linux_dsm_epyc7002/arch/ppc/boot/simple/mv64x60_tty.c
Lee Nicks 3acb23440f [PATCH] ppc32: add support for Marvell EV64360BP board
This patch adds support for Marvell EV64360BP board.  So far, it supports
mpsc serial console, gigabit ethernet, jffs2 root filesystem, etc.  Other
device support, like watchdog, RTC, will be added later.

Signed-off-by: Lee Nicks <allinux@gmail.com>
Signed-off-by: Andrew Morton <akpm@osdl.org>
Signed-off-by: Linus Torvalds <torvalds@osdl.org>
2005-09-05 00:05:59 -07:00

368 lines
9.8 KiB
C

/*
* arch/ppc/boot/simple/mv64x60_tty.c
*
* Bootloader version of the embedded MPSC/UART driver for the Marvell 64x60.
* Note: Due to a GT64260A erratum, DMA will be used for UART input (via SDMA).
*
* Author: Mark A. Greer <mgreer@mvista.com>
*
* 2001 (c) MontaVista Software, Inc. This file is licensed under
* the terms of the GNU General Public License version 2. This program
* is licensed "as is" without any warranty of any kind, whether express
* or implied.
*/
/* This code assumes that the data cache has been disabled (L1, L2, L3). */
#include <linux/config.h>
#include <linux/types.h>
#include <linux/serial_reg.h>
#include <asm/serial.h>
#include <asm/io.h>
#include <asm/mv64x60_defs.h>
#include <mpsc_defs.h>
#ifdef CONFIG_EV64360
#include <platforms/ev64360.h>
u32 mv64x60_console_baud = EV64360_DEFAULT_BAUD;
u32 mv64x60_mpsc_clk_src = EV64360_MPSC_CLK_SRC; /* TCLK */
u32 mv64x60_mpsc_clk_freq = EV64360_MPSC_CLK_FREQ;
#else
u32 mv64x60_console_baud = 9600;
u32 mv64x60_mpsc_clk_src = 8; /* TCLK */
u32 mv64x60_mpsc_clk_freq = 100000000;
#endif
extern void udelay(long);
static void stop_dma(int chan);
static void __iomem *mv64x60_base = (void __iomem *)CONFIG_MV64X60_NEW_BASE;
struct sdma_regs {
u32 sdc;
u32 sdcm;
u32 rx_desc;
u32 rx_buf_ptr;
u32 scrdp;
u32 tx_desc;
u32 sctdp;
u32 sftdp;
};
static struct sdma_regs sdma_regs[2];
#define SDMA_REGS_INIT(s, reg_base) { \
(s)->sdc = (reg_base) + SDMA_SDC; \
(s)->sdcm = (reg_base) + SDMA_SDCM; \
(s)->rx_desc = (reg_base) + SDMA_RX_DESC; \
(s)->rx_buf_ptr = (reg_base) + SDMA_RX_BUF_PTR; \
(s)->scrdp = (reg_base) + SDMA_SCRDP; \
(s)->tx_desc = (reg_base) + SDMA_TX_DESC; \
(s)->sctdp = (reg_base) + SDMA_SCTDP; \
(s)->sftdp = (reg_base) + SDMA_SFTDP; \
}
static u32 mpsc_base[2] = { MV64x60_MPSC_0_OFFSET, MV64x60_MPSC_1_OFFSET };
struct mv64x60_rx_desc {
u16 bufsize;
u16 bytecnt;
u32 cmd_stat;
u32 next_desc_ptr;
u32 buffer;
};
struct mv64x60_tx_desc {
u16 bytecnt;
u16 shadow;
u32 cmd_stat;
u32 next_desc_ptr;
u32 buffer;
};
#define MAX_RESET_WAIT 10000
#define MAX_TX_WAIT 10000
#define RX_NUM_DESC 2
#define TX_NUM_DESC 2
#define RX_BUF_SIZE 32
#define TX_BUF_SIZE 32
static struct mv64x60_rx_desc rd[2][RX_NUM_DESC] __attribute__ ((aligned(32)));
static struct mv64x60_tx_desc td[2][TX_NUM_DESC] __attribute__ ((aligned(32)));
static char rx_buf[2][RX_NUM_DESC * RX_BUF_SIZE] __attribute__ ((aligned(32)));
static char tx_buf[2][TX_NUM_DESC * TX_BUF_SIZE] __attribute__ ((aligned(32)));
static int cur_rd[2] = { 0, 0 };
static int cur_td[2] = { 0, 0 };
static char chan_initialized[2] = { 0, 0 };
#define RX_INIT_RDP(rdp) { \
(rdp)->bufsize = 2; \
(rdp)->bytecnt = 0; \
(rdp)->cmd_stat = SDMA_DESC_CMDSTAT_L | SDMA_DESC_CMDSTAT_F | \
SDMA_DESC_CMDSTAT_O; \
}
#ifdef CONFIG_MV64360
static u32 cpu2mem_tab[MV64x60_CPU2MEM_WINDOWS][2] = {
{ MV64x60_CPU2MEM_0_BASE, MV64x60_CPU2MEM_0_SIZE },
{ MV64x60_CPU2MEM_1_BASE, MV64x60_CPU2MEM_1_SIZE },
{ MV64x60_CPU2MEM_2_BASE, MV64x60_CPU2MEM_2_SIZE },
{ MV64x60_CPU2MEM_3_BASE, MV64x60_CPU2MEM_3_SIZE }
};
static u32 com2mem_tab[MV64x60_CPU2MEM_WINDOWS][2] = {
{ MV64360_MPSC2MEM_0_BASE, MV64360_MPSC2MEM_0_SIZE },
{ MV64360_MPSC2MEM_1_BASE, MV64360_MPSC2MEM_1_SIZE },
{ MV64360_MPSC2MEM_2_BASE, MV64360_MPSC2MEM_2_SIZE },
{ MV64360_MPSC2MEM_3_BASE, MV64360_MPSC2MEM_3_SIZE }
};
static u32 dram_selects[MV64x60_CPU2MEM_WINDOWS] = { 0xe, 0xd, 0xb, 0x7 };
#endif
unsigned long
serial_init(int chan, void *ignored)
{
u32 mpsc_routing_base, sdma_base, brg_bcr, cdv;
int i;
chan = (chan == 1); /* default to chan 0 if anything but 1 */
if (chan_initialized[chan])
return chan;
chan_initialized[chan] = 1;
if (chan == 0) {
sdma_base = MV64x60_SDMA_0_OFFSET;
brg_bcr = MV64x60_BRG_0_OFFSET + BRG_BCR;
SDMA_REGS_INIT(&sdma_regs[0], MV64x60_SDMA_0_OFFSET);
} else {
sdma_base = MV64x60_SDMA_1_OFFSET;
brg_bcr = MV64x60_BRG_1_OFFSET + BRG_BCR;
SDMA_REGS_INIT(&sdma_regs[0], MV64x60_SDMA_1_OFFSET);
}
mpsc_routing_base = MV64x60_MPSC_ROUTING_OFFSET;
stop_dma(chan);
/* Set up ring buffers */
for (i=0; i<RX_NUM_DESC; i++) {
RX_INIT_RDP(&rd[chan][i]);
rd[chan][i].buffer = (u32)&rx_buf[chan][i * RX_BUF_SIZE];
rd[chan][i].next_desc_ptr = (u32)&rd[chan][i+1];
}
rd[chan][RX_NUM_DESC - 1].next_desc_ptr = (u32)&rd[chan][0];
for (i=0; i<TX_NUM_DESC; i++) {
td[chan][i].bytecnt = 0;
td[chan][i].shadow = 0;
td[chan][i].buffer = (u32)&tx_buf[chan][i * TX_BUF_SIZE];
td[chan][i].cmd_stat = SDMA_DESC_CMDSTAT_F|SDMA_DESC_CMDSTAT_L;
td[chan][i].next_desc_ptr = (u32)&td[chan][i+1];
}
td[chan][TX_NUM_DESC - 1].next_desc_ptr = (u32)&td[chan][0];
/* Set MPSC Routing */
out_le32(mv64x60_base + mpsc_routing_base + MPSC_MRR, 0x3ffffe38);
#ifdef CONFIG_GT64260
out_le32(mv64x60_base + GT64260_MPP_SERIAL_PORTS_MULTIPLEX, 0x00001102);
#else /* Must be MV64360 or MV64460 */
{
u32 enables, prot_bits, v;
/* Set up comm unit to memory mapping windows */
/* Note: Assumes MV64x60_CPU2MEM_WINDOWS == 4 */
enables = in_le32(mv64x60_base + MV64360_CPU_BAR_ENABLE) & 0xf;
prot_bits = 0;
for (i=0; i<MV64x60_CPU2MEM_WINDOWS; i++) {
if (!(enables & (1 << i))) {
v = in_le32(mv64x60_base + cpu2mem_tab[i][0]);
v = ((v & 0xffff) << 16) | (dram_selects[i] << 8);
out_le32(mv64x60_base + com2mem_tab[i][0], v);
v = in_le32(mv64x60_base + cpu2mem_tab[i][1]);
v = (v & 0xffff) << 16;
out_le32(mv64x60_base + com2mem_tab[i][1], v);
prot_bits |= (0x3 << (i << 1)); /* r/w access */
}
}
out_le32(mv64x60_base + MV64360_MPSC_0_REMAP, 0);
out_le32(mv64x60_base + MV64360_MPSC_1_REMAP, 0);
out_le32(mv64x60_base + MV64360_MPSC2MEM_ACC_PROT_0, prot_bits);
out_le32(mv64x60_base + MV64360_MPSC2MEM_ACC_PROT_1, prot_bits);
out_le32(mv64x60_base + MV64360_MPSC2MEM_BAR_ENABLE, enables);
}
#endif
/* MPSC 0/1 Rx & Tx get clocks BRG0/1 */
out_le32(mv64x60_base + mpsc_routing_base + MPSC_RCRR, 0x00000100);
out_le32(mv64x60_base + mpsc_routing_base + MPSC_TCRR, 0x00000100);
/* clear pending interrupts */
out_le32(mv64x60_base + MV64x60_SDMA_INTR_OFFSET + SDMA_INTR_MASK, 0);
out_le32(mv64x60_base + SDMA_SCRDP + sdma_base, (int)&rd[chan][0]);
out_le32(mv64x60_base + SDMA_SCTDP + sdma_base,
(int)&td[chan][TX_NUM_DESC - 1]);
out_le32(mv64x60_base + SDMA_SFTDP + sdma_base,
(int)&td[chan][TX_NUM_DESC - 1]);
out_le32(mv64x60_base + SDMA_SDC + sdma_base,
SDMA_SDC_RFT | SDMA_SDC_SFM | SDMA_SDC_BLMR | SDMA_SDC_BLMT |
(3 << 12));
cdv = ((mv64x60_mpsc_clk_freq/(32*mv64x60_console_baud))-1);
out_le32(mv64x60_base + brg_bcr,
((mv64x60_mpsc_clk_src << 18) | (1 << 16) | cdv));
/* Put MPSC into UART mode, no null modem, 16x clock mode */
out_le32(mv64x60_base + MPSC_MMCRL + mpsc_base[chan], 0x000004c4);
out_le32(mv64x60_base + MPSC_MMCRH + mpsc_base[chan], 0x04400400);
out_le32(mv64x60_base + MPSC_CHR_1 + mpsc_base[chan], 0);
out_le32(mv64x60_base + MPSC_CHR_9 + mpsc_base[chan], 0);
out_le32(mv64x60_base + MPSC_CHR_10 + mpsc_base[chan], 0);
out_le32(mv64x60_base + MPSC_CHR_3 + mpsc_base[chan], 4);
out_le32(mv64x60_base + MPSC_CHR_4 + mpsc_base[chan], 0);
out_le32(mv64x60_base + MPSC_CHR_5 + mpsc_base[chan], 0);
out_le32(mv64x60_base + MPSC_CHR_6 + mpsc_base[chan], 0);
out_le32(mv64x60_base + MPSC_CHR_7 + mpsc_base[chan], 0);
out_le32(mv64x60_base + MPSC_CHR_8 + mpsc_base[chan], 0);
/* 8 data bits, 1 stop bit */
out_le32(mv64x60_base + MPSC_MPCR + mpsc_base[chan], (3 << 12));
out_le32(mv64x60_base + SDMA_SDCM + sdma_base, SDMA_SDCM_ERD);
out_le32(mv64x60_base + MPSC_CHR_2 + mpsc_base[chan], MPSC_CHR_2_EH);
udelay(100);
return chan;
}
static void
stop_dma(int chan)
{
int i;
/* Abort MPSC Rx (aborting Tx messes things up) */
out_le32(mv64x60_base + MPSC_CHR_2 + mpsc_base[chan], MPSC_CHR_2_RA);
/* Abort SDMA Rx, Tx */
out_le32(mv64x60_base + sdma_regs[chan].sdcm,
SDMA_SDCM_AR | SDMA_SDCM_STD);
for (i=0; i<MAX_RESET_WAIT; i++) {
if ((in_le32(mv64x60_base + sdma_regs[chan].sdcm) &
(SDMA_SDCM_AR | SDMA_SDCM_AT)) == 0)
break;
udelay(100);
}
}
static int
wait_for_ownership(int chan)
{
int i;
for (i=0; i<MAX_TX_WAIT; i++) {
if ((in_le32(mv64x60_base + sdma_regs[chan].sdcm) &
SDMA_SDCM_TXD) == 0)
break;
udelay(1000);
}
return (i < MAX_TX_WAIT);
}
void
serial_putc(unsigned long com_port, unsigned char c)
{
struct mv64x60_tx_desc *tdp;
if (wait_for_ownership(com_port) == 0)
return;
tdp = &td[com_port][cur_td[com_port]];
if (++cur_td[com_port] >= TX_NUM_DESC)
cur_td[com_port] = 0;
*(unchar *)(tdp->buffer ^ 7) = c;
tdp->bytecnt = 1;
tdp->shadow = 1;
tdp->cmd_stat = SDMA_DESC_CMDSTAT_L | SDMA_DESC_CMDSTAT_F |
SDMA_DESC_CMDSTAT_O;
out_le32(mv64x60_base + sdma_regs[com_port].sctdp, (int)tdp);
out_le32(mv64x60_base + sdma_regs[com_port].sftdp, (int)tdp);
out_le32(mv64x60_base + sdma_regs[com_port].sdcm,
in_le32(mv64x60_base + sdma_regs[com_port].sdcm) |
SDMA_SDCM_TXD);
}
unsigned char
serial_getc(unsigned long com_port)
{
struct mv64x60_rx_desc *rdp;
unchar c = '\0';
rdp = &rd[com_port][cur_rd[com_port]];
if ((rdp->cmd_stat & (SDMA_DESC_CMDSTAT_O|SDMA_DESC_CMDSTAT_ES)) == 0) {
c = *(unchar *)(rdp->buffer ^ 7);
RX_INIT_RDP(rdp);
if (++cur_rd[com_port] >= RX_NUM_DESC)
cur_rd[com_port] = 0;
}
return c;
}
int
serial_tstc(unsigned long com_port)
{
struct mv64x60_rx_desc *rdp;
int loop_count = 0;
int rc = 0;
rdp = &rd[com_port][cur_rd[com_port]];
/* Go thru rcv desc's until empty looking for one with data (no error)*/
while (((rdp->cmd_stat & SDMA_DESC_CMDSTAT_O) == 0) &&
(loop_count++ < RX_NUM_DESC)) {
/* If there was an error, reinit the desc & continue */
if ((rdp->cmd_stat & SDMA_DESC_CMDSTAT_ES) != 0) {
RX_INIT_RDP(rdp);
if (++cur_rd[com_port] >= RX_NUM_DESC)
cur_rd[com_port] = 0;
rdp = (struct mv64x60_rx_desc *)rdp->next_desc_ptr;
} else {
rc = 1;
break;
}
}
return rc;
}
void
serial_close(unsigned long com_port)
{
stop_dma(com_port);
}