blob: adfc9013884a9edbebfa290a5a9f66730a2bedd0 [file] [log] [blame] [raw]
"use strict";
/**
* @constructor
* @param {CPU} dev
*/
function DMA(dev)
{
/** @const */
this.memory = dev.memory;
this.channel_addr = new Int32Array(4);
this.channel_count = new Int32Array(4);
this.lsb_msb_flipflop = 0;
var io = dev.io;
io.register_write(0x04, this, this.port_write.bind(this, 0x04));
io.register_write(0x05, this, this.port_write.bind(this, 0x05));
io.register_write(0x0A, this, this.portA_write);
io.register_write(0x0B, this, this.portB_write);
io.register_write(0x0C, this, this.portC_write);
io.register_write(0x81, this, this.port81_write);
}
DMA.prototype.get_state = function()
{
return [
this.channel_addr,
this.channel_count,
this.lsb_msb_flipflop,
];
};
DMA.prototype.set_state = function(state)
{
this.channel_addr = state[0];
this.channel_count = state[1];
this.lsb_msb_flipflop = state[2];
};
DMA.prototype.port_write = function(port, data_byte)
{
dbg_log("port " + port + " write " + data_byte, LOG_DMA);
if(port < 8)
{
var channel = port >> 1;
if(port & 1)
{
this.channel_count[channel] = this.flipflop_get(this.channel_count[channel], data_byte);
}
else
{
this.channel_addr[channel] = this.flipflop_get(this.channel_addr[channel], data_byte);
}
}
};
DMA.prototype.port_read = function(port)
{
if(port < 8)
{
var channel = port >> 1;
if(port & 1)
{
return this.channel_count[channel];
}
else
{
// Bug?
return this.channel_addr[channel];
}
}
else
{
dbg_log("port " + h(port) + " read", LOG_DMA);
}
};
DMA.prototype.portA_write = function(data_byte)
{
dbg_log("port A write: " + h(data_byte), LOG_DMA);
};
DMA.prototype.portB_write = function(data_byte)
{
dbg_log("port B write: " + h(data_byte), LOG_DMA);
};
DMA.prototype.portC_write = function(data_byte)
{
this.lsb_msb_flipflop = 0;
}
DMA.prototype.port81_write = function(data_byte)
{
this.channel_addr[2] = this.channel_addr[2] & 0xFFFF | data_byte << 16;
}
// read data, write to memory
DMA.prototype.do_read = function(buffer, start, len, channel, fn)
{
var read_count = this.channel_count[channel] + 1,
addr = this.channel_addr[channel];
dbg_log("DMA write channel " + channel, LOG_DMA);
dbg_log("to " + h(addr) + " len " + h(read_count), LOG_DMA);
if(len < read_count)
{
dbg_log("DMA should read more than provided: " + h(len) + " " + h(read_count), LOG_DMA);
}
if(start + read_count > buffer.byteLength)
{
dbg_log("DMA read outside of buffer", LOG_DMA);
fn(true);
}
else
{
var memory = this.memory;
this.channel_addr[channel] += read_count;
buffer.get(start, read_count, function(data)
{
memory.write_blob(data, addr);
fn(false);
});
}
};
// write data, read memory
DMA.prototype.do_write = function(buffer, start, len, channel, fn)
{
var read_count = this.channel_count[channel],
addr = this.channel_addr[channel];
dbg_log("DMA write channel " + channel, LOG_DMA);
dbg_log("to " + h(addr) + " len " + h(read_count), LOG_DMA);
if(len < read_count)
{
dbg_log("DMA should read more than provided", LOG_DMA);
}
if(start + read_count > buffer.byteLength)
{
dbg_log("DMA write outside of buffer", LOG_DMA);
fn(true);
}
else
{
this.channel_addr[channel] += read_count;
buffer.set(start,
new Uint8Array(this.memory.buffer, addr, read_count + 1),
function() {
fn(false);
}
);
}
}
DMA.prototype.flipflop_get = function(old_dword, new_byte)
{
this.lsb_msb_flipflop ^= 1;
if(this.lsb_msb_flipflop)
{
// low byte
return old_dword & ~0xFF | new_byte;
}
else
{
// high byte
return old_dword & ~0xFF00 | new_byte << 8;
}
}