blob: 1758c9776629dad9d29e587cc0e1f78d2ed8cfc3 [file] [log] [blame] [raw]
"use strict";
/**
* The ISA IO bus
* Devices register their ports here
*
* @constructor
*/
function IO(memory)
{
var memory_size = memory.size;
this._state_skip = ["devices", "ports",];
function get_port_description(addr)
{
// via seabios ioport.h
var ports = {
0x0004: "PORT_DMA_ADDR_2",
0x0005: "PORT_DMA_CNT_2",
0x000a: "PORT_DMA1_MASK_REG",
0x000b: "PORT_DMA1_MODE_REG",
0x000c: "PORT_DMA1_CLEAR_FF_REG",
0x000d: "PORT_DMA1_MASTER_CLEAR",
0x0020: "PORT_PIC1_CMD",
0x0021: "PORT_PIC1_DATA",
0x0040: "PORT_PIT_COUNTER0",
0x0041: "PORT_PIT_COUNTER1",
0x0042: "PORT_PIT_COUNTER2",
0x0043: "PORT_PIT_MODE",
0x0060: "PORT_PS2_DATA",
0x0061: "PORT_PS2_CTRLB",
0x0064: "PORT_PS2_STATUS",
0x0070: "PORT_CMOS_INDEX",
0x0071: "PORT_CMOS_DATA",
0x0080: "PORT_DIAG",
0x0081: "PORT_DMA_PAGE_2",
0x0092: "PORT_A20",
0x00a0: "PORT_PIC2_CMD",
0x00a1: "PORT_PIC2_DATA",
0x00b2: "PORT_SMI_CMD",
0x00b3: "PORT_SMI_STATUS",
0x00d4: "PORT_DMA2_MASK_REG",
0x00d6: "PORT_DMA2_MODE_REG",
0x00da: "PORT_DMA2_MASTER_CLEAR",
0x00f0: "PORT_MATH_CLEAR",
0x0170: "PORT_ATA2_CMD_BASE",
0x01f0: "PORT_ATA1_CMD_BASE",
0x0278: "PORT_LPT2",
0x02e8: "PORT_SERIAL4",
0x02f8: "PORT_SERIAL2",
0x0374: "PORT_ATA2_CTRL_BASE",
0x0378: "PORT_LPT1",
0x03e8: "PORT_SERIAL3",
//0x03f4: "PORT_ATA1_CTRL_BASE",
0x03f0: "PORT_FD_BASE",
0x03f2: "PORT_FD_DOR",
0x03f4: "PORT_FD_STATUS",
0x03f5: "PORT_FD_DATA",
0x03f6: "PORT_HD_DATA",
0x03f7: "PORT_FD_DIR",
0x03f8: "PORT_SERIAL1",
0x0cf8: "PORT_PCI_CMD",
0x0cf9: "PORT_PCI_REBOOT",
0x0cfc: "PORT_PCI_DATA",
0x0402: "PORT_BIOS_DEBUG",
0x0510: "PORT_QEMU_CFG_CTL",
0x0511: "PORT_QEMU_CFG_DATA",
0xb000: "PORT_ACPI_PM_BASE",
0xb100: "PORT_SMB_BASE",
0x8900: "PORT_BIOS_APM"
};
if(ports[addr])
{
return " (" + ports[addr] + ")";
}
else
{
return "";
}
}
function empty_port_read8()
{
return 0xFF;
}
function empty_port_read16()
{
return 0xFFFF;
}
function empty_port_read32()
{
return -1;
}
function empty_port_write(x)
{
}
this.ports = [];
this.devices = Array(0x10000);
for(var i = 0; i < 0x10000; i++)
{
this.ports[i] = {
read8: empty_port_read8,
read16: empty_port_read16,
read32: empty_port_read32,
write8: empty_port_write,
write16: empty_port_write,
write32: empty_port_write,
device: undefined,
};
}
/**
* @param {number} port_addr
* @param {Object} device
* @param {function():number} r8
* @param {function():number=} r16
* @param {function():number=} r32
*/
this.register_read = function(port_addr, device, r8, r16, r32)
{
dbg_assert(typeof port_addr === "number");
dbg_assert(typeof device === "object");
dbg_assert(!r8 || typeof r8 === "function");
dbg_assert(!r16 || typeof r16 === "function");
dbg_assert(!r32 || typeof r32 === "function");
dbg_assert(r8 || r16 || r32);
if(DEBUG)
{
var fail = function(n) {
dbg_assert(false, "Overlapped read" + n + " " + h(port_addr, 4));
return -1;
};
if(!r8) r8 = fail.bind(this, 8);
if(!r16) r16 = fail.bind(this, 16);
if(!r32) r32 = fail.bind(this, 32);
}
if(r8) this.ports[port_addr].read8 = r8;
if(r16) this.ports[port_addr].read16 = r16;
if(r32) this.ports[port_addr].read32 = r32;
this.ports[port_addr].device = device;
};
/**
* @param {number} port_addr
* @param {Object} device
* @param {function(number)} w8
* @param {function(number)=} w16
* @param {function(number)=} w32
*/
this.register_write = function(port_addr, device, w8, w16, w32)
{
dbg_assert(typeof port_addr === "number");
dbg_assert(typeof device === "object");
dbg_assert(!w8 || typeof w8 === "function");
dbg_assert(!w16 || typeof w16 === "function");
dbg_assert(!w32 || typeof w32 === "function");
dbg_assert(w8 || w16 || w32);
if(DEBUG)
{
var fail = function(n) {
dbg_assert(false, "Overlapped write" + n + " " + h(port_addr));
};
if(!w8) w8 = fail.bind(this, 8);
if(!w16) w16 = fail.bind(this, 16);
if(!w32) w32 = fail.bind(this, 32);
}
if(w8) this.ports[port_addr].write8 = w8;
if(w16) this.ports[port_addr].write16 = w16;
if(w32) this.ports[port_addr].write32 = w32;
this.ports[port_addr].device = device;
};
/*
* > Any two consecutive 8-bit ports can be treated as a 16-bit port;
* > and four consecutive 8-bit ports can be treated as a 32-bit port
* > http://css.csail.mit.edu/6.858/2012/readings/i386/s08_01.htm
*
* This info is not correct for all ports, but handled by the following functions
*
* Register the write of 2 or 4 consecutive 8-bit ports, 1 or 2 16-bit
* ports and 0 or 1 32-bit ports
*/
this.register_read_consecutive = function(port_addr, device, r8_1, r8_2, r8_3, r8_4)
{
dbg_assert(arguments.length === 4 || arguments.length === 6);
function r16_1()
{
return r8_1.call(this) |
r8_2.call(this) << 8;
}
function r16_2()
{
return r8_3.call(this) |
r8_4.call(this) << 8;
}
function r32()
{
return r8_1.call(this) |
r8_2.call(this) << 8 |
r8_3.call(this) << 16 |
r8_4.call(this) << 24;
}
if(r8_3 && r8_4)
{
this.register_read(port_addr, device, r8_1, r16_1, r32);
this.register_read(port_addr + 1, device, r8_2);
this.register_read(port_addr + 2, device, r8_3, r16_2);
this.register_read(port_addr + 3, device, r8_4);
}
else
{
this.register_read(port_addr, device, r8_1, r16_1);
this.register_read(port_addr + 1, device, r8_2);
}
};
this.register_write_consecutive = function(port_addr, device, w8_1, w8_2, w8_3, w8_4)
{
dbg_assert(arguments.length === 4 || arguments.length === 6);
function w16_1(data)
{
w8_1.call(this, data & 0xFF);
w8_2.call(this, data >> 8 & 0xFF);
}
function w16_2(data)
{
w8_3.call(this, data & 0xFF);
w8_4.call(this, data >> 8 & 0xFF);
}
function w32(data)
{
w8_1.call(this, data & 0xFF);
w8_2.call(this, data >> 8 & 0xFF);
w8_3.call(this, data >> 16 & 0xFF);
w8_4.call(this, data >>> 24);
}
if(w8_3 && w8_4)
{
this.register_write(port_addr, device, w8_1, w16_1, w32);
this.register_write(port_addr + 1, device, w8_2);
this.register_write(port_addr + 2, device, w8_3, w16_2);
this.register_write(port_addr + 3, device, w8_4);
}
else
{
this.register_write(port_addr, device, w8_1, w16_1);
this.register_write(port_addr + 1, device, w8_2);
}
};
this.mmap_read32_shim = function(addr)
{
var aligned_addr = addr >>> MMAP_BLOCK_BITS;
var fn = memory.memory_map_read8[aligned_addr];
return fn(addr) | fn(addr + 1) << 8 |
fn(addr + 2) << 16 | fn(addr + 3) << 24;
};
this.mmap_write32_shim = function(addr, value)
{
var aligned_addr = addr >>> MMAP_BLOCK_BITS;
var fn = memory.memory_map_write8[aligned_addr];
fn(addr, value & 0xFF);
fn(addr + 1, value >> 8 & 0xFF);
fn(addr + 2, value >> 16 & 0xFF);
fn(addr + 3, value >>> 24);
};
/**
* @param {number} addr
* @param {number} size
* @param {*} read_func8
* @param {*} write_func8
* @param {*=} read_func32
* @param {*=} write_func32
*/
this.mmap_register = function(addr, size, read_func8, write_func8, read_func32, write_func32)
{
dbg_log("mmap_register addr=" + h(addr >>> 0, 8) + " size=" + h(size, 8), LOG_IO);
dbg_assert((addr & MMAP_BLOCK_SIZE - 1) === 0);
dbg_assert(size && (size & MMAP_BLOCK_SIZE - 1) === 0);
if(!read_func32)
read_func32 = this.mmap_read32_shim;
if(!write_func32)
write_func32 = this.mmap_write32_shim;
var aligned_addr = addr >>> MMAP_BLOCK_BITS;
for(; size > 0; aligned_addr++)
{
memory.memory_map_registered[aligned_addr] = 1;
memory.memory_map_read8[aligned_addr] = read_func8;
memory.memory_map_write8[aligned_addr] = write_func8;
memory.memory_map_read32[aligned_addr] = read_func32;
memory.memory_map_write32[aligned_addr] = write_func32;
size -= MMAP_BLOCK_SIZE;
}
};
for(var i = 0; (i << MMAP_BLOCK_BITS) < memory_size; i++)
{
// avoid sparse arrays
memory.memory_map_read8[i] = memory.memory_map_write8[i] = undefined;
memory.memory_map_read32[i] = memory.memory_map_write32[i] = undefined;
}
this.mmap_register(memory_size, 0x100000000 - memory_size,
function(addr) {
// read outside of the memory size
dbg_log("Read from unmapped memory space, addr=" + h(addr >>> 0, 8), LOG_IO);
return 0xFF;
},
function(addr, value) {
// write outside of the memory size
dbg_log("Write to unmapped memory space, addr=" + h(addr >>> 0, 8) + " value=" + h(value, 2), LOG_IO);
},
function(addr) {
dbg_log("Read from unmapped memory space, addr=" + h(addr >>> 0, 8), LOG_IO);
return -1;
},
function(addr, value) {
dbg_log("Write to unmapped memory space, addr=" + h(addr >>> 0, 8) + " value=" + h(value >>> 0, 8), LOG_IO);
}
);
this.in_mmap_range = function(start, count)
{
start >>>= 0;
count >>>= 0;
var end = start + count;
if(end >= memory_size)
{
return true;
}
//dbg_log("in_mmap_range start=" + start + " count=" + count);
start &= ~(MMAP_BLOCK_SIZE - 1);
while(start < end)
{
if(memory.memory_map_registered[start >> MMAP_BLOCK_BITS])
{
return true;
}
start += MMAP_BLOCK_SIZE;
}
return false;
};
this.port_write8 = function(port_addr, data)
{
var entry = this.ports[port_addr];
if(entry.write8 === empty_port_write)
{
dbg_log(
"write8 port #" + h(port_addr, 4) + " <- " + h(data, 2) + get_port_description(port_addr),
LOG_IO
);
}
return entry.write8.call(entry.device, data);
};
this.port_write16 = function(port_addr, data)
{
var entry = this.ports[port_addr];
if(entry.write16 === empty_port_write)
{
dbg_log(
"write16 port #" + h(port_addr, 4) + " <- " + h(data, 4) + get_port_description(port_addr),
LOG_IO
);
}
return entry.write16.call(entry.device, data);
};
this.port_write32 = function(port_addr, data)
{
var entry = this.ports[port_addr];
if(entry.write32 === empty_port_write)
{
dbg_log(
"write32 port #" + h(port_addr, 4) + " <- " + h(data, 8) + get_port_description(port_addr),
LOG_IO
);
}
return entry.write32.call(entry.device, data);
};
this.port_read8 = function(port_addr)
{
var entry = this.ports[port_addr];
if(entry.read8 === empty_port_read8)
{
dbg_log(
"read8 port #" + h(port_addr, 4) + get_port_description(port_addr),
LOG_IO
);
}
return entry.read8.call(entry.device);
};
this.port_read16 = function(port_addr)
{
var entry = this.ports[port_addr];
if(entry.read16 === empty_port_read16)
{
dbg_log(
"read16 port #" + h(port_addr, 4) + get_port_description(port_addr),
LOG_IO
);
}
return entry.read16.call(entry.device);
};
this.port_read32 = function(port_addr)
{
var entry = this.ports[port_addr];
if(entry.read32 === empty_port_read32)
{
dbg_log(
"read32 port #" + h(port_addr, 4) + get_port_description(port_addr),
LOG_IO
);
}
return entry.read32.call(entry.device);
};
}