//***************************************************************************** // // epi.c - Driver for the EPI module. // // Copyright (c) 2008-2014 Texas Instruments Incorporated. All rights reserved. // Software License Agreement // // 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. // // This is part of revision 2.1.0.12573 of the Tiva Peripheral Driver Library. // //***************************************************************************** #include #include #include "inc/hw_epi.h" #include "inc/hw_ints.h" #include "inc/hw_memmap.h" #include "inc/hw_sysctl.h" #include "inc/hw_types.h" #include "driverlib/debug.h" #include "driverlib/epi.h" #include "driverlib/interrupt.h" //***************************************************************************** // //! \addtogroup epi_api //! @{ // //***************************************************************************** //***************************************************************************** // // Helper masks for chip select configuration options. // //***************************************************************************** #define EPI_HB8_CS_MASK (EPI_HB8_MODE_FIFO | EPI_HB8_RDWAIT_3 | \ EPI_HB8_WRWAIT_3 | EPI_HB8_RDHIGH | \ EPI_HB8_WRHIGH | EPI_HB8_ALE_HIGH) #define EPI_HB16_CS_MASK (EPI_HB8_CS_MASK | EPI_HB16_BURST_TRAFFIC) //***************************************************************************** // // Ensure that erratum workaround inline functions have a public version // available in exactly one object module (this one). // //***************************************************************************** //***************************************************************************** // //! Safely writes a word to the EPI 0x10000000 address space. //! //! \param pui32Addr is the address which is to be written. //! \param ui32Value is the 32-bit word to write. //! //! This function must be used when writing words to EPI-attached memory //! configured to use the address space at 0x10000000 on devices affected by //! the EPI#01 erratum. Direct access to memory in these cases can cause data //! corruption depending upon memory accesses immediately before or after the //! EPI access but using this function will allow EPI accesses to complete //! correctly. The function is defined as ``inline'' in epi.h. //! //! Use of this function on a device not affected by the erratum is safe but //! will impact performance due to an additional overhead of at least 2 cycles //! per access. This erratum affects only the 0x10000000 address space //! typically used to store the LCD controller frame buffer. The 0x60000000 //! address space is not affected and applications using this address mapping //! need not use this function. //! //! \return None. // //***************************************************************************** extern void EPIWorkaroundWordWrite(uint32_t *pui32Addr, uint32_t ui32Value); //***************************************************************************** // //! Safely reads a word from the EPI 0x10000000 address space. //! //! \param pui32Addr is the address which is to be read. //! //! This function must be used when reading words from EPI-attached memory //! configured to use the address space at 0x10000000 on devices affected by //! the EPI#01 erratum. Direct access to memory in these cases can cause data //! corruption depending upon memory accesses immediately before or after the //! EPI access but using this function will allow EPI accesses to complete //! correctly. The function is defined as ``inline'' in epi.h. //! //! Use of this function on a device not affected by the erratum is safe but //! will impact performance due to an additional overhead of at least 2 cycles //! per access. This erratum affects only the 0x10000000 address space //! typically used to store the LCD controller frame buffer. The 0x60000000 //! address space is not affected and applications using this address mapping //! need not use this function. //! //! \return The 32-bit word stored at address \e pui32Addr. // //***************************************************************************** extern uint32_t EPIWorkaroundWordRead(uint32_t *pui32Addr); //***************************************************************************** // //! Safely writes a half-word to the EPI 0x10000000 address space. //! //! \param pui16Addr is the address which is to be written. //! \param ui16Value is the 16-bit half-word to write. //! //! This function must be used when writing half-words to EPI-attached memory //! configured to use the address space at 0x10000000 on devices affected by //! the EPI#01 erratum. Direct access to memory in these cases can cause data //! corruption depending upon memory accesses immediately before or after the //! EPI access but using this function will allow EPI accesses to complete //! correctly. The function is defined as ``inline'' in epi.h. //! //! Use of this function on a device not affected by the erratum is safe but //! will impact performance due to an additional overhead of at least 2 cycles //! per access. This erratum affects only the 0x10000000 address space //! typically used to store the LCD controller frame buffer. The 0x60000000 //! address space is not affected and applications using this address mapping //! need not use this function. //! //! \return None. // //***************************************************************************** extern void EPIWorkaroundHWordWrite(uint16_t *pui16Addr, uint16_t ui16Value); //***************************************************************************** // //! Safely reads a half-word from the EPI 0x10000000 address space. //! //! \param pui16Addr is the address which is to be read. //! //! This function must be used when reading half-words from EPI-attached memory //! configured to use the address space at 0x10000000 on devices affected by //! the EPI#01 erratum. Direct access to memory in these cases can cause data //! corruption depending upon memory accesses immediately before or after the //! EPI access but using this function will allow EPI accesses to complete //! correctly. The function is defined as ``inline'' in epi.h. //! //! Use of this function on a device not affected by the erratum is safe but //! will impact performance due to an additional overhead of at least 2 cycles //! per access. This erratum affects only the 0x10000000 address space //! typically used to store the LCD controller frame buffer. The 0x60000000 //! address space is not affected and applications using this address mapping //! need not use this function. //! //! \return The 16-bit word stored at address \e pui16Addr. // //***************************************************************************** extern uint16_t EPIWorkaroundHWordRead(uint16_t *pui16Addr); //***************************************************************************** // //! Safely writes a byte to the EPI 0x10000000 address space. //! //! \param pui8Addr is the address which is to be written. //! \param ui8Value is the 8-bit byte to write. //! //! This function must be used when writing bytes to EPI-attached memory //! configured to use the address space at 0x10000000 on devices affected by //! the EPI#01 erratum. Direct access to memory in these cases can cause data //! corruption depending upon memory accesses immediately before or after the //! EPI access but using this function will allow EPI accesses to complete //! correctly. The function is defined as ``inline'' in epi.h. //! //! Use of this function on a device not affected by the erratum is safe but //! will impact performance due to an additional overhead of at least 2 cycles //! per access. This erratum affects only the 0x10000000 address space //! typically used to store the LCD controller frame buffer. The 0x60000000 //! address space is not affected and applications using this address mapping //! need not use this function. //! //! \return None. // //***************************************************************************** extern void EPIWorkaroundByteWrite(uint8_t *pui8Addr, uint8_t ui8Value); //***************************************************************************** // //! Safely reads a byte from the EPI 0x10000000 address space. //! //! \param pui8Addr is the address which is to be read. //! //! This function must be used when reading bytes from EPI-attached memory //! configured to use the address space at 0x10000000 on devices affected by //! the EPI#01 erratum. Direct access to memory in these cases can cause data //! corruption depending upon memory accesses immediately before or after the //! EPI access but using this function will allow EPI accesses to complete //! correctly. The function is defined as ``inline'' in epi.h. //! //! Use of this function on a device not affected by the erratum is safe but //! will impact performance due to an additional overhead of at least 2 cycles //! per access. This erratum affects only the 0x10000000 address space //! typically used to store the LCD controller frame buffer. The 0x60000000 //! address space is not affected and applications using this address mapping //! need not use this function. //! //! \return The 8-bit byte stored at address \e pui8Addr. // //***************************************************************************** extern uint8_t EPIWorkaroundByteRead(uint8_t *pui8Addr); //***************************************************************************** // //! Sets the usage mode of the EPI module. //! //! \param ui32Base is the EPI module base address. //! \param ui32Mode is the usage mode of the EPI module. //! //! This functions sets the operating mode of the EPI module. The parameter //! \e ui32Mode must be one of the following: //! //! - \b EPI_MODE_GENERAL - use for general-purpose mode operation //! - \b EPI_MODE_SDRAM - use with SDRAM device //! - \b EPI_MODE_HB8 - use with host-bus 8-bit interface //! - \b EPI_MODE_HB16 - use with host-bus 16-bit interface //! - \b EPI_MODE_DISABLE - disable the EPI module //! //! Selection of any of the above modes enables the EPI module, except //! for \b EPI_MODE_DISABLE, which is used to disable the module. //! //! \return None. // //***************************************************************************** void EPIModeSet(uint32_t ui32Base, uint32_t ui32Mode) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT((ui32Mode == EPI_MODE_GENERAL) || (ui32Mode == EPI_MODE_SDRAM) || (ui32Mode == EPI_MODE_HB8) || (ui32Mode == EPI_MODE_HB16) || (ui32Mode == EPI_MODE_DISABLE)); // // Write the mode word to the register. // HWREG(ui32Base + EPI_O_CFG) = ui32Mode; } //***************************************************************************** // //! Sets the clock divider for the EPI module's CS0n/CS1n. //! //! \param ui32Base is the EPI module base address. //! \param ui32Divider is the value of the clock divider to be applied to //! the external interface (0-65535). //! //! This function sets the clock divider(s) that is used to determine the //! clock rate of the external interface. The \e ui32Divider value is used to //! derive the EPI clock rate from the system clock based on the following //! formula. //! //! EPIClk = (Divider == 0) ? SysClk : (SysClk / (((Divider / 2) + 1) * 2)) //! //! For example, a divider value of 1 results in an EPI clock rate of half //! the system clock, value of 2 or 3 yields one quarter of the system clock //! and a value of 4 results in one sixth of the system clock rate. //! //! In cases where a dual chip select mode is in use and different clock rates //! are required for each chip select, the \e ui32Divider parameter must //! contain two dividers. The lower 16 bits define the divider to be used with //! CS0n and the upper 16 bits define the divider for CS1n. //! //! \return None. // //***************************************************************************** void EPIDividerSet(uint32_t ui32Base, uint32_t ui32Divider) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); // // Write the divider value to the register. // HWREG(ui32Base + EPI_O_BAUD) = ui32Divider; } //***************************************************************************** // //! Sets the clock divider for the specified CS in the EPI module. //! //! \param ui32Base is the EPI module base address. //! \param ui32CS is the chip select to modify and has a valid range of 0-3. //! \param ui32Divider is the value of the clock divider to be applied to //! the external interface (0-65535). //! //! This function sets the clock divider(s) for the specified CS that is used //! to determine the clock rate of the external interface. The \e ui32Divider //! value is used to derive the EPI clock rate from the system clock based on //! the following formula. //! //! EPIClk = (Divider == 0) ? SysClk : (SysClk / (((Divider / 2) + 1) * 2)) //! //! For example, a divider value of 1 results in an EPI clock rate of half //! the system clock, value of 2 or 3 yields one quarter of the system clock //! and a value of 4 results in one sixth of the system clock rate. //! //! \note The availability of CS2n and CS3n varies based on the Tiva part //! in use. Please consult the data sheet to determine if this feature is //! available. //! //! \return None. // //***************************************************************************** void EPIDividerCSSet(uint32_t ui32Base, uint32_t ui32CS, uint32_t ui32Divider) { uint32_t ui32Reg; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32CS < 4); // // Write the divider value to the register bitfield. // if(ui32CS < 2) { ui32Reg = HWREG(ui32Base + EPI_O_BAUD) & ~(0xffff << (16 * ui32CS)); ui32Reg |= ((ui32Divider & 0xffff) << (16 * ui32CS)); HWREG(ui32Base + EPI_O_BAUD) = ui32Reg; } else { ui32Reg = (HWREG(ui32Base + EPI_O_BAUD2) & ~(0xffff << (16 * (ui32CS - 2)))); ui32Reg |= ((ui32Divider & 0xffff) << (16 * (ui32CS - 2))); HWREG(ui32Base + EPI_O_BAUD2) = ui32Reg; } } //***************************************************************************** // //! Sets the transfer count for uDMA transmit operations on EPI. //! //! \param ui32Base is the EPI module base address. //! \param ui32Count is the number of units to transmit by uDMA to WRFIFO. //! //! This function is used to help configure the EPI uDMA transmit operations. //! A non-zero transmit count in combination with a FIFO threshold trigger //! asserts an EPI uDMA transmit. //! //! Note that, although the EPI peripheral can handle counts of up to 65535, //! a single uDMA transfer has a maximum length of 1024 units so \e ui32Count //! should be set to values less than or equal to 1024. //! //! \note The availability of the EPI DMA TX count varies based on the //! Tiva part in use. Please consult the data sheet to determine if this //! feature is available. //! //! \return None. // //***************************************************************************** void EPIDMATxCount(uint32_t ui32Base, uint32_t ui32Count) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Count <= 1024); // // Assign the DMA TX count value provided. // HWREG(ui32Base + EPI_O_DMATXCNT) = ui32Count & 0xffff; } //***************************************************************************** // //! Configures the SDRAM mode of operation. //! //! \param ui32Base is the EPI module base address. //! \param ui32Config is the SDRAM interface configuration. //! \param ui32Refresh is the refresh count in core clocks (0-2047). //! //! This function is used to configure the SDRAM interface, when the SDRAM //! mode is chosen with the function EPIModeSet(). The parameter //! \e ui32Config is the logical OR of several sets of choices: //! //! The processor core frequency must be specified with one of the following: //! //! - \b EPI_SDRAM_CORE_FREQ_0_15 defines core clock as 0 MHz < clk <= 15 MHz //! - \b EPI_SDRAM_CORE_FREQ_15_30 defines core clock as 15 MHz < clk <= 30 MHz //! - \b EPI_SDRAM_CORE_FREQ_30_50 defines core clock as 30 MHz < clk <= 50 MHz //! - \b EPI_SDRAM_CORE_FREQ_50_100 defines core clock as 50 MHz < clk <= //! 100 MHz //! //! The low power mode is specified with one of the following: //! //! - \b EPI_SDRAM_LOW_POWER enter low power, self-refresh state. //! - \b EPI_SDRAM_FULL_POWER normal operating state. //! //! The SDRAM device size is specified with one of the following: //! //! - \b EPI_SDRAM_SIZE_64MBIT size is a 64 Mbit device (8 MB). //! - \b EPI_SDRAM_SIZE_128MBIT size is a 128 Mbit device (16 MB). //! - \b EPI_SDRAM_SIZE_256MBIT size is a 256 Mbit device (32 MB). //! - \b EPI_SDRAM_SIZE_512MBIT size is a 512 Mbit device (64 MB). //! //! The parameter \e ui16Refresh sets the refresh counter in units of core //! clock ticks. It is an 11-bit value with a range of 0 - 2047 counts. //! //! \return None. // //***************************************************************************** void EPIConfigSDRAMSet(uint32_t ui32Base, uint32_t ui32Config, uint32_t ui32Refresh) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Refresh < 2048); // // Fill in the refresh count field of the configuration word. // ui32Config &= ~EPI_SDRAMCFG_RFSH_M; ui32Config |= ui32Refresh << EPI_SDRAMCFG_RFSH_S; // // Write the SDRAM configuration register. // HWREG(ui32Base + EPI_O_SDRAMCFG) = ui32Config; } //***************************************************************************** // //! Configures the interface for Host-bus 8 operation. //! //! \param ui32Base is the EPI module base address. //! \param ui32Config is the interface configuration. //! \param ui32MaxWait is the maximum number of external clocks to wait //! if a FIFO ready signal is holding off the transaction, 0-255. //! //! This function is used to configure the interface when used in host-bus 8 //! operation as chosen with the function EPIModeSet(). The parameter //! \e ui32Config is the logical OR of the following: //! //! - Host-bus 8 submode, select one of: //! - \b EPI_HB8_MODE_ADMUX sets data and address muxed, AD[7:0] //! - \b EPI_HB8_MODE_ADDEMUX sets up data and address separate, D[7:0] //! - \b EPI_HB8_MODE_SRAM as \b EPI_HB8_MODE_ADDEMUX, but uses address //! switch for multiple reads instead of OEn strobing, D[7:0] //! - \b EPI_HB8_MODE_FIFO adds XFIFO with sense of XFIFO full and XFIFO //! empty, D[7:0] //! //! - \b EPI_HB8_USE_TXEMPTY enables TXEMPTY signal with FIFO //! - \b EPI_HB8_USE_RXFULL enables RXFULL signal with FIFO //! - \b EPI_HB8_WRHIGH sets active high write strobe, otherwise it is //! active low //! - \b EPI_HB8_RDHIGH sets active high read strobe, otherwise it is //! active low //! //! - Write wait state when \b EPI_HB8_BAUD is used, select one of: //! - \b EPI_HB8_WRWAIT_0 sets write wait state to 2 EPI clocks (default) //! - \b EPI_HB8_WRWAIT_1 sets write wait state to 4 EPI clocks //! - \b EPI_HB8_WRWAIT_2 sets write wait state to 6 EPI clocks //! - \b EPI_HB8_WRWAIT_3 sets write wait state to 8 EPI clocks //! //! - Read wait state when \b EPI_HB8_BAUD is used, select one of: //! - \b EPI_HB8_RDWAIT_0 sets read wait state to 2 EPI clocks (default) //! - \b EPI_HB8_RDWAIT_1 sets read wait state to 4 EPI clocks //! - \b EPI_HB8_RDWAIT_2 sets read wait state to 6 EPI clocks //! - \b EPI_HB8_RDWAIT_3 sets read wait state to 8 EPI clocks //! //! - \b EPI_HB8_WORD_ACCESS - use Word Access mode to route bytes to the //! correct byte lanes allowing data to be stored in bits [31:8]. If absent, //! all data transfers use bits [7:0]. //! //! - \b EPI_HB8_CLOCK_GATE_IDLE sets the EPI clock to be held low when no data //! is available to read or write //! - \b EPI_HB8_CLOCK_INVERT inverts the EPI clock //! - \b EPI_HB8_IN_READY_EN sets EPIS032 as a ready/stall signal, active high //! - \b EPI_HB8_IN_READY_EN_INVERT sets EPIS032 as ready/stall signal, active //! low //! - \b EPI_HB8_ALE_HIGH sets the address latch active high (default) //! - \b EPI_HB8_ALE_LOW sets address latch active low //! - \b EPI_HB8_CSBAUD use different baud rates when accessing devices on each //! chip select. CS0n uses the baud rate specified by the lower 16 bits //! of the divider passed to EPIDividerSet() and CS1n uses the divider passed //! in the upper 16 bits. If this option is absent, both chip selects use //! the baud rate resulting from the divider in the lower 16 bits of the //! parameter passed to EPIDividerSet(). //! //! In addition, some parts support CS2n and CS3n for a total of 4 chip //! selects. If \b EPI_HB8_CSBAUD is configured, EPIDividerCSSet() should be //! used to to configure the divider for CS2n and CS3n. They both also use the //! lower 16 bits passed to EPIDividerSet() if this option is absent. //! //! The use of \b EPI_HB8_CSBAUD also allows for unique chip select //! configurations. CS0n, CS1n, CS2n, and CS3n can each be configured by //! calling EPIConfigHB8CSSet() if \b EPI_HB8_CSBAUD is used. Otherwise, the //! configuration provided in \e ui32Config is used for all chip selects //! enabled. //! //! - Chip select configuration, select one of: //! - \b EPI_HB8_CSCFG_CS sets EPIS030 to operate as a chip select signal. //! - \b EPI_HB8_CSCFG_ALE sets EPIS030 to operate as an address latch //! (ALE). //! - \b EPI_HB8_CSCFG_DUAL_CS sets EPIS030 to operate as CS0n and EPIS027 //! as CS1n with the asserted chip select determined from the most //! significant address bit for the respective external address map. //! - \b EPI_HB8_CSCFG_ALE_DUAL_CS sets EPIS030 as an address latch (ALE), //! EPIS027 as CS0n and EPIS026 as CS1n with the asserted chip select //! determined from the most significant address bit for the respective //! external address map. //! - \b EPI_HB8_CSCFG_ALE_SINGLE_CS sets EPIS030 to operate as an address //! latch (ALE) and EPIS027 is used as a chip select. //! - \b EPI_HB8_CSCFG_QUAD_CS sets EPIS030 as CS0n, EPIS027 as CS1n, //! EPIS034 as CS2n and EPIS033 as CS3n. //! - \b EPI_HB8_CSCFG_ALE_QUAD_CS sets EPIS030 as an address latch (ALE), //! EPIS026 as CS0n, EPIS027 as CS1n, EPIS034 as CS2n and EPIS033 as CS3n. //! \note Dual or quad chip select configurations cannot be used with //! EPI_HB8_MODE_SRAM. //! //! The parameter \e ui32MaxWait is used if the FIFO mode is chosen. If a //! FIFO is used aint32_t with RXFULL or TXEMPTY ready signals, then this //! parameter determines the maximum number of clocks to wait when the //! transaction is being held off by by the FIFO using one of these ready //! signals. A value of 0 means to wait forever. //! //! \note Availability of configuration options varies based on the Tiva //! part in use. Please consult the data sheet to determine if the features //! desired are available. //! //! \return None. // //***************************************************************************** void EPIConfigHB8Set(uint32_t ui32Base, uint32_t ui32Config, uint32_t ui32MaxWait) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32MaxWait < 256); // // Determine the CS and word access modes. // HWREG(ui32Base + EPI_O_HB8CFG2) = ((ui32Config & EPI_HB8_CSBAUD) ? EPI_HB8CFG2_CSBAUD : 0) | ((ui32Config & EPI_HB8_CSCFG_MASK) << 15); // // Fill in the max wait field of the configuration word. // ui32Config &= ~EPI_HB8CFG_MAXWAIT_M; ui32Config |= ui32MaxWait << EPI_HB8CFG_MAXWAIT_S; // // Write the main HostBus8 configuration register. // HWREG(ui32Base + EPI_O_HB8CFG) = ui32Config; } //***************************************************************************** // //! Configures the interface for Host-bus 16 operation. //! //! \param ui32Base is the EPI module base address. //! \param ui32Config is the interface configuration. //! \param ui32MaxWait is the maximum number of external clocks to wait //! if a FIFO ready signal is holding off the transaction. //! //! This function is used to configure the interface when used in Host-bus 16 //! operation as chosen with the function EPIModeSet(). The parameter //! \e ui32Config is the logical OR of the following: //! - Host-bus 16 submode, select one of: //! - \b EPI_HB16_MODE_ADMUX sets data and address muxed, AD[15:0]. //! - \b EPI_HB16_MODE_ADDEMUX sets up data and address as separate, //! D[15:0]. //! - \b EPI_HB16_MODE_SRAM sets as \b EPI_HB16_MODE_ADDEMUX but uses //! address switch for multiple reads instead of OEn strobing, D[15:0]. //! - \b EPI_HB16_MODE_FIFO addes XFIFO controls with sense of XFIFO full //! and XFIFO empty, D[15:0]. This submode uses no address or ALE. //! //! - \b EPI_HB16_USE_TXEMPTY enables TXEMPTY signal with FIFO. //! - \b EPI_HB16_USE_RXFULL enables RXFULL signal with FIFO. //! - \b EPI_HB16_WRHIGH use active high write strobe, otherwise it is //! active low. //! - \b EPI_HB16_RDHIGH use active high read strobe, otherwise it is //! active low. //! - Write wait state, select one of: //! - \b EPI_HB16_WRWAIT_0 sets write wait state to 2 EPI clocks. //! - \b EPI_HB16_WRWAIT_1 sets write wait state to 4 EPI clocks. //! - \b EPI_HB16_WRWAIT_2 sets write wait state to 6 EPI clocks. //! - \b EPI_HB16_WRWAIT_3 sets write wait state to 8 EPI clocks. //! //! - Read wait state, select one of: //! - \b EPI_HB16_RDWAIT_0 sets read wait state to 2 EPI clocks. //! - \b EPI_HB16_RDWAIT_1 sets read wait state to 4 EPI clocks. //! - \b EPI_HB16_RDWAIT_2 sets read wait state to 6 EPI clocks. //! - \b EPI_HB16_RDWAIT_3 sets read wait state to 8 EPI clocks. //! //! - \b EPI_HB16_WORD_ACCESS use Word Access mode to route bytes to the //! correct byte lanes allowing data to be stored in bits [31:16]. If //! absent, all data transfers use bits [15:0]. //! //! \note \b EPI_HB16_WORD_ACCESS is not available on all parts. Please //! consult the data sheet to determine if this feature is available. //! //! - \b EPI_HB16_CLOCK_GATE_IDLE holds the EPI clock low when no data is //! available to read or write. //! - \b EPI_HB16_CLOCK_INVERT inverts the EPI clock. //! - \b EPI_HB16_IN_READY_EN sets EPIS032 as a ready/stall signal, active //! high. //! - \b EPI_HB16_IN_READY_EN_INVERTED sets EPIS032 as ready/stall signal, //! active low. //! - Address latch logic, select one of: //! - \b EPI_HB16_ALE_HIGH sets the address latch active high (default). //! - \b EPI_HB16_ALE_LOW sets address latch active low. //! //! - \b EPI_HB16_BURST_TRAFFIC enables burst traffic. Only valid with //! \b EPI_HB16_MODE_ADMUX and a chip select configuration that utilizes an //! ALE. //! - \b EPI_HB16_BSEL enables byte selects. In this mode, two EPI signals //! operate as byte selects allowing 8-bit transfers. If this flag is not //! specified, data must be read and written using only 16-bit transfers. //! - \b EPI_HB16_CSBAUD use different baud rates when accessing devices //! on each chip select. CS0n uses the baud rate specified by the lower 16 //! bits of the divider passed to EPIDividerSet() and CS1n uses the divider //! passed in the upper 16 bits. If this option is absent, both chip selects //! use the baud rate resulting from the divider in the lower 16 bits of the //! parameter passed to EPIDividerSet(). //! //! In addition, some parts support CS2n and CS3n for a total of 4 chip //! selects. If \b EPI_HB16_CSBAUD is configured, EPIDividerCSSet() should be //! used to to configure the divider for CS2n and CS3n. They both also use the //! lower 16 bits passed to EPIDividerSet() if this option is absent. //! //! The use of \b EPI_HB16_CSBAUD also allows for unique chip select //! configurations. CS0n, CS1n, CS2n, and CS3n can each be configured by //! calling EPIConfigHB16CSSet() if \b EPI_HB16_CSBAUD is used. Otherwise, the //! configuration provided in \e ui32Config is used for all chip selects. //! //! - Chip select configuration, select one of: //! - \b EPI_HB16_CSCFG_CS sets EPIS030 to operate as a chip select signal. //! - \b EPI_HB16_CSCFG_ALE sets EPIS030 to operate as an address latch //! (ALE). //! - \b EPI_HB16_CSCFG_DUAL_CS sets EPIS030 to operate as CS0n and EPIS027 //! as CS1n with the asserted chip select determined from the most //! significant address bit for the respective external address map. //! - \b EPI_HB16_CSCFG_ALE_DUAL_CS sets EPIS030 as an address latch (ALE), //! EPIS027 as CS0n and EPIS026 as CS1n with the asserted chip select //! determined from the most significant address bit for the respective //! external address map. //! - \b EPI_HB16_CSCFG_ALE_SINGLE_CS sets EPIS030 to operate as an address //! latch (ALE) and EPIS027 is used as a chip select. //! - \b EPI_HB16_CSCFG_QUAD_CS sets EPIS030 as CS0n, EPIS027 as CS1n, //! EPIS034 as CS2n and EPIS033 as CS3n. //! - \b EPI_HB16_CSCFG_ALE_QUAD_CS sets EPIS030 as an address latch //! (ALE), EPIS026 as CS0n, EPIS027 as CS1n, EPIS034 as CS2n and EPIS033 //! as CS3n. //! \note Dual or quad chip select configurations cannot be used with //! EPI_HB16_MODE_SRAM. //! //! The parameter \e ui32MaxWait is used if the FIFO mode is chosen. If a //! FIFO is used along with RXFULL or TXEMPTY ready signals, then this //! parameter determines the maximum number of clocks to wait when the //! transaction is being held off by by the FIFO using one of these ready //! signals. A value of 0 means to wait forever. //! //! \note Availability of configuration options varies based on the Tiva //! part in use. Please consult the data sheet to determine if the features //! desired are available. //! //! \return None. // //***************************************************************************** void EPIConfigHB16Set(uint32_t ui32Base, uint32_t ui32Config, uint32_t ui32MaxWait) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32MaxWait < 256); // // Determine the CS and word access modes. // HWREG(ui32Base + EPI_O_HB16CFG2) = ((ui32Config & EPI_HB16_CSBAUD) ? EPI_HB16CFG2_CSBAUD : 0) | ((ui32Config & EPI_HB16_CSCFG_MASK) << 15); // // Fill in the max wait field of the configuration word. // ui32Config &= ~EPI_HB16CFG_MAXWAIT_M; ui32Config |= ui32MaxWait << EPI_HB16CFG_MAXWAIT_S; // // Write the main HostBus16 configuration register. // HWREG(ui32Base + EPI_O_HB16CFG) = ui32Config; } //***************************************************************************** // //! Sets the individual chip select configuration for the Host-bus 8 interface. //! //! \param ui32Base is the EPI module base address. //! \param ui32CS is the chip select value to configure. //! \param ui32Config is the configuration settings. //! //! This function is used to configure individual chip select settings for the //! Host-bus 8 interface mode. EPIConfigHB8Set() must have been setup with //! the \b EPI_HB8_CSBAUD flag for the individual chip select configuration //! option to be available. //! //! The \e ui32Base parameter is the base address for the EPI hardware module. //! The \e ui32CS parameter specifies the chip select to configure and has a //! valid range of 0-3. The parameter \e ui32Config is the logical OR of the //! following: //! //! - Host-bus 8 submode, select one of: //! - \b EPI_HB8_MODE_ADMUX sets data and address muxed, AD[7:0]. //! - \b EPI_HB8_MODE_ADDEMUX sets up data and address separate, D[7:0]. //! - \b EPI_HB8_MODE_SRAM as \b EPI_HB8_MODE_ADDEMUX, but uses address //! switch for multiple reads instead of OEn strobing, D[7:0]. //! - \b EPI_HB8_MODE_FIFO adds XFIFO with sense of XFIFO full and XFIFO //! empty, D[7:0]. This is only available for CS0n and CS1n. //! //! - \b EPI_HB8_WRHIGH sets active high write strobe, otherwise it is //! active low. //! - \b EPI_HB8_RDHIGH sets active high read strobe, otherwise it is //! active low. //! - Write wait state when \b EPI_HB8_BAUD is used, select one of: //! - \b EPI_HB8_WRWAIT_0 sets write wait state to 2 EPI clocks (default). //! - \b EPI_HB8_WRWAIT_1 sets write wait state to 4 EPI clocks. //! - \b EPI_HB8_WRWAIT_2 sets write wait state to 6 EPI clocks. //! - \b EPI_HB8_WRWAIT_3 sets write wait state to 8 EPI clocks. //! - Read wait state when \b EPI_HB8_BAUD is used, select one of: //! - \b EPI_HB8_RDWAIT_0 sets read wait state to 2 EPI clocks (default). //! - \b EPI_HB8_RDWAIT_1 sets read wait state to 4 EPI clocks. //! - \b EPI_HB8_RDWAIT_2 sets read wait state to 6 EPI clocks. //! - \b EPI_HB8_RDWAIT_3 sets read wait state to 8 EPI clocks. //! - \b EPI_HB8_ALE_HIGH sets the address latch active high (default). //! - \b EPI_HB8_ALE_LOW sets address latch active low. //! //! \note The availability of a unique chip select configuration within //! Host-bus 8 interface mode varies based on the Tiva part in use. //! Please consult the data sheet to determine if this feature is available. //! //! \return None. // //***************************************************************************** void EPIConfigHB8CSSet(uint32_t ui32Base, uint32_t ui32CS, uint32_t ui32Config) { uint32_t ui32Offset, ui32Reg; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32CS < 4); // // Determine the register offset based on the ui32CS provided. // if(ui32CS < 2) { ui32Offset = EPI_O_HB8CFG + (ui32CS << 2); } else { ui32Offset = EPI_O_HB8CFG3 + ((ui32CS - 2) << 2); } // // Preserve the bits that will not be modified. // ui32Reg = HWREG(ui32Base + ui32Offset) & ~EPI_HB8_CS_MASK; // // Write the target chip select HostBus8 configuration fields. // HWREG(ui32Base + ui32Offset) = (ui32Reg | ui32Config); } //***************************************************************************** // //! Sets the individual chip select configuration for the Host-bus 16 //! interface. //! //! \param ui32Base is the EPI module base address. //! \param ui32CS is the chip select value to configure. //! \param ui32Config is the configuration settings. //! //! This function is used to configure individual chip select settings for the //! Host-bus 16 interface mode. EPIConfigHB16Set() must have been set up with //! the \b EPI_HB16_CSBAUD flag for the individual chip select configuration //! option to be available. //! //! The \e ui32Base parameter is the base address for the EPI hardware module. //! The \e ui32CS parameter specifies the chip select to configure and has a //! valid range of 0-3. The parameter \e ui32Config is the logical OR the //! following: //! //! - Host-bus 16 submode, select one of: //! - \b EPI_HB16_MODE_ADMUX sets data and address muxed, AD[15:0]. //! - \b EPI_HB16_MODE_ADDEMUX sets up data and address separate, D[15:0]. //! - \b EPI_HB16_MODE_SRAM same as \b EPI_HB8_MODE_ADDEMUX, but uses //! address switch for multiple reads instead of OEn strobing, D[15:0]. //! - \b EPI_HB16_MODE_FIFO adds XFIFO with sense of XFIFO full and XFIFO //! empty, D[15:0]. This feature is only available on CS0n and CS1n. //! - \b EPI_HB16_WRHIGH sets active high write strobe, otherwise it is //! active low. //! - \b EPI_HB16_RDHIGH sets active high read strobe, otherwise it is //! active low. //! - Write wait state when \b EPI_HB16_BAUD is used, select one of: //! - \b EPI_HB16_WRWAIT_0 sets write wait state to 2 EPI clocks (default). //! - \b EPI_HB16_WRWAIT_1 sets write wait state to 4 EPI clocks. //! - \b EPI_HB16_WRWAIT_2 sets write wait state to 6 EPI clocks. //! - \b EPI_HB16_WRWAIT_3 sets write wait state to 8 EPI clocks. //! - Read wait state when \b EPI_HB16_BAUD is used, select one of: //! - \b EPI_HB16_RDWAIT_0 sets read wait state to 2 EPI clocks (default). //! - \b EPI_HB16_RDWAIT_1 sets read wait state to 4 EPI clocks. //! - \b EPI_HB16_RDWAIT_2 sets read wait state to 6 EPI clocks. //! - \b EPI_HB16_RDWAIT_3 sets read wait state to 8 EPI clocks. //! - \b EPI_HB16_ALE_HIGH sets the address latch active high (default). //! - \b EPI_HB16_ALE_LOW sets address latch active low. //! - \b EPI_HB16_BURST_TRAFFIC enables burst traffic. Only valid with //! \b EPI_HB16_MODE_ADMUX and a chip select configuration that utilizes an //! ALE. //! //! \note The availability of the unique chip select configuration within the //! Host-bus 16 interface mode varies based on the Tiva part in use. //! Please consult the data sheet to determine if this feature is available. //! //! \return None. // //***************************************************************************** void EPIConfigHB16CSSet(uint32_t ui32Base, uint32_t ui32CS, uint32_t ui32Config) { uint32_t ui32Offset, ui32Reg; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32CS < 4); // // Determine the register offset based on the ui32CS provided. // if(ui32CS < 2) { ui32Offset = EPI_O_HB16CFG + (ui32CS << 2); } else { ui32Offset = EPI_O_HB16CFG3 + ((ui32CS - 2) << 2); } // // Preserve the bits that will not be modified. // ui32Reg = HWREG(ui32Base + ui32Offset) & ~EPI_HB16_CS_MASK; // // Write the target chip select HostBus16 configuration fields. // HWREG(ui32Base + ui32Offset) = (ui32Reg | ui32Config); } //***************************************************************************** // //! Sets the individual chip select timing settings for the Host-bus 8 //! interface. //! //! \param ui32Base is the EPI module base address. //! \param ui32CS is the chip select value to configure. //! \param ui32Config is the configuration settings. //! //! This function is used to set individual chip select timings for the //! Host-bus 8 interface mode. //! //! The \e ui32Base parameter is the base address for the EPI hardware module. //! The \e ui32CS parameter specifies the chip select to configure and has a //! valid range of 0-3. The parameter \e ui32Config is the logical OR of the //! following: //! //! - Input ready stall delay, select one of: //! - \b EPI_HB8_IN_READY_DELAY_1 sets the stall on input ready (EPIS032) //! to start 1 EPI clock after signaled. //! - \b EPI_HB8_IN_READY_DELAY_2 sets the stall on input ready (EPIS032) //! to start 2 EPI clocks after signaled. //! - \b EPI_HB8_IN_READY_DELAY_3 sets the stall on input ready (EPIS032) //! to start 3 EPI clocks after signaled. //! //! - Host bus transfer delay, select one of: //! - \b EPI_HB8_CAP_WIDTH_1 defines the inter-transfer capture width to //! create a delay of 1 EPI clock. //! - \b EPI_HB8_CAP_WIDTH_2 defines the inter-transfer capture width //! to create a delay of 2 EPI clocks. //! //! - \b EPI_HB8_WRWAIT_MINUS_DISABLE disables the additional write wait state //! reduction. //! - \b EPI_HB8_WRWAIT_MINUS_ENABLE enables a 1 EPI clock write wait state //! reduction. //! - \b EPI_HB8_RDWAIT_MINUS_DISABLE disables the additional read wait state //! reduction. //! - \b EPI_HB8_RDWAIT_MINUS_ENABLE enables a 1 EPI clock read wait state //!reduction. //! //! \note The availability of unique chip select timings within Host-bus 8 //! interface mode varies based on the Tiva part in use. Please consult //! the data sheet to determine if this feature is available. //! //! \return None. // //***************************************************************************** void EPIConfigHB8TimingSet(uint32_t ui32Base, uint32_t ui32CS, uint32_t ui32Config) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32CS < 4); // // Write the target chip select HostBus8 timing register. // HWREG(ui32Base + (EPI_O_HB8TIME + (ui32CS << 2))) = ui32Config; } //***************************************************************************** // //! Sets the individual chip select timing settings for the Host-bus 16 //! interface. //! //! \param ui32Base is the EPI module base address. //! \param ui32CS is the chip select value to configure. //! \param ui32Config is the configuration settings. //! //! This function is used to set individual chip select timings for the //! Host-bus 16 interface mode. //! //! The \e ui32Base parameter is the base address for the EPI hardware module. //! The \e ui32CS parameter specifies the chip select to configure and has a //! valid range of 0-3. The parameter \e ui32Config is the logical OR of the //! following: //! //! - Input ready stall delay, select one of: //! - \b EPI_HB16_IN_READY_DELAY_1 sets the stall on input ready (EPIS032) //! to start 1 EPI clock after signaled. //! - \b EPI_HB16_IN_READY_DELAY_2 sets the stall on input ready (EPIS032) //! to start 2 EPI clocks after signaled. //! - \b EPI_HB16_IN_READY_DELAY_3 sets the stall on input ready (EPIS032) //! to start 3 EPI clocks after signaled. //! //! - PSRAM size limitation, select one of: //! - \b EPI_HB16_PSRAM_NO_LIMIT defines no row size limitation. //! - \b EPI_HB16_PSRAM_128 defines the PSRAM row size to 128 bytes. //! - \b EPI_HB16_PSRAM_256 defines the PSRAM row size to 256 bytes. //! - \b EPI_HB16_PSRAM_512 defines the PSRAM row size to 512 bytes. //! - \b EPI_HB16_PSRAM_1024 defines the PSRAM row size to 1024 bytes. //! - \b EPI_HB16_PSRAM_2048 defines the PSRAM row size to 2048 bytes. //! - \b EPI_HB16_PSRAM_4096 defines the PSRAM row size to 4096 bytes. //! - \b EPI_HB16_PSRAM_8192 defines the PSRAM row size to 8192 bytes. //! //! - Host bus transfer delay, select one of: //! - \b EPI_HB16_CAP_WIDTH_1 defines the inter-transfer capture width to //! create a delay of 1 EPI clock //! - \b EPI_HB16_CAP_WIDTH_2 defines the inter-transfer capture width //! to create a delay of 2 EPI clocks. //! //! - Write wait state timing reduction, select one of: //! - \b EPI_HB16_WRWAIT_MINUS_DISABLE disables the additional write wait //! state reduction. //! - \b EPI_HB16_WRWAIT_MINUS_ENABLE enables a 1 EPI clock write wait //! state reduction. //! //! - Read wait state timing reduction, select one of: //! - \b EPI_HB16_RDWAIT_MINUS_DISABLE disables the additional read wait //! state reduction. //! - \b EPI_HB16_RDWAIT_MINUS_ENABLE enables a 1 EPI clock read wait state //! reduction. //! //! \note The availability of unique chip select timings within Host-bus 16 //! interface mode varies based on the Tiva part in use. Please consult //! the data sheet to determine if this feature is available. //! //! \return None. // //***************************************************************************** void EPIConfigHB16TimingSet(uint32_t ui32Base, uint32_t ui32CS, uint32_t ui32Config) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32CS < 4); // // Write the target chip select HostBus16 timing register. // HWREG(ui32Base + (EPI_O_HB16TIME + (ui32CS << 2))) = ui32Config; } //***************************************************************************** // //! Sets the PSRAM configuration register. //! //! \param ui32Base is the EPI module base address. //! \param ui32CS is the chip select target. //! \param ui32CR is the PSRAM configuration register value. //! //! This function sets the PSRAM's configuration register by using the PSRAM //! configuration register enable signal. The Host-bus 16 interface mode //! should be configured prior to calling this function. //! //! The \e ui32Base parameter is the base address for the EPI hardware module. //! The \e ui32CS parameter specifies the chip select to configure and has a //! valid range of 0-3. The parameter \e ui32CR value is determined by //! consulting the PSRAM's data sheet. //! //! \note The availability of PSRAM support varies based on the Tiva part //! in use. Please consult the data sheet to determine if this feature is //! available. //! //! \return None. // //***************************************************************************** void EPIPSRAMConfigRegSet(uint32_t ui32Base, uint32_t ui32CS, uint32_t ui32CR) { uint32_t ui32Offset; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32CS < 4); // // Determine the register offset based on the ui32CS provided. // if(ui32CS < 2) { ui32Offset = EPI_O_HB16CFG + (ui32CS << 2); } else { ui32Offset = EPI_O_HB16CFG3 + ((ui32CS - 2) << 2); } // // Setup for the PSRAM configuration register write. Only 21 bits are // valid on a write. // HWREG(ui32Base + EPI_O_HBPSRAM) = (ui32CR & 0x1fffff); // // Set the PSRAM configuration register write enable. // HWREG(ui32Base + ui32Offset) |= EPI_HB16CFG_WRCRE; } //***************************************************************************** // //! Requests a configuration register read from the PSRAM. //! //! \param ui32Base is the EPI module base address. //! \param ui32CS is the chip select target. //! //! This function requests a read of the PSRAM's configuration register. The //! Host-bus 16 interface mode should be configured prior to calling this //! function. //! The EPIPSRAMConfigRegGet() and EPIPSRAMConfigRegGetNonBlocking() can //! be used to retrieve the configuration register value. //! //! The \e ui32Base parameter is the base address for the EPI hardware module. //! The \e ui32CS parameter specifies the chip select to configure and has a //! valid range of 0-3. //! //! \note The availability of PSRAM support varies based on the Tiva part //! in use. Please consult the data sheet to determine if this feature is //! available. //! //! \return none. // //***************************************************************************** void EPIPSRAMConfigRegRead(uint32_t ui32Base, uint32_t ui32CS) { uint32_t ui32Offset; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32CS < 4); // // Determine the register offset based on the ui32CS provided. // if(ui32CS < 2) { ui32Offset = EPI_O_HB16CFG + (ui32CS << 2); } else { ui32Offset = EPI_O_HB16CFG3 + ((ui32CS - 2) << 2); } // // Set the PSRAM configuration register read enable. // HWREG(ui32Base + ui32Offset) |= EPI_HB16CFG_RDCRE; } //***************************************************************************** // //! Retrieves the contents of the EPI PSRAM configuration register. //! //! \param ui32Base is the EPI module base address. //! \param ui32CS is the chip select target. //! \param pui32CR is the provided storage used to hold the register value. //! //! This function copies the contents of the EPI PSRAM configuration register //! to the provided storage if the PSRAM read configuration register enable //! is no longer asserted. Otherwise the provided storage is not modified. //! //! The Host-bus 16 interface mode should be set up and EPIPSRAMConfigRegRead() //! should be called prior to calling this function. //! //! The \e ui32Base parameter is the base address for the EPI hardware module. //! The \e ui32CS parameter specifies the chip select to configure and has a //! valid range of 0-3. The \e pui32CR parameter is a pointer to provided //! storage used to hold the register value. //! //! \note The availability of PSRAM support varies based on the Tiva part //! in use. Please consult the data sheet to determine if this feature is //! available. //! //! \return \b true if the value was copied to the provided storage and //! \b false if it was not. // //***************************************************************************** bool EPIPSRAMConfigRegGetNonBlocking(uint32_t ui32Base, uint32_t ui32CS, uint32_t *pui32CR) { uint32_t ui32Offset; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32CS < 4); // // Determine the register offset based on the ui32CS provided. // if(ui32CS < 2) { ui32Offset = EPI_O_HB16CFG + (ui32CS << 2); } else { ui32Offset = EPI_O_HB16CFG3 + ((ui32CS - 2) << 2); } // // Verify PSRAM read enable is not asserted. // if(HWREG(ui32Base + ui32Offset) & EPI_HB16CFG_RDCRE) { return(false); } // // Copy the PSRAM configuration register value to the provided storage. // Only the lower 16 bits are valid on a read. // *pui32CR = HWREG(ui32Base + EPI_O_HBPSRAM) & 0xffff; // // Notify caller the provided storage holds the EPI PSRAM configuration // register contents. // return(true); } //***************************************************************************** // //! Retrieves the contents of the EPI PSRAM configuration register. //! //! \param ui32Base is the EPI module base address. //! \param ui32CS is the chip select target. //! //! This function retrieves the EPI PSRAM configuration register. The register //! is read once the EPI PSRAM configuration register read enable signal is //! de-asserted. //! //! The Host-bus 16 interface mode should be set up and EPIPSRAMConfigRegRead() //! should be called prior to calling this function. //! //! The \e ui32Base parameter is the base address for the EPI hardware module. //! The \e ui32CS parameter specifies the chip select to configure and has a //! valid range of 0-3. //! //! \note The availability of PSRAM support varies based on the Tiva part //! in use. Please consult the data sheet to determine if this feature is //! available. //! //! \return none. // //***************************************************************************** uint32_t EPIPSRAMConfigRegGet(uint32_t ui32Base, uint32_t ui32CS) { uint32_t ui32Offset; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32CS < 4); // // Determine the register offset based on the ui32CS provided. // if(ui32CS < 2) { ui32Offset = EPI_O_HB16CFG + (ui32CS << 2); } else { ui32Offset = EPI_O_HB16CFG3 + ((ui32CS - 2) << 2); } // // Wait for PSRAM read enable to deassert if necessary. // while(HWREG(ui32Base + ui32Offset) & EPI_HB16CFG_RDCRE) { } // // Return the EPI PSRAM configuration register contents. // Only the lower 16 bits are valid on a read. // return(HWREG(ui32Base + EPI_O_HBPSRAM) & 0xffff); } //***************************************************************************** // //! Configures the interface for general-purpose mode operation. //! //! \param ui32Base is the EPI module base address. //! \param ui32Config is the interface configuration. //! \param ui32FrameCount is the frame size in clocks, if the frame signal //! is used (0-15). //! \param ui32MaxWait is currently not used. //! //! This function is used to configure the interface when used in //! general-purpose operation as chosen with the function EPIModeSet(). The //! parameter \e ui32Config is the logical OR of the following: //! //! - \b EPI_GPMODE_CLKPIN interface clock as output on a pin. //! - \b EPI_GPMODE_CLKGATE clock is stopped when there is no transaction, //! otherwise it is free-running. //! - \b EPI_GPMODE_FRAME50 framing signal is 50/50 duty cycle, otherwise it //! is a pulse. //! - \b EPI_GPMODE_WRITE2CYCLE a two-cycle write is used, otherwise a //! single-cycle write is used. //! - Address bus size, select one of: //! - \b EPI_GPMODE_ASIZE_NONE sets no address bus. //! - \b EPI_GPMODE_ASIZE_4 sets an address bus size of 4 bits. //! - \b EPI_GPMODE_ASIZE_12 sets an address bus size of 12 bits. //! - \b EPI_GPMODE_ASIZE_20 sets an address bus size of 20 bits. //! - Data bus size, select one of: //! - \b EPI_GPMODE_DSIZE_8 sets a data bus size of 8 bits. //! - \b EPI_GPMODE_DSIZE_16 sets a data bus size of 16 bits. //! - \b EPI_GPMODE_DSIZE_24 sets a data bus size of 24 bits. //! - \b EPI_GPMODE_DSIZE_32 sets a data bus size of 32 bits. //! //! The parameter \e ui32FrameCount is the number of clocks used to form the //! framing signal, if the framing signal is used. The behavior depends on //! whether the frame signal is a pulse or a 50/50 duty cycle. //! //! //! \return None. // //***************************************************************************** void EPIConfigGPModeSet(uint32_t ui32Base, uint32_t ui32Config, uint32_t ui32FrameCount, uint32_t ui32MaxWait) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32FrameCount < 16); ASSERT(ui32MaxWait < 256); // // Fill in the frame count field of the configuration word. // ui32Config &= ~EPI_GPCFG_FRMCNT_M; ui32Config |= ui32FrameCount << EPI_GPCFG_FRMCNT_S; // // Write the non-moded configuration register. // HWREG(ui32Base + EPI_O_GPCFG) = ui32Config; } //***************************************************************************** // //! Configures the address map for the external interface. //! //! \param ui32Base is the EPI module base address. //! \param ui32Map is the address mapping configuration. //! //! This function is used to configure the address mapping for the external //! interface, which then determines the base address of the external memory or //! device within the processor peripheral and/or memory space. //! //! The parameter \e ui32Map is the logical OR of the following: //! //! - Peripheral address space size, select one of: //! - \b EPI_ADDR_PER_SIZE_256B sets the peripheral address space to 256 //! bytes. //! - \b EPI_ADDR_PER_SIZE_64KB sets the peripheral address space to 64 //! Kbytes. //! - \b EPI_ADDR_PER_SIZE_16MB sets the peripheral address space to 16 //! Mbytes. //! - \b EPI_ADDR_PER_SIZE_256MB sets the peripheral address space to 256 //! Mbytes. //! - Peripheral base address, select one of: //! - \b EPI_ADDR_PER_BASE_NONE sets the peripheral base address to none. //! - \b EPI_ADDR_PER_BASE_A sets the peripheral base address to //! 0xA0000000. //! - \b EPI_ADDR_PER_BASE_C sets the peripheral base address to //! 0xC0000000. //! - RAM address space, select one of: //! - \b EPI_ADDR_RAM_SIZE_256B sets the RAM address space to 256 bytes. //! - \b EPI_ADDR_RAM_SIZE_64KB sets the RAM address space to 64 Kbytes. //! - \b EPI_ADDR_RAM_SIZE_16MB sets the RAM address space to 16 Mbytes. //! - \b EPI_ADDR_RAM_SIZE_256MB sets the RAM address space to 256 Mbytes. //! - RAM base address, select one of: //! - \b EPI_ADDR_RAM_BASE_NONE sets the RAM space address to none. //! - \b EPI_ADDR_RAM_BASE_6 sets the RAM space address to 0x60000000. //! - \b EPI_ADDR_RAM_BASE_8 sets the RAM space address to 0x80000000. //! - \b EPI_ADDR_RAM_QUAD_MODE maps CS0n to 0x60000000, CS1n to 0x80000000, //! CS2n to 0xA0000000, and CS3n to 0xC0000000. //! - \b EPI_ADDR_CODE_SIZE_256B sets an external code size of 256 bytes, range //! 0x00 to 0xFF. //! - \b EPI_ADDR_CODE_SIZE_64KB sets an external code size of 64 Kbytes, range //! 0x0000 to 0xFFFF. //! - \b EPI_ADDR_CODE_SIZE_16MB sets an external code size of 16 Mbytes, range //! 0x000000 to 0xFFFFFF. //! - \b EPI_ADDR_CODE_SIZE_256MB sets an external code size of 256 Mbytes, //! range 0x0000000 to 0xFFFFFFF. //! - \b EPI_ADDR_CODE_BASE_NONE sets external code base to not mapped. //! - \b EPI_ADDR_CODE_BASE_1 sets external code base to 0x10000000. //! //! \note The availability of \b EPI_ADDR_RAM_QUAD_MODE and \b EPI_ADDR_CODE_* //! varies based on the Tiva part in use. Please consult the data sheet //! to determine if these features are available. //! //! \return None. // //***************************************************************************** void EPIAddressMapSet(uint32_t ui32Base, uint32_t ui32Map) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Map < 0x1000); // // Set the value of the address mapping register. // HWREG(ui32Base + EPI_O_ADDRMAP) = ui32Map; } //***************************************************************************** // //! Configures a non-blocking read transaction. //! //! \param ui32Base is the EPI module base address. //! \param ui32Channel is the read channel (0 or 1). //! \param ui32DataSize is the size of the data items to read. //! \param ui32Address is the starting address to read. //! //! This function is used to configure a non-blocking read channel for a //! transaction. Two channels are available that can be used in a ping-pong //! method for continuous reading. It is not necessary to use both channels //! to perform a non-blocking read. //! //! The parameter \e ui8DataSize is one of \b EPI_NBCONFIG_SIZE_8, //! \b EPI_NBCONFIG_SIZE_16, or \b EPI_NBCONFIG_SIZE_32 for 8-bit, 16-bit, //! or 32-bit sized data transfers. //! //! The parameter \e ui32Address is the starting address for the read, relative //! to the external device. The start of the device is address 0. //! //! Once configured, the non-blocking read is started by calling //! EPINonBlockingReadStart(). If the addresses to be read from the device //! are in a sequence, it is not necessary to call this function multiple //! times. Until it is changed, the EPI module stores the last address //! that was used for a non-blocking read (per channel). //! //! \return None. // //***************************************************************************** void EPINonBlockingReadConfigure(uint32_t ui32Base, uint32_t ui32Channel, uint32_t ui32DataSize, uint32_t ui32Address) { uint32_t ui32Offset; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Channel < 2); ASSERT(ui32DataSize < 4); ASSERT(ui32Address < 0x20000000); // // Compute the offset needed to select the correct channel regs. // ui32Offset = ui32Channel * (EPI_O_RSIZE1 - EPI_O_RSIZE0); // // Write the data size register for the channel. // HWREG(ui32Base + EPI_O_RSIZE0 + ui32Offset) = ui32DataSize; // // Write the starting address register for the channel. // HWREG(ui32Base + EPI_O_RADDR0 + ui32Offset) = ui32Address; } //***************************************************************************** // //! Starts a non-blocking read transaction. //! //! \param ui32Base is the EPI module base address. //! \param ui32Channel is the read channel (0 or 1). //! \param ui32Count is the number of items to read (1-4095). //! //! This function starts a non-blocking read that was previously configured //! with the function EPINonBlockingReadConfigure(). Once this function is //! called, the EPI module begins reading data from the external device //! into the read FIFO. The EPI stops reading when the FIFO fills up //! and resumes reading when the application drains the FIFO, until the //! total specified count of data items has been read. //! //! Once a read transaction is completed and the FIFO drained, another //! transaction can be started from the next address by calling this //! function again. //! //! \return None. // //***************************************************************************** void EPINonBlockingReadStart(uint32_t ui32Base, uint32_t ui32Channel, uint32_t ui32Count) { uint32_t ui32Offset; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Channel < 2); ASSERT(ui32Count < 4096); // // Compute the offset needed to select the correct channel regs. // ui32Offset = ui32Channel * (EPI_O_RPSTD1 - EPI_O_RPSTD0); // // Write to the read count register. // HWREG(ui32Base + EPI_O_RPSTD0 + ui32Offset) = ui32Count; } //***************************************************************************** // //! Stops a non-blocking read transaction. //! //! \param ui32Base is the EPI module base address. //! \param ui32Channel is the read channel (0 or 1). //! //! This function cancels a non-blocking read transaction that is already //! in progress. //! //! \return None. // //***************************************************************************** void EPINonBlockingReadStop(uint32_t ui32Base, uint32_t ui32Channel) { uint32_t ui32Offset; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Channel < 2); // // Compute the offset needed to select the correct channel regs. // ui32Offset = ui32Channel * (EPI_O_RPSTD1 - EPI_O_RPSTD0); // // Write a 0 to the read count register, which cancels the transaction. // HWREG(ui32Base + EPI_O_RPSTD0 + ui32Offset) = 0; } //***************************************************************************** // //! Get the count remaining for a non-blocking transaction. //! //! \param ui32Base is the EPI module base address. //! \param ui32Channel is the read channel (0 or 1). //! //! This function gets the remaining count of items for a non-blocking read //! transaction. //! //! \return The number of items remaining in the non-blocking read transaction. // //***************************************************************************** uint32_t EPINonBlockingReadCount(uint32_t ui32Base, uint32_t ui32Channel) { uint32_t ui32Offset; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Channel < 2); // // Compute the offset needed to select the correct channel regs. // ui32Offset = ui32Channel * (EPI_O_RPSTD1 - EPI_O_RPSTD0); // // Read the count remaining and return the value to the caller. // return(HWREG(ui32Base + EPI_O_RPSTD0 + ui32Offset)); } //***************************************************************************** // //! Get the count of items available in the read FIFO. //! //! \param ui32Base is the EPI module base address. //! //! This function gets the number of items that are available to read in //! the read FIFO. The read FIFO is filled by a non-blocking read transaction //! which is configured by the functions EPINonBlockingReadConfigure() and //! EPINonBlockingReadStart(). //! //! \return The number of items available to read in the read FIFO. // //***************************************************************************** uint32_t EPINonBlockingReadAvail(uint32_t ui32Base) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); // // Read the FIFO count and return it to the caller. // return(HWREG(ui32Base + EPI_O_RFIFOCNT)); } //***************************************************************************** // //! Read available data from the read FIFO, as 32-bit data items. //! //! \param ui32Base is the EPI module base address. //! \param ui32Count is the maximum count of items to read. //! \param pui32Buf is the caller supplied buffer where the read data is //! stored. //! //! This function reads 32-bit data items from the read FIFO and stores //! the values in a caller-supplied buffer. The function reads and stores //! data from the FIFO until there is no more data in the FIFO or the maximum //! count is reached as specified in the parameter \e ui32Count. The actual //! count of items is returned. //! //! \return The number of items read from the FIFO. // //***************************************************************************** uint32_t EPINonBlockingReadGet32(uint32_t ui32Base, uint32_t ui32Count, uint32_t *pui32Buf) { uint32_t ui32CountRead = 0; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Count < 4096); ASSERT(pui32Buf); // // Read from the FIFO while there are any items to read and // the caller's specified count is not exceeded. // while(HWREG(ui32Base + EPI_O_RFIFOCNT) && ui32Count--) { // // Read from the FIFO and store in the caller supplied buffer. // *pui32Buf = HWREG(ui32Base + EPI_O_READFIFO0); // // Update the caller's buffer pointer and the count of items read. // pui32Buf++; ui32CountRead++; } // // Return the count of items read to the caller. // return(ui32CountRead); } //***************************************************************************** // //! Read available data from the read FIFO, as 16-bit data items. //! //! \param ui32Base is the EPI module base address. //! \param ui32Count is the maximum count of items to read. //! \param pui16Buf is the caller-supplied buffer where the read data is //! stored. //! //! This function reads 16-bit data items from the read FIFO and stores //! the values in a caller-supplied buffer. The function reads and stores //! data from the FIFO until there is no more data in the FIFO or the maximum //! count is reached as specified in the parameter \e ui32Count. The actual //! count of items is returned. //! //! \return The number of items read from the FIFO. // //***************************************************************************** uint32_t EPINonBlockingReadGet16(uint32_t ui32Base, uint32_t ui32Count, uint16_t *pui16Buf) { uint32_t ui32CountRead = 0; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Count < 4096); ASSERT(pui16Buf); // // Read from the FIFO while there are any items to read, and // the caller's specified count is not exceeded. // while(HWREG(ui32Base + EPI_O_RFIFOCNT) && ui32Count--) { // // Read from the FIFO and store in the caller-supplied buffer. // *pui16Buf = (uint16_t)HWREG(ui32Base + EPI_O_READFIFO0); // // Update the caller's buffer pointer and the count of items read. // pui16Buf++; ui32CountRead++; } // // Return the count of items read to the caller. // return(ui32CountRead); } //***************************************************************************** // //! Read available data from the read FIFO, as 8-bit data items. //! //! \param ui32Base is the EPI module base address. //! \param ui32Count is the maximum count of items to read. //! \param pui8Buf is the caller-supplied buffer where the read data is //! stored. //! //! This function reads 8-bit data items from the read FIFO and stores //! the values in a caller-supplied buffer. The function reads and stores //! data from the FIFO until there is no more data in the FIFO or the maximum //! count is reached as specified in the parameter \e ui32Count. The actual //! count of items is returned. //! //! \return The number of items read from the FIFO. // //***************************************************************************** uint32_t EPINonBlockingReadGet8(uint32_t ui32Base, uint32_t ui32Count, uint8_t *pui8Buf) { uint32_t ui32CountRead = 0; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Count < 4096); ASSERT(pui8Buf); // // Read from the FIFO while there are any items to read, and // the caller's specified count is not exceeded. // while(HWREG(ui32Base + EPI_O_RFIFOCNT) && ui32Count--) { // // Read from the FIFO and store in the caller supplied buffer. // *pui8Buf = (uint8_t)HWREG(ui32Base + EPI_O_READFIFO0); // // Update the caller's buffer pointer and the count of items read. // pui8Buf++; ui32CountRead++; } // // Return the count of items read to the caller. // return(ui32CountRead); } //***************************************************************************** // //! Configures the read FIFO. //! //! \param ui32Base is the EPI module base address. //! \param ui32Config is the FIFO configuration. //! //! This function configures the FIFO trigger levels and error //! generation. The parameter \e ui32Config is the logical OR of the //! following: //! //! - \b EPI_FIFO_CONFIG_WTFULLERR enables an error interrupt when a write is //! attempted and the write FIFO is full //! - \b EPI_FIFO_CONFIG_RSTALLERR enables an error interrupt when a read is //! stalled due to an interleaved write or other reason //! - FIFO TX trigger level, select one of: //! - \b EPI_FIFO_CONFIG_TX_EMPTY sets the FIFO TX trigger level to empty. //! - \b EPI_FIFO_CONFIG_TX_1_4 sets the FIFO TX trigger level to 1/4. //! - \b EPI_FIFO_CONFIG_TX_1_2 sets the FIFO TX trigger level to 1/2. //! - \b EPI_FIFO_CONFIG_TX_3_4 sets the FIFO TX trigger level to 3/4. //! - FIFO RX trigger level, select one of: //! - \b EPI_FIFO_CONFIG_RX_1_8 sets the FIFO RX trigger level to 1/8. //! - \b EPI_FIFO_CONFIG_RX_1_4 sets the FIFO RX trigger level to 1/4. //! - \b EPI_FIFO_CONFIG_RX_1_2 sets the FIFO RX trigger level to 1/2. //! - \b EPI_FIFO_CONFIG_RX_3_4 sets the FIFO RX trigger level to 3/4. //! - \b EPI_FIFO_CONFIG_RX_7_8 sets the FIFO RX trigger level to 7/8. //! - \b EPI_FIFO_CONFIG_RX_FULL sets the FIFO RX trigger level to full. //! //! \return None. // //***************************************************************************** void EPIFIFOConfig(uint32_t ui32Base, uint32_t ui32Config) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32Config == (ui32Config & 0x00030077)); // // Load the configuration into the FIFO config reg. // HWREG(ui32Base + EPI_O_FIFOLVL) = ui32Config; } //***************************************************************************** // //! Reads the number of empty slots in the write transaction FIFO. //! //! \param ui32Base is the EPI module base address. //! //! This function returns the number of slots available in the transaction //! FIFO. It can be used in a polling method to avoid attempting a write //! that would stall. //! //! \return The number of empty slots in the transaction FIFO. // //***************************************************************************** uint32_t EPIWriteFIFOCountGet(uint32_t ui32Base) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); // // Read the FIFO count and return it to the caller. // return(HWREG(ui32Base + EPI_O_WFIFOCNT)); } //***************************************************************************** // //! Enables EPI interrupt sources. //! //! \param ui32Base is the EPI module base address. //! \param ui32IntFlags is a bit mask of the interrupt sources to be enabled. //! //! This function enables the specified EPI sources to generate interrupts. //! The \e ui32IntFlags parameter can be the logical OR of any of the following //! values: //! //! - \b EPI_INT_TXREQ interrupt when transmit FIFO is below the trigger level. //! - \b EPI_INT_RXREQ interrupt when read FIFO is above the trigger level. //! - \b EPI_INT_ERR interrupt when an error condition occurs. //! - \b EPI_INT_DMA_TX_DONE interrupt when the transmit DMA completes. //! - \b EPI_INT_DMA_RX_DONE interrupt when the read DMA completes. //! //! \return Returns None. // //***************************************************************************** void EPIIntEnable(uint32_t ui32Base, uint32_t ui32IntFlags) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32IntFlags < 17); // // Write the interrupt flags mask to the mask register. // HWREG(ui32Base + EPI_O_IM) |= ui32IntFlags; } //***************************************************************************** // //! Disables EPI interrupt sources. //! //! \param ui32Base is the EPI module base address. //! \param ui32IntFlags is a bit mask of the interrupt sources to be disabled. //! //! This function disables the specified EPI sources for interrupt //! generation. The \e ui32IntFlags parameter can be the logical OR of any of //! the following values: //! //! - \b EPI_INT_TXREQ interrupt when transmit FIFO is below the trigger level. //! - \b EPI_INT_RXREQ interrupt when read FIFO is above the trigger level. //! - \b EPI_INT_ERR interrupt when an error condition occurs. //! - \b EPI_INT_DMA_TX_DONE interrupt when the transmit DMA completes. //! - \b EPI_INT_DMA_RX_DONE interrupt when the read DMA completes. //! //! \return Returns None. // //***************************************************************************** void EPIIntDisable(uint32_t ui32Base, uint32_t ui32IntFlags) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32IntFlags < 17); // // Write the interrupt flags mask to the mask register. // HWREG(ui32Base + EPI_O_IM) &= ~ui32IntFlags; } //***************************************************************************** // //! Gets the EPI interrupt status. //! //! \param ui32Base is the EPI module base address. //! \param bMasked is set \b true to get the masked interrupt status, or //! \b false to get the raw interrupt status. //! //! This function returns the EPI interrupt status. It can return either //! the raw or masked interrupt status. //! //! \return Returns the masked or raw EPI interrupt status, as a bit field //! of any of the following values: //! //! - \b EPI_INT_TXREQ interrupt when transmit FIFO is below the trigger level. //! - \b EPI_INT_RXREQ interrupt when read FIFO is above the trigger level. //! - \b EPI_INT_ERR interrupt when an error condition occurs. //! - \b EPI_INT_DMA_TX_DONE interrupt when the transmit DMA completes. //! - \b EPI_INT_DMA_RX_DONE interrupt when the read DMA completes. // //***************************************************************************** uint32_t EPIIntStatus(uint32_t ui32Base, bool bMasked) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); // // Return either the interrupt status or the raw interrupt status as // requested. // if(bMasked) { return(HWREG(ui32Base + EPI_O_MIS)); } else { return(HWREG(ui32Base + EPI_O_RIS)); } } //***************************************************************************** // //! Gets the EPI error interrupt status. //! //! \param ui32Base is the EPI module base address. //! //! This function returns the error status of the EPI. If the return value of //! the function EPIIntStatus() has the flag \b EPI_INT_ERR set, then this //! function can be used to determine the cause of the error. //! //! \return Returns a bit mask of error flags, which can be the logical //! OR of any of the following: //! //! - \b EPI_INT_ERR_WTFULL occurs when a write stalled when the transaction //! FIFO was full //! - \b EPI_INT_ERR_RSTALL occurs when a read stalled //! - \b EPI_INT_ERR_TIMEOUT occurs when the external clock enable held //! off a transaction longer than the configured maximum wait time // //***************************************************************************** uint32_t EPIIntErrorStatus(uint32_t ui32Base) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); // // Read the error status and return to caller. // return(HWREG(ui32Base + EPI_O_EISC)); } //***************************************************************************** // //! Clears pending EPI error sources. //! //! \param ui32Base is the EPI module base address. //! \param ui32ErrFlags is a bit mask of the error sources to be cleared. //! //! This function clears the specified pending EPI errors. The \e ui32ErrFlags //! parameter can be the logical OR of any of the following values: //! //! - \b EPI_INT_ERR_DMAWRIC clears the EPI_INT_DMA_TX_DONE as an interrupt //! source //! - \b EPI_INT_ERR_DMARDIC clears the EPI_INT_DMA_RX_DONE as an interrupt //! source //! - \b EPI_INT_ERR_WTFULL occurs when a write stalled when the transaction //! FIFO was full //! - \b EPI_INT_ERR_RSTALL occurs when a read stalled //! - \b EPI_INT_ERR_TIMEOUT occurs when the external clock enable held //! off a transaction longer than the configured maximum wait time //! //! \return Returns None. // //***************************************************************************** void EPIIntErrorClear(uint32_t ui32Base, uint32_t ui32ErrFlags) { // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(ui32ErrFlags < 0x20); // // Write the error flags to the register to clear the pending errors. // HWREG(ui32Base + EPI_O_EISC) = ui32ErrFlags; } //***************************************************************************** // //! Returns the interrupt number for a given EPI base address. //! //! \param ui32Base is the base address of the EPI module. //! //! This function returns the interrupt number for the EPI module with the base //! address passed in the \e ui32Base parameter. //! //! \return Returns the EPI interrupt number or 0 if the interrupt does not //! exist. // //***************************************************************************** static uint32_t _EPIIntNumberGet(uint32_t ui32Base) { uint32_t ui32Int; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); // // By default, assume EPI is not supported. // ui32Int = 0; if(CLASS_IS_TM4C129) { ui32Int = INT_EPI0_TM4C129; } return(ui32Int); } //***************************************************************************** // //! Registers an interrupt handler for the EPI module. //! //! \param ui32Base is the EPI module base address. //! \param pfnHandler is a pointer to the function to be called when the //! interrupt is activated. //! //! This sets and enables the handler to be called when the EPI module //! generates an interrupt. Specific EPI interrupts must still be enabled //! with the EPIIntEnable() function. //! //! \sa IntRegister() for important information about registering interrupt //! handlers. //! //! \return None. // //***************************************************************************** void EPIIntRegister(uint32_t ui32Base, void (*pfnHandler)(void)) { uint32_t ui32Int; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); ASSERT(pfnHandler); // // Get the interrupt number for the EPI interface. // ui32Int = _EPIIntNumberGet(ui32Base); ASSERT(ui32Int != 0); // // Register the interrupt handler. // IntRegister(ui32Int, pfnHandler); // // Enable the EPI interface interrupt. // IntEnable(ui32Int); } //***************************************************************************** // //! Removes a registered interrupt handler for the EPI module. //! //! \param ui32Base is the EPI module base address. //! //! This function disables and clears the handler to be called when the //! EPI interrupt occurs. //! //! \sa IntRegister() for important information about registering interrupt //! handlers. //! //! \return None. // //***************************************************************************** void EPIIntUnregister(uint32_t ui32Base) { uint32_t ui32Int; // // Check the arguments. // ASSERT(ui32Base == EPI0_BASE); // // Get the interrupt number for the EPI interface. // ui32Int = _EPIIntNumberGet(ui32Base); ASSERT(ui32Int != 0); // // Disable the EPI interface interrupt. // IntDisable(ui32Int); // // Unregister the interrupt handler. // IntUnregister(ui32Int); } //***************************************************************************** // // Close the Doxygen group. //! @} // //*****************************************************************************