mb/google/brya/var/orisa: Update Type C DisplayPort HPD Configuration
[coreboot2.git] / src / device / resource_allocator_v4.c
blob44782d87a1eaa6f8dea98c0a89dfdc17df0f9c51
1 /* SPDX-License-Identifier: GPL-2.0-only */
3 #include <commonlib/bsd/helpers.h>
4 #include <console/console.h>
5 #include <device/device.h>
6 #include <memrange.h>
7 #include <post.h>
8 #include <types.h>
10 static const char *resource2str(const struct resource *res)
12 if (res->flags & IORESOURCE_IO)
13 return "io";
14 if (res->flags & IORESOURCE_PREFETCH)
15 return "prefmem";
16 if (res->flags & IORESOURCE_MEM)
17 return "mem";
18 return "undefined";
21 static void print_domain_res(const struct device *dev,
22 const struct resource *res, const char *suffix)
24 printk(BIOS_DEBUG, "%s %s: base: %llx size: %llx align: %u gran: %u limit: %llx%s\n",
25 dev_path(dev), resource2str(res), res->base, res->size,
26 res->align, res->gran, res->limit, suffix);
29 #define res_printk(depth, str, ...) printk(BIOS_DEBUG, "%*c"str, depth, ' ', __VA_ARGS__)
31 static void print_bridge_res(const struct device *dev, const struct resource *res,
32 int depth, const char *suffix)
34 res_printk(depth, "%s %s: size: %llx align: %u gran: %u limit: %llx%s\n", dev_path(dev),
35 resource2str(res), res->size, res->align, res->gran, res->limit, suffix);
38 static void print_child_res(const struct device *dev, const struct resource *res, int depth)
40 res_printk(depth + 1, "%s %02lx * [0x%llx - 0x%llx] %s\n", dev_path(dev),
41 res->index, res->base, res->base + res->size - 1, resource2str(res));
44 static void print_fixed_res(const struct device *dev,
45 const struct resource *res, const char *prefix)
47 printk(BIOS_DEBUG, " %s: %s %02lx base %08llx limit %08llx %s (fixed)\n",
48 prefix, dev_path(dev), res->index, res->base, res->base + res->size - 1,
49 resource2str(res));
52 static void print_assigned_res(const struct device *dev, const struct resource *res)
54 printk(BIOS_DEBUG, " %s %02lx * [0x%llx - 0x%llx] limit: %llx %s\n",
55 dev_path(dev), res->index, res->base, res->limit, res->limit, resource2str(res));
58 static void print_failed_res(const struct device *dev, const struct resource *res)
60 printk(BIOS_DEBUG, " %s %02lx * size: 0x%llx limit: %llx %s\n",
61 dev_path(dev), res->index, res->size, res->limit, resource2str(res));
64 static void print_resource_ranges(const struct device *dev, const struct memranges *ranges)
66 const struct range_entry *r;
68 printk(BIOS_INFO, " %s: Resource ranges:\n", dev_path(dev));
70 if (memranges_is_empty(ranges))
71 printk(BIOS_INFO, " * EMPTY!!\n");
73 memranges_each_entry(r, ranges) {
74 printk(BIOS_INFO, " * Base: %llx, Size: %llx, Tag: %lx\n",
75 range_entry_base(r), range_entry_size(r), range_entry_tag(r));
79 static bool dev_has_children(const struct device *dev)
81 const struct bus *bus = dev->downstream;
82 return bus && bus->children;
85 static resource_t effective_limit(const struct resource *const res)
87 if (CONFIG(ALWAYS_ALLOW_ABOVE_4G_ALLOCATION))
88 return res->limit;
90 /* Always allow bridge resources above 4G. */
91 if (res->flags & IORESOURCE_BRIDGE)
92 return res->limit;
94 const resource_t quirk_4g_limit =
95 res->flags & IORESOURCE_ABOVE_4G ? UINT64_MAX : UINT32_MAX;
96 return MIN(res->limit, quirk_4g_limit);
100 * During pass 1, once all the requirements for downstream devices of a
101 * bridge are gathered, this function calculates the overall resource
102 * requirement for the bridge. It starts by picking the largest resource
103 * requirement downstream for the given resource type and works by
104 * adding requirements in descending order.
106 * Additionally, it takes alignment and limits of the downstream devices
107 * into consideration and ensures that they get propagated to the bridge
108 * resource. This is required to guarantee that the upstream bridge/
109 * domain honors the limit and alignment requirements for this bridge
110 * based on the tightest constraints downstream.
112 * Last but not least, it stores the offset inside the bridge resource
113 * for each child resource in its base field. This simplifies pass 2
114 * for resources behind a bridge, as we only have to add offsets to the
115 * allocated base of the bridge resource.
117 static void update_bridge_resource(const struct device *bridge, struct resource *bridge_res,
118 int print_depth)
120 const struct device *child;
121 struct resource *child_res;
122 resource_t base;
123 const unsigned long type_mask = IORESOURCE_TYPE_MASK | IORESOURCE_PREFETCH;
124 const unsigned long type_match = bridge_res->flags & type_mask;
125 struct bus *bus = bridge->downstream;
127 child_res = NULL;
130 * `base` keeps track of where the next allocation for child resources
131 * can take place from within the bridge resource window. Since the
132 * bridge resource window allocation is not performed yet, it can start
133 * at 0. Base gets updated every time a resource requirement is
134 * accounted for in the loop below. After scanning all these resources,
135 * base will indicate the total size requirement for the current bridge
136 * resource window.
138 base = 0;
140 print_bridge_res(bridge, bridge_res, print_depth, "");
142 while ((child = largest_resource(bus, &child_res, type_mask, type_match))) {
143 /* Size 0 resources can be skipped. */
144 if (!child_res->size)
145 continue;
147 /* Resources with 0 limit can't be assigned anything. */
148 if (!child_res->limit)
149 continue;
152 * Propagate the resource alignment to the bridge resource. The
153 * condition can only be true for the first (largest) resource. For all
154 * other child resources, alignment is taken care of by rounding their
155 * base up.
157 if (child_res->align > bridge_res->align)
158 bridge_res->align = child_res->align;
161 * Propagate the resource limit to the bridge resource. If a downstream
162 * device has stricter requirements w.r.t. limits for any resource, that
163 * constraint needs to be propagated back up to the bridges downstream
164 * of the domain. This way, the whole bridge resource fulfills the limit.
166 if (effective_limit(child_res) < bridge_res->limit)
167 bridge_res->limit = effective_limit(child_res);
170 * Alignment value of 0 means that the child resource has no alignment
171 * requirements and so the base value remains unchanged here.
173 base = ALIGN_UP(base, POWER_OF_2(child_res->align));
176 * Store the relative offset inside the bridge resource for later
177 * consumption in allocate_bridge_resources(), and invalidate flags
178 * related to the base.
180 child_res->base = base;
181 child_res->flags &= ~(IORESOURCE_ASSIGNED | IORESOURCE_STORED);
183 print_child_res(child, child_res, print_depth);
185 base += child_res->size;
189 * After all downstream device resources are scanned, `base` represents
190 * the total size requirement for the current bridge resource window.
191 * This size needs to be rounded up to the granularity requirement of
192 * the bridge to ensure that the upstream bridge/domain allocates big
193 * enough window.
195 bridge_res->size = ALIGN_UP(base, POWER_OF_2(bridge_res->gran));
197 print_bridge_res(bridge, bridge_res, print_depth, " done");
201 * During pass 1, at the bridge level, the resource allocator gathers
202 * requirements from downstream devices and updates its own resource
203 * windows for the provided resource type.
205 static void compute_bridge_resources(const struct device *bridge, unsigned long type_match,
206 int print_depth)
208 const struct device *child;
209 struct resource *res;
210 struct bus *bus = bridge->downstream;
211 const unsigned long type_mask = IORESOURCE_TYPE_MASK | IORESOURCE_PREFETCH;
213 for (res = bridge->resource_list; res; res = res->next) {
214 if (!(res->flags & IORESOURCE_BRIDGE))
215 continue;
217 if ((res->flags & type_mask) != type_match)
218 continue;
221 * Ensure that the resource requirements for all downstream bridges are
222 * gathered before updating the window for current bridge resource.
224 for (child = bus->children; child; child = child->sibling) {
225 if (!dev_has_children(child))
226 continue;
227 compute_bridge_resources(child, type_match, print_depth + 1);
231 * Update the window for current bridge resource now that all downstream
232 * requirements are gathered.
234 update_bridge_resource(bridge, res, print_depth);
239 * During pass 1, the resource allocator walks down the entire sub-tree
240 * of a domain. It gathers resource requirements for every downstream
241 * bridge by looking at the resource requests of its children. Thus, the
242 * requirement gathering begins at the leaf devices and is propagated
243 * back up to the downstream bridges of the domain.
245 * At the domain level, it identifies every downstream bridge and walks
246 * down that bridge to gather requirements for each resource type i.e.
247 * i/o, mem and prefmem. Since bridges have separate windows for mem and
248 * prefmem, requirements for each need to be collected separately.
250 * Domain resource windows are fixed ranges and hence requirement
251 * gathering does not result in any changes to these fixed ranges.
253 static void compute_domain_resources(const struct device *domain)
255 const struct device *child;
256 const int print_depth = 1;
258 if (domain->downstream == NULL)
259 return;
261 for (child = domain->downstream->children; child; child = child->sibling) {
262 /* Skip if this is not a bridge or has no children under it. */
263 if (!dev_has_children(child))
264 continue;
266 compute_bridge_resources(child, IORESOURCE_IO, print_depth);
267 compute_bridge_resources(child, IORESOURCE_MEM, print_depth);
268 compute_bridge_resources(child, IORESOURCE_MEM | IORESOURCE_PREFETCH,
269 print_depth);
274 * Scan the entire tree to identify any fixed resources allocated by
275 * any device to ensure that the address map for domain resources are
276 * appropriately updated.
278 * Domains can typically provide a memrange for entire address space.
279 * So, this function punches holes in the address space for all fixed
280 * resources that are already defined. Both I/O and normal memory
281 * resources are added as fixed. Both need to be removed from address
282 * space where dynamic resource allocations are sourced.
284 static void avoid_fixed_resources(struct memranges *ranges, const struct device *dev,
285 unsigned long mask_match)
287 const struct resource *res;
288 const struct device *child;
289 const struct bus *bus;
291 for (res = dev->resource_list; res != NULL; res = res->next) {
292 if ((res->flags & mask_match) != mask_match)
293 continue;
294 if (!res->size)
295 continue;
296 print_fixed_res(dev, res, __func__);
297 memranges_create_hole(ranges, res->base, res->size);
300 bus = dev->downstream;
301 if (bus == NULL)
302 return;
304 for (child = bus->children; child != NULL; child = child->sibling)
305 avoid_fixed_resources(ranges, child, mask_match);
309 * This function creates a list of memranges of given type using the
310 * resource that is provided. It applies additional constraints to
311 * ensure that the memranges do not overlap any of the fixed resources
312 * under the domain. The domain typically provides a memrange for the
313 * entire address space. Thus, it is up to the chipset to add DRAM and
314 * all other windows which cannot be used for resource allocation as
315 * fixed resources.
317 static void setup_resource_ranges(const struct device *const domain,
318 const unsigned long type,
319 struct memranges *const ranges)
321 /* Align mem resources to 2^12 (4KiB pages) at a minimum, so they
322 can be memory-mapped individually (e.g. for virtualization guests). */
323 const unsigned char alignment = type == IORESOURCE_MEM ? 12 : 0;
324 const unsigned long type_mask = IORESOURCE_TYPE_MASK | IORESOURCE_FIXED;
326 memranges_init_empty_with_alignment(ranges, NULL, 0, alignment);
328 for (struct resource *res = domain->resource_list; res != NULL; res = res->next) {
329 if ((res->flags & type_mask) != type)
330 continue;
331 print_domain_res(domain, res, "");
332 memranges_insert(ranges, res->base, res->limit - res->base + 1, type);
335 if (type == IORESOURCE_IO) {
337 * Don't allow allocations in the VGA I/O range. PCI has special
338 * cases for that.
340 memranges_create_hole(ranges, 0x3b0, 0x3df - 0x3b0 + 1);
343 * Resource allocator no longer supports the legacy behavior where
344 * I/O resource allocation is guaranteed to avoid aliases over legacy
345 * PCI expansion card addresses.
349 avoid_fixed_resources(ranges, domain, type | IORESOURCE_FIXED);
351 print_resource_ranges(domain, ranges);
354 static void cleanup_domain_resource_ranges(const struct device *dev, struct memranges *ranges,
355 unsigned long type)
357 memranges_teardown(ranges);
358 for (struct resource *res = dev->resource_list; res != NULL; res = res->next) {
359 if (res->flags & IORESOURCE_FIXED)
360 continue;
361 if ((res->flags & IORESOURCE_TYPE_MASK) != type)
362 continue;
363 print_domain_res(dev, res, " done");
367 static void assign_resource(struct resource *const res, const resource_t base,
368 const struct device *const dev)
370 res->base = base;
371 res->limit = res->base + res->size - 1;
372 res->flags |= IORESOURCE_ASSIGNED;
373 res->flags &= ~IORESOURCE_STORED;
375 print_assigned_res(dev, res);
379 * This is where the actual allocation of resources happens during
380 * pass 2. We construct a list of memory ranges corresponding to the
381 * resource of a given type, then look for the biggest unallocated
382 * resource on the downstream bus. This continues in a descending order
383 * until all resources of a given type have space allocated within the
384 * domain's resource window.
386 static void allocate_toplevel_resources(const struct device *const domain,
387 const unsigned long type)
389 const unsigned long type_mask = IORESOURCE_TYPE_MASK;
390 struct resource *res = NULL;
391 const struct device *dev;
392 struct memranges ranges;
393 resource_t base;
395 if (!dev_has_children(domain))
396 return;
398 setup_resource_ranges(domain, type, &ranges);
400 while ((dev = largest_resource(domain->downstream, &res, type_mask, type))) {
401 if (!res->size)
402 continue;
404 if (!memranges_steal(&ranges, effective_limit(res), res->size, res->align,
405 type, &base, CONFIG(RESOURCE_ALLOCATION_TOP_DOWN))) {
406 printk(BIOS_ERR, "Resource didn't fit!!!\n");
407 print_failed_res(dev, res);
408 continue;
411 assign_resource(res, base, dev);
414 cleanup_domain_resource_ranges(domain, &ranges, type);
418 * Pass 2 of the resource allocator at the bridge level loops through
419 * all the resources for the bridge and assigns all the base addresses
420 * of its children's resources of the same type. update_bridge_resource()
421 * of pass 1 pre-calculated the offsets of these bases inside the bridge
422 * resource. Now that the bridge resource is allocated, all we have to
423 * do is to add its final base to these offsets.
425 * Once allocation at the current bridge is complete, resource allocator
426 * continues walking down the downstream bridges until it hits the leaf
427 * devices.
429 static void assign_resource_cb(void *param, struct device *dev, struct resource *res)
431 /* We have to filter the same resources as update_bridge_resource(). */
432 if (!res->size || !res->limit)
433 return;
435 assign_resource(res, *(const resource_t *)param + res->base, dev);
437 static void allocate_bridge_resources(const struct device *bridge)
439 const unsigned long type_mask =
440 IORESOURCE_TYPE_MASK | IORESOURCE_PREFETCH | IORESOURCE_FIXED;
441 struct bus *const bus = bridge->downstream;
442 struct resource *res;
443 struct device *child;
445 for (res = bridge->resource_list; res != NULL; res = res->next) {
446 if (!res->size)
447 continue;
449 if (!(res->flags & IORESOURCE_BRIDGE))
450 continue;
452 if (!(res->flags & IORESOURCE_ASSIGNED))
453 continue;
455 /* Run assign_resource_cb() for all downstream resources of the same type. */
456 search_bus_resources(bus, type_mask, res->flags & type_mask,
457 assign_resource_cb, &res->base);
460 for (child = bus->children; child != NULL; child = child->sibling) {
461 if (!dev_has_children(child))
462 continue;
464 allocate_bridge_resources(child);
469 * Pass 2 of resource allocator begins at the domain level. Every domain
470 * has two types of resources - io and mem. For each of these resources,
471 * this function creates a list of memory ranges that can be used for
472 * downstream resource allocation. This list is constrained to remove
473 * any fixed resources in the domain sub-tree of the given resource
474 * type. It then uses the memory ranges to apply best fit on the
475 * resource requirements of the downstream devices.
477 * Once resources are allocated to all downstream devices of the domain,
478 * it walks down each downstream bridge to finish resource assignment
479 * of its children resources within its own window.
481 static void allocate_domain_resources(const struct device *domain)
483 /* Resource type I/O */
484 allocate_toplevel_resources(domain, IORESOURCE_IO);
487 * Resource type Mem:
488 * Domain does not distinguish between mem and prefmem resources. Thus,
489 * the resource allocation at domain level considers mem and prefmem
490 * together when finding the best fit based on the biggest resource
491 * requirement.
493 allocate_toplevel_resources(domain, IORESOURCE_MEM);
495 struct device *child;
496 for (child = domain->downstream->children; child; child = child->sibling) {
497 if (!dev_has_children(child))
498 continue;
500 /* Continue allocation for all downstream bridges. */
501 allocate_bridge_resources(child);
506 * This function forms the guts of the resource allocator. It walks
507 * through the entire device tree for each domain two times.
509 * Every domain has a fixed set of ranges. These ranges cannot be
510 * relaxed based on the requirements of the downstream devices. They
511 * represent the available windows from which resources can be allocated
512 * to the different devices under the domain.
514 * In order to identify the requirements of downstream devices, resource
515 * allocator walks in a DFS fashion. It gathers the requirements from
516 * leaf devices and propagates those back up to their upstream bridges
517 * until the requirements for all the downstream devices of the domain
518 * are gathered. This is referred to as pass 1 of the resource allocator.
520 * Once the requirements for all the devices under the domain are
521 * gathered, the resource allocator walks a second time to allocate
522 * resources to downstream devices as per the requirements. It always
523 * picks the biggest resource request as per the type (i/o and mem) to
524 * allocate space from its fixed window to the immediate downstream
525 * device of the domain. In order to accomplish best fit for the
526 * resources, a list of ranges is maintained by each resource type (i/o
527 * and mem). At the domain level we don't differentiate between mem and
528 * prefmem. Since they are allocated space from the same window, the
529 * resource allocator at the domain level ensures that the biggest
530 * requirement is selected independent of the prefetch type. Once the
531 * resource allocation for all immediate downstream devices is complete
532 * at the domain level, the resource allocator walks down the subtree
533 * for each downstream bridge to continue the allocation process at the
534 * bridge level. Since bridges have either their whole window allocated
535 * or nothing, we only need to place downstream resources inside these
536 * windows by re-using offsets that were pre-calculated in pass 1. This
537 * continues until resource allocation is realized for all downstream
538 * bridges in the domain sub-tree. This is referred to as pass 2 of the
539 * resource allocator.
541 * Some rules that are followed by the resource allocator:
542 * - Allocate resource locations for every device as long as
543 * the requirements can be satisfied.
544 * - Don't overlap with resources in fixed locations.
545 * - Don't overlap and follow the rules of bridges -- downstream
546 * devices of bridges should use parts of the address space
547 * allocated to the bridge.
549 void allocate_resources(const struct device *root)
551 const struct device *child;
553 if ((root == NULL) || (root->downstream == NULL))
554 return;
556 for (child = root->downstream->children; child; child = child->sibling) {
557 if (child->path.type != DEVICE_PATH_DOMAIN)
558 continue;
560 post_log_path(child);
562 /* Pass 1 - Relative placement. */
563 printk(BIOS_INFO, "=== Resource allocator: %s - Pass 1 (relative placement) ===\n",
564 dev_path(child));
565 compute_domain_resources(child);
567 /* Pass 2 - Allocate resources as per gathered requirements. */
568 printk(BIOS_INFO, "=== Resource allocator: %s - Pass 2 (allocating resources) ===\n",
569 dev_path(child));
570 allocate_domain_resources(child);
572 printk(BIOS_INFO, "=== Resource allocator: %s - resource allocation complete ===\n",
573 dev_path(child));