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/*
* (C) Copyright 2007
* Matthias Fuchs, esd gmbh, matthias.fuchs@esd-electronics.com.
*
* 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
*/
#include <common.h>
#include <asm/io.h>
#include <spartan2.h>
#include <spartan3.h>
#include <command.h>
#include "fpga.h"
#include "pmc440.h"
DECLARE_GLOBAL_DATA_PTR;
#if defined(CONFIG_FPGA)
#define USE_SP_CODE
#ifdef USE_SP_CODE
Xilinx_Spartan3_Slave_Parallel_fns pmc440_fpga_fns = {
fpga_pre_config_fn,
fpga_pgm_fn,
fpga_init_fn,
NULL, /* err */
fpga_done_fn,
fpga_clk_fn,
fpga_cs_fn,
fpga_wr_fn,
NULL, /* rdata */
fpga_wdata_fn,
fpga_busy_fn,
fpga_abort_fn,
fpga_post_config_fn,
};
#else
Xilinx_Spartan3_Slave_Serial_fns pmc440_fpga_fns = {
fpga_pre_config_fn,
fpga_pgm_fn,
fpga_clk_fn,
fpga_init_fn,
fpga_done_fn,
fpga_wr_fn,
fpga_post_config_fn,
};
#endif
Xilinx_Spartan2_Slave_Serial_fns ngcc_fpga_fns = {
ngcc_fpga_pre_config_fn,
ngcc_fpga_pgm_fn,
ngcc_fpga_clk_fn,
ngcc_fpga_init_fn,
ngcc_fpga_done_fn,
ngcc_fpga_wr_fn,
ngcc_fpga_post_config_fn
};
Xilinx_desc fpga[CONFIG_FPGA_COUNT] = {
XILINX_XC3S1200E_DESC(
#ifdef USE_SP_CODE
slave_parallel,
#else
slave_serial,
#endif
(void *)&pmc440_fpga_fns,
0),
XILINX_XC2S200_DESC(
slave_serial,
(void *)&ngcc_fpga_fns,
0)
};
/*
* Set the active-low FPGA reset signal.
*/
void fpga_reset(int assert)
{
debug("%s:%d: RESET ", __FUNCTION__, __LINE__);
if (assert) {
out_be32((void*)GPIO1_OR, in_be32((void*)GPIO1_OR) & ~GPIO1_FPGA_DATA);
debug("asserted\n");
} else {
out_be32((void*)GPIO1_OR, in_be32((void*)GPIO1_OR) | GPIO1_FPGA_DATA);
debug("deasserted\n");
}
}
/*
* Initialize the SelectMap interface. We assume that the mode and the
* initial state of all of the port pins have already been set!
*/
void fpga_serialslave_init(void)
{
debug("%s:%d: Initialize serial slave interface\n", __FUNCTION__,
__LINE__);
fpga_pgm_fn(false, false, 0); /* make sure program pin is inactive */
}
/*
* Set the FPGA's active-low SelectMap program line to the specified level
*/
int fpga_pgm_fn(int assert, int flush, int cookie)
{
debug("%s:%d: FPGA PROGRAM ",
__FUNCTION__, __LINE__);
if (assert) {
out_be32((void*)GPIO1_OR, in_be32((void*)GPIO1_OR) & ~GPIO1_FPGA_PRG);
debug("asserted\n");
} else {
out_be32((void*)GPIO1_OR, in_be32((void*)GPIO1_OR) | GPIO1_FPGA_PRG);
debug("deasserted\n");
}
return assert;
}
/*
* Test the state of the active-low FPGA INIT line. Return 1 on INIT
* asserted (low).
*/
int fpga_init_fn(int cookie)
{
if (in_be32((void*)GPIO1_IR) & GPIO1_FPGA_INIT)
return 0;
else
return 1;
}
#ifdef USE_SP_CODE
int fpga_abort_fn(int cookie)
{
return 0;
}
int fpga_cs_fn(int assert_cs, int flush, int cookie)
{
return assert_cs;
}
int fpga_busy_fn(int cookie)
{
return 1;
}
#endif
/*
* Test the state of the active-high FPGA DONE pin
*/
int fpga_done_fn(int cookie)
{
if (in_be32((void*)GPIO1_IR) & GPIO1_FPGA_DONE)
return 1;
else
return 0;
}
/*
* FPGA pre-configuration function. Just make sure that
* FPGA reset is asserted to keep the FPGA from starting up after
* configuration.
*/
int fpga_pre_config_fn(int cookie)
{
debug("%s:%d: FPGA pre-configuration\n", __FUNCTION__, __LINE__);
fpga_reset(true);
/* release init# */
out_be32((void*)GPIO0_OR, in_be32((void*)GPIO0_OR) | GPIO0_FPGA_FORCEINIT);
/* disable PLD IOs */
out_be32((void*)GPIO1_OR, in_be32((void*)GPIO1_OR) | GPIO1_IOEN_N);
return 0;
}
/*
* FPGA post configuration function. Blip the FPGA reset line and then see if
* the FPGA appears to be running.
*/
int fpga_post_config_fn(int cookie)
{
pmc440_fpga_t *fpga = (pmc440_fpga_t *)FPGA_BA;
int rc=0;
char *s;
debug("%s:%d: FPGA post configuration\n", __FUNCTION__, __LINE__);
/* enable PLD0..7 pins */
out_be32((void*)GPIO1_OR, in_be32((void*)GPIO1_OR) & ~GPIO1_IOEN_N);
fpga_reset(true);
udelay (100);
fpga_reset(false);
udelay (100);
FPGA_OUT32(&fpga->status, (gd->board_type << STATUS_HWREV_SHIFT) & STATUS_HWREV_MASK);
/* NGCC/CANDES only: enable ledlink */
if ((s = getenv("bd_type")) &&
((!strcmp(s, "ngcc")) || (!strcmp(s, "candes"))))
FPGA_SETBITS(&fpga->ctrla, 0x29f8c000);
return rc;
}
int fpga_clk_fn(int assert_clk, int flush, int cookie)
{
if (assert_clk)
out_be32((void*)GPIO1_OR, in_be32((void*)GPIO1_OR) | GPIO1_FPGA_CLK);
else
out_be32((void*)GPIO1_OR, in_be32((void*)GPIO1_OR) & ~GPIO1_FPGA_CLK);
return assert_clk;
}
int fpga_wr_fn(int assert_write, int flush, int cookie)
{
if (assert_write)
out_be32((void*)GPIO1_OR, in_be32((void*)GPIO1_OR) | GPIO1_FPGA_DATA);
else
out_be32((void*)GPIO1_OR, in_be32((void*)GPIO1_OR) & ~GPIO1_FPGA_DATA);
return assert_write;
}
#ifdef USE_SP_CODE
int fpga_wdata_fn(uchar data, int flush, int cookie)
{
uchar val = data;
ulong or = in_be32((void*)GPIO1_OR);
int i = 7;
do {
/* Write data */
if (val & 0x80)
or = (or & ~GPIO1_FPGA_CLK) | GPIO1_FPGA_DATA;
else
or = or & ~(GPIO1_FPGA_CLK | GPIO1_FPGA_DATA);
out_be32((void*)GPIO1_OR, or);
/* Assert the clock */
or |= GPIO1_FPGA_CLK;
out_be32((void*)GPIO1_OR, or);
val <<= 1;
i --;
} while (i > 0);
/* Write last data bit (the 8th clock comes from the sp_load() code */
if (val & 0x80)
or = (or & ~GPIO1_FPGA_CLK) | GPIO1_FPGA_DATA;
else
or = or & ~(GPIO1_FPGA_CLK | GPIO1_FPGA_DATA);
out_be32((void*)GPIO1_OR, or);
return 0;
}
#endif
#define NGCC_FPGA_PRG CLOCK_EN
#define NGCC_FPGA_DATA RESET_OUT
#define NGCC_FPGA_DONE CLOCK_IN
#define NGCC_FPGA_INIT IRIGB_R_IN
#define NGCC_FPGA_CLK CLOCK_OUT
void ngcc_fpga_serialslave_init(void)
{
debug("%s:%d: Initialize serial slave interface\n",
__FUNCTION__, __LINE__);
/* make sure program pin is inactive */
ngcc_fpga_pgm_fn(false, false, 0);
}
/*
* Set the active-low FPGA reset signal.
*/
void ngcc_fpga_reset(int assert)
{
debug("%s:%d: RESET ", __FUNCTION__, __LINE__);
if (assert) {
FPGA_CLRBITS(NGCC_CTRL_BASE, NGCC_CTRL_FPGARST_N);
debug("asserted\n");
} else {
FPGA_SETBITS(NGCC_CTRL_BASE, NGCC_CTRL_FPGARST_N);
debug("deasserted\n");
}
}
/*
* Set the FPGA's active-low SelectMap program line to the specified level
*/
int ngcc_fpga_pgm_fn(int assert, int flush, int cookie)
{
pmc440_fpga_t *fpga = (pmc440_fpga_t *)FPGA_BA;
debug("%s:%d: FPGA PROGRAM ", __FUNCTION__, __LINE__);
if (assert) {
FPGA_CLRBITS(&fpga->ctrla, NGCC_FPGA_PRG);
debug("asserted\n");
} else {
FPGA_SETBITS(&fpga->ctrla, NGCC_FPGA_PRG);
debug("deasserted\n");
}
return assert;
}
/*
* Test the state of the active-low FPGA INIT line. Return 1 on INIT
* asserted (low).
*/
int ngcc_fpga_init_fn(int cookie)
{
pmc440_fpga_t *fpga = (pmc440_fpga_t *)FPGA_BA;
debug("%s:%d: INIT check... ", __FUNCTION__, __LINE__);
if (FPGA_IN32(&fpga->status) & NGCC_FPGA_INIT) {
debug("high\n");
return 0;
} else {
debug("low\n");
return 1;
}
}
/*
* Test the state of the active-high FPGA DONE pin
*/
int ngcc_fpga_done_fn(int cookie)
{
pmc440_fpga_t *fpga = (pmc440_fpga_t *)FPGA_BA;
debug("%s:%d: DONE check... ", __FUNCTION__, __LINE__);
if (FPGA_IN32(&fpga->status) & NGCC_FPGA_DONE) {
debug("DONE high\n");
return 1;
} else {
debug("low\n");
return 0;
}
}
/*
* FPGA pre-configuration function.
*/
int ngcc_fpga_pre_config_fn(int cookie)
{
pmc440_fpga_t *fpga = (pmc440_fpga_t *)FPGA_BA;
debug("%s:%d: FPGA pre-configuration\n", __FUNCTION__, __LINE__);
ngcc_fpga_reset(true);
FPGA_CLRBITS(&fpga->ctrla, 0xfffffe00);
ngcc_fpga_reset(true);
return 0;
}
/*
* FPGA post configuration function. Blip the FPGA reset line and then see if
* the FPGA appears to be running.
*/
int ngcc_fpga_post_config_fn(int cookie)
{
pmc440_fpga_t *fpga = (pmc440_fpga_t *)FPGA_BA;
debug("%s:%d: NGCC FPGA post configuration\n", __FUNCTION__, __LINE__);
udelay (100);
ngcc_fpga_reset(false);
FPGA_SETBITS(&fpga->ctrla, 0x29f8c000);
return 0;
}
int ngcc_fpga_clk_fn(int assert_clk, int flush, int cookie)
{
pmc440_fpga_t *fpga = (pmc440_fpga_t *)FPGA_BA;
if (assert_clk)
FPGA_SETBITS(&fpga->ctrla, NGCC_FPGA_CLK);
else
FPGA_CLRBITS(&fpga->ctrla, NGCC_FPGA_CLK);
return assert_clk;
}
int ngcc_fpga_wr_fn(int assert_write, int flush, int cookie)
{
pmc440_fpga_t *fpga = (pmc440_fpga_t *)FPGA_BA;
if (assert_write)
FPGA_SETBITS(&fpga->ctrla, NGCC_FPGA_DATA);
else
FPGA_CLRBITS(&fpga->ctrla, NGCC_FPGA_DATA);
return assert_write;
}
/*
* Initialize the fpga. Return 1 on success, 0 on failure.
*/
int pmc440_init_fpga(void)
{
char *s;
debug("%s:%d: Initialize FPGA interface\n",
__FUNCTION__, __LINE__);
fpga_init();
fpga_serialslave_init ();
debug("%s:%d: Adding fpga 0\n", __FUNCTION__, __LINE__);
fpga_add (fpga_xilinx, &fpga[0]);
/* NGCC only */
if ((s = getenv("bd_type")) && !strcmp(s, "ngcc")) {
ngcc_fpga_serialslave_init ();
debug("%s:%d: Adding fpga 1\n", __FUNCTION__, __LINE__);
fpga_add (fpga_xilinx, &fpga[1]);
}
return 0;
}
#endif /* CONFIG_FPGA */