Mercurial > public > mk2
view code_part1/OSTC_code_asm_part1/oled_samsung.asm @ 167:cb055a7d75f3
+ Use overlay local vars.
+ Make all private functions static.
+ Merge calc_tissue 2sec and 1min
+ Merge sim_tissue 1min and 10min
+ Expose basic display utilities for c-code.
+ Prepare stand-alone utilities for p2_main.c testing platform.
+ New c utility: int read_custom_function(cf#)
| author | JeanDo |
|---|---|
| date | Mon, 24 Jan 2011 23:31:57 +0100 |
| parents | fc699a7460e6 |
| children | 447390289f47 |
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; OSTC - diving computer code ; Copyright (C) 2009 HeinrichsWeikamp GbR ; This program is free software: you can redistribute it and/or modify ; it under the terms of the GNU General Public License as published by ; the Free Software Foundation, either version 3 of the License, or ; (at your option) any later version. ; This program is distributed in the hope that it will be useful, ; but WITHOUT ANY WARRANTY; without even the implied warranty of ; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ; GNU General Public License for more details. ; You should have received a copy of the GNU General Public License ; along with this program. If not, see <http://www.gnu.org/licenses/>. ; hardware routines for S6E6D6 Samsung OLED Driver IC ; written by: Matthias Heinrichs, info@heinrichsweikamp.com ; written: 090801 ; History: ; 2009-08-30: [MH] last updated. ; 2011-01-07: [jDG] Added flip_screen option ; known bugs: pixel-write (loogbok curves) not done yet... ; ToDo: WIN_FONT macro win_font_input movlw win_font_input movff WREG,win_font endm WIN_TOP macro win_top_input movlw win_top_input movff WREG,win_top endm WIN_LEFT macro win_left_input movlw win_left_input movff WREG,win_leftx2 endm WIN_INVERT macro win_invert_input movlw win_invert_input movff WREG,win_invert endm WIN_COLOR macro win_color_input movlw win_color_input call PLED_set_color endm ;============================================================================= word_processor: ; word_processor: clrf POSTINC2 ; Required, to mark end of string. call aa_wordprocessor movlb b'00000001' ; Back to Rambank1 return ;============================================================================= ; Macro to provides our own interface code. ; PIXEL_WRITE macro colRegister, rowRegister movff colRegister,win_leftx2 movff rowRegister,win_top call pixel_write endm INIT_PIXEL_WROTE macro colRegister movff colRegister,win_leftx2 call init_pixel_write endm HALF_PIXEL_WRITE macro rowRegister movff rowRegister,win_top call half_pixel_write endm ;----------------------------------------------------------------------------- ; Init for half_pixel_write ; Set column register on OLED device, and current color. ; Inputs: win_leftx2 ; Outputs: win_color:2 ; Trashed: WREG, PROD init_pixel_write: movff win_leftx2,WREG mullw 2 rcall pixel_write_col320 ; Start Address Vertical (.0 - .319) goto PLED_standard_color ;----------------------------------------------------------------------------- ; Writes two half-pixels at position (win_top,win_leftx2) ; Inputs: win_leftx2, win_top, win_color:2 ; Trashed: WREG, PROD pixel_write: movff win_leftx2,WREG mullw 2 rcall pixel_write_col320 ; Start Address Vertical (.0 - .319) rcall half_pixel_write ; Write this half-one. movff win_leftx2,WREG ; Address of next one mullw 2 infsnz PRODL ; +1 incf PRODH rcall pixel_write_col320 bra half_pixel_write ; Note: Cmd 0x20 is mandatory, because ; of the autoincrement going vertical ;---- Do the 16bit 319-X-->X, if needed, and send to OLED ------------ pixel_write_col320: movff win_flags,WREG ; BEWARE: bank0 bit-test btfss WREG,0 ; 180° rotation ? bra pixel_write_noflip_H movf PRODL,W ; 16bits 319 - PROD --> PROD sublw LOW(.319) ; 319-W --> W movwf PRODL movf PRODH,W btfss STATUS,C ; Borrow = /CARRY incf WREG sublw HIGH(.319) movwf PRODH pixel_write_noflip_H: movlw 0x21 ; Start Address Vertical (.0 - .319) rcall PLED_CmdWrite bra PLED_DataWrite_PROD ;----------------------------------------------------------------------------- ; Writes one half-pixel at position (win_top,win_leftx2). ; Inputs: win_leftx2, win_top, win_color:2 ; Trashed: WREG, PROD half_pixel_write: movff win_top,WREG ; d'0' ... d'239' movff win_flags,PRODL ; BEWARE: bank0 bit-test btfsc PRODL,0 ; 180° rotation ? sublw .239 ; 239-Y --> Y mullw 1 ; Copy row to PRODH:L movlw 0x20 ; Horizontal Address START:END rcall PLED_CmdWrite rcall PLED_DataWrite_PROD movlw 0x22 ; Start Writing Data to GRAM rcall PLED_CmdWrite bsf oled_rs ; Data! movff win_color1, PORTD bcf oled_rw bsf oled_rw ; Upper movff win_color2, PORTD bcf oled_rw bsf oled_rw ; Lower return ; ----------------------------- ; PLED Display Off ; ----------------------------- PLED_DisplayOff: clrf PORTD bcf oled_hv bcf oled_vdd bcf oled_cs bcf oled_e_nwr bcf oled_rw bcf oled_nreset return ;============================================================================= ; Fast macros to write to OLED display. ; Adding a call/return adds 3 words and a pipeline flush, hence make it ; nearly twice slower... ; ; Input : commande as macro parameter. ; Output : NONE ; Trash : WREG ; AA_CMD_WRITE macro cmd movlw cmd rcall PLED_CmdWrite ; bcf oled_rs ; Cmd mode ; movwf PORTD,A ; bcf oled_rw ; Tick the clock ; bsf oled_rw endm ; ; Input : PRODH:L as 16bits data. ; Output : NONE ; Trash : NONE ; AA_DATA_WRITE_PROD macro rcall PLED_DataWrite_PROD ; bsf oled_rs ; Data mode ; movff PRODH,PORTD ; NOTE: OLED is BIGENDIAN! ; bcf oled_rw ; Tick the clock ; bsf oled_rw ; movff PRODL,PORTD ; bcf oled_rw ; Tick the clock ; bsf oled_rw endm ;============================================================================= ; Output OLED Window Address commands. ; Inputs : win_top, win_leftx2, win_height, aa_width. ; Output : PortD commands. ; Trashed: PROD ; PLED_box_write: movff win_leftx2,WREG ; Compute left = 2*leftx2 --> PROD mullw 2 movff win_flags,WREG ; BEWARE: bank0 bit-test btfsc WREG,0 ; 180° rotation ? bra PLED_box_flip_H ; YES: ;---- Normal horizontal window --------------------------------------- ; Output 0x35 left, ; 0x36 right == left + width - 1. AA_CMD_WRITE 0x35 ; this is the left border AA_DATA_WRITE_PROD ; Output left AA_CMD_WRITE 0x21 ; Also the horizontal first pix coord. AA_DATA_WRITE_PROD movf aa_width+0,W,ACCESS ; right = left + width - 1 addwf PRODL,F movf aa_width+1,W,ACCESS addwfc PRODH,F decf PRODL,F,A ; decrement result btfss STATUS,C decf PRODH,F,A AA_CMD_WRITE 0x36 ; Write and the right border AA_DATA_WRITE_PROD bra PLED_box_noflip_H ;---- Flipped horizontal window -------------------------------------- PLED_box_flip_H: ; Output 0x36 flipped(left) = 319-left ; 0x35 flipped(right) = 319-right = 320 - left - width movf PRODL,W ; 16bits 319 - PROD --> PROD sublw LOW(.319) ; 319-W --> W movwf PRODL movf PRODH,W btfss STATUS,C ; Borrow = /CARRY incf WREG sublw HIGH(.319) movwf PRODH AA_CMD_WRITE 0x36 ; this is the left border AA_DATA_WRITE_PROD ; Output left AA_CMD_WRITE 0x21 AA_DATA_WRITE_PROD movf aa_width+0,W ; 16bits PROD - width --> PROD subwf PRODL,F ; PRODL - WREG --> PRODL movf aa_width+1,W subwfb PRODH,F infsnz PRODL ; PROD+1 --> PROD incf PRODH AA_CMD_WRITE 0x35 ; this is the left border AA_DATA_WRITE_PROD ; Output left PLED_box_noflip_H: movff win_flags,WREG ; BEWARE: bank0 bit-test btfsc WREG,0 ; 180° rotation ? bra PLED_box_flip_V ;---- Normal vertical window ----------------------------------------- ; Output 0x37 (top) (bottom) movff win_top,PRODH ; top --> PRODH (first byte) movff win_height,WREG addwf PRODH,W decf WREG movwf PRODL ; top+height-1 --> PRODL (second byte) AA_CMD_WRITE 0x37 AA_DATA_WRITE_PROD movff PRODH,PRODL clrf PRODH ; Start pixel V coord == top. AA_CMD_WRITE 0x20 AA_DATA_WRITE_PROD return ;---- Flipped vertical window ---------------------------------------- ; Output 0x37 flipped(bottom) = 239-bottom = 240 - top - height ; flipped(top) = 239-top PLED_box_flip_V: movff win_top,PRODL movff win_height,WREG addwf PRODL,W sublw .240 ; 240 - top - height movwf PRODH ; First byte movf PRODL,W sublw .239 ; 249-top movwf PRODL ; --> second byte. AA_CMD_WRITE 0x37 AA_DATA_WRITE_PROD clrf PRODH ; Start pixel V coord. AA_CMD_WRITE 0x20 AA_DATA_WRITE_PROD return ;============================================================================= ; PLED_frame : draw a frame around current box with current color. ; Inputs: win_top, win_leftx2, win_height, win_width, win_color1, win_color2 ; Outputs: (none) ; Trashed: WREG, PROD, aa_start:2, aa_end:2, win_leftx2, win_width:1 global PLED_frame PLED_frame: movff win_top,aa_start+0 ; Backup everything. movff win_height,aa_start+1 movff win_leftx2,aa_end+0 movff win_width,aa_end+1 ;---- TOP line ----------------------------------------------------------- movlw 1 ; row ~ height=1 movff WREG,win_height rcall PLED_box ;---- BOTTOM line -------------------------------------------------------- movff aa_start+0,PRODL ; Get back top, movff aa_start+1,WREG ; and height addwf PRODL,W ; top+height decf WREG ; top+height-1 movff WREG,win_top ; top+height-1 --> top rcall PLED_box ;---- LEFT column -------------------------------------------------------- movff aa_start+0,win_top ; Restore top/height. movff aa_start+1,win_height movlw 1 ; column ~ width=1 movff WREG,win_width rcall PLED_box ;---- RIGHT column ------------------------------------------------------- movff aa_end+0,WREG movff aa_end+1,PRODL addwf PRODL,W decf WREG movff WREG,win_leftx2 bra PLED_box ;============================================================================= ; PLED_box : fills current box with current color. ; Inputs: win_top, win_leftx2, win_height, win_width, win_color1, win_color2 ; Outputs: (none) ; Trashed: WREG, PROD global PLED_box PLED_box: ;---- Define Window ------------------------------------------------------ movff win_width,WREG bcf STATUS,C rlcf WREG movwf aa_width+0 movlw 0 rlcf WREG movwf aa_width+1 rcall PLED_box_write ;---- Fill Window -------------------------------------------------------- movlw 0x22 ; Start Writing Data to GRAM rcall PLED_CmdWrite clrf PRODH ; Column counter. bsf oled_rs ; Data! PLED_box2: ; Loop height times movff win_height,PRODL PLED_box3: ; loop width times movff win_color1,PORTD bcf oled_rw bsf oled_rw ; Upper movff win_color2,PORTD bcf oled_rw bsf oled_rw ; Lower movff win_color1,PORTD bcf oled_rw bsf oled_rw ; Upper movff win_color2,PORTD bcf oled_rw bsf oled_rw ; Lower decfsz PRODL,F ; row loop finished ? bra PLED_box3 ; No: continue. incf PRODH,F ; column count ++ movff win_bargraph,WREG ; current column == bargraph ? cpfseq PRODH bra PLED_box4 ; No: just loop. clrf WREG ; Yes: switch to black movff WREG,win_color1 movff WREG,win_color2 PLED_box4: movff win_width,WREG cpfseq PRODH bra PLED_box2 movlw 0x00 ; NOP, to stop window mode rcall PLED_CmdWrite setf WREG ; Reset bargraph mode... movff WREG,win_bargraph return ;============================================================================= ; PLED_ClearScreen: An optimized version of PLEX_box, for full screen black. ; Trashed: WREG, PROD global PLED_ClearScreen PLED_ClearScreen: movlw 0x35 ; VerticalStartAddress HIGH:LOW rcall PLED_CmdWrite mullw 0 rcall PLED_DataWrite_PROD movlw 0x36 ; VerticalEndAddress HIGH:LOW rcall PLED_CmdWrite movlw 0x01 rcall PLED_DataWrite movlw 0x3F rcall PLED_DataWrite movlw 0x37 ; HorizontalAddress START:END rcall PLED_CmdWrite movlw 0x00 rcall PLED_DataWrite movlw 0xEF rcall PLED_DataWrite movlw 0x20 ; Start Address Horizontal (.0 - .239) rcall PLED_CmdWrite rcall PLED_DataWrite_PROD movlw 0x21 ; Start Address Vertical (.0 - .319) rcall PLED_CmdWrite rcall PLED_DataWrite_PROD movlw 0x22 ; Start Writing Data to GRAM rcall PLED_CmdWrite ; See Page 101 of OLED Driver IC Datasheet how to handle rs/rw clocks bsf oled_rs ; Data! movlw .160 movwf PRODH PLED_ClearScreen2: movlw .240 movwf PRODL PLED_ClearScreen3: clrf PORTD ; Need to generate trace here too. bcf oled_rw bsf oled_rw ; Upper clrf PORTD ; Need to generate trace here too. bcf oled_rw bsf oled_rw ; Lower clrf PORTD ; Need to generate trace here too. bcf oled_rw bsf oled_rw ; Upper clrf PORTD ; Need to generate trace here too. bcf oled_rw bsf oled_rw ; Lower decfsz PRODL,F bra PLED_ClearScreen3 decfsz PRODH,F bra PLED_ClearScreen2 movlw 0x00 ; NOP, to stop Address Update Counter bra PLED_CmdWrite ; ----------------------------- ; PLED Write Cmd via W ; ----------------------------- PLED_CmdWrite: bcf oled_rs ; Command! movwf PORTD ; Move Data to PORTD bcf oled_rw bsf oled_rw return ; ----------------------------- ; PLED Write Display Data via W ; ----------------------------- PLED_DataWrite: bsf oled_rs ; Data! movwf PORTD ; Move Data to PORTD bcf oled_rw bsf oled_rw return ; ----------------------------- ; PLED Data Cmd via W ; ----------------------------- PLED_DataWrite_PROD: bsf oled_rs ; Data! movff PRODH,PORTD ; Move high byte to PORTD (OLED is bigendian) bcf oled_rw bsf oled_rw movff PRODL,PORTD ; Move low byte to PORTD bcf oled_rw bsf oled_rw return ; ----------------------------- ; PLED boot ; ----------------------------- PLED_boot: bcf oled_hv WAITMS d'32' bsf oled_vdd nop bcf oled_cs nop bsf oled_nreset ; WAITMS d'10' ; Quick wake-up WAITMS d'250' ; Standard wake-up bsf oled_e_nwr nop bcf oled_nreset WAIT10US d'2' bsf oled_nreset WAITMS d'10' movlw 0x24 ; 80-System 8-Bit Mode rcall PLED_CmdWrite movlw 0x02 ; RGB Interface Control (S6E63D6 Datasheet page 42) rcall PLED_CmdWrite movlw 0x00 ; X X X X X X X RM rcall PLED_DataWrite movlw 0x00 ; DM X RIM1 RIM0 VSPL HSPL EPL DPL rcall PLED_DataWrite ; System Interface: RIM is ignored, Internal Clock movlw 0x03 ; Entry Mode (S6E63D6 Datasheet page 46) rcall PLED_CmdWrite movlw 0x00 ; CLS MDT1 MDT0 BGR X X X SS 65k Color rcall PLED_DataWrite ; Change direction for block-writes of pixels lfsr FSR0,win_flags btfss INDF0,0 ; BANK-SAFE bit test. movlw b'00110000' ; [normal] X X I/D1 I/D0 X X X AM btfsc INDF0,0 movlw b'00000000' ; [flipped] X X I/D1 I/D0 X X X AM rcall PLED_DataWrite movlw 0x18 rcall PLED_CmdWrite movlw 0x00 rcall PLED_DataWrite movlw 0x28 rcall PLED_DataWrite movlw 0xF8 rcall PLED_CmdWrite movlw 0x00 rcall PLED_DataWrite movlw 0x0F rcall PLED_DataWrite movlw 0xF9 rcall PLED_CmdWrite movlw 0x00 rcall PLED_DataWrite movlw 0x0F rcall PLED_DataWrite movlw 0x10 rcall PLED_CmdWrite movlw 0x00 rcall PLED_DataWrite movlw 0x00 rcall PLED_DataWrite ; Now Gamma settings... rcall PLED_brightness_full ;rcall PLED_brightness_low ; End Gamma Settings rcall PLED_ClearScreen bsf oled_hv WAITMS d'32' movlw 0x05 rcall PLED_CmdWrite movlw 0x00 rcall PLED_DataWrite movlw 0x01 rcall PLED_DataWrite ; Display ON return PLED_brightness_full: movlw 0x70 rcall PLED_CmdWrite movlw 0x1F rcall PLED_DataWrite movlw 0x00 rcall PLED_DataWrite movlw 0x71 rcall PLED_CmdWrite movlw 0x23 rcall PLED_DataWrite movlw 0x80 rcall PLED_DataWrite movlw 0x72 rcall PLED_CmdWrite movlw 0x2A rcall PLED_DataWrite movlw 0x80 rcall PLED_DataWrite movlw 0x73 rcall PLED_CmdWrite movlw 0x15 rcall PLED_DataWrite movlw 0x11 rcall PLED_DataWrite movlw 0x74 rcall PLED_CmdWrite movlw 0x1C rcall PLED_DataWrite movlw 0x11 rcall PLED_DataWrite movlw 0x75 rcall PLED_CmdWrite movlw 0x1B rcall PLED_DataWrite movlw 0x15 rcall PLED_DataWrite movlw 0x76 rcall PLED_CmdWrite movlw 0x1A rcall PLED_DataWrite movlw 0x15 rcall PLED_DataWrite movlw 0x77 rcall PLED_CmdWrite movlw 0x1C rcall PLED_DataWrite movlw 0x18 rcall PLED_DataWrite movlw 0x78 rcall PLED_CmdWrite movlw 0x21 rcall PLED_DataWrite movlw 0x15 rcall PLED_DataWrite return PLED_brightness_low: movlw 0x70 rcall PLED_CmdWrite movlw 0x14 rcall PLED_DataWrite movlw 0x00 rcall PLED_DataWrite movlw 0x71 rcall PLED_CmdWrite movlw 0x17 rcall PLED_DataWrite movlw 0x00 rcall PLED_DataWrite movlw 0x72 rcall PLED_CmdWrite movlw 0x15 rcall PLED_DataWrite movlw 0x80 rcall PLED_DataWrite movlw 0x73 rcall PLED_CmdWrite movlw 0x15 rcall PLED_DataWrite movlw 0x11 rcall PLED_DataWrite movlw 0x74 rcall PLED_CmdWrite movlw 0x14 rcall PLED_DataWrite movlw 0x0B rcall PLED_DataWrite movlw 0x75 rcall PLED_CmdWrite movlw 0x1B rcall PLED_DataWrite movlw 0x15 rcall PLED_DataWrite movlw 0x76 rcall PLED_CmdWrite movlw 0x13 rcall PLED_DataWrite movlw 0x0E rcall PLED_DataWrite movlw 0x77 rcall PLED_CmdWrite movlw 0x1C rcall PLED_DataWrite movlw 0x18 rcall PLED_DataWrite movlw 0x78 rcall PLED_CmdWrite movlw 0x15 rcall PLED_DataWrite movlw 0x0E rcall PLED_DataWrite return PLED_set_color:;Converts 8Bit RGB b'RRRGGGBB' into 16Bit RGB b'RRRRRGGGGGGBBBBB' movwf oled1_temp ; Get 8Bit RGB b'RRRGGGBB' movff oled1_temp, oled2_temp ; Copy ; Mask Bit 7,6,5,4,3,2 movlw b'00000011' andwf oled2_temp,F movlw b'00000000' dcfsnz oled2_temp,F movlw b'01010000' dcfsnz oled2_temp,F movlw b'10100000' dcfsnz oled2_temp,F movlw b'11111000' movwf oled3_temp ; Blue done. movff oled1_temp, oled2_temp ; Copy ; Mask Bit 7,6,5,1,0 movlw b'00011100' andwf oled2_temp,F rrncf oled2_temp,F rrncf oled2_temp,F movlw b'00000000' dcfsnz oled2_temp,F movlw b'00000100' dcfsnz oled2_temp,F movlw b'00001000' dcfsnz oled2_temp,F movlw b'00001100' dcfsnz oled2_temp,F movlw b'00010000' dcfsnz oled2_temp,F movlw b'00010100' dcfsnz oled2_temp,F movlw b'00100000' dcfsnz oled2_temp,F movlw b'00111111' movwf oled4_temp rrcf oled4_temp,F rrcf oled3_temp,F rrcf oled4_temp,F rrcf oled3_temp,F rrcf oled4_temp,F rrcf oled3_temp,F ; oled3_temp (b'GGGBBBBB') done. movff oled1_temp, oled2_temp ; Copy clrf oled1_temp rrcf oled4_temp,F rrcf oled1_temp,F rrcf oled4_temp,F rrcf oled1_temp,F rrcf oled4_temp,F rrcf oled1_temp,F ; Green done. ; Mask Bit 4,3,2,1,0 movlw b'11100000' andwf oled2_temp,F rrncf oled2_temp,F rrncf oled2_temp,F rrncf oled2_temp,F rrncf oled2_temp,F rrncf oled2_temp,F movlw b'00000000' dcfsnz oled2_temp,F movlw b'00000100' dcfsnz oled2_temp,F movlw b'00001000' dcfsnz oled2_temp,F movlw b'00001100' dcfsnz oled2_temp,F movlw b'00010000' dcfsnz oled2_temp,F movlw b'00010100' dcfsnz oled2_temp,F movlw b'00100000' dcfsnz oled2_temp,F movlw b'00111111' movwf oled4_temp rrcf oled4_temp,F rrcf oled1_temp,F rrcf oled4_temp,F rrcf oled1_temp,F rrcf oled4_temp,F rrcf oled1_temp,F rrcf oled4_temp,F rrcf oled1_temp,F rrcf oled4_temp,F rrcf oled1_temp,F ; Red done. movff oled1_temp,win_color1 movff oled3_temp,win_color2 ; Set Bank0 Color registers... return