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

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/*
* This file is part of the coreboot project.
*
* It was originally based on the Linux kernel (arch/i386/kernel/pci-pc.c).
*
* Modifications are:
* Copyright (C) 2003 Eric Biederman <ebiederm@xmission.com>
* Copyright (C) 2003-2004 Linux Networx
* (Written by Eric Biederman <ebiederman@lnxi.com> for Linux Networx)
* Copyright (C) 2003 Ronald G. Minnich <rminnich@gmail.com>
* Copyright (C) 2004-2005 Li-Ta Lo <ollie@lanl.gov>
* Copyright (C) 2005-2006 Tyan
* (Written by Yinghai Lu <yhlu@tyan.com> for Tyan)
* Copyright (C) 2005-2006 Stefan Reinauer <stepan@openbios.org>
* Copyright (C) 2009 Myles Watson <mylesgw@gmail.com>
*/
/*
* (c) 1999--2000 Martin Mares <mj@suse.cz>
*/
/*
* 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 <arch/io.h>
#include <device/device.h>
#include <device/pci_def.h>
#include <device/pci_ids.h>
#include <stdlib.h>
#include <string.h>
#include <smp/spinlock.h>
Prepare the BIOS data areas before device init. Since we do not run option roms in normal mode nothing was initializing the BDA/EBDA and yet Linux depends very much on it having sane values here. For the most part the kernel tries to work around this not being initialized, but every once in awhile (1/300 boots or so) it would end up reading something that looked sane from BDA but was not and then it would panic. In this change the EBDA is unconditionally setup before devices are initialized. I'm not set on the location in dev_initialize() but there does not seem to be another place to hook it in so that it runs just once for ALL platforms regardless of whether they use option roms or not. (possibly hardwaremain?) The EBDA setup code has been moved into its own location in arch/x86/lib/ebda.c so it can be compiled in even if the option rom code is not. The low memory size is still set to 1MB which is enough to make linux happy without having to hook into each mainboard to get a more appropriate value. The setup_ebda() function takes inputs so it could be changed for a mainboard if needed. OLD/BROKEN would read garbage. Examples from different boots: ebda_addr=0x75e80 lowmem=0x1553400 ebda_addr=0x5e080 lowmem=0x3e51400 ebda_addr=0x7aa80 lowmem=0x2f8a800 NEW/FIXED now reads consistent values: ebda_addr=0xf6000 lowmem=0x100000 Change-Id: I6cb79f0e3e43cc65f7e5fe98b6cad1a557ccd949 Signed-off-by: Duncan Laurie <dlaurie@google.com> Reviewed-on: http://review.coreboot.org/769 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2012-01-17 18:03:11 +01:00
#if CONFIG_ARCH_X86
#include <arch/ebda.h>
#endif
#include <timer.h>
/** Linked list of ALL devices */
- Moved hlt() to it's own header. - Reworked pnp superio device support. Now complete superio support is less than 100 lines. - Added support for hard coding resource assignments in Config.lb - Minor bug fixes to romcc - Initial support for catching the x86 processor BIST error codes. I've only seen this trigger once in production during a very suspcious reset but... - added raminit_test to test the code paths in raminit.c for the Opteron - Removed the IORESOURCE_SET bit and added IORESOURCE_ASSIGNED and IORESOURCE_STORED so we can tell what we have really done. - Added generic AGP/IOMMU setting code to x86 - Added an implementation of memmove and removed reserved identifiers from memcpy - Added minimal support for booting on pre b3 stepping K8 cores - Moved the checksum on amd8111 boards because our default location was on top of extended RTC registers - On the Hdama added support for enabling i2c hub so we can get at the temperature sensors. Not that i2c bus was implemented well enough to make that useful. - Redid the Opteron port so we should only need one reset and most of memory initialization is done in cpu_fixup. This is much, much faster. - Attempted to make the VGA IO region assigment work. The code seems to work now... - Redid the error handling in amdk8/raminit.c to distinguish between a bad value and a smbus error, and moved memory clearing out to cpufixup. - Removed CONFIG_KEYBOARD as it was useless. See pc87360/superio.c for how to setup a legacy keyboard properly. - Reworked the register values for standard hardware, moving the defintions from chip.h into the headers of the initialization routines. This is much saner and is actually implemented. - Made the hdama port an under clockers BIOS. I debuged so many interesting problems. - On amd8111_lpc added setup of architectural/legacy hardware - Enabled PCI error reporting as much as possible. - Enhanded build_opt_tbl to generate a header of the cmos option locations so that romcc compiled code can query the cmos options. - In romcc gracefully handle function names that degenerate into function pointers - Bumped the version to 1.1.6 as we are getting closer to 2.0 TODO finish optimizing the HT links of non dual boards TODO make all Opteron board work again TODO convert all superio devices to use the new helpers TODO convert the via/epia to freebios2 conventions TODO cpu fixup/setup by cpu type git-svn-id: svn://svn.coreboot.org/coreboot/trunk@1390 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2004-03-11 16:01:31 +01:00
struct device *all_devices = &dev_root;
/** Pointer to the last device */
extern struct device *last_dev;
/** Linked list of free resources */
struct resource *free_resources = NULL;
/**
* Initialize all chips of statically known devices.
*
* Will be called before bus enumeration to initialize chips stated in the
* device tree.
*/
void dev_initialize_chips(void)
{
struct device *dev;
for (dev = all_devices; dev; dev = dev->next) {
/* Initialize chip if we haven't yet. */
if (dev->chip_ops && dev->chip_ops->init &&
!dev->chip_ops->initialized) {
post_log_path(dev);
dev->chip_ops->init(dev->chip_info);
dev->chip_ops->initialized = 1;
}
}
post_log_clear();
}
/**
* Finalize all chips of statically known devices.
*
* This is the last call before calling the payload. This is a good place
* to lock registers or other final cleanup.
*/
void dev_finalize_chips(void)
{
struct device *dev;
for (dev = all_devices; dev; dev = dev->next) {
/* Initialize chip if we haven't yet. */
if (dev->chip_ops && dev->chip_ops->final &&
!dev->chip_ops->finalized) {
dev->chip_ops->final(dev->chip_info);
dev->chip_ops->finalized = 1;
}
}
}
DECLARE_SPIN_LOCK(dev_lock)
#if CONFIG_GFXUMA
/* IGD UMA memory */
uint64_t uma_memory_base = 0;
uint64_t uma_memory_size = 0;
#endif
/**
* Allocate a new device structure.
*
* Allocate a new device structure and attach it to the device tree as a
* child of the parent bus.
*
* @param parent Parent bus the newly created device should be attached to.
* @param path Path to the device to be created.
* @return Pointer to the newly created device structure.
*
* @see device_path
*/
static device_t __alloc_dev(struct bus *parent, struct device_path *path)
{
device_t dev, child;
/* 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("alloc_dev(): out of memory.\n");
memset(dev, 0, sizeof(*dev));
memcpy(&dev->path, path, sizeof(*path));
/* 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->next = dev;
last_dev = dev;
return dev;
}
device_t alloc_dev(struct bus *parent, struct device_path *path)
{
device_t dev;
spin_lock(&dev_lock);
dev = __alloc_dev(parent, path);
spin_unlock(&dev_lock);
return dev;
}
/**
* See if a device structure already exists and if not allocate it.
*
* @param parent The bus to find the device on.
* @param path The relative path from the bus to the appropriate device.
* @return Pointer to a device structure for the device on bus at path.
*/
device_t alloc_find_dev(struct bus *parent, struct device_path *path)
{
device_t child;
spin_lock(&dev_lock);
child = find_dev_path(parent, path);
if (!child)
child = __alloc_dev(parent, path);
spin_unlock(&dev_lock);
return child;
}
/**
* Round a number up to an alignment.
*
* @param val The starting value.
* @param pow Alignment as a power of two.
* @return 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(BIOS_SPEW, "%s %s bus %x link: %d\n", dev_path(bus->dev),
__func__, bus->secondary, bus->link_num);
/* Walk through all devices and find which resources they need. */
for (curdev = bus->children; curdev; curdev = curdev->sibling) {
struct bus *link;
if (!curdev->enabled)
continue;
if (!curdev->ops || !curdev->ops->read_resources) {
printk(BIOS_ERR, "%s missing read_resources\n",
dev_path(curdev));
continue;
}
post_log_path(curdev);
curdev->ops->read_resources(curdev);
/* Read in the resources behind the current device's links. */
for (link = curdev->link_list; link; link = link->next)
read_resources(link);
}
post_log_clear();
printk(BIOS_SPEW, "%s read_resources bus %d link: %d done\n",
dev_path(bus->dev), bus->secondary, bus->link_num);
}
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 (resource->flags & IORESOURCE_FIXED)
return; /* Skip it. */
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 = NULL;
state.result = NULL;
state.seen_last = 0;
search_bus_resources(bus, type_mask, type, pick_largest_resource,
&state);
*result_res = state.result;
return state.result_dev;
}
/**
* This function is the guts of the resource allocator.
*
* The problem.
* - Allocate resource 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 their 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 us 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.
*
* @param bus The bus we are traversing.
* @param bridge The bridge resource which must contain the bus' resources.
* @param type_mask This value gets ANDed with the resource type.
* @param type This value must match the result of the AND.
* @return TODO
*/
static void compute_resources(struct bus *bus, struct resource *bridge,
unsigned long type_mask, unsigned long type)
{
struct device *dev;
struct resource *resource;
resource_t base;
base = round(bridge->base, bridge->align);
printk(BIOS_SPEW, "%s %s_%s: base: %llx size: %llx align: %d gran: %d"
" limit: %llx\n", dev_path(bus->dev), __func__,
(type & IORESOURCE_IO) ? "io" : (type & IORESOURCE_PREFETCH) ?
"prefmem" : "mem", base, bridge->size, bridge->align,
bridge->gran, bridge->limit);
/* For each child which is a bridge, compute the resource needs. */
for (dev = bus->children; dev; dev = dev->sibling) {
struct resource *child_bridge;
if (!dev->link_list)
continue;
/* Find the resources with matching type flags. */
for (child_bridge = dev->resource_list; child_bridge;
child_bridge = child_bridge->next) {
struct bus* link;
if (!(child_bridge->flags & IORESOURCE_BRIDGE)
|| (child_bridge->flags & type_mask) != type)
continue;
/*
* Split prefetchable memory if combined. Many domains
* use the same address space for prefetchable memory
* and non-prefetchable memory. Bridges below them need
* it separated. Add the PREFETCH flag to the type_mask
* and type.
*/
link = dev->link_list;
while (link && link->link_num !=
IOINDEX_LINK(child_bridge->index))
link = link->next;
if (link == NULL) {
printk(BIOS_ERR, "link %ld not found on %s\n",
IOINDEX_LINK(child_bridge->index),
dev_path(dev));
}
compute_resources(link, child_bridge,
type_mask | IORESOURCE_PREFETCH,
type | (child_bridge->flags &
IORESOURCE_PREFETCH));
}
}
/* Remember we haven't found anything yet. */
resource = NULL;
/*
* Walk through all the resources on the current bus and compute the
* amount of address space taken by them. Take granularity and
* alignment into account.
*/
while ((dev = largest_resource(bus, &resource, type_mask, type))) {
/* Size 0 resources can be skipped. */
if (!resource->size)
continue;
/* Propagate the resource alignment to the bridge resource. */
if (resource->align > bridge->align)
bridge->align = resource->align;
/* Propagate the resource limit to the bridge register. */
if (bridge->limit > resource->limit)
bridge->limit = resource->limit;
/* Warn if it looks like APICs aren't declared. */
if ((resource->limit == 0xffffffff) &&
(resource->flags & IORESOURCE_ASSIGNED)) {
printk(BIOS_ERR,
"Resource limit looks wrong! (no APIC?)\n");
printk(BIOS_ERR, "%s %02lx limit %08llx\n",
dev_path(dev), resource->index, resource->limit);
}
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 0x100 - 0x3ff. Therefore, only
* 0x00 - 0xff can be used out of each 0x400 block of
* I/O space.
*/
if ((base & 0x300) != 0) {
base = (base & ~0x3ff) + 0x400;
}
/*
* Don't allow allocations in the VGA I/O range.
* PCI has special cases for that.
*/
else if ((base >= 0x3b0) && (base <= 0x3df)) {
base = 0x3e0;
}
}
/* Base must be aligned. */
base = round(base, resource->align);
resource->base = base;
base += resource->size;
printk(BIOS_SPEW, "%s %02lx * [0x%llx - 0x%llx] %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 positively decoded by the bridge.
*/
bridge->size = round(base, bridge->gran) -
round(bridge->base, bridge->align);
printk(BIOS_SPEW, "%s %s_%s: base: %llx size: %llx align: %d gran: %d"
" limit: %llx done\n", dev_path(bus->dev), __func__,
(bridge->flags & IORESOURCE_IO) ? "io" :
(bridge->flags & IORESOURCE_PREFETCH) ? "prefmem" : "mem",
base, bridge->size, bridge->align, bridge->gran, bridge->limit);
}
/**
* This function is the second part of the resource allocator.
*
* See the compute_resources function for a more detailed explanation.
*
* This function assigns the resources a value.
*
* @param bus The bus we are traversing.
* @param bridge The bridge resource which must contain the bus' resources.
* @param type_mask This value gets ANDed with the resource type.
* @param type This value must match the result of the AND.
*
* @see compute_resources
*/
static void allocate_resources(struct bus *bus, struct resource *bridge,
unsigned long type_mask, unsigned long type)
{
struct device *dev;
struct resource *resource;
resource_t base;
base = bridge->base;
printk(BIOS_SPEW, "%s %s_%s: base:%llx size:%llx align:%d gran:%d "
"limit:%llx\n", dev_path(bus->dev), __func__,
(type & IORESOURCE_IO) ? "io" : (type & IORESOURCE_PREFETCH) ?
"prefmem" : "mem",
base, bridge->size, bridge->align, bridge->gran, bridge->limit);
/* Remember we haven't found anything yet. */
resource = NULL;
/*
* Walk through all the resources on the current bus and allocate them
* address space.
*/
while ((dev = largest_resource(bus, &resource, type_mask, type))) {
/* Propagate the bridge limit to the resource register. */
if (resource->limit > bridge->limit)
resource->limit = bridge->limit;
/* Size 0 resources can be skipped. */
if (!resource->size) {
/* Set the base to limit so it doesn't confuse tolm. */
resource->base = resource->limit;
resource->flags |= IORESOURCE_ASSIGNED;
continue;
}
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 0x100 - 0x3ff. Therefore, only
* 0x00 - 0xff can be used out of each 0x400 block of
* I/O space.
*/
if ((base & 0x300) != 0) {
base = (base & ~0x3ff) + 0x400;
}
/*
* Don't allow allocations in the VGA I/O range.
* PCI has special cases for that.
*/
else if ((base >= 0x3b0) && (base <= 0x3df)) {
base = 0x3e0;
}
}
if ((round(base, resource->align) + resource->size - 1) <=
resource->limit) {
/* Base must be aligned. */
base = round(base, resource->align);
resource->base = base;
resource->flags |= IORESOURCE_ASSIGNED;
resource->flags &= ~IORESOURCE_STORED;
base += resource->size;
} else {
printk(BIOS_ERR, "!! Resource didn't fit !!\n");
printk(BIOS_ERR, " aligned base %llx size %llx "
"limit %llx\n", round(base, resource->align),
resource->size, resource->limit);
printk(BIOS_ERR, " %llx needs to be <= %llx "
"(limit)\n", (round(base, resource->align) +
resource->size) - 1, resource->limit);
printk(BIOS_ERR, " %s%s %02lx * [0x%llx - 0x%llx]"
" %s\n", (resource->flags & IORESOURCE_ASSIGNED)
? "Assigned: " : "", dev_path(dev),
resource->index, resource->base,
resource->base + resource->size - 1,
(resource->flags & IORESOURCE_IO) ? "io"
: (resource->flags & IORESOURCE_PREFETCH)
? "prefmem" : "mem");
}
printk(BIOS_SPEW, "%s%s %02lx * [0x%llx - 0x%llx] %s\n",
(resource->flags & IORESOURCE_ASSIGNED) ? "Assigned: "
: "", dev_path(dev), resource->index, resource->base,
resource->size ? resource->base + resource->size - 1 :
resource->base, (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 positively decoded by the bridge.
*/
bridge->flags |= IORESOURCE_ASSIGNED;
printk(BIOS_SPEW, "%s %s_%s: next_base: %llx size: %llx align: %d "
"gran: %d done\n", dev_path(bus->dev), __func__,
(type & IORESOURCE_IO) ? "io" : (type & IORESOURCE_PREFETCH) ?
"prefmem" : "mem", base, bridge->size, bridge->align,
bridge->gran);
/* For each child which is a bridge, allocate_resources. */
for (dev = bus->children; dev; dev = dev->sibling) {
struct resource *child_bridge;
if (!dev->link_list)
continue;
/* Find the resources with matching type flags. */
for (child_bridge = dev->resource_list; child_bridge;
child_bridge = child_bridge->next) {
struct bus* link;
if (!(child_bridge->flags & IORESOURCE_BRIDGE) ||
(child_bridge->flags & type_mask) != type)
continue;
/*
* Split prefetchable memory if combined. Many domains
* use the same address space for prefetchable memory
* and non-prefetchable memory. Bridges below them need
* it separated. Add the PREFETCH flag to the type_mask
* and type.
*/
link = dev->link_list;
while (link && link->link_num !=
IOINDEX_LINK(child_bridge->index))
link = link->next;
if (link == NULL)
printk(BIOS_ERR, "link %ld not found on %s\n",
IOINDEX_LINK(child_bridge->index),
dev_path(dev));
allocate_resources(link, child_bridge,
type_mask | IORESOURCE_PREFETCH,
type | (child_bridge->flags &
IORESOURCE_PREFETCH));
}
}
}
#if CONFIG_PCI_64BIT_PREF_MEM
#define MEM_MASK (IORESOURCE_PREFETCH | IORESOURCE_MEM)
#else
#define MEM_MASK (IORESOURCE_MEM)
#endif
#define IO_MASK (IORESOURCE_IO)
#define PREF_TYPE (IORESOURCE_PREFETCH | IORESOURCE_MEM)
#define MEM_TYPE (IORESOURCE_MEM)
#define IO_TYPE (IORESOURCE_IO)
struct constraints {
struct resource pref, io, mem;
};
static void constrain_resources(struct device *dev, struct constraints* limits)
{
struct device *child;
struct resource *res;
struct resource *lim;
struct bus *link;
printk(BIOS_SPEW, "%s: %s\n", __func__, dev_path(dev));
/* Constrain limits based on the fixed resources of this device. */
for (res = dev->resource_list; res; res = res->next) {
if (!(res->flags & IORESOURCE_FIXED))
continue;
if (!res->size) {
/* It makes no sense to have 0-sized, fixed resources.*/
printk(BIOS_ERR, "skipping %s@%lx fixed resource, "
"size=0!\n", dev_path(dev), res->index);
continue;
}
/* PREFETCH, MEM, or I/O - skip any others. */
if ((res->flags & MEM_MASK) == PREF_TYPE)
lim = &limits->pref;
else if ((res->flags & MEM_MASK) == MEM_TYPE)
lim = &limits->mem;
else if ((res->flags & IO_MASK) == IO_TYPE)
lim = &limits->io;
else
continue;
/*
* Is it a fixed resource outside the current known region?
* If so, we don't have to consider it - it will be handled
* correctly and doesn't affect current region's limits.
*/
if (((res->base + res->size -1) < lim->base)
|| (res->base > lim->limit))
continue;
/*
* Choose to be above or below fixed resources. This check is
* signed so that "negative" amounts of space are handled
* correctly.
*/
if ((signed long long)(lim->limit - (res->base + res->size -1))
> (signed long long)(res->base - lim->base))
lim->base = res->base + res->size;
else
lim->limit = res->base -1;
}
/* Descend into every enabled child and look for fixed resources. */
for (link = dev->link_list; link; link = link->next) {
for (child = link->children; child; child = child->sibling) {
if (child->enabled)
constrain_resources(child, limits);
}
}
}
static void avoid_fixed_resources(struct device *dev)
{
struct constraints limits;
struct resource *res;
printk(BIOS_SPEW, "%s: %s\n", __func__, dev_path(dev));
/* Initialize constraints to maximum size. */
limits.pref.base = 0;
limits.pref.limit = 0xffffffffffffffffULL;
limits.io.base = 0;
limits.io.limit = 0xffffffffffffffffULL;
limits.mem.base = 0;
limits.mem.limit = 0xffffffffffffffffULL;
/* Constrain the limits to dev's initial resources. */
for (res = dev->resource_list; res; res = res->next) {
if ((res->flags & IORESOURCE_FIXED))
continue;
printk(BIOS_SPEW, "%s:@%s %02lx limit %08llx\n", __func__,
dev_path(dev), res->index, res->limit);
if ((res->flags & MEM_MASK) == PREF_TYPE &&
(res->limit < limits.pref.limit))
limits.pref.limit = res->limit;
if ((res->flags & MEM_MASK) == MEM_TYPE &&
(res->limit < limits.mem.limit))
limits.mem.limit = res->limit;
if ((res->flags & IO_MASK) == IO_TYPE &&
(res->limit < limits.io.limit))
limits.io.limit = res->limit;
}
/* Look through the tree for fixed resources and update the limits. */
constrain_resources(dev, &limits);
/* Update dev's resources with new limits. */
for (res = dev->resource_list; res; res = res->next) {
struct resource *lim;
if ((res->flags & IORESOURCE_FIXED))
continue;
/* PREFETCH, MEM, or I/O - skip any others. */
if ((res->flags & MEM_MASK) == PREF_TYPE)
lim = &limits.pref;
else if ((res->flags & MEM_MASK) == MEM_TYPE)
lim = &limits.mem;
else if ((res->flags & IO_MASK) == IO_TYPE)
lim = &limits.io;
else
continue;
printk(BIOS_SPEW, "%s2: %s@%02lx limit %08llx\n", __func__,
dev_path(dev), res->index, res->limit);
printk(BIOS_SPEW, "\tlim->base %08llx lim->limit %08llx\n",
lim->base, lim->limit);
/* Is the resource outside the limits? */
if (lim->base > res->base)
res->base = lim->base;
if (res->limit > lim->limit)
res->limit = lim->limit;
}
}
device_t vga_pri = 0;
static void set_vga_bridge_bits(void)
{
/*
* FIXME: Modify set_vga_bridge() so it is less PCI-centric!
* This function knows too much about PCI stuff, it should be just
* an iterator/visitor.
*/
/* FIXME: Handle the VGA palette snooping. */
struct device *dev, *vga, *vga_onboard;
struct bus *bus;
bus = 0;
vga = 0;
vga_onboard = 0;
dev = NULL;
while ((dev = dev_find_class(PCI_CLASS_DISPLAY_VGA << 8, dev))) {
if (!dev->enabled)
continue;
printk(BIOS_DEBUG, "found VGA at %s\n", dev_path(dev));
if (dev->on_mainboard) {
vga_onboard = dev;
} else {
vga = dev;
}
/* It isn't safe to enable all VGA cards. */
dev->command &= ~(PCI_COMMAND_MEMORY | PCI_COMMAND_IO);
}
if (!vga)
vga = vga_onboard;
if (CONFIG_ONBOARD_VGA_IS_PRIMARY && vga_onboard)
vga = vga_onboard;
/* If we prefer plugin VGA over chipset VGA, the chipset might
want to know. */
if (!CONFIG_ONBOARD_VGA_IS_PRIMARY && (vga != vga_onboard) &&
vga_onboard && vga_onboard->ops && vga_onboard->ops->disable) {
printk(BIOS_DEBUG, "Use plugin graphics over integrated.\n");
vga_onboard->ops->disable(vga_onboard);
}
if (vga) {
/* VGA is first add-on card or the only onboard VGA. */
printk(BIOS_DEBUG, "Setting up VGA for %s\n", dev_path(vga));
/* All legacy VGA cards have MEM & I/O space registers. */
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(BIOS_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;
}
}
/**
* Assign the computed resources to the devices on the 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()
*
* @param bus Pointer to the structure for this bus.
*/
void assign_resources(struct bus *bus)
{
struct device *curdev;
printk(BIOS_SPEW, "%s assign_resources, bus %d link: %d\n",
dev_path(bus->dev), bus->secondary, bus->link_num);
for (curdev = bus->children; curdev; curdev = curdev->sibling) {
if (!curdev->enabled || !curdev->resource_list)
continue;
if (!curdev->ops || !curdev->ops->set_resources) {
printk(BIOS_ERR, "%s missing set_resources\n",
dev_path(curdev));
continue;
}
post_log_path(curdev);
curdev->ops->set_resources(curdev);
}
post_log_clear();
printk(BIOS_SPEW, "%s assign_resources, bus %d link: %d\n",
dev_path(bus->dev), bus->secondary, bus->link_num);
}
/**
* Enable the resources for devices on a link.
*
* 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 before its children's enable_resources() methods.
*
* @param link The link whose devices' resources are to be enabled.
*/
static void enable_resources(struct bus *link)
{
struct device *dev;
struct bus *c_link;
for (dev = link->children; dev; dev = dev->sibling) {
if (dev->enabled && dev->ops && dev->ops->enable_resources) {
post_log_path(dev);
dev->ops->enable_resources(dev);
}
}
for (dev = link->children; dev; dev = dev->sibling) {
for (c_link = dev->link_list; c_link; c_link = c_link->next)
enable_resources(c_link);
}
post_log_clear();
}
/**
* Reset all of the devices on a bus and clear the bus's reset_needed flag.
*
* @param bus Pointer to the bus structure.
* @return 1 if the bus was successfully reset, 0 otherwise.
*/
int reset_bus(struct bus *bus)
{
if (bus && bus->dev && bus->dev->ops && bus->dev->ops->reset_bus) {
bus->dev->ops->reset_bus(bus);
bus->reset_needed = 0;
return 1;
}
return 0;
}
/**
* Scan for devices on a bus.
*
* If there are bridges on the bus, recursively scan the buses behind the
* bridges. If the setting up and tuning of the bus causes a reset to be
* required, reset the bus and scan it again.
*
* @param busdev Pointer to the bus device.
* @param max Current bus number.
* @return The maximum bus number found, after scanning all subordinate buses.
*/
unsigned int scan_bus(struct device *busdev, unsigned int max)
{
unsigned int new_max;
int do_scan_bus;
if (!busdev || !busdev->enabled || !busdev->ops ||
!busdev->ops->scan_bus) {
return max;
}
post_log_path(busdev);
do_scan_bus = 1;
while (do_scan_bus) {
struct bus *link;
new_max = busdev->ops->scan_bus(busdev, max);
do_scan_bus = 0;
for (link = busdev->link_list; link; link = link->next) {
if (link->reset_needed) {
if (reset_bus(link))
do_scan_bus = 1;
else
busdev->bus->reset_needed = 1;
}
}
}
return new_max;
}
/**
* Determine the existence of devices and extend the device tree.
*
* Most of the devices in the system are listed in the mainboard devicetree.cb
* 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 devicetree.cb,
* 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', scans the buses in
* the system recursively, and modifies 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;
printk(BIOS_INFO, "Enumerating buses...\n");
root = &dev_root;
show_all_devs(BIOS_SPEW, "Before device enumeration.");
printk(BIOS_SPEW, "Compare with tree...\n");
show_devs_tree(root, BIOS_SPEW, 0, 0);
if (root->chip_ops && root->chip_ops->enable_dev)
root->chip_ops->enable_dev(root);
if (!root->ops || !root->ops->scan_bus) {
printk(BIOS_ERR, "dev_root missing scan_bus operation");
return;
}
scan_bus(root, 0);
post_log_clear();
printk(BIOS_INFO, "done\n");
}
/**
* 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)
* required by each device. In the second pass, the resources ranges are
* relocated to their final position and stored to the hardware.
*
* I/O resources grow upward. MEM resources grow downward.
*
* Since the assignment is hierarchical we set the values into the dev_root
* struct.
*/
void dev_configure(void)
{
struct resource *res;
struct device *root;
struct device *child;
set_vga_bridge_bits();
printk(BIOS_INFO, "Allocating resources...\n");
root = &dev_root;
/*
* Each domain should create resources which contain the entire address
* space for IO, MEM, and PREFMEM resources in the domain. The
* allocation of device resources will be done from this address space.
*/
/* Read the resources for the entire tree. */
printk(BIOS_INFO, "Reading resources...\n");
read_resources(root->link_list);
printk(BIOS_INFO, "Done reading resources.\n");
print_resource_tree(root, BIOS_SPEW, "After reading.");
/* Compute resources for all domains. */
for (child = root->link_list->children; child; child = child->sibling) {
if (!(child->path.type == DEVICE_PATH_DOMAIN))
continue;
post_log_path(child);
for (res = child->resource_list; res; res = res->next) {
if (res->flags & IORESOURCE_FIXED)
continue;
if (res->flags & IORESOURCE_PREFETCH) {
compute_resources(child->link_list,
res, MEM_MASK, PREF_TYPE);
continue;
}
if (res->flags & IORESOURCE_MEM) {
compute_resources(child->link_list,
res, MEM_MASK, MEM_TYPE);
continue;
}
if (res->flags & IORESOURCE_IO) {
compute_resources(child->link_list,
res, IO_MASK, IO_TYPE);
continue;
}
}
}
/* For all domains. */
for (child = root->link_list->children; child; child=child->sibling)
if (child->path.type == DEVICE_PATH_DOMAIN)
avoid_fixed_resources(child);
/*
* Now we need to adjust the resources. MEM resources need to start at
* the highest address manageable.
*/
for (child = root->link_list->children; child; child = child->sibling) {
if (child->path.type != DEVICE_PATH_DOMAIN)
continue;
for (res = child->resource_list; res; res = res->next) {
if (!(res->flags & IORESOURCE_MEM) ||
res->flags & IORESOURCE_FIXED)
continue;
res->base = resource_max(res);
}
}
- Moved hlt() to it's own header. - Reworked pnp superio device support. Now complete superio support is less than 100 lines. - Added support for hard coding resource assignments in Config.lb - Minor bug fixes to romcc - Initial support for catching the x86 processor BIST error codes. I've only seen this trigger once in production during a very suspcious reset but... - added raminit_test to test the code paths in raminit.c for the Opteron - Removed the IORESOURCE_SET bit and added IORESOURCE_ASSIGNED and IORESOURCE_STORED so we can tell what we have really done. - Added generic AGP/IOMMU setting code to x86 - Added an implementation of memmove and removed reserved identifiers from memcpy - Added minimal support for booting on pre b3 stepping K8 cores - Moved the checksum on amd8111 boards because our default location was on top of extended RTC registers - On the Hdama added support for enabling i2c hub so we can get at the temperature sensors. Not that i2c bus was implemented well enough to make that useful. - Redid the Opteron port so we should only need one reset and most of memory initialization is done in cpu_fixup. This is much, much faster. - Attempted to make the VGA IO region assigment work. The code seems to work now... - Redid the error handling in amdk8/raminit.c to distinguish between a bad value and a smbus error, and moved memory clearing out to cpufixup. - Removed CONFIG_KEYBOARD as it was useless. See pc87360/superio.c for how to setup a legacy keyboard properly. - Reworked the register values for standard hardware, moving the defintions from chip.h into the headers of the initialization routines. This is much saner and is actually implemented. - Made the hdama port an under clockers BIOS. I debuged so many interesting problems. - On amd8111_lpc added setup of architectural/legacy hardware - Enabled PCI error reporting as much as possible. - Enhanded build_opt_tbl to generate a header of the cmos option locations so that romcc compiled code can query the cmos options. - In romcc gracefully handle function names that degenerate into function pointers - Bumped the version to 1.1.6 as we are getting closer to 2.0 TODO finish optimizing the HT links of non dual boards TODO make all Opteron board work again TODO convert all superio devices to use the new helpers TODO convert the via/epia to freebios2 conventions TODO cpu fixup/setup by cpu type git-svn-id: svn://svn.coreboot.org/coreboot/trunk@1390 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2004-03-11 16:01:31 +01:00
/* Store the computed resource allocations into device registers ... */
printk(BIOS_INFO, "Setting resources...\n");
for (child = root->link_list->children; child; child = child->sibling) {
if (!(child->path.type == DEVICE_PATH_DOMAIN))
continue;
post_log_path(child);
for (res = child->resource_list; res; res = res->next) {
if (res->flags & IORESOURCE_FIXED)
continue;
if (res->flags & IORESOURCE_PREFETCH) {
allocate_resources(child->link_list,
res, MEM_MASK, PREF_TYPE);
continue;
}
if (res->flags & IORESOURCE_MEM) {
allocate_resources(child->link_list,
res, MEM_MASK, MEM_TYPE);
continue;
}
if (res->flags & IORESOURCE_IO) {
allocate_resources(child->link_list,
res, IO_MASK, IO_TYPE);
continue;
}
}
}
assign_resources(root->link_list);
printk(BIOS_INFO, "Done setting resources.\n");
print_resource_tree(root, BIOS_SPEW, "After assigning values.");
printk(BIOS_INFO, "Done allocating resources.\n");
}
/**
* 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)
{
struct bus *link;
printk(BIOS_INFO, "Enabling resources...\n");
/* Now enable everything. */
for (link = dev_root.link_list; link; link = link->next)
enable_resources(link);
printk(BIOS_INFO, "done.\n");
}
/**
* Initialize a specific device.
*
* The parent should be initialized first to avoid having an ordering problem.
* This is done by calling the parent's init() method before its children's
* init() methods.
*
* @param dev The device to be initialized.
*/
static void init_dev(struct device *dev)
{
if (!dev->enabled)
return;
if (!dev->initialized && dev->ops && dev->ops->init) {
#if CONFIG_HAVE_MONOTONIC_TIMER
struct mono_time start_time;
struct rela_time dev_init_time;
timer_monotonic_get(&start_time);
#endif
if (dev->path.type == DEVICE_PATH_I2C) {
printk(BIOS_DEBUG, "smbus: %s[%d]->",
dev_path(dev->bus->dev), dev->bus->link_num);
}
printk(BIOS_DEBUG, "%s init\n", dev_path(dev));
dev->initialized = 1;
dev->ops->init(dev);
#if CONFIG_HAVE_MONOTONIC_TIMER
dev_init_time = current_time_from(&start_time);
printk(BIOS_DEBUG, "%s init %ld usecs\n", dev_path(dev),
rela_time_in_microseconds(&dev_init_time));
#endif
}
}
static void init_link(struct bus *link)
{
struct device *dev;
struct bus *c_link;
for (dev = link->children; dev; dev = dev->sibling) {
Clean up POST codes for Boot State machine Now that there is a clearly defined boot state machine we can add some useful post codes to indicate the current point in the state machine by having it log a post code before the execution of each state. This removes the currently defined POST codes that were used by hardwaremain in favor of a new contiguous range that are defined for each boot state. The reason for this is that the existing codes are mostly used to indicate when something is done, which is confusing for actual debug because POST code debugging relies on knowing what is about to happen (to know what may be at fault) rather than what has just finished. One additonal change is added during device init step as this step often does the bulk of the work, and frequently logs POST codes itself. Therefore in order to keep better track of what device is being initialized POST_BS_DEV_INIT is logged before each device is initialized. interrupted boot with reset button and gathered the eventlog. Mosys has been extended to decode the well-known POST codes: 26 | 2013-06-10 10:32:48 | System boot | 120 27 | 2013-06-10 10:32:48 | Last post code in previous boot | 0x75 | Device Initialize 28 | 2013-06-10 10:32:48 | Extra info from previous boot | PCI | 00:16.0 29 | 2013-06-10 10:32:48 | Reset Button 30 | 2013-06-10 10:32:48 | System Reset Change-Id: Ida1e1129d274d28cbe8e49e4a01483e335a03d96 Signed-off-by: Duncan Laurie <dlaurie@chromium.org> Reviewed-on: https://gerrit.chromium.org/gerrit/58106 Reviewed-on: http://review.coreboot.org/4231 Tested-by: build bot (Jenkins) Reviewed-by: Alexandru Gagniuc <mr.nuke.me@gmail.com>
2013-06-10 19:41:04 +02:00
post_code(POST_BS_DEV_INIT);
post_log_path(dev);
init_dev(dev);
}
for (dev = link->children; dev; dev = dev->sibling) {
for (c_link = dev->link_list; c_link; c_link = c_link->next)
init_link(c_link);
}
}
/**
* Initialize all devices in the global device tree.
*
* Starting at the root device, call the device's init() method to do
* device-specific setup, then call each child's init() method.
*/
void dev_initialize(void)
{
struct bus *link;
printk(BIOS_INFO, "Initializing devices...\n");
Prepare the BIOS data areas before device init. Since we do not run option roms in normal mode nothing was initializing the BDA/EBDA and yet Linux depends very much on it having sane values here. For the most part the kernel tries to work around this not being initialized, but every once in awhile (1/300 boots or so) it would end up reading something that looked sane from BDA but was not and then it would panic. In this change the EBDA is unconditionally setup before devices are initialized. I'm not set on the location in dev_initialize() but there does not seem to be another place to hook it in so that it runs just once for ALL platforms regardless of whether they use option roms or not. (possibly hardwaremain?) The EBDA setup code has been moved into its own location in arch/x86/lib/ebda.c so it can be compiled in even if the option rom code is not. The low memory size is still set to 1MB which is enough to make linux happy without having to hook into each mainboard to get a more appropriate value. The setup_ebda() function takes inputs so it could be changed for a mainboard if needed. OLD/BROKEN would read garbage. Examples from different boots: ebda_addr=0x75e80 lowmem=0x1553400 ebda_addr=0x5e080 lowmem=0x3e51400 ebda_addr=0x7aa80 lowmem=0x2f8a800 NEW/FIXED now reads consistent values: ebda_addr=0xf6000 lowmem=0x100000 Change-Id: I6cb79f0e3e43cc65f7e5fe98b6cad1a557ccd949 Signed-off-by: Duncan Laurie <dlaurie@google.com> Reviewed-on: http://review.coreboot.org/769 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2012-01-17 18:03:11 +01:00
#if CONFIG_ARCH_X86
/* Ensure EBDA is prepared before Option ROMs. */
setup_default_ebda();
#endif
/* First call the mainboard init. */
init_dev(&dev_root);
/* Now initialize everything. */
for (link = dev_root.link_list; link; link = link->next)
init_link(link);
post_log_clear();
printk(BIOS_INFO, "Devices initialized\n");
show_all_devs(BIOS_SPEW, "After init.");
}
/**
* Finalize a specific device.
*
* The parent should be finalized first to avoid having an ordering problem.
* This is done by calling the parent's final() method before its childrens'
* final() methods.
*
* @param dev The device to be initialized.
*/
static void final_dev(struct device *dev)
{
if (!dev->enabled)
return;
if (dev->ops && dev->ops->final) {
printk(BIOS_DEBUG, "%s final\n", dev_path(dev));
dev->ops->final(dev);
}
}
static void final_link(struct bus *link)
{
struct device *dev;
struct bus *c_link;
for (dev = link->children; dev; dev = dev->sibling)
final_dev(dev);
for (dev = link->children; dev; dev = dev->sibling) {
for (c_link = dev->link_list; c_link; c_link = c_link->next)
final_link(c_link);
}
}
/**
* Finalize all devices in the global device tree.
*
* Starting at the root device, call the device's final() method to do
* device-specific cleanup, then call each child's final() method.
*/
void dev_finalize(void)
{
struct bus *link;
printk(BIOS_INFO, "Finalize devices...\n");
/* First call the mainboard finalize. */
final_dev(&dev_root);
/* Now finalize everything. */
for (link = dev_root.link_list; link; link = link->next)
final_link(link);
printk(BIOS_INFO, "Devices finalized\n");
}