xref: /openbmc/qemu/docs/devel/loads-stores.rst (revision 5b76dd13)
1..
2   Copyright (c) 2017 Linaro Limited
3   Written by Peter Maydell
4
5===================
6Load and Store APIs
7===================
8
9QEMU internally has multiple families of functions for performing
10loads and stores. This document attempts to enumerate them all
11and indicate when to use them. It does not provide detailed
12documentation of each API -- for that you should look at the
13documentation comments in the relevant header files.
14
15
16``ld*_p and st*_p``
17~~~~~~~~~~~~~~~~~~~
18
19These functions operate on a host pointer, and should be used
20when you already have a pointer into host memory (corresponding
21to guest ram or a local buffer). They deal with doing accesses
22with the desired endianness and with correctly handling
23potentially unaligned pointer values.
24
25Function names follow the pattern:
26
27load: ``ld{type}{sign}{size}_{endian}_p(ptr)``
28
29store: ``st{type}{size}_{endian}_p(ptr, val)``
30
31``type``
32 - (empty) : integer access
33 - ``f`` : float access
34
35``sign``
36 - (empty) : for 32 or 64 bit sizes (including floats and doubles)
37 - ``u`` : unsigned
38 - ``s`` : signed
39
40``size``
41 - ``b`` : 8 bits
42 - ``w`` : 16 bits
43 - ``l`` : 32 bits
44 - ``q`` : 64 bits
45
46``endian``
47 - ``he`` : host endian
48 - ``be`` : big endian
49 - ``le`` : little endian
50
51The ``_{endian}`` infix is omitted for target-endian accesses.
52
53The target endian accessors are only available to source
54files which are built per-target.
55
56There are also functions which take the size as an argument:
57
58load: ``ldn{endian}_p(ptr, sz)``
59
60which performs an unsigned load of ``sz`` bytes from ``ptr``
61as an ``{endian}`` order value and returns it in a uint64_t.
62
63store: ``stn{endian}_p(ptr, sz, val)``
64
65which stores ``val`` to ``ptr`` as an ``{endian}`` order value
66of size ``sz`` bytes.
67
68
69Regexes for git grep
70 - ``\<ldf\?[us]\?[bwlq]\(_[hbl]e\)\?_p\>``
71 - ``\<stf\?[bwlq]\(_[hbl]e\)\?_p\>``
72 - ``\<ldn_\([hbl]e\)?_p\>``
73 - ``\<stn_\([hbl]e\)?_p\>``
74
75``cpu_{ld,st}_*``
76~~~~~~~~~~~~~~~~~
77
78These functions operate on a guest virtual address. Be aware
79that these functions may cause a guest CPU exception to be
80taken (e.g. for an alignment fault or MMU fault) which will
81result in guest CPU state being updated and control longjumping
82out of the function call. They should therefore only be used
83in code that is implementing emulation of the target CPU.
84
85These functions may throw an exception (longjmp() back out
86to the top level TCG loop). This means they must only be used
87from helper functions where the translator has saved all
88necessary CPU state before generating the helper function call.
89It's usually better to use the ``_ra`` variants described below
90from helper functions, but these functions are the right choice
91for calls made from hooks like the CPU do_interrupt hook or
92when you know for certain that the translator had to save all
93the CPU state that ``cpu_restore_state()`` would restore anyway.
94
95Function names follow the pattern:
96
97load: ``cpu_ld{sign}{size}_{mmusuffix}(env, ptr)``
98
99store: ``cpu_st{size}_{mmusuffix}(env, ptr, val)``
100
101``sign``
102 - (empty) : for 32 or 64 bit sizes
103 - ``u`` : unsigned
104 - ``s`` : signed
105
106``size``
107 - ``b`` : 8 bits
108 - ``w`` : 16 bits
109 - ``l`` : 32 bits
110 - ``q`` : 64 bits
111
112``mmusuffix`` is one of the generic suffixes ``data`` or ``code``, or
113(for softmmu configs) a target-specific MMU mode suffix as defined
114in the target's ``cpu.h``.
115
116Regexes for git grep
117 - ``\<cpu_ld[us]\?[bwlq]_[a-zA-Z0-9]\+\>``
118 - ``\<cpu_st[bwlq]_[a-zA-Z0-9]\+\>``
119
120``cpu_{ld,st}_*_ra``
121~~~~~~~~~~~~~~~~~~~~
122
123These functions work like the ``cpu_{ld,st}_*`` functions except
124that they also take a ``retaddr`` argument. This extra argument
125allows for correct unwinding of any exception that is taken,
126and should generally be the result of GETPC() called directly
127from the top level HELPER(foo) function (i.e. the return address
128in the generated code).
129
130These are generally the preferred way to do accesses by guest
131virtual address from helper functions; see the documentation
132of the non-``_ra`` variants for when those would be better.
133
134Calling these functions with a ``retaddr`` argument of 0 is
135equivalent to calling the non-``_ra`` version of the function.
136
137Function names follow the pattern:
138
139load: ``cpu_ld{sign}{size}_{mmusuffix}_ra(env, ptr, retaddr)``
140
141store: ``cpu_st{sign}{size}_{mmusuffix}_ra(env, ptr, val, retaddr)``
142
143Regexes for git grep
144 - ``\<cpu_ld[us]\?[bwlq]_[a-zA-Z0-9]\+_ra\>``
145 - ``\<cpu_st[bwlq]_[a-zA-Z0-9]\+_ra\>``
146
147``helper_*_{ld,st}*mmu``
148~~~~~~~~~~~~~~~~~~~~~~~~
149
150These functions are intended primarily to be called by the code
151generated by the TCG backend. They may also be called by target
152CPU helper function code. Like the ``cpu_{ld,st}_*_ra`` functions
153they perform accesses by guest virtual address; the difference is
154that these functions allow you to specify an ``opindex`` parameter
155which encodes (among other things) the mmu index to use for the
156access. This is necessary if your helper needs to make an access
157via a specific mmu index (for instance, an "always as non-privileged"
158access) rather than using the default mmu index for the current state
159of the guest CPU.
160
161The ``opindex`` parameter should be created by calling ``make_memop_idx()``.
162
163The ``retaddr`` parameter should be the result of GETPC() called directly
164from the top level HELPER(foo) function (or 0 if no guest CPU state
165unwinding is required).
166
167**TODO** The names of these functions are a bit odd for historical
168reasons because they were originally expected to be called only from
169within generated code. We should rename them to bring them
170more in line with the other memory access functions.
171
172load: ``helper_{endian}_ld{sign}{size}_mmu(env, addr, opindex, retaddr)``
173
174load (code): ``helper_{endian}_ld{sign}{size}_cmmu(env, addr, opindex, retaddr)``
175
176store: ``helper_{endian}_st{size}_mmu(env, addr, val, opindex, retaddr)``
177
178``sign``
179 - (empty) : for 32 or 64 bit sizes
180 - ``u`` : unsigned
181 - ``s`` : signed
182
183``size``
184 - ``b`` : 8 bits
185 - ``w`` : 16 bits
186 - ``l`` : 32 bits
187 - ``q`` : 64 bits
188
189``endian``
190 - ``le`` : little endian
191 - ``be`` : big endian
192 - ``ret`` : target endianness
193
194Regexes for git grep
195 - ``\<helper_\(le\|be\|ret\)_ld[us]\?[bwlq]_c\?mmu\>``
196 - ``\<helper_\(le\|be\|ret\)_st[bwlq]_mmu\>``
197
198``address_space_*``
199~~~~~~~~~~~~~~~~~~~
200
201These functions are the primary ones to use when emulating CPU
202or device memory accesses. They take an AddressSpace, which is the
203way QEMU defines the view of memory that a device or CPU has.
204(They generally correspond to being the "master" end of a hardware bus
205or bus fabric.)
206
207Each CPU has an AddressSpace. Some kinds of CPU have more than
208one AddressSpace (for instance ARM guest CPUs have an AddressSpace
209for the Secure world and one for NonSecure if they implement TrustZone).
210Devices which can do DMA-type operations should generally have an
211AddressSpace. There is also a "system address space" which typically
212has all the devices and memory that all CPUs can see. (Some older
213device models use the "system address space" rather than properly
214modelling that they have an AddressSpace of their own.)
215
216Functions are provided for doing byte-buffer reads and writes,
217and also for doing one-data-item loads and stores.
218
219In all cases the caller provides a MemTxAttrs to specify bus
220transaction attributes, and can check whether the memory transaction
221succeeded using a MemTxResult return code.
222
223``address_space_read(address_space, addr, attrs, buf, len)``
224
225``address_space_write(address_space, addr, attrs, buf, len)``
226
227``address_space_rw(address_space, addr, attrs, buf, len, is_write)``
228
229``address_space_ld{sign}{size}_{endian}(address_space, addr, attrs, txresult)``
230
231``address_space_st{size}_{endian}(address_space, addr, val, attrs, txresult)``
232
233``sign``
234 - (empty) : for 32 or 64 bit sizes
235 - ``u`` : unsigned
236
237(No signed load operations are provided.)
238
239``size``
240 - ``b`` : 8 bits
241 - ``w`` : 16 bits
242 - ``l`` : 32 bits
243 - ``q`` : 64 bits
244
245``endian``
246 - ``le`` : little endian
247 - ``be`` : big endian
248
249The ``_{endian}`` suffix is omitted for byte accesses.
250
251Regexes for git grep
252 - ``\<address_space_\(read\|write\|rw\)\>``
253 - ``\<address_space_ldu\?[bwql]\(_[lb]e\)\?\>``
254 - ``\<address_space_st[bwql]\(_[lb]e\)\?\>``
255
256``address_space_write_rom``
257~~~~~~~~~~~~~~~~~~~~~~~~~~~
258
259This function performs a write by physical address like
260``address_space_write``, except that if the write is to a ROM then
261the ROM contents will be modified, even though a write by the guest
262CPU to the ROM would be ignored. This is used for non-guest writes
263like writes from the gdb debug stub or initial loading of ROM contents.
264
265Note that portions of the write which attempt to write data to a
266device will be silently ignored -- only real RAM and ROM will
267be written to.
268
269Regexes for git grep
270 - ``address_space_write_rom``
271
272``{ld,st}*_phys``
273~~~~~~~~~~~~~~~~~
274
275These are functions which are identical to
276``address_space_{ld,st}*``, except that they always pass
277``MEMTXATTRS_UNSPECIFIED`` for the transaction attributes, and ignore
278whether the transaction succeeded or failed.
279
280The fact that they ignore whether the transaction succeeded means
281they should not be used in new code, unless you know for certain
282that your code will only be used in a context where the CPU or
283device doing the access has no way to report such an error.
284
285``load: ld{sign}{size}_{endian}_phys``
286
287``store: st{size}_{endian}_phys``
288
289``sign``
290 - (empty) : for 32 or 64 bit sizes
291 - ``u`` : unsigned
292
293(No signed load operations are provided.)
294
295``size``
296 - ``b`` : 8 bits
297 - ``w`` : 16 bits
298 - ``l`` : 32 bits
299 - ``q`` : 64 bits
300
301``endian``
302 - ``le`` : little endian
303 - ``be`` : big endian
304
305The ``_{endian}_`` infix is omitted for byte accesses.
306
307Regexes for git grep
308 - ``\<ldu\?[bwlq]\(_[bl]e\)\?_phys\>``
309 - ``\<st[bwlq]\(_[bl]e\)\?_phys\>``
310
311``cpu_physical_memory_*``
312~~~~~~~~~~~~~~~~~~~~~~~~~
313
314These are convenience functions which are identical to
315``address_space_*`` but operate specifically on the system address space,
316always pass a ``MEMTXATTRS_UNSPECIFIED`` set of memory attributes and
317ignore whether the memory transaction succeeded or failed.
318For new code they are better avoided:
319
320* there is likely to be behaviour you need to model correctly for a
321  failed read or write operation
322* a device should usually perform operations on its own AddressSpace
323  rather than using the system address space
324
325``cpu_physical_memory_read``
326
327``cpu_physical_memory_write``
328
329``cpu_physical_memory_rw``
330
331Regexes for git grep
332 - ``\<cpu_physical_memory_\(read\|write\|rw\)\>``
333
334``cpu_memory_rw_debug``
335~~~~~~~~~~~~~~~~~~~~~~~
336
337Access CPU memory by virtual address for debug purposes.
338
339This function is intended for use by the GDB stub and similar code.
340It takes a virtual address, converts it to a physical address via
341an MMU lookup using the current settings of the specified CPU,
342and then performs the access (using ``address_space_rw`` for
343reads or ``cpu_physical_memory_write_rom`` for writes).
344This means that if the access is a write to a ROM then this
345function will modify the contents (whereas a normal guest CPU access
346would ignore the write attempt).
347
348``cpu_memory_rw_debug``
349
350``dma_memory_*``
351~~~~~~~~~~~~~~~~
352
353These behave like ``address_space_*``, except that they perform a DMA
354barrier operation first.
355
356**TODO**: We should provide guidance on when you need the DMA
357barrier operation and when it's OK to use ``address_space_*``, and
358make sure our existing code is doing things correctly.
359
360``dma_memory_read``
361
362``dma_memory_write``
363
364``dma_memory_rw``
365
366Regexes for git grep
367 - ``\<dma_memory_\(read\|write\|rw\)\>``
368
369``pci_dma_*`` and ``{ld,st}*_pci_dma``
370~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
371
372These functions are specifically for PCI device models which need to
373perform accesses where the PCI device is a bus master. You pass them a
374``PCIDevice *`` and they will do ``dma_memory_*`` operations on the
375correct address space for that device.
376
377``pci_dma_read``
378
379``pci_dma_write``
380
381``pci_dma_rw``
382
383``load: ld{sign}{size}_{endian}_pci_dma``
384
385``store: st{size}_{endian}_pci_dma``
386
387``sign``
388 - (empty) : for 32 or 64 bit sizes
389 - ``u`` : unsigned
390
391(No signed load operations are provided.)
392
393``size``
394 - ``b`` : 8 bits
395 - ``w`` : 16 bits
396 - ``l`` : 32 bits
397 - ``q`` : 64 bits
398
399``endian``
400 - ``le`` : little endian
401 - ``be`` : big endian
402
403The ``_{endian}_`` infix is omitted for byte accesses.
404
405Regexes for git grep
406 - ``\<pci_dma_\(read\|write\|rw\)\>``
407 - ``\<ldu\?[bwlq]\(_[bl]e\)\?_pci_dma\>``
408 - ``\<st[bwlq]\(_[bl]e\)\?_pci_dma\>``
409