/*
* Copyright (c) 2013-2017, Intel Corporation
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* * Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
* * Neither the name of Intel Corporation nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#include "pt_image.h"
#include "pt_section.h"
#include "pt_asid.h"
#include "pt_image_section_cache.h"
#include <stdlib.h>
#include <string.h>
static char *dupstr(const char *str)
{
char *dup;
size_t len;
if (!str)
return NULL;
len = strlen(str);
dup = malloc(len + 1);
if (!dup)
return NULL;
return strcpy(dup, str);
}
static struct pt_section_list *pt_mk_section_list(struct pt_section *section,
const struct pt_asid *asid,
uint64_t vaddr, int isid)
{
struct pt_section_list *list;
int errcode;
list = malloc(sizeof(*list));
if (!list)
return NULL;
memset(list, 0, sizeof(*list));
errcode = pt_section_get(section);
if (errcode < 0)
goto out_mem;
pt_msec_init(&list->section, section, asid, vaddr);
list->isid = isid;
return list;
out_mem:
free(list);
return NULL;
}
static void pt_section_list_free(struct pt_section_list *list)
{
if (!list)
return;
if (list->mapped)
pt_section_unmap(list->section.section);
pt_section_put(list->section.section);
pt_msec_fini(&list->section);
free(list);
}
static void pt_section_list_free_tail(struct pt_section_list *list)
{
while (list) {
struct pt_section_list *trash;
trash = list;
list = list->next;
pt_section_list_free(trash);
}
}
void pt_image_init(struct pt_image *image, const char *name)
{
if (!image)
return;
memset(image, 0, sizeof(*image));
image->name = dupstr(name);
image->cache = 10;
}
void pt_image_fini(struct pt_image *image)
{
if (!image)
return;
pt_section_list_free_tail(image->sections);
free(image->name);
memset(image, 0, sizeof(*image));
}
struct pt_image *pt_image_alloc(const char *name)
{
struct pt_image *image;
image = malloc(sizeof(*image));
if (image)
pt_image_init(image, name);
return image;
}
void pt_image_free(struct pt_image *image)
{
pt_image_fini(image);
free(image);
}
const char *pt_image_name(const struct pt_image *image)
{
if (!image)
return NULL;
return image->name;
}
static int pt_image_clone(struct pt_section_list **list,
const struct pt_mapped_section *msec,
uint64_t begin, uint64_t end, int isid)
{
const struct pt_asid *masid;
struct pt_section_list *next;
struct pt_section *section, *sec;
uint64_t mbegin, sbegin, offset, size;
int errcode;
if (!list || !msec)
return -pte_internal;
sec = pt_msec_section(msec);
masid = pt_msec_asid(msec);
mbegin = pt_msec_begin(msec);
sbegin = pt_section_offset(sec);
if (end <= begin)
return -pte_internal;
if (begin < mbegin)
return -pte_internal;
offset = begin - mbegin;
size = end - begin;
errcode = pt_section_clone(§ion, sec, sbegin + offset, size);
if (errcode < 0)
return errcode;
next = pt_mk_section_list(section, masid, begin, isid);
if (!next) {
(void) pt_section_put(section);
return -pte_nomem;
}
/* The image list got its own reference; let's drop ours. */
errcode = pt_section_put(section);
if (errcode < 0) {
pt_section_list_free(next);
return errcode;
}
/* Add the new section. */
next->next = *list;
*list = next;
return 0;
}
int pt_image_add(struct pt_image *image, struct pt_section *section,
const struct pt_asid *asid, uint64_t vaddr, int isid)
{
struct pt_section_list **list, *next, *removed;
uint64_t begin, end;
int errcode;
if (!image || !section)
return -pte_internal;
next = pt_mk_section_list(section, asid, vaddr, isid);
if (!next)
return -pte_nomem;
removed = NULL;
errcode = 0;
begin = vaddr;
end = begin + pt_section_size(section);
/* Check for overlaps while we move to the end of the list. */
list = &(image->sections);
while (*list) {
const struct pt_mapped_section *msec;
const struct pt_asid *masid;
struct pt_section_list *current;
struct pt_section *lsec;
uint64_t lbegin, lend;
current = *list;
msec = ¤t->section;
masid = pt_msec_asid(msec);
errcode = pt_asid_match(masid, asid);
if (errcode < 0)
break;
if (!errcode) {
list = &((*list)->next);
continue;
}
lbegin = pt_msec_begin(msec);
lend = pt_msec_end(msec);
if ((end <= lbegin) || (lend <= begin)) {
list = &((*list)->next);
continue;
}
/* The new section overlaps with @msec's section. */
lsec = pt_msec_section(msec);
/* Let's check for an identical overlap that may be the result
* of repeatedly copying images or repeatedly adding the same
* file.
*/
if ((begin == lbegin) && (end == lend) &&
(isid == current->isid)) {
const char *fname, *lfname;
fname = pt_section_filename(section);
lfname = pt_section_filename(lsec);
if (!fname || !lfname) {
errcode = -pte_internal;
break;
}
if (strcmp(fname, lfname) == 0) {
/* There should not have been any removals or
* additions.
*/
if (removed || next->next) {
errcode = -pte_internal;
break;
}
pt_section_list_free(next);
return 0;
}
}
/* We remove @msec and insert new sections for the remaining
* parts, if any. Those new sections are not mapped initially
* and need to be added to the end of the section list.
*/
*list = current->next;
/* Keep a list of removed sections so we can re-add them in case
* of errors.
*/
current->next = removed;
removed = current;
/* Unmap the removed section. If we need to re-add it, it will
* be moved to the end of the section list where the unmapped
* sections are.
*/
if (current->mapped) {
pt_section_unmap(lsec);
current->mapped = 0;
}
/* Add a section covering the remaining bytes at the front.
*
* We preserve the section identifier to indicate that the new
* section originated from the original section.
*/
if (lbegin < begin) {
errcode = pt_image_clone(&next, msec, lbegin, begin,
current->isid);
if (errcode < 0)
break;
}
/* Add a section covering the remaining bytes at the back.
*
* We preserve the section identifier to indicate that the new
* section originated from the original section.
*/
if (end < lend) {
errcode = pt_image_clone(&next, msec, end, lend,
current->isid);
if (errcode < 0)
break;
}
}
if (errcode < 0) {
pt_section_list_free_tail(next);
/* Re-add removed sections to the tail of the section list. */
for (; *list; list = &((*list)->next))
;
*list = removed;
return errcode;
}
pt_section_list_free_tail(removed);
*list = next;
return 0;
}
int pt_image_remove(struct pt_image *image, struct pt_section *section,
const struct pt_asid *asid, uint64_t vaddr)
{
struct pt_section_list **list;
if (!image || !section)
return -pte_internal;
for (list = &image->sections; *list; list = &((*list)->next)) {
struct pt_mapped_section *msec;
const struct pt_section *sec;
const struct pt_asid *masid;
struct pt_section_list *trash;
uint64_t begin;
int errcode;
trash = *list;
msec = &trash->section;
masid = pt_msec_asid(msec);
errcode = pt_asid_match(masid, asid);
if (errcode < 0)
return errcode;
if (!errcode)
continue;
begin = pt_msec_begin(msec);
sec = pt_msec_section(msec);
if (sec == section && begin == vaddr) {
*list = trash->next;
pt_section_list_free(trash);
return 0;
}
}
return -pte_bad_image;
}
int pt_image_add_file(struct pt_image *image, const char *filename,
uint64_t offset, uint64_t size,
const struct pt_asid *uasid, uint64_t vaddr)
{
struct pt_section *section;
struct pt_asid asid;
int errcode;
if (!image || !filename)
return -pte_invalid;
errcode = pt_asid_from_user(&asid, uasid);
if (errcode < 0)
return errcode;
section = pt_mk_section(filename, offset, size);
if (!section)
return -pte_invalid;
errcode = pt_image_add(image, section, &asid, vaddr, 0);
if (errcode < 0) {
(void) pt_section_put(section);
return errcode;
}
/* The image list got its own reference; let's drop ours. */
errcode = pt_section_put(section);
if (errcode < 0)
return errcode;
return 0;
}
int pt_image_copy(struct pt_image *image, const struct pt_image *src)
{
struct pt_section_list *list;
int ignored;
if (!image || !src)
return -pte_invalid;
ignored = 0;
for (list = src->sections; list; list = list->next) {
int errcode;
errcode = pt_image_add(image, list->section.section,
&list->section.asid,
list->section.vaddr,
list->isid);
if (errcode < 0)
ignored += 1;
}
return ignored;
}
int pt_image_remove_by_filename(struct pt_image *image, const char *filename,
const struct pt_asid *uasid)
{
struct pt_section_list **list;
struct pt_asid asid;
int errcode, removed;
if (!image || !filename)
return -pte_invalid;
errcode = pt_asid_from_user(&asid, uasid);
if (errcode < 0)
return errcode;
removed = 0;
for (list = &image->sections; *list;) {
struct pt_mapped_section *msec;
const struct pt_section *sec;
const struct pt_asid *masid;
struct pt_section_list *trash;
const char *tname;
trash = *list;
msec = &trash->section;
masid = pt_msec_asid(msec);
errcode = pt_asid_match(masid, &asid);
if (errcode < 0)
return errcode;
if (!errcode) {
list = &trash->next;
continue;
}
sec = pt_msec_section(msec);
tname = pt_section_filename(sec);
if (tname && (strcmp(tname, filename) == 0)) {
*list = trash->next;
pt_section_list_free(trash);
removed += 1;
} else
list = &trash->next;
}
return removed;
}
int pt_image_remove_by_asid(struct pt_image *image,
const struct pt_asid *uasid)
{
struct pt_section_list **list;
struct pt_asid asid;
int errcode, removed;
if (!image)
return -pte_invalid;
errcode = pt_asid_from_user(&asid, uasid);
if (errcode < 0)
return errcode;
removed = 0;
for (list = &image->sections; *list;) {
struct pt_mapped_section *msec;
const struct pt_asid *masid;
struct pt_section_list *trash;
trash = *list;
msec = &trash->section;
masid = pt_msec_asid(msec);
errcode = pt_asid_match(masid, &asid);
if (errcode < 0)
return errcode;
if (!errcode) {
list = &trash->next;
continue;
}
*list = trash->next;
pt_section_list_free(trash);
removed += 1;
}
return removed;
}
int pt_image_set_callback(struct pt_image *image,
read_memory_callback_t *callback, void *context)
{
if (!image)
return -pte_invalid;
image->readmem.callback = callback;
image->readmem.context = context;
return 0;
}
static int pt_image_prune_cache(struct pt_image *image)
{
struct pt_section_list *list;
uint16_t cache, mapped;
int status;
if (!image)
return -pte_internal;
cache = image->cache;
status = 0;
mapped = 0;
for (list = image->sections; list; list = list->next) {
int errcode;
/* Let's traverse the entire list. It isn't very long and
* this allows us to fix up any previous unmap errors.
*/
if (!list->mapped)
continue;
mapped += 1;
if (mapped <= cache)
continue;
errcode = pt_section_unmap(list->section.section);
if (errcode < 0) {
status = errcode;
continue;
}
list->mapped = 0;
mapped -= 1;
}
image->mapped = mapped;
return status;
}
static int pt_image_read_callback(struct pt_image *image, int *isid,
uint8_t *buffer, uint16_t size,
const struct pt_asid *asid, uint64_t addr)
{
read_memory_callback_t *callback;
if (!image || !isid)
return -pte_internal;
callback = image->readmem.callback;
if (!callback)
return -pte_nomap;
*isid = 0;
return callback(buffer, size, asid, addr, image->readmem.context);
}
/* Check whether a mapped section contains an address.
*
* Returns zero if @msec contains @vaddr.
* Returns a negative error code otherwise.
* Returns -pte_nomap if @msec does not contain @vaddr.
*/
static inline int pt_image_check_msec(const struct pt_mapped_section *msec,
const struct pt_asid *asid,
uint64_t vaddr)
{
const struct pt_asid *masid;
uint64_t begin, end;
int errcode;
if (!msec)
return -pte_internal;
begin = pt_msec_begin(msec);
end = pt_msec_end(msec);
if (vaddr < begin || end <= vaddr)
return -pte_nomap;
masid = pt_msec_asid(msec);
errcode = pt_asid_match(masid, asid);
if (errcode <= 0) {
if (!errcode)
errcode = -pte_nomap;
return errcode;
}
return 0;
}
/* Read memory from a mapped section.
*
* @msec's section must be mapped.
*
* Returns the number of bytes read on success.
* Returns a negative error code otherwise.
*/
static int pt_image_read_msec(uint8_t *buffer, uint16_t size,
const struct pt_mapped_section *msec,
uint64_t addr)
{
struct pt_section *section;
uint64_t offset;
if (!msec)
return -pte_internal;
section = pt_msec_section(msec);
offset = pt_msec_unmap(msec, addr);
return pt_section_read(section, buffer, size, offset);
}
/* Find the section containing a given address in a given address space.
*
* On success, the found section is moved to the front of the section list.
* If caching is enabled, maps the section.
*
* Returns zero on success, a negative error code otherwise.
*/
static int pt_image_fetch_section(struct pt_image *image,
const struct pt_asid *asid, uint64_t vaddr)
{
struct pt_section_list **start, **list;
if (!image)
return -pte_internal;
start = &image->sections;
for (list = start; *list;) {
struct pt_mapped_section *msec;
struct pt_section_list *elem;
int errcode;
elem = *list;
msec = &elem->section;
errcode = pt_image_check_msec(msec, asid, vaddr);
if (errcode < 0) {
if (errcode != -pte_nomap)
return errcode;
list = &elem->next;
continue;
}
/* Move the section to the front if it isn't already. */
if (list != start) {
*list = elem->next;
elem->next = *start;
*start = elem;
}
/* Map the section if it isn't already - provided we do cache
* recently used sections.
*/
if (!elem->mapped) {
uint16_t cache, already;
already = image->mapped;
cache = image->cache;
if (cache) {
struct pt_section *section;
section = pt_msec_section(msec);
errcode = pt_section_map(section);
if (errcode < 0)
return errcode;
elem->mapped = 1;
already += 1;
image->mapped = already;
if (cache < already)
return pt_image_prune_cache(image);
}
}
return 0;
}
return -pte_nomap;
}
static int pt_image_read_cold(struct pt_image *image, int *isid,
uint8_t *buffer, uint16_t size,
const struct pt_asid *asid, uint64_t addr)
{
struct pt_mapped_section *msec;
struct pt_section_list *section;
int errcode;
if (!image || !isid)
return -pte_internal;
errcode = pt_image_fetch_section(image, asid, addr);
if (errcode < 0) {
if (errcode != -pte_nomap)
return errcode;
}
section = image->sections;
if (!section)
return pt_image_read_callback(image, isid, buffer, size, asid,
addr);
msec = §ion->section;
errcode = pt_image_check_msec(msec, asid, addr);
if (errcode < 0) {
if (errcode != -pte_nomap)
return errcode;
return pt_image_read_callback(image, isid, buffer, size, asid,
addr);
}
*isid = section->isid;
if (section->mapped)
return pt_image_read_msec(buffer, size, msec, addr);
else {
struct pt_section *sec;
int status;
sec = pt_msec_section(msec);
errcode = pt_section_map(sec);
if (errcode < 0)
return errcode;
status = pt_image_read_msec(buffer, size, msec, addr);
errcode = pt_section_unmap(sec);
if (errcode < 0)
return errcode;
return status;
}
}
int pt_image_read(struct pt_image *image, int *isid, uint8_t *buffer,
uint16_t size, const struct pt_asid *asid, uint64_t addr)
{
struct pt_mapped_section *msec;
struct pt_section_list *section;
int errcode;
if (!image || !isid)
return -pte_internal;
section = image->sections;
if (!section)
return pt_image_read_callback(image, isid, buffer, size, asid,
addr);
if (!section->mapped)
return pt_image_read_cold(image, isid, buffer, size, asid,
addr);
msec = §ion->section;
errcode = pt_image_check_msec(msec, asid, addr);
if (errcode < 0) {
if (errcode != -pte_nomap)
return errcode;
return pt_image_read_cold(image, isid, buffer, size, asid,
addr);
}
*isid = section->isid;
return pt_image_read_msec(buffer, size, msec, addr);
}
int pt_image_add_cached(struct pt_image *image,
struct pt_image_section_cache *iscache, int isid,
const struct pt_asid *uasid)
{
struct pt_section *section;
struct pt_asid asid;
uint64_t vaddr;
int errcode, status;
if (!image || !iscache)
return -pte_invalid;
errcode = pt_iscache_lookup(iscache, §ion, &vaddr, isid);
if (errcode < 0)
return errcode;
errcode = pt_asid_from_user(&asid, uasid);
if (errcode < 0)
return errcode;
status = pt_image_add(image, section, &asid, vaddr, isid);
/* We grab a reference when we add the section. Drop the one we
* obtained from cache lookup.
*/
errcode = pt_section_put(section);
if (errcode < 0)
return errcode;
return status;
}
static int pt_image_find_cold(struct pt_image *image,
struct pt_section **psection, uint64_t *laddr,
const struct pt_asid *asid, uint64_t vaddr)
{
struct pt_mapped_section *msec;
struct pt_section_list *slist;
struct pt_section *section;
int errcode;
if (!image || !psection || !laddr)
return -pte_internal;
errcode = pt_image_fetch_section(image, asid, vaddr);
if (errcode < 0)
return errcode;
slist = image->sections;
if (!slist)
return -pte_nomap;
msec = &slist->section;
errcode = pt_image_check_msec(msec, asid, vaddr);
if (errcode < 0)
return errcode;
section = pt_msec_section(msec);
errcode = pt_section_get(section);
if (errcode < 0)
return errcode;
*psection = section;
*laddr = pt_msec_begin(msec);
return slist->isid;
}
int pt_image_find(struct pt_image *image, struct pt_section **psection,
uint64_t *laddr, const struct pt_asid *asid, uint64_t vaddr)
{
struct pt_mapped_section *msec;
struct pt_section_list *slist;
struct pt_section *section;
int errcode;
if (!image || !psection || !laddr)
return -pte_internal;
slist = image->sections;
if (!slist)
return -pte_nomap;
if (!slist->mapped)
return pt_image_find_cold(image, psection, laddr, asid, vaddr);
msec = &slist->section;
errcode = pt_image_check_msec(msec, asid, vaddr);
if (errcode < 0) {
if (errcode != -pte_nomap)
return errcode;
return pt_image_find_cold(image, psection, laddr, asid, vaddr);
}
section = pt_msec_section(msec);
errcode = pt_section_get(section);
if (errcode < 0)
return errcode;
*psection = section;
*laddr = pt_msec_begin(msec);
return slist->isid;
}
int pt_image_validate(const struct pt_image *image, const struct pt_asid *asid,
uint64_t vaddr, const struct pt_section *section,
uint64_t laddr, int isid)
{
struct pt_mapped_section *msec;
struct pt_section_list *slist;
if (!image)
return -pte_internal;
/* We only look at the top of our LRU stack and accept sporadic
* validation fails if @section moved down in the LRU stack or has been
* evicted.
*
* A failed validation requires decoders to re-fetch the section so it
* only results in a (relatively small) performance loss.
*/
slist = image->sections;
if (!slist)
return -pte_nomap;
if (slist->isid != isid)
return -pte_nomap;
msec = &slist->section;
if (pt_msec_section(msec) != section)
return -pte_nomap;
if (pt_msec_begin(msec) != laddr)
return -pte_nomap;
return pt_image_check_msec(msec, asid, vaddr);
}