xemu/util/iova-tree.c
Eugenio Pérez 69292a8e40 util: accept iova_tree_remove_parameter by value
It's convenient to call iova_tree_remove from a map returned from
iova_tree_find or iova_tree_find_iova. With the current code this is not
possible, since we will free it, and then we will try to search for it
again.

Fix it making accepting the map by value, forcing a copy of the
argument. Not applying a fixes tag, since there is no use like that at
the moment.

Signed-off-by: Eugenio Pérez <eperezma@redhat.com>
Signed-off-by: Jason Wang <jasowang@redhat.com>
2022-09-02 10:22:39 +08:00

283 lines
7.0 KiB
C

/*
* IOVA tree implementation based on GTree.
*
* Copyright 2018 Red Hat, Inc.
*
* Authors:
* Peter Xu <peterx@redhat.com>
*
* This work is licensed under the terms of the GNU GPL, version 2 or later.
*/
#include "qemu/osdep.h"
#include "qemu/iova-tree.h"
struct IOVATree {
GTree *tree;
};
/* Args to pass to iova_tree_alloc foreach function. */
struct IOVATreeAllocArgs {
/* Size of the desired allocation */
size_t new_size;
/* The minimum address allowed in the allocation */
hwaddr iova_begin;
/* Map at the left of the hole, can be NULL if "this" is first one */
const DMAMap *prev;
/* Map at the right of the hole, can be NULL if "prev" is the last one */
const DMAMap *this;
/* If found, we fill in the IOVA here */
hwaddr iova_result;
/* Whether have we found a valid IOVA */
bool iova_found;
};
typedef struct IOVATreeFindIOVAArgs {
const DMAMap *needle;
const DMAMap *result;
} IOVATreeFindIOVAArgs;
/**
* Iterate args to the next hole
*
* @args: The alloc arguments
* @next: The next mapping in the tree. Can be NULL to signal the last one
*/
static void iova_tree_alloc_args_iterate(struct IOVATreeAllocArgs *args,
const DMAMap *next)
{
args->prev = args->this;
args->this = next;
}
static int iova_tree_compare(gconstpointer a, gconstpointer b, gpointer data)
{
const DMAMap *m1 = a, *m2 = b;
if (m1->iova > m2->iova + m2->size) {
return 1;
}
if (m1->iova + m1->size < m2->iova) {
return -1;
}
/* Overlapped */
return 0;
}
IOVATree *iova_tree_new(void)
{
IOVATree *iova_tree = g_new0(IOVATree, 1);
/* We don't have values actually, no need to free */
iova_tree->tree = g_tree_new_full(iova_tree_compare, NULL, g_free, NULL);
return iova_tree;
}
const DMAMap *iova_tree_find(const IOVATree *tree, const DMAMap *map)
{
return g_tree_lookup(tree->tree, map);
}
static gboolean iova_tree_find_address_iterator(gpointer key, gpointer value,
gpointer data)
{
const DMAMap *map = key;
IOVATreeFindIOVAArgs *args = data;
const DMAMap *needle;
g_assert(key == value);
needle = args->needle;
if (map->translated_addr + map->size < needle->translated_addr ||
needle->translated_addr + needle->size < map->translated_addr) {
return false;
}
args->result = map;
return true;
}
const DMAMap *iova_tree_find_iova(const IOVATree *tree, const DMAMap *map)
{
IOVATreeFindIOVAArgs args = {
.needle = map,
};
g_tree_foreach(tree->tree, iova_tree_find_address_iterator, &args);
return args.result;
}
const DMAMap *iova_tree_find_address(const IOVATree *tree, hwaddr iova)
{
const DMAMap map = { .iova = iova, .size = 0 };
return iova_tree_find(tree, &map);
}
static inline void iova_tree_insert_internal(GTree *gtree, DMAMap *range)
{
/* Key and value are sharing the same range data */
g_tree_insert(gtree, range, range);
}
int iova_tree_insert(IOVATree *tree, const DMAMap *map)
{
DMAMap *new;
if (map->iova + map->size < map->iova || map->perm == IOMMU_NONE) {
return IOVA_ERR_INVALID;
}
/* We don't allow to insert range that overlaps with existings */
if (iova_tree_find(tree, map)) {
return IOVA_ERR_OVERLAP;
}
new = g_new0(DMAMap, 1);
memcpy(new, map, sizeof(*new));
iova_tree_insert_internal(tree->tree, new);
return IOVA_OK;
}
static gboolean iova_tree_traverse(gpointer key, gpointer value,
gpointer data)
{
iova_tree_iterator iterator = data;
DMAMap *map = key;
g_assert(key == value);
return iterator(map);
}
void iova_tree_foreach(IOVATree *tree, iova_tree_iterator iterator)
{
g_tree_foreach(tree->tree, iova_tree_traverse, iterator);
}
void iova_tree_remove(IOVATree *tree, DMAMap map)
{
const DMAMap *overlap;
while ((overlap = iova_tree_find(tree, &map))) {
g_tree_remove(tree->tree, overlap);
}
}
/**
* Try to find an unallocated IOVA range between prev and this elements.
*
* @args: Arguments to allocation
*
* Cases:
*
* (1) !prev, !this: No entries allocated, always succeed
*
* (2) !prev, this: We're iterating at the 1st element.
*
* (3) prev, !this: We're iterating at the last element.
*
* (4) prev, this: this is the most common case, we'll try to find a hole
* between "prev" and "this" mapping.
*
* Note that this function assumes the last valid iova is HWADDR_MAX, but it
* searches linearly so it's easy to discard the result if it's not the case.
*/
static void iova_tree_alloc_map_in_hole(struct IOVATreeAllocArgs *args)
{
const DMAMap *prev = args->prev, *this = args->this;
uint64_t hole_start, hole_last;
if (this && this->iova + this->size < args->iova_begin) {
return;
}
hole_start = MAX(prev ? prev->iova + prev->size + 1 : 0, args->iova_begin);
hole_last = this ? this->iova : HWADDR_MAX;
if (hole_last - hole_start > args->new_size) {
args->iova_result = hole_start;
args->iova_found = true;
}
}
/**
* Foreach dma node in the tree, compare if there is a hole with its previous
* node (or minimum iova address allowed) and the node.
*
* @key: Node iterating
* @value: Node iterating
* @pargs: Struct to communicate with the outside world
*
* Return: false to keep iterating, true if needs break.
*/
static gboolean iova_tree_alloc_traverse(gpointer key, gpointer value,
gpointer pargs)
{
struct IOVATreeAllocArgs *args = pargs;
DMAMap *node = value;
assert(key == value);
iova_tree_alloc_args_iterate(args, node);
iova_tree_alloc_map_in_hole(args);
return args->iova_found;
}
int iova_tree_alloc_map(IOVATree *tree, DMAMap *map, hwaddr iova_begin,
hwaddr iova_last)
{
struct IOVATreeAllocArgs args = {
.new_size = map->size,
.iova_begin = iova_begin,
};
if (unlikely(iova_last < iova_begin)) {
return IOVA_ERR_INVALID;
}
/*
* Find a valid hole for the mapping
*
* Assuming low iova_begin, so no need to do a binary search to
* locate the first node.
*
* TODO: Replace all this with g_tree_node_first/next/last when available
* (from glib since 2.68). To do it with g_tree_foreach complicates the
* code a lot.
*
*/
g_tree_foreach(tree->tree, iova_tree_alloc_traverse, &args);
if (!args.iova_found) {
/*
* Either tree is empty or the last hole is still not checked.
* g_tree_foreach does not compare (last, iova_last] range, so we check
* it here.
*/
iova_tree_alloc_args_iterate(&args, NULL);
iova_tree_alloc_map_in_hole(&args);
}
if (!args.iova_found || args.iova_result + map->size > iova_last) {
return IOVA_ERR_NOMEM;
}
map->iova = args.iova_result;
return iova_tree_insert(tree, map);
}
void iova_tree_destroy(IOVATree *tree)
{
g_tree_destroy(tree->tree);
g_free(tree);
}