/*------------------------------------------------------------------------- SST89x5xRDx.h Register Declarations for SST SST89E516RD2, ST89E516RD, SST89V516RD2, and SST89V516RD Processors (Based on datasheed S71273-03-000 1/07) Copyright (C) 2007, Jesus Calvino-Fraga / jesusc at ece.ubc.ca This library 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 2, or (at your option) any later version. This library 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 library; see the file COPYING. If not, write to the Free Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. As a special exception, if you link this library with other files, some of which are compiled with SDCC, to produce an executable, this library does not by itself cause the resulting executable to be covered by the GNU General Public License. This exception does not however invalidate any other reasons why the executable file might be covered by the GNU General Public License. -------------------------------------------------------------------------*/ #ifndef REG_SST89x5xRDx_H #define REG_SST89x5xRDx_H #include // From TABLE 3-5: CPU related SFRs SFR(ACC, 0xE0); // Accumulator SBIT(ACC_0, 0xE0, 0); // Accumulator bit 0 SBIT(ACC_1, 0xE0, 1); // Accumulator bit 1 SBIT(ACC_2, 0xE0, 2); // Accumulator bit 2 SBIT(ACC_3, 0xE0, 3); // Accumulator bit 3 SBIT(ACC_4, 0xE0, 4); // Accumulator bit 4 SBIT(ACC_5, 0xE0, 5); // Accumulator bit 5 SBIT(ACC_6, 0xE0, 6); // Accumulator bit 6 SBIT(ACC_7, 0xE0, 7); // Accumulator bit 7 SFR(B, 0xF0); // B Register SBIT(B_0, 0xF0, 0); // Register B bit 0 SBIT(B_1, 0xF0, 1); // Register B bit 1 SBIT(B_2, 0xF0, 2); // Register B bit 2 SBIT(B_3, 0xF0, 3); // Register B bit 3 SBIT(B_4, 0xF0, 4); // Register B bit 4 SBIT(B_5, 0xF0, 5); // Register B bit 5 SBIT(B_6, 0xF0, 6); // Register B bit 6 SBIT(B_7, 0xF0, 7); // Register B bit 7 SFR(PSW, 0xD0); // Program Status Word SBIT(P, 0xD0, 0); // Parity Flag SBIT(F1, 0xD0, 1); // User-Defined Flag SBIT(OV, 0xD0, 2); // Overflow Flag SBIT(RS0, 0xD0, 3); // Register Bank Select 0 SBIT(RS1, 0xD0, 4); // Register Bank Select 1 SBIT(F0, 0xD0, 5); // User-Defined Flag SBIT(AC, 0xD0, 6); // Auxiliary Carry Flag SBIT(CY, 0xD0, 7); // Carry Flag SFR(SP, 0x81); // Stack Pointer SFR(DPL, 0x82); // Data Pointer Low SFR(DPH, 0x83); // Data Pointer High SFR(IE, 0xA8); // Interrupt Enable SBIT(EA, 0xA8, 7); // Global Interrupt Enable SBIT(EC, 0xA8, 6); // PCA Interrupt Enable SBIT(ET2, 0xA8, 5); // Timer 2 Interrupt Enable SBIT(ES, 0xA8, 4); // Serial Interrupt Enable SBIT(ET1, 0xA8, 3); // Timer 1 Interrupt Enable SBIT(EX1, 0xA8, 2); // External 1 Interrupt Enable SBIT(ET0, 0xA8, 1); // Timer 0 Interrupt Enable SBIT(EX0, 0xA8, 0); // External 0 Interrupt Enable SFR(IEA, 0xE8); // Interrupt Enable A SBIT(EBO, 0xE8, 3); // Brown-out Interrupt Enable. (Vector is 0x00b4) SFR(IP, 0xB8); // Interrupt Priority Reg SBIT(PPC, 0xB8, 6); // PCA interrupt priority bit SBIT(PT2, 0xB8, 5); // Timer 2 interrupt priority bit SBIT(PS, 0xB8, 4); // Serial Port interrupt priority bit SBIT(PT1, 0xB8, 3); // Timer 1 interrupt priority bit SBIT(PX1, 0xB8, 2); // External interrupt 1 priority bit SBIT(PT0, 0xB8, 1); // Timer 0 interrupt priority bit SBIT(PX0, 0xB8, 0); // External interrupt 0 priority bit SFR(IPH, 0xB7); // Interrupt Priority Reg High #define PPCH 0x40 // PCA Interrupt Priority High Bit #define PT2H 0x20 // Timer 2 Interrupt Interrupt Priority High Bit #define PSH 0x10 // Serial Port Interrupt Priority High Bit #define PT1H 0x08 // Timer 1 Interrupt Priority High Bit #define PX1H 0x04 // External Interrupt 1 Priority High Bit #define PT0H 0x02 // Timer 0 Interrupt Priority High Bit #define PX0H 0x01 // External Interrupt 0 Priority High Bit SFR(IP1, 0xF8); // Interrupt Priority Reg A SBIT(PBO, 0xF8, 4); // Brown-out interrupt priority bit SBIT(PX2, 0xF8, 1); // External Interrupt 2 priority bit SBIT(PX3, 0xF8, 2); // External Interrupt 3 priority bit SFR(IP1H, 0xF7); // Interrupt Priority Reg A High #define PBOH 0x08 // Brown-out Interrupt priority bit high #define PX2H 0x02 // External Interrupt 2 priority bit high #define PX3H 0x04 // External Interrupt 3 priority bit high SFR(PCON, 0x87); // Power Control #define SMOD1 0x80 // Double Baud rate bit #define SMOD0 0x40 // FE/SM0 Selection bit #define BOF 0x20 // Brown-out detection status bit #define POF 0x10 // Power-on reset status bit #define GF1 0x08 // General-purpose flag bit #define GF0 0x04 // General-purpose flag bit #define PD 0x02 // Power-down bit #define IDL 0x01 // Idle mode bit SFR(AUXR, 0x8E); // Auxiliary Reg #define EXTRAM 0x02 // Internal/External RAM access #define AO 0x01 // Disable/Enable ALE SFR(AUXR1, 0xA2); // Auxiliary Reg 1 #define GF2 0x08 // General purpose user-defined flag #define DPS 0x01 // DPTR registers select bit SFR(XICON, 0xAE); // External Interrupt Control #define EX2 0x04 #define IE2 0x02 #define IT2 0x01 #define EX3 0x40 #define IE3 0x20 #define IT3 0x10 // TABLE 3-6: Flash Memory Programming SFRs SFR(SFCF, 0xB1); // SuperFlash Configuration #define IAPEN 0x40 // Enable IAP operation #define SWR 0x02 // Software Reset #define BSEL 0x01 // Program memory block switching bit SFR(SFCM, 0xB2); // SuperFlash Command #define FIE 0x80 // Flash Interrupt Enable #define CHIP_ERASE 0x01 #define SECTOR_ERASE 0x0B #define BLOCK_ERASE 0x0D #define BYTE_VERIFY 0x0C #define BYTE_PROGRAM 0x0E #define PROG_SB1 0x0F #define PROG_SB2 0x03 #define PROG_SB3 0x05 #define PROG_SC0 0x09 #define ENABLE_CLOCK_DOUBLE 0x08 SFR(SFAL, 0xB3); // SuperFlash Address Low Register - A7 to A0 SFR(SFAH, 0xB4); // SuperFlash Address High Register - A15 to A8 SFR(SFDT, 0xB5); // SuperFlash Data Register SFR(SFST, 0xB6); // SuperFlash Status #define SB1_i 0x80 // Security Bit 1 status (inverse of SB1 bit) #define SB2_i 0x40 // Security Bit 2 status (inverse of SB2 bit) #define SB3_i 0x20 // Security Bit 3 status (inverse of SB3 bit) #define EDC_i 0x08 // Double Clock Status #define FLASH_BUSY 0x04 // Flash operation completion polling bit // TABLE 3-7: Watchdog Timer SFRs SFR(WDTC, 0xC0); // Watchdog Timer Control SBIT(WDOUT, 0xC0, 4); // Watchdog output enable SBIT(WDRE, 0xC0, 3); // Watchdog timer reset enable SBIT(WDTS, 0xC0, 2); // Watchdog timer reset flag SBIT(WDT, 0xC0, 1); // Watchdog timer refresh SBIT(SWDT, 0xC0, 0); // Start watchdog timer SFR(WDTD, 0x85); // Watchdog Timer Data/Reload // TABLE 3-8: Timer/Counters SFRs SFR(TMOD, 0x89); // Timer/Counter Mode Control GATE C/T# M1 M0 GATE C/T# M1 M0 #define GATE1 0x80 // External enable for timer 1 #define C_T1 0x40 // Timer or counter select for timer 1 #define M1_1 0x20 // Operation mode bit 1 for timer 1 #define M0_1 0x10 // Operation mode bit 0 for timer 1 #define GATE0 0x08 // External enable for timer 0 #define C_T0 0x04 // Timer or counter select for timer 0 #define M1_0 0x02 // Operation mode bit 1 for timer 0 #define M0_0 0x01 // Operation mode bit 0 for timer 0 SFR(TCON, 0x88); // Timer/Counter Control TF1 TR1 TF0 TR0 IE1 IT1 IE0 IT0 SBIT(TF1, 0x88, 7); // Timer 1 overflow flag SBIT(TR1, 0x88, 6); // Timer 1 run control flag SBIT(TF0, 0x88, 5); // Timer 0 overflow flag SBIT(TR0, 0x88, 4); // Timer 0 run control flag SBIT(IE1, 0x88, 3); // Interrupt 1 flag SBIT(IT1, 0x88, 2); // Interrupt 1 type control bit SBIT(IE0, 0x88, 1); // Interrupt 0 flag SBIT(IT0, 0x88, 0); // Interrupt 0 type control bit SFR(TH0, 0x8C); // Timer 0 MSB SFR(TL0, 0x8A); // Timer 0 LSB SFR(TH1, 0x8D); // Timer 1 MSB SFR(TL1, 0x8B); // Timer 1 LSB SFR(T2CON, 0xC8); // Timer / Counter 2 Control SBIT(TF2, 0xC8, 7); // Timer 2 overflow flag SBIT(EXF2, 0xC8, 6); // Timer 2 external flag SBIT(RCLK, 0xC8, 5); // Receive clock flag SBIT(TCLK, 0xC8, 4); // Transmit clock flag SBIT(EXEN2, 0xC8, 3); // Timer 2 external enable flag SBIT(TR2, 0xC8, 2); // Start/stop control for timer 2 SBIT(C_T2, 0xC8, 1); // Timer or coutner select SBIT(CP_RL2,0xC8, 0); // Capture/reload flag SFR(T2MOD, 0xC9); // Timer 2 Mode Control #define DCEN 0x02 // Down count enable bit #define T2OE 0x01 // Timer 2 output enable bit SFR(TH2, 0xCD); // Timer 2 MSB SFR(TL2, 0xCC); // Timer 2 LSB SFR(RCAP2H, 0xCB); // Timer 2 Capture MSB SFR(RCAP2L, 0xCA); // Timer 2 Capture LSB // TABLE 3-9: Interface SFRs SFR(SBUF, 0x99); // Serial Data Buffer SFR(SCON, 0x98); // Serial Port Control SBIT(FE, 0x98, 7); // Framing Error when reading, SM0 when writing SBIT(SM0, 0x98, 7); // Serial Port Mode Bit 0 SBIT(SM1, 0x98, 6); // Serial Port Mode Bit 1 SBIT(SM2, 0x98, 5); // Serial Port Mode Bit 2 SBIT(REN, 0x98, 4); // Enables serial reception SBIT(TB8, 0x98, 3); // The 9th data bit that will be transmitted in Modes 2 and 3 SBIT(RB8, 0x98, 2); // In Modes 2 and 3, the 9th data bit that was received SBIT(TI, 0x98, 1); // Transmit interrupt flag SBIT(RI, 0x98, 0); // Receive interrupt flag SFR(SADDR, 0xA9); // Slave Address SFR(SADEN, 0xB9); // Slave Address Mask SFR(SPCR, 0xD5); // SPI Control Register #define SPIE 0x80 // If both SPIE and ES are set to one, SPI interrupts are enabled #define SPE 0x40 // SPI enable bit. When set enables SPI #define DORD 0x20 // Data trans. order. 0=MSB first; 1=LSB first #define MSTR 0x10 // 1=master mode. 0=slave mode #define CPOL 0x08 // 1=SCK is high when idle (active low), 0=SCK is low when idle (active high) #define CPHA 0x04 // 1=shift triggered on the trailing edge of SCK. 0=shift trig. on leading edge #define SPR1 0x02 // SPI Clork Rate select bit 1 #define SPR0 0x01 // SPI Clork Rate select bit 0 // 00 = Fosc/4 // 01 = Fosc/16 // 10 = Fosc/64 // 11 = Fosc/128 SFR(SPSR, 0xAA); // SPI Status Register #define SPIF 0x80 // SPI interrupt flag #define WCOL 0x40 // Write collision Flag SFR(SPDR, 0x86); // SPI Data Register SFR(P0, 0x80); // Port 0 SBIT(P0_0, 0x80, 0); // Port 0 bit 0 SBIT(P0_1, 0x80, 1); // Port 0 bit 1 SBIT(P0_2, 0x80, 2); // Port 0 bit 2 SBIT(P0_3, 0x80, 3); // Port 0 bit 3 SBIT(P0_4, 0x80, 4); // Port 0 bit 4 SBIT(P0_5, 0x80, 5); // Port 0 bit 5 SBIT(P0_6, 0x80, 6); // Port 0 bit 6 SBIT(P0_7, 0x80, 7); // Port 0 bit 7 SFR(P1, 0x90); // Port 1 SBIT(P1_0, 0x90, 0); // Port 1 bit 0 SBIT(P1_1, 0x90, 1); // Port 1 bit 1 SBIT(P1_2, 0x90, 2); // Port 1 bit 2 SBIT(P1_3, 0x90, 3); // Port 1 bit 3 SBIT(P1_4, 0x90, 4); // Port 1 bit 4 SBIT(P1_5, 0x90, 5); // Port 1 bit 5 SBIT(P1_6, 0x90, 6); // Port 1 bit 6 SBIT(P1_7, 0x90, 7); // Port 1 bit 7 // Alternate names SBIT(T2, 0x90, 0); // Port 1 bit 0 SBIT(T2EX, 0x90, 1); // Port 1 bit 1 SBIT(ECI, 0x90, 2); // Port 1 bit 2 SBIT(CEX0, 0x90, 3); // Port 1 bit 3 SBIT(CEX1, 0x90, 4); // Port 1 bit 4 SBIT(CEX2, 0x90, 5); // Port 1 bit 5 SBIT(CEX3, 0x90, 6); // Port 1 bit 6 SBIT(CEX4, 0x90, 7); // Port 1 bit 7 // More alternate names SBIT(SS, 0x90, 4); // Port 1 bit 4 SBIT(MOSI, 0x90, 5); // Port 1 bit 5 SBIT(MISO, 0x90, 6); // Port 1 bit 6 SBIT(SCK, 0x90, 7); // Port 1 bit 7 SFR(P2, 0xA0); // Port 2 SBIT(P2_0, 0xA0, 0); // Port 2 bit 0 SBIT(P2_1, 0xA0, 1); // Port 2 bit 1 SBIT(P2_2, 0xA0, 2); // Port 2 bit 2 SBIT(P2_3, 0xA0, 3); // Port 2 bit 3 SBIT(P2_4, 0xA0, 4); // Port 2 bit 4 SBIT(P2_5, 0xA0, 5); // Port 2 bit 5 SBIT(P2_6, 0xA0, 6); // Port 2 bit 6 SBIT(P2_7, 0xA0, 7); // Port 2 bit 7 SFR(P3, 0xB0); // Port 3 SBIT(P3_0, 0xB0, 0); // Port 2 bit 0 SBIT(P3_1, 0xB0, 1); // Port 2 bit 1 SBIT(P3_2, 0xB0, 2); // Port 2 bit 2 SBIT(P3_3, 0xB0, 3); // Port 2 bit 3 SBIT(P3_4, 0xB0, 4); // Port 2 bit 4 SBIT(P3_5, 0xB0, 5); // Port 2 bit 5 SBIT(P3_6, 0xB0, 6); // Port 2 bit 6 SBIT(P3_7, 0xB0, 7); // Port 2 bit 7 // Alternate names SBIT(RXD, 0xB0, 0); // Port 2 bit 0 SBIT(TXD, 0xB0, 1); // Port 2 bit 1 SBIT(INT0, 0xB0, 2); // Port 2 bit 2 SBIT(INT1, 0xB0, 3); // Port 2 bit 3 SBIT(T0, 0xB0, 4); // Port 2 bit 4 SBIT(T1, 0xB0, 5); // Port 2 bit 5 SBIT(WR, 0xB0, 6); // Port 2 bit 6 SBIT(RD, 0xB0, 7); // Port 2 bit 7 SFR(P4, 0xA5); // Port 4 - not bit addressable #define P4_0 0x01 #define P4_1 0x02 #define P4_2 0x04 #define P4_3 0x08 // TABLE 3-10: PCA SFRs SFR(CH, 0xF9); // PCA Timer/Counter High SFR(CL, 0xE9); // PCA Timer/Counter Low SFR(CCON, 0xD8); // PCA Timer/Counter Control Register CF CR - CCF4 CCF3 CCF2 CCF1 CCF0 00x00000b SBIT(CF, 0xD8, 7); // PCA Counter overflow flag SBIT(CR, 0xD8, 6); // PCA Counter Run Control Bit SBIT(CCF4, 0xD8, 4); // PCA Module 4 Interrupt Flag SBIT(CCF3, 0xD8, 3); // PCA Module 3 Interrupt Flag SBIT(CCF2, 0xD8, 2); // PCA Module 2 Interrupt Flag SBIT(CCF1, 0xD8, 1); // PCA Module 1 Interrupt Flag SBIT(CCF0, 0xD8, 0); // PCA Module 0 Interrupt Flag SFR(CMOD, 0xD9); // PCA Timer/Counter Mode Register #define CIDL 0x80 // CIDL=0 program the PCA counter to work during idle mode #define WDTE 0x40 // Watchdog Timer Enable #define CPS1 0x04 // PCA Count Pulse Select bit 1 #define CPS0 0x02 // PCA Count Pulse Select bit 0 // 00=Internal clock, Fosc/6 // 01=Internal clock, Fosc/6 // 10=Timer 0 overflow // 11=External clock at ECI/P1.2 pin (max rate=Fosc/4) #define ECF 0x01 // PCA Enable Counter Overflow Interrupt SFR(CCAP0H, 0xFA); // PCA Module 0 Compare/Capture Register High SFR(CCAP0L, 0xEA); // PCA Module 0 Compare/Capture Register Low SFR(CCAP1H, 0xFB); // PCA Module 1 Compare/Capture Register High SFR(CCAP1L, 0xEB); // PCA Module 1 Compare/Capture Register Low SFR(CCAP2H, 0xFC); // PCA Module 2 Compare/Capture Register High SFR(CCAP2L, 0xEC); // PCA Module 2 Compare/Capture Register Low SFR(CCAP3H, 0xFD); // PCA Module 3 Compare/Capture Register High SFR(CCAP3L, 0xED); // PCA Module 3 Compare/Capture Register Low SFR(CCAP4H, 0xFE); // PCA Module 4 Compare/Capture Register High SFR(CCAP4L, 0xEE); // PCA Module 4 Compare/Capture Register Low SFR(CCAPM0, 0xDA); // PCA Compare/Capture Module 0 Mode Register SFR(CCAPM1, 0xDB); // PCA Compare/Capture Module 1 Mode Register SFR(CCAPM2, 0xDC); // PCA Compare/Capture Module 2 Mode Register SFR(CCAPM3, 0xDD); // PCA Compare/Capture Module 3 Mode Register SFR(CCAPM4, 0xDE); // PCA Compare/Capture Module 4 Mode Register // The preceding five registers have the following bits: #define ECOM 0x40 // Enable Comparator #define CAPP 0x20 // 1=enables positive edge capture #define CAPN 0x10 // 1=enables negative edge capture #define MAT 0x08 // When counter matches sets CCFn bit causing and interrupt #define TOG 0x04 // Toggle output on match #define PWM 0x02 // Pulse width modulation mode #define ECCF 0x01 // Enable CCF interrupt #endif /*REG_SST89x5xRDx_H*/