//########################################################################### // // FILE: F2837xD_McBSP.c // // TITLE: F2837xD Device McBSP Initialization & Support Functions. // //########################################################################### // $TI Release: F2837xD Support Library v3.05.00.00 $ // $Release Date: Tue Jun 26 03:15:23 CDT 2018 $ // $Copyright: // Copyright (C) 2013-2018 Texas Instruments Incorporated - http://www.ti.com/ // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions // are met: // // Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // // Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in the // documentation and/or other materials provided with the // distribution. // // Neither the name of Texas Instruments Incorporated nor the names of // its contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // $ //########################################################################### // // Included Files // #include "F2837xD_device.h" #include "F2837xD_Examples.h" // // MCBSP_INIT_DELAY determines the amount of CPU cycles in the 2 sample rate // generator (SRG) cycles required for the Mcbsp initialization routine. // MCBSP_CLKG_DELAY determines the amount of CPU cycles in the 2 clock // generator (CLKG) cycles required for the Mcbsp initialization routine. // // // Defines // #define CPU_SPD 200E6 #define MCBSP_SRG_FREQ CPU_SPD/4 // SRG input is LSPCLK (SYSCLKOUT/4) // for examples #define CLKGDV_VAL 1 // # of CPU cycles in 2 SRG cycles-init delay #define MCBSP_INIT_DELAY 2*(CPU_SPD/MCBSP_SRG_FREQ) // # of CPU cycles in 2 CLKG cycles-init delay #define MCBSP_CLKG_DELAY 2*(CPU_SPD/(MCBSP_SRG_FREQ/(1+CLKGDV_VAL))) // // Function Prototypes // void delay_loop(void); // Delay function used for SRG initialization void clkg_delay_loop(void); // Delay function used for CLKG initialization // // InitMcbsp - This function initializes the McBSP to a known state. // void InitMcbspa(void) { // // Reset the McBSP // Disable all interrupts // Frame sync generator reset // Sample rate generator reset // Transmitter reset // Receiver reset // McbspaRegs.SPCR2.bit.FRST = 0; McbspaRegs.SPCR2.bit.GRST = 0; McbspaRegs.SPCR2.bit.XRST = 0; McbspaRegs.SPCR1.bit.RRST = 0; // // Enable loop back mode // This does not require external hardware // McbspaRegs.SPCR2.all = 0x0000; McbspaRegs.SPCR1.all = 0x8000; // // RX data delay is 1 bit // TX data delay is 1 bit // McbspaRegs.RCR2.bit.RDATDLY = 1; McbspaRegs.XCR2.bit.XDATDLY = 1; // // No clock sync for CLKG // Frame-synchronization period // McbspaRegs.SRGR2.bit.GSYNC = 0; McbspaRegs.SRGR2.bit.FPER = 320; // // Frame-synchronization pulses from // the sample rate generator // McbspaRegs.SRGR2.bit.FSGM = 1; // // Sample rate generator input clock is LSPCLK // McbspaRegs.SRGR2.bit.CLKSM = 1; McbspaRegs.PCR.bit.SCLKME = 0; // // Divide-down value for CLKG // Frame-synchronization pulse width // McbspaRegs.SRGR1.bit.CLKGDV = CLKGDV_VAL; clkg_delay_loop(); McbspaRegs.SRGR1.bit.FWID = 1; // // CLKX is driven by the sample rate generator // Transmit frame synchronization generated by internal // sample rate generator // McbspaRegs.PCR.bit.CLKXM = 1; McbspaRegs.PCR.bit.FSXM = 1; // // Enable Sample rate generator and // wait at least 2 CLKG clock cycles // McbspaRegs.SPCR2.bit.GRST = 1; clkg_delay_loop(); // // Release from reset // RX, TX and frame sync generator // McbspaRegs.SPCR2.bit.XRST = 1; McbspaRegs.SPCR1.bit.RRST = 1; McbspaRegs.SPCR2.bit.FRST = 1; } // // InitMcbspaInt - Enable TX and RX interrupts // void InitMcbspaInt(void) { // Reset TX and RX // Enable interrupts for TX and RX // Release TX and RX McbspaRegs.SPCR2.bit.XRST = 0; McbspaRegs.SPCR1.bit.RRST = 0; McbspaRegs.MFFINT.bit.XINT = 1; McbspaRegs.MFFINT.bit.RINT = 1; McbspaRegs.SPCR2.bit.XRST = 1; McbspaRegs.SPCR1.bit.RRST = 1; } // // InitMcbspa8bit - McBSP uses an 8-bit word for both TX and RX // void InitMcbspa8bit(void) { McbspaRegs.RCR1.bit.RWDLEN1 = 0; McbspaRegs.XCR1.bit.XWDLEN1 = 0; } // // InitMcbspa12bit - McBSP uses an 12-bit word for both TX and RX // void InitMcbspa12bit(void) { McbspaRegs.RCR1.bit.RWDLEN1 = 1; McbspaRegs.XCR1.bit.XWDLEN1 = 1; } // // InitMcbspa16bit - McBSP uses an 16-bit word for both TX and RX // void InitMcbspa16bit(void) { McbspaRegs.RCR1.bit.RWDLEN1 = 2; McbspaRegs.XCR1.bit.XWDLEN1 = 2; } // // InitMcbspa20bit - McBSP uses an 20-bit word for both TX and RX // void InitMcbspa20bit(void) { McbspaRegs.RCR1.bit.RWDLEN1 = 3; McbspaRegs.XCR1.bit.XWDLEN1 = 3; } // // InitMcbspa24bit - McBSP uses an 24-bit word for both TX and RX // void InitMcbspa24bit(void) { McbspaRegs.RCR1.bit.RWDLEN1 = 4; McbspaRegs.XCR1.bit.XWDLEN1 = 4; } // // InitMcbspa32bit - McBSP uses an 32-bit word for both TX and RX // void InitMcbspa32bit(void) { McbspaRegs.RCR1.bit.RWDLEN1 = 5; McbspaRegs.XCR1.bit.XWDLEN1 = 5; } // // InitMcbspaGpio - Assign GPIO pins to the McBSP peripheral // (Note: This function must be called from CPU1.) // void InitMcbspaGpio(void) { #ifdef CPU1 EALLOW; // // This specifies which of the possible GPIO pins will be // McBSPA functional pins. Comment out unwanted connections. // Set qualification for selected input pins to asynchronous only // This will select asynchronous (no qualification) for the selected pins. // // // MDXA // GPIO20 // GPIO84 // GpioCtrlRegs.GPAMUX2.bit.GPIO20 = 2; //GpioCtrlRegs.GPCGMUX2.bit.GPIO84 = 3; //GpioCtrlRegs.GPCMUX2.bit.GPIO84 = 3; // // MDRA // GPIO21 with asynchronous qualification // GPIO85 with asynchronous qualification // GpioCtrlRegs.GPAMUX2.bit.GPIO21 = 2; GpioCtrlRegs.GPAQSEL2.bit.GPIO21 = 3; //GpioCtrlRegs.GPCGMUX2.bit.GPIO85 = 3; //GpioCtrlRegs.GPCMUX2.bit.GPIO85 = 3; //GpioCtrlRegs.GPCQSEL2.bit.GPIO85 = 3; // // MCLKXA // GPIO22 with asynchronous qualification // GPIO86 with asynchronous qualification // GpioCtrlRegs.GPAMUX2.bit.GPIO22 = 2; //GpioCtrlRegs.GPAQSEL2.bit.GPIO22 = 3; //GpioCtrlRegs.GPCGMUX2.bit.GPIO86 = 3; //GpioCtrlRegs.GPCMUX2.bit.GPIO86 = 3; //GpioCtrlRegs.GPCQSEL2.bit.GPIO86 = 3; // // MCLKRA // Select one of the following // GPIO7 with asynchronous qualification // GPIO58 with asynchronous qualification // GpioCtrlRegs.GPAMUX1.bit.GPIO7 = 2; GpioCtrlRegs.GPAQSEL1.bit.GPIO7 = 3; //GpioCtrlRegs.GPBMUX2.bit.GPIO58 = 1; //GpioCtrlRegs.GPBQSEL2.bit.GPIO58 = 3; // // MFSXA // GPIO23 with asynchronous qualification // GPIO87 with asynchronous qualification // GpioCtrlRegs.GPAMUX2.bit.GPIO23 = 2; //GpioCtrlRegs.GPAQSEL2.bit.GPIO23 = 3; //GpioCtrlRegs.GPCGMUX2.bit.GPIO87 = 3; //GpioCtrlRegs.GPCMUX2.bit.GPIO87 = 3; //GpioCtrlRegs.GPCQSEL2.bit.GPIO87 = 3; // // MFSRA // Select one of the following // GPIO5 with asynchronous qualification // GPIO59 with asynchronous qualification // GpioCtrlRegs.GPAMUX1.bit.GPIO5 = 2; GpioCtrlRegs.GPAQSEL1.bit.GPIO5 = 3; //GpioCtrlRegs.GPBMUX2.bit.GPIO59 = 1; //GpioCtrlRegs.GPBQSEL2.bit.GPIO59 = 3; EDIS; #endif } // // InitMcbspb - McBSPB initialization routine for examples // void InitMcbspb(void) { // // Reset the McBSP // Disable all interrupts // Frame sync generator reset // Sample rate generator reset // Transmitter reset // Receiver reset // McbspbRegs.SPCR2.bit.FRST = 0; McbspbRegs.SPCR2.bit.GRST = 0; McbspbRegs.SPCR2.bit.XRST = 0; McbspbRegs.SPCR1.bit.RRST = 0; // // Enable loop back mode // This does not require external hardware // McbspbRegs.SPCR2.all = 0x0000; McbspbRegs.SPCR1.all = 0x8000; // // RX data delay is 1 bit // TX data delay is 1 bit // McbspbRegs.RCR2.bit.RDATDLY = 1; McbspbRegs.XCR2.bit.XDATDLY = 1; // // No clock sync for CLKG // Frame-synchronization period // McbspbRegs.SRGR2.bit.GSYNC = 0; McbspbRegs.SRGR2.bit.FPER = 320; // // Frame-synchronization pulses from // the sample rate generator // McbspbRegs.SRGR2.bit.FSGM = 1; // // Sample rate generator input clock is LSPCLK // McbspbRegs.SRGR2.bit.CLKSM = 1; McbspbRegs.PCR.bit.SCLKME = 0; // // Divide-down value for CLKG // Frame-synchronization pulse width // McbspbRegs.SRGR1.bit.CLKGDV = CLKGDV_VAL; clkg_delay_loop(); McbspbRegs.SRGR1.bit.FWID = 1; // // CLKX is driven by the sample rate generator // Transmit frame synchronization generated by internal // sample rate generator // McbspbRegs.PCR.bit.CLKXM = 1; McbspbRegs.PCR.bit.FSXM = 1; // // Enable Sample rate generator and // wait at least 2 CLKG clock cycles // McbspbRegs.SPCR2.bit.GRST = 1; clkg_delay_loop(); // // Release from reset // RX, TX and frame sync generator // McbspbRegs.SPCR2.bit.XRST = 1; McbspbRegs.SPCR1.bit.RRST = 1; McbspbRegs.SPCR2.bit.FRST = 1; } // // InitMcbspbInt - Enable TX and RX interrupts // void InitMcbspbInt(void) { // // Reset TX and RX // Enable interrupts for TX and RX // Release TX and RX // McbspbRegs.SPCR2.bit.XRST = 0; McbspbRegs.SPCR1.bit.RRST = 0; McbspbRegs.MFFINT.bit.XINT = 1; McbspbRegs.MFFINT.bit.RINT = 1; McbspbRegs.SPCR2.bit.XRST = 1; McbspbRegs.SPCR1.bit.RRST = 1; } // // InitMcbspb8bit - McBSPB uses an 8-bit word for both TX and RX // void InitMcbspb8bit(void) { McbspbRegs.RCR1.bit.RWDLEN1 = 0; McbspbRegs.XCR1.bit.XWDLEN1 = 0; } // // IniMcbspb12bit - McBSPB uses an 12-bit word for both TX and RX // void IniMcbspb12bit(void) { McbspbRegs.RCR1.bit.RWDLEN1 = 1; McbspbRegs.XCR1.bit.XWDLEN1 = 1; } // // InitMcbspb16bit - McBSPB uses an 16-bit word for both TX and RX // void InitMcbspb16bit(void) { McbspbRegs.RCR1.bit.RWDLEN1 = 2; McbspbRegs.XCR1.bit.XWDLEN1 = 2; } // // InitMcbspb20bit - McBSPB uses an 20-bit word for both TX and RX // void InitMcbspb20bit(void) { McbspbRegs.RCR1.bit.RWDLEN1 = 3; McbspbRegs.XCR1.bit.XWDLEN1 = 3; } // // InitMcbspb24bit - McBSPB uses an 24-bit word for both TX and RX // void InitMcbspb24bit(void) { McbspbRegs.RCR1.bit.RWDLEN1 = 4; McbspbRegs.XCR1.bit.XWDLEN1 = 4; } // // InitMcbspb32bit - McBSPB uses an 32-bit word for both TX and RX // void InitMcbspb32bit(void) { McbspbRegs.RCR1.bit.RWDLEN1 = 5; McbspbRegs.XCR1.bit.XWDLEN1 = 5; } // // InitMcbspbGpio - Assign GPIO pins to the McBSP peripheral // (Note: This function must be called from CPU1.) // void InitMcbspbGpio(void) { #ifdef CPU1 EALLOW; // // This specifies which of the possible GPIO pins will be // McBSPB functional pins. Comment out unwanted connections. // Set qualification for selected input pins to asynchronous only // This will select asynchronous (no qualification) for the selected pins. // // // Select one of the following for MDXB // GPIO24 // GPIO84 // //GpioCtrlRegs.GPAMUX2.bit.GPIO24 = 3; GpioCtrlRegs.GPCGMUX2.bit.GPIO84 = 1; GpioCtrlRegs.GPCMUX2.bit.GPIO84 = 2; // // MDRB // GPIO13 with asynchronous qualification // GPIO25 with asynchronous qualification // GPIO85 with asynchronous qualification // //GpioCtrlRegs.GPAMUX1.bit.GPIO13 = 3; //GpioCtrlRegs.GPAQSEL1.bit.GPIO13 = 3; //GpioCtrlRegs.GPAMUX2.bit.GPIO25 = 3; //GpioCtrlRegs.GPAQSEL2.bit.GPIO25 = 3; GpioCtrlRegs.GPCGMUX2.bit.GPIO85 = 1; GpioCtrlRegs.GPCMUX2.bit.GPIO85 = 2; GpioCtrlRegs.GPCQSEL2.bit.GPIO85 = 3; // // MCLKXB // GPIO14 with asynchronous qualification // GPIO26 with asynchronous qualification // GPIO86 with asynchronous qualification // //GpioCtrlRegs.GPAMUX1.bit.GPIO14 = 3; //GpioCtrlRegs.GPAQSEL1.bit.GPIO14 = 3; //GpioCtrlRegs.GPAMUX2.bit.GPIO26 = 3; //GpioCtrlRegs.GPAQSEL2.bit.GPIO26 = 3; GpioCtrlRegs.GPCGMUX2.bit.GPIO86 = 1; GpioCtrlRegs.GPCMUX2.bit.GPIO86 = 2; GpioCtrlRegs.GPCQSEL2.bit.GPIO86= 3; // // MCLKRB // Select one of the following // GPIO3 with asynchronous qualification // GPIO60 with asynchronous qualification // //GpioCtrlRegs.GPAMUX1.bit.GPIO3 = 3; //GpioCtrlRegs.GPAQSEL1.bit.GPIO3 = 3; GpioCtrlRegs.GPBMUX2.bit.GPIO60 = 1; GpioCtrlRegs.GPBQSEL2.bit.GPIO60 = 3; // // MFSXB // GPIO15 with asynchronous qualification // GPIO27 with asynchronous qualification // GPIO87 with asynchronous qualification // //GpioCtrlRegs.GPAMUX1.bit.GPIO15 = 3; //GpioCtrlRegs.GPAQSEL1.bit.GPIO15 = 3; //GpioCtrlRegs.GPAMUX2.bit.GPIO27 = 3; //GpioCtrlRegs.GPAQSEL2.bit.GPIO27 = 3; GpioCtrlRegs.GPCGMUX2.bit.GPIO87 = 1; GpioCtrlRegs.GPCMUX2.bit.GPIO87 = 2; GpioCtrlRegs.GPCQSEL2.bit.GPIO87= 3; // // MFSRB // Select one of the following // GPIO1 with asynchronous qualification // GPIO61 with asynchronous qualification // //GpioCtrlRegs.GPAMUX1.bit.GPIO1 = 3; //GpioCtrlRegs.GPAQSEL1.bit.GPIO1 = 3; GpioCtrlRegs.GPBMUX2.bit.GPIO61 = 1; GpioCtrlRegs.GPBQSEL2.bit.GPIO61 = 3; EDIS; #endif } // // delay_loop - Delay function (at least 2 SRG cycles) // Required in McBSP initialization // void delay_loop(void) { long i; for (i = 0; i < MCBSP_INIT_DELAY; i++) {} } // // clkg_delay_loop - Delay function (at least 2 CLKG cycles) // Required in McBSP init // void clkg_delay_loop(void) { long i; for (i = 0; i < MCBSP_CLKG_DELAY; i++) {} } // // End of file //