| /*----------------------------------------------------------*/ |
| /* striVe, a raven/ravenna-like architecture in SkyWater s8 */ |
| /* */ |
| /* 1st edition, test of SkyWater s8 process */ |
| /* This version is missing all analog functionality, */ |
| /* including crystal oscillator, voltage regulator, and PLL */ |
| /* For simplicity, the pad arrangement of Raven has been */ |
| /* retained, even though many pads have no internal */ |
| /* connection. */ |
| /* */ |
| /* Copyright 2020 efabless, Inc. */ |
| /* Written by Tim Edwards, December 2019 */ |
| /* This file is open source hardware released under the */ |
| /* Apache 2.0 license. See file LICENSE. */ |
| /* */ |
| /*----------------------------------------------------------*/ |
| |
| `timescale 1 ns / 1 ps |
| |
| `define USE_OPENRAM |
| `define USE_PG_PIN |
| `define functional |
| |
| `ifdef SYNTH_OPENLANE |
| `include "../stubs/scs8hd_conb_1.v" |
| `include "../stubs/s8iom0s8.v" |
| `include "../stubs/power_pads_lib.v" |
| `else |
| |
| `ifndef LVS |
| `include "/ef/tech/SW/EFS8A/libs.ref/verilog/s8iom0s8/s8iom0s8.v" |
| `include "/ef/tech/SW/EFS8A/libs.ref/verilog/s8iom0s8/power_pads_lib.v" |
| `include "/ef/tech/SW/EFS8A/libs.ref/verilog/scs8hd/scs8hd.v" |
| |
| `include "lvlshiftdown.v" |
| `include "mgmt_soc.v" |
| `include "striVe_spi.v" |
| `include "digital_pll.v" |
| `include "striVe_clkrst.v" |
| `include "../ip/crossbar.v" |
| `include "../dv/dummy_slave.v" |
| |
| `endif |
| `endif |
| |
| `ifdef USE_OPENRAM |
| `include "sram_1rw1r_32_256_8_sky130.v" |
| `endif |
| |
| //`define TOP_ROUTING |
| `ifndef TOP_ROUTING |
| `define ABUTMENT_PINS \ |
| .amuxbus_a(analog_a),\ |
| .amuxbus_b(analog_b),\ |
| .vssa(vss),\ |
| .vdda(vdd),\ |
| .vswitch(vdd),\ |
| .vddio_q(vddio_q),\ |
| .vcchib(vdd1v8),\ |
| .vddio(vdd),\ |
| .vccd(vdd1v8),\ |
| .vssio(vss),\ |
| .vssd(vss),\ |
| .vssio_q(vssio_q), |
| `else |
| `define ABUTMENT_PINS |
| `endif |
| |
| // Crossbar Slaves |
| `ifndef SLAVE_ADR |
| `define SLAVE_ADR { \ |
| {8'hB0, {24{1'b0}}},\ |
| {8'hA0, {24{1'b0}}},\ |
| {8'h90, {24{1'b0}}},\ |
| {8'h80, {24{1'b0}}}\ |
| }\ |
| `endif |
| |
| `ifndef ADR_MASK |
| `define ADR_MASK { \ |
| {8'hFF, {24{1'b0}}}, \ |
| {8'hFF, {24{1'b0}}}, \ |
| {8'hFF, {24{1'b0}}}, \ |
| {8'hFF, {24{1'b0}}} \ |
| }\ |
| `endif |
| |
| `define NM 2 // Crossbar switch number of masters |
| `define NS 4 // Crossbar switch number of slaves |
| `define DW 32 |
| `define AW 32 |
| |
| module harness (vdd, vdd1v8, vss, gpio, xi, xo, adc0_in, adc1_in, adc_high, adc_low, |
| comp_inn, comp_inp, RSTB, ser_rx, ser_tx, irq, SDO, SDI, CSB, SCK, |
| xclk, flash_csb, flash_clk, flash_io0, flash_io1, flash_io2, flash_io3); |
| |
| inout vdd; |
| inout vdd1v8; |
| inout vss; |
| inout [15:0] gpio; |
| input xi; // CMOS clock input, not a crystal |
| output xo; // divide-by-16 clock output |
| input adc0_in; |
| input adc1_in; |
| input adc_high; |
| input adc_low; |
| input comp_inn; |
| input comp_inp; |
| input RSTB; // NOTE: Replaces analog_out pin from raven chip |
| input ser_rx; |
| output ser_tx; |
| input irq; |
| output SDO; |
| input SDI; |
| input CSB; |
| input SCK; |
| input xclk; |
| output flash_csb; |
| output flash_clk; |
| output flash_io0; |
| output flash_io1; |
| output flash_io2; |
| output flash_io3; |
| |
| wire [15:0] gpio_out_core; |
| wire [15:0] gpio_in_core; |
| wire [15:0] gpio_mode0_core; |
| wire [15:0] gpio_mode1_core; |
| wire [15:0] gpio_outenb_core; |
| wire [15:0] gpio_inenb_core; |
| |
| wire analog_a, analog_b; /* Placeholders for analog signals */ |
| |
| wire porb_h; |
| wire porb_l; |
| wire por_h; |
| wire por; |
| wire SCK_core; |
| wire SDI_core; |
| wire CSB_core; |
| wire SDO_core; |
| wire SDO_enb; |
| wire spi_ro_xtal_ena_core; |
| wire spi_ro_reg_ena_core; |
| wire spi_ro_pll_dco_ena_core; |
| wire [2:0] spi_ro_pll_sel_core; |
| wire [4:0] spi_ro_pll_div_core; |
| wire [25:0] spi_ro_pll_trim_core; |
| wire ext_clk_sel_core; |
| wire irq_spi_core; |
| wire ext_reset_core; |
| wire trap_core; |
| wire [11:0] spi_ro_mfgr_id_core; |
| wire [7:0] spi_ro_prod_id_core; |
| wire [3:0] spi_ro_mask_rev_core; |
| |
| // Instantiate power cells for VDD3V3 domain (8 total; 4 high clamps and |
| // 4 low clamps) |
| s8iom0_vdda_hvc_pad vdd3v3hclamp [1:0] ( |
| `ABUTMENT_PINS |
| .drn_hvc(), |
| .src_bdy_hvc() |
| ); |
| |
| s8iom0_vddio_hvc_pad vddiohclamp [1:0] ( |
| `ABUTMENT_PINS |
| .drn_hvc(), |
| .src_bdy_hvc() |
| ); |
| |
| |
| s8iom0_vdda_lvc_pad vdd3v3lclamp [3:0] ( |
| `ABUTMENT_PINS |
| .bdy2_b2b(), |
| .drn_lvc1(), |
| .drn_lvc2(), |
| .src_bdy_lvc1(), |
| .src_bdy_lvc2() |
| ); |
| |
| // Instantiate the core voltage supply (since it is not generated on-chip) |
| // (1.8V) (4 total, 2 high and 2 low clamps) |
| |
| s8iom0_vccd_hvc_pad vdd1v8hclamp [1:0] ( |
| `ABUTMENT_PINS |
| .drn_hvc(), |
| .src_bdy_hvc() |
| ); |
| |
| s8iom0_vccd_lvc_pad vdd1v8lclamp [1:0] ( |
| `ABUTMENT_PINS |
| .bdy2_b2b(), |
| .drn_lvc1(), |
| .drn_lvc2(), |
| .src_bdy_lvc1(), |
| .src_bdy_lvc2() |
| ); |
| |
| // Instantiate ground cells (7 total, 4 high clamps and 3 low clamps) |
| |
| s8iom0_vssa_hvc_pad vsshclamp [3:0] ( |
| `ABUTMENT_PINS |
| .drn_hvc(), |
| .src_bdy_hvc() |
| ); |
| |
| s8iom0_vssa_lvc_pad vssalclamp ( |
| `ABUTMENT_PINS |
| .bdy2_b2b(), |
| .drn_lvc1(), |
| .drn_lvc2(), |
| .src_bdy_lvc1(), |
| .src_bdy_lvc2() |
| ); |
| |
| s8iom0_vssd_lvc_pad vssdlclamp ( |
| `ABUTMENT_PINS |
| .bdy2_b2b(), |
| .drn_lvc1(), |
| .drn_lvc2(), |
| .src_bdy_lvc1(), |
| .src_bdy_lvc2() |
| ); |
| |
| s8iom0_vssio_lvc_pad vssiolclamp ( |
| `ABUTMENT_PINS |
| .bdy2_b2b(), |
| .drn_lvc1(), |
| .drn_lvc2(), |
| .src_bdy_lvc1(), |
| .src_bdy_lvc2() |
| ); |
| |
| wire [47:0] dm_all; |
| |
| assign dm_all = {gpio_mode1_core[15], gpio_mode1_core[15], gpio_mode0_core[15], |
| gpio_mode1_core[14], gpio_mode1_core[14], gpio_mode0_core[14], |
| gpio_mode1_core[13], gpio_mode1_core[13], gpio_mode0_core[13], |
| gpio_mode1_core[12], gpio_mode1_core[12], gpio_mode0_core[12], |
| gpio_mode1_core[11], gpio_mode1_core[11], gpio_mode0_core[11], |
| gpio_mode1_core[10], gpio_mode1_core[10], gpio_mode0_core[10], |
| gpio_mode1_core[9], gpio_mode1_core[9], gpio_mode0_core[9], |
| gpio_mode1_core[8], gpio_mode1_core[8], gpio_mode0_core[8], |
| gpio_mode1_core[7], gpio_mode1_core[7], gpio_mode0_core[7], |
| gpio_mode1_core[6], gpio_mode1_core[6], gpio_mode0_core[6], |
| gpio_mode1_core[5], gpio_mode1_core[5], gpio_mode0_core[5], |
| gpio_mode1_core[4], gpio_mode1_core[4], gpio_mode0_core[4], |
| gpio_mode1_core[3], gpio_mode1_core[3], gpio_mode0_core[3], |
| gpio_mode1_core[2], gpio_mode1_core[2], gpio_mode0_core[2], |
| gpio_mode1_core[1], gpio_mode1_core[1], gpio_mode0_core[1], |
| gpio_mode1_core[0], gpio_mode1_core[0], gpio_mode0_core[0]}; |
| |
| // GPIO pads |
| s8iom0_gpiov2_pad gpio_pad [15:0] ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(gpio), |
| `endif |
| .out(gpio_out_core), // Signal from core to pad |
| .oe_n(gpio_outenb_core), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold signals during deep sleep (sense inverted) |
| .enable_h(porb_h), // Post-reset enable |
| .enable_inp_h(loopb0), // Input buffer state when disabled |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(gpio_inenb_core), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm(dm_all), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(gpio_in_core), // Signal from pad to core |
| .in_h(), // VDDA domain signal (unused) |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb0) |
| ); |
| |
| s8iom0_gpiov2_pad xi_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(xi), |
| `endif |
| .out(), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb1), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(por), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vdd1v8}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(xi_core), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb1) |
| ); |
| |
| s8iom0_gpiov2_pad xo_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(xo), |
| `endif |
| .out(pll_clk16), // Signal from core to pad |
| .oe_n(vss), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb2), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(vdd1v8), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vdd1v8, vdd1v8, vss}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb2) |
| ); |
| |
| s8iom0_gpiov2_pad adc0_in_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(adc0_in), |
| `endif |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb3), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(vdd1v8), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vdd1v8), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vss}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| s8iom0_gpiov2_pad adc1_in_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(adc1_in), |
| `endif |
| .pad_a_noesd_h(), // Direct pad connection |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb4), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(vdd1v8), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vdd1v8), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vss}), // (3 bits) Mode control |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| s8iom0_gpiov2_pad adc_high_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(adc_high), |
| `endif |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb5), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(vdd1v8), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vdd1v8), // |
| .analog_sel(vdd1v8), // |
| .analog_pol(vdd1v8), // |
| .dm({vss, vss, vss}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| s8iom0_gpiov2_pad adc_low_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(adc_low), |
| `endif |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb6), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(vdd1v8), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vdd1v8), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vss}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| s8iom0_gpiov2_pad comp_inn_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(comp_inn), |
| `endif |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb7), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(vdd1v8), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vdd1v8), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vss}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| s8iom0_gpiov2_pad comp_inp_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(comp_inp), |
| `endif |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb8), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(vdd1v8), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vdd1v8), // |
| .analog_sel(vdd1v8), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vss}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| // NOTE: The analog_out pad from the raven chip has been replaced by |
| // the digital reset input RSTB on striVe due to the lack of an on-board |
| // power-on-reset circuit. The XRES pad is used for providing a glitch- |
| // free reset. |
| |
| s8iom0s8_top_xres4v2 RSTB_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(RSTB), |
| `endif |
| .tie_weak_hi_h(xresloop), // Loop-back connection to pad through pad_a_esd_h |
| .tie_hi_esd(), |
| .tie_lo_esd(), |
| .pad_a_esd_h(xresloop), |
| .xres_h_n(porb_h), |
| .disable_pullup_h(vss), // 0 = enable pull-up on reset pad |
| .enable_h(vdd), // Power-on-reset to the power-on-reset input?? |
| .en_vddio_sig_h(vss), // No idea. |
| .inp_sel_h(vss), // 1 = use filt_in_h else filter the pad input |
| .filt_in_h(vss), // Alternate input for glitch filter |
| .pullup_h(vss), // Pullup connection for alternate filter input |
| .enable_vddio(vdd1v8) |
| ); |
| |
| s8iom0_gpiov2_pad irq_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(irq), |
| `endif |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb10), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(por), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vdd1v8}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(irq_pin_core), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb10) |
| ); |
| |
| s8iom0_gpiov2_pad SDO_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(SDO), |
| `endif |
| .out(SDO_core), // Signal from core to pad |
| .oe_n(SDO_enb), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb11), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(vdd1v8), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vdd1v8, vdd1v8, vss}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb11) |
| ); |
| |
| s8iom0_gpiov2_pad SDI_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(SDI), |
| `endif |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb12), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(por), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vdd1v8}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(SDI_core), // Signal from pad to core |
| .in_h(SDI_core_h), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| s8iom0_gpiov2_pad CSB_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(CSB), |
| `endif |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb13), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(por), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vdd1v8}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(CSB_core), // Signal from pad to core |
| .in_h(CSB_core_h), |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb13) |
| ); |
| |
| s8iom0_gpiov2_pad SCK_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(SCK), |
| `endif |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb14), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(por), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vdd1v8}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(SCK_core), // Signal from pad to core |
| .in_h(SCK_core_h), // Signal in vdda domain (3.3V) |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb14) |
| ); |
| |
| s8iom0_gpiov2_pad xclk_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(xclk), |
| `endif |
| .out(vss), // Signal from core to pad |
| .oe_n(vdd1v8), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb15), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(por), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vss, vss, vdd1v8}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(ext_clk_core), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb15) |
| ); |
| |
| // assign flash_csb = (input) ? |
| s8iom0_gpiov2_pad flash_csb_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(flash_csb), |
| `endif |
| .out(flash_csb_core), // Signal from core to pad |
| .oe_n(flash_csb_oeb_core), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb16), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(flash_csb_ieb_core), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vdd1v8, vdd1v8, vss}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| s8iom0_gpiov2_pad flash_clk_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(flash_clk), |
| `endif |
| .out(flash_clk_core), // Signal from core to pad |
| .oe_n(flash_clk_oeb_core), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb17), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(flash_clk_ieb_core), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({vdd1v8, vdd1v8, vss}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| s8iom0_gpiov2_pad flash_io0_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(flash_io0), |
| `endif |
| .out(flash_io0_do_core), // Signal from core to pad |
| .oe_n(flash_io0_oeb_core), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb18), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(flash_io0_ieb_core), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({flash_io0_ieb_core, flash_io0_ieb_core, flash_io0_oeb_core}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(flash_io0_di_core), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb18) |
| ); |
| |
| s8iom0_gpiov2_pad flash_io1_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(flash_io1), |
| `endif |
| .out(flash_io1_do_core), // Signal from core to pad |
| .oe_n(flash_io1_oeb_core), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb19), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(flash_io1_ieb_core), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({flash_io1_ieb_core, flash_io1_ieb_core, flash_io1_oeb_core}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(flash_io1_di_core), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb19) |
| ); |
| |
| s8iom0_gpiov2_pad flash_io2_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(flash_io2), |
| `endif |
| .out(flash_io2_do_core), // Signal from core to pad |
| .oe_n(flash_io2_oeb_core), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb20), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(flash_io2_ieb_core), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({flash_io2_ieb_core, flash_io2_ieb_core, flash_io2_oeb_core}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(flash_io2_di_core), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb20) |
| ); |
| |
| s8iom0_gpiov2_pad flash_io3_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(flash_io3), |
| `endif |
| .out(flash_io3_do_core), // Signal from core to pad |
| .oe_n(flash_io3_oeb_core), // Output enable (sense inverted) |
| .hld_h_n(vdd), // Hold |
| .enable_h(porb_h), // Enable |
| .enable_inp_h(loopb21), // Enable input buffer |
| .enable_vdda_h(porb_h), // |
| .enable_vswitch_h(vss), // |
| .enable_vddio(vdd1v8), // |
| .inp_dis(flash_io3_ieb_core), // Disable input buffer |
| .ib_mode_sel(vss), // |
| .vtrip_sel(vss), // |
| .slow(vss), // |
| .hld_ovr(vss), // |
| .analog_en(vss), // |
| .analog_sel(vss), // |
| .analog_pol(vss), // |
| .dm({flash_io3_ieb_core, flash_io3_ieb_core, flash_io3_oeb_core}), // (3 bits) Mode control |
| .pad_a_noesd_h(), // Direct pad connection |
| .pad_a_esd_0_h(), // Pad connection through 150 ohms |
| .pad_a_esd_1_h(), // Pad connection through 150 ohms |
| .in(flash_io3_di_core), // Signal from pad to core |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd(loopb21) |
| ); |
| |
| // Instantiate GPIO overvoltage (I2C) compliant cell |
| // (Use this for ser_rx and ser_tx; no reason other than testing |
| // the use of the cell.) (Might be worth adding in the I2C IP from |
| // ravenna just to test on a proper I2C channel.) |
| |
| s8iom0s8_top_gpio_ovtv2 ser_rx_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(ser_rx), |
| `endif |
| .out(vss), |
| .oe_n(vdd1v8), |
| .hld_h_n(vdd), |
| .enable_h(porb_h), |
| .enable_inp_h(loopb22), |
| .enable_vdda_h(porb_h), |
| .enable_vddio(vdd1v8), |
| .enable_vswitch_h(vss), |
| .inp_dis(por), |
| .vtrip_sel(vss), |
| .hys_trim(vdd1v8), |
| .slow(vss), |
| .slew_ctl({vss, vss}), // 2 bits |
| .hld_ovr(vss), |
| .analog_en(vss), |
| .analog_sel(vss), |
| .analog_pol(vss), |
| .dm({vss, vss, vdd1v8}), // 3 bits |
| .ib_mode_sel({vss, vss}), // 2 bits |
| .vinref(vdd1v8), |
| .pad_a_noesd_h(), |
| .pad_a_esd_0_h(), |
| .pad_a_esd_1_h(), |
| .in(ser_rx_core), |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| s8iom0s8_top_gpio_ovtv2 ser_tx_pad ( |
| `ABUTMENT_PINS |
| `ifndef TOP_ROUTING |
| .pad(ser_tx), |
| `endif |
| .out(ser_tx_core), |
| .oe_n(vss), |
| .hld_h_n(vdd), |
| .enable_h(porb_h), |
| .enable_inp_h(loopb23), |
| .enable_vdda_h(porb_h), |
| .enable_vddio(vdd1v8), |
| .enable_vswitch_h(vss), |
| .inp_dis(vdd1v8), |
| .vtrip_sel(vss), |
| .hys_trim(vdd1v8), |
| .slow(vss), |
| .slew_ctl({vss, vss}), // 2 bits |
| .hld_ovr(vss), |
| .analog_en(vss), |
| .analog_sel(vss), |
| .analog_pol(vss), |
| .dm({vdd1v8, vdd1v8, vss}), // 3 bits |
| .ib_mode_sel({vss, vss}), // 2 bits |
| .vinref(vdd1v8), |
| .pad_a_noesd_h(), |
| .pad_a_esd_0_h(), |
| .pad_a_esd_1_h(), |
| .in(), |
| .in_h(), |
| .tie_hi_esd(), |
| .tie_lo_esd() |
| ); |
| |
| // Corner cells (These are overlay cells; it is not clear what is normally |
| // supposed to go under them.) |
| `ifndef TOP_ROUTING |
| s8iom0_corner_pad corner [3:0] ( |
| .vssio(vss), |
| .vddio(vdd), |
| .vddio_q(vddio_q), |
| .vssio_q(vssio_q), |
| .amuxbus_a(analog_a), |
| .amuxbus_b(analog_b), |
| .vssd(vss), |
| .vssa(vss), |
| .vswitch(vdd), |
| .vdda(vdd), |
| .vccd(vdd1v8), |
| .vcchib(vdd1v8) |
| //`ABUTMENT_PINS |
| ); |
| `endif |
| |
| // SoC core |
| wire [9:0] adc0_data_core; |
| wire [1:0] adc0_inputsrc_core; |
| wire [9:0] adc1_data_core; |
| wire [1:0] adc1_inputsrc_core; |
| wire [9:0] dac_value_core; |
| wire [1:0] comp_ninputsrc_core; |
| wire [1:0] comp_pinputsrc_core; |
| wire [7:0] spi_ro_config_core; |
| |
| wire xbar_cyc_o_core; |
| wire xbar_stb_o_core; |
| wire xbar_we_o_core; |
| wire [3:0] xbar_sel_o_core; |
| wire [31:0] xbar_adr_o_core; |
| wire [31:0] xbar_dat_o_core; |
| wire xbar_ack_i_core; |
| wire [31:0] xbar_dat_i_core; |
| |
| wire striVe_clk, striVe_rstn; |
| |
| striVe_clkrst clkrst( |
| `ifdef LVS |
| .vdd1v8(vdd1v8), |
| .vss(vss), |
| `endif |
| .ext_clk_sel(ext_clk_sel_core), |
| .ext_clk(ext_clk_core), |
| .pll_clk(pll_clk_core), |
| .reset(por), |
| .ext_reset(ext_reset_core), |
| .clk(striVe_clk), |
| .resetn(striVe_rstn) |
| ); |
| |
| mgmt_soc core ( |
| `ifdef LVS |
| .vdd1v8(vdd1v8), |
| .vss(vss), |
| `endif |
| .pll_clk(pll_clk_core), |
| .ext_clk(ext_clk_core), |
| .ext_clk_sel(ext_clk_sel_core), |
| .clk(striVe_clk), |
| .resetn(striVe_rstn), |
| .gpio_out_pad(gpio_out_core), |
| .gpio_in_pad(gpio_in_core), |
| .gpio_mode0_pad(gpio_mode0_core), |
| .gpio_mode1_pad(gpio_mode1_core), |
| .gpio_outenb_pad(gpio_outenb_core), |
| .gpio_inenb_pad(gpio_inenb_core), |
| .adc0_ena(adc0_ena_core), |
| .adc0_convert(adc0_convert_core), |
| .adc0_data(adc0_data_core), |
| .adc0_done(adc0_done_core), |
| .adc0_clk(adc0_clk_core), |
| .adc0_inputsrc(adc0_inputsrc_core), |
| .adc1_ena(adc1_ena_core), |
| .adc1_convert(adc1_convert_core), |
| .adc1_clk(adc1_clk_core), |
| .adc1_inputsrc(adc1_inputsrc_core), |
| .adc1_data(adc1_data_core), |
| .adc1_done(adc1_done_core), |
| .xtal_in(xtal_in_core), |
| .comp_in(comp_in_core), |
| .spi_sck(SCK_core), |
| .spi_ro_config(spi_ro_config_core), |
| .spi_ro_xtal_ena(spi_ro_xtal_ena_core), |
| .spi_ro_reg_ena(spi_ro_reg_ena_core), |
| .spi_ro_pll_dco_ena(spi_ro_pll_dco_ena_core), |
| .spi_ro_pll_div(spi_ro_pll_div_core), |
| .spi_ro_pll_sel(spi_ro_pll_sel_core), |
| .spi_ro_pll_trim(spi_ro_pll_trim_core), |
| .spi_ro_mfgr_id(spi_ro_mfgr_id_core), |
| .spi_ro_prod_id(spi_ro_prod_id_core), |
| .spi_ro_mask_rev(spi_ro_mask_rev_core), |
| .ser_tx(ser_tx_core), |
| .ser_rx(ser_rx_core), |
| .irq_pin(irq_pin_core), |
| .irq_spi(irq_spi_core), |
| .trap(trap_core), |
| .flash_csb(flash_csb_core), |
| .flash_clk(flash_clk_core), |
| .flash_csb_oeb(flash_csb_oeb_core), |
| .flash_clk_oeb(flash_clk_oeb_core), |
| .flash_io0_oeb(flash_io0_oeb_core), |
| .flash_io1_oeb(flash_io1_oeb_core), |
| .flash_io2_oeb(flash_io2_oeb_core), |
| .flash_io3_oeb(flash_io3_oeb_core), |
| .flash_csb_ieb(flash_csb_ieb_core), |
| .flash_clk_ieb(flash_clk_ieb_core), |
| .flash_io0_ieb(flash_io0_ieb_core), |
| .flash_io1_ieb(flash_io1_ieb_core), |
| .flash_io2_ieb(flash_io2_ieb_core), |
| .flash_io3_ieb(flash_io3_ieb_core), |
| .flash_io0_do(flash_io0_do_core), |
| .flash_io1_do(flash_io1_do_core), |
| .flash_io2_do(flash_io2_do_core), |
| .flash_io3_do(flash_io3_do_core), |
| .flash_io0_di(flash_io0_di_core), |
| .flash_io1_di(flash_io1_di_core), |
| .flash_io2_di(flash_io2_di_core), |
| .flash_io3_di(flash_io3_di_core), |
| .xbar_cyc_o(xbar_cyc_o_core), |
| .xbar_stb_o(xbar_stb_o_core), |
| .xbar_we_o (xbar_we_o_core), |
| .xbar_sel_o(xbar_sel_o_core), |
| .xbar_adr_o(xbar_adr_o_core), |
| .xbar_dat_o(xbar_dat_o_core), |
| .xbar_ack_i(xbar_ack_i_core), |
| .xbar_dat_i(xbar_dat_i_core) |
| ); |
| |
| // Mega-Project |
| wire mega_cyc_o; |
| wire mega_stb_o; |
| wire mega_we_o; |
| wire [3:0] mega_sel_o; |
| wire [31:0] mega_adr_o; |
| wire [31:0] mega_dat_o; |
| wire mega_ack_i; |
| wire [31:0] mega_dat_i; |
| |
| // Masters interface |
| wire [`NM-1:0] wbm_cyc_i; |
| wire [`NM-1:0] wbm_stb_i; |
| wire [`NM-1:0] wbm_we_i; |
| wire [(`NM*(`DW/8))-1:0] wbm_sel_i; |
| wire [(`NM*`AW)-1:0] wbm_adr_i; |
| wire [(`NM*`DW)-1:0] wbm_dat_i; |
| |
| wire [`NM-1:0] wbm_ack_o; |
| wire [(`NM*`DW)-1:0] wbm_dat_o; |
| |
| // Slaves interfaces |
| wire [`NS-1:0] wbs_ack_o; |
| wire [(`NS*`DW)-1:0] wbs_dat_i; |
| wire [`NS-1:0] wbs_cyc_o; |
| wire [`NS-1:0] wbs_stb_o; |
| wire [`NS-1:0] wbs_we_o; |
| wire [(`NS*(`DW/8))-1:0] wbs_sel_o; |
| wire [(`NS*`AW)-1:0] wbs_adr_o; |
| wire [(`NS*`DW)-1:0] wbs_dat_o; |
| |
| assign wbm_cyc_i = {mega_cyc_o, xbar_cyc_o_core}; |
| assign wbm_stb_i = {mega_stb_o, xbar_stb_o_core}; |
| assign wbm_we_i = {mega_we_o , xbar_we_o_core}; |
| assign wbm_sel_i = {mega_sel_o, xbar_sel_o_core}; |
| assign wbm_adr_i = {mega_adr_o, xbar_adr_o_core}; |
| assign wbm_dat_i = {mega_dat_o, xbar_dat_o_core}; |
| |
| assign xbar_ack_i_core = wbm_ack_o[0]; |
| assign mega_ack_i = wbm_ack_o[1]; |
| assign xbar_dat_i_core = wbm_dat_o[`DW-1:0]; |
| assign mega_dat_i = wbm_dat_o[`DW*2-1:`DW]; |
| |
| // Instantiate four dummy slaves for testing (TO-BE-REMOVED) |
| dummy_slave dummy_slaves [`NS-1:0]( |
| .wb_clk_i({`NS{striVe_clk}}), |
| .wb_rst_i({`NS{~striVe_rstn}}), |
| .wb_stb_i(wbs_stb_o), |
| .wb_cyc_i(wbs_cyc_o), |
| .wb_we_i(wbs_we_o), |
| .wb_sel_i(wbs_sel_o), |
| .wb_adr_i(wbs_adr_o), |
| .wb_dat_i(wbs_dat_i), |
| .wb_dat_o(wbs_dat_o), |
| .wb_ack_o(wbs_ack_o) |
| ); |
| // Crossbar Switch |
| wb_xbar #( |
| .NM(`NM), |
| .NS(`NS), |
| .AW(`AW), |
| .DW(`DW), |
| .SLAVE_ADR(`SLAVE_ADR), |
| .ADR_MASK(`ADR_MASK) |
| ) |
| wb_xbar( |
| .wb_clk_i(striVe_clk), |
| .wb_rst_i(~striVe_rstn), |
| |
| // Masters interface |
| .wbm_cyc_i(wbm_cyc_i), |
| .wbm_stb_i(wbm_stb_i), |
| .wbm_we_i (wbm_we_i), |
| .wbm_sel_i(wbm_sel_i), |
| .wbm_adr_i(wbm_adr_i), |
| .wbm_dat_i(wbm_dat_i), |
| .wbm_ack_o(wbm_ack_o), |
| .wbm_dat_o(wbm_dat_o), |
| |
| // Slaves interfaces |
| .wbs_ack_i(wbs_ack_o), |
| .wbs_dat_i(wbs_dat_o), |
| .wbs_cyc_o(wbs_cyc_o), |
| .wbs_stb_o(wbs_stb_o), |
| .wbs_we_o (wbs_we_o), |
| .wbs_sel_o(wbs_sel_o), |
| .wbs_adr_o(wbs_adr_o), |
| .wbs_dat_o(wbs_dat_i) |
| ); |
| |
| // For the mask revision input, use an array of digital constant logic cells |
| wire [3:0] mask_rev; |
| wire [3:0] no_connect; |
| scs8hd_conb_1 mask_rev_value [3:0] ( |
| `ifdef LVS |
| .vpwr(vdd1v8), |
| .vpb(vdd1v8), |
| .vnb(vss), |
| .vgnd(vss), |
| `endif |
| .HI({no_connect[3:1], mask_rev[0]}), |
| .LO({mask_rev[3:1], no_connect[0]}) |
| ); |
| |
| // Housekeeping SPI at 1.8V. |
| |
| striVe_spi housekeeping ( |
| `ifdef LVS |
| .vdd(vdd1v8), |
| .vss(vss), |
| `endif |
| .RSTB(porb_l), |
| .SCK(SCK_core), |
| .SDI(SDI_core), |
| .CSB(CSB_core), |
| .SDO(SDO_core), |
| .sdo_enb(SDO_enb), |
| |
| .xtal_ena(spi_ro_xtal_ena_core), |
| .reg_ena(spi_ro_reg_ena_core), |
| .pll_dco_ena(spi_ro_pll_dco_ena_core), |
| .pll_sel(spi_ro_pll_sel_core), |
| .pll_div(spi_ro_pll_div_core), |
| .pll_trim(spi_ro_pll_trim_core), |
| .pll_bypass(ext_clk_sel_core), |
| .irq(irq_spi_core), |
| .RST(por), |
| .reset(ext_reset_core), |
| .trap(trap_core), |
| .mfgr_id(spi_ro_mfgr_id_core), |
| .prod_id(spi_ro_prod_id_core), |
| .mask_rev_in(mask_rev), |
| .mask_rev(spi_ro_mask_rev_core) |
| ); |
| |
| lvlshiftdown porb_level_shift ( |
| `ifdef LVS |
| .vpwr(vdd1v8), |
| .vpb(vdd1v8), |
| .vnb(vss), |
| .vgnd(vss), |
| `endif |
| .A(porb_h), |
| .X(porb_l) |
| ); |
| |
| // On-board experimental digital PLL |
| // Use xi_core, assumed to be a CMOS digital clock signal. xo_core |
| // is used as an output and set from pll_clk16. |
| |
| digital_pll pll ( |
| `ifdef LVS |
| .vdd(vdd1v8), |
| .vss(vss), |
| `endif |
| .reset(por), |
| .extclk_sel(ext_clk_sel_core), |
| .osc(xi_core), |
| .clockc(pll_clk_core), |
| .clockp({pll_clk_core0, pll_clk_core90}), |
| .clockd({pll_clk2, pll_clk4, pll_clk8, pll_clk16}), |
| .div(spi_ro_pll_div_core), |
| .sel(spi_ro_pll_sel_core), |
| .dco(spi_ro_pll_dco_ena_core), |
| .ext_trim(spi_ro_pll_trim_core) |
| ); |
| |
| endmodule |