			`iter->prefix = xstrdup(prefix);`
			`iter->trim = trim;`

			`return ref_iterator;`
			`}`