Commit 28b974c3 authored by Andrey Filippov's avatar Andrey Filippov

continue on C exporting

parent fcd19b51
...@@ -85,7 +85,7 @@ ...@@ -85,7 +85,7 @@
// 0x1030..1031 - MCONTR_EN // 0 bits, disable/enable memory controller // 0x1030..1031 - MCONTR_EN // 0 bits, disable/enable memory controller
// 0x1032..1033 - REFRESH_EN // 0 bits, disable/enable memory refresh // 0x1032..1033 - REFRESH_EN // 0 bits, disable/enable memory refresh
// 0x1034..1037 - reserved // 0x1034..1037 - reserved
parameter MCONTR_TOP_0BIT_MCONTR_EN = 'h0, // set pre-programmed delays parameter MCONTR_TOP_0BIT_MCONTR_EN = 'h0, // disable/enable memory controller
parameter MCONTR_TOP_0BIT_REFRESH_EN = 'h2, // disable/enable command/address outputs parameter MCONTR_TOP_0BIT_REFRESH_EN = 'h2, // disable/enable command/address outputs
//0x1040..107f - 16-bit data //0x1040..107f - 16-bit data
// 0x1040..104f - RUN_CHN // address to set sequncer channel and run (4 LSB-s - channel) - bits? // 0x1040..104f - RUN_CHN // address to set sequncer channel and run (4 LSB-s - channel) - bits?
......
...@@ -220,13 +220,97 @@ class X393ExportC(object): ...@@ -220,13 +220,97 @@ class X393ExportC(object):
name = "x393_mcntr_dqs_dqm_tri_rw", name = "x393_mcntr_dqs_dqm_tri_rw",
frmt_spcs = frmt_spcs) frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "DDR3 memory controller I/O delay",
data = self._enc_mcntrl_dly(),
name = "x393_dly_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Extra delay in mclk (fDDR/2) cycles) to data write buffer",
data = self._enc_wbuf_dly(),
name = "x393_wbuf_dly_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Control for the gamma-conversion module",
data = self._enc_gamma_ctl(),
name = "x393_gamma_ctl_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Write gamma table address/data",
data = [self._enc_gamma_tbl_addr(), # generate typedef union
self._enc_gamma_tbl_data()],
name = "x393_gamma_tbl_wo",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Heights of the first two subchannels frames",
data = self._enc_gamma_height01(),
name = "x393_gamma_height01m1_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Height of the third subchannel frame",
data = self._enc_gamma_height2(),
name = "x393_gamma_height2m1_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Sensor port I/O control",
data = [self._enc_sensio_ctrl_par12(),
self._enc_sensio_ctrl_hispi()],
name = "x393_sensio_ctl_wo",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Programming interface for multiplexer FPGA",
data = self._enc_sensio_jtag(),
name = "x393_sensio_jpag_wo",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Sensor delays (uses 4 DWORDs)",
data = [self._enc_sensio_dly_par12(),
self._enc_sensio_dly_hispi()],
name = "x393_sensio_dly_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Set sensor frame width (0 - use received)",
data = self._enc_sensio_width(),
name = "x393_sensio_width_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Lens vignetting parameter (write address first, then data that may overlap som address bits)",
data = [self._enc_lens_addr(),
self._enc_lens_ax(),
self._enc_lens_ay(),
self._enc_lens_bx(),
self._enc_lens_by(),
self._enc_lens_c(),
self._enc_lens_scale(),
self._enc_lens_fatzero_in(),
self._enc_lens_fatzero_out(),
self._enc_lens_post_scale()],
name = "x393_lens_corr_wo",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Height of the subchannel frame for vignetting correction",
data = self._enc_lens_height_m1(),
name = "x393_lens_height_m1_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Histogram window left/top margins",
data = self._enc_histogram_lt(),
name = "x393_hist_left_top_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Histogram window width and height minus 1 (0 use full)",
data = self._enc_histogram_wh_m1(),
name = "x393_hist_width_height_m1_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Histograms DMA mode",
data = self._enc_hist_saxi_mode(),
name = "x393_hist_saxi_mode_rw",
frmt_spcs = frmt_spcs)
stypedefs += self.get_typedef32(comment = "Histograms DMA addresses",
data = self._enc_hist_saxi_page_addr(),
name = "x393_hist_saxi_addr_rw",
frmt_spcs = frmt_spcs)
return stypedefs return stypedefs
def define_macros(self): def define_macros(self):
#memory arbiter priorities #memory arbiter priorities
ba = vrlg.CONTROL_ADDR ba = vrlg.CONTROL_ADDR
z3= (0,3) z3= (0,3)
z7 = (0,7)
z15= (0,15) z15= (0,15)
z31= (0,31)
ia = 1 ia = 1
c = "chn" c = "chn"
sdefines = [] sdefines = []
...@@ -239,19 +323,37 @@ class X393ExportC(object): ...@@ -239,19 +323,37 @@ class X393ExportC(object):
(("X393_MCNTRL_CHN_EN", c, vrlg.MCONTR_TOP_16BIT_ADDR + vrlg.MCONTR_TOP_16BIT_CHN_EN + ba, 0, None, "x393_mcntr_chn_en_rw", "Enable/disable memory channels (currently r/w, may become just wo)")), (("X393_MCNTRL_CHN_EN", c, vrlg.MCONTR_TOP_16BIT_ADDR + vrlg.MCONTR_TOP_16BIT_CHN_EN + ba, 0, None, "x393_mcntr_chn_en_rw", "Enable/disable memory channels (currently r/w, may become just wo)")),
(("X393_MCNTRL_DQS_DQM_PATT",c, vrlg.MCONTR_PHY_16BIT_ADDR+ vrlg.MCONTR_PHY_16BIT_PATTERNS + ba, 0, None, "x393_mcntr_dqs_dqm_patt_rw", "Setup DQS and DQM patterns")), (("X393_MCNTRL_DQS_DQM_PATT",c, vrlg.MCONTR_PHY_16BIT_ADDR+ vrlg.MCONTR_PHY_16BIT_PATTERNS + ba, 0, None, "x393_mcntr_dqs_dqm_patt_rw", "Setup DQS and DQM patterns")),
(("X393_MCNTRL_DQ_DQS_TRI", c, vrlg.MCONTR_PHY_16BIT_ADDR + vrlg.MCONTR_PHY_16BIT_PATTERNS_TRI+ ba, 0, None, "x393_mcntr_dqs_dqm_tri_rw", "Setup DQS and DQ on/off sequence")), (("X393_MCNTRL_DQ_DQS_TRI", c, vrlg.MCONTR_PHY_16BIT_ADDR + vrlg.MCONTR_PHY_16BIT_PATTERNS_TRI+ ba, 0, None, "x393_mcntr_dqs_dqm_tri_rw", "Setup DQS and DQ on/off sequence")),
(("Following enable/disable addresses can be written with any data,only addresses matter",)), (("Following enable/disable addresses can be written with any data, only addresses matter",)),
(("X393_MCNTRL_DIS", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_MCONTR_EN + ba + 0, 0, None, "", "Disable DDR3 memory controller")), (("X393_MCNTRL_DIS", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_MCONTR_EN + ba + 0, 0, None, "", "Disable DDR3 memory controller")),
(("X393_MCNTRL_EN", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_MCONTR_EN + ba + 1, 0, None, "", "Enable DDR3 memory controller")), (("X393_MCNTRL_EN", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_MCONTR_EN + ba + 1, 0, None, "", "Enable DDR3 memory controller")),
(("X393_MCNTRL_REFRESH_DIS",c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_REFRESH_EN + ba + 0, 0, None, "", "Disable DDR3 memory refresh")), (("X393_MCNTRL_REFRESH_DIS",c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_REFRESH_EN + ba + 0, 0, None, "", "Disable DDR3 memory refresh")),
(("X393_MCNTRL_REFRESH_EN", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_REFRESH_EN + ba + 1, 0, None, "", "Enable DDR3 memory refresh")), (("X393_MCNTRL_REFRESH_EN", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_REFRESH_EN + ba + 1, 0, None, "", "Enable DDR3 memory refresh")),
(("X393_MCNTRL_SDRST_DIS", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_SDRST_ACT + ba + 0, 0, None, "", "Disable DDR3 memory reset")), (("X393_MCNTRL_SDRST_DIS", c, vrlg.MCONTR_PHY_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_SDRST_ACT + ba + 0, 0, None, "", "Disable DDR3 memory reset")),
(("X393_MCNTRL_SDRST_EN", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_SDRST_ACT + ba + 1, 0, None, "", "Enable DDR3 memory reset")), (("X393_MCNTRL_SDRST_EN", c, vrlg.MCONTR_PHY_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_SDRST_ACT + ba + 1, 0, None, "", "Enable DDR3 memory reset")),
(("X393_MCNTRL_CKE_DIS", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_CKE_EN + ba + 0, 0, None, "", "Disable DDR3 memory CKE")), (("X393_MCNTRL_CKE_DIS", c, vrlg.MCONTR_PHY_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_CKE_EN + ba + 0, 0, None, "", "Disable DDR3 memory CKE")),
(("X393_MCNTRL_CKE_EN", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_CKE_EN + ba + 1, 0, None, "", "Enable DDR3 memory CKE")), (("X393_MCNTRL_CKE_EN", c, vrlg.MCONTR_PHY_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_CKE_EN + ba + 1, 0, None, "", "Enable DDR3 memory CKE")),
(("X393_MCNTRL_CMDA_DIS", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_CMDA_EN + ba + 0, 0, None, "", "Disable DDR3 memory command/address lines")), (("X393_MCNTRL_CMDA_DIS", c, vrlg.MCONTR_PHY_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_CMDA_EN + ba + 0, 0, None, "", "Disable DDR3 memory command/address lines")),
(("X393_MCNTRL_CMDA_EN", c, vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_CMDA_EN + ba + 1, 0, None, "", "Enable DDR3 memory command/address lines")), (("X393_MCNTRL_CMDA_EN", c, vrlg.MCONTR_PHY_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_CMDA_EN + ba + 1, 0, None, "", "Enable DDR3 memory command/address lines")),
]
ba = vrlg.CONTROL_ADDR
#"x393_dly_rw"
sdefines +=[
(('Set DDR3 memory controller I/O delays and other timing parameters (should use individually calibrated values)',)),
(("X393_MCNTRL_DQ_ODLY0", c, vrlg.LD_DLY_LANE0_ODELAY + ba, 1, z7, "x393_dly_rw", "Lane0 DQ output delays ")),
(("X393_MCNTRL_DQ_ODLY1", c, vrlg.LD_DLY_LANE1_ODELAY + ba, 1, z7, "x393_dly_rw", "Lane1 DQ output delays ")),
(("X393_MCNTRL_DQ_IDLY0", c, vrlg.LD_DLY_LANE0_IDELAY + ba, 1, z7, "x393_dly_rw", "Lane0 DQ input delays ")),
(("X393_MCNTRL_DQ_IDLY1", c, vrlg.LD_DLY_LANE1_IDELAY + ba, 1, z7, "x393_dly_rw", "Lane1 DQ input delays ")),
(("X393_MCNTRL_DQS_ODLY0", c, vrlg.LD_DLY_LANE0_ODELAY + ba + 8, 0, None, "x393_dly_rw", "Lane0 DQS output delay ")),
(("X393_MCNTRL_DQS_ODLY1", c, vrlg.LD_DLY_LANE1_ODELAY + ba + 8, 0, None, "x393_dly_rw", "Lane1 DQS output delay ")),
(("X393_MCNTRL_DQS_IDLY0", c, vrlg.LD_DLY_LANE0_IDELAY + ba + 8, 0, None, "x393_dly_rw", "Lane0 DQS input delay ")),
(("X393_MCNTRL_DQS_IDLY1", c, vrlg.LD_DLY_LANE1_IDELAY + ba + 8, 0, None, "x393_dly_rw", "Lane1 DQS input delay ")),
(("X393_MCNTRL_DM_ODLY0", c, vrlg.LD_DLY_LANE0_ODELAY + ba + 9, 0, None, "x393_dly_rw", "Lane0 DM output delay ")),
(("X393_MCNTRL_DM_ODLY1", c, vrlg.LD_DLY_LANE1_ODELAY + ba + 9, 0, None, "x393_dly_rw", "Lane1 DM output delay ")),
(("X393_MCNTRL_CMDA_ODLY", c, vrlg.LD_DLY_CMDA + ba, 1, z31, "x393_dly_rw", "Address, bank and commands delays")),
(("X393_MCNTRL_CMDA_ODLY", c, vrlg.LD_DLY_PHASE + ba, 0, None, "x393_dly_rw", "Clock phase")),
(("X393_MCNTRL_DLY_SET", c, vrlg.MCONTR_PHY_0BIT_ADDR + vrlg.MCONTR_PHY_0BIT_DLY_SET + ba, 0, None, "", "Set all pre-programmed delays")),
(("X393_MCNTRL_WBUF_DLY", c, vrlg.MCONTR_PHY_16BIT_ADDR + vrlg.MCONTR_PHY_16BIT_WBUF_DELAY + ba, 0, None, "x393_wbuf_dly_rw", "Set write buffer delay")),
] ]
ba = vrlg.MCONTR_SENS_BASE ba = vrlg.MCONTR_SENS_BASE
ia = vrlg.MCONTR_SENS_INC ia = vrlg.MCONTR_SENS_INC
c = "chn" c = "chn"
...@@ -323,7 +425,7 @@ class X393ExportC(object): ...@@ -323,7 +425,7 @@ class X393ExportC(object):
ia = 0 ia = 0
c = "" c = ""
sdefines +=[ sdefines +=[
(('Write-only addresses to to program status report mode For memory controller',)), (('Write-only addresses to to program status report mode for memory controller',)),
(("X393_MCONTR_PHY_STATUS_CNTRL", c, vrlg.MCONTR_PHY_STATUS_CNTRL + ba, 0, None, "x393_status_ctrl_wo", "Set status control register (status update mode)")), (("X393_MCONTR_PHY_STATUS_CNTRL", c, vrlg.MCONTR_PHY_STATUS_CNTRL + ba, 0, None, "x393_status_ctrl_wo", "Set status control register (status update mode)")),
(("X393_MCONTR_TOP_16BIT_STATUS_CNTRL", c, vrlg.MCONTR_TOP_16BIT_STATUS_CNTRL + ba, 0, None, "x393_status_ctrl_wo", "Set status control register (status update mode)")), (("X393_MCONTR_TOP_16BIT_STATUS_CNTRL", c, vrlg.MCONTR_TOP_16BIT_STATUS_CNTRL + ba, 0, None, "x393_status_ctrl_wo", "Set status control register (status update mode)")),
] ]
...@@ -371,7 +473,99 @@ class X393ExportC(object): ...@@ -371,7 +473,99 @@ class X393ExportC(object):
(("X393_SENSI2C_STATUS", c, vrlg.SENSI2C_CTRL_RADDR + vrlg.SENSI2C_STATUS + ba, ia, z3, "x393_status_ctrl_wo", "Setup sensor i2c status report mode")), (("X393_SENSI2C_STATUS", c, vrlg.SENSI2C_CTRL_RADDR + vrlg.SENSI2C_STATUS + ba, ia, z3, "x393_status_ctrl_wo", "Setup sensor i2c status report mode")),
(("X393_SENS_SYNC_MULT", c, vrlg.SENS_SYNC_RADDR + vrlg.SENS_SYNC_MULT+ ba, ia, z3, "x393_sens_sync_mult_wo", "Configure frames combining")), (("X393_SENS_SYNC_MULT", c, vrlg.SENS_SYNC_RADDR + vrlg.SENS_SYNC_MULT+ ba, ia, z3, "x393_sens_sync_mult_wo", "Configure frames combining")),
(("X393_SENS_SYNC_LATE", c, vrlg.SENS_SYNC_RADDR + vrlg.SENS_SYNC_LATE+ ba, ia, z3, "x393_sens_sync_late_wo", "Configure frame sync delay")), (("X393_SENS_SYNC_LATE", c, vrlg.SENS_SYNC_RADDR + vrlg.SENS_SYNC_LATE+ ba, ia, z3, "x393_sens_sync_late_wo", "Configure frame sync delay")),
(("X393_SENSIO_CTRL", c, vrlg.SENSIO_RADDR + vrlg.SENSIO_CTRL+ ba, ia, z3, "x393_sensio_ctl_wo", "Configure sensor I/O port")),
(("X393_SENSIO_STATUS_CNTRL", c, vrlg.SENSIO_RADDR + vrlg.SENSIO_STATUS+ ba, ia, z3, "x393_status_ctrl_wo", "Set status control for SENSIO module")),
(("X393_SENSIO_JTAG", c, vrlg.SENSIO_RADDR + vrlg.SENSIO_JTAG+ ba, ia, z3, "x393_sensio_jpag_wo", "Programming interface for multiplexer FPGA (with X393_SENSIO_STATUS)")),
(("X393_SENSIO_WIDTH", c, vrlg.SENSIO_RADDR + vrlg.SENSIO_WIDTH+ ba, ia, z3, "x393_sensio_width_rw", "Set sensor line in pixels (0 - use line sync from the sensor)")),
(("X393_SENSIO_DELAYS", c, vrlg.SENSIO_RADDR + vrlg.SENSIO_DELAYS+ ba, ia, z3, "x393_sensio_dly_rw", "Sensor port input delays (uses 4 DWORDs)")),
] ]
#Registers to control sensor channels
ba = vrlg.SENSOR_GROUP_ADDR
ia = vrlg.SENSOR_BASE_INC
c = "sens_num"
sdefines +=[
(('''I2C command sequencer, block of 16 DWORD slots for absolute frame numbers (modulo 16) and 15 slots for relative ones
// 0 - ASAP, 1 next frame, 14 -14-th next.
// Data written depends on context:
// 1 - I2C register write: index page (MSB), 3 payload bytes. Payload bytes are used according to table and sent
// after the slave address and optional high address byte. Other bytes are sent in descending order (LSB- last).
// If less than 4 bytes are programmed in the table the high bytes (starting with the one from the table) are
// skipped.
// If more than 4 bytes are programmed in the table for the page (high byte), one or two next 32-bit words
// bypass the index table and all 4 bytes are considered payload ones. If less than 4 extra bytes are to be
// sent for such extra word, only the lower bytes are sent.
//
// 2 - I2C register read: index page, slave address (8-bit, with lower bit 0) and one or 2 address bytes (as programmed
// in the table. Slave address is always in byte 2 (bits 23:16), byte1 (high register address) is skipped if
// read address in the table is programmed to be a single-byte one''',)),
(("X393_SENSI2C_ABS", c, vrlg.SENSI2C_ABS_RADDR + ba, ia, z3, "u32*", "Write sensor i2c sequencer")),
(("X393_SENSI2C_REL", c, vrlg.SENSI2C_REL_RADDR + ba, ia, z3, "u32*", "Write sensor i2c sequencer")),
]
#Lens vignetting correction
ba = vrlg.SENSOR_GROUP_ADDR + vrlg.SENS_LENS_RADDR
ia = vrlg.SENSOR_BASE_INC
c = "sens_num"
sdefines +=[
(('Lens vignetting correction (for each sub-frame separately)',)),
(("X393_LENS_HEIGHT0_M1", c, 0 + ba, ia, z3, "x393_lens_height_m1_rw", "Subframe 0 height minus 1")),
(("X393_LENS_HEIGHT1_M1", c, 1 + ba, ia, z3, "x393_lens_height_m1_rw", "Subframe 1 height minus 1")),
(("X393_LENS_HEIGHT2_M1", c, 2 + ba, ia, z3, "x393_lens_height_m1_rw", "Subframe 2 height minus 1")),
(("X393_LENS_CORR_CNH_ADDR_DATA", c, vrlg.SENS_LENS_COEFF + ba, ia, z3, "x393_lens_corr_wo", "Combined address/data to write lens vignetting correction coefficients")),
(('Lens vignetting coefficient addresses - use with x393_lens_corr_wo_t (X393_LENS_CORR_CNH_ADDR_DATA)',)),
(("X393_LENS_AX", "", vrlg.SENS_LENS_AX , 0, None, None, "Address of correction parameter Ax")),
(("X393_LENS_AX_MASK", "", vrlg.SENS_LENS_AX_MASK , 0, None, None, "Correction parameter Ax mask")),
(("X393_LENS_AY", "", vrlg.SENS_LENS_AY , 0, None, None, "Address of correction parameter Ay")),
(("X393_LENS_AY_MASK", "", vrlg.SENS_LENS_AY_MASK , 0, None, None, "Correction parameter Ay mask")),
(("X393_LENS_C", "", vrlg.SENS_LENS_C , 0, None, None, "Address of correction parameter C")),
(("X393_LENS_C_MASK", "", vrlg.SENS_LENS_C_MASK , 0, None, None, "Correction parameter C mask")),
(("X393_LENS_BX", "", vrlg.SENS_LENS_BX , 0, None, None, "Address of correction parameter Bx")),
(("X393_LENS_BX_MASK", "", vrlg.SENS_LENS_BX_MASK , 0, None, None, "Correction parameter Bx mask")),
(("X393_LENS_BY", "", vrlg.SENS_LENS_BY , 0, None, None, "Address of correction parameter By")),
(("X393_LENS_BY_MASK", "", vrlg.SENS_LENS_BY_MASK , 0, None, None, "Correction parameter By mask")),
(("X393_LENS_SCALE0", "", vrlg.SENS_LENS_SCALES , 0, None, None, "Address of correction parameter scale0")),
(("X393_LENS_SCALE1", "", vrlg.SENS_LENS_SCALES + 2 , 0, None, None, "Address of correction parameter scale1")),
(("X393_LENS_SCALE2", "", vrlg.SENS_LENS_SCALES + 4 , 0, None, None, "Address of correction parameter scale2")),
(("X393_LENS_SCALE3", "", vrlg.SENS_LENS_SCALES + 6 , 0, None, None, "Address of correction parameter scale3")),
(("X393_LENS_SCALES_MASK", "", vrlg.SENS_LENS_SCALES_MASK , 0, None, None, "Common mask for scales")),
(("X393_LENS_FAT0_IN", "", vrlg.SENS_LENS_FAT0_IN , 0, None, None, "Address of input fat zero parameter (to subtract from input)")),
(("X393_LENS_FAT0_IN_MASK", "", vrlg.SENS_LENS_FAT0_IN_MASK , 0, None, None, "Mask for fat zero input parameter")),
(("X393_LENS_FAT0_OUT", "", vrlg.SENS_LENS_FAT0_OUT, 0, None, None, "Address of output fat zero parameter (to add to output)")),
(("X393_LENS_FAT0_OUT_MASK", "", vrlg.SENS_LENS_FAT0_OUT_MASK , 0, None, None, "Mask for fat zero output parameters")),
(("X393_LENS_POST_SCALE", "", vrlg.SENS_LENS_POST_SCALE , 0, None, None, "Address of post scale (shift output) parameter")),
(("X393_LENS_POST_SCALE_MASK","", vrlg.SENS_LENS_POST_SCALE_MASK, 0, None, None, "Mask for post scale parameter"))]
#Gamma tables (See Python code for examples of the table data generation)
ba = vrlg.SENSOR_GROUP_ADDR + vrlg.SENS_GAMMA_RADDR
ia = vrlg.SENSOR_BASE_INC
c = "sens_num"
sdefines +=[
(('Sensor gamma conversion control (See Python code for examples of the table data generation)',)),
(("X393_SENS_GAMMA_CTRL", c, vrlg.SENS_GAMMA_CTRL + ba, ia, z3, "x393_gamma_ctl_rw", "Gamma module control")),
(("X393_SENS_GAMMA_TBL", c, vrlg.SENS_GAMMA_ADDR_DATA + ba, ia, z3, "x393_gamma_tbl_wo", "Write sensor gamma table address/data (with autoincrement)")),
(("X393_SENS_GAMMA_HEIGHT01M1", c, vrlg.SENS_GAMMA_HEIGHT01 + ba, ia, z3, "x393_gamma_height01m1_rw", "Gamma module subframes 0,1 heights minus 1")),
(("X393_SENS_GAMMA_HEIGHT2M1", c, vrlg.SENS_GAMMA_HEIGHT2 + ba, ia, z3, "x393_gamma_height2m1_rw", "Gamma module subframe 2 height minus 1"))]
#Histogram window controls
ba = vrlg.SENSOR_GROUP_ADDR
ia = vrlg.SENSOR_BASE_INC
c = "sens_num"
sdefines +=[
(('Windows for histogram subchannels',)),
(("X393_HISTOGRAM_LT0", c, vrlg.HISTOGRAM_RADDR0 + ba, ia, z3, "x393_hist_left_top_rw", "Specify histogram 0 left/top")),
(("X393_HISTOGRAM_WH0", c, vrlg.HISTOGRAM_RADDR0 + 1 + ba, ia, z3, "x393_hist_width_height_m1_rw", "Specify histogram 0 width/height")),
(("X393_HISTOGRAM_LT1", c, vrlg.HISTOGRAM_RADDR1 + ba, ia, z3, "x393_hist_left_top_rw", "Specify histogram 1 left/top")),
(("X393_HISTOGRAM_WH1", c, vrlg.HISTOGRAM_RADDR1 + 1 + ba, ia, z3, "x393_hist_width_height_m1_rw", "Specify histogram 1 width/height")),
(("X393_HISTOGRAM_LT2", c, vrlg.HISTOGRAM_RADDR2 + ba, ia, z3, "x393_hist_left_top_rw", "Specify histogram 2 left/top")),
(("X393_HISTOGRAM_WH2", c, vrlg.HISTOGRAM_RADDR2 + 1 + ba, ia, z3, "x393_hist_width_height_m1_rw", "Specify histogram 2 width/height")),
(("X393_HISTOGRAM_LT3", c, vrlg.HISTOGRAM_RADDR3 + ba, ia, z3, "x393_hist_left_top_rw", "Specify histogram 3 left/top")),
(("X393_HISTOGRAM_WH3", c, vrlg.HISTOGRAM_RADDR3 + 1 + ba, ia, z3, "x393_hist_width_height_m1_rw", "Specify histogram 3 width/height"))]
ba = vrlg.SENSOR_GROUP_ADDR
ia = vrlg.SENSOR_BASE_INC
c = "subchannel"
sdefines +=[
(('DMA control for the histograms. Subchannel here is 4*sensor_port+ histogram_subchannel',)),
(("X393_HIST_SAXI_MODE", c, vrlg.HIST_SAXI_MODE_ADDR_REL + ba, 0, None, "x393_hist_saxi_mode_rw", "Histogram DMA operation mode")),
(("X393_HIST_SAXI_ADDR", c, vrlg.HIST_SAXI_ADDR_REL + ba, ia, z15, "x393_hist_saxi_addr_rw", "Histogram DMA addresses (in 4096 byte pages)"))]
#sensors status #sensors status
ba = vrlg.STATUS_ADDR + vrlg.SENSI2C_STATUS_REG_BASE ba = vrlg.STATUS_ADDR + vrlg.SENSI2C_STATUS_REG_BASE
...@@ -384,7 +578,6 @@ class X393ExportC(object): ...@@ -384,7 +578,6 @@ class X393ExportC(object):
] ]
""" """
""" """
return sdefines return sdefines
...@@ -431,23 +624,30 @@ class X393ExportC(object): ...@@ -431,23 +624,30 @@ class X393ExportC(object):
(("X393_MCNTRL_CHN4_TILED_WINDOW_X0Y0", c, vrlg.MCNTRL_TILED_WINDOW_X0Y0 + ba, 0, None, "x393_mcntrl_window_left_top_wo", "Set frame position")), (("X393_MCNTRL_CHN4_TILED_WINDOW_X0Y0", c, vrlg.MCNTRL_TILED_WINDOW_X0Y0 + ba, 0, None, "x393_mcntrl_window_left_top_wo", "Set frame position")),
(("X393_MCNTRL_CHN4_TILED_STARTXY", c, vrlg.MCNTRL_TILED_WINDOW_STARTXY + ba, 0, None, "x393_mcntrl_window_startx_starty_wo", "Set startXY register")), (("X393_MCNTRL_CHN4_TILED_STARTXY", c, vrlg.MCNTRL_TILED_WINDOW_STARTXY + ba, 0, None, "x393_mcntrl_window_startx_starty_wo", "Set startXY register")),
(("X393_MCNTRL_CHN4_TILED_TILE_WHS", c, vrlg.MCNTRL_TILED_TILE_WHS + ba, 0, None, "x393_mcntrl_window_tile_whs_wo", "Set tile size/step (tiled mode only)"))] (("X393_MCNTRL_CHN4_TILED_TILE_WHS", c, vrlg.MCNTRL_TILED_TILE_WHS + ba, 0, None, "x393_mcntrl_window_tile_whs_wo", "Set tile size/step (tiled mode only)"))]
return sdefines return sdefines
def expand_define_maxi0(self, define_tuple, frmt_spcs = None): def expand_define_maxi0(self, define_tuple, frmt_spcs = None):
if len(define_tuple) ==1 : if len(define_tuple) ==1 :
return self.expand_define(define_tuple = define_tuple, frmt_spcs = frmt_spcs) return self.expand_define(define_tuple = define_tuple, frmt_spcs = frmt_spcs)
else: else:
return self.expand_define(define_tuple = (define_tuple[0], name, var_name, address, address_inc, var_range, data_type, comment = define_tuple
define_tuple[1], if data_type is None:
define_tuple[2] * 4 + self.MAXI0_BASE, return self.expand_define(define_tuple = (name,
define_tuple[3] * 4, var_name,
define_tuple[4], address,
define_tuple[5], address_inc,
define_tuple[6]), var_range,
data_type,
comment),
frmt_spcs = frmt_spcs)
else:
return self.expand_define(define_tuple = (name,
var_name,
address * 4 + self.MAXI0_BASE,
address_inc * 4,
var_range,
data_type,
comment),
frmt_spcs = frmt_spcs) frmt_spcs = frmt_spcs)
def expand_define(self, define_tuple, frmt_spcs = None): def expand_define(self, define_tuple, frmt_spcs = None):
...@@ -487,6 +687,7 @@ class X393ExportC(object): ...@@ -487,6 +687,7 @@ class X393ExportC(object):
for define_tuple in in_defs: for define_tuple in in_defs:
if len(define_tuple) == 7: if len(define_tuple) == 7:
name, var_name, address, address_inc, var_range, data_type, comment = define_tuple name, var_name, address, address_inc, var_range, data_type, comment = define_tuple
if not data_type is None:
if address_inc == 0: if address_inc == 0:
exp_defs.append(define_tuple) exp_defs.append(define_tuple)
nextAddr = address + 4 nextAddr = address + 4
...@@ -792,7 +993,228 @@ class X393ExportC(object): ...@@ -792,7 +993,228 @@ class X393ExportC(object):
dw.append(("dqs_tri_last", 12, 4, 0xc, "DQS tristate end (0xe,0xc,0x8); early, nominal, late")) dw.append(("dqs_tri_last", 12, 4, 0xc, "DQS tristate end (0xe,0xc,0x8); early, nominal, late"))
return dw return dw
def _enc_mcntrl_dly(self):
dw=[]
dw.append(("dly", 0, 8, 0, "8-bit delay value: 5MSBs(0..31) and 3LSBs(0..4)"))
return dw
def _enc_wbuf_dly(self):
dw=[]
dw.append(("wbuf_dly", 0, 4, 9, "Extra delay in mclk (fDDR/2) cycles) to data write buffer"))
return dw
def _enc_gamma_ctl(self):
dw=[]
dw.append(("bayer", 0, 2, 0, "Bayer color shift (pixel to gamma table)"))
dw.append(("page", 2, 1, 0, "Table page (only available if SENS_GAMMA_BUFFER in Verilog)"))
dw.append(("en", 3, 1, 1, "Enable module"))
dw.append(("repet", 4, 1, 1, "Repetitive (normal) mode. Set 0 for testing of the single-frame mode"))
dw.append(("trig", 5, 1, 0, "Single trigger used when repetitive mode is off (self clearing bit)"))
return dw
def _enc_gamma_tbl_addr(self):
dw=[]
dw.append(("addr", 0, 8, 0, "Start address in a gamma page (normally 0)"))
dw.append(("color", 8, 2, 0, "Color channel"))
if vrlg.SENS_GAMMA_BUFFER:
dw.append(("page", 10, 1, 0, "Table page (only available for buffered mode)"))
sub_chn_bit = 11
else:
sub_chn_bit = 10
dw.append(("sub_chn",sub_chn_bit, 2, 0, "Sensor sub-channel (multiplexed to the same port)"))
dw.append(("a_n_d", 20, 1, 1, "Address/not data, should be set to 1 here"))
return dw
def _enc_gamma_tbl_data(self):
dw=[]
dw.append(("base", 0, 10, 0, "Knee point value (to be interpolated between)"))
dw.append(("diff", 10, 7, 0, "Difference to next (signed, -64..+63)"))
dw.append(("diff", 17, 1, 0, "Difference scale: 0 - keep diff, 1- multiply diff by 16"))
return dw
def _enc_gamma_height01(self):
dw=[]
dw.append(("height0m1", 0, 16, 0, "Height of subchannel 0 frame minus 1"))
dw.append(("height1m1", 16, 16, 0, "Height of subchannel 1 frame minus 1"))
return dw
def _enc_gamma_height2(self):
dw=[]
dw.append(("height2m1", 0, 16, 0, "Height of subchannel 2 frame minus 1"))
return dw
def _enc_sensio_ctrl_par12(self):
dw=[]
dw.append(("mrst", vrlg.SENS_CTRL_MRST, 1, 0, "MRST signal level to the sensor (0 - low(active), 1 - high (inactive)"))
dw.append(("mrst_set", vrlg.SENS_CTRL_MRST + 1, 1, 0, "when set to 1, MRST is set to the 'mrst' field value"))
dw.append(("arst", vrlg.SENS_CTRL_ARST, 1, 0, "ARST signal to the sensor"))
dw.append(("arst_set", vrlg.SENS_CTRL_ARST + 1, 1, 0, "ARST set to the 'arst' field"))
dw.append(("aro", vrlg.SENS_CTRL_ARO, 1, 0, "ARO signal to the sensor"))
dw.append(("aro_set", vrlg.SENS_CTRL_ARO + 1, 1, 0, "ARO set to the 'aro' field"))
dw.append(("mmcm_rst", vrlg.SENS_CTRL_RST_MMCM, 1, 0, "MMCM (for sesnor clock) reset signal"))
dw.append(("mmcm_rst_set", vrlg.SENS_CTRL_RST_MMCM + 1, 1, 0, "MMCM reset set to 'mmcm_rst' field"))
dw.append(("ext_clk", vrlg.SENS_CTRL_EXT_CLK, 1, 0, "MMCM clock input: 0: clock to the sensor, 1 - clock from the sensor"))
dw.append(("ext_clk_set", vrlg.SENS_CTRL_EXT_CLK + 1, 1, 0, "Set MMCM clock input to 'ext_clk' field"))
dw.append(("set_dly", vrlg.SENS_CTRL_LD_DLY, 1, 0, "Set all pre-programmed delays to the sensor port input delays"))
dw.append(("quadrants", vrlg.SENS_CTRL_QUADRANTS, vrlg. SENS_CTRL_QUADRANTS_WIDTH, 1, "90-degree shifts for data [1:0], hact [3:2] and vact [5:4]"))
dw.append(("quadrants_set",vrlg.SENS_CTRL_QUADRANTS_EN, 1, 0, "Set 'quadrants' values"))
return dw
def _enc_sensio_ctrl_hispi(self):
dw=[]
dw.append(("mrst", vrlg.SENS_CTRL_MRST, 1, 0, "MRST signal level to the sensor (0 - low(active), 1 - high (inactive)"))
dw.append(("mrst_set", vrlg.SENS_CTRL_MRST + 1, 1, 0, "when set to 1, MRST is set to the 'mrst' field value"))
dw.append(("arst", vrlg.SENS_CTRL_ARST, 1, 0, "ARST signal to the sensor"))
dw.append(("arst_set", vrlg.SENS_CTRL_ARST + 1, 1, 0, "ARST set to the 'arst' field"))
dw.append(("aro", vrlg.SENS_CTRL_ARO, 1, 0, "ARO signal to the sensor"))
dw.append(("aro_set", vrlg.SENS_CTRL_ARO + 1, 1, 0, "ARO set to the 'aro' field"))
dw.append(("mmcm_rst", vrlg.SENS_CTRL_RST_MMCM, 1, 0, "MMCM (for sesnor clock) reset signal"))
dw.append(("mmcm_rst_set", vrlg.SENS_CTRL_RST_MMCM + 1, 1, 0, "MMCM reset set to 'mmcm_rst' field"))
dw.append(("ign_embed", vrlg.SENS_CTRL_IGNORE_EMBED, 1, 0, "Ignore embedded data (non-image pixel lines"))
dw.append(("ign_embed_set",vrlg.SENS_CTRL_IGNORE_EMBED + 1,1,0, "Set mode to 'ign_embed' field"))
dw.append(("set_dly", vrlg.SENS_CTRL_LD_DLY, 1, 0, "Set all pre-programmed delays to the sensor port input delays"))
dw.append(("gp0", vrlg.SENS_CTRL_GP0, 1, 0 , "GP0 multipurpose signal to the sensor"))
dw.append(("gp0_set", vrlg.SENS_CTRL_GP0 + 1, 1, 0, "Set GP0 to 'gp0' value"))
dw.append(("gp1", vrlg.SENS_CTRL_GP1, 1, 0 , "GP1 multipurpose signal to the sensor"))
dw.append(("gp1_set", vrlg.SENS_CTRL_GP1 + 1, 1, 0, "Set GP1 to 'gp1' value"))
return dw
def _enc_sensio_jtag(self):
dw=[]
dw.append(("tdi", vrlg.SENS_JTAG_TDI, 1, 0, "JTAG TDI level"))
dw.append(("tdi_set", vrlg.SENS_JTAG_TDI + 1, 1, 0, "JTAG TDI set to 'tdi' field"))
dw.append(("tms", vrlg.SENS_JTAG_TMS, 1, 0, "JTAG TMS level"))
dw.append(("tms_set", vrlg.SENS_JTAG_TMS + 1, 1, 0, "JTAG TMS set to 'tms' field"))
dw.append(("tck", vrlg.SENS_JTAG_TCK, 1, 0, "JTAG TCK level"))
dw.append(("tck_set", vrlg.SENS_JTAG_TCK + 1, 1, 0, "JTAG TCK set to 'tck' field"))
dw.append(("prog", vrlg.SENS_JTAG_PROG, 1, 0, "Sensor port PROG level"))
dw.append(("prog_set", vrlg.SENS_JTAG_PROG + 1, 1, 0, "Sensor port PROG set to 'prog' field"))
dw.append(("pgmen", vrlg.SENS_JTAG_PGMEN, 1, 0 , "Sensor port PGMEN level"))
dw.append(("pgmen_set", vrlg.SENS_JTAG_PGMEN + 1, 1, 0, "Sensor port PGMEN set to 'pgmen' field"))
return dw
def _enc_sensio_dly_par12(self):
dw=[]
dw.append(("pxd0", 0, 8, 0, "PXD0 input delay (3 LSB not used)"))
dw.append(("pxd1", 8, 8, 0, "PXD1 input delay (3 LSB not used)"))
dw.append(("pxd2", 16, 8, 0, "PXD2 input delay (3 LSB not used)"))
dw.append(("pxd3", 24, 8, 0, "PXD3 input delay (3 LSB not used)"))
dw.append(("pxd4", 32, 8, 0, "PXD4 input delay (3 LSB not used)"))
dw.append(("pxd5", 40, 8, 0, "PXD5 input delay (3 LSB not used)"))
dw.append(("pxd6", 48, 8, 0, "PXD6 input delay (3 LSB not used)"))
dw.append(("pxd7", 56, 8, 0, "PXD7 input delay (3 LSB not used)"))
dw.append(("pxd8", 64, 8, 0, "PXD8 input delay (3 LSB not used)"))
dw.append(("pxd9", 72, 8, 0, "PXD9 input delay (3 LSB not used)"))
dw.append(("pxd10", 80, 8, 0, "PXD10 input delay (3 LSB not used)"))
dw.append(("pxd11", 88, 8, 0, "PXD11 input delay (3 LSB not used)"))
dw.append(("hact", 96, 8, 0, "HACT input delay (3 LSB not used)"))
dw.append(("vact", 104, 8, 0, "VACT input delay (3 LSB not used)"))
dw.append(("bpf", 112, 8, 0, "BPF (clock from sensor) input delay (3 LSB not used)"))
dw.append(("phase_p", 120, 8, 0, "MMCM phase"))
return dw
def _enc_sensio_dly_hispi(self):
dw=[]
dw.append(("fifo_lag", 0, 4, 7, "FIFO delay to start output"))
dw.append(("phys_lane0", 32, 2, 1, "Physical lane for logical lane 0"))
dw.append(("phys_lane1", 34, 2, 2, "Physical lane for logical lane 1"))
dw.append(("phys_lane2", 36, 2, 3, "Physical lane for logical lane 2"))
dw.append(("phys_lane3", 38, 2, 0, "Physical lane for logical lane 3"))
dw.append(("dly_lane0", 64, 8, 0, "lane 0 (phys) input delay (3 LSB not used)"))
dw.append(("dly_lane1", 72, 8, 0, "lane 1 (phys) input delay (3 LSB not used)"))
dw.append(("dly_lane2", 80, 8, 0, "lane 2 (phys) input delay (3 LSB not used)"))
dw.append(("dly_lane3", 88, 8, 0, "lane 3 (phys) input delay (3 LSB not used)"))
dw.append(("phase_h", 96, 8, 0, "MMCM phase"))
return dw
def _enc_sensio_width(self):
dw=[]
dw.append(("sensor_width", 0, 16, 0, "Sensor frame width (0 - use line sync signals from the sensor)"))
return dw
def _enc_lens_addr(self):
dw=[]
dw.append(("addr", 16, 8, 0, "Lens correction address, should be written first (overlaps with data)"))
dw.append(("sub_chn", 24, 2, 0, "Sensor subchannel"))
return dw
def _enc_lens_ax(self):
dw=[]
dw.append(("ax", 0, 19, 0x20000, "Coefficient Ax"))
return dw
def _enc_lens_ay(self):
dw=[]
dw.append(("ay", 0, 19, 0x20000, "Coefficient Ay"))
return dw
def _enc_lens_bx(self):
dw=[]
dw.append(("bx", 0, 21, 0x180000, "Coefficient Bx"))
return dw
def _enc_lens_by(self):
dw=[]
dw.append(("by", 0, 21, 0x180000, "Coefficient By"))
return dw
def _enc_lens_c(self):
dw=[]
dw.append(("c", 0, 19, 0x8000, "Coefficient C"))
return dw
def _enc_lens_scale(self):
dw=[]
dw.append(("scale", 0, 17, 0x8000, "Scale (4 per-color values)"))
return dw
def _enc_lens_fatzero_in(self):
dw=[]
dw.append(("fatzero_in", 0, 16, 0, "'Fat zero' on the input (subtract from the input)"))
return dw
def _enc_lens_fatzero_out(self):
dw=[]
dw.append(("fatzero_out", 0, 16, 0, "'Fat zero' on the output (add to the result)"))
return dw
def _enc_lens_post_scale(self):
dw=[]
dw.append(("post_scale", 0, 4, 1, "Shift result (bits)"))
return dw
def _enc_lens_height_m1(self):
dw=[]
dw.append(("height_m1", 0, 16, 0, "Height of subframe minus 1"))
return dw
def _enc_histogram_wh_m1(self):
dw=[]
dw.append(("width_m1" , 0, 16, 0, "Width of the histogram window minus 1. If 0 - use frame right margin (end of HACT)"))
dw.append(("height_m1", 16, 16, 0, "Height of he histogram window minus 1. If 0 - use frame bottom margin (end of VACT)"))
return dw
def _enc_histogram_lt(self):
dw=[]
dw.append(("left" , 0, 16, 0, "Histogram window left margin"))
dw.append(("top", 16, 16, 0, "Histogram window top margin"))
return dw
def _enc_hist_saxi_mode(self):
dw=[]
dw.append(("en" , vrlg.HIST_SAXI_EN, 1, 1, "Enable histograms DMA"))
dw.append(("nrst" , vrlg.HIST_SAXI_NRESET, 1, 1, "0 - reset histograms DMA"))
dw.append(("confirm" , vrlg.HIST_CONFIRM_WRITE, 1, 1, "1 - wait for confirmation that histogram was written to the system memory"))
dw.append(("cache" , vrlg.HIST_SAXI_AWCACHE, 4, 3, "AXI cache mode (normal - 3), ignored by Zynq?"))
return dw
def _enc_hist_saxi_page_addr(self):
dw=[]
dw.append(("page" , 0, 20, 0, "Start address of the subchannel histogram (in pages = 4096 bytes"))
return dw
""" """
parameter SENSIO_WIDTH = 'h3, // 1.. 2^16, 0 - use HACT
parameter SENSIO_DELAYS = 'h4, // 'h4..'h7
// 4 of 8-bit delays per register
DQSTRI_LAST, DQSTRI_FIRST, DQTRI_LAST, DQTRI_FIRST DQSTRI_LAST, DQSTRI_FIRST, DQTRI_LAST, DQTRI_FIRST
""" """
...@@ -808,8 +1230,8 @@ DQSTRI_LAST, DQSTRI_FIRST, DQTRI_LAST, DQTRI_FIRST ...@@ -808,8 +1230,8 @@ DQSTRI_LAST, DQSTRI_FIRST, DQTRI_LAST, DQTRI_FIRST
raise Exception("Overlapping bit fields in %s, %s and %s"%(name, str(padded_data[-1]), str(item))) raise Exception("Overlapping bit fields in %s, %s and %s"%(name, str(padded_data[-1]), str(item)))
padded_data.append(item) padded_data.append(item)
next_bit = item[1]+item[2] next_bit = item[1]+item[2]
if padLast and (next_bit < wlen): if padLast and (next_bit % wlen):
padded_data.append(("", next_bit, wlen-next_bit, 0,"")) padded_data.append(("", next_bit, wlen- (next_bit % wlen), 0,""))
return padded_data return padded_data
......
...@@ -822,7 +822,8 @@ class X393PIOSequences(object): ...@@ -822,7 +822,8 @@ class X393PIOSequences(object):
self.x393_axi_tasks.write_control_register(vrlg.MCONTR_TOP_16BIT_ADDR + vrlg.MCONTR_TOP_16BIT_REFRESH_PERIOD, t_refi) self.x393_axi_tasks.write_control_register(vrlg.MCONTR_TOP_16BIT_ADDR + vrlg.MCONTR_TOP_16BIT_REFRESH_PERIOD, t_refi)
# enable refresh - should it be done here? # enable refresh - should it be done here?
if en_refresh: if en_refresh:
self.x393_axi_tasks.write_control_register(vrlg.MCONTR_PHY_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_REFRESH_EN + 1, 0) # self.x393_axi_tasks.write_control_register(vrlg.MCONTR_PHY_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_REFRESH_EN + 1, 0)
self.x393_axi_tasks.write_control_register(vrlg.MCONTR_TOP_0BIT_ADDR + vrlg.MCONTR_TOP_0BIT_REFRESH_EN + 1, 0)
def set_mrs(self, # will also calibrate ZQ def set_mrs(self, # will also calibrate ZQ
......
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