From: Luke Kenneth Casson Leighton Date: Thu, 19 Jul 2018 12:35:55 +0000 (+0100) Subject: add qspi peripheral X-Git-Url: https://git.libre-soc.org/?a=commitdiff_plain;h=846dff879cd90b469bc19cf9f3f107223d4a6210;p=pinmux.git add qspi peripheral --- diff --git a/src/bsv/bsv_lib/instance_defines.bsv b/src/bsv/bsv_lib/instance_defines.bsv index 7f56625..c8b34be 100644 --- a/src/bsv/bsv_lib/instance_defines.bsv +++ b/src/bsv/bsv_lib/instance_defines.bsv @@ -29,5 +29,14 @@ `define I2C0End 'h000114FF // 8 32-bit registers +`define QSPI0 enable + `define QSPI0CfgBase 'h00011800 + `define QSPI0CfgEnd 'h000118FF // 13 32-bit registers + `define QSPI0MemBase 'h90000000 + `define QSPI0MemEnd 'h9FFFFFFF // 256 MB + + `define PWMBase 'h00011A00 + `define PWMEnd 'h00011A0C // 4 32-bit registers + //`define PWM_AXI4Lite enable diff --git a/src/bsv/bsv_lib/qspi.bsv b/src/bsv/bsv_lib/qspi.bsv new file mode 100644 index 0000000..47e79e3 --- /dev/null +++ b/src/bsv/bsv_lib/qspi.bsv @@ -0,0 +1,1320 @@ +/* +Copyright (c) 2013, IIT Madras +All rights reserved. + +Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: + +* Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. +* Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. +* Neither the name of IIT Madras nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. + +THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. +--------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- +*/ +package qspi; +/* + TODOs + To use the following registers: + dcr_csht +* Done Pre-scaler. +> Memory mapped mode should continue to fetch data and fill the fifo even if the Core + is not requesting +* Done Status polling mode. +> This could not be replicated since the tof flag is set. + Memory mapped mode with dcyc =10 creates an extra cycle after Dummy phase. +> Data Read phase is on posedge and Data write is on negdege +-- send the received arid and bid's so that DMA can identify. duplicate instead of extend +*/ + import TriState::*; + import ConcatReg ::*; + import Semi_FIFOF :: *; + import AXI4_Lite_Types :: *; + import AXI4_Lite_Fabric :: *; + import FIFO::*; + import FIFOF::*; + import SpecialFIFOs::*; + import MIMO::*; + import DefaultValue :: *; + `include "instance_defines.bsv" + `include "qspi.defs" + import ConfigReg::*; + import Vector::*; + import UniqueWrappers :: * ; + import DReg::*; + import BUtils::*; + (*always_ready, always_enabled*) + interface QSPI_out; + /*(* always_ready, result="clk_o" *) */ method bit clk_o; + /*(* always_ready, result="io_o" *) */ method Bit#(4) io_o; + /*(* always_ready, result="io0_sdio_ctrl" *) */ method Bit#(9) io0_sdio_ctrl; + /*(* always_ready, result="io1_sdio_ctrl" *) */ method Bit#(9) io1_sdio_ctrl; + /*(* always_ready, result="io2_sdio_ctrl" *) */ method Bit#(9) io2_sdio_ctrl; + /*(* always_ready, result="io3_sdio_ctrl" *) */ method Bit#(9) io3_sdio_ctrl; + /*(* always_ready, result="io_enable" *)*/ method Bit#(4) io_enable; + /*(* always_ready, always_enabled *) */ method Action io_i ((* port="io_i" *) Bit#(4) io_in); // in + /*(* always_ready, result="ncs_o" *) */ method bit ncs_o; + endinterface + + interface Ifc_qspi; + interface QSPI_out out; + interface AXI4_Lite_Slave_IFC#(`PADDR,`Reg_width,`USERSPACE) slave; + method Bit#(6) interrupts; // 0=TOF, 1=SMF, 2=Threshold, 3=TCF, 4=TEF 5 = request_ready +`ifdef simulate + method Phase curphase; +`endif + endinterface + + function Reg#(t) readOnlyReg(t r); + return (interface Reg; + method t _read = r; + method Action _write(t x) = noAction; + endinterface); + endfunction + + function Reg#(t) conditionalWrite(Reg#(t) r, Bool a); + return (interface Reg; + method t _read = r._read; + method Action _write(t x); + if(a) + r._write(x); + endmethod + endinterface); + endfunction + + function Reg#(t) clearSideEffect(Reg#(t) r, Action a, Action b) + provisos( Literal#(t),Eq#(t)); + return (interface Reg; + method t _read = r._read; + method Action _write(t x); + r._write(x); + if(x==1) begin + a; + b; + end + endmethod + endinterface); + endfunction + + function Reg#(Bit#(32)) writeSideEffect(Reg#(Bit#(32)) r, Action a); + return (interface Reg; + method Bit#(32) _read = r._read; + method Action _write(Bit#(32) x); + r._write(x); + a; + endmethod + endinterface); + endfunction + + function Reg#(Bit#(n)) writeCCREffect(Reg#(Bit#(n)) r, Action a, Action b); + return (interface Reg; + method Bit#(n) _read = r._read; + method Action _write(Bit#(n) x); + r._write(x); + `ifdef verbose1 $display("x: %h",x); `endif + if(x[11:10]==0 && (x[27:26] == 'b00 || x[27:26]=='b01 || x[25:24]=='b0) && x[9:8]!=0) begin // no address required and nodata from firmware (i.e. no write) + a; + end + if(x[27:26]=='b11) //Memory Mapped Mode + b; + endmethod + endinterface); + endfunction + + typedef enum {Instruction_phase=0, + Address_phase=1, + AlternateByte_phase=2, + Dummy_phase=3, + DataRead_phase=4, + DataWrite_phase=5, + Idle=6} Phase deriving (Bits,Eq,FShow); + + (*synthesize*) + module mkqspi(Ifc_qspi); + + AXI4_Lite_Slave_Xactor_IFC #(`PADDR, `Reg_width, `USERSPACE) s_xactor <- mkAXI4_Lite_Slave_Xactor; + /*************** List of implementation defined Registers *****************/ + Reg#(bit) rg_clk <-mkReg(1); + Reg#(Bit#(8)) rg_clk_counter<-mkReg(0); + MIMOConfiguration cfg=defaultValue; + cfg.unguarded=True; + MIMO#(4,4,16,Bit#(8)) fifo <-mkMIMO(cfg); + Reg#(Phase) rg_phase <-mkReg(Idle); + Reg#(Phase) rg_phase_delayed <-mkReg(Idle); + Reg#(Bit#(4)) rg_output <-mkReg(0); + Reg#(Bit#(4)) rg_output_en <-mkReg(0); + Reg#(Bool) rg_input_en <-mkReg(False); + Wire#(Bit#(4)) rg_input <-mkDWire(0); + Reg#(Bit#(32)) rg_count_bits <-mkReg(0); // count bits to be transfered + Reg#(Bit#(32)) rg_count_bytes <-mkReg(0); // count bytes to be transfered + Wire#(Bool) wr_sdr_clock <-mkDWire(False); // use this to trigger posedge of sclk + Reg#(Bool) wr_sdr_delayed <- mkReg(False); + Reg#(Bool) wr_instruction_written<-mkDReg(False); // this wire is se when the instruction is written by the AXI Master + Reg#(Bool) wr_address_written<-mkDReg(False); // this wire is set when the address is written by the AXI Master + Reg#(Bool) wr_read_request_from_AXI<-mkDReg(False); // this wire is set when the address is written by the AXI Master + Reg#(Bool) wr_data_written<-mkDReg(False); // this wire is set when the data is written by the AXI Master + Reg#(Bool) instruction_sent<-mkReg(False); // This register is set when the instruction has been sent once to the flash + Reg#(Bit#(1)) ncs <-mkReg(1); // this is the chip select + Reg#(Bit#(1)) delay_ncs <-mkReg(1); // this is the chip select + Wire#(Bool) wr_status_read<-mkDWire(False); // this wire is set when the status register is written + Wire#(Bool) wr_data_read<-mkDWire(False); // this wire is set when the data register is written + Reg#(Bool) half_cycle_delay<-mkReg(False); + Reg#(Bit#(16)) timecounter<-mkReg(0); + Reg#(Bool) read_true <- mkReg(False); + Reg#(Bool) first_read <- mkReg(False); + /*************** End of implementation defined Registers *****************/ + + /*************** List of QSPI defined Registers *****************/ + Reg#(Bit#(1)) sr_busy <-mkConfigReg(0); // set when the operation is in progress. + Reg#(Bit#(5)) sr_flevel <-mkReg(0); // FIFO Level. Number of valid bytes held in the FIFO. 0: empty + Reg#(Bit#(1)) sr_tof <-mkReg(0); // set when the timeout occurs. + Reg#(Bit#(1)) sr_smf <-mkReg(0); // set when the unmasked receieved data matches psmar. + Reg#(Bit#(1)) sr_ftf <-mkReg(0); // set when the FIFO threshold is reached. + Reg#(Bit#(1)) sr_tcf <-mkReg(0); // set when programmed number of data has been transfered or when aborted. + Reg#(Bit#(1)) delay_sr_tcf <-mkReg(0); // set when programmed number of data has been transfered or when aborted. + Reg#(Bit#(1)) sr_tef <-mkReg(0); // set when an error occurs on transfer. + Reg#(Bit#(32)) sr = concatReg9(readOnlyReg(19'd0),readOnlyReg(sr_flevel),readOnlyReg(2'd0),readOnlyReg(sr_busy),readOnlyReg(sr_tof),readOnlyReg(sr_smf),readOnlyReg(sr_ftf),readOnlyReg(sr_tcf),readOnlyReg(sr_tef)); + + + Reg#(Bit#(8)) prescaler<-mkReg(0); + Reg#(Bit#(8)) cr_prescaler=conditionalWrite(prescaler,sr_busy==0); // prescaler register part of the control register. + Reg#(Bit#(1)) pmm <-mkReg(0); + Reg#(Bit#(1)) cr_pmm =conditionalWrite(pmm,sr_busy==0); // polling match mode. 0: AND match and 1: OR match. + Reg#(Bit#(1)) apms <-mkReg(0); + Reg#(Bit#(1)) cr_apms =conditionalWrite(apms,sr_busy==0); // automatic poll mode stop. 1: stop when match. 0: stopped by disabling qspi. + Reg#(Bit#(1)) cr_toie <-mkReg(0); // enabled interrupt on time-out. + Reg#(Bit#(1)) cr_smie <-mkReg(0); // enables status match interrupt. + Reg#(Bit#(1)) cr_ftie <-mkReg(0); // enables interrupt on FIFO threshold. + Reg#(Bit#(1)) cr_tcie <-mkReg(0); // enables interrupt on completion of transfer. + Reg#(Bit#(1)) cr_teie <-mkReg(0); // enables interrupt on error of transfer. + Reg#(Bit#(4)) cr_fthres<-mkReg(0); // defines the number of bytes in the FIFO that will cause the FTF in sr to be raised. + Reg#(Bit#(1)) fsel<-mkReg(0); + Reg#(Bit#(1)) cr_fsel=conditionalWrite(fsel,sr_busy==0); // used for flash memory selection TODO: Not required. + Reg#(Bit#(1)) dfm<-mkReg(0); + Reg#(Bit#(1)) cr_dfm =conditionalWrite(dfm,sr_busy==0); // used for dual flash mode TODO: Not required. + Reg#(Bit#(1)) sshift<-mkReg(0); + Reg#(Bit#(1)) cr_sshift =conditionalWrite(sshift,sr_busy==0); // sample shift to account for delays from the flash. TODO: Might not be required. + Reg#(Bit#(1)) tcen<-mkReg(0); + Reg#(Bit#(1)) cr_tcen =conditionalWrite(tcen,sr_busy==0); // enables the timeout counter. + Reg#(Bit#(1)) cr_dmaen <- mkReg(0); // enables the dma transfer. + Reg#(Bit#(1)) cr_abort <- mkReg(0); // this bit aborts the ongoing transaction. + Reg#(Bit#(1)) cr_en <-mkReg(0); // this bit enables the qspi. + Reg#(Bit#(32)) cr=concatReg19(cr_prescaler,cr_pmm,cr_apms,readOnlyReg(1'b0),cr_toie,cr_smie,cr_ftie,cr_tcie,cr_teie,readOnlyReg(4'd0),cr_fthres,cr_fsel,cr_dfm,readOnlyReg(1'b0),cr_sshift,cr_tcen,cr_dmaen,cr_abort,cr_en); + + Reg#(Bit#(5)) fsize<-mkReg(0); + Reg#(Bit#(5)) dcr_fsize =conditionalWrite(fsize,sr_busy==0); // flash memory size. + Reg#(Bit#(3)) csht <-mkReg(0); + Reg#(Bit#(3)) dcr_csht = conditionalWrite(csht,sr_busy==0); // chip select high time. + Reg#(Bit#(1)) ckmode <-mkReg(0); + Reg#(Bit#(1)) dcr_ckmode =conditionalWrite(ckmode,sr_busy==0); // mode 0 or mode 3. + Reg#(Bit#(8)) dcr_mode_byte <- mkReg(0); + Reg#(Bit#(32)) dcr = concatReg7(readOnlyReg(3'd0),dcr_mode_byte,dcr_fsize,readOnlyReg(5'd0),dcr_csht,readOnlyReg(7'd0),dcr_ckmode); + Reg#(Bit#(32)) rg_mode_bytes = concatReg2(dcr_mode_byte,readOnlyReg(24'd0)); + Reg#(Bit#(5)) rg_mode_byte_counter <- mkReg('d31); + + Reg#(Bit#(1)) fcr_ctof <-mkReg(0); // writing 1 clears the sr_tof flag. + Reg#(Bit#(1)) fcr_csmf <-mkReg(0); // writing 1 clears the sr_smf flag. + Reg#(Bit#(1)) fcr_ctcf <-mkReg(0); // writing 1 clears the sr_tcf flag. + Reg#(Bit#(1)) fcr_ctef <-mkReg(0); // writing 1 clears the sr_tef flag. + Reg#(Bit#(32)) fcr=concatReg6(readOnlyReg(27'd0),clearSideEffect(fcr_ctof,sr_tof._write(0),noAction),clearSideEffect(fcr_csmf,sr_smf._write(0),noAction),readOnlyReg(1'b0),clearSideEffect(fcr_ctcf,sr_tcf._write(0),delay_sr_tcf._write(0)),clearSideEffect(fcr_ctef,sr_tef._write(0),noAction)); + + Reg#(Bit#(32)) data_length<-mkReg(0); + Reg#(Bit#(32)) dlr=conditionalWrite(data_length,sr_busy==0); // data length register + + Reg#(Bit#(1)) ddrm<-mkReg(0); + Reg#(Bit#(1)) ccr_ddrm =conditionalWrite(ddrm,sr_busy==0); // double data rate mode. + Reg#(Bit#(1)) dhhc <-mkReg(0); + Reg#(Bit#(1)) ccr_dhhc =conditionalWrite(dhhc,sr_busy==0); // delay output by 1/4 in DDR mode. TODO: Not required. + Reg#(Bit#(1)) sioo <-mkReg(0); + Reg#(Bit#(1)) ccr_sioo =conditionalWrite(sioo,sr_busy==0); // send instruction based on mode selected. + Reg#(Bit#(2)) fmode <-mkReg(0); + Reg#(Bit#(2)) ccr_fmode =conditionalWrite(fmode,sr_busy==0); // 00: indirect Read, 01: indirect Write, 10: Auto polling, 11: MMapped. + Reg#(Bit#(2)) dmode <-mkReg(0); + Reg#(Bit#(2)) ccr_dmode =conditionalWrite(dmode,sr_busy==0); // data mode. 01: single line, 10: two line, 11: four lines. + Reg#(Bit#(5)) dcyc <-mkReg(0); + Reg#(Bit#(5)) ccr_dcyc =conditionalWrite(dcyc,sr_busy==0); // number of dummy cycles. + Reg#(Bit#(2)) absize <-mkReg(0); + Reg#(Bit#(2)) ccr_absize=conditionalWrite(absize,sr_busy==0); // number of alternate byte sizes. + Reg#(Bit#(2)) abmode <-mkReg(0); + Reg#(Bit#(2)) ccr_abmode=conditionalWrite(abmode,sr_busy==0); // alternate byte mode. + Reg#(Bit#(2)) adsize <-mkReg(0); + Reg#(Bit#(2)) ccr_adsize=conditionalWrite(adsize,sr_busy==0); // address size. + Reg#(Bit#(2)) admode <-mkReg(0); + Reg#(Bit#(2)) ccr_admode=conditionalWrite(admode,sr_busy==0); // address mode. + Reg#(Bit#(2)) imode <-mkReg(0); + Reg#(Bit#(2)) ccr_imode =conditionalWrite(imode,sr_busy==0); // instruction mode. + Reg#(Bit#(8)) instruction <-mkReg(0); + Reg#(Bit#(8)) ccr_instruction =conditionalWrite(instruction,sr_busy==0); // instruction to be sent externally. + Reg#(Bit#(1)) ccr_dummy_confirmation <- mkReg(0); //Programming Dummy confirmation bit needed by Micron model to trigger XIP mode + Reg#(Bit#(1)) ccr_dummy_bit <- mkReg(0); //Dummy bit to be sent + Reg#(Bit#(32)) ccr =writeCCREffect(concatReg14(ccr_ddrm,ccr_dhhc,ccr_dummy_bit,ccr_sioo,ccr_fmode,ccr_dmode,ccr_dummy_confirmation,ccr_dcyc,ccr_absize,ccr_abmode,ccr_adsize,ccr_admode,ccr_imode,ccr_instruction),wr_instruction_written._write(True),first_read._write(True)); + + Reg#(Bit#(32)) mm_data_length <-mkConfigReg(0); + Reg#(Bit#(28)) mm_address <-mkConfigReg(0); + Reg#(Bit#(28)) rg_prev_addr <- mkConfigReg(0); + Reg#(Bit#(32)) rg_address <-mkReg(0); + Reg#(Bit#(32)) ar =conditionalWrite(writeSideEffect(rg_address,wr_address_written._write(True)),sr_busy==0 && ccr_fmode!='b11); // address register + + Reg#(Bit#(32)) rg_alternatebyte_reg<-mkReg(0); + Reg#(Bit#(32)) abr=conditionalWrite(rg_alternatebyte_reg,sr_busy==0); // alternate byte register + + Reg#(Bit#(32)) rg_data <-mkReg(0); + Reg#(Bit#(32)) dr =writeSideEffect(rg_data,wr_data_written._write(True)); // data register + + Reg#(Bit#(32)) rg_psmkr <-mkReg(0); + Reg#(Bit#(32)) psmkr =conditionalWrite(rg_psmkr,sr_busy==0); // polling status mask register + + Reg#(Bit#(32)) rg_psmar <-mkReg(0); + Reg#(Bit#(32)) psmar =conditionalWrite(rg_psmar,sr_busy==0); // polling statue match register + + Reg#(Bit#(16)) pir_interval <-mkReg(0); // polling interval + Reg#(Bit#(32)) pir =conditionalWrite(concatReg2(readOnlyReg(16'd0),pir_interval),sr_busy==0); // polling interval register + + Reg#(Bit#(16)) lptr_timeout <-mkReg(0); // timeout period + Reg#(Bit#(32)) lptr =conditionalWrite(concatReg2(readOnlyReg(16'd0),lptr_timeout),sr_busy==0); // low power timeout register. + Reg#(Bool) thres <- mkReg(False); + Reg#(Bit#(32)) sdio0r <- mkReg(32'h00000073); + Reg#(Bit#(32)) sdio1r <- mkReg(32'h00000073); + Reg#(Bit#(32)) sdio2r <- mkReg(32'h00000073); + Reg#(Bit#(32)) sdio3r <- mkReg(32'h00000073); + Reg#(Bool) rg_request_ready <- mkReg(True); + Bool ddr_clock = ((wr_sdr_clock&&!wr_sdr_delayed)||(!wr_sdr_clock&&wr_sdr_delayed)); + Bool transfer_cond = (sr_busy==1 && cr_abort==0 && cr_en==1); + Bool clock_cond = ((wr_sdr_clock && ccr_ddrm==0) || (ddr_clock && ccr_ddrm==1)); + Bool qspi_flush = (cr_abort==1 || cr_en==0); + /*************** End of QSPI defined Registers *****************/ + function Reg#(Bit#(32)) access_register(Bit#(8) address); + Reg#(Bit#(32)) register=( + case(address) + `CR : cr; + `DCR : dcr; + `FCR : fcr; + `DLR : dlr; + `CCR : ccr; + `AR : ar; + `ABR : abr; + `DR : dr; + `SR : sr; + `PSMKR : psmkr; + `PSMAR : psmar; + `PIR : pir; + `LPTR : lptr; + `SDIO0 : sdio0r; + `SDIO1 : sdio1r; + `SDIO2 : sdio2r; + `SDIO3 : sdio3r; + default: readOnlyReg(0); + endcase + ); + return register; + endfunction + + /* This function defines the next phase that needs to be executed. indicates if + the operation is over and also the value of rg_count_bits for the next phase*/ + function Tuple3#(Bit#(32),Bit#(1),Phase) phase_change(Phase current_phase, Bit#(32) count_val, Bit#(1) smf); + Phase next_phase=Idle; + if(current_phase==Idle) + next_phase=Instruction_phase; + if(current_phase==Instruction_phase) + next_phase=Address_phase; + if(current_phase==Address_phase) + next_phase=AlternateByte_phase; + if(current_phase==AlternateByte_phase) + next_phase=Dummy_phase; + if(current_phase==Dummy_phase) + next_phase=(ccr_fmode=='b00)?DataWrite_phase:DataRead_phase; + if(current_phase==DataRead_phase)begin + if(ccr_fmode=='b01 || ccr_fmode=='b10) // indirect modes + next_phase=Idle; + else if(ccr_fmode=='b10) // auto-status polling mode + if(smf==1) + next_phase=Idle; + else + next_phase=Dummy_phase; + else + next_phase=DataRead_phase; //Memory Mapped mode + end + if(current_phase==DataWrite_phase) + next_phase=Idle; + + if(next_phase==Instruction_phase && (ccr_imode==0||(ccr_sioo==1 && instruction_sent))) // if single instruction mode or no instruction mode + next_phase=Address_phase; + if(next_phase==Address_phase && ccr_admode==0) + next_phase=AlternateByte_phase; + if(next_phase==AlternateByte_phase && ccr_abmode==0) + next_phase=Dummy_phase; + if(next_phase==Dummy_phase && ccr_dcyc==0) + next_phase=ccr_fmode==0?DataWrite_phase:DataRead_phase; + if(next_phase==Dummy_phase && (ccr_fmode=='b10 && pir_interval==0))begin // TODO Check if this is correct or needs more logic. + next_phase=Instruction_phase; + end + if((next_phase==DataWrite_phase || next_phase==DataRead_phase) && ccr_dmode==0 && ccr_fmode!='b11)begin + if(ccr_fmode=='b01 || ccr_fmode=='b00) + next_phase=Idle; + else if(ccr_fmode=='b10) + if(smf==1) + next_phase=Idle; + else + next_phase=Dummy_phase; + end + + if(next_phase==Instruction_phase)begin + count_val=8; + end + if(next_phase==Address_phase)begin + count_val=(ccr_fmode=='b11)?32:(case(ccr_adsize) 0:8; 1:16; 2:24; 3:32; endcase); + end + if(next_phase==AlternateByte_phase)begin + count_val=(case(ccr_absize) 0:8; 1:16; 2:24; 3:32; endcase); + end + if(next_phase==Dummy_phase)begin + count_val=(ccr_fmode=='b10)? zeroExtend(pir_interval):zeroExtend(ccr_dcyc); + end + if(next_phase==DataWrite_phase)begin + count_val=8; + end + if(next_phase==DataRead_phase)begin + count_val=0; + end + Bit#(1) tcf=0; + if(current_phase!=Idle && next_phase==Idle && (ccr_fmode=='b00 || ccr_fmode=='b01))begin // only in indirect mode raise completion of transfer TODO remove ccr_fmode=='b11 from this line. + tcf=1; + end + return tuple3(count_val,tcf,next_phase); + endfunction + + Wrapper3#(Phase,Bit#(32),Bit#(1),Tuple3#(Bit#(32),Bit#(1),Phase)) change_phase<-mkUniqueWrapper3(phase_change); + /* This rule receives the write request from the AXI and updates the relevant + QSPI register set using the lower 12 bits as address map */ + rule rl_write_request_from_AXI; + let aw <- pop_o (s_xactor.o_wr_addr); + let w <- pop_o (s_xactor.o_wr_data); + AXI4_Lite_Resp axi4_bresp = AXI4_LITE_OKAY; + if(ccr_fmode=='b11 && aw.awaddr[7:0]==`DR) begin //Undefined behavior when written into integral fields in CR, CCR!!! + axi4_bresp = AXI4_LITE_SLVERR; + `ifdef verbose $display("Sending AXI4_LITE_SLVERR because store in memory mapped mode and not clearing Interrupt Flags"); `endif + end + `ifdef verbose $display($time,"\tReceived AXI write request to Address: %h Data: %h Size: %h",aw.awaddr,w.wdata,aw.awsize); `endif + if(aw.awaddr[7:0]==`DR)begin + if(aw.awsize==0)begin + dr[7:0]<=w.wdata[7:0]; + Vector#(4,Bit#(8)) temp=newVector(); + temp[0]=w.wdata[7:0]; + if(fifo.enqReadyN(1)) + fifo.enq(1,temp); + end + else if(aw.awsize==1)begin + dr[15:0]<=w.wdata[15:0]; + Vector#(4,Bit#(8)) temp = newVector(); + temp[0]=w.wdata[7:0]; + temp[1]=w.wdata[15:8]; + if(fifo.enqReadyN(2)) + fifo.enq(2,temp); + end + else if(aw.awsize==2)begin + dr<=w.wdata[31:0]; + Vector#(4,Bit#(8)) temp = newVector(); + temp[3]=w.wdata[31:24]; + temp[2]=w.wdata[23:16]; + temp[1]=w.wdata[15:8]; + temp[0]=w.wdata[7:0]; + if(fifo.enqReadyN(4)) + fifo.enq(4,temp); + end + else begin + axi4_bresp = AXI4_LITE_SLVERR; + `ifdef verbose $display("Sending AXI4_LITE_SLVERR because DR awsize is 64-bit"); `endif + end + end + else begin + let reg1=access_register(aw.awaddr[7:0]); + `ifdef verbose $display("Write Reg access: %h Write Data: %h Size: %h",aw.awaddr[7:0],w.wdata,aw.awsize); `endif + //Byte and Half-Word Writes are not permitted in ConfigReg Space + if(aw.awsize==2) // 32 bits + reg1<=w.wdata[31:0]; + else begin + axi4_bresp = AXI4_LITE_SLVERR; + `ifdef verbose $display("Sending SLVERR because Accessed register's awsize was different"); `endif + end + end + + let b = AXI4_Lite_Wr_Resp {bresp: axi4_bresp, buser: aw.awuser}; + s_xactor.i_wr_resp.enq (b); + endrule + + /* This rule receives the read request from the AXI and responds with the relevant + QSPI register set using the lower 12 bits as address map */ + (*descending_urgency="rl_read_request_from_AXI,rl_write_request_from_AXI"*) //experimental + rule rl_read_request_from_AXI(rg_request_ready==True); + let axir<- pop_o(s_xactor.o_rd_addr); + Bool request_ready = True; + `ifdef verbose $display($time,"\tReceived AXI read request to Address: %h Size: %h",axir.araddr,axir.arsize); `endif + if((axir.araddr[27:0]>=`STARTMM && axir.araddr[27:0]<=`ENDMM) && axir.araddr[31]==1'b1)begin // memory mapped space + + wr_read_request_from_AXI<=True; //Could this lead to some error? Need to think about this, without fail + AXI4_Lite_Resp axi4_rresp = AXI4_LITE_OKAY; + mm_address<=truncate(axir.araddr); + Bit#(4) data_length = axir.arsize==0?1:axir.arsize==1?2:axir.arsize==2?4:8; + mm_data_length<= zeroExtend(data_length); + Bit#(28) address_limit = 1 << dcr_fsize; + + //It is forbidden to access the flash bank area before the SPI is properly configured -- fmode is '11?? + //If not sending a SLVERR now if the mode is not memory mapped and if an access is made outside allowed + if(ccr_fmode!='b11 || axir.araddr[27:0] > address_limit) begin + `ifdef verbose $display("Sending Slave Error ccr_fmode: %h mm_address: %h address_limit: %h dcr_fsize: %h",ccr_fmode,mm_address,address_limit, dcr_fsize); `endif + axi4_rresp = AXI4_LITE_SLVERR; + let r = AXI4_Lite_Rd_Data {rresp: axi4_rresp, rdata: 0 , ruser: 0}; + s_xactor.i_rd_data.enq(r); + axi4_rresp = AXI4_LITE_SLVERR; + rg_phase <= Idle; //Will this work? + cr_en <= 0; + sr_busy <= 0; + ncs <= 1; //Just resetting all the parameters, just in case. Should Ask Neel + first_read <= True; + end + else if(sr_busy==1 ||thres) begin //Bus is busy with Memory mapped maybe? + `ifdef verbose $display($time,"sr_busy: %d, thres: %d rg_prev_addr: %h axir.araddr: %h fifo_count: %d", sr_busy, thres, rg_prev_addr, axir.araddr, fifo.count); `endif + Bit#(28) eff_addr = rg_prev_addr + zeroExtend(data_length); + if((eff_addr!= truncate(axir.araddr)) || pack(fifo.count)==0 || ccr_dummy_bit==1'b1) begin + `ifdef verbose $display($time,"Not Equal eff_addr: %h mm_address : %h axir.araddr: %h rg_prev_addr: %h data_length : %h sum : %h fifo.count: %h ccr_dummy_bit: %h",eff_addr,mm_address,axir.araddr,rg_prev_addr,data_length,rg_prev_addr+zeroExtend(data_length),pack(fifo.count),ccr_dummy_bit); `endif + sr_busy<=0; + rg_phase<=Idle; + ncs<=1; + fifo.clear(); + thres <= False; + //$display($time,"Setting Thres to FALSE"); + first_read <= True; + request_ready = False; + end + else if(!first_read) begin + request_ready = True; + rg_prev_addr <= truncate(axir.araddr); + Bit#(32) reg1 = 0; + if(axir.arsize==0) begin // 8 bits + if(fifo.deqReadyN(1))begin + let temp=fifo.first[0]; + reg1=duplicate(temp); + fifo.deq(1); + end + end + else if(axir.arsize==1) begin // 16 bits + if(fifo.deqReadyN(2)) begin + let temp={fifo.first[0],fifo.first[1]}; + reg1=duplicate(temp); + fifo.deq(2); + end + end + else if(axir.arsize==2) begin // 32 bits + if(fifo.deqReadyN(4)) begin + let temp={fifo.first[0],fifo.first[1],fifo.first[2],fifo.first[3]}; + reg1=duplicate(temp); + fifo.deq(4); + end + end + else + axi4_rresp = AXI4_LITE_SLVERR; + `ifdef verbose $display("Sending Response to the core: reg1: %h", reg1); `endif + let r = AXI4_Lite_Rd_Data {rresp: axi4_rresp, rdata: duplicate(reg1) , ruser: 0}; + s_xactor.i_rd_data.enq(r); + end + end + end + else begin + let reg1=access_register(axir.araddr[7:0]); + `ifdef verbose $display("Reg Read Access: %h arsize: %h",axir.araddr[7:0], axir.arsize); `endif + if(axir.araddr[7:0]==`SR) + wr_status_read<=True; + if(axir.araddr[7:0]==`DR)begin // accessing the data register for read. + `ifdef verbose $display("Accessed DR fifo_count : %d axi.arsize: %d", fifo.count, axir.arsize); `endif + if(ccr_fmode=='b10) + wr_data_read<=True; + if(axir.arsize==0) begin // 8 bits + if(fifo.deqReadyN(1))begin + let temp=fifo.first[0]; + reg1=duplicate(temp); + fifo.deq(1); + end + end + else if(axir.arsize==1) begin // 16 bits + if(fifo.deqReadyN(2)) begin + let temp={fifo.first[0],fifo.first[1]}; + reg1=duplicate(temp); + fifo.deq(2); + end + end + else /*if(axir.arsize==2)*/ begin // 32 bits -- Even if the request is a long int, respond with int since that's the max we can do + if(fifo.deqReadyN(4)) begin + let temp={fifo.first[0],fifo.first[1],fifo.first[2],fifo.first[3]}; + reg1=duplicate(temp); + fifo.deq(4); + end + end + end + `ifdef verbose $display("Sending Response : reg1: %x", reg1); `endif + let r = AXI4_Lite_Rd_Data {rresp: AXI4_LITE_OKAY, rdata: duplicate(reg1) ,ruser: 0}; + request_ready = True; + s_xactor.i_rd_data.enq(r); + end + rg_request_ready <= request_ready; + `ifdef verbose $display($time,"QSPI: Is Request ready? : %h",request_ready); `endif + endrule + + + rule timeout_counter; + if(cr_tcen==1 && sr_tof==0) // timecounter is enabled + if(timecounter==lptr_timeout[15:0])begin + timecounter<=0; + sr_tof<=1; + end + else + timecounter<=timecounter+1; + endrule + + rule delayed_sr_tcf_signal(transfer_cond && + ((ccr_ddrm==1 && ddr_clock && (ccr_admode!=0 || ccr_dmode!=0)) || wr_sdr_clock)); + sr_tcf<=delay_sr_tcf; + endrule + + rule delayed_ncs_generation; + delay_ncs<=ncs; + endrule + + rule delay_sdr; + wr_sdr_delayed <= wr_sdr_clock; + endrule + + + /* This rule generates the clk signal. The Prescaler register defines the + division factor wrt to the Global clock. The prescaler will only work when the + chip select is low i.e when the operation has been initiated. */ + rule rl_generate_clk_from_master; + if(delay_ncs==1)begin + rg_clk_counter<=0; + rg_clk<=dcr_ckmode; + `ifdef verbose1 $display("dcr_ckmode: %h",dcr_ckmode); `endif + end + else begin + let half_clock_value=cr_prescaler>>1; + if(cr_prescaler[0]==0)begin // odd division + if(rg_clk_counter<=half_clock_value) + rg_clk<=0; + else + rg_clk<=1; + if(rg_clk_counter==cr_prescaler) + rg_clk_counter<=0; + else + rg_clk_counter<=rg_clk_counter+1; + if(rg_clk_counter == half_clock_value || rg_clk_counter==cr_prescaler)begin + wr_sdr_clock<=rg_phase==DataRead_phase?unpack(~rg_clk):unpack(rg_clk); + end + end + else begin // even division + if(rg_clk_counter==half_clock_value)begin + rg_clk<=~rg_clk; + rg_clk_counter<=0; + wr_sdr_clock<=rg_phase==DataRead_phase?unpack(~rg_clk):unpack(rg_clk); + end + else if(delay_ncs==0) + rg_clk_counter<=rg_clk_counter+1; + end + end + endrule + + /* update the status flag on each cycle */ + rule rl_update_fifo_level; + sr_flevel<=pack(fifo.count); + endrule + /* set the fifo threshold flag when the FIFO level is equal to the FTHRESH value */ + (*preempts="rl_set_busy_signal,rl_update_threshold_flag"*) + rule rl_update_threshold_flag; + if(ccr_fmode=='b00)begin// indirect write mode + sr_ftf<=pack(16-pack(fifo.count)>={1'b0,cr_fthres}+1); + end + else if(ccr_fmode=='b01) begin + sr_ftf<=pack(pack(fifo.count)>=({1'b0,cr_fthres}+1)); + `ifdef verbose1 $display("fifo count: %d fthres: %d",fifo.count,cr_fthres); `endif + end + else if(ccr_fmode=='b10 && wr_status_read)begin // auto_status polling mode + sr_ftf<=1; + end + else if(ccr_fmode=='b10 && wr_data_read)begin // auto_status polling mode + sr_ftf<=0; + end + else if(ccr_fmode=='b11 && pack(fifo.count)>={1'b0,cr_fthres}+1) begin + ncs<=1; + sr_busy<=0; + rg_phase<=Idle; // Will this work? + thres<= True; + rg_request_ready <= True; + // $display($time,"THRES is being set to TRUE kyaaaa?"); + end + endrule + + /* If abort is raised or the QSPI is disabled go back to Idle Phase*/ + //(*descending_urgency = "if_abort,rl_read_request_from_AXI"*) + //(*descending_urgency = "if_abort,rl_write_request_from_AXI"*) + (*preempts = "if_abort,rl_update_threshold_flag"*) + rule if_abort(qspi_flush); + //$display("Received Abort or Disable request, going to idle"); + rg_phase<=Idle; + ncs <= 1; + sr_busy <= 0; + thres <= False; + read_true <= False; + first_read <= False; + instruction_sent <= False; + half_cycle_delay <= False; + fifo.clear(); //What if its already empty? clearing the fifo, so doesn't matter + endrule + + /*operate the busy signal in different mode */ + rule rl_reset_busy_signal(sr_busy==1); + if(cr_abort==1)begin + sr_busy<=0; + ncs<=1; + end + else if(ccr_fmode=='b00 || ccr_fmode=='b01)begin // indirect write or read mode; + if(/*fifo.count==0 &&*/ sr_tcf==1)begin // if FIFO is empty and the transaction is complete + sr_busy<=0; + ncs<=1; + end + end + else if(ccr_fmode=='b10)begin // automatic polling mode + if(sr_smf==1)begin + sr_busy<=0; + ncs<=1; + end + end + else if(ccr_fmode=='b11)begin + if(sr_tof==1 || cr_en==0 || cr_abort==1) begin// timeout event + sr_busy<=0; + ncs<=1; + end + end + endrule + (*descending_urgency="rl_set_busy_signal,rl_read_request_from_AXI"*) + (*descending_urgency="rl_set_busy_signal,rl_write_request_from_AXI"*) + rule rl_set_busy_signal(sr_busy==0 && rg_phase==Idle && cr_abort==0 && cr_en==1); + rg_output_en<=0; + instruction_sent<=False; + `ifdef verbose1 $display($time,"\tWaiting for change in phase wr_read_request_from_AXI: %b ccr_fmode: %h thres: %h",wr_read_request_from_AXI,ccr_fmode,thres); `endif + if(wr_instruction_written)begin + sr_busy<=1; + ncs<=0; + rg_phase<=Instruction_phase; + rg_count_bits<=8; + end + else if((wr_address_written && ccr_admode!=0 && (ccr_fmode=='b01 || ccr_dmode=='d0 || ccr_fmode=='b10))|| (wr_data_written && ccr_admode!=0 && ccr_dmode!=0 && ccr_fmode=='b00))begin + sr_busy<=1; // start some transaction + `ifdef verbose $display("Address Written and going to Some mode"); `endif + ncs<=0; + let {x,y,z}<-change_phase.func(rg_phase,0,0); + rg_count_bits<=x; + rg_count_bytes<=0; + rg_phase<=z; + `ifdef verbose $display("Mode is :",fshow(z),"Count_bits : %d",x); `endif + if(z==DataRead_phase) + read_true <= True; + end + else if(wr_read_request_from_AXI && ccr_fmode=='b11 && !thres)begin // memory-mapped mode. + `ifdef verbose $display("Entering Memory mapped mode"); `endif + sr_busy<=1; + ncs<=0; + let {x,y,z}<-change_phase.func(rg_phase,0,0); + rg_count_bits<=x; + rg_count_bytes<=0; + rg_phase<=z; + `ifdef verbose $display("rg_phase :",fshow(z)); `endif + if(z==DataRead_phase) + read_true <= True; + end + endrule + + /* This rule generates the error signal interrupt in different scenarios */ + rule set_error_signal; + Bit#(32) actual_address=1<<(dcr_fsize); + if(wr_address_written && ar>actual_address && (ccr_fmode=='b00 || ccr_fmode=='b01)) + sr_tef<=1; + else if(wr_address_written && ar+dlr>actual_address &&(ccr_fmode=='b00 || ccr_fmode=='b01)) + sr_tef<=1; + else if(wr_address_written) + sr_tef<=0; + endrule + + /* Rule to transfer the instruction of 8-bits outside. THe size of instruction is fixed + to 8 bits by protocol. Instruction phase will always be in SDR mode */ + rule rl_transfer_instruction(rg_phase==Instruction_phase && transfer_cond && wr_sdr_clock && !qspi_flush); + Bool end_of_phase=False; + let reverse_instruction=ccr_instruction; + let count_val=rg_count_bits; + `ifdef verbose1 $display("Executing Instruction Phase SPI Mode: %b Count_bits: %d InstructionReverse: %h",ccr_imode,rg_count_bits,reverse_instruction); `endif + Bit#(4) enable_o=0; + if(ccr_imode=='b01)begin // single spi mode; + enable_o=4'b1101; + rg_output<={1'b1,1'b0,1'b0,reverse_instruction[rg_count_bits-1]}; + if(rg_count_bits==1)begin// end of instruction stream + end_of_phase=True; + end + else + count_val=rg_count_bits-1; + end + else if (ccr_imode=='b10)begin // dual mode; + enable_o=4'b1111; + rg_output<={1'b1,1'b0,reverse_instruction[rg_count_bits-1:rg_count_bits-2]}; + if(rg_count_bits==2)begin// end of instruction stream + end_of_phase=True; + end + else + count_val=rg_count_bits-2; + end + else if (ccr_imode=='b11)begin // quad mode; + enable_o=4'b1111; + rg_output<=reverse_instruction[rg_count_bits-1:rg_count_bits-4]; + if(rg_count_bits==4)begin// end of instruction stream + end_of_phase=True; + end + else + count_val=rg_count_bits-4; + end + if(end_of_phase || ccr_imode==0)begin // end of instruction or no instruction phase + let {x,y,z}<-change_phase.func(rg_phase,count_val,0); + instruction_sent<=True; + rg_count_bits<=x; + delay_sr_tcf<=y; + rg_phase<=z; + rg_count_bytes<=0; + if(ccr_ddrm==1) + half_cycle_delay<=True; + if(z==DataRead_phase) + read_true <= True; + end + else + rg_count_bits<=count_val; + rg_output_en<=enable_o; + endrule + + /* Rule to transfer the address bits of address outside. The size of address is + defined by the ccr_adsize register in ccr */ + rule rl_transfer_address(rg_phase==Address_phase && transfer_cond && clock_cond && !qspi_flush); + if(half_cycle_delay) begin + half_cycle_delay<=False; + read_true <= True; //A workaround for the delay .. For DDR mode, the clock should be pushed one cycle and not half + end + else if(read_true) + read_true <= False; + else begin + Bool end_of_phase=False; + Bit#(4) enable_o=0; + let count_val=rg_count_bits; + Bit#(32) address=(ccr_fmode=='b11)?zeroExtend(mm_address):ar; + rg_prev_addr <= truncate(address); + `ifdef verbose1 $display($time,"Executing Address Phase SPI Mode: %b Address Size: %d Count_bits: %d Address: %b",ccr_admode,ccr_adsize,rg_count_bits,address); `endif + if(ccr_admode=='b01)begin // single spi mode; + enable_o=4'b1101; + rg_output<={1'b1,1'b0,1'b0,address[rg_count_bits-1]}; + `ifdef verbose $display($time,"Single: Sending Address bit %h bit_number: %d total_address: %h",rg_count_bits-1,address[rg_count_bits-1],address); `endif + if(rg_count_bits==1)begin// end of address stream + end_of_phase=True; + end + else + count_val=rg_count_bits-1; + end + else if (ccr_admode=='b10)begin // dual mode; + enable_o=4'b1111; + rg_output<={1'b1,1'b0,address[rg_count_bits-1:rg_count_bits-2]}; + `ifdef verbose $display($time,"Double: Sending Address bit %h bit_number: %d total_address: %h",rg_count_bits-1,address[rg_count_bits-1],address); `endif + if(rg_count_bits==2)begin// end of address stream + end_of_phase=True; + end + else + count_val=rg_count_bits-2; + end + else if (ccr_admode=='b11)begin // quad mode; + enable_o=4'b1111; + rg_output<=address[rg_count_bits-1:rg_count_bits-4]; + `ifdef verbose $display($time,"Quad: Sending Address bit %h bit_number: %d total_address: %h",rg_count_bits-1,address[rg_count_bits-1],address); `endif + if(rg_count_bits==4)begin// end of address stream + end_of_phase=True; + end + else + count_val=rg_count_bits-4; + end + if(end_of_phase || ccr_admode==0)begin // end of address phase + let {x,y,z}<-change_phase.func(rg_phase,count_val,0); + rg_count_bits<=x; + delay_sr_tcf<=y; + rg_phase<=z; + rg_count_bytes<=0; + if(z==DataRead_phase) + read_true <= True; + end + else + rg_count_bits<=count_val; + rg_output_en<=enable_o; + end + endrule + + /* Rule to transfer the alternate bytes. The size of alternate bytes is + defined by the ccr_absize register in ccr */ + rule rl_transfer_alternatebytes(rg_phase==AlternateByte_phase && transfer_cond && clock_cond && !qspi_flush); + Bool end_of_phase=False; + let count_val=rg_count_bits; + `ifdef verbose1 $display("Executing AltByte Phase SPI Mode: %b AltByte Size: %d Count_bits: %d AltByte: %b",ccr_abmode,ccr_absize,rg_count_bits,abr); `endif + Bit#(4) enable_o=0; + if(ccr_abmode=='b01)begin // single spi mode; + enable_o=4'b1101; + rg_output<={1'b1,1'b0,1'b0,abr[rg_count_bits-1]}; + if(rg_count_bits==1)begin// end of instruction stream + end_of_phase=True; + end + else + count_val=rg_count_bits-1; + end + else if (ccr_abmode=='b10)begin // dual mode; + enable_o=4'b1111; + rg_output<={1'b1,1'b0,abr[rg_count_bits-1:rg_count_bits-2]}; + if(rg_count_bits==2)begin// end of instruction stream + end_of_phase=True; + end + else + count_val=rg_count_bits-2; + end + else if (ccr_abmode=='b11)begin // quad mode; + enable_o=4'b1111; + rg_output<=abr[rg_count_bits-1:rg_count_bits-4]; + if(rg_count_bits==4)begin// end of instruction stream + end_of_phase=True; + end + else + count_val=rg_count_bits-4; + end + if(end_of_phase || ccr_abmode==0)begin // end of alternate byte phase + let {x,y,z}<-change_phase.func(rg_phase,count_val,0); + rg_count_bits<=x; + delay_sr_tcf<=y; + rg_phase<=z; + rg_count_bytes<=0; + if(z==DataRead_phase) + read_true <= True;end + else + rg_count_bits<=count_val; + rg_output_en<=enable_o; + endrule + + + rule rl_transfer_dummy_cycle(rg_phase==Dummy_phase && transfer_cond && wr_sdr_clock && !qspi_flush); + let {x,y,z} <- change_phase.func(rg_phase,rg_count_bits,0); + Bit#(5) count_val = rg_mode_byte_counter; + Bit#(4) enable_o = rg_output_en; + `ifdef verbose $display("\t Executing Dummy Phase: rg_mode_bytes: %b rg_mode_byte_counter: %d",rg_mode_bytes, rg_mode_byte_counter); `endif + if(ccr_dmode==1) begin + if(ccr_dummy_confirmation==1) begin + //rg_output_en <= 4'b1101; + enable_o = 4'b1101; + rg_output <= {1'b1,1'b0,1'b0,rg_mode_bytes[rg_mode_byte_counter]}; + if(count_val!=0) + count_val = count_val - 1; + else + enable_o = 4'b0000; + end + else begin + //rg_output_en <= 4'b1101; + enable_o = 4'b1101; + rg_output <= {1'b1,1'b0,1'b0,1'b0}; + end + end + else if(ccr_dmode==2) begin + if(ccr_dummy_confirmation==1) begin + //rg_output_en <= 4'b1111; + enable_o = 4'b1111; + rg_output <= {1'b1,1'b0,rg_mode_bytes[rg_mode_byte_counter:rg_mode_byte_counter-1]}; + if(count_val!=0) + count_val = count_val - 2; + else + enable_o = 4'b0000; + end + else begin + //rg_output_en <= 4'b1100; + enable_o = 4'b1100; + rg_output <= {1'b1,1'b0,1'b0,1'b0}; + end + end + else begin + if(ccr_dummy_confirmation==1) begin + //rg_output_en <= 4'b1111; + enable_o = 4'b1111; + rg_output <= rg_mode_bytes[rg_mode_byte_counter:rg_mode_byte_counter-3]; + if(count_val!=3) + count_val = count_val - 4; + else + enable_o = 4'b0000; + end + else begin + //rg_output_en <= 4'b0000; + enable_o = 4'b0000; + end + end + if(rg_count_bits==0 || (rg_count_bits==1 && z!=DataRead_phase))begin // end of dummy cycles; + delay_sr_tcf<=y; + rg_phase<=z; + `ifdef verbose $display("From Dummy to :",fshow(z)); `endif + if(z==DataRead_phase) + read_true <= True; + rg_count_bytes<=0; + rg_count_bits<=x; + rg_mode_byte_counter <= 'd-1; //All ones + if(ccr_ddrm==1) + half_cycle_delay<=True; + end + else begin + rg_count_bits<=rg_count_bits-1; + rg_mode_byte_counter <= count_val; + rg_output_en <= enable_o; + end + endrule + + + /* Rule to transfer the dummy_cycles. The size of dummy cycles is + defined by the ccr_dcyc register in ccr. The number of dummy cycles should be calculated of + the complete cycle even in DDR mode hence using sdr clock*/ +/* rule rl_transfer_dummy_cycle(rg_phase==Dummy_phase && transfer_cond && wr_sdr_clock && !qspi_flush); + let {x,y,z}<-change_phase.func(rg_phase,rg_count_bits,0); + `ifdef verbose $display($time,"Executing Dummy Phase, Dummy_confirmation_bit : %d dummy_bit : %d", ccr_dummy_confirmation, ccr_dummy_bit); `endif + if(ccr_dmode==1) begin + if(ccr_dummy_confirmation==1) begin + rg_output_en <= 4'b1101; + rg_output <= {1'b1,1'b0,1'b0,ccr_dummy_bit}; + ccr_dummy_confirmation<=0; + end + else begin + rg_output_en <= 4'b1101; + rg_output <= {1'b1,1'b0,1'b0,1'b0}; + end + end + else if(ccr_dmode==2) begin + if(ccr_dummy_confirmation==1) begin + rg_output_en <= 4'b1101; + rg_output <= {1'b1,1'b0,1'b0,ccr_dummy_bit}; + ccr_dummy_confirmation <= 0; + end + else begin + rg_output_en <= 4'b1100; + rg_output <= {1'b1,1'b0,1'b0,1'b0}; + end + end + else begin + if(ccr_dummy_confirmation==1) begin + `ifdef verbose $display("Data going to output %d", ccr_dummy_bit); `endif + rg_output_en <= 1; + rg_output[0] <= ccr_dummy_bit; + ccr_dummy_confirmation<=0; + end + else + rg_output_en <= 0; + end + if(rg_count_bits==0 || (rg_count_bits==1 && z!=DataRead_phase))begin // end of dummy cycles; + delay_sr_tcf<=y; + rg_phase<=z; + `ifdef verbose $display("From Dummy to :",fshow(z)); `endif + if(z==DataRead_phase) + read_true <= True; + rg_count_bytes<=0; + rg_count_bits<=x; + if(ccr_ddrm==1) + half_cycle_delay<=True; + end + else begin + rg_count_bits<=rg_count_bits-1; + end + endrule*/ + + /* read data from the flash memory and store it in the DLR register. Simulataneously + put Bytes in the FIFO*/ + (*descending_urgency="rl_data_read_phase,rl_read_request_from_AXI"*) + (*descending_urgency="rl_data_read_phase,rl_write_request_from_AXI"*) + rule rl_data_read_phase(rg_phase==DataRead_phase /*&& ccr_fmode!='b11*/ && transfer_cond && clock_cond && !qspi_flush); + //rg_output_en<=0; + if(half_cycle_delay || read_true) begin + half_cycle_delay<=False; + read_true <= False; + end + else begin + Bit#(32) data_reg=dr; + Bit#(32) count_byte=rg_count_bytes; + Bit#(32) count_bits=rg_count_bits; + Bit#(32) data_length1=(ccr_fmode=='b11)?mm_data_length:dlr; + `ifdef verbose1 $display($time,"Executing DataRead Phase SPI Mode: %b DLR : %d Count_bits: %d Input :%b ccr_ddrm: %b",ccr_dmode,data_length1,rg_count_bits,rg_input,ccr_ddrm); `endif + /* write incoming bit to the data register */ + if(ccr_dmode==1)begin // single line mode; + data_reg=data_reg<<1; + data_reg[0]=rg_input[1]; + `ifdef verbose $display($time,"Single data_reg : %b",data_reg); `endif + count_bits=count_bits+1; + rg_output_en <= 4'b1101; + rg_output <= {1'b1,1'b0,1'b0,1'b0}; + + end + else if(ccr_dmode==2)begin // dual line mode; + rg_output_en <= 4'b1100; + data_reg=data_reg<<2; + data_reg[1:0]=rg_input[1:0]; + `ifdef verbose $display($time,"Dual data_reg : %b",data_reg); `endif + count_bits=count_bits+1; + rg_output <= {1'b1,1'b0,1'b0,1'b0}; + end + else if(ccr_dmode==3) begin// quad line mode; + rg_output_en <= 4'b0000; + data_reg=data_reg<<4; + data_reg[3:0]=rg_input; + `ifdef verbose $display($time,"Quad data_reg : %b",data_reg); `endif + count_bits=count_bits+1; + end + + /* write the last successfully received byte into the FIFO */ + if(ccr_dmode==1)begin// single line mode + if(count_byte==data_length-1 && ccr_ddrm==1 && count_bits[2:0]=='b111) //To make sure that the Flash does not send any data the next half edge since ncs is made 1 after the second edge + ncs<=1; + if(rg_count_bits[2:0]=='b111)begin // multiple of eight bits have been read. + `ifdef verbose1 $display("Enquing FIFO"); `endif + Vector#(4,Bit#(8)) temp = newVector(); + temp[0]=data_reg[7:0]; + `ifdef verbose $display($time,"Single Enqueing FIFO : data is %h",temp[0]); `endif + if(!first_read) + fifo.enq(1,temp); + count_byte=count_byte+1; + end + end + else if(ccr_dmode==2) begin // dual line mode + if(count_byte==data_length-1 && ccr_ddrm==1 && count_bits[1:0]=='b11) //To make sure that the Flash does not send any data the next half edge since ncs is made 1 after the second edge + ncs<=1; + if(rg_count_bits[1:0]=='b11)begin // multiple of eight bits have been read. + `ifdef verbose1 $display("Enquing FIFO"); `endif + Vector#(4,Bit#(8)) temp = newVector(); + temp[0]=data_reg[7:0]; + `ifdef verbose $display($time,"Dual Enqueing FIFO : data is %h",temp[0]); `endif + if(!first_read) + fifo.enq(1,temp); + count_byte=count_byte+1; + end + end + else if(ccr_dmode==3) begin // quad line mode + if(count_byte==data_length-1 && ccr_ddrm==1 && count_bits[0]=='b1) //To make sure that the Flash does not send any data the next half edge since ncs is made 1 after the second edge + ncs<=1; + if(rg_count_bits[0]=='b1)begin // multiple of eight bits have been read. + `ifdef verbose1 $display("Enquing FIFO"); `endif + Vector#(4,Bit#(8)) temp = newVector(); + temp[0]=data_reg[7:0]; + `ifdef verbose $display($time,"Quad Enqueing FIFO : data is %h",temp[0]); `endif + if(!first_read) + fifo.enq(1,temp); + count_byte=count_byte+1; + end + end + + bit smf=0; + `ifdef verbose $display("count_byte: %d data_length1: %d",count_byte,data_length1); `endif + /* condition for termination of dataread_phase */ + if(data_length1!='hFFFFFFFF)begin // if limit is not undefined + if(count_byte==data_length1)begin // if limit has bee reached. + `ifdef verbose $display($time,"Limit has reached: rg_count_bytes %h data_length %h",count_byte,data_length); `endif + if(ccr_fmode=='b10)begin // auto-status polling mode + if(cr_pmm==0)begin // ANDed mode + if((psmar&psmkr) == (psmkr&dr)) // is the unmasked bits match + smf=1; + else + smf=0; + end + else begin// ORed mode + let p=psmkr&dr; + let q=psmkr&psmar; + let r=~(p^q); + if(|(r)==1) + smf=1; + else + smf=0; + end + end + else if(ccr_fmode=='b11)begin// memory mapped mode + if(first_read) begin + `ifdef verbose $display("Sending response back to the proc data_reg: %h",data_reg); `endif + let r = AXI4_Lite_Rd_Data {rresp: AXI4_LITE_OKAY, rdata: duplicate(data_reg) , ruser: 0}; + s_xactor.i_rd_data.enq(r); + first_read <= False; + //rg_request_ready <= True; + end + end + let {x,y,z}<-change_phase.func(rg_phase,rg_count_bits,smf); + /* if(z==DataRead_phase) + read_true <= True;*/ + rg_phase<=z; + `ifdef verbose $display("rg_phase:",fshow(z),"sr_tcf: %d",y); `endif + sr_tcf<=y; // set completion of transfer flag + rg_count_bytes<=0; + rg_count_bits<=0; + end + else begin + rg_count_bytes<=count_byte; + rg_count_bits<=count_bits; + end + end + else if(dcr_fsize!='h1f)begin // if limit is not infinite + Bit#(32) new_limit=1<<(dcr_fsize); + `ifdef verbose1 $display("Sending completion -- newlimit : %h",new_limit); `endif + if(truncate(rg_count_bytes)==new_limit)begin // if reached end of Flash memory + let {x,y,z}<-change_phase.func(rg_phase,rg_count_bits,smf&cr_apms); + rg_phase<=z; + if(z==DataRead_phase) + read_true <= True; + sr_tcf<=y; // set completion of transfer flag + rg_count_bytes<=0; + rg_count_bits<=0; + end + else begin + rg_count_bytes<=count_byte; + rg_count_bits<=count_bits; + end + end + else begin // keep looping untill abort signal is not raised. + rg_count_bytes<=count_byte; + rg_count_bits<=count_bits; + end + dr<=data_reg; + sr_smf<=smf; + end + endrule + + /* write data from the FIFO to the FLASH. Simulataneously*/ + (*descending_urgency="rl_data_write_phase,rl_read_request_from_AXI"*) + (*descending_urgency="rl_data_write_phase,rl_write_request_from_AXI"*) + rule rl_data_write_phase(rg_phase==DataWrite_phase && transfer_cond && clock_cond && !qspi_flush); + if(half_cycle_delay) + half_cycle_delay<=False; + else begin + Bit#(8) data_reg=fifo.first()[0]; + Bit#(32) count_byte=rg_count_bytes; + Bit#(32) count_bits=rg_count_bits; + Bit#(4) enable_o=0; + /* write incoming bit to the data register */ + if(ccr_dmode==1)begin // single line mode; + enable_o=4'b1101; + rg_output<={1'b1,1'b0,1'b0,data_reg[rg_count_bits-1]}; + count_bits=count_bits-1; + end + else if(ccr_dmode==2)begin // dual line mode; + enable_o=4'b1111; + rg_output<={1'b1,1'b0,data_reg[rg_count_bits-1:rg_count_bits-2]}; + count_bits=count_bits-2; + end + else if(ccr_dmode==3) begin// quad line mode; + enable_o=4'b1111; + rg_output<=data_reg[rg_count_bits-1:rg_count_bits-4]; + count_bits=count_bits-4; + end + `ifdef verbose1 $display("Executing DataWrite Phase SPI Mode: %b DLR : %d Count_bits: %d Input :%b Enable: %b",ccr_dmode,dlr,rg_count_bits,rg_input,enable_o); `endif + + /* write the last successfully received byte into the FIFO */ + if(ccr_dmode==1)begin// single line mode + if(rg_count_bits==1)begin // multiple of eight bits have been read. + fifo.deq(1); + count_byte=count_byte+1; + count_bits=8; + end + end + else if(ccr_dmode==2) begin // dual line mode + if(rg_count_bits==2)begin // multiple of eight bits have been read. + fifo.deq(1); + count_byte=count_byte+1; + count_bits=8; + end + end + else if(ccr_dmode==3) begin // quad line mode + if(rg_count_bits==4)begin // multiple of eight bits have been read. + fifo.deq(1); + count_byte=count_byte+1; + count_bits=8; + end + end + + /* condition for termination of dataread_phase */ + if(dlr!='hFFFFFFFF)begin // if limit is not undefined + if(rg_count_bytes==dlr)begin // if limit has bee reached. + rg_phase<=Idle; + sr_tcf<=1; // set completion of transfer flag + rg_count_bytes<=0; + rg_count_bits<=0; + end + else begin + rg_count_bytes<=count_byte; + rg_count_bits<=count_bits; + end + end + else if(dcr_fsize!='h1f)begin // if limit is not infinite + Bit#(32) new_limit=1<<(dcr_fsize); + if(truncate(rg_count_bytes)==new_limit)begin // if reached end of Flash memory + rg_phase<=Idle; + sr_tcf<=1; // set completion of transfer flag + rg_count_bytes<=0; + rg_count_bits<=0; + end + else begin + rg_count_bytes<=count_byte; + rg_count_bits<=count_bits; + end + end + else begin // keep looping untill abort signal is not raised. + rg_count_bytes<=count_byte; + rg_count_bits<=count_bits; + end + rg_output_en<=enable_o; + end + endrule + + rule display_all_Registers; + `ifdef verbose1 $display($time,"\tPhase: ",fshow(rg_phase)," CR WRitten %d",wr_instruction_written, "Address Written: %d",wr_address_written); `endif + `ifdef verbose1 $display($time,"\tCR: %h\tDCR: %h\tSR: %h\tFCR: %h",cr,dcr,sr,fcr); `endif + `ifdef verbose1 $display($time,"\tDLR: %h\tCCR: %h\tAR: %h\tABR: %h",dlr,ccr,ar,abr); `endif + `ifdef verbose1 $display($time,"\tDR: %h\tPSMKR: %h\tPSMAR: %h\tPIR: %h",dr,psmkr,psmar,pir,"\n"); `endif + endrule + + `ifdef simulate + rule delay_phase(((wr_sdr_clock && ccr_ddrm==0) || (ddr_clock && ccr_ddrm==1))); + rg_phase_delayed<=rg_phase; + endrule + `endif + + interface QSPI_out out; + method bit clk_o; + return delay_ncs==1?dcr_ckmode:rg_clk; + endmethod + method Bit#(9) io0_sdio_ctrl; + return sdio0r[8:0]; + endmethod + method Bit#(9) io1_sdio_ctrl; + return sdio1r[8:0]; + endmethod + method Bit#(9) io2_sdio_ctrl; + return sdio2r[8:0]; + endmethod + method Bit#(9) io3_sdio_ctrl; + return sdio3r[8:0]; + endmethod + method Bit#(4) io_o; + return rg_output; + endmethod + method Bit#(4) io_enable; + return rg_output_en; + endmethod + method Action io_i (Bit#(4) io_in); // in + rg_input<=io_in; + endmethod + method bit ncs_o = ncs; + endinterface + + interface slave= s_xactor.axi_side; + + method Bit#(6) interrupts; // 0=TOF, 1=SMF, 2=Threshold, 3=TCF, 4=TEF 5=request_ready + return {pack(rg_request_ready),sr_tef&cr_teie, sr_tcf&cr_tcie, sr_ftf&cr_ftie, sr_smf&cr_smie , sr_tof&cr_toie}; + endmethod + `ifdef simulate method curphase = rg_phase_delayed; `endif + endmodule + +endpackage diff --git a/src/bsv/bsv_lib/qspi.defs b/src/bsv/bsv_lib/qspi.defs new file mode 100644 index 0000000..11738c5 --- /dev/null +++ b/src/bsv/bsv_lib/qspi.defs @@ -0,0 +1,19 @@ +`define CR 'h00 +`define DCR 'h04 +`define SR 'h08 +`define FCR 'h0c +`define DLR 'h10 +`define CCR 'h14 +`define AR 'h18 +`define ABR 'h1c +`define DR 'h20 +`define PSMKR 'h24 +`define PSMAR 'h28 +`define PIR 'h2c +`define LPTR 'h30 +`define SDIO0 'h34 +`define SDIO1 'h38 +`define SDIO2 'h3c +`define SDIO3 'h40 +`define STARTMM 'h0000000 +`define ENDMM 'hFFFFFFF