from litesata.common import * class K7LiteSATAPHYCRG(Module): def __init__(self, pads, gtx, speed, clk_freq): self.reset = Signal() self.ready = Signal() self.cd_sata_tx = ClockDomain() self.cd_sata_rx = ClockDomain() # CPLL # (SATA3) 150MHz / VCO @ 3GHz / Line rate @ 6Gbps # (SATA2 & SATA1) VCO still @ 3 GHz, Line rate is decreased with output dividers. refclk = Signal() self.specials += Instance("IBUFDS_GTE2", i_CEB=0, i_I=pads.refclk_p, i_IB=pads.refclk_n, o_O=refclk ) self.comb += gtx.gtrefclk0.eq(refclk) # TX clocking # (SATA3) 150MHz from CPLL TXOUTCLK, sata_tx clk @ 300MHz (16-bits) # (SATA2) 150MHz from CPLL TXOUTCLK, sata_tx clk @ 150MHz (16-bits) # (SATA1) 150MHz from CPLL TXOUTCLK, sata_tx clk @ 75MHz (16-bits) mmcm_reset = Signal() mmcm_locked = Signal() mmcm_fb = Signal() mmcm_clk_i = Signal() mmcm_clk0_o = Signal() mmcm_div_config = { "SATA1" : 16.0, "SATA2" : 8.0, "SATA3" : 4.0 } mmcm_div = mmcm_div_config[speed] self.specials += [ Instance("BUFG", i_I=gtx.txoutclk, o_O=mmcm_clk_i), Instance("MMCME2_ADV", p_BANDWIDTH="HIGH", p_COMPENSATION="ZHOLD", i_RST=mmcm_reset, o_LOCKED=mmcm_locked, # DRP i_DCLK=0, i_DEN=0, i_DWE=0, #o_DRDY=, i_DADDR=0, i_DI=0, #o_DO=, # VCO p_REF_JITTER1=0.01, p_CLKIN1_PERIOD=6.666, p_CLKFBOUT_MULT_F=8.000, p_CLKFBOUT_PHASE=0.000, p_DIVCLK_DIVIDE=1, i_CLKIN1=mmcm_clk_i, i_CLKFBIN=mmcm_fb, o_CLKFBOUT=mmcm_fb, # CLK0 p_CLKOUT0_DIVIDE_F=mmcm_div, p_CLKOUT0_PHASE=0.000, o_CLKOUT0=mmcm_clk0_o, ), Instance("BUFG", i_I=mmcm_clk0_o, o_O=self.cd_sata_tx.clk), ] self.comb += [ gtx.txusrclk.eq(self.cd_sata_tx.clk), gtx.txusrclk2.eq(self.cd_sata_tx.clk) ] # RX clocking # (SATA3) sata_rx recovered clk @ 300MHz from GTX RXOUTCLK # (SATA2) sata_rx recovered clk @ 150MHz from GTX RXOUTCLK # (SATA1) sata_rx recovered clk @ 150MHz from GTX RXOUTCLK self.specials += [ Instance("BUFG", i_I=gtx.rxoutclk, o_O=self.cd_sata_rx.clk), ] self.comb += [ gtx.rxusrclk.eq(self.cd_sata_rx.clk), gtx.rxusrclk2.eq(self.cd_sata_rx.clk) ] # Configuration Reset # After configuration, GTX's resets have to stay low for at least 500ns # See AR43482 reset_en = Signal() clk_period_ns = 1000000000/clk_freq reset_en_cnt_max = math.ceil(500/clk_period_ns) reset_en_cnt = Signal(max=reset_en_cnt_max, reset=reset_en_cnt_max-1) self.sync += \ If(self.reset, reset_en_cnt.eq(reset_en_cnt.reset) ).Elif(~reset_en, reset_en_cnt.eq(reset_en_cnt-1) ) self.comb += reset_en.eq(reset_en_cnt == 0) # TX Reset FSM tx_reset_fsm = InsertReset(FSM(reset_state="IDLE")) self.submodules += tx_reset_fsm self.comb += tx_reset_fsm.reset.eq(self.reset) tx_reset_fsm.act("IDLE", If(reset_en, NextState("RESET_GTX"), ) ) tx_reset_fsm.act("RESET_GTX", gtx.gttxreset.eq(1), If(gtx.cplllock & mmcm_locked, NextState("RELEASE_GTX") ) ) tx_reset_fsm.act("RELEASE_GTX", gtx.txuserrdy.eq(1), If(gtx.txresetdone, NextState("READY") ) ) tx_reset_fsm.act("READY", gtx.txuserrdy.eq(1) ) # RX Reset FSM rx_reset_fsm = InsertReset(FSM(reset_state="IDLE")) self.submodules += rx_reset_fsm self.comb += rx_reset_fsm.reset.eq(self.reset) rx_reset_fsm.act("IDLE", If(reset_en, NextState("RESET_GTX"), ) ) rx_reset_fsm.act("RESET_GTX", gtx.gtrxreset.eq(1), If(gtx.cplllock & mmcm_locked, NextState("RELEASE_GTX") ) ) rx_reset_fsm.act("RELEASE_GTX", gtx.rxuserrdy.eq(1), If(gtx.rxresetdone, NextState("READY") ) ) rx_reset_fsm.act("READY", gtx.rxuserrdy.eq(1) ) # Ready self.tx_ready = tx_reset_fsm.ongoing("READY") self.rx_ready = rx_reset_fsm.ongoing("READY") self.comb += self.ready.eq(self.tx_ready & self.rx_ready) # Reset PLL self.comb += gtx.cpllreset.eq(ResetSignal() | self.reset | ~reset_en) # Reset MMCM self.comb += mmcm_reset.eq(ResetSignal() | self.reset | ~gtx.cplllock) # Reset for SATA TX/RX clock domains self.specials += [ AsyncResetSynchronizer(self.cd_sata_tx, ~self.tx_ready), AsyncResetSynchronizer(self.cd_sata_rx, ~self.rx_ready), ]