SummerCart64/fw/rtl/memory/memory_sdram.sv
Mateusz Faderewski 24f04ae916 verilator init
2024-07-07 00:09:03 +02:00

270 lines
8.2 KiB
Systemverilog

module memory_sdram (
input clk,
input reset,
mem_bus.memory mem_bus,
output logic sdram_cs,
output logic sdram_ras,
output logic sdram_cas,
output logic sdram_we,
output logic [1:0] sdram_ba,
output logic [12:0] sdram_a,
output logic [1:0] sdram_dqm,
inout [15:0] sdram_dq
);
// in Hz
localparam real FREQUENCY = 100_000_000.0;
// in clocks
localparam bit [2:0] CAS_LATENCY = 3'd2;
// in nanoseconds
localparam real T_INIT = 100_000.0;
localparam real T_RC = 60.0;
localparam real T_RP = 15.0;
localparam real T_RCD = 15.0;
localparam real T_MRD = 14.0;
localparam real T_REF = 7_812.5;
localparam real T_CLK = (1.0 / FREQUENCY) * 1_000_000_000.0;
const bit [13:0] C_INIT = 14'(int'($ceil(T_INIT / T_CLK)));
const bit [4:0] C_RC = 5'(int'($ceil(T_RC / T_CLK)));
const bit [4:0] C_RP = 5'(int'($ceil(T_RP / T_CLK)));
const bit [4:0] C_RCD = 5'(int'($ceil(T_RCD / T_CLK)));
const bit [4:0] C_MRD = 5'(int'($ceil(T_MRD / T_CLK)));
const bit [13:0] C_REF = 14'(int'($ceil(T_REF / T_CLK)));
const bit [4:0] INIT_PRECHARGE = 5'd0;
const bit [4:0] INIT_REFRESH_1 = INIT_PRECHARGE + C_RP;
const bit [4:0] INIT_REFRESH_2 = INIT_REFRESH_1 + C_RC;
const bit [4:0] INIT_MODE_REG = INIT_REFRESH_2 + C_RC;
const bit [4:0] INIT_DONE = INIT_MODE_REG + C_MRD;
// /CS, /RAS, /CAS, /WE
typedef enum bit [3:0] {
CMD_DESL = 4'b1111,
CMD_NOP = 4'b0111,
CMD_READ = 4'b0101,
CMD_WRITE = 4'b0100,
CMD_ACT = 4'b0011,
CMD_PRE = 4'b0010,
CMD_REF = 4'b0001,
CMD_MRS = 4'b0000
} e_sdram_cmd;
e_sdram_cmd sdram_next_cmd;
logic [15:0] sdram_dq_input;
logic [15:0] sdram_dq_output;
logic sdram_dq_output_enable;
logic [14:0] current_active_bank_row;
logic request_in_current_active_bank_row;
always_ff @(posedge clk) begin
{sdram_cs, sdram_ras, sdram_cas, sdram_we} <= 4'(sdram_next_cmd);
{sdram_ba, sdram_a} <= 15'd0;
sdram_dqm <= 2'b00;
sdram_dq_input <= sdram_dq;
sdram_dq_output <= mem_bus.wdata;
sdram_dq_output_enable <= 1'b0;
case (sdram_next_cmd)
CMD_READ, CMD_WRITE: begin
{sdram_ba, sdram_a} <= {mem_bus.address[25:24], 3'b000, mem_bus.address[10:1]};
sdram_dqm <= (sdram_next_cmd == CMD_WRITE) ? (~mem_bus.wmask) : 2'b00;
sdram_dq_output_enable <= (sdram_next_cmd == CMD_WRITE);
end
CMD_ACT: begin
{sdram_ba, sdram_a} <= mem_bus.address[25:11];
current_active_bank_row <= mem_bus.address[25:11];
end
CMD_PRE: begin
{sdram_ba, sdram_a} <= {
2'b00, // [BA1:BA0] Don't care
2'b00, // [A12:A11] Don't care
1'b1, // [A10] Precharge all banks
10'd0 // [A9:A0] Don't care
};
end
CMD_MRS: begin
{sdram_ba, sdram_a} <= {
2'b00, // [BA1:BA0] Reserved = 0
3'b00, // [A12:A10] Reserved = 0
1'b0, // [A9] Write Burst Mode = Programmed Burst Length
2'b00, // [A8:A7] Operating Mode = Standard Operation
CAS_LATENCY, // [A6:A4] Latency Mode = 2
1'b0, // [A3] Burst Type = Sequential
3'b000 // [A2:A0] Burst Length = 1
};
end
default: begin end
endcase
end
assign sdram_dq = sdram_dq_output_enable ? sdram_dq_output : 16'hZZZZ;
always_comb begin
mem_bus.rdata = sdram_dq_input;
request_in_current_active_bank_row = mem_bus.address[25:11] == current_active_bank_row;
end
typedef enum bit [2:0] {
S_POWERUP,
S_INIT,
S_IDLE,
S_ACTIVATING,
S_ACTIVE,
S_BUSY,
S_PRECHARGE,
S_REFRESH
} e_state;
e_state state;
e_state next_state;
always_ff @(posedge clk) begin
if (reset) begin
state <= S_POWERUP;
end else begin
state <= next_state;
end
end
logic [13:0] refresh_counter;
logic [4:0] wait_counter;
logic powerup_done;
logic pending_refresh;
always_ff @(posedge clk) begin
refresh_counter <= refresh_counter + 1'd1;
if (refresh_counter == C_INIT) begin
refresh_counter <= 14'd0;
powerup_done <= 1'b1;
end
if (powerup_done && refresh_counter == C_REF - 14'd1) begin
refresh_counter <= 14'd0;
pending_refresh <= 1'b1;
end
if (sdram_next_cmd == CMD_REF) begin
pending_refresh <= 1'b0;
end
if (reset) begin
refresh_counter <= 14'd0;
powerup_done <= 1'b0;
pending_refresh <= 1'b0;
end
wait_counter <= wait_counter + 1'd1;
if (state != next_state) begin
wait_counter <= 5'd0;
end
end
logic [(CAS_LATENCY):0] read_cmd_ack_delay;
always_ff @(posedge clk) begin
mem_bus.ack <= 1'b0;
read_cmd_ack_delay <= {sdram_next_cmd == CMD_READ, read_cmd_ack_delay[(CAS_LATENCY):1]};
if (sdram_next_cmd == CMD_WRITE || read_cmd_ack_delay[0]) begin
mem_bus.ack <= 1'b1;
end
end
always_comb begin
sdram_next_cmd = CMD_NOP;
next_state = state;
case (state)
S_POWERUP: begin
sdram_next_cmd = CMD_DESL;
if (powerup_done) begin
next_state = S_INIT;
end
end
S_INIT: begin
if (wait_counter == INIT_PRECHARGE) begin
sdram_next_cmd = CMD_PRE;
end
if (wait_counter == INIT_REFRESH_1 || wait_counter == INIT_REFRESH_2) begin
sdram_next_cmd = CMD_REF;
end
if (wait_counter == INIT_MODE_REG) begin
sdram_next_cmd = CMD_MRS;
end
if (wait_counter == INIT_DONE) begin
next_state = S_IDLE;
end
end
S_IDLE: begin
if (pending_refresh) begin
next_state = S_REFRESH;
sdram_next_cmd = CMD_REF;
end else if (mem_bus.request) begin
next_state = S_ACTIVATING;
sdram_next_cmd = CMD_ACT;
end
end
S_ACTIVATING: begin
if (wait_counter == C_RCD - 5'd2) begin
next_state = S_ACTIVE;
end
end
S_ACTIVE: begin
if (pending_refresh) begin
next_state = S_PRECHARGE;
sdram_next_cmd = CMD_PRE;
end else if (mem_bus.request) begin
if (request_in_current_active_bank_row) begin
next_state = S_BUSY;
sdram_next_cmd = mem_bus.write ? CMD_WRITE : CMD_READ;
end else begin
next_state = S_PRECHARGE;
sdram_next_cmd = CMD_PRE;
end
end
end
S_BUSY: begin
if (mem_bus.ack) begin
next_state = S_ACTIVE;
end
end
S_PRECHARGE: begin
if (wait_counter == C_RP - 5'd2) begin
next_state = S_IDLE;
end
end
S_REFRESH: begin
if (wait_counter == C_RC - 5'd2) begin
next_state = S_IDLE;
end
end
default: begin
next_state = S_IDLE;
end
endcase
end
endmodule