YAWM-ModMii-Edition/source/mini_seeprom.c

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2024-03-23 05:43:32 +01:00
/*
mini - a Free Software replacement for the Nintendo/BroadOn IOS.
SEEPROM support
Copyright (C) 2008, 2009 Sven Peter <svenpeter@gmail.com>
Copyright (C) 2008, 2009 Haxx Enterprises <bushing@gmail.com>
Copyright (C) 2008, 2009 Hector Martin "marcan" <marcan@marcansoft.com>
Copyright (C) 2008, 2009 John Kelley <wiidev@kelley.ca>
Copyright (C) 2020 Pablo Curiel "DarkMatterCore" <pabloacurielz@gmail.com>
# This code is licensed to you under the terms of the GNU GPL, version 2;
# see http://www.gnu.org/licenses/old-licenses/gpl-2.0.txt
*/
#include <ogc/machine/processor.h>
#include <unistd.h>
#include <string.h>
#include "mini_seeprom.h"
#define HW_REG_BASE 0xd800000
#define HW_GPIO1OUT (HW_REG_BASE + 0x0e0)
#define HW_GPIO1IN (HW_REG_BASE + 0x0e8)
#define HW_SEEPROM_BLK_SIZE 2
#define HW_SEEPROM_BLK_CNT (SEEPROM_SIZE / HW_SEEPROM_BLK_SIZE)
#define eeprom_delay() usleep(5)
enum {
GP_EEP_CS = 0x000400,
GP_EEP_CLK = 0x000800,
GP_EEP_MOSI = 0x001000,
GP_EEP_MISO = 0x002000
};
static void seeprom_send_bits(u16 value, u8 bits)
{
if (!bits || bits > 16) return;
while(bits--)
{
if (value & (1 << bits))
{
mask32(HW_GPIO1OUT, 0, GP_EEP_MOSI);
} else {
mask32(HW_GPIO1OUT, GP_EEP_MOSI, 0);
}
eeprom_delay();
mask32(HW_GPIO1OUT, 0, GP_EEP_CLK);
eeprom_delay();
mask32(HW_GPIO1OUT, GP_EEP_CLK, 0);
eeprom_delay();
}
}
static u16 seeprom_recv_bits(u8 bits)
{
if (!bits || bits > 16) return 0;
int res = 0;
while(bits--)
{
res <<= 1;
mask32(HW_GPIO1OUT, 0, GP_EEP_CLK);
eeprom_delay();
mask32(HW_GPIO1OUT, GP_EEP_CLK, 0);
eeprom_delay();
res |= !!(read32(HW_GPIO1IN) & GP_EEP_MISO);
}
return (u16)res;
}
u16 seeprom_read(void *dst, u16 offset, u16 size)
{
/*
* WiiUBrew told me that you interact with the SEEPROM the exact same way you do on Wii.
* However the contents are way different. Like there's absolutely no vWii stuff here.
*/
if (read16(0xCD8005A0) == 0xCAFE) return 0;
if (!dst || offset >= SEEPROM_SIZE || !size || (offset + size) > SEEPROM_SIZE) return 0;
u16 cur_offset = 0;
u8 *ptr = (u8*)dst;
u8 val[HW_SEEPROM_BLK_SIZE] = {0};
// Calculate block offsets and sizes
u8 start_addr = (u8)(offset / HW_SEEPROM_BLK_SIZE);
u8 start_addr_offset = (u8)(offset % HW_SEEPROM_BLK_SIZE);
u8 end_addr = (u8)((offset + size) / HW_SEEPROM_BLK_SIZE);
u8 end_addr_size = (u8)((offset + size) % HW_SEEPROM_BLK_SIZE);
if (!end_addr_size)
{
end_addr--;
end_addr_size = HW_SEEPROM_BLK_SIZE;
}
if (end_addr == start_addr) end_addr_size -= start_addr_offset;
mask32(HW_GPIO1OUT, GP_EEP_CLK, 0);
mask32(HW_GPIO1OUT, GP_EEP_CS, 0);
eeprom_delay();
for(u16 i = start_addr; i <= end_addr; i++)
{
if (cur_offset >= size) break;
// Start command cycle
mask32(HW_GPIO1OUT, 0, GP_EEP_CS);
// Send read command + address
seeprom_send_bits(0x600 | i, 11);
// Receive data
*((u16*)val) = seeprom_recv_bits(16);
// End of command cycle
mask32(HW_GPIO1OUT, GP_EEP_CS, 0);
eeprom_delay();
// Copy read data to destination buffer
if (i == start_addr && start_addr_offset != 0)
{
// Handle unaligned read at start address
memcpy(ptr + cur_offset, val + start_addr_offset, HW_SEEPROM_BLK_SIZE - start_addr_offset);
cur_offset += (HW_SEEPROM_BLK_SIZE - start_addr_offset);
} else
if (i == end_addr && end_addr_size != HW_SEEPROM_BLK_SIZE)
{
// Handle unaligned read at end address
memcpy(ptr + cur_offset, val, end_addr_size);
cur_offset += end_addr_size;
} else {
// Normal read
memcpy(ptr + cur_offset, val, HW_SEEPROM_BLK_SIZE);
cur_offset += HW_SEEPROM_BLK_SIZE;
}
}
return cur_offset;
}
#if 0
u16 seeprom_write(const void *src, u16 offset, u16 size)
{
if (!src || offset >= SEEPROM_SIZE || !size || (offset + size) > SEEPROM_SIZE) return 0;
u32 level = 0;
u16 cur_offset = 0;
const u8 *ptr = (const u8*)src;
u8 val[HW_SEEPROM_BLK_SIZE] = {0};
// Calculate block offsets and sizes
u8 start_addr = (u8)(offset / HW_SEEPROM_BLK_SIZE);
u8 start_addr_offset = (u8)(offset % HW_SEEPROM_BLK_SIZE);
u8 end_addr = (u8)((offset + size) / HW_SEEPROM_BLK_SIZE);
u8 end_addr_size = (u8)((offset + size) % HW_SEEPROM_BLK_SIZE);
if (!end_addr_size)
{
end_addr--;
end_addr_size = HW_SEEPROM_BLK_SIZE;
}
if (end_addr == start_addr) end_addr_size -= start_addr_offset;
// Disable CPU interruptions
_CPU_ISR_Disable(level);
mask32(HW_GPIO1OUT, GP_EEP_CLK, 0);
mask32(HW_GPIO1OUT, GP_EEP_CS, 0);
eeprom_delay();
// EWEN - Enable programming commands
mask32(HW_GPIO1OUT, 0, GP_EEP_CS);
seeprom_send_bits(0x4FF, 11);
mask32(HW_GPIO1OUT, GP_EEP_CS, 0);
eeprom_delay();
for(u16 i = start_addr; i <= end_addr; i++)
{
if (cur_offset >= size) break;
// Copy data to write from source buffer
if ((i == start_addr && start_addr_offset != 0) || (i == end_addr && end_addr_size != HW_SEEPROM_BLK_SIZE))
{
// Read data from SEEPROM to handle unaligned writes
// Start command cycle
mask32(HW_GPIO1OUT, 0, GP_EEP_CS);
// Send read command + address
seeprom_send_bits(0x600 | i, 11);
// Receive data
*((u16*)val) = seeprom_recv_bits(16);
// End of command cycle
mask32(HW_GPIO1OUT, GP_EEP_CS, 0);
eeprom_delay();
if (i == start_addr && start_addr_offset != 0)
{
// Handle unaligned write at start address
memcpy(val + start_addr_offset, ptr + cur_offset, HW_SEEPROM_BLK_SIZE - start_addr_offset);
cur_offset += (HW_SEEPROM_BLK_SIZE - start_addr_offset);
} else {
// Handle unaligned write at end address
memcpy(val, ptr + cur_offset, end_addr_size);
cur_offset += end_addr_size;
}
} else {
// Normal write
memcpy(val, ptr + cur_offset, HW_SEEPROM_BLK_SIZE);
cur_offset += HW_SEEPROM_BLK_SIZE;
}
// Start command cycle
mask32(HW_GPIO1OUT, 0, GP_EEP_CS);
// Send write command + address
seeprom_send_bits(0x500 | i, 11);
// Send data
seeprom_send_bits(*((u16*)val), 16);
// End of command cycle
mask32(HW_GPIO1OUT, GP_EEP_CS, 0);
eeprom_delay();
// Wait until SEEPROM is ready (write cycle is self-timed so no clocking needed)
mask32(HW_GPIO1OUT, 0, GP_EEP_CS);
do {
eeprom_delay();
} while(!(read32(HW_GPIO1IN) & GP_EEP_MISO));
mask32(HW_GPIO1OUT, GP_EEP_CS, 0);
eeprom_delay();
}
// EWDS - Disable programming commands
mask32(HW_GPIO1OUT, 0, GP_EEP_CS);
seeprom_send_bits(0x400, 11);
mask32(HW_GPIO1OUT, GP_EEP_CS, 0);
eeprom_delay();
// Enable CPU interruptions
_CPU_ISR_Restore(level);
return cur_offset;
}
#endif