neorv32/sw/example/demo_dma/main.c

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// #################################################################################################
// # << NEORV32 - DMA Demo Program >> #
// # ********************************************************************************************* #
// # BSD 3-Clause License #
// # #
// # Copyright (c) 2024, Stephan Nolting. All rights reserved. #
// # #
// # Redistribution and use in source and binary forms, with or without modification, are #
// # permitted provided that the following conditions are met: #
// # #
// # 1. Redistributions of source code must retain the above copyright notice, this list of #
// # conditions and the following disclaimer. #
// # #
// # 2. 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. #
// # #
// # 3. Neither the name of the copyright holder 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 HOLDER 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. #
// # ********************************************************************************************* #
// # The NEORV32 Processor - https://github.com/stnolting/neorv32 (c) Stephan Nolting #
// #################################################################################################
/**********************************************************************//**
* @file demo_dma/main.c
* @author Stephan Nolting
* @brief DMA demo program.
**************************************************************************/
#include <neorv32.h>
/**********************************************************************//**
* @name User configuration
**************************************************************************/
/**@{*/
/** UART BAUD rate */
#define BAUD_RATE 19200
/**@}*/
// arrays for DMA data
volatile uint32_t dma_src[4], dma_dst[4];
// prototypes
void show_arrays(void);
void dma_firq_handler(void);
/**********************************************************************//**
* Simple demo program to showcase the NEORV32 DMA controller.
*
* @note This program requires UART0 and the DMA controller to be synthesized.
*
* @return Irrelevant.
**************************************************************************/
int main() {
uint32_t cmd;
int rc;
// setup NEORV32 runtime environment
neorv32_rte_setup();
// setup UART at default baud rate, no interrupts
neorv32_uart0_setup(BAUD_RATE, 0);
// intro
neorv32_uart0_printf("\n<<< DMA Controller Demo Program >>>\n\n");
// check if DMA controller is implemented at all
if (neorv32_dma_available() == 0) {
neorv32_uart0_printf("ERROR! DMA controller not implemented!\n");
return 1;
}
// show base address of test data arrays
neorv32_uart0_printf("Source test data: %u bytes @ 0x%x\n", (uint32_t)(sizeof(dma_src)), (uint32_t)(&dma_src[0]));
neorv32_uart0_printf("Destination test data: %u bytes @ 0x%x\n", (uint32_t)(sizeof(dma_src)), (uint32_t)(&dma_dst[0]));
// install DMA interrupt handler
neorv32_rte_handler_install(DMA_RTE_ID, dma_firq_handler);
// enable DMA
neorv32_dma_enable();
// issue a FENCE operation when the DMA transfer completes (without errors); this
// will re-sync /flush and reload) all downstream caches
neorv32_dma_fence_enable();
// initialize and data arrays
dma_src[0] = 0x66778899UL;
dma_src[1] = 0x22334455UL;
dma_src[2] = 0xaabbccddUL;
dma_src[3] = 0x0011eeffUL;
dma_dst[0] = 0;
dma_dst[1] = 0;
dma_dst[2] = 0;
dma_dst[3] = 0;
asm volatile ("fence"); // re-sync caches
// ----------------------------------------------------------
// example 1
// ----------------------------------------------------------
neorv32_uart0_printf("\nExample 1: Manual byte-to-byte block transfer with Endianness conversion using busy wait.\n");
// configure transfer type
cmd = DMA_CMD_B2B | // read source in byte quantities, write destination in byte quantities
DMA_CMD_SRC_INC | // auto-increment source address
DMA_CMD_DST_INC | // auto-increment destination address
DMA_CMD_ENDIAN; // change Endianness
// trigger manual DMA transfer
neorv32_dma_transfer((uint32_t)(&dma_src[0]), // source array base address - byte-aligned!
(uint32_t)(&dma_dst[0]), // destination array base address - byte-aligned!
16, // number of elements to transfer: 16
cmd); // transfer type configuration
// wait for transfer to complete using polling
neorv32_uart0_printf("Waiting for DMA... ");
while (1) {
rc = neorv32_dma_status();
if (rc == DMA_STATUS_IDLE) {
neorv32_uart0_printf("Transfer done.\n");
break;
}
else if ((rc == DMA_STATUS_ERR_RD) || (rc == DMA_STATUS_ERR_WR)) {
neorv32_uart0_printf("Transfer failed!\n");
break;
}
}
show_arrays();
// ----------------------------------------------------------
// example 2
// ----------------------------------------------------------
neorv32_uart0_printf("\nExample 2: Manual word-to-word one-to-many transfer using busy wait.\n");
// configure transfer type
cmd = DMA_CMD_W2W | // read source in word quantities, write destination in word quantities
DMA_CMD_SRC_CONST | // constant source address
DMA_CMD_DST_INC; // auto-increment destination address
// trigger manual DMA transfer
neorv32_dma_transfer((uint32_t)(&dma_src[0]), // source array base address - word-aligned!
(uint32_t)(&dma_dst[0]), // destination array base address - word-aligned!
4, // number of elements to transfer: 4
cmd); // transfer type configuration
// wait for transfer to complete using polling
neorv32_uart0_printf("Waiting for DMA... ");
while (1) {
rc = neorv32_dma_status();
if (rc == DMA_STATUS_IDLE) {
neorv32_uart0_printf("Transfer done.\n");
break;
}
else if ((rc == DMA_STATUS_ERR_RD) || (rc == DMA_STATUS_ERR_WR)) {
neorv32_uart0_printf("Transfer failed!\n");
break;
}
}
show_arrays();
// ----------------------------------------------------------
// example 3
// ----------------------------------------------------------
neorv32_uart0_printf("\nExample 3: Manual byte-to-signed-word block transfer using transfer-done interrupt.\n");
// configure DMA interrupt
neorv32_cpu_csr_clr(CSR_MIP, 1 << DMA_FIRQ_PENDING); // clear any pending DMA FIRQ
neorv32_cpu_csr_set(CSR_MIE, 1 << DMA_FIRQ_ENABLE); // enable DMA interrupt source
neorv32_cpu_csr_set(CSR_MSTATUS, 1 << CSR_MSTATUS_MIE); // enable machine-mode interrupts
// configure transfer type
cmd = DMA_CMD_B2SW | // read source in byte quantities, write destination in sign-extended word quantities
DMA_CMD_SRC_INC | // auto-increment source address
DMA_CMD_DST_INC; // auto-increment destination address
// trigger manual DMA transfer
neorv32_dma_transfer((uint32_t)(&dma_src[0]), // source array base address - byte-aligned!
(uint32_t)(&dma_dst[0]), // destination array base address - word-aligned!
4, // number of elements to transfer: 4
cmd); // transfer type configuration
// go to sleep mode, wakeup on DMA transfer-done interrupt
neorv32_cpu_sleep();
// check if transfer was successful
if (neorv32_dma_status() != DMA_STATUS_IDLE) {
neorv32_uart0_printf("Transfer failed!\n");
}
show_arrays();
// ----------------------------------------------------------
// example 4
// ----------------------------------------------------------
neorv32_uart0_printf("\nExample 4: Automatic byte-to-byte one-to-many transfer using transfer-done interrupt.\n");
neorv32_uart0_printf( " The GPTMR FIRQ channel is used to trigger the DMA.\n");
if (neorv32_gptmr_available()) { // only execute if GPTMR is available
// configure DMA interrupt
neorv32_cpu_csr_clr(CSR_MIP, 1 << DMA_FIRQ_PENDING); // clear any pending DMA FIRQ
neorv32_cpu_csr_set(CSR_MIE, 1 << DMA_FIRQ_ENABLE); // enable DMA interrupt source
neorv32_cpu_csr_set(CSR_MSTATUS, 1 << CSR_MSTATUS_MIE); // enable machine-mode interrupts
// configure GPTMR
neorv32_gptmr_setup(CLK_PRSC_2, // GPTM clock = 1/2 main clock
4096, // counter threshold for triggering IRQ
1); // enable timer-match interrupt
// configure transfer type
cmd = DMA_CMD_B2B | // read source in byte quantities, write destination in byte quantities
DMA_CMD_SRC_CONST | // constant source address
DMA_CMD_DST_INC; // auto-increment destination address
// configure automatic DMA transfer
neorv32_dma_transfer_auto((uint32_t)(&dma_src[3]), // source array base address (data = 0xff)
(uint32_t)(&dma_dst[0]), // destination array base address
16, // number of elements to transfer: 16
cmd, // transfer type configuration
1 << GPTMR_FIRQ_PENDING); // trigger transfer on pending GPTMR interrupt
// sleep until interrupt (from DMA)
neorv32_cpu_sleep();
// transfer successful (and actually executed)?
if ((neorv32_dma_done() == 0) || // check if the DMA has actually completed a transfer
(neorv32_dma_status() != DMA_STATUS_IDLE)) { // DMA is in idle mode without errors
neorv32_uart0_printf("Transfer failed!\n");
}
show_arrays();
}
else {
neorv32_uart0_printf("Example skipped as GPTMR is not implemented.\n");
}
neorv32_uart0_printf("\nProgram completed.\n");
return 0;
}
/**********************************************************************//**
* Print test data arrays
**************************************************************************/
void show_arrays(void) {
asm volatile ("fence"); // re-sync caches
neorv32_uart0_printf("---------------------------\n");
neorv32_uart0_printf(" SRC DST\n");
neorv32_uart0_printf("[0] 0x%x 0x%x\n", dma_src[0], dma_dst[0]);
neorv32_uart0_printf("[1] 0x%x 0x%x\n", dma_src[1], dma_dst[1]);
neorv32_uart0_printf("[2] 0x%x 0x%x\n", dma_src[2], dma_dst[2]);
neorv32_uart0_printf("[3] 0x%x 0x%x\n", dma_src[3], dma_dst[3]);
neorv32_uart0_printf("---------------------------\n");
}
/**********************************************************************//**
* DMA FIRQ handler.
*
* @warning This function has to be of type "void xyz(void)" and must not use any interrupt attributes!
**************************************************************************/
void dma_firq_handler(void) {
neorv32_cpu_csr_clr(CSR_MIP, 1 << DMA_FIRQ_PENDING); // clear/ack pending FIRQ
neorv32_gptmr_disable(); // disable GPTMR
neorv32_uart0_printf("<<DMA interrupt>>\n");
}