== Ports ===========================================================
data in: inCBD
-data in: inAddr.read
-data in: inAddr.write
-data in: inAddr.readMany
-data in: inAddr.writeMany
-data in: inData
+data in: inAddrRead
+data in: inAddrWrite
+data in: inDataWrite
data in: inStride
data in: inCount
data out: out
+== TeX ==============================================================
+
+The {\tt Memory} ship represents an interface to a storage space,
+which can be used to read from it or write to it. This storage space
+might be a fast on-chip cache, off chip DRAM, or perhaps even a disk drive.
+
+There may be multiple {\tt Memory} ships which interface to the same
+physical storage space. An implementation of Fleet must provide
+additional documentation to the programmer indicating which {\tt
+Memory} ships correspond to which storage spaces. A single {\tt
+Memory} ship may also access a ``virtual storage space'' formed by
+concatenating multiple physical storage spaces.
+
+\subsection*{Code Bag Fetch}
+
+When a word appears at the {\tt inCBD} port, it is treated as a {\it
+code bag descriptor}, as shown below:
+
+\begin{center}
+\setlength{\bitwidth}{3mm}
+{\tt
+\begin{bytefield}{37}
+ \bitheader[b]{36,6,5,0}\\
+ \bitbox{31}{Address}
+ \bitbox{6}{size}
+\end{bytefield}
+}
+\end{center}
+
+When a word arrives at the {\tt inCBD} port, it is treated as a memory
+read with {\tt inAddrRead=Address}, {\tt inStride=1}, and {\tt
+inCount=size}.
+
+\subsection*{Reading}
+
+When a word is delivered to {\tt inAddrRead}, the word residing in
+memory at that address is provided at {\tt out}.
+
+\subsection*{Writing}
+
+When a word is delivered to {\tt inAddrWrite} and {\tt inDataWrite},
+the word at {\tt inDataWrite} is written to the address specified by
+{\tt inAddrWrite}. Once the word is successfully committed to memory,
+the value {\tt inAddr+inStride} is provided at {\tt out} (that is, the
+address of the next word to be written).
+
+\subsection*{To Do}
+
+Stride and count are not implemented.
+
+We need a way to do an ``unordered fetch'' -- a way to tell the memory
+unit to retrieve some block of words in any order it likes. This can
+considerably accelerate fetches when the first word of the region is
+not cached, but other parts are cached. This can also be used for
+dispatching codebags efficiently -- but how will we make sure that
+instructions destined for a given pump are dispatched in the correct
+order (source sequence guarantee)?
+
+A more advanced form would be ``unordered fetch of ordered records''
+-- the ability to specify a record size (in words), the offset of the
+first record, and the number of records to be fetched. The memory
+unit would then fetch the records in any order it likes, but would be
+sure to return the words comprising a record in the order in which
+they appear in memory. This feature could be used to solve the source
+sequence guarantee problem mentioned in the previous paragraph.
+
== Fleeterpreter ====================================================
private long[] mem = new long[0];
public long readMem(int addr) { return mem[addr]; }
long size = val & 0x3f;
dispatch((int)addr, (int)size);
}
- if (count > 0 && writing) {
- if (box_inData.dataReadyForShip() && box_out.readyForDataFromShip()) {
- writeMem((int)addr, box_inData.removeDataForShip());
- box_out.addDataFromShip(0);
- count--;
- addr += stride;
+ if (count > 0) {
+ if (writing) {
+ if (box_inDataWrite.dataReadyForShip() && box_out.readyForDataFromShip()) {
+ writeMem((int)addr, box_inDataWrite.removeDataForShip());
+ box_out.addDataFromShip(0);
+ count--;
+ addr += stride;
+ }
+ } else {
+ if (box_out.readyForDataFromShip()) {
+ box_out.addDataFromShip(readMem((int)addr));
+ count--;
+ addr += stride;
+ }
}
- } else if (count > 0 && !writing) {
- if (box_out.readyForDataFromShip()) {
- box_out.addDataFromShip(readMem((int)addr));
- count--;
- addr += stride;
- }
-
- } else if (box_inAddr.dataReadyForShip() && box_out.readyForDataFromShip()) {
- Packet packet = box_inAddr.peekPacketForShip();
- if (packet.destination.getDestinationName().equals("read")) {
- box_out.addDataFromShip(readMem((int)box_inAddr.removeDataForShip()));
- } else if (packet.destination.getDestinationName().equals("write") && box_inData.dataReadyForShip()) {
- writeMem((int)box_inAddr.removeDataForShip(),
- box_inData.removeDataForShip());
- box_out.addDataFromShip(0);
- } else if (packet.destination.getDestinationName().equals("writeMany")
- && box_inStride.dataReadyForShip()
- && box_inCount.dataReadyForShip()) {
- addr = box_inAddr.removeDataForShip();
- stride = box_inStride.removeDataForShip();
- count = box_inCount.removeDataForShip();
- writing = true;
- } else if (packet.destination.getDestinationName().equals("readMany")
- && box_inStride.dataReadyForShip()
- && box_inCount.dataReadyForShip()) {
- addr = box_inAddr.removeDataForShip();
- stride = box_inStride.removeDataForShip();
- count = box_inCount.removeDataForShip();
- writing = false;
- }
+ } else if (box_inAddrRead.dataReadyForShip()) {
+ addr = box_inAddrRead.removeDataForShip();
+ stride = 0;
+ count = 1;
+ writing = false;
+
+ } else if (box_inAddrWrite.dataReadyForShip()) {
+ addr = box_inAddrWrite.peekPacketForShip().value;
+ box_inAddrWrite.removeDataForShip();
+ stride = 0;
+ count = 1;
+ writing = true;
}
}
`define BRAM_ADDR_WIDTH 14
`define BRAM_DATA_WIDTH `INSTRUCTION_WIDTH
`define BRAM_NAME some_bram
-`include "bram.inc"
+
+/* bram.inc */
+module `BRAM_NAME(clk, we, a, dpra, di, spo, dpo);
+ input clk;
+ input we;
+ input [(`BRAM_ADDR_WIDTH-1):0] a;
+ input [(`BRAM_ADDR_WIDTH-1):0] dpra;
+ input [(`BRAM_DATA_WIDTH-1):0] di;
+ output [(`BRAM_DATA_WIDTH-1):0] spo;
+ output [(`BRAM_DATA_WIDTH-1):0] dpo;
+ reg [(`BRAM_DATA_WIDTH-1):0] ram [((1<<(`BRAM_ADDR_WIDTH))-1):0];
+ reg [(`BRAM_ADDR_WIDTH-1):0] read_a;
+ reg [(`BRAM_ADDR_WIDTH-1):0] read_dpra;
+ always @(posedge clk) begin
+ if (we)
+ ram[a] <= di;
+ read_a <= a;
+ read_dpra <= dpra;
+ end
+ assign spo = ram[read_a];
+ assign dpo = ram[read_dpra];
+endmodule
+/* bram.inc */
module memory (clk,
cbd_r, cbd_a_, cbd_d,
in_addr_r, in_addr_a_, in_addr_d,
+ write_addr_r, write_addr_a_, write_addr_d,
write_data_r, write_data_a_, write_data_d,
stride_r, stride_a_, stride_d,
count_r, count_a_, count_d,
input clk;
`input(in_addr_r, in_addr_a, in_addr_a_, [(2+`DATAWIDTH-1):0], in_addr_d)
+ `input(write_addr_r, write_addr_a, write_addr_a_, [(2+`DATAWIDTH-1):0], write_addr_d)
`input(write_data_r, write_data_a, write_data_a_, [(`DATAWIDTH-1):0], write_data_d)
`input(stride_r, stride_a, stride_a_, [(`DATAWIDTH-1):0], stride_d)
`input(count_r, count_a, count_a_, [(`DATAWIDTH-1):0], count_d)
`output(out_r, out_r_, out_a, [(`DATAWIDTH-1):0], out_d_)
- //`defreg(out_d_, [(`DATAWIDTH-1):0], out_d)
-
`input(preload_r, preload_a, preload_a_, [(`DATAWIDTH-1):0], preload_d)
`input(cbd_r, cbd_a, cbd_a_, [(`DATAWIDTH-1):0], cbd_d)
- `output(ihorn_r, ihorn_r_, ihorn_a, [(`INSTRUCTION_WIDTH-1):0], ihorn_d_)
- `defreg(ihorn_d_, [(`INSTRUCTION_WIDTH-1):0], ihorn_d)
+ `output(ihorn_r, ihorn_r_, ihorn_a, [(`PACKET_WIDTH-1):0], ihorn_d_)
+ `defreg(ihorn_d_, [(`PACKET_WIDTH-1):0], ihorn_d)
`output(dhorn_r, dhorn_r_, dhorn_a, [(`PACKET_WIDTH-1):0], dhorn_d_)
`defreg(dhorn_d_, [(`PACKET_WIDTH-1):0], dhorn_d)
if (!in_addr_r && in_addr_a) in_addr_a = 0;
if (!write_data_r && write_data_a) write_data_a = 0;
+ if (!write_addr_r && write_addr_a) write_addr_a = 0;
if (command_valid_read) begin
command_valid_read <= 0;
send_read <= 0;
end
- end else if (in_addr_r && !in_addr_d[`DATAWIDTH]) begin
+ end else if (in_addr_r) begin
in_addr_a = 1;
send_read <= 1;
current_instruction_read_from <= in_addr_d[(`DATAWIDTH-1):0];
- end else if (in_addr_r && in_addr_d[`DATAWIDTH] && write_data_r) begin
- in_addr_a = 1;
+ end else if (write_addr_r && write_data_r) begin
+ write_addr_a = 1;
write_data_a = 1;
send_done <= 1;
write_flag <= 1;
- in_addr <= in_addr_d[(`DATAWIDTH-1):0];
+ in_addr <= write_addr_d[(`DATAWIDTH-1):0];
write_data <= write_data_d;
end else if (ihorn_full && launched) begin
end else if (command_valid) begin
command_valid <= 0;
command = ramread;
- case (command[(`INSTRUCTION_WIDTH-1):(`INSTRUCTION_WIDTH-2)])
- 0: begin
- ihorn_full <= 1;
- ihorn_d <= command;
- end
- 1: begin
- dhorn_full <= 1;
- temp = command[(`INSTRUCTION_WIDTH-(2+`DESTINATION_ADDRESS_BITS)):0];
- temp = temp + ( { current_instruction_read_from, {(`CODEBAG_SIZE_BITS){1'b0}} });
- data[(`DATAWIDTH-1):(`CODEBAG_SIZE_BITS)] = temp;
- data[(`CODEBAG_SIZE_BITS-1):0] = command[(`CODEBAG_SIZE_BITS-1):0];
- `packet_data(dhorn_d) <= temp;
- `packet_dest(dhorn_d) <=
- command[(`INSTRUCTION_WIDTH-3):(`INSTRUCTION_WIDTH-(3+`DESTINATION_ADDRESS_BITS)+1)];
- end
- 2: begin
- dhorn_full <= 1;
- `packet_data(dhorn_d) <= { {(`DATAWIDTH-24){command[23]}}, command[23:0] };
- `packet_dest(dhorn_d) <= command[34:24];
- end
- 3: begin
- dhorn_full <= 1;
- `packet_data(dhorn_d) <= { {(`DATAWIDTH-24){command[23]}}, command[23:0] } + current_instruction_read_from;
- `packet_dest(dhorn_d) <= command[34:24];
- end
- endcase
+ ihorn_full <= 1;
+ `packet_data(ihorn_d) <= `instruction_data(command);
+ `packet_dest(ihorn_d) <= `instruction_dest(command);
end else if (cbd_pos < cbd_size) begin
current_instruction_read_from <= cbd_base+cbd_pos;
+== Test ==============================================================
+// expected output
+#expect 12
+#expect 13
+#expect 14
+
+// ships required in order to run this code
+#ship debug : Debug
+#ship memory : Memory
+
+// instructions not in any codebag are part of the "root codebag"
+// which is dispatched when the code is loaded
+
+memory.inCBD:
+ literal BOB;
+ deliver;
+
+BOB: {
+ debug.in:
+ literal 12; deliver;
+ literal 13; deliver;
+ literal 14; deliver;
+}
== Constants ========================================================
-== TeX ==============================================================
-\begin{verbatim}
-TODO: count/stride
-TODO: multiple interfaces to a single memory
-\end{verbatim}
== Contributors =========================================================
Adam Megacz <megacz@cs.berkeley.edu>