Covers application checkpoint/restart, overall design, interfaces, usage, shared objects, and and checkpoint image format. Changelog[v19-rc1]: - Update documentation and examples for new syscalls API - [Liu Alexander] Fix typos - [Serge Hallyn] Update checkpoint image format Changelog[v16]: - Update documentation - Unify into readme.txt and usage.txt Changelog[v14]: - Discard the 'h.parent' field - New image format (shared objects appear before they are referenced unless they are compound) Changelog[v8]: - Split into multiple files in Documentation/checkpoint/... - Extend documentation, fix typos and comments from feedback Signed-off-by: Oren Laadan <orenl@xxxxxxxxxxxxxxx> Signed-off-by: Dave Hansen <dave@xxxxxxxxxxxxxxxxxx> Acked-by: Serge E. Hallyn <serue@xxxxxxxxxx> Tested-by: Serge E. Hallyn <serue@xxxxxxxxxx> --- Documentation/checkpoint/checkpoint.c | 38 +++ Documentation/checkpoint/readme.txt | 370 ++++++++++++++++++++++++++++ Documentation/checkpoint/self_checkpoint.c | 69 +++++ Documentation/checkpoint/self_restart.c | 40 +++ Documentation/checkpoint/usage.txt | 247 +++++++++++++++++++ 5 files changed, 764 insertions(+), 0 deletions(-) create mode 100644 Documentation/checkpoint/checkpoint.c create mode 100644 Documentation/checkpoint/readme.txt create mode 100644 Documentation/checkpoint/self_checkpoint.c create mode 100644 Documentation/checkpoint/self_restart.c create mode 100644 Documentation/checkpoint/usage.txt diff --git a/Documentation/checkpoint/checkpoint.c b/Documentation/checkpoint/checkpoint.c new file mode 100644 index 0000000..8560f30 --- /dev/null +++ b/Documentation/checkpoint/checkpoint.c @@ -0,0 +1,38 @@ +#include <stdio.h> +#include <stdlib.h> +#include <errno.h> +#include <unistd.h> +#include <sys/syscall.h> + +#include <linux/checkpoint.h> + +static inline int checkpoint(pid_t pid, int fd, unsigned long flags) +{ + return syscall(__NR_checkpoint, pid, fd, flags); +} + +int main(int argc, char *argv[]) +{ + pid_t pid; + int ret; + + if (argc != 2) { + printf("usage: ckpt PID\n"); + exit(1); + } + + pid = atoi(argv[1]); + if (pid <= 0) { + printf("invalid pid\n"); + exit(1); + } + + ret = checkpoint(pid, STDOUT_FILENO, CHECKPOINT_SUBTREE); + + if (ret < 0) + perror("checkpoint"); + else + printf("checkpoint id %d\n", ret); + + return (ret > 0 ? 0 : 1); +} diff --git a/Documentation/checkpoint/readme.txt b/Documentation/checkpoint/readme.txt new file mode 100644 index 0000000..4fa5560 --- /dev/null +++ b/Documentation/checkpoint/readme.txt @@ -0,0 +1,370 @@ + + Checkpoint-Restart support in the Linux kernel + ========================================================== + +Copyright (C) 2008-2010 Oren Laadan + +Author: Oren Laadan <orenl@xxxxxxxxxxxxxxx> + +License: The GNU Free Documentation License, Version 1.2 + (dual licensed under the GPL v2) + +Contributors: Oren Laadan <orenl@xxxxxxxxxxxxxxx> + Serge Hallyn <serue@xxxxxxxxxx> + Dan Smith <danms@xxxxxxxxxx> + Matt Helsley <matthltc@xxxxxxxxxx> + Nathan Lynch <ntl@xxxxxxxxx> + Sukadev Bhattiprolu <sukadev@xxxxxxxxxxxxxxxxxx> + Dave Hansen <dave@xxxxxxxxxxxxxxxxxx> + + +Introduction +============ + +Application checkpoint/restart [C/R] is the ability to save the state +of a running application so that it can later resume its execution +from the time at which it was checkpointed. An application can be +migrated by checkpointing it on one machine and restarting it on +another. C/R can provide many potential benefits: + +* Failure recovery: by rolling back to a previous checkpoint + +* Improved response time: by restarting applications from checkpoints + instead of from scratch. + +* Improved system utilization: by suspending long running CPU + intensive jobs and resuming them when load decreases. + +* Fault resilience: by migrating applications off faulty hosts. + +* Dynamic load balancing: by migrating applications to less loaded + hosts. + +* Improved service availability and administration: by migrating + applications before host maintenance so that they continue to run + with minimal downtime + +* Time-travel: by taking periodic checkpoints and restarting from + any previous checkpoint. + +Compared to hypervisor approaches, application C/R is more lightweight +since it need only save the state associated with applications, while +operating system data structures (e.g. buffer cache, drivers state +and the like) are uninteresting. + + +Overall design +============== + +Checkpoint and restart are done in the kernel as much as possible. +Two new system calls are introduced to provide C/R: sys_checkpoint() +and sys_restart(). They both operate on a process tree (hierarchy), +either a whole container or a subtree of a container. + +Checkpointing entire containers ensures that there are no dependencies +on anything outside the container, which guarantees that a matching +restart will succeed (assuming that the file system state remains +consistent). However, it requires that users will always run the tasks +that they wish to checkpoint inside containers. This is ideal for, +e.g., private virtual servers and the like. + +In contrast, when checkpointing a subtree of a container it is up to +the user to ensure that dependencies either don't exist or can be +safely ignored. This is useful, for instance, for HPC scenarios or +even a user that would like to periodically checkpoint a long-running +batch job. + +An additional system call, a la madvise(), is planned, so that tasks +can advise the kernel how to handle specific resources. For instance, +a task could ask to skip a memory area at checkpoint to save space, +or to use a preset file descriptor at restart instead of restoring it +from the checkpoint image. It will provide the flexibility that is +particularly useful to address the needs of a diverse crowd of users +and use-cases. + +Syscall sys_checkpoint() is given a pid that indicates the top of the +hierarchy, a file descriptor to store the image, and flags. The code +serializes internal user- and kernel-state and writes it out to the +file descriptor. The resulting image is stream-able. The processes are +expected to be frozen for the duration of the checkpoint. + +In general, a checkpoint consists of 5 steps: +1. Pre-dump +2. Freeze the container/subtree +3. Save tasks' and kernel state <-- sys_checkpoint() +4. Thaw (or kill) the container/subtree +5. Post-dump + +Step 3 is done by calling sys_checkpoint(). Steps 1 and 5 are an +optimization to reduce application downtime. In particular, "pre-dump" +works before freezing the container, e.g. the pre-copy for live +migration, and "post-dump" works after the container resumes +execution, e.g. write-back the data to secondary storage. + +The kernel exports a relatively opaque 'blob' of data to userspace +which can then be handed to the new kernel at restart time. The +'blob' contains data and state of select portions of kernel structures +such as VMAs and mm_structs, as well as copies of the actual memory +that the tasks use. Any changes in this blob's format between kernel +revisions can be handled by an in-userspace conversion program. + +To restart, userspace first create a process hierarchy that matches +that of the checkpoint, and each task calls sys_restart(). The syscall +reads the saved kernel state from a file descriptor, and re-creates +the resources that the tasks need to resume execution. The restart +code is executed by each task that is restored in the new hierarchy to +reconstruct its own state. + +In general, a restart consists of 3 steps: +1. Create hierarchy +2. Restore tasks' and kernel state <-- sys_restart() +3. Resume userspace (or freeze tasks) + +Because the process hierarchy, during restart in created in userspace, +the restarting tasks have the flexibility to prepare before calling +sys_restart(). + + +Checkpoint image format +======================= + +The checkpoint image format is built of records that consist of a +pre-header identifying its contents, followed by a payload. This +format allow userspace tools to easily parse and skip through the +image without requiring intimate knowledge of the data. It will also +be handy to enable parallel checkpointing in the future where multiple +threads interleave data from multiple processes into a single stream. + +The pre-header is defined by 'struct ckpt_hdr' as follows: @type +identifies the type of the payload, @len tells its length in bytes +including the pre-header. + +struct ckpt_hdr { + __s32 type; + __s32 len; +}; + +The pre-header must be the first component in all other headers. For +instance, the task data is saved in 'struct ckpt_hdr_task', which +looks something like this: + +struct ckpt_hdr_task { + struct ckpt_hdr h; + __u32 pid; + ... +}; + +THE IMAGE FORMAT IS EXPECTED TO CHANGE over time as more features are +supported, or as existing features change in the kernel and require to +adjust their representation. Any such changes will be be handled by +in-userspace conversion tools. + +The general format of the checkpoint image is as follows: +* Image header +* Container configuration +* Task hierarchy +* Tasks' state +* Image trailer + +The image always begins with a general header that holds a magic +number, an architecture identifier (little endian format), a format +version number (@rev), followed by information about the kernel +(currently version and UTS data). It also holds the time of the +checkpoint and the flags given to sys_checkpoint(). This header is +followed by an arch-specific header. + +The container configuration section containers information that is +global to the container. Security (LSM) configuration is one example. +Network configuration and container-wide mounts may also go here, so +that the userspace restart coordinator can re-create a suitable +environment. + +The task hierarchy comes next so that userspace tools can read it +early (even from a stream) and re-create the restarting tasks. This is +basically an array of all checkpointed tasks, and their relationships +(parent, siblings, threads, etc). + +Then the state of all tasks is saved, in the order that they appear in +the tasks array above. For each state, we save data like task_struct, +namespaces, open files, memory layout, memory contents, cpu state, +signals and signal handlers, etc. For resources that are shared among +multiple processes, we first checkpoint said resource (and only once), +and in the task data we give a reference to it. More about shared +resources below. + +Finally, the image always ends with a trailer that holds a (different) +magic number, serving for sanity check. + + +Shared objects +============== + +Many resources may be shared by multiple tasks (e.g. file descriptors, +memory address space, etc), or even have multiple references from +other resources (e.g. a single inode that represents two ends of a +pipe). + +Shared objects are tracked using a hash table (objhash) to ensure that +they are only checkpointed or restored once. To handle a shared +object, it is first looked up in the hash table, to determine if is +the first encounter or a recurring appearance. The hash table itself +is not saved as part of the checkpoint image: it is constructed +dynamically during both checkpoint and restart, and discarded at the +end of the operation. + +During checkpoint, when a shared object is encountered for the first +time, it is inserted to the hash table, indexed by its kernel address. +It is assigned an identifier (@objref) in order of appearance, and +then its state is saved. Subsequent lookups of that object in the hash +will yield that entry, in which case only the @objref is saved, as +opposed the entire state of the object. + +During restart, shared objects are indexed by their @objref as given +during the checkpoint. On the first appearance of each shared object, +a new resource will be created and its state restored from the image. +Then the object is added to the hash table. Subsequent lookups of the +same unique identifier in the hash table will yield that entry, and +then the existing object instance is reused instead of creating +a new one. + +The hash grabs a reference to each object that is inserted, and +maintains this reference for the entire lifetime of the hash. Thus, +it is always safe to reference an object that is stored in the hash. +The hash is "one-way" in the sense that objects that are added are +never deleted from the hash until the hash is discarded. This, in +turn, happens only when the checkpoint (or restart) terminates. + +Shared objects are thus saved when they are first seen, and _before_ +the parent object that uses them. Therefore by the time the parent +objects needs them, they should already be in the objhash. The one +exception is when more than a single shared resource will be restarted +at once (e.g. like the two ends of a pipe, or all the namespaces in an +nsproxy). In this case the parent object is dumped first followed by +the individual sub-resources). + +The checkpoint image is stream-able, meaning that restarting from it +may not require lseek(). This is enforced at checkpoint time, by +carefully selecting the order of shared objects, to respect the rule +that an object is always saved before the objects that refers to it. + + +Memory contents format +====================== + +The memory contents of a given memory address space (->mm) is dumped +as a sequence of vma objects, represented by 'struct ckpt_hdr_vma'. +This header details the vma properties, and a reference to a file +(if file backed) or an inode (or shared memory) object. + +The vma header is followed by the actual contents - but only those +pages that need to be saved, i.e. dirty pages. They are written in +chunks of data, where each chunks contains a header that indicates +that number of pages in the chunk, followed by an array of virtual +addresses and then an array of actual page contents. The last chunk +holds zero pages. + +To illustrate this, consider a single simple task with two vmas: one +is file mapped with two dumped pages, and the other is anonymous with +three dumped pages. The memory dump will look like this: + + ckpt_hdr + ckpt_hdr_vma + ckpt_hdr_pgarr (nr_pages = 2) + addr1, addr2 + page1, page2 + ckpt_hdr_pgarr (nr_pages = 0) + ckpt_hdr + ckpt_hdr_vma + ckpt_hdr_pgarr (nr_pages = 3) + addr3, addr4, addr5 + page3, page4, page5 + ckpt_hdr_pgarr (nr_pages = 0) + + +Error handling +============== + +Both checkpoint and restart operations may fail due to a variety of +reasons. Using a simple, single return value from the system call is +insufficient to report the reason of a failure. + +Instead, both sys_checkpoint() and sys_restart() accept an additional +argument - a file descriptor to which the kernel writes diagnostic +and debugging information. Both the checkpoint and restart userspace +utilities have options to specify a filename to store this log. + +In addition, checkpoint provides informative status report upon +failure in the checkpoint image in the form of (one or more) error +objects, 'struct ckpt_hdr_err'. An error objects consists of a +mandatory pre-header followed by a null character ('\0'), and then a +string that describes the error. By default, if an error occurs, this +will be the last object written to the checkpoint image. + +Upon failure, the caller can examine the image (e.g. with 'ckptinfo') +and extract the detailed error message. The leading '\0' is useful if +one wants to seek back from the end of the checkpoint image, instead +of parsing the entire image separately. + + +Security +======== + +The main question is whether sys_checkpoint() and sys_restart() +require privileged or unprivileged operation. + +Early versions checked capable(CAP_SYS_ADMIN) assuming that we would +attempt to remove the need for privilege, so that all users could +safely use it. Arnd Bergmann pointed out that it'd make more sense to +let unprivileged users use them now, so that we'll be more careful +about the security as patches roll in. + +Checkpoint: the main concern is whether a task that performs the +checkpoint of another task has sufficient privileges to access its +state. We address this by requiring that the checkpointer task will be +able to ptrace the target task, by means of ptrace_may_access() with +access mode. + +Restart: the main concern is that we may allow an unprivileged user to +feed the kernel with random data. To this end, the restart works in a +way that does not skip the usual security checks. Task credentials, +i.e. euid, reuid, and LSM security contexts currently come from the +caller, not the checkpoint image. As credentials are restored too, +the ability of a task that calls sys_restore() to setresuid/setresgid +to those values must be checked. + +Keeping the restart procedure to operate within the limits of the +caller's credentials means that there various scenarios that cannot +be supported. For instance, a setuid program that opened a protected +log file and then dropped privileges will fail the restart, because +the user won't have enough credentials to reopen the file. In these +cases, we should probably treat restarting like inserting a kernel +module: surely the user can cause havoc by providing incorrect data, +but then again we must trust the root account. + +So that's why we don't want CAP_SYS_ADMIN required up-front. That way +we will be forced to more carefully review each of those features. +However, this can be controlled with a sysctl-variable. + + +Kernel interfaces +================= + +* To checkpoint a vma, the 'struct vm_operations_struct' needs to + provide a method ->checkpoint: + int checkpoint(struct ckpt_ctx *, struct vma_struct *) + Restart requires a matching (exported) restore: + int restore(struct ckpt_ctx *, struct mm_struct *, struct ckpt_hdr_vma *) + +* To checkpoint a file, the 'struct file_operations' needs to provide + the methods ->checkpoint and ->collect: + int checkpoint(struct ckpt_ctx *, struct file *) + int collect(struct ckpt_ctx *, struct file *) + Restart requires a matching (exported) restore: + int restore(struct ckpt_ctx *, struct ckpt_hdr_file *) + For most file systems, generic_file_{checkpoint,restore}() can be + used. + +* To checkpoint a socket, the 'struct proto_ops' needs to provide + the methods ->checkpoint, ->collect and ->restore: + int checkpoint(struct ckpt_ctx *ctx, struct socket *sock); + int collect(struct ckpt_ctx *ctx, struct socket *sock); + int restore(struct ckpt_ctx *, struct socket *sock, struct ckpt_hdr_socket *h) + diff --git a/Documentation/checkpoint/self_checkpoint.c b/Documentation/checkpoint/self_checkpoint.c new file mode 100644 index 0000000..27dba0d --- /dev/null +++ b/Documentation/checkpoint/self_checkpoint.c @@ -0,0 +1,69 @@ +/* + * self_checkpoint.c: demonstrate self-checkpoint + * + * Copyright (C) 2008 Oren Laadan + * + * This file is subject to the terms and conditions of the GNU General Public + * License. See the file COPYING in the main directory of the Linux + * distribution for more details. + */ + +#include <stdio.h> +#include <stdlib.h> +#include <string.h> +#include <unistd.h> +#include <errno.h> +#include <math.h> +#include <sys/syscall.h> + +#include <linux/checkpoint.h> + +static inline int checkpoint(pid_t pid, int fd, unsigned long flags) +{ + return syscall(__NR_checkpoint, pid, fd, flags, CHECKPOINT_FD_NONE); +} + +#define OUTFILE "/tmp/cr-self.out" + +int main(int argc, char *argv[]) +{ + pid_t pid = getpid(); + FILE *file; + int i, ret; + + close(0); + close(2); + + unlink(OUTFILE); + file = fopen(OUTFILE, "w+"); + if (!file) { + perror("open"); + exit(1); + } + if (dup2(0, 2) < 0) { + perror("dup2"); + exit(1); + } + + fprintf(file, "hello, world!\n"); + fflush(file); + + for (i = 0; i < 1000; i++) { + sleep(1); + fprintf(file, "count %d\n", i); + fflush(file); + + if (i != 2) + continue; + ret = checkpoint(pid, STDOUT_FILENO, CHECKPOINT_SUBTREE); + if (ret < 0) { + fprintf(file, "ckpt: %s\n", strerror(errno)); + exit(2); + } + + fprintf(file, "checkpoint ret: %d\n", ret); + fflush(file); + } + + return 0; +} diff --git a/Documentation/checkpoint/self_restart.c b/Documentation/checkpoint/self_restart.c new file mode 100644 index 0000000..647ce51 --- /dev/null +++ b/Documentation/checkpoint/self_restart.c @@ -0,0 +1,40 @@ +/* + * self_restart.c: demonstrate self-restart + * + * Copyright (C) 2008 Oren Laadan + * + * This file is subject to the terms and conditions of the GNU General Public + * License. See the file COPYING in the main directory of the Linux + * distribution for more details. + */ + +#define _GNU_SOURCE /* or _BSD_SOURCE or _SVID_SOURCE */ + +#include <stdio.h> +#include <stdlib.h> +#include <errno.h> +#include <fcntl.h> +#include <unistd.h> +#include <unistd.h> +#include <sys/syscall.h> + +#include <linux/checkpoint.h> + +static inline int restart(pid_t pid, int fd, unsigned long flags) +{ + return syscall(__NR_restart, pid, fd, flags, CHECKPOINT_FD_NONE); +} + +int main(int argc, char *argv[]) +{ + pid_t pid = getpid(); + int ret; + + ret = restart(pid, STDIN_FILENO, RESTART_TASKSELF); + if (ret < 0) + perror("restart"); + + printf("should not reach here !\n"); + + return 0; +} diff --git a/Documentation/checkpoint/usage.txt b/Documentation/checkpoint/usage.txt new file mode 100644 index 0000000..c6fc045 --- /dev/null +++ b/Documentation/checkpoint/usage.txt @@ -0,0 +1,247 @@ + + How to use Checkpoint-Restart + ========================================= + + +API +=== + +The API consists of three new system calls: + +* long checkpoint(pid_t pid, int fd, unsigned long flag, int logfd); + + Checkpoint a (sub-)container whose root task is identified by @pid, + to the open file indicated by @fd. If @logfd isn't -1, it indicates + an open file to which error and debug messages are written. @flags + may be one or more of: + - CHECKPOINT_SUBTREE : allow checkpoint of sub-container + (other value are not allowed). + + Returns: a positive checkpoint identifier (ckptid) upon success, 0 if + it returns from a restart, and -1 if an error occurs. The ckptid will + uniquely identify a checkpoint image, for as long as the checkpoint + is kept in the kernel (e.g. if one wishes to keep a checkpoint, or a + partial checkpoint, residing in kernel memory). + +* long sys_restart(pid_t pid, int fd, unsigned long flags, int logfd); + + Restart a process hierarchy from a checkpoint image that is read from + the blob stored in the file indicated by @fd. If @logfd isn't -1, it + indicates an open file to which error and debug messages are written. + @flags will have future meaning (must be 0 for now). @pid indicates + the root of the hierarchy as seen in the coordinator's pid-namespace, + and is expected to be a child of the coordinator. @flags may be one + or more of: + - RESTART_TASKSELF : (self) restart of a single process + - RESTART_FROEZN : processes remain frozen once restart completes + - RESTART_GHOST : process is a ghost (placeholder for a pid) + (Note that this argument may mean 'ckptid' to identify an in-kernel + checkpoint image, with some @flags in the future). + + Returns: -1 if an error occurs, 0 on success when restarting from a + "self" checkpoint, and return value of system call at the time of the + checkpoint when restarting from an "external" checkpoint. + + (If a process was frozen for checkpoint while in userspace, it will + resume running in userspace exactly where it was interrupted. If it + was frozen while in kernel doing a syscall, it will return what the + syscall returned when interrupted/completed, and proceed from there + as if it had only been frozen and then thawed. Finally, if it did a + self-checkpoint, it will resume to the first instruction after the + call to checkpoint(2), having returned 0, to indicate whether the + return is from the checkpoint or a restart). + +* int clone_with_pid(unsigned long clone_flags, void *news, + int *parent_tidptr, int *child_tidptr, + struct target_pid_set *pid_set) + + struct target_pid_set { + int num_pids; + pid_t *target_pids; + } + + Container restart requires that a task have the same pid it had when + it was checkpointed. When containers are nested the tasks within the + containers exist in multiple pid namespaces and hence have multiple + pids to specify during restart. + + clone_with_pids(), intended for use during restart, is similar to + clone(), except that it takes a 'target_pid_set' parameter. This + parameter lets caller choose specific pid numbers for the child + process, in the process's active and ancestor pid namespaces. + + Unlike clone(), clone_with_pids() needs CAP_SYS_ADMIN, at least for + now, to prevent unprivileged processes from misusing this interface. + + If a target-pid is 0, the kernel continues to assign a pid for the + process in that namespace. If a requested pid is taken, the system + call fails with -EBUSY. If 'pid_set.num_pids' exceeds the current + nesting level of pid namespaces, the system call fails with -EINVAL. + + +Sysctl/proc +=========== + +/proc/sys/kernel/ckpt_unpriv_allowed [default = 1] + controls whether c/r operation is allowed for unprivileged users + + +Operation +========= + +The granularity of a checkpoint usually is a process hierarchy. The +'pid' argument is interpreted in the caller's pid namespace. So to +checkpoint a container whose init task (pid 1 in that pidns) appears +as pid 3497 the caller's pidns, the caller must use pid 3497. Passing +pid 1 will attempt to checkpoint the caller's container, and if the +caller isn't privileged and init is owned by root, it will fail. + +Unless the CHECKPOINT_SUBTREE flag is set, if the caller passes a pid +which does not refer to a container's init task, then sys_checkpoint() +would return -EINVAL. + +We assume that during checkpoint and restart the container state is +quiescent. During checkpoint, this means that all affected tasks are +frozen (or otherwise stopped). During restart, this means that all +affected tasks are executing the sys_restart() call. In both cases, if +there are other tasks possible sharing state with the container, they +must not modify it during the operation. It is the responsibility of +the caller to follow this requirement. + +If the assumption that all tasks are frozen and that there is no other +sharing doesn't hold - then the results of the operation are undefined +(just as, e.g. not calling execve() immediately after vfork() produces +undefined results). In particular, either checkpoint will fail, or it +may produce a checkpoint image that can't be restarted, or (unlikely) +the restart may produce a container whose state does not match that of +the original container. + + +User tools +========== + +* checkpoint(1): a tool to perform a checkpoint of a container/subtree +* restart(1): a tool to restart a container/subtree +* ckptinfo: a tool to examine a checkpoint image + +It is best to use the dedicated user tools for checkpoint and restart. + +If you insist, then here is a code snippet that illustrates how a +checkpoint is initiated by a process inside a container - the logic is +similar to fork(): + ... + ckptid = checkpoint(0, ...); + switch (crid) { + case -1: + perror("checkpoint failed"); + break; + default: + fprintf(stderr, "checkpoint succeeded, CRID=%d\n", ret); + /* proceed with execution after checkpoint */ + ... + break; + case 0: + fprintf(stderr, "returned after restart\n"); + /* proceed with action required following a restart */ + ... + break; + } + ... + +And to initiate a restart, the process in an empty container can use +logic similar to execve(): + ... + if (restart(pid, ...) < 0) + perror("restart failed"); + /* only get here if restart failed */ + ... + +Note, that the code also supports "self" checkpoint, where a process +can checkpoint itself. This mode does not capture the relationships of +the task with other tasks, or any shared resources. It is useful for +application that wish to be able to save and restore their state. +They will either not use (or care about) shared resources, or they +will be aware of the operations and adapt suitably after a restart. +The code above can also be used for "self" checkpoint. + + +You may find the following sample programs useful: + +* checkpoint.c: accepts a 'pid' and checkpoint that task to stdout +* self_checkpoint.c: a simple test program doing self-checkpoint +* self_restart.c: restarts a (self-) checkpoint image from stdin + +See also the utilities 'checkpoint' and 'restart' (from user-cr). + + +"External" checkpoint +===================== + +To do "external" checkpoint, you need to first freeze that other task +either using the freezer cgroup. + +Restart does not preserve the original PID yet, (because we haven't +solved yet the fork-with-specific-pid issue). In a real scenario, you +probably want to first create a new names space, and have the init +task there call 'sys_restart()'. + +I tested it this way: + $ ./test & + [1] 3493 + + $ echo 3493 > /cgroup/0/tasks + $ echo FROZEN > /cgroup/0/freezer.state + $ ./checkpoint 3493 > ckpt.image + + $ mv /tmp/cr-test.out /tmp/cr-test.out.orig + $ cp /tmp/cr-test.out.orig /tmp/cr-test.out + + $ echo THAWED > /cgroup/0/freezer.state + + $ ./self_restart < ckpt.image +Now compare the output of the two output files. + + +"Self" checkpoint +================ + +To do self-checkpoint, you can incorporate the code from +self_checkpoint.c into your application. + +Here is how to test the self-checkpoint: + $ ./self_checkpoint > self.image & + [1] 3512 + + $ sleep 3 + $ mv /tmp/cr-self.out /tmp/cr-self.out.orig + $ cp /tmp/cr-self.out.orig /tmp/cr-self.out + + $ cat /tmp/cr-self.out + hello, world! + count 0 + count 1 + count 2 + checkpoint ret: 1 + count 3 + ... + + $ sed -i 's/count/xxxxx/g' /tmp/cr-self.out + + $ ./self_restart < self.image & + +Now compare the output of the two output files. + $ cat /tmp/cr-self.out + hello, world! + xxxxx 0 + xxxxx 1 + xxxxx 2 + checkpoint ret: 0 + count 3 + ... + + +Note how in test.c we close stdin, stdout, stderr - that's because +currently we only support regular files (not ttys/ptys). + +If you check the output of ps, you'll see that "self_restart" changed +its name to "test" or "self_checkpoint", as expected. -- 1.6.3.3 -- To unsubscribe, send a message with 'unsubscribe linux-mm' in the body to majordomo@xxxxxxxxxx For more info on Linux MM, see: http://www.linux-mm.org/ . 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