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/*
* This file is part of wl1271
*
* Copyright (C) 2008-2010 Nokia Corporation
*
* Contact: Luciano Coelho <luciano.coelho@nokia.com>
*
* 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.
*
* 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., 51 Franklin St, Fifth Floor, Boston, MA
* 02110-1301 USA
*
*/
#include <linux/module.h>
#include <linux/platform_device.h>
#include <linux/crc7.h>
#include <linux/spi/spi.h>
#include "wl1271.h"
#include "wl12xx_80211.h"
#include "wl1271_spi.h"
#include "wl1271_io.h"
static int wl1271_translate_addr(struct wl1271 *wl, int addr)
{
/*
* To translate, first check to which window of addresses the
* particular address belongs. Then subtract the starting address
* of that window from the address. Then, add offset of the
* translated region.
*
* The translated regions occur next to each other in physical device
* memory, so just add the sizes of the preceeding address regions to
* get the offset to the new region.
*
* Currently, only the two first regions are addressed, and the
* assumption is that all addresses will fall into either of those
* two.
*/
if ((addr >= wl->part.reg.start) &&
(addr < wl->part.reg.start + wl->part.reg.size))
return addr - wl->part.reg.start + wl->part.mem.size;
else
return addr - wl->part.mem.start;
}
/* Set the SPI partitions to access the chip addresses
*
* To simplify driver code, a fixed (virtual) memory map is defined for
* register and memory addresses. Because in the chipset, in different stages
* of operation, those addresses will move around, an address translation
* mechanism is required.
*
* There are four partitions (three memory and one register partition),
* which are mapped to two different areas of the hardware memory.
*
* Virtual address
* space
*
* | |
* ...+----+--> mem.start
* Physical address ... | |
* space ... | | [PART_0]
* ... | |
* 00000000 <--+----+... ...+----+--> mem.start + mem.size
* | | ... | |
* |MEM | ... | |
* | | ... | |
* mem.size <--+----+... | | {unused area)
* | | ... | |
* |REG | ... | |
* mem.size | | ... | |
* + <--+----+... ...+----+--> reg.start
* reg.size | | ... | |
* |MEM2| ... | | [PART_1]
* | | ... | |
* ...+----+--> reg.start + reg.size
* | |
*
*/
int wl1271_set_partition(struct wl1271 *wl,
struct wl1271_partition_set *p)
{
/* copy partition info */
memcpy(&wl->part, p, sizeof(*p));
wl1271_debug(DEBUG_SPI, "mem_start %08X mem_size %08X",
p->mem.start, p->mem.size);
wl1271_debug(DEBUG_SPI, "reg_start %08X reg_size %08X",
p->reg.start, p->reg.size);
wl1271_debug(DEBUG_SPI, "mem2_start %08X mem2_size %08X",
p->mem2.start, p->mem2.size);
wl1271_debug(DEBUG_SPI, "mem3_start %08X mem3_size %08X",
p->mem3.start, p->mem3.size);
/* write partition info to the chipset */
wl1271_raw_write32(wl, HW_PART0_START_ADDR, p->mem.start);
wl1271_raw_write32(wl, HW_PART0_SIZE_ADDR, p->mem.size);
wl1271_raw_write32(wl, HW_PART1_START_ADDR, p->reg.start);
wl1271_raw_write32(wl, HW_PART1_SIZE_ADDR, p->reg.size);
wl1271_raw_write32(wl, HW_PART2_START_ADDR, p->mem2.start);
wl1271_raw_write32(wl, HW_PART2_SIZE_ADDR, p->mem2.size);
wl1271_raw_write32(wl, HW_PART3_START_ADDR, p->mem3.start);
return 0;
}
void wl1271_io_reset(struct wl1271 *wl)
{
wl1271_spi_reset(wl);
}
void wl1271_io_init(struct wl1271 *wl)
{
wl1271_spi_init(wl);
}
void wl1271_raw_write(struct wl1271 *wl, int addr, void *buf,
size_t len, bool fixed)
{
wl1271_spi_raw_write(wl, addr, buf, len, fixed);
}
void wl1271_raw_read(struct wl1271 *wl, int addr, void *buf,
size_t len, bool fixed)
{
wl1271_spi_raw_read(wl, addr, buf, len, fixed);
}
void wl1271_read(struct wl1271 *wl, int addr, void *buf, size_t len,
bool fixed)
{
int physical;
physical = wl1271_translate_addr(wl, addr);
wl1271_spi_raw_read(wl, physical, buf, len, fixed);
}
void wl1271_write(struct wl1271 *wl, int addr, void *buf, size_t len,
bool fixed)
{
int physical;
physical = wl1271_translate_addr(wl, addr);
wl1271_spi_raw_write(wl, physical, buf, len, fixed);
}
u32 wl1271_read32(struct wl1271 *wl, int addr)
{
return wl1271_raw_read32(wl, wl1271_translate_addr(wl, addr));
}
void wl1271_write32(struct wl1271 *wl, int addr, u32 val)
{
wl1271_raw_write32(wl, wl1271_translate_addr(wl, addr), val);
}
void wl1271_top_reg_write(struct wl1271 *wl, int addr, u16 val)
{
/* write address >> 1 + 0x30000 to OCP_POR_CTR */
addr = (addr >> 1) + 0x30000;
wl1271_write32(wl, OCP_POR_CTR, addr);
/* write value to OCP_POR_WDATA */
wl1271_write32(wl, OCP_DATA_WRITE, val);
/* write 1 to OCP_CMD */
wl1271_write32(wl, OCP_CMD, OCP_CMD_WRITE);
}
u16 wl1271_top_reg_read(struct wl1271 *wl, int addr)
{
u32 val;
int timeout = OCP_CMD_LOOP;
/* write address >> 1 + 0x30000 to OCP_POR_CTR */
addr = (addr >> 1) + 0x30000;
wl1271_write32(wl, OCP_POR_CTR, addr);
/* write 2 to OCP_CMD */
wl1271_write32(wl, OCP_CMD, OCP_CMD_READ);
/* poll for data ready */
do {
val = wl1271_read32(wl, OCP_DATA_READ);
} while (!(val & OCP_READY_MASK) && --timeout);
if (!timeout) {
wl1271_warning("Top register access timed out.");
return 0xffff;
}
/* check data status and return if OK */
if ((val & OCP_STATUS_MASK) == OCP_STATUS_OK)
return val & 0xffff;
else {
wl1271_warning("Top register access returned error.");
return 0xffff;
}
}
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