verilog/dv/testOut/testOut.c - third_party/shuttle/sky130/mpw-003/slot-034 - Git at Google

 /*
  * SPDX-FileCopyrightText: 2020 Efabless Corporation
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  * SPDX-License-Identifier: Apache-2.0
  */

 // This include is relative to $CARAVEL_PATH (see Makefile)
 #include "verilog/dv/caravel/defs.h"
 #include "verilog/dv/caravel/stub.c"


 void elpis_load_memory(uint32_t*  program_data, uint32_t*  program_addr)
 {
 	int i, continue_reading;
 	continue_reading = 1;
 	i = 0;

 	while (continue_reading)
 	{
 		if (program_data[i] == ((uint32_t) 0xFFFFFFFF))
 		{
 			continue_reading = 0;
 		}else {
 			reg_la0_data = program_addr[i];
 			reg_la1_data = program_data[i];
 		}
 		reg_la3_data = 0x00000005;
 		reg_la3_data = 0x00000004;
 		i++;
 	}
 	reg_la3_data = 0x00000001;
 	reg_la3_data = 0x00000000;
 }

 // --------------------------------------------------------

 /*
 	MPRJ Logic Analyzer Test:
 		- Observes counter value through LA probes [31:0]
 		- Sets counter initial value through LA probes [63:32]
 		- Flags when counter value exceeds 500 through the management SoC gpio
 		- Outputs message to the UART when the test concludes successfuly
 */
 void main()
 {

 	/* Set up the housekeeping SPI to be connected internally so	*/
 	/* that external pin changes don't affect it.			*/

 	reg_spimaster_config = 0xa002; // Enable, prescaler = 2,
 								   // connect to housekeeping SPI

 	// Connect the housekeeping SPI to the SPI master
 	// so that the CSB line is not left floating.  This allows
 	// all of the GPIO pins to be used for user functions.

 	// The upper GPIO pins are configured to be output
 	// and accessble to the management SoC.
 	// Used to flad the start/end of a test
 	// The lower GPIO pins are configured to be output
 	// and accessible to the user project.  They show
 	// the project count value, although this test is
 	// designed to read the project count through the
 	// logic analyzer probes.
 	// I/O 6 is configured for the UART Tx line

 	reg_mprj_io_31 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_30 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_29 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_28 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_27 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_26 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_25 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_24 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_23 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_22 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_21 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_20 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_19 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_18 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_17 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_16 = GPIO_MODE_USER_STD_OUTPUT;

 	reg_mprj_io_15 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_14 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_13 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_12 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_11 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_10 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_9 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_8 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_7 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_5 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_4 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_3 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_2 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_1 = GPIO_MODE_USER_STD_OUTPUT;
 	reg_mprj_io_0 = GPIO_MODE_USER_STD_OUTPUT;

 	reg_mprj_io_6 = GPIO_MODE_MGMT_STD_OUTPUT;

 	// Set UART clock to 64 kbaud (enable before I/O configuration)
 	reg_uart_clkdiv = 625;
 	reg_uart_enable = 1;

 	/* Apply configuration */
 	reg_mprj_xfer = 1;
 	while (reg_mprj_xfer == 1);

 	// Configuring LA probes
 	// outputs from the cpu are inputs for my project denoted for been 0
 	// inputs to the cpu are outpus for my project denoted for been 1
 	reg_la0_oenb = reg_la0_iena = 0x00000000; // [31:0]
 	reg_la1_oenb = reg_la1_iena = 0x00000000; // [63:32]
 	reg_la2_oenb = reg_la2_iena = 0x00000000; // [95:64]
 	reg_la3_oenb = reg_la3_iena = 0xFFFFFFF8; // [127:96]

 	// Flag start of the test
 	reg_mprj_datal = 0xAB400000;

 	// Elpis OS information
 	uint32_t OS_DATA[30];
 	OS_DATA[0] = 0x00502023;
 	OS_DATA[1] = 0x00602223;
 	OS_DATA[2] = 0x00702423;
 	OS_DATA[3] = 0x00802623;
 	OS_DATA[4] = 0x00902823;
 	OS_DATA[5] = 0x00400413;
 	OS_DATA[6] = 0x00500493;
 	OS_DATA[7] = 0x00600293;
 	OS_DATA[8] = 0x00700313;
 	OS_DATA[9] = 0x002003af;
 	OS_DATA[10] = 0x00838c63;
 	OS_DATA[11] = 0x00938a63;
 	OS_DATA[12] = 0x00538c63;
 	OS_DATA[13] = 0x00638e63;
 	OS_DATA[14] = 0x00038e63;
 	OS_DATA[15] = 0x02000863;
 	OS_DATA[16] = 0x0000002e;
 	OS_DATA[17] = 0x00000863;
 	OS_DATA[18] = 0x0200007D;
 	OS_DATA[19] = 0x00000463;
 	OS_DATA[20] = 0x0400007D;
 	OS_DATA[21] = 0x00002283;
 	OS_DATA[22] = 0x00402303;
 	OS_DATA[23] = 0x00802383;
 	OS_DATA[24] = 0x00c02403;
 	OS_DATA[25] = 0x01002483;
 	OS_DATA[26] = 0x0000007F;
 	OS_DATA[27] = 0x00000033;
 	OS_DATA[28] = 0x00002050;
 	OS_DATA[29] = 0xFFFFFFFF;

 	uint32_t OS_ADDR[30];
 	OS_ADDR[0] = 0x00000800;
 	OS_ADDR[1] = 0x00000801;
 	OS_ADDR[2] = 0x00000802;
 	OS_ADDR[3] = 0x00000803;
 	OS_ADDR[4] = 0x00000804;
 	OS_ADDR[5] = 0x00000805;
 	OS_ADDR[6] = 0x00000806;
 	OS_ADDR[7] = 0x00000807;
 	OS_ADDR[8] = 0x00000808;
 	OS_ADDR[9] = 0x00000809;
 	OS_ADDR[10] = 0x0000080a;
 	OS_ADDR[11] = 0x0000080b;
 	OS_ADDR[12] = 0x0000080c;
 	OS_ADDR[13] = 0x0000080d;
 	OS_ADDR[14] = 0x0000080e;
 	OS_ADDR[15] = 0x0000080f;
 	OS_ADDR[16] = 0x00000810;
 	OS_ADDR[17] = 0x00000811;
 	OS_ADDR[18] = 0x00000812;
 	OS_ADDR[19] = 0x00000813;
 	OS_ADDR[20] = 0x00000814;
 	OS_ADDR[21] = 0x00000815;
 	OS_ADDR[22] = 0x00000816;
 	OS_ADDR[23] = 0x00000817;
 	OS_ADDR[24] = 0x00000818;
 	OS_ADDR[25] = 0x00000819;
 	OS_ADDR[26] = 0x0000081a;
 	OS_ADDR[27] = 0x0000081b;
 	OS_ADDR[28] = 0x00000005;
 	OS_ADDR[29] = 0xFFFFFFFF;

 	// Elpis user program


 	// Loading elpis memory
 	elpis_load_memory(OS_DATA, OS_ADDR);


 	reg_la3_oenb = reg_la3_iena = 0xFFFFFFF9; // Recovering fast clock not controlled by the user

 	// Reset of Elpis and start of computation at Elpis
 	reg_la3_data = 0x00000002;
 	reg_la3_data = 0x00000000;

 	reg_mprj_datal = 0xAB410000;
 	print("\n");
 	print("Monitor: Test 1 Passed\n\n"); // Makes simulation very long!
 	reg_mprj_datal = 0xAB510000;
 }
	/*
	* SPDX-FileCopyrightText: 2020 Efabless Corporation
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	* SPDX-License-Identifier: Apache-2.0
	*/

	// This include is relative to $CARAVEL_PATH (see Makefile)
	#include "verilog/dv/caravel/defs.h"
	#include "verilog/dv/caravel/stub.c"


	void elpis_load_memory(uint32_t* program_data, uint32_t* program_addr)
	{
	int i, continue_reading;
	continue_reading = 1;
	i = 0;

	while (continue_reading)
	{
	if (program_data[i] == ((uint32_t) 0xFFFFFFFF))
	{
	continue_reading = 0;
	}else {
	reg_la0_data = program_addr[i];
	reg_la1_data = program_data[i];
	}
	reg_la3_data = 0x00000005;
	reg_la3_data = 0x00000004;
	i++;
	}
	reg_la3_data = 0x00000001;
	reg_la3_data = 0x00000000;
	}

	// --------------------------------------------------------

	/*
	MPRJ Logic Analyzer Test:
	- Observes counter value through LA probes [31:0]
	- Sets counter initial value through LA probes [63:32]
	- Flags when counter value exceeds 500 through the management SoC gpio
	- Outputs message to the UART when the test concludes successfuly
	*/
	void main()
	{

	/* Set up the housekeeping SPI to be connected internally so */
	/* that external pin changes don't affect it. */

	reg_spimaster_config = 0xa002; // Enable, prescaler = 2,
	// connect to housekeeping SPI

	// Connect the housekeeping SPI to the SPI master
	// so that the CSB line is not left floating. This allows
	// all of the GPIO pins to be used for user functions.

	// The upper GPIO pins are configured to be output
	// and accessble to the management SoC.
	// Used to flad the start/end of a test
	// The lower GPIO pins are configured to be output
	// and accessible to the user project. They show
	// the project count value, although this test is
	// designed to read the project count through the
	// logic analyzer probes.
	// I/O 6 is configured for the UART Tx line

	reg_mprj_io_31 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_30 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_29 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_28 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_27 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_26 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_25 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_24 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_23 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_22 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_21 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_20 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_19 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_18 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_17 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_16 = GPIO_MODE_USER_STD_OUTPUT;

	reg_mprj_io_15 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_14 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_13 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_12 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_11 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_10 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_9 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_8 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_7 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_5 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_4 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_3 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_2 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_1 = GPIO_MODE_USER_STD_OUTPUT;
	reg_mprj_io_0 = GPIO_MODE_USER_STD_OUTPUT;

	reg_mprj_io_6 = GPIO_MODE_MGMT_STD_OUTPUT;

	// Set UART clock to 64 kbaud (enable before I/O configuration)
	reg_uart_clkdiv = 625;
	reg_uart_enable = 1;

	/* Apply configuration */
	reg_mprj_xfer = 1;
	while (reg_mprj_xfer == 1);

	// Configuring LA probes
	// outputs from the cpu are inputs for my project denoted for been 0
	// inputs to the cpu are outpus for my project denoted for been 1
	reg_la0_oenb = reg_la0_iena = 0x00000000; // [31:0]
	reg_la1_oenb = reg_la1_iena = 0x00000000; // [63:32]
	reg_la2_oenb = reg_la2_iena = 0x00000000; // [95:64]
	reg_la3_oenb = reg_la3_iena = 0xFFFFFFF8; // [127:96]

	// Flag start of the test
	reg_mprj_datal = 0xAB400000;

	// Elpis OS information
	uint32_t OS_DATA[30];
	OS_DATA[0] = 0x00502023;
	OS_DATA[1] = 0x00602223;
	OS_DATA[2] = 0x00702423;
	OS_DATA[3] = 0x00802623;
	OS_DATA[4] = 0x00902823;
	OS_DATA[5] = 0x00400413;
	OS_DATA[6] = 0x00500493;
	OS_DATA[7] = 0x00600293;
	OS_DATA[8] = 0x00700313;
	OS_DATA[9] = 0x002003af;
	OS_DATA[10] = 0x00838c63;
	OS_DATA[11] = 0x00938a63;
	OS_DATA[12] = 0x00538c63;
	OS_DATA[13] = 0x00638e63;
	OS_DATA[14] = 0x00038e63;
	OS_DATA[15] = 0x02000863;
	OS_DATA[16] = 0x0000002e;
	OS_DATA[17] = 0x00000863;
	OS_DATA[18] = 0x0200007D;
	OS_DATA[19] = 0x00000463;
	OS_DATA[20] = 0x0400007D;
	OS_DATA[21] = 0x00002283;
	OS_DATA[22] = 0x00402303;
	OS_DATA[23] = 0x00802383;
	OS_DATA[24] = 0x00c02403;
	OS_DATA[25] = 0x01002483;
	OS_DATA[26] = 0x0000007F;
	OS_DATA[27] = 0x00000033;
	OS_DATA[28] = 0x00002050;
	OS_DATA[29] = 0xFFFFFFFF;

	uint32_t OS_ADDR[30];
	OS_ADDR[0] = 0x00000800;
	OS_ADDR[1] = 0x00000801;
	OS_ADDR[2] = 0x00000802;
	OS_ADDR[3] = 0x00000803;
	OS_ADDR[4] = 0x00000804;
	OS_ADDR[5] = 0x00000805;
	OS_ADDR[6] = 0x00000806;
	OS_ADDR[7] = 0x00000807;
	OS_ADDR[8] = 0x00000808;
	OS_ADDR[9] = 0x00000809;
	OS_ADDR[10] = 0x0000080a;
	OS_ADDR[11] = 0x0000080b;
	OS_ADDR[12] = 0x0000080c;
	OS_ADDR[13] = 0x0000080d;
	OS_ADDR[14] = 0x0000080e;
	OS_ADDR[15] = 0x0000080f;
	OS_ADDR[16] = 0x00000810;
	OS_ADDR[17] = 0x00000811;
	OS_ADDR[18] = 0x00000812;
	OS_ADDR[19] = 0x00000813;
	OS_ADDR[20] = 0x00000814;
	OS_ADDR[21] = 0x00000815;
	OS_ADDR[22] = 0x00000816;
	OS_ADDR[23] = 0x00000817;
	OS_ADDR[24] = 0x00000818;
	OS_ADDR[25] = 0x00000819;
	OS_ADDR[26] = 0x0000081a;
	OS_ADDR[27] = 0x0000081b;
	OS_ADDR[28] = 0x00000005;
	OS_ADDR[29] = 0xFFFFFFFF;

	// Elpis user program


	// Loading elpis memory
	elpis_load_memory(OS_DATA, OS_ADDR);


	reg_la3_oenb = reg_la3_iena = 0xFFFFFFF9; // Recovering fast clock not controlled by the user

	// Reset of Elpis and start of computation at Elpis
	reg_la3_data = 0x00000002;
	reg_la3_data = 0x00000000;

	reg_mprj_datal = 0xAB410000;
	print("\n");
	print("Monitor: Test 1 Passed\n\n"); // Makes simulation very long!
	reg_mprj_datal = 0xAB510000;
	}