Remove now duplicated Win_GParted::display_partitions member (#227)

Now Win_GParted::m_display_device.partitions is an identical copy of
Win_GParted::display_partitions with the same lifetime.  That's wasteful
and pointless.  Therefore remove the later and use the former in it's
place.

Closes #227 - Unable to allocate 1 MiB between partitions when moving to
              the right
This commit is contained in:
Mike Fleetwood 2023-04-20 10:34:45 +01:00 committed by Curtis Gedak
parent e9f3977452
commit e801689680
2 changed files with 50 additions and 55 deletions

View File

@ -207,13 +207,12 @@ private:
//private variables
unsigned int current_device ;
PartitionVector display_partitions; // Copy of current device's partitions with any pending
// operations applied, as currently being shown in the GUI.
const Partition * selected_partition_ptr; // Pointer to the selected partition. (Alias to element
// in Win_GParted::display_partitions[] vector).
const Partition * copied_partition; // NULL or copy of source partition object.
std::vector<Device> devices;
Device m_display_device; // Copy of devices[current_device] with copy of display_partitions.
Device m_display_device; // Copy of devices[current_device] with pending operations
// operations applied to partitions for displaying in the UI.
const Partition * selected_partition_ptr; // Pointer to the selected partition. (Alias to element
// in Win_GParted::m_display_device.partitions[] vector).
const Partition * copied_partition; // NULL or copy of source partition object.
std::vector<Operation *> operations;
//gui stuff

View File

@ -985,9 +985,6 @@ void Win_GParted::Refresh_Visual()
// Data owner: Device Win_GParted::m_display_device
// Lifetime: Valid until the next call to Refresh_Visual().
// Function: Refresh_Visual()
// Data owner: PartitionVector Win_GParted::display_partitions
// Lifetime: Valid until the next call to Refresh_Visual().
// Function: Refresh_Visual()
//
// (3) Loads the disk graphic and partition list with partitions to be shown in
// the GUI. Both classes store pointers pointing back to each partition
@ -1049,15 +1046,12 @@ void Win_GParted::Refresh_Visual()
// Specifically longer than the next call to Refresh_Visual().
// Function: Win_GParted::activate_copy()
display_partitions = devices[current_device].partitions;
//make all operations visible
for ( unsigned int t = 0 ; t < operations .size(); t++ )
if ( operations[ t ] ->device == devices[ current_device ] )
operations[t]->apply_to_visual( display_partitions );
m_display_device = devices[current_device].get_copy_without_partitions();
m_display_device.partitions = display_partitions;
m_display_device = devices[current_device];
for (unsigned int i = 0; i < operations.size(); i++)
if (operations[i]->device == m_display_device)
operations[i]->apply_to_visual(m_display_device.partitions);
hbox_operations .load_operations( operations ) ;
@ -1080,42 +1074,42 @@ void Win_GParted::Refresh_Visual()
Sector largest_unalloc_size = -1 ;
Sector current_size ;
for ( unsigned int t = 0 ; t < display_partitions.size() ; t++ )
for (unsigned int i = 0; i < m_display_device.partitions.size(); i++)
{
if ( copied_partition != NULL && display_partitions[t].get_path() == copied_partition->get_path() )
if (copied_partition != NULL && m_display_device.partitions[i].get_path() == copied_partition->get_path())
{
delete copied_partition;
copied_partition = display_partitions[t].clone();
copied_partition = m_display_device.partitions[i].clone();
}
if (display_partitions[t].fstype == FS_UNALLOCATED)
if (m_display_device.partitions[i].fstype == FS_UNALLOCATED)
{
current_size = display_partitions[t].get_sector_length();
if ( current_size > largest_unalloc_size )
current_size = m_display_device.partitions[i].get_sector_length();
if (current_size > largest_unalloc_size)
{
largest_unalloc_size = current_size;
selected_partition_ptr = & display_partitions[t];
selected_partition_ptr = & m_display_device.partitions[i];
}
}
if ( display_partitions[t].type == TYPE_EXTENDED )
if (m_display_device.partitions[i].type == TYPE_EXTENDED)
{
for ( unsigned int u = 0 ; u < display_partitions[t].logicals.size() ; u ++ )
for (unsigned int j = 0; j < m_display_device.partitions[i].logicals.size(); j++)
{
if ( copied_partition != NULL &&
display_partitions[t].logicals[u].get_path() == copied_partition->get_path() )
if (copied_partition != NULL &&
m_display_device.partitions[i].logicals[j].get_path() == copied_partition->get_path())
{
delete copied_partition;
copied_partition = display_partitions[t].logicals[u].clone();
copied_partition = m_display_device.partitions[i].logicals[j].clone();
}
if (display_partitions[t].logicals[u].fstype == FS_UNALLOCATED)
if (m_display_device.partitions[i].logicals[j].fstype == FS_UNALLOCATED)
{
current_size = display_partitions[t].logicals[u].get_sector_length();
current_size = m_display_device.partitions[i].logicals[j].get_sector_length();
if ( current_size > largest_unalloc_size )
{
largest_unalloc_size = current_size;
selected_partition_ptr = & display_partitions[t].logicals[u];
selected_partition_ptr = & m_display_device.partitions[i].logicals[j];
}
}
}
@ -1123,10 +1117,10 @@ void Win_GParted::Refresh_Visual()
}
// frame visualdisk
drawingarea_visualdisk.load_partitions( display_partitions, devices[current_device].length );
drawingarea_visualdisk.load_partitions(m_display_device.partitions, m_display_device.length);
// treeview details
treeview_detail.load_partitions( display_partitions );
treeview_detail.load_partitions(m_display_device.partitions);
set_valid_operations() ;
@ -1145,19 +1139,19 @@ void Win_GParted::Refresh_Visual()
// Confirms that the pointer points to one of the partition objects in the vector of
// displayed partitions, Win_GParted::display_partitions[].
// Usage: g_assert( valid_display_partition_ptr( my_partition_ptr ) );
// displayed partitions, Win_GParted::m_display_device.partitions[].
// Usage: g_assert(valid_display_partition_ptr(my_partition_ptr));
bool Win_GParted::valid_display_partition_ptr( const Partition * partition_ptr )
{
for ( unsigned int i = 0 ; i < display_partitions.size() ; i++ )
for (unsigned int i = 0; i < m_display_device.partitions.size();i++)
{
if ( & display_partitions[i] == partition_ptr )
if (& m_display_device.partitions[i] == partition_ptr)
return true;
else if ( display_partitions[i].type == TYPE_EXTENDED )
else if (m_display_device.partitions[i].type == TYPE_EXTENDED)
{
for ( unsigned int j = 0 ; j < display_partitions[i].logicals.size() ; j++ )
for (unsigned int j = 0; j < m_display_device.partitions[i].logicals.size(); j++)
{
if ( & display_partitions[i].logicals[j] == partition_ptr )
if (& m_display_device.partitions[i].logicals[j] == partition_ptr)
return true;
}
}
@ -1165,6 +1159,7 @@ bool Win_GParted::valid_display_partition_ptr( const Partition * partition_ptr )
return false;
}
bool Win_GParted::Quit_Check_Operations()
{
if ( operations .size() )
@ -1967,27 +1962,28 @@ void Win_GParted::on_partition_popup_menu( unsigned int button, unsigned int tim
bool Win_GParted::max_amount_prim_reached()
{
int primary_count = 0;
for ( unsigned int i = 0 ; i < display_partitions.size() ; i ++ )
for (unsigned int i = 0; i < m_display_device.partitions.size(); i++)
{
if ( display_partitions[i].type == TYPE_PRIMARY || display_partitions[i].type == TYPE_EXTENDED )
if (m_display_device.partitions[i].type == TYPE_PRIMARY ||
m_display_device.partitions[i].type == TYPE_EXTENDED )
{
primary_count ++;
}
}
//Display error if user tries to create more primary partitions than the partition table can hold.
if ( ! selected_partition_ptr->inside_extended && primary_count >= devices[current_device].max_prims )
if (! selected_partition_ptr->inside_extended && primary_count >= m_display_device.max_prims)
{
Gtk::MessageDialog dialog(
*this,
Glib::ustring::compose( ngettext( "It is not possible to create more than %1 primary partition"
, "It is not possible to create more than %1 primary partitions"
, devices[ current_device ] .max_prims
)
, devices[ current_device ] .max_prims
),
Glib::ustring::compose(ngettext("It is not possible to create more than %1 primary partition",
"It is not possible to create more than %1 primary partitions",
m_display_device.max_prims),
m_display_device.max_prims),
false,
Gtk::MESSAGE_ERROR,
Gtk::BUTTONS_OK,
true ) ;
true);
dialog .set_secondary_text(
_( "If you want more partitions you should first create an extended partition. Such a partition can contain other partitions. Because an extended partition is also a primary partition it might be necessary to remove a primary partition first.") ) ;
@ -2014,12 +2010,12 @@ void Win_GParted::activate_resize()
return;
}
PartitionVector * display_partitions_ptr = &display_partitions;
PartitionVector* display_partitions_ptr = & m_display_device.partitions;
if ( selected_partition_ptr->type == TYPE_LOGICAL )
{
int index_extended = find_extended_partition( display_partitions );
int index_extended = find_extended_partition(m_display_device.partitions);
if ( index_extended >= 0 )
display_partitions_ptr = &display_partitions[index_extended].logicals;
display_partitions_ptr = & m_display_device.partitions[index_extended].logicals;
}
Partition * working_ptn;
@ -2414,7 +2410,7 @@ void Win_GParted::activate_new()
// Check if an extended partition already exist; so that the dialog can
// decide whether to allow the creation of the only extended partition
// type or not.
bool any_extended = ( find_extended_partition( display_partitions ) >= 0 );
bool any_extended = find_extended_partition(m_display_device.partitions) >= 0;
Dialog_Partition_New dialog(m_display_device,
*selected_partition_ptr,
any_extended,