Message ID | 20140401172939.GG20061@arm.com |
---|---|
State | New |
Headers | show |
On Tue, 2014-04-01 at 18:29 +0100, Catalin Marinas wrote: > On Tue, Apr 01, 2014 at 05:10:57PM +0100, Jon Medhurst (Tixy) wrote: > > On Mon, 2014-03-31 at 18:52 +0100, Catalin Marinas wrote: > > > The following changes since commit cfbf8d4857c26a8a307fb7cd258074c9dcd8c691: > > > > > > Linux 3.14-rc4 (2014-02-23 17:40:03 -0800) > > > > > > are available in the git repository at: > > > > > > git://git.kernel.org/pub/scm/linux/kernel/git/arm64/linux tags/arm64-upstream > > > > > > for you to fetch changes up to 196adf2f3015eacac0567278ba538e3ffdd16d0e: > > > > > > arm64: Remove pgprot_dmacoherent() (2014-03-24 10:35:35 +0000) > > > > I may have spotted a bug in commit 7363590d2c46 (arm64: Implement > > coherent DMA API based on swiotlb), see my inline comment below... > > > > [...] > > > diff --git a/arch/arm64/mm/cache.S b/arch/arm64/mm/cache.S > > > index 1ea9f26..97fcef5 100644 > > > --- a/arch/arm64/mm/cache.S > > > +++ b/arch/arm64/mm/cache.S > > > @@ -166,3 +166,81 @@ ENTRY(__flush_dcache_area) > > > dsb sy > > > ret > > > ENDPROC(__flush_dcache_area) > > > + > > > +/* > > > + * __dma_inv_range(start, end) > > > + * - start - virtual start address of region > > > + * - end - virtual end address of region > > > + */ > > > +__dma_inv_range: > > > + dcache_line_size x2, x3 > > > + sub x3, x2, #1 > > > + bic x0, x0, x3 > > > + bic x1, x1, x3 > > > > Why is the 'end' value in x1 above rounded down to be cache aligned? > > This means the cache invalidate won't include the cache line containing > > the final bytes of the region, unless it happened to already be cache > > line aligned. This looks especially suspect as the other two cache > > operations added in the same patch (below) don't do that. > > Cache invalidation is destructive, so we want to make sure that it > doesn't affect anything beyond x1. But you are right, if either end of > the buffer is not cache line aligned it can get it wrong. The fix is to > use clean+invalidate on the unaligned ends: Like the ARMv7 implementation does :-) However, I wonder, is it possible for the Cache Writeback Granule (CWG) to come into play? If the CWG of further out caches was bigger than closer (to CPU) caches then it would cause data corruption. So for these region ends, should we not be using the CWG size, not the minimum D cache line size? On second thoughts, that wouldn't be safe either in the converse case where the CWG of a closer cache was bigger. So we would need to first use minimum cache line size to clean a CWG sized region, then invalidate cache lines by the same method. But then that leaves a time period where a write can happen between the clean and the invalidate, again leading to data corruption. I hope all this means I've either got rather confused or that that cache architectures are smart enough to automatically cope. I also have a couple of comments on the specific changes below... > > diff --git a/arch/arm64/mm/cache.S b/arch/arm64/mm/cache.S > index c46f48b33c14..6a26bf1965d3 100644 > --- a/arch/arm64/mm/cache.S > +++ b/arch/arm64/mm/cache.S > @@ -175,10 +175,17 @@ ENDPROC(__flush_dcache_area) > __dma_inv_range: > dcache_line_size x2, x3 > sub x3, x2, #1 > - bic x0, x0, x3 > + tst x1, x3 // end cache line aligned? > bic x1, x1, x3 > -1: dc ivac, x0 // invalidate D / U line > - add x0, x0, x2 > + b.eq 1f > + dc civac, x1 // clean & invalidate D / U line That is actually cleaning the address one byte past the end of the region, not sure it matters though because it is still within the same minimum cache line sized region. > +1: tst x0, x3 // start cache line aligned? > + bic x0, x0, x3 > + b.eq 2f > + dc civac, x0 // clean & invalidate D / U line > + b 3f > +2: dc ivac, x0 // invalidate D / U line > +3: add x0, x0, x2 > cmp x0, x1 > b.lo 1b The above obviously also needs changing to branch to 3b > dsb sy >
On Wed, Apr 02, 2014 at 09:52:02AM +0100, Jon Medhurst (Tixy) wrote: > On Tue, 2014-04-01 at 18:29 +0100, Catalin Marinas wrote: > > On Tue, Apr 01, 2014 at 05:10:57PM +0100, Jon Medhurst (Tixy) wrote: > > > On Mon, 2014-03-31 at 18:52 +0100, Catalin Marinas wrote: > > > > +__dma_inv_range: > > > > + dcache_line_size x2, x3 > > > > + sub x3, x2, #1 > > > > + bic x0, x0, x3 > > > > + bic x1, x1, x3 > > > > > > Why is the 'end' value in x1 above rounded down to be cache aligned? > > > This means the cache invalidate won't include the cache line containing > > > the final bytes of the region, unless it happened to already be cache > > > line aligned. This looks especially suspect as the other two cache > > > operations added in the same patch (below) don't do that. > > > > Cache invalidation is destructive, so we want to make sure that it > > doesn't affect anything beyond x1. But you are right, if either end of > > the buffer is not cache line aligned it can get it wrong. The fix is to > > use clean+invalidate on the unaligned ends: > > Like the ARMv7 implementation does :-) However, I wonder, is it possible > for the Cache Writeback Granule (CWG) to come into play? If the CWG of > further out caches was bigger than closer (to CPU) caches then it would > cause data corruption. So for these region ends, should we not be using > the CWG size, not the minimum D cache line size? On second thoughts, > that wouldn't be safe either in the converse case where the CWG of a > closer cache was bigger. So we would need to first use minimum cache > line size to clean a CWG sized region, then invalidate cache lines by > the same method. CWG gives us the maximum size (of all cache levels in the system, even on a different CPU for example in big.LITTLE configurations) that would be evicted by the cache operation. So we need small loops of Dmin size that go over the bigger CWG (and that's guaranteed to be at least Dmin). > But then that leaves a time period where a write can > happen between the clean and the invalidate, again leading to data > corruption. I hope all this means I've either got rather confused or > that that cache architectures are smart enough to automatically cope. You are right. I think having unaligned DMA buffers for inbound transfers is pointless. We can avoid losing data written by another CPU in the same cache line but, depending on the stage of the DMA transfer, it can corrupt the DMA data. I wonder whether it's easier to define the cache_line_size() macro to read CWG and assume that the DMA buffers are always aligned, ignoring the invalidation of the unaligned boundaries. This wouldn't be much different from your scenario where the shared cache line is written (just less likely to trigger but still a bug, so I would rather notice this early). The ARMv7 code has a similar issue, it performs clean&invalidate on the unaligned start but it doesn't move r0, so it goes into the main loop invalidating the same cache line again. If it was written by something else, the information would be lost. > I also have a couple of comments on the specific changes below... > > > diff --git a/arch/arm64/mm/cache.S b/arch/arm64/mm/cache.S > > index c46f48b33c14..6a26bf1965d3 100644 > > --- a/arch/arm64/mm/cache.S > > +++ b/arch/arm64/mm/cache.S > > @@ -175,10 +175,17 @@ ENDPROC(__flush_dcache_area) > > __dma_inv_range: > > dcache_line_size x2, x3 > > sub x3, x2, #1 > > - bic x0, x0, x3 > > + tst x1, x3 // end cache line aligned? > > bic x1, x1, x3 > > -1: dc ivac, x0 // invalidate D / U line > > - add x0, x0, x2 > > + b.eq 1f > > + dc civac, x1 // clean & invalidate D / U line > > That is actually cleaning the address one byte past the end of the > region, not sure it matters though because it is still within the same > minimum cache line sized region. It shouldn't, there is a "bic x1, x1, x3" above and this dc only happens if the address was unaligned. > > +1: tst x0, x3 // start cache line aligned? > > + bic x0, x0, x3 > > + b.eq 2f > > + dc civac, x0 // clean & invalidate D / U line > > + b 3f > > +2: dc ivac, x0 // invalidate D / U line > > +3: add x0, x0, x2 > > cmp x0, x1 > > b.lo 1b > > The above obviously also needs changing to branch to 3b Good point. (but I'm no longer convinced we need the hassle above ;))
On Wed, Apr 02, 2014 at 10:20:32AM +0100, Catalin Marinas wrote: > You are right. I think having unaligned DMA buffers for inbound > transfers is pointless. We can avoid losing data written by another CPU > in the same cache line but, depending on the stage of the DMA transfer, > it can corrupt the DMA data. > > I wonder whether it's easier to define the cache_line_size() macro to > read CWG and assume that the DMA buffers are always aligned, ignoring > the invalidation of the unaligned boundaries. This wouldn't be much > different from your scenario where the shared cache line is written > (just less likely to trigger but still a bug, so I would rather notice > this early). > > The ARMv7 code has a similar issue, it performs clean&invalidate on the > unaligned start but it doesn't move r0, so it goes into the main loop > invalidating the same cache line again. If it was written by something > else, the information would be lost. You can't make that a requirement. People have shared stuff across a cache line for years in Linux, and people have brought it up and tried to fix it, but there's much resistance against it. In particular is SCSI, which submits the sense buffer as part of a larger structure (the host.) SCSI sort-of guarantees that the surrounding struct members won't be touched, but their data has to be preserved. In any case, remember that there are strict rules about ownership of the DMA memory vs calls to the DMA API. It is invalid to call the DMA streaming API functions while a DMA transfer is active.
On Wed, 2014-04-02 at 10:20 +0100, Catalin Marinas wrote: > On Wed, Apr 02, 2014 at 09:52:02AM +0100, Jon Medhurst (Tixy) wrote: > > On Tue, 2014-04-01 at 18:29 +0100, Catalin Marinas wrote: > > > On Tue, Apr 01, 2014 at 05:10:57PM +0100, Jon Medhurst (Tixy) wrote: > > > > On Mon, 2014-03-31 at 18:52 +0100, Catalin Marinas wrote: > > > > > +__dma_inv_range: > > > > > + dcache_line_size x2, x3 > > > > > + sub x3, x2, #1 > > > > > + bic x0, x0, x3 > > > > > + bic x1, x1, x3 > > > > > > > > Why is the 'end' value in x1 above rounded down to be cache aligned? > > > > This means the cache invalidate won't include the cache line containing > > > > the final bytes of the region, unless it happened to already be cache > > > > line aligned. This looks especially suspect as the other two cache > > > > operations added in the same patch (below) don't do that. > > > > > > Cache invalidation is destructive, so we want to make sure that it > > > doesn't affect anything beyond x1. But you are right, if either end of > > > the buffer is not cache line aligned it can get it wrong. The fix is to > > > use clean+invalidate on the unaligned ends: > > > > Like the ARMv7 implementation does :-) However, I wonder, is it possible > > for the Cache Writeback Granule (CWG) to come into play? If the CWG of > > further out caches was bigger than closer (to CPU) caches then it would > > cause data corruption. So for these region ends, should we not be using > > the CWG size, not the minimum D cache line size? On second thoughts, > > that wouldn't be safe either in the converse case where the CWG of a > > closer cache was bigger. So we would need to first use minimum cache > > line size to clean a CWG sized region, then invalidate cache lines by > > the same method. > > CWG gives us the maximum size (of all cache levels in the system, even > on a different CPU for example in big.LITTLE configurations) that would > be evicted by the cache operation. So we need small loops of Dmin size > that go over the bigger CWG (and that's guaranteed to be at least Dmin). Yes, that's what I was getting at. > > > But then that leaves a time period where a write can > > happen between the clean and the invalidate, again leading to data > > corruption. I hope all this means I've either got rather confused or > > that that cache architectures are smart enough to automatically cope. > > You are right. I think having unaligned DMA buffers for inbound > transfers is pointless. We can avoid losing data written by another CPU > in the same cache line but, depending on the stage of the DMA transfer, > it can corrupt the DMA data. > > I wonder whether it's easier to define the cache_line_size() macro to > read CWG That won't work, the stride of cache operations needs to be the _minimum_ cache line size, otherwise we might skip over some cache lines and not flush them. (We've been hit before by bugs caused by the fact that big.LITTLE systems report different minimum i-cache line sizes depend on whether you execute on the big or LITTLE cores [1], we need the 'real' minimum otherwise things go horribly wrong.) [1] http://lists.infradead.org/pipermail/linux-arm-kernel/2013-February/149950.html > and assume that the DMA buffers are always aligned, We can't assume the region in any particular DMA transfer is cache aligned, but I agree, that if multiple actors were operating on adjacent memory locations in the same cache line, without implementing their own coordination then there's nothing the low level DMA code can do to avoid data corruption from cache cleaning. We at least need to make sure that the memory allocation functions used for DMA buffers return regions of whole CWG size, to avoid unrelated buffers corrupting each other. If I have correctly read __dma_alloc_noncoherent and the functions it calls, then it looks like buffers are actually whole pages, so that's not a problem. > ignoring > the invalidation of the unaligned boundaries. This wouldn't be much > different from your scenario where the shared cache line is written > (just less likely to trigger but still a bug, so I would rather notice > this early). > > The ARMv7 code has a similar issue, it performs clean&invalidate on the > unaligned start but it doesn't move r0, so it goes into the main loop > invalidating the same cache line again. Yes, and as it's missing a dsb could also lead to the wrong behaviour if the invalidate was reordered to execute prior to the clean+invalidate on the same line. I just dug into git history to see if I could find a clue as to how the v7 code came to look like it does, but I see that it's been like that since the day it was submitted in 2007, by a certain Catalin Marinas ;-)
On Wed, 2014-04-02 at 10:20 +0100, Catalin Marinas wrote: > On Wed, Apr 02, 2014 at 09:52:02AM +0100, Jon Medhurst (Tixy) wrote: > > On Tue, 2014-04-01 at 18:29 +0100, Catalin Marinas wrote: > > > +1: tst x0, x3 // start cache line aligned? > > > + bic x0, x0, x3 > > > + b.eq 2f > > > + dc civac, x0 // clean & invalidate D / U line > > > + b 3f > > > +2: dc ivac, x0 // invalidate D / U line > > > +3: add x0, x0, x2 > > > cmp x0, x1 > > > b.lo 1b > > > > The above obviously also needs changing to branch to 3b > > Good point. Actually, it should be 2b :-)
On Wed, Apr 02, 2014 at 10:40:45AM +0100, Russell King - ARM Linux wrote: > On Wed, Apr 02, 2014 at 10:20:32AM +0100, Catalin Marinas wrote: > > You are right. I think having unaligned DMA buffers for inbound > > transfers is pointless. We can avoid losing data written by another CPU > > in the same cache line but, depending on the stage of the DMA transfer, > > it can corrupt the DMA data. > > > > I wonder whether it's easier to define the cache_line_size() macro to > > read CWG and assume that the DMA buffers are always aligned, ignoring > > the invalidation of the unaligned boundaries. This wouldn't be much > > different from your scenario where the shared cache line is written > > (just less likely to trigger but still a bug, so I would rather notice > > this early). > > > > The ARMv7 code has a similar issue, it performs clean&invalidate on the > > unaligned start but it doesn't move r0, so it goes into the main loop > > invalidating the same cache line again. If it was written by something > > else, the information would be lost. > > You can't make that a requirement. People have shared stuff across a > cache line for years in Linux, and people have brought it up and tried > to fix it, but there's much resistance against it. In particular is > SCSI, which submits the sense buffer as part of a larger structure (the > host.) SCSI sort-of guarantees that the surrounding struct members > won't be touched, but their data has to be preserved. Let's hope that CWG stays small enough on real hardware (as the architecture specifies it to max 2K). > In any case, remember that there are strict rules about ownership of the > DMA memory vs calls to the DMA API. It is invalid to call the DMA > streaming API functions while a DMA transfer is active. Yes, I was referring to non-DMA buffer area in the same cache line being touched during a DMA transfer.
On Wed, Apr 02, 2014 at 11:41:30AM +0100, Jon Medhurst (Tixy) wrote: > On Wed, 2014-04-02 at 10:20 +0100, Catalin Marinas wrote: > > On Wed, Apr 02, 2014 at 09:52:02AM +0100, Jon Medhurst (Tixy) wrote: > > > But then that leaves a time period where a write can > > > happen between the clean and the invalidate, again leading to data > > > corruption. I hope all this means I've either got rather confused or > > > that that cache architectures are smart enough to automatically cope. > > > > You are right. I think having unaligned DMA buffers for inbound > > transfers is pointless. We can avoid losing data written by another CPU > > in the same cache line but, depending on the stage of the DMA transfer, > > it can corrupt the DMA data. > > > > I wonder whether it's easier to define the cache_line_size() macro to > > read CWG > > That won't work, the stride of cache operations needs to be the > _minimum_ cache line size, otherwise we might skip over some cache lines > and not flush them. (We've been hit before by bugs caused by the fact > that big.LITTLE systems report different minimum i-cache line sizes > depend on whether you execute on the big or LITTLE cores [1], we need > the 'real' minimum otherwise things go horribly wrong.) > > [1] http://lists.infradead.org/pipermail/linux-arm-kernel/2013-February/149950.html Yes, I remember this. CWG should also be the same in a big.LITTLE system. > > and assume that the DMA buffers are always aligned, > > We can't assume the region in any particular DMA transfer is cache > aligned, but I agree, that if multiple actors were operating on adjacent > memory locations in the same cache line, without implementing their own > coordination then there's nothing the low level DMA code can do to avoid > data corruption from cache cleaning. > > We at least need to make sure that the memory allocation functions used > for DMA buffers return regions of whole CWG size, to avoid unrelated > buffers corrupting each other. If I have correctly read > __dma_alloc_noncoherent and the functions it calls, then it looks like > buffers are actually whole pages, so that's not a problem. It's not about dma_alloc but the streaming DMA API like dma_map_sg(). > > ignoring > > the invalidation of the unaligned boundaries. This wouldn't be much > > different from your scenario where the shared cache line is written > > (just less likely to trigger but still a bug, so I would rather notice > > this early). > > > > The ARMv7 code has a similar issue, it performs clean&invalidate on the > > unaligned start but it doesn't move r0, so it goes into the main loop > > invalidating the same cache line again. > > Yes, and as it's missing a dsb could also lead to the wrong behaviour if > the invalidate was reordered to execute prior to the clean+invalidate on > the same line. I just dug into git history to see if I could find a clue > as to how the v7 code came to look like it does, but I see that it's > been like that since the day it was submitted in 2007, by a certain > Catalin Marinas ;-) I don't remember ;). But there are some rules about reordering of cache line operations by MVA with regards to memory accesses. I have to check whether they apply to other d-cache maintenance to the same address as well. I'll try to come up with another patch using CWG.
diff --git a/arch/arm64/mm/cache.S b/arch/arm64/mm/cache.S index c46f48b33c14..6a26bf1965d3 100644 --- a/arch/arm64/mm/cache.S +++ b/arch/arm64/mm/cache.S @@ -175,10 +175,17 @@ ENDPROC(__flush_dcache_area) __dma_inv_range: dcache_line_size x2, x3 sub x3, x2, #1 - bic x0, x0, x3 + tst x1, x3 // end cache line aligned? bic x1, x1, x3 -1: dc ivac, x0 // invalidate D / U line - add x0, x0, x2 + b.eq 1f + dc civac, x1 // clean & invalidate D / U line +1: tst x0, x3 // start cache line aligned? + bic x0, x0, x3 + b.eq 2f + dc civac, x0 // clean & invalidate D / U line + b 3f +2: dc ivac, x0 // invalidate D / U line +3: add x0, x0, x2 cmp x0, x1 b.lo 1b dsb sy