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Merge remote-tracking branch 'upstream/master' into edpt_ISO_xfer

This commit is contained in:
Reinhard Panhuber 2021-01-09 12:10:08 +01:00
parent 09d8ead4b8 cfcffe94ce
commit 485d8fa77e
23 changed files with 867 additions and 124 deletions
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1
docs/boards.md
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@ -86,6 +86,7 @@ This code base already had supported for a handful of following boards (sorted a
- [LPCXpresso 54114](https://www.nxp.com/design/microcontrollers-developer-resources/lpcxpresso-boards/lpcxpresso54114-board:OM13089)
- [LPCXpresso 55s69 EVK](https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/general-purpose-mcus/lpc5500-cortex-m33/lpcxpresso55s69-development-board:LPC55S69-EVK)
- [NGX LPC4330-Xplorer](https://www.nxp.com/design/designs/lpc4330-xplorer-board:OM13027)
- [Double M33 Express](https://www.crowdsupply.com/steiert-solutions/double-m33-express)
### Sony

234
hw/bsp/double_m33_express/LPC55S69_cm33_core0_uf2.ld Normal file
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@ -0,0 +1,234 @@
/*
** ###################################################################
** Processors: LPC55S69JBD100_cm33_core0
** LPC55S69JBD64_cm33_core0
** LPC55S69JEV98_cm33_core0
**
** Compiler: GNU C Compiler
** Reference manual: LPC55S6x/LPC55S2x/LPC552x User manual(UM11126) Rev.1.3 16 May 2019
** Version: rev. 1.1, 2019-05-16
** Build: b191008
**
** Abstract:
** Linker file for the GNU C Compiler
**
** Copyright 2016 Freescale Semiconductor, Inc.
** Copyright 2016-2019 NXP
** All rights reserved.
**
** SPDX-License-Identifier: BSD-3-Clause
**
** http: www.nxp.com
** mail: support@nxp.com
**
** ###################################################################
*/
/* Entry Point */
ENTRY(Reset_Handler)
HEAP_SIZE = DEFINED(__heap_size__) ? __heap_size__ : 0x0400;
STACK_SIZE = DEFINED(__stack_size__) ? __stack_size__ : 0x0800;
RPMSG_SHMEM_SIZE = DEFINED(__use_shmem__) ? 0x1800 : 0;
/* Specify the memory areas */
MEMORY
{
m_interrupts (RX) : ORIGIN = 0x00010000, LENGTH = 0x00000200
m_text (RX) : ORIGIN = 0x00010200, LENGTH = 0x0007FE00
m_core1_image (RX) : ORIGIN = 0x00090000, LENGTH = 0x00008000
m_data (RW) : ORIGIN = 0x20000000, LENGTH = 0x00033000 - RPMSG_SHMEM_SIZE
rpmsg_sh_mem (RW) : ORIGIN = 0x20033000 - RPMSG_SHMEM_SIZE, LENGTH = RPMSG_SHMEM_SIZE
m_usb_sram (RW) : ORIGIN = 0x40100000, LENGTH = 0x00004000
}
/* Define output sections */
SECTIONS
{
/* section for storing the secondary core image */
.m0code :
{
. = ALIGN(4) ;
KEEP (*(.m0code))
*(.m0code*)
. = ALIGN(4) ;
} > m_core1_image
/* NOINIT section for rpmsg_sh_mem */
.noinit_rpmsg_sh_mem (NOLOAD) : ALIGN(4)
{
__RPMSG_SH_MEM_START__ = .;
*(.noinit.$rpmsg_sh_mem*)
. = ALIGN(4) ;
__RPMSG_SH_MEM_END__ = .;
} > rpmsg_sh_mem
/* The startup code goes first into internal flash */
.interrupts :
{
. = ALIGN(4);
KEEP(*(.isr_vector)) /* Startup code */
. = ALIGN(4);
} > m_interrupts
/* The program code and other data goes into internal flash */
.text :
{
. = ALIGN(4);
*(.text) /* .text sections (code) */
*(.text*) /* .text* sections (code) */
*(.rodata) /* .rodata sections (constants, strings, etc.) */
*(.rodata*) /* .rodata* sections (constants, strings, etc.) */
*(.glue_7) /* glue arm to thumb code */
*(.glue_7t) /* glue thumb to arm code */
*(.eh_frame)
KEEP (*(.init))
KEEP (*(.fini))
. = ALIGN(4);
} > m_text
.ARM.extab :
{
*(.ARM.extab* .gnu.linkonce.armextab.*)
} > m_text
.ARM :
{
__exidx_start = .;
*(.ARM.exidx*)
__exidx_end = .;
} > m_text
.ctors :
{
__CTOR_LIST__ = .;
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
from the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE(*crtend?.o *crtend.o) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
__CTOR_END__ = .;
} > m_text
.dtors :
{
__DTOR_LIST__ = .;
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE(*crtend?.o *crtend.o) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
__DTOR_END__ = .;
} > m_text
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array*))
PROVIDE_HIDDEN (__preinit_array_end = .);
} > m_text
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT(.init_array.*)))
KEEP (*(.init_array*))
PROVIDE_HIDDEN (__init_array_end = .);
} > m_text
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT(.fini_array.*)))
KEEP (*(.fini_array*))
PROVIDE_HIDDEN (__fini_array_end = .);
} > m_text
__etext = .; /* define a global symbol at end of code */
__DATA_ROM = .; /* Symbol is used by startup for data initialization */
.data : AT(__DATA_ROM)
{
. = ALIGN(4);
__DATA_RAM = .;
__data_start__ = .; /* create a global symbol at data start */
*(.ramfunc*) /* for functions in ram */
*(.data) /* .data sections */
*(.data*) /* .data* sections */
KEEP(*(.jcr*))
. = ALIGN(4);
__data_end__ = .; /* define a global symbol at data end */
} > m_data
__DATA_END = __DATA_ROM + (__data_end__ - __data_start__);
text_end = ORIGIN(m_text) + LENGTH(m_text);
ASSERT(__DATA_END <= text_end, "region m_text overflowed with text and data")
/* Uninitialized data section */
.bss :
{
/* This is used by the startup in order to initialize the .bss section */
. = ALIGN(4);
__START_BSS = .;
__bss_start__ = .;
*(.bss)
*(.bss*)
*(COMMON)
. = ALIGN(4);
__bss_end__ = .;
__END_BSS = .;
} > m_data
.heap :
{
. = ALIGN(8);
__end__ = .;
PROVIDE(end = .);
__HeapBase = .;
. += HEAP_SIZE;
__HeapLimit = .;
__heap_limit = .; /* Add for _sbrk */
} > m_data
.stack :
{
. = ALIGN(8);
. += STACK_SIZE;
} > m_data
m_usb_bdt (NOLOAD) :
{
. = ALIGN(512);
*(m_usb_bdt)
} > m_usb_sram
m_usb_global (NOLOAD) :
{
*(m_usb_global)
} > m_usb_sram
/* Initializes stack on the end of block */
__StackTop = ORIGIN(m_data) + LENGTH(m_data);
__StackLimit = __StackTop - STACK_SIZE;
PROVIDE(__stack = __StackTop);
.ARM.attributes 0 : { *(.ARM.attributes) }
ASSERT(__StackLimit >= __HeapLimit, "region m_data overflowed with stack and heap")
}

51
hw/bsp/double_m33_express/board.mk Normal file
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@ -0,0 +1,51 @@
CFLAGS += \
-flto \
-mthumb \
-mabi=aapcs \
-mcpu=cortex-m33 \
-mfloat-abi=hard \
-mfpu=fpv5-sp-d16 \
-DCPU_LPC55S69JBD100_cm33_core0 \
-DCFG_TUSB_MCU=OPT_MCU_LPC55XX \
-DCFG_TUSB_MEM_SECTION='__attribute__((section(".data")))' \
-DCFG_TUSB_MEM_ALIGN='__attribute__((aligned(64)))'
# mcu driver cause following warnings
CFLAGS += -Wno-error=unused-parameter -Wno-error=float-equal
MCU_DIR = hw/mcu/nxp/sdk/devices/LPC55S69
# All source paths should be relative to the top level.
LD_FILE = hw/bsp/$(BOARD)/LPC55S69_cm33_core0_uf2.ld
SRC_C += \
$(MCU_DIR)/system_LPC55S69_cm33_core0.c \
$(MCU_DIR)/drivers/fsl_clock.c \
$(MCU_DIR)/drivers/fsl_gpio.c \
$(MCU_DIR)/drivers/fsl_power.c \
$(MCU_DIR)/drivers/fsl_reset.c \
$(MCU_DIR)/drivers/fsl_usart.c \
$(MCU_DIR)/drivers/fsl_flexcomm.c
INC += \
$(TOP)/$(MCU_DIR)/../../CMSIS/Include \
$(TOP)/$(MCU_DIR) \
$(TOP)/$(MCU_DIR)/drivers
SRC_S += $(MCU_DIR)/gcc/startup_LPC55S69_cm33_core0.S
LIBS += $(TOP)/$(MCU_DIR)/gcc/libpower_hardabi.a
# For TinyUSB port source
VENDOR = nxp
CHIP_FAMILY = lpc_ip3511
# For freeRTOS port source
FREERTOS_PORT = ARM_CM33_NTZ/non_secure
# For flash-jlink target
JLINK_DEVICE = LPC55S69
# flash using pyocd
flash: $(BUILD)/$(BOARD)-firmware.hex
pyocd flash -t LPC55S69 $<

400
hw/bsp/double_m33_express/double_m33_express.c Normal file
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@ -0,0 +1,400 @@
/*
* The MIT License (MIT)
*
* Copyright (c) 2018, hathach (tinyusb.org)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
* This file is part of the TinyUSB stack.
*/
#include "../board.h"
#include "fsl_device_registers.h"
#include "fsl_gpio.h"
#include "fsl_power.h"
#include "fsl_iocon.h"
#include "fsl_sctimer.h"
//--------------------------------------------------------------------+
// Forward USB interrupt events to TinyUSB IRQ Handler
//--------------------------------------------------------------------+
void USB0_IRQHandler(void)
{
tud_int_handler(0);
}
void USB1_IRQHandler(void)
{
tud_int_handler(1);
}
//--------------------------------------------------------------------+
// MACRO TYPEDEF CONSTANT ENUM
//--------------------------------------------------------------------+
#define LED_PORT 0
#define LED_PIN 1
#define LED_STATE_ON 1
// WAKE button
#define BUTTON_PORT 0
#define BUTTON_PIN 5
#define BUTTON_STATE_ACTIVE 0
// Number of neopixels
#define NEOPIXEL_NUMBER 2
#define NEOPIXEL_PORT 0
#define NEOPIXEL_PIN 27
// UART
#define UART_DEV USART0
// IOCON pin mux
#define IOCON_PIO_DIGITAL_EN 0x0100u /*!<@brief Enables digital function */
#define IOCON_PIO_FUNC0 0x00u /*!<@brief Selects pin function 0 */
#define IOCON_PIO_FUNC1 0x01u /*!<@brief Selects pin function 1 */
#define IOCON_PIO_FUNC4 0x04u /*!<@brief Selects pin function 4 */
#define IOCON_PIO_FUNC7 0x07u /*!<@brief Selects pin function 7 */
#define IOCON_PIO_INV_DI 0x00u /*!<@brief Input function is not inverted */
#define IOCON_PIO_MODE_INACT 0x00u /*!<@brief No addition pin function */
#define IOCON_PIO_OPENDRAIN_DI 0x00u /*!<@brief Open drain is disabled */
#define IOCON_PIO_SLEW_STANDARD 0x00u /*!<@brief Standard mode, output slew rate control is enabled */
#define IOCON_PIO_DIG_FUNC0_EN (IOCON_PIO_DIGITAL_EN | IOCON_PIO_FUNC0) /*!<@brief Digital pin function 0 enabled */
#define IOCON_PIO_DIG_FUNC1_EN (IOCON_PIO_DIGITAL_EN | IOCON_PIO_FUNC1) /*!<@brief Digital pin function 1 enabled */
#define IOCON_PIO_DIG_FUNC4_EN (IOCON_PIO_DIGITAL_EN | IOCON_PIO_FUNC4) /*!<@brief Digital pin function 2 enabled */
#define IOCON_PIO_DIG_FUNC7_EN (IOCON_PIO_DIGITAL_EN | IOCON_PIO_FUNC7) /*!<@brief Digital pin function 2 enabled */
//--------------------------------------------------------------------+
// Neopixel Driver
//--------------------------------------------------------------------+
#define NEO_SCT SCT0
#define NEO_MATCH_PERIOD 0
#define NEO_MATCH_0 1
#define NEO_MATCH_1 2
#define NEO_EVENT_RISE 2
#define NEO_EVENT_FALL_0 0
#define NEO_EVENT_FALL_1 1
#define NEO_EVENT_NEXT 3
#define NEO_EVENT_START 4
#define NEO_SCT_OUTPUT 6
#define NEO_STATE_IDLE 24
//#define NEO_ARRAY_SIZE (3 * NEOPIXEL_NUMBER)
//volatile uint32_t _neopixel_array[NEO_ARRAY_SIZE] = {0x10, 0x20, 0x30, 0x40, 0x50, 0x60};
volatile uint32_t _neopixel_array[NEOPIXEL_NUMBER] = {0x404040, 0x202020};
volatile uint32_t _neopixel_count = 0;
void neopixel_int_handler(void){
uint32_t eventFlag = NEO_SCT->EVFLAG;
if (eventFlag & (1 << NEO_EVENT_NEXT)) {
_neopixel_count += 1;
if (_neopixel_count < (NEOPIXEL_NUMBER)) {
NEO_SCT->EV[NEO_EVENT_FALL_0].STATE = 0xFFFFFF & (~_neopixel_array[_neopixel_count]);
NEO_SCT->CTRL &= ~(SCT_CTRL_HALT_L_MASK);
}
}
NEO_SCT->EVFLAG = eventFlag;
}
void SCT0_DriverIRQHandler(void){
neopixel_int_handler();
SDK_ISR_EXIT_BARRIER;
}
void neopixel_set(uint32_t pixel, uint32_t color){
if (pixel < NEOPIXEL_NUMBER) {
_neopixel_array[pixel] = color;
}
}
void neopixel_update(void){
// while (NEO_SCT->CTRL & SCT_CTRL_HALT_L_MASK);
_neopixel_count = 0;
NEO_SCT->EV[NEO_EVENT_FALL_0].STATE = 0xFFFFFF & (~_neopixel_array[0]);
NEO_SCT->CTRL &= ~(SCT_CTRL_HALT_L_MASK);
}
/*
void neopixel_int_handler(void){
uint32_t eventFlag = NEO_SCT->EVFLAG;
// if ((eventFlag & (1 << NEO_EVENT_NEXT)) && (_neopixel_count < (NEO_ARRAY_SIZE))) {
// NEO_SCT->EV[NEO_EVENT_FALL_0].STATE = 0xFF & (~_neopixel_array[_neopixel_count]);
if ((eventFlag & (1 << NEO_EVENT_NEXT)) && (_neopixel_count < (NEOPIXEL_NUMBER))) {
_neopixel_count += 1;
NEO_SCT->EV[NEO_EVENT_FALL_0].STATE = 0xFFFFFF & (~_neopixel_array[_neopixel_count]);
NEO_SCT->EVFLAG = eventFlag;
NEO_SCT->CTRL &= ~(SCT_CTRL_HALT_L_MASK);
} else {
NEO_SCT->EVFLAG = eventFlag;
}
}
void SCT0_DriverIRQHandler(void){
neopixel_int_handler();
SDK_ISR_EXIT_BARRIER;
}
void neopixel_update(uint32_t pixel, uint32_t color){
if (pixel < NEOPIXEL_NUMBER) {
_neopixel_array[pixel] = color;
_neopixel_count = 0;
// NEO_SCT->EV[NEO_EVENT_FALL_0].STATE = 0xFF & (~_neopixel_array[0]);
NEO_SCT->EV[NEO_EVENT_FALL_0].STATE = 0xFFFFFF & (~_neopixel_array[0]);
NEO_SCT->CTRL &= ~(SCT_CTRL_HALT_L_MASK);
}
}
*/
void neopixel_init(void) {
CLOCK_EnableClock(kCLOCK_Sct0);
RESET_PeripheralReset(kSCT0_RST_SHIFT_RSTn);
NEO_SCT->CONFIG = (
SCT_CONFIG_UNIFY(1) |
SCT_CONFIG_CLKMODE(kSCTIMER_System_ClockMode) |
SCT_CONFIG_NORELOAD_L(1) );
NEO_SCT->CTRL = (
SCT_CTRL_HALT_L(1) |
SCT_CTRL_CLRCTR_L(1) );
NEO_SCT->MATCH[NEO_MATCH_PERIOD] = 120;
NEO_SCT->MATCH[NEO_MATCH_0] = 30;
NEO_SCT->MATCH[NEO_MATCH_1] = 60;
NEO_SCT->EV[NEO_EVENT_START].STATE = (1 << NEO_STATE_IDLE);
NEO_SCT->EV[NEO_EVENT_START].CTRL = (
kSCTIMER_OutputLowEvent | SCT_EV_CTRL_IOSEL(NEO_SCT_OUTPUT) |
SCT_EV_CTRL_STATELD(1) | SCT_EV_CTRL_STATEV(23));
// NEO_SCT->EV[NEO_EVENT_RISE].STATE = 0xFE;
NEO_SCT->EV[NEO_EVENT_RISE].STATE = 0xFFFFFE;
NEO_SCT->EV[NEO_EVENT_RISE].CTRL = (
kSCTIMER_MatchEventOnly | SCT_EV_CTRL_MATCHSEL(NEO_MATCH_PERIOD) |
SCT_EV_CTRL_STATELD(0) | SCT_EV_CTRL_STATEV(31));
NEO_SCT->EV[NEO_EVENT_FALL_0].STATE = 0x0;
NEO_SCT->EV[NEO_EVENT_FALL_0].CTRL = (
kSCTIMER_MatchEventOnly | SCT_EV_CTRL_MATCHSEL(NEO_MATCH_0) |
SCT_EV_CTRL_STATELD(0) );
// NEO_SCT->EV[NEO_EVENT_FALL_1].STATE = 0xFF;
NEO_SCT->EV[NEO_EVENT_FALL_1].STATE = 0xFFFFFF;
NEO_SCT->EV[NEO_EVENT_FALL_1].CTRL = (
kSCTIMER_MatchEventOnly | SCT_EV_CTRL_MATCHSEL(NEO_MATCH_1) |
SCT_EV_CTRL_STATELD(0) );
NEO_SCT->EV[NEO_EVENT_NEXT].STATE = 0x1;
NEO_SCT->EV[NEO_EVENT_NEXT].CTRL = (
kSCTIMER_MatchEventOnly | SCT_EV_CTRL_MATCHSEL(NEO_MATCH_PERIOD) |
SCT_EV_CTRL_STATELD(1) | SCT_EV_CTRL_STATEV(NEO_STATE_IDLE));
NEO_SCT->LIMIT = (1 << NEO_EVENT_START) | (1 << NEO_EVENT_RISE) | (1 << NEO_EVENT_NEXT);
NEO_SCT->HALT = (1 << NEO_EVENT_NEXT);
NEO_SCT->START = (1 << NEO_EVENT_START);
NEO_SCT->OUT[NEO_SCT_OUTPUT].SET = (1 << NEO_EVENT_START) | (1 << NEO_EVENT_RISE);
NEO_SCT->OUT[NEO_SCT_OUTPUT].CLR = (1 << NEO_EVENT_FALL_0) | (1 << NEO_EVENT_FALL_1) | (1 << NEO_EVENT_NEXT);
NEO_SCT->STATE = NEO_STATE_IDLE;
NEO_SCT->OUTPUT = 0x0;
NEO_SCT->RES = SCT_RES_O6RES(0x2);
NEO_SCT->EVEN = (1 << NEO_EVENT_NEXT);
EnableIRQ(SCT0_IRQn);
neopixel_set(0, 0x101000);
neopixel_set(1, 0x101000);
neopixel_update();
}
/****************************************************************
name: BOARD_BootClockFROHF96M
outputs:
- {id: SYSTICK_clock.outFreq, value: 96 MHz}
- {id: System_clock.outFreq, value: 96 MHz}
settings:
- {id: SYSCON.MAINCLKSELA.sel, value: SYSCON.fro_hf}
sources:
- {id: SYSCON.fro_hf.outFreq, value: 96 MHz}
******************************************************************/
void BootClockFROHF96M(void)
{
/*!< Set up the clock sources */
/*!< Set up FRO */
POWER_DisablePD(kPDRUNCFG_PD_FRO192M); /*!< Ensure FRO is on */
CLOCK_SetupFROClocking(12000000U); /*!< Set up FRO to the 12 MHz, just for sure */
CLOCK_AttachClk(kFRO12M_to_MAIN_CLK); /*!< Switch to FRO 12MHz first to ensure we can change voltage without
accidentally being below the voltage for current speed */
CLOCK_SetupFROClocking(96000000U); /*!< Set up high frequency FRO output to selected frequency */
POWER_SetVoltageForFreq(96000000U); /*!< Set voltage for the one of the fastest clock outputs: System clock output */
CLOCK_SetFLASHAccessCyclesForFreq(96000000U); /*!< Set FLASH wait states for core */
/*!< Set up dividers */
CLOCK_SetClkDiv(kCLOCK_DivAhbClk, 1U, false); /*!< Set AHBCLKDIV divider to value 1 */
/*!< Set up clock selectors - Attach clocks to the peripheries */
CLOCK_AttachClk(kFRO_HF_to_MAIN_CLK); /*!< Switch MAIN_CLK to FRO_HF */
/*!< Set SystemCoreClock variable. */
SystemCoreClock = 96000000U;
}
void board_init(void)
{
// Enable IOCON clock
CLOCK_EnableClock(kCLOCK_Iocon);
// Init 96 MHz clock
BootClockFROHF96M();
#if CFG_TUSB_OS == OPT_OS_NONE
// 1ms tick timer
SysTick_Config(SystemCoreClock / 1000);
#elif CFG_TUSB_OS == OPT_OS_FREERTOS
// If freeRTOS is used, IRQ priority is limit by max syscall ( smaller is higher )
NVIC_SetPriority(USB0_IRQn, configLIBRARY_MAX_SYSCALL_INTERRUPT_PRIORITY );
#endif
GPIO_PortInit(GPIO, 0);
GPIO_PortInit(GPIO, 1);
// LED
/* PORT0 PIN1 configured as PIO0_1 */
IOCON_PinMuxSet(IOCON, 0U, 1U, IOCON_PIO_DIG_FUNC0_EN);
gpio_pin_config_t const led_config = { kGPIO_DigitalOutput, 1};
GPIO_PinInit(GPIO, LED_PORT, LED_PIN, &led_config);
// Neopixel
/* PORT0 PIN27 configured as SCT0_OUT6 */
IOCON_PinMuxSet(IOCON, NEOPIXEL_PORT, NEOPIXEL_PIN, IOCON_PIO_DIG_FUNC4_EN);
neopixel_init();
// Button
/* PORT0 PIN5 configured as PIO0_5 */
IOCON_PinMuxSet(IOCON, BUTTON_PORT, BUTTON_PIN, IOCON_PIO_DIG_FUNC0_EN);
gpio_pin_config_t const button_config = { kGPIO_DigitalInput, 0};
GPIO_PinInit(GPIO, BUTTON_PORT, BUTTON_PIN, &button_config);
// UART
/* PORT0 PIN29 (coords: 92) is configured as FC0_RXD_SDA_MOSI_DATA */
IOCON_PinMuxSet(IOCON, 0U, 29U, IOCON_PIO_DIG_FUNC1_EN);
/* PORT0 PIN30 (coords: 94) is configured as FC0_TXD_SCL_MISO_WS */
IOCON_PinMuxSet(IOCON, 0U, 30U, IOCON_PIO_DIG_FUNC1_EN);
#if defined(UART_DEV) && CFG_TUSB_DEBUG
// Enable UART when debug log is on
CLOCK_AttachClk(kFRO12M_to_FLEXCOMM0);
usart_config_t uart_config;
USART_GetDefaultConfig(&uart_config);
uart_config.baudRate_Bps = BOARD_UART_BAUDRATE;
uart_config.enableTx = true;
uart_config.enableRx = true;
USART_Init(UART_DEV, &uart_config, 12000000);
#endif
// USB VBUS
/* PORT0 PIN22 configured as USB0_VBUS */
IOCON_PinMuxSet(IOCON, 0U, 22U, IOCON_PIO_DIG_FUNC7_EN);
// USB Controller
POWER_DisablePD(kPDRUNCFG_PD_USB0_PHY); /*Turn on USB0 Phy */
POWER_DisablePD(kPDRUNCFG_PD_USB1_PHY); /*< Turn on USB1 Phy */
/* reset the IP to make sure it's in reset state. */
RESET_PeripheralReset(kUSB0D_RST_SHIFT_RSTn);
RESET_PeripheralReset(kUSB0HSL_RST_SHIFT_RSTn);
RESET_PeripheralReset(kUSB0HMR_RST_SHIFT_RSTn);
RESET_PeripheralReset(kUSB1H_RST_SHIFT_RSTn);
RESET_PeripheralReset(kUSB1D_RST_SHIFT_RSTn);
RESET_PeripheralReset(kUSB1_RST_SHIFT_RSTn);
RESET_PeripheralReset(kUSB1RAM_RST_SHIFT_RSTn);
#if (defined CFG_TUSB_RHPORT1_MODE) && (CFG_TUSB_RHPORT1_MODE & OPT_MODE_DEVICE)
CLOCK_EnableClock(kCLOCK_Usbh1);
/* Put PHY powerdown under software control */
USBHSH->PORTMODE = USBHSH_PORTMODE_SW_PDCOM_MASK;
/* According to reference mannual, device mode setting has to be set by access usb host register */
USBHSH->PORTMODE |= USBHSH_PORTMODE_DEV_ENABLE_MASK;
/* enable usb1 host clock */
CLOCK_DisableClock(kCLOCK_Usbh1);
#endif
#if (defined CFG_TUSB_RHPORT0_MODE) && (CFG_TUSB_RHPORT0_MODE & OPT_MODE_DEVICE)
// Enable USB Clock Adjustments to trim the FRO for the full speed controller
ANACTRL->FRO192M_CTRL |= ANACTRL_FRO192M_CTRL_USBCLKADJ_MASK;
CLOCK_SetClkDiv(kCLOCK_DivUsb0Clk, 1, false);
CLOCK_AttachClk(kFRO_HF_to_USB0_CLK);
/* enable usb0 host clock */
CLOCK_EnableClock(kCLOCK_Usbhsl0);
/*According to reference mannual, device mode setting has to be set by access usb host register */
USBFSH->PORTMODE |= USBFSH_PORTMODE_DEV_ENABLE_MASK;
/* disable usb0 host clock */
CLOCK_DisableClock(kCLOCK_Usbhsl0);
CLOCK_EnableUsbfs0DeviceClock(kCLOCK_UsbfsSrcFro, CLOCK_GetFreq(kCLOCK_FroHf)); /* enable USB Device clock */
#endif
}
//--------------------------------------------------------------------+
// Board porting API
//--------------------------------------------------------------------+
void board_led_write(bool state)
{
GPIO_PinWrite(GPIO, LED_PORT, LED_PIN, state ? LED_STATE_ON : (1-LED_STATE_ON));
if (state) {
neopixel_set(0, 0x100000);
neopixel_set(1, 0x101010);
} else {
neopixel_set(0, 0x001000);
neopixel_set(1, 0x000010);
}
neopixel_update();
}
uint32_t board_button_read(void)
{
// active low
return BUTTON_STATE_ACTIVE == GPIO_PinRead(GPIO, BUTTON_PORT, BUTTON_PIN);
}
int board_uart_read(uint8_t* buf, int len)
{
(void) buf; (void) len;
return 0;
}
int board_uart_write(void const * buf, int len)
{
(void) buf; (void) len;
return 0;
}
#if CFG_TUSB_OS == OPT_OS_NONE
volatile uint32_t system_ticks = 0;
void SysTick_Handler(void)
{
system_ticks++;
}
uint32_t board_millis(void)
{
return system_ticks;
}
#endif

2
src/class/hid/hid_device.h
View File

@ -46,7 +46,7 @@
#endif
#ifndef CFG_TUD_HID_EP_BUFSIZE
#define CFG_TUD_HID_EP_BUFSIZE 16
#define CFG_TUD_HID_EP_BUFSIZE 64
#endif
//--------------------------------------------------------------------+

18
src/device/usbd.c
View File

@ -1103,6 +1103,24 @@ bool usbd_edpt_open(uint8_t rhport, tusb_desc_endpoint_t const * desc_ep)
{
TU_LOG2(" Open EP %02X with Size = %u\r\n", desc_ep->bEndpointAddress, desc_ep->wMaxPacketSize.size);
if (TUSB_XFER_ISOCHRONOUS == desc_ep->bmAttributes.xfer)
{
TU_ASSERT(desc_ep->wMaxPacketSize.size <= (_usbd_dev.speed == TUSB_SPEED_HIGH ? 1024 : 1023));
}
else
{
uint16_t const max_epsize = (_usbd_dev.speed == TUSB_SPEED_HIGH ? 512 : 64);
if (TUSB_XFER_BULK == desc_ep->bmAttributes.xfer)
{
// Bulk must be EXACTLY 512/64 bytes
TU_ASSERT(desc_ep->wMaxPacketSize.size == max_epsize);
}else
{
TU_ASSERT(desc_ep->wMaxPacketSize.size <= max_epsize);
}
}
return dcd_edpt_open(rhport, desc_ep);
}

7
src/portable/dialog/da146xx/dcd_da146xx.c
View File

@ -664,7 +664,7 @@ static void handle_bus_reset(void)
(void)USB->USB_ALTEV_REG;
_dcd.in_reset = true;
dcd_event_bus_signal(0, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(0, TUSB_SPEED_FULL, true);
USB->USB_DMA_CTRL_REG = 0;
USB->USB_MAMSK_REG = USB_USB_MAMSK_REG_USB_M_INTR_Msk |
@ -821,14 +821,13 @@ void dcd_disconnect(uint8_t rhport)
bool dcd_edpt_open(uint8_t rhport, tusb_desc_endpoint_t const * desc_edpt)
{
(void)rhport;
uint8_t const epnum = tu_edpt_number(desc_edpt->bEndpointAddress);
uint8_t const dir = tu_edpt_dir(desc_edpt->bEndpointAddress);
xfer_ctl_t * xfer = XFER_CTL_BASE(epnum, dir);
uint8_t iso_mask = 0;
(void)rhport;
TU_ASSERT(desc_edpt->wMaxPacketSize.size <= 1023);
TU_ASSERT(epnum < EP_MAX);
xfer->max_packet_size = desc_edpt->wMaxPacketSize.size;

1
src/portable/espressif/esp32s2/dcd_esp32s2.c
View File

@ -252,7 +252,6 @@ bool dcd_edpt_open(uint8_t rhport, tusb_desc_endpoint_t const *desc_edpt)
uint8_t const epnum = tu_edpt_number(desc_edpt->bEndpointAddress);
uint8_t const dir = tu_edpt_dir(desc_edpt->bEndpointAddress);
TU_ASSERT(desc_edpt->wMaxPacketSize.size <= 64);
TU_ASSERT(epnum < EP_MAX);
xfer_ctl_t *xfer = XFER_CTL_BASE(epnum, dir);

15
src/portable/microchip/samd/dcd_samd.c
View File

@ -37,14 +37,23 @@
/* MACRO TYPEDEF CONSTANT ENUM
*------------------------------------------------------------------*/
static TU_ATTR_ALIGNED(4) UsbDeviceDescBank sram_registers[8][2];
static TU_ATTR_ALIGNED(4) uint8_t _setup_packet[8];
// Setup packet is only 8 bytes in length. However under certain scenario,
// USB DMA controller may decide to overwrite/overflow the buffer with
// 2 extra bytes of CRC. From datasheet's "Management of SETUP Transactions" section
// If the number of received data bytes is the maximum data payload specified by
// PCKSIZE.SIZE minus one, only the first CRC data is written to the data buffer.
// If the number of received data is equal or less than the data payload specified
// by PCKSIZE.SIZE minus two, both CRC data bytes are written to the data buffer.
// Therefore we will need to increase it to 10 bytes here.
static TU_ATTR_ALIGNED(4) uint8_t _setup_packet[8+2];
// ready for receiving SETUP packet
static inline void prepare_setup(void)
{
// Only make sure the EP0 OUT buffer is ready
sram_registers[0][0].ADDR.reg = (uint32_t) _setup_packet;
sram_registers[0][0].PCKSIZE.bit.MULTI_PACKET_SIZE = sizeof(_setup_packet);
sram_registers[0][0].PCKSIZE.bit.MULTI_PACKET_SIZE = sizeof(tusb_control_request_t);
sram_registers[0][0].PCKSIZE.bit.BYTE_COUNT = 0;
}
@ -378,7 +387,7 @@ void dcd_int_handler (uint8_t rhport)
USB->DEVICE.INTENCLR.reg = USB_DEVICE_INTFLAG_WAKEUP | USB_DEVICE_INTFLAG_SUSPEND;
bus_reset();
dcd_event_bus_signal(0, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(0, TUSB_SPEED_FULL, true);
}
// Handle SETUP packet

2
src/portable/microchip/samg/dcd_samg.c
View File

@ -338,7 +338,7 @@ void dcd_int_handler(uint8_t rhport)
if (intr_status & UDP_ISR_ENDBUSRES_Msk)
{
bus_reset();
dcd_event_bus_signal(rhport, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(rhport, TUSB_SPEED_FULL, true);
}
// SOF

2
src/portable/nordic/nrf5x/dcd_nrf5x.c
View File

@ -533,7 +533,7 @@ void dcd_int_handler(uint8_t rhport)
if ( int_status & USBD_INTEN_USBRESET_Msk )
{
bus_reset();
dcd_event_bus_signal(0, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(0, TUSB_SPEED_FULL, true);
}
// ISOIN: Data was moved to endpoint buffer, client will be notified in SOF

3
src/portable/nuvoton/nuc120/dcd_nuc120.c
View File

@ -329,8 +329,7 @@ void dcd_int_handler(uint8_t rhport)
USBD->ATTR |= USBD_ATTR_USB_EN_Msk | USBD_ATTR_PHY_EN_Msk;
bus_reset();
dcd_event_bus_signal(0, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(0, TUSB_SPEED_FULL, true);
}
if(state & USBD_STATE_SUSPEND)

2
src/portable/nuvoton/nuc121/dcd_nuc121.c
View File

@ -340,7 +340,7 @@ void dcd_int_handler(uint8_t rhport)
bus_reset();
dcd_event_bus_signal(0, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(0, TUSB_SPEED_FULL, true);
}
if(state & USBD_ATTR_SUSPEND_Msk)

2
src/portable/nxp/khci/dcd_khci.c
View File

@ -224,7 +224,7 @@ static void process_bus_reset(uint8_t rhport)
_dcd.addr = 0;
prepare_next_setup_packet(rhport);
KHCI->CTL &= ~USB_CTL_ODDRST_MASK;
dcd_event_bus_signal(rhport, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(rhport, TUSB_SPEED_FULL, true);
}
static void process_bus_inactive(uint8_t rhport)

2
src/portable/nxp/lpc17_40/dcd_lpc17_40.c
View File

@ -471,7 +471,7 @@ static void bus_event_isr(uint8_t rhport)
if (dev_status & SIE_DEV_STATUS_RESET_MASK)
{
bus_reset();
dcd_event_bus_signal(rhport, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(rhport, TUSB_SPEED_FULL, true);
}
if (dev_status & SIE_DEV_STATUS_CONNECT_CHANGE_MASK)

4
src/portable/nxp/lpc_ip3511/dcd_lpc_ip3511.c
View File

@ -243,7 +243,7 @@ bool dcd_edpt_open(uint8_t rhport, tusb_desc_endpoint_t const * p_endpoint_desc)
(void) rhport;
// TODO not support ISO yet
if (p_endpoint_desc->bmAttributes.xfer == TUSB_XFER_ISOCHRONOUS) return false;
TU_VERIFY(p_endpoint_desc->bmAttributes.xfer != TUSB_XFER_ISOCHRONOUS);
//------------- Prepare Queue Head -------------//
uint8_t ep_id = ep_addr2id(p_endpoint_desc->bEndpointAddress);
@ -357,7 +357,7 @@ void dcd_int_handler(uint8_t rhport)
if ( cmd_stat & CMDSTAT_RESET_CHANGE_MASK) // bus reset
{
bus_reset();
dcd_event_bus_signal(0, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(0, TUSB_SPEED_FULL, true);
}
if (cmd_stat & CMDSTAT_CONNECT_CHANGE_MASK)

2
src/portable/st/stm32_fsdev/dcd_stm32_fsdev.c
View File

@ -547,7 +547,7 @@ void dcd_int_handler(uint8_t rhport) {
// USBRST is start of reset.
clear_istr_bits(USB_ISTR_RESET);
dcd_handle_bus_reset();
dcd_event_bus_signal(0, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(0, TUSB_SPEED_FULL, true);
return; // Don't do the rest of the things here; perhaps they've been cleared?
}

215
src/portable/st/synopsys/dcd_synopsys.c
View File

@ -46,13 +46,13 @@
#define STM32L4_SYNOPSYS
#endif
#if TUSB_OPT_DEVICE_ENABLED && \
#if TUSB_OPT_DEVICE_ENABLED && \
( (CFG_TUSB_MCU == OPT_MCU_STM32F1 && defined(STM32F1_SYNOPSYS)) || \
CFG_TUSB_MCU == OPT_MCU_STM32F2 || \
CFG_TUSB_MCU == OPT_MCU_STM32F4 || \
CFG_TUSB_MCU == OPT_MCU_STM32F7 || \
CFG_TUSB_MCU == OPT_MCU_STM32H7 || \
(CFG_TUSB_MCU == OPT_MCU_STM32L4 && defined(STM32L4_SYNOPSYS)) \
CFG_TUSB_MCU == OPT_MCU_STM32F2 || \
CFG_TUSB_MCU == OPT_MCU_STM32F4 || \
CFG_TUSB_MCU == OPT_MCU_STM32F7 || \
CFG_TUSB_MCU == OPT_MCU_STM32H7 || \
(CFG_TUSB_MCU == OPT_MCU_STM32L4 && defined(STM32L4_SYNOPSYS)) \
)
// EP_MAX : Max number of bi-directional endpoints including EP0
@ -116,6 +116,7 @@
#define EP_FIFO_SIZE EP_FIFO_SIZE_HS
#define RHPORT_REGS_BASE USB_OTG_HS_PERIPH_BASE
#define RHPORT_IRQn OTG_HS_IRQn
#endif
#define GLOBAL_BASE(_port) ((USB_OTG_GlobalTypeDef*) RHPORT_REGS_BASE)
@ -141,25 +142,40 @@ typedef struct {
uint8_t interval;
} xfer_ctl_t;
// EP size and transfer type report
typedef struct TU_ATTR_PACKED {
// The following format may look complicated but it is the most elegant way of addressing the required fields: EP number, EP direction, and EP transfer type.
// The codes assigned to those fields, according to the USB specification, can be neatly used as indices.
uint16_t ep_size[EP_MAX][2]; ///< dim 1: EP number, dim 2: EP direction denoted by TUSB_DIR_OUT (= 0) and TUSB_DIR_IN (= 1)
bool ep_transfer_type[EP_MAX][2][4]; ///< dim 1: EP number, dim 2: EP direction, dim 3: transfer type, where 0 = Control, 1 = Isochronous, 2 = Bulk, and 3 = Interrupt
///< I know very well that EP0 can only be used as control EP and we waste space here but for the sake of simplicity we accept that. It is used in a non-persistent way anyway!
} ep_sz_tt_report_t;
typedef volatile uint32_t * usb_fifo_t;
xfer_ctl_t xfer_status[EP_MAX][2];
#define XFER_CTL_BASE(_ep, _dir) &xfer_status[_ep][_dir]
// EP0 transfers are limited to 1 packet - larger sizes has to be split
static uint16_t ep0_pending[2]; // Index determines direction as tusb_dir_t type
static uint16_t ep0_pending[2]; // Index determines direction as tusb_dir_t type
// FIFO RAM allocation so far in words
static uint16_t _allocated_fifo_words;
// TX FIFO RAM allocation so far in words - RX FIFO size is readily available from usb_otg->GRXFSIZ
static uint16_t _allocated_fifo_words_tx; // TX FIFO size in words (IN EPs)
static bool _out_ep_closed; // Flag to check if RX FIFO size needs an update (reduce its size)
// Calculate the RX FIFO size according to recommendations from reference manual
static inline uint16_t calc_rx_ff_size(uint16_t ep_size)
{
return 15 + 2*(ep_size/4) + 2*EP_MAX;
}
static void update_grxfsiz(uint8_t rhport)
{
(void) rhport;
USB_OTG_GlobalTypeDef * usb_otg = GLOBAL_BASE(rhport);
// Determine largest EP size for RX FIFO
uint16_t max_epsize = 0;
for (uint8_t epnum = 0; epnum < EP_MAX; epnum++)
{
max_epsize = tu_max16(max_epsize, xfer_status[epnum][TUSB_DIR_OUT].max_size);
}
// Update size of RX FIFO
usb_otg->GRXFSIZ = calc_rx_ff_size(max_epsize);
}
// Setup the control endpoint 0.
static void bus_reset(uint8_t rhport)
@ -172,6 +188,7 @@ static void bus_reset(uint8_t rhport)
USB_OTG_INEndpointTypeDef * in_ep = IN_EP_BASE(rhport);
tu_memclr(xfer_status, sizeof(xfer_status));
_out_ep_closed = false;
for(uint8_t n = 0; n < EP_MAX; n++) {
out_ep[n].DOEPCTL |= USB_OTG_DOEPCTL_SNAK;
@ -184,16 +201,28 @@ static void bus_reset(uint8_t rhport)
// "USB Data FIFOs" section in reference manual
// Peripheral FIFO architecture
//
// The FIFO is split up in a lower part where the RX FIFO is located and an upper part where the TX FIFOs start.
// We do this to allow the RX FIFO to grow dynamically which is possible since the free space is located
// between the RX and TX FIFOs. This is required by ISO OUT EPs which need a bigger FIFO than the standard
// configuration done below.
//
// Dynamically FIFO sizes are of interest only for ISO EPs since all others are usually not opened and closed.
// All EPs other than ISO are opened as soon as the driver starts up i.e. when the host sends a
// configure interface command. Hence, all IN EPs other the ISO will be located at the top. IN ISO EPs are usually
// opened when the host sends an additional command: setInterface. At this point in time
// the ISO EP will be located next to the free space and can change its size. In case more IN EPs change its size
// an additional memory
//
// --------------- 320 or 1024 ( 1280 or 4096 bytes )
// | IN FIFO 0 |
// --------------- (320 or 1024) - 16
// | IN FIFO 1 |
// --------------- (320 or 1024) - 16 - x
// | . . . . |
// --------------- (320 or 1024) - 16 - x - y - ... - z
// | IN FIFO MAX |
// ---------------
// | ... |
// --------------- y + x + 16 + GRXFSIZ
// | IN FIFO 2 |
// --------------- x + 16 + GRXFSIZ
// | IN FIFO 1 |
// --------------- 16 + GRXFSIZ
// | IN FIFO 0 |
// | FREE |
// --------------- GRXFSIZ
// | OUT FIFO |
// | ( Shared ) |
@ -215,24 +244,16 @@ static void bus_reset(uint8_t rhport)
// NOTE: Largest-EPsize & EPOUTnum is actual used endpoints in configuration. Since DCD has no knowledge
// of the overall picture yet. We will use the worst scenario: largest possible + EP_MAX
//
// FIXME: for Isochronous, largest EP size can be 1023/1024 for FS/HS respectively. In addition if multiple ISO
// For Isochronous, largest EP size can be 1023/1024 for FS/HS respectively. In addition if multiple ISO
// are enabled at least "2 x (Largest-EPsize/4) + 1" are recommended. Maybe provide a macro for application to
// overwrite this.
#if TUD_OPT_HIGH_SPEED
_allocated_fifo_words = 271 + 2*EP_MAX;
#else
_allocated_fifo_words = 47 + 2*EP_MAX;
#endif
usb_otg->GRXFSIZ = calc_rx_ff_size(TUD_OPT_HIGH_SPEED ? 512 : 64);
usb_otg->GRXFSIZ = _allocated_fifo_words;
_allocated_fifo_words_tx = 16;
// Control IN uses FIFO 0 with 64 bytes ( 16 32-bit word )
usb_otg->DIEPTXF0_HNPTXFSIZ = (16 << USB_OTG_TX0FD_Pos) | _allocated_fifo_words;
_allocated_fifo_words += 16;
// TU_LOG2_INT(_allocated_fifo_words);
usb_otg->DIEPTXF0_HNPTXFSIZ = (16 << USB_OTG_TX0FD_Pos) | (EP_FIFO_SIZE/4 - _allocated_fifo_words_tx);
// Fixed control EP0 size to 64 bytes
in_ep[0].DIEPCTL &= ~(0x03 << USB_OTG_DIEPCTL_MPSIZ_Pos);
@ -536,6 +557,8 @@ void dcd_disconnect(uint8_t rhport)
bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * desc_edpt)
{
(void) rhport;
USB_OTG_GlobalTypeDef * usb_otg = GLOBAL_BASE(rhport);
USB_OTG_DeviceTypeDef * dev = DEVICE_BASE(rhport);
USB_OTG_OUTEndpointTypeDef * out_ep = OUT_EP_BASE(rhport);
@ -546,21 +569,26 @@ bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * desc_edpt)
TU_ASSERT(epnum < EP_MAX);
if (desc_edpt->bmAttributes.xfer == TUSB_XFER_ISOCHRONOUS)
{
TU_ASSERT(desc_edpt->wMaxPacketSize.size <= (get_speed(rhport) == TUSB_SPEED_HIGH ? 1024 : 1023));
}
else
{
TU_ASSERT(desc_edpt->wMaxPacketSize.size <= (get_speed(rhport) == TUSB_SPEED_HIGH ? 512 : 64));
}
xfer_ctl_t * xfer = XFER_CTL_BASE(epnum, dir);
xfer->max_size = desc_edpt->wMaxPacketSize.size;
xfer->interval = desc_edpt->bInterval;
uint16_t const fifo_size = (desc_edpt->wMaxPacketSize.size + 3) / 4; // Round up to next full word
if(dir == TUSB_DIR_OUT)
{
// Calculate required size of RX FIFO
uint16_t const sz = calc_rx_ff_size(4*fifo_size);
// If size_rx needs to be extended check if possible and if so enlarge it
if (usb_otg->GRXFSIZ < sz)
{
TU_ASSERT(sz + _allocated_fifo_words_tx <= EP_FIFO_SIZE/4);
// Enlarge RX FIFO
usb_otg->GRXFSIZ = sz;
}
out_ep[epnum].DOEPCTL |= (1 << USB_OTG_DOEPCTL_USBAEP_Pos) |
(desc_edpt->bmAttributes.xfer << USB_OTG_DOEPCTL_EPTYP_Pos) |
(desc_edpt->wMaxPacketSize.size << USB_OTG_DOEPCTL_MPSIZ_Pos);
@ -573,15 +601,15 @@ bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * desc_edpt)
// Peripheral FIFO architecture
//
// --------------- 320 or 1024 ( 1280 or 4096 bytes )
// | IN FIFO 0 |
// --------------- (320 or 1024) - 16
// | IN FIFO 1 |
// --------------- (320 or 1024) - 16 - x
// | . . . . |
// --------------- (320 or 1024) - 16 - x - y - ... - z
// | IN FIFO MAX |
// ---------------
// | ... |
// --------------- y + x + 16 + GRXFSIZ
// | IN FIFO 2 |
// --------------- x + 16 + GRXFSIZ
// | IN FIFO 1 |
// --------------- 16 + GRXFSIZ
// | IN FIFO 0 |
// | FREE |
// --------------- GRXFSIZ
// | OUT FIFO |
// | ( Shared ) |
@ -589,34 +617,15 @@ bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * desc_edpt)
//
// In FIFO is allocated by following rules:
// - IN EP 1 gets FIFO 1, IN EP "n" gets FIFO "n".
// - Offset: allocated so far
// - Size
// - Interrupt is EPSize
// - Bulk/ISO is max(EPSize, remaining-fifo / non-opened-EPIN)
uint16_t const fifo_remaining = EP_FIFO_SIZE/4 - _allocated_fifo_words;
uint16_t fifo_size = (desc_edpt->wMaxPacketSize.size + 3) / 4; // +3 for rounding up to next full word
// Check if free space is available
TU_ASSERT(_allocated_fifo_words_tx + fifo_size + usb_otg->GRXFSIZ <= EP_FIFO_SIZE/4);
if ( desc_edpt->bmAttributes.xfer != TUSB_XFER_INTERRUPT )
{
uint8_t opened = 0;
for(uint8_t i = 0; i < EP_MAX; i++)
{
if ( (i != epnum) && (xfer_status[i][TUSB_DIR_IN].max_size > 0) ) opened++;
}
// EP Size or equally divided of remaining whichever is larger
fifo_size = tu_max16(fifo_size, fifo_remaining / (EP_MAX - opened));
}
// FIFO overflows, we probably need a better allocating scheme
TU_ASSERT(fifo_size <= fifo_remaining);
_allocated_fifo_words_tx += fifo_size;
// DIEPTXF starts at FIFO #1.
// Both TXFD and TXSA are in unit of 32-bit words.
usb_otg->DIEPTXF[epnum - 1] = (fifo_size << USB_OTG_DIEPTXF_INEPTXFD_Pos) | _allocated_fifo_words;
_allocated_fifo_words += fifo_size;
usb_otg->DIEPTXF[epnum - 1] = (fifo_size << USB_OTG_DIEPTXF_INEPTXFD_Pos) | (EP_FIFO_SIZE/4 - _allocated_fifo_words_tx);
in_ep[epnum].DIEPCTL |= (1 << USB_OTG_DIEPCTL_USBAEP_Pos) |
(epnum << USB_OTG_DIEPCTL_TXFNUM_Pos) |
@ -758,13 +767,21 @@ void dcd_edpt_close (uint8_t rhport, uint8_t ep_addr)
uint8_t const dir = tu_edpt_dir(ep_addr);
dcd_edpt_disable(rhport, ep_addr, false);
// Update max_size
xfer_status[epnum][dir].max_size = 0; // max_size = 0 marks a disabled EP - required for changing FIFO allocation
if (dir == TUSB_DIR_IN)
{
uint16_t const fifo_size = (usb_otg->DIEPTXF[epnum - 1] & USB_OTG_DIEPTXF_INEPTXFD_Msk) >> USB_OTG_DIEPTXF_INEPTXFD_Pos;
uint16_t const fifo_start = (usb_otg->DIEPTXF[epnum - 1] & USB_OTG_DIEPTXF_INEPTXSA_Msk) >> USB_OTG_DIEPTXF_INEPTXSA_Pos;
// For now only endpoint that has FIFO at the end of FIFO memory can be closed without fuss.
TU_ASSERT(fifo_start + fifo_size == _allocated_fifo_words,);
_allocated_fifo_words -= fifo_size;
// For now only the last opened endpoint can be closed without fuss.
TU_ASSERT(fifo_start == EP_FIFO_SIZE/4 - _allocated_fifo_words_tx,);
_allocated_fifo_words_tx -= fifo_size;
}
else
{
_out_ep_closed = true; // Set flag such that RX FIFO gets reduced in size once RX FIFO is empty
}
}
@ -1025,13 +1042,15 @@ void dcd_int_handler(uint8_t rhport)
uint32_t int_status = usb_otg->GINTSTS;
if(int_status & USB_OTG_GINTSTS_USBRST) {
if(int_status & USB_OTG_GINTSTS_USBRST)
{
// USBRST is start of reset.
usb_otg->GINTSTS = USB_OTG_GINTSTS_USBRST;
bus_reset(rhport);
}
if(int_status & USB_OTG_GINTSTS_ENUMDNE) {
if(int_status & USB_OTG_GINTSTS_ENUMDNE)
{
// ENUMDNE is the end of reset where speed of the link is detected
usb_otg->GINTSTS = USB_OTG_GINTSTS_ENUMDNE;
@ -1068,45 +1087,59 @@ void dcd_int_handler(uint8_t rhport)
}
#if USE_SOF
if(int_status & USB_OTG_GINTSTS_SOF) {
if(int_status & USB_OTG_GINTSTS_SOF)
{
usb_otg->GINTSTS = USB_OTG_GINTSTS_SOF;
dcd_event_bus_signal(rhport, DCD_EVENT_SOF, true);
}
#endif
// RxFIFO non-empty interrupt handling.
if(int_status & USB_OTG_GINTSTS_RXFLVL) {
if(int_status & USB_OTG_GINTSTS_RXFLVL)
{
// RXFLVL bit is read-only
// Mask out RXFLVL while reading data from FIFO
usb_otg->GINTMSK &= ~USB_OTG_GINTMSK_RXFLVLM;
// Loop until all available packets were handled
do {
do
{
handle_rxflvl_ints(rhport, out_ep);
int_status = usb_otg->GINTSTS;
} while(int_status & USB_OTG_GINTSTS_RXFLVL);
// Manage RX FIFO size
if (_out_ep_closed)
{
update_grxfsiz(rhport);
// Disable flag
_out_ep_closed = false;
}
usb_otg->GINTMSK |= USB_OTG_GINTMSK_RXFLVLM;
}
// OUT endpoint interrupt handling.
if(int_status & USB_OTG_GINTSTS_OEPINT) {
if(int_status & USB_OTG_GINTSTS_OEPINT)
{
// OEPINT is read-only
handle_epout_ints(rhport, dev, out_ep);
}
// IN endpoint interrupt handling.
if(int_status & USB_OTG_GINTSTS_IEPINT) {
if(int_status & USB_OTG_GINTSTS_IEPINT)
{
// IEPINT bit read-only
handle_epin_ints(rhport, dev, in_ep);
}
// // Check for Incomplete isochronous IN transfer
// if(int_status & USB_OTG_GINTSTS_IISOIXFR) {
// printf(" IISOIXFR!\r\n");
//// TU_LOG2(" IISOIXFR!\r\n");
// }
// // Check for Incomplete isochronous IN transfer
// if(int_status & USB_OTG_GINTSTS_IISOIXFR) {
// printf(" IISOIXFR!\r\n");
//// TU_LOG2(" IISOIXFR!\r\n");
// }
}
#endif

6
src/portable/ti/msp430x5xx/dcd_msp430x5xx.c
View File

@ -232,9 +232,9 @@ bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * desc_edpt)
uint8_t const epnum = tu_edpt_number(desc_edpt->bEndpointAddress);
uint8_t const dir = tu_edpt_dir(desc_edpt->bEndpointAddress);
// Unsupported endpoint numbers/size or type (Iso not supported. Control
// Unsupported endpoint numbers or type (Iso not supported. Control
// not supported on nonzero endpoints).
if((desc_edpt->wMaxPacketSize.size > 64) || (epnum > 7) || \
if( (epnum > 7) || \
(desc_edpt->bmAttributes.xfer == 0) || \
(desc_edpt->bmAttributes.xfer == 1)) {
return false;
@ -572,7 +572,7 @@ void dcd_int_handler(uint8_t rhport)
{
case USBVECINT_RSTR:
bus_reset();
dcd_event_bus_signal(0, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(0, TUSB_SPEED_FULL, true);
break;
// Clear the (hardware-enforced) NAK on EP 0 after a SETUP packet

2
src/portable/valentyusb/eptri/dcd_eptri.c
View File

@ -332,7 +332,7 @@ static void dcd_reset(void)
usb_out_ev_enable_write(1);
usb_setup_ev_enable_write(3);
dcd_event_bus_signal(0, DCD_EVENT_BUS_RESET, true);
dcd_event_bus_reset(0, TUSB_SPEED_FULL, true);
}
// Initializes the USB peripheral for device mode and enables it.

12
src/tusb_option.h
View File

@ -151,22 +151,22 @@
#define CFG_TUSB_RHPORT1_MODE OPT_MODE_NONE
#endif
#if ((CFG_TUSB_RHPORT0_MODE & OPT_MODE_HOST ) && (CFG_TUSB_RHPORT1_MODE & OPT_MODE_HOST )) || \
((CFG_TUSB_RHPORT0_MODE & OPT_MODE_DEVICE) && (CFG_TUSB_RHPORT1_MODE & OPT_MODE_DEVICE))
#if (((CFG_TUSB_RHPORT0_MODE) & OPT_MODE_HOST ) && ((CFG_TUSB_RHPORT1_MODE) & OPT_MODE_HOST )) || \
(((CFG_TUSB_RHPORT0_MODE) & OPT_MODE_DEVICE) && ((CFG_TUSB_RHPORT1_MODE) & OPT_MODE_DEVICE))
#error "TinyUSB currently does not support same modes on more than 1 roothub port"
#endif
// Which roothub port is configured as host
#define TUH_OPT_RHPORT ( (CFG_TUSB_RHPORT0_MODE & OPT_MODE_HOST) ? 0 : ((CFG_TUSB_RHPORT1_MODE & OPT_MODE_HOST) ? 1 : -1) )
#define TUH_OPT_RHPORT ( ((CFG_TUSB_RHPORT0_MODE) & OPT_MODE_HOST) ? 0 : (((CFG_TUSB_RHPORT1_MODE) & OPT_MODE_HOST) ? 1 : -1) )
#define TUSB_OPT_HOST_ENABLED ( TUH_OPT_RHPORT >= 0 )
// Which roothub port is configured as device
#define TUD_OPT_RHPORT ( (CFG_TUSB_RHPORT0_MODE & OPT_MODE_DEVICE) ? 0 : ((CFG_TUSB_RHPORT1_MODE & OPT_MODE_DEVICE) ? 1 : -1) )
#define TUD_OPT_RHPORT ( ((CFG_TUSB_RHPORT0_MODE) & OPT_MODE_DEVICE) ? 0 : (((CFG_TUSB_RHPORT1_MODE) & OPT_MODE_DEVICE) ? 1 : -1) )
#if TUD_OPT_RHPORT == 0
#define TUD_OPT_HIGH_SPEED ( CFG_TUSB_RHPORT0_MODE & OPT_MODE_HIGH_SPEED )
#define TUD_OPT_HIGH_SPEED ( (CFG_TUSB_RHPORT0_MODE) & OPT_MODE_HIGH_SPEED )
#else
#define TUD_OPT_HIGH_SPEED ( CFG_TUSB_RHPORT1_MODE & OPT_MODE_HIGH_SPEED )
#define TUD_OPT_HIGH_SPEED ( (CFG_TUSB_RHPORT1_MODE) & OPT_MODE_HIGH_SPEED )
#endif
#define TUSB_OPT_DEVICE_ENABLED ( TUD_OPT_RHPORT >= 0 )

2
test/test/device/msc/test_msc_device.c
View File

@ -202,7 +202,7 @@ void setUp(void)
tusb_init();
}
dcd_event_bus_signal(rhport, DCD_EVENT_BUS_RESET, false);
dcd_event_bus_reset(rhport, TUSB_SPEED_HIGH, false);
tud_task();
}

6
test/test/support/tusb_config.h
View File

@ -86,8 +86,8 @@
//------------- CDC -------------//
// FIFO size of CDC TX and RX
#define CFG_TUD_CDC_RX_BUFSIZE 64
#define CFG_TUD_CDC_TX_BUFSIZE 64
#define CFG_TUD_CDC_RX_BUFSIZE 512
#define CFG_TUD_CDC_TX_BUFSIZE 512
//------------- MSC -------------//
@ -97,7 +97,7 @@
//------------- HID -------------//
// Should be sufficient to hold ID (if any) + Data
#define CFG_TUD_HID_EP_BUFSIZE 16
#define CFG_TUD_HID_EP_BUFSIZE 64
#ifdef __cplusplus
}