| blob | 7044133e2d70dc035b8b96d20ed8204828d27e41 |
1 /*
2 * ARM Generic Interrupt Controller v3
3 *
4 * Copyright (c) 2015 Huawei.
5 * Copyright (c) 2016 Linaro Limited
6 * Written by Shlomo Pongratz, Peter Maydell
7 *
8 * This code is licensed under the GPL, version 2 or (at your option)
9 * any later version.
10 */
12 /* This file contains implementation code for an interrupt controller
13 * which implements the GICv3 architecture. Specifically this is where
14 * the device class itself and the functions for handling interrupts
15 * coming in and going out live.
16 */
25 {
26 /* Return true if this IRQ at this priority should take
27 * precedence over the current recorded highest priority
28 * pending interrupt for this CPU. We also return true if
29 * the current recorded highest priority pending interrupt
30 * is the same as this one (a property which the calling code
31 * relies on).
32 */
35 }
36 /* If multiple pending interrupts have the same priority then it is an
37 * IMPDEF choice which of them to signal to the CPU. We choose to
38 * signal the one with the lowest interrupt number.
39 */
42 }
44 }
47 {
48 /* Recalculate which distributor interrupts are actually pending
49 * in the group of 32 interrupts starting at irq (which should be a multiple
50 * of 32), and return a 32-bit integer which has a bit set for each
51 * interrupt that is eligible to be signaled to the CPU interface.
52 *
53 * An interrupt is pending if:
54 * + the PENDING latch is set OR it is level triggered and the input is 1
55 * + its ENABLE bit is set
56 * + the GICD enable bit for its group is set
57 * + its ACTIVE bit is not set (otherwise it would be Active+Pending)
58 * Conveniently we can bulk-calculate this with bitwise operations.
59 */
75 }
80 }
83 }
86 }
90 }
93 {
94 /* Recalculate which redistributor interrupts are actually pending,
95 * and return a 32-bit integer which has a bit set for each interrupt
96 * that is eligible to be signaled to the CPU interface.
97 *
98 * An interrupt is pending if:
99 * + the PENDING latch is set OR it is level triggered and the input is 1
100 * + its ENABLE bit is set
101 * + the GICD enable bit for its group is set
102 * + its ACTIVE bit is not set (otherwise it would be Active+Pending)
103 * Conveniently we can bulk-calculate this with bitwise operations.
104 */
115 }
120 }
123 }
126 }
130 }
132 /* Update the interrupt status after state in a redistributor
133 * or CPU interface has changed, but don't tell the CPU i/f.
134 */
136 {
137 /* Find the highest priority pending interrupt among the
138 * redistributor interrupts (SGIs and PPIs).
139 */
145 /* Find out which redistributor interrupts are eligible to be
146 * signaled to the CPU interface.
147 */
154 }
160 }
161 }
162 }
166 }
168 /* If the best interrupt we just found would preempt whatever
169 * was the previous best interrupt before this update, then
170 * we know it's definitely the best one now.
171 * If we didn't find an interrupt that would preempt the previous
172 * best, and the previous best is outside our range (or there was no
173 * previous pending interrupt at all), then that is still valid, and
174 * we leave it as the best.
175 * Otherwise, we need to do a full update (because the previous best
176 * interrupt has reduced in priority and any other interrupt could
177 * now be the new best one).
178 */
181 }
182 }
184 /* Update the GIC status after state in a redistributor or
185 * CPU interface has changed, and inform the CPU i/f of
186 * its new highest priority pending interrupt.
187 */
189 {
192 }
194 /* Update the GIC status after state in the distributor has
195 * changed affecting @len interrupts starting at @start,
196 * but don't tell the CPU i/f.
197 */
199 {
209 }
211 /* Find the highest priority pending interrupt in this range. */
216 /* Calculate the next 32 bits worth of pending status */
218 }
222 }
225 /* Interrupts targeting no implemented CPU should remain pending
226 * and not be forwarded to any CPU.
227 */
229 }
235 }
236 }
238 /* If the best interrupt we just found would preempt whatever
239 * was the previous best interrupt before this update, then
240 * we know it's definitely the best one now.
241 * If we didn't find an interrupt that would preempt the previous
242 * best, and the previous best is outside our range (or there was
243 * no previous pending interrupt at all), then that
244 * is still valid, and we leave it as the best.
245 * Otherwise, we need to do a full update (because the previous best
246 * interrupt has reduced in priority and any other interrupt could
247 * now be the new best one).
248 */
254 }
260 }
261 }
262 }
265 {
271 }
272 }
275 {
276 /* Completely recalculate the GIC status from scratch, but
277 * don't update any outbound IRQ lines.
278 */
283 }
285 /* Note that we can guarantee that these functions will not
286 * recursively call back into gicv3_full_update(), because
287 * at each point the "previous best" is always outside the
288 * range we ask them to update.
289 */
294 }
295 }
298 {
299 /* Completely recalculate the GIC status from scratch, including
300 * updating outbound IRQ lines.
301 */
307 }
308 }
310 /* Process a change in an external IRQ input. */
312 {
313 /* Meaning of the 'irq' parameter:
314 * [0..N-1] : external interrupts
315 * [N..N+31] : PPI (internal) interrupts for CPU 0
316 * [N+32..N+63] : PPI (internal interrupts for CPU 1
317 * ...
318 */
322 /* external interrupt (SPI) */
325 /* per-cpu interrupt (PPI) */
332 /* Raising SGIs via this function would be a bug in how the board
333 * model wires up interrupts.
334 */
337 }
338 }
341 {
342 /* Recalculate our cached idea of the current highest priority
343 * pending interrupt, but don't set IRQ or FIQ lines.
344 */
346 /* Repopulate the cache of GICv3CPUState pointers for target CPUs */
348 }
351 {
355 },
356 {
360 }
361 };
364 {
365 /* Device instance realize function for the GIC sysbus device */
374 }
380 }
386 }
389 }
392 {
399 }
407 };
410 {
412 }