Moved from freebios

git-svn-id: svn://svn.coreboot.org/coreboot/trunk@862 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
This commit is contained in:
Greg Watson 2003-06-09 21:29:23 +00:00
parent fd958cea68
commit 0322115932
31 changed files with 3939 additions and 0 deletions

83
src/arch/ppc/boot/boot.c Normal file
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#include <ip_checksum.h>
#include <boot/elf.h>
#include <boot/elf_boot.h>
#include <string.h>
#include <printk.h>
#ifndef CMD_LINE
#define CMD_LINE ""
#endif
#define UPSZ(X) ((sizeof(X) + 3) &~3)
static struct {
Elf_Bhdr hdr;
Elf_Nhdr ft_hdr;
unsigned char ft_desc[UPSZ(FIRMWARE_TYPE)];
Elf_Nhdr bl_hdr;
unsigned char bl_desc[UPSZ(BOOTLOADER)];
Elf_Nhdr blv_hdr;
unsigned char blv_desc[UPSZ(BOOTLOADER_VERSION)];
Elf_Nhdr cmd_hdr;
unsigned char cmd_desc[UPSZ(CMD_LINE)];
} elf_boot_notes = {
.hdr = {
.b_signature = 0x0E1FB007,
.b_size = sizeof(elf_boot_notes),
.b_checksum = 0,
.b_records = 4,
},
.ft_hdr = {
.n_namesz = 0,
.n_descsz = sizeof(FIRMWARE_TYPE),
.n_type = EBN_FIRMWARE_TYPE,
},
.ft_desc = FIRMWARE_TYPE,
.bl_hdr = {
.n_namesz = 0,
.n_descsz = sizeof(BOOTLOADER),
.n_type = EBN_BOOTLOADER_NAME,
},
.bl_desc = BOOTLOADER,
.blv_hdr = {
.n_namesz = 0,
.n_descsz = sizeof(BOOTLOADER_VERSION),
.n_type = EBN_BOOTLOADER_VERSION,
},
.blv_desc = BOOTLOADER_VERSION,
.cmd_hdr = {
.n_namesz = 0,
.n_descsz = sizeof(CMD_LINE),
.n_type = EBN_COMMAND_LINE,
},
.cmd_desc = CMD_LINE,
};
int elf_check_arch(Elf_ehdr *ehdr)
{
return (
(ehdr->e_machine == EM_PPC) &&
(ehdr->e_ident[EI_CLASS] == ELFCLASS32) &&
(ehdr->e_ident[EI_DATA] == ELFDATA2MSB)
);
}
void jmp_to_elf_entry(void *entry, unsigned long buffer)
{
void (*kernel_entry)(void);
kernel_entry = entry;
/* On ppc we don't currently support loading over LinuxBIOS.
* So ignore the buffer.
*/
/* Jump to kernel */
kernel_entry();
}

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#include <mem.h>
#include <ip_checksum.h>
#include <boot/linuxbios_tables.h>
#include <boot/linuxbios_table.h>
#include <printk.h>
#include <string.h>
#include <version.h>
struct lb_header *lb_table_init(unsigned long addr)
{
struct lb_header *header;
/* 16 byte align the address */
addr += 15;
addr &= ~15;
header = (void *)addr;
header->signature[0] = 'L';
header->signature[1] = 'B';
header->signature[2] = 'I';
header->signature[3] = 'O';
header->header_bytes = sizeof(*header);
header->header_checksum = 0;
header->table_bytes = 0;
header->table_checksum = 0;
header->table_entries = 0;
return header;
}
struct lb_record *lb_first_record(struct lb_header *header)
{
struct lb_record *rec;
rec = (void *)(((char *)header) + sizeof(*header));
return rec;
}
struct lb_record *lb_last_record(struct lb_header *header)
{
struct lb_record *rec;
rec = (void *)(((char *)header) + sizeof(*header) + header->table_bytes);
return rec;
}
struct lb_record *lb_next_record(struct lb_record *rec)
{
rec = (void *)(((char *)rec) + rec->size);
return rec;
}
struct lb_record *lb_new_record(struct lb_header *header)
{
struct lb_record *rec;
rec = lb_last_record(header);
if (header->table_entries) {
header->table_bytes += rec->size;
}
rec = lb_last_record(header);
header->table_entries++;
rec->tag = LB_TAG_UNUSED;
rec->size = sizeof(*rec);
return rec;
}
struct lb_memory *lb_memory(struct lb_header *header)
{
struct lb_record *rec;
struct lb_memory *mem;
rec = lb_new_record(header);
mem = (struct lb_memory *)rec;
mem->tag = LB_TAG_MEMORY;
mem->size = sizeof(*mem);
return mem;
}
struct lb_mainboard *lb_mainboard(struct lb_header *header)
{
struct lb_record *rec;
struct lb_mainboard *mainboard;
rec = lb_new_record(header);
mainboard = (struct lb_mainboard *)rec;
mainboard->tag = LB_TAG_MAINBOARD;
mainboard->size = (sizeof(*mainboard) +
strlen(mainboard_vendor) + 1 +
strlen(mainboard_part_number) + 1 +
3) & ~3;
mainboard->vendor_idx = 0;
mainboard->part_number_idx = strlen(mainboard_vendor) + 1;
memcpy(mainboard->strings + mainboard->vendor_idx,
mainboard_vendor, strlen(mainboard_vendor) + 1);
memcpy(mainboard->strings + mainboard->part_number_idx,
mainboard_part_number, strlen(mainboard_part_number) + 1);
return mainboard;
}
void lb_strings(struct lb_header *header)
{
static const struct {
uint32_t tag;
const uint8_t *string;
} strings[] = {
{ LB_TAG_VERSION, linuxbios_version, },
{ LB_TAG_EXTRA_VERSION, linuxbios_extra_version, },
{ LB_TAG_BUILD, linuxbios_build, },
{ LB_TAG_COMPILE_TIME, linuxbios_compile_time, },
{ LB_TAG_COMPILE_BY, linuxbios_compile_by, },
{ LB_TAG_COMPILE_HOST, linuxbios_compile_host, },
{ LB_TAG_COMPILE_DOMAIN, linuxbios_compile_domain, },
{ LB_TAG_COMPILER, linuxbios_compiler, },
{ LB_TAG_LINKER, linuxbios_linker, },
{ LB_TAG_ASSEMBLER, linuxbios_assembler, },
};
int i;
for(i = 0; i < sizeof(strings)/sizeof(strings[0]); i++) {
struct lb_record *rec;
struct lb_string *str;
size_t len;
rec = lb_new_record(header);
str = (struct lb_string *)rec;
len = strlen(strings[i].string);
str->tag = strings[i].tag;
str->size = (sizeof(*rec) + len + 1 + 3) & ~3;
memcpy(str->string, strings[i].string, len+1);
}
}
/* Some version of gcc have problems with 64 bit types so
* take an unsigned long instead of a uint64_t for now.
*/
void lb_memory_range(struct lb_memory *mem,
uint32_t type, unsigned long start, unsigned long size)
{
int entries;
entries = (mem->size - sizeof(*mem))/sizeof(mem->map[0]);
mem->map[entries].start = start;
mem->map[entries].size = size;
mem->map[entries].type = type;
mem->size += sizeof(mem->map[0]);
}
static void lb_memory_rangek(struct lb_memory *mem,
uint32_t type, unsigned long startk, unsigned long endk)
{
int entries;
entries = (mem->size - sizeof(*mem))/sizeof(mem->map[0]);
mem->map[entries].start = startk;
mem->map[entries].start <<= 10;
mem->map[entries].size = endk - startk;
mem->map[entries].size <<= 10;
mem->map[entries].type = type;
mem->size += sizeof(mem->map[0]);
}
static void lb_reserve_table_memory(struct lb_header *head)
{
struct lb_record *last_rec;
struct lb_memory *mem;
uint64_t start;
uint64_t end;
int i, entries;
last_rec = lb_last_record(head);
mem = get_lb_mem();
start = (unsigned long)head;
end = (unsigned long)last_rec;
entries = (mem->size - sizeof(*mem))/sizeof(mem->map[0]);
/* Resize the right two memory areas so this table is in
* a reserved area of memory. Everything has been carefully
* setup so that is all we need to do.
*/
for(i = 0; i < entries; i++ ) {
uint64_t map_start = mem->map[i].start;
uint64_t map_end = map_start + mem->map[i].size;
/* Does this area need to be expanded? */
if (map_end == start) {
mem->map[i].size = end - map_start;
}
/* Does this area need to be contracted? */
else if (map_start == start) {
mem->map[i].start = end;
mem->map[i].size = map_end - end;
}
}
}
unsigned long lb_table_fini(struct lb_header *head)
{
struct lb_record *rec, *first_rec;
rec = lb_last_record(head);
if (head->table_entries) {
head->table_bytes += rec->size;
}
lb_reserve_table_memory(head);
first_rec = lb_first_record(head);
head->table_checksum = compute_ip_checksum(first_rec, head->table_bytes);
head->header_checksum = 0;
head->header_checksum = compute_ip_checksum(head, sizeof(*head));
printk_debug("Wrote linuxbios table at: %p - %p checksum %lx\n",
head, rec, head->table_checksum);
return (unsigned long)rec;
}
/* Routines to extract part so the linuxBIOS table or
* information from the linuxBIOS table after we have written it.
* Currently get_lb_mem relies on a global we can change the
* implementaiton.
*/
static struct lb_memory *mem_ranges = 0;
struct lb_memory *get_lb_mem(void)
{
return mem_ranges;
}
unsigned long write_linuxbios_table(
unsigned long *processor_map,
struct mem_range *ram,
unsigned long low_table_start, unsigned long low_table_end,
unsigned long rom_table_startk, unsigned long rom_table_endk)
{
unsigned long table_size;
struct mem_range *ramp;
struct lb_header *head;
struct lb_memory *mem;
#if HAVE_OPTION_TABLE == 1
struct lb_record *rec_dest, *rec_src;
#endif
head = lb_table_init(low_table_end);
low_table_end = (unsigned long)head;
#if HAVE_OPTION_TABLE == 1
/* Write the option config table... */
rec_dest = lb_new_record(head);
rec_src = (struct lb_record *)&option_table;
memcpy(rec_dest, rec_src, rec_src->size);
#endif
mem = lb_memory(head);
mem_ranges = mem;
/* I assume there is always ram at address 0 */
/* Reserve our tables in low memory */
table_size = (low_table_end - low_table_start);
lb_memory_range(mem, LB_MEM_TABLE, 0, table_size);
lb_memory_range(mem, LB_MEM_RAM, table_size, (ram[0].sizek << 10) - table_size);
/* Reserving pci memory mapped space will keep the kernel from booting seeing
* any pci resources.
*/
for(ramp = &ram[1]; ramp->sizek; ramp++) {
unsigned long startk, endk;
startk = ramp->basek;
endk = startk + ramp->sizek;
if ((startk < rom_table_startk) && (endk > rom_table_startk)) {
lb_memory_rangek(mem, LB_MEM_RAM, startk, rom_table_startk);
startk = rom_table_startk;
}
if ((startk == rom_table_startk) && (endk > startk)) {
unsigned long tend;
tend = rom_table_endk;
if (tend > endk) {
tend = endk;
}
lb_memory_rangek(mem, LB_MEM_TABLE, rom_table_startk, tend);
startk = tend;
}
if (endk > startk) {
lb_memory_rangek(mem, LB_MEM_RAM, startk, endk);
}
}
/* Record our motheboard */
lb_mainboard(head);
/* Record our various random string information */
lb_strings(head);
low_table_end = lb_table_fini(head);
/* Remember where my valid memory ranges are */
return low_table_end;
}

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#ifndef ASM_I386_BOOT_H
#define ASM_I386_BOOT_H
#define ELF_CLASS ELFCLASS32
#define ELF_DATA ELFDATA2MSB
#define ELF_ARCH EM_PPC
#endif /* ASM_I386_BOOT_H */

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/*
* BK Id: SCCS/s.io.h 1.14 10/16/01 15:58:42 trini
*/
#ifndef _PPC_IO_H
#define _PPC_IO_H
#include <types.h>
#define SIO_CONFIG_RA 0x398
#define SIO_CONFIG_RD 0x399
#define SLOW_DOWN_IO
#define PMAC_ISA_MEM_BASE 0
#define PMAC_PCI_DRAM_OFFSET 0
#define CHRP_ISA_IO_BASE 0xf8000000
#define CHRP_ISA_MEM_BASE 0xf7000000
#define CHRP_PCI_DRAM_OFFSET 0
#define PREP_ISA_IO_BASE 0x80000000
#define PREP_ISA_MEM_BASE 0xc0000000
#define PREP_PCI_DRAM_OFFSET 0x80000000
#define _IO_BASE 0xfe000000
#define readb(addr) in_8((volatile u8 *)(addr))
#define writeb(b,addr) out_8((volatile u8 *)(addr), (b))
#define readw(addr) in_le16((volatile u16 *)(addr))
#define readl(addr) in_le32((volatile u32 *)(addr))
#define writew(b,addr) out_le16((volatile u16 *)(addr),(b))
#define writel(b,addr) out_le32((volatile u32 *)(addr),(b))
#define __raw_readb(addr) (*(volatile unsigned char *)(addr))
#define __raw_readw(addr) (*(volatile unsigned short *)(addr))
#define __raw_readl(addr) (*(volatile unsigned int *)(addr))
#define __raw_writeb(v, addr) (*(volatile unsigned char *)(addr) = (v))
#define __raw_writew(v, addr) (*(volatile unsigned short *)(addr) = (v))
#define __raw_writel(v, addr) (*(volatile unsigned int *)(addr) = (v))
/*
* The insw/outsw/insl/outsl macros don't do byte-swapping.
* They are only used in practice for transferring buffers which
* are arrays of bytes, and byte-swapping is not appropriate in
* that case. - paulus
*/
#define insb(port, buf, ns) _insb((u8 *)((port)+_IO_BASE), (buf), (ns))
#define outsb(port, buf, ns) _outsb((u8 *)((port)+_IO_BASE), (buf), (ns))
#define insw(port, buf, ns) _insw_ns((u16 *)((port)+_IO_BASE), (buf), (ns))
#define outsw(port, buf, ns) _outsw_ns((u16 *)((port)+_IO_BASE), (buf), (ns))
#define insl(port, buf, nl) _insl_ns((u32 *)((port)+_IO_BASE), (buf), (nl))
#define outsl(port, buf, nl) _outsl_ns((u32 *)((port)+_IO_BASE), (buf), (nl))
#define inb(port) in_8((u8 *)((port)+_IO_BASE))
#define outb(val, port) out_8((u8 *)((port)+_IO_BASE), (val))
#define inw(port) in_le16((u16 *)((port)+_IO_BASE))
#define outw(val, port) out_le16((u16 *)((port)+_IO_BASE), (val))
#define inl(port) in_le32((u32 *)((port)+_IO_BASE))
#define outl(val, port) out_le32((u32 *)((port)+_IO_BASE), (val))
#define inb_p(port) inb((port))
#define outb_p(val, port) outb((val), (port))
#define inw_p(port) inw((port))
#define outw_p(val, port) outw((val), (port))
#define inl_p(port) inl((port))
#define outl_p(val, port) outl((val), (port))
extern void _insb(volatile u8 *port, void *buf, int ns);
extern void _outsb(volatile u8 *port, const void *buf, int ns);
extern void _insw(volatile u16 *port, void *buf, int ns);
extern void _outsw(volatile u16 *port, const void *buf, int ns);
extern void _insl(volatile u32 *port, void *buf, int nl);
extern void _outsl(volatile u32 *port, const void *buf, int nl);
extern void _insw_ns(volatile u16 *port, void *buf, int ns);
extern void _outsw_ns(volatile u16 *port, const void *buf, int ns);
extern void _insl_ns(volatile u32 *port, void *buf, int nl);
extern void _outsl_ns(volatile u32 *port, const void *buf, int nl);
/*
* The *_ns versions below don't do byte-swapping.
* Neither do the standard versions now, these are just here
* for older code.
*/
#define insw_ns(port, buf, ns) _insw_ns((u16 *)((port)+_IO_BASE), (buf), (ns))
#define outsw_ns(port, buf, ns) _outsw_ns((u16 *)((port)+_IO_BASE), (buf), (ns))
#define insl_ns(port, buf, nl) _insl_ns((u32 *)((port)+_IO_BASE), (buf), (nl))
#define outsl_ns(port, buf, nl) _outsl_ns((u32 *)((port)+_IO_BASE), (buf), (nl))
#define IO_SPACE_LIMIT ~0
#define memset_io(a,b,c) memset((void *)(a),(b),(c))
#define memcpy_fromio(a,b,c) memcpy((a),(void *)(b),(c))
#define memcpy_toio(a,b,c) memcpy((void *)(a),(b),(c))
/*
* Enforce In-order Execution of I/O:
* Acts as a barrier to ensure all previous I/O accesses have
* completed before any further ones are issued.
*/
extern inline void eieio(void)
{
__asm__ __volatile__ ("eieio" : : : "memory");
}
/* Enforce in-order execution of data I/O.
* No distinction between read/write on PPC; use eieio for all three.
*/
#define iobarrier_rw() eieio()
#define iobarrier_r() eieio()
#define iobarrier_w() eieio()
/*
* 8, 16 and 32 bit, big and little endian I/O operations, with barrier.
*/
extern inline int in_8(volatile unsigned char *addr)
{
int ret;
__asm__ __volatile__("lbz%U1%X1 %0,%1; eieio" : "=r" (ret) : "m" (*addr));
return ret;
}
extern inline void out_8(volatile unsigned char *addr, int val)
{
__asm__ __volatile__("stb%U0%X0 %1,%0; eieio" : "=m" (*addr) : "r" (val));
}
extern inline int in_le16(volatile unsigned short *addr)
{
int ret;
__asm__ __volatile__("lhbrx %0,0,%1; eieio" : "=r" (ret) :
"r" (addr), "m" (*addr));
return ret;
}
extern inline int in_be16(volatile unsigned short *addr)
{
int ret;
__asm__ __volatile__("lhz%U1%X1 %0,%1; eieio" : "=r" (ret) : "m" (*addr));
return ret;
}
extern inline void out_le16(volatile unsigned short *addr, int val)
{
__asm__ __volatile__("sthbrx %1,0,%2; eieio" : "=m" (*addr) :
"r" (val), "r" (addr));
}
extern inline void out_be16(volatile unsigned short *addr, int val)
{
__asm__ __volatile__("sth%U0%X0 %1,%0; eieio" : "=m" (*addr) : "r" (val));
}
extern inline unsigned in_le32(volatile unsigned *addr)
{
unsigned ret;
__asm__ __volatile__("lwbrx %0,0,%1; eieio" : "=r" (ret) :
"r" (addr), "m" (*addr));
return ret;
}
extern inline unsigned in_be32(volatile unsigned *addr)
{
unsigned ret;
__asm__ __volatile__("lwz%U1%X1 %0,%1; eieio" : "=r" (ret) : "m" (*addr));
return ret;
}
extern inline void out_le32(volatile unsigned *addr, int val)
{
__asm__ __volatile__("stwbrx %1,0,%2; eieio" : "=m" (*addr) :
"r" (val), "r" (addr));
}
extern inline void out_be32(volatile unsigned *addr, int val)
{
__asm__ __volatile__("stw%U0%X0 %1,%0; eieio" : "=m" (*addr) : "r" (val));
}
extern inline void _insw_ns(volatile u16 *port, void *buf, int ns)
{
u16 * b = (u16 *)buf;
while (ns > 0) {
*b++ = readw(port);
ns--;
}
}
#endif

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#ifndef ARCH_PIRQ_ROUTING_H
#define ARCH_PIRQ_ROUTING_H
#include <types.h>
#define PIRQ_SIGNATURE (('$' << 0) + ('P' << 8) + ('I' << 16) + ('R' << 24))
#define PIRQ_VERSION 0x0100
struct irq_info {
u8 bus, devfn; /* Bus, device and function */
struct {
u8 link; /* IRQ line ID, chipset dependent, 0=not routed */
u16 bitmap; /* Available IRQs */
} __attribute__((packed)) irq[4];
u8 slot; /* Slot number, 0=onboard */
u8 rfu;
} __attribute__((packed));
#if defined(IRQ_SLOT_COUNT)
#define IRQ_SLOTS_COUNT IRQ_SLOT_COUNT
#elif (__GNUC__ < 3)
#define IRQ_SLOTS_COUNT 1
#else
#define IRQ_SLOTS_COUNT
#endif
struct irq_routing_table {
u32 signature; /* PIRQ_SIGNATURE should be here */
u16 version; /* PIRQ_VERSION */
u16 size; /* Table size in bytes */
u8 rtr_bus, rtr_devfn; /* Where the interrupt router lies */
u16 exclusive_irqs; /* IRQs devoted exclusively to PCI usage */
u16 rtr_vendor, rtr_device; /* Vendor and device ID of interrupt router */
u32 miniport_data; /* Crap */
u8 rfu[11];
u8 checksum; /* Modulo 256 checksum must give zero */
struct irq_info slots[IRQ_SLOTS_COUNT];
} __attribute__((packed));
extern const struct irq_routing_table intel_irq_routing_table;
#if defined(DEBUG) && defined(HAVE_PIRQ_TABLE)
void check_pirq_routing_table(void);
#else
#define check_pirq_routing_table() do {} while(0)
#endif
#if defined(HAVE_PIRQ_TABLE)
unsigned long copy_pirq_routing_table(unsigned long start);
#else
#define copy_pirq_routing_table(start) (start)
#endif
#endif /* ARCH_PIRQ_ROUTING_H */

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#ifndef I386_BITOPS_H
#define I386_BITOPS_H
/**
* log2 - Find the truncated log base 2 of x
*/
static inline unsigned long log2(unsigned long x)
{
unsigned long r = 0;
/*
__asm__(
"bsrl %1, %0\n\t"
"jnz 1f\n\t"
"movl $-1, %0\n\t"
"1:\n\t"
: "=r" (r) : "r" (x));
*/
return r;
}
#endif /* I386_BITOPS_H */

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/* $Id$ */
/* Copyright 2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
#ifndef _PPC_H
#define _PPC_H
#define BIG_ENDIAN
#define RODATA __attribute__ ((__section__ (".rodata")))
/* Do CPU specific setup, with optional icache */
void ppc_setup_cpu(int icache);
void ppc_enable_dcache(void);
void ppc_disable_dcache(void);
void ppc_enable_mmu(void);
/* Describe which sort of ppc CPU I am */
void ppc_identify(void);
#endif

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/*
* (C) Copyright 2000
* Wolfgang Denk, DENX Software Engineering, wd@denx.de.
*
* See file CREDITS for list of people who contributed to this
* project.
*
* 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; either version 2 of
* the License, or (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
/*
* This file contains all the macros and symbols which define
* a PowerPC assembly language environment.
*/
#ifndef __PPC_ASM_TMPL__
#define __PPC_ASM_TMPL__
/***************************************************************************
*
* These definitions simplify the ugly declarations necessary for GOT
* definitions.
*
* Stolen from prepboot/bootldr.h, (C) 1998 Gabriel Paubert, paubert@iram.es
*
* Uses r14 to access the GOT
*/
#define START_GOT \
.section ".got2","aw"; \
.LCTOC1 = .+32768
#define END_GOT \
.text
#define GET_GOT \
bl 1f ; \
.text 2 ; \
0: .long .LCTOC1-1f ; \
.text ; \
1: mflr r14 ; \
lwz r0,0b-1b(r14) ; \
add r14,r0,r14 ;
#define GOT_ENTRY(NAME) .L_ ## NAME = . - .LCTOC1 ; .long NAME
#define GOT(NAME) .L_ ## NAME (r14)
/***************************************************************************
* Register names
*/
#define r0 0
#define r1 1
#define r2 2
#define r3 3
#define r4 4
#define r5 5
#define r6 6
#define r7 7
#define r8 8
#define r9 9
#define r10 10
#define r11 11
#define r12 12
#define r13 13
#define r14 14
#define r15 15
#define r16 16
#define r17 17
#define r18 18
#define r19 19
#define r20 20
#define r21 21
#define r22 22
#define r23 23
#define r24 24
#define r25 25
#define r26 26
#define r27 27
#define r28 28
#define r29 29
#define r30 30
#define r31 31
/*
* FP register names
*/
#define fr0 0
#define fr1 1
#define fr2 2
#define fr3 3
#define fr4 4
#define fr5 5
#define fr6 6
#define fr7 7
#define fr8 8
#define fr9 9
#define fr10 10
#define fr11 11
#define fr12 12
#define fr13 13
#define fr14 14
#define fr15 15
#define fr16 16
#define fr17 17
#define fr18 18
#define fr19 19
#define fr20 20
#define fr21 21
#define fr22 22
#define fr23 23
#define fr24 24
#define fr25 25
#define fr26 26
#define fr27 27
#define fr28 28
#define fr29 29
#define fr30 30
#define fr31 31
/* Some special registers */
#define TBRU 269 /* Time base Upper/Lower (Reading) */
#define TBRL 268
#define TBWU 284 /* Time base Upper/Lower (Writing) */
#define TBWL 285
#define XER 1
#define LR 8
#define CTR 9
#define HID0 1008 /* Hardware Implementation */
#define PVR 287 /* Processor Version */
#define SDR1 25 /* MMU hash base register */
#define DAR 19 /* Data Address Register */
#define SPR0 272 /* Supervisor Private Registers */
#define SPRG0 272
#define SPR1 273
#define SPRG1 273
#define SPR2 274
#define SPRG2 274
#define SPR3 275
#define SPRG3 275
#define DSISR 18
#define SRR0 26 /* Saved Registers (exception) */
#define SRR1 27
#define DEC 22 /* Decrementer */
#define EAR 282 /* External Address Register */
#define ICR 148 /* Interrupt Cause Register (37-44) */
#define DER 149
#define COUNTA 150 /* Breakpoint Counter (37-44) */
#define COUNTB 151 /* Breakpoint Counter (37-44) */
#define LCTRL1 156 /* Load/Store Support (37-40) */
#define LCTRL2 157 /* Load/Store Support (37-41) */
#define ICTRL 158
/* Registers in the processor's internal memory map that we use.
*/
#define IMMR 0xff000000
#define SYPCR 0x00000004
#define BR0 0x00000100
#define OR0 0x00000104
#define BR1 0x00000108
#define OR1 0x0000010c
#define BR2 0x00000110
#define OR2 0x00000114
#define BR3 0x00000118
#define OR3 0x0000011c
#define BR4 0x00000120
#define OR4 0x00000124
#define MAR 0x00000164
#define MCR 0x00000168
#define MAMR 0x00000170
#define MBMR 0x00000174
#define MSTAT 0x00000178
#define MPTPR 0x0000017a
#define MDR 0x0000017c
#define TBSCR 0x00000200
#define TBREFF0 0x00000204
#define PLPRCR 0x00000284
#define curptr r2
#define SYNC \
sync; \
isync
/*
* Macros for storing registers into and loading registers from
* exception frames.
*/
#define SAVE_GPR(n, base) stw n,GPR0+4*(n)(base)
#define SAVE_2GPRS(n, base) SAVE_GPR(n, base); SAVE_GPR(n+1, base)
#define SAVE_4GPRS(n, base) SAVE_2GPRS(n, base); SAVE_2GPRS(n+2, base)
#define SAVE_8GPRS(n, base) SAVE_4GPRS(n, base); SAVE_4GPRS(n+4, base)
#define SAVE_10GPRS(n, base) SAVE_8GPRS(n, base); SAVE_2GPRS(n+8, base)
#define REST_GPR(n, base) lwz n,GPR0+4*(n)(base)
#define REST_2GPRS(n, base) REST_GPR(n, base); REST_GPR(n+1, base)
#define REST_4GPRS(n, base) REST_2GPRS(n, base); REST_2GPRS(n+2, base)
#define REST_8GPRS(n, base) REST_4GPRS(n, base); REST_4GPRS(n+4, base)
#define REST_10GPRS(n, base) REST_8GPRS(n, base); REST_2GPRS(n+8, base)
/*
* GCC sometimes accesses words at negative offsets from the stack
* pointer, although the SysV ABI says it shouldn't. To cope with
* this, we leave this much untouched space on the stack on exception
* entry.
*/
#define STACK_UNDERHEAD 64
#if 0 /* we don't use virtual addresses in PPCBOOT */
#define tophys(rd,rs,rt) addis rd,rs,-KERNELBASE@h
#define tovirt(rd,rs,rt) addis rd,rs,KERNELBASE@h
#else
#define tophys(rd,rs,rt) mr rd,rs
#define tovirt(rd,rs,rt) mr rd,rs
#endif
/*
* Exception entry code. This code runs with address translation
* turned off, i.e. using physical addresses.
* We assume sprg3 has the physical address of the current
* task's thread_struct.
*/
#define EXCEPTION_PROLOG \
mtspr SPRG0,r20; \
mtspr SPRG1,r21; \
mfcr r20; \
tophys(r21,r1,r21); /* use tophys(kernel sp) otherwise */ \
subi r21,r21,INT_FRAME_SIZE+STACK_UNDERHEAD; /* alloc exc. frame */\
1: stw r20,_CCR(r21); /* save registers */ \
stw r22,GPR22(r21); \
stw r23,GPR23(r21); \
mfspr r20,SPRG0; \
stw r20,GPR20(r21); \
mfspr r22,SPRG1; \
stw r22,GPR21(r21); \
mflr r20; \
stw r20,_LINK(r21); \
mfctr r22; \
stw r22,_CTR(r21); \
mfspr r20,XER; \
stw r20,_XER(r21); \
mfspr r22,SRR0; \
mfspr r23,SRR1; \
stw r0,GPR0(r21); \
stw r1,GPR1(r21); \
stw r2,GPR2(r21); \
stw r1,0(r21); \
tovirt(r1,r21,r1); /* set new kernel sp */ \
SAVE_4GPRS(3, r21);
/*
* Note: code which follows this uses cr0.eq (set if from kernel),
* r21, r22 (SRR0), and r23 (SRR1).
*/
/*
* Exception vectors.
*
* The data words for `hdlr' and `int_return' are initialized with
* OFFSET values only; they must be relocated first before they can
* be used!
*/
#define STD_EXCEPTION(n, label, hdlr) \
. = n; \
label: \
EXCEPTION_PROLOG; \
lwz r3,GOT(transfer_to_handler); \
mtlr r3; \
addi r3,r1,STACK_FRAME_OVERHEAD; \
li r20,MSR_KERNEL; \
blrl ; \
.L_ ## label : \
.long hdlr - _start + EXC_OFF_SYS_RESET; \
.long int_return - _start + EXC_OFF_SYS_RESET
#endif /* __PPC_ASM_TMPL__ */

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/* $Id$ */
/* Copyright 2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
/* In the MSR, not all bits are interesting to us
13 - POW - Power management
14 - TGPR - temporary registers for page table routines
15 - ILE - Exception little endian
16 - EE - External interrupts
17 - PR - Privilege level
18 - FP - Floating Point available
19 - ME - Machine check exception enable
20 - FE0 - Floating exception mode 0
21 - SE - Single step trace mode
22 - BE - Branch trace enable
23 - FE1 - Floating exception mode 1
25 - IP - Exception prefix
26 - IR - Instruction address translation
27 - DR - Data address translation
30 - RI - Recoverable exception
31 - LE - Little endian mode
MSR_MASK is the bits we do not change.
*/
#define MSR_MASK 0xfff8008c
#define MSR_POW 0x00040000
#define MSR_TGPR 0x00020000
#define MSR_ILE 0x00010000
#define MSR_EE 0x00008000
#define MSR_PR 0x00004000
#define MSR_FP 0x00002000
#define MSR_ME 0x00001000
#define MSR_FE0 0x00000800
#define MSR_SE 0x00000400
#define MSR_BE 0x00000200
#define MSR_FE1 0x00000100
#define MSR_IP 0x00000040
#define MSR_IR 0x00000020
#define MSR_DR 0x00000010
#define MSR_RI 0x00000002
#define MSR_LE 0x00000001
#define MSR_DEFAULT (MSR_FP | MSR_IR | MSR_DR)
/* We are interested in the following hid0 bits:
6 - ECLK - Enable external test clock (603 only)
11 - DPM - Turn on dynamic power management (603 only)
15 - NHR - Not hard reset
16 - ICE - Instruction cache enable
17 - DCE - Data cache enable
18 - ILOCK - Instruction cache lock
19 - DLOCK - Data cache lock
20 - ICFI - Instruction cache invalidate
21 - DCFI - Data cache invalidate
24 - NOSER - Serial execution disable (604 only - turbo mode)
24 - SGE - Store gathering enable (7410 only)
29 - BHT - Branch history table (604 only)
I made up the tags for the 604 specific bits, as they aren't
named in the 604 book. The 603 book calls the invalidate bits
ICFI and DCI, and I have no idea why it isn't DCFI. Maybe IBM named
one, and Motorola named the other. */
#define HID0_ECLK 0x02000000
#define HID0_DPM 0x00100000
#define HID0_NHR 0x00010000
#define HID0_ICE 0x00008000
#define HID0_DCE 0x00004000
#define HID0_ILOCK 0x00002000
#define HID0_DLOCK 0x00001000
#define HID0_ICFI 0x00000800
#define HID0_DCFI 0x00000400
#define HID0_NOSER 0x00000080
#define HID0_SGE 0x00000080
#define HID0_BTIC 0x00000020
#define HID0_BHT 0x00000004
/*
* BAT defines
*/
/*
* BL field in upper BAT register
*/
#define BAT_BL_128K 0x00000000
#define BAT_BL_256K 0x00000004
#define BAT_BL_512K 0x0000000C
#define BAT_BL_1M 0x0000001C
#define BAT_BL_2M 0x0000003C
#define BAT_BL_4M 0x0000007C
#define BAT_BL_8M 0x000000FC
#define BAT_BL_16M 0x000001FC
#define BAT_BL_32M 0x000003FC
#define BAT_BL_64M 0x000007FC
#define BAT_BL_128M 0x00000FFC
#define BAT_BL_256M 0x00001FFC
/*
* Supervisor/user valid mode in upper BAT register
*/
#define BAT_VALID_SUPERVISOR 0x00000002
#define BAT_VALID_USER 0x00000001
#define BAT_INVALID 0x00000000
/*
* WIMG bit setting in lower BAT register
*/
#define BAT_WRITE_THROUGH 0x00000040
#define BAT_CACHE_INHIBITED 0x00000020
#define BAT_COHERENT 0x00000010
#define BAT_GUARDED 0x00000008
/*
* Protection bits in lower BAT register
*/
#define BAT_NO_ACCESS 0x00000000
#define BAT_READ_ONLY 0x00000001
#define BAT_READ_WRITE 0x00000002
#ifndef ASM
unsigned __getmsr(void);
void __setmsr(unsigned value);
unsigned __gethid0(void);
unsigned __gethid1(void);
void __sethid0(unsigned value);
unsigned __getpvr(void);
#endif

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#ifndef PPC_STDDEF_H
#define PPC_STDDEF_H
typedef long ptrdiff_t;
typedef unsigned long size_t;
typedef long ssize_t;
typedef int wchar_t;
typedef unsigned int wint_t;
#define NULL 0
#define offsetof(TYPE, MEMBER) ((size_t) &((TYPE *)0)->MEMBER)
#endif /* PPC_STDDEF_H */

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#ifndef PPC_STDINT_H
#define PPC_STDINT_H
/* Exact integral types */
typedef unsigned char uint8_t;
typedef signed char int8_t;
typedef unsigned short uint16_t;
typedef signed short int16_t;
typedef unsigned int uint32_t;
typedef signed int int32_t;
typedef unsigned long long uint64_t;
typedef signed long long int64_t;
/* Small types */
typedef unsigned char uint_least8_t;
typedef signed char int_least8_t;
typedef unsigned short uint_least16_t;
typedef signed short int_least16_t;
typedef unsigned int uint_least32_t;
typedef signed int int_least32_t;
typedef unsigned long long uint_least64_t;
typedef signed long long int_least64_t;
/* Fast Types */
typedef unsigned char uint_fast8_t;
typedef signed char int_fast8_t;
typedef unsigned int uint_fast16_t;
typedef signed int int_fast16_t;
typedef unsigned int uint_fast32_t;
typedef signed int int_fast32_t;
typedef unsigned long long uint_fast64_t;
typedef signed long long int_fast64_t;
/* Types for `void *' pointers. */
typedef int intptr_t;
typedef unsigned int uintptr_t;
/* Largest integral types */
typedef long long int intmax_t;
typedef unsigned long long uintmax_t;
#endif /* PPC_STDINT_H */

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/* $Id$ */
/* Copyright 2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
#ifndef _TIMER_H
#define __TIMER_H
unsigned get_hz(void);
unsigned ticks_since_boot(void);
void sleep_ticks(unsigned);
void udelay(int);
#endif

109
src/arch/ppc/lib/c_start.S Normal file
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/* $Id$ */
/* Copyright 2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
/*
* The assumption is that we're located in ROM and we have a fake stack
* located in cache. Our task is to turn on memory proper, the finish
* configuring the machine.
*/
#define ASM
#include "ppcreg.h"
#include <ppc_asm.tmpl>
.section ".text"
.globl _start
_start:
/*
* init stack pointer to real ram now that memory is on
*/
lis r1, _estack@ha
addi r1, r1, _estack@l
stwu r0,-64(r1)
stwu r1,-24(r1)
/*
* Clear stack
*/
lis r4, _stack@ha
addi r4, r4, _stack@l
lis r7, _estack@ha
addi r7, r7, _estack@l
lis r5, 0
1: stwx r5, 0, r4
addi r4, r4, 4
cmp 0, 0, r4, r7
ble 1b
sync
/*
* Clear bss
*/
lis r4, _bss@ha
addi r4, r4, _bss@l
lis r7, _ebss@ha
addi r7, r7, _ebss@l
lis r5, 0
1: stwx r5, 0, r4
addi r4, r4, 4
cmp 0, 0, r4, r7
ble 1b
sync
/*
* Set up the EABI pointers, before we enter any C code
*/
lis r13, _SDA_BASE_@ha
addi r13, r13, _SDA_BASE_@l
lis r2, _SDA2_BASE_@ha
addi r2, r2, _SDA2_BASE_@l
/*
* load start address into SRR0 for rfi
*/
lis r3, hardwaremain@ha
addi r3, r3, hardwaremain@l
mtspr SRR0, r3
/*
* load the current MSR into SRR1 so that it will be copied
* back into MSR on rfi
*/
mfmsr r4
mtspr SRR1, r4 // load SRR1 with r4
/*
* If something returns after rfi then die
*/
lis r3, dead@ha
addi r3, r3, dead@l
mtlr r3
/*
* Complete rest of initialization in C (hardwaremain)
*/
rfi
/*
* Stop here if something goes wrong
*/
dead:
b dead
/*NOTREACHED*/
/* Remove need for ecrti.o and ectrn.o */
.globl __init
__init:
.globl __fini
__fini:
.globl __CTOR_LIST__
__CTOR_LIST__:
.globl __CTOR_END__
__CTOR_END__:
.globl __DTOR_LIST__
__DTOR_LIST__:
.globl __DTOR_END__
__DTOR_END__:
blr

45
src/arch/ppc/lib/floats.S Normal file
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/* $Id$ */
/* Copyright 1999-2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
#include <ppc_asm.tmpl>
.globl _init_float_registers
_init_float_registers:
lfd fr0, 0(r3)
lfd fr1, 0(r3)
lfd fr2, 0(r3)
lfd fr3, 0(r3)
lfd fr4, 0(r3)
lfd fr5, 0(r3)
lfd fr6, 0(r3)
lfd fr7, 0(r3)
lfd fr8, 0(r3)
lfd fr9, 0(r3)
lfd fr10, 0(r3)
lfd fr11, 0(r3)
lfd fr12, 0(r3)
lfd fr13, 0(r3)
lfd fr14, 0(r3)
lfd fr15, 0(r3)
lfd fr16, 0(r3)
lfd fr17, 0(r3)
lfd fr18, 0(r3)
lfd fr19, 0(r3)
lfd fr20, 0(r3)
lfd fr21, 0(r3)
lfd fr22, 0(r3)
lfd fr23, 0(r3)
lfd fr24, 0(r3)
lfd fr25, 0(r3)
lfd fr26, 0(r3)
lfd fr27, 0(r3)
lfd fr28, 0(r3)
lfd fr29, 0(r3)
lfd fr30, 0(r3)
lfd fr31, 0(r3)
blr
.end

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/* $Id$ */
/* Copyright 1999-2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
/* .text*/
.globl _init_float_registers
_init_float_registers:
lfd 0, 0(3)
lfd 1, 0(3)
lfd 2, 0(3)
lfd 3, 0(3)
lfd 4, 0(3)
lfd 5, 0(3)
lfd 6, 0(3)
lfd 7, 0(3)
lfd 8, 0(3)
lfd 9, 0(3)
lfd 10, 0(3)
lfd 11, 0(3)
lfd 12, 0(3)
lfd 13, 0(3)
lfd 14, 0(3)
lfd 15, 0(3)
lfd 16, 0(3)
lfd 17, 0(3)
lfd 18, 0(3)
lfd 19, 0(3)
lfd 20, 0(3)
lfd 21, 0(3)
lfd 22, 0(3)
lfd 23, 0(3)
lfd 24, 0(3)
lfd 25, 0(3)
lfd 26, 0(3)
lfd 27, 0(3)
lfd 28, 0(3)
lfd 29, 0(3)
lfd 30, 0(3)
lfd 31, 0(3)
blr
.end

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src/arch/ppc/lib/setup.c Normal file
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/* $Id$ */
/* Copyright 2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
#include "ppc.h"
#include "ppcreg.h"
unsigned __getmsr(void)
{
unsigned result;
__asm__ volatile ("mfmsr %0" : "=r" (result));
return result;
}
unsigned __gethid0(void)
{
unsigned result;
__asm__ volatile ("mfspr %0,1008" : "=r" (result));
return result;
}
unsigned __gethid1(void)
{
unsigned result;
__asm__ volatile ("mfspr %0,1009" : "=r" (result));
return result;
}
void __sethid0(unsigned value)
{
__asm__ volatile ("mtspr 1008,%0" : : "r" (value));
}
unsigned __getpvr(void)
{
int result;
__asm__("mfspr %0, 287" : "=r" (result));
return result;
}
void __setmsr(unsigned value)
{
__asm__ volatile ("mtmsr %0; sync" :: "r" (value));
}
void __set1015(unsigned value)
{
__asm__ volatile ("mtspr 1015,%0" : : "r" (value));
}
extern void _init_float_registers(const double *);
/*RODATA static const double dummy_float = 1.0;*/
static const double dummy_float = 1.0;
#define HID0_DCACHE HID0_DCE
#define MSR_DATA MSR_DR
void ppc_setup_cpu(int icache)
{
int type = __getpvr() >> 16;
int version = __getpvr() & 0xffff;
if (type == 0xc)
{
if (version == 0x0200)
__set1015(0x19000004);
else if (((version & 0xff00) == 0x0200) &&
(version != 0x0209))
__set1015(0x01000000);
}
if (icache)
{
__sethid0(HID0_NHR | HID0_BHT | HID0_ICE | HID0_ICFI | HID0_BTIC
| HID0_DCACHE);
__sethid0(HID0_DPM | HID0_NHR | HID0_BHT | HID0_ICE | HID0_BTIC
| HID0_DCACHE);
}
else
{
__sethid0(HID0_DPM | HID0_NHR | HID0_BHT | HID0_BTIC | HID0_DCACHE);
}
#if 1
/* if (type == 8 || type == 12) */
{
__setmsr(MSR_FP | MSR_DATA);
_init_float_registers(&dummy_float);
}
#endif
}
void ppc_enable_dcache(void)
{
/*
* Already enabled in crt0.S
*/
#if 0
unsigned hid0 = __gethid0();
__sethid0(hid0 | HID0_DCFI | HID0_DCE);
__sethid0(hid0 | HID0_DCE);
#endif
}
void ppc_disable_dcache(void)
{
unsigned hid0 = __gethid0();
__sethid0(hid0 & ~HID0_DCE);
}
void ppc_enable_mmu(void)
{
unsigned msr = __getmsr();
__setmsr(msr | MSR_DR | MSR_IR);
}
void make_coherent(void *base, unsigned length)
{
unsigned hid0 = __gethid0();
if (hid0 & HID0_DCE)
{
unsigned i;
unsigned offset = 0x1f & (unsigned) base;
unsigned adjusted_base = (unsigned) base & ~0x1f;
for(i = 0; i < length + offset; i+= 32)
__asm__ volatile ("dcbf %1,%0" : : "r" (adjusted_base), "r" (i));
if (hid0 & HID0_ICE)
for(i = 0; i < length + offset; i+= 32)
__asm__ volatile ("icbi %1,%0" : : "r" (adjusted_base), "r" (i));
}
}

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/* $Id$ */
/* Copyright 1999-2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
.text
.globl _timebase
_timebase:
mftbu 3
mftb 4
mftbu 5
cmpw 3, 5
bne _timebase
blr

31
src/arch/ppc/lib/timer.c Normal file
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/* $Id$ */
/* Copyright 2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
#include <timer.h>
#include <bsp.h>
unsigned get_hz(void)
{
return bsp_clock_speed();
}
unsigned ticks_since_boot(void)
{
extern unsigned long long _timebase(void);
return (unsigned) (_timebase());
}
void sleep_ticks(unsigned ticks)
{
unsigned then = ticks + ticks_since_boot();
while(ticks_since_boot() < then)
;
}
void udelay(int usecs)
{
unsigned ticksperusec = get_hz() / 1000000;
sleep_ticks(ticksperusec * usecs);
}

210
src/include/pc80/ide.h Normal file
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/*
* UBL, The Universal Talkware Boot Loader
* Copyright (C) 2000 Universal Talkware Inc.
* Copyright (C) 2002 Eric Biederman
*
* 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; either version 2 of the License, or
* (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*
*/
typedef uint64_t sector_t;
struct controller {
uint16_t cmd_base;
uint16_t ctrl_base;
};
struct harddisk_info {
struct controller *ctrl;
uint16_t heads;
uint16_t cylinders;
uint16_t sectors_per_track;
uint8_t model_number[41];
uint8_t slave;
sector_t sectors;
int address_mode; /* am i lba (0x40) or chs (0x00) */
#define ADDRESS_MODE_CHS 0
#define ADDRESS_MODE_LBA 1
#define ADDRESS_MODE_LBA48 2
int drive_exists;
int slave_absent;
int basedrive;
};
#define IDE_SECTOR_SIZE 0x200
#define IDE_BASE0 (0x1F0u) /* primary controller */
#define IDE_BASE1 (0x170u) /* secondary */
#define IDE_BASE2 (0x0F0u) /* third */
#define IDE_BASE3 (0x070u) /* fourth */
#define IDE_REG_EXTENDED_OFFSET (0x204u)
#define IDE_REG_DATA(ctrl) ((ctrl)->cmd_base + 0u) /* word register */
#define IDE_REG_ERROR(ctrl) ((ctrl)->cmd_base + 1u)
#define IDE_REG_PRECOMP(ctrl) ((ctrl)->cmd_base + 1u)
#define IDE_REG_FEATURE(ctrl) ((ctrl)->cmd_base + 1u)
#define IDE_REG_SECTOR_COUNT(ctrl) ((ctrl)->cmd_base + 2u)
#define IDE_REG_SECTOR_NUMBER(ctrl) ((ctrl)->cmd_base + 3u)
#define IDE_REG_LBA_LOW(ctrl) ((ctrl)->cmd_base + 3u)
#define IDE_REG_CYLINDER_LSB(ctrl) ((ctrl)->cmd_base + 4u)
#define IDE_REG_LBA_MID(ctrl) ((ctrl)->cmd_base + 4u)
#define IDE_REG_CYLINDER_MSB(ctrl) ((ctrl)->cmd_base + 5u)
#define IDE_REG_LBA_HIGH(ctrl) ((ctrl)->cmd_base + 5u)
#define IDE_REG_DRIVEHEAD(ctrl) ((ctrl)->cmd_base + 6u)
#define IDE_REG_DEVICE(ctrl) ((ctrl)->cmd_base + 6u)
#define IDE_REG_STATUS(ctrl) ((ctrl)->cmd_base + 7u)
#define IDE_REG_COMMAND(ctrl) ((ctrl)->cmd_base + 7u)
#define IDE_REG_ALTSTATUS(ctrl) ((ctrl)->ctrl_base + 2u)
#define IDE_REG_DEVICE_CONTROL(ctrl) ((ctrl)->ctrl_base + 2u)
struct ide_pio_command
{
uint8_t feature;
uint8_t sector_count;
uint8_t lba_low;
uint8_t lba_mid;
uint8_t lba_high;
uint8_t device;
# define IDE_DH_DEFAULT (0xA0)
# define IDE_DH_HEAD(x) ((x) & 0x0F)
# define IDE_DH_MASTER (0x00)
# define IDE_DH_SLAVE (0x10)
# define IDE_DH_LBA (0x40)
# define IDE_DH_CHS (0x00)
uint8_t command;
uint8_t sector_count2;
uint8_t lba_low2;
uint8_t lba_mid2;
uint8_t lba_high2;
};
#define IDE_DEFAULT_COMMAND { 0xFFu, 0x01, 0x00, 0x0000, IDE_DH_DEFAULT }
#define IDE_ERR_ICRC 0x80 /* ATA Ultra DMA bad CRC */
#define IDE_ERR_BBK 0x80 /* ATA bad block */
#define IDE_ERR_UNC 0x40 /* ATA uncorrected error */
#define IDE_ERR_MC 0x20 /* ATA media change */
#define IDE_ERR_IDNF 0x10 /* ATA id not found */
#define IDE_ERR_MCR 0x08 /* ATA media change request */
#define IDE_ERR_ABRT 0x04 /* ATA command aborted */
#define IDE_ERR_NTK0 0x02 /* ATA track 0 not found */
#define IDE_ERR_NDAM 0x01 /* ATA address mark not found */
#define IDE_STATUS_BSY 0x80 /* busy */
#define IDE_STATUS_RDY 0x40 /* ready */
#define IDE_STATUS_DF 0x20 /* device fault */
#define IDE_STATUS_WFT 0x20 /* write fault (old name) */
#define IDE_STATUS_SKC 0x10 /* seek complete */
#define IDE_STATUS_DRQ 0x08 /* data request */
#define IDE_STATUS_CORR 0x04 /* corrected */
#define IDE_STATUS_IDX 0x02 /* index */
#define IDE_STATUS_ERR 0x01 /* error (ATA) */
#define IDE_STATUS_CHK 0x01 /* check (ATAPI) */
#define IDE_CTRL_HD15 0x08 /* bit should always be set to one */
#define IDE_CTRL_SRST 0x04 /* soft reset */
#define IDE_CTRL_NIEN 0x02 /* disable interrupts */
/* Most mandtory and optional ATA commands (from ATA-3), */
#define IDE_CMD_CFA_ERASE_SECTORS 0xC0
#define IDE_CMD_CFA_REQUEST_EXT_ERR_CODE 0x03
#define IDE_CMD_CFA_TRANSLATE_SECTOR 0x87
#define IDE_CMD_CFA_WRITE_MULTIPLE_WO_ERASE 0xCD
#define IDE_CMD_CFA_WRITE_SECTORS_WO_ERASE 0x38
#define IDE_CMD_CHECK_POWER_MODE1 0xE5
#define IDE_CMD_CHECK_POWER_MODE2 0x98
#define IDE_CMD_DEVICE_RESET 0x08
#define IDE_CMD_EXECUTE_DEVICE_DIAGNOSTIC 0x90
#define IDE_CMD_FLUSH_CACHE 0xE7
#define IDE_CMD_FORMAT_TRACK 0x50
#define IDE_CMD_IDENTIFY_DEVICE 0xEC
#define IDE_CMD_IDENTIFY_DEVICE_PACKET 0xA1
#define IDE_CMD_IDENTIFY_PACKET_DEVICE 0xA1
#define IDE_CMD_IDLE1 0xE3
#define IDE_CMD_IDLE2 0x97
#define IDE_CMD_IDLE_IMMEDIATE1 0xE1
#define IDE_CMD_IDLE_IMMEDIATE2 0x95
#define IDE_CMD_INITIALIZE_DRIVE_PARAMETERS 0x91
#define IDE_CMD_INITIALIZE_DEVICE_PARAMETERS 0x91
#define IDE_CMD_NOP 0x00
#define IDE_CMD_PACKET 0xA0
#define IDE_CMD_READ_BUFFER 0xE4
#define IDE_CMD_READ_DMA 0xC8
#define IDE_CMD_READ_DMA_QUEUED 0xC7
#define IDE_CMD_READ_MULTIPLE 0xC4
#define IDE_CMD_READ_SECTORS 0x20
#define IDE_CMD_READ_SECTORS_EXT 0x24
#define IDE_CMD_READ_VERIFY_SECTORS 0x40
#define IDE_CMD_RECALIBRATE 0x10
#define IDE_CMD_SEEK 0x70
#define IDE_CMD_SET_FEATURES 0xEF
#define IDE_CMD_SET_MAX_ADDR_EXT 0x24
#define IDE_CMD_SET_MULTIPLE_MODE 0xC6
#define IDE_CMD_SLEEP1 0xE6
#define IDE_CMD_SLEEP2 0x99
#define IDE_CMD_STANDBY1 0xE2
#define IDE_CMD_STANDBY2 0x96
#define IDE_CMD_STANDBY_IMMEDIATE1 0xE0
#define IDE_CMD_STANDBY_IMMEDIATE2 0x94
#define IDE_CMD_WRITE_BUFFER 0xE8
#define IDE_CMD_WRITE_DMA 0xCA
#define IDE_CMD_WRITE_DMA_QUEUED 0xCC
#define IDE_CMD_WRITE_MULTIPLE 0xC5
#define IDE_CMD_WRITE_SECTORS 0x30
#define IDE_CMD_WRITE_VERIFY 0x3C
/* IDE_CMD_SET_FEATURE sub commands */
#define IDE_FEATURE_CFA_ENABLE_8BIT_PIO 0x01
#define IDE_FEATURE_ENABLE_WRITE_CACHE 0x02
#define IDE_FEATURE_SET_TRANSFER_MODE 0x03
#define IDE_FEATURE_ENABLE_POWER_MANAGEMENT 0x05
#define IDE_FEATURE_ENABLE_POWERUP_IN_STANDBY 0x06
#define IDE_FEATURE_STANDBY_SPINUP_DRIVE 0x07
#define IDE_FEATURE_CFA_ENABLE_POWER_MODE1 0x0A
#define IDE_FEATURE_DISABLE_MEDIA_STATUS_NOTIFICATION 0x31
#define IDE_FEATURE_ENABLE_AUTOMATIC_ACOUSTIC_MANAGEMENT 0x42
#define IDE_FEATURE_SET_MAXIMUM_HOST_INTERFACE_SECTOR_TIMES 0x43
#define IDE_FEATURE_DISABLE_READ_LOOKAHEAD 0x55
#define IDE_FEATURE_ENABLE_RELEASE_INTERRUPT 0x5D
#define IDE_FEATURE_ENABLE_SERVICE_INTERRUPT 0x5E
#define IDE_FEATURE_DISABLE_REVERTING_TO_POWERON_DEFAULTS 0x66
#define IDE_FEATURE_CFA_DISABLE_8BIT_PIO 0x81
#define IDE_FEATURE_DISABLE_WRITE_CACHE 0x82
#define IDE_FEATURE_DISABLE_POWER_MANAGEMENT 0x85
#define IDE_FEATURE_DISABLE_POWERUP_IN_STANDBY 0x86
#define IDE_FEATURE_CFA_DISABLE_POWER_MODE1 0x8A
#define IDE_FEATURE_ENABLE_MEDIA_STATUS_NOTIFICATION 0x95
#define IDE_FEATURE_ENABLE_READ_LOOKAHEAD 0xAA
#define IDE_FEATURE_DISABLE_AUTOMATIC_ACOUSTIC_MANAGEMENT 0xC2
#define IDE_FEATURE_ENABLE_REVERTING_TO_POWERON_DEFAULTS 0xCC
#define IDE_FEATURE_DISABLE_SERVICE_INTERRUPT 0xDE
#define NUM_HD (4)
#define SECTOR_SIZE 512
#define SECTOR_SHIFT 9
/* Maximum block_size that may be set. */
#define DISK_BUFFER_SIZE (18 * SECTOR_SIZE)
extern struct harddisk_info harddisk_info[NUM_HD];
extern int ide_init(void);
extern int ide_read_sector(int driveno, void * buf, unsigned int sector,
int byte_offset, int n_bytes);

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# These are keyword-value pairs.
# a : separates the keyword from the value
# the value is arbitrary text delimited by newline.
# continuation, if needed, will be via the \ at the end of a line
# comments are indicated by a '#' as the first character.
# the keywords are case-INSENSITIVE
owner: Greg Watson
email: gwatson@lanl.gov
#status: One of unsupported, unstable, stable
status: unstable
explanation: currently under development
flash-types:
payload-types:
# e.g. linux, plan 9, wince, etc.
OS-types: linux
# e.g. "Plan 9 interrupts don't work on this chipset"
OS-issues:
console-types: serial
# vga is unsupported, unstable, or stable
vga: unsupported
# Last-known-good follows the internationl date standard: day/month/year
last-known-good: 19/04/2003
Comments:
Links:
Mainboard-revision:
# What other mainboards are like this one? List them here.
AKA:

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/* $Id$ */
/* Copyright 2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
#ifndef _FLASH_H
#define _FLASH_H
struct flash_device;
typedef struct flash_fn
{
const char *(* identify)(struct flash_device *flash);
void *(* ptr)(void *data);
int (* erase_all)(void *data);
int (* erase)(void *data, unsigned offset, unsigned length);
int (* program)(void *data, unsigned offset, const void *source, unsigned length);
u8 ( *read_byte)(void *data, unsigned offset);
} flash_fn;
typedef struct flash_device
{
const flash_fn *fn;
char *tag;
void *data;
unsigned long base;
unsigned size;
unsigned erase_size;
unsigned store_size;
struct flash_device *next;
} flash_device;
int register_flash_device(const flash_fn *fn, char *tag, void *data);
flash_device *find_flash_device(const char *tag);
int init_flash_amd800(char *tag, unsigned base, unsigned spacing);
#endif

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/* $Id$ */
/* Copyright 2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
/* Definitions for nvram devices - these are flash or eeprom devices used to
store information across power cycles and resets. Though they are byte
addressable, writes must be committed to allow flash devices to write
complete sectors. */
#ifndef _NVRAM_H
#define _NVRAM_H
typedef struct nvram_device
{
unsigned (*size)(struct nvram_device *data);
int (*read_block)(struct nvram_device *dev, unsigned offset,
unsigned char *data, unsigned length);
int (*write_byte)(struct nvram_device *dev, unsigned offset, unsigned char byte);
void (*commit)(struct nvram_device *data);
void *data;
} nvram_device;
int nvram_init (nvram_device *dev);
void nvram_clear(void);
extern nvram_device pcrtc_nvram;
extern void nvram_putenv(const char *name, const char *value);
extern int nvram_getenv(const char *name, char *buffer, unsigned size);
typedef const struct nvram_constant
{
const char *name;
const char *value;
} nvram_constant;
extern nvram_constant hardcoded_environment[];
#endif

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/**************************************************
*
* copyright @ motorola, 1999
*
*************************************************/
#include <pci.h>
#include <printk.h>
#include <northbridge/motorola/mpc107/epic.h>
extern struct pci_ops pci_direct_ppc;
typedef void (*VOIDFUNCPTR) (void); /* ptr to function returning void */
struct SrcVecTable SrcVecTable[MAXVEC] = /* Addr/Vector cross-reference tbl */
{
{ EPIC_EX_INT0_VEC_REG, "External Direct/Serial Source 0"},
{ EPIC_EX_INT1_VEC_REG, "External Direct/Serial Source 1"},
{ EPIC_EX_INT2_VEC_REG, "External Direct/Serial Source 2"},
{ EPIC_EX_INT3_VEC_REG, "External Direct/Serial Source 3"},
{ EPIC_EX_INT4_VEC_REG, "External Direct/Serial Source 4"},
{ EPIC_SR_INT5_VEC_REG, "External Serial Source 5"},
{ EPIC_SR_INT6_VEC_REG, "External Serial Source 6"},
{ EPIC_SR_INT7_VEC_REG, "External Serial Source 7"},
{ EPIC_SR_INT8_VEC_REG, "External Serial Source 8"},
{ EPIC_SR_INT9_VEC_REG, "External Serial Source 9"},
{ EPIC_SR_INT10_VEC_REG, "External Serial Source 10"},
{ EPIC_SR_INT11_VEC_REG, "External Serial Source 11"},
{ EPIC_SR_INT12_VEC_REG, "External Serial Source 12"},
{ EPIC_SR_INT13_VEC_REG, "External Serial Source 13"},
{ EPIC_SR_INT14_VEC_REG, "External Serial Source 14"},
{ EPIC_SR_INT15_VEC_REG, "External Serial Source 15"},
{ EPIC_I2C_INT_VEC_REG, "Internal I2C Source"},
{ EPIC_DMA0_INT_VEC_REG, "Internal DMA0 Source"},
{ EPIC_DMA1_INT_VEC_REG, "Internal DMA1 Source"},
{ EPIC_MSG_INT_VEC_REG, "Internal Message Source"},
};
VOIDFUNCPTR intVecTbl[MAXVEC]; /* Interrupt vector table */
/****************************************************************************
* epicInit - Initialize the EPIC registers
*
* This routine resets the Global Configuration Register, thus it:
* - Disables all interrupts
* - Sets epic registers to reset values
* - Sets the value of the Processor Current Task Priority to the
* highest priority (0xF).
* epicInit then sets the EPIC operation mode to Mixed Mode (vs. Pass
* Through or 8259 compatible mode).
*
* If IRQType (input) is Direct IRQs:
* - IRQType is written to the SIE bit of the EPIC Interrupt
* Configuration register (ICR).
* - clkRatio is ignored.
* If IRQType is Serial IRQs:
* - both IRQType and clkRatio will be written to the ICR register
*/
void epicInit
(
unsigned int IRQType, /* Direct or Serial */
unsigned int clkRatio /* Clk Ratio for Serial IRQs */
)
{
ULONG tmp;
tmp = sysEUMBBARRead(EPIC_GLOBAL_REG);
tmp |= 0xa0000000; /* Set the Global Conf. register */
sysEUMBBARWrite(EPIC_GLOBAL_REG, tmp);
/*
* Wait for EPIC to reset - CLH
*/
while( (sysEUMBBARRead(EPIC_GLOBAL_REG) & 0x80000000) == 1);
sysEUMBBARWrite(EPIC_GLOBAL_REG, 0x20000000);
tmp = sysEUMBBARRead(EPIC_INT_CONF_REG); /* Read interrupt conf. reg */
if (IRQType == EPIC_DIRECT_IRQ) /* direct mode */
sysEUMBBARWrite(EPIC_INT_CONF_REG, tmp & 0xf7ffffff);
else /* Serial mode */
{
tmp = (clkRatio << 28) | 0x08000000; /* Set clock ratio */
sysEUMBBARWrite(EPIC_INT_CONF_REG, tmp);
}
while (epicIntAck() != 0xff) /* Clear all pending interrupts */
epicEOI();
}
/****************************************************************************
* epicIntEnable - Enable an interrupt source
*
* This routine clears the mask bit of an external, an internal or
* a Timer register to enable the interrupt.
*
* RETURNS: None
*/
void epicIntEnable(int intVec)
{
ULONG tmp;
ULONG srAddr;
srAddr = SrcVecTable[intVec].srcAddr; /* Retrieve src Vec/Prio register */
tmp = sysEUMBBARRead(srAddr);
tmp &= ~EPIC_VEC_PRI_MASK; /* Clear the mask bit */
tmp |= (EPIC_VEC_PRI_DFLT_PRI << 16); /* Set priority to Default - CLH */
tmp |= intVec; /* Set Vector number */
sysEUMBBARWrite(srAddr, tmp);
return;
}
/****************************************************************************
* epicIntDisable - Disable an interrupt source
*
* This routine sets the mask bit of an external, an internal or
* a Timer register to disable the interrupt.
*
* RETURNS: OK or ERROR
*
*/
void epicIntDisable
(
int intVec /* Interrupt vector number */
)
{
ULONG tmp, srAddr;
srAddr = SrcVecTable[intVec].srcAddr;
tmp = sysEUMBBARRead(srAddr);
tmp |= 0x80000000; /* Set the mask bit */
sysEUMBBARWrite(srAddr, tmp);
return;
}
/****************************************************************************
* epicIntSourceConfig - Set properties of an interrupt source
*
* This function sets interrupt properites (Polarity, Sense, Interrupt
* Prority, and Interrupt Vector) of an Interrupt Source. The properties
* can be set when the current source is not in-request or in-service,
* which is determined by the Activity bit. This routine return ERROR
* if the the Activity bit is 1 (in-request or in-service).
*
* This function assumes that the Source Vector/Priority register (input)
* is a valid address.
*
* RETURNS: OK or ERROR
*/
int epicIntSourceConfig
(
int Vect, /* interrupt source vector number */
int Polarity, /* interrupt source polarity */
int Sense, /* interrupt source Sense */
int Prio /* interrupt source priority */
)
{
ULONG tmp, newVal;
ULONG actBit, srAddr;
srAddr = SrcVecTable[Vect].srcAddr;
tmp = sysEUMBBARRead(srAddr);
actBit = (tmp & 40000000) >> 30; /* retrieve activity bit - bit 30 */
if (actBit == 1)
return ERROR;
tmp &= 0xff30ff00; /* Erase previously set P,S,Prio,Vector bits */
newVal = (Polarity << 23) | (Sense << 22) | (Prio << 16) | Vect;
sysEUMBBARWrite(srAddr, tmp | newVal );
return (OK);
}
/****************************************************************************
* epicIntAck - acknowledge an interrupt
*
* This function reads the Interrupt acknowldge register and return
* the vector number of the highest pending interrupt.
*
* RETURNS: Interrupt Vector number.
*/
unsigned int epicIntAck(void)
{
return(sysEUMBBARRead( EPIC_PROC_INT_ACK_REG ));
}
/****************************************************************************
* epicEOI - signal an end of interrupt
*
* This function writes 0x0 to the EOI register to signal end of interrupt.
* It is usually called after an interrupt routine is served.
*
* RETURNS: None
*/
void epicEOI(void)
{
sysEUMBBARWrite(EPIC_PROC_EOI_REG, 0x0);
}
/****************************************************************************
* epicCurTaskPrioSet - sets the priority of the Processor Current Task
*
* This function should be called after epicInit() to lower the priority
* of the processor current task.
*
* RETURNS: OK or ERROR
*/
int epicCurTaskPrioSet
(
int prioNum /* New priority value */
)
{
if ( (prioNum < 0) || (prioNum > 0xF))
return ERROR;
sysEUMBBARWrite(EPIC_PROC_CTASK_PRI_REG, prioNum);
return OK;
}
/************************************************************************
* function: epicIntTaskGet
*
* description: Get value of processor current interrupt task priority register
*
* note:
***********************************************************************/
unsigned char epicIntTaskGet()
{
/* get the interrupt task priority register */
ULONG reg;
unsigned char rec;
reg = sysEUMBBARRead( EPIC_PROC_CTASK_PRI_REG );
rec = ( reg & 0x0F );
return rec;
}
/**************************************************************
* function: epicISR
*
* description: EPIC service routine called by the core exception
* at 0x500
*
* note:
**************************************************************/
unsigned int epicISR(void)
{
return 0;
}
/************************************************************
* function: epicModeGet
*
* description: query EPIC mode, return 0 if pass through mode
* return 1 if mixed mode
*
* note:
*************************************************************/
unsigned int epicModeGet(void)
{
ULONG val;
val = sysEUMBBARRead( EPIC_GLOBAL_REG );
return (( val & 0x20000000 ) >> 29);
}
/*********************************************
* function: epicConfigGet
*
* description: Get the EPIC interrupt Configuration
* return 0 if not error, otherwise return 1
*
* note:
********************************************/
void epicConfigGet( unsigned int *clkRatio, unsigned int *serEnable)
{
ULONG val;
val = sysEUMBBARRead( EPIC_INT_CONF_REG );
*clkRatio = ( val & 0x70000000 ) >> 28;
*serEnable = ( val & 0x8000000 ) >> 27;
}
/*******************************************************************
* sysEUMBBARRead - Read a 32-bit EUMBBAR register
*
* This routine reads the content of a register in the Embedded
* Utilities Memory Block, and swaps to big endian before returning
* the value.
*
* RETURNS: The content of the specified EUMBBAR register.
*/
ULONG sysEUMBBARRead
(
ULONG regNum
)
{
u32 temp;
pci_direct_ppc.read_dword(0, 0, regNum, &temp);
return ( temp );
}
/*******************************************************************
* sysEUMBBARWrite - Write a 32-bit EUMBBAR register
*
* This routine swaps the value to little endian then writes it to
* a register in the Embedded Utilities Memory Block address space.
*
* RETURNS: N/A
*/
void sysEUMBBARWrite
(
ULONG regNum, /* EUMBBAR register address */
u32 regVal /* Value to be written */
)
{
pci_direct_ppc.read_dword(0, 0, regNum, &regVal);
return ;
}
/********************************************************
* function: epicVendorId
*
* description: return the EPIC Vendor Identification
* register:
*
* siliccon version, device id, and vendor id
*
* note:
********************************************************/
void epicVendorId
(
unsigned int *step,
unsigned int *devId,
unsigned int *venId
)
{
ULONG val;
val = sysEUMBBARRead( EPIC_VENDOR_ID_REG );
*step = ( val & 0x00FF0000 ) >> 16;
*devId = ( val & 0x0000FF00 ) >> 8;
*venId = ( val & 0x000000FF );
}
/**************************************************
* function: epicFeatures
*
* description: return the number of IRQ supported,
* number of CPU, and the version of the
* OpenEPIC
*
* note:
*************************************************/
void epicFeatures
(
unsigned int *noIRQs,
unsigned int *noCPUs,
unsigned int *verId
)
{
ULONG val;
val = sysEUMBBARRead( EPIC_FEATURES_REG );
*noIRQs = ( val & 0x07FF0000 ) >> 16;
*noCPUs = ( val & 0x00001F00 ) >> 8;
*verId = ( val & 0x000000FF );
}
/*********************************************************
* function: epciTmFrequncySet
*
* description: Set the timer frequency reporting register
********************************************************/
void epicTmFrequencySet( unsigned int frq )
{
sysEUMBBARWrite(EPIC_TM_FREQ_REG, frq);
}
/*******************************************************
* function: epicTmFrequncyGet
*
* description: Get the current value of the Timer Frequency
* Reporting register
*
******************************************************/
unsigned int epicTmFrequencyGet(void)
{
return( sysEUMBBARRead(EPIC_TM_FREQ_REG)) ;
}
/****************************************************
* function: epicTmBaseSet
*
* description: Set the #n global timer base count register
* return 0 if no error, otherwise return 1.
*
* note:
****************************************************/
unsigned int epicTmBaseSet
(
ULONG srcAddr, /* Address of the Timer Base register */
unsigned int cnt, /* Base count */
unsigned int inhibit /* 1 - count inhibit */
)
{
unsigned int val = 0x80000000;
/* First inhibit counting the timer */
sysEUMBBARWrite(srcAddr, val) ;
/* set the new value */
val = (cnt & 0x7fffffff) | ((inhibit & 0x1) << 31);
sysEUMBBARWrite(srcAddr, val) ;
return 0;
}
/***********************************************************************
* function: epicTmBaseGet
*
* description: Get the current value of the global timer base count register
* return 0 if no error, otherwise return 1.
*
* note:
***********************************************************************/
unsigned int epicTmBaseGet( ULONG srcAddr, unsigned int *val )
{
*val = sysEUMBBARRead( srcAddr );
*val = *val & 0x7fffffff;
return 0;
}
/***********************************************************
* function: epicTmCountGet
*
* description: Get the value of a given global timer
* current count register
* return 0 if no error, otherwise return 1
* note:
**********************************************************/
unsigned int epicTmCountGet( ULONG srcAddr, unsigned int *val )
{
*val = sysEUMBBARRead( srcAddr );
*val = *val & 0x7fffffff;
return 0;
}
/***********************************************************
* function: epicTmInhibit
*
* description: Stop counting of a given global timer
* return 0 if no error, otherwise return 1
*
* note:
***********************************************************/
unsigned int epicTmInhibit( unsigned int srcAddr )
{
ULONG val;
val = sysEUMBBARRead( srcAddr );
val |= 0x80000000;
sysEUMBBARWrite( srcAddr, val );
return 0;
}
/******************************************************************
* function: epicTmEnable
*
* description: Enable counting of a given global timer
* return 0 if no error, otherwise return 1
*
* note:
*****************************************************************/
unsigned int epicTmEnable( ULONG srcAddr )
{
ULONG val;
val = sysEUMBBARRead( srcAddr );
val &= 0x7fffffff;
sysEUMBBARWrite( srcAddr, val );
return 0;
}
void epicSourcePrint(int Vect)
{
ULONG srcVal;
srcVal = sysEUMBBARRead(SrcVecTable[Vect].srcAddr);
printk_info("%s\n", SrcVecTable[Vect].srcName);
printk_info("Address = 0x%lx\n", SrcVecTable[Vect].srcAddr);
printk_info("Vector = %ld\n", (srcVal & 0x000000FF) );
printk_info("Mask = %ld\n", srcVal >> 31);
printk_info("Activitiy = %ld\n", (srcVal & 40000000) >> 30);
printk_info("Polarity = %ld\n", (srcVal & 0x00800000) >> 23);
printk_info("Sense = %ld\n", (srcVal & 0x00400000) >> 22);
printk_info("Priority = %ld\n", (srcVal & 0x000F0000) >> 16);
}

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/* $Id$
* (C) Copyright 2002
* Humboldt Solutions Ltd, <adrian@humboldt.co.uk>
*
* 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; either version 2 of
* the License, or (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
#include <types.h>
#include <stdlib.h>
#include <string.h>
#include "i2c.h"
static i2c_bus *first_i2c = NULL;
#if 0
int register_i2c_bus(const i2c_fn *fn, char *tag, void *data)
{
i2c_bus *bus = malloc (sizeof (i2c_bus));
if (bus)
{
bus->fn = fn;
bus->tag = tag;
bus->data = data;
bus->next = first_i2c;
first_i2c = bus;
return 0;
}
return -1;
}
#endif
i2c_bus *find_i2c_bus(const char *name)
{
int len;
if (! name)
return first_i2c;
if (first_i2c)
{
i2c_bus *i2c;
len = strlen(name);
for (i2c = first_i2c; i2c; i2c = i2c->next)
if (strlen(i2c->tag) == len && memcmp (name, i2c->tag, len) == 0)
return i2c;
}
return NULL;
}
void i2c_start(struct i2c_bus *bus)
{
if (! bus)
bus = first_i2c;
bus->fn->start(bus);
}
void i2c_stop(struct i2c_bus *bus)
{
if (! bus)
bus = first_i2c;
bus->fn->stop(bus);
}
int i2c_master_write(struct i2c_bus *bus, int target, int address,
const u8 *data, int length)
{
if (! bus)
bus = first_i2c;
return bus->fn->master_write(bus, target, address, data, length);
}
int i2c_master_read(struct i2c_bus *bus, int target, int address,
u8 *data, int length)
{
if (! bus)
bus = first_i2c;
return bus->fn->master_read(bus, target, address, data, length);
}

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/* $Id$
* (C) Copyright 2002
* Humboldt Solutions Ltd, <adrian@humboldt.co.uk>
*
* 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; either version 2 of
* the License, or (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
#ifndef _I2C_H
#define _I2C_H
struct i2c_bus;
typedef struct i2c_fn
{
void (* start)(struct i2c_bus *bus);
void (* stop)(struct i2c_bus *bus);
int (* master_write)(struct i2c_bus *bus, int target, int address,
const u8 *data, int length);
int (* master_read)(struct i2c_bus *bus, int target, int address,
u8 *data, int length);
} i2c_fn;
typedef struct i2c_bus
{
const i2c_fn *fn;
char *tag;
void *data;
struct i2c_bus *next;
} i2c_bus;
i2c_bus *find_i2c_bus(const char *name);
int register_i2c_bus(const i2c_fn *fn, char *tag, void *data);
void i2c_start(struct i2c_bus *bus);
void i2c_stop(struct i2c_bus *bus);
int i2c_master_write(struct i2c_bus *bus, int target, int address,
const u8 *data, int length);
int i2c_master_read(struct i2c_bus *bus, int target, int address,
u8 *data, int length);
void init_i2c_nvram(const char *i2c_tag);
extern i2c_fn mpc107_i2c_fn;
#endif

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/*
* (C) Copyright 2001
* Humboldt Solutions Ltd, adrian@humboldt.co.uk.
*
* 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; either version 2 of
* the License, or (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
#include <printk.h>
#include "mpc107.h"
void
sdram_dimm_to_bank_info(const char *data, sdram_dimm_info *dimm, int verbose)
{
sdram_bank_info *bank1 = dimm->bank1;
sdram_bank_info *bank2 = dimm->bank2;
unsigned char csum = 0;
unsigned char x;
int i;
int no_cas_latencies = 0;
char latency[3];
/* Mark banks initially broken */
bank1->size = 0;
bank2->size = 0;
if (data[0] < 64)
{
if (verbose)
printk_info("SPD data too short\n");
return;
}
for(i = 0; i < 63; i++)
csum += data[i];
if (csum != data[63])
{
if (verbose)
printk_info("Broken checksum\n");
return;
}
if (data[2] != 0x04)
{
if (verbose)
printk_info("SDRAM Only\n");
return;
}
bank1->row_bits = data[3] & 0x0f;
if (data[3] >> 4)
bank2->row_bits = data[3] >> 4;
else
bank2->row_bits = bank1->row_bits;
bank1->internal_banks = bank2->internal_banks = data[17];
bank1->col_bits = data[4] & 0x0f;
if (data[4] >> 4)
bank2->col_bits = data[4] >> 4;
else
bank2->col_bits = bank1->col_bits;
if (data[7] || (data[6] != 80 && data[6] != 72 && data[6] != 64))
{
if (verbose)
printk_info("Data width incorrect\n");
return;
}
if (data[8] != 0x01)
{
if (verbose)
printk_info("3.3V TTL DIMMS only\n");
return;
}
/* Extract CAS latencies in reverse order, as we only get info on
the highest ones. */
x = data[18];
for(i = 7; i > 0; i--)
{
if (x & 0x40)
{
if (no_cas_latencies < 3)
latency[no_cas_latencies] = i;
no_cas_latencies++;
}
x <<= 1;
}
/* Now fill in other timings - we're most interested in the lowest
CAS latency, so we shuffle data to put that first. */
for(i = no_cas_latencies; i >= 0; i--)
bank1->cas_latency[no_cas_latencies - i - 1] =
bank2->cas_latency[no_cas_latencies - i - 1] =
latency[i];
for(i = no_cas_latencies; i < 3; i++)
bank1->cas_latency[i] = bank2->cas_latency[i] = 0;
/* Store values for the highest cas latency */
bank1->cycle_time[no_cas_latencies - 1] =
bank2->cycle_time[no_cas_latencies- 1] =
100 * (data[9] >> 4) + 10 * (data[9] & 0xf);
bank1->access_time[no_cas_latencies - 1] =
bank2->access_time[no_cas_latencies - 1] =
100 * (data[10] >> 4) + 10 * (data[10] & 0xf);
/* Then the second highest */
if (no_cas_latencies > 1)
{
bank1->cycle_time[no_cas_latencies - 2] =
bank2->cycle_time[no_cas_latencies- 2] =
100 * (data[23] >> 4) + 10 * (data[23] & 0xf);
bank1->access_time[no_cas_latencies - 2] =
bank2->access_time[no_cas_latencies - 2] =
100 * (data[24] >> 4) + 10 * (data[24] & 0xf);
}
/* Then the third highest */
if (no_cas_latencies > 2)
{
bank1->cycle_time[no_cas_latencies - 3] =
bank2->cycle_time[no_cas_latencies- 3] =
100 * (data[25] >> 2) + 25 * (data[25] & 0x3);
bank1->access_time[no_cas_latencies - 3] =
bank2->access_time[no_cas_latencies - 3] =
100 * (data[26] >> 2) + 25 * (data[26] & 0x3);
}
if (verbose)
for(i = 0; i < no_cas_latencies; i++)
printk_info("CL %d: cycle %dns access %dns\n",
bank1->cas_latency[i], bank1->cycle_time[i] / 100,
bank1->access_time[i] / 100);
/* Other timings */
bank1->min_back_to_back = bank2->min_back_to_back = data[15];
bank1->min_row_precharge = bank2->min_row_precharge = data[27];
bank1->min_active_to_active = bank2->min_active_to_active = data[28];
bank1->min_ras_to_cas = bank2->min_ras_to_cas = data[29];
bank1->min_ras = bank2->min_ras = data[30];
/* Error detection type */
bank1->error_detect = bank2->error_detect = data[11];
/* Crucial row sizes - these mark the data as valid */
for(i = 7; i >= 0; i--)
{
if (data[31] & (1 << i))
{
bank1->size = (4*1024*1024) << i;
break;
}
}
if (data[5] > 1)
{
for(i-- ; i >= 0; i--)
{
if (data[31] & (1 << i))
{
bank2->size = (4*1024*1024) << i;
break;
}
}
if (! bank2->size)
bank2->size = bank1->size;
}
dimm->size = bank1->size + bank2->size;
}
void
print_sdram_bank_info(const sdram_bank_info *bank)
{
printk_info("Bank %d: %dMB\n", bank->number, bank->size / (1024*1024));
}
static const char *error_types[] = {"", "Parity ", "ECC "};
void
print_sdram_dimm_info(const sdram_dimm_info *dimm)
{
printk_info("Dimm %d: ", dimm->number);
if (dimm->size)
printk_info("%dMB CL%d (%s): Running at CL%d %s\n",
dimm->size / (1024*1024), dimm->bank1->cas_latency[0],
dimm->part_number,
dimm->bank1->actual_cas,
error_types[dimm->bank1->actual_detect]);
else
printk_info("(none)\n");
}

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/*
* (C) Copyright 2001
* Humboldt Solutions Ltd, adrian@humboldt.co.uk.
*
* 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; either version 2 of
* the License, or (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
#include <bsp.h>
#include <ppc.h>
#include <pci.h>
#include <mem.h>
#include <types.h>
#include <string.h>
#include <printk.h>
#include <arch/io.h>
#include "i2c.h"
#include "mpc107.h"
#include <timer.h>
#define NUM_DIMMS 1
#define NUM_BANKS 2
extern struct pci_ops pci_direct_ppc;
struct mem_range *
getmeminfo(void)
{
int i;
sdram_dimm_info dimm[NUM_DIMMS];
sdram_bank_info bank[NUM_BANKS];
static struct mem_range meminfo;
hostbridge_probe_dimms(NUM_DIMMS, dimm, bank);
meminfo.basek = 0;
meminfo.sizek = 0;
for (i = 0; i < NUM_BANKS; i++) {
meminfo.sizek += bank[i].size;
}
meminfo.sizek >>= 10;
return &meminfo;
}
/*
* Memory is already turned on, but with pessimistic settings. Now
* we optimize settings to the actual memory configuration.
*/
unsigned
mpc107_config_memory(void)
{
sdram_dimm_info sdram_dimms[NUM_DIMMS];
sdram_bank_info sdram_banks[NUM_BANKS];
hostbridge_probe_dimms(NUM_DIMMS, sdram_dimms, sdram_banks);
return hostbridge_config_memory(NUM_BANKS, sdram_banks, 2);
}
/*
* Configure memory settings.
*/
unsigned long
hostbridge_config_memory(int no_banks, sdram_bank_info * bank, int for_real)
{
int i, j;
char ignore[8];
/* Convert bus clock to cycle time in 100ns units */
unsigned cycle_time = 10 * (2500000000U / bsp_clock_speed());
/* Approximate */
unsigned access_time = cycle_time - 300;
unsigned cas_latency = 0;
unsigned rdlat;
unsigned refint;
unsigned refrec;
unsigned acttorw, acttopre;
unsigned pretoact, bstopre;
enum sdram_error_detect error_detect;
u32 mccr1;
u32 mccr2;
u32 mccr3;
u32 mccr4;
u8 bank_enable;
u32 memstart1, memstart2;
u32 extmemstart1, extmemstart2;
u32 memend1, memend2;
u32 extmemend1, extmemend2;
u32 address;
/* Set up the ignore mask */
for(i = 0; i < no_banks; i++)
ignore[i] = (bank[i].size == 0);
/* Pick best CAS latency possible */
for (i = 0; i < no_banks; i++)
{
if (! ignore[i])
{
for (j = 0; j < 3; j++)
{
if (cycle_time >= bank[i].cycle_time[j] &&
access_time >= bank[i].access_time[j])
{
cas_latency = bank[i].cas_latency[j];
break;
}
}
}
}
if (!cas_latency)
return 0;
/* For various parameters there is a risk of clashing between banks */
error_detect = (for_real > 1) ? ERRORS_ECC : ERRORS_NONE;
for (i = 0; i < no_banks; i++)
{
if (! ignore[i])
{
{
for (j = 0; j < 3; j++)
if (bank[i].cas_latency[j] == cas_latency)
break;
if (j == 3)
{
ignore[i] = 1;
if (! for_real)
printk_info("Disabling memory bank %d (cas latency)\n", i);
}
if (bank[i].error_detect < error_detect)
error_detect = bank[i].error_detect;
}
}
}
/* Read in configuration of port X */
pci_direct_ppc.read_dword(0, 0, 0xf0, &mccr1);
pci_direct_ppc.read_dword(0, 0, 0xf4, &mccr2);
pci_direct_ppc.read_dword(0, 0, 0xfc, &mccr4);
mccr1 &= 0xfff00000;
mccr2 &= 0xffe00000;
mccr3 = 0;
mccr4 &= 0x00230000;
pretoact = 0;
acttorw = 0;
acttopre = 0;
for (i = 0; i < no_banks; i++)
if (! ignore[i])
{
int rowcode = -1;
if (for_real)
{
bank[i].actual_detect = error_detect;
bank[i].actual_cas = cas_latency;
}
switch (bank[i].row_bits) {
case 13:
if (bank[i].internal_banks == 4)
rowcode = 2;
else if (bank[i].internal_banks == 2)
rowcode = 1;
break;
case 12:
if (bank[i].internal_banks == 4)
rowcode = 0;
else if (bank[i].internal_banks == 2)
rowcode = 1;
break;
case 11:
if (bank[i].internal_banks == 4)
rowcode = 0;
else if (bank[i].internal_banks == 2)
rowcode = 3;
break;
}
if (rowcode == -1) {
ignore[i] = 1;
if (! for_real)
printk_info("Memory bank %d disabled: row bits %d and banks %d not supported\n", i, bank[i].row_bits, bank[i].internal_banks);
} else
mccr1 |= rowcode << (2 * i);
/* Update worst case settings */
if (! ignore[i]) {
if (bank[i].min_row_precharge > pretoact)
pretoact = bank[i].min_row_precharge;
if (bank[i].min_ras_to_cas > acttorw)
acttorw = bank[i].min_ras_to_cas;
if (bank[i].min_ras > acttopre)
acttopre = bank[i].min_ras;
}
}
/* Now convert to clock cycles, rounding up */
pretoact = (100 * pretoact + cycle_time - 1) / cycle_time;
acttopre = (100 * acttopre + cycle_time - 1) / cycle_time;
acttorw = (100 * acttorw + cycle_time - 1) / cycle_time;
refrec = acttopre;
bstopre = 0x240; /* Set conservative values, because we can't derive */
refint = 1000;
if (error_detect == ERRORS_ECC)
{
rdlat = cas_latency + 2;
mccr4 |= 0x00400000;
mccr2 |= 0x000c0001;
}
else
{
rdlat = cas_latency + 1;
mccr4 |= 0x00100000;
}
if (pretoact > 16 || acttopre > 16 || acttorw > 16)
if (! for_real)
printk_info("Timings out of range\n");
mccr4 |= ((pretoact & 0x0f) << 28) | ((acttopre & 0xf) << 24) |
((acttorw & 0x0f) << 4) |
((bstopre & 0x003) << 18) | ((bstopre & 0x3c0) >> 6) |
(cas_latency << 12) | 0x00000200 /* burst length */ ;
mccr3 |= ((bstopre & 0x03c) << 26) |
((refrec & 0x0f) << 24) | (rdlat << 20);
mccr2 |= refint << 2;
mccr1 |= 0x00080000; /* memgo */
address = 0;
memstart1 = memstart2 = 0;
extmemstart1 = extmemstart2 = 0;
memend1 = memend2 = 0;
extmemend1 = extmemend2 = 0;
bank_enable = 0;
for (i = 0; i < no_banks; i++) {
if (! ignore[i]) {
u32 end = address + bank[i].size - 1;
bank_enable |= 1 << i;
if (i < 4) {
memstart1 |= ((address >> 20) & 0xff) << (8 * i);
extmemstart1 |= ((address >> 28) & 0x03) << (8 * i);
memend1 |= ((end >> 20) & 0xff) << (8 * i);
extmemend1 |= ((end >> 28) & 0x03) << (8 * i);
} else {
int k = i - 4;
memstart2 |= ((address >> 20) & 0xff) << (8 * k);
extmemstart2 |= ((address >> 28) & 0x03) << (8 * k);
memend2 |= ((end >> 20) & 0xff) << (8 * k);
extmemend2 |= ((end >> 28) & 0x03) << (8 * k);
}
address += bank[i].size;
}
}
if (for_real)
{
pci_direct_ppc.write_byte(0, 0, 0xa0, bank_enable);
pci_direct_ppc.write_dword(0, 0, 0x80, memstart1);
pci_direct_ppc.write_dword(0, 0, 0x84, memstart2);
pci_direct_ppc.write_dword(0, 0, 0x88, extmemstart1);
pci_direct_ppc.write_dword(0, 0, 0x8c, extmemstart2);
pci_direct_ppc.write_dword(0, 0, 0x90, memend1);
pci_direct_ppc.write_dword(0, 0, 0x94, memend2);
pci_direct_ppc.write_dword(0, 0, 0x98, extmemend1);
pci_direct_ppc.write_dword(0, 0, 0x9c, extmemend2);
pci_direct_ppc.write_dword(0, 0, 0xfc, mccr4);
pci_direct_ppc.write_dword(0, 0, 0xf8, mccr3);
pci_direct_ppc.write_dword(0, 0, 0xf4, mccr2);
pci_direct_ppc.write_dword(0, 0, 0xf0, mccr1);
}
return address;
}
static int
i2c_wait(unsigned timeout, int writing)
{
u32 x;
while (((x = readl(MPC107_BASE + MPC107_I2CSR)) & (MPC107_I2C_CSR_MCF | MPC107_I2C_CSR_MIF))
!= (MPC107_I2C_CSR_MCF | MPC107_I2C_CSR_MIF)) {
if (ticks_since_boot() > timeout)
return -1;
}
if (x & MPC107_I2C_CSR_MAL) {
return -1;
}
if (writing && (x & MPC107_I2C_CSR_RXAK)) {
printk_info("No RXAK\n");
/* generate stop */
writel(MPC107_I2C_CCR_MEN, MPC107_BASE + MPC107_I2CCR);
return -1;
}
writel(0, MPC107_BASE + MPC107_I2CSR);
return 0;
}
static void
mpc107_i2c_start(struct i2c_bus *bus)
{
/* Set clock */
writel(0x1031, MPC107_BASE + MPC107_I2CFDR);
/* Clear arbitration */
writel(0, MPC107_BASE + MPC107_I2CSR);
}
static void
mpc107_i2c_stop(struct i2c_bus *bus)
{
/* After last DIMM shut down I2C */
writel(0x0, MPC107_BASE + MPC107_I2CCR);
}
static int
mpc107_i2c_byte_write(struct i2c_bus *bus, int target, int address, u8 data)
{
unsigned timeout = ticks_since_boot() + 3 * get_hz();
/* Must wait here for clocks to start */
sleep_ticks(get_hz() / 40);
/* Start with MEN */
writel(MPC107_I2C_CCR_MEN, MPC107_BASE + MPC107_I2CCR);
/* Start as master */
writel(MPC107_I2C_CCR_MEN | MPC107_I2C_CCR_MSTA | MPC107_I2C_CCR_MTX, MPC107_BASE + MPC107_I2CCR);
/* Write target byte */
writel(target, MPC107_BASE + MPC107_I2CDR);
if (i2c_wait(timeout, 1) < 0)
return -1;
/* Write data address byte */
writel(address, MPC107_BASE + MPC107_I2CDR);
if (i2c_wait(timeout, 1) < 0)
return -1;
/* Write data byte */
writel(data, MPC107_BASE + MPC107_I2CDR);
if (i2c_wait(timeout, 1) < 0)
return -1;
/* generate stop */
writel(MPC107_I2C_CCR_MEN, MPC107_BASE + MPC107_I2CCR);
return 0;
}
static int
mpc107_i2c_master_write(struct i2c_bus *bus, int target, int address, const u8 *data, int length)
{
unsigned count;
for(count = 0; count < length; count++)
{
if (mpc107_i2c_byte_write(bus, target, address, data[count]) < 0)
return -1;
}
return count;
}
#define DIMM_LENGTH 0xfff
static int
mpc107_i2c_master_read(struct i2c_bus *bus, int target, int address,
u8 *data, int length)
{
unsigned timeout = ticks_since_boot() + 3 * get_hz();
unsigned count;
/* Must wait here for clocks to start */
sleep_ticks(get_hz() / 40);
/* Start with MEN */
writel(MPC107_I2C_CCR_MEN, MPC107_BASE + MPC107_I2CCR);
/* Start as master */
writel(MPC107_I2C_CCR_MEN | MPC107_I2C_CCR_MSTA | MPC107_I2C_CCR_MTX, MPC107_BASE + MPC107_I2CCR);
/* Write target byte */
writel(target, MPC107_BASE + MPC107_I2CDR);
if (i2c_wait(timeout, 1) < 0)
return -1;
/* Write data address byte */
writel(address, MPC107_BASE + MPC107_I2CDR);
if (i2c_wait(timeout, 1) < 0)
return -1;
/* Switch to read - restart */
writel(MPC107_I2C_CCR_MEN | MPC107_I2C_CCR_MSTA | MPC107_I2C_CCR_MTX | MPC107_I2C_CCR_RSTA, MPC107_BASE + MPC107_I2CCR);
/* Write target address byte - this time with the read flag set */
writel(target | 1, MPC107_BASE + MPC107_I2CDR);
if (i2c_wait(timeout, 0) < 0)
return -1;
if (length == 1)
writel(MPC107_I2C_CCR_MEN | MPC107_I2C_CCR_MSTA | MPC107_I2C_CCR_TXAK, MPC107_BASE + MPC107_I2CCR);
else
writel(MPC107_I2C_CCR_MEN | MPC107_I2C_CCR_MSTA, MPC107_BASE + MPC107_I2CCR);
/* Dummy read */
readl(MPC107_BASE + MPC107_I2CDR);
count = 0;
while (count < length) {
if (i2c_wait(timeout, 0) < 0)
return -1;
/* Generate txack on next to last byte */
if (count == length - 2)
writel(MPC107_I2C_CCR_MEN | MPC107_I2C_CCR_MSTA | MPC107_I2C_CCR_TXAK, MPC107_BASE + MPC107_I2CCR);
/* Generate stop on last byte */
if (count == length - 1)
writel(MPC107_I2C_CCR_MEN | MPC107_I2C_CCR_TXAK, MPC107_BASE + MPC107_I2CCR);
data[count] = readl(MPC107_BASE + MPC107_I2CDR);
if (count == 0 && length == DIMM_LENGTH) {
if (data[0] == 0xff) {
printk_debug("I2C device not present\n");
length = 3;
} else {
length = data[0];
if (length < 3)
length = 3;
}
}
count++;
}
/* Finish with disable master */
writel(MPC107_I2C_CCR_MEN, MPC107_BASE + MPC107_I2CCR);
return length;
}
i2c_fn mpc107_i2c_fn = {
mpc107_i2c_start, mpc107_i2c_stop,
mpc107_i2c_master_write, mpc107_i2c_master_read
};
/*
* Find dimm information.
*/
void
hostbridge_probe_dimms(int no_dimms, sdram_dimm_info *dimms, sdram_bank_info * bank)
{
unsigned char data[256];
unsigned dimm;
printk_debug("i2c testing\n");
mpc107_i2c_start(NULL);
for(dimm = 0; dimm < no_dimms; dimm++)
{
dimms[dimm].number = dimm;
dimms[dimm].bank1 = bank + dimm*2;
dimms[dimm].bank2 = bank + dimm*2 + 1;
bank[dimm*2].size = 0;
bank[dimm*2+1].size = 0;
bank[dimm*2].number = 0;
bank[dimm*2+1].number = 1;
}
for (dimm = 0; dimm < no_dimms; dimm ++) {
unsigned limit = mpc107_i2c_master_read(NULL, 0xa0 + 2*dimm, 0,
data, DIMM_LENGTH);
if (limit > 3) {
sdram_dimm_to_bank_info(data, dimms + dimm, 0);
memcpy(dimms[dimm].part_number, data + 73, 18);
dimms[dimm].part_number[18] = 0;
printk_debug("Part Number: %s\n", dimms[dimm].part_number);
}
}
mpc107_i2c_stop(NULL);
}

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/*
* (C) Copyright 2001
* Humboldt Solutions Ltd, adrian@humboldt.co.uk.
*
* 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; either version 2 of
* the License, or (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
#ifndef _MPC107_H
#define _MPC107_H
#ifdef ASM
#define BMC_BASE 0x8000 /* Bridge memory controller base address */
#else
#define MPC107_BASE 0xfc000000
#define MPC107_EUMBBAR 0x78
#define MPC107_PIC1 0xa8
#define MPC107_PIC1_CF_MP 0x000003
#define MPC107_PIC1_SPEC_PCI 0x000004
#define MPC107_PIC1_CF_APARK 0x000008
#define MPC107_PIC1_CF_LOOP_SNOOP 0x000010
#define MPC107_PIC1_LE_MODE 0x000020
#define MPC107_PIC1_ST_GATH_EN 0x000040
#define MPC107_PIC1_NO_BUS_WIDTH_CHECK 0x000080
#define MPC107_PIC1_TEA_EN 0x000400
#define MPC107_PIC1_MCP_EN 0x000800
#define MPC107_PIC1_FLASH_WR_EN 0x001000
#define MPC107_PIC1_CF_LBA_EN 0x002000
#define MPC107_PIC1_CF_MP_ID 0x00c000
#define MPC107_PIC1_ADDRESS_MAP 0x010000
#define MPC107_PIC1_PROC_TYPE 0x050000
#define MPC107_PIC1_RCS0 0x100000
#define MPC107_PIC1_CF_BREAD_WS 0xc00000
#define MPC107_I2CADR 0x3000
#define MPC107_I2CFDR 0x3004
#define MPC107_I2CCR 0x3008
#define MPC107_I2CSR 0x300c
#define MPC107_I2CDR 0x3010
#define MPC107_I2C_CCR_MEN 0x80
#define MPC107_I2C_CCR_MIEN 0x40
#define MPC107_I2C_CCR_MSTA 0x20
#define MPC107_I2C_CCR_MTX 0x10
#define MPC107_I2C_CCR_TXAK 0x08
#define MPC107_I2C_CCR_RSTA 0x04
#define MPC107_I2C_CSR_MCF 0x80
#define MPC107_I2C_CSR_MAAS 0x40
#define MPC107_I2C_CSR_MBB 0x20
#define MPC107_I2C_CSR_MAL 0x10
#define MPC107_I2C_CSR_SRW 0x04
#define MPC107_I2C_CSR_MIF 0x02
#define MPC107_I2C_CSR_RXAK 0x01
enum sdram_error_detect {
ERRORS_NONE, ERRORS_PARITY, ERRORS_ECC
};
typedef struct sdram_dimm_info
{
unsigned size;
unsigned number;
char part_number[20];
struct sdram_bank_info *bank1;
struct sdram_bank_info *bank2;
} sdram_dimm_info;
typedef struct sdram_bank_info
{
unsigned number;
unsigned char row_bits;
unsigned char internal_banks;
unsigned char col_bits;
unsigned char data_width;
/* Cycle and access times are stored with lowest CAS latency first. Units
are 0.01ns */
unsigned short cycle_time[3];
unsigned short access_time[3];
/* Best CAS latencies */
unsigned char cas_latency[3];
unsigned char cs_latency;
unsigned char we_latency;
unsigned char min_back_to_back;
unsigned char min_row_precharge;
unsigned char min_active_to_active;
unsigned char min_ras_to_cas;
unsigned char min_ras;
unsigned char burst_mask;
enum sdram_error_detect error_detect;
/* Bank size */
unsigned size;
unsigned long start;
unsigned long end;
enum sdram_error_detect actual_detect;
unsigned char actual_cas;
} sdram_bank_info;
void sdram_dimm_to_bank_info(const char *dimm_data, sdram_dimm_info *dimm, int verbose);
void print_sdram_dimm_info(const sdram_dimm_info *dimm);
void print_sdram_bank_info(const sdram_bank_info *bank);
unsigned long hostbridge_config_memory(int no_banks, sdram_bank_info *bank, int for_real);
void hostbridge_probe_dimms(int no_dimms, sdram_dimm_info *dimm, sdram_bank_info * bank);
unsigned mpc107_config_memory(void);
#endif
#endif

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#include <pci.h>
#include "mpc107.h"
void
wait_for_other_cpus(void)
{
}
unsigned long
this_processors_id(void)
{
u32 pic1;
pcibios_read_config_dword(0, 0, MPC107_PIC1, &pic1);
return (pic1 & MPC107_PIC1_CF_MP_ID) >> 14;
}
unsigned long
processor_index(unsigned long id)
{
return id;
}
void
startup_other_cpus(unsigned long *map)
{
}

513
src/pc80/ide/ide.c Normal file
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#define BSY_SET_DURING_SPINUP 1
/*
* UBL, The Universal Talkware Boot Loader
* Copyright (C) 2000 Universal Talkware Inc.
* Copyright (C) 2002 Eric Biederman
*
* 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; either version 2 of the License, or
* (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*
*/
#include <arch/io.h>
#include <printk.h>
#include <string.h>
#include <delay.h>
#include <pci.h>
#include <pc80/ide.h>
#include <arch/io.h>
struct controller controller;
struct harddisk_info harddisk_info[NUM_HD];
static int await_ide(int (*done)(struct controller *ctrl),
struct controller *ctrl, unsigned long timeout)
{
int result;
for(;;) {
result = done(ctrl);
if (result) {
return 0;
}
if (timeout-- <= 0) {
break;
}
udelay(1000); /* Added to avoid spinning GRW */
}
return -1;
}
/* The maximum time any IDE command can last 31 seconds,
* So if any IDE commands takes this long we know we have problems.
*/
#define IDE_TIMEOUT (32*1000)
static int not_bsy(struct controller *ctrl)
{
return !(inb(IDE_REG_STATUS(ctrl)) & IDE_STATUS_BSY);
}
#if !BSY_SET_DURING_SPINUP
static int timeout(struct controller *ctrl)
{
return 0;
}
#endif
static int ide_software_reset(struct controller *ctrl)
{
/* Wait a little bit in case this is immediately after
* hardware reset.
*/
udelay(2000);
/* A software reset should not be delivered while the bsy bit
* is set. If the bsy bit does not clear in a reasonable
* amount of time give up.
*/
if (await_ide(not_bsy, ctrl, IDE_TIMEOUT) < 0) {
return -1;
}
/* Disable Interrupts and reset the ide bus */
outb(IDE_CTRL_HD15 | IDE_CTRL_SRST | IDE_CTRL_NIEN,
IDE_REG_DEVICE_CONTROL(ctrl));
udelay(5);
outb(IDE_CTRL_HD15 | IDE_CTRL_NIEN, IDE_REG_DEVICE_CONTROL(ctrl));
udelay(2000);
if (await_ide(not_bsy, ctrl, IDE_TIMEOUT) < 0) {
return -1;
}
return 0;
}
static void pio_set_registers(
struct controller *ctrl, const struct ide_pio_command *cmd)
{
uint8_t device;
/* Disable Interrupts */
outb(IDE_CTRL_HD15 | IDE_CTRL_NIEN, IDE_REG_DEVICE_CONTROL(ctrl));
/* Possibly switch selected device */
device = inb(IDE_REG_DEVICE(ctrl));
outb(cmd->device, IDE_REG_DEVICE(ctrl));
if ((device & (1UL << 4)) != (cmd->device & (1UL << 4))) {
/* Allow time for the selected drive to switch,
* The linux ide code suggests 50ms is the right
* amount of time to use here.
*/
udelay(50000);
}
outb(cmd->feature, IDE_REG_FEATURE(ctrl));
outb(cmd->sector_count2, IDE_REG_SECTOR_COUNT(ctrl));
outb(cmd->sector_count, IDE_REG_SECTOR_COUNT(ctrl));
outb(cmd->lba_low2, IDE_REG_LBA_LOW(ctrl));
outb(cmd->lba_low, IDE_REG_LBA_LOW(ctrl));
outb(cmd->lba_mid2, IDE_REG_LBA_MID(ctrl));
outb(cmd->lba_mid, IDE_REG_LBA_MID(ctrl));
outb(cmd->lba_high2, IDE_REG_LBA_HIGH(ctrl));
outb(cmd->lba_high, IDE_REG_LBA_HIGH(ctrl));
outb(cmd->command, IDE_REG_COMMAND(ctrl));
}
static int pio_non_data(struct controller *ctrl, const struct ide_pio_command *cmd)
{
/* Wait until the busy bit is clear */
if (await_ide(not_bsy, ctrl, IDE_TIMEOUT) < 0) {
return -1;
}
pio_set_registers(ctrl, cmd);
if (await_ide(not_bsy, ctrl, IDE_TIMEOUT) < 0) {
return -1;
}
/* FIXME is there more error checking I could do here? */
return 0;
}
static int pio_data_in(struct controller *ctrl, const struct ide_pio_command *cmd,
void *buffer, size_t bytes)
{
unsigned int status;
/* FIXME handle commands with multiple blocks */
/* Wait until the busy bit is clear */
if (await_ide(not_bsy, ctrl, IDE_TIMEOUT) < 0) {
return -1;
}
/* How do I tell if INTRQ is asserted? */
pio_set_registers(ctrl, cmd);
if (await_ide(not_bsy, ctrl, IDE_TIMEOUT) < 0) {
return -1;
}
status = inb(IDE_REG_STATUS(ctrl));
if (!(status & IDE_STATUS_DRQ)) {
return -1;
}
insw(IDE_REG_DATA(ctrl), buffer, bytes/2);
status = inb(IDE_REG_STATUS(ctrl));
if (status & IDE_STATUS_ERR) {
return -1;
}
return 0;
}
static inline int ide_read_sector_chs(
struct harddisk_info *info, void *buffer, unsigned long sector)
{
struct ide_pio_command cmd;
unsigned int track;
unsigned int offset;
unsigned int cylinder;
memset(&cmd, 0, sizeof(cmd));
cmd.sector_count = 1;
track = sector / info->sectors_per_track;
/* Sector number */
offset = 1 + (sector % info->sectors_per_track);
cylinder = track / info->heads;
cmd.lba_low = offset;
cmd.lba_mid = cylinder & 0xff;
cmd.lba_high = (cylinder >> 8) & 0xff;
cmd.device = IDE_DH_DEFAULT |
IDE_DH_HEAD(track % info->heads) |
info->slave |
IDE_DH_CHS;
cmd.command = IDE_CMD_READ_SECTORS;
return pio_data_in(info->ctrl, &cmd, buffer, IDE_SECTOR_SIZE);
}
static inline int ide_read_sector_lba(
struct harddisk_info *info, void *buffer, unsigned long sector)
{
struct ide_pio_command cmd;
memset(&cmd, 0, sizeof(cmd));
cmd.sector_count = 1;
cmd.lba_low = sector & 0xff;
cmd.lba_mid = (sector >> 8) & 0xff;
cmd.lba_high = (sector >> 16) & 0xff;
cmd.device = IDE_DH_DEFAULT |
((sector >> 24) & 0x0f) |
info->slave |
IDE_DH_LBA;
cmd.command = IDE_CMD_READ_SECTORS;
return pio_data_in(info->ctrl, &cmd, buffer, IDE_SECTOR_SIZE);
}
static inline int ide_read_sector_lba48(
struct harddisk_info *info, void *buffer, sector_t sector)
{
struct ide_pio_command cmd;
memset(&cmd, 0, sizeof(cmd));
cmd.sector_count = 1;
cmd.lba_low = sector & 0xff;
cmd.lba_mid = (sector >> 8) & 0xff;
cmd.lba_high = (sector >> 16) & 0xff;
cmd.lba_low2 = (sector >> 24) & 0xff;
cmd.lba_mid2 = (sector >> 32) & 0xff;
cmd.lba_high2 = (sector >> 40) & 0xff;
cmd.device = info->slave | IDE_DH_LBA;
cmd.command = IDE_CMD_READ_SECTORS_EXT;
return pio_data_in(info->ctrl, &cmd, buffer, IDE_SECTOR_SIZE);
}
int ide_read_sector(int driveno, void * buf, unsigned int sector,
int byte_offset, int n_bytes)
{
struct harddisk_info *info = &harddisk_info[driveno];
int result;
/* Report the buffer is empty */
if (sector > info->sectors) {
return -1;
}
if (info->address_mode == ADDRESS_MODE_CHS) {
result = ide_read_sector_chs(info, buf, sector);
}
else if (info->address_mode == ADDRESS_MODE_LBA) {
result = ide_read_sector_lba(info, buf, sector);
}
else if (info->address_mode == ADDRESS_MODE_LBA48) {
result = ide_read_sector_lba48(info, buf, sector);
}
else {
result = -1;
}
return result;
}
static int init_drive(struct harddisk_info *info, struct controller *ctrl, int slave, int basedrive)
{
uint16_t* drive_info;
struct ide_pio_command cmd;
unsigned char disk_buffer[DISK_BUFFER_SIZE];
int i;
info->ctrl = ctrl;
info->heads = 0u;
info->cylinders = 0u;
info->sectors_per_track = 0u;
info->address_mode = IDE_DH_CHS;
info->sectors = 0ul;
info->drive_exists = 0;
info->slave_absent = 0;
info->slave = slave?IDE_DH_SLAVE: IDE_DH_MASTER;
info->basedrive = basedrive;
printk_info("Testing for disk %d\n", info->basedrive);
/* Select the drive that we are testing */
outb(IDE_DH_DEFAULT | IDE_DH_HEAD(0) | IDE_DH_CHS | info->slave,
IDE_REG_DEVICE(ctrl));
udelay(50000);
/* Test to see if the drive registers exist,
* In many cases this quickly rules out a missing drive.
*/
for(i = 0; i < 4; i++) {
outb(0xaa + i, (ctrl->cmd_base) + 2 + i);
}
for(i = 0; i < 4; i++) {
if (inb((ctrl->cmd_base) + 2 + i) != 0xaa + i) {
return 1;
}
}
for(i = 0; i < 4; i++) {
outb(0x55 + i, (ctrl->cmd_base) + 2 + i);
}
for(i = 0; i < 4; i++) {
if (inb((ctrl->cmd_base) + 2 + i) != 0x55 + i) {
return 1;
}
}
printk_info("Probing for disk %d\n", info->basedrive);
memset(&cmd, 0, sizeof(cmd));
cmd.device = IDE_DH_DEFAULT | IDE_DH_HEAD(0) | IDE_DH_CHS | info->slave;
cmd.command = IDE_CMD_IDENTIFY_DEVICE;
if (pio_data_in(ctrl, &cmd, disk_buffer, IDE_SECTOR_SIZE) < 0) {
/* Well, if that command didn't work, we probably don't have drive. */
return 1;
}
/* Now suck the data out */
drive_info = (uint16_t *)disk_buffer;
if (drive_info[2] == 0x37C8) {
/* If the response is incomplete spin up the drive... */
memset(&cmd, 0, sizeof(cmd));
cmd.device = IDE_DH_DEFAULT | IDE_DH_HEAD(0) | IDE_DH_CHS |
info->slave;
cmd.feature = IDE_FEATURE_STANDBY_SPINUP_DRIVE;
if (pio_non_data(ctrl, &cmd) < 0) {
/* If the command doesn't work give up on the drive */
return 1;
}
}
if ((drive_info[2] == 0x37C8) || (drive_info[2] == 0x8C73)) {
/* The response is incomplete retry the drive info command */
memset(&cmd, 0, sizeof(cmd));
cmd.device = IDE_DH_DEFAULT | IDE_DH_HEAD(0) | IDE_DH_CHS |
info->slave;
cmd.command = IDE_CMD_IDENTIFY_DEVICE;
if(pio_data_in(ctrl, &cmd, disk_buffer, IDE_SECTOR_SIZE) < 0) {
/* If the command didn't work give up on the drive. */
return 1;
}
}
if ((drive_info[2] != 0x37C8) &&
(drive_info[2] != 0x738C) &&
(drive_info[2] != 0x8C73) &&
(drive_info[2] != 0xC837) &&
(drive_info[2] != 0x0000)) {
printk_info("Invalid IDE Configuration: %hx\n", drive_info[2]);
return 1;
}
for(i = 27; i < 47; i++) {
info->model_number[((i-27)<< 1)] = (drive_info[i] >> 8) & 0xff;
info->model_number[((i-27)<< 1)+1] = drive_info[i] & 0xff;
}
info->model_number[40] = '\0';
info->drive_exists = 1;
/* See if LBA is supported */
if (drive_info[49] & (1 << 9)) {
info->address_mode = ADDRESS_MODE_LBA;
info->sectors = (drive_info[61] << 16) | (drive_info[60]);
/* Enable LBA48 mode if it is present */
if (drive_info[83] & (1 <<10)) {
/* Should LBA48 depend on LBA? */
printk_info("LBA48 mode\n");
info->address_mode = ADDRESS_MODE_LBA48;
info->sectors =
(((sector_t)drive_info[103]) << 48) |
(((sector_t)drive_info[102]) << 32) |
(((sector_t)drive_info[101]) << 16) |
(((sector_t)drive_info[100]) << 0);
}
} else {
info->address_mode = ADDRESS_MODE_CHS;
info->heads = drive_info[3];
info->cylinders = drive_info[1];
info->sectors_per_track = drive_info[6];
info->sectors =
info->sectors_per_track *
info->heads *
info->cylinders;
printk_info("%s sectors_per_track=[%d], heads=[%d], cylinders=[%d]\n",
__FUNCTION__,
info->sectors_per_track,
info->heads,
info->cylinders);
}
/* See if we have a slave */
if (!info->slave && (((drive_info[93] >> 14) & 3) == 1)) {
info->slave_absent = !(drive_info[93] & (1 << 5));
}
/* See if we need to put the device in CFA power mode 1 */
if ((drive_info[160] & ((1 << 15) | (1 << 13)| (1 << 12))) ==
((1 << 15) | (1 << 13)| (1 << 12))) {
memset(&cmd, 0, sizeof(cmd));
cmd.device = IDE_DH_DEFAULT | IDE_DH_HEAD(0) | IDE_DH_CHS | info->slave;
cmd.feature = IDE_FEATURE_CFA_ENABLE_POWER_MODE1;
if (pio_non_data(ctrl, &cmd) < 0) {
/* If I need to power up the drive, and I can't
* give up.
*/
printk_info("Cannot power up CFA device\n");
return 1;
}
}
printk_info("disk%d %dk cap: %hx\n",
info->basedrive,
(unsigned long)(info->sectors >> 1),
drive_info[49]);
return 0;
}
static int init_controller(struct controller *ctrl, int basedrive)
{
struct harddisk_info *info;
/* Put the drives ide channel in a know state and wait
* for the drives to spinup.
*
* In practice IDE disks tend not to respond to commands until
* they have spun up. This makes IDE hard to deal with
* immediately after power up, as the delays can be quite
* long, so we must be very careful here.
*
* There are two pathological cases that must be dealt with:
*
* - The BSY bit not being set while the IDE drives spin up.
* In this cases only a hard coded delay will work. As
* I have not reproduced it, and this is out of spec for
* IDE drives the work around can be enabled by setting
* BSY_SET_DURING_SPINUP to 0.
*
* - The BSY bit floats high when no drives are plugged in.
* This case will not be detected except by timing out but
* we avoid the problems by only probing devices we are
* supposed to boot from. If we don't do the probe we
* will not experience the problem.
*
* So speed wise I am only slow if the BSY bit is not set
* or not reported by the IDE controller during spinup, which
* is quite rare.
*
*/
#if !BSY_SET_DURING_SPINUP
if (await_ide(timeout, ctrl, IDE_TIMEOUT) < 0) {
return -1;
}
#endif
if (ide_software_reset(ctrl) < 0) {
return -1;
}
/* Note: I have just done a software reset. It may be
* reasonable to just read the boot time signatures
* off of the drives to see if they are present.
*
* For now I will go with just sending commands to the drives
* and assuming filtering out missing drives by detecting registers
* that won't set and commands that fail to execute properly.
*/
/* Now initialize the individual drives */
info = &harddisk_info[basedrive];
init_drive(info, ctrl, 0, basedrive & 1);
/* at the moment this only works for the first drive */
#if 0
if (info->drive_exists && !info->slave_absent) {
basedrive++;
info++;
init_drive(info, ctrl, 1, basedrive & 1);
}
#endif
return 0;
}
int ide_init(void)
{
int index;
int drives = 0;
/* Intialize the harddisk_info structures */
memset(harddisk_info, 0, sizeof(harddisk_info));
for(index = 0; index < 1; index++) {
#if 0
/* IDE normal pci mode */
unsigned cmd_reg, ctrl_reg;
uint32_t cmd_base, ctrl_base;
if (index < 2) {
cmd_reg = PCI_BASE_ADDRESS_0;
ctrl_reg = PCI_BASE_ADDRESS_1;
} else {
cmd_reg = PCI_BASE_ADDRESS_2;
ctrl_reg = PCI_BASE_ADDRESS_3;
}
pcibios_read_config_dword(0, 0, cmd_reg, &cmd_base);
pcibios_read_config_dword(0, 0, ctrl_reg, &ctrl_base);
controller.cmd_base = cmd_base & ~3;
controller.ctrl_base = ctrl_base & ~3;
#endif
uint16_t base;
base = (index < 1)?IDE_BASE0:IDE_BASE1;
controller.cmd_base = base;
controller.ctrl_base = base + IDE_REG_EXTENDED_OFFSET;
printk_info("init_controller %d at (%x, %x)\n", index, controller.cmd_base, controller.ctrl_base);
if (init_controller(&controller, index << 1) < 0) {
/* nothing behind the controller */
continue;
}
drives++;
}
return drives > 0 ? 0 : -1;
}

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@ -0,0 +1,68 @@
/* $Id$ */
/* Copyright 2000 AG Electronics Ltd. */
/* This code is distributed without warranty under the GPL v2 (see COPYING) */
#include <ppc.h>
#include <ppcreg.h>
#include <types.h>
#include <string.h>
#include <pci.h>
#include <printk.h>
#define ONEMEG 0x00100000
#define HALFMEG 0x00080000
unsigned long memory_base = 0;
unsigned long memory_top = 0;
unsigned long memory_size = 0;
//extern char __heap_end[];
extern unsigned mpc107_config_memory(void);
unsigned config_memory(unsigned offset)
{
//extern char __start[];
//extern char __bss_start[];
//unsigned rom_image = (unsigned) __start & 0xfff00000;
//unsigned physical = rom_image + offset;
//unsigned codesize = (unsigned) __bss_start - rom_image;
#if 0
/* At this point, DBAT 0 is memory, 1 is variable, 2 is the rom image,
and 3 is IO. */
ppc_set_io_dbat_reloc(2, rom_image, physical, ONEMEG);
ppc_set_io_dbat (3, 0xf0000000, 0x10000000);
if ( rom_image != physical )
ppc_set_ibats_reloc(rom_image, physical, ONEMEG);
else
ppc_set_ibats(physical, ONEMEG);
printk_debug("bsp_init_memory...\n");
#endif
ppc_setup_cpu(1); /* icache enable = 1 */
//ppc_enable_mmu();
memory_size = mpc107_config_memory();
/* If we have some working RAM, we copy the code and rodata into it.
* This allows us to reprogram the flash later. */
#if 0
if (memory_size)
{
unsigned onemeg = memory_size - ONEMEG;
ppc_set_mem_dbat_reloc(1, onemeg, onemeg, ONEMEG);
memcpy((void *)onemeg, (void *)rom_image, codesize);
memset((void *)(onemeg + codesize), 0, ONEMEG - codesize);
ppc_set_ibats_reloc2(rom_image, physical, onemeg, ONEMEG);
ppc_set_mem_dbat_reloc(2, rom_image, onemeg, ONEMEG);
make_coherent((void *)onemeg, ONEMEG);
}
ppc_set_memory_dbat (memory_size);
#endif
//ppc_enable_dcache ();
return memory_size;
}