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[/] [openrisc/] [trunk/] [rtos/] [freertos-6.1.1/] [Demo/] [CORTEX_LM3S811_IAR/] [LuminaryCode/] [ssi.c] - Rev 581
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//***************************************************************************** // // ssi.c - Driver for Synchronous Serial Interface. // // Copyright (c) 2005,2006 Luminary Micro, Inc. All rights reserved. // // Software License Agreement // // Luminary Micro, Inc. (LMI) is supplying this software for use solely and // exclusively on LMI's Stellaris Family of microcontroller products. // // The software is owned by LMI and/or its suppliers, and is protected under // applicable copyright laws. All rights are reserved. Any use in violation // of the foregoing restrictions may subject the user to criminal sanctions // under applicable laws, as well as to civil liability for the breach of the // terms and conditions of this license. // // THIS SOFTWARE IS PROVIDED "AS IS". NO WARRANTIES, WHETHER EXPRESS, IMPLIED // OR STATUTORY, INCLUDING, BUT NOT LIMITED TO, IMPLIED WARRANTIES OF // MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. // LMI SHALL NOT, IN ANY CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR // CONSEQUENTIAL DAMAGES, FOR ANY REASON WHATSOEVER. // // This is part of revision 991 of the Stellaris Driver Library. // //***************************************************************************** //***************************************************************************** // //! \addtogroup ssi_api //! @{ // //***************************************************************************** #include "../hw_ints.h" #include "../hw_memmap.h" #include "../hw_ssi.h" #include "../hw_types.h" #include "debug.h" #include "interrupt.h" #include "ssi.h" #include "sysctl.h" //***************************************************************************** // //! Configures the synchronous serial interface. //! //! \param ulBase specifies the SSI module base address. //! \param ulProtocol specifies the data transfer protocol. //! \param ulMode specifies the mode of operation. //! \param ulBitRate specifies the clock rate. //! \param ulDataWidth specifies number of bits transfered per frame. //! //! This function configures the synchronous serial interface. It sets //! the SSI protocol, mode of operation, bit rate, and data width. //! //! The parameter \e ulProtocol defines the data frame format. The parameter //! \e ulProtocol can be one of the following values: SSI_FRF_MOTO_MODE_0, //! SSI_FRF_MOTO_MODE_1, SSI_FRF_MOTO_MODE_2, SSI_FRF_MOTO_MODE_3, //! SSI_FRF_TI, or SSI_FRF_NMW. The Motorola frame formats imply the //! following polarity and phase configurations: //! <pre> //! Polarity Phase Mode //! 0 0 SSI_FRF_MOTO_MODE_0 //! 0 1 SSI_FRF_MOTO_MODE_1 //! 1 0 SSI_FRF_MOTO_MODE_2 //! 1 1 SSI_FRF_MOTO_MODE_3 //! </pre> //! //! The parameter \e ulMode defines the operating mode of the SSI module. The //! SSI module can operate as a master or slave; if a slave, the SSI can be //! configured to disable output on its serial output line. The parameter //! \e ulMode can be one of the following values: SSI_MODE_MASTER, //! SSI_MODE_SLAVE, or SSI_MODE_SLAVE_OD. //! //! The parameter \e ulBitRate defines the bit rate for the SSI. This bit rate //! must satisfy the following clock ratio criteria: //! - FSSI >= 2 * bit rate (master mode) //! - FSSI >= 12 * bit rate (slave modes) //! //! where FSSI is the frequency of the clock supplied to the SSI module. //! //! The parameter \e ulDataWidth defines the width of the data transfers. //! The parameter \e ulDataWidth can be a value between 4 and 16, inclusive. //! //! The SSI clocking is dependent upon the system clock rate returned by //! SysCtlClockGet(); if it does not return the correct system clock rate then //! the SSI clock rate will be incorrect. //! //! \return None. // //***************************************************************************** #if defined(GROUP_config) || defined(BUILD_ALL) || defined(DOXYGEN) void SSIConfig(unsigned long ulBase, unsigned long ulProtocol, unsigned long ulMode, unsigned long ulBitRate, unsigned long ulDataWidth) { unsigned long ulMaxBitRate; unsigned long ulRegVal; unsigned long ulPreDiv; unsigned long ulSCR; unsigned long ulSPH_SPO; unsigned long ulClock; // // Check the arguments. // ASSERT(ulBase == SSI_BASE); ASSERT((ulProtocol == SSI_FRF_MOTO_MODE_0) || (ulProtocol == SSI_FRF_MOTO_MODE_1) || (ulProtocol == SSI_FRF_MOTO_MODE_2) || (ulProtocol == SSI_FRF_MOTO_MODE_3) || (ulProtocol == SSI_FRF_TI) || (ulProtocol == SSI_FRF_NMW)); ASSERT((ulMode == SSI_MODE_MASTER) || (ulMode == SSI_MODE_SLAVE) || (ulMode == SSI_MODE_SLAVE_OD)); ASSERT((ulDataWidth >= 4) && (ulDataWidth <= 16)); // // Get the processor clock rate. // ulClock = SysCtlClockGet(); // // Validate the clock speed. // ASSERT(((ulMode == SSI_MODE_MASTER) && (ulBitRate <= (ulClock / 2))) || ((ulMode != SSI_MODE_MASTER) && (ulBitRate <= (ulClock / 12)))); ASSERT((ulClock / ulBitRate) <= (254 * 256)); // // Set the mode. // ulRegVal = (ulMode == SSI_MODE_SLAVE_OD) ? SSI_CR1_SOD : 0; ulRegVal |= (ulMode == SSI_MODE_MASTER) ? 0 : SSI_CR1_MS; HWREG(ulBase + SSI_O_CR1) = ulRegVal; // // Set the clock predivider. // ulMaxBitRate = ulClock / ulBitRate; ulPreDiv = 0; do { ulPreDiv += 2; ulSCR = (ulMaxBitRate / ulPreDiv) - 1; } while(ulSCR > 255); HWREG(ulBase + SSI_O_CPSR) = ulPreDiv; // // Set protocol and clock rate. // ulSPH_SPO = ulProtocol << 6; ulProtocol &= SSI_CR0_FRF_MASK; ulRegVal = (ulSCR << 8) | ulSPH_SPO | ulProtocol | (ulDataWidth - 1); HWREG(ulBase + SSI_O_CR0) = ulRegVal; } #endif //***************************************************************************** // //! Enables the synchronous serial interface. //! //! \param ulBase specifies the SSI module base address. //! //! This will enable operation of the synchronous serial interface. It must be //! configured before it is enabled. //! //! \return None. // //***************************************************************************** #if defined(GROUP_enable) || defined(BUILD_ALL) || defined(DOXYGEN) void SSIEnable(unsigned long ulBase) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); // // Read-modify-write the enable bit. // HWREG(ulBase + SSI_O_CR1) |= SSI_CR1_SSE; } #endif //***************************************************************************** // //! Disables the synchronous serial interface. //! //! \param ulBase specifies the SSI module base address. //! //! This will disable operation of the synchronous serial interface. //! //! \return None. // //***************************************************************************** #if defined(GROUP_disable) || defined(BUILD_ALL) || defined(DOXYGEN) void SSIDisable(unsigned long ulBase) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); // // Read-modify-write the enable bit. // HWREG(ulBase + SSI_O_CR1) &= ~(SSI_CR1_SSE); } #endif //***************************************************************************** // //! Registers an interrupt handler for the synchronous serial interface. //! //! \param ulBase specifies the SSI module base address. //! \param pfnHandler is a pointer to the function to be called when the //! synchronous serial interface interrupt occurs. //! //! This sets the handler to be called when an SSI interrupt //! occurs. This will enable the global interrupt in the interrupt controller; //! specific SSI interrupts must be enabled via SSIIntEnable(). If necessary, //! it is the interrupt handler's responsibility to clear the interrupt source //! via SSIIntClear(). //! //! \sa IntRegister() for important information about registering interrupt //! handlers. //! //! \return None. // //***************************************************************************** #if defined(GROUP_intregister) || defined(BUILD_ALL) || defined(DOXYGEN) void SSIIntRegister(unsigned long ulBase, void (*pfnHandler)(void)) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); // // Register the interrupt handler, returning an error if an error occurs. // IntRegister(INT_SSI, pfnHandler); // // Enable the synchronous serial interface interrupt. // IntEnable(INT_SSI); } #endif //***************************************************************************** // //! Unregisters an interrupt handler for the synchronous serial interface. //! //! \param ulBase specifies the SSI module base address. //! //! This function will clear the handler to be called when a SSI //! interrupt occurs. This will also mask off the interrupt in the interrupt //! controller so that the interrupt handler no longer is called. //! //! \sa IntRegister() for important information about registering interrupt //! handlers. //! //! \return None. // //***************************************************************************** #if defined(GROUP_intunregister) || defined(BUILD_ALL) || defined(DOXYGEN) void SSIIntUnregister(unsigned long ulBase) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); // // Disable the interrupt. // IntDisable(INT_SSI); // // Unregister the interrupt handler. // IntUnregister(INT_SSI); } #endif //***************************************************************************** // //! Enables individual SSI interrupt sources. //! //! \param ulBase specifies the SSI module base address. //! \param ulIntFlags is a bit mask of the interrupt sources to be enabled. //! //! Enables the indicated SSI interrupt sources. Only the sources that are //! enabled can be reflected to the processor interrupt; disabled sources //! have no effect on the processor. The parameter \e ulIntFlags Can be //! any of the SSI_TXFF, SSI_RXFF, SSI_RXTO, or SSI_RXOR values. //! //! \return None. // //***************************************************************************** #if defined(GROUP_intenable) || defined(BUILD_ALL) || defined(DOXYGEN) void SSIIntEnable(unsigned long ulBase, unsigned long ulIntFlags) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); // // Enable the specified interrupts. // HWREG(ulBase + SSI_O_IM) |= ulIntFlags; } #endif //***************************************************************************** // //! Disables individual SSI interrupt sources. //! //! \param ulBase specifies the SSI module base address. //! \param ulIntFlags is a bit mask of the interrupt sources to be disabled. //! //! Disables the indicated SSI interrupt sources. The parameter //! \e ulIntFlags Can be any of the SSI_TXFF, SSI_RXFF, SSI_RXTO, //! or SSI_RXOR values. //! //! \return None. // //***************************************************************************** #if defined(GROUP_intdisable) || defined(BUILD_ALL) || defined(DOXYGEN) void SSIIntDisable(unsigned long ulBase, unsigned long ulIntFlags) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); // // Disable the specified interrupts. // HWREG(ulBase + SSI_O_IM) &= ~(ulIntFlags); } #endif //***************************************************************************** // //! Gets the current interrupt status. //! //! \param ulBase specifies the SSI module base address. //! \param bMasked is false if the raw interrupt status is required and //! true if the masked interrupt status is required. //! //! This returns the interrupt status for the SSI module. //! Either the raw interrupt status or the status of interrupts that are //! allowed to reflect to the processor can be returned. //! //! \return The current interrupt status, enumerated as a bit field of //! SSI_TXFF, SSI_RXFF, SSI_RXTO, and SSI_RXOR. // //***************************************************************************** #if defined(GROUP_intstatus) || defined(BUILD_ALL) || defined(DOXYGEN) unsigned long SSIIntStatus(unsigned long ulBase, tBoolean bMasked) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); // // Return either the interrupt status or the raw interrupt status as // requested. // if(bMasked) { return(HWREG(ulBase + SSI_O_MIS)); } else { return(HWREG(ulBase + SSI_O_RIS)); } } #endif //***************************************************************************** // //! Clears SSI interrupt sources. //! //! \param ulBase specifies the SSI module base address. //! \param ulIntFlags is a bit mask of the interrupt sources to be cleared. //! //! The specified SSI interrupt sources are cleared, so that //! they no longer assert. This must be done in the interrupt handler to //! keep it from being called again immediately upon exit. //! The parameter \e ulIntFlags can consist of either or both the SSI_RXTO //! and SSI_RXOR values. //! //! \return None. // //***************************************************************************** #if defined(GROUP_intclear) || defined(BUILD_ALL) || defined(DOXYGEN) void SSIIntClear(unsigned long ulBase, unsigned long ulIntFlags) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); // // Clear the requested interrupt sources. // HWREG(ulBase + SSI_O_ICR) = ulIntFlags; } #endif //***************************************************************************** // //! Puts a data element into the SSI transmit FIFO. //! //! \param ulBase specifies the SSI module base address. //! \param ulData data to be transmitted over the SSI interface. //! //! This function will place the supplied data into the transmit FIFO of //! the specified SSI module. //! //! \note The upper 32 - N bits of the \e ulData will be discarded by the //! hardware, where N is the data width as configured by SSIConfig(). For //! example, if the interface is configured for 8 bit data width, the upper 24 //! bits of \e ulData will be discarded. //! //! \return None. // //***************************************************************************** #if defined(GROUP_dataput) || defined(BUILD_ALL) || defined(DOXYGEN) void SSIDataPut(unsigned long ulBase, unsigned long ulData) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); ASSERT((ulData & (0xfffffffe << (HWREG(ulBase + SSI_O_CR0) & SSI_CR0_DSS))) == 0); // // Wait until there is space. // while(!(HWREG(ulBase + SSI_O_SR) & SSI_SR_TNF)) { } // // Write the data to the SSI. // HWREG(ulBase + SSI_O_DR) = ulData; } #endif //***************************************************************************** // //! Puts a data element into the SSI transmit FIFO. //! //! \param ulBase specifies the SSI module base address. //! \param ulData data to be transmitted over the SSI interface. //! //! This function will place the supplied data into the transmit FIFO of //! the specified SSI module. If there is no space in the FIFO, then this //! function will return a zero. //! //! \note The upper 32 - N bits of the \e ulData will be discarded by the //! hardware, where N is the data width as configured by SSIConfig(). For //! example, if the interface is configured for 8 bit data width, the upper 24 //! bits of \e ulData will be discarded. //! //! \return Returns the number of elements written to the SSI transmit FIFO. // //***************************************************************************** #if defined(GROUP_datanonblockingput) || defined(BUILD_ALL) || defined(DOXYGEN) long SSIDataNonBlockingPut(unsigned long ulBase, unsigned long ulData) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); ASSERT((ulData & (0xfffffffe << (HWREG(ulBase + SSI_O_CR0) & SSI_CR0_DSS))) == 0); // // Check for space to write. // if(HWREG(ulBase + SSI_O_SR) & SSI_SR_TNF) { HWREG(ulBase + SSI_O_DR) = ulData; return(1); } else { return(0); } } #endif //***************************************************************************** // //! Gets a data element from the SSI receive FIFO. //! //! \param ulBase specifies the SSI module base address. //! \param pulData pointer to a storage location for data that was received //! over the SSI interface. //! //! This function will get received data from the receive FIFO of the specified //! SSI module, and place that data into the location specified by the //! \e pulData parameter. //! //! \note Only the lower N bits of the value written to \e pulData will contain //! valid data, where N is the data width as configured by SSIConfig(). For //! example, if the interface is configured for 8 bit data width, only the //! lower 8 bits of the value written to \e pulData will contain valid data. //! //! \return None. // //***************************************************************************** #if defined(GROUP_dataget) || defined(BUILD_ALL) || defined(DOXYGEN) void SSIDataGet(unsigned long ulBase, unsigned long *pulData) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); // // Wait until there is data to be read. // while(!(HWREG(ulBase + SSI_O_SR) & SSI_SR_RNE)) { } // // Read data from SSI. // *pulData = HWREG(ulBase + SSI_O_DR); } #endif //***************************************************************************** // //! Gets a data element from the SSI receive FIFO. //! //! \param ulBase specifies the SSI module base address. //! \param pulData pointer to a storage location for data that was received //! over the SSI interface. //! //! This function will get received data from the receive FIFO of //! the specified SSI module, and place that data into the location specified //! by the \e ulData parameter. If there is no data in the FIFO, then this //! function will return a zero. //! //! \note Only the lower N bits of the value written to \e pulData will contain //! valid data, where N is the data width as configured by SSIConfig(). For //! example, if the interface is configured for 8 bit data width, only the //! lower 8 bits of the value written to \e pulData will contain valid data. //! //! \return Returns the number of elements read from the SSI receive FIFO. // //***************************************************************************** #if defined(GROUP_datanonblockingget) || defined(BUILD_ALL) || defined(DOXYGEN) long SSIDataNonBlockingGet(unsigned long ulBase, unsigned long *pulData) { // // Check the arguments. // ASSERT(ulBase == SSI_BASE); // // Check for data to read. // if(HWREG(ulBase + SSI_O_SR) & SSI_SR_RNE) { *pulData = HWREG(ulBase + SSI_O_DR); return(1); } else { return(0); } } #endif //***************************************************************************** // // Close the Doxygen group. //! @} // //*****************************************************************************