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tgy.asm
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tgy.asm
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;**** **** **** **** ****
;
;Die Benutzung der Software ist mit folgenden Bedingungen verbunden:
;
;1. Da ich alles kostenlos zur Verfügung stelle, gebe ich keinerlei Garantie
; und übernehme auch keinerlei Haftung für die Folgen der Benutzung.
;
;2. Die Software ist ausschließlich zur privaten Nutzung bestimmt. Ich
; habe nicht geprüft, ob bei gewerblicher Nutzung irgendwelche Patentrechte
; verletzt werden oder sonstige rechtliche Einschränkungen vorliegen.
;
;3. Jeder darf Änderungen vornehmen, z.B. um die Funktion seinen Bedürfnissen
; anzupassen oder zu erweitern. Ich würde mich freuen, wenn ich weiterhin als
; Co-Autor in den Unterlagen erscheine und mir ein Link zur entprechenden Seite
; (falls vorhanden) mitgeteilt wird.
;
;4. Auch nach den Änderungen sollen die Software weiterhin frei sein, d.h. kostenlos bleiben.
;
;!! Wer mit den Nutzungbedingungen nicht einverstanden ist, darf die Software nicht nutzen !!
;
; tp-18a
; October 2004
; autor: Bernhard Konze
; email: [email protected]
;--
; Based on upon Bernhard's "tp-18a" and others; see
; http://home.versanet.de/~b-konze/blc_18a/blc_18a.htm
; Copyright (C) 2004 Bernhard Konze
; Copyright (C) 2011-2012 Simon Kirby and other contributors
; NO WARRANTY EXPRESSED OR IMPLIED. USE AT YOUR OWN RISK. Always test
; without propellers! Please respect Bernhard Konze's license above.
;--
; WARNING: I have blown FETs on Turnigy Plush 18A ESCs in previous versions
; of this code with my modifications. Some bugs have since been fixed, such
; as leaving PWM enabled while busy-looping forever outside of ISR code.
; However, this does run with higher PWM frequency than most original code,
; so higher FET temperatures may occur! USE AT YOUR OWN RISK, and maybe see
; how it compares and let me know!
;
; WARNING: This does not check temperature or voltage ADC inputs.
;
; NOTE: We do 16-bit PWM on timer2 at full CPU clock rate resolution, using
; tcnt2h to simulate the high byte. An input FULL to STOP range of 800 plus
; a MIN_DUTY of 56 (a POWER_RANGE of 856) gives 800 unique PWM steps at an
; about 18kHz on a 16MHz CPU clock. The output frequency is slightly lower
; than F_CPU / POWER_RANGE due to cycles used in the interrupt as TCNT2 is
; reloaded.
;
; Simon Kirby <[email protected]>
;
;-- Device ----------------------------------------------------------------
;
.include "m8def.inc"
;
; 8K Bytes of In-System Self-Programmable Flash
; 512 Bytes EEPROM
; 1K Byte Internal SRAM
;
;-- Fuses -----------------------------------------------------------------
;
; Old fuses for internal RC oscillator at 8MHz were lfuse=0xa4 hfuse=0xdf,
; but since we now set OSCCAL to 0xff (about 16MHz), running under 4.5V is
; officially out of spec. We'd better set the brown-out detection to 4.0V.
; The resulting code works with or without external 16MHz oscillators.
; Boards with external oscillators can use lfuse=0x3f.
;
; If the boot loader is enabled, the last nibble of the hfuse should be set
; to 'a' or '2' to also enable EESAVE - save EEPROM on chip erase. This is
; a 512-word boot flash section (0xe00), and enable BOOTRST to jump to it.
; Setting these fuses actually has no harm even without the boot loader,
; since 0xffff is nop, and it will just nop-sled around into normal code.
;
; Suggested fuses with 4.0V brown-out voltage:
; Without external oscillator: avrdude -U lfuse:w:0x24:m -U hfuse:w:0xda:m
; With external oscillator: avrdude -U lfuse:w:0x3f:m -U hfuse:w:0xca:m
;
; Don't set WDTON if using the boot loader. We will enable it on start.
;
;-- Board -----------------------------------------------------------------
;
; The following only works with avra or avrasm2.
; For avrasm32, just comment out all but the include you need.
#if defined(afro_esc)
#include "afro.inc" ; AfroESC (ICP PWM, I2C, UART)
#elif defined(afro2_esc)
#include "afro2.inc" ; AfroESC 2 (ICP PWM, I2C, UART)
#elif defined(afro_hv_esc)
#include "afro_hv.inc" ; AfroESC HV with drivers (ICP PWM, I2C, UART)
#elif defined(afro_nfet_esc)
#include "afro_nfet.inc" ; AfroESC 3 with all nFETs (ICP PWM, I2C, UART)
#elif defined(afro_pr0_esc)
#include "afro_pr0.inc" ; AfroESC prototype rev0 with NCP5911 (ICP PWM)
#elif defined(afro_pr1_esc)
#include "afro_pr1.inc" ; AfroESC prototype rev1 with NCP5911 (ICP PWM)
#elif defined(arctictiger_esc)
#include "arctictiger.inc" ; Arctic Tiger 30A ESC with all nFETs (ICP PWM)
#elif defined(birdie70a_esc)
#include "birdie70a.inc" ; Birdie 70A with all nFETs (INT0 PWM)
#elif defined(mkblctrl1_esc)
#include "mkblctrl1.inc" ; MK BL-Ctrl v1.2 (ICP PWM, I2C, UART, high side PWM, sense hack)
#elif defined(bs_esc)
#include "bs.inc" ; HobbyKing BlueSeries / Mystery (INT0 PWM)
#elif defined(bs_nfet_esc)
#include "bs_nfet.inc" ; HobbyKing BlueSeries / Mystery with all nFETs (INT0 PWM)
#elif defined(bs40a_esc)
#include "bs40a.inc" ; HobbyKing BlueSeries / Mystery 40A (INT0 PWM)
#elif defined(dlu40a_esc)
#include "dlu40a.inc" ; Pulso Advance Plus 40A DLU40A inverted-PWM-opto (INT0 PWM)
#elif defined(dlux_esc)
#include "dlux.inc" ; HobbyKing Dlux Turnigy ESC 20A
#elif defined(diy0_esc)
#include "diy0.inc" ; HobbyKing DIY Open ESC (unreleased rev 0)
#elif defined(dys_nfet_esc)
#include "dys_nfet.inc" ; DYS 30A ESC with all nFETs (ICP PWM, I2C, UART)
#elif defined(hk200a_esc)
#include "hk200a.inc" ; HobbyKing SS Series 190-200A with all nFETs (INT0 PWM)
#elif defined(hm135a_esc)
#include "hm135a.inc" ; Hacker/Jeti Master 135-O-F5B 135A inverted-PWM-opto (INT0 PWM)
#elif defined(hxt200a_esc)
#include "hxt200a.inc" ; HexTronik F3J HXT200A HV ESC (INT0 PWM, I2C, UART)
#elif defined(kda_esc)
#include "kda.inc" ; Keda/Multistar 12A, 20A, 30A (original) (inverted INT0 PWM)
#elif defined(kda_8khz_esc)
#include "kda_8khz.inc" ; Keda/Multistar 30A (early 2014) (inverted INT0 PWM)
#elif defined(kda_nfet_esc)
#include "kda_nfet.inc" ; Keda/Multistar 30A with all nFETs (inverted INT0 PWM)
#elif defined(kda_nfet_ni_esc)
#include "kda_nfet_ni.inc" ; Keda/Multistar/Sunrise ~30A with all nFETs (INT0 PWM)
#elif defined(rb50a_esc)
#include "rb50a.inc" ; Red Brick 50A with all nFETs (INT0 PWM)
#elif defined(rb70a_esc)
#include "rb70a.inc" ; Red Brick 70A with all nFETs (INT0 PWM)
#elif defined(rb70a2_esc)
#include "rb70a2.inc" ; Newer Red Brick 70A with blue pcb and all nFETs (INT0 PWM)
#elif defined(rct50a_esc)
#include "rct50a.inc" ; RCTimer 50A (MLF version) with all nFETs (INT0 PWM)
#elif defined(tbs_esc)
#include "tbs.inc" ; TBS 30A ESC (Team BlackSheep) with all nFETs (ICP PWM, UART)
#elif defined(tbs_hv_esc)
#include "tbs_hv.inc" ; TBS high voltage ESC (Team BlackSheep) with all nFETs (ICP PWM, UART)
#elif defined(tp_esc)
#include "tp.inc" ; TowerPro 25A/HobbyKing 18A "type 1" (INT0 PWM)
#elif defined(tp_8khz_esc)
#include "tp_8khz.inc" ; TowerPro 25A/HobbyKing 18A "type 1" (INT0 PWM) at 8kHz PWM
#elif defined(tp_i2c_esc)
#include "tp_i2c.inc" ; TowerPro 25A/HobbyKing 18A "type 1" (I2C)
#elif defined(tp_nfet_esc)
#include "tp_nfet.inc" ; TowerPro 25A with all nFETs "type 3" (INT0 PWM)
#elif defined(tp70a_esc)
#include "tp70a.inc" ; TowerPro 70A with BL8003 FET drivers (INT0 PWM)
#elif defined(tgy6a_esc)
#include "tgy6a.inc" ; Turnigy Plush 6A (INT0 PWM)
#elif defined(tgy_8mhz_esc)
#include "tgy_8mhz.inc" ; TowerPro/Turnigy Basic/Plush "type 2" w/8MHz oscillator (INT0 PWM)
#elif defined(tgy_esc)
#include "tgy.inc" ; TowerPro/Turnigy Basic/Plush "type 2" (INT0 PWM)
#else
#error "Unrecognized board type."
#endif
.equ CPU_MHZ = F_CPU / 1000000
.equ BOOT_LOADER = 1 ; Include Turnigy USB linker STK500v2 boot loader on PWM input pin
.equ BOOT_JUMP = 1 ; Jump to any boot loader when PWM input stays high
.equ BOOT_START = THIRDBOOTSTART
.if !defined(COMP_PWM)
.equ COMP_PWM = 0 ; During PWM off, switch high side on (unsafe on some boards!)
.endif
.if !defined(DEAD_LOW_NS)
.equ DEAD_LOW_NS = 300 ; Low-side dead time w/COMP_PWM (62.5ns steps @ 16MHz, max 2437ns)
.equ DEAD_HIGH_NS = 300 ; High-side dead time w/COMP_PWM (62.5ns steps @ 16MHz, max roughly PWM period)
.endif
.equ DEAD_TIME_LOW = DEAD_LOW_NS * CPU_MHZ / 1000
.equ DEAD_TIME_HIGH = DEAD_HIGH_NS * CPU_MHZ / 1000
.if !defined(MOTOR_ADVANCE)
.equ MOTOR_ADVANCE = 18 ; Degrees of timing advance (0 - 30, 30 meaning no delay)
.endif
.if !defined(TIMING_OFFSET)
.equ TIMING_OFFSET = 0 ; Motor timing offset in microseconds
.endif
.equ MOTOR_BRAKE = 0 ; Enable brake during neutral/idle ("motor drag" brake)
.equ LOW_BRAKE = 0 ; Enable brake on very short RC pulse ("thumb" brake like on Airtronics XL2P)
.if !defined(MOTOR_REVERSE)
.equ MOTOR_REVERSE = 0 ; Reverse normal commutation direction
.endif
.equ RC_PULS_REVERSE = 0 ; Enable RC-car style forward/reverse throttle
.equ RC_CALIBRATION = 1 ; Support run-time calibration of min/max pulse lengths
.equ SLOW_THROTTLE = 0 ; Limit maximum throttle jump to try to prevent overcurrent
.equ BEACON = 1 ; Beep periodically when RC signal is lost
.equ BEACON_IDLE = 0 ; Beep periodically if idle for a long period
.if !defined(CHECK_HARDWARE)
.equ CHECK_HARDWARE = 0 ; Check for correct pin configuration, sense inputs, and functioning MOSFETs
.endif
.equ CELL_MAX_DV = 43 ; Maximum battery cell deciV
.equ CELL_MIN_DV = 35 ; Minimum battery cell deciV
.equ CELL_COUNT = 0 ; 0: auto, >0: hard-coded number of cells (for reliable LVC > ~4S)
.equ BLIP_CELL_COUNT = 0 ; Blip out cell count before arming
.equ DEBUG_ADC_DUMP = 0 ; Output an endless loop of all ADC values (no normal operation)
.equ MOTOR_DEBUG = 0 ; Output sync pulses on MOSI or SCK, debug flag on MISO
.equ I2C_ADDR = 0x50 ; MK-style I2C address
.equ MOTOR_ID = 1 ; MK-style I2C motor ID, or UART motor number
.equ RCP_TOT = 2 ; Number of 65536us periods before considering rc pulse lost
; These are now defaults which can be adjusted via throttle calibration
; (stick high, stick low, (stick neutral) at start).
; These might be a bit wide for most radios, but lines up with POWER_RANGE.
.equ STOP_RC_PULS = 1060 ; Stop motor at or below this pulse length
.equ FULL_RC_PULS = 1860 ; Full speed at or above this pulse length
.equ MAX_RC_PULS = 2400 ; Throw away any pulses longer than this
.equ MIN_RC_PULS = 768 ; Throw away any pulses shorter than this
.equ MID_RC_PULS = (STOP_RC_PULS + FULL_RC_PULS) / 2 ; Neutral when RC_PULS_REVERSE = 1
.equ RCP_ALIAS_SHIFT = 3 ; Enable 1/8th PWM input alias ("oneshot125")
.equ BEEP_RCP_ERROR = 0 ; Beep at stop if invalid PWM pulses were received
.if RC_PULS_REVERSE
.equ RCP_DEADBAND = 50 ; Do not start until this much above or below neutral
.equ PROGRAM_RC_PULS = (STOP_RC_PULS + FULL_RC_PULS * 3) / 4 ; Normally 1660
.else
.equ RCP_DEADBAND = 0
.equ PROGRAM_RC_PULS = (STOP_RC_PULS + FULL_RC_PULS) / 2 ; Normally 1460
.endif
.if LOW_BRAKE
.equ RCP_LOW_DBAND = 60 ; Brake at this many microseconds below low pulse
.endif
.equ MAX_DRIFT_PULS = 10 ; Maximum jitter/drift microseconds during programming
; Minimum PWM on-time (too low and FETs won't turn on, hard starting)
.if !defined(MIN_DUTY)
.equ MIN_DUTY = 56 * CPU_MHZ / 16
.endif
; Number of PWM steps (too high and PWM frequency drops into audible range)
.if !defined(POWER_RANGE)
.equ POWER_RANGE = 800 * CPU_MHZ / 16 + MIN_DUTY
.endif
.equ MAX_POWER = (POWER_RANGE-1)
.equ PWR_COOL_START = (POWER_RANGE/24) ; Power limit while starting to reduce heating
.equ PWR_MIN_START = (POWER_RANGE/6) ; Power limit while starting (to start)
.equ PWR_MAX_START = (POWER_RANGE/4) ; Power limit while starting (if still not running)
.equ PWR_MAX_RPM1 = (POWER_RANGE/4) ; Power limit when running slower than TIMING_RANGE1
.equ PWR_MAX_RPM2 = (POWER_RANGE/2) ; Power limit when running slower than TIMING_RANGE2
.equ BRAKE_POWER = MAX_POWER*2/3 ; Brake force is exponential, so start fairly high
.equ BRAKE_SPEED = 3 ; Speed to reach MAX_POWER, 0 (slowest) - 8 (fastest)
.equ LOW_BRAKE_POWER = MAX_POWER*2/3
.equ LOW_BRAKE_SPEED = 5
.equ TIMING_MIN = 0x8000 ; 8192us per commutation
.equ TIMING_RANGE1 = 0x4000 ; 4096us per commutation
.equ TIMING_RANGE2 = 0x2000 ; 2048us per commutation
.equ TIMING_RANGE3 = 0x1000 ; 1024us per commutation
.equ TIMING_MAX = 0x0080 ; 32us per commutation (312,500eRPM)
.equ TIMEOUT_START = 48000 ; Timeout per commutation for ZC during starting
.if !defined(START_DELAY_US)
.equ START_DELAY_US = 0 ; Initial post-commutation wait during starting
.endif
.equ START_DSTEP_US = 8 ; Microseconds per start delay step
.equ START_DELAY_INC = 15 ; Wait step count increase (wraps in a byte)
.equ START_MOD_INC = 4 ; Start power modulation step count increase (wraps in a byte)
.equ START_MOD_LIMIT = 48 ; Value at which power is reduced to avoid overheating
.equ START_FAIL_INC = 16 ; start_tries step count increase (wraps in a byte, upon which we disarm)
.equ ENOUGH_GOODIES = 12 ; This many start cycles without timeout will transition to running mode
.equ ZC_CHECK_FAST = 12 ; Number of ZC check loops under which PWM noise should not matter
.equ ZC_CHECK_MAX = POWER_RANGE / 32 ; Limit ZC checking to about 1/2 PWM interval
.equ ZC_CHECK_MIN = 3
.equ T0CLK = (1<<CS01) ; clk/8 == 2MHz
.equ T1CLK = (1<<CS10)+(USE_ICP<<ICES1)+(USE_ICP<<ICNC1) ; clk/1 == 16MHz
.equ T2CLK = (1<<CS20) ; clk/1 == 16MHz
.equ EEPROM_SIGN = 31337 ; Random 16-bit value
.equ EEPROM_OFFSET = 0x80 ; Offset into 512-byte space (why not)
; Conditional code inclusion
.set DEBUG_TX = 0 ; Output debugging on UART TX pin
.set ADC_READ_NEEDED = 0 ; Reading from ADCs
;**** **** **** **** ****
; Register Definitions
.def temp5 = r0 ; aux temporary (L) (limited operations)
.def temp6 = r1 ; aux temporary (H) (limited operations)
.def duty_l = r2 ; on duty cycle low, one's complement
.def duty_h = r3 ; on duty cycle high
.def off_duty_l = r4 ; off duty cycle low, one's complement
.def off_duty_h = r5 ; off duty cycle high
.def rx_l = r6 ; received throttle low
.def rx_h = r7 ; received throttle high
.def tcnt2h = r8 ; timer2 high byte
.def i_sreg = r9 ; status register save in interrupts
.def temp7 = r10 ; really aux temporary (limited operations)
.def rc_timeout = r11
.def sys_control_l = r12 ; duty limit low (word register aligned)
.def sys_control_h = r13 ; duty limit high
.def timing_duty_l = r14 ; timing duty limit low
.def timing_duty_h = r15 ; timing duty limit high
.def flags0 = r16 ; state flags
.equ OCT1_PENDING = 0 ; if set, output compare interrupt is pending
.equ SET_DUTY = 1 ; if set when armed, set duty during evaluate_rc
.equ RCP_ERROR = 2 ; if set, corrupted PWM input was seen
.equ RCP_ALIAS = 3 ; if set, rc alias (shifted) range is active
.equ EEPROM_RESET = 4 ; if set, reset EEPROM
.equ EEPROM_WRITE = 5 ; if set, save settings to EEPROM
.equ UART_SYNC = 6 ; if set, we are waiting for our serial throttle byte
.equ NO_CALIBRATION = 7 ; if set, disallow calibration (unsafe reset cause)
.def flags1 = r17 ; state flags
.equ POWER_ON = 0 ; if set, switching fets is enabled
.equ FULL_POWER = 1 ; 100% on - don't switch off, but do OFF_CYCLE working
.equ I2C_MODE = 2 ; if receiving updates via I2C
.equ UART_MODE = 3 ; if receiving updates via UART
.equ EVAL_RC = 4 ; if set, evaluate rc command while waiting for OCT1
.equ ACO_EDGE_HIGH = 5 ; if set, looking for ACO high - same bit position as ACO
.equ STARTUP = 6 ; if set, startup-phase is active
.equ REVERSE = 7 ; if set, do reverse commutation
.def flags2 = r18
.equ A_FET = 0 ; if set, A FET is being PWMed
.equ B_FET = 1 ; if set, B FET is being PWMed
.equ C_FET = 2 ; if set, C FET is being PWMed
.equ ALL_FETS = (1<<A_FET)+(1<<B_FET)+(1<<C_FET)
.equ TIMING_FAST = 6 ; if set, timing fits in 16 bits
.equ SKIP_CPWM = 7 ; if set, skip complementary PWM (for short off period)
;.def = r19
.def i_temp1 = r20 ; interrupt temporary
.def i_temp2 = r21 ; interrupt temporary
.def temp3 = r22 ; main temporary (L)
.def temp4 = r23 ; main temporary (H)
.def temp1 = r24 ; main temporary (L), adiw-capable
.def temp2 = r25 ; main temporary (H), adiw-capable
; XL: general temporary
; XH: general temporary
; YL: general temporary
; YH: general temporary
; ZL: Next PWM interrupt vector (low)
; ZH: Next PWM interrupt vector (high, stays at zero) -- used as "zero" register
;**** **** **** **** ****
; RAM Definitions
.dseg ; DATA segment
.org SRAM_START
orig_osccal: .byte 1 ; original OSCCAL value
goodies: .byte 1 ; Number of rounds without timeout
powerskip: .byte 1 ; Skip power through this number of steps
ocr1ax: .byte 1 ; 3rd byte of OCR1A
tcnt1x: .byte 1 ; 3rd byte of TCNT1
pwm_on_ptr: .byte 1 ; Next PWM ON vector
rct_boot: .byte 1 ; Counter which increments while rc_timeout is 0 to jump to boot loader
rct_beacon: .byte 1 ; Counter which increments while rc_timeout is 0 to disarm and beep occasionally
idle_beacon: .byte 1 ; Counter which increments while armed and idle to beep occasionally
last_tcnt1_l: .byte 1 ; last timer1 value
last_tcnt1_h: .byte 1
last_tcnt1_x: .byte 1
l2_tcnt1_l: .byte 1 ; last last timer1 value
l2_tcnt1_h: .byte 1
l2_tcnt1_x: .byte 1
timing_l: .byte 1 ; interval of 2 commutations
timing_h: .byte 1
timing_x: .byte 1
com_time_l: .byte 1 ; time of last commutation
com_time_h: .byte 1
com_time_x: .byte 1
start_delay: .byte 1 ; delay count after starting commutations before checking back-EMF
start_modulate: .byte 1 ; Start modulation counter (to reduce heating from PWR_MAX_START if stuck)
start_fail: .byte 1 ; Number of start_modulate loops for eventual failure and disarm
rcp_beep_count: .byte 1 ; Number of RC pulse error beeps
rc_duty_l: .byte 1 ; desired duty cycle
rc_duty_h: .byte 1
fwd_scale_l: .byte 1 ; 16.16 multipliers to scale input RC pulse to POWER_RANGE
fwd_scale_h: .byte 1
rev_scale_l: .byte 1
rev_scale_h: .byte 1
neutral_l: .byte 1 ; Offset for neutral throttle (in CPU_MHZ)
neutral_h: .byte 1
.if RCP_DEADBAND && defined(RCP_ALIAS_SHIFT)
deadband_l: .byte 1 ; Deadband scaled for possible input alias
deadband_h: .byte 1
.endif
.if LOW_BRAKE
low_brake_l: .byte 1 ; Low brake position with deadband applied
low_brake_h: .byte 1
.endif
.if USE_I2C
i2c_max_pwm: .byte 1 ; MaxPWM for MK (NOTE: 250 while stopped is magic and enables v2)
i2c_rx_state: .byte 1
i2c_blc_offset: .byte 1
.endif
motor_count: .byte 1 ; Motor number for serial control
brake_sub: .byte 1 ; Brake speed subtrahend (power of two)
brake_want: .byte 1 ; Type of brake desired
brake_active: .byte 1 ; Type of brake active
;**** **** **** **** ****
; The following entries are block-copied from/to EEPROM
eeprom_sig_l: .byte 1
eeprom_sig_h: .byte 1
puls_high_l: .byte 1 ; -,
puls_high_h: .byte 1 ; |
puls_low_l: .byte 1 ; |- saved pulse lengths during throttle calibration
puls_low_h: .byte 1 ; | (order used by rc_prog)
puls_neutral_l: .byte 1 ; |
puls_neutral_h: .byte 1 ; -'
.if USE_I2C
blc_revision: .byte 1 ; BLConfig revision
blc_setmask: .byte 1 ; BLConfig settings mask
blc_pwmscaling: .byte 1 ; BLConfig pwm scaling
blc_currlimit: .byte 1 ; BLConfig current limit
blc_templimit: .byte 1 ; BLConfig temperature limit
blc_currscale: .byte 1 ; BLConfig current scaling
blc_bitconfig: .byte 1 ; BLConfig bitconfig (1 == MOTOR_REVERSE)
blc_checksum: .byte 1 ; BLConfig checksum (0xaa + above bytes)
.endif
eeprom_end: .byte 1
;-----bko-----------------------------------------------------------------
;**** **** **** **** ****
.cseg
.org 0
;**** **** **** **** ****
; ATmega8 interrupts
;.equ INT0addr=$001 ; External Interrupt0 Vector Address
;.equ INT1addr=$002 ; External Interrupt1 Vector Address
;.equ OC2addr =$003 ; Output Compare2 Interrupt Vector Address
;.equ OVF2addr=$004 ; Overflow2 Interrupt Vector Address
;.equ ICP1addr=$005 ; Input Capture1 Interrupt Vector Address
;.equ OC1Aaddr=$006 ; Output Compare1A Interrupt Vector Address
;.equ OC1Baddr=$007 ; Output Compare1B Interrupt Vector Address
;.equ OVF1addr=$008 ; Overflow1 Interrupt Vector Address
;.equ OVF0addr=$009 ; Overflow0 Interrupt Vector Address
;.equ SPIaddr =$00a ; SPI Interrupt Vector Address
;.equ URXCaddr=$00b ; USART Receive Complete Interrupt Vector Address
;.equ UDREaddr=$00c ; USART Data Register Empty Interrupt Vector Address
;.equ UTXCaddr=$00d ; USART Transmit Complete Interrupt Vector Address
;.equ ADCCaddr=$00e ; ADC Interrupt Vector Address
;.equ ERDYaddr=$00f ; EEPROM Interrupt Vector Address
;.equ ACIaddr =$010 ; Analog Comparator Interrupt Vector Address
;.equ TWIaddr =$011 ; Irq. vector address for Two-Wire Interface
;.equ SPMaddr =$012 ; SPM complete Interrupt Vector Address
;.equ SPMRaddr =$012 ; SPM complete Interrupt Vector Address
;-----bko-----------------------------------------------------------------
; Reset and interrupt jump table
; When multiple interrupts are pending, the vectors are executed from top
; (ext_int0) to bottom.
rjmp reset ; reset
rjmp rcp_int ; ext_int0
reti ; ext_int1
reti ; t2oc_int
ijmp ; t2ovfl_int
rjmp rcp_int ; icp1_int
rjmp t1oca_int ; t1oca_int
reti ; t1ocb_int
rjmp t1ovfl_int ; t1ovfl_int
reti ; t0ovfl_int
reti ; spi_int
rjmp urxc_int ; urxc
reti ; udre
reti ; utxc
reti ; adc_int
reti ; eep_int
reti ; aci_int
rjmp i2c_int ; twi_int
reti ; spmc_int
eeprom_defaults_w:
.db low(EEPROM_SIGN), high(EEPROM_SIGN)
.db byte1(FULL_RC_PULS * CPU_MHZ), byte2(FULL_RC_PULS * CPU_MHZ)
.db byte1(STOP_RC_PULS * CPU_MHZ), byte2(STOP_RC_PULS * CPU_MHZ)
.db byte1(MID_RC_PULS * CPU_MHZ), byte2(MID_RC_PULS * CPU_MHZ)
.if USE_I2C
.equ BL_REVISION = 2
.db BL_REVISION, 144 ; Revision, SetMask -- Settings mask should encode MOTOR_REVERSE bit
.db 255, 255 ; PwmScaling, CurrentLimit
.db 127, 0 ; TempLimit, CurrentScaling
.db 0, byte1(0xaa + BL_REVISION + 144 + 255 + 255 + 127 + 0 + 0) ; BitConfig, crc (0xaa + sum of above bytes)
.endif
;-- Instruction extension macros -----------------------------------------
; Add any 16-bit immediate to a register pair (@0:@1 += @2), no Z flag
.macro adi2
.if byte1(-@2)
subi @0, byte1(-@2)
sbci @1, byte1(-byte2(@2 + 0xff))
.else
subi @1, byte1(-byte2(@2 + 0xff))
.endif
.endmacro
; Smaller version for r24 and above, Z flag not reliable
.macro adiwx
.if !(@2 & 0xff) || (@2) & ~0x3f
adi2 @0, @1, @2
.else
adiw @0, @2
.endif
.endmacro
; Compare any 16-bit immediate from a register pair (@0:@1 -= @2, maybe clobbering @3)
.macro cpiz2
cpi @0, byte1(@2)
.if byte2(@2)
ldi @3, byte2(@2)
cpc @1, @3
.else
cpc @1, ZH
.endif
.endmacro
; Compare any 16-bit immediate from a register pair (@0:@1 -= @2, maybe clobbering @3), no Z flag
; Do not follow by Z flag tests like breq, brne, brlt, brge, brlo, brsh!
; The idea here is that the low byte being compared with (subtracted by)
; 0 will never set carry, so skipping it and cpi'ing the high byte is the
; same other than the result of the Z flag.
.macro cpi2
.if byte1(@2)
cpiz2 @0, @1, @2, @3
.else
cpi @1, byte2(@2)
.endif
.endmacro
; Compare any 24-bit immediate from a register triplet (@0:@1:@2 -= @3, maybe clobbering @4)
.macro cpiz3
cpi @0, byte1(@3)
.if byte2(@3)
ldi @4, byte2(@3)
cpc @1, @4
.else
cpc @1, ZH
.endif
.if byte3(@3)
ldi @4, byte3(@3)
cpc @2, @4
.else
cpc @2, ZH
.endif
.endmacro
; Compare any 24-bit immediate from a register triplet (@0:@1:@2 -= @3, maybe clobbering @4)
; May not set Z flag, as above.
.macro cpi3
.if byte1(@3)
cpiz3 @0, @1, @2, @3, @4
.else
cpi2 @1, @2, @3 >> 8, @4
.endif
.endmacro
; Subtract any 16-bit immediate from a register pair (@0:@1 -= @2), no Z flag
.macro sbi2
.if byte1(@2)
subi @0, byte1(@2)
sbci @1, byte2(@2)
.else
subi @1, byte2(@2)
.endif
.endmacro
; Smaller version for r24 and above, Z flag not reliable
.macro sbiwx
.if !(@2 & 0xff) || (@2) & ~0x3f
sbi2 @0, @1, @2
.else
sbiw @0, @2
.endif
.endmacro
; Load 2-byte immediate
.macro ldi2
ldi @0, byte1(@2)
ldi @1, byte2(@2)
.endmacro
; Load 3-byte immediate
.macro ldi3
ldi @0, byte1(@3)
ldi @1, byte2(@3)
ldi @2, byte3(@3)
.endmacro
; Register out to any address (memory-mapped if necessary)
.macro outr
.if @0 < 64
out @0, @1
.else
sts @0, @1
.endif
.endmacro
; Register in from any address (memory-mapped if necessary)
.macro inr
.if @1 < 64
in @0, @1
.else
lds @0, @1
.endif
.endmacro
; Immediate out to any port (possibly via @2 as a temporary)
.macro outi
.if @1
ldi @2, @1
outr @0, @2
.else
outr @0, ZH
.endif
.endmacro
;-- LED macros -----------------------------------------------------------
.if !defined(red_led)
.macro RED_on
.endmacro
.macro RED_off
.endmacro
.endif
.if !defined(green_led)
.macro GRN_on
.endmacro
.macro GRN_off
.endmacro
.endif
.if !defined(blue_led)
.macro BLUE_on
.endmacro
.macro BLUE_off
.endmacro
.endif
;-- FET driving macros ---------------------------------------------------
; Careful: "if" conditions split over multiple lines (with backslashes)
; work with arva, but avrasm2.exe silently produces wrong results.
.if !defined(HIGH_SIDE_PWM)
.equ HIGH_SIDE_PWM = 0
.endif
.if defined(AnFET)
; Traditional direct high and low side drive, inverted if INIT_Px is set.
; Dead-time insertion is supported for COMP_PWM.
.equ CPWM_SOFT = COMP_PWM
.macro FET_on
.if (INIT_PB & ((@0 == PORTB) << @1)) | (INIT_PC & ((@0 == PORTC) << @1)) | (INIT_PD & ((@0 == PORTD) << @1))
cbi @0, @1
.else
sbi @0, @1
.endif
.endmacro
.macro FET_off
.if (INIT_PB & ((@0 == PORTB) << @1)) | (INIT_PC & ((@0 == PORTC) << @1)) | (INIT_PD & ((@0 == PORTD) << @1))
sbi @0, @1
.else
cbi @0, @1
.endif
.endmacro
.macro AnFET_on
FET_on AnFET_port, AnFET
.endmacro
.macro AnFET_off
FET_off AnFET_port, AnFET
.endmacro
.macro ApFET_on
FET_on ApFET_port, ApFET
.endmacro
.macro ApFET_off
FET_off ApFET_port, ApFET
.endmacro
.macro BnFET_on
FET_on BnFET_port, BnFET
.endmacro
.macro BnFET_off
FET_off BnFET_port, BnFET
.endmacro
.macro BpFET_on
FET_on BpFET_port, BpFET
.endmacro
.macro BpFET_off
FET_off BpFET_port, BpFET
.endmacro
.macro CnFET_on
FET_on CnFET_port, CnFET
.endmacro
.macro CnFET_off
FET_off CnFET_port, CnFET
.endmacro
.macro CpFET_on
FET_on CpFET_port, CpFET
.endmacro
.macro CpFET_off
FET_off CpFET_port, CpFET
.endmacro
.macro PWM_FOCUS_A_on
.if COMP_PWM
cpse temp3, temp4
PWM_COMP_A_on
.endif
.endmacro
.macro PWM_FOCUS_A_off
.if COMP_PWM
in temp3, PWM_COMP_A_PORT_in
PWM_COMP_A_off
in temp4, PWM_COMP_A_PORT_in
.endif
.endmacro
.macro PWM_FOCUS_B_on
.if COMP_PWM
cpse temp3, temp4
PWM_COMP_B_on
.endif
.endmacro
.macro PWM_FOCUS_B_off
.if COMP_PWM
in temp3, PWM_COMP_B_PORT_in
PWM_COMP_B_off
in temp4, PWM_COMP_B_PORT_in
.endif
.endmacro
.macro PWM_FOCUS_C_on
.if COMP_PWM
cpse temp3, temp4
PWM_COMP_C_on
.endif
.endmacro
.macro PWM_FOCUS_C_off
.if COMP_PWM
in temp3, PWM_COMP_C_PORT_in
PWM_COMP_C_off
in temp4, PWM_COMP_C_PORT_in
.endif
.endmacro
; For PWM state mirroring in commutation routines
.if HIGH_SIDE_PWM
.equ PWM_A_PORT_in = ApFET_port
.equ PWM_B_PORT_in = BpFET_port
.equ PWM_C_PORT_in = CpFET_port
.equ PWM_COMP_A_PORT_in = AnFET_port
.equ PWM_COMP_B_PORT_in = BnFET_port
.equ PWM_COMP_C_PORT_in = CnFET_port
.else
.equ PWM_A_PORT_in = AnFET_port
.equ PWM_B_PORT_in = BnFET_port
.equ PWM_C_PORT_in = CnFET_port
.equ PWM_COMP_A_PORT_in = ApFET_port
.equ PWM_COMP_B_PORT_in = BpFET_port
.equ PWM_COMP_C_PORT_in = CpFET_port
.endif
.macro PWM_ALL_off
.if HIGH_SIDE_PWM
all_pFETs_off @0
.else
all_nFETs_off @0
.endif
.endmacro
.macro all_pFETs_off
.if ApFET_port != BpFET_port || ApFET_port != CpFET_port
ApFET_off
BpFET_off
CpFET_off
.else
in @0, ApFET_port
.if (INIT_PB & ((ApFET_port == PORTB) << ApFET)) | (INIT_PC & ((ApFET_port == PORTC) << ApFET)) | (INIT_PD & ((ApFET_port == PORTD) << ApFET))
sbr @0, (1<<ApFET)+(1<<BpFET)+(1<<CpFET)
.else
cbr @0, (1<<ApFET)+(1<<BpFET)+(1<<CpFET)
.endif
out ApFET_port, @0
.endif
.endmacro
.macro all_nFETs_off
.if AnFET_port != BnFET_port || AnFET_port != CnFET_port
AnFET_off
BnFET_off
CnFET_off
.else
in @0, AnFET_port
.if (INIT_PB & ((AnFET_port == PORTB) << AnFET)) | (INIT_PC & ((AnFET_port == PORTC) << AnFET)) | (INIT_PD & ((AnFET_port == PORTD) << AnFET))
sbr @0, (1<<AnFET)+(1<<BnFET)+(1<<CnFET)
.else
cbr @0, (1<<AnFET)+(1<<BnFET)+(1<<CnFET)
.endif
out AnFET_port, @0
.endif
.endmacro
.macro nFET_brake
.if AnFET_port != BnFET_port || AnFET_port != CnFET_port
AnFET_on
BnFET_on
CnFET_on
.else
in @0, AnFET_port
.if (INIT_PB & ((AnFET_port == PORTB) << AnFET)) | (INIT_PC & ((AnFET_port == PORTC) << AnFET)) | (INIT_PD & ((AnFET_port == PORTD) << AnFET))
cbr @0, (1<<AnFET)+(1<<BnFET)+(1<<CnFET)
.else
sbr @0, (1<<AnFET)+(1<<BnFET)+(1<<CnFET)
.endif
out AnFET_port, @0
.endif
.endmacro
.elif defined(ENABLE_ALL)
; Three logic level PWM/ENABLE-style driver, with diode emulation mode or
; off state at the middle level on the PWM pin. This is accomplished by
; setting a pull-up rather than drive high. With this method, every FET
; toggle can be a single I/O instruction, rather than having to select
; high or low in advance to toggling enable. The following macros are used:
;
; XnFET_on -> cbi PWM_X_PORT, PWM_X (drain through ext pull-down)
; XnFET_off -> sbi PWM_X_PORT, PWM_X (pull-up pin with ext pull-down)
; XpFET_on -> sbi PWM_X_DDR, PWM_X (drive-up pin)
; XpFET_off -> cbi PWM_X_DDR, PWM_X (pull-up pin with ext pull-down)
;
; COMP_PWM on these is done in hardware rather than software, so we can
; just toggle the PORT value after PWM_FOCUS sets DDR (output mode).
; This results in the following macro arrangement:
;
; TRI CPWM HIGH_SIDE_PWM : PWM ON PWM OFF PWM_X_PORT_in
; 0 0 0 : XnFET_on XnFET_off XnFET_port
; 0 0 1 : XpFET_on XpFET_off XpFET_port
; 0 1 0 : XnFET_on XnFET_off XnFET_port
; 0 1 1 : XpFET_on XpFET_off XpFET_port
; 1 0 0 : XnFET_on XnFET_off PWM_X_PORT
; 1 0 1 : XpFET_on XpFET_off PWM_X_DDR
; 1 1 0 : XnFET_on XnFET_off PWM_X_PORT
; 1 1 1 : XnFET_off XnFET_on PWM_X_PORT
;
; For the last case, PWM_X_off actually turns low side on which isn't how
; we want to leave the phase after commutating. PWM_X_clear will take care
; of this.
;
; We leave ENABLE high once initialized as some drivers will actually
; shut down rather than just using the input as a logic gate.
;
; We prefer HIGH_SIDE_PWM as diode emulation mode in these drivers
; typically allows active freewheeling only in this orientation.
.equ CPWM_SOFT = 0
.macro AnFET_on
cbi PWM_A_PORT, PWM_A
.endmacro
.macro AnFET_off
sbi PWM_A_PORT, PWM_A
.endmacro
.macro ApFET_on
sbi PWM_A_DDR, PWM_A
.endmacro
.macro ApFET_off
cbi PWM_A_DDR, PWM_A
.endmacro
.macro BnFET_on
cbi PWM_B_PORT, PWM_B
.endmacro
.macro BnFET_off
sbi PWM_B_PORT, PWM_B
.endmacro
.macro BpFET_on
sbi PWM_B_DDR, PWM_B
.endmacro
.macro BpFET_off
cbi PWM_B_DDR, PWM_B
.endmacro
.macro CnFET_on
cbi PWM_C_PORT, PWM_C
.endmacro
.macro CnFET_off
sbi PWM_C_PORT, PWM_C
.endmacro
.macro CpFET_on
sbi PWM_C_DDR, PWM_C
.endmacro
.macro CpFET_off
cbi PWM_C_DDR, PWM_C
.endmacro
.macro PWM_FOCUS_A_on
.if COMP_PWM
sbrc flags1, POWER_ON
ApFET_on
.endif
.endmacro
.macro PWM_FOCUS_A_off
.if COMP_PWM
ApFET_off
.endif
.endmacro
.macro PWM_FOCUS_B_on
.if COMP_PWM
sbrc flags1, POWER_ON
BpFET_on
.endif
.endmacro
.macro PWM_FOCUS_B_off
.if COMP_PWM
BpFET_off
.endif
.endmacro
.macro PWM_FOCUS_C_on
.if COMP_PWM
sbrc flags1, POWER_ON
CpFET_on
.endif
.endmacro
.macro PWM_FOCUS_C_off
.if COMP_PWM
CpFET_off
.endif
.endmacro
; For PWM state mirroring in commutation routines
.if COMP_PWM || !HIGH_SIDE_PWM
.equ PWM_A_PORT_in = PWM_A_PORT
.equ PWM_B_PORT_in = PWM_B_PORT
.equ PWM_C_PORT_in = PWM_C_PORT
.else
.equ PWM_A_PORT_in = PWM_A_DDR
.equ PWM_B_PORT_in = PWM_B_DDR
.equ PWM_C_PORT_in = PWM_C_DDR
.endif
.macro PWM_ALL_off
all_nFETs_off @0
.endmacro
.macro all_pFETs_off
.if PWM_A_DDR != PWM_B_DDR || PWM_A_DDR != PWM_C_DDR
ApFET_off
BpFET_off
CpFET_off
.else
in @0, PWM_A_DDR
cbr @0, (1<<PWM_A)+(1<<PWM_B)+(1<<PWM_C)
out PWM_A_DDR, @0
.endif
.endmacro
.macro all_nFETs_off
.if PWM_A_PORT != PWM_B_PORT || PWM_A_PORT != PWM_C_PORT
AnFET_off
BnFET_off
CnFET_off
.else
in @0, PWM_A_PORT
sbr @0, (1<<PWM_A)+(1<<PWM_B)+(1<<PWM_C)
out PWM_A_PORT, @0
.endif
.endmacro
.macro nFET_brake
.if PWM_A_PORT != PWM_B_PORT || PWM_A_PORT != PWM_C_PORT
AnFET_on
BnFET_on
CnFET_on
.else
in @0, PWM_A_PORT
cbr @0, (1<<PWM_A)+(1<<PWM_B)+(1<<PWM_C)
out PWM_A_PORT, @0
.endif
.endmacro
.endif
;-- Commutation drive macros ---------------------------------------------
.if HIGH_SIDE_PWM
.macro COMMUTATE_A_on
AnFET_on
.endmacro
.macro COMMUTATE_A_off
AnFET_off
.endmacro
.macro COMMUTATE_B_on
BnFET_on
.endmacro
.macro COMMUTATE_B_off
BnFET_off
.endmacro
.macro COMMUTATE_C_on
CnFET_on