SummerCart64/fw/rtl/serv/serv_state.v

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module serv_state
#(parameter RESET_STRATEGY = "MINI",
parameter [0:0] WITH_CSR = 1,
parameter [0:0] ALIGN =0,
parameter [0:0] MDU = 0,
parameter W = 1
)
(
input wire i_clk,
input wire i_rst,
//State
input wire i_new_irq,
input wire i_alu_cmp,
output wire o_init,
output reg o_cnt_en,
output wire o_cnt0to3,
output wire o_cnt12to31,
output wire o_cnt0,
output wire o_cnt1,
output wire o_cnt2,
output wire o_cnt3,
output wire o_cnt7,
output wire o_cnt_done,
output wire o_bufreg_en,
output wire o_ctrl_pc_en,
output reg o_ctrl_jump,
output wire o_ctrl_trap,
input wire i_ctrl_misalign,
input wire i_sh_done,
input wire i_sh_done_r,
output wire [1:0] o_mem_bytecnt,
input wire i_mem_misalign,
//Control
input wire i_bne_or_bge,
input wire i_cond_branch,
input wire i_dbus_en,
input wire i_two_stage_op,
input wire i_branch_op,
input wire i_shift_op,
input wire i_sh_right,
input wire i_slt_or_branch,
input wire i_e_op,
input wire i_rd_op,
//MDU
input wire i_mdu_op,
output wire o_mdu_valid,
//Extension
input wire i_mdu_ready,
//External
output wire o_dbus_cyc,
input wire i_dbus_ack,
output wire o_ibus_cyc,
input wire i_ibus_ack,
//RF Interface
output wire o_rf_rreq,
output wire o_rf_wreq,
input wire i_rf_ready,
output wire o_rf_rd_en);
reg stage_two_req;
reg init_done;
wire misalign_trap_sync;
reg [4:2] o_cnt;
reg [3:0] cnt_r;
reg ibus_cyc;
//Update PC in RUN or TRAP states
assign o_ctrl_pc_en = o_cnt_en & !o_init;
assign o_mem_bytecnt = o_cnt[4:3];
assign o_cnt0to3 = (o_cnt[4:2] == 3'd0);
assign o_cnt12to31 = (o_cnt[4] | (o_cnt[3:2] == 2'b11));
assign o_cnt0 = (o_cnt[4:2] == 3'd0) & cnt_r[0];
assign o_cnt1 = (o_cnt[4:2] == 3'd0) & cnt_r[1];
assign o_cnt2 = (o_cnt[4:2] == 3'd0) & cnt_r[2];
assign o_cnt3 = (o_cnt[4:2] == 3'd0) & cnt_r[3];
assign o_cnt7 = (o_cnt[4:2] == 3'd1) & cnt_r[3];
//Take branch for jump or branch instructions (opcode == 1x0xx) if
//a) It's an unconditional branch (opcode[0] == 1)
//b) It's a conditional branch (opcode[0] == 0) of type beq,blt,bltu (funct3[0] == 0) and ALU compare is true
//c) It's a conditional branch (opcode[0] == 0) of type bne,bge,bgeu (funct3[0] == 1) and ALU compare is false
//Only valid during the last cycle of INIT, when the branch condition has
//been calculated.
wire take_branch = i_branch_op & (!i_cond_branch | (i_alu_cmp^i_bne_or_bge));
//valid signal for mdu
assign o_mdu_valid = MDU & !o_cnt_en & init_done & i_mdu_op;
//Prepare RF for writes when everything is ready to enter stage two
// and the first stage didn't cause a misalign exception
assign o_rf_wreq = !misalign_trap_sync & !o_cnt_en & init_done &
((i_shift_op & (i_sh_done | !i_sh_right)) |
i_dbus_ack | (MDU & i_mdu_ready) |
i_slt_or_branch);
assign o_dbus_cyc = !o_cnt_en & init_done & i_dbus_en & !i_mem_misalign;
//Prepare RF for reads when a new instruction is fetched
// or when stage one caused an exception (rreq implies a write request too)
assign o_rf_rreq = i_ibus_ack | (stage_two_req & misalign_trap_sync);
assign o_rf_rd_en = i_rd_op & !o_init;
/*
bufreg is used during mem. branch and shift operations
mem : bufreg is used for dbus address. Shift in data during phase 1.
Shift out during phase 2 if there was an misalignment exception.
branch : Shift in during phase 1. Shift out during phase 2
shift : Shift in during phase 1. Continue shifting between phases (except
for the first cycle after init). Shift out during phase 2
*/
assign o_bufreg_en = (o_cnt_en & (o_init | ((o_ctrl_trap | i_branch_op) & i_two_stage_op))) | (i_shift_op & !stage_two_req & (i_sh_right | i_sh_done_r) & init_done);
assign o_ibus_cyc = ibus_cyc & !i_rst;
assign o_init = i_two_stage_op & !i_new_irq & !init_done;
assign o_cnt_done = (o_cnt[4:2] == 3'b111) & cnt_r[3];
always @(posedge i_clk) begin
//ibus_cyc changes on three conditions.
//1. i_rst is asserted. Together with the async gating above, o_ibus_cyc
// will be asserted as soon as the reset is released. This is how the
// first instruction is fetced
//2. o_cnt_done and o_ctrl_pc_en are asserted. This means that SERV just
// finished updating the PC, is done with the current instruction and
// o_ibus_cyc gets asserted to fetch a new instruction
//3. When i_ibus_ack, a new instruction is fetched and o_ibus_cyc gets
// deasserted to finish the transaction
if (i_ibus_ack | o_cnt_done | i_rst)
ibus_cyc <= o_ctrl_pc_en | i_rst;
if (o_cnt_done) begin
init_done <= o_init & !init_done;
o_ctrl_jump <= o_init & take_branch;
end
//Need a strobe for the first cycle in the IDLE state after INIT
stage_two_req <= o_cnt_done & o_init;
if (i_rst) begin
if (RESET_STRATEGY != "NONE") begin
init_done <= 1'b0;
o_ctrl_jump <= 1'b0;
stage_two_req <= 1'b0;
end
end
end
always @(posedge i_clk) begin
/*
Because SERV is 32-bit bit-serial we need a counter than can count 0-31
to keep track of which bit we are currently processing. o_cnt and cnt_r
are used together to create such a counter.
The top three bits (o_cnt) are implemented as a normal counter, but
instead of the two LSB, cnt_r is a 4-bit shift register which loops 0-3
When cnt_r[3] is 1, o_cnt will be increased.
The counting starts when the core is idle and the i_rf_ready signal
comes in from the RF module by shifting in the i_rf_ready bit as LSB of
the shift register. Counting is stopped by using o_cnt_done to block the
bit that was supposed to be shifted into bit 0 of cnt_r.
There are two benefit of doing the counter this way
1. We only need to check four bits instead of five when we want to check
if the counter is at a certain value. For 4-LUT architectures this means
we only need one LUT instead of two for each comparison.
2. We don't need a separate enable signal to turn on and off the counter
between stages, which saves an extra FF and a unique control signal. We
just need to check if cnt_r is not zero to see if the counter is
currently running
*/
if (W == 4) begin
if (i_rf_ready) o_cnt_en <= 1; else
if (o_cnt_done) o_cnt_en <= 0;
o_cnt <= o_cnt + { 2'b0, o_cnt_en };
end else if (W == 1) begin
o_cnt <= o_cnt + {2'd0,cnt_r[3]};
cnt_r <= {cnt_r[2:0],(cnt_r[3] & !o_cnt_done) | (i_rf_ready & !o_cnt_en)};
end
if (i_rst) begin
if (RESET_STRATEGY != "NONE") begin
o_cnt <= 3'd0;
if (W == 1)
cnt_r <= 4'b0000;
else if (W == 4)
o_cnt_en <= 1'b0;
end
end
end
always @(*)
if (W == 1)
o_cnt_en = |cnt_r;
else if (W == 4)
cnt_r = 4'b1111;
assign o_ctrl_trap = WITH_CSR & (i_e_op | i_new_irq | misalign_trap_sync);
generate
if (WITH_CSR) begin : gen_csr
reg misalign_trap_sync_r;
//trap_pending is only guaranteed to have correct value during the
// last cycle of the init stage
wire trap_pending = WITH_CSR & ((take_branch & i_ctrl_misalign & !ALIGN) |
(i_dbus_en & i_mem_misalign));
always @(posedge i_clk) begin
if (i_ibus_ack | o_cnt_done | i_rst)
misalign_trap_sync_r <= !(i_ibus_ack | i_rst) & ((trap_pending & o_init) | misalign_trap_sync_r);
end
assign misalign_trap_sync = misalign_trap_sync_r;
end else begin : gen_no_csr
assign misalign_trap_sync = 1'b0;
end
endgenerate
endmodule