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foss-eda-tools / third_party / shuttle / sky130 / mpw-001 / slot-015 / f744e2e9183a49c672605f2b9f3ed680184ecac4 / . / verilog / rtl / mgmt_protect.v
blob: 4dcf1117306599dbe3fe8755b91f8844f3bbbf39 [file] [log] [blame]
/*----------------------------------------------------------------------*/
/* Buffers protecting the management region from the user region. */
/* This mainly consists of tristate buffers that are enabled by a */
/* "logic 1" output connected to the user's VCCD domain. This ensures */
/* that the buffer is disabled and the output high-impedence when the */
/* user 1.8V supply is absent. */
/*----------------------------------------------------------------------*/
/* Because there is no tristate buffer with a non-inverted enable, a */
/* tristate inverter with non-inverted enable is used in series with */
/* another (normal) inverter. */
/*----------------------------------------------------------------------*/
/* For the sake of placement/routing, one conb (logic 1) cell is used */
/* for every buffer. */
/*----------------------------------------------------------------------*/
module mgmt_protect (
inout vccd,
inout vssd,
inout vccd1,
inout vssd1,
inout vccd2,
inout vssd2,
inout vdda1,
inout vssa1,
inout vdda2,
inout vssa2,
input caravel_clk,
input caravel_clk2,
input caravel_rstn,
input mprj_cyc_o_core,
input mprj_stb_o_core,
input mprj_we_o_core,
input [3:0] mprj_sel_o_core,
input [31:0] mprj_adr_o_core,
input [31:0] mprj_dat_o_core,
input [127:0] la_output_core,
input [127:0] la_oen,
output user_clock,
output user_clock2,
output user_resetn,
output mprj_cyc_o_user,
output mprj_stb_o_user,
output mprj_we_o_user,
output [3:0] mprj_sel_o_user,
output [31:0] mprj_adr_o_user,
output [31:0] mprj_dat_o_user,
output [127:0] la_data_in_mprj,
output user1_vcc_powergood,
output user2_vcc_powergood,
output user1_vdd_powergood,
output user2_vdd_powergood
);
wire [74:0] mprj_logic1;
wire mprj2_logic1;
wire mprj_vdd_logic1_h;
wire mprj2_vdd_logic1_h;
wire mprj_vdd_logic1;
wire mprj2_vdd_logic1;
wire user1_vcc_powergood;
wire user2_vcc_powergood;
wire user1_vdd_powergood;
wire user2_vdd_powergood;
sky130_fd_sc_hd__conb_1 mprj_logic_high [74:0] (
.VPWR(vccd1),
.VGND(vssd1),
.VPB(vccd1),
.VNB(vssd1),
.HI(mprj_logic1),
.LO()
);
sky130_fd_sc_hd__conb_1 mprj2_logic_high (
.VPWR(vccd2),
.VGND(vssd2),
.VPB(vccd2),
.VNB(vssd2),
.HI(mprj2_logic1),
.LO()
);
// Logic high in the VDDA (3.3V) domains
sky130_fd_sc_hvl__conb_1 mprj_logic_high_hvl (
.VPWR(vdda1),
.VGND(vssa1),
.VPB(vdda1),
.VNB(vssa1),
.HI(mprj_vdd_logic1_h),
.LO()
);
sky130_fd_sc_hvl__conb_1 mprj2_logic_high_hvl (
.VPWR(vdda2),
.VGND(vssa2),
.VPB(vdda2),
.VNB(vssa2),
.HI(mprj2_vdd_logic1_h),
.LO()
);
// Level shift the logic high signals into the 1.8V domain
sky130_fd_sc_hvl__lsbufhv2lv mprj_logic_high_lv (
.VPWR(vdda1),
.VGND(vssd),
.LVPWR(vccd),
.VPB(vdda1),
.VNB(vssd),
.X(mprj_vdd_logic1),
.A(mprj_vdd_logic1_h)
);
sky130_fd_sc_hvl__lsbufhv2lv mprj2_logic_high_lv (
.VPWR(vdda2),
.VGND(vssd),
.LVPWR(vccd),
.VPB(vdda2),
.VNB(vssd),
.X(mprj2_vdd_logic1),
.A(mprj2_vdd_logic1_h)
);
sky130_fd_sc_hd__einvp_8 mprj_rstn_buf (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.Z(user_resetn),
.A(~caravel_rstn),
.TE(mprj_logic1[0])
);
sky130_fd_sc_hd__einvp_8 mprj_clk_buf (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.Z(user_clock),
.A(~caravel_clk),
.TE(mprj_logic1[1])
);
sky130_fd_sc_hd__einvp_8 mprj_clk2_buf (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.Z(user_clock2),
.A(~caravel_clk2),
.TE(mprj_logic1[2])
);
sky130_fd_sc_hd__einvp_8 mprj_cyc_buf (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.Z(mprj_cyc_o_user),
.A(~mprj_cyc_o_core),
.TE(mprj_logic1[3])
);
sky130_fd_sc_hd__einvp_8 mprj_stb_buf (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.Z(mprj_stb_o_user),
.A(~mprj_stb_o_core),
.TE(mprj_logic1[4])
);
sky130_fd_sc_hd__einvp_8 mprj_we_buf (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.Z(mprj_we_o_user),
.A(~mprj_we_o_core),
.TE(mprj_logic1[5])
);
sky130_fd_sc_hd__einvp_8 mprj_sel_buf [3:0] (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.Z(mprj_sel_o_user),
.A(~mprj_sel_o_core),
.TE(mprj_logic1[9:6])
);
sky130_fd_sc_hd__einvp_8 mprj_adr_buf [31:0] (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.Z(mprj_adr_o_user),
.A(~mprj_adr_o_core),
.TE(mprj_logic1[41:10])
);
sky130_fd_sc_hd__einvp_8 mprj_dat_buf [31:0] (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.Z(mprj_dat_o_user),
.A(~mprj_dat_o_core),
.TE(mprj_logic1[73:42])
);
/* The LA buffers are controlled from the user side, so */
/* it is only necessary to make sure that the function */
/* is inverting the OEB signal and using positive-sense */
/* enable, so that the buffer is disabled on user-side */
/* power-down of vccd1. */
sky130_fd_sc_hd__einvp_8 la_buf [127:0] (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.Z(la_data_in_mprj),
.A(~la_output_core),
.TE(~la_oen)
);
/* The conb cell output is a resistive connection directly to */
/* the power supply, so when returning the user1_powergood */
/* signal, make sure that it is buffered properly. */
sky130_fd_sc_hd__buf_8 mprj_pwrgood (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.A(mprj_logic1[74]),
.X(user1_vcc_powergood)
);
sky130_fd_sc_hd__buf_8 mprj2_pwrgood (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.A(mprj2_logic1),
.X(user2_vcc_powergood)
);
sky130_fd_sc_hd__buf_8 mprj_vdd_pwrgood (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.A(mprj_vdd_logic1),
.X(user_vdd_powergood)
);
sky130_fd_sc_hd__buf_8 mprj2_vdd_pwrgood (
.VPWR(vccd),
.VGND(vssd),
.VPB(vccd),
.VNB(vssd),
.A(mprj2_vdd_logic1),
.X(user2_vdd_powergood)
);
endmodule