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- // -----------------------------------------------------------------------
- //
- // Copyright 2010-2021 H. Peter Anvin - All Rights Reserved
- //
- // 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, Inc., 51 Franklin St, Fifth Floor,
- // Boston MA 02110-1301, USA; either version 2 of the License, or
- // (at your option) any later version; incorporated herein by reference.
- //
- // -----------------------------------------------------------------------
- //
- // Simple SDRAM controller
- //
- // Very simple non-parallelizing SDRAM controller.
- //
- //
- // Two ports are provided:
- // Port 1 does aligned 4-byte accesses with byte enables.
- // Port 2 does aligned 8-byte accesses, write only, with no byte
- // enables; it supports streaming from a FIFO.
- //
- // Port 1 is multiplexed via an arbiter, which receives a bus
- // defined by the sdram_bus interface.
- //
- // All signals are in the sdram clock domain.
- //
- // [rw]ack is asserted at the beginning of a read- or write cycle and
- // deasserted afterwards; rready is asserted once all data is read and
- // the read data (rdX port) is valid; it remains asserted after the
- // transaction is complete and rack is deasserted.
- //
- //
- // The interface to the port modules. The read data is 16 bits
- // at a time, and is only valid in the cycle rstrb[x] is asserted.
- //
- // The only output signal that is unique to this port
- // is "start". All other signals are broadcast.
- //
- interface dram_bus;
- logic [1:0] prio; // Priority vs refresh
- logic rst_n;
- logic clk;
- logic [24:0] addr;
- logic addr0; // addr[0] latched at transaction start
- logic [15:0] rd;
- logic req;
- logic [1:0] rstrb; // Data read strobe
- logic [31:0] wd;
- logic [3:0] wstrb;
- logic start; // Transaction start
- logic wrack; // Transaction is a write
- // Upstream direction
- modport ustr (
- input prio,
- output rst_n,
- output clk,
- input addr,
- output addr0,
- output rd,
- input req,
- output rstrb,
- input wd,
- input wstrb,
- output start,
- output wrack
- );
- // Downstream direction
- modport dstr (
- output prio,
- input rst_n,
- input clk,
- output addr,
- input addr0,
- input rd,
- output req,
- input rstrb,
- output wd,
- output wstrb,
- input start,
- input wrack
- );
- endinterface // dram_bus
- // Port into the DRAM
- module dram_port
- #(parameter width = 32)
- (
- dram_bus.dstr bus,
- input [1:0] prio,
- input [24:0] addr,
- output reg [width-1:0] rd,
- input valid,
- output reg ready,
- input [width-1:0] wd,
- input [(width >> 3)-1:0] wstrb
- );
- reg started;
- assign bus.prio = prio;
- assign bus.addr = addr;
- assign bus.req = valid & ~started;
- always_comb
- begin
- bus.wd = 32'hxxxx_xxxx;
- bus.wstrb = 4'b0000;
- if (width == 8)
- begin
- bus.wd[15:0] = { wd, wd };
- bus.wstrb[1:0] = { wstrb[0] & addr[0], wstrb[0] & ~addr[0] };
- end
- else
- begin
- bus.wd[width-1:0] = wd;
- bus.wstrb[(width >> 3)-1:0] = wstrb;
- end
- end
- always @(negedge bus.rst_n or posedge bus.clk)
- if (~bus.rst_n)
- begin
- ready <= 1'b0;
- started <= 1'b0;
- end
- else
- begin
- if (~valid)
- begin
- ready <= 1'b0;
- started <= 1'b0;
- end
- else if (bus.start)
- begin
- started <= 1'b1;
- ready <= bus.wrack;
- end
- else if (started & ~ready)
- begin
- ready <= bus.rstrb[(width - 1) >> 4];
- end
- end // else: !if(~bus.rst_n)
- genvar i;
- generate
- for (i = 0; i < ((width + 15) >> 4); i++)
- begin : w
- always @(posedge bus.clk)
- if (started & ~ready & bus.rstrb[i])
- begin
- if (width == 8)
- rd <= bus.addr0 ? bus.rd[15:8] : bus.rd[7:0];
- else
- rd[i*16+15:i*16] <= bus.rd;
- end
- end
- endgenerate
- endmodule // dram_port
- module dram_arbiter
- #(parameter port_count = 1)
- (
- dram_bus.ustr ustr [1:port_count],
- dram_bus.dstr dstr,
- input [1:0] rfsh_prio,
- output logic do_rfsh
- );
- logic [31:0] u_wd[1:port_count];
- logic [3:0] u_wstrb[1:port_count];
- logic [24:0] u_addr[1:port_count];
- logic [port_count:0] grant;
- assign grant[0] = 1'b0; // Dummy to make the below logic simpler
- reg [port_count:0] grant_q;
- always @(negedge dstr.rst_n or posedge dstr.clk)
- if (~dstr.rst_n)
- grant_q <= 'b0;
- else
- grant_q <= grant;
- generate
- genvar i;
- for (i = 1; i <= port_count; i++)
- begin : u
- assign ustr[i].rst_n = dstr.rst_n;
- assign ustr[i].clk = dstr.clk;
- assign ustr[i].addr0 = dstr.addr0;
- assign ustr[i].rd = dstr.rd;
- assign ustr[i].rstrb = dstr.rstrb;
- assign ustr[i].wrack = dstr.wrack;
- assign grant[i] = ~|grant[i-1:0] & ustr[i].req &
- (ustr[i].prio >= rfsh_prio);
- assign u_addr[i] = ustr[i].addr;
- assign u_wd[i] = ustr[i].wd;
- assign u_wstrb[i] = ustr[i].wstrb;
- // Note: start indicates that the requestor from the *previous*
- // cycle was started.
- assign ustr[i].start = grant_q[i] & dstr.start;
- end // block: u
- endgenerate
- always_comb
- begin
- dstr.addr = 'bx;
- dstr.wd = 'bx;
- dstr.wstrb = 4'b0;
- dstr.req = 1'b0;
- do_rfsh = |rfsh_prio;
- for (int j = 1; j <= port_count; j++)
- if (grant[j])
- begin
- dstr.addr = u_addr[j];
- dstr.wd = u_wd[j];
- dstr.wstrb = u_wstrb[j];
- dstr.req = 1'b1;
- do_rfsh = 1'b0;
- end
- end // always_comb
- endmodule // dram_arbiter
- module sdram
- #( parameter
- port1_count = 1,
- // Timing parameters
- // The parameters are hardcoded for Micron MT48LC16M16A2-6A,
- // per datasheet:
- // 100 MHz 167 MHz
- // ----------------------------------------------------------
- // CL 2 3 READ to data out
- // tRCD 18 ns 2 3 ACTIVE to READ/WRITE
- // tRFC 60 ns 6 10 REFRESH to ACTIVE
- // tRP 18 ns 2 3 PRECHARGE to ACTIVE/REFRESH
- // tRAS 42 ns 5 7 ACTIVE to PRECHARGE
- // tRC 60 ns 6 10 ACTIVE to ACTIVE (same bank)
- // tRRD 12 ns 2 2 ACTICE to ACTIVE (different bank)
- // tWR 12 ns 2 2 Last write data to PRECHARGE
- // tMRD 2 2 MODE REGISTER to ACTIVE/REFRESH
- //
- // These parameters are set by power of 2:
- // tREFi 64/8192 ms 781 1302 Refresh time per row (max)
- // tP 100 us 10000 16667 Time until first command (min)
- t_cl = 3,
- t_rcd = 3,
- t_rfc = 10,
- t_rp = 3,
- t_ras = 7,
- t_rc = 10,
- t_rrd = 2,
- t_wr = 2,
- t_mrd = 2,
- t_refi_lg2 = 10, // 1024 cycles
- t_p_lg2 = 15, // 32768 cycles
- burst_lg2 = 1 // log2(burst length)
- )
- (
- // Reset and clock
- input rst_n,
- input clk,
- input init_tmr, // tRP timer
- input rfsh_tmr, // tREFI/2 timer
- // SDRAM hardware interface
- output sr_cs_n, // SDRAM CS#
- output sr_ras_n, // SDRAM RAS#
- output sr_cas_n, // SDRAM CAS#
- output sr_we_n, // SDRAM WE#
- output [1:0] sr_dqm, // SDRAM DQM (per byte)
- output [1:0] sr_ba, // SDRAM bank selects
- output [12:0] sr_a, // SDRAM address bus
- inout [15:0] sr_dq, // SDRAM data bus
- // Port 1
- dram_bus.ustr port1 [1:port1_count],
- // Port 2
- input [24:1] a2,
- input [15:0] wd2,
- input [1:0] wrq2,
- output reg wacc2 // Data accepted, advance data & addr
- );
- `include "functions.sv" // For modelsim
- // Mode register data
- wire mrd_wburst = 1'b1; // Write bursts enabled
- wire [2:0] mrd_cl = t_cl;
- wire [2:0] mrd_burst = burst_lg2;
- wire mrd_interleave = 1'b0; // Interleaved bursts
- wire [12:0] mrd_val = { 3'b000, // Reserved
- ~mrd_wburst, // Write burst disable
- 2'b00, // Normal operation
- mrd_cl, // CAS latency
- mrd_interleave, // Interleaved bursts
- mrd_burst }; // Burst length
- // Where to issue a PRECHARGE when we only want to read one word
- // (terminate the burst as soon as possible, but no sooner...)
- localparam t_pre_rd_when = max(t_ras, t_rcd + 1);
- // Where to issue a PRECHARGE when we only want to write one word
- // (terminate the burst as soon as possible, but no sooner...)
- localparam t_pre_wr_when = max(t_ras, t_rcd + t_wr);
- // Actual burst length (2^burst_lg2)
- localparam burst_n = 1 << burst_lg2;
- // Command opcodes and attributes (is_rfsh, CS#, RAS#, CAS#, WE#)
- localparam cmd_desl = 5'b0_1111; // Deselect (= NOP)
- localparam cmd_nop = 5'b0_0111; // NO OPERATION
- localparam cmd_bst = 5'b0_0110; // BURST TERMINATE
- localparam cmd_rd = 5'b0_0101; // READ
- localparam cmd_wr = 5'b0_0100; // WRITE
- localparam cmd_act = 5'b0_0011; // ACTIVE
- localparam cmd_pre = 5'b0_0010; // PRECHARGE
- localparam cmd_ref = 5'b1_0001; // AUTO REFRESH
- localparam cmd_mrd = 5'b0_0000; // LOAD MODE REGISTER
- reg [4:0] dram_cmd;
- wire is_rfsh = dram_cmd[4];
- assign sr_cs_n = dram_cmd[3];
- assign sr_ras_n = dram_cmd[2];
- assign sr_cas_n = dram_cmd[1];
- assign sr_we_n = dram_cmd[0];
- // SDRAM output signal registers
- reg [12:0] dram_a;
- assign sr_a = dram_a;
- reg [1:0] dram_ba;
- assign sr_ba = dram_ba;
- reg [1:0] dram_dqm;
- assign sr_dqm = dram_dqm;
- reg [15:0] dram_d; // Data to DRAM
- reg [15:0] dram_q; // Data from DRAM (I/O buffers)
- reg dram_d_en; // Drive data out
- assign sr_dq = dram_d_en ? dram_d : 16'hzzzz;
- // Refresh timer logic
- reg rfsh_tmr_q;
- reg [1:0] rfsh_prio; // Refresh priority (0-3)
- // Port1 and refresh arbiter
- dram_bus p1 ();
- wire do_rfsh;
- assign p1.rst_n = rst_n;
- assign p1.clk = clk;
- dram_arbiter #(.port_count(port1_count))
- arbiter (
- .ustr ( port1 ),
- .dstr ( p1.dstr ),
- .rfsh_prio ( rfsh_prio ),
- .do_rfsh ( do_rfsh )
- );
- // The actual values are unimportant; the compiler will optimize
- // the state machine implementation.
- typedef enum logic [3:0] {
- st_reset, // Reset until init timer expires
- st_init_rfsh, // Refresh cycles during initialization
- st_init_mrd, // MRD register write during initialization
- st_ready, // Ready to issue command in the next cycle
- st_rfsh, // Refresh cycle
- st_rd_wr_act, // Port 1 ACT command
- st_rd_wr, // Port 1 transaction
- st_wr2_act, // Port 2 write ACT command
- st_wr2 // Port 2 write (burstable)
- } state_t;
- state_t state = st_reset;
- always @(posedge clk or negedge rst_n)
- if (~rst_n)
- begin
- rfsh_tmr_q <= 1'b0;
- rfsh_prio <= 2'b00;
- end
- else
- begin
- rfsh_tmr_q <= rfsh_tmr; // Edge detect
- // Refresh priority management: saturating 2-bit counter
- if (is_rfsh)
- rfsh_prio <= 2'b00; // This is a refresh cycle
- else if (rfsh_tmr & ~rfsh_tmr_q)
- rfsh_prio <= rfsh_prio + (~&rfsh_prio);
- end // else: !if(~rst_n)
- reg [5:0] op_ctr; // Cycle into the current state
- wire [3:0] op_cycle = op_ctr[3:0]; // Cycle into the current command
- wire [1:0] init_op_ctr = op_ctr[5:4]; // Init operation counter
- reg op_zero; // op_cycle wrap around (init_op_ctr changed)
- reg [31:0] wdata_q;
- reg [ 3:0] be_q;
- reg [24:0] addr;
- reg wrq2_more;
- wire [13:0] row_addr = addr[24:12];
- wire [1:0] bank_addr = addr[11:10];
- wire [8:0] col_addr = addr[9:1];
- assign p1.addr0 = addr[0];
- assign p1.rd = dram_q;
- //
- // Careful with the timing here... there is one cycle between
- // registers and wires, and the DRAM observes the clock 1/2
- // cycle from the internal logic. This affects read timing.
- //
- // Note that rready starts out as 1. This allows a 0->1 detection
- // on the rready line to be used as cycle termination signal.
- //
- always @(posedge clk or negedge rst_n)
- if (~rst_n)
- begin
- dram_cmd <= cmd_desl;
- dram_a <= 13'hxxxx;
- dram_ba <= 2'bxx;
- dram_dqm <= 2'b00;
- dram_d <= 16'hxxxx;
- dram_q <= 16'hxxxx;
- dram_d_en <= 1'b1; // Don't float except during read
- op_ctr <= 6'h0;
- op_zero <= 1'b0;
- state <= st_reset;
- p1.start <= 1'b0;
- p1.wrack <= 1'bx;
- p1.rd <= 16'hxxxx;
- p1.rstrb <= 2'b00;
- wacc2 <= 1'b0;
- wrq2_more <= 1'bx;
- wdata_q <= 32'hxxxx_xxxx;
- be_q <= 4'bxxxx;
- addr <= 25'bx;
- end
- else
- begin
- // Default values
- dram_a <= 13'b0;
- dram_ba <= bank_addr;
- dram_dqm <= 2'b00;
- dram_d <= { 8'hAA, 3'b000, dram_cmd };
- dram_cmd <= cmd_nop;
- dram_d_en <= 1'b1; // Don't float except during read
- dram_q <= sr_dq;
- p1.rstrb <= 2'b00;
- wacc2 <= 1'b0;
- op_ctr <= op_ctr + 1'b1;
- op_zero <= &op_cycle; // About to wrap around
- p1.start <= 1'b0;
- case (state)
- st_reset:
- begin
- op_ctr <= 6'b0;
- op_zero <= 1'b0;
- dram_a[10] <= 1'b1; // Precharge all banks
- dram_cmd <= cmd_nop;
- if (init_tmr)
- begin
- dram_cmd <= cmd_pre;
- state <= st_init_rfsh;
- end
- end
- st_init_rfsh:
- begin
- if (op_zero)
- begin
- dram_cmd <= cmd_ref;
- if (init_op_ctr == 2'b11)
- state <= st_init_mrd;
- end
- end
- st_init_mrd:
- begin
- dram_a <= mrd_val;
- dram_ba <= 2'b00;
- if (op_zero)
- if (init_op_ctr[0])
- state <= st_ready;
- else
- dram_cmd <= cmd_mrd;
- end
- st_ready:
- begin
- op_ctr <= 6'b0;
- op_zero <= 1'b0;
- dram_cmd <= cmd_desl;
- p1.wrack <= 1'bx;
- be_q <= 4'bxxxx;
- wdata_q <= 32'hxxxx_xxxx;
- addr <= 25'bx;
- dram_a <= 13'h1bb;
- dram_d <= 16'hbbbb;
- // Port 1 and refresh have priority over port 2;
- // the various port 1 instances and refresh have
- // priorities set by the arbiter block.
- if (do_rfsh)
- begin
- state <= st_rfsh;
- end
- else if (p1.req)
- begin
- addr <= p1.addr;
- p1.wrack <= |p1.wstrb;
- wdata_q <= p1.wd;
- be_q <= p1.wstrb;
- state <= st_rd_wr_act;
- p1.start <= 1'b1;
- end // if (p1.req)
- else if (wrq2[0])
- begin
- // Begin port 2 write
- addr <= { a2, 1'b0 };
- state <= st_wr2_act;
- end
- end // case: st_ready
- st_rfsh: begin
- if (op_cycle == 0)
- dram_cmd <= cmd_ref;
- else if (op_cycle == t_rfc-2)
- state <= st_ready;
- end
- st_rd_wr_act: begin
- op_ctr <= 6'b0;
- op_zero <= 1'b0;
- dram_cmd <= cmd_act;
- dram_a <= row_addr;
- dram_ba <= bank_addr;
- state <= st_rd_wr;
- end
- st_rd_wr:
- begin
- dram_d_en <= p1.wrack;
- dram_dqm <= {2{p1.wrack}};
- dram_d <= 16'hcccc ^ {16{p1.wrack}};
- // Commands
- //
- // This assumes:
- // tRCD = 3
- // rRRD = 2
- // CL = 3
- // tRC = 10
- // tRAS = 7
- // tWR = 2
- // tRP = 3
- //
- case (op_cycle)
- 2: begin
- dram_a[10] <= 1'b0; // No auto precharge
- dram_a[8:0] <= col_addr;
- dram_cmd <= p1.wrack ? cmd_wr : cmd_rd;
- dram_d <= wdata_q[15:0];
- dram_dqm <= {2{p1.wrack}} & ~be_q[1:0];
- end
- 3: begin
- dram_d <= wdata_q[31:16];
- dram_dqm <= {2{p1.wrack}} & ~be_q[3:2];
- end
- 6: begin
- // Earliest legal cycle to precharge
- // It seems auto precharge violates tRAS(?)
- // so do it explicitly.
- dram_a[10] <= 1'b1; // One bank
- dram_cmd <= cmd_pre;
- end
- // CL+2 cycles after the read command
- // The +2 accounts for internal and I/O delays
- 7: begin
- p1.rstrb[0] <= ~p1.wrack;
- end
- 8: begin
- p1.rstrb[1] <= ~p1.wrack;
- state <= st_ready;
- end
- default: begin
- // Do nothing
- end
- endcase // case (op_cycle)
- end // case: st_rd_wr
- st_wr2_act:
- begin
- op_ctr <= 6'b0;
- op_zero <= 1'b0;
- dram_a <= row_addr;
- dram_ba <= bank_addr;
- dram_cmd <= cmd_act;
- state <= st_wr2;
- end
- st_wr2:
- begin
- // Streamable write from flash ROM
- // Note: wacc is asserted in the cycle *before* the
- // data and address is latched/consumed.
- dram_d <= wd2;
- dram_a[10] <= 1'b0; // No auto precharge/precharge one bank
- dram_a[8:0] <= a2[9:1];
- dram_dqm <= 2'b11;
- case (op_cycle)
- 0, 1: begin
- wacc2 <= 1'b1;
- dram_dqm <= 2'b00;
- end
- 2: begin
- dram_cmd <= cmd_wr;
- wacc2 <= 1'b1;
- dram_dqm <= 2'b00;
- wrq2_more <= wrq2[1] & (~&a2[9:3]);
- end
- 3: begin
- wacc2 <= 1'b1;
- dram_dqm <= 2'b00;
- end
- 4: begin
- dram_cmd <= cmd_wr;
- dram_dqm <= 2'b00;
- if (wrq2_more & ~(p1.req | do_rfsh))
- begin
- // Burst can continue
- wacc2 <= 1'b1;
- op_ctr[3:0] <= 4'd1;
- end
- end
- 5: begin
- dram_dqm <= 2'b00;
- end
- 6: begin
- // Nothing
- end
- 7: begin
- // tWR completed
- dram_cmd <= cmd_pre;
- end
- 8: begin
- // tRP will be complete before the next ACT
- state <= st_ready;
- end
- default: begin
- // Do nothing
- end
- endcase // case (op_cycle)
- end // case: st_wr2
- endcase // case(state)
- end // else: !if(~rst_n)
- endmodule // dram
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