1.. Copyright 2001 Matthew Wilcox 2.. 3.. This documentation is free software; you can redistribute 4.. it and/or modify it under the terms of the GNU General Public 5.. License as published by the Free Software Foundation; either 6.. version 2 of the License, or (at your option) any later 7.. version. 8 9=============================== 10Bus-Independent Device Accesses 11=============================== 12 13:Author: Matthew Wilcox 14:Author: Alan Cox 15 16Introduction 17============ 18 19Linux provides an API which abstracts performing IO across all busses 20and devices, allowing device drivers to be written independently of bus 21type. 22 23Memory Mapped IO 24================ 25 26Getting Access to the Device 27---------------------------- 28 29The most widely supported form of IO is memory mapped IO. That is, a 30part of the CPU's address space is interpreted not as accesses to 31memory, but as accesses to a device. Some architectures define devices 32to be at a fixed address, but most have some method of discovering 33devices. The PCI bus walk is a good example of such a scheme. This 34document does not cover how to receive such an address, but assumes you 35are starting with one. Physical addresses are of type unsigned long. 36 37This address should not be used directly. Instead, to get an address 38suitable for passing to the accessor functions described below, you 39should call ioremap(). An address suitable for accessing 40the device will be returned to you. 41 42After you've finished using the device (say, in your module's exit 43routine), call iounmap() in order to return the address 44space to the kernel. Most architectures allocate new address space each 45time you call ioremap(), and they can run out unless you 46call iounmap(). 47 48Accessing the device 49-------------------- 50 51The part of the interface most used by drivers is reading and writing 52memory-mapped registers on the device. Linux provides interfaces to read 53and write 8-bit, 16-bit, 32-bit and 64-bit quantities. Due to a 54historical accident, these are named byte, word, long and quad accesses. 55Both read and write accesses are supported; there is no prefetch support 56at this time. 57 58The functions are named readb(), readw(), readl(), readq(), 59readb_relaxed(), readw_relaxed(), readl_relaxed(), readq_relaxed(), 60writeb(), writew(), writel() and writeq(). 61 62Some devices (such as framebuffers) would like to use larger transfers than 638 bytes at a time. For these devices, the memcpy_toio(), 64memcpy_fromio() and memset_io() functions are 65provided. Do not use memset or memcpy on IO addresses; they are not 66guaranteed to copy data in order. 67 68The read and write functions are defined to be ordered. That is the 69compiler is not permitted to reorder the I/O sequence. When the ordering 70can be compiler optimised, you can use __readb() and friends to 71indicate the relaxed ordering. Use this with care. 72 73While the basic functions are defined to be synchronous with respect to 74each other and ordered with respect to each other the busses the devices 75sit on may themselves have asynchronicity. In particular many authors 76are burned by the fact that PCI bus writes are posted asynchronously. A 77driver author must issue a read from the same device to ensure that 78writes have occurred in the specific cases the author cares. This kind 79of property cannot be hidden from driver writers in the API. In some 80cases, the read used to flush the device may be expected to fail (if the 81card is resetting, for example). In that case, the read should be done 82from config space, which is guaranteed to soft-fail if the card doesn't 83respond. 84 85The following is an example of flushing a write to a device when the 86driver would like to ensure the write's effects are visible prior to 87continuing execution:: 88 89 static inline void 90 qla1280_disable_intrs(struct scsi_qla_host *ha) 91 { 92 struct device_reg *reg; 93 94 reg = ha->iobase; 95 /* disable risc and host interrupts */ 96 WRT_REG_WORD(®->ictrl, 0); 97 /* 98 * The following read will ensure that the above write 99 * has been received by the device before we return from this 100 * function. 101 */ 102 RD_REG_WORD(®->ictrl); 103 ha->flags.ints_enabled = 0; 104 } 105 106PCI ordering rules also guarantee that PIO read responses arrive after any 107outstanding DMA writes from that bus, since for some devices the result of 108a readb() call may signal to the driver that a DMA transaction is 109complete. In many cases, however, the driver may want to indicate that the 110next readb() call has no relation to any previous DMA writes 111performed by the device. The driver can use readb_relaxed() for 112these cases, although only some platforms will honor the relaxed 113semantics. Using the relaxed read functions will provide significant 114performance benefits on platforms that support it. The qla2xxx driver 115provides examples of how to use readX_relaxed(). In many cases, a majority 116of the driver's readX() calls can safely be converted to readX_relaxed() 117calls, since only a few will indicate or depend on DMA completion. 118 119Port Space Accesses 120=================== 121 122Port Space Explained 123-------------------- 124 125Another form of IO commonly supported is Port Space. This is a range of 126addresses separate to the normal memory address space. Access to these 127addresses is generally not as fast as accesses to the memory mapped 128addresses, and it also has a potentially smaller address space. 129 130Unlike memory mapped IO, no preparation is required to access port 131space. 132 133Accessing Port Space 134-------------------- 135 136Accesses to this space are provided through a set of functions which 137allow 8-bit, 16-bit and 32-bit accesses; also known as byte, word and 138long. These functions are inb(), inw(), 139inl(), outb(), outw() and 140outl(). 141 142Some variants are provided for these functions. Some devices require 143that accesses to their ports are slowed down. This functionality is 144provided by appending a ``_p`` to the end of the function. 145There are also equivalents to memcpy. The ins() and 146outs() functions copy bytes, words or longs to the given 147port. 148 149__iomem pointer tokens 150====================== 151 152The data type for an MMIO address is an ``__iomem`` qualified pointer, such as 153``void __iomem *reg``. On most architectures it is a regular pointer that 154points to a virtual memory address and can be offset or dereferenced, but in 155portable code, it must only be passed from and to functions that explicitly 156operated on an ``__iomem`` token, in particular the ioremap() and 157readl()/writel() functions. The 'sparse' semantic code checker can be used to 158verify that this is done correctly. 159 160While on most architectures, ioremap() creates a page table entry for an 161uncached virtual address pointing to the physical MMIO address, some 162architectures require special instructions for MMIO, and the ``__iomem`` pointer 163just encodes the physical address or an offsettable cookie that is interpreted 164by readl()/writel(). 165 166Differences between I/O access functions 167======================================== 168 169readq(), readl(), readw(), readb(), writeq(), writel(), writew(), writeb() 170 171 These are the most generic accessors, providing serialization against other 172 MMIO accesses and DMA accesses as well as fixed endianness for accessing 173 little-endian PCI devices and on-chip peripherals. Portable device drivers 174 should generally use these for any access to ``__iomem`` pointers. 175 176 Note that posted writes are not strictly ordered against a spinlock, see 177 Documentation/driver-api/io_ordering.rst. 178 179readq_relaxed(), readl_relaxed(), readw_relaxed(), readb_relaxed(), 180writeq_relaxed(), writel_relaxed(), writew_relaxed(), writeb_relaxed() 181 182 On architectures that require an expensive barrier for serializing against 183 DMA, these "relaxed" versions of the MMIO accessors only serialize against 184 each other, but contain a less expensive barrier operation. A device driver 185 might use these in a particularly performance sensitive fast path, with a 186 comment that explains why the usage in a specific location is safe without 187 the extra barriers. 188 189 See memory-barriers.txt for a more detailed discussion on the precise ordering 190 guarantees of the non-relaxed and relaxed versions. 191 192ioread64(), ioread32(), ioread16(), ioread8(), 193iowrite64(), iowrite32(), iowrite16(), iowrite8() 194 195 These are an alternative to the normal readl()/writel() functions, with almost 196 identical behavior, but they can also operate on ``__iomem`` tokens returned 197 for mapping PCI I/O space with pci_iomap() or ioport_map(). On architectures 198 that require special instructions for I/O port access, this adds a small 199 overhead for an indirect function call implemented in lib/iomap.c, while on 200 other architectures, these are simply aliases. 201 202ioread64be(), ioread32be(), ioread16be() 203iowrite64be(), iowrite32be(), iowrite16be() 204 205 These behave in the same way as the ioread32()/iowrite32() family, but with 206 reversed byte order, for accessing devices with big-endian MMIO registers. 207 Device drivers that can operate on either big-endian or little-endian 208 registers may have to implement a custom wrapper function that picks one or 209 the other depending on which device was found. 210 211 Note: On some architectures, the normal readl()/writel() functions 212 traditionally assume that devices are the same endianness as the CPU, while 213 using a hardware byte-reverse on the PCI bus when running a big-endian kernel. 214 Drivers that use readl()/writel() this way are generally not portable, but 215 tend to be limited to a particular SoC. 216 217hi_lo_readq(), lo_hi_readq(), hi_lo_readq_relaxed(), lo_hi_readq_relaxed(), 218ioread64_lo_hi(), ioread64_hi_lo(), ioread64be_lo_hi(), ioread64be_hi_lo(), 219hi_lo_writeq(), lo_hi_writeq(), hi_lo_writeq_relaxed(), lo_hi_writeq_relaxed(), 220iowrite64_lo_hi(), iowrite64_hi_lo(), iowrite64be_lo_hi(), iowrite64be_hi_lo() 221 222 Some device drivers have 64-bit registers that cannot be accessed atomically 223 on 32-bit architectures but allow two consecutive 32-bit accesses instead. 224 Since it depends on the particular device which of the two halves has to be 225 accessed first, a helper is provided for each combination of 64-bit accessors 226 with either low/high or high/low word ordering. A device driver must include 227 either <linux/io-64-nonatomic-lo-hi.h> or <linux/io-64-nonatomic-hi-lo.h> to 228 get the function definitions along with helpers that redirect the normal 229 readq()/writeq() to them on architectures that do not provide 64-bit access 230 natively. 231 232__raw_readq(), __raw_readl(), __raw_readw(), __raw_readb(), 233__raw_writeq(), __raw_writel(), __raw_writew(), __raw_writeb() 234 235 These are low-level MMIO accessors without barriers or byteorder changes and 236 architecture specific behavior. Accesses are usually atomic in the sense that 237 a four-byte __raw_readl() does not get split into individual byte loads, but 238 multiple consecutive accesses can be combined on the bus. In portable code, it 239 is only safe to use these to access memory behind a device bus but not MMIO 240 registers, as there are no ordering guarantees with regard to other MMIO 241 accesses or even spinlocks. The byte order is generally the same as for normal 242 memory, so unlike the other functions, these can be used to copy data between 243 kernel memory and device memory. 244 245inl(), inw(), inb(), outl(), outw(), outb() 246 247 PCI I/O port resources traditionally require separate helpers as they are 248 implemented using special instructions on the x86 architecture. On most other 249 architectures, these are mapped to readl()/writel() style accessors 250 internally, usually pointing to a fixed area in virtual memory. Instead of an 251 ``__iomem`` pointer, the address is a 32-bit integer token to identify a port 252 number. PCI requires I/O port access to be non-posted, meaning that an outb() 253 must complete before the following code executes, while a normal writeb() may 254 still be in progress. On architectures that correctly implement this, I/O port 255 access is therefore ordered against spinlocks. Many non-x86 PCI host bridge 256 implementations and CPU architectures however fail to implement non-posted I/O 257 space on PCI, so they can end up being posted on such hardware. 258 259 In some architectures, the I/O port number space has a 1:1 mapping to 260 ``__iomem`` pointers, but this is not recommended and device drivers should 261 not rely on that for portability. Similarly, an I/O port number as described 262 in a PCI base address register may not correspond to the port number as seen 263 by a device driver. Portable drivers need to read the port number for the 264 resource provided by the kernel. 265 266 There are no direct 64-bit I/O port accessors, but pci_iomap() in combination 267 with ioread64/iowrite64 can be used instead. 268 269inl_p(), inw_p(), inb_p(), outl_p(), outw_p(), outb_p() 270 271 On ISA devices that require specific timing, the _p versions of the I/O 272 accessors add a small delay. On architectures that do not have ISA buses, 273 these are aliases to the normal inb/outb helpers. 274 275readsq, readsl, readsw, readsb 276writesq, writesl, writesw, writesb 277ioread64_rep, ioread32_rep, ioread16_rep, ioread8_rep 278iowrite64_rep, iowrite32_rep, iowrite16_rep, iowrite8_rep 279insl, insw, insb, outsl, outsw, outsb 280 281 These are helpers that access the same address multiple times, usually to copy 282 data between kernel memory byte stream and a FIFO buffer. Unlike the normal 283 MMIO accessors, these do not perform a byteswap on big-endian kernels, so the 284 first byte in the FIFO register corresponds to the first byte in the memory 285 buffer regardless of the architecture. 286 287Device memory mapping modes 288=========================== 289 290Some architectures support multiple modes for mapping device memory. 291ioremap_*() variants provide a common abstraction around these 292architecture-specific modes, with a shared set of semantics. 293 294ioremap() is the most common mapping type, and is applicable to typical device 295memory (e.g. I/O registers). Other modes can offer weaker or stronger 296guarantees, if supported by the architecture. From most to least common, they 297are as follows: 298 299ioremap() 300--------- 301 302The default mode, suitable for most memory-mapped devices, e.g. control 303registers. Memory mapped using ioremap() has the following characteristics: 304 305* Uncached - CPU-side caches are bypassed, and all reads and writes are handled 306 directly by the device 307* No speculative operations - the CPU may not issue a read or write to this 308 memory, unless the instruction that does so has been reached in committed 309 program flow. 310* No reordering - The CPU may not reorder accesses to this memory mapping with 311 respect to each other. On some architectures, this relies on barriers in 312 readl_relaxed()/writel_relaxed(). 313* No repetition - The CPU may not issue multiple reads or writes for a single 314 program instruction. 315* No write-combining - Each I/O operation results in one discrete read or write 316 being issued to the device, and multiple writes are not combined into larger 317 writes. This may or may not be enforced when using __raw I/O accessors or 318 pointer dereferences. 319* Non-executable - The CPU is not allowed to speculate instruction execution 320 from this memory (it probably goes without saying, but you're also not 321 allowed to jump into device memory). 322 323On many platforms and buses (e.g. PCI), writes issued through ioremap() 324mappings are posted, which means that the CPU does not wait for the write to 325actually reach the target device before retiring the write instruction. 326 327On many platforms, I/O accesses must be aligned with respect to the access 328size; failure to do so will result in an exception or unpredictable results. 329 330ioremap_wc() 331------------ 332 333Maps I/O memory as normal memory with write combining. Unlike ioremap(), 334 335* The CPU may speculatively issue reads from the device that the program 336 didn't actually execute, and may choose to basically read whatever it wants. 337* The CPU may reorder operations as long as the result is consistent from the 338 program's point of view. 339* The CPU may write to the same location multiple times, even when the program 340 issued a single write. 341* The CPU may combine several writes into a single larger write. 342 343This mode is typically used for video framebuffers, where it can increase 344performance of writes. It can also be used for other blocks of memory in 345devices (e.g. buffers or shared memory), but care must be taken as accesses are 346not guaranteed to be ordered with respect to normal ioremap() MMIO register 347accesses without explicit barriers. 348 349On a PCI bus, it is usually safe to use ioremap_wc() on MMIO areas marked as 350``IORESOURCE_PREFETCH``, but it may not be used on those without the flag. 351For on-chip devices, there is no corresponding flag, but a driver can use 352ioremap_wc() on a device that is known to be safe. 353 354ioremap_wt() 355------------ 356 357Maps I/O memory as normal memory with write-through caching. Like ioremap_wc(), 358but also, 359 360* The CPU may cache writes issued to and reads from the device, and serve reads 361 from that cache. 362 363This mode is sometimes used for video framebuffers, where drivers still expect 364writes to reach the device in a timely manner (and not be stuck in the CPU 365cache), but reads may be served from the cache for efficiency. However, it is 366rarely useful these days, as framebuffer drivers usually perform writes only, 367for which ioremap_wc() is more efficient (as it doesn't needlessly trash the 368cache). Most drivers should not use this. 369 370ioremap_np() 371------------ 372 373Like ioremap(), but explicitly requests non-posted write semantics. On some 374architectures and buses, ioremap() mappings have posted write semantics, which 375means that writes can appear to "complete" from the point of view of the 376CPU before the written data actually arrives at the target device. Writes are 377still ordered with respect to other writes and reads from the same device, but 378due to the posted write semantics, this is not the case with respect to other 379devices. ioremap_np() explicitly requests non-posted semantics, which means 380that the write instruction will not appear to complete until the device has 381received (and to some platform-specific extent acknowledged) the written data. 382 383This mapping mode primarily exists to cater for platforms with bus fabrics that 384require this particular mapping mode to work correctly. These platforms set the 385``IORESOURCE_MEM_NONPOSTED`` flag for a resource that requires ioremap_np() 386semantics and portable drivers should use an abstraction that automatically 387selects it where appropriate (see the `Higher-level ioremap abstractions`_ 388section below). 389 390The bare ioremap_np() is only available on some architectures; on others, it 391always returns NULL. Drivers should not normally use it, unless they are 392platform-specific or they derive benefit from non-posted writes where 393supported, and can fall back to ioremap() otherwise. The normal approach to 394ensure posted write completion is to do a dummy read after a write as 395explained in `Accessing the device`_, which works with ioremap() on all 396platforms. 397 398ioremap_np() should never be used for PCI drivers. PCI memory space writes are 399always posted, even on architectures that otherwise implement ioremap_np(). 400Using ioremap_np() for PCI BARs will at best result in posted write semantics, 401and at worst result in complete breakage. 402 403Note that non-posted write semantics are orthogonal to CPU-side ordering 404guarantees. A CPU may still choose to issue other reads or writes before a 405non-posted write instruction retires. See the previous section on MMIO access 406functions for details on the CPU side of things. 407 408ioremap_uc() 409------------ 410 411ioremap_uc() behaves like ioremap() except that on the x86 architecture without 412'PAT' mode, it marks memory as uncached even when the MTRR has designated 413it as cacheable, see Documentation/arch/x86/pat.rst. 414 415Portable drivers should avoid the use of ioremap_uc(). 416 417ioremap_cache() 418--------------- 419 420ioremap_cache() effectively maps I/O memory as normal RAM. CPU write-back 421caches can be used, and the CPU is free to treat the device as if it were a 422block of RAM. This should never be used for device memory which has side 423effects of any kind, or which does not return the data previously written on 424read. 425 426It should also not be used for actual RAM, as the returned pointer is an 427``__iomem`` token. memremap() can be used for mapping normal RAM that is outside 428of the linear kernel memory area to a regular pointer. 429 430Portable drivers should avoid the use of ioremap_cache(). 431 432Architecture example 433-------------------- 434 435Here is how the above modes map to memory attribute settings on the ARM64 436architecture: 437 438+------------------------+--------------------------------------------+ 439| API | Memory region type and cacheability | 440+------------------------+--------------------------------------------+ 441| ioremap_np() | Device-nGnRnE | 442+------------------------+--------------------------------------------+ 443| ioremap() | Device-nGnRE | 444+------------------------+--------------------------------------------+ 445| ioremap_uc() | (not implemented) | 446+------------------------+--------------------------------------------+ 447| ioremap_wc() | Normal-Non Cacheable | 448+------------------------+--------------------------------------------+ 449| ioremap_wt() | (not implemented; fallback to ioremap) | 450+------------------------+--------------------------------------------+ 451| ioremap_cache() | Normal-Write-Back Cacheable | 452+------------------------+--------------------------------------------+ 453 454Higher-level ioremap abstractions 455================================= 456 457Instead of using the above raw ioremap() modes, drivers are encouraged to use 458higher-level APIs. These APIs may implement platform-specific logic to 459automatically choose an appropriate ioremap mode on any given bus, allowing for 460a platform-agnostic driver to work on those platforms without any special 461cases. At the time of this writing, the following ioremap() wrappers have such 462logic: 463 464devm_ioremap_resource() 465 466 Can automatically select ioremap_np() over ioremap() according to platform 467 requirements, if the ``IORESOURCE_MEM_NONPOSTED`` flag is set on the struct 468 resource. Uses devres to automatically unmap the resource when the driver 469 probe() function fails or a device in unbound from its driver. 470 471 Documented in Documentation/driver-api/driver-model/devres.rst. 472 473of_address_to_resource() 474 475 Automatically sets the ``IORESOURCE_MEM_NONPOSTED`` flag for platforms that 476 require non-posted writes for certain buses (see the nonposted-mmio and 477 posted-mmio device tree properties). 478 479of_iomap() 480 481 Maps the resource described in a ``reg`` property in the device tree, doing 482 all required translations. Automatically selects ioremap_np() according to 483 platform requirements, as above. 484 485pci_ioremap_bar(), pci_ioremap_wc_bar() 486 487 Maps the resource described in a PCI base address without having to extract 488 the physical address first. 489 490pci_iomap(), pci_iomap_wc() 491 492 Like pci_ioremap_bar()/pci_ioremap_bar(), but also works on I/O space when 493 used together with ioread32()/iowrite32() and similar accessors 494 495pcim_iomap() 496 497 Like pci_iomap(), but uses devres to automatically unmap the resource when 498 the driver probe() function fails or a device in unbound from its driver 499 500 Documented in Documentation/driver-api/driver-model/devres.rst. 501 502Not using these wrappers may make drivers unusable on certain platforms with 503stricter rules for mapping I/O memory. 504 505Generalizing Access to System and I/O Memory 506============================================ 507 508.. kernel-doc:: include/linux/iosys-map.h 509 :doc: overview 510 511.. kernel-doc:: include/linux/iosys-map.h 512 :internal: 513 514Public Functions Provided 515========================= 516 517.. kernel-doc:: arch/x86/include/asm/io.h 518 :internal: 519 520.. kernel-doc:: lib/pci_iomap.c 521 :export: 522