From mboxrd@z Thu Jan 1 00:00:00 1970 From: Daniel Colascione Subject: Re: [RFC 7/7] mm: madvise support MADV_ANONYMOUS_FILTER and MADV_FILE_FILTER Date: Tue, 28 May 2019 04:21:44 -0700 Message-ID: References: <20190521062628.GE32329@dhcp22.suse.cz> <20190527075811.GC6879@google.com> <20190527124411.GC1658@dhcp22.suse.cz> <20190528032632.GF6879@google.com> <20190528062947.GL1658@dhcp22.suse.cz> <20190528081351.GA159710@google.com> <20190528084927.GB159710@google.com> <20190528090821.GU1658@dhcp22.suse.cz> <20190528103312.GV1658@dhcp22.suse.cz> Mime-Version: 1.0 Content-Type: text/plain; charset="UTF-8" Return-path: In-Reply-To: <20190528103312.GV1658@dhcp22.suse.cz> Sender: linux-kernel-owner@vger.kernel.org To: Michal Hocko Cc: Minchan Kim , Andrew Morton , LKML , linux-mm , Johannes Weiner , Tim Murray , Joel Fernandes , Suren Baghdasaryan , Shakeel Butt , Sonny Rao , Brian Geffon , Linux API List-Id: linux-api@vger.kernel.org On Tue, May 28, 2019 at 3:33 AM Michal Hocko wrote: > > On Tue 28-05-19 02:39:03, Daniel Colascione wrote: > > On Tue, May 28, 2019 at 2:08 AM Michal Hocko wrote: > > > > > > On Tue 28-05-19 17:49:27, Minchan Kim wrote: > > > > On Tue, May 28, 2019 at 01:31:13AM -0700, Daniel Colascione wrote: > > > > > On Tue, May 28, 2019 at 1:14 AM Minchan Kim wrote: > > > > > > if we went with the per vma fd approach then you would get this > > > > > > > feature automatically because map_files would refer to file backed > > > > > > > mappings while map_anon could refer only to anonymous mappings. > > > > > > > > > > > > The reason to add such filter option is to avoid the parsing overhead > > > > > > so map_anon wouldn't be helpful. > > > > > > > > > > Without chiming on whether the filter option is a good idea, I'd like > > > > > to suggest that providing an efficient binary interfaces for pulling > > > > > memory map information out of processes. Some single-system-call > > > > > method for retrieving a binary snapshot of a process's address space > > > > > complete with attributes (selectable, like statx?) for each VMA would > > > > > reduce complexity and increase performance in a variety of areas, > > > > > e.g., Android memory map debugging commands. > > > > > > > > I agree it's the best we can get *generally*. > > > > Michal, any opinion? > > > > > > I am not really sure this is directly related. I think the primary > > > question that we have to sort out first is whether we want to have > > > the remote madvise call process or vma fd based. This is an important > > > distinction wrt. usability. I have only seen pid vs. pidfd discussions > > > so far unfortunately. > > > > I don't think the vma fd approach is viable. We have some processes > > with a *lot* of VMAs --- system_server had 4204 when I checked just > > now (and that's typical) --- and an FD operation per VMA would be > > excessive. > > What do you mean by excessive here? Do you expect the process to have > them open all at once? Minchan's already done timing. More broadly, in an era with various speculative execution mitigations, making a system call is pretty expensive. If we have two options for remote VMA manipulation, one that requires thousands of system calls (with the count proportional to the address space size of the process) and one that requires only a few system calls no matter how large the target process is, the latter ought to start off with more points than the former under any kind of design scoring. > > VMAs also come and go pretty easily depending on changes in > > protections and various faults. > > Is this really too much different from /proc//map_files? It's very different. See below. > > > An interface to query address range information is a separate but > > > although a related topic. We have /proc//[s]maps for that right > > > now and I understand it is not a general win for all usecases because > > > it tends to be slow for some. I can see how /proc//map_anons could > > > provide per vma information in a binary form via a fd based interface. > > > But I would rather not conflate those two discussions much - well except > > > if it could give one of the approaches more justification but let's > > > focus on the madvise part first. > > > > I don't think it's a good idea to focus on one feature in a > > multi-feature change when the interactions between features can be > > very important for overall design of the multi-feature system and the > > design of each feature. > > > > Here's my thinking on the high-level design: > > > > I'm imagining an address-range system that would work like this: we'd > > create some kind of process_vm_getinfo(2) system call [1] that would > > accept a statx-like attribute map and a pid/fd parameter as input and > > return, on output, two things: 1) an array [2] of VMA descriptors > > containing the requested information, and 2) a VMA configuration > > sequence number. We'd then have process_madvise() and other > > cross-process VM interfaces accept both address ranges and this > > sequence number; they'd succeed only if the VMA configuration sequence > > number is still current, i.e., the target process hasn't changed its > > VMA configuration (implicitly or explicitly) since the call to > > process_vm_getinfo(). > > The sequence number is essentially a cookie that is transparent to the > userspace right? If yes, how does it differ from a fd (returned from > /proc//map_{anons,files}/range) which is a cookie itself and it can If you want to operate on N VMAs simultaneously under an FD-per-VMA model, you'd need to have those N FDs all open at the same time *and* add some kind of system call that accepted those N FDs and an operation to perform. The sequence number I'm proposing also applies to the whole address space, not just one VMA. Even if you did have these N FDs open all at once and supplied them all to some batch operation, you couldn't guarantee via the FD mechanism that some *new* VMA didn't appear in the address range you want to manipulate. A global sequence number would catch this case. I still think supplying a list of address ranges (like we already do for scatter-gather IO) is less error-prone, less resource-intensive, more consistent with existing practice, and equally flexible, especially if we start supporting destructive cross-process memory operations, which may be useful for things like checkpointing and optimizing process startup. Besides: process_vm_readv and process_vm_writev already work on address ranges. Why should other cross-process memory APIs use a very different model for naming memory regions? > be used to revalidate when the operation is requested and fail if > something has changed. Moreover we already do have a fd based madvise > syscall so there shouldn't be really a large need to add a new set of > syscalls. We have various system calls that provide hints for open files, but the memory operations are distinct. Modeling anonymous memory as a kind of file-backed memory for purposes of VMA manipulation would also be a departure from existing practice. Can you help me understand why you seem to favor the FD-per-VMA approach so heavily? I don't see any arguments *for* an FD-per-VMA model for remove memory manipulation and I see a lot of arguments against it. Is there some compelling advantage I'm missing? > > Or maybe the whole sequence number thing is overkill and we don't need > > atomicity? But if there's a concern that A shouldn't operate on B's > > memory without knowing what it's operating on, then the scheme I've > > proposed above solves this knowledge problem in a pretty lightweight > > way. > > This is the main question here. Do we really want to enforce an external > synchronization between the two processes to make sure that they are > both operating on the same range - aka protect from the range going away > and being reused for a different purpose. Right now it wouldn't be fatal > because both operations are non destructive but I can imagine that there > will be more madvise operations to follow (including those that are > destructive) because people will simply find usecases for that. This > should be reflected in the proposed API. A sequence number gives us this synchronization at very low cost and adds safety. It's also a general-purpose mechanism that would safeguard *any* cross-process VM operation, not just the VM operations we're discussing right now.