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/*
* SPDX - FileCopyrightText : 2023 - 2024 Espressif Systems ( Shanghai ) CO LTD
*
* SPDX - License - Identifier : Apache - 2.0
*/
# include <stdlib.h>
# include <sys/queue.h>
# include <sys/lock.h>
# include "esp_check.h"
# include "freertos/portmacro.h"
# include "freertos/FreeRTOS.h"
# include "freertos/task.h"
# include "esp_intr_alloc.h"
# include "esp_heap_caps.h"
# include "esp_memory_utils.h"
# include "esp_attr.h"
# include "esp_log.h"
# include "esp_private/periph_ctrl.h"
# include "dma2d_priv.h"
# include "esp_private/dma2d.h"
# include "hal/dma2d_hal.h"
# include "hal/dma2d_ll.h"
# include "soc/dma2d_channel.h"
# include "soc/dma2d_periph.h"
# include "soc/soc_caps.h"
# include "esp_bit_defs.h"
/**
* The 2 D - DMA driver is designed with a pool & client model + queue design pattern .
*
* Pools represents the groups of 2 D - DMA module , which contain the limited resource , channels .
* Clients represents the upper modules which are the consumers of the 2 D - DMA channels , such as JPEG and PPA .
*
* Each pool has a queue to store the 2 D - DMA transactions that are waiting to be processed .
*
* The upper modules should register themselves as the clients to a 2 D - DMA pool . And then they should push the
* 2 D - DMA transactions into the pool queue . The driver will continuously look for the desired resources from the pool to
* complete the transactions .
*/
static const char * TAG = " dma2d " ;
typedef struct dma2d_platform_t {
_lock_t mutex ; // platform level mutex lock to protect the dma2d_acquire_pool/dma2d_release_pool process
dma2d_group_t * groups [ SOC_DMA2D_GROUPS ] ; // array of 2D-DMA group instances
int group_ref_counts [ SOC_DMA2D_GROUPS ] ; // reference count used to protect group install/uninstall
} dma2d_platform_t ;
// 2D-DMA driver platform
static dma2d_platform_t s_platform = {
. groups = { } ,
} ;
// extern 2D-DMA channel reserved mask variables to be ORed in the constructors
uint32_t dma2d_tx_channel_reserved_mask [ SOC_DMA2D_GROUPS ] = { [ 0 . . . SOC_DMA2D_GROUPS - 1 ] = 0 } ;
uint32_t dma2d_rx_channel_reserved_mask [ SOC_DMA2D_GROUPS ] = { [ 0 . . . SOC_DMA2D_GROUPS - 1 ] = 0 } ;
// The most number of channels required for a 2D-DMA transaction (a PPA Blend operation requires 2 TX + 1 RX)
# define DMA2D_MAX_CHANNEL_NUM_PER_TRANSACTION 3
/* This static function is not thread-safe, group's spinlock protection should be added in its caller */
static bool acquire_free_channels_for_trans ( dma2d_group_t * dma2d_group , const dma2d_trans_config_t * trans_desc , dma2d_trans_channel_info_t * channel_handle_array )
{
bool found = true ;
uint32_t idx = 0 ;
uint32_t bundled_tx_channel_mask = 0 ;
if ( trans_desc - > tx_channel_num > 0 ) {
uint32_t tx_free_channel_mask ;
if ( ! trans_desc - > specified_tx_channel_mask ) {
tx_free_channel_mask = dma2d_group - > tx_channel_free_mask ;
tx_free_channel_mask & = ( ( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_TX_REORDER ) ? DMA2D_LL_TX_CHANNEL_SUPPORT_RO_MASK : UINT32_MAX ) &
( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_TX_CSC ) ? DMA2D_LL_TX_CHANNEL_SUPPORT_CSC_MASK : UINT32_MAX ) ) ;
tx_free_channel_mask & = ~ dma2d_group - > tx_channel_reserved_mask ;
if ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_SIBLING ) {
uint32_t rx_channel_candidate = dma2d_group - > rx_channel_free_mask &
( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_RX_REORDER ) ? DMA2D_LL_RX_CHANNEL_SUPPORT_RO_MASK : UINT32_MAX ) &
( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_RX_CSC ) ? DMA2D_LL_RX_CHANNEL_SUPPORT_CSC_MASK : UINT32_MAX ) &
~ dma2d_group - > rx_channel_reserved_mask ;
tx_free_channel_mask & = rx_channel_candidate ;
}
// As long as __builtin_popcount(tx_free_channel_mask) >= trans_desc->tx_channel_num, it can meet the criteria of "found"
} else {
tx_free_channel_mask = trans_desc - > specified_tx_channel_mask & dma2d_group - > tx_channel_free_mask ;
// tx_free_channel_mask need to be exactly equal to trans_desc->specified_tx_channel_mask to meet the criteria of "found"
}
for ( int i = 0 ; i < trans_desc - > tx_channel_num ; i + + ) {
if ( tx_free_channel_mask ) {
int channel_id = 31 - __builtin_clz ( tx_free_channel_mask ) ; // channel 0 has the most features, acquire other channels first if possible
tx_free_channel_mask & = ~ ( 1 < < channel_id ) ;
dma2d_group - > tx_channel_free_mask & = ~ ( 1 < < channel_id ) ;
bundled_tx_channel_mask | = ( 1 < < channel_id ) ;
// Record channel status
memset ( & dma2d_group - > tx_chans [ channel_id ] - > base . status , 0 , sizeof ( dma2d_group - > tx_chans [ channel_id ] - > base . status ) ) ;
dma2d_group - > tx_chans [ channel_id ] - > base . status . periph_sel_id = - 1 ;
if ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_TX_REORDER ) {
dma2d_group - > tx_chans [ channel_id ] - > base . status . reorder_en = true ;
}
channel_handle_array [ idx ] . chan = & dma2d_group - > tx_chans [ channel_id ] - > base ;
channel_handle_array [ idx ] . dir = DMA2D_CHANNEL_DIRECTION_TX ;
idx + + ;
} else {
found = false ;
goto revert ;
}
}
}
if ( trans_desc - > rx_channel_num > 0 ) {
uint32_t rx_free_channel_mask ;
if ( trans_desc - > specified_rx_channel_mask ) {
rx_free_channel_mask = trans_desc - > specified_rx_channel_mask & dma2d_group - > rx_channel_free_mask ;
// rx_free_channel_mask need to be exactly equal to trans_desc->specified_rx_channel_mask to meet the criteria of "found"
} else if ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_SIBLING ) {
// rx channel has already been determined
rx_free_channel_mask = bundled_tx_channel_mask ;
} else {
rx_free_channel_mask = dma2d_group - > rx_channel_free_mask ;
rx_free_channel_mask & = ( ( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_RX_REORDER ) ? DMA2D_LL_RX_CHANNEL_SUPPORT_RO_MASK : UINT32_MAX ) &
( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_RX_CSC ) ? DMA2D_LL_RX_CHANNEL_SUPPORT_CSC_MASK : UINT32_MAX ) ) ;
rx_free_channel_mask & = ~ dma2d_group - > rx_channel_reserved_mask ;
// As long as __builtin_popcount(rx_free_channel_mask) >= trans_desc->rx_channel_num, it can meet the criteria of "found"
}
// Requires one RX channel at most, no need a for loop
if ( rx_free_channel_mask ) {
int channel_id = 31 - __builtin_clz ( rx_free_channel_mask ) ; // channel 0 has full features, acquire other channels first if possible
rx_free_channel_mask & = ~ ( 1 < < channel_id ) ;
dma2d_group - > rx_channel_free_mask & = ~ ( 1 < < channel_id ) ;
// Record channel status
memset ( & dma2d_group - > rx_chans [ channel_id ] - > base . status , 0 , sizeof ( dma2d_group - > rx_chans [ channel_id ] - > base . status ) ) ;
dma2d_group - > rx_chans [ channel_id ] - > base . status . periph_sel_id = - 1 ;
if ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_RX_REORDER ) {
dma2d_group - > rx_chans [ channel_id ] - > base . status . reorder_en = true ;
}
channel_handle_array [ idx ] . chan = & dma2d_group - > rx_chans [ channel_id ] - > base ;
channel_handle_array [ idx ] . dir = DMA2D_CHANNEL_DIRECTION_RX ;
idx + + ;
// Record its bundled TX channels, to be freed in the isr
dma2d_rx_channel_t * rx_chan = dma2d_group - > rx_chans [ channel_id ] ;
portENTER_CRITICAL_SAFE ( & rx_chan - > base . spinlock ) ;
rx_chan - > bundled_tx_channel_mask = bundled_tx_channel_mask ;
portEXIT_CRITICAL_SAFE ( & rx_chan - > base . spinlock ) ;
} else {
found = false ;
goto revert ;
}
}
revert :
if ( ! found ) {
for ( int i = 0 ; i < idx ; i + + ) {
int free_channel_mask = ( 1 < < channel_handle_array [ i ] . chan - > channel_id ) ;
if ( channel_handle_array [ i ] . dir = = DMA2D_CHANNEL_DIRECTION_TX ) {
dma2d_group - > tx_channel_free_mask | = free_channel_mask ;
} else {
dma2d_group - > rx_channel_free_mask | = free_channel_mask ;
}
}
}
return found ;
}
/* This function will free up the RX channel and its bundled TX channels, then check for whether there is next transaction to be picked up */
static bool free_up_channels ( dma2d_group_t * group , dma2d_rx_channel_t * rx_chan )
{
bool need_yield = false ;
uint32_t channel_id = rx_chan - > base . channel_id ;
// 1. Clean up channels
uint32_t bundled_tx_channel_mask = rx_chan - > bundled_tx_channel_mask ;
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uint32_t tx_periph_sel_id_mask = 0 ;
uint32_t rx_periph_sel_id_mask = 0 ;
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// Disable RX channel interrupt
portENTER_CRITICAL_SAFE ( & rx_chan - > base . spinlock ) ;
dma2d_ll_rx_enable_interrupt ( group - > hal . dev , channel_id , UINT32_MAX , false ) ;
// Reset RX channel event related pointers and flags
rx_chan - > on_recv_eof = NULL ;
rx_chan - > on_desc_done = NULL ;
// Disconnect RX channel from the peripheral
dma2d_ll_rx_disconnect_from_periph ( group - > hal . dev , channel_id ) ;
// Clear the pointer that points to the finished transaction
rx_chan - > base . status . transaction = NULL ;
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// Record its periph_sel_id
assert ( rx_chan - > base . status . periph_sel_id ! = - 1 ) ;
rx_periph_sel_id_mask | = ( 1 < < rx_chan - > base . status . periph_sel_id ) ;
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portEXIT_CRITICAL_SAFE ( & rx_chan - > base . spinlock ) ;
// For every bundled TX channels:
while ( rx_chan - > bundled_tx_channel_mask ) {
uint32_t nbit = __builtin_ffs ( rx_chan - > bundled_tx_channel_mask ) - 1 ;
rx_chan - > bundled_tx_channel_mask & = ~ ( 1 < < nbit ) ;
dma2d_tx_channel_t * tx_chan = group - > tx_chans [ nbit ] ;
// Disable TX channel interrupt
portENTER_CRITICAL_SAFE ( & tx_chan - > base . spinlock ) ;
dma2d_ll_tx_enable_interrupt ( group - > hal . dev , nbit , UINT32_MAX , false ) ;
// Reset TX channel event related pointers
tx_chan - > on_desc_done = NULL ;
// Disconnect TX channel from the peripheral
dma2d_ll_tx_disconnect_from_periph ( group - > hal . dev , nbit ) ;
// Clear the pointer that points to the finished transaction
tx_chan - > base . status . transaction = NULL ;
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// Record its periph_sel_id
assert ( tx_chan - > base . status . periph_sel_id ! = - 1 ) ;
tx_periph_sel_id_mask | = ( 1 < < tx_chan - > base . status . periph_sel_id ) ;
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portEXIT_CRITICAL_SAFE ( & tx_chan - > base . spinlock ) ;
}
// Channel functionality flags will be reset and assigned new values inside `acquire_free_channels_for_trans`
// Channel reset will always be done at `dma2d_connect` (i.e. when the channel is selected for a new transaction)
// 2. Check if next pending transaction in the tailq can start
bool channels_found = false ;
const dma2d_trans_config_t * next_trans = NULL ;
dma2d_trans_channel_info_t channel_handle_array [ DMA2D_MAX_CHANNEL_NUM_PER_TRANSACTION ] ;
portENTER_CRITICAL_SAFE ( & group - > spinlock ) ;
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// Release channels
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group - > tx_channel_free_mask | = bundled_tx_channel_mask ;
group - > rx_channel_free_mask | = ( 1 < < channel_id ) ;
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// Release M2M periph_sel_id
group - > tx_periph_m2m_free_id_mask | = ( tx_periph_sel_id_mask & DMA2D_LL_TX_CHANNEL_PERIPH_M2M_AVAILABLE_ID_MASK ) ;
group - > rx_periph_m2m_free_id_mask | = ( rx_periph_sel_id_mask & DMA2D_LL_RX_CHANNEL_PERIPH_M2M_AVAILABLE_ID_MASK ) ;
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dma2d_trans_t * next_trans_elm = TAILQ_FIRST ( & group - > pending_trans_tailq ) ;
if ( next_trans_elm ) {
// There is a pending transaction
next_trans = next_trans_elm - > desc ;
channels_found = acquire_free_channels_for_trans ( group , next_trans , channel_handle_array ) ;
}
if ( channels_found ) {
TAILQ_REMOVE ( & group - > pending_trans_tailq , next_trans_elm , entry ) ;
}
portEXIT_CRITICAL_SAFE ( & group - > spinlock ) ;
if ( channels_found ) {
// If the transaction can be processed, let consumer handle the transaction
uint32_t total_channel_num = next_trans - > tx_channel_num + next_trans - > rx_channel_num ;
// Store the acquired rx_chan into trans_elm (dma2d_trans_t) in case upper driver later need it to call `dma2d_force_end`
// Upper driver controls the life cycle of trans_elm
for ( int i = 0 ; i < total_channel_num ; i + + ) {
if ( channel_handle_array [ i ] . dir = = DMA2D_CHANNEL_DIRECTION_RX ) {
next_trans_elm - > rx_chan = channel_handle_array [ i ] . chan ;
}
// Also save the transaction pointer
channel_handle_array [ i ] . chan - > status . transaction = next_trans_elm ;
}
need_yield | = next_trans - > on_job_picked ( total_channel_num , channel_handle_array , next_trans - > user_config ) ;
}
return need_yield ;
}
static NOINLINE_ATTR bool _dma2d_default_tx_isr ( dma2d_group_t * group , int channel_id )
{
bool need_yield = false ;
dma2d_tx_channel_t * tx_chan = group - > tx_chans [ channel_id ] ;
dma2d_event_data_t edata = {
. transaction = tx_chan - > base . status . transaction ,
} ;
// Clear pending interrupt event
uint32_t intr_status = dma2d_ll_tx_get_interrupt_status ( group - > hal . dev , channel_id ) ;
dma2d_ll_tx_clear_interrupt_status ( group - > hal . dev , channel_id , intr_status ) ;
// Handle callback
if ( intr_status & DMA2D_LL_EVENT_TX_DONE ) {
if ( tx_chan - > on_desc_done ) {
need_yield | = tx_chan - > on_desc_done ( & tx_chan - > base , & edata , tx_chan - > user_data ) ;
}
}
return need_yield ;
}
static NOINLINE_ATTR bool _dma2d_default_rx_isr ( dma2d_group_t * group , int channel_id )
{
bool need_yield = false ;
dma2d_rx_channel_t * rx_chan = group - > rx_chans [ channel_id ] ;
dma2d_event_data_t edata = {
. transaction = rx_chan - > base . status . transaction ,
} ;
// Clear pending interrupt event
uint32_t intr_status = dma2d_ll_rx_get_interrupt_status ( group - > hal . dev , channel_id ) ;
dma2d_ll_rx_clear_interrupt_status ( group - > hal . dev , channel_id , intr_status ) ;
// Save RX channel EOF callback pointers temporarily, could be overwritten by new ones
dma2d_event_callback_t on_recv_eof = rx_chan - > on_recv_eof ;
void * user_data = rx_chan - > user_data ;
uint32_t suc_eof_desc_addr = dma2d_ll_rx_get_success_eof_desc_addr ( group - > hal . dev , channel_id ) ;
// It is guaranteed in hardware that if SUC_EOF/ERR_EOF interrupt is raised, it will always be raised together with
// RX_DONE interrupt at the same time.
// On RX_DONE triggered, it may be an indication of partially done, call `on_desc_done` callback, allowing 2D-DMA
// channel operations on the currently acquired channels. Channel may continue running again.
if ( intr_status & DMA2D_LL_EVENT_RX_DONE ) {
if ( rx_chan - > on_desc_done ) {
need_yield | = rx_chan - > on_desc_done ( & rx_chan - > base , & edata , user_data ) ;
}
}
// If last transcation completes (regardless success or not), free the channels
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if ( intr_status & ( DMA2D_LL_EVENT_RX_SUC_EOF | DMA2D_LL_EVENT_RX_ERR_EOF | DMA2D_LL_EVENT_RX_DESC_ERROR ) ) {
if ( ! ( intr_status & DMA2D_LL_EVENT_RX_ERR_EOF ) ) {
assert ( dma2d_ll_rx_is_fsm_idle ( group - > hal . dev , channel_id ) ) ;
}
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need_yield | = free_up_channels ( group , rx_chan ) ;
}
// Handle last transaction's end callbacks (at this point, last transaction's channels are completely freed,
// therefore, we don't pass in channel handle to the callbacks anymore)
if ( intr_status & DMA2D_LL_EVENT_RX_SUC_EOF ) {
if ( on_recv_eof ) {
edata . rx_eof_desc_addr = suc_eof_desc_addr ;
need_yield | = on_recv_eof ( NULL , & edata , user_data ) ;
}
}
return need_yield ;
}
static void dma2d_default_isr ( void * args )
{
dma2d_channel_t * chan = ( dma2d_channel_t * ) args ;
dma2d_group_t * group = chan - > group ;
bool need_yield = false ;
if ( chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
need_yield | = _dma2d_default_tx_isr ( group , chan - > channel_id ) ;
} else {
// For RX channel interrupt triggered, we need to check whether there is any interrupt triggered for the
// bundled TX channels but hasn't been processed. If so, handle TX interrupt first.
uint32_t bundled_tx_channel_mask = group - > rx_chans [ chan - > channel_id ] - > bundled_tx_channel_mask ;
while ( bundled_tx_channel_mask ) {
uint32_t chan_id = __builtin_ffs ( bundled_tx_channel_mask ) - 1 ;
bundled_tx_channel_mask & = ~ ( 1 < < chan_id ) ;
need_yield | = _dma2d_default_tx_isr ( group , chan_id ) ;
}
need_yield | = _dma2d_default_rx_isr ( group , chan - > channel_id ) ;
}
if ( need_yield ) {
portYIELD_FROM_ISR ( ) ;
}
}
esp_err_t dma2d_acquire_pool ( const dma2d_pool_config_t * config , dma2d_pool_handle_t * ret_pool )
{
esp_err_t ret = ESP_OK ;
ESP_RETURN_ON_FALSE ( config & & ret_pool , ESP_ERR_INVALID_ARG , TAG , " invalid argument " ) ;
ESP_RETURN_ON_FALSE ( config - > pool_id < SOC_DMA2D_GROUPS , ESP_ERR_INVALID_ARG , TAG , " invalid pool_id " ) ;
if ( config - > intr_priority ) {
ESP_RETURN_ON_FALSE ( 1 < < ( config - > intr_priority ) & ESP_INTR_FLAG_LOWMED , ESP_ERR_INVALID_ARG , TAG ,
" invalid interrupt priority: % " PRIu32 , config - > intr_priority ) ;
}
int group_id = config - > pool_id ; // A pool is referring to a module group in hardware
_lock_acquire ( & s_platform . mutex ) ;
if ( ! s_platform . groups [ group_id ] ) {
dma2d_group_t * pre_alloc_group = heap_caps_calloc ( 1 , sizeof ( dma2d_group_t ) , DMA2D_MEM_ALLOC_CAPS ) ;
dma2d_tx_channel_t * pre_alloc_tx_channels = heap_caps_calloc ( SOC_DMA2D_TX_CHANNELS_PER_GROUP , sizeof ( dma2d_tx_channel_t ) , DMA2D_MEM_ALLOC_CAPS ) ;
dma2d_rx_channel_t * pre_alloc_rx_channels = heap_caps_calloc ( SOC_DMA2D_RX_CHANNELS_PER_GROUP , sizeof ( dma2d_rx_channel_t ) , DMA2D_MEM_ALLOC_CAPS ) ;
if ( pre_alloc_group & & pre_alloc_tx_channels & & pre_alloc_rx_channels ) {
pre_alloc_group - > group_id = group_id ;
pre_alloc_group - > spinlock = ( portMUX_TYPE ) portMUX_INITIALIZER_UNLOCKED ;
TAILQ_INIT ( & pre_alloc_group - > pending_trans_tailq ) ;
pre_alloc_group - > tx_channel_free_mask = ( 1 < < SOC_DMA2D_TX_CHANNELS_PER_GROUP ) - 1 ;
pre_alloc_group - > rx_channel_free_mask = ( 1 < < SOC_DMA2D_RX_CHANNELS_PER_GROUP ) - 1 ;
pre_alloc_group - > tx_channel_reserved_mask = dma2d_tx_channel_reserved_mask [ group_id ] ;
pre_alloc_group - > rx_channel_reserved_mask = dma2d_rx_channel_reserved_mask [ group_id ] ;
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pre_alloc_group - > tx_periph_m2m_free_id_mask = DMA2D_LL_TX_CHANNEL_PERIPH_M2M_AVAILABLE_ID_MASK ;
pre_alloc_group - > rx_periph_m2m_free_id_mask = DMA2D_LL_RX_CHANNEL_PERIPH_M2M_AVAILABLE_ID_MASK ;
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pre_alloc_group - > intr_priority = - 1 ;
for ( int i = 0 ; i < SOC_DMA2D_TX_CHANNELS_PER_GROUP ; i + + ) {
pre_alloc_group - > tx_chans [ i ] = & pre_alloc_tx_channels [ i ] ;
dma2d_tx_channel_t * tx_chan = pre_alloc_group - > tx_chans [ i ] ;
tx_chan - > base . group = pre_alloc_group ;
tx_chan - > base . channel_id = i ;
tx_chan - > base . direction = DMA2D_CHANNEL_DIRECTION_TX ;
tx_chan - > base . spinlock = ( portMUX_TYPE ) portMUX_INITIALIZER_UNLOCKED ;
}
for ( int i = 0 ; i < SOC_DMA2D_RX_CHANNELS_PER_GROUP ; i + + ) {
pre_alloc_group - > rx_chans [ i ] = & pre_alloc_rx_channels [ i ] ;
dma2d_rx_channel_t * rx_chan = pre_alloc_group - > rx_chans [ i ] ;
rx_chan - > base . group = pre_alloc_group ;
rx_chan - > base . channel_id = i ;
rx_chan - > base . direction = DMA2D_CHANNEL_DIRECTION_RX ;
rx_chan - > base . spinlock = ( portMUX_TYPE ) portMUX_INITIALIZER_UNLOCKED ;
}
s_platform . groups [ group_id ] = pre_alloc_group ; // register to platform
// Enable bus clock for the 2D-DMA registers
PERIPH_RCC_ATOMIC ( ) {
dma2d_ll_enable_bus_clock ( group_id , true ) ;
dma2d_ll_reset_register ( group_id ) ;
}
dma2d_hal_init ( & pre_alloc_group - > hal , group_id ) ; // initialize HAL context
// Enable 2D-DMA module clock
dma2d_ll_hw_enable ( s_platform . groups [ group_id ] - > hal . dev , true ) ;
} else {
ret = ESP_ERR_NO_MEM ;
free ( pre_alloc_tx_channels ) ;
free ( pre_alloc_rx_channels ) ;
free ( pre_alloc_group ) ;
}
}
// Tracks the number of consumers of 2D-DMA module (clients of the pool)
if ( s_platform . groups [ group_id ] ) {
s_platform . group_ref_counts [ group_id ] + + ;
}
// Allocate interrupts
// First figure out the interrupt priority
bool intr_priority_conflict = false ;
if ( s_platform . groups [ group_id ] - > intr_priority = = - 1 ) {
s_platform . groups [ group_id ] - > intr_priority = config - > intr_priority ;
} else if ( config - > intr_priority ! = 0 ) {
intr_priority_conflict = ( s_platform . groups [ group_id ] - > intr_priority ! = config - > intr_priority ) ;
}
ESP_GOTO_ON_FALSE ( ! intr_priority_conflict , ESP_ERR_INVALID_ARG , wrap_up , TAG , " intr_priority conflict, already is %d but attempt to % " PRIu32 , s_platform . groups [ group_id ] - > intr_priority , config - > intr_priority ) ;
uint32_t intr_flags = DMA2D_INTR_ALLOC_FLAGS ;
if ( s_platform . groups [ group_id ] - > intr_priority ) {
intr_flags | = ( 1 < < s_platform . groups [ group_id ] - > intr_priority ) ;
} else {
intr_flags | = ESP_INTR_FLAG_LOWMED ;
}
// Allocate TX and RX interrupts
if ( s_platform . groups [ group_id ] ) {
for ( int i = 0 ; i < SOC_DMA2D_RX_CHANNELS_PER_GROUP ; i + + ) {
dma2d_rx_channel_t * rx_chan = s_platform . groups [ group_id ] - > rx_chans [ i ] ;
if ( rx_chan - > base . intr = = NULL ) {
ret = esp_intr_alloc_intrstatus ( dma2d_periph_signals . groups [ group_id ] . rx_irq_id [ i ] ,
intr_flags ,
( uint32_t ) dma2d_ll_rx_get_interrupt_status_reg ( s_platform . groups [ group_id ] - > hal . dev , i ) ,
DMA2D_LL_RX_EVENT_MASK , dma2d_default_isr , & rx_chan - > base , & rx_chan - > base . intr ) ;
if ( ret ! = ESP_OK ) {
ret = ESP_FAIL ;
ESP_LOGE ( TAG , " alloc interrupt failed on rx channel (%d, %d) " , group_id , i ) ;
goto wrap_up ;
}
}
}
for ( int i = 0 ; i < SOC_DMA2D_TX_CHANNELS_PER_GROUP ; i + + ) {
dma2d_tx_channel_t * tx_chan = s_platform . groups [ group_id ] - > tx_chans [ i ] ;
if ( tx_chan - > base . intr = = NULL ) {
ret = esp_intr_alloc_intrstatus ( dma2d_periph_signals . groups [ group_id ] . tx_irq_id [ i ] ,
intr_flags ,
( uint32_t ) dma2d_ll_tx_get_interrupt_status_reg ( s_platform . groups [ group_id ] - > hal . dev , i ) ,
DMA2D_LL_TX_EVENT_MASK , dma2d_default_isr , & tx_chan - > base , & tx_chan - > base . intr ) ;
if ( ret ! = ESP_OK ) {
ret = ESP_FAIL ;
ESP_LOGE ( TAG , " alloc interrupt failed on tx channel (%d, %d) " , group_id , i ) ;
goto wrap_up ;
}
}
}
}
wrap_up :
_lock_release ( & s_platform . mutex ) ;
if ( ret ! = ESP_OK & & s_platform . groups [ group_id ] ) {
dma2d_release_pool ( s_platform . groups [ group_id ] ) ;
}
* ret_pool = s_platform . groups [ group_id ] ;
return ret ;
}
esp_err_t dma2d_release_pool ( dma2d_pool_handle_t dma2d_pool )
{
esp_err_t ret = ESP_OK ;
ESP_RETURN_ON_FALSE ( dma2d_pool , ESP_ERR_INVALID_ARG , TAG , " invalid argument " ) ;
dma2d_group_t * dma2d_group = dma2d_pool ;
bool do_deinitialize = false ;
int group_id = dma2d_group - > group_id ;
_lock_acquire ( & s_platform . mutex ) ;
// Remove a client from the 2D-DMA pool
s_platform . group_ref_counts [ group_id ] - - ;
// If the pool has no client, then release pool resources
if ( s_platform . group_ref_counts [ group_id ] = = 0 ) {
assert ( s_platform . groups [ group_id ] ) ;
do_deinitialize = true ;
// There must be no transaction pending (this should be handled by upper (consumer) driver)
// Transaction tailq should be empty at this moment
if ( ! TAILQ_EMPTY ( & dma2d_group - > pending_trans_tailq ) ) {
ret = ESP_ERR_NOT_ALLOWED ;
ESP_LOGE ( TAG , " Still pending transaction in the pool " ) ;
s_platform . group_ref_counts [ group_id ] + + ;
goto err ;
}
s_platform . groups [ group_id ] = NULL ; // deregister from platform
// Disable 2D-DMA module clock
dma2d_ll_hw_enable ( dma2d_group - > hal . dev , false ) ;
// Disable the bus clock for the 2D-DMA registers
PERIPH_RCC_ATOMIC ( ) {
dma2d_ll_enable_bus_clock ( group_id , false ) ;
}
}
if ( do_deinitialize ) {
for ( int i = 0 ; i < SOC_DMA2D_RX_CHANNELS_PER_GROUP ; i + + ) {
if ( dma2d_group - > rx_chans [ i ] - > base . intr ) {
esp_intr_free ( dma2d_group - > rx_chans [ i ] - > base . intr ) ;
}
}
for ( int i = 0 ; i < SOC_DMA2D_TX_CHANNELS_PER_GROUP ; i + + ) {
if ( dma2d_group - > tx_chans [ i ] - > base . intr ) {
esp_intr_free ( dma2d_group - > tx_chans [ i ] - > base . intr ) ;
}
}
free ( * ( dma2d_group - > tx_chans ) ) ;
free ( * ( dma2d_group - > rx_chans ) ) ;
free ( dma2d_group ) ;
s_platform . groups [ group_id ] = NULL ;
}
err :
_lock_release ( & s_platform . mutex ) ;
return ret ;
}
esp_err_t dma2d_connect ( dma2d_channel_handle_t dma2d_chan , const dma2d_trigger_t * trig_periph )
{
esp_err_t ret = ESP_OK ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_chan & & trig_periph , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
int channel_id = dma2d_chan - > channel_id ;
// Find periph_sel_id for the channel
int peri_sel_id = trig_periph - > periph_sel_id ;
2024-03-18 04:47:38 -04:00
uint32_t * periph_m2m_free_id_mask = NULL ;
uint32_t periph_m2m_available_id_mask = 0 ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
periph_m2m_free_id_mask = & group - > tx_periph_m2m_free_id_mask ;
periph_m2m_available_id_mask = DMA2D_LL_TX_CHANNEL_PERIPH_M2M_AVAILABLE_ID_MASK ;
} else {
periph_m2m_free_id_mask = & group - > rx_periph_m2m_free_id_mask ;
periph_m2m_available_id_mask = DMA2D_LL_RX_CHANNEL_PERIPH_M2M_AVAILABLE_ID_MASK ;
}
2023-08-21 05:04:55 -04:00
portENTER_CRITICAL_SAFE ( & group - > spinlock ) ;
if ( trig_periph - > periph = = DMA2D_TRIG_PERIPH_M2M ) {
if ( peri_sel_id = = - 1 ) {
// Unspecified periph_sel_id, decide by the driver
2024-03-18 04:47:38 -04:00
peri_sel_id = __builtin_ctz ( * periph_m2m_free_id_mask ) ;
2023-08-21 05:04:55 -04:00
} else {
// Check whether specified periph_sel_id is valid
2024-03-18 04:47:38 -04:00
if ( ! ( ( 1 < < peri_sel_id ) & * periph_m2m_free_id_mask & periph_m2m_available_id_mask ) ) {
peri_sel_id = - 1 ; // Occupied or invalid m2m peri_sel_id
2023-08-21 05:04:55 -04:00
}
}
}
if ( peri_sel_id > = 0 ) {
dma2d_chan - > status . periph_sel_id = peri_sel_id ;
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* periph_m2m_free_id_mask & = ~ ( 1 < < peri_sel_id ) ; // acquire m2m periph_sel_id
2023-08-21 05:04:55 -04:00
}
portEXIT_CRITICAL_SAFE ( & group - > spinlock ) ;
ESP_GOTO_ON_FALSE_ISR ( peri_sel_id > = 0 , ESP_ERR_INVALID_ARG , err , TAG , " invalid periph_sel_id " ) ;
portENTER_CRITICAL_SAFE ( & dma2d_chan - > spinlock ) ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
dma2d_ll_tx_stop ( group - > hal . dev , channel_id ) ;
dma2d_hal_tx_reset_channel ( & group - > hal , channel_id ) ;
dma2d_ll_tx_connect_to_periph ( group - > hal . dev , channel_id , trig_periph - > periph , peri_sel_id ) ;
// Configure reorder functionality
dma2d_ll_tx_enable_reorder ( group - > hal . dev , channel_id , dma2d_chan - > status . reorder_en ) ;
// Assume dscr_port enable or not can be directly derived from trig_periph
2024-03-04 07:50:29 -05:00
dma2d_ll_tx_enable_dscr_port ( group - > hal . dev , channel_id , trig_periph - > periph = = DMA2D_TRIG_PERIPH_PPA_SRM ) ;
2023-08-21 05:04:55 -04:00
// Reset to certain settings
dma2d_ll_tx_enable_owner_check ( group - > hal . dev , channel_id , false ) ;
dma2d_ll_tx_enable_auto_write_back ( group - > hal . dev , channel_id , false ) ;
dma2d_ll_tx_enable_eof_mode ( group - > hal . dev , channel_id , true ) ;
dma2d_ll_tx_enable_descriptor_burst ( group - > hal . dev , channel_id , false ) ;
dma2d_ll_tx_set_data_burst_length ( group - > hal . dev , channel_id , DMA2D_DATA_BURST_LENGTH_128 ) ;
dma2d_ll_tx_enable_page_bound_wrap ( group - > hal . dev , channel_id , true ) ;
dma2d_ll_tx_set_macro_block_size ( group - > hal . dev , channel_id , DMA2D_MACRO_BLOCK_SIZE_NONE ) ;
if ( ( 1 < < channel_id ) & DMA2D_LL_TX_CHANNEL_SUPPORT_CSC_MASK ) {
dma2d_ll_tx_configure_color_space_conv ( group - > hal . dev , channel_id , DMA2D_CSC_TX_NONE ) ;
}
// Disable and clear all interrupt events
dma2d_ll_tx_enable_interrupt ( group - > hal . dev , channel_id , UINT32_MAX , false ) ; // disable all interrupt events
dma2d_ll_tx_clear_interrupt_status ( group - > hal . dev , channel_id , UINT32_MAX ) ; // clear all pending events
} else {
dma2d_ll_rx_stop ( group - > hal . dev , channel_id ) ;
dma2d_hal_rx_reset_channel ( & group - > hal , channel_id ) ;
dma2d_ll_rx_connect_to_periph ( group - > hal . dev , channel_id , trig_periph - > periph , peri_sel_id ) ;
// Configure reorder functionality
dma2d_ll_rx_enable_reorder ( group - > hal . dev , channel_id , dma2d_chan - > status . reorder_en ) ;
// Assume dscr_port enable or not can be directly derived from trig_periph
2024-03-04 07:50:29 -05:00
dma2d_ll_rx_enable_dscr_port ( group - > hal . dev , channel_id , trig_periph - > periph = = DMA2D_TRIG_PERIPH_PPA_SRM ) ;
2023-08-21 05:04:55 -04:00
// Reset to certain settings
dma2d_ll_rx_enable_owner_check ( group - > hal . dev , channel_id , false ) ;
2024-03-18 04:47:38 -04:00
dma2d_ll_rx_set_auto_return_owner ( group - > hal . dev , channel_id , DMA2D_DESCRIPTOR_BUFFER_OWNER_CPU ) ; // After auto write back, the owner field will be cleared
2023-08-21 05:04:55 -04:00
dma2d_ll_rx_enable_descriptor_burst ( group - > hal . dev , channel_id , false ) ;
dma2d_ll_rx_set_data_burst_length ( group - > hal . dev , channel_id , DMA2D_DATA_BURST_LENGTH_128 ) ;
dma2d_ll_rx_enable_page_bound_wrap ( group - > hal . dev , channel_id , true ) ;
dma2d_ll_rx_set_macro_block_size ( group - > hal . dev , channel_id , DMA2D_MACRO_BLOCK_SIZE_NONE ) ;
if ( ( 1 < < channel_id ) & DMA2D_LL_RX_CHANNEL_SUPPORT_CSC_MASK ) {
dma2d_ll_rx_configure_color_space_conv ( group - > hal . dev , channel_id , DMA2D_CSC_RX_NONE ) ;
}
// Disable and clear all interrupt events
dma2d_ll_rx_enable_interrupt ( group - > hal . dev , channel_id , UINT32_MAX , false ) ; // disable all interrupt events
dma2d_ll_rx_clear_interrupt_status ( group - > hal . dev , channel_id , UINT32_MAX ) ; // clear all pending events
}
portEXIT_CRITICAL_SAFE ( & dma2d_chan - > spinlock ) ;
err :
return ret ;
}
esp_err_t dma2d_register_tx_event_callbacks ( dma2d_channel_handle_t dma2d_chan , dma2d_tx_event_callbacks_t * cbs , void * user_data )
{
esp_err_t ret = ESP_OK ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_chan & & dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX & & cbs , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_chan - > intr , ESP_ERR_INVALID_STATE , err , TAG , " tx channel intr not allocated " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
dma2d_tx_channel_t * tx_chan = __containerof ( dma2d_chan , dma2d_tx_channel_t , base ) ;
# if CONFIG_DMA2D_ISR_IRAM_SAFE
if ( cbs - > on_desc_done ) {
ESP_GOTO_ON_FALSE_ISR ( esp_ptr_in_iram ( cbs - > on_desc_done ) ,
ESP_ERR_INVALID_ARG , err , TAG , " on_desc_done not in IRAM " ) ;
}
if ( user_data ) {
ESP_GOTO_ON_FALSE_ISR ( esp_ptr_internal ( user_data ) ,
ESP_ERR_INVALID_ARG , err , TAG , " user context not in internal RAM " ) ;
}
# endif
// Enable/Disable 2D-DMA interrupt events for the TX channel
uint32_t mask = 0 ;
portENTER_CRITICAL_SAFE ( & tx_chan - > base . spinlock ) ;
if ( cbs - > on_desc_done ) {
tx_chan - > on_desc_done = cbs - > on_desc_done ;
mask | = DMA2D_LL_EVENT_TX_DONE ;
}
tx_chan - > user_data = user_data ;
dma2d_ll_tx_enable_interrupt ( group - > hal . dev , tx_chan - > base . channel_id , mask , true ) ;
portEXIT_CRITICAL_SAFE ( & tx_chan - > base . spinlock ) ;
err :
return ret ;
}
esp_err_t dma2d_register_rx_event_callbacks ( dma2d_channel_handle_t dma2d_chan , dma2d_rx_event_callbacks_t * cbs , void * user_data )
{
esp_err_t ret = ESP_OK ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_chan & & dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_RX & & cbs , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
dma2d_rx_channel_t * rx_chan = __containerof ( dma2d_chan , dma2d_rx_channel_t , base ) ;
# if CONFIG_DMA2D_ISR_IRAM_SAFE
if ( cbs - > on_recv_eof ) {
ESP_GOTO_ON_FALSE_ISR ( esp_ptr_in_iram ( cbs - > on_recv_eof ) ,
ESP_ERR_INVALID_ARG , err , TAG , " on_recv_eof not in IRAM " ) ;
}
if ( cbs - > on_desc_done ) {
ESP_GOTO_ON_FALSE_ISR ( esp_ptr_in_iram ( cbs - > on_desc_done ) ,
ESP_ERR_INVALID_ARG , err , TAG , " on_desc_done not in IRAM " ) ;
}
if ( user_data ) {
ESP_GOTO_ON_FALSE_ISR ( esp_ptr_internal ( user_data ) ,
ESP_ERR_INVALID_ARG , err , TAG , " user context not in internal RAM " ) ;
}
# endif
// Enable/Disable 2D-DMA interrupt events for the RX channel
uint32_t mask = 0 ;
portENTER_CRITICAL_SAFE ( & rx_chan - > base . spinlock ) ;
if ( cbs - > on_recv_eof ) {
rx_chan - > on_recv_eof = cbs - > on_recv_eof ;
mask | = DMA2D_LL_EVENT_RX_SUC_EOF ;
}
if ( cbs - > on_desc_done ) {
rx_chan - > on_desc_done = cbs - > on_desc_done ;
mask | = DMA2D_LL_EVENT_RX_DONE ;
}
rx_chan - > user_data = user_data ;
dma2d_ll_rx_enable_interrupt ( group - > hal . dev , rx_chan - > base . channel_id , mask , true ) ;
portEXIT_CRITICAL_SAFE ( & rx_chan - > base . spinlock ) ;
err :
return ret ;
}
esp_err_t dma2d_set_desc_addr ( dma2d_channel_handle_t dma2d_chan , intptr_t desc_base_addr )
{
esp_err_t ret = ESP_OK ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_chan & & desc_base_addr , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
// 2D-DMA descriptor addr needs 8-byte alignment and not in TCM (addr not in TCM is IDF restriction)
ESP_GOTO_ON_FALSE_ISR ( ( desc_base_addr & 0x7 ) = = 0 & & ! esp_ptr_in_tcm ( ( void * ) desc_base_addr ) , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
int channel_id = dma2d_chan - > channel_id ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
dma2d_ll_tx_set_desc_addr ( group - > hal . dev , channel_id , desc_base_addr ) ;
} else {
dma2d_ll_rx_set_desc_addr ( group - > hal . dev , channel_id , desc_base_addr ) ;
}
err :
return ret ;
}
esp_err_t dma2d_start ( dma2d_channel_handle_t dma2d_chan )
{
esp_err_t ret = ESP_OK ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_chan , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
int channel_id = dma2d_chan - > channel_id ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_RX ) {
// dma2d driver relies on going into ISR to free the channels,
// so even if callbacks are not necessary in some cases, minimum interrupt events should be enabled to trigger ISR
dma2d_ll_rx_enable_interrupt ( group - > hal . dev , channel_id , DMA2D_RX_DEFAULT_INTR_FLAG , true ) ;
}
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
assert ( dma2d_ll_tx_is_fsm_idle ( group - > hal . dev , channel_id ) ) ;
dma2d_ll_tx_start ( group - > hal . dev , channel_id ) ;
} else {
assert ( dma2d_ll_rx_is_fsm_idle ( group - > hal . dev , channel_id ) ) ;
dma2d_ll_rx_start ( group - > hal . dev , channel_id ) ;
}
err :
return ret ;
}
esp_err_t dma2d_stop ( dma2d_channel_handle_t dma2d_chan )
{
ESP_RETURN_ON_FALSE_ISR ( dma2d_chan , ESP_ERR_INVALID_ARG , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
int channel_id = dma2d_chan - > channel_id ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
dma2d_ll_tx_stop ( group - > hal . dev , channel_id ) ;
} else {
dma2d_ll_rx_stop ( group - > hal . dev , channel_id ) ;
}
return ESP_OK ;
}
esp_err_t dma2d_append ( dma2d_channel_handle_t dma2d_chan )
{
ESP_RETURN_ON_FALSE_ISR ( dma2d_chan , ESP_ERR_INVALID_ARG , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
int channel_id = dma2d_chan - > channel_id ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
dma2d_ll_tx_restart ( group - > hal . dev , channel_id ) ;
} else {
dma2d_ll_rx_restart ( group - > hal . dev , channel_id ) ;
}
return ESP_OK ;
}
esp_err_t dma2d_reset ( dma2d_channel_handle_t dma2d_chan )
{
ESP_RETURN_ON_FALSE_ISR ( dma2d_chan , ESP_ERR_INVALID_ARG , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
int channel_id = dma2d_chan - > channel_id ;
portENTER_CRITICAL_SAFE ( & dma2d_chan - > spinlock ) ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
dma2d_hal_tx_reset_channel ( & group - > hal , channel_id ) ;
} else {
dma2d_hal_rx_reset_channel ( & group - > hal , channel_id ) ;
}
portEXIT_CRITICAL_SAFE ( & dma2d_chan - > spinlock ) ;
return ESP_OK ;
}
esp_err_t dma2d_apply_strategy ( dma2d_channel_handle_t dma2d_chan , const dma2d_strategy_config_t * config )
{
esp_err_t ret = ESP_OK ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_chan & & config , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
int channel_id = dma2d_chan - > channel_id ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
dma2d_ll_tx_enable_owner_check ( group - > hal . dev , channel_id , config - > owner_check ) ;
dma2d_ll_tx_enable_auto_write_back ( group - > hal . dev , channel_id , config - > auto_update_desc ) ;
dma2d_ll_tx_enable_eof_mode ( group - > hal . dev , channel_id , config - > eof_till_data_popped ) ;
} else {
dma2d_ll_rx_enable_owner_check ( group - > hal . dev , channel_id , config - > owner_check ) ;
// RX channels do not have control over auto_write_back (always auto_write_back) and eof_mode
}
err :
return ret ;
}
esp_err_t dma2d_set_transfer_ability ( dma2d_channel_handle_t dma2d_chan , const dma2d_transfer_ability_t * ability )
{
esp_err_t ret = ESP_OK ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_chan & & ability , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
ESP_GOTO_ON_FALSE_ISR ( ability - > data_burst_length < DMA2D_DATA_BURST_LENGTH_INVALID , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
ESP_GOTO_ON_FALSE_ISR ( ability - > mb_size < DMA2D_MACRO_BLOCK_SIZE_INVALID , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
int channel_id = dma2d_chan - > channel_id ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
dma2d_ll_tx_enable_descriptor_burst ( group - > hal . dev , channel_id , ability - > desc_burst_en ) ;
dma2d_ll_tx_set_data_burst_length ( group - > hal . dev , channel_id , ability - > data_burst_length ) ;
dma2d_ll_tx_set_macro_block_size ( group - > hal . dev , channel_id , ability - > mb_size ) ;
} else {
dma2d_ll_rx_enable_descriptor_burst ( group - > hal . dev , channel_id , ability - > desc_burst_en ) ;
dma2d_ll_rx_set_data_burst_length ( group - > hal . dev , channel_id , ability - > data_burst_length ) ;
dma2d_ll_rx_set_macro_block_size ( group - > hal . dev , channel_id , ability - > mb_size ) ;
}
err :
return ret ;
}
esp_err_t dma2d_configure_color_space_conversion ( dma2d_channel_handle_t dma2d_chan , const dma2d_csc_config_t * config )
{
esp_err_t ret = ESP_OK ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_chan & & config , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
int channel_id = dma2d_chan - > channel_id ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
ESP_GOTO_ON_FALSE_ISR ( ( 1 < < channel_id ) & DMA2D_LL_TX_CHANNEL_SUPPORT_CSC_MASK , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
ESP_GOTO_ON_FALSE_ISR ( config - > tx_csc_option < DMA2D_CSC_TX_INVALID , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
ESP_GOTO_ON_FALSE_ISR ( config - > post_scramble = = 0 , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
ESP_GOTO_ON_FALSE_ISR ( config - > pre_scramble = = DMA2D_SCRAMBLE_ORDER_BYTE2_1_0 | | ( config - > pre_scramble ! = DMA2D_SCRAMBLE_ORDER_BYTE2_1_0 & & config - > tx_csc_option ! = DMA2D_CSC_TX_NONE ) ,
ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_ll_tx_configure_color_space_conv ( group - > hal . dev , channel_id , config - > tx_csc_option ) ;
dma2d_ll_tx_set_csc_pre_scramble ( group - > hal . dev , channel_id , config - > pre_scramble ) ;
} else {
ESP_GOTO_ON_FALSE_ISR ( ( 1 < < channel_id ) & DMA2D_LL_RX_CHANNEL_SUPPORT_CSC_MASK , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
ESP_GOTO_ON_FALSE_ISR ( config - > rx_csc_option < DMA2D_CSC_RX_INVALID , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
ESP_GOTO_ON_FALSE_ISR ( ( config - > pre_scramble = = DMA2D_SCRAMBLE_ORDER_BYTE2_1_0 & & config - > post_scramble = = DMA2D_SCRAMBLE_ORDER_BYTE2_1_0 ) | |
( ( config - > pre_scramble ! = DMA2D_SCRAMBLE_ORDER_BYTE2_1_0 | | config - > post_scramble ! = DMA2D_SCRAMBLE_ORDER_BYTE2_1_0 ) & & config - > rx_csc_option ! = DMA2D_CSC_RX_NONE ) ,
ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_ll_rx_configure_color_space_conv ( group - > hal . dev , channel_id , config - > rx_csc_option ) ;
dma2d_ll_rx_set_csc_pre_scramble ( group - > hal . dev , channel_id , config - > pre_scramble ) ;
dma2d_ll_rx_set_csc_post_scramble ( group - > hal . dev , channel_id , config - > post_scramble ) ;
}
err :
return ret ;
}
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esp_err_t dma2d_configure_dscr_port_mode ( dma2d_channel_handle_t dma2d_chan , const dma2d_dscr_port_mode_config_t * config )
{
esp_err_t ret = ESP_OK ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_chan & & config , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_group_t * group = dma2d_chan - > group ;
int channel_id = dma2d_chan - > channel_id ;
if ( dma2d_chan - > direction = = DMA2D_CHANNEL_DIRECTION_TX ) {
ESP_GOTO_ON_FALSE_ISR ( config - > block_h > 0 & & config - > block_v > 0 , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
dma2d_ll_tx_set_dscr_port_block_size ( group - > hal . dev , channel_id , config - > block_h , config - > block_v ) ;
}
err :
return ret ;
}
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esp_err_t dma2d_enqueue ( dma2d_pool_handle_t dma2d_pool , const dma2d_trans_config_t * trans_desc , dma2d_trans_t * trans_placeholder )
{
esp_err_t ret = ESP_OK ;
ESP_GOTO_ON_FALSE_ISR ( dma2d_pool & & trans_desc & & trans_placeholder , ESP_ERR_INVALID_ARG , err , TAG , " invalid argument " ) ;
ESP_GOTO_ON_FALSE_ISR ( trans_desc - > rx_channel_num < = 1 , ESP_ERR_INVALID_ARG , err , TAG , " one trans at most has one rx channel " ) ;
uint32_t total_channel_num = trans_desc - > tx_channel_num + trans_desc - > rx_channel_num ;
ESP_GOTO_ON_FALSE_ISR ( total_channel_num < = DMA2D_MAX_CHANNEL_NUM_PER_TRANSACTION , ESP_ERR_INVALID_ARG , err , TAG , " too many channels acquiring for a trans " ) ;
dma2d_group_t * dma2d_group = dma2d_pool ;
if ( trans_desc - > specified_tx_channel_mask | | trans_desc - > specified_rx_channel_mask ) {
ESP_GOTO_ON_FALSE_ISR (
( trans_desc - > specified_tx_channel_mask ? ( trans_desc - > specified_tx_channel_mask & dma2d_group - > tx_channel_reserved_mask ) : 1 ) & &
( trans_desc - > specified_rx_channel_mask ? ( trans_desc - > specified_rx_channel_mask & dma2d_group - > rx_channel_reserved_mask ) : 1 ) ,
ESP_ERR_INVALID_ARG , err , TAG , " specified channel(s) not reserved " ) ;
ESP_GOTO_ON_FALSE_ISR (
( __builtin_popcount ( trans_desc - > specified_tx_channel_mask ) = = trans_desc - > tx_channel_num ) & &
( __builtin_popcount ( trans_desc - > specified_rx_channel_mask ) = = trans_desc - > rx_channel_num ) & &
( ! trans_desc - > tx_channel_num ? 1 : ( trans_desc - > specified_tx_channel_mask & ( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_TX_REORDER ) ? DMA2D_LL_TX_CHANNEL_SUPPORT_RO_MASK : UINT32_MAX ) & ( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_TX_CSC ) ? DMA2D_LL_TX_CHANNEL_SUPPORT_CSC_MASK : UINT32_MAX ) ) ) & &
( ! trans_desc - > rx_channel_num ? 1 : ( trans_desc - > specified_rx_channel_mask & ( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_RX_REORDER ) ? DMA2D_LL_RX_CHANNEL_SUPPORT_RO_MASK : UINT32_MAX ) & ( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_RX_CSC ) ? DMA2D_LL_RX_CHANNEL_SUPPORT_CSC_MASK : UINT32_MAX ) ) ) & &
( ( trans_desc - > channel_flags & DMA2D_CHANNEL_FUNCTION_FLAG_SIBLING ) ? ( trans_desc - > specified_tx_channel_mask = = trans_desc - > specified_rx_channel_mask ) : 1 ) ,
ESP_ERR_INVALID_ARG , err , TAG , " specified channels cannot meet function requirements " ) ;
}
# if CONFIG_DMA2D_ISR_IRAM_SAFE
ESP_GOTO_ON_FALSE_ISR ( trans_desc - > on_job_picked & & esp_ptr_in_iram ( trans_desc - > on_job_picked ) ,
ESP_ERR_INVALID_ARG , err , TAG , " on_job_picked not in IRAM " ) ;
ESP_GOTO_ON_FALSE_ISR ( trans_desc - > user_config & & esp_ptr_internal ( trans_desc - > user_config ) ,
ESP_ERR_INVALID_ARG , err , TAG , " user context not in internal RAM " ) ;
# endif
trans_placeholder - > desc = trans_desc ;
dma2d_trans_channel_info_t channel_handle_array [ DMA2D_MAX_CHANNEL_NUM_PER_TRANSACTION ] ;
portENTER_CRITICAL_SAFE ( & dma2d_group - > spinlock ) ;
bool enqueue = ! acquire_free_channels_for_trans ( dma2d_group , trans_desc , channel_handle_array ) ;
if ( enqueue ) {
if ( ! trans_desc - > specified_tx_channel_mask & & ! trans_desc - > specified_rx_channel_mask ) {
TAILQ_INSERT_TAIL ( & dma2d_group - > pending_trans_tailq , trans_placeholder , entry ) ;
} else {
TAILQ_INSERT_HEAD ( & dma2d_group - > pending_trans_tailq , trans_placeholder , entry ) ;
}
}
portEXIT_CRITICAL_SAFE ( & dma2d_group - > spinlock ) ;
if ( ! enqueue ) {
// Free channels available, start transaction immediately
// Store the acquired rx_chan into trans_placeholder (dma2d_trans_t) in case upper driver later need it to call `dma2d_force_end`
// Upper driver controls the life cycle of trans_placeholder
for ( int i = 0 ; i < total_channel_num ; i + + ) {
if ( channel_handle_array [ i ] . dir = = DMA2D_CHANNEL_DIRECTION_RX ) {
trans_placeholder - > rx_chan = channel_handle_array [ i ] . chan ;
}
// Also save the transaction pointer
channel_handle_array [ i ] . chan - > status . transaction = trans_placeholder ;
}
trans_desc - > on_job_picked ( total_channel_num , channel_handle_array , trans_desc - > user_config ) ;
}
err :
return ret ;
}
esp_err_t dma2d_force_end ( dma2d_trans_t * trans , bool * need_yield )
{
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ESP_RETURN_ON_FALSE_ISR ( trans & & trans - > rx_chan & & need_yield , ESP_ERR_INVALID_ARG , TAG , " invalid argument " ) ;
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assert ( trans - > rx_chan - > direction = = DMA2D_CHANNEL_DIRECTION_RX ) ;
dma2d_group_t * group = trans - > rx_chan - > group ;
bool in_flight = false ;
// We judge whether the transaction is in-flight by checking the RX channel it uses is in-use or free
portENTER_CRITICAL_SAFE ( & group - > spinlock ) ;
if ( ! ( group - > rx_channel_free_mask & ( 1 < < trans - > rx_chan - > channel_id ) ) ) {
in_flight = true ;
dma2d_ll_rx_enable_interrupt ( group - > hal . dev , trans - > rx_chan - > channel_id , UINT32_MAX , false ) ;
assert ( ! dma2d_ll_rx_is_fsm_idle ( group - > hal . dev , trans - > rx_chan - > channel_id ) ) ;
}
portEXIT_CRITICAL_SAFE ( & group - > spinlock ) ;
ESP_RETURN_ON_FALSE_ISR ( in_flight , ESP_ERR_INVALID_STATE , TAG , " transaction not in-flight " ) ;
dma2d_rx_channel_t * rx_chan = group - > rx_chans [ trans - > rx_chan - > channel_id ] ;
// Stop the RX channel and its bundled TX channels first
dma2d_stop ( & rx_chan - > base ) ;
uint32_t tx_chans = rx_chan - > bundled_tx_channel_mask ;
for ( int i = 0 ; i < SOC_DMA2D_TX_CHANNELS_PER_GROUP ; i + + ) {
if ( tx_chans & ( 1 < < i ) ) {
dma2d_stop ( & group - > tx_chans [ i ] - > base ) ;
}
}
// Then release channels
* need_yield = free_up_channels ( group , rx_chan ) ;
return ESP_OK ;
}
size_t dma2d_get_trans_elm_size ( void )
{
return sizeof ( dma2d_trans_t ) ;
}