coreboot-kgpe-d16/util/sconfig/main.c

775 lines
17 KiB
C

/*
* sconfig, coreboot device tree compiler
*
* Copyright (C) 2010 coresystems GmbH
* written by Patrick Georgi <patrick@georgi-clan.de>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; version 2 of the License.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
#include <ctype.h>
#include "sconfig.h"
#include "sconfig.tab.h"
extern int linenum;
struct device *head, *lastnode;
static struct chip chip_header;
/*
* This is intentionally shared between chip and device structure ids because it
* is easier to track the order of parsing for chip and device.
*/
static int count = 0;
typedef enum {
UNSLASH,
SPLIT_1ST,
TO_LOWER,
TO_UPPER,
} translate_t;
static struct device root;
static struct chip_instance mainboard_instance;
static struct chip mainboard_chip = {
.name = "mainboard",
.name_underscore = "mainboard",
.instance = &mainboard_instance,
};
static struct chip_instance mainboard_instance = {
.id = 0,
.chip = &mainboard_chip,
};
static struct device root = {
.name = "dev_root",
.id = 0,
.chip_instance = &mainboard_instance,
.path = " .type = DEVICE_PATH_ROOT ",
.ops = "&default_dev_ops_root",
.parent = &root,
.enabled = 1
};
static struct queue {
void *data;
struct queue *next;
struct queue *prev;
} *q;
#define S_ALLOC(_s) s_alloc(__func__, _s)
static void *s_alloc(const char *f, size_t s)
{
void *data = calloc(1, s);
if (!data) {
fprintf(stderr, "%s: Failed to alloc mem!\n", f, s);
exit(1);
}
return data;
}
struct queue *new_queue_entry(void *data)
{
struct queue *e = S_ALLOC(sizeof(*e));
e->data = data;
e->next = e->prev = e;
return e;
}
void chip_enqueue_tail(void *data)
{
struct queue *tmp = new_queue_entry(data);
if (!q) {
q = tmp;
return;
}
q->prev->next = tmp;
tmp->prev = q->prev;
q->prev = tmp;
tmp->next = q;
}
void *chip_dequeue_tail(void)
{
struct queue *tmp = q->prev;
void *data;
if (tmp == q)
q = NULL;
else {
tmp->prev->next = q;
q->prev = tmp->prev;
}
data = tmp->data;
free(tmp);
return data;
}
static struct device *new_dev(struct device *parent)
{
struct device *dev = S_ALLOC(sizeof(struct device));
dev->id = ++count;
dev->parent = parent;
dev->subsystem_vendor = -1;
dev->subsystem_device = -1;
head->next = dev;
head = dev;
return dev;
}
static int device_match(struct device *a, struct device *b)
{
if ((a->bustype == b->bustype) && (a->parent == b->parent)
&& (a->path_a == b->path_a) && (a->path_b == b->path_b))
return 1;
return 0;
}
void fold_in(struct device *parent)
{
struct device *child = parent->children;
struct device *latest = 0;
while (child != latest) {
if (child->children) {
if (!latest)
latest = child->children;
parent->latestchild->next_sibling = child->children;
parent->latestchild = child->latestchild;
}
child = child->next_sibling;
}
}
int yywrap(void)
{
return 1;
}
void yyerror(char const *str)
{
extern char *yytext;
fprintf(stderr, "line %d: %s: %s\n", linenum + 1, yytext, str);
exit(1);
}
void postprocess_devtree(void)
{
root.next_sibling = root.children;
/*
* Since root is statically created we need to call fold_in explicitly
* here to have the next_sibling and latestchild setup correctly.
*/
fold_in(&root);
struct device *dev = &root;
while (dev) {
/* skip functions of the same device in sibling chain */
while (dev->sibling && dev->sibling->used)
dev->sibling = dev->sibling->sibling;
/* skip duplicate function elements in next chain */
while (dev->next && dev->next->used)
dev->next = dev->next->next;
dev = dev->next_sibling;
}
}
char *translate_name(const char *str, translate_t mode)
{
char *b, *c;
b = c = strdup(str);
while (c && *c) {
if ((mode == SPLIT_1ST) && (*c == '/')) {
*c = 0;
break;
}
if (*c == '/')
*c = '_';
if (*c == '-')
*c = '_';
if (mode == TO_UPPER)
*c = toupper(*c);
if (mode == TO_LOWER)
*c = tolower(*c);
c++;
}
return b;
}
static struct chip *get_chip(char *path)
{
struct chip *h = &chip_header;
while (h->next) {
int result = strcmp(path, h->next->name);
if (result == 0)
return h->next;
if (result < 0)
break;
h = h->next;
}
struct chip *new_chip = S_ALLOC(sizeof(struct chip));
new_chip->next = h->next;
h->next = new_chip;
new_chip->chiph_exists = 1;
new_chip->name = path;
new_chip->name_underscore = translate_name(path, UNSLASH);
struct stat st;
char *chip_h = S_ALLOC(strlen(path) + 18);
sprintf(chip_h, "src/%s", path);
if ((stat(chip_h, &st) == -1) && (errno == ENOENT)) {
/* root_complex gets away without a separate directory, but
* exists on on pretty much all AMD chipsets.
*/
if (!strstr(path, "/root_complex")) {
fprintf(stderr, "ERROR: Chip component %s does not exist.\n",
path);
exit(1);
}
}
sprintf(chip_h, "src/%s/chip.h", path);
if ((stat(chip_h, &st) == -1) && (errno == ENOENT))
new_chip->chiph_exists = 0;
free(chip_h);
return new_chip;
}
struct chip_instance *new_chip_instance(char *path)
{
struct chip *chip = get_chip(path);
struct chip_instance *instance = S_ALLOC(sizeof(*instance));
instance->id = ++count;
instance->chip = chip;
instance->next = chip->instance;
chip->instance = instance;
return instance;
}
struct device *new_device(struct device *parent,
struct chip_instance *chip_instance,
const int bustype, const char *devnum,
int enabled)
{
struct device *new_d = new_dev(parent);
new_d->bustype = bustype;
char *tmp;
new_d->path_a = strtol(devnum, &tmp, 16);
if (*tmp == '.') {
tmp++;
new_d->path_b = strtol(tmp, NULL, 16);
}
char *name = S_ALLOC(10);
sprintf(name, "_dev%d", new_d->id);
new_d->name = name;
new_d->enabled = enabled;
new_d->chip_instance = chip_instance;
if (parent->latestchild) {
parent->latestchild->next_sibling = new_d;
parent->latestchild->sibling = new_d;
}
parent->latestchild = new_d;
if (!parent->children)
parent->children = new_d;
lastnode->next = new_d;
lastnode = new_d;
switch (bustype) {
case PCI:
new_d->path = ".type=DEVICE_PATH_PCI,{.pci={ .devfn = PCI_DEVFN(0x%x,%d)}}";
break;
case PNP:
new_d->path = ".type=DEVICE_PATH_PNP,{.pnp={ .port = 0x%x, .device = 0x%x }}";
break;
case I2C:
new_d->path = ".type=DEVICE_PATH_I2C,{.i2c={ .device = 0x%x, .mode_10bit = %d }}";
break;
case APIC:
new_d->path = ".type=DEVICE_PATH_APIC,{.apic={ .apic_id = 0x%x }}";
break;
case CPU_CLUSTER:
new_d->path = ".type=DEVICE_PATH_CPU_CLUSTER,{.cpu_cluster={ .cluster = 0x%x }}";
break;
case CPU:
new_d->path = ".type=DEVICE_PATH_CPU,{.cpu={ .id = 0x%x }}";
break;
case DOMAIN:
new_d->path = ".type=DEVICE_PATH_DOMAIN,{.domain={ .domain = 0x%x }}";
break;
case IOAPIC:
new_d->path = ".type=DEVICE_PATH_IOAPIC,{.ioapic={ .ioapic_id = 0x%x }}";
break;
case GENERIC:
new_d->path = ".type=DEVICE_PATH_GENERIC,{.generic={ .id = 0x%x, .subid = 0x%x }}";
break;
case SPI:
new_d->path = ".type=DEVICE_PATH_SPI,{.spi={ .cs = 0x%x }}";
break;
case USB:
new_d->path = ".type=DEVICE_PATH_USB,{.usb={ .port_type = %d, .port_id = %d }}";
break;
case MMIO:
new_d->path = ".type=DEVICE_PATH_MMIO,{.mmio={ .addr = 0x%x }}";
break;
}
return new_d;
}
void alias_siblings(struct device *d)
{
while (d) {
int link = 0;
struct device *cmp = d->next_sibling;
while (cmp && (cmp->parent == d->parent) && (cmp->path_a == d->path_a)
&& (cmp->path_b == d->path_b)) {
if (!cmp->used) {
if (device_match(d, cmp)) {
d->multidev = 1;
cmp->id = d->id;
cmp->name = d->name;
cmp->used = 1;
cmp->link = ++link;
}
}
cmp = cmp->next_sibling;
}
d = d->next_sibling;
}
}
void add_resource(struct device *dev, int type, int index, int base)
{
struct resource *r = S_ALLOC(sizeof(struct resource));
r->type = type;
r->index = index;
r->base = base;
if (dev->res) {
struct resource *head = dev->res;
while (head->next)
head = head->next;
head->next = r;
} else {
dev->res = r;
}
dev->rescnt++;
}
void add_register(struct chip_instance *chip_instance, char *name, char *val)
{
struct reg *r = S_ALLOC(sizeof(struct reg));
r->key = name;
r->value = val;
if (chip_instance->reg) {
struct reg *head = chip_instance->reg;
// sorting to be equal to sconfig's behaviour
int sort = strcmp(r->key, head->key);
if (sort == 0) {
printf("ERROR: duplicate 'register' key.\n");
exit(1);
}
if (sort < 0) {
r->next = head;
chip_instance->reg = r;
} else {
while ((head->next)
&& (strcmp(head->next->key, r->key) < 0))
head = head->next;
r->next = head->next;
head->next = r;
}
} else {
chip_instance->reg = r;
}
}
void add_pci_subsystem_ids(struct device *dev, int vendor, int device,
int inherit)
{
if (dev->bustype != PCI && dev->bustype != DOMAIN) {
printf("ERROR: 'subsystem' only allowed for PCI devices\n");
exit(1);
}
dev->subsystem_vendor = vendor;
dev->subsystem_device = device;
dev->inherit_subsystem = inherit;
}
void add_ioapic_info(struct device *dev, int apicid, const char *_srcpin,
int irqpin)
{
int srcpin;
if (!_srcpin || strlen(_srcpin) < 4 || strncasecmp(_srcpin, "INT", 3) ||
_srcpin[3] < 'A' || _srcpin[3] > 'D') {
printf("ERROR: malformed ioapic_irq args: %s\n", _srcpin);
exit(1);
}
srcpin = _srcpin[3] - 'A';
if (dev->bustype != PCI && dev->bustype != DOMAIN) {
printf("ERROR: ioapic config only allowed for PCI devices\n");
exit(1);
}
if (srcpin > 3) {
printf("ERROR: srcpin '%d' invalid\n", srcpin);
exit(1);
}
dev->pci_irq_info[srcpin].ioapic_irq_pin = irqpin;
dev->pci_irq_info[srcpin].ioapic_dst_id = apicid;
}
static void pass0(FILE *fil, struct device *ptr)
{
if (ptr->id == 0)
fprintf(fil, "DEVTREE_CONST struct bus %s_links[];\n",
ptr->name);
if ((ptr->id != 0) && (!ptr->used)) {
fprintf(fil, "DEVTREE_CONST static struct device %s;\n",
ptr->name);
if (ptr->rescnt > 0)
fprintf(fil,
"DEVTREE_CONST struct resource %s_res[];\n",
ptr->name);
if (ptr->children || ptr->multidev)
fprintf(fil, "DEVTREE_CONST struct bus %s_links[];\n",
ptr->name);
}
}
static void pass1(FILE *fil, struct device *ptr)
{
int pin;
struct chip_instance *chip_ins = ptr->chip_instance;
if (!ptr->used) {
if (ptr->id != 0)
fprintf(fil, "static ");
fprintf(fil, "DEVTREE_CONST struct device %s = {\n",
ptr->name);
fprintf(fil, "#if !DEVTREE_EARLY\n");
fprintf(fil, "\t.ops = %s,\n", (ptr->ops) ? (ptr->ops) : "0");
fprintf(fil, "#endif\n");
fprintf(fil, "\t.bus = &%s_links[%d],\n", ptr->parent->name,
ptr->parent->link);
fprintf(fil, "\t.path = {");
fprintf(fil, ptr->path, ptr->path_a, ptr->path_b);
fprintf(fil, "},\n");
fprintf(fil, "\t.enabled = %d,\n", ptr->enabled);
fprintf(fil, "\t.on_mainboard = 1,\n");
if (ptr->subsystem_vendor > 0)
fprintf(fil, "\t.subsystem_vendor = 0x%04x,\n",
ptr->subsystem_vendor);
for (pin = 0; pin < 4; pin++) {
if (ptr->pci_irq_info[pin].ioapic_irq_pin > 0)
fprintf(fil, "\t.pci_irq_info[%d].ioapic_irq_pin = %d,\n",
pin, ptr->pci_irq_info[pin].ioapic_irq_pin);
if (ptr->pci_irq_info[pin].ioapic_dst_id > 0)
fprintf(fil, "\t.pci_irq_info[%d].ioapic_dst_id = %d,\n",
pin, ptr->pci_irq_info[pin].ioapic_dst_id);
}
if (ptr->subsystem_device > 0)
fprintf(fil, "\t.subsystem_device = 0x%04x,\n",
ptr->subsystem_device);
if (ptr->rescnt > 0) {
fprintf(fil, "\t.resource_list = &%s_res[0],\n",
ptr->name);
}
if (ptr->children || ptr->multidev)
fprintf(fil, "\t.link_list = &%s_links[0],\n",
ptr->name);
else
fprintf(fil, "\t.link_list = NULL,\n");
if (ptr->sibling)
fprintf(fil, "\t.sibling = &%s,\n", ptr->sibling->name);
fprintf(fil, "#if !DEVTREE_EARLY\n");
fprintf(fil, "\t.chip_ops = &%s_ops,\n",
chip_ins->chip->name_underscore);
if (chip_ins == &mainboard_instance)
fprintf(fil, "\t.name = mainboard_name,\n");
fprintf(fil, "#endif\n");
if (chip_ins->chip->chiph_exists)
fprintf(fil, "\t.chip_info = &%s_info_%d,\n",
chip_ins->chip->name_underscore, chip_ins->id);
if (ptr->next)
fprintf(fil, "\t.next=&%s\n", ptr->next->name);
fprintf(fil, "};\n");
}
if (ptr->rescnt > 0) {
int i = 1;
fprintf(fil, "DEVTREE_CONST struct resource %s_res[] = {\n",
ptr->name);
struct resource *r = ptr->res;
while (r) {
fprintf(fil,
"\t\t{ .flags=IORESOURCE_FIXED | IORESOURCE_ASSIGNED | IORESOURCE_");
if (r->type == IRQ)
fprintf(fil, "IRQ");
if (r->type == DRQ)
fprintf(fil, "DRQ");
if (r->type == IO)
fprintf(fil, "IO");
fprintf(fil, ", .index=0x%x, .base=0x%x,", r->index,
r->base);
if (r->next)
fprintf(fil, ".next=&%s_res[%d]},\n", ptr->name,
i++);
else
fprintf(fil, ".next=NULL },\n");
r = r->next;
}
fprintf(fil, "\t };\n");
}
if (!ptr->used && (ptr->children || ptr->multidev)) {
fprintf(fil, "DEVTREE_CONST struct bus %s_links[] = {\n",
ptr->name);
if (ptr->multidev) {
struct device *d = ptr;
while (d) {
if (device_match(d, ptr)) {
fprintf(fil, "\t\t[%d] = {\n", d->link);
fprintf(fil, "\t\t\t.link_num = %d,\n",
d->link);
fprintf(fil, "\t\t\t.dev = &%s,\n",
d->name);
if (d->children)
fprintf(fil,
"\t\t\t.children = &%s,\n",
d->children->name);
if (d->next_sibling
&& device_match(d->next_sibling,
ptr))
fprintf(fil,
"\t\t\t.next=&%s_links[%d],\n",
d->name, d->link + 1);
else
fprintf(fil,
"\t\t\t.next = NULL,\n");
fprintf(fil, "\t\t},\n");
}
d = d->next_sibling;
}
} else {
if (ptr->children) {
fprintf(fil, "\t\t[0] = {\n");
fprintf(fil, "\t\t\t.link_num = 0,\n");
fprintf(fil, "\t\t\t.dev = &%s,\n", ptr->name);
fprintf(fil, "\t\t\t.children = &%s,\n",
ptr->children->name);
fprintf(fil, "\t\t\t.next = NULL,\n");
fprintf(fil, "\t\t},\n");
}
}
fprintf(fil, "\t};\n");
}
}
static void walk_device_tree(FILE *fil, struct device *ptr,
void (*func)(FILE *, struct device *),
struct device *chips)
{
do {
func(fil, ptr);
ptr = ptr->next_sibling;
} while (ptr);
}
static void emit_chip_headers(FILE *fil, struct chip *chip)
{
struct chip *tmp = chip;
fprintf(fil, "#include <device/device.h>\n");
fprintf(fil, "#include <device/pci.h>\n");
while (chip) {
if (chip->chiph_exists)
fprintf(fil, "#include \"%s/chip.h\"\n", chip->name);
chip = chip->next;
}
fprintf(fil, "\n#if !DEVTREE_EARLY\n");
fprintf(fil,
"__attribute__((weak)) struct chip_operations mainboard_ops = {};\n");
chip = tmp;
while (chip) {
fprintf(fil,
"__attribute__((weak)) struct chip_operations %s_ops = {};\n",
chip->name_underscore);
chip = chip->next;
}
fprintf(fil, "#endif\n");
}
static void emit_chip_instance(FILE *fil, struct chip_instance *instance)
{
fprintf(fil, "DEVTREE_CONST struct %s_config %s_info_%d = {",
instance->chip->name_underscore,
instance->chip->name_underscore,
instance->id);
if (instance->reg) {
fprintf(fil, "\n");
struct reg *r = instance->reg;
while (r) {
fprintf(fil, "\t.%s = %s,\n", r->key, r->value);
r = r->next;
}
}
fprintf(fil, "};\n\n");
}
static void emit_chips(FILE *fil)
{
struct chip *chip = chip_header.next;
struct chip_instance *instance;
emit_chip_headers(fil, chip);
for (; chip; chip = chip->next) {
if (!chip->chiph_exists)
continue;
instance = chip->instance;
while (instance) {
emit_chip_instance(fil, instance);
instance = instance->next;
}
}
}
static void inherit_subsystem_ids(FILE *file, struct device *dev)
{
struct device *p;
if (dev->subsystem_vendor != -1 && dev->subsystem_device != -1) {
/* user already gave us a subsystem vendor/device */
return;
}
for (p = dev; p && p != p->parent; p = p->parent) {
if (p->bustype != PCI && p->bustype != DOMAIN)
continue;
if (p->inherit_subsystem) {
dev->subsystem_vendor = p->subsystem_vendor;
dev->subsystem_device = p->subsystem_device;
break;
}
}
}
static void usage(void)
{
printf("usage: sconfig devicetree_file output_file\n");
exit(1);
}
enum {
DEVICEFILE_ARG = 1,
OUTPUTFILE_ARG
};
#define ARG_COUNT 3
int main(int argc, char **argv)
{
if (argc != ARG_COUNT)
usage();
char *devtree = argv[DEVICEFILE_ARG];
char *outputc = argv[OUTPUTFILE_ARG];
FILE *filec = fopen(devtree, "r");
if (!filec) {
perror(NULL);
exit(1);
}
yyrestart(filec);
lastnode = head = &root;
yyparse();
fclose(filec);
FILE *autogen = fopen(outputc, "w");
if (!autogen) {
fprintf(stderr, "Could not open file '%s' for writing: ",
outputc);
perror(NULL);
exit(1);
}
emit_chips(autogen);
walk_device_tree(autogen, &root, inherit_subsystem_ids, NULL);
fprintf(autogen, "\n/* pass 0 */\n");
walk_device_tree(autogen, &root, pass0, NULL);
fprintf(autogen, "\n/* pass 1 */\n"
"DEVTREE_CONST struct device * DEVTREE_CONST last_dev = &%s;\n",
lastnode->name);
walk_device_tree(autogen, &root, pass1, NULL);
fclose(autogen);
return 0;
}