mini/ipc.c
2009-05-15 05:33:11 -07:00

356 lines
8.8 KiB
C

/*
mini - a Free Software replacement for the Nintendo/BroadOn IOS.
inter-processor communications
Copyright (C) 2008, 2009 Hector Martin "marcan" <marcan@marcansoft.com>
Copyright (C) 2008, 2009 Haxx Enterprises <bushing@gmail.com>
Copyright (C) 2008, 2009 Sven Peter <svenpeter@gmail.com>
Copyright (C) 2009 Andre Heider "dhewg" <dhewg@wiibrew.org>
Copyright (C) 2009 John Kelley <wiidev@kelley.ca>
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, version 2.
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 <stdarg.h>
#include "types.h"
#include "irq.h"
#include "memory.h"
#include "utils.h"
#include "hollywood.h"
#include "gecko.h"
#include "ipc.h"
#include "nand.h"
#include "sdhcvar.h"
#include "sdmmc.h"
#include "crypto.h"
#include "boot2.h"
#include "powerpc.h"
#include "panic.h"
#define MINI_VERSION_MAJOR 1
#define MINI_VERSION_MINOR 0
static volatile ipc_request in_queue[IPC_IN_SIZE] ALIGNED(32) MEM2_BSS;
static volatile ipc_request out_queue[IPC_OUT_SIZE] ALIGNED(32) MEM2_BSS;
static volatile ipc_request slow_queue[IPC_SLOW_SIZE];
extern char __mem2_area_start[];
// These defines are for the ARMCTRL regs
// See http://wiibrew.org/wiki/Hardware/IPC
#define IPC_CTRL_Y1 0x01
#define IPC_CTRL_X2 0x02
#define IPC_CTRL_X1 0x04
#define IPC_CTRL_Y2 0x08
#define IPC_CTRL_IX1 0x10
#define IPC_CTRL_IX2 0x20
// Our definitions for this IPC interface
#define IPC_CTRL_OUT IPC_CTRL_Y1
#define IPC_CTRL_IN IPC_CTRL_X1
#define IPC_CTRL_IRQ_IN IPC_CTRL_IX1
// reset both flags (X* for ARM and Y* for PPC)
#define IPC_CTRL_RESET 0x06
const ipc_infohdr __ipc_info ALIGNED(32) MEM2_RODATA = {
.magic = "IPC",
.version = 1,
.mem2_boundary = __mem2_area_start,
.ipc_in = in_queue,
.ipc_in_size = IPC_IN_SIZE,
.ipc_out = out_queue,
.ipc_out_size = IPC_OUT_SIZE,
};
static u16 slow_queue_head;
static vu16 slow_queue_tail;
static u16 in_head;
static u16 out_tail;
static inline void poke_outtail(u16 num)
{
mask32(HW_IPC_ARMMSG, 0xFFFF, num);
}
static inline void poke_inhead(u16 num)
{
mask32(HW_IPC_ARMMSG, 0xFFFF0000, num<<16);
}
static inline u16 peek_intail(void)
{
return read32(HW_IPC_PPCMSG) & 0xFFFF;
}
static inline u16 peek_outhead(void)
{
return read32(HW_IPC_PPCMSG) >> 16;
}
void ipc_post(u32 code, u32 tag, u32 num_args, ...)
{
int arg = 0;
va_list ap;
u32 cookie = irq_kill();
if(peek_outhead() == ((out_tail + 1)&(IPC_OUT_SIZE-1))) {
gecko_printf("IPC: out queue full, PPC slow/dead/flooded\n");
while(peek_outhead() == ((out_tail + 1)&(IPC_OUT_SIZE-1)));
}
out_queue[out_tail].code = code;
out_queue[out_tail].tag = tag;
if(num_args) {
va_start(ap, num_args);
while(num_args--) {
out_queue[out_tail].args[arg++] = va_arg(ap, u32);
}
va_end(ap);
}
dc_flush_block_fast((void*)&out_queue[out_tail]);
out_tail = (out_tail+1)&(IPC_OUT_SIZE-1);
poke_outtail(out_tail);
write32(HW_IPC_ARMCTRL, IPC_CTRL_IRQ_IN | IPC_CTRL_OUT);
irq_restore(cookie);
}
void ipc_flush(void)
{
while(peek_outhead() != out_tail);
}
static u32 process_slow(volatile ipc_request *req)
{
//gecko_printf("IPC: process slow_queue @ %p\n",req);
//gecko_printf("IPC: req %08x %08x [%08x %08x %08x %08x %08x %08x]\n", req->code, req->tag,
// req->args[0], req->args[1], req->args[2], req->args[3], req->args[4], req->args[5]);
switch(req->device) {
case IPC_DEV_SYS:
switch(req->req) {
case IPC_SYS_PING: //PING can be both slow and fast for testing purposes
ipc_post(req->code, req->tag, 0);
break;
case IPC_SYS_JUMP:
return req->args[0];
case IPC_SYS_GETVERS:
ipc_post(req->code, req->tag, 1, MINI_VERSION_MAJOR << 16 | MINI_VERSION_MINOR);
break;
default:
gecko_printf("IPC: unknown SLOW SYS request %04x\n", req->req);
}
break;
case IPC_DEV_NAND:
nand_ipc(req);
break;
case IPC_DEV_SDHC:
sdhc_ipc(req);
break;
case IPC_DEV_SDMMC:
sdmmc_ipc(req);
break;
case IPC_DEV_KEYS:
crypto_ipc(req);
break;
case IPC_DEV_AES:
aes_ipc(req);
break;
case IPC_DEV_BOOT2:
return boot2_ipc(req);
break;
case IPC_DEV_PPC:
powerpc_ipc(req);
break;
default:
gecko_printf("IPC: unknown SLOW request %02x-%04x\n", req->device, req->req);
}
return 0;
}
void ipc_add_slow(volatile ipc_request *req)
{
if(slow_queue_head == ((slow_queue_tail + 1)&(IPC_SLOW_SIZE-1))) {
gecko_printf("IPC: Slowqueue overrun\n");
panic2(0, PANIC_IPCOVF);
}
slow_queue[slow_queue_tail] = *req;
slow_queue_tail = (slow_queue_tail+1)&(IPC_SLOW_SIZE-1);
}
static void process_in(void)
{
volatile ipc_request *req = &in_queue[in_head];
//gecko_printf("IPC: process in %d @ %p\n",in_head,req);
dc_inval_block_fast((void*)req);
//gecko_printf("IPC: req %08x %08x [%08x %08x %08x %08x %08x %08x]\n", req->code, req->tag,
// req->args[0], req->args[1], req->args[2], req->args[3], req->args[4], req->args[5]);
if(req->flags & IPC_FAST) {
switch(req->device) {
case IPC_DEV_SYS:
// handle fast SYS requests here
switch(req->req) {
case IPC_SYS_PING:
ipc_post(req->code, req->tag, 0);
break;
case IPC_SYS_WRITE32:
write32(req->args[0], req->args[1]);
break;
case IPC_SYS_WRITE16:
write16(req->args[0], req->args[1]);
break;
case IPC_SYS_WRITE8:
write8(req->args[0], req->args[1]);
break;
case IPC_SYS_READ32:
ipc_post(req->code, req->tag, 1, read32(req->args[0]));
break;
case IPC_SYS_READ16:
ipc_post(req->code, req->tag, 1, read16(req->args[0]));
break;
case IPC_SYS_READ8:
ipc_post(req->code, req->tag, 1, read8(req->args[0]));
break;
case IPC_SYS_SET32:
set32(req->args[0], req->args[1]);
break;
case IPC_SYS_SET16:
set16(req->args[0], req->args[1]);
break;
case IPC_SYS_SET8:
set8(req->args[0], req->args[1]);
break;
case IPC_SYS_CLEAR32:
clear32(req->args[0], req->args[1]);
break;
case IPC_SYS_CLEAR16:
clear16(req->args[0], req->args[1]);
break;
case IPC_SYS_CLEAR8:
clear8(req->args[0], req->args[1]);
break;
case IPC_SYS_MASK32:
mask32(req->args[0], req->args[1], req->args[2]);
break;
case IPC_SYS_MASK16:
mask16(req->args[0], req->args[1], req->args[2]);
break;
case IPC_SYS_MASK8:
mask8(req->args[0], req->args[1], req->args[2]);
break;
default:
gecko_printf("IPC: unknown FAST SYS request %04x\n", req->req);
break;
}
break;
default:
gecko_printf("IPC: unknown FAST request %02x-%04x\n", req->device, req->req);
break;
}
} else {
ipc_add_slow(req);
}
}
void ipc_irq(void)
{
int donebell = 0;
while(read32(HW_IPC_ARMCTRL) & IPC_CTRL_IN) {
write32(HW_IPC_ARMCTRL, IPC_CTRL_IRQ_IN | IPC_CTRL_IN);
while(peek_intail() != in_head) {
process_in();
in_head = (in_head+1)&(IPC_IN_SIZE-1);
poke_inhead(in_head);
}
donebell++;
}
if(!donebell)
gecko_printf("IPC: IRQ but no bell!\n");
}
void ipc_queue_slow_jump(u32 addr)
{
volatile ipc_request *req = &in_queue[in_head];
if(slow_queue_head == ((slow_queue_tail + 1)&(IPC_SLOW_SIZE-1))) {
gecko_printf("IPC: Slowqueue overrun\n");
panic2(0, PANIC_IPCOVF);
}
req->flags = IPC_SLOW;
req->device = IPC_DEV_SYS;
req->req = IPC_SYS_JUMP;
req->tag = 0;
req->args[0] = addr;
slow_queue[slow_queue_tail] = *req;
slow_queue_tail = (slow_queue_tail+1)&(IPC_SLOW_SIZE-1);
}
void ipc_initialize(void)
{
write32(HW_IPC_ARMMSG, 0);
write32(HW_IPC_PPCMSG, 0);
write32(HW_IPC_PPCCTRL, IPC_CTRL_RESET);
write32(HW_IPC_ARMCTRL, IPC_CTRL_RESET);
slow_queue_head = 0;
slow_queue_tail = 0;
in_head = 0;
out_tail = 0;
irq_enable(IRQ_IPC);
write32(HW_IPC_ARMCTRL, IPC_CTRL_IRQ_IN);
}
void ipc_shutdown(void)
{
// Don't kill message registers so our PPC side doesn't get confused
//write32(HW_IPC_ARMMSG, 0);
//write32(HW_IPC_PPCMSG, 0);
// Do kill flags so Nintendo's SDK doesn't get confused
write32(HW_IPC_PPCCTRL, IPC_CTRL_RESET);
write32(HW_IPC_ARMCTRL, IPC_CTRL_RESET);
irq_disable(IRQ_IPC);
}
u32 ipc_process_slow(void)
{
u32 vector = 0;
while (!vector) {
while (slow_queue_head != slow_queue_tail) {
vector = process_slow(&slow_queue[slow_queue_head]);
slow_queue_head = (slow_queue_head+1)&(IPC_SLOW_SIZE-1);
}
u32 cookie = irq_kill();
if(slow_queue_head == slow_queue_tail)
irq_wait();
irq_restore(cookie);
}
return vector;
}