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caravel/verilog/rtl/housekeeping_spi.v

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Seeding with documentation of pinout and verilog RTL (mostly unchanged from original except to remove blocks that are not supposed to be in this repository like the processor core and the storage).
2021-10-12 15:31:42 -05:00
// SPDX-FileCopyrightText: 2020 Efabless Corporation
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// SPDX-License-Identifier: Apache-2.0
`default_nettype none
//-------------------------------------
// SPI controller for Caravel (PicoSoC)
//-------------------------------------
// Written by Tim Edwards
// efabless, inc. September 27, 2020
//-------------------------------------
//-----------------------------------------------------------
// This is a standalone slave SPI for the caravel chip that is
// intended to be independent of the picosoc and independent
// of all IP blocks except the power-on-reset. This SPI has
// register outputs controlling the functions that critically
// affect operation of the picosoc and so cannot be accessed
// from the picosoc itself. This includes the PLL enables
// and trim, and the crystal oscillator enable. It also has
// a general reset for the picosoc, an IRQ input, a bypass for
// the entire crystal oscillator and PLL chain, the
// manufacturer and product IDs and product revision number.
// To be independent of the 1.8V regulator, the slave SPI is
// synthesized with the 3V digital library and runs off of
// the 3V supply.
//
// This module is designed to be decoupled from the chip
// padframe and redirected to the wishbone bus under
// register control from the management SoC, such that the
// contents can be accessed from the management core via the
// SPI master.
//
//-----------------------------------------------------------
//------------------------------------------------------------
// Caravel defined registers:
// Register 0: SPI status and control (unused & reserved)
// Register 1 and 2: Manufacturer ID (0x0456) (readonly)
// Register 3: Product ID (= 16) (readonly)
// Register 4-7: Mask revision (readonly) --- Externally programmed
// with via programming. Via programmed with a script to match
// each customer ID.
//
// Register 8: PLL enables (2 bits)
// Register 9: PLL bypass (1 bit)
// Register 10: IRQ (1 bit)
// Register 11: reset (1 bit)
// Register 12: trap (1 bit) (readonly)
// Register 13-16: PLL trim (26 bits)
// Register 17: PLL output divider (3 bits)
// Register 18: PLL feedback divider (5 bits)
// Register 19: User GPIO bit-bang control (5 bits)
// Register 20: SRAM read-only control (2 bits)
// Register 21: SRAM read-only address (8 bits)
// Register 22-25: SRAM read-only data (32 bits)
//------------------------------------------------------------
module housekeeping_spi(
`ifdef USE_POWER_PINS
vdd, vss,
`endif
RSTB, SCK, SDI, CSB, SDO, sdo_enb,
pll_ena, pll_dco_ena, pll_div, pll_sel,
pll90_sel, pll_trim, pll_bypass, irq, reset,
gpio_clock, gpio_resetn, gpio_data_1, gpio_data_2, gpio_enable,
sram_clk, sram_csb, sram_addr, sram_rdata,
trap, mask_rev_in,
pass_thru_mgmt_reset, pass_thru_user_reset,
pass_thru_mgmt_sck, pass_thru_mgmt_csb,
pass_thru_mgmt_sdi, pass_thru_mgmt_sdo,
pass_thru_user_sck, pass_thru_user_csb,
pass_thru_user_sdi, pass_thru_user_sdo
);
`ifdef USE_POWER_PINS
inout vdd; // 3.3V supply
inout vss; // common ground
`endif
input RSTB; // from padframe
input SCK; // from padframe
input SDI; // from padframe
input CSB; // from padframe
output SDO; // to padframe
output sdo_enb; // to padframe
output pll_ena;
output pll_dco_ena;
output [4:0] pll_div;
output [2:0] pll_sel;
output [2:0] pll90_sel;
output [25:0] pll_trim;
output pll_bypass;
output irq;
output reset;
input trap;
input [31:0] mask_rev_in; // metal programmed; 3.3V domain
// Bit-bang control of GPIO serial loader
output gpio_enable;
output gpio_resetn;
output gpio_clock;
output gpio_data_1;
output gpio_data_2;
// Bit-bang control of SRAM block 2nd read port
output sram_clk;
output sram_csb;
output [7:0] sram_addr;
input [31:0] sram_rdata;
// Pass-through programming mode for management area SPI flash
output pass_thru_mgmt_reset;
output pass_thru_user_reset;
output pass_thru_mgmt_sck;
output pass_thru_mgmt_csb;
output pass_thru_mgmt_sdi;
input pass_thru_mgmt_sdo;
// Pass-through programming mode for user area SPI flash
output pass_thru_user_sck;
output pass_thru_user_csb;
output pass_thru_user_sdi;
input pass_thru_user_sdo;
reg [25:0] pll_trim;
reg [4:0] pll_div;
reg [2:0] pll_sel;
reg [2:0] pll90_sel;
reg pll_dco_ena;
reg pll_ena;
reg pll_bypass;
reg reset_reg;
reg irq;
reg gpio_enable;
reg gpio_clock;
reg gpio_resetn;
reg gpio_data_1;
reg gpio_data_2;
reg sram_clk;
reg sram_csb;
reg [7:0] sram_addr;
wire [7:0] odata;
wire [7:0] idata;
wire [7:0] iaddr;
wire trap;
wire rdstb;
wire wrstb;
wire pass_thru_mgmt; // Mode detected by spi_slave
wire pass_thru_mgmt_delay;
wire pass_thru_user; // Mode detected by spi_slave
wire pass_thru_user_delay;
wire loc_sdo;
// Pass-through mode handling. Signals may only be applied when the
// core processor is in reset.
assign pass_thru_mgmt_csb = ~pass_thru_mgmt_delay;
assign pass_thru_mgmt_sck = (pass_thru_mgmt ? SCK : 1'b0);
assign pass_thru_mgmt_sdi = (pass_thru_mgmt_delay ? SDI : 1'b0);
assign pass_thru_user_csb = ~pass_thru_user_delay;
assign pass_thru_user_sck = (pass_thru_user ? SCK : 1'b0);
assign pass_thru_user_sdi = (pass_thru_user_delay ? SDI : 1'b0);
assign SDO = pass_thru_mgmt ? pass_thru_mgmt_sdo :
pass_thru_user ? pass_thru_user_sdo : loc_sdo;
assign reset = pass_thru_mgmt_reset ? 1'b1 : reset_reg;
// Instantiate the SPI slave module
housekeeping_spi_slave U1 (
.reset(~RSTB),
.SCK(SCK),
.SDI(SDI),
.CSB(CSB),
.SDO(loc_sdo),
.sdoenb(sdo_enb),
.idata(odata),
.odata(idata),
.oaddr(iaddr),
.rdstb(rdstb),
.wrstb(wrstb),
.pass_thru_mgmt(pass_thru_mgmt),
.pass_thru_mgmt_delay(pass_thru_mgmt_delay),
.pass_thru_user(pass_thru_user),
.pass_thru_user_delay(pass_thru_user_delay),
.pass_thru_mgmt_reset(pass_thru_mgmt_reset),
.pass_thru_user_reset(pass_thru_user_reset)
);
wire [11:0] mfgr_id;
wire [7:0] prod_id;
wire [31:0] mask_rev;
assign mfgr_id = 12'h456; // Hard-coded
assign prod_id = 8'h10; // Hard-coded
assign mask_rev = mask_rev_in; // Copy in to out.
// Send register contents to odata on SPI read command
// All values are 1-4 bits and no shadow registers are required.
assign odata =
(iaddr == 8'h00) ? 8'h00 : // SPI status (fixed)
(iaddr == 8'h01) ? {4'h0, mfgr_id[11:8]} : // Manufacturer ID (fixed)
(iaddr == 8'h02) ? mfgr_id[7:0] : // Manufacturer ID (fixed)
(iaddr == 8'h03) ? prod_id : // Product ID (fixed)
(iaddr == 8'h04) ? mask_rev[31:24] : // Mask rev (metal programmed)
(iaddr == 8'h05) ? mask_rev[23:16] : // Mask rev (metal programmed)
(iaddr == 8'h06) ? mask_rev[15:8] : // Mask rev (metal programmed)
(iaddr == 8'h07) ? mask_rev[7:0] : // Mask rev (metal programmed)
(iaddr == 8'h08) ? {6'b000000, pll_dco_ena, pll_ena} :
(iaddr == 8'h09) ? {7'b0000000, pll_bypass} :
(iaddr == 8'h0a) ? {7'b0000000, irq} :
(iaddr == 8'h0b) ? {7'b0000000, reset} :
(iaddr == 8'h0c) ? {7'b0000000, trap} :
(iaddr == 8'h0d) ? pll_trim[7:0] :
(iaddr == 8'h0e) ? pll_trim[15:8] :
(iaddr == 8'h0f) ? pll_trim[23:16] :
(iaddr == 8'h10) ? {6'b000000, pll_trim[25:24]} :
(iaddr == 8'h11) ? {2'b00, pll90_sel, pll_sel} :
(iaddr == 8'h12) ? {3'b000, pll_div} :
(iaddr == 8'h13) ? {3'b000, gpio_data_2, gpio_data_1, gpio_clock,
gpio_resetn, gpio_enable} :
(iaddr == 8'h14) ? {6'b000000, sram_clk, sram_csb} :
(iaddr == 8'h15) ? sram_addr :
(iaddr == 8'h16) ? sram_rdata[7:0] :
(iaddr == 8'h17) ? sram_rdata[15:8] :
(iaddr == 8'h18) ? sram_rdata[23:16] :
(iaddr == 8'h19) ? sram_rdata[31:24] :
8'h00; // Default
// Register mapping and I/O to slave module
always @(posedge SCK or negedge RSTB) begin
if (RSTB == 1'b0) begin
// Set trim for PLL at (almost) slowest rate (~90MHz). However,
// pll_trim[12] must be set to zero for proper startup.
pll_trim <= 26'b11111111111110111111111111;
pll_sel <= 3'b010; // Default output divider divide-by-2
pll90_sel <= 3'b010; // Default secondary output divider divide-by-2
pll_div <= 5'b00100; // Default feedback divider divide-by-8
pll_dco_ena <= 1'b1; // Default free-running PLL
pll_ena <= 1'b0; // Default PLL turned off
pll_bypass <= 1'b1; // Default bypass mode (don't use PLL)
irq <= 1'b0;
reset_reg <= 1'b0;
gpio_enable <= 1'b0;
gpio_data_1 <= 1'b0;
gpio_data_2 <= 1'b0;
gpio_clock <= 1'b0;
gpio_resetn <= 1'b0;
sram_clk <= 1'b0;
sram_csb <= 1'b1;
sram_addr <= 8'd0;
end else if (wrstb == 1'b1) begin
case (iaddr)
8'h08: begin
pll_ena <= idata[0];
pll_dco_ena <= idata[1];
end
8'h09: begin
pll_bypass <= idata[0];
end
8'h0a: begin
irq <= idata[0];
end
8'h0b: begin
reset_reg <= idata[0];
end
// Register 0xc is read-only
8'h0d: begin
pll_trim[7:0] <= idata;
end
8'h0e: begin
pll_trim[15:8] <= idata;
end
8'h0f: begin
pll_trim[23:16] <= idata;
end
8'h10: begin
pll_trim[25:24] <= idata[1:0];
end
8'h11: begin
pll_sel <= idata[2:0];
pll90_sel <= idata[5:3];
end
8'h12: begin
pll_div <= idata[4:0];
end
8'h13: begin
gpio_enable <= idata[0];
gpio_resetn <= idata[1];
gpio_clock <= idata[2];
gpio_data_1 <= idata[3];
gpio_data_2 <= idata[4];
end
8'h14: begin
sram_csb <= idata[0];
sram_clk <= idata[1];
end
8'h15: begin
sram_addr <= idata;
end
// Registers 0x16-0x19 are read-only
endcase // (iaddr)
end
end
endmodule // housekeeping_spi
//------------------------------------------------------
// housekeeping_spi_slave.v
//------------------------------------------------------
// General purpose SPI slave module for the Caravel chip
//------------------------------------------------------
// Written by Tim Edwards
// efabless, inc., September 28, 2020
//------------------------------------------------
// This file is distributed free and open source
//------------------------------------------------
// SCK --- Clock input
// SDI --- Data input
// SDO --- Data output
// CSB --- Chip select (sense negative)
// idata --- Data from chip to transmit out, in 8 bits
// odata --- Input data to chip, in 8 bits
// addr --- Decoded address to upstream circuits
// rdstb --- Read strobe, tells upstream circuit to supply next byte to idata
// wrstb --- Write strobe, tells upstream circuit to latch odata.
// Data format (general purpose):
// 8 bit format
// 1st byte: Command word (see below)
// 2nd byte: Address word (register 0 to 255)
// 3rd byte: Data word (value 0 to 255)
// Command format:
// 00000000 No operation
// 10000000 Write until CSB raised
// 01000000 Read until CSB raised
// 11000000 Simultaneous read/write until CSB raised
// 11000100 Pass-through read/write to management area flash SPI until CSB raised
// 11000010 Pass-through read/write to user area flash SPI until CSB raised
// wrnnn000 Read/write as above, for nnn = 1 to 7 bytes, then terminate
// Lower three bits are reserved for future use.
// All serial bytes are read and written msb first.
// Fixed control and status registers
// Address 0 is reserved and contains flags for SPI mode. This is
// currently undefined and is always value 0.
// Address 1 is reserved and contains manufacturer ID low 8 bits.
// Address 2 is reserved and contains manufacturer ID high 4 bits.
// Address 3 is reserved and contains product ID (8 bits).
// Addresses 4 to 7 are reserved and contain the mask ID (32 bits).
// Addresses 8 to 255 are available for general purpose use.
`define COMMAND 3'b000
`define ADDRESS 3'b001
`define DATA 3'b010
`define USERPASS 3'b100
`define MGMTPASS 3'b101
module housekeeping_spi_slave(reset, SCK, SDI, CSB, SDO,
sdoenb, idata, odata, oaddr, rdstb, wrstb,
pass_thru_mgmt, pass_thru_mgmt_delay,
pass_thru_user, pass_thru_user_delay,
pass_thru_mgmt_reset, pass_thru_user_reset);
input reset;
input SCK;
input SDI;
input CSB;
output SDO;
output sdoenb;
input [7:0] idata;
output [7:0] odata;
output [7:0] oaddr;
output rdstb;
output wrstb;
output pass_thru_mgmt;
output pass_thru_mgmt_delay;
output pass_thru_user;
output pass_thru_user_delay;
output pass_thru_mgmt_reset;
output pass_thru_user_reset;
reg [7:0] addr;
reg wrstb;
reg rdstb;
reg sdoenb;
reg [2:0] state;
reg [2:0] count;
reg writemode;
reg readmode;
reg [2:0] fixed;
wire [7:0] odata;
reg [6:0] predata;
wire [7:0] oaddr;
reg [7:0] ldata;
reg pass_thru_mgmt;
reg pass_thru_mgmt_delay;
reg pre_pass_thru_mgmt;
reg pass_thru_user;
reg pass_thru_user_delay;
reg pre_pass_thru_user;
wire csb_reset;
assign odata = {predata, SDI};
assign oaddr = (state == `ADDRESS) ? {addr[6:0], SDI} : addr;
assign SDO = ldata[7];
assign csb_reset = CSB | reset;
assign pass_thru_mgmt_reset = pass_thru_mgmt_delay | pre_pass_thru_mgmt;
assign pass_thru_user_reset = pass_thru_user_delay | pre_pass_thru_user;
// Readback data is captured on the falling edge of SCK so that
// it is guaranteed valid at the next rising edge.
always @(negedge SCK or posedge csb_reset) begin
if (csb_reset == 1'b1) begin
wrstb <= 1'b0;
ldata <= 8'b00000000;
sdoenb <= 1'b1;
end else begin
// After CSB low, 1st SCK starts command
if (state == `DATA) begin
if (readmode == 1'b1) begin
sdoenb <= 1'b0;
if (count == 3'b000) begin
ldata <= idata;
end else begin
ldata <= {ldata[6:0], 1'b0}; // Shift out
end
end else begin
sdoenb <= 1'b1;
end
// Apply write strobe on SCK negative edge on the next-to-last
// data bit so that it updates data on the rising edge of SCK
// on the last data bit.
if (count == 3'b111) begin
if (writemode == 1'b1) begin
wrstb <= 1'b1;
end
end else begin
wrstb <= 1'b0;
end
end else if (state == `MGMTPASS || state == `USERPASS) begin
wrstb <= 1'b0;
sdoenb <= 1'b0;
end else begin
wrstb <= 1'b0;
sdoenb <= 1'b1;
end // ! state `DATA
end // ! csb_reset
end // always @ ~SCK
always @(posedge SCK or posedge csb_reset) begin
if (csb_reset == 1'b1) begin
// Default state on reset
addr <= 8'h00;
rdstb <= 1'b0;
predata <= 7'b0000000;
state <= `COMMAND;
count <= 3'b000;
readmode <= 1'b0;
writemode <= 1'b0;
fixed <= 3'b000;
pass_thru_mgmt <= 1'b0;
pass_thru_mgmt_delay <= 1'b0;
pre_pass_thru_mgmt <= 1'b0;
pass_thru_user = 1'b0;
pass_thru_user_delay <= 1'b0;
pre_pass_thru_user <= 1'b0;
end else begin
// After csb_reset low, 1st SCK starts command
if (state == `COMMAND) begin
rdstb <= 1'b0;
count <= count + 1;
if (count == 3'b000) begin
writemode <= SDI;
end else if (count == 3'b001) begin
readmode <= SDI;
end else if (count < 3'b101) begin
fixed <= {fixed[1:0], SDI};
end else if (count == 3'b101) begin
pre_pass_thru_mgmt <= SDI;
end else if (count == 3'b110) begin
pre_pass_thru_user <= SDI;
pass_thru_mgmt_delay <= pre_pass_thru_mgmt;
end else if (count == 3'b111) begin
pass_thru_user_delay <= pre_pass_thru_user;
if (pre_pass_thru_mgmt == 1'b1) begin
state <= `MGMTPASS;
pre_pass_thru_mgmt <= 1'b0;
end else if (pre_pass_thru_user == 1'b1) begin
state <= `USERPASS;
pre_pass_thru_user <= 1'b0;
end else begin
state <= `ADDRESS;
end
end
end else if (state == `ADDRESS) begin
count <= count + 1;
addr <= {addr[6:0], SDI};
if (count == 3'b111) begin
if (readmode == 1'b1) begin
rdstb <= 1'b1;
end
state <= `DATA;
end else begin
rdstb <= 1'b0;
end
end else if (state == `DATA) begin
predata <= {predata[6:0], SDI};
count <= count + 1;
if (count == 3'b111) begin
if (fixed == 3'b001) begin
state <= `COMMAND;
end else if (fixed != 3'b000) begin
fixed <= fixed - 1;
addr <= addr + 1; // Auto increment address (fixed)
end else begin
addr <= addr + 1; // Auto increment address (streaming)
end
end else begin
rdstb <= 1'b0;
end
end else if (state == `MGMTPASS) begin
pass_thru_mgmt <= 1'b1;
end else if (state == `USERPASS) begin
pass_thru_user <= 1'b1;
end // ! state `DATA | `MGMTPASS | `USERPASS
end // ! csb_reset
end // always @ SCK
endmodule // housekeeping_spi_slave
`default_nettype wire