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//============================================================================= // // quicc2_diag.c // // HAL diagnostic I/O support routines for MPC8260/QUICC2 // //============================================================================= //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // Copyright (C) 2002 Gary Thomas // // eCos 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. // // eCos 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 eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //============================================================================= //#####DESCRIPTIONBEGIN#### // // Author(s): hmt // Contributors:hmt, gthomas // Date: 1999-06-08 // Purpose: HAL diagnostics I/O support // Description: // //####DESCRIPTIONEND#### // //============================================================================= #include <pkgconf/hal.h> #include <cyg/hal/hal_mem.h> // HAL memory definitions #include <cyg/infra/cyg_type.h> #include <cyg/hal/hal_if.h> // hal_if_init #include <cyg/hal/hal_io.h> // hal_if_init #include <cyg/hal/hal_misc.h> // cyg_hal_is_break #include <cyg/hal/drv_api.h> // CYG_ISR_HANDLED // Added by WPD #include <cyg/hal/hal_diag.h> #include <cyg/hal/ppc_regs.h> #include <cyg/hal/var_intr.h> #include <cyg/hal/mpc8260.h> // Needed for IMMR structure // For Baud Rate Calculation, see MPC8260 PowerQUICC II User's Manual // 16.3 UART Baud Rate Examples, page 16-5. // BRGCx[DIV16] = 0 ==> value of 1 (Prescale divider) // BRGCx[EXTC] = 16.667 MHz (Baud Rate generator input clock) // GSMRx_L[xDCR] = 16 (Sampling Rate) // UART_CLK_DIV + 1 = // BRGCx[EXTC] / (BRGCx[DIV16] * UART_BAUD_RATE * GSMRx_L[xDCR]) // UART_CLK_DIV = ((66.667 MHz / 4) / (UART_BAUD_RATE * 16)) - 1 // UART_CLK_DIV = ((66.667 MHz ) / (UART_BAUD_RATE * 64)) - 1 // UART_CLK_DIV = ((CYGHWR_HAL_POWERPC_BOARD_SPEED*1000000 ) // / (UART_BAUD_RATE * 64)) (Calculation will truncate, so // lose the -1 ) #define UART_BIT_RATE(n) \ (((int)(CYGHWR_HAL_POWERPC_BOARD_SPEED*1000000))/(n * 64)) #define UART_BAUD_RATE CYGNUM_HAL_DIAG_BAUD /***********************/ /* Global Declarations */ /***********************/ //#define USE_SMC1 volatile t_PQ2IMM *IMM; /* IMM base pointer */ volatile BDRINGS *RxTxBD; /* buffer descriptors base pointer */ volatile LB *SCC1Buffers; /* SCC1 base pointers */ #define SMC1_PRAM 0x04703800 #define BD_RX_ERROR 0xBF /* Mask for set of Receive Buffer Errors, including: DE, LG, NO, AB, CR, OV, CD */ /*---------------------*/ /* Function Prototypes */ /*---------------------*/ static void InitSCC1Uart(void); static void ConfigSCC1Clock(void); static void InitParallelPorts(void); static cyg_uint8 SCC1Poll(void); static void InitBDs(void); static cyg_uint8 cyg_hal_plf_serial_getc(void* __ch_data); static cyg_bool cyg_hal_plf_serial_getc_nonblock(void* __ch_data, cyg_uint8* ch); static cyg_bool cyg_hal_plf_serial_getc_timeout(void* __ch_data, cyg_uint8* ch); static void cyg_hal_plf_serial_putc(void* __ch_data, cyg_uint8 ch); static void cyg_hal_plf_serial_write(void* __ch_data, const cyg_uint8* __buf, cyg_uint32 __len); static void cyg_hal_plf_serial_read(void* __ch_data, cyg_uint8* __buf, cyg_uint32 __len); static void cyg_hal_plf_serial_init_channel(void); static int cyg_hal_plf_serial_isr(void *__ch_data, int* __ctrlc, CYG_ADDRWORD __vector, CYG_ADDRWORD __data); static int cyg_hal_plf_serial_control(void *__ch_data, __comm_control_cmd_t __func, ...); static int cyg_hal_plf_serial_isr(void *__ch_data, int* __ctrlc, CYG_ADDRWORD __vector, CYG_ADDRWORD __data) { t_PQ2IMM *immr = (t_PQ2IMM*) __ch_data; struct cp_bufdesc *bd; char ch; int res = 0; cyg_uint32 regval; CYGARC_HAL_SAVE_GP(); //GREEN_LED_ON; /* dbg_values[3]++; dbg_values[10+dbg_values[3]] = RxTxBD->RxBD.bd_cstatus | (immr->scc_regs[SCC1].scce<<16); */ *__ctrlc = 0; if (immr->scc_regs[SCC1].scce & 0x0001) { // Clear the event by writing a "1" to the prpoper bit. immr->scc_regs[SCC1].scce = 0x0001; if((RxTxBD->RxBD.bd_cstatus & 0x8000) == 0){ ch = *(RxTxBD->RxBD.bd_addr); /*----------------------*/ /* Set Buffer Empty bit */ /*----------------------*/ //dbg_values[10+dbg_values[3]] = __vector | 0xffff0000; //dbg_values[10+dbg_values[3]] |= ch << 8; RxTxBD->RxBD.bd_cstatus |= 0x8000; if( cyg_hal_is_break( &ch , 1 ) ){ //GREEN_LED_ON; *__ctrlc = 1; //dbg_values[7] = immr->ic_sivec; } } // Interrupt handled. Acknowledge it. //eppc->cpmi_cisr = 0x10; // Clear interrupt in SIPNR_L by writing a one to bit 8 (0x800000) HAL_READ_UINT32( ((char *) IMM) + 0x10000 + CYGARC_REG_IMM_SIPNR_L, regval); regval |= 0x00800000; HAL_WRITE_UINT32( ((char *) IMM) + 0x10000 + CYGARC_REG_IMM_SIPNR_L, regval); res = CYG_ISR_HANDLED; } //GREEN_LED_OFF; CYGARC_HAL_RESTORE_GP(); return res; } /* Early initialization of comm channels. Must not rely * on interrupts, yet. Interrupt operation can be enabled * in _bsp_board_init(). */ void cyg_hal_plf_serial_init(void) { #ifdef CYGSEM_HAL_VIRTUAL_VECTOR_SUPPORT hal_virtual_comm_table_t* comm; int cur = CYGACC_CALL_IF_SET_CONSOLE_COMM(CYGNUM_CALL_IF_SET_COMM_ID_QUERY_CURRENT); static int init = 0; // It's wrong to do this more than once if (init) return; init++; // init_channel sets the global *IMM == 0x04700000, the base of the // Internal Memory map for the MPC8260 cyg_hal_plf_serial_init_channel(); // Setup procs in the vector table // Set channel 0 CYGACC_CALL_IF_SET_CONSOLE_COMM(0);// Should be configurable! comm = CYGACC_CALL_IF_CONSOLE_PROCS(); CYGACC_COMM_IF_CH_DATA_SET(*comm, IMM); CYGACC_COMM_IF_WRITE_SET(*comm, cyg_hal_plf_serial_write); CYGACC_COMM_IF_READ_SET(*comm, cyg_hal_plf_serial_read); CYGACC_COMM_IF_PUTC_SET(*comm, cyg_hal_plf_serial_putc); CYGACC_COMM_IF_GETC_SET(*comm, cyg_hal_plf_serial_getc); CYGACC_COMM_IF_CONTROL_SET(*comm, cyg_hal_plf_serial_control); CYGACC_COMM_IF_DBG_ISR_SET(*comm, cyg_hal_plf_serial_isr); CYGACC_COMM_IF_GETC_TIMEOUT_SET(*comm, cyg_hal_plf_serial_getc_timeout); // Restore original console CYGACC_CALL_IF_SET_CONSOLE_COMM(cur); #else // No CYGSEM_HAL_VIRTUAL_VECTOR_SUPPORT static int init = 0; // It's wrong to do this more than once if (init) return; init++; cyg_hal_plf_serial_init_channel(); #endif } static void cyg_hal_plf_serial_init_channel(void) { /* We will assume here that the IMMR has been programmed such that * the internal Memory Map starts at 0x04700000. Initialization * should have done that setup. */ IMM = (t_PQ2IMM *)0x04700000; /* MPC8260 internal register map */ /*----------------------------------------------------------------------*/ /* Get a pointer to the BD area on DP RAM. The buffer descriptors (BDs) */ /* and the Rx/Tx data buffers will be located right after SCC1's para- */ /* meter RAM area because only 2 BDs and 2 data buffers are being used */ /* for this port and SCC1 only uses 64 bytes of it's allotted 256 for */ /* it's parameter ram. One BD and one data buffer each for transmit and */ /* receive will be used. This buffer descriptor area will take up 16 */ /* bytes. */ /*----------------------------------------------------------------------*/ RxTxBD = (BDRINGS *) 0x04708070; // (((CYG_WORD)&(IMM->pram.serials.scc_pram[SCC1])) + 72); //RxTxBD = (BDRINGS *) // (((CYG_WORD)&(IMM->pram.serials.scc_pram[SCC1])) + 72); /*-------------------------------------------------------------------*/ /* Establish the buffer pool in Dual Port RAM. We do this because the*/ /* pool size is only 2 bytes (1 for Rx and 1 for Tx) and to avoid */ /* disabling data cache for the memory region where BufferPool would */ /* reside. The CPM does not recognize data in buffer pools once it */ /* been cached. It's acesses are direct through DMA to external */ /* memory. */ /*-------------------------------------------------------------------*/ //SCC1Buffers = (LB *) // (((CYG_WORD)&(IMM->pram.serials.scc_pram[SCC1])) + 96); SCC1Buffers = (LB *) 0x04708090; // (((CYG_WORD)&(IMM->pram.serials.scc_pram[SCC1])) // + 72 + 14); /*----------------------------------------*/ /* Initialize SCC1 and buffer descriptors */ /*----------------------------------------*/ /* while(1); */ InitSCC1Uart(); } /*--------------------------------------------------------------------------- * * FUNCTION NAME: InitBDs * * * DESCRIPTION: * * Initializes BD rings to point RX BDs to first half of buffer pool and TX * BDs to second half of buffer pool. This function also initializes the * buffer descriptors control and data length fields. It also ensures that * transmit and recieve functions are disabled before buffer descriptors are * initialized. * * EXTERNAL EFFECTS: Disable Tx/Rx functions. Changes BDs in dual port ram. * * PARAMETERS: None * * RETURNS: None * *---------------------------------------------------------------------------*/ void InitBDs() { /*--------------------------------------------------------------------*/ /* First let's ensure the SCC1 functions are off while we program the */ /* buffer descriptors and the parameter ram. Clear the ENT/ENR bits */ /* in the GSMR -- disable Transmit/Receive */ /*--------------------------------------------------------------------*/ IMM->scc_regs[SCC1].gsmr_l &= DISABLE_TX_RX; /*--------------------------------------*/ /* Issue Init Stop TX Command for SCC1. */ /*--------------------------------------*/ while ((IMM->cpm_cpcr & CPCR_FLG) != READY_TO_RX_CMD); IMM->cpm_cpcr = SCC1_PAGE_SUBBLOCK | CPCR_STOP_TX | CPCR_FLG; /* ISSUE COMMAND */ while ((IMM->cpm_cpcr & CPCR_FLG) != READY_TO_RX_CMD); /*-----------------------------------*/ /* Setup Receiver Buffer Descriptors */ /*-----------------------------------*/ #if defined(CYGDBG_HAL_DEBUG_GDB_BREAK_SUPPORT) \ || defined(CYGDBG_HAL_DEBUG_GDB_CTRLC_SUPPORT) /* Set receive Buffer to generate an interrupt when buffer full */ RxTxBD->RxBD.bd_cstatus = 0xB000; /* 0xB000; */ #else RxTxBD->RxBD.bd_cstatus = 0xA000; /* Empty, Wrap Bit */ #endif //dbg_values[3] = RxTxBD->RxBD.bd_cstatus; RxTxBD->RxBD.bd_length = 1; RxTxBD->RxBD.bd_addr = &(SCC1Buffers->RxBuffer); /*--------------------------------------*/ /* Setup Transmitter Buffer Descriptors */ /*--------------------------------------*/ RxTxBD->TxBD.bd_cstatus = 0x2800; /* Buffer not yet ready; Wrap Bit Clear-to-send_report */ RxTxBD->TxBD.bd_length = 1; RxTxBD->TxBD.bd_addr = &(SCC1Buffers->TxBuffer); } /* end InitBDs */ /*--------------------------------------------------------------------------- * * FUNCTION NAME: InitSCC1Uart * * * DESCRIPTION: * * SCC1 Uart Mode Initialization Routine. * * EXTERNAL EFFECT: * * Initializes SCC1 to operate in Uart mode at 9600 Baud, No Parity, 8 data * bits, and 1 stop bit. * * PARAMETERS: None * * RETURNS: None * *--------------------------------------------------------------------------*/ void InitSCC1Uart() { cyg_uint32 regval; /*----------------------------------------------------------------------*/ /* Configure the parallel ports so that TXD and RXD are connected to */ /* the appropriate port pins and are configured according to their */ /* functions. */ /*----------------------------------------------------------------------*/ InitParallelPorts(); /*------------------------------------------*/ /* Configure Clock Source and Clock Routing */ /*------------------------------------------*/ ConfigSCC1Clock(); /*-----------------------------------*/ /* Initialize the Buffer Descriptors */ /*-----------------------------------*/ InitBDs(); /*----------------------------------------------------------------------*/ /* Program Rx and Tx Function Codes (RFCRx/TFCRx). */ /* */ /* - Bits 0-1 reserved. Set to zero. */ /* */ /* - GBL (Global) = 0 = Snooping Disabled. */ /* */ /* - BO (Byte Ordering) = 11 = Big-endian or true little-endian. */ /* */ /* - TC[2] (Transfer Code) = 0 = Transfer code is 0 */ /* */ /* - DTB (Data Bus Indicator) = 1 = */ /* */ /* Use the Local Bus for SDMA operation. In this example it doesn't */ /* matter because the buffer were located in parameter ram. Normally */ /* this bit would be set because data buffers normally will reside */ /* in Local memory. */ /*----------------------------------------------------------------------*/ IMM->pram.serials.scc_pram[SCC1].rfcr = 0x18; IMM->pram.serials.scc_pram[SCC1].tfcr = 0x18; IMM->scc_regs[SCC1].psmr = 0xB000; /*------------------------------------------------------------*/ /* Set RBASE, TBASE -- Rx,Tx Buffer Descriptor Base Addresses */ /*------------------------------------------------------------*/ IMM->pram.serials.scc_pram[SCC1].rbase = (CYG_WORD16)&RxTxBD->RxBD; IMM->pram.serials.scc_pram[SCC1].tbase = (CYG_WORD16)&RxTxBD->TxBD; /*-----------------------------------------*/ /* Set MRBLR -- Max. Receive Buffer Length */ /*-----------------------------------------*/ IMM->pram.serials.scc_pram[SCC1].mrblr = 1; /*----------------------------------------------------------------------*/ /* Program the General SCC Mode Register High (GSMR_H) */ /* */ /* - Bits 0-14 Reserved. Set to 0. */ /* */ /* - GDE (Glitch Detect Enable) = 0 = No Glitch Detect. BRG supplies */ /* the clock so there's no need to */ /* detect glitches. */ /* */ /* - TCRC (Transparent CRC) = 00 = This field is ignored for Uart mode. */ /* */ /* - REVD (Reverse Data) = 0 = This field is ignored for Uart mode. */ /* */ /* - TRX,TTX (Transparent Receiver/Transmitter) = 00 = Normal operation */ /* */ /* - CDP,CTSP (CD/ & CTS/ sampling) = 00 = Normal Operation (envelope */ /* mode. */ /* */ /* - CDS,CTSS (CD/ & CTSS Sampling) = 00 = */ /* */ /* CD/ or CTS/ is assumed to be asynchronous with data. It is */ /* internally synchronized by the SCC, then data is received (CD/) */ /* or sent (CTS/) after several clock delays. */ /* */ /* - TFL (Transmit FIFO length) = 0 = */ /* */ /* Normal Operation. The SCC transmit FIFO is 32 bytes. */ /* */ /* - RFW (Rx FIFO Width) = 1 = */ /* */ /* Low-latency operation.The receive FIFO is 8 bits wide, reducing */ /* the Rx FIFO to a quarter of it's normal size. This allows data to */ /* be written to the buffer as soon as a character is received, */ /* instead of waiting to receive 32 bits. This configuration must be */ /* chosen for character-oriented protocols, such as UART. It can */ /* also be used for low-performance, low-latency, transparent */ /* operation. */ /* */ /* - TXSY (Trasnmitter Synchronized) = 0 = */ /* */ /* No synchronization between receiver and transmitter. */ /* */ /* - SYNL (Sync Length) = 0 = An external sync (CD/) is used instead of */ /* the sync pattern in the DSR. */ /* */ /* - RTSM (RTS/ Mode) = 0 = Send idles between frames as defined by the */ /* protocol and the TEND bit. TRS/ is negated */ /* between frames. */ /* */ /* - RSYN (Receive Synchronization Timing) = 0 = This field is ignored */ /* for Uart mode. */ /* */ /*----------------------------------------------------------------------*/ IMM->scc_regs[SCC1].gsmr_h = 0x00000060; /*----------------------------------------------------------------------*/ /* Program the General SCC Mode Register High (GSMR_L) */ /* */ /* - Bit 0 Reserved. Set to 0. */ /* */ /* - EDGE (Clock Edge) = 00 = Ignored in Uart Mode. */ /* */ /* - TCI (Transmit Clock Invert) = 0 = Normal Operation */ /* */ /* - TSNC (Transmit Sense) = 00 = Infinite. Carrier sense is always */ /* active. */ /* */ /* - RINV (DPLL Rx Input Invert) = 0 = Do not invert. */ /* */ /* - TINV (DPLL Tx Input Invert) = 0 = Do not invert. */ /* */ /* - TPL (Tx Preamble Length) = 000 = No Preamble. */ /* */ /* - TPP (Tx Preamble Pattern) = 00 = All zeros. This field is ignored */ /* for Uart mode. */ /* */ /* - TEND (Transmitter Frame Ending) = 0 = */ /* */ /* Default operation. TxD is encoded only when data is sent, */ /* including the preamble and opening and closing flags/syncs. When */ /* no data is available to send, the signal is driven high. */ /* */ /* - TDCR (Transmitter DPLL Clock Rate) = 10 = */ /* */ /* 16x clock mode. This value is normally chosen for Uart mode. */ /* */ /* - RDCR (Receiver DPLL Clock Rate) = 10 = */ /* */ /* 16x clock mode. This value is normally chosen for Uart mode. */ /* */ /* - RENC (Receiver Decoding Method) = 000 = */ /* */ /* NRZ. Required for Uart Mode (asynchronous or synchronous). */ /* */ /* - TENC (Transmitter Encoding Method) = 000 = */ /* */ /* NRZ. Required for Uart Mode (asynchronous or synchronous). */ /* */ /* - DIAG (Diagnostic Mode) = 01 = Loopback */ /* */ /* - ENR (Enable Receiver) = 0 = Disabled for now. Will enabled later in*/ /* this function. */ /* */ /* - ENT (Enable Transmitter) = 0 = Disabled for now. Will enable later */ /* in this function. */ /* */ /* - MODE (Channel Protocol Mode) = 0100 = Uart mode. */ /* */ /*----------------------------------------------------------------------*/ IMM->scc_regs[SCC1].gsmr_l = 0x00028004; /*-----------------------------------------*/ /* Clear SCCE Register by writing all 1's. */ /*-----------------------------------------*/ IMM->scc_regs[SCC1].scce = ALL_ONES; /*----------------------------------------------------------------------*/ /* Issue Init RX & TX Parameters Command for SCC1. This command to the */ /* CP lets it know to reinitialize SCC1 with the new parameter RAM */ /* values. When the ENT/ENR bits are set below Hunt Mode will begin */ /* automatically. */ /*----------------------------------------------------------------------*/ while ((IMM->cpm_cpcr & CPCR_FLG) != READY_TO_RX_CMD); IMM->cpm_cpcr = SCC1_PAGE_SUBBLOCK | CPCR_INIT_TX_RX_PARAMS | CPCR_FLG; /* ISSUE COMMAND */ while ((IMM->cpm_cpcr & CPCR_FLG) != READY_TO_RX_CMD); /*-------------------------------------------------------------*/ /* Set the ENT/ENR bits in the GSMR -- Enable Transmit/Receive */ /*-------------------------------------------------------------*/ IMM->scc_regs[SCC1].gsmr_l |= GSMR_L1_ENT | GSMR_L1_ENR; #if defined(CYGDBG_HAL_DEBUG_GDB_BREAK_SUPPORT) \ || defined(CYGDBG_HAL_DEBUG_GDB_CTRLC_SUPPORT) #define PFADDED #ifdef PFADDED // Fill out the control Character Table. Make the first entry // an end of table line. // cc[0] = 0x4003 ==> reject if char = 0x3, write to RCCR IMM->pram.serials.scc_pram[SCC1].SpecificProtocol.u.cc[0] = 0x4003; { int i; for (i = 0; i < 8; i++){ IMM->pram.serials.scc_pram[SCC1].SpecificProtocol.u.cc[i] = 0x8000; } } IMM->pram.serials.scc_pram[SCC1].SpecificProtocol.u.rccm = 0xc000; #endif /*-----------------------------------------*/ /* Write to the SCCM mask register to enable an CCR interrupt*/ /*-----------------------------------------*/ IMM->scc_regs[SCC1].sccm = 0x1; /* Unmask the CPM SCC1 interrupt */ HAL_READ_UINT32( ((char *) IMM) + 0x10000 + CYGARC_REG_IMM_SIMR_L, regval); regval |= 0x00800000; HAL_WRITE_UINT32( ((char *) IMM) + 0x10000 + CYGARC_REG_IMM_SIMR_L, regval); #endif } /* end SCC1HInit() */ /*-------------------------------------------------------------------------- * * FUNCTION NAME: ConfigSCC1Clock * * DESCRIPTION: * * This function will configure SCC1 to utilize Baud Rate Generator #1. It * will program the the baud rate generator and configure the SMXSCR * register in the CPM Mux block to route the clock to SCC1. SCC2, SCC3, and * SCC4 are also programmed to assume Baud Rate Generator #1, #2, and #3 * respectively to be routed to them. There was no special reason for doing * this; The bit values needed to be programmed to something. * * * EXTERNAL EFFECTS: BRGC1 and CMXSCR * * PARAMETERS: * * RETURNS: Nothing * *--------------------------------------------------------------------------*/ void ConfigSCC1Clock() { /* FIXME --- This picture is not accurate */ /*----------------------------------------------------------------------*/ /* Initialize Baud Rate Generator #1 to generate a 9600 clock. The */ /* source of the clock starts with the input clock that is generated */ /* external to the MPC8260 by a clock generator. This clock is then */ /* fed to the CPM PLL where it is multiplied up and the output freq- */ /* uency is determined by the MODCLK_HI bits in the Hard Reset Config- */ /* uration Word and MODCK pins on the MPC8260. This output is fed to a */ /* general purpose Baud Rate Generator Divider that services all 8 baud */ /* rate generators. From the output of this divider the the clock goes */ /* to the baud rate generator circuitry where, in this case, BRGCLK is */ /* selected to be BRGO1 (the output clock). This frequency is deter- */ /* mined by a Divide by 1 or 16 divider and then a 12 bit Prescaler */ /* divider. the clock then goes to the CPM Mux where BRG1 is selected */ /* to be TCLK and RCLK to SCC1. This is accomplished by programming the */ /* CMXSCR register. TCLK and RCLK are then routed to the SCC1 DPLL */ /* circuitry at 9600 baud where the DPLL will be programmed to multiply */ /* the frequency by X16 for UART over-sampling. Here a diagram and the */ /* programming: */ /* */ /* ---------- --------- --------------------- */ /* |External| |MPC8260| 132 Mhz |General Purpose | 16.5 Mhz */ /* |Clk Gen |----|CPM PLL|---------|Baud Rate Generator|--------->| */ /* |66 Mhz | |Block | |Divider [/8] (SCCR)| | */ /* ---------- --------- --------------------- | */ /* | */ /* |<-------------------------------------------------------------| */ /* | */ /* | ------------------------ ------------------- */ /* |-->|Divide by 1 or 16 in | 1.03125 Mhz |12 Bit Prescaler | BRG01 */ /* |Baud Rate Generator |------------->|in Baud Rate Gen. |--| */ /* |Block [/16 selected] | |Block [107(0x6B) | | */ /* |(BRGC1 Programmed) | |(BRGC1 Programmed)| | */ /* ------------------------ -------------------- | */ /* | */ /* |<--------------------------------------------------------------| */ /* | */ /* | -------------- TCLK ---------- */ /* | 9.638 Khz | CPM Mux |------>| SCC1 |----> TCLK*16 }*16 for */ /* |----------->| (CMXSCR) | RCLK | DPLL | }over- */ /* |(Programmed)|------>| *16 |----> RCLK*16 }sampling */ /* -------------- |(GSMR_L)| */ /* ---------- */ /* */ /* SCCR was programmed in init8260.s. BRGC1,CMXSCR will be programmed */ /* in this function. GSMR_L will be programmed in InitSCC1Uart(). */ /* */ /*----------------------------------------------------------------------*/ /*----------------------------------------------------------------------*/ /* Program Baud Rate Generator Configuration #1 Register (BRGC1). */ /* */ /* - Bits 0-13 are reserved. Set to 0. */ /* */ /* - RST (Reset BRG) = 0 = Enable the BRG */ /* */ /* - EN (Enable BRG Count) = 1 = Enable clocks to the BRG */ /* */ /* - EXTC (External Clock Source) = 00 = */ /* */ /* The BRG input clock comes from the BRGCLK */ /* */ /* - ATB (AutoBaud) = 0 = Normal operation of the BRG. */ /* */ /* - CD (Clock Divider) = 0x6C = 108 decimal = */ /* */ /* The input frequency is 1.03125 Mhz Dividing it by 107 will give */ /* 9.638 Khz. However 1 must be added to the count value because it */ /* counts down to 0. So the programmed value is 108. */ /* */ /* PF edit - changed CD = 0x1A = 26 ==> baud rate of 4 * 9600 = 38400 */ /* - DIV16 (Divide-by-16) = 0 = divide by 1. */ /*----------------------------------------------------------------------*/ // IMM->brgs_brgc1 = 0x000100D6; //IMM->brgs_brgc1 = 0x00010034; /* Attempt to get 38400 baud */ // IMM->brgs_brgc1 = 0x00010022; /* Attempt to get 57600 baud */ //IMM->brgs_brgc1 = 0x00010010; /* Attempt to get 115200 baud */ IMM->brgs_brgc1 = 0x00010000 | (UART_BIT_RATE(UART_BAUD_RATE) << 1); /*----------------------------------------------------------------------*/ /* Program the CMX SCC Route Register (CMXSCR). */ /* */ /* - GR1 (Grant support of SCC1) = 0 = */ /* */ /* SCC1 transmitter does not support the grant mechanism. The grant */ /* is always asserted internally. */ /* */ /* - SC1 (SCC1 connection) = 0 */ /* */ /* SCC1 is not connected to the TSA of the SIs but is connected */ /* directly to the NMSIx pins. */ /* */ /* - RS1CS (Receive SCC1 or clock source) = 000 = */ /* */ /* SCC1 receive clock is BRG1. */ /* */ /* - TS1CS (Transmit SCC1 clock source) = 000 = */ /* */ /* SCC1 transmit clock is BRG1. */ /* */ /* - GR2 (Grant support of SCC2) = 0 = */ /* */ /* SCC1 transmitter does not support the grant mechanism. The grant */ /* is always asserted internally. */ /* */ /* - SC2 (SCC2 connection) = 0 */ /* */ /* SCC2 is not connected to the TSA of the SIs but is connected */ /* directly to the NMSIx pins. */ /* */ /* - RS2CS (Receive SCC2 or clock source) = 001 = */ /* */ /* SCC1 receive clock is BRG2. */ /* */ /* - TS2CS (Transmit SCC2 clock source) = 001 = */ /* */ /* SCC2 transmit clock is BRG2. */ /* */ /* - GR3 (Grant support of SCC3) = 0 = */ /* */ /* SCC3 transmitter does not support the grant mechanism. The grant */ /* is always asserted internally. */ /* */ /* - SC3 (SCC3 connection) = 0 */ /* */ /* SCC3 is not connected to the TSA of the SIs but is connected */ /* directly to the NMSIx pins. */ /* */ /* - RS3CS (Receive SCC3 or clock source) = 010 = */ /* */ /* SCC3 receive clock is BRG3. */ /* */ /* - TS3CS (Transmit SCC3 clock source) = 010 = */ /* */ /* SCC3 transmit clock is BRG3. */ /* */ /* - GR4 (Grant support of SCC4) = 0 = */ /* */ /* SCC4 transmitter does not support the grant mechanism. The grant */ /* is always asserted internally. */ /* */ /* - SC4 (SCC4 connection) = 0 */ /* */ /* SCC4 is not connected to the TSA of the SIs but is connected */ /* directly to the NMSIx pins. */ /* */ /* - RS4CS (Receive SCC4 or clock source) = 011 = */ /* */ /* SCC4 receive clock is BRG4. */ /* */ /* - TS4CS (Transmit SCC4 clock source) = 011 = */ /* */ /* SCC4 transmit clock is BRG4. */ /* */ /*----------------------------------------------------------------------*/ IMM->cpm_mux_cmxscr = 0x0009121B; } /* end of ConfigSCC1Clock() */ /*-------------------------------------------------------------------------- * * FUNCTION NAME: InitParallelPorts * * DESCRIPTION: * * This function programs the parallel port configuration registers to * utilize the pins required for proper SCC1 operation. The pins programmed * here are TxD and RxD for SCC1 and CD1 for SCC1. * * EXTERNAL EFFECTS: Parallel Port C and D Configuration Registers * * PARAMETERS: * * RETURNS: Nothing * *--------------------------------------------------------------------------*/ void InitParallelPorts() { /*--------------------------------------------*/ /* Program the Port Special Options Registers */ /*--------------------------------------------*/ IMM->io_regs[PORT_C].psor &= 0xFFFDFFFF; /* CD/ pin 14 */ IMM->io_regs[PORT_D].psor &= 0xFFFFFFFC; /* clear first */ IMM->io_regs[PORT_D].psor |= 0x00000002; /* TXD pin 30| RXD pin 31 */ /*-------------------------------------------*/ /* Program the Port Pin Assignment Registers */ /*-------------------------------------------*/ IMM->io_regs[PORT_C].ppar |= 0x00020000; /* CD/ pin 14 */ IMM->io_regs[PORT_D].ppar |= 0x00000003; /* TXD pin 30| RXD pin 31 */ /*-------------------------------------------*/ /* Program the Port Data Direction Registers */ /*-------------------------------------------*/ IMM->io_regs[PORT_C].pdir &= 0xFFFDFFFF; /* CD/ pin 14 */ IMM->io_regs[PORT_D].pdir &= 0xFFFFFFFC; /* clear first */ IMM->io_regs[PORT_D].pdir |= 0x00000002; /* TXD pin 30| RXD pin 31 */ /*---------------------------------------*/ /* Program the Port Open-Drain Registers */ /*---------------------------------------*/ IMM->io_regs[PORT_C].podr &= 0xFFFDFFFF; /* CD/ pin 14 */ IMM->io_regs[PORT_D].podr &= 0xFFFFFFFC; /* TXD pin 30| RXD pin 31 */ } /*--------------------------------------------------------------------------- * * FUNCTION NAME: BDRxError * * DESCRIPTION: * * Return TRUE if Buffer Descriptor Status bd_cstatus indicates Receive * Error; Return FALSE otherwise note Receive Errors are as follows: * * 0x80: DPLL Error (DE) * 0x20: Length Violation (LG) * 0x10: Non-Octet Aligned (NO) * 0x8: Rx Abort Sequence (AB) * 0x4: Rx CRC Error (CR) * 0x2: Overrun (OV) * 0x1: Carrier Detect Lost (CD) * * EXTERNAL EFFECTS: None * * PARAMETERS: * * bd_cstatus * * RETURNS: TRUE if there was an error and FALSE if there wasn't * *---------------------------------------------------------------------------*/ CYG_WORD16 BDRxError(CYG_WORD16 bd_cstatus) { if (bd_cstatus & BD_RX_ERROR) return true; else return false; } /* end BDRxError */ /*--------------------------------------------------------------------------- * * FUNCTION NAME: SCC1Poll * * DESCRIPTION: Poll SCC1 RxBD and check to see if a character was received * * EXTERNAL EFFECT: NONE * * PARAMETERS: NONE * * RETURNS: A one if there is a character available in the receive buffer, * else zero. * *--------------------------------------------------------------------------*/ cyg_uint8 SCC1Poll(void) { if(RxTxBD->RxBD.bd_cstatus & 0x8000) { return 0; /* character NOT available */ } else { return 1; /* character IS available */ } } /* END SCC1Poll */ #ifndef CYGSEM_HAL_VIRTUAL_VECTOR_SUPPORT void cyg_hal_plf_serial_putc(cyg_uint8 ch) #else static void cyg_hal_plf_serial_putc(void* __ch_data, cyg_uint8 ch) #endif { /*-----------------------------------*/ /* Loop until transmission completed */ /*-----------------------------------*/ #if 1 volatile CYG_WORD16 stat = 1; while (stat){ stat = RxTxBD->TxBD.bd_cstatus & 0x8000; } #else while (RxTxBD->TxBD.bd_cstatus & 0x8000); #endif /*------------*/ /* Store data */ /*------------*/ *(RxTxBD->TxBD.bd_addr) = ch; RxTxBD->TxBD.bd_length = 1; /*---------------*/ /* Set Ready bit */ /*---------------*/ RxTxBD->TxBD.bd_cstatus |= 0x8000; } static cyg_bool cyg_hal_plf_serial_getc_nonblock(void* __ch_data, cyg_uint8* ch) { cyg_bool retval; if ( (retval = SCC1Poll() ) ){ /* Check BD status for Rx characters */ *ch = cyg_hal_plf_serial_getc(__ch_data); } return retval; } #ifndef CYGSEM_HAL_VIRTUAL_VECTOR_SUPPORT cyg_uint8 cyg_hal_plf_serial_getc(void) #else static cyg_uint8 cyg_hal_plf_serial_getc(void* __ch_data) #endif { cyg_uint8 ch; /*--------------------*/ /* Loop if RxBD empty */ /*--------------------*/ #if 1 volatile short stat = 1; while (stat){ stat = RxTxBD->RxBD.bd_cstatus & 0x8000; } #else while (RxTxBD->RxBD.bd_cstatus & 0x8000); #endif /*--------------*/ /* Receive data */ /*--------------*/ ch = *(RxTxBD->RxBD.bd_addr); /*----------------------*/ /* Set Buffer Empty bit */ /*----------------------*/ RxTxBD->RxBD.bd_cstatus |= 0x8000; return ch; } static void cyg_hal_plf_serial_write(void* __ch_data, const cyg_uint8* __buf, cyg_uint32 __len) { //CYGARC_HAL_SAVE_GP(); while(__len-- > 0) #ifndef CYGSEM_HAL_VIRTUAL_VECTOR_SUPPORT cyg_hal_plf_serial_putc(*__buf++); #else cyg_hal_plf_serial_putc(__ch_data, *__buf++); #endif //CYGARC_HAL_RESTORE_GP(); } static void cyg_hal_plf_serial_read(void* __ch_data, cyg_uint8* __buf, cyg_uint32 __len) { CYGARC_HAL_SAVE_GP(); while(__len-- > 0) #ifndef CYGSEM_HAL_VIRTUAL_VECTOR_SUPPORT *__buf++ = cyg_hal_plf_serial_getc(); #else *__buf++ = cyg_hal_plf_serial_getc(__ch_data); #endif CYGARC_HAL_RESTORE_GP(); } cyg_int32 msec_timeout = 1000; static cyg_bool cyg_hal_plf_serial_getc_timeout(void* __ch_data, cyg_uint8* ch) { int delay_count = msec_timeout * 10; // delay in .1 ms steps cyg_bool res; CYGARC_HAL_SAVE_GP(); for(;;) { res = cyg_hal_plf_serial_getc_nonblock(__ch_data, ch); if (res || 0 == delay_count--) break; CYGACC_CALL_IF_DELAY_US(100); } CYGARC_HAL_RESTORE_GP(); return res; } static int cyg_hal_plf_serial_control(void *__ch_data, __comm_control_cmd_t __func, ...) { static int irq_state = 0; int ret = 0; cyg_uint32 regval; CYGARC_HAL_SAVE_GP(); switch (__func) { case __COMMCTL_IRQ_ENABLE: //HAL_INTERRUPT_UNMASK(CYGNUM_HAL_INTERRUPT_CPM_SMC1); // For now, don't bother calling a macro, just do it here // Bit 8 in the SIMR_L corresponds to SCC1 HAL_READ_UINT32( ((char *) IMM) + 0x10000 + CYGARC_REG_IMM_SIMR_L, regval); regval |= 0x00800000; HAL_WRITE_UINT32( ((char *) IMM) + 0x10000 + CYGARC_REG_IMM_SIMR_L, regval); asm volatile ("ori %0, 0, 0x1234;" \ : /* No output */ \ : "I" (22)); /* %0 ==> r2 */ //RxTxBD->RxBD.bd_cstatus = 0xB000; irq_state = 1; //RED_LED_ON; break; case __COMMCTL_IRQ_DISABLE: ret = irq_state; irq_state = 0; //HAL_INTERRUPT_MASK(CYGNUM_HAL_INTERRUPT_CPM_SMC1); HAL_READ_UINT32( ((char *) IMM) + 0x10000 + CYGARC_REG_IMM_SIMR_L, regval); regval &= 0xFF7FFFFF; HAL_WRITE_UINT32( ((char *) IMM) + 0x10000 + CYGARC_REG_IMM_SIMR_L, regval); //RED_LED_OFF; //RxTxBD->RxBD.bd_cstatus = 0xA000; break; case __COMMCTL_DBG_ISR_VECTOR: //ret = CYGNUM_HAL_INTERRUPT_CPM_SMC1; ret = CYGNUM_HAL_INTERRUPT_SCC1; //ret = 0x01; break; case __COMMCTL_SET_TIMEOUT: { va_list ap; va_start(ap, __func); ret = msec_timeout; msec_timeout = va_arg(ap, cyg_uint32); va_end(ap); } default: break; } CYGARC_HAL_RESTORE_GP(); return ret; } // EOF hal_aux.c
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