android_kernel_xiaomi_sm8350/arch/powerpc/boot/cuboot-pq2.c
David Gibson 2f0dfeaa84 [POWERPC] Use embedded libfdt in the bootwrapper
This incorporates libfdt (from the source embedded in an earlier
commit) into the wrapper.a library used by the bootwrapper.  This
includes adding a libfdt_env.h file, which the libfdt sources need in
order to integrate into the bootwrapper environment, and a
libfdt-wrapper.c which provides glue to connect the bootwrapper's
abstract device tree callbacks to the libfdt functions.

In addition, this changes the various wrapper and platform files to
use libfdt functions instead of the older flatdevtree.c library.

Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
Signed-off-by: Paul Mackerras <paulus@samba.org>
2007-12-11 13:46:14 +11:00

262 lines
6.6 KiB
C

/*
* Old U-boot compatibility for PowerQUICC II
* (a.k.a. 82xx with CPM, not the 8240 family of chips)
*
* Author: Scott Wood <scottwood@freescale.com>
*
* Copyright (c) 2007 Freescale Semiconductor, Inc.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 as published
* by the Free Software Foundation.
*/
#include "ops.h"
#include "stdio.h"
#include "cuboot.h"
#include "io.h"
#include "fsl-soc.h"
#define TARGET_CPM2
#define TARGET_HAS_ETH1
#include "ppcboot.h"
static bd_t bd;
struct cs_range {
u32 csnum;
u32 base; /* must be zero */
u32 addr;
u32 size;
};
struct pci_range {
u32 flags;
u32 pci_addr[2];
u32 phys_addr;
u32 size[2];
};
struct cs_range cs_ranges_buf[MAX_PROP_LEN / sizeof(struct cs_range)];
struct pci_range pci_ranges_buf[MAX_PROP_LEN / sizeof(struct pci_range)];
/* Different versions of u-boot put the BCSR in different places, and
* some don't set up the PCI PIC at all, so we assume the device tree is
* sane and update the BRx registers appropriately.
*
* For any node defined as compatible with fsl,pq2-localbus,
* #address/#size must be 2/1 for the localbus, and 1/1 for the parent bus.
* Ranges must be for whole chip selects.
*/
static void update_cs_ranges(void)
{
void *bus_node, *parent_node;
u32 *ctrl_addr;
unsigned long ctrl_size;
u32 naddr, nsize;
int len;
int i;
bus_node = finddevice("/localbus");
if (!bus_node || !dt_is_compatible(bus_node, "fsl,pq2-localbus"))
return;
dt_get_reg_format(bus_node, &naddr, &nsize);
if (naddr != 2 || nsize != 1)
goto err;
parent_node = get_parent(bus_node);
if (!parent_node)
goto err;
dt_get_reg_format(parent_node, &naddr, &nsize);
if (naddr != 1 || nsize != 1)
goto err;
if (!dt_xlate_reg(bus_node, 0, (unsigned long *)&ctrl_addr,
&ctrl_size))
goto err;
len = getprop(bus_node, "ranges", cs_ranges_buf, sizeof(cs_ranges_buf));
for (i = 0; i < len / sizeof(struct cs_range); i++) {
u32 base, option;
int cs = cs_ranges_buf[i].csnum;
if (cs >= ctrl_size / 8)
goto err;
if (cs_ranges_buf[i].base != 0)
goto err;
base = in_be32(&ctrl_addr[cs * 2]);
/* If CS is already valid, use the existing flags.
* Otherwise, guess a sane default.
*/
if (base & 1) {
base &= 0x7fff;
option = in_be32(&ctrl_addr[cs * 2 + 1]) & 0x7fff;
} else {
base = 0x1801;
option = 0x10;
}
out_be32(&ctrl_addr[cs * 2], 0);
out_be32(&ctrl_addr[cs * 2 + 1],
option | ~(cs_ranges_buf[i].size - 1));
out_be32(&ctrl_addr[cs * 2], base | cs_ranges_buf[i].addr);
}
return;
err:
printf("Bad /localbus node\r\n");
}
/* Older u-boots don't set PCI up properly. Update the hardware to match
* the device tree. The prefetch mem region and non-prefetch mem region
* must be contiguous in the host bus. As required by the PCI binding,
* PCI #addr/#size must be 3/2. The parent bus must be 1/1. Only
* 32-bit PCI is supported. All three region types (prefetchable mem,
* non-prefetchable mem, and I/O) must be present.
*/
static void fixup_pci(void)
{
struct pci_range *mem = NULL, *mmio = NULL,
*io = NULL, *mem_base = NULL;
u32 *pci_regs[3];
u8 *soc_regs;
int i, len;
void *node, *parent_node;
u32 naddr, nsize, mem_log2;
node = finddevice("/pci");
if (!node || !dt_is_compatible(node, "fsl,pq2-pci"))
return;
for (i = 0; i < 3; i++)
if (!dt_xlate_reg(node, i,
(unsigned long *)&pci_regs[i], NULL))
goto err;
soc_regs = (u8 *)fsl_get_immr();
if (!soc_regs)
goto err;
dt_get_reg_format(node, &naddr, &nsize);
if (naddr != 3 || nsize != 2)
goto err;
parent_node = get_parent(node);
if (!parent_node)
goto err;
dt_get_reg_format(parent_node, &naddr, &nsize);
if (naddr != 1 || nsize != 1)
goto err;
len = getprop(node, "ranges", pci_ranges_buf,
sizeof(pci_ranges_buf));
for (i = 0; i < len / sizeof(struct pci_range); i++) {
u32 flags = pci_ranges_buf[i].flags & 0x43000000;
if (flags == 0x42000000)
mem = &pci_ranges_buf[i];
else if (flags == 0x02000000)
mmio = &pci_ranges_buf[i];
else if (flags == 0x01000000)
io = &pci_ranges_buf[i];
}
if (!mem || !mmio || !io)
goto err;
if (mem->phys_addr + mem->size[1] == mmio->phys_addr)
mem_base = mem;
else if (mmio->phys_addr + mmio->size[1] == mem->phys_addr)
mem_base = mmio;
else
goto err;
out_be32(&pci_regs[1][0], mem_base->phys_addr | 1);
out_be32(&pci_regs[2][0], ~(mem->size[1] + mmio->size[1] - 1));
out_be32(&pci_regs[1][1], io->phys_addr | 1);
out_be32(&pci_regs[2][1], ~(io->size[1] - 1));
out_le32(&pci_regs[0][0], mem->pci_addr[1] >> 12);
out_le32(&pci_regs[0][2], mem->phys_addr >> 12);
out_le32(&pci_regs[0][4], (~(mem->size[1] - 1) >> 12) | 0xa0000000);
out_le32(&pci_regs[0][6], mmio->pci_addr[1] >> 12);
out_le32(&pci_regs[0][8], mmio->phys_addr >> 12);
out_le32(&pci_regs[0][10], (~(mmio->size[1] - 1) >> 12) | 0x80000000);
out_le32(&pci_regs[0][12], io->pci_addr[1] >> 12);
out_le32(&pci_regs[0][14], io->phys_addr >> 12);
out_le32(&pci_regs[0][16], (~(io->size[1] - 1) >> 12) | 0xc0000000);
/* Inbound translation */
out_le32(&pci_regs[0][58], 0);
out_le32(&pci_regs[0][60], 0);
mem_log2 = 1 << (__ilog2_u32(bd.bi_memsize - 1) + 1);
out_le32(&pci_regs[0][62], 0xa0000000 | ~((1 << (mem_log2 - 12)) - 1));
/* If PCI is disabled, drive RST high to enable. */
if (!(in_le32(&pci_regs[0][32]) & 1)) {
/* Tpvrh (Power valid to RST# high) 100 ms */
udelay(100000);
out_le32(&pci_regs[0][32], 1);
/* Trhfa (RST# high to first cfg access) 2^25 clocks */
udelay(1020000);
}
/* Enable bus master and memory access */
out_le32(&pci_regs[0][64], 0x80000004);
out_le32(&pci_regs[0][65], in_le32(&pci_regs[0][65]) | 6);
/* Park the bus on PCI, and elevate PCI's arbitration priority,
* as required by section 9.6 of the user's manual.
*/
out_8(&soc_regs[0x10028], 3);
out_be32((u32 *)&soc_regs[0x1002c], 0x01236745);
return;
err:
printf("Bad PCI node\r\n");
}
static void pq2_platform_fixups(void)
{
void *node;
dt_fixup_memory(bd.bi_memstart, bd.bi_memsize);
dt_fixup_mac_addresses(bd.bi_enetaddr, bd.bi_enet1addr);
dt_fixup_cpu_clocks(bd.bi_intfreq, bd.bi_busfreq / 4, bd.bi_busfreq);
node = finddevice("/soc/cpm");
if (node)
setprop(node, "clock-frequency", &bd.bi_cpmfreq, 4);
node = finddevice("/soc/cpm/brg");
if (node)
setprop(node, "clock-frequency", &bd.bi_brgfreq, 4);
update_cs_ranges();
fixup_pci();
}
void platform_init(unsigned long r3, unsigned long r4, unsigned long r5,
unsigned long r6, unsigned long r7)
{
CUBOOT_INIT();
fdt_init(_dtb_start);
serial_console_init();
platform_ops.fixups = pq2_platform_fixups;
}