coreboot-kgpe-d16/src/devices/device.c

631 lines
18 KiB
C

/*
* (c) 1999--2000 Martin Mares <mj@suse.cz>
* (c) 2003 Eric Biederman <ebiederm@xmission.com>
* (c) 2003 Linux Networx
*/
/* lots of mods by ron minnich (rminnich@lanl.gov), with
* the final architecture guidance from Tom Merritt (tjm@codegen.com)
* In particular, we changed from the one-pass original version to
* Tom's recommended multiple-pass version. I wasn't sure about doing
* it with multiple passes, until I actually started doing it and saw
* the wisdom of Tom's recommendations ...
*
* Lots of cleanups by Eric Biederman to handle bridges, and to
* handle resource allocation for non-pci devices.
*/
#include <console/console.h>
#include <bitops.h>
#include <arch/io.h>
#include <device/device.h>
#include <device/pci.h>
#include <device/pci_ids.h>
#include <stdlib.h>
#include <string.h>
#include <smp/spinlock.h>
/** Linked list of ALL devices */
struct device *all_devices = &dev_root;
/** Pointer to the last device */
extern struct device **last_dev_p;
/** The upper limit of MEM resource of the devices.
* Reserve 20M for the system */
#define DEVICE_MEM_HIGH 0xFEBFFFFFUL
/** The lower limit of IO resource of the devices.
* Reserve 4k for ISA/Legacy devices */
#define DEVICE_IO_START 0x1000
/**
* @brief Allocate a new device structure.
*
* Allocte a new device structure and attached it to the device tree as a
* child of the parent bus.
*
* @param parent parent bus the newly created device attached to.
* @param path path to the device to be created.
*
* @return pointer to the newly created device structure.
*
* @see device_path
*/
static spinlock_t dev_lock = SPIN_LOCK_UNLOCKED;
device_t alloc_dev(struct bus *parent, struct device_path *path)
{
device_t dev, child;
int link;
spin_lock(&dev_lock);
/* Find the last child of our parent */
for (child = parent->children; child && child->sibling; ) {
child = child->sibling;
}
dev = malloc(sizeof(*dev));
if (dev == 0) {
die("DEV: out of memory.\n");
}
memset(dev, 0, sizeof(*dev));
memcpy(&dev->path, path, sizeof(*path));
/* Initialize the back pointers in the link fields */
for (link = 0; link < MAX_LINKS; link++) {
dev->link[link].dev = dev;
dev->link[link].link = link;
}
/* By default devices are enabled */
dev->enabled = 1;
/* Add the new device to the list of children of the bus. */
dev->bus = parent;
if (child) {
child->sibling = dev;
} else {
parent->children = dev;
}
/* Append a new device to the global device list.
* The list is used to find devices once everything is set up.
*/
*last_dev_p = dev;
last_dev_p = &dev->next;
spin_unlock(&dev_lock);
return dev;
}
/**
* @brief round a number up to an alignment.
* @param val the starting value
* @param roundup Alignment as a power of two
* @returns rounded up number
*/
static resource_t round(resource_t val, unsigned long pow)
{
resource_t mask;
mask = (1ULL << pow) - 1ULL;
val += mask;
val &= ~mask;
return val;
}
/** Read the resources on all devices of a given bus.
* @param bus bus to read the resources on.
*/
static void read_resources(struct bus *bus)
{
struct device *curdev;
printk_spew("%s read_resources bus %d link: %d\n",
dev_path(bus->dev), bus->secondary, bus->link);
/* Walk through all of the devices and find which resources they need. */
for (curdev = bus->children; curdev; curdev = curdev->sibling) {
unsigned links;
int i;
if (curdev->have_resources) {
continue;
}
if (!curdev->enabled) {
continue;
}
if (!curdev->ops || !curdev->ops->read_resources) {
printk_err("%s missing read_resources\n",
dev_path(curdev));
continue;
}
curdev->ops->read_resources(curdev);
curdev->have_resources = 1;
/* Read in subtractive resources behind the current device */
links = 0;
for (i = 0; i < curdev->resources; i++) {
struct resource *resource;
unsigned link;
resource = &curdev->resource[i];
if (!(resource->flags & IORESOURCE_SUBTRACTIVE))
continue;
link = IOINDEX_SUBTRACTIVE_LINK(resource->index);
if (link > MAX_LINKS) {
printk_err("%s subtractive index on link: %d\n",
dev_path(curdev), link);
continue;
}
if (!(links & (1 << link))) {
links |= (1 << link);
read_resources(&curdev->link[resource->index]);
}
}
}
printk_spew("%s read_resources bus %d link: %d done\n",
dev_path(bus->dev), bus->secondary, bus->link);
}
struct pick_largest_state {
struct resource *last;
struct device *result_dev;
struct resource *result;
int seen_last;
};
static void pick_largest_resource(void *gp,
struct device *dev, struct resource *resource)
{
struct pick_largest_state *state = gp;
struct resource *last;
last = state->last;
/* Be certain to pick the successor to last */
if (resource == last) {
state->seen_last = 1;
return;
}
if (last && (
(last->align < resource->align) ||
((last->align == resource->align) &&
(last->size < resource->size)) ||
((last->align == resource->align) &&
(last->size == resource->size) &&
(!state->seen_last)))) {
return;
}
if (!state->result ||
(state->result->align < resource->align) ||
((state->result->align == resource->align) &&
(state->result->size < resource->size))) {
state->result_dev = dev;
state->result = resource;
}
}
static struct device *largest_resource(struct bus *bus, struct resource **result_res,
unsigned long type_mask, unsigned long type)
{
struct pick_largest_state state;
state.last = *result_res;
state.result_dev = 0;
state.result = 0;
state.seen_last = 0;
search_bus_resources(bus, type_mask, type, pick_largest_resource, &state);
*result_res = state.result;
return state.result_dev;
}
/* Compute allocate resources is the guts of the resource allocator.
*
* The problem.
* - Allocate resources locations for every device.
* - Don't overlap, and follow the rules of bridges.
* - Don't overlap with resources in fixed locations.
* - Be efficient so we don't have ugly strategies.
*
* The strategy.
* - Devices that have fixed addresses are the minority so don't
* worry about them too much. Instead only use part of the address
* space for devices with programmable addresses. This easily handles
* everything except bridges.
*
* - PCI devices are required to have thier sizes and their alignments
* equal. In this case an optimal solution to the packing problem
* exists. Allocate all devices from highest alignment to least
* alignment or vice versa. Use this.
*
* - So we can handle more than PCI run two allocation passes on
* bridges. The first to see how large the resources are behind
* the bridge, and what their alignment requirements are. The
* second to assign a safe address to the devices behind the
* bridge. This allows me to treat a bridge as just a device with
* a couple of resources, and not need to special case it in the
* allocator. Also this allows handling of other types of bridges.
*
*/
void compute_allocate_resource(
struct bus *bus,
struct resource *bridge,
unsigned long type_mask,
unsigned long type)
{
struct device *dev;
struct resource *resource;
resource_t base;
unsigned long align, min_align;
min_align = 0;
base = bridge->base;
printk_spew("%s compute_allocate_%s: base: %08Lx size: %08Lx align: %d gran: %d\n",
dev_path(bus->dev),
(bridge->flags & IORESOURCE_IO)? "io":
(bridge->flags & IORESOURCE_PREFETCH)? "prefmem" : "mem",
base, bridge->size, bridge->align, bridge->gran);
/* We want different minimum alignments for different kinds of
* resources. These minimums are not device type specific
* but resource type specific.
*/
if (bridge->flags & IORESOURCE_IO) {
min_align = log2(DEVICE_IO_ALIGN);
}
if (bridge->flags & IORESOURCE_MEM) {
min_align = log2(DEVICE_MEM_ALIGN);
}
/* Make certain I have read in all of the resources */
read_resources(bus);
/* Remember I haven't found anything yet. */
resource = 0;
/* Walk through all the devices on the current bus and
* compute the addresses.
*/
while ((dev = largest_resource(bus, &resource, type_mask, type))) {
resource_t size;
/* Do NOT I repeat do not ignore resources which have zero size.
* If they need to be ignored dev->read_resources should not even
* return them. Some resources must be set even when they have
* no size. PCI bridge resources are a good example of this.
*/
/* Propogate the resource alignment to the bridge register */
if (resource->align > bridge->align) {
bridge->align = resource->align;
}
/* Make certain we are dealing with a good minimum size */
size = resource->size;
align = resource->align;
if (align < min_align) {
align = min_align;
}
if (resource->flags & IORESOURCE_FIXED) {
continue;
}
/* Propogate the resource limit to the bridge register */
if (bridge->limit > resource->limit) {
bridge->limit = resource->limit;
}
/* Artificially deny limits between DEVICE_MEM_HIGH and 0xffffffff */
if ((bridge->limit > DEVICE_MEM_HIGH) && (bridge->limit <= 0xffffffff)) {
bridge->limit = DEVICE_MEM_HIGH;
}
if (resource->flags & IORESOURCE_IO) {
/* Don't allow potential aliases over the
* legacy pci expansion card addresses.
* The legacy pci decodes only 10 bits,
* uses 100h - 3ffh. Therefor, only 0 - ff
* can be used out of each 400h block of io
* space.
*/
if ((base & 0x300) != 0) {
base = (base & ~0x3ff) + 0x400;
}
/* Don't allow allocations in the VGA IO range.
* PCI has special cases for that.
*/
else if ((base >= 0x3b0) && (base <= 0x3df)) {
base = 0x3e0;
}
}
if (((round(base, align) + size) -1) <= resource->limit) {
/* base must be aligned to size */
base = round(base, align);
resource->base = base;
resource->flags |= IORESOURCE_ASSIGNED;
resource->flags &= ~IORESOURCE_STORED;
base += size;
printk_spew("%s %02x * [0x%08Lx - 0x%08Lx] %s\n",
dev_path(dev),
resource->index,
resource->base,
resource->base + resource->size - 1,
(resource->flags & IORESOURCE_IO)? "io":
(resource->flags & IORESOURCE_PREFETCH)? "prefmem": "mem");
}
}
/* A pci bridge resource does not need to be a power
* of two size, but it does have a minimum granularity.
* Round the size up to that minimum granularity so we
* know not to place something else at an address postitively
* decoded by the bridge.
*/
bridge->size = round(base, bridge->gran) - bridge->base;
printk_spew("%s compute_allocate_%s: base: %08Lx size: %08Lx align: %d gran: %d done\n",
dev_path(bus->dev),
(bridge->flags & IORESOURCE_IO)? "io":
(bridge->flags & IORESOURCE_PREFETCH)? "prefmem" : "mem",
base, bridge->size, bridge->align, bridge->gran);
}
#if CONFIG_CONSOLE_VGA == 1
device_t vga_pri = 0;
static void allocate_vga_resource(void)
{
#warning "FIXME modify allocate_vga_resource so it is less pci centric!"
#warning "This function knows to much about PCI stuff, it should be just a ietrator/visitor."
/* FIXME handle the VGA pallette snooping */
struct device *dev, *vga, *vga_onboard;
struct bus *bus;
bus = 0;
vga = 0;
vga_onboard = 0;
for (dev = all_devices; dev; dev = dev->next) {
if ( !dev->enabled ) continue;
if (((dev->class >> 16) == PCI_BASE_CLASS_DISPLAY) &&
((dev->class >> 8) != PCI_CLASS_DISPLAY_OTHER)) {
if (!vga) {
if (dev->on_mainboard) {
vga_onboard = dev;
}
else {
vga = dev;
}
}
/* It isn't safe to enable other VGA cards */
dev->command &= ~(PCI_COMMAND_MEMORY | PCI_COMMAND_IO);
}
}
if (!vga) {
vga = vga_onboard;
}
if (vga) { // vga is first add on card or the only onboard vga
printk_debug("Allocating VGA resource %s\n", dev_path(vga));
vga->command |= (PCI_COMMAND_MEMORY | PCI_COMMAND_IO);
vga_pri = vga;
bus = vga->bus;
}
/* Now walk up the bridges setting the VGA enable */
while (bus) {
printk_debug("Setting PCI_BRIDGE_CTL_VGA for bridge %s\n",
dev_path(bus->dev));
bus->bridge_ctrl |= PCI_BRIDGE_CTL_VGA;
bus = (bus == bus->dev->bus)? 0 : bus->dev->bus;
}
}
#endif
/**
* @brief Assign the computed resources to the devices on the bus.
*
* @param bus Pointer to the structure for this bus
*
* Use the device specific set_resources method to store the computed
* resources to hardware. For bridge devices, the set_resources() method
* has to recurse into every down stream buses.
*
* Mutual recursion:
* assign_resources() -> device_operation::set_resources()
* device_operation::set_resources() -> assign_resources()
*/
void assign_resources(struct bus *bus)
{
struct device *curdev;
printk_spew("%s assign_resources, bus %d link: %d\n",
dev_path(bus->dev), bus->secondary, bus->link);
for (curdev = bus->children; curdev; curdev = curdev->sibling) {
if (!curdev->enabled || !curdev->resources) {
continue;
}
if (!curdev->ops || !curdev->ops->set_resources) {
printk_err("%s missing set_resources\n",
dev_path(curdev));
continue;
}
curdev->ops->set_resources(curdev);
}
printk_spew("%s assign_resources, bus %d link: %d\n",
dev_path(bus->dev), bus->secondary, bus->link);
}
/**
* @brief Enable the resources for a specific device
*
* @param dev the device whose resources are to be enabled
*
* Enable resources of the device by calling the device specific
* enable_resources() method.
*
* The parent's resources should be enabled first to avoid having enabling
* order problem. This is done by calling the parent's enable_resources()
* method and let that method to call it's children's enable_resoruces()
* method via the (global) enable_childrens_resources().
*
* Indirect mutual recursion:
* enable_resources() -> device_operations::enable_resource()
* device_operations::enable_resource() -> enable_children_resources()
* enable_children_resources() -> enable_resources()
*/
void enable_resources(struct device *dev)
{
if (!dev->enabled) {
return;
}
if (!dev->ops || !dev->ops->enable_resources) {
printk_err("%s missing enable_resources\n", dev_path(dev));
return;
}
dev->ops->enable_resources(dev);
}
/**
* @brief Determine the existence of devices and extend the device tree.
*
* Most of the devices in the system are listed in the mainboard Config.lb
* file. The device structures for these devices are generated at compile
* time by the config tool and are organized into the device tree. This
* function determines if the devices created at compile time actually exist
* in the physical system.
*
* For devices in the physical system but not listed in the Config.lb file,
* the device structures have to be created at run time and attached to the
* device tree.
*
* This function starts from the root device 'dev_root', scan the buses in
* the system recursively, modify the device tree according to the result of
* the probe.
*
* This function has no idea how to scan and probe buses and devices at all.
* It depends on the bus/device specific scan_bus() method to do it. The
* scan_bus() method also has to create the device structure and attach
* it to the device tree.
*/
void dev_enumerate(void)
{
struct device *root;
unsigned subordinate;
printk_info("Enumerating buses...\n");
root = &dev_root;
if (root->chip_ops && root->chip_ops->enable_dev) {
root->chip_ops->enable_dev(root);
}
if (!root->ops || !root->ops->scan_bus) {
printk_err("dev_root missing scan_bus operation");
return;
}
subordinate = root->ops->scan_bus(root, 0);
printk_info("done\n");
}
/**
* @brief Configure devices on the devices tree.
*
* Starting at the root of the device tree, travel it recursively in two
* passes. In the first pass, we compute and allocate resources (ranges)
* requried by each device. In the second pass, the resources ranges are
* relocated to their final position and stored to the hardware.
*
* I/O resources start at DEVICE_IO_START and grow upward. MEM resources start
* at DEVICE_MEM_START and grow downward.
*
* Since the assignment is hierarchical we set the values into the dev_root
* struct.
*/
void dev_configure(void)
{
struct resource *io, *mem;
struct device *root;
printk_info("Allocating resources...\n");
root = &dev_root;
if (!root->ops || !root->ops->read_resources) {
printk_err("dev_root missing read_resources\n");
return;
}
if (!root->ops || !root->ops->set_resources) {
printk_err("dev_root missing set_resources\n");
return;
}
printk_info("Reading resources...\n");
root->ops->read_resources(root);
printk_info("Done reading resources.\n");
/* Get the resources */
io = &root->resource[0];
mem = &root->resource[1];
/* Make certain the io devices are allocated somewhere safe. */
io->base = DEVICE_IO_START;
io->flags |= IORESOURCE_ASSIGNED;
io->flags &= ~IORESOURCE_STORED;
/* Now reallocate the pci resources memory with the
* highest addresses I can manage.
*/
mem->base = resource_max(&root->resource[1]);
mem->flags |= IORESOURCE_ASSIGNED;
mem->flags &= ~IORESOURCE_STORED;
#if CONFIG_CONSOLE_VGA == 1
/* Allocate the VGA I/O resource.. */
allocate_vga_resource();
#endif
/* Store the computed resource allocations into device registers ... */
printk_info("Setting resources...\n");
root->ops->set_resources(root);
printk_info("Done setting resources.\n");
#if 0
mem->flags |= IORESOURCE_STORED;
report_resource_stored(root, mem, "");
#endif
printk_info("Done allocating resources.\n");
}
/**
* @brief Enable devices on the device tree.
*
* Starting at the root, walk the tree and enable all devices/bridges by
* calling the device's enable_resources() method.
*/
void dev_enable(void)
{
printk_info("Enabling resourcess...\n");
/* now enable everything. */
enable_resources(&dev_root);
printk_info("done.\n");
}
/**
* @brief Initialize all devices in the global device list.
*
* Starting at the first device on the global device link list,
* walk the list and call the device's init() method to do deivce
* specific setup.
*/
void dev_initialize(void)
{
struct device *dev;
printk_info("Initializing devices...\n");
for (dev = all_devices; dev; dev = dev->next) {
if (dev->enabled && !dev->initialized &&
dev->ops && dev->ops->init)
{
if(dev->path.type == DEVICE_PATH_I2C)
printk_debug("smbus: %s[%d]->", dev_path(dev->bus->dev), dev->bus->link );
printk_debug("%s init\n", dev_path(dev));
dev->initialized = 1;
dev->ops->init(dev);
}
}
printk_info("Devices initialized\n");
}