686 lines
26 KiB
C
686 lines
26 KiB
C
/* SPDX-License-Identifier: GPL-2.0-only */
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#include <console/console.h>
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#include <device/device.h>
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#include <memrange.h>
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#include <post.h>
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/**
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* Round a number up to an alignment.
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*
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* @param val The starting value.
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* @param pow Alignment as a power of two.
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* @return Rounded up number.
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*/
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static resource_t round(resource_t val, unsigned long pow)
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{
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return ALIGN_UP(val, POWER_OF_2(pow));
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}
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static const char *resource2str(const struct resource *res)
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{
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if (res->flags & IORESOURCE_IO)
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return "io";
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if (res->flags & IORESOURCE_PREFETCH)
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return "prefmem";
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if (res->flags & IORESOURCE_MEM)
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return "mem";
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return "undefined";
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}
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static bool dev_has_children(const struct device *dev)
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{
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const struct bus *bus = dev->link_list;
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return bus && bus->children;
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}
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#define res_printk(depth, str, ...) printk(BIOS_DEBUG, "%*c"str, depth, ' ', __VA_ARGS__)
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/*
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* During pass 1, once all the requirements for downstream devices of a bridge are gathered,
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* this function calculates the overall resource requirement for the bridge. It starts by
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* picking the largest resource requirement downstream for the given resource type and works by
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* adding requirements in descending order.
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*
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* Additionally, it takes alignment and limits of the downstream devices into consideration and
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* ensures that they get propagated to the bridge resource. This is required to guarantee that
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* the upstream bridge/domain honors the limit and alignment requirements for this bridge based
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* on the tightest constraints downstream.
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*/
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static void update_bridge_resource(const struct device *bridge, struct resource *bridge_res,
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unsigned long type_match, int print_depth)
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{
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const struct device *child;
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struct resource *child_res;
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resource_t base;
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bool first_child_res = true;
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const unsigned long type_mask = IORESOURCE_TYPE_MASK | IORESOURCE_PREFETCH;
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struct bus *bus = bridge->link_list;
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child_res = NULL;
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/*
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* `base` keeps track of where the next allocation for child resource can take place
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* from within the bridge resource window. Since the bridge resource window allocation
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* is not performed yet, it can start at 0. Base gets updated every time a resource
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* requirement is accounted for in the loop below. After scanning all these resources,
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* base will indicate the total size requirement for the current bridge resource
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* window.
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*/
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base = 0;
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res_printk(print_depth, "%s %s: size: %llx align: %d gran: %d limit: %llx\n",
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dev_path(bridge), resource2str(bridge_res), bridge_res->size,
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bridge_res->align, bridge_res->gran, bridge_res->limit);
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while ((child = largest_resource(bus, &child_res, type_mask, type_match))) {
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/* Size 0 resources can be skipped. */
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if (!child_res->size)
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continue;
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/*
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* Propagate the resource alignment to the bridge resource if this is the first
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* child resource with non-zero size being considered. For all other children
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* resources, alignment is taken care of by updating the base to round up as per
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* the child resource alignment. It is guaranteed that pass 2 follows the exact
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* same method of picking the resource for allocation using
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* largest_resource(). Thus, as long as the alignment for first child resource
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* is propagated up to the bridge resource, it can be guaranteed that the
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* alignment for all resources is appropriately met.
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*/
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if (first_child_res && (child_res->align > bridge_res->align))
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bridge_res->align = child_res->align;
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first_child_res = false;
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/*
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* Propagate the resource limit to the bridge resource only if child resource
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* limit is non-zero. If a downstream device has stricter requirements
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* w.r.t. limits for any resource, that constraint needs to be propagated back
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* up to the downstream bridges of the domain. This guarantees that the resource
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* allocation which starts at the domain level takes into account all these
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* constraints thus working on a global view.
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*/
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if (child_res->limit && (child_res->limit < bridge_res->limit))
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bridge_res->limit = child_res->limit;
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/*
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* Propagate the downstream resource request to allocate above 4G boundary to
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* upstream bridge resource. This ensures that during pass 2, the resource
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* allocator at domain level has a global view of all the downstream device
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* requirements and thus address space is allocated as per updated flags in the
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* bridge resource.
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*
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* Since the bridge resource is a single window, all the downstream resources of
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* this bridge resource will be allocated space above 4G boundary.
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*/
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if (child_res->flags & IORESOURCE_ABOVE_4G)
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bridge_res->flags |= IORESOURCE_ABOVE_4G;
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/*
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* Alignment value of 0 means that the child resource has no alignment
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* requirements and so the base value remains unchanged here.
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*/
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base = round(base, child_res->align);
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res_printk(print_depth + 1, "%s %02lx * [0x%llx - 0x%llx] %s\n",
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dev_path(child), child_res->index, base, base + child_res->size - 1,
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resource2str(child_res));
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base += child_res->size;
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}
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/*
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* After all downstream device resources are scanned, `base` represents the total size
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* requirement for the current bridge resource window. This size needs to be rounded up
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* to the granularity requirement of the bridge to ensure that the upstream
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* bridge/domain allocates big enough window.
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*/
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bridge_res->size = round(base, bridge_res->gran);
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res_printk(print_depth, "%s %s: size: %llx align: %d gran: %d limit: %llx done\n",
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dev_path(bridge), resource2str(bridge_res), bridge_res->size,
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bridge_res->align, bridge_res->gran, bridge_res->limit);
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}
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/*
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* During pass 1, resource allocator at bridge level gathers requirements from downstream
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* devices and updates its own resource windows for the provided resource type.
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*/
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static void compute_bridge_resources(const struct device *bridge, unsigned long type_match,
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int print_depth)
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{
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const struct device *child;
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struct resource *res;
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struct bus *bus = bridge->link_list;
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const unsigned long type_mask = IORESOURCE_TYPE_MASK | IORESOURCE_PREFETCH;
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for (res = bridge->resource_list; res; res = res->next) {
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if (!(res->flags & IORESOURCE_BRIDGE))
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continue;
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if ((res->flags & type_mask) != type_match)
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continue;
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/*
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* Ensure that the resource requirements for all downstream bridges are
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* gathered before updating the window for current bridge resource.
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*/
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for (child = bus->children; child; child = child->sibling) {
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if (!dev_has_children(child))
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continue;
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compute_bridge_resources(child, type_match, print_depth + 1);
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}
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/*
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* Update the window for current bridge resource now that all downstream
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* requirements are gathered.
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*/
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update_bridge_resource(bridge, res, type_match, print_depth);
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}
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}
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/*
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* During pass 1, resource allocator walks down the entire sub-tree of a domain. It gathers
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* resource requirements for every downstream bridge by looking at the resource requests of its
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* children. Thus, the requirement gathering begins at the leaf devices and is propagated back
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* up to the downstream bridges of the domain.
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*
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* At domain level, it identifies every downstream bridge and walks down that bridge to gather
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* requirements for each resource type i.e. i/o, mem and prefmem. Since bridges have separate
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* windows for mem and prefmem, requirements for each need to be collected separately.
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*
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* Domain resource windows are fixed ranges and hence requirement gathering does not result in
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* any changes to these fixed ranges.
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*/
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static void compute_domain_resources(const struct device *domain)
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{
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const struct device *child;
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const int print_depth = 1;
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if (domain->link_list == NULL)
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return;
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for (child = domain->link_list->children; child; child = child->sibling) {
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/* Skip if this is not a bridge or has no children under it. */
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if (!dev_has_children(child))
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continue;
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compute_bridge_resources(child, IORESOURCE_IO, print_depth);
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compute_bridge_resources(child, IORESOURCE_MEM, print_depth);
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compute_bridge_resources(child, IORESOURCE_MEM | IORESOURCE_PREFETCH,
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print_depth);
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}
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}
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static unsigned char get_alignment_by_resource_type(const struct resource *res)
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{
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if (res->flags & IORESOURCE_MEM)
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return 12; /* Page-aligned --> log2(4KiB) */
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else if (res->flags & IORESOURCE_IO)
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return 0; /* No special alignment required --> log2(1) */
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die("Unexpected resource type: flags(%d)!\n", res->flags);
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}
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/*
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* If the resource is NULL or if the resource is not assigned, then it cannot be used for
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* allocation for downstream devices.
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*/
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static bool is_resource_invalid(const struct resource *res)
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{
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return (res == NULL) || !(res->flags & IORESOURCE_ASSIGNED);
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}
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static void initialize_domain_io_resource_memranges(struct memranges *ranges,
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const struct resource *res,
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unsigned long memrange_type)
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{
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memranges_insert(ranges, res->base, res->limit - res->base + 1, memrange_type);
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}
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static void initialize_domain_mem_resource_memranges(struct memranges *ranges,
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const struct resource *res,
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unsigned long memrange_type)
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{
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resource_t res_base;
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resource_t res_limit;
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const resource_t limit_4g = 0xffffffff;
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res_base = res->base;
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res_limit = res->limit;
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/*
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* Split the resource into two separate ranges if it crosses the 4G boundary. Memrange
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* type is set differently to ensure that memrange does not merge these two ranges. For
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* the range above 4G boundary, given memrange type is ORed with IORESOURCE_ABOVE_4G.
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*/
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if (res_base <= limit_4g) {
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resource_t range_limit;
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/* Clip the resource limit at 4G boundary if necessary. */
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range_limit = MIN(res_limit, limit_4g);
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memranges_insert(ranges, res_base, range_limit - res_base + 1, memrange_type);
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/*
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* If the resource lies completely below the 4G boundary, nothing more needs to
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* be done.
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*/
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if (res_limit <= limit_4g)
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return;
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/*
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* If the resource window crosses the 4G boundary, then update res_base to add
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* another entry for the range above the boundary.
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*/
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res_base = limit_4g + 1;
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}
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if (res_base > res_limit)
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return;
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/*
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* If resource lies completely above the 4G boundary or if the resource was clipped to
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* add two separate ranges, the range above 4G boundary has the resource flag
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* IORESOURCE_ABOVE_4G set. This allows domain to handle any downstream requests for
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* resource allocation above 4G differently.
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*/
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memranges_insert(ranges, res_base, res_limit - res_base + 1,
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memrange_type | IORESOURCE_ABOVE_4G);
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}
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/*
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* This function initializes memranges for domain device. If the resource crosses 4G boundary,
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* then this function splits it into two ranges -- one for the window below 4G and the other for
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* the window above 4G. The latter range has IORESOURCE_ABOVE_4G flag set to satisfy resource
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* requests from downstream devices for allocations above 4G.
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*/
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static void initialize_domain_memranges(struct memranges *ranges, const struct resource *res,
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unsigned long memrange_type)
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{
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unsigned char align = get_alignment_by_resource_type(res);
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memranges_init_empty_with_alignment(ranges, NULL, 0, align);
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if (is_resource_invalid(res))
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return;
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if (res->flags & IORESOURCE_IO)
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initialize_domain_io_resource_memranges(ranges, res, memrange_type);
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else
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initialize_domain_mem_resource_memranges(ranges, res, memrange_type);
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}
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/*
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* This function initializes memranges for bridge device. Unlike domain, bridge does not need to
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* care about resource window crossing 4G boundary. This is handled by the resource allocator at
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* domain level to ensure that all downstream bridges are allocated space either above or below
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* 4G boundary as per the state of IORESOURCE_ABOVE_4G for the respective bridge resource.
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*
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* So, this function creates a single range of the entire resource window available for the
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* bridge resource. Thus all downstream resources of the bridge for the given resource type get
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* allocated space from the same window. If there is any downstream resource of the bridge which
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* requests allocation above 4G, then all other downstream resources of the same type under the
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* bridge get allocated above 4G.
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*/
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static void initialize_bridge_memranges(struct memranges *ranges, const struct resource *res,
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unsigned long memrange_type)
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{
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unsigned char align = get_alignment_by_resource_type(res);
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memranges_init_empty_with_alignment(ranges, NULL, 0, align);
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if (is_resource_invalid(res))
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return;
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memranges_insert(ranges, res->base, res->limit - res->base + 1, memrange_type);
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}
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static void print_resource_ranges(const struct device *dev, const struct memranges *ranges)
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{
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const struct range_entry *r;
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printk(BIOS_INFO, " %s: Resource ranges:\n", dev_path(dev));
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if (memranges_is_empty(ranges))
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printk(BIOS_INFO, " * EMPTY!!\n");
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memranges_each_entry(r, ranges) {
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printk(BIOS_INFO, " * Base: %llx, Size: %llx, Tag: %lx\n",
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range_entry_base(r), range_entry_size(r), range_entry_tag(r));
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}
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}
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/*
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* This is where the actual allocation of resources happens during pass 2. Given the list of
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* memory ranges corresponding to the resource of given type, it finds the biggest unallocated
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* resource using the type mask on the downstream bus. This continues in a descending
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* order until all resources of given type are allocated address space within the current
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* resource window.
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*/
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static void allocate_child_resources(struct bus *bus, struct memranges *ranges,
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unsigned long type_mask, unsigned long type_match)
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{
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struct resource *resource = NULL;
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const struct device *dev;
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while ((dev = largest_resource(bus, &resource, type_mask, type_match))) {
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if (!resource->size)
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continue;
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if (memranges_steal(ranges, resource->limit, resource->size, resource->align,
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type_match, &resource->base) == false) {
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printk(BIOS_ERR, " ERROR: Resource didn't fit!!! ");
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printk(BIOS_DEBUG, " %s %02lx * size: 0x%llx limit: %llx %s\n",
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dev_path(dev), resource->index,
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resource->size, resource->limit, resource2str(resource));
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continue;
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}
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resource->limit = resource->base + resource->size - 1;
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resource->flags |= IORESOURCE_ASSIGNED;
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printk(BIOS_DEBUG, " %s %02lx * [0x%llx - 0x%llx] limit: %llx %s\n",
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dev_path(dev), resource->index, resource->base,
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resource->size ? resource->base + resource->size - 1 :
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resource->base, resource->limit, resource2str(resource));
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}
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}
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static void update_constraints(struct memranges *ranges, const struct device *dev,
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const struct resource *res)
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{
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if (!res->size)
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return;
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printk(BIOS_DEBUG, " %s: %s %02lx base %08llx limit %08llx %s (fixed)\n",
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__func__, dev_path(dev), res->index, res->base,
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res->base + res->size - 1, resource2str(res));
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memranges_create_hole(ranges, res->base, res->size);
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}
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/*
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* Scan the entire tree to identify any fixed resources allocated by any device to
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* ensure that the address map for domain resources are appropriately updated.
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*
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* Domains can typically provide memrange for entire address space. So, this function
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* punches holes in the address space for all fixed resources that are already
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* defined. Both IO and normal memory resources are added as fixed. Both need to be
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* removed from address space where dynamic resource allocations are sourced.
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*/
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static void avoid_fixed_resources(struct memranges *ranges, const struct device *dev,
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unsigned long mask_match)
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{
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const struct resource *res;
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const struct device *child;
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const struct bus *bus;
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for (res = dev->resource_list; res != NULL; res = res->next) {
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if ((res->flags & mask_match) != mask_match)
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continue;
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update_constraints(ranges, dev, res);
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}
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bus = dev->link_list;
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if (bus == NULL)
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return;
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for (child = bus->children; child != NULL; child = child->sibling)
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avoid_fixed_resources(ranges, child, mask_match);
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}
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static void constrain_domain_resources(const struct device *domain, struct memranges *ranges,
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unsigned long type)
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{
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unsigned long mask_match = type | IORESOURCE_FIXED;
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if (type == IORESOURCE_IO) {
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/*
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* Don't allow allocations in the VGA I/O range. PCI has special cases for
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* that.
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*/
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memranges_create_hole(ranges, 0x3b0, 0x3df - 0x3b0 + 1);
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/*
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* Resource allocator no longer supports the legacy behavior where I/O resource
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* allocation is guaranteed to avoid aliases over legacy PCI expansion card
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* addresses.
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*/
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}
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avoid_fixed_resources(ranges, domain, mask_match);
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}
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/*
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* This function creates a list of memranges of given type using the resource that is
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* provided. If the given resource is NULL or if the resource window size is 0, then it creates
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* an empty list. This results in resource allocation for that resource type failing for all
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* downstream devices since there is nothing to allocate from.
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*
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* In case of domain, it applies additional constraints to ensure that the memranges do not
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* overlap any of the fixed resources under that domain. Domain typically seems to provide
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* memrange for entire address space. Thus, it is up to the chipset to add DRAM and all other
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* windows which cannot be used for resource allocation as fixed resources.
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*/
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static void setup_resource_ranges(const struct device *dev, const struct resource *res,
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unsigned long type, struct memranges *ranges)
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{
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printk(BIOS_DEBUG, "%s %s: base: %llx size: %llx align: %d gran: %d limit: %llx\n",
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dev_path(dev), resource2str(res), res->base, res->size, res->align,
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res->gran, res->limit);
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if (dev->path.type == DEVICE_PATH_DOMAIN) {
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initialize_domain_memranges(ranges, res, type);
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constrain_domain_resources(dev, ranges, type);
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} else {
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initialize_bridge_memranges(ranges, res, type);
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}
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print_resource_ranges(dev, ranges);
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}
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|
|
|
static void cleanup_resource_ranges(const struct device *dev, struct memranges *ranges,
|
|
const struct resource *res)
|
|
{
|
|
memranges_teardown(ranges);
|
|
printk(BIOS_DEBUG, "%s %s: base: %llx size: %llx align: %d gran: %d limit: %llx done\n",
|
|
dev_path(dev), resource2str(res), res->base, res->size, res->align,
|
|
res->gran, res->limit);
|
|
}
|
|
|
|
/*
|
|
* Pass 2 of resource allocator at the bridge level loops through all the resources for the
|
|
* bridge and generates a list of memory ranges similar to that at the domain level. However,
|
|
* there is no need to apply any additional constraints since the window allocated to the bridge
|
|
* is guaranteed to be non-overlapping by the allocator at domain level.
|
|
*
|
|
* Allocation at the bridge level works the same as at domain level (starts with the biggest
|
|
* resource requirement from downstream devices and continues in descending order). One major
|
|
* difference at the bridge level is that it considers prefmem resources separately from mem
|
|
* resources.
|
|
*
|
|
* Once allocation at the current bridge is complete, resource allocator continues walking down
|
|
* the downstream bridges until it hits the leaf devices.
|
|
*/
|
|
static void allocate_bridge_resources(const struct device *bridge)
|
|
{
|
|
struct memranges ranges;
|
|
const struct resource *res;
|
|
struct bus *bus = bridge->link_list;
|
|
unsigned long type_match;
|
|
struct device *child;
|
|
const unsigned long type_mask = IORESOURCE_TYPE_MASK | IORESOURCE_PREFETCH;
|
|
|
|
for (res = bridge->resource_list; res; res = res->next) {
|
|
if (!res->size)
|
|
continue;
|
|
|
|
if (!(res->flags & IORESOURCE_BRIDGE))
|
|
continue;
|
|
|
|
type_match = res->flags & type_mask;
|
|
|
|
setup_resource_ranges(bridge, res, type_match, &ranges);
|
|
allocate_child_resources(bus, &ranges, type_mask, type_match);
|
|
cleanup_resource_ranges(bridge, &ranges, res);
|
|
}
|
|
|
|
for (child = bus->children; child; child = child->sibling) {
|
|
if (!dev_has_children(child))
|
|
continue;
|
|
|
|
allocate_bridge_resources(child);
|
|
}
|
|
}
|
|
|
|
static const struct resource *find_domain_resource(const struct device *domain,
|
|
unsigned long type)
|
|
{
|
|
const struct resource *res;
|
|
|
|
for (res = domain->resource_list; res; res = res->next) {
|
|
if (res->flags & IORESOURCE_FIXED)
|
|
continue;
|
|
|
|
if ((res->flags & IORESOURCE_TYPE_MASK) == type)
|
|
return res;
|
|
}
|
|
|
|
return NULL;
|
|
}
|
|
|
|
/*
|
|
* Pass 2 of resource allocator begins at the domain level. Every domain has two types of
|
|
* resources - io and mem. For each of these resources, this function creates a list of memory
|
|
* ranges that can be used for downstream resource allocation. This list is constrained to
|
|
* remove any fixed resources in the domain sub-tree of the given resource type. It then uses
|
|
* the memory ranges to apply best fit on the resource requirements of the downstream devices.
|
|
*
|
|
* Once resources are allocated to all downstream devices of the domain, it walks down each
|
|
* downstream bridge to continue the same process until resources are allocated to all devices
|
|
* under the domain.
|
|
*/
|
|
static void allocate_domain_resources(const struct device *domain)
|
|
{
|
|
struct memranges ranges;
|
|
struct device *child;
|
|
const struct resource *res;
|
|
|
|
/* Resource type I/O */
|
|
res = find_domain_resource(domain, IORESOURCE_IO);
|
|
if (res) {
|
|
setup_resource_ranges(domain, res, IORESOURCE_IO, &ranges);
|
|
allocate_child_resources(domain->link_list, &ranges, IORESOURCE_TYPE_MASK,
|
|
IORESOURCE_IO);
|
|
cleanup_resource_ranges(domain, &ranges, res);
|
|
}
|
|
|
|
/*
|
|
* Resource type Mem:
|
|
* Domain does not distinguish between mem and prefmem resources. Thus, the resource
|
|
* allocation at domain level considers mem and prefmem together when finding the best
|
|
* fit based on the biggest resource requirement.
|
|
*
|
|
* However, resource requests for allocation above 4G boundary need to be handled
|
|
* separately if the domain resource window crosses this boundary. There is a single
|
|
* window for resource of type IORESOURCE_MEM. When creating memranges, this resource
|
|
* is split into two separate ranges -- one for the window below 4G boundary and other
|
|
* for the window above 4G boundary (with IORESOURCE_ABOVE_4G flag set). Thus, when
|
|
* allocating child resources, requests for below and above the 4G boundary are handled
|
|
* separately by setting the type_mask and type_match to allocate_child_resources()
|
|
* accordingly.
|
|
*/
|
|
res = find_domain_resource(domain, IORESOURCE_MEM);
|
|
if (res) {
|
|
setup_resource_ranges(domain, res, IORESOURCE_MEM, &ranges);
|
|
allocate_child_resources(domain->link_list, &ranges,
|
|
IORESOURCE_TYPE_MASK | IORESOURCE_ABOVE_4G,
|
|
IORESOURCE_MEM);
|
|
allocate_child_resources(domain->link_list, &ranges,
|
|
IORESOURCE_TYPE_MASK | IORESOURCE_ABOVE_4G,
|
|
IORESOURCE_MEM | IORESOURCE_ABOVE_4G);
|
|
cleanup_resource_ranges(domain, &ranges, res);
|
|
}
|
|
|
|
for (child = domain->link_list->children; child; child = child->sibling) {
|
|
if (!dev_has_children(child))
|
|
continue;
|
|
|
|
/* Continue allocation for all downstream bridges. */
|
|
allocate_bridge_resources(child);
|
|
}
|
|
}
|
|
|
|
/*
|
|
* This function forms the guts of the resource allocator. It walks through the entire device
|
|
* tree for each domain two times.
|
|
*
|
|
* Every domain has a fixed set of ranges. These ranges cannot be relaxed based on the
|
|
* requirements of the downstream devices. They represent the available windows from which
|
|
* resources can be allocated to the different devices under the domain.
|
|
*
|
|
* In order to identify the requirements of downstream devices, resource allocator walks in a
|
|
* DFS fashion. It gathers the requirements from leaf devices and propagates those back up
|
|
* to their upstream bridges until the requirements for all the downstream devices of the domain
|
|
* are gathered. This is referred to as pass 1 of resource allocator.
|
|
*
|
|
* Once the requirements for all the devices under the domain are gathered, resource allocator
|
|
* walks a second time to allocate resources to downstream devices as per the
|
|
* requirements. It always picks the biggest resource request as per the type (i/o and mem) to
|
|
* allocate space from its fixed window to the immediate downstream device of the domain. In
|
|
* order to accomplish best fit for the resources, a list of ranges is maintained by each
|
|
* resource type (i/o and mem). Domain does not differentiate between mem and prefmem. Since
|
|
* they are allocated space from the same window, the resource allocator at the domain level
|
|
* ensures that the biggest requirement is selected independent of the prefetch type. Once the
|
|
* resource allocation for all immediate downstream devices is complete at the domain level,
|
|
* resource allocator walks down the subtree for each downstream bridge to continue the
|
|
* allocation process at the bridge level. Since bridges have separate windows for i/o, mem and
|
|
* prefmem, best fit algorithm at bridge level looks for the biggest requirement considering
|
|
* prefmem resources separately from non-prefmem resources. This continues until resource
|
|
* allocation is performed for all downstream bridges in the domain sub-tree. This is referred
|
|
* to as pass 2 of resource allocator.
|
|
*
|
|
* Some rules that are followed by the resource allocator:
|
|
* - Allocate resource locations for every device as long as the requirements can be satisfied.
|
|
* - If a resource cannot be allocated any address space, then that resource needs to be
|
|
* properly updated to ensure that it does not incorrectly overlap some address space reserved
|
|
* for a different purpose.
|
|
* - Don't overlap with resources in fixed locations.
|
|
* - Don't overlap and follow the rules of bridges -- downstream devices of bridges should use
|
|
* parts of the address space allocated to the bridge.
|
|
*/
|
|
void allocate_resources(const struct device *root)
|
|
{
|
|
const struct device *child;
|
|
|
|
if ((root == NULL) || (root->link_list == NULL))
|
|
return;
|
|
|
|
for (child = root->link_list->children; child; child = child->sibling) {
|
|
|
|
if (child->path.type != DEVICE_PATH_DOMAIN)
|
|
continue;
|
|
|
|
post_log_path(child);
|
|
|
|
/* Pass 1 - Gather requirements. */
|
|
printk(BIOS_INFO, "=== Resource allocator: %s - Pass 1 (gathering requirements) ===\n",
|
|
dev_path(child));
|
|
compute_domain_resources(child);
|
|
|
|
/* Pass 2 - Allocate resources as per gathered requirements. */
|
|
printk(BIOS_INFO, "=== Resource allocator: %s - Pass 2 (allocating resources) ===\n",
|
|
dev_path(child));
|
|
allocate_domain_resources(child);
|
|
|
|
printk(BIOS_INFO, "=== Resource allocator: %s - resource allocation complete ===\n",
|
|
dev_path(child));
|
|
}
|
|
}
|