package ifu import lib._ import chisel3._ import chisel3.util._ class el2_ifu_ifc_ctl extends Module with el2_lib with RequireAsyncReset { val io = IO(new Bundle{ val free_clk = Input(Clock()) val active_clk = Input(Clock()) val scan_mode = Input(Bool()) val ic_hit_f = Input(Bool()) val ifu_ic_mb_empty = Input(Bool()) val ifu_fb_consume1 = Input(Bool()) val ifu_fb_consume2 = Input(Bool()) val dec_tlu_flush_noredir_wb = Input(Bool()) val exu_flush_final = Input(Bool()) val exu_flush_path_final = Input(UInt(31.W)) val ifu_bp_hit_taken_f = Input(Bool()) val ifu_bp_btb_target_f = Input(UInt(31.W)) val ic_dma_active = Input(Bool()) val ic_write_stall = Input(Bool()) val dma_iccm_stall_any = Input(Bool()) val dec_tlu_mrac_ff = Input(UInt(32.W)) val ifc_fetch_addr_f = Output(UInt(31.W)) val ifc_fetch_addr_bf = Output(UInt(31.W)) val ifc_fetch_req_f = Output(Bool()) val ifu_pmu_fetch_stall = Output(Bool()) val ifc_fetch_uncacheable_bf = Output(Bool()) val ifc_fetch_req_bf = Output(Bool()) val ifc_fetch_req_bf_raw = Output(Bool()) val ifc_iccm_access_bf = Output(Bool()) val ifc_region_acc_fault_bf = Output(Bool()) val ifc_dma_access_ok = Output(Bool()) }) val fetch_addr_bf = WireInit(UInt(31.W), init = 0.U) val fetch_addr_next_0 = WireInit(Bool(), 0.U) val fetch_addr_next = WireInit(UInt(31.W), init = 0.U) val fb_write_ns = WireInit(UInt(4.W), init = 0.U) val fb_write_f = WireInit(UInt(4.W), init = 0.U) val fb_full_f_ns = WireInit(Bool(), init = 0.U) val fb_right = WireInit(Bool(), init = 0.U) val fb_right2 = WireInit(Bool(), init = 0.U) val fb_left = WireInit(Bool(), init = 0.U) val wfm = WireInit(Bool(), init = 0.U) val idle = WireInit(Bool(), init = 0.U) val miss_f = WireInit(Bool(), init = 0.U) val miss_a = WireInit(Bool(), init = 0.U) val flush_fb = WireInit(Bool(), init = 0.U) val mb_empty_mod = WireInit(Bool(), init = 0.U) val goto_idle = WireInit(Bool(), init = 0.U) val leave_idle = WireInit(Bool(), init = 0.U) val fetch_bf_en = WireInit(Bool(), init = 0.U) val line_wrap = WireInit(Bool(), init = 0.U) val state = WireInit(UInt(2.W), init = 0.U) val dma_iccm_stall_any_f = WireInit(Bool(), init = 0.U) val idle_E :: fetch_E :: stall_E :: wfm_E :: Nil = Enum(4) val dma_stall = io.ic_dma_active | dma_iccm_stall_any_f dma_iccm_stall_any_f := withClock(io.free_clk) {RegNext(io.dma_iccm_stall_any, init=0.U)} miss_a := withClock(io.free_clk) {RegNext(miss_f, init=0.U)} val sel_last_addr_bf = !io.exu_flush_final & (!io.ifc_fetch_req_f | !io.ic_hit_f) val sel_btb_addr_bf = !io.exu_flush_final & io.ifc_fetch_req_f & io.ifu_bp_hit_taken_f & io.ic_hit_f val sel_next_addr_bf = !io.exu_flush_final & io.ifc_fetch_req_f & !io.ifu_bp_hit_taken_f & io.ic_hit_f // TODO: Make an assertion for the 1H-Mux under here io.ifc_fetch_addr_bf := Mux1H(Seq(io.exu_flush_final.asBool -> io.exu_flush_path_final, // Replay PC sel_last_addr_bf.asBool -> io.ifc_fetch_addr_f, // Hold the current PC sel_btb_addr_bf.asBool -> io.ifu_bp_btb_target_f, // Take the predicted PC sel_next_addr_bf.asBool -> fetch_addr_next)) // PC+4 val address_upper = io.ifc_fetch_addr_f(30,1)+1.U fetch_addr_next_0 := !(address_upper(ICACHE_TAG_INDEX_LO-2) ^ io.ifc_fetch_addr_f(ICACHE_TAG_INDEX_LO-1)) & io.ifc_fetch_addr_f(0) fetch_addr_next := Cat(address_upper, fetch_addr_next_0) io.ifc_fetch_req_bf_raw := ~idle io.ifc_fetch_req_bf := io.ifc_fetch_req_bf_raw & !(fb_full_f_ns & !(io.ifu_fb_consume2 | io.ifu_fb_consume1)) & !dma_stall & !io.ic_write_stall & !io.dec_tlu_flush_noredir_wb fetch_bf_en := io.exu_flush_final | io.ifc_fetch_req_f miss_f := io.ifc_fetch_req_f & !io.ic_hit_f & !io.exu_flush_final mb_empty_mod := (io.ifu_ic_mb_empty | io.exu_flush_final) & !dma_stall & !miss_f & !miss_a goto_idle := io.exu_flush_final & io.dec_tlu_flush_noredir_wb leave_idle := io.exu_flush_final & !io.dec_tlu_flush_noredir_wb & idle val next_state_1 = (!state(1) & state(0) & miss_f & !goto_idle) | (state(1) & !mb_empty_mod & !goto_idle) val next_state_0 = (!goto_idle & leave_idle) | (state(0) & !goto_idle) state := withClock(io.active_clk) {RegNext(Cat(next_state_1, next_state_0), init = 0.U)} flush_fb := io.exu_flush_final fb_right := ( io.ifu_fb_consume1 & !io.ifu_fb_consume2 & (!io.ifc_fetch_req_f | miss_f)) | (io.ifu_fb_consume2 & io.ifc_fetch_req_f) fb_right2 := (io.ifu_fb_consume2 & (~io.ifc_fetch_req_f | miss_f)) fb_left := io.ifc_fetch_req_f & !(io.ifu_fb_consume1 | io.ifu_fb_consume2) & !miss_f fb_write_ns := Mux1H(Seq(flush_fb.asBool -> 1.U(4.W), (!flush_fb & fb_right).asBool -> Cat(0.U(1.W), fb_write_f(3,1)), (!flush_fb & fb_right2).asBool -> Cat(0.U(2.W), fb_write_f(3,2)), (!flush_fb & fb_left).asBool -> Cat(fb_write_f(2,0), 0.U(1.W)), (!flush_fb & !fb_right & !fb_right2 & !fb_left).asBool -> fb_write_f(3,0) )) idle := state === 0.U(2.W) wfm := state === 3.U(2.W) fb_full_f_ns := fb_write_ns(3) val fb_full_f = withClock(io.active_clk) {RegNext(fb_full_f_ns, init = 0.U)} fb_write_f := withClock(io.active_clk) {RegNext(fb_write_ns, 0.U)} io.ifu_pmu_fetch_stall := wfm | (io.ifc_fetch_req_bf_raw & ((fb_full_f & !(io.ifu_fb_consume2 | io.ifu_fb_consume1 | io.exu_flush_final)) | dma_stall)) val (iccm_acc_in_region_bf, iccm_acc_in_range_bf) = if(ICCM_ENABLE) rvrangecheck(ICCM_SADR, ICCM_SIZE, Cat(io.ifc_fetch_addr_bf,0.U)) else (0.U, 0.U) io.ifc_iccm_access_bf := iccm_acc_in_range_bf io.ifc_dma_access_ok := ( (!io.ifc_iccm_access_bf | (fb_full_f & !(io.ifu_fb_consume2 | io.ifu_fb_consume1)) | (wfm & !io.ifc_fetch_req_bf) | idle ) & !io.exu_flush_final) | dma_iccm_stall_any_f io.ifc_region_acc_fault_bf := !iccm_acc_in_range_bf & iccm_acc_in_region_bf io.ifc_fetch_uncacheable_bf := ~io.dec_tlu_mrac_ff(Cat(io.ifc_fetch_addr_bf(30,27), 0.U)) io.ifc_fetch_req_f := withClock(io.active_clk){RegNext(io.ifc_fetch_req_bf, init=0.U)} io.ifc_fetch_addr_f := rvdffe(io.ifc_fetch_addr_bf, io.exu_flush_final|io.ifc_fetch_req_f, clock, io.scan_mode) //rvdffe(io.ifc_fetch_addr_bf,(io.exu_flush_final|io.ifc_fetch_req_f).asBool,clock,io.scan_mode) } object ifu_ifc extends App { println((new chisel3.stage.ChiselStage).emitVerilog(new el2_ifu_ifc_ctl())) }