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Merge branch 'master' into develop

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This commit is contained in:
hathach 2019-12-24 21:13:05 +07:00
commit 2caa1ac078
29 changed files with 1452 additions and 98 deletions
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6
.gitmodules vendored
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@ -1,9 +1,6 @@
[submodule "hw/mcu/nordic/nrfx"]
path = hw/mcu/nordic/nrfx
url = https://github.com/NordicSemiconductor/nrfx.git
[submodule "hw/mcu/microchip/samd/asf4"]
path = hw/mcu/microchip/samd/asf4
url = https://github.com/adafruit/asf4.git
[submodule "tools/uf2"]
path = tools/uf2
url = https://github.com/microsoft/uf2.git
@ -19,3 +16,6 @@
[submodule "hw/mcu/nxp"]
path = hw/mcu/nxp
url = https://github.com/hathach/nxp_driver.git
[submodule "hw/mcu/microchip"]
path = hw/mcu/microchip
url = https://github.com/hathach/microchip_driver.git

34
examples/device/cdc_msc/src/usb_descriptors.c
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@ -86,12 +86,32 @@ enum
#if CFG_TUSB_MCU == OPT_MCU_LPC175X_6X || CFG_TUSB_MCU == OPT_MCU_LPC177X_8X || CFG_TUSB_MCU == OPT_MCU_LPC40XX
// LPC 17xx and 40xx endpoint type (bulk/interrupt/iso) are fixed by its number
// 0 control, 1 In, 2 Bulk, 3 Iso, 4 In etc ...
// Note: since CDC EP ( 1 & 2), HID (4) are spot-on, thus we only need to force
// endpoint number for MSC to 5
#define EPNUM_MSC 0x05
// 0 control, 1 In, 2 Bulk, 3 Iso, 4 In, 5 Bulk etc ...
#define EPNUM_CDC_NOTIF 0x81
#define EPNUM_CDC_OUT 0x02
#define EPNUM_CDC_IN 0x82
#define EPNUM_MSC_OUT 0x05
#define EPNUM_MSC_IN 0x85
#elif CFG_TUSB_MCU == OPT_MCU_SAMG
// SAMG doesn't support a same endpoint number with IN and OUT
// e.g EP1 OUT & EP1 IN cannot exist together
#define EPNUM_CDC_NOTIF 0x81
#define EPNUM_CDC_OUT 0x02
#define EPNUM_CDC_IN 0x83
#define EPNUM_MSC_OUT 0x04
#define EPNUM_MSC_IN 0x85
#else
#define EPNUM_MSC 0x03
#define EPNUM_CDC_NOTIF 0x81
#define EPNUM_CDC_OUT 0x02
#define EPNUM_CDC_IN 0x82
#define EPNUM_MSC_OUT 0x03
#define EPNUM_MSC_IN 0x83
#endif
uint8_t const desc_configuration[] =
@ -100,10 +120,10 @@ uint8_t const desc_configuration[] =
TUD_CONFIG_DESCRIPTOR(ITF_NUM_TOTAL, 0, CONFIG_TOTAL_LEN, TUSB_DESC_CONFIG_ATT_REMOTE_WAKEUP, 100),
// Interface number, string index, EP notification address and size, EP data address (out, in) and size.
TUD_CDC_DESCRIPTOR(ITF_NUM_CDC, 4, 0x81, 8, 0x02, 0x82, 64),
TUD_CDC_DESCRIPTOR(ITF_NUM_CDC, 4, EPNUM_CDC_NOTIF, 8, EPNUM_CDC_OUT, EPNUM_CDC_IN, 64),
// Interface number, string index, EP Out & EP In address, EP size
TUD_MSC_DESCRIPTOR(ITF_NUM_MSC, 5, EPNUM_MSC, 0x80 | EPNUM_MSC, (CFG_TUSB_RHPORT0_MODE & OPT_MODE_HIGH_SPEED) ? 512 : 64),
TUD_MSC_DESCRIPTOR(ITF_NUM_MSC, 5, EPNUM_MSC_OUT, EPNUM_MSC_IN, (CFG_TUSB_RHPORT0_MODE & OPT_MODE_HIGH_SPEED) ? 512 : 64),
};

2
hw/bsp/circuitplayground_express/circuitplayground_express.c
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@ -24,9 +24,9 @@
* This file is part of the TinyUSB stack.
*/
#include "sam.h"
#include "bsp/board.h"
#include "sam.h"
#include "hal/include/hal_gpio.h"
#include "hal/include/hal_init.h"
#include "hri/hri_nvmctrl_d21.h"

2
hw/bsp/feather_m0_express/feather_m0_express.c
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@ -24,9 +24,9 @@
* This file is part of the TinyUSB stack.
*/
#include "sam.h"
#include "bsp/board.h"
#include "sam.h"
#include "hal/include/hal_gpio.h"
#include "hal/include/hal_init.h"
#include "hri/hri_nvmctrl_d21.h"

2
hw/bsp/feather_m4_express/feather_m4_express.c
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@ -24,9 +24,9 @@
* This file is part of the TinyUSB stack.
*/
#include "sam.h"
#include "bsp/board.h"
#include "sam.h"
#include "hal/include/hal_gpio.h"
#include "hal/include/hal_init.h"
#include "hpl/gclk/hpl_gclk_base.h"

2
hw/bsp/metro_m0_express/metro_m0_express.c
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@ -24,9 +24,9 @@
* This file is part of the TinyUSB stack.
*/
#include "sam.h"
#include "bsp/board.h"
#include "sam.h"
#include "hal/include/hal_gpio.h"
#include "hal/include/hal_init.h"
#include "hri/hri_nvmctrl_d21.h"

2
hw/bsp/metro_m4_express/metro_m4_express.c
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@ -24,9 +24,9 @@
* This file is part of the TinyUSB stack.
*/
#include "sam.h"
#include "bsp/board.h"
#include "sam.h"
#include "hal/include/hal_gpio.h"
#include "hal/include/hal_init.h"
#include "hpl/gclk/hpl_gclk_base.h"

53
hw/bsp/samg55xplained/board.mk Normal file
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@ -0,0 +1,53 @@
CFLAGS += \
-flto \
-mthumb \
-mabi=aapcs \
-mcpu=cortex-m4 \
-mfloat-abi=hard \
-mfpu=fpv4-sp-d16 \
-nostdlib -nostartfiles \
-D__SAMG55J19__ \
-DCFG_TUSB_MCU=OPT_MCU_SAMG
#CFLAGS += -Wno-error=undef
ASF_DIR = hw/mcu/microchip/samg55
# All source paths should be relative to the top level.
LD_FILE = hw/bsp/$(BOARD)/samg55j19_flash.ld
SRC_C += \
$(ASF_DIR)/samg55/gcc/gcc/startup_samg55j19.c \
$(ASF_DIR)/samg55/gcc/system_samg55j19.c \
$(ASF_DIR)/hpl/core/hpl_init.c \
$(ASF_DIR)/hpl/usart/hpl_usart.c \
$(ASF_DIR)/hpl/pmc/hpl_pmc.c \
$(ASF_DIR)/hal/src/hal_atomic.c
INC += \
$(TOP)/hw/bsp/$(BOARD) \
$(TOP)/$(ASF_DIR) \
$(TOP)/$(ASF_DIR)/config \
$(TOP)/$(ASF_DIR)/samg55/include \
$(TOP)/$(ASF_DIR)/hal/include \
$(TOP)/$(ASF_DIR)/hal/utils/include \
$(TOP)/$(ASF_DIR)/hpl/core \
$(TOP)/$(ASF_DIR)/hpl/pio \
$(TOP)/$(ASF_DIR)/hpl/pmc \
$(TOP)/$(ASF_DIR)/hri \
$(TOP)/$(ASF_DIR)/CMSIS/Core/Include
# For TinyUSB port source
VENDOR = microchip
CHIP_FAMILY = samg
# For freeRTOS port source
FREERTOS_PORT = ARM_CM4F
# For flash-jlink target
JLINK_DEVICE = ATSAMD51J19
JLINK_IF = swd
# flash using edbg from https://github.com/ataradov/edbg
flash: $(BUILD)/$(BOARD)-firmware.bin
edbg --verbose -t samg55 -pv -f $<

215
hw/bsp/samg55xplained/hpl_usart_config.h Normal file
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@ -0,0 +1,215 @@
/* Auto-generated config file hpl_usart_config.h */
#ifndef HPL_USART_CONFIG_H
#define HPL_USART_CONFIG_H
// <<< Use Configuration Wizard in Context Menu >>>
#include <peripheral_clk_config.h>
#ifndef CONF_USART_7_ENABLE
#define CONF_USART_7_ENABLE 1
#endif
// <h> Basic Configuration
// <o> Frame parity
// <0x0=>Even parity
// <0x1=>Odd parity
// <0x2=>Parity forced to 0
// <0x3=>Parity forced to 1
// <0x4=>No parity
// <i> Parity bit mode for USART frame
// <id> usart_parity
#ifndef CONF_USART_7_PARITY
#define CONF_USART_7_PARITY 0x4
#endif
// <o> Character Size
// <0x0=>5 bits
// <0x1=>6 bits
// <0x2=>7 bits
// <0x3=>8 bits
// <i> Data character size in USART frame
// <id> usart_character_size
#ifndef CONF_USART_7_CHSIZE
#define CONF_USART_7_CHSIZE 0x3
#endif
// <o> Stop Bit
// <0=>1 stop bit
// <1=>1.5 stop bits
// <2=>2 stop bits
// <i> Number of stop bits in USART frame
// <id> usart_stop_bit
#ifndef CONF_USART_7_SBMODE
#define CONF_USART_7_SBMODE 0
#endif
// <o> Clock Output Select
// <0=>The USART does not drive the SCK pin
// <1=>The USART drives the SCK pin if USCLKS does not select the external clock SCK
// <i> Clock Output Select in USART sck, if in usrt master mode, please drive SCK.
// <id> usart_clock_output_select
#ifndef CONF_USART_7_CLKO
#define CONF_USART_7_CLKO 0
#endif
// <o> Baud rate <1-3000000>
// <i> USART baud rate setting
// <id> usart_baud_rate
#ifndef CONF_USART_7_BAUD
#define CONF_USART_7_BAUD 9600
#endif
// </h>
// <e> Advanced configuration
// <id> usart_advanced
#ifndef CONF_USART_7_ADVANCED_CONFIG
#define CONF_USART_7_ADVANCED_CONFIG 0
#endif
// <o> Channel Mode
// <0=>Normal Mode
// <1=>Automatic Echo
// <2=>Local Loopback
// <3=>Remote Loopback
// <i> Channel mode in USART frame
// <id> usart_channel_mode
#ifndef CONF_USART_7_CHMODE
#define CONF_USART_7_CHMODE 0
#endif
// <q> 9 bits character enable
// <i> Enable 9 bits character, this has high priority than 5/6/7/8 bits.
// <id> usart_9bits_enable
#ifndef CONF_USART_7_MODE9
#define CONF_USART_7_MODE9 0
#endif
// <o> Variable Sync
// <0=>User defined configuration
// <1=>sync field is updated when a character is written into US_THR
// <i> Variable Synchronization of Command/Data Sync Start Frarm Delimiter
// <id> variable_sync
#ifndef CONF_USART_7_VAR_SYNC
#define CONF_USART_7_VAR_SYNC 0
#endif
// <o> Oversampling Mode
// <0=>16 Oversampling
// <1=>8 Oversampling
// <i> Oversampling Mode in UART mode
// <id> usart__oversampling_mode
#ifndef CONF_USART_7_OVER
#define CONF_USART_7_OVER 0
#endif
// <o> Inhibit Non Ack
// <0=>The NACK is generated
// <1=>The NACK is not generated
// <i> Inhibit Non Acknowledge
// <id> usart__inack
#ifndef CONF_USART_7_INACK
#define CONF_USART_7_INACK 1
#endif
// <o> Disable Successive NACK
// <0=>NACK is sent on the ISO line as soon as a parity error occurs
// <1=>Many parity errors generate a NACK on the ISO line
// <i> Disable Successive NACK
// <id> usart_dsnack
#ifndef CONF_USART_7_DSNACK
#define CONF_USART_7_DSNACK 0
#endif
// <o> Inverted Data
// <0=>Data isn't inverted, nomal mode
// <1=>Data is inverted
// <i> Inverted Data
// <id> usart_invdata
#ifndef CONF_USART_7_INVDATA
#define CONF_USART_7_INVDATA 0
#endif
// <o> Maximum Number of Automatic Iteration <0-7>
// <i> Defines the maximum number of iterations in mode ISO7816, protocol T = 0.
// <id> usart_max_iteration
#ifndef CONF_USART_7_MAX_ITERATION
#define CONF_USART_7_MAX_ITERATION 0
#endif
// <q> Receive Line Filter enable
// <i> whether the USART filters the receive line using a three-sample filter
// <id> usart_receive_filter_enable
#ifndef CONF_USART_7_FILTER
#define CONF_USART_7_FILTER 0
#endif
// <q> Manchester Encoder/Decoder Enable
// <i> whether the USART Manchester Encoder/Decoder
// <id> usart_manchester_filter_enable
#ifndef CONF_USART_7_MAN
#define CONF_USART_7_MAN 0
#endif
// <o> Manchester Synchronization Mode
// <0=>The Manchester start bit is a 0 to 1 transition
// <1=>The Manchester start bit is a 1 to 0 transition
// <i> Manchester Synchronization Mode
// <id> usart_manchester_synchronization_mode
#ifndef CONF_USART_7_MODSYNC
#define CONF_USART_7_MODSYNC 0
#endif
// <o> Start Frame Delimiter Selector
// <0=>Start frame delimiter is COMMAND or DATA SYNC
// <1=>Start frame delimiter is one bit
// <i> Start Frame Delimiter Selector
// <id> usart_start_frame_delimiter
#ifndef CONF_USART_7_ONEBIT
#define CONF_USART_7_ONEBIT 0
#endif
// <o> Fractional Part <0-7>
// <i> Fractional part of the baud rate if baud rate generator is in fractional mode
// <id> usart_arch_fractional
#ifndef CONF_USART_7_FRACTIONAL
#define CONF_USART_7_FRACTIONAL 0x0
#endif
// <o> Data Order
// <0=>LSB is transmitted first
// <1=>MSB is transmitted first
// <i> Data order of the data bits in the frame
// <id> usart_arch_msbf
#ifndef CONF_USART_7_MSBF
#define CONF_USART_7_MSBF 0
#endif
// </e>
#define CONF_USART_7_MODE 0x0
// Calculate BAUD register value in UART mode
#if CONF_FLEXCOM7_CK_SRC < 3
#ifndef CONF_USART_7_BAUD_CD
#define CONF_USART_7_BAUD_CD ((CONF_FLEXCOM7_FREQUENCY) / CONF_USART_7_BAUD / 8 / (2 - CONF_USART_7_OVER))
#endif
#ifndef CONF_USART_7_BAUD_FP
#define CONF_USART_7_BAUD_FP \
((CONF_FLEXCOM7_FREQUENCY) / CONF_USART_7_BAUD / (2 - CONF_USART_7_OVER) - 8 * CONF_USART_7_BAUD_CD)
#endif
#elif CONF_FLEXCOM7_CK_SRC == 3
// No division is active. The value written in US_BRGR has no effect.
#ifndef CONF_USART_7_BAUD_CD
#define CONF_USART_7_BAUD_CD 1
#endif
#ifndef CONF_USART_7_BAUD_FP
#define CONF_USART_7_BAUD_FP 1
#endif
#endif
// <<< end of configuration section >>>
#endif // HPL_USART_CONFIG_H

85
hw/bsp/samg55xplained/peripheral_clk_config.h Normal file
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@ -0,0 +1,85 @@
/* Auto-generated config file peripheral_clk_config.h */
#ifndef PERIPHERAL_CLK_CONFIG_H
#define PERIPHERAL_CLK_CONFIG_H
// <<< Use Configuration Wizard in Context Menu >>>
/**
* \def CONF_HCLK_FREQUENCY
* \brief HCLK's Clock frequency
*/
#ifndef CONF_HCLK_FREQUENCY
#define CONF_HCLK_FREQUENCY 8000000
#endif
/**
* \def CONF_FCLK_FREQUENCY
* \brief FCLK's Clock frequency
*/
#ifndef CONF_FCLK_FREQUENCY
#define CONF_FCLK_FREQUENCY 8000000
#endif
/**
* \def CONF_CPU_FREQUENCY
* \brief CPU's Clock frequency
*/
#ifndef CONF_CPU_FREQUENCY
#define CONF_CPU_FREQUENCY 8000000
#endif
/**
* \def CONF_SLCK_FREQUENCY
* \brief Slow Clock frequency
*/
#define CONF_SLCK_FREQUENCY 32768
/**
* \def CONF_MCK_FREQUENCY
* \brief Master Clock frequency
*/
#define CONF_MCK_FREQUENCY 8000000
// <o> USB Clock Source
// <0=> USB Clock Controller (USB_48M)
// <id> usb_clock_source
// <i> Select the clock source for USB.
#ifndef CONF_UDP_SRC
#define CONF_UDP_SRC 0
#endif
/**
* \def CONF_UDP_FREQUENCY
* \brief UDP's Clock frequency
*/
#ifndef CONF_UDP_FREQUENCY
#define CONF_UDP_FREQUENCY 48005120
#endif
// <h> FLEXCOM Clock Settings
// <o> FLEXCOM Clock source
// <0=> Master Clock (MCK)
// <1=> MCK / 8
// <2=> Programmable Clock Controller 6 (PMC_PCK6)
// <2=> Programmable Clock Controller 7 (PMC_PCK7)
// <3=> External Clock
// <i> This defines the clock source for the FLEXCOM, PCK6 is used for FLEXCOM0/1/2/3 and PCK7 is used for FLEXCOM4/5/6/7
// <id> flexcom_clock_source
#ifndef CONF_FLEXCOM7_CK_SRC
#define CONF_FLEXCOM7_CK_SRC 0
#endif
// <o> FLEXCOM External Clock Input on SCK <1-4294967295>
// <i> Inputs the external clock frequency on SCK
// <id> flexcom_clock_freq
#ifndef CONF_FLEXCOM7_SCK_FREQ
#define CONF_FLEXCOM7_SCK_FREQ 10000000
#endif
#ifndef CONF_FLEXCOM7_FREQUENCY
#define CONF_FLEXCOM7_FREQUENCY 8000000
#endif
// <<< end of configuration section >>>
#endif // PERIPHERAL_CLK_CONFIG_H

158
hw/bsp/samg55xplained/samg55j19_flash.ld Normal file
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@ -0,0 +1,158 @@
/**
* \file
*
* \brief GCC linker script (flash) for ATSAMG55J19
*
* Copyright (c) 2017 Atmel Corporation, a wholly owned subsidiary of Microchip Technology Inc.
*
* \license_start
*
* \page License
*
* 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.
*
* \license_stop
*
*/
/*------------------------------------------------------------------------------
* Linker script for running in internal FLASH on the ATSAMG55J19
*----------------------------------------------------------------------------*/
OUTPUT_FORMAT("elf32-littlearm", "elf32-littlearm", "elf32-littlearm")
OUTPUT_ARCH(arm)
/* Memory Spaces Definitions */
MEMORY
{
rom (rx) : ORIGIN = 0x00400000, LENGTH = 0x00080000 /* rom, 524288K */
ram (rwx) : ORIGIN = 0x20000000, LENGTH = 0x00028000 /* ram, 163840K */
}
/* The stack size used by the application. NOTE: you need to adjust according to your application. */
STACK_SIZE = DEFINED(STACK_SIZE) ? STACK_SIZE : DEFINED(__stack_size__) ? __stack_size__ : 0x0400;
/* The heapsize used by the application. NOTE: you need to adjust according to your application. */
HEAP_SIZE = DEFINED(HEAP_SIZE) ? HEAP_SIZE : DEFINED(__heap_size__) ? __heap_size__ : 0x0200;
/* Section Definitions */
SECTIONS
{
.text :
{
. = ALIGN(4);
_sfixed = .;
KEEP(*(.vectors .vectors.*))
*(.text .text.* .gnu.linkonce.t.*)
*(.glue_7t) *(.glue_7)
*(.rodata .rodata* .gnu.linkonce.r.*)
*(.ARM.extab* .gnu.linkonce.armextab.*)
/* Support C constructors, and C destructors in both user code
and the C library. This also provides support for C++ code. */
. = ALIGN(4);
KEEP(*(.init))
. = ALIGN(4);
__preinit_array_start = .;
KEEP (*(.preinit_array))
__preinit_array_end = .;
. = ALIGN(4);
__init_array_start = .;
KEEP (*(SORT(.init_array.*)))
KEEP (*(.init_array))
__init_array_end = .;
. = ALIGN(0x4);
KEEP (*crtbegin.o(.ctors))
KEEP (*(EXCLUDE_FILE (*crtend.o) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*crtend.o(.ctors))
. = ALIGN(4);
KEEP(*(.fini))
. = ALIGN(4);
__fini_array_start = .;
KEEP (*(.fini_array))
KEEP (*(SORT(.fini_array.*)))
__fini_array_end = .;
KEEP (*crtbegin.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*crtend.o(.dtors))
. = ALIGN(4);
_efixed = .; /* End of text section */
} > rom
/* .ARM.exidx is sorted, so has to go in its own output section. */
PROVIDE_HIDDEN (__exidx_start = .);
.ARM.exidx :
{
*(.ARM.exidx* .gnu.linkonce.armexidx.*)
} > rom
PROVIDE_HIDDEN (__exidx_end = .);
. = ALIGN(4);
_etext = .;
.relocate : AT (_etext)
{
. = ALIGN(4);
_srelocate = .;
*(.ramfunc .ramfunc.*);
*(.data .data.*);
. = ALIGN(4);
_erelocate = .;
} > ram
/* .bss section which is used for uninitialized data */
.bss (NOLOAD) :
{
. = ALIGN(4);
_sbss = . ;
_szero = .;
*(.bss .bss.*)
*(COMMON)
. = ALIGN(4);
_ebss = . ;
_ezero = .;
end = .;
} > ram
/* heap section */
.heap (NOLOAD):
{
. = ALIGN(8);
_sheap = .;
. = . + HEAP_SIZE;
. = ALIGN(8);
_eheap = .;
} > ram
/* stack section */
.stack (NOLOAD):
{
. = ALIGN(8);
_sstack = .;
. = . + STACK_SIZE;
. = ALIGN(8);
_estack = .;
} > ram
. = ALIGN(4);
_end = . ;
_ram_end_ = ORIGIN(ram) + LENGTH(ram) - 1 ;
}

157
hw/bsp/samg55xplained/samg55xplained.c Normal file
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@ -0,0 +1,157 @@
/*
* The MIT License (MIT)
*
* Copyright (c) 2019, 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.
*
*/
#include "sam.h"
#include "peripheral_clk_config.h"
#include "hal/include/hal_init.h"
#include "hal/include/hpl_usart_sync.h"
#include "hpl/pmc/hpl_pmc.h"
#include "hal/include/hal_gpio.h"
#include "bsp/board.h"
//--------------------------------------------------------------------+
// MACRO TYPEDEF CONSTANT ENUM DECLARATION
//--------------------------------------------------------------------+
#define LED_PIN GPIO(GPIO_PORTA, 6)
#define BUTTON_PIN GPIO(GPIO_PORTA, 2)
#define BUTTON_STATE_ACTIVE 0
#define UART_TX_PIN GPIO(GPIO_PORTA, 28)
#define UART_RX_PIN GPIO(GPIO_PORTA, 27)
struct _usart_sync_device _edbg_com;
//------------- IMPLEMENTATION -------------//
void board_init(void)
{
init_mcu();
_pmc_enable_periph_clock(ID_PIOA);
/* Disable Watchdog */
hri_wdt_set_MR_WDDIS_bit(WDT);
// LED
gpio_set_pin_level(LED_PIN, false);
gpio_set_pin_direction(LED_PIN, GPIO_DIRECTION_OUT);
gpio_set_pin_function(LED_PIN, GPIO_PIN_FUNCTION_OFF);
// Button
gpio_set_pin_direction(BUTTON_PIN, GPIO_DIRECTION_IN);
gpio_set_pin_pull_mode(BUTTON_PIN, GPIO_PULL_UP);
gpio_set_pin_function(BUTTON_PIN, GPIO_PIN_FUNCTION_OFF);
// Uart via EDBG Com
_pmc_enable_periph_clock(ID_FLEXCOM7);
gpio_set_pin_function(UART_RX_PIN, MUX_PA27B_FLEXCOM7_RXD);
gpio_set_pin_function(UART_TX_PIN, MUX_PA28B_FLEXCOM7_TXD);
_usart_sync_init(&_edbg_com, FLEXCOM7);
_usart_sync_set_baud_rate(&_edbg_com, CFG_BOARD_UART_BAUDRATE);
_usart_sync_set_mode(&_edbg_com, USART_MODE_ASYNCHRONOUS);
_usart_sync_enable(&_edbg_com);
#if CFG_TUSB_OS == OPT_OS_NONE
// 1ms tick timer (samd SystemCoreClock may not correct)
SysTick_Config(CONF_CPU_FREQUENCY / 1000);
#endif
// USB Pin, Clock init
/* Clear SYSIO 10 & 11 for USB DM & DP */
hri_matrix_clear_CCFG_SYSIO_reg(MATRIX, CCFG_SYSIO_SYSIO10 | CCFG_SYSIO_SYSIO11);
// Enable clock
_pmc_enable_periph_clock(ID_UDP);
/* USB Device mode & Transceiver active */
hri_matrix_write_CCFG_USBMR_reg(MATRIX, CCFG_USBMR_USBMODE);
}
//--------------------------------------------------------------------+
// USB Interrupt Handler
//--------------------------------------------------------------------+
void UDP_Handler(void)
{
#if CFG_TUSB_RHPORT0_MODE & OPT_MODE_DEVICE
tud_isr(0);
#endif
}
//--------------------------------------------------------------------+
// Board porting API
//--------------------------------------------------------------------+
void board_led_write(bool state)
{
gpio_set_pin_level(LED_PIN, state);
}
uint32_t board_button_read(void)
{
return BUTTON_STATE_ACTIVE == gpio_get_pin_level(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)
{
uint8_t const * buf8 = (uint8_t const *) buf;
for(int i=0; i<len; i++)
{
while ( !_usart_sync_is_ready_to_send(&_edbg_com) ) {}
_usart_sync_write_byte(&_edbg_com, buf8[i]);
}
return len;
}
#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
// Required by __libc_init_array in startup code if we are compiling using
// -nostdlib/-nostartfiles.
void _init(void)
{
}

1
hw/mcu/microchip Submodule

@ -0,0 +1 @@
Subproject commit 66b5a11995025426224e0ba6f377322e6e8893b6

1
hw/mcu/microchip/samd/asf4

@ -1 +0,0 @@
Subproject commit 82fe3aa05bc3b9f4956ee775c748a3885443f66b

37
src/class/msc/msc_device.c
View File

@ -97,6 +97,34 @@ static inline uint16_t rdwr10_get_blockcount(uint8_t const command[])
return tu_ntohs(block_count);
}
//--------------------------------------------------------------------+
// Debug
//--------------------------------------------------------------------+
#if CFG_TUSB_DEBUG >= 2
static lookup_entry_t const _msc_scsi_cmd_lookup[] =
{
{ .key = SCSI_CMD_TEST_UNIT_READY , .data = "Test Unit Ready" },
{ .key = SCSI_CMD_INQUIRY , .data = "Inquiry" },
{ .key = SCSI_CMD_MODE_SELECT_6 , .data = "Mode_Select 6" },
{ .key = SCSI_CMD_MODE_SENSE_6 , .data = "Mode_Sense 6" },
{ .key = SCSI_CMD_START_STOP_UNIT , .data = "Start Stop Unit" },
{ .key = SCSI_CMD_PREVENT_ALLOW_MEDIUM_REMOVAL , .data = "Prevent Allow Medium Removal" },
{ .key = SCSI_CMD_READ_CAPACITY_10 , .data = "Read Capacity10" },
{ .key = SCSI_CMD_REQUEST_SENSE , .data = "Request Sense" },
{ .key = SCSI_CMD_READ_FORMAT_CAPACITY , .data = "Read Format Capacity" },
{ .key = SCSI_CMD_READ_10 , .data = "Read10" },
{ .key = SCSI_CMD_WRITE_10 , .data = "Write10" }
};
static lookup_table_t const _msc_scsi_cmd_table =
{
.count = TU_ARRAY_SIZE(_msc_scsi_cmd_lookup),
.items = _msc_scsi_cmd_lookup
};
#endif
//--------------------------------------------------------------------+
// APPLICATION API
//--------------------------------------------------------------------+
@ -378,6 +406,9 @@ bool mscd_xfer_cb(uint8_t rhport, uint8_t ep_addr, xfer_result_t event, uint32_t
TU_ASSERT( event == XFER_RESULT_SUCCESS &&
xferred_bytes == sizeof(msc_cbw_t) && p_cbw->signature == MSC_CBW_SIGNATURE );
TU_LOG2(" SCSI Command: %s\n", lookup_find(&_msc_scsi_cmd_table, p_cbw->command[0]));
// TU_LOG2_MEM(p_cbw, xferred_bytes, 2);
p_csw->signature = MSC_CSW_SIGNATURE;
p_csw->tag = p_cbw->tag;
p_csw->data_residue = 0;
@ -448,6 +479,9 @@ bool mscd_xfer_cb(uint8_t rhport, uint8_t ep_addr, xfer_result_t event, uint32_t
break;
case MSC_STAGE_DATA:
TU_LOG2(" SCSI Data\n");
//TU_LOG2_MEM(_mscd_buf, xferred_bytes, 2);
// OUT transfer, invoke callback if needed
if ( !tu_bit_test(p_cbw->dir, 7) )
{
@ -538,6 +572,9 @@ bool mscd_xfer_cb(uint8_t rhport, uint8_t ep_addr, xfer_result_t event, uint32_t
// Wait for the command status wrapper complete event
if( (ep_addr == p_msc->ep_in) && (xferred_bytes == sizeof(msc_csw_t)) )
{
TU_LOG2(" SCSI Status: %u\n", p_csw->status);
// TU_LOG2_MEM(p_csw, xferred_bytes, 2);
// Move to default CMD stage
p_msc->stage = MSC_STAGE_CMD;

43
src/common/tusb_common.h
View File

@ -139,9 +139,9 @@ static inline uint8_t tu_log2(uint32_t value)
}
// Bit
static inline uint32_t tu_bit_set (uint32_t value, uint8_t n) { return value | TU_BIT(n); }
static inline uint32_t tu_bit_clear(uint32_t value, uint8_t n) { return value & (~TU_BIT(n)); }
static inline bool tu_bit_test (uint32_t value, uint8_t n) { return (value & TU_BIT(n)) ? true : false; }
static inline uint32_t tu_bit_set (uint32_t value, uint8_t pos) { return value | TU_BIT(pos); }
static inline uint32_t tu_bit_clear(uint32_t value, uint8_t pos) { return value & (~TU_BIT(pos)); }
static inline bool tu_bit_test (uint32_t value, uint8_t pos) { return (value & TU_BIT(pos)) ? true : false; }
/*------------------------------------------------------------------*/
/* Count number of arguments of __VA_ARGS__
@ -213,22 +213,47 @@ static inline bool tu_bit_test (uint32_t value, uint8_t n) { return (value &
// 2 : print out log
#if CFG_TUSB_DEBUG
void tu_print_mem(void const *buf, uint8_t size, uint16_t count);
void tu_print_mem(void const *buf, uint16_t count, uint8_t indent);
#ifndef tu_printf
#define tu_printf printf
#define tu_printf printf
#endif
// Log with debug level 1
#define TU_LOG1 tu_printf
#define TU_LOG1_MEM tu_print_mem
#define TU_LOG1 tu_printf
#define TU_LOG1_MEM tu_print_mem
#define TU_LOG1_LOCATION() tu_printf("%s: %d:\n", __PRETTY_FUNCTION__, __LINE__)
// Log with debug level 2
#if CFG_TUSB_DEBUG > 1
#define TU_LOG2 TU_LOG1
#define TU_LOG2_MEM TU_LOG1_MEM
#define TU_LOG2 TU_LOG1
#define TU_LOG2_MEM TU_LOG1_MEM
#define TU_LOG2_LOCATION() TU_LOG1_LOCATION()
#endif
typedef struct
{
uint32_t key;
char const * data;
}lookup_entry_t;
typedef struct
{
uint16_t count;
lookup_entry_t const* items;
} lookup_table_t;
static inline char const* lookup_find(lookup_table_t const* p_table, uint32_t key)
{
for(uint16_t i=0; i<p_table->count; i++)
{
if (p_table->items[i].key == key) return p_table->items[i].data;
}
return NULL;
}
#endif // CFG_TUSB_DEBUG
#ifndef TU_LOG1

4
src/device/dcd.h
View File

@ -110,6 +110,10 @@ void dcd_remote_wakeup(uint8_t rhport);
// Endpoint API
//--------------------------------------------------------------------+
// Invoked when a control transfer's status stage is complete.
// May help DCD to prepare for next control transfer, this API is optional.
void dcd_edpt0_status_complete(uint8_t rhport, tusb_control_request_t const * request) TU_ATTR_WEAK;
// Configure endpoint's registers according to descriptor
bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * p_endpoint_desc);

50
src/device/usbd.c
View File

@ -202,15 +202,16 @@ static bool process_control_request(uint8_t rhport, tusb_control_request_t const
static bool process_set_config(uint8_t rhport, uint8_t cfg_num);
static bool process_get_descriptor(uint8_t rhport, tusb_control_request_t const * p_request);
void usbd_control_reset (uint8_t rhport);
bool usbd_control_xfer_cb (uint8_t rhport, uint8_t ep_addr, xfer_result_t event, uint32_t xferred_bytes);
void usbd_control_reset(void);
void usbd_control_set_request(tusb_control_request_t const *request);
void usbd_control_set_complete_callback( bool (*fp) (uint8_t, tusb_control_request_t const * ) );
bool usbd_control_xfer_cb (uint8_t rhport, uint8_t ep_addr, xfer_result_t event, uint32_t xferred_bytes);
//--------------------------------------------------------------------+
// Debugging
//--------------------------------------------------------------------+
#if CFG_TUSB_DEBUG > 1
#if CFG_TUSB_DEBUG >= 2
static char const* const _usbd_event_str[DCD_EVENT_COUNT] =
{
"INVALID" ,
@ -321,7 +322,7 @@ static void usbd_reset(uint8_t rhport)
memset(_usbd_dev.itf2drv, DRVID_INVALID, sizeof(_usbd_dev.itf2drv)); // invalid mapping
memset(_usbd_dev.ep2drv , DRVID_INVALID, sizeof(_usbd_dev.ep2drv )); // invalid mapping
usbd_control_reset(rhport);
usbd_control_reset();
for (uint8_t i = 0; i < USBD_CLASS_DRIVER_COUNT; i++)
{
@ -375,8 +376,7 @@ void tud_task (void)
break;
case DCD_EVENT_SETUP_RECEIVED:
TU_LOG2(" ");
TU_LOG1_MEM(&event.setup_received, 1, 8);
TU_LOG2_MEM(&event.setup_received, 8, 2);
// Mark as connected after receiving 1st setup packet.
// But it is easier to set it every time instead of wasting time to check then set
@ -385,7 +385,7 @@ void tud_task (void)
// Process control request
if ( !process_control_request(event.rhport, &event.setup_received) )
{
TU_LOG1(" Stall EP0\r\n");
TU_LOG2(" Stall EP0\r\n");
// Failed -> stall both control endpoint IN and OUT
dcd_edpt_stall(event.rhport, 0);
dcd_edpt_stall(event.rhport, 0 | TUSB_DIR_IN_MASK);
@ -405,7 +405,6 @@ void tud_task (void)
if ( 0 == epnum )
{
TU_LOG1(" EP Addr = 0x%02X, len = %ld\r\n", ep_addr, event.xfer_complete.len);
usbd_control_xfer_cb(event.rhport, ep_addr, event.xfer_complete.result, event.xfer_complete.len);
}
else
@ -500,10 +499,12 @@ static bool process_control_request(uint8_t rhport, tusb_control_request_t const
switch ( p_request->bRequest )
{
case TUSB_REQ_SET_ADDRESS:
// Depending on mcu, status phase could be sent either before or after changing device address
// Therefore DCD must include zero-length status response
// Depending on mcu, status phase could be sent either before or after changing device address,
// or even require stack to not response with status at all
// Therefore DCD must take full responsibility to response and include zlp status packet if needed.
usbd_control_set_request(p_request); // set request since DCD has no access to tud_control_status() API
dcd_set_address(rhport, (uint8_t) p_request->wValue);
return true; // skip status
// skip tud_control_status()
break;
case TUSB_REQ_GET_CONFIGURATION:
@ -830,19 +831,15 @@ void dcd_event_handler(dcd_event_t const * event, bool in_isr)
{
switch (event->event_id)
{
case DCD_EVENT_BUS_RESET:
osal_queue_send(_usbd_q, event, in_isr);
break;
case DCD_EVENT_UNPLUGGED:
_usbd_dev.connected = 0;
_usbd_dev.connected = 0;
_usbd_dev.configured = 0;
_usbd_dev.suspended = 0;
_usbd_dev.suspended = 0;
osal_queue_send(_usbd_q, event, in_isr);
break;
case DCD_EVENT_SOF:
// nothing to do now
return; // skip SOF event for now
break;
case DCD_EVENT_SUSPEND:
@ -857,6 +854,7 @@ void dcd_event_handler(dcd_event_t const * event, bool in_isr)
break;
case DCD_EVENT_RESUME:
// skip event if not connected (especially required for SAMD)
if ( _usbd_dev.connected )
{
_usbd_dev.suspended = 0;
@ -864,21 +862,9 @@ void dcd_event_handler(dcd_event_t const * event, bool in_isr)
}
break;
case DCD_EVENT_SETUP_RECEIVED:
default:
osal_queue_send(_usbd_q, event, in_isr);
break;
case DCD_EVENT_XFER_COMPLETE:
osal_queue_send(_usbd_q, event, in_isr);
TU_ASSERT(event->xfer_complete.result == XFER_RESULT_SUCCESS,);
break;
// Not an DCD event, just a convenient way to defer ISR function should we need to
case USBD_EVENT_FUNC_CALL:
osal_queue_send(_usbd_q, event, in_isr);
break;
default: break;
}
}
@ -962,6 +948,8 @@ bool usbd_edpt_xfer(uint8_t rhport, uint8_t ep_addr, uint8_t * buffer, uint16_t
TU_VERIFY( dcd_edpt_xfer(rhport, ep_addr, buffer, total_bytes) );
_usbd_dev.ep_status[epnum][dir].busy = true;
TU_LOG2(" XFER Endpoint: 0x%02X, Bytes: %d\r\n", ep_addr, total_bytes);
return true;
}

14
src/device/usbd_control.c
View File

@ -64,6 +64,7 @@ static inline bool _status_stage_xact(uint8_t rhport, tusb_control_request_t con
return dcd_edpt_xfer(rhport, request->bmRequestType_bit.direction ? EDPT_CTRL_OUT : EDPT_CTRL_IN, NULL, 0);
}
// Status phase
bool tud_control_status(uint8_t rhport, tusb_control_request_t const * request)
{
_ctrl_xfer.request = (*request);
@ -118,9 +119,8 @@ bool tud_control_xfer(uint8_t rhport, tusb_control_request_t const * request, vo
// USBD API
//--------------------------------------------------------------------+
void usbd_control_reset (uint8_t rhport)
void usbd_control_reset(void)
{
(void) rhport;
tu_varclr(&_ctrl_xfer);
}
@ -130,6 +130,15 @@ void usbd_control_set_complete_callback( bool (*fp) (uint8_t, tusb_control_reque
_ctrl_xfer.complete_cb = fp;
}
// useful for dcd_set_address where DCD is responsible for status response
void usbd_control_set_request(tusb_control_request_t const *request)
{
_ctrl_xfer.request = (*request);
_ctrl_xfer.buffer = NULL;
_ctrl_xfer.total_xferred = 0;
_ctrl_xfer.data_len = 0;
}
// callback when a transaction complete on
// - DATA stage of control endpoint or
// - Status stage
@ -141,6 +150,7 @@ bool usbd_control_xfer_cb (uint8_t rhport, uint8_t ep_addr, xfer_result_t result
if ( tu_edpt_dir(ep_addr) != _ctrl_xfer.request.bmRequestType_bit.direction )
{
TU_ASSERT(0 == xferred_bytes);
if (dcd_edpt0_status_complete) dcd_edpt0_status_complete(rhport, &_ctrl_xfer.request);
return true;
}

36
src/portable/microchip/samd21/dcd_samd21.c
View File

@ -28,8 +28,8 @@
#if TUSB_OPT_DEVICE_ENABLED && CFG_TUSB_MCU == OPT_MCU_SAMD21
#include "device/dcd.h"
#include "sam.h"
#include "device/dcd.h"
/*------------------------------------------------------------------*/
/* MACRO TYPEDEF CONSTANT ENUM
@ -98,13 +98,13 @@ void dcd_int_disable(uint8_t rhport)
void dcd_set_address (uint8_t rhport, uint8_t dev_addr)
{
// Response with status first before changing device address
dcd_edpt_xfer(rhport, tu_edpt_addr(0, TUSB_DIR_IN), NULL, 0);
(void) dev_addr;
// Wait for EP0 to finish before switching the address.
while (USB->DEVICE.DeviceEndpoint[0].EPSTATUS.bit.BK1RDY == 1) {}
// Response with zlp status
dcd_edpt_xfer(rhport, 0x80, NULL, 0);
USB->DEVICE.DADD.reg = USB_DEVICE_DADD_DADD(dev_addr) | USB_DEVICE_DADD_ADDEN;
// DCD can only set address after status for this request is complete
// do it at dcd_edpt0_status_complete()
// Enable SUSPEND interrupt since the bus signal D+/D- are stable now.
USB->DEVICE.INTFLAG.reg = USB_DEVICE_INTENCLR_SUSPEND; // clear pending
@ -116,7 +116,6 @@ void dcd_set_config (uint8_t rhport, uint8_t config_num)
(void) rhport;
(void) config_num;
// Nothing to do
}
void dcd_remote_wakeup(uint8_t rhport)
@ -130,6 +129,23 @@ void dcd_remote_wakeup(uint8_t rhport)
/* DCD Endpoint port
*------------------------------------------------------------------*/
// Invoked when a control transfer's status stage is complete.
// May help DCD to prepare for next control transfer, this API is optional.
void dcd_edpt0_status_complete(uint8_t rhport, tusb_control_request_t const * request)
{
if (request->bmRequestType_bit.recipient == TUSB_REQ_RCPT_DEVICE &&
request->bmRequestType_bit.type == TUSB_REQ_TYPE_STANDARD &&
request->bRequest == TUSB_REQ_SET_ADDRESS )
{
uint8_t const dev_addr = (uint8_t) request->wValue;
USB->DEVICE.DADD.reg = USB_DEVICE_DADD_DADD(dev_addr) | USB_DEVICE_DADD_ADDEN;
}
// Just finished status stage, prepare for next setup packet
dcd_edpt_xfer(rhport, 0x00, _setup_packet, sizeof(_setup_packet));
}
bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * desc_edpt)
{
(void) rhport;
@ -282,12 +298,6 @@ void maybe_transfer_complete(void) {
uint8_t ep_addr = epnum;
dcd_event_xfer_complete(0, ep_addr, total_transfer_size, XFER_RESULT_SUCCESS, true);
}
// Just finished status stage (total size = 0), prepare for next setup packet
// TODO could cause issue with actual zero length data used by class such as DFU
if (epnum == 0 && total_transfer_size == 0) {
dcd_edpt_xfer(0, 0, _setup_packet, sizeof(_setup_packet));
}
}
}

33
src/portable/microchip/samd51/dcd_samd51.c
View File

@ -28,8 +28,8 @@
#if TUSB_OPT_DEVICE_ENABLED && CFG_TUSB_MCU == OPT_MCU_SAMD51
#include "device/dcd.h"
#include "sam.h"
#include "device/dcd.h"
/*------------------------------------------------------------------*/
/* MACRO TYPEDEF CONSTANT ENUM
@ -104,13 +104,13 @@ void dcd_int_disable(uint8_t rhport)
void dcd_set_address (uint8_t rhport, uint8_t dev_addr)
{
// Response with status first before changing device address
dcd_edpt_xfer(rhport, tu_edpt_addr(0, TUSB_DIR_IN), NULL, 0);
(void) dev_addr;
// Wait for EP0 to finish before switching the address.
while (USB->DEVICE.DeviceEndpoint[0].EPSTATUS.bit.BK1RDY == 1) {}
// Response with zlp status
dcd_edpt_xfer(rhport, 0x80, NULL, 0);
USB->DEVICE.DADD.reg = USB_DEVICE_DADD_DADD(dev_addr) | USB_DEVICE_DADD_ADDEN;
// DCD can only set address after status for this request is complete
// do it at dcd_edpt0_status_complete()
// Enable SUSPEND interrupt since the bus signal D+/D- are stable now.
USB->DEVICE.INTFLAG.reg = USB_DEVICE_INTENCLR_SUSPEND; // clear pending
@ -135,6 +135,22 @@ void dcd_remote_wakeup(uint8_t rhport)
/* DCD Endpoint port
*------------------------------------------------------------------*/
// Invoked when a control transfer's status stage is complete.
// May help DCD to prepare for next control transfer, this API is optional.
void dcd_edpt0_status_complete(uint8_t rhport, tusb_control_request_t const * request)
{
if (request->bmRequestType_bit.recipient == TUSB_REQ_RCPT_DEVICE &&
request->bmRequestType_bit.type == TUSB_REQ_TYPE_STANDARD &&
request->bRequest == TUSB_REQ_SET_ADDRESS )
{
uint8_t const dev_addr = (uint8_t) request->wValue;
USB->DEVICE.DADD.reg = USB_DEVICE_DADD_DADD(dev_addr) | USB_DEVICE_DADD_ADDEN;
}
// Just finished status stage, prepare for next setup packet
dcd_edpt_xfer(rhport, 0x00, _setup_packet, sizeof(_setup_packet));
}
bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * desc_edpt)
{
(void) rhport;
@ -334,11 +350,6 @@ void transfer_complete(uint8_t direction) {
}
dcd_event_xfer_complete(0, ep_addr, total_transfer_size, XFER_RESULT_SUCCESS, true);
// just finished status stage (total size = 0), prepare for next setup packet
if (epnum == 0 && total_transfer_size == 0) {
dcd_edpt_xfer(0, 0, _setup_packet, sizeof(_setup_packet));
}
if (direction == TUSB_DIR_IN) {
ep->EPINTFLAG.reg = USB_DEVICE_EPINTFLAG_TRCPT1;
} else {

443
src/portable/microchip/samg/dcd_samg.c Normal file
View File

@ -0,0 +1,443 @@
/*
* 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 "tusb_option.h"
#if CFG_TUSB_MCU == OPT_MCU_SAMG
#include "sam.h"
#include "device/dcd.h"
// TODO should support (SAM3S || SAM4S || SAM4E || SAMG55)
//--------------------------------------------------------------------+
// MACRO TYPEDEF CONSTANT ENUM DECLARATION
//--------------------------------------------------------------------+
#define EP_COUNT 6
// Transfer descriptor
typedef struct
{
uint8_t* buffer;
uint16_t total_len;
volatile uint16_t actual_len;
uint16_t epsize;
} xfer_desc_t;
// Endpoint 0-5, each can only be either OUT or In
xfer_desc_t _dcd_xfer[EP_COUNT];
void xfer_epsize_set(xfer_desc_t* xfer, uint16_t epsize)
{
xfer->epsize = epsize;
}
void xfer_begin(xfer_desc_t* xfer, uint8_t * buffer, uint16_t total_bytes)
{
xfer->buffer = buffer;
xfer->total_len = total_bytes;
xfer->actual_len = 0;
}
void xfer_end(xfer_desc_t* xfer)
{
xfer->buffer = NULL;
xfer->total_len = 0;
xfer->actual_len = 0;
}
uint16_t xfer_packet_len(xfer_desc_t* xfer)
{
// also cover zero-length packet
return tu_min16(xfer->total_len - xfer->actual_len, xfer->epsize);
}
void xfer_packet_done(xfer_desc_t* xfer)
{
uint16_t const xact_len = xfer_packet_len(xfer);
xfer->buffer += xact_len;
xfer->actual_len += xact_len;
}
//------------- Transaction helpers -------------//
// Write data to EP FIFO, return number of written bytes
static void xact_ep_write(uint8_t epnum, uint8_t* buffer, uint16_t xact_len)
{
for(uint16_t i=0; i<xact_len; i++)
{
UDP->UDP_FDR[epnum] = (uint32_t) buffer[i];
}
}
// Read data from EP FIFO
static void xact_ep_read(uint8_t epnum, uint8_t* buffer, uint16_t xact_len)
{
for(uint16_t i=0; i<xact_len; i++)
{
buffer[i] = (uint8_t) UDP->UDP_FDR[epnum];
}
}
/*------------------------------------------------------------------*/
/* Device API
*------------------------------------------------------------------*/
// Set up endpoint 0, clear all other endpoints
static void bus_reset(void)
{
tu_memclr(_dcd_xfer, sizeof(_dcd_xfer));
xfer_epsize_set(&_dcd_xfer[0], CFG_TUD_ENDPOINT0_SIZE);
// Enable EP0 control
UDP->UDP_CSR[0] = UDP_CSR_EPEDS_Msk;
// Enable interrupt : EP0, Suspend, Resume, Wakeup
UDP->UDP_IER = UDP_IER_EP0INT_Msk | UDP_IER_RXSUSP_Msk | UDP_IER_RXRSM_Msk | UDP_IER_WAKEUP_Msk;
// Enable transceiver
UDP->UDP_TXVC &= ~UDP_TXVC_TXVDIS_Msk;
}
// Initialize controller to device mode
void dcd_init (uint8_t rhport)
{
(void) rhport;
tu_memclr(_dcd_xfer, sizeof(_dcd_xfer));
// Enable pull-up, disable transceiver
UDP->UDP_TXVC = UDP_TXVC_PUON | UDP_TXVC_TXVDIS_Msk;
}
// Enable device interrupt
void dcd_int_enable (uint8_t rhport)
{
(void) rhport;
NVIC_EnableIRQ(UDP_IRQn);
}
// Disable device interrupt
void dcd_int_disable (uint8_t rhport)
{
(void) rhport;
NVIC_DisableIRQ(UDP_IRQn);
}
// Receive Set Address request, mcu port must also include status IN response
void dcd_set_address (uint8_t rhport, uint8_t dev_addr)
{
(void) rhport;
(void) dev_addr;
// Response with zlp status
dcd_edpt_xfer(rhport, 0x80, NULL, 0);
// DCD can only set address after status for this request is complete.
// do it at dcd_edpt0_status_complete()
}
// Receive Set Configure request
void dcd_set_config (uint8_t rhport, uint8_t config_num)
{
(void) rhport;
(void) config_num;
// Configured State
// UDP->UDP_GLB_STAT |= UDP_GLB_STAT_CONFG_Msk;
}
// Wake up host
void dcd_remote_wakeup (uint8_t rhport)
{
(void) rhport;
}
//--------------------------------------------------------------------+
// Endpoint API
//--------------------------------------------------------------------+
// Invoked when a control transfer's status stage is complete.
// May help DCD to prepare for next control transfer, this API is optional.
void dcd_edpt0_status_complete(uint8_t rhport, tusb_control_request_t const * request)
{
(void) rhport;
if (request->bmRequestType_bit.recipient == TUSB_REQ_RCPT_DEVICE &&
request->bmRequestType_bit.type == TUSB_REQ_TYPE_STANDARD )
{
if (request->bRequest == TUSB_REQ_SET_ADDRESS)
{
uint8_t const dev_addr = (uint8_t) request->wValue;
// Enable addressed state
UDP->UDP_GLB_STAT |= UDP_GLB_STAT_FADDEN_Msk;
// Set new address & Function enable bit
UDP->UDP_FADDR = UDP_FADDR_FEN_Msk | UDP_FADDR_FADD(dev_addr);
}else if (request->bRequest == TUSB_REQ_SET_CONFIGURATION)
{
// Configured State
UDP->UDP_GLB_STAT |= UDP_GLB_STAT_CONFG_Msk;
}
}
}
// Configure endpoint's registers according to descriptor
// SAMG doesn't support a same endpoint number with IN and OUT
// e.g EP1 OUT & EP1 IN cannot exist together
bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * ep_desc)
{
(void) rhport;
uint8_t const epnum = tu_edpt_number(ep_desc->bEndpointAddress);
uint8_t const dir = tu_edpt_dir(ep_desc->bEndpointAddress);
// TODO Isochronous is not supported yet
TU_VERIFY(ep_desc->bmAttributes.xfer != TUSB_XFER_ISOCHRONOUS);
TU_VERIFY(epnum < EP_COUNT);
// Must not already enabled
TU_ASSERT((UDP->UDP_CSR[epnum] & UDP_CSR_EPEDS_Msk) == 0);
xfer_epsize_set(&_dcd_xfer[epnum], ep_desc->wMaxPacketSize.size);
// Configure type and eanble EP
UDP->UDP_CSR[epnum] = UDP_CSR_EPEDS_Msk | UDP_CSR_EPTYPE(ep_desc->bmAttributes.xfer + 4*dir);
// Enable EP Interrupt for IN
if (dir == TUSB_DIR_IN) UDP->UDP_IER |= (1 << epnum);
return true;
}
// Submit a transfer, When complete dcd_event_xfer_complete() is invoked to notify the stack
bool dcd_edpt_xfer (uint8_t rhport, uint8_t ep_addr, uint8_t * buffer, uint16_t total_bytes)
{
(void) rhport;
uint8_t const epnum = tu_edpt_number(ep_addr);
uint8_t const dir = tu_edpt_dir(ep_addr);
xfer_desc_t* xfer = &_dcd_xfer[epnum];
xfer_begin(xfer, buffer, total_bytes);
if (dir == TUSB_DIR_IN)
{
// Set DIR bit for EP0
if ( epnum == 0 ) UDP->UDP_CSR[epnum] |= UDP_CSR_DIR_Msk;
xact_ep_write(epnum, xfer->buffer, xfer_packet_len(xfer));
// TX ready for transfer
UDP->UDP_CSR[epnum] |= UDP_CSR_TXPKTRDY_Msk;
}
else
{
// Clear DIR bit for EP0
if ( epnum == 0 ) UDP->UDP_CSR[epnum] &= ~UDP_CSR_DIR_Msk;
// OUT Data may already received and acked by hardware
// Read it as 1st packet then continue with transfer if needed
if ( UDP->UDP_CSR[epnum] & (UDP_CSR_RX_DATA_BK0_Msk | UDP_CSR_RX_DATA_BK1_Msk) )
{
// uint16_t const xact_len = (uint16_t) ((UDP->UDP_CSR[epnum] & UDP_CSR_RXBYTECNT_Msk) >> UDP_CSR_RXBYTECNT_Pos);
// TU_LOG2("xact_len = %d\r", xact_len);
// // Read from EP fifo
// xact_ep_read(epnum, xfer->buffer, xact_len);
// xfer_packet_done(xfer);
//
// // Clear DATA Bank0 bit
// UDP->UDP_CSR[epnum] &= ~UDP_CSR_RX_DATA_BK0_Msk;
//
// if ( 0 == xfer_packet_len(xfer) )
// {
// // Disable OUT EP interrupt when transfer is complete
// UDP->UDP_IER &= ~(1 << epnum);
//
// dcd_event_xfer_complete(rhport, epnum, xact_len, XFER_RESULT_SUCCESS, false);
// return true; // complete
// }
}
// Enable interrupt when starting OUT transfer
if (epnum != 0) UDP->UDP_IER |= (1 << epnum);
}
return true;
}
// Stall endpoint
void dcd_edpt_stall (uint8_t rhport, uint8_t ep_addr)
{
(void) rhport;
uint8_t const epnum = tu_edpt_number(ep_addr);
// Set force stall bit
UDP->UDP_CSR[epnum] |= UDP_CSR_FORCESTALL_Msk;
}
// clear stall, data toggle is also reset to DATA0
void dcd_edpt_clear_stall (uint8_t rhport, uint8_t ep_addr)
{
(void) rhport;
uint8_t const epnum = tu_edpt_number(ep_addr);
// clear stall
UDP->UDP_CSR[epnum] &= ~UDP_CSR_FORCESTALL_Msk;
// must also reset EP to clear data toggle
UDP->UDP_RST_EP = tu_bit_set(UDP->UDP_RST_EP, epnum);
UDP->UDP_RST_EP = tu_bit_clear(UDP->UDP_RST_EP, epnum);
}
//--------------------------------------------------------------------+
// ISR
//--------------------------------------------------------------------+
void dcd_isr(uint8_t rhport)
{
uint32_t const intr_mask = UDP->UDP_IMR;
uint32_t const intr_status = UDP->UDP_ISR & intr_mask;
// clear interrupt
UDP->UDP_ICR = intr_status;
// Bus reset
if (intr_status & UDP_ISR_ENDBUSRES_Msk)
{
bus_reset();
dcd_event_bus_signal(rhport, DCD_EVENT_BUS_RESET, true);
}
// SOF
// if (intr_status & UDP_ISR_SOFINT_Msk) dcd_event_bus_signal(rhport, DCD_EVENT_SOF, true);
// Suspend
// if (intr_status & UDP_ISR_RXSUSP_Msk) dcd_event_bus_signal(rhport, DCD_EVENT_SUSPEND, true);
// Resume
// if (intr_status & UDP_ISR_RXRSM_Msk) dcd_event_bus_signal(rhport, DCD_EVENT_RESUME, true);
// Wakeup
// if (intr_status & UDP_ISR_WAKEUP_Msk) dcd_event_bus_signal(rhport, DCD_EVENT_RESUME, true);
//------------- Endpoints -------------//
if ( intr_status & TU_BIT(0) )
{
// setup packet
if (UDP->UDP_CSR[0] & UDP_CSR_RXSETUP)
{
// get setup from FIFO
uint8_t setup[8];
for(uint8_t i=0; i<sizeof(setup); i++)
{
setup[i] = (uint8_t) UDP->UDP_FDR[0];
}
// notify usbd
dcd_event_setup_received(rhport, setup, true);
// Clear Setup bit
UDP->UDP_CSR[0] &= ~UDP_CSR_RXSETUP_Msk;
return;
}
}
for(uint8_t epnum = 0; epnum < EP_COUNT; epnum++)
{
if ( intr_status & TU_BIT(epnum) )
{
xfer_desc_t* xfer = &_dcd_xfer[epnum];
// Endpoint IN
if (UDP->UDP_CSR[epnum] & UDP_CSR_TXCOMP_Msk)
{
xfer_packet_done(xfer);
uint16_t const xact_len = xfer_packet_len(xfer);
if (xact_len)
{
// write to EP fifo
xact_ep_write(epnum, xfer->buffer, xact_len);
// TX ready for transfer
UDP->UDP_CSR[epnum] |= UDP_CSR_TXPKTRDY_Msk;
}else
{
// xfer is complete
dcd_event_xfer_complete(rhport, epnum | TUSB_DIR_IN_MASK, xfer->actual_len, XFER_RESULT_SUCCESS, true);
}
// Clear TX Complete bit
UDP->UDP_CSR[epnum] &= ~UDP_CSR_TXCOMP_Msk;
}
// Endpoint OUT
// Ping-Pong is a must for Bulk/Iso
// When both Bank0 and Bank1 are both set, there is not way to know which one comes first
if (UDP->UDP_CSR[epnum] & (UDP_CSR_RX_DATA_BK0_Msk | UDP_CSR_RX_DATA_BK1_Msk))
{
uint16_t const xact_len = (uint16_t) ((UDP->UDP_CSR[epnum] & UDP_CSR_RXBYTECNT_Msk) >> UDP_CSR_RXBYTECNT_Pos);
//if (epnum != 0) TU_LOG2("xact_len = %d\r", xact_len);
// Read from EP fifo
xact_ep_read(epnum, xfer->buffer, xact_len);
xfer_packet_done(xfer);
if ( 0 == xfer_packet_len(xfer) )
{
// Disable OUT EP interrupt when transfer is complete
if (epnum != 0) UDP->UDP_IDR |= (1 << epnum);
dcd_event_xfer_complete(rhport, epnum, xact_len, XFER_RESULT_SUCCESS, true);
// xfer_end(xfer);
}
// Clear DATA Bank0 bit
UDP->UDP_CSR[epnum] &= ~(UDP_CSR_RX_DATA_BK0_Msk | UDP_CSR_RX_DATA_BK1_Msk);
}
// Stall sent to host
if (UDP->UDP_CSR[epnum] & UDP_CSR_STALLSENT_Msk)
{
UDP->UDP_CSR[epnum] &= ~UDP_CSR_STALLSENT_Msk;
}
}
}
}
#endif

37
src/portable/st/stm32_fsdev/dcd_stm32_fsdev.c
View File

@ -175,7 +175,6 @@ static inline xfer_ctl_t* xfer_ctl_ptr(uint32_t epnum, uint32_t dir)
static TU_ATTR_ALIGNED(4) uint32_t _setup_packet[6];
static uint8_t newDADDR; // Used to set the new device address during the CTR IRQ handler
static uint8_t remoteWakeCountdown; // When wake is requested
// EP Buffers assigned from end of memory location, to minimize their chance of crashing
@ -298,14 +297,14 @@ void dcd_int_disable(uint8_t rhport)
// Receive Set Address request, mcu port must also include status IN response
void dcd_set_address(uint8_t rhport, uint8_t dev_addr)
{
(void)rhport;
// We cannot immediatly change it; it must be queued to change after the STATUS packet is sent.
// (CTR handler will actually change the address once it sees that the transmission is complete)
newDADDR = dev_addr;
(void) rhport;
(void) dev_addr;
// Respond with status
dcd_edpt_xfer(rhport, tu_edpt_addr(0, TUSB_DIR_IN), NULL, 0);
// DCD can only set address after status for this request is complete.
// do it at dcd_edpt0_status_complete()
}
// Receive Set Config request
@ -362,7 +361,7 @@ static void dcd_handle_bus_reset(void)
ep_buf_ptr = DCD_STM32_BTABLE_BASE + 8*MAX_EP_COUNT; // 8 bytes per endpoint (two TX and two RX words, each)
dcd_edpt_open (0, &ep0OUT_desc);
dcd_edpt_open (0, &ep0IN_desc);
newDADDR = 0u;
USB->DADDR = USB_DADDR_EF; // Set enable flag, and leaving the device address as zero.
}
@ -398,13 +397,7 @@ static uint16_t dcd_ep_ctr_handler(void)
if((xfer->total_len == xfer->queued_len))
{
dcd_event_xfer_complete(0u, (uint8_t)(0x80 + EPindex), xfer->total_len, XFER_RESULT_SUCCESS, true);
if((newDADDR != 0) && ( xfer->total_len == 0U))
{
// Delayed setting of the DADDR after the 0-len DATA packet acking the request is sent.
reg16_clear_bits(&USB->DADDR, USB_DADDR_ADD);
USB->DADDR = (uint16_t)(USB->DADDR | newDADDR); // leave the enable bit set
newDADDR = 0;
}
if(xfer->total_len == 0) // Probably a status message?
{
pcd_clear_rx_dtog(USB,EPindex);
@ -602,6 +595,24 @@ static void dcd_fs_irqHandler(void) {
// Endpoint API
//--------------------------------------------------------------------+
// Invoked when a control transfer's status stage is complete.
// May help DCD to prepare for next control transfer, this API is optional.
void dcd_edpt0_status_complete(uint8_t rhport, tusb_control_request_t const * request)
{
(void) rhport;
if (request->bmRequestType_bit.recipient == TUSB_REQ_RCPT_DEVICE &&
request->bmRequestType_bit.type == TUSB_REQ_TYPE_STANDARD &&
request->bRequest == TUSB_REQ_SET_ADDRESS )
{
uint8_t const dev_addr = (uint8_t) request->wValue;
// Setting new address after the whole request is complete
reg16_clear_bits(&USB->DADDR, USB_DADDR_ADD);
USB->DADDR = (uint16_t)(USB->DADDR | dev_addr); // leave the enable bit set
}
}
// The STM32F0 doesn't seem to like |= or &= to manipulate the EP#R registers,
// so I'm using the #define from HAL here, instead.

1
src/portable/st/synopsys/dcd_synopsys.c
View File

@ -232,7 +232,6 @@ void dcd_set_address (uint8_t rhport, uint8_t dev_addr)
(void) rhport;
USB_OTG_DeviceTypeDef * dev = DEVICE_BASE;
dev->DCFG |= (dev_addr << USB_OTG_DCFG_DAD_Pos) & USB_OTG_DCFG_DAD_Msk;
// Response with status after changing device address

116
src/portable/template/dcd_template.c Normal file
View File

@ -0,0 +1,116 @@
/*
* 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 "tusb_option.h"
#if CFG_TUSB_MCU == OPT_MCU_NONE
#include "device/dcd.h"
//--------------------------------------------------------------------+
// MACRO TYPEDEF CONSTANT ENUM DECLARATION
//--------------------------------------------------------------------+
/*------------------------------------------------------------------*/
/* Device API
*------------------------------------------------------------------*/
// Initialize controller to device mode
void dcd_init (uint8_t rhport)
{
(void) rhport;
}
// Enable device interrupt
void dcd_int_enable (uint8_t rhport)
{
(void) rhport;
}
// Disable device interrupt
void dcd_int_disable (uint8_t rhport)
{
(void) rhport;
}
// Receive Set Address request, mcu port must also include status IN response
void dcd_set_address (uint8_t rhport, uint8_t dev_addr)
{
(void) rhport;
(void) dev_addr;
}
// Receive Set Configure request
void dcd_set_config (uint8_t rhport, uint8_t config_num)
{
(void) rhport;
(void) config_num;
}
// Wake up host
void dcd_remote_wakeup (uint8_t rhport)
{
(void) rhport;
}
//--------------------------------------------------------------------+
// Endpoint API
//--------------------------------------------------------------------+
// Configure endpoint's registers according to descriptor
bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * ep_desc)
{
(void) rhport;
(void) ep_desc;
return false;
}
// Submit a transfer, When complete dcd_event_xfer_complete() is invoked to notify the stack
bool dcd_edpt_xfer (uint8_t rhport, uint8_t ep_addr, uint8_t * buffer, uint16_t total_bytes)
{
(void) rhport;
(void) ep_addr;
(void) buffer;
(void) total_bytes;
return false;
}
// Stall endpoint
void dcd_edpt_stall (uint8_t rhport, uint8_t ep_addr)
{
(void) rhport;
(void) ep_addr;
}
// clear stall, data toggle is also reset to DATA0
void dcd_edpt_clear_stall (uint8_t rhport, uint8_t ep_addr)
{
(void) rhport;
(void) ep_addr;
}
#endif

6
src/tusb.c
View File

@ -81,8 +81,10 @@ static void dump_str_line(uint8_t const* buf, uint16_t count)
// size : item size in bytes
// count : number of item
// print offet or not (handfy for dumping large memory)
void tu_print_mem(void const *buf, uint8_t size, uint16_t count)
void tu_print_mem(void const *buf, uint16_t count, uint8_t indent)
{
uint8_t const size = 1; // fixed 1 byte for now
if ( !buf || !count )
{
tu_printf("NULL\r\n");
@ -110,6 +112,8 @@ void tu_print_mem(void const *buf, uint8_t size, uint16_t count)
tu_printf("\r\n");
}
for(uint8_t s=0; s < indent; s++) tu_printf(" ");
// print offset or absolute address
tu_printf("%03lX: ", 16*i/item_per_line);
}

3
src/tusb_option.h
View File

@ -36,6 +36,8 @@
* \ref CFG_TUSB_MCU must be defined to one of these
* @{ */
#define OPT_MCU_NONE 0
// LPC
#define OPT_MCU_LPC11UXX 1 ///< NXP LPC11Uxx
#define OPT_MCU_LPC13XX 2 ///< NXP LPC13xx
@ -55,6 +57,7 @@
// SAM
#define OPT_MCU_SAMD21 200 ///< MicroChip SAMD21
#define OPT_MCU_SAMD51 201 ///< MicroChip SAMD51
#define OPT_MCU_SAMG 202 ///< MicroChip SAMDG series
// STM32
#define OPT_MCU_STM32F0 300 ///< ST STM32F0

5
test/test/device/usbd/test_usbd.c
View File

@ -149,6 +149,8 @@ void test_usbd_get_device_descriptor(void)
// status
dcd_edpt_xfer_ExpectAndReturn(rhport, EDPT_CTRL_OUT, NULL, 0, true);
dcd_event_xfer_complete(rhport, EDPT_CTRL_OUT, 0, 0, false);
dcd_edpt0_status_complete_ExpectWithArray(rhport, &req_get_desc_device, 1);
tud_task();
}
@ -180,6 +182,8 @@ void test_usbd_get_configuration_descriptor(void)
// status
dcd_edpt_xfer_ExpectAndReturn(rhport, EDPT_CTRL_OUT, NULL, 0, true);
dcd_event_xfer_complete(rhport, EDPT_CTRL_OUT, 0, 0, false);
dcd_edpt0_status_complete_ExpectWithArray(rhport, &req_get_desc_configuration, 1);
tud_task();
}
@ -231,6 +235,7 @@ void test_usbd_control_in_zlp(void)
// Status
dcd_edpt_xfer_ExpectAndReturn(rhport, EDPT_CTRL_OUT, NULL, 0, true);
dcd_event_xfer_complete(rhport, EDPT_CTRL_OUT, 0, 0, false);
dcd_edpt0_status_complete_ExpectWithArray(rhport, &req_get_desc_configuration, 1);
tud_task();
}

2
tools/build_all.py
View File

@ -36,7 +36,7 @@ for entry in os.scandir("hw/bsp"):
def build_example(example, board):
subprocess.run("make -C examples/device/{} BOARD={} clean".format(example, board), shell=True,
stdout=subprocess.PIPE, stderr=subprocess.STDOUT)
return subprocess.run("make -j 8 -C examples/device/{} BOARD={} all".format(example, board), shell=True,
return subprocess.run("make -j 4 -C examples/device/{} BOARD={} all".format(example, board), shell=True,
stdout=subprocess.PIPE, stderr=subprocess.STDOUT)