Merge branch 'add-spi'

7 years ago · 766cfdba06
parent 645619e9c5 b5d9d146f9
commit 766cfdba06
24 changed files with 1090 additions and 265 deletions
--- a/comm/msg_bulkread.c
+++ b/comm/msg_bulkread.c
@ -11,7 +11,7 @@
 #include "utils/payload_builder.h"
 /** Buffer for preparing bulk chunks */
-static uint8_t bulkread_buffer[BULKREAD_MAX_CHUNK];
+static uint8_t bulkread_buffer[BULK_READ_BUF_LEN];
 /**
 * TF listener for the bulk read transaction
@ -36,7 +36,7 @@ static TF_Result bulkread_lst(TinyFrame *tf, TF_Msg *msg)
        uint32_t chunk = pp_u32(&pp);
        chunk = MIN(chunk, bulk->len - bulk->offset);
-        chunk = MIN(chunk, BULKREAD_MAX_CHUNK);
+        chunk = MIN(chunk, BULK_READ_BUF_LEN);
        // load data into the buffer
        bulk->read(bulk, chunk, bulkread_buffer);
@ -81,7 +81,7 @@ void bulkread_start(TinyFrame *tf, BulkRead *bulk)
        uint8_t buf[8];
        PayloadBuilder pb = pb_start(buf, 4, NULL);
        pb_u32(&pb, bulk->len);
-        pb_u32(&pb, BULKREAD_MAX_CHUNK);
+        pb_u32(&pb, BULK_READ_BUF_LEN);
        // We use userdata1 to hold a reference to the bulk transfer
        TF_Msg msg = {
--- a/framework/resources.c
+++ b/framework/resources.c
@ -6,32 +6,57 @@
 #include "unit.h"
 #include "resources.h"
 #include "pin_utils.h"
 #include "unit_registry.h"
 static bool rsc_initialized = false;
-// This takes quite a lot of space, we could use u8 and IDs instead if needed
+static ResourceMap global_rscmap;
 struct resouce_slot {
    const char *name;
    Unit *owner;
 } __attribute__((packed));
-static struct resouce_slot resources[R_RESOURCE_COUNT];
+// here are the resource names for better debugging
-// here are the resource names for better debugging (could also be removed if absolutely necessary)
+// this list doesn't include GPIO names, they can be easily generated
 const char *const rsc_names[] = {
 #define X(res_name) #res_name,
    XX_RESOURCES
 #undef X
 };
 /** Get rsc name */
 const char * rsc_get_name(Resource rsc)
 {
    assert_param(rsc < RESOURCE_COUNT);
    static char gpionamebuf[4];
    if (rsc >= R_PA0) {
        // we assume the returned value is not stored anywhere
        // and is directly used in a sprintf call.
        uint8_t index = rsc - R_PA0;
        SNPRINTF(gpionamebuf, 4, "%c%d", 'A'+(index/16), index%16);
        return gpionamebuf;
    }
    return rsc_names[rsc];
 }
 /** Get rsc owner name */
 const char * rsc_get_owner_name(Resource rsc)
 {
    assert_param(rsc < RESOURCE_COUNT);
    Unit *pUnit = ureg_get_rsc_owner(rsc);
    if (pUnit == NULL) return "NULL";
    return pUnit->name;
 }
 /**
 * Initialize the resources registry
 */
 void rsc_init_registry(void)
 {
-    for (int i = 0; i < R_RESOURCE_COUNT; i++) {
+    for(uint32_t i = 0; i < RSCMAP_LEN; i++) {
-        resources[i].owner = &UNIT_PLATFORM;
+        UNIT_PLATFORM.resources[i] = global_rscmap[i] = 0xFF;
    }
    rsc_initialized = true;
 }
@ -45,18 +70,31 @@ void rsc_init_registry(void)
 error_t rsc_claim(Unit *unit, Resource rsc)
 {
    assert_param(rsc_initialized);
-    assert_param(rsc > R_NONE && rsc < R_RESOURCE_COUNT);
+    assert_param(rsc < RESOURCE_COUNT);
    assert_param(unit != NULL);
-    if (resources[rsc].owner) {
+    dbg("%s claims %s", unit->name, rsc_get_name(rsc));
-        //TODO properly report to user
+
    if (RSC_IS_HELD(global_rscmap, rsc)) {
        // this whole branch is just reporting the error
        Unit *holder = ureg_get_rsc_owner(rsc);
        assert_param(holder != NULL);
        dbg("ERROR!! Unit %s failed to claim resource %s, already held by %s!",
-            unit->name, rsc_names[rsc], resources[rsc].owner->name);
+            unit->name,
            rsc_get_name(rsc),
            holder->name);
        unit->failed_rsc = rsc;
        return E_RESOURCE_NOT_AVAILABLE;
    }
-    resources[rsc].owner = unit;
+    // must claim both in global and in unit
    RSC_CLAIM(global_rscmap, rsc);
    RSC_CLAIM(unit->resources, rsc);
    return E_SUCCESS;
 }
@ -71,8 +109,9 @@ error_t rsc_claim(Unit *unit, Resource rsc)
 error_t rsc_claim_range(Unit *unit, Resource rsc0, Resource rsc1)
 {
    assert_param(rsc_initialized);
-    assert_param(rsc0 > R_NONE && rsc0 < R_RESOURCE_COUNT);
+    assert_param(rsc0 < RESOURCE_COUNT);
-    assert_param(rsc1 > R_NONE && rsc1 < R_RESOURCE_COUNT);
+    assert_param(rsc1 < RESOURCE_COUNT);
    assert_param(rsc0 <= rsc1);
    assert_param(unit != NULL);
    for (int i = rsc0; i <= rsc1; i++) {
@ -97,6 +136,15 @@ error_t rsc_claim_gpios(Unit *unit, char port_name, uint16_t pins)
    return E_SUCCESS;
 }
 error_t rsc_claim_pin(Unit *unit, char port_name, uint8_t pin)
 {
    bool suc = true;
    Resource rsc = pin2resource(port_name,  pin, &suc);
    if (!suc) return E_BAD_CONFIG;
    TRY(rsc_claim(unit, rsc));
    return E_SUCCESS;
 }
 /**
 * Free a resource for other use
 *
@ -106,11 +154,31 @@ error_t rsc_claim_gpios(Unit *unit, char port_name, uint16_t pins)
 void rsc_free(Unit *unit, Resource rsc)
 {
    assert_param(rsc_initialized);
-    assert_param(rsc > R_NONE && rsc < R_RESOURCE_COUNT);
+    assert_param(rsc < RESOURCE_COUNT);
    dbg("Free resource %s", rsc_get_name(rsc));
    if (RSC_IS_FREE(global_rscmap, rsc)) return;
-    if (unit == NULL || resources[rsc].owner == unit) {
+    // free it in any unit that holds it
-        resources[rsc].owner = NULL;
+    if (unit) {
        if (RSC_IS_HELD(unit->resources, rsc)) {
            RSC_FREE(unit->resources, rsc);
        }
    } else {
        // Try to free it in any unit that may hold it
        unit = ureg_get_rsc_owner(rsc);
        if (unit == NULL) {
            // try one of the built-in ones
            if (RSC_IS_HELD(UNIT_SYSTEM.resources, rsc)) unit = &UNIT_SYSTEM;
            else if (RSC_IS_HELD(UNIT_PLATFORM.resources, rsc)) unit = &UNIT_PLATFORM;
        }
        if (unit != NULL) RSC_FREE(unit->resources, rsc);
    }
    // also free it in the global map
    RSC_FREE(global_rscmap, rsc);
 }
 /**
@ -123,18 +191,18 @@ void rsc_free(Unit *unit, Resource rsc)
 void rsc_free_range(Unit *unit, Resource rsc0, Resource rsc1)
 {
    assert_param(rsc_initialized);
-    assert_param(rsc0 > R_NONE && rsc0 < R_RESOURCE_COUNT);
+    assert_param(rsc0 < RESOURCE_COUNT);
-    assert_param(rsc1 > R_NONE && rsc1 < R_RESOURCE_COUNT);
+    assert_param(rsc1 < RESOURCE_COUNT);
    assert_param(rsc0 <= rsc1);
    for (int i = rsc0; i <= rsc1; i++) {
-        if (unit == NULL || resources[i].owner == unit) {
+        rsc_free(unit, (Resource) i);
            resources[i].owner = NULL;
        }
    }
 }
 /**
- * Tear down a unit - release all resources owned by the unit
+ * Tear down a unit - release all resources owned by the unit.
 * Also de-init all GPIOs
 *
 * @param unit - unit to tear down; free only resources claimed by this unit
 */
@ -143,9 +211,11 @@ void rsc_teardown(Unit *unit)
    assert_param(rsc_initialized);
    assert_param(unit != NULL);
-    for (int i = R_NONE+1; i < R_RESOURCE_COUNT; i++) {
+    dbg("Tearing down unit %s", unit->name);
-        if (resources[i].owner == unit) {
+    deinit_unit_pins(unit);
-            resources[i].owner = NULL;
+
-        }
+    for (uint32_t i = 0; i < RSCMAP_LEN; i++) {
        global_rscmap[i] &= ~unit->resources[i];
        unit->resources[i] = 0;
    }
 }
--- a/framework/resources.h
+++ b/framework/resources.h
@ -7,80 +7,13 @@
 #include "platform.h"
 #include "unit.h"
 #include "rsc_enum.h"
 #define CHECK_SUC() do { if (!suc) return false; } while (0)
 // X macro: Resource name,
 #define XX_RESOURCES \
    X(NONE) \
    X(PA0) X(PA1) X(PA2) X(PA3) X(PA4) X(PA5) X(PA6) X(PA7) \
    X(PA8) X(PA9) X(PA10) X(PA11) X(PA12) X(PA13) X(PA14) X(PA15) \
    X(PB0) X(PB1) X(PB2) X(PB3) X(PB4) X(PB5) X(PB6) X(PB7) \
    X(PB8) X(PB9) X(PB10) X(PB11) X(PB12) X(PB13) X(PB14) X(PB15) \
    X(PC0) X(PC1) X(PC2) X(PC3) X(PC4) X(PC5) X(PC6) X(PC7) \
    X(PC8) X(PC9) X(PC10) X(PC11) X(PC12) X(PC13) X(PC14) X(PC15) \
    X(PD0) X(PD1) X(PD2) X(PD3) X(PD4) X(PD5) X(PD6) X(PD7) \
    X(PD8) X(PD9) X(PD10) X(PD11) X(PD12) X(PD13) X(PD14) X(PD15) \
    X(PE0) X(PE1) X(PE2) X(PE3) X(PE4) X(PE5) X(PE6) X(PE7) \
    X(PE8) X(PE9) X(PE10) X(PE11) X(PE12) X(PE13) X(PE14) X(PE15) \
    X(PF0) X(PF1) X(PF2) X(PF3) X(PF4) X(PF5) X(PF6) X(PF7) \
    X(PF8) X(PF9) X(PF10) X(PF11) X(PF12) X(PF13) X(PF14) X(PF15) \
    X(SPI1) X(SPI2) X(SPI3) \
    X(I2C1) X(I2C2) X(I2C3) \
    X(I2S1) X(I2S2) X(I2S3) \
    X(ADC1) X(ADC2) X(ADC3) X(ADC4) \
    X(OPAMP1) X(OPAMP2) X(OPAMP3) X(OPAMP4) \
    X(DAC1) X(DAC2) \
    X(CAN1) X(CAN2) \
    X(TSC) \
    X(DCMI) \
    X(ETH) \
    X(FSMC) \
    X(SDIO) \
    X(COMP1) X(COMP2) X(COMP3) X(COMP4) X(COMP5) X(COMP6) X(COMP7) \
    X(HDMI_CEC) \
    X(USART1) X(USART2) X(USART3) X(USART4) X(USART5) X(USART6) \
    X(TIM1) X(TIM2) X(TIM3) X(TIM4) X(TIM5) \
    X(TIM6) X(TIM7) X(TIM8) X(TIM9) X(TIM10) X(TIM11) X(TIM12) X(TIM13) X(TIM14) \
    X(TIM15) X(TIM16) X(TIM17) \
    X(DMA1) X(DMA2) \
    X(RNG) X(LCD)
 // GPIOs are allocated whenever the pin is needed
 //  (e.g. when used for SPI, the R_SPI resource as well as the corresponding R_GPIO resources must be claimed)
 // Peripheral blocks (IPs) - not all chips have all blocks, usually the 1 and 2 are present as a minimum, if any.
 //  It doesn't really make sense to expose multiple instances of buses that support addressing
 // ADCs - some more advanced chips support differential input mode on some (not all!) inputs
 //  Usually only one or two instances are present
 // DAC - often only one is present, or none.
 // UARTs
 //  - 1 and 2 are present universally, 2 is connected to VCOM on Nucleo/Discovery boards, good for debug messages
 //  4 and 5 don't support synchronous mode.
 // Timers
 //  - some support quadrature input, probably all support external clock / gating / clock-out/PWM generation
 //  Not all chips have all timers and not all timers are equal.
 // DMA - Direct memory access lines - TODO split those to channels, they can be used separately
 // The resource registry will be pre-loaded with platform-specific config of which blocks are available - the rest will be "pre-claimed"
 // (i.e. unavailable to functional modules)
 typedef enum hw_resource Resource;
 enum hw_resource {
 #define X(res_name) R_##res_name,
    XX_RESOURCES
 #undef X
    R_RESOURCE_COUNT
 };
 void rsc_init_registry(void);
 error_t rsc_claim_pin(Unit *unit, char port_name, uint8_t pin);
 error_t rsc_claim(Unit *unit, Resource rsc);
 error_t rsc_claim_range(Unit *unit, Resource rsc0, Resource rsc1);
 /**
@ -98,4 +31,9 @@ void rsc_teardown(Unit *unit);
 void rsc_free(Unit *unit, Resource rsc);
 void rsc_free_range(Unit *unit, Resource rsc0, Resource rsc1);
 const char * rsc_get_name(Resource rsc);
 /** Get rsc owner name */
 const char * rsc_get_owner_name(Resource rsc);
 #endif //GEX_RESOURCES_H
--- a/framework/rsc_enum.h
+++ b/framework/rsc_enum.h
@ -0,0 +1,92 @@
 //
 // Created by MightyPork on 2018/01/06.
 //
 #ifndef GEX_F072_RSC_ENUM_H
 #define GEX_F072_RSC_ENUM_H
 // X macro: Resource name,
 #define XX_RESOURCES \
    X(SPI1) X(SPI2) X(SPI3) \
    X(I2C1) X(I2C2) X(I2C3) \
    X(ADC1) X(ADC2) X(ADC3) X(ADC4) \
    X(DAC1) X(DAC2) \
    X(USART1) X(USART2) X(USART3) X(USART4) X(USART5) X(USART6) \
    X(TIM1) X(TIM2) X(TIM3) X(TIM4) X(TIM5) \
    X(TIM6) X(TIM7) X(TIM8) X(TIM9) X(TIM10) X(TIM11) X(TIM12) X(TIM13) X(TIM14) \
    X(TIM15) X(TIM16) X(TIM17) \
    X(DMA1) X(DMA2)
 // Resources not used anywhere:
 // X(I2S1) X(I2S2) X(I2S3)
 // X(OPAMP1) X(OPAMP2) X(OPAMP3) X(OPAMP4)
 // X(CAN1) X(CAN2)
 // X(TSC)
 // X(DCMI)
 // X(ETH)
 // X(FSMC)
 // X(SDIO)
 // X(RNG) X(LCD)
 // X(HDMI_CEC)
 // X(COMP1) X(COMP2) X(COMP3) X(COMP4) X(COMP5) X(COMP6) X(COMP7)
 #define XX_RESOURCES_GPIO \
    X(PA0) X(PA1) X(PA2) X(PA3) X(PA4) X(PA5) X(PA6) X(PA7) \
    X(PA8) X(PA9) X(PA10) X(PA11) X(PA12) X(PA13) X(PA14) X(PA15) \
    X(PB0) X(PB1) X(PB2) X(PB3) X(PB4) X(PB5) X(PB6) X(PB7) \
    X(PB8) X(PB9) X(PB10) X(PB11) X(PB12) X(PB13) X(PB14) X(PB15) \
    X(PC0) X(PC1) X(PC2) X(PC3) X(PC4) X(PC5) X(PC6) X(PC7) \
    X(PC8) X(PC9) X(PC10) X(PC11) X(PC12) X(PC13) X(PC14) X(PC15) \
    X(PD0) X(PD1) X(PD2) X(PD3) X(PD4) X(PD5) X(PD6) X(PD7) \
    X(PD8) X(PD9) X(PD10) X(PD11) X(PD12) X(PD13) X(PD14) X(PD15) \
    X(PE0) X(PE1) X(PE2) X(PE3) X(PE4) X(PE5) X(PE6) X(PE7) \
    X(PE8) X(PE9) X(PE10) X(PE11) X(PE12) X(PE13) X(PE14) X(PE15) \
    X(PF0) X(PF1) X(PF2) X(PF3) X(PF4) X(PF5) X(PF6) X(PF7) \
    X(PF8) X(PF9) X(PF10) X(PF11) X(PF12) X(PF13) X(PF14) X(PF15) \
 // GPIOs are allocated whenever the pin is needed
 //  (e.g. when used for SPI, the R_SPI resource as well as the corresponding R_GPIO resources must be claimed)
 // Peripheral blocks (IPs) - not all chips have all blocks, usually the 1 and 2 are present as a minimum, if any.
 //  It doesn't really make sense to expose multiple instances of buses that support addressing
 // ADCs - some more advanced chips support differential input mode on some (not all!) inputs
 //  Usually only one or two instances are present
 // DAC - often only one is present, or none.
 // UARTs
 //  - 1 and 2 are present universally, 2 is connected to VCOM on Nucleo/Discovery boards, good for debug messages
 //  4 and 5 don't support synchronous mode.
 // Timers
 //  - some support quadrature input, probably all support external clock / gating / clock-out/PWM generation
 //  Not all chips have all timers and not all timers are equal.
 // DMA - Direct memory access lines - TODO split those to channels, they can be used separately
 // The resource registry will be pre-loaded with platform-specific config of which blocks are available - the rest will be "pre-claimed"
 // (i.e. unavailable to functional modules)
 typedef enum hw_resource Resource;
 enum hw_resource {
 #define X(res_name) R_##res_name,
    XX_RESOURCES
    XX_RESOURCES_GPIO
 #undef X
    R_NONE,
    RESOURCE_COUNT = R_NONE,
 };
 #define RSCMAP_LEN ((RESOURCE_COUNT/8)+1)
 typedef uint8_t ResourceMap[RSCMAP_LEN];
 #define RSC_IS_FREE(rscmap, rsc) (0 == (rscmap[((rsc)>>3)&0xFF] & (1<<((rsc)&0x7))))
 #define RSC_IS_HELD(rscmap, rsc) (!RSC_IS_FREE(rscmap, rsc))
 #define RSC_CLAIM(rscmap, rsc)   do { rscmap[((rsc)>>3)&0xFF] |= (1<<((rsc)&0x7)); } while(0)
 #define RSC_FREE(rscmap, rsc)   do { rscmap[((rsc)>>3)&0xFF] &= ~(1<<((rsc)&0x7)); } while(0)
 #endif //GEX_F072_RSC_ENUM_H
--- a/framework/settings.c
+++ b/framework/settings.c
@ -223,6 +223,8 @@ static void ini_preamble(IniWriter *iw, const char *filename)
    iw_comment(iw, "Close the LOCK jumper to save them to Flash.");
 }
 extern osMutexId mutScratchBufferHandle;
 /**
 * Write system settings to INI (without section)
 */
@ -230,7 +232,11 @@ void settings_build_units_ini(IniWriter *iw)
 {
    ini_preamble(iw, "UNITS.INI");
    assert_param(osOK == osMutexWait(mutScratchBufferHandle, 5000));
    {
        ureg_build_ini(iw);
    }
    assert_param(osOK == osMutexRelease(mutScratchBufferHandle));
 }
 /**
--- a/framework/unit.c
+++ b/framework/unit.c
@ -6,7 +6,7 @@
 #include "unit.h"
 #include "resources.h"
-char unit_tmp512[512];
+char unit_tmp512[UNIT_TMP_LEN];
 // Abort partly inited unit
 void clean_failed_unit(Unit *unit)
--- a/framework/unit.h
+++ b/framework/unit.h
@ -10,13 +10,14 @@
 #include "utils/ini_writer.h"
 #include "utils/payload_builder.h"
 #include "utils/payload_parser.h"
 #include "rsc_enum.h"
 #define CHECK_TYPE(_unit, _driver) do { \
    if ((_unit->driver) != (_driver)) \
        return E_BAD_UNIT_TYPE; \
 } while (0)
-extern char unit_tmp512[512]; // temporary static buffer - not expected to be accessed asynchronously
+extern char unit_tmp512[UNIT_TMP_LEN]; // temporary static buffer - not expected to be accessed asynchronously
 // TODO add mutex?
 typedef struct unit Unit;
@ -33,11 +34,17 @@ struct unit {
     */
    void *data;
    /** Unit call sign for messages */
    uint8_t callsign;
    /** Unit init status */
    error_t status;
-    /** Unit call sign for messages */
+    /** If RSC not avail. error is caught, the resource is stored here. */
-    uint8_t callsign;
+    Resource failed_rsc;
    /** Bit-map of held resources */
    ResourceMap resources;
 };
 /**
--- a/framework/unit_registry.c
+++ b/framework/unit_registry.c
@ -42,6 +42,7 @@ static int32_t unit_count = -1;
 void ureg_add_type(const UnitDriver *driver)
 {
    bool suc = true;
    assert_param(driver != NULL);
    assert_param(driver->name != NULL);
@ -57,7 +58,9 @@ void ureg_add_type(const UnitDriver *driver)
    assert_param(driver->deInit != NULL);
    assert_param(driver->handleRequest != NULL);
-    UregEntry *re = malloc_s(sizeof(UregEntry));
+    UregEntry *re = calloc_ck(1, sizeof(UregEntry), &suc);
    assert_param(suc);
    re->driver = driver;
    re->next = NULL;
@ -108,7 +111,7 @@ Unit *ureg_instantiate(const char *driver_name)
    while (re != NULL) {
        if (streq(re->driver->name, driver_name)) {
            // Create new list entry
-            UlistEntry *le = malloc_ck(sizeof(UlistEntry), &suc);
+            UlistEntry *le = calloc_ck(1, sizeof(UlistEntry), &suc);
            CHECK_SUC();
            le->next = NULL;
@ -355,8 +358,23 @@ static void export_unit_do(UlistEntry *li, IniWriter *iw)
    iw_section(iw, "%s:%s@%d", pUnit->driver->name, pUnit->name, (int)pUnit->callsign);
    if (pUnit->status != E_SUCCESS) {
        // temporarily force comments ON
        bool sc = SystemSettings.ini_comments;
        SystemSettings.ini_comments = true;
        {
            // special message for failed unit die to resource
            if (pUnit->status == E_RESOURCE_NOT_AVAILABLE) {
                iw_comment(iw, "!!! %s not available, already held by %s",
                           rsc_get_name(pUnit->failed_rsc),
                           rsc_get_owner_name(pUnit->failed_rsc));
            }
            else {
                iw_comment(iw, "!!! %s", error_get_message(pUnit->status));
            }
            iw_cmt_newline(iw);
        }
        SystemSettings.ini_comments = sc;
    }
    pUnit->driver->cfgWriteIni(pUnit, iw);
 }
@ -431,9 +449,14 @@ uint32_t ureg_get_num_units(void)
    return (uint32_t) unit_count;
 }
 extern osMutexId mutScratchBufferHandle;
 /** Deliver message to it's destination unit */
 void ureg_deliver_unit_request(TF_Msg *msg)
 {
    // we must claim the scratch buffer because it's used by many units internally
    assert_param(osOK == osMutexWait(mutScratchBufferHandle, 5000));
    {
        PayloadParser pp = pp_start(msg->data, msg->len, NULL);
        uint8_t callsign = pp_u8(&pp);
        uint8_t command = pp_u8(&pp);
@ -444,7 +467,7 @@ void ureg_deliver_unit_request(TF_Msg *msg)
        if (callsign == 0 || !pp.ok) {
            com_respond_error(msg->frame_id, E_MALFORMED_COMMAND);
-        return;
+            goto quit;
        }
        UlistEntry *li = ulist_head;
@ -457,16 +480,20 @@ void ureg_deliver_unit_request(TF_Msg *msg)
                // error is expected to have already been reported.
                if (rv == E_SUCCESS) {
                    if (confirmed) com_respond_ok(msg->frame_id);
-            } else {
+                }
                else {
                    com_respond_error(msg->frame_id, rv);
                }
-            return;
+                goto quit;
            }
            li = li->next;
        }
        // Not found
        com_respond_error(msg->frame_id, E_NO_SUCH_UNIT);
    }
    quit:
    assert_param(osOK == osMutexRelease(mutScratchBufferHandle));
 }
 /** Send a response for a unit-list request */
@ -488,7 +515,7 @@ void ureg_report_active_units(TF_ID frame_id)
    msglen += count; // one byte per message for the callsign
    bool suc = true;
-    uint8_t *buff = malloc_ck(msglen, &suc);
+    uint8_t *buff = calloc_ck(1, msglen, &suc);
    if (!suc) {
        com_respond_error(frame_id, E_OUT_OF_MEM);
        return;
@ -514,3 +541,19 @@ void ureg_report_active_units(TF_ID frame_id)
    }
    free(buff);
 }
 Unit *ureg_get_rsc_owner(Resource resource)
 {
    UlistEntry *li = ulist_head;
    while (li != NULL) {
        if (RSC_IS_HELD(li->unit.resources, resource)) {
            return &li->unit;
        }
        li = li->next;
    }
    if (RSC_IS_HELD(UNIT_SYSTEM.resources, resource)) return &UNIT_SYSTEM;
    if (RSC_IS_HELD(UNIT_PLATFORM.resources, resource)) return &UNIT_PLATFORM;
    return NULL;
 }
--- a/framework/unit_registry.h
+++ b/framework/unit_registry.h
@ -127,4 +127,12 @@ void ureg_deliver_unit_request(TF_Msg *msg);
 */
 void ureg_report_active_units(TF_ID frame_id);
 /**
 * Get unit holding a resource, or NULL.
 *
 * @param resource
 * @return unit
 */
 Unit *ureg_get_rsc_owner(Resource resource);
 #endif //GEX_UNIT_REGISTRY_H
--- a/freertos.c
+++ b/freertos.c
@ -84,6 +84,9 @@ osStaticMutexDef_t mutTinyFrameTxControlBlock;
 osSemaphoreId semVcomTxReadyHandle;
 osStaticSemaphoreDef_t semVcomTxReadyControlBlock;
 osMutexId mutScratchBufferHandle;
 osStaticMutexDef_t mutScratchBufferControlBlock;
 /* USER CODE BEGIN Variables */
 /* USER CODE END Variables */
@ -142,6 +145,9 @@ void MX_FREERTOS_Init(void) {
  osMutexStaticDef(mutTinyFrameTx, &mutTinyFrameTxControlBlock);
  mutTinyFrameTxHandle = osMutexCreate(osMutex(mutTinyFrameTx));
  osMutexStaticDef(mutScratchBuffer, &mutScratchBufferControlBlock);
  mutScratchBufferHandle = osMutexCreate(osMutex(mutScratchBuffer));
  /* USER CODE BEGIN RTOS_MUTEX */
  /* add mutexes, ... */
  /* USER CODE END RTOS_MUTEX */
--- a/gex.mk
+++ b/gex.mk
@ -11,6 +11,7 @@ GEX_SRC_DIR = \
    User/units/digital_out \
    User/units/digital_in \
    User/units/i2c \
    User/units/spi \
    User/TinyFrame \
    User/CWPack \
    User/tasks
@ -82,7 +83,7 @@ GEX_CDEFS = $(GEX_CDEFS_BASE) \
    -DVERBOSE_ASSERT=1 \
    -DDEBUG_VFS=0 \
    -DDEBUG_FLASH_WRITE=0 \
-    -DVERBOSE_HARDFAULT=1 \
+    -DVERBOSE_HARDFAULT=0 \
    -DUSE_STACK_MONITOR=0 \
    -DUSE_DEBUG_UART=1
--- a/platform/pin_utils.c
+++ b/platform/pin_utils.c
@ -208,17 +208,17 @@ char * str_pinmask(uint16_t pins, char *buffer)
        } else {
            if (on) {
                if (!first) {
-                    b += sprintf(b, ",");
+                    b += SPRINTF(b, ",");
                }
                if (start == (uint32_t)(i+1)) {
-                    b += sprintf(b, "%"PRIu32, start);
+                    b += SPRINTF(b, "%"PRIu32, start);
                }
                else if (start == (uint32_t)(i+2)) {
                    // exception for 2-long ranges - don't show as range
-                    b += sprintf(b, "%"PRIu32",%"PRIu32, start, i + 1);
+                    b += SPRINTF(b, "%"PRIu32",%"PRIu32, start, i + 1);
                }
                else {
-                    b += sprintf(b, "%"PRIu32"-%"PRIu32, start, i + 1);
+                    b += SPRINTF(b, "%"PRIu32"-%"PRIu32, start, i + 1);
                }
                first = false;
                on = false;
@ -260,3 +260,55 @@ uint16_t port_pack(uint16_t spread, uint16_t mask)
    }
    return result;
 }
 void deinit_unit_pins(Unit *unit)
 {
    for (uint32_t rsc = R_PA0; rsc <= R_PF15; rsc++) {
        if (RSC_IS_HELD(unit->resources, rsc)) {
            dbg("Freeing pin %s", rsc_get_name((Resource)rsc));
            GPIO_TypeDef *port = port_periphs[(rsc-R_PA0) / 16];
            uint32_t ll_pin = ll_pins[(rsc-R_PA0)%16];
            LL_GPIO_SetPinMode(port, ll_pin, LL_GPIO_MODE_ANALOG);
        }
    }
 }
 error_t configure_gpio_alternate(char port_name, uint8_t pin_num, uint32_t af)
 {
    bool suc = true;
    GPIO_TypeDef *port = port2periph(port_name, &suc);
    uint32_t ll_pin = pin2ll(pin_num, &suc);
    if (!suc) return E_BAD_CONFIG;
    if (pin_num < 8)
        LL_GPIO_SetAFPin_0_7(port, ll_pin, af);
    else
        LL_GPIO_SetAFPin_8_15(port, ll_pin, af);
    LL_GPIO_SetPinMode(port, ll_pin, LL_GPIO_MODE_ALTERNATE);
    return E_SUCCESS;
 }
 error_t configure_sparse_pins(char port_name, uint16_t mask, GPIO_TypeDef **port_dest, uint32_t mode, uint32_t otype)
 {
    bool suc = true;
    GPIO_TypeDef *port = port2periph(port_name, &suc);
    if (!suc) return E_BAD_CONFIG;
    for (int i = 0; i < 16; i++) {
        if (mask & (1<<i)) {
            uint32_t ll_pin = pin2ll((uint8_t) i, &suc);
            LL_GPIO_SetPinMode(port, ll_pin, mode);
            LL_GPIO_SetPinOutputType(port, ll_pin, otype);
            LL_GPIO_SetPinSpeed(port, ll_pin, LL_GPIO_SPEED_FREQ_HIGH);
        }
    }
    if (port_dest != NULL) {
        *port_dest = port;
    }
    return E_SUCCESS;
 }
--- a/platform/pin_utils.h
+++ b/platform/pin_utils.h
@ -68,4 +68,14 @@ uint16_t port_spread(uint16_t packed, uint16_t mask);
 */
 uint16_t port_pack(uint16_t spread, uint16_t mask);
 /**
 * Set all GPIO resources held by unit to analog
 *
 * @param unit - holding unit
 */
 void deinit_unit_pins(Unit *unit);
 error_t configure_gpio_alternate(char port_name, uint8_t pin_num, uint32_t af);
 error_t configure_sparse_pins(char port_name, uint16_t mask, GPIO_TypeDef **port_dest, uint32_t mode, uint32_t otype);
 #endif //GEX_PIN_UTILS_H
--- a/platform/plat_compat.h
+++ b/platform/plat_compat.h
@ -9,10 +9,11 @@
 // -------- Static buffers ---------
 #define TSK_STACK_MAIN      220 // USB / VFS task stack size
-#define TSK_STACK_MSG       200 // TF message handler task stack size
+#define TSK_STACK_MSG       220 // TF message handler task stack size
 #define TSK_STACK_JOBRUNNER 80 // Job runner task stack size
-#define BULKREAD_MAX_CHUNK  256 // Bulk read buffer
+#define BULK_READ_BUF_LEN 256   // Buffer for TF bulk reads
 #define UNIT_TMP_LEN      512   // Buffer for bulk read and varions internal unit operations
 #define FLASH_SAVE_BUF_LEN  256 // Static buffer for saving to flash
--- a/platform/platform.c
+++ b/platform/platform.c
@ -13,6 +13,7 @@
 #include "units/neopixel/unit_neopixel.h"
 #include "units/i2c/unit_i2c.h"
 #include "units/test/unit_test.h"
 #include "units/spi/unit_spi.h"
 void plat_init_resources(void)
 {
@ -77,17 +78,18 @@ void plat_init_resources(void)
    ureg_add_type(&UNIT_DIN);
    ureg_add_type(&UNIT_NEOPIXEL);
    ureg_add_type(&UNIT_I2C);
    ureg_add_type(&UNIT_SPI);
    // Free all present resources
    {
        rsc_free(NULL, R_ADC1);
-        rsc_free(NULL, R_CAN1);
+//        rsc_free(NULL, R_CAN1);
-        rsc_free_range(NULL, R_COMP1, R_COMP2);
+//        rsc_free_range(NULL, R_COMP1, R_COMP2);
        rsc_free(NULL, R_DAC1);
-        rsc_free(NULL, R_HDMI_CEC);
+//        rsc_free(NULL, R_HDMI_CEC);
-        rsc_free(NULL, R_TSC);
+//        rsc_free(NULL, R_TSC);
        rsc_free_range(NULL, R_I2C1, R_I2C2);
-        rsc_free_range(NULL, R_I2S1, R_I2S2);
+//        rsc_free_range(NULL, R_I2S1, R_I2S2);
        rsc_free_range(NULL, R_SPI1, R_SPI2);
        rsc_free_range(NULL, R_TIM1, R_TIM3);
        rsc_free_range(NULL, R_TIM6, R_TIM7);
@ -129,18 +131,18 @@ void plat_init_resources(void)
    // Free all present resources
    {
        rsc_free_range(NULL, R_ADC1, R_ADC4);
-        rsc_free(NULL, R_CAN1);
+//        rsc_free(NULL, R_CAN1);
-        rsc_free_range(NULL, R_COMP1, R_COMP7);
+//        rsc_free_range(NULL, R_COMP1, R_COMP7);
-        rsc_free(NULL, R_HDMI_CEC);
+//        rsc_free(NULL, R_HDMI_CEC);
        rsc_free(NULL, R_DAC1);
        rsc_free_range(NULL, R_I2C1, R_I2C2);
        rsc_free_range(NULL, R_I2S2, R_I2S3);
-        rsc_free_range(NULL, R_OPAMP1, R_OPAMP4);
+//        rsc_free_range(NULL, R_OPAMP1, R_OPAMP4);
        rsc_free_range(NULL, R_SPI1, R_SPI3);
        rsc_free_range(NULL, R_TIM1, R_TIM4);
        rsc_free_range(NULL, R_TIM6, R_TIM8);
        rsc_free_range(NULL, R_TIM15, R_TIM17);
-        rsc_free(NULL, R_TSC);
+//        rsc_free(NULL, R_TSC);
        rsc_free_range(NULL, R_USART1, R_USART5);
        rsc_free_range(NULL, R_PA0, R_PA15);
@ -182,15 +184,15 @@ void plat_init_resources(void)
    // Free all present resources
    {
        rsc_free_range(NULL, R_ADC1, R_ADC3);
-        rsc_free_range(NULL, R_CAN1, R_CAN2);
+//        rsc_free_range(NULL, R_CAN1, R_CAN2);
-        rsc_free_range(NULL, R_COMP1, R_COMP7);
+//        rsc_free_range(NULL, R_COMP1, R_COMP7);
        rsc_free(NULL, R_DAC1);
-        rsc_free(NULL, R_DCMI);
+//        rsc_free(NULL, R_DCMI);
-        rsc_free(NULL, R_ETH);
+//        rsc_free(NULL, R_ETH);
-        rsc_free(NULL, R_FSMC);
+//        rsc_free(NULL, R_FSMC);
        rsc_free_range(NULL, R_I2C1, R_I2C3);
        rsc_free_range(NULL, R_I2S2, R_I2S3);
-        rsc_free(NULL, R_SDIO);
+//        rsc_free(NULL, R_SDIO);
        rsc_free_range(NULL, R_SPI1, R_SPI3);
        rsc_free_range(NULL, R_TIM1, R_TIM14);
        rsc_free_range(NULL, R_USART1, R_USART3);
--- a/tasks/task_msg.c
+++ b/tasks/task_msg.c
@ -26,6 +26,7 @@ void TaskMessaging(const void * argument)
        xQueueReceive(queRxDataHandle, &slot, osWaitForever);
        assert_param(slot.len>0 && slot.len<=64); // check the len is within bounds
        // We need thr scratch buffer for many unit command handlers
        TF_Accept(comm, slot.data, slot.len);
 #if USE_STACK_MONITOR
--- a/units/digital_in/unit_din.c
+++ b/units/digital_in/unit_din.c
@ -161,23 +161,7 @@ static error_t DI_init(Unit *unit)
 /** Tear down the unit */
 static void DI_deInit(Unit *unit)
 {
-    struct priv *priv = unit->data;
+    // pins are de-inited during teardown
    if (unit->status == E_SUCCESS) {
        assert_param(priv->port);
        bool suc = true;
        uint16_t mask = 1;
        for (int i = 0; i < 16; i++, mask <<= 1) {
            if (priv->pins & mask) {
                uint32_t ll_pin = pin2ll((uint8_t) i, &suc);
                assert_param(suc); // this should never fail if we got this far
                // configure the pin as analog
                LL_GPIO_SetPinMode(priv->port, ll_pin, LL_GPIO_MODE_ANALOG);
            }
        }
    }
    // Release all resources
    rsc_teardown(unit);
@ -210,7 +194,7 @@ static error_t DI_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, Pay
        case CMD_READ:;
            TRY(UU_DI_Read(unit, &packed));
-            PayloadBuilder pb = pb_start((uint8_t*)unit_tmp512, 64, NULL);
+            PayloadBuilder pb = pb_start((uint8_t*)unit_tmp512, UNIT_TMP_LEN, NULL);
            pb_u16(&pb, packed);
            com_respond_buf(frame_id, MSG_SUCCESS, (uint8_t *) unit_tmp512, pb_length(&pb));
            return E_SUCCESS;
--- a/units/digital_out/unit_dout.c
+++ b/units/digital_out/unit_dout.c
@ -62,7 +62,7 @@ static error_t DO_loadIni(Unit *unit, const char *key, const char *value)
    else if (streq(key, "initial")) {
        priv->initial = parse_pinmask(value, &suc);
    }
-    else if (streq(key, "opendrain")) {
+    else if (streq(key, "open-drain")) {
        priv->open_drain = parse_pinmask(value, &suc);
    }
    else {
@ -88,7 +88,7 @@ static void DO_writeIni(Unit *unit, IniWriter *iw)
    iw_entry(iw, "initial", "%s", str_pinmask(priv->initial, unit_tmp512));
    iw_comment(iw, "Open-drain pins");
-    iw_entry(iw, "opendrain", "%s", str_pinmask(priv->open_drain, unit_tmp512));
+    iw_entry(iw, "open-drain", "%s", str_pinmask(priv->open_drain, unit_tmp512));
 }
 // ------------------------------------------------------------------------
@ -125,18 +125,14 @@ static error_t DO_init(Unit *unit)
    // Claim all needed pins
    TRY(rsc_claim_gpios(unit, priv->port_name, priv->pins));
-    uint16_t mask = 1;
+    for (int i = 0; i < 16; i++) {
-    for (int i = 0; i < 16; i++, mask <<= 1) {
+        if (priv->pins & (1 << i)) {
        if (priv->pins & mask) {
            uint32_t ll_pin = pin2ll((uint8_t) i, &suc);
            // --- Init hardware ---
            LL_GPIO_SetPinMode(priv->port, ll_pin, LL_GPIO_MODE_OUTPUT);
-
+            LL_GPIO_SetPinOutputType(priv->port, ll_pin,
-            LL_GPIO_SetPinOutputType(priv->port, ll_pin, (priv->open_drain & mask) ?
+                                     (priv->open_drain & (1 << i)) ? LL_GPIO_OUTPUT_OPENDRAIN : LL_GPIO_OUTPUT_PUSHPULL);
                                                         LL_GPIO_OUTPUT_OPENDRAIN :
                                                         LL_GPIO_OUTPUT_PUSHPULL);
            LL_GPIO_SetPinSpeed(priv->port, ll_pin, LL_GPIO_SPEED_FREQ_HIGH);
        }
    }
@ -151,25 +147,7 @@ static error_t DO_init(Unit *unit)
 /** Tear down the unit */
 static void DO_deInit(Unit *unit)
 {
-    struct priv *priv = unit->data;
+    // pins are de-inited during teardown
    // de-init the pins only if inited correctly
    if (unit->status == E_SUCCESS) {
        assert_param(priv->port);
        bool suc = true;
        uint16_t mask = 1;
        for (int i = 0; i < 16; i++, mask <<= 1) {
            if (priv->pins & mask) {
                uint32_t ll_pin = pin2ll((uint8_t) i, &suc);
                assert_param(suc); // this should never fail if we got this far
                // configure the pin as analog
                LL_GPIO_SetPinMode(priv->port, ll_pin, LL_GPIO_MODE_ANALOG);
            }
        }
    }
    // Release all resources
    rsc_teardown(unit);
@ -234,9 +212,18 @@ error_t UU_DO_Toggle(Unit *unit, uint16_t packed)
    return E_SUCCESS;
 }
 error_t UU_DO_GetPinCount(Unit *unit, uint8_t *count)
 {
    CHECK_TYPE(unit, &UNIT_DOUT);
    struct priv *priv = unit->data;
    uint32_t packed = port_pack(0xFFFF, priv->pins);
    *count = (uint8_t)(32 - __CLZ(packed));
    return E_SUCCESS;
 }
 enum PinCmd_ {
-    CMD_WRITE = 0,
+    CMD_QUERY = 0,
    CMD_SET = 1,
    CMD_CLEAR = 2,
    CMD_TOGGLE = 3,
@ -245,12 +232,10 @@ enum PinCmd_ {
 /** Handle a request message */
 static error_t DO_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
 {
    struct priv *priv = unit->data;
    uint16_t packed = pp_u16(pp);
    switch (command) {
-        case CMD_WRITE:
+        case CMD_QUERY:
            return UU_DO_Write(unit, packed);
        case CMD_SET:
--- a/units/digital_out/unit_dout.h
+++ b/units/digital_out/unit_dout.h
@ -9,4 +9,14 @@
 extern const UnitDriver UNIT_DOUT;
 error_t UU_DO_Write(Unit *unit, uint16_t packed);
 error_t UU_DO_Set(Unit *unit, uint16_t packed);
 error_t UU_DO_Clear(Unit *unit, uint16_t packed);
 error_t UU_DO_Toggle(Unit *unit, uint16_t packed);
 error_t UU_DO_GetPinCount(Unit *unit, uint8_t *count);
 #endif //U_DOUT_H
--- a/units/i2c/unit_i2c.c
+++ b/units/i2c/unit_i2c.c
@ -2,6 +2,7 @@
 // Created by MightyPork on 2018/01/02.
 //
 #include <framework/system_settings.h>
 #include "comm/messages.h"
 #include "unit_base.h"
 #include "utils/avrlibc.h"
@ -12,15 +13,17 @@
 /** Private data structure */
 struct priv {
    uint8_t periph_num; //!< 1 or 2
    uint8_t remap;      //!< I2C remap option
    bool anf;    //!< Enable analog noise filter
    uint8_t dnf; //!< Enable digital noise filter (1-15 ... max spike width)
    uint8_t speed; //!< 0 - Standard, 1 - Fast, 2 - Fast+
    I2C_TypeDef *periph;
-    GPIO_TypeDef *port;
+//    GPIO_TypeDef *port;
-    uint32_t ll_pin_scl;
+//    uint32_t ll_pin_scl;
-    uint32_t ll_pin_sda;
+//    uint32_t ll_pin_sda;
 };
 // ------------------------------------------------------------------------
@ -37,6 +40,10 @@ static void UI2C_loadBinary(Unit *unit, PayloadParser *pp)
    priv->anf = pp_bool(pp);
    priv->dnf = pp_u8(pp);
    priv->speed = pp_u8(pp);
    if (version >= 1) {
        priv->remap = pp_u8(pp);
    }
 }
 /** Write to a binary buffer for storing in Flash */
@ -44,12 +51,13 @@ static void UI2C_writeBinary(Unit *unit, PayloadBuilder *pb)
 {
    struct priv *priv = unit->data;
-    pb_u8(pb, 0); // version
+    pb_u8(pb, 1); // version
    pb_u8(pb, priv->periph_num);
    pb_bool(pb, priv->anf);
    pb_u8(pb, priv->dnf);
    pb_u8(pb, priv->speed);
    pb_u8(pb, priv->remap);
 }
 // ------------------------------------------------------------------------
@ -63,6 +71,9 @@ static error_t UI2C_loadIni(Unit *unit, const char *key, const char *value)
    if (streq(key, "device")) {
        priv->periph_num = (uint8_t) avr_atoi(value);
    }
    else if (streq(key, "remap")) {
        priv->remap = (uint8_t) avr_atoi(value);
    }
    else if (streq(key, "analog-filter")) {
        priv->anf = str_parse_yn(value, &suc);
    }
@ -88,6 +99,22 @@ static void UI2C_writeIni(Unit *unit, IniWriter *iw)
    iw_comment(iw, "Peripheral number (I2Cx)");
    iw_entry(iw, "device", "%d", (int)priv->periph_num);
    iw_comment(iw, "Pin mappings (SCL,SDA)");
 #if GEX_PLAT_F072_DISCOVERY
    iw_comment(iw, " I2C1: (0) B6,B7    (1) B8,B9");
    iw_comment(iw, " I2C2: (0) B10,B11  (1) B13,B14");
 #elif GEX_PLAT_F103_BLUEPILL
    #error "NO IMPL"
 #elif GEX_PLAT_F303_DISCOVERY
    #error "NO IMPL"
 #elif GEX_PLAT_F407_DISCOVERY
    #error "NO IMPL"
 #else
    #error "BAD PLATFORM!"
 #endif
    iw_entry(iw, "remap", "%d", (int)priv->remap);
    iw_cmt_newline(iw);
    iw_comment(iw, "Speed: 1-Standard, 2-Fast, 3-Fast+");
    iw_entry(iw, "speed", "%d", (int)priv->speed);
@ -157,17 +184,38 @@ static error_t UI2C_init(Unit *unit)
 #if GEX_PLAT_F072_DISCOVERY
    // scl - 6 or 8 for I2C1, 10 for I2C2
    // sda - 7 or 9 for I2C1, 11 for I2C2
    portname = 'B';
    if (priv->periph_num == 1) {
        // I2C1
        if (priv->remap == 0) {
            af_i2c = LL_GPIO_AF_1;
            portname = 'B';
            pin_scl = 6;
            pin_sda = 7;
        } else if (priv->remap == 1) {
            af_i2c = LL_GPIO_AF_1;
            portname = 'B';
            pin_scl = 8;
            pin_sda = 9;
        } else {
            return E_BAD_CONFIG;
        }
    } else {
        // I2C2
        if (priv->remap == 0) {
            af_i2c = LL_GPIO_AF_1;
            portname = 'B';
            pin_scl = 10;
-        pin_sda = 12;
+            pin_sda = 11;
        } else if (priv->remap == 1) {
            af_i2c = LL_GPIO_AF_5;
            portname = 'B';
            pin_scl = 13;
            pin_sda = 14;
        } else {
            return E_BAD_CONFIG;
        }
    }
    af_i2c = LL_GPIO_AF_1;
    if (priv->speed == 1)
        timing = 0x00301D2B; // Standard
    else if (priv->speed == 2)
@ -186,32 +234,11 @@ static error_t UI2C_init(Unit *unit)
 #endif
    // first, we have to claim the pins
-    Resource r_sda = pin2resource(portname, pin_sda, &suc);
+    TRY(rsc_claim_pin(unit, portname, pin_sda));
-    Resource r_scl = pin2resource(portname, pin_scl, &suc);
+    TRY(rsc_claim_pin(unit, portname, pin_scl));
    if (!suc) return E_BAD_CONFIG;
    TRY(rsc_claim(unit, r_sda));
    TRY(rsc_claim(unit, r_scl));
    priv->port = port2periph(portname, &suc);
    uint32_t ll_pin_scl = pin2ll(pin_scl, &suc);
    uint32_t ll_pin_sda = pin2ll(pin_sda, &suc);
    if (!suc) return E_BAD_CONFIG;
    // configure AF
    if (pin_scl < 8) LL_GPIO_SetAFPin_0_7(priv->port, ll_pin_scl, af_i2c);
    else LL_GPIO_SetAFPin_8_15(priv->port, ll_pin_scl, af_i2c);
    if (pin_sda < 8) LL_GPIO_SetAFPin_0_7(priv->port, ll_pin_sda, af_i2c);
    else LL_GPIO_SetAFPin_8_15(priv->port, ll_pin_sda, af_i2c);
    LL_GPIO_SetPinMode(priv->port, ll_pin_scl, LL_GPIO_MODE_ALTERNATE);
    LL_GPIO_SetPinMode(priv->port, ll_pin_sda, LL_GPIO_MODE_ALTERNATE);
    // set as OpenDrain (this may not be needed - TODO check)
    LL_GPIO_SetPinOutputType(priv->port, ll_pin_scl, LL_GPIO_OUTPUT_OPENDRAIN);
    LL_GPIO_SetPinOutputType(priv->port, ll_pin_sda, LL_GPIO_OUTPUT_OPENDRAIN);
    configure_gpio_alternate(portname, pin_sda, af_i2c);
    configure_gpio_alternate(portname, pin_scl, af_i2c);
    if (priv->periph_num == 1) {
        __HAL_RCC_I2C1_CLK_ENABLE();
@ -222,8 +249,7 @@ static error_t UI2C_init(Unit *unit)
    /* Disable the selected I2Cx Peripheral */
    LL_I2C_Disable(priv->periph);
    LL_I2C_ConfigFilters(priv->periph,
-                         priv->anf ? LL_I2C_ANALOGFILTER_ENABLE
+                         (priv->anf ? LL_I2C_ANALOGFILTER_ENABLE : LL_I2C_ANALOGFILTER_DISABLE),
                                   : LL_I2C_ANALOGFILTER_DISABLE,
                         priv->dnf);
    LL_I2C_SetTiming(priv->periph, timing);
@ -244,7 +270,6 @@ static void UI2C_deInit(Unit *unit)
    // de-init the pins & peripheral only if inited correctly
    if (unit->status == E_SUCCESS) {
        assert_param(priv->periph);
        assert_param(priv->port);
        LL_I2C_DeInit(priv->periph);
@ -253,9 +278,6 @@ static void UI2C_deInit(Unit *unit)
        } else {
            __HAL_RCC_I2C2_CLK_DISABLE();
        }
        LL_GPIO_SetPinMode(priv->port, priv->ll_pin_sda, LL_GPIO_MODE_ANALOG);
        LL_GPIO_SetPinMode(priv->port, priv->ll_pin_scl, LL_GPIO_MODE_ANALOG);
    }
    // Release all resources
@ -269,7 +291,7 @@ static void UI2C_deInit(Unit *unit)
 // ------------------------------------------------------------------------
 enum PinCmd_ {
-    CMD_WRITE = 0,
+    CMD_QUERY = 0,
    CMD_READ = 1,
    CMD_WRITE_REG = 2,
    CMD_READ_REG = 3,
@ -380,7 +402,7 @@ error_t UU_I2C_WriteReg(Unit *unit, uint16_t addr, uint8_t regnum, const uint8_t
    CHECK_TYPE(unit, &UNIT_I2C);
    // we have to insert the address first - needs a buffer (XXX realistically the buffer needs 1-4 bytes + addr)
-    PayloadBuilder pb = pb_start((uint8_t*)unit_tmp512, 512, NULL);
+    PayloadBuilder pb = pb_start((uint8_t*)unit_tmp512, UNIT_TMP_LEN, NULL);
    pb_u8(&pb, regnum);
    pb_buf(&pb, bytes, width);
@ -400,7 +422,7 @@ static error_t UI2C_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, P
    switch (command) {
        /** Write byte(s) - addr:u16, byte(s)  */
-        case CMD_WRITE:
+        case CMD_QUERY:
            addr = pp_u16(pp);
            const uint8_t *bb = pp_tail(pp, &len);
--- a/units/neopixel/unit_neopixel.c
+++ b/units/neopixel/unit_neopixel.c
@ -121,13 +121,7 @@ static error_t Npx_init(Unit *unit)
 /** Tear down the unit */
 static void Npx_deInit(Unit *unit)
 {
-    struct priv *priv = unit->data;
+    // pins are de-inited during teardown
    if (unit->status == E_SUCCESS) {
        assert_param(priv->port);
        // configure the pin as analog
        LL_GPIO_SetPinMode(priv->port, priv->ll_pin, LL_GPIO_MODE_ANALOG);
    }
    // Release all resources
    rsc_teardown(unit);
--- a/units/spi/unit_spi.c
+++ b/units/spi/unit_spi.c
@ -0,0 +1,529 @@
 //
 // Created by MightyPork on 2018/01/02.
 //
 #include <framework/system_settings.h>
 #include <stm32f072xb.h>
 #include "comm/messages.h"
 #include "unit_base.h"
 #include "utils/avrlibc.h"
 #include "unit_spi.h"
 // SPI master
 /** Private data structure */
 struct priv {
    uint8_t periph_num; //!< 1 or 2
    uint8_t remap;      //!< SPI remap option
    uint16_t prescaller; //!< Clock prescaller, stored as the dividing factor
    bool cpol;          //!< CPOL setting
    bool cpha;          //!< CPHA setting
    bool tx_only;       //!< If true, Enable only the MOSI line
    bool lsb_first;     //!< Option to send LSB first
    char ssn_port_name; //!< SSN port
    uint16_t ssn_pins;  //!< SSN pin mask
    SPI_TypeDef *periph;
    GPIO_TypeDef *ssn_port;
 };
 // ------------------------------------------------------------------------
 /** Load from a binary buffer stored in Flash */
 static void USPI_loadBinary(Unit *unit, PayloadParser *pp)
 {
    struct priv *priv = unit->data;
    uint8_t version = pp_u8(pp);
    (void)version;
    priv->periph_num = pp_u8(pp);
    priv->prescaller = pp_u16(pp);
    priv->remap = pp_u8(pp);
    priv->cpol = pp_bool(pp);
    priv->cpha = pp_bool(pp);
    priv->tx_only = pp_bool(pp);
    priv->lsb_first = pp_bool(pp);
    priv->ssn_port_name = pp_char(pp);
    priv->ssn_pins = pp_u16(pp);
 }
 /** Write to a binary buffer for storing in Flash */
 static void USPI_writeBinary(Unit *unit, PayloadBuilder *pb)
 {
    struct priv *priv = unit->data;
    pb_u8(pb, 0); // version
    pb_u8(pb, priv->periph_num);
    pb_u16(pb, priv->prescaller);
    pb_u8(pb, priv->remap);
    pb_bool(pb, priv->cpol);
    pb_bool(pb, priv->cpha);
    pb_bool(pb, priv->tx_only);
    pb_bool(pb, priv->lsb_first);
    pb_char(pb, priv->ssn_port_name);
    pb_u16(pb, priv->ssn_pins);
 }
 // ------------------------------------------------------------------------
 /** Parse a key-value pair from the INI file */
 static error_t USPI_loadIni(Unit *unit, const char *key, const char *value)
 {
    bool suc = true;
    struct priv *priv = unit->data;
    if (streq(key, "device")) {
        priv->periph_num = (uint8_t) avr_atoi(value);
    }
    else if (streq(key, "remap")) {
        priv->remap = (uint8_t) avr_atoi(value);
    }
    else if (streq(key, "prescaller")) {
        priv->prescaller = (uint16_t ) avr_atoi(value);
    }
    else if (streq(key, "cpol")) {
        priv->cpol = (bool) avr_atoi(value);
    }
    else if (streq(key, "cpha")) {
        priv->cpha = (bool) avr_atoi(value);
    }
    else if (streq(key, "tx-only")) {
        priv->tx_only = str_parse_yn(value, &suc);
    }
    else if (streq(key, "lsb-first")) {
        priv->lsb_first = str_parse_yn(value, &suc);
    }
    else if (streq(key, "port")) {
        suc = parse_port(value, &priv->ssn_port_name);
    }
    else if (streq(key, "pins")) {
        priv->ssn_pins = parse_pinmask(value, &suc);
    }
    else {
        return E_BAD_KEY;
    }
    if (!suc) return E_BAD_VALUE;
    return E_SUCCESS;
 }
 /** Generate INI file section for the unit */
 static void USPI_writeIni(Unit *unit, IniWriter *iw)
 {
    struct priv *priv = unit->data;
    iw_comment(iw, "Peripheral number (SPIx)");
    iw_entry(iw, "device", "%d", (int)priv->periph_num);
    // TODO show a legend for peripherals and remaps
    iw_comment(iw, "Pin mappings (SCK,MISO,MOSI)");
 #if GEX_PLAT_F072_DISCOVERY
    iw_comment(iw, " SPI1: (0) A5,A6,A7     (1) B3,B4,B5  (2) E13,E14,E15");
    iw_comment(iw, " SPI2: (0) B13,B14,B15  (1) D1,D3,D4");
 #elif GEX_PLAT_F103_BLUEPILL
    #error "NO IMPL"
 #elif GEX_PLAT_F303_DISCOVERY
    #error "NO IMPL"
 #elif GEX_PLAT_F407_DISCOVERY
    #error "NO IMPL"
 #else
    #error "BAD PLATFORM!"
 #endif
    iw_entry(iw, "remap", "%d", (int)priv->remap);
    iw_cmt_newline(iw);
    iw_comment(iw, "Prescaller: 2,4,8,...,256");
    iw_entry(iw, "prescaller", "%d", (int)priv->prescaller);
    iw_comment(iw, "Clock polarity: 0,1 (clock idle level)");
    iw_entry(iw, "cpol", "%d", (int)priv->cpol);
    iw_comment(iw, "Clock phase: 0,1 (active edge, 0-first, 1-second)");
    iw_entry(iw, "cpha", "%d", (int)priv->cpha);
    iw_comment(iw, "Transmit only, disable MISO");
    iw_entry(iw, "tx-only", str_yn(priv->tx_only));
    iw_comment(iw, "Use LSB-first bit order");
    iw_entry(iw, "lsb-first", str_yn(priv->lsb_first));
    iw_cmt_newline(iw);
    iw_comment(iw, "SS port name");
    iw_entry(iw, "port", "%c", priv->ssn_port_name);
    iw_comment(iw, "SS pins (comma separated, supports ranges)");
    iw_entry(iw, "pins", "%s", str_pinmask(priv->ssn_pins, unit_tmp512));
 }
 // ------------------------------------------------------------------------
 /** Allocate data structure and set defaults */
 static error_t USPI_preInit(Unit *unit)
 {
    bool suc = true;
    struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv), &suc);
    if (!suc) return E_OUT_OF_MEM;
    // some defaults
    priv->periph_num = 1;
    priv->prescaller = 64;
    priv->remap = 0;
    priv->cpol = 0;
    priv->cpha = 0;
    priv->tx_only = false;
    priv->lsb_first = false;
    priv->ssn_port_name = 'A';
    priv->ssn_pins = 0x0001;
    return E_SUCCESS;
 }
 /** Finalize unit set-up */
 static error_t USPI_init(Unit *unit)
 {
    bool suc = true;
    struct priv *priv = unit->data;
    if (!(priv->periph_num >= 1 && priv->periph_num <= 2)) {
        dbg("!! Bad SPI periph");
        // XXX some chips have also SPI3
        return E_BAD_CONFIG;
    }
    // assign and claim the peripheral
    if (priv->periph_num == 1) {
        TRY(rsc_claim(unit, R_SPI1));
        priv->periph = SPI1;
    }
    else if (priv->periph_num == 2) {
        TRY(rsc_claim(unit, R_SPI2));
        priv->periph = SPI2;
    }
    // This is written for F072, other platforms will need adjustments
    // Configure SPI own pins (AF)
    char spi_portname;
    uint8_t pin_miso;
    uint8_t pin_mosi;
    uint8_t pin_sck;
    uint32_t af_spi;
    // TODO
 #if GEX_PLAT_F072_DISCOVERY
    // SPI1 - many options
    // sck, miso, mosi, af
    if (priv->periph_num == 1) {
        // SPI1
        if (priv->remap == 0) {
            spi_portname = 'A';
            af_spi = LL_GPIO_AF_0;
            pin_sck = 5;
            pin_miso = 6;
            pin_mosi = 7;
        }
        else if (priv->remap == 1) {
            spi_portname = 'B';
            af_spi = LL_GPIO_AF_0;
            pin_sck = 3;
            pin_miso = 4;
            pin_mosi = 5;
        }
        else if (priv->remap == 2) {
            // large packages only
            spi_portname = 'E';
            af_spi = LL_GPIO_AF_1;
            pin_sck = 13;
            pin_miso = 14;
            pin_mosi = 15;
        }
        else {
            return E_BAD_CONFIG;
        }
    }
    else {
        // SPI2
        if (priv->remap == 0) {
            spi_portname = 'B';
            af_spi = LL_GPIO_AF_0;
            pin_sck = 13;
            pin_miso = 14;
            pin_mosi = 15;
        }
        else if (priv->remap == 1) {
            // NOTE: the's also a incomplete remap in PB and PC
            spi_portname = 'D';
            af_spi = LL_GPIO_AF_0;
            pin_sck = 1;
            pin_miso = 3;
            pin_mosi = 4;
        }
        else {
            return E_BAD_CONFIG;
        }
    }
 #elif GEX_PLAT_F103_BLUEPILL
    #error "NO IMPL"
 #elif GEX_PLAT_F303_DISCOVERY
    #error "NO IMPL"
 #elif GEX_PLAT_F407_DISCOVERY
    #error "NO IMPL"
 #else
    #error "BAD PLATFORM!"
 #endif
    // first, we have to claim the pins
    TRY(rsc_claim_pin(unit, spi_portname, pin_mosi));
    TRY(rsc_claim_pin(unit, spi_portname, pin_miso));
    TRY(rsc_claim_pin(unit, spi_portname, pin_sck));
    configure_gpio_alternate(spi_portname, pin_mosi, af_spi);
    configure_gpio_alternate(spi_portname, pin_miso, af_spi);
    configure_gpio_alternate(spi_portname, pin_sck, af_spi);
    if (priv->periph_num == 1) {
        __HAL_RCC_SPI1_CLK_ENABLE();
    } else {
        __HAL_RCC_SPI2_CLK_ENABLE();
    }
    // configure SSN GPIOs
    {
        // Claim all needed pins
        TRY(rsc_claim_gpios(unit, priv->ssn_port_name, priv->ssn_pins));
        TRY(configure_sparse_pins(priv->ssn_port_name, priv->ssn_pins, &priv->ssn_port,
                                  LL_GPIO_MODE_OUTPUT, LL_GPIO_OUTPUT_PUSHPULL));
        // Set the initial state - all high
        priv->ssn_port->BSRR = priv->ssn_pins;
    }
    // Configure SPI - must be configured under reset
    LL_SPI_Disable(priv->periph);
    {
        uint32_t presc = priv->prescaller;
        uint32_t lz = __CLZ(presc);
        if (lz < 23) lz = 23;
        if (lz > 30) lz = 30;
        presc = (32 - lz - 2);
        LL_SPI_SetBaudRatePrescaler(priv->periph, (presc<<SPI_CR1_BR_Pos)&SPI_CR1_BR_Msk);
        LL_SPI_SetClockPolarity(priv->periph,     priv->cpol ? LL_SPI_POLARITY_HIGH : LL_SPI_POLARITY_LOW);
        LL_SPI_SetClockPhase(priv->periph,        priv->cpha ? LL_SPI_PHASE_1EDGE : LL_SPI_PHASE_2EDGE);
        LL_SPI_SetTransferDirection(priv->periph, priv->tx_only ? LL_SPI_HALF_DUPLEX_TX : LL_SPI_FULL_DUPLEX);
        LL_SPI_SetTransferBitOrder(priv->periph,  priv->lsb_first ? LL_SPI_LSB_FIRST : LL_SPI_MSB_FIRST);
        LL_SPI_SetNSSMode(priv->periph, LL_SPI_NSS_SOFT);
        LL_SPI_SetDataWidth(priv->periph, LL_SPI_DATAWIDTH_8BIT);
        LL_SPI_SetRxFIFOThreshold(priv->periph, LL_SPI_RX_FIFO_TH_QUARTER); // trigger RXNE on 1 byte
        LL_SPI_SetMode(priv->periph, LL_SPI_MODE_MASTER);
    }
    LL_SPI_Enable(priv->periph);
    return E_SUCCESS;
 }
 /** Tear down the unit */
 static void USPI_deInit(Unit *unit)
 {
    struct priv *priv = unit->data;
    // de-init the pins & peripheral only if inited correctly
    if (unit->status == E_SUCCESS) {
        assert_param(priv->periph);
        LL_SPI_DeInit(priv->periph);
        if (priv->periph_num == 1) {
            __HAL_RCC_SPI1_CLK_DISABLE();
        } else {
            __HAL_RCC_SPI2_CLK_DISABLE();
        }
    }
    // Release all resources
    rsc_teardown(unit);
    // Free memory
    free(unit->data);
    unit->data = NULL;
 }
 // ------------------------------------------------------------------------
 static error_t spi_wait_until_flag(struct priv *priv, uint32_t flag, bool stop_state)
 {
    uint32_t t_start = HAL_GetTick();
    while (((priv->periph->SR & flag) != 0) != stop_state) {
        if (HAL_GetTick() - t_start > 10) {
            return E_HW_TIMEOUT;
        }
    }
    return E_SUCCESS;
 }
 /**
 * Perform a low level SPI transfer
 *
 * @param priv - private object of the SPI unit
 * @param request - request buffer
 * @param response - response buffer
 * @param req_len - request len
 * @param resp_skip - response skip bytes
 * @param resp_len - response len
 * @return success
 */
 static error_t xfer_do(struct priv *priv, const uint8_t *request,
                       uint8_t *response,
                       uint32_t req_len,
                       uint32_t resp_skip,
                       uint32_t resp_len)
 {
    // TODO this is slow, use DMA
    if (response == NULL) resp_len = 0;
    // avoid skip causing stretch beyond tx window if nothing is to be read back
    if (resp_len == 0) resp_skip = 0;
    // in tx only mode, return zeros
    if (priv->tx_only && resp_len>0) {
        memset(response, 0, resp_len);
    }
    uint8_t tb;
    uint32_t end = MAX(req_len, resp_len + resp_skip);
    for (uint32_t i = 0; i < end; i++) {
        if (i < req_len) tb = *request++;
        else tb = 0;
        TRY(spi_wait_until_flag(priv, SPI_SR_TXE, true));
        LL_SPI_TransmitData8(priv->periph, tb);
        if (!priv->tx_only) {
            TRY(spi_wait_until_flag(priv, SPI_SR_RXNE, true));
            uint8_t rb = LL_SPI_ReceiveData8(priv->periph);
            if (resp_skip > 0) resp_skip--;
            else if (resp_len > 0) {
                resp_len--;
                *response++ = rb;
            }
        }
    }
    return E_SUCCESS;
 }
 error_t UU_SPI_Multicast(Unit *unit, uint16_t slaves,
                     const uint8_t *request, uint32_t req_len)
 {
    struct priv *priv= unit->data;
    uint16_t mask = port_spread(slaves, priv->ssn_pins);
    priv->ssn_port->BRR = mask;
    {
        TRY(xfer_do(priv, request, NULL, req_len, 0, 0));
    }
    priv->ssn_port->BSRR = mask;
    return E_SUCCESS;
 }
 error_t UU_SPI_Write(Unit *unit, uint8_t slave_num,
                     const uint8_t *request, uint8_t *response,
                     uint32_t req_len, uint32_t resp_skip, uint32_t resp_len)
 {
    struct priv *priv= unit->data;
    uint16_t mask = port_spread((uint16_t) (1 << slave_num), priv->ssn_pins);
    priv->ssn_port->BRR = mask;
    {
        TRY(xfer_do(priv, request, response, req_len, resp_len, resp_skip));
    }
    priv->ssn_port->BSRR = mask;
    return E_SUCCESS;
 }
 enum PinCmd_ {
    CMD_QUERY = 0,
    CMD_MULTICAST = 1,
 };
 /** Handle a request message */
 static error_t USPI_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
 {
    uint8_t slave;
    uint16_t slaves;
    uint16_t req_len;
    uint16_t resp_skip;
    uint16_t resp_len;
    const uint8_t *bb;
    uint32_t len;
    switch (command) {
        /** Write and read byte(s) - slave_num:u8, req_len:u16, resp_skip:u16, resp_len:u16, byte(s)  */
        case CMD_QUERY:
            slave = pp_u8(pp);
            resp_skip = pp_u16(pp);
            resp_len = pp_u16(pp);
            bb = pp_tail(pp, &len);
            TRY(UU_SPI_Write(unit, slave,
                             bb, (uint8_t *) unit_tmp512,
                             len, resp_skip, resp_len));
            // no response if we aren't reading
            if (resp_len > 0) {
                com_respond_buf(frame_id, MSG_SUCCESS, (uint8_t *) unit_tmp512, resp_len);
            }
            return E_SUCCESS;
        /** Write byte(s) to multiple slaves - slaves:u16, req_len:u16, byte(s)  */
        case CMD_MULTICAST:
            slaves = pp_u16(pp);
            bb = pp_tail(pp, &len);
            TRY(UU_SPI_Multicast(unit, slaves, bb, len));
            return E_SUCCESS;
        default:
            return E_UNKNOWN_COMMAND;
    }
 }
 // ------------------------------------------------------------------------
 /** Unit template */
 const UnitDriver UNIT_SPI = {
    .name = "SPI",
    .description = "SPI master",
    // Settings
    .preInit = USPI_preInit,
    .cfgLoadBinary = USPI_loadBinary,
    .cfgWriteBinary = USPI_writeBinary,
    .cfgLoadIni = USPI_loadIni,
    .cfgWriteIni = USPI_writeIni,
    // Init
    .init = USPI_init,
    .deInit = USPI_deInit,
    // Function
    .handleRequest = USPI_handleRequest,
 };
--- a/units/spi/unit_spi.h
+++ b/units/spi/unit_spi.h
@ -0,0 +1,63 @@
 //
 // Created by MightyPork on 2018/01/02.
 //
 #ifndef GEX_F072_UNIT_SPI_H
 #define GEX_F072_UNIT_SPI_H
 #include "unit.h"
 extern const UnitDriver UNIT_SPI;
 // Unit-to-Unit API
 /**
 * Raw read/write via SPI.
 * It's possible to simultaneously write and read, or skip bytes in either direction.
 *
 * Example scenarios:
 *
 * req 2, skip 2, read 3
 * |<-- req_len --->|
 * [ write ][ write ] . . . . . . . .
 * . . . . . . . . . [ read ][ read ][ read ]
 * |<-- resp_skip ->|<------ resp_len ----->|
 *
 * req 2, skip 0, read 2
 * |<-- req_len --->|
 * [ write ][ write ]
 * [ read  ][ read  ]
 * |<-- resp_len -->|
 *
 * @param unit - SPI unit
 * @param slave_num - slave number (SS pin index, counted from least significant bit)
 * @param request - request bytes buffer
 * @param response - response bytes buffer
 * @param req_len - number of bytes in the request. Will be right-padded with zeros.
 * @param resp_skip - response bytes to discard before starting to capture them
 * @param resp_len - number of bytes to capture, after discarding resp_skip received bytes
 * @return success
 */
 error_t UU_SPI_Write(Unit *unit, uint8_t slave_num,
                     const uint8_t *request,
                     uint8_t *response,
                     uint32_t req_len,
                     uint32_t resp_skip,
                     uint32_t resp_len);
 /**
 * Write to multiple slaves at once.
 * This is similar to UU_SPI_Write, but performs no read and works only if the device
 * is configured as tx-only.
 *
 * @param unit - SPI unit
 * @param slaves - bitmap of slaves to write (packed bits representing the SSN pins)
 * @param request - request bytes buffer
 * @param req_len - length of the request buffer
 * @return success
 */
 error_t UU_SPI_Multicast(Unit *unit, uint16_t slaves,
                         const uint8_t *request,
                         uint32_t req_len);
 #endif //GEX_F072_UNIT_SPI_H
--- a/utils/error.h
+++ b/utils/error.h
@ -42,6 +42,7 @@
    X(OVERRUN, NULL) /* used in bulk transfer */ \
    X(PROTOCOL_BREACH, NULL) /* eating with the wrong spoon */  \
    X(BAD_UNIT_TYPE, NULL) \
    X(NOT_IMPLEMENTED, NULL) \
    \
    /* VFS user errors (those are meant to be shown to user) */ \
    X(ERROR_DURING_TRANSFER, "Error during transfer") \
@ -57,7 +58,7 @@
    X(BAD_KEY, "Unexpected config key") \
    X(BAD_VALUE, "Bad config value") \
    X(OUT_OF_MEM, "Not enough RAM") \
-    X(RESOURCE_NOT_AVAILABLE, "Required pin / peripheral not available")
+    X(RESOURCE_NOT_AVAILABLE, NULL)
 // Keep in sync with the list error_message
 typedef enum {